
Article 1 
Directive 97/68/EC is amended as follows:

1)) the following indents shall be added to Article 2:
“
— "inland waterway vessel" shall mean a vessel intended for use on inland waterways having a length of 20 metres or more and having a volume of 100 m3 or more according to the formula defined in Annex I, Section 2, point 2.8a, or tugs or pusher craft having been built to tow or to push or to move alongside vessels of 20 metres or more,
This definition does not include:

— vessels intended for passenger transport carrying no more that 12 people in addition to the crew,
— recreational craft with a length of less than 24 metres (as defined in Article 1(2) of Directive 94/25/EC of the European Parliament and of the Council of 16 June 1994 on the approximation of the laws, regulations and administrative provisions of the Member States relating to recreational craft),
— service craft belonging to supervisory authorities,
— fire-service vessels,
— naval vessels,
— fishing vessels on the fishing vessels register of the Community,
— sea-going vessels, including sea-going tugs and pusher craft operating or based on tidal waters or temporarily on inland waterways, provided that they carry a valid navigation or safety certificate as defined in Annex I, Section 2, point 2.8b.
— "Original equipment manufacturer (OEM)" shall mean a manufacturer of a type of non-road mobile machine,
— "Flexibility scheme" shall mean the procedure allowing an engine manufacturer to place on the market, during the period between two successive stages of limit values, a limited number of engines, to be installed in non-road mobile machinery, that only comply with the previous stage of emission limit values.”
2)) Article 4 shall be amended as follows:

((a)) The following text shall be added at the end of paragraph 2:
“Annex VIII shall be amended in accordance with the procedure referred to in Article 15 ”.
((b)) The following paragraph shall be added:
“
6. Compression ignition engines for use other than in propulsion of locomotives, railcars and inland waterway vessels may be placed on the market under a flexible scheme in accordance with the procedure referred to in Annex XIII in addition to paragraphs 1 to 5
”.
3)) In Article 6 the following paragraph shall be added:
“
5. Compression ignition engines placed on the market under a "flexible scheme" shall be labelled in accordance with Annex XIII.
”
4)) The following Article shall be inserted after Article 7:
“
Article 7a 

1. The following provisions shall apply to engines to be installed in inland waterway vessels. Paragraphs 2 and 3 shall not apply until the equivalence between the requirements established by this Directive and those established in the framework of the Mannheim Convention for the Navigation of the Rhine is recognised by the Central Commission of Navigation on Rhine (hereinafter: CCNR) and the Commission is informed thereof.
2. Until 30 June 2007, Member States may not refuse the placing on the market of engines which meet the requirements established by CCNR stage I, the emission limit values for which are set out in Annex XIV.
3. As from 1 July 2007 and until the entry into force of a further set of limit values which would result from further amendments to this Directive, Member States may not refuse the placing on the market of engines which meet the requirements established by CCNR stage II, the emission limit values for which are set out in Annex XV.
4. In accordance with the procedure referred to in Article 15, Annex VII shall be adapted to integrate the additional and specific information which may be required as regards the type approval certificate for engines to be installed in inland waterway vessels.
5. For the purposes of this Directive, as far as inland waterway vessels are concerned, any auxiliary engine with a power of more than 560 kW shall be subject to the same requirements as propulsion engines.”
(5)) Article 8 shall be amended as follows:

((a)) The title shall be replaced by "Placing on the market":
((b)) Paragraph 1 shall be replaced by the following:
“
1. Member States may not refuse the placing on the market of engines, whether or not already installed in machinery, which meet the requirements of this Directive.
”
((c)) The following paragraph shall be inserted after paragraph 2:
“
2a. Member States shall not issue the Community Inland Water Navigation certificate established by Council Directive 82/714/EC of 4 October 1982 laying down technical requirements for inland waterway vessels to any vessels whose engines do not meet the requirements of this Directive.
”
6)) Article 9 shall be amended as follows:

((a)) The introductory phrase of paragraph 3 shall be replaced by the following:
“Member States shall refuse to grant type-approval for an engine type or engine family and to issue the document as described in Annex VII and shall refuse to grant any other type-approval for non-road mobile machinery, in which an engine, not already placed on the market, is installed”.
((b)) The following paragraphs shall be inserted after paragraph 3:
“
3a. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII, and shall refuse to grant any other type-approval for non-road mobile machinery in which an engine, not already placed on the market, is installed:


— H: after 30 June 2005 for engines - other than constant speed engines - of a power output: 130 kW ≤ P ≤ 560 kW,
— I: after 31 December 2005 for engines — other than constant speed engines — of a power output: 75 kW≤ P < 130 kW,
— J: after 31 December 2006 for engines — other than constant speed engines — of a power output: 37 kW ≤ P < 75kW,
— K: after 31 December 2005 for engines — other than constant speed engines — of a power output: 19 kW ≤ P < 37 kW,

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values as set out in the table in section 4.1.2.4. of Annex I.

3b. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII, and shall refuse to grant any other type-approval for non-road mobile machinery in which an engine, not already placed on the market, is installed:


— Constant speed H engines: after 31 December 2009 for engines of a power output: 130 kW ≤ P < 560 kW,
— Constant speed I engines: after 31 December 2009 for engines of a power output: 75 kW ≤ P < 130 kW,
— Constant speed J engines: after 31 December 2010 for engines of a power output: 37 kW ≤ P < 75 kW,
— Constant speed K engines: after 31 December 2009 for engines of a power output: 19 kW ≤ P < 37 kW,

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values set out in the table in Section 4.1.2.4. of Annex I.

3c. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII, and shall refuse to grant any other type-approval for non-road mobile machinery in which an engine, not already placed on the market, is installed:


— L: after 31 December 2009 for engines — other than constant speed engines — of a power output: 130 kW ≤ P < 560 kW,
— M: after 31 December 2010 for engines — other than constant speed engines — of a power output: 75 kW ≤ P < 130 kW,
— N: after 31 December 2010 for engines — other than constant speed engines — of a power output: 56 kW ≤ P < 75 kW,
— P: after 31 December 2011 for engines — other than constant speed engines — of a power output: 37 kW ≤ P < 56 kW,

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values set out in the table in Section 4.1.2.5. of Annex I.

3d. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII, and shall refuse to grant any other type-approval for non-road mobile machinery in which an engine, not already placed on the market, is installed:


— Q: after 31 December 2012 for engines — other than constant speed engines — of a power output: 130 kW ≤ P ≤ 560 kW,
— R: after 30 September 2013 for engines — other than constant speed engines — of a power output: 56 kW ≤ P < 130 kW,

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values set out in the table in Section 4.1.2.6. of Annex I.

3e. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII:

Vl:1: after 31 December 2005 for engines of power output at or above 37 kW and swept volume below 0.9 litres per cylinder,

Vl:2: after 30 June 2005 for engines with swept volume at or above 0.9 but below 1.2 litres per cylinder,

Vl:3: after 30 June 2005 for engines with swept volume at or above 1.2 but below 2.5 litres per cylinder and an engine power output of: 37 kW ≤ P < 75 kW,

VI:4: after 31 December 2006 for engines with swept volume at or above 2.5 but below 5 litres per cylinder,

V2: after 31 December 2007 for engines with swept volume at or above 5 litres per cylinder,

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values as set out in the table in section 4.1.2.4 of Annex I.

3f. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII:


— RC A: after 30 June 2005 for engines of power output above 130 kW
where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values as set out in the table in section 4.1.2.4 of Annex I.

3g. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII:


— RC B: after 31 December 2010 for engines of power output above 130 kW

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values as set out in the table in section 4.1.2.5 of Annex I.

3h. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII:


— RL A: after 31 December 2005 for engines of power output: 130 kW≤ P ≤ 560 kW
— RH A: after 31 December 2007 for engines of power output: 560 kW < P

where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values as set out in the table in section 4.1.2.4 of Annex I. The provisions of this paragraph shall not apply to the engine types and families referred to where a contract has been entered into to purchase the engine before ... and provided that the engine is placed on the market no later than two years after the applicable date for the relevant category of locomotive.

3i. 
Member States shall refuse to grant type-approval for the following engine types or families and to issue the document as described in Annex VII:


— R B: after 31 December 2010 for engines of power output above 130 kW
where the engine fails to meet the requirements specified in this Directive and where the emissions of particulate and gaseous pollutants from the engine do not comply with the limit values as set out in the table in section 4.1.2.5 of Annex I. The provisions of this paragraph shall not apply to the engine types and families referred to where a contract has been entered into to purchase the engine before ... and provided that the engine is placed on the market no later than two years after the applicable date for the relevant category of locomotives.
”
((c)) The title of paragraph 4 shall be replaced by the following:
“PLACING ON THE MARKET: ENGINE PRODUCTION DATES”
((d)) The following paragraph shall be inserted:
“
4a. 
Stage III A other than constant speed engines


— category H: 31 December 2005
— category I: 31 December 2006
— category J: 31 December 2007
— category K: 31 December 2006

Stage III A inland waterway vessel engines


— category V 1: 1: 31 December 2006
— category V 1:2: 31 December 2006
— category V 1:3: 31 December 2006
— category V1:4: 31 December 2008
— categories V2: 31 December 2008.

Stage III A constant speed engines


— category H: 31 December 2010
— category I: 31 December 2010
— category J: 31 December 2011
— category K: 31 December 2010

Stage III A railcar engines


— category RC A: 31 December 2005

Stage III A locomotive engines


— category RL A:31 December 2006
— category RH A:31 December 2008

Stage III B other than constant speed engines


— category L: 31 December 2010
— category M: 31 December 2011
— category N: 31 December 2011
— category P: 31 December 2012

Stage III B railcar engines


— category RC B: 31 December 2011

Stage III B locomotive engines


— category R B: 31 December 2011

Stage IV other than constant speed engines


— category Q: 31 December 2013
— category R: 30 September 2014

For each category, the above requirements shall be postponed by two years in respect of engines with a production date prior to the said date.

The permission granted for one stage of emission limit values shall be terminated with effect from the mandatory implementation of the next stage of limit values.
”
((e)) The following paragraph shall be added:
“
4b. 
For engine types or engine families meeting the limit values set out in the table in section 4.1.2.4, 4.1.2.5 and 4.1.2.6 of Annex I before the dates laid down in paragraph 4 of this Article, Member States shall allow special labelling and marking to show that the equipment concerned meets the required limit values before the dates laid down.
”
(7)) Article 10 shall be amended as follows:

((a)) Paragraphs 1 and 1 a shall be replaced by the following:
“
1. 

— engines for use by the armed services,
— engines exempted in accordance with paragraphs la and 2,
— engines for use in machines intended primarily for the launch and recovery of lifeboats,
— engines for use in machines intended primarily for the launch and recovery of beach launched vessels.

1a. 
The text "REPLACEMENT ENGINE" shall be attached to a label on the engine or inserted into the owner's manual.
”
((b)) The following paragraphs shall be added:
“
5. Engines may be placed on the market under a "flexible scheme" in accordance with the provisions in Annex XIII.

6. Paragraph 2 shall not apply to propulsion engines to be installed in inland waterway vessels.

7. Member States shall permit the placing on the market of engines, as defined under A(i) and A(ii) of Annex I, under the "flexibility scheme" in accordance with the provisions in Annex XIII.
”
8)) The Annexes shall be amended as follows:

((a)) Annexes I, III, V, VII and XII shall be amended in accordance with Annex I to this Directive;
((b)) Annex VI shall be replaced by the text in Annex II to this Directive;
((c)) A new Annex XIII as set out in Annex III to this Directive shall be added;
((d)) A new Annex XIV as set out in Annex IV to this Directive shall be added;
((e)) A new Annex XV as set out in Annex IV to this Directive shall be added;
and the list of the existing Annexes shall be amended acordingly.
Article 2 
The Commission shall, not later than 31 December 2007:

((a)) re-assess its non-road emission inventory estimates and specifically examine potential cross-checks and correction factors;
((b)) consider the available technology, including the cost/benefits, with a view to confirming Stage III B and IV limit values and evaluating the possible need for additional flexibilities, exemptions or later introduction dates for certain types of equipment or engines and taking into account engines installed in non-road mobile machinery used in seasonal applications;
((c)) evaluate the application of test cycles for engines in railcars and locomotives and, in the case of engines in locomotives, the cost and benefits of a further reduction of emission limit values in view of the application of NOx after-treatment technology;
((d)) consider the need to introduce a further set of limit values for engines to be used in inland waterway vessels taking into account in particular the technical and economic feasibility of secondary abatement options in this application;
((e)) consider the need to introduce emission limit values for engines below 19 kW and above 560 kW;
((f)) consider the availability of fuels required by the technologies used to meet the Stage IIIB and IV standards levels;
((g)) consider the engine operating conditions under which the maximum permissible percentages by which the emission limit values laid down in Section 4.1.2.5 and 4.1.2.6 of Annex I may be exceeded and present proposals as appropriate to technically adapt the Directive in accordance with the procedure referred to in Article 15 of Directive 97/68/EC;
((h)) assess the need for a system for "in-use compliance" and examine possible options for its implementation;
((i)) consider detailed rules to prevent "cycle beating" and cycle by-pass;
and submit, where appropriate, proposals to the European Parliament and the Council.
Article 3 

1. Member States shall bring into force the laws, regulations and administrative provisions necessary to comply with this Directive by .... They shall forthwith inform the Commission thereof.When Member States adopt those measures, they shall contain a reference to this Directive or shall be accompanied by such a reference on the occasion of their official publication. The methods of making such reference shall be laid down by Member States.
2. Member States shall communicate to the Commission the text of the main provisions of national law which they adopt in the field covered by this Directive.
Article 4 
Member States shall determine the sanctions applicable to breaches of the national provisions adopted pursuant to this Directive and shall take all necessary measures for their implementation. The sanctions determined must be effective, proportionate and dissuasive. Member States shall notify these provisions to the Commission by ..., and shall notify any subsequent modifications thereof as soon as possible.
Article 5 
This Directive shall enter into force on the twentieth day following that of its publication in the Official Journal of the European Union.
Article 6 
This Directive is addressed to the Member States.
Done at Strasbourg, 21 April 2004
For the European Parliament
The President
P. COX
For the Council
The President
D. ROCHE
ANNEX I
1. 

1)) SECTION 1 SHALL BE AMENDED AS FOLLOWS:

((a)) Point A shall be replaced by the following:
“ A. 

((i)) a C.I. engine having a net power in accordance with section 2.4 that is higher than or equal to 19 kW but not more than 560 kW and that is operated under intermittent speed rather than a single constant speed;
or
((ii)) a C.I. engine having a net power in accordance with section 2.4 that is higher than or equal to 19 kW but not more than 560 kW and that is operated under constant speed. Limits only apply from 31 December 2006;
or
((iii)) a petrol fuelled S.I. engine having a net power in accordance with section 2.4 of not more than 19 kW;
or
((iv)) engines designed for the propulsion of railcars, which are self propelled on-track vehicles specifically designed to carry goods and/or passengers;
or
((v)) engines designed for the propulsion of locomotives which are self-propelled pieces of on-track equipment designed for moving or propelling cars that are designed to carry freight, passengers and other equipment, but which themselves are not designed or intended to carry freight, passengers (other than those operating the locomotive) or other equipment. Any auxiliary engine or engine intended to power equipment designed to perform maintenance or construction work on the tracks is not classified under this paragraph but under A(i).
”;
((b)) Point B shall be replaced by the following:
“ "B. Ships, except vessels intended for use on inland waterways
”;
((c)) Point C shall be deleted
2)) Section 2 shall be amended as follows:

((a)) The following shall be inserted:
“ 2.8a: volume of 100m3 or more with regard to a vessel intended for use on inland waterways means its volume calculated on the formula LxBxT, "L" being the maximum length of the hull, excluding rudder and bowsprit, "B" being the maximum breadth of the hull in metres, measured to the outer edge of the shell plating (excluding paddle wheels, rubbing strakes, etc.) and "T" being the vertical distance between the lowest moulded point of the hull or the keel and the maximum draught line.
 2.8b: 

((a)) a certificate proving conformity with the 1974 International Convention for the Safety of Life at Sea (SOLAS), as amended, or equivalent, or
((b)) a certificate proving conformity with the 1966 International Convention on Load Lines, as amended, or equivalent, and an IOPP certificate proving conformity with the 1973 International Convention for the Prevention of Pollution from Ships (MARPOL), as amended.
 2.8c: Defeat device shall mean a device which measures, senses or responds to operating variables for the purpose of activating, modulating, delaying or deactivating the operation of any component or function of the emission control system such that the effectiveness of the control system is reduced under conditions encountered during the normal non-road mobile machinery use unless the use of such a device is substantially included in the applied emission test certification procedure.
 2.8d: Irrational control strategy shall mean any strategy or measure that, when the non-road mobile machinery is operated under normal conditions of use, reduces the effectiveness of the emission control system to a level below that expected in the applicable emission test procedures.
”
((b)) The following section shall be inserted:
“ 2.17 test cycle shall mean a sequence of test points, each with a defined speed and torque, to be followed by the engine under steady state (NRSC test) or transient operating conditions (NRTC test);
”
((c)) Current Section 2.17 shall be renumbered 2.18 and be replaced by the following:
“ 2.18.  2.18.1. 

Symbol Unit Term
A/Fst - Stoichiometric air/fuel ratio
AP m2 Cross sectional area of the isokinetic sampling probe
AT m2 Cross sectional area of the exhaust pipe
Aver  Weighted average values for:
 m3/h - volume flow
 kg/h - mass flow
C1 - Carbon 1 equivalent hydrocarbon
Cd - Discharge coefficient of the SSV
Conc ppm Vol% Concentration (with suffix of the component nominating)
Concc ppm Vol% Background corrected concentration
Concd ppm Vol% Concentration of the pollutant measured in the dilution air
Conce ppm Vol% Concentration of the pollutant measured in the diluted exhaust gas
d m Diameter
DF - Dilution factor
fa - Laboratory atmospheric factor
GAIRD kg/h Intake air mass flow rate on dry basis
GAIRW kg/h Intake air mass flow rate on wet basis
GDILW kg/h Dilution air mass flow rate on wet basis
GEDFW kg/h Equivalent diluted exhaust gas mass flow rate on wet basis
GEXHW kg/h Exhaust gas mass flow rate on wet basis
GFUEL kg/h Fuel mass flow rate
GSE kg/h Sampled exhaust mass flow rate
GT cm3/min Tracer gas flow rate
GTOTW kg/h Diluted exhaust gas mass flow rate on wet basis
Ha g/kg Absolute humidity of the intake air
Hd g/kg Absolute humidity of the dilution air
HREF g/kg Reference value of absolute humidity (10,71 g/kg)
i - Subscript denoting an individual mode (for NRSC test)or an instananeous value (for NRTC test)
KH - Humidity correction factor for NOx
Kp - Humidity correction factor for particulate
KV - CFV calibration function
KW,a - Dry to wet correction factor for the intake air
KW,d - Dry to wet correction factor for the dilution air
KW,e - Dry to wet correction factor for the diluted exhaust gas
KW,r - Dry to wet correction factor for the raw exhaust gas
L % Percent torque related to the maximum torque for the test speed
Md mg Particulate sample mass of the dilution air collected
MDIL kg Mass of the dilution air sample passed through the particulate sampling filters
MEDFW kg Mass of equivalent diluted exhaust gas over the cycle
MEXHW kg Total exhaust mass flow over the cycle
Mf mg Particulate sample mass collected
Mf,p mg Particulate sample mass collected on primary filter
Mf,b mg Particulate sample mass collected on back-up filter
Mgas g Total mass of gaseous pollutant over the cycle
MPT g Total mass of particulate over the cycle
MSAM kg Mass of the diluted exhaust sample passed through the particulate sampling filters
MSE kg Sampled exhaust mass over the cycle
MSEC kg Mass of secondary dilution air
MTOT kg Total mass of double diluted exhaust over the cycle
MTOTW kg Total mass of diluted exhaust gas passing the dilution tunnel over the cycle on wet basis
MTOTW,I kg Instantaneous mass of diluted exhaust gas passing the dilution tunnel on wet basis
mass g/h Subscript denoting emissions mass flow (rate)
NP - Total revolutions of PDP over the cycle
nref min-1 Reference engine speed for NRTC test
n.sp s-2 Derivative of the engine speed
P kW Power, brake uncorrected
p1 kPa Pressure drop below atmospheric at the pump inlet of PDP
PA kPa Absolute pressure
Pa kPa Saturation vapour pressure of the engine intake air (ISO 3046: psy=PSY test ambient)
PAE kW Declared total power absorbed by auxiliaries fitted for the test which are not required by paragraph 2.4 of this Annex
PB kPa Total atmospheric pressure (ISO 3046:Px=PX Site ambient total pressurePy=PY Test ambient total pressure)
Pd kPa Saturation vapour pressure of the dilution air
PM kW Maximum power at the test speed under test conditions (see Annex VII, Appendix 1)
Pm kW Power measured on test bed
ps kPa Dry atmospheric pressure
q - Dilution ratio
Qs m3/s CVS volume flow rate
r - Ratio of the SSV throat to inlet absolute, static pressure
r  Ratio of cross sectional areas of isokinetic probe and exhaust pipe
Ra % Relative humidity of the intake air
Rd % Relative humidity of the dilution air
Re - Reynolds number
Rf - FID response factor
T K Absolute temperature
t s Measuring time
Ta K Absolute temperature of the intake air
TD K Absolute dew point temperature
Tref K Reference temperature of combustion air: (298 K)
Tsp N·m Demanded torque of the transient cycle
t10 s Time between step input and 10% of final reading
t50 s Time between step input and 50% of final reading
t90 s Time between step input and 90% of final reading
Δti s Time interval for instantaneous CFV flow
V0 m3/rev PDP volume flow rate at actual conditions
Wact kWh Actual cycle work of NRTC
WF - Weighting factor
WFE - Effective weighting factor
Xo m3/rev Calibration function of PDP volume flow rate
ΘD kg·m2 Rotational inertia of the eddy-current dynamometer
ß - Ratio of the SSV throat diameter, d, to the inlet pipe inner diameter
λ - Relative air/fuel ratio, actual A/F divided by stoichiometric A/F
ρEXH kg/m3 Density of the exhaust gas
 2.18.2. 
CH4MethaneC3H8PropaneC2H6EthaneCOCarbon monoxideCO2Carbon dioxideDOPDi-octylphthalateH2OWaterHCHydrocarbonsNOxOxides of nitrogenNONitric oxideNO2Nitrogen dioxideO2OxygenPTParticulatesPTFEPolytetrafluoroethylene
 2.18.3. 
CFVCritical Flow VenturiCLDChemiluminescent detectorCICompression IgnitionFIDFlame Ionisation DetectorFSFull scaleHCLDHeated Chemiluminescent DetectorHFIDHeated Flame Ionisation DetectorNDIRNon-Dispersive Infrared AnalyserNGNatural GasNRSCNon-Road Steady CycleNRTCNon-Road Transient CyclePDPPositive Displacement PumpSISpark IgnitionSSVSub-Sonic Venturi
”
3)) Section 3 shall be amended as follows:

((a)) The following section shall be inserted:
“ 3.1.4. labels in accordance with Annex XIII, if the engine is placed on the market under flexible scheme provisions.
”
4)) Section 4 is amended as follows:

((a)) At the end of section 4.1.1. the following shall be added:
“All engines that expel exhaust gases mixed with water shall be equipped with a connection in the engine exhaust system that is located downstream of the engine and before any point at which the exhaust contacts water (or any other cooling/scrubbing medium) for the temporary attachment of gaseous or particulate emissions sampling equipment. It is important that the location of this connection allows a well mixed representative sample of the exhaust. This connection shall be internally threaded with standard pipe threads of a size not larger than one-half inch, and shall be closed by a plug when not in use (equivalent connections are allowed).”
((b)) The following section shall be added:
“ 4.1.2.4. 
Engines for use in other applications than propulsion of inland waterway vessels, locomotives and railcars:


Category: Net power(P)(kW) Carbon monoxide(CO)(g/kWh) Sum of hydrocarbons and oxides of nitrogen(HC+NOx)(g/kWh) Particulates(PT)(g/kWh)
H: 130 kW ≤ P ≤ 560 kW 3,5 4,0 0,2
I:75 kW ≤ P < 130 kW 5,0 4,0 0,3
J: 37 kW ≤ P <75 kW 5,0 4,7 0,4
K: 19 kW ≤ P < 37 kW 5,5 7,5 0,6


Category: swept volume/net power(SV/P)(litres per cylinder/kW) Carbon monoxide(CO)(g/kWh) Sum of hydrocarbons and oxides of nitrogen(HC+NOx)(g/kWh) Particulates(PT)(g/kWh)
V1:1 SV < 0,9 and P ≥ 37 kW 5.0 7.5 0.40
V1:2 0,9≤SV< 1,2 5.0 7.2 0.30
V1:3 1,2≤SV< 2,5 5.0 7.2 0.20
V1:4 2,5≤SV< 5 5.0 7.2 0.20
V2:1 5≤SV<15 5.0 7.8 0.27
V2:2 15≤SV< 20 and P < 3300 kW 5.0 8.7 0.50
V2:3 15≤SV< 20 and P ≥ 3300 kW 5.0 9.8 0.50
V2:4 20≤SV< 25 5,0 9.8 0.50
V2:5 25≤SV< 30 5,0 11.0 0.50


Category: Net power(P)(kW) Carbon monoxide(CO)(g/kWh) Sum of hydrocarbons and oxides of nitrogen(HC+NOx)(g/kWh) Particulates(PT)(g/kWh)
RL A: 130 kW ≤ P ≤ 560 kW 3,5 4,0 0,2
 Carbon monoxide(CO)(g/kWh) Hydrocarbons(HC)(g/kWh) Oxides of nitrogen(NOx)(g/kWh) Particulates(PT)(g/kWh)
RH A: P > 560 kW 3,5 0,5 6,0 0,2
RH A Engines with P > 2000 kW and SV> 5 l/cylinder 3,5 0,4 7,4 0,2


Category: net power (P) (kW) Carbon monoxide(CO)(g/kWh) Sum of hydrocarbons and oxides of nitrogen(HC+NOx)(g/kWh) Particulates(PT)(g/kWh)
RC A: 130 kW < P 3,5 4,0 0,20


”
((c)) The following section shall be inserted:
 "4.1.2.5. 

Category: net power(P)(kW) Carbon monoxide(CO)(g/kWh) Hydrocarbons(HC)(g/kWh) Oxides of nitrogen(Nox)(g/kWh) Particulates(PT)(g/kWh)
L: 130 kW ≤ P ≤ 560 kW 3,5 0,19 2,0 0,025
M: 75 kW ≤ P < 130 kW 5,0 0,19 3,3 0,025
N: 56 kW ≤ P < 75 kW 5,0 0,19 3,3 0,025
  Sum of hydrocarbons and oxides ofnitrogen(HC+NOx)(g/kWh) 
P: 37 kW ≤ P < 56 kW 5,0 4,7 0,025


Category: net power(P)(kW) Carbon monoxide(CO)(g/kWh) Hydrocarbons(HC)(g/kWh) Oxides of nitrogen(NOx)(g/kWh) Particulates(PT)(g/kWh)
RC B: 130 kW < P 3,5 0.19 2,0 0,025


Category: Net power(P)(kW) Carbon monoxide(CO)(g/kWh) Sum of hydrocarbons and oxides of nitrogen(HC+NOx)(g/kWh) Particulates(PT)(g/kWh)
R B: 130 kW < P 3,5 4,0 0,025

((d)) The following section shall be inserted after the new section 4.1.2.5:
“ 4.1.2.6. 

Category: Net power(P)(kW) Carbon monoxide(CO)(g/kWh) Hydrocarbons(HC)(g/kWh) Oxides of nitrogen(NOx)(g/kWh) Particulates(PT)(g/kWh)
Q: 130 kW ≤ P ≤ 560 kW 3,5 0,19 0,4 0,025
R: 56 kW ≤ P < 130 kW 5,0 0,19 0,4 0,025


”
((e)) The following section shall be inserted:
“ 4.1.2.7. 
In the case of limit values standards contained in sections 4.1.2.5 and 4.1.2.6, under all randomly selected load conditions, belonging to a definite control area and with the exception of specified engine operating conditions which are not subject to such a provision, the emissions sampled during a time duration as small as 30 s shall not exceed by more than 100% the limit values of the above tables. The control area to which the percentage not to be exceeded shall apply and the excluded engine operating conditions shall be defined in accordance with the procedure referred to in Article 15.
”
((f)) Section 4.1.2.4 shall be renumbered to 4.1.2.8

2. 

1)) Section 1 shall be amended as follows:

((a)) The following shall be added to section 1.1.:
“Two test cycles are described that shall be applied according to the provisions of Annex I, Section 1:
— the NRSC (Non-Road Steady Cycle) which shall be used for stages I, II and IIIA and for constant speed engines as well as for stages IIIB and IV in the case of gaseous pollutants,
— the NRTC (Non-Road Transient Cycle) which shall be used for the measurement of particulate emissions for stages IIIB and IV and for all engines but constant speed engines. By the choice of the manufacturer this test can be used also for stage IIIA and for the gaseous pollutants in stages IIIB and IV.
— For engines intended to be used in inland waterway vessels the ISO test procedure as specified by ISO 8178-4:2002 [E] and IMO MARPOL 73/78, Annex VI (NOx Code) shall be used.
— For engines intended for propulsion of railcars an NRSC shall be used for the measurement of gaseous and particulate pollutants for stage III A and for stage III B.
— For engines intended for propulsion of locomotives an NRSC shall be used for the measurement of gaseous and particulate pollutants for stage III A and for stage III B.”
((b)) The following section shall be added:
“ 1.3. 
The engine exhaust emissions to be measured include the gaseous components (carbon monoxide, total hydrocarbons and oxides of nitrogen), and the particulates. Additionally, carbon dioxide is often used as a tracer gas for determining the dilution ratio of partial and full flow dilution systems. Good engineering practice recommends the general measurement of carbon dioxide as an excellent tool for the detection of measurement problems during the test run.
 1.3.1. 
During a prescribed sequence of operating conditions, with the engines warmed up, the amounts of the above exhaust emissions shall be examined continuously by taking a sample from the raw exhaust gas. The test cycle consists of a number of speed and torque (load) modes, which cover the typical operating range of diesel engines. During each mode, the concentration of each gaseous pollutant, exhaust flow and power output shall be determined, and the measured values weighted. The particulate sample shall be diluted with conditioned ambient air. One sample over the complete test procedure shall be taken and collected on suitable filters.

Alternatively, a sample shall be taken on separate filters, one for each mode, and cycle-weighted results computed.

The grams of each pollutant emitted per kilowatt -hour shall be calculated as described in Appendix 3 to this Annex.
 1.3.2. 
The prescribed transient test cycle, based closely on the operating conditions of diesel engines installed in non-road machinery, is run twice:


— The first time (cold start) after the engine has soaked to room temperature and the engine coolant and oil temperatures, after treatment systems and all auxiliary engine control devices are stabilised between 20 and 30oC.
— The second time (hot start) after a twenty-minute hot soak that commences immediately after the completion of the cold start cycle.

During this test sequence the above pollutants shall be examined. Using the engine torque and speed feedback signals of the engine dynamometer, the power shall be integrated with respect to the time of the cycle, resulting in the work produced by the engine over the cycle. The concentrations of the gaseous components shall be determined over the cycle, either in the raw exhaust gas by integration of the analyzer signal in accordance with Appendix 3 to this Annex, or in the diluted exhaust gas of a CVS full-flow dilution system by integration or by bag sampling in accordance with Appendix 3 to this Annex. For particulates, a proportional sample shall be collected from the diluted exhaust gas on a specified filter by either partial flow dilution or full-flow dilution. Depending on the method used, the diluted or undiluted exhaust gas flow rate shall be determined over the cycle to calculate the mass emission values of the pollutants. The mass emission values shall be related to the engine work to give the grams of each pollutant emitted per kilowatt-hour.

Emissions (g/kWh) shall be measured during both the cold and hot start cycles. Composite weighted emissions shall be computed by weighting the cold start results 10% and the hot start results 90%. Weighted composite results shall meet the standards.

Prior to the introduction of the cold/hot composite test sequence, the symbols (Annex I, section 2.18) the test sequence (Annex III) and calculation equations (Annex III, Appendix III) shall be modified in accordance with the procedure referred to in Article 15.
”
2)) Section 2 shall be amended as follows:

((a)) Section 2.2.3 shall be replaced by the following:
“ 2.2.3. 
The charge air temperature shall be recorded and, at the declared rated speed and full load, shall be within ± 5 K of the maximum charge air temperature specified by the manufacturer. The temperature of the cooling medium shall be at least 293 K (20oC).

If a test shop system or external blower is used, the charge air temperature shall be set to within ± 5 K of the maximum charge air temperature specified by the manufacturer at the speed of the declared maximum power and full load. Coolant temperature and coolant flow rate of the charge air cooler at the above set point shall not be changed for the whole test cycle. The charge air cooler volume shall be based upon good engineering practice and typical vehicle/machinery applications.

Optionally, the setting of the charge air cooler may be done in accordance with SAE J 1937 as published in January 1995.
”
((b)) The text under section 2.3 shall be replaced by the following:
“The test engine shall be equipped with an air inlet system presenting an air inlet restriction within ± 300 Pa of the value specified by the manufacturer for a clean air cleaner at the engine operating conditions as specified by the manufacturer, which result in maximum air flow. The restrictions are to be set at rated speed and full load. A test shop system may be used, provided it duplicates actual engine operating conditions.”
((c)) The text under section 2.4 Engine exhaust system shall be replaced by the following:
“The test engine shall be equipped with an exhaust system with exhaust back pressure within ± 650 Pa of the value specified by the manufacturer at the engine operating conditions resulting in maximum declared power.If the engine is equipped with an exhaust after-treatment device, the exhaust pipe shall have the same diameter as found in-use for at least 4 pipe diameters upstream to the inlet of the beginning of the expansion section containing the after-treatment device. The distance from the exhaust manifold flange or turbocharger outlet to the exhaust after-treatment device shall be the same as in the machine configuration or within the distance specifications of the manufacturer. The exhaust backpressure or restriction shall follow the same criteria as above, and may be set with a valve. The aftertreatment container may be removed during dummy tests and during engine mapping, and replaced with an equivalent container having an inactive catalyst support.”
((d)) Section 2.8 shall be deleted.
3)) Section 3 shall be amended as follows:

((a)) The title of section 3 shall be replaced by:
“
3.”
((b)) The following section shall be inserted:
“ 3.1. 
The basis of specific emissions measurement is uncorrected brake power according to ISO 14396: 2002.

Certain auxiliaries, which are necessary only for the operation of the machine and may be mounted on the engine, should be removed for the test. The following incomplete list is given as an example:


— air compressor for brakes
— power steering compressor
— air conditioning compressor
— pumps for hydraulic actuators.

Where auxiliaries have not been removed, the power absorbed by them at the test speeds shall be determined in order to calculate the dynamometer settings, except for engines where such auxiliaries form an integral part of the engine (e.g. cooling fans for air cool engines).

The settings of inlet restriction and exhaust pipe backpressure shall be adjusted to the manufacturer's upper limits, in accordance with sections 2.3 and 2.4.

The maximum torque values at the specified test speeds shall be determined by experimentation in order to calculate the torque values for the specified test modes. For engines which are not designed to operate over a range on a full load torque curve, the maximum torque at the test speeds shall be declared by the manufacturer.

The engine setting for each test mode shall be calculated using the formula:
S = PM + PAExL100 - PAE
If the ratio,
PAEPM ≥ 0,03
the value of PAE may be verified by the technical authority granting type approval.
”
((c)) Current sections 3.1 - 3.3 shall be renumbered 3.2 - 3.4
((d)) Current section 3.4 shall be renumbered 3.5 and replaced by the following:
“ 3.5. 
The particulate sampling system shall be started and running on bypass for the single filter method (optional for the multiple filter method). The particulate background level of the dilution air may be determined by passing dilution air through the particulate filters. If filtered dilution air is used, one measurement may be done at any time prior to, during, or after the test. If the dilution air is not filtered, the measurement must be done on one sample taken for the duration of the test.

The dilution air shall be set to obtain a filter face temperature between 315 K (42oC) and 325 K (52oC) at each mode. The total dilution ratio shall not be less than four.

NOTE: For steady-state procedure, the filter temperature may be kept at or below the maximum temperature of 325 K (52oC) instead of respecting the temperature range of 42oC - 52oC.

For the single and multiple filter methods, the sample mass flow rate through the filter shall be maintained at a constant proportion of the dilute exhaust mass flow rate for full flow systems for all modes. This mass ratio shall be within ± 5% with respect to the averaged value of the mode, except for the first 10 seconds of each mode for systems without bypass capability. For partial flow dilution systems with single filter method, the mass flow rate through the filter shall be constant within ± 5% with respect to the averaged value of the mode, except for the first 10 seconds of each mode for systems without bypass capability.

For CO2 or NOx concentration controlled systems, the CO2 or NOx content of the dilution air must be measured at the beginning and at the end of each test. The pre and post test background CO2 or NOx concentration measurements of the dilution air must be within 100 ppm or 5 ppm of each other, respectively.

When using a dilute exhaust gas analysis system, the relevant background concentrations shall be determined by sampling dilution air into a sampling bag over the complete test sequence.

Continuous (non-bag) background concentration may be taken at the minimum of three points, at the beginning, at the end, and a point near the middle of the cycle and averaged. At the manufacturer's request background measurements may be omitted.
”
((e)) Current sections 3.5-3.6 shall be renumbered 3.6-3.7.
((f)) Current sections 3.6.1 shall be replaced by the following:
“ 3.7.1. 

3.7.1.1. Specification A.
For engines covered by Section 1A(i) and A(iv) of Annex I, the following 8-mode cycle shall be followed in dynamometer operation on the test engine:

Mode Number Engine Speed Load Weighting Factor
1 Rated 100 0,15
2 Rated 75 0,15
3 Rated 50 0,15
4 Rated 10 0,10
5 Intermediate 100 0,10
6 Intermediate 75 0,10
7 Intermediate 50 0,10
8 Idle --- 0,15
3.7.1.2. Specification B.
For engines covered by Section lA(ii) of Annex I, the following 5-mode cycle shall be followed in dynamometer operation on the test engine:

Mode Number Engine Speed Load Weighting Factor
1 Rated 100 0,05
2 Rated 75 0,25
3 Rated 50 0,30
4 Rated 25 0,30
5 Rated 10 0,10
The load figures are percentage values of the torque corresponding to the prime power rating defined as the maximum power available during a variable power sequence, which may be run for an unlimited number of hours per year, between stated maintenance intervals and under the stated ambient conditions, the maintenance being carried out as prescribed by the manufacturer.
3.7.1.3 Specification C.
For propulsion engines intended to be used in inland waterway vessels the ISO test procedure as specified by ISO 81784:2002(E) and IMO MARPOL 73/78, Annex VI (NOx Code) shall be used.
Propulsion engines that operate on a fixed-pitch propeller curve shall be tested on a dynamometer using the following 4-mode steady-state cycle developed to represent in-use operation of commercial marine diesel engines:

Mode Number Engine Speed Load Weighting Factor
1 100%(Rated) 100 0,20
2 91% 75 0,50
3 80% 50 0,15
4 63% 25 0,15
Fixed speed inland waterway propulsion engines with variable pitch or electrically coupled propellers shall be tested on a dynamometer using the following 4-mode steady-state cycle characterised by the same load and weighting factors as the above cycle, but with engine operated in each mode at rated speed:

Mode Number Engine Speed Load Weighting Factor
1 Rated 100 0,20
2 Rated 75 0,50
3 Rated 50 0,15
4 Rated 25 0,15
3.7.1.4. Specification D
For engines covered by Section 1A(v) of Annex I, the following 3-mode cycle shall be followed in dynamometer operation on the test engine:

Mode Number Engine Speed Load Weighting Factor
1 Rated 100 0,25
2 Intermediate 50 0,15
3 Idle - 0,60
”
((g)) Current section 3.7.3. shall be replaced by the following:
“The test sequence shall be started. The test shall be performed in the order of the mode numbers as set out above for the test cycles.During each mode of the given test cycle after the initial transition period, the specified speed shall be held to within ±1% of rated speed or ± 3 min-1, whichever is greater, except for low idle which shall be within the tolerances declared by the manufacturer. The specified torque shall be held so that the average over the period during which the measurements are being taken is within ± 2% of the maximum torque at the test speed.For each measuring point a minimum time of 10 minutes is necessary. If for the testing of an engine, longer sampling times are required for reasons of obtaining sufficient particulate mass on the measuring filter the test mode period can be extended as necessary.The mode length shall be recorded and reported.The gaseous exhaust emission concentration values shall be measured and recorded during the last three minutes of the mode.The particulate sampling and the gaseous emission measurement should not commence before engine stabilisation, as defined by the manufacturer, has been achieved and their completion must be coincident.The fuel temperature shall be measured at the inlet to the fuel injection pump or as specified by the manufacturer, and the location of measurement recorded.”
((h)) The current section 3.7 shall be renumbered 3.8.
4)) The following section shall be inserted:
“ 4.  4.1. 
The non-road transient cycle (NRTC) is listed in Annex III, Appendix 4 as a second-by-second sequence of normalized speed and torque values applicable to all diesel engines covered by this Directive. In order to perform the test on an engine test cell, the normalised values shall be converted to the actual values for the individual engine under test, based on the engine mapping curve. This conversion is referred to as denormalisation, and the test cycle developed is referred to as the reference cycle of the engine to be tested. With these reference speed and torque values, the cycle shall be run on the test cell, and the feedback speed and torque values recorded. In order to validate the test run, a regression analysis between reference and feedback speed and torque values shall be conducted upon completion of the test.
 4.1.1. The use of defeat devices or irrational control or irrational emission control strategies shall be prohibited
 4.2. 
When generating the NRTC on the test cell, the engine shall be mapped before running the test cycle to determine the speed vs torque curve.
 4.2.1. 
The minimum and maximum mapping speeds are defined as follows:

Minimum mapping speedidle speedMaximum mapping speednhi x 1,02 or speed where full load torque drops off to zero, whichever is lower

(where nhi is the high speed, defined as the highest engine speed where 70% of the rated power is delivered).
 4.2.2. 
The engine shall be warmed up at maximum power in order to stabilise the engine parameters according to the recommendation of the manufacturer and good engineering practice. When the engine is stabilised, the engine mapping shall be performed according to the following procedures.
 4.2.2.1. 

((a)) The engine shall be unloaded and operated at idle speed.
((b)) The engine shall be operated at full load setting of the injection pump at minimum mapping speed.
((c)) The engine speed shall be increased at an average rate of 8 ± 1 min-1 /s from minimum to maximum mapping speed. Engine speed and torque points shall be recorded at a sample rate of at least one point per second.
 4.2.2.2. 

((a)) The engine shall be unloaded and operated at idle speed.
((b)) The engine shall be operated at full load setting of the injection pump at minimum mapping speed.
((c)) While maintaining full load, the minimum mapping speed shall be maintained for at least 15 s, and the average torque during the last 5 s shall be recorded. The maximum torque curve from minimum to maximum mapping speed shall be determined in no greater than 100 ± 20 /min speed increments. Each test point shall be held for at least 15 s, and the average torque during the last 5 s shall be recorded.
 4.2.3. 
All data points recorded under section 4.2.2 shall be connected using linear interpolation between points. The resulting torque curve is the mapping curve and shall be used to convert the normalized torque values of the engine dynamometer schedule of Annex IV into actual torque values for the test cycle, as described in section 4.3.3.
 4.2.4. 
If a manufacturer believes that the above mapping techniques are unsafe or unrepresentative for any given engine, alternate mapping techniques may be used. These alternate techniques must satisfy the intent of the specified mapping procedures to determine the maximum available torque at all engine speeds achieved during the test cycles. Deviations from the mapping techniques specified in this section for reasons of safety or representativeness shall be approved by the parties involved along with the justification for their use. In no case, however, shall the torque curve be run by descending engine speeds for governed or turbocharged engines.
 4.2.5. 
An engine need not be mapped before each and every test cycle. An engine must be remapped prior to a test cycle if:


— an unreasonable amount of time has transpired since the last map, as determined by engineering judgement,
or,
— physical changes or recalibrations have been made to the engine, which may potentially affect engine performance.
 4.3.  4.3.1. 
The reference speed (nref) corresponds to the 100% normalized speed values specified in the engine dynamometer schedule of Annex III, Appendix 4. It is obvious that the actual engine cycle resulting from denormalization to the reference speed largely depends on selection of the proper reference speed. The reference speed shall be determined by the following definition:

nref = low speed + 0,95 x (high speed - low speed)

(the high speed is the highest engine speed where 70% of the rated power is delivered, while the low speed is the lowest engine speed where 50% of the rated power is delivered).
 4.3.2. 
The speed shall be denormalized using the following equation:

Actual speed = %speed × reference speed - idle speed100 + idle speed
 4.3.3. 
The torque values in the engine dynamometer schedule of Annex III, Appendix 4 are normalized to the maximum torque at the respective speed. The torque values of the reference cycle shall be denormalized, using the mapping curve determined according to Section 4.2.2, as follows:

Actual torque = % torque × max. torque100 (5)

for the respective actual speed as determined in Section 4.3.2.
 4.3.4. 
As an example, the following test point shall be denormalized:

% speed = 43%

% torque = 82%

Given the following values:

reference speed = 2200 /min

idle speed = 600 /min

results in

actual speed = 43 × 2200 - 600100 + 600 = 1288/min

With the maximum torque of 700 Nm observed from the mapping curve at 1288 /min

actual torque = 82 × 700100 = 574 Nm
 4.4.  4.4.1. When using a load cell, the torque signal shall be transferred to the engine axis and the inertia of the dyno shall be considered. The actual engine torque is the torque read on the load cell plus the moment of inertia of the brake multiplied by the angular acceleration. The control system has to perform this calculation in real time.
 4.4.2. If the engine is tested with an eddy-current dynamometer, it is recommended that the number of points, where the difference Tsp - 2 · π · n.sp · ΘD is smaller than - 5% of the peak torque, does not exceed 30 (where Tsp is the demanded torque, n.sp is the derivative of the engine speed and· ΘD is the rotational inertia of the eddy-current dynamometer).
 4.5. 
The following flow chart outlines the test sequence.

One or more Practice Cycles may be run as necessary to check engine, test cell and emissions systems before the measurement cycle.
 4.5.1. 
At least one hour before the test, each filter shall be placed in a petri dish, which is protected against dust contamination and allows air exchange, and placed in a weighing chamber for stabilization. At the end of the stabilization period, each filter shall be weighed and the weight shall be recorded. The filter shall then be stored in a closed petri dish or sealed filter holder until needed for testing. The filter shall be used within eight hours of its removal from the weighing chamber. The tare weight shall be recorded.
 4.5.2. 
The instrumentation and sample probes shall be installed as required. The tailpipe shall be connected to the full flow dilution system, if used.
 4.5.3. 
The dilution system and the engine shall be started and warmed up. The sampling system preconditioning shall be conducted by operating the engine at a condition of rated-speed, 100 percent torque for a minimum of 20 minutes while simultaneously operating either the Partial flow Sampling System or the Full flow CVS with secondary dilution system. Dummy particulate matter emissions samples are then collected. Particulate sample filters need not be stabilized or weighed, and may be discarded. Filter media may be changed during conditioning as long as the total sampled time through the filters and sampling system exceeds 20 minutes. Flow rates shall be set at the approximate flow rates selected for transient testing. Torque shall be reduced from 100 percent torque while maintaining the rated speed condition as necessary so as not to exceed the 191 o C maximum sample zone temperature specifications.
 4.5.4. 
The particulate sampling system shall be started and run on by-pass. The particulate background level of the dilution air may be determined by sampling the dilution air prior to entrance of the exhaust into the dilution tunnel. It is preferred that background particulate sample be collected during the transient cycle if another PM sampling system is available. Otherwise, the PM sampling system used to collect transient cycle PM can be used. If filtered dilution air is used, one measurement may be done prior to or after the test. If the dilution air is not filtered, measurements should be carried out prior to the beginning and after the end of the cycle and the values averaged.
 4.5.5. 
The total diluted exhaust gas flow of a full flow dilution system or the diluted exhaust gas flow through a partial flow dilution system shall be set to eliminate water condensation in the system, and to obtain a filter face temperature between 315 K (42oC) and 325 K (52oC).
 4.5.6. 
The emission analyzers shall be set at zero and spanned. If sample bags are used, they shall be evacuated.
 4.5.7. 
The stabilized engine shall be started within 5 min after completion of warm-up according to the starting procedure recommended by the manufacturer in the owner's manual, using either a production starter motor or the dynamometer. Optionally, the test may start within 5 min of the engine preconditioning phase without shutting the engine off, when the engine has been brought to an idle condition.
 4.5.8.  4.5.8.1. 
The test sequence shall commence when the engine is started from shut down after the preconditioning phase or from idle conditions when starting directly from the preconditioning phase with the engine running. The test shall be performed according to the reference cycle as set out in Annex III, Appendix 4. Engine speed and torque command set points shall be issued at 5 Hz (10 Hz recommended) or greater. The set points shall be calculated by linear interpolation between the 1 Hz set points of the reference cycle. Feedback engine speed and torque shall be recorded at least once every second during the test cycle, and the signals may be electronically filtered.
 4.5.8.2. 
At the start of the engine or test sequence, if the cycle is started directly from preconditioning, the measuring equipment shall be started, simultaneously:


— start collecting or analyzing dilution air, if a full flow dilution system is used;
— start collecting or analyzing raw or diluted exhaust gas, depending on the method used;
— start measuring the amount of diluted exhaust gas and the required temperatures and pressures;
— start recording the exhaust gas mass flow rate, if raw exhaust gas analysis is used;
— recording the feedback data of speed and torque of the dynamometer.

If raw exhaust measurement is used, the emission concentrations (HC, CO and NOx) and the exhaust gas mass flow rate shall be measured continuously and stored with at least 2 Hz on a computer system. All other data may be recorded with a sample rate of at least 1 Hz. For analogue analyzers the response shall be recorded, and the calibration data may be applied online or offline during the data evaluation.

If a full flow dilution system is used, HC and NOx shall be measured continuously in the dilution tunnel with a frequency of at least 2 Hz. The average concentrations shall be determined by integrating the analyzer signals over the test cycle. The system response time shall be no greater than 20 s, and shall be coordinated with CVS flow fluctuations and sampling time/test cycle offsets, if necessary. CO and CO2 shall be determined by integration or by analyzing the concentrations in the sample bag collected over the cycle. The concentrations of the gaseous pollutants in the dilution air shall be determined by integration or by collection in the background bag. All other parameters that need to be measured shall be recorded with a minimum of one measurement per second (1 Hz).
 4.5.8.3. 
At the start of the engine or test sequence, if the cycle is started directly from preconditioning, the particulate sampling system shall be switched from by-pass to collecting particulates.

If a partial flow dilution system is used, the sample pump(s) shall be adjusted so that the flow rate through the particulate sample probe or transfer tube is maintained proportional to the exhaust mass flow rate.

If a full flow dilution system is used, the sample pump(s) shall be adjusted so that the flow rate through the particulate sample probe or transfer tube is maintained at a value within ± 5% of the set flow rate. If flow compensation (i.e., proportional control of sample flow) is used, it must be demonstrated that the ratio of main tunnel flow to particulate sample flow does not change by more than ± 5% of its set value (except for the first 10 seconds of sampling).
NOTE: For double dilution operation, sample flow is the net difference between the flow rate through the sample filters and the secondary dilution airflow rate.
The average temperature and pressure at the gas meter(s) or flow instrumentation inlet shall be recorded. If the set flow rate cannot be maintained over the complete cycle (within ± 5%) because of high particulate loading on the filter, the test shall be voided. The test shall be rerun using a lower flow rate and/or a larger diameter filter.
 4.5.8.4. 
If the engine stalls anywhere during the test cycle, the engine shall be preconditioned and restarted, and the test repeated. If a malfunction occurs in any of the required test equipment during the test cycle, the test shall be voided.
 4.5.8.5. 
At the completion of the test, the measurement of the exhaust gas mass flow rate, the diluted exhaust gas volume, the gas flow into the collecting bags and the particulate sample pump shall be stopped. For an integrating analyzer system, sampling shall continue until system response times have elapsed.

The concentrations of the collecting bags, if used, shall be analyzed as soon as possible and in any case not later than 20 minutes after the end of the test cycle.

After the emission test, a zero gas and the same span gas shall be used for re-checking the analyzers. The test will be considered acceptable if the difference between the pre-test and post-test results is less than 2% of the span gas value.

The particulate filters shall be returned to the weighing chamber no later than one hour after completion of the test. They shall be conditioned in a petri dish, which is protected against dust contamination and allows air exchange, for at least one hour, and then weighed. The gross weight of the filters shall be recorded.
 4.6.  4.6.1. 
To minimise the biasing effect of the time lag between the feedback and reference cycle values, the entire engine speed and torque feedback signal sequence may be advanced or delayed in time with respect to the reference speed and torque sequence. If the feedback signals are shifted, both speed and torque must be shifted by the same amount in the same direction.
 4.6.2. 
The actual cycle work Wact (kWh) shall be calculated using each pair of engine feedback speed and torque values recorded. The actual cycle work Wact is used for comparison to the reference cycle work Wref and for calculating the brake specific emissions. The same methodology shall be used for integrating both reference and actual engine power. If values are to be determined between adjacent reference or adjacent measured values, linear interpolation shall be used.

In integrating the reference and actual cycle work, all negative torque values shall be set equal to zero and included. If integration is performed at a frequency of less than 5 Hertz, and if, during a given time segment, the torque value changes from positive to negative or negative to positive, the negative portion shall be computed and set equal to zero. The positive portion shall be included in the integrated value.

Wact shall be between -15% and + 5% of Wref.
 4.6.3. 
Linear regressions of the feedback values on the reference values shall be performed for speed, torque and power. This shall be done after any feedback data shift has occurred, if this option is selected. The method of least squares shall be used, with the best fit equation having the form:

y = mx + b

where:

yfeedback (actual) value of speed (min-1), torque (N·m), or
power (kW)mslope of the regression linexreference value of speed (min-1), torque (N·m), or power (kW)by intercept of the regression line

The standard error of estimate (SE) of y on x and the coefficient of determination (r2) shall be calculated for each regression line.

It is recommended that this analysis be performed at 1 Hertz. For a test to be considered valid, the criteria of Table 1 must be met.


 Speed Torque Power
Standard error of estimate (SE) of Y on X max 100 min-1 max 13 % of power mapmaximum engine torque max 8% of power mapmaximum engine power
Slope of the regression line, m 0,95 to 1,03 0,83 - 1,03 0,89 - 1,03
Coefficient of determination, r2 min 0,9700 min 0,8800 min 0,9100
Y intercept of the regression line, b ± 50 min-1 ± 20 N·m or ± 2% of max torque, whichever is greater ± 4 kW or ± 2% of max power, whichever is greater

For regression purposes only, point deletions are permitted where noted in Table 2 before doing the regression calculation. However, those points must not be deleted for the calculation of cycle work and emissions. An idle point is defined as a point having a normalized reference torque of 0% and a normalized reference speed of 0%. Point deletion may be applied to the whole or to any part of the cycle.


CONDITION SPEED AND/OR TORQUE AND/OR POWER POINTS WHICH MAY BE DELETED WITH REFERENCE TO THE CONDITIONS LISTED IN THE LEFT COLUMN
First 24 (±1) sand last 25 s Speed, torque and power
Wide open throttle, and torque feedback < 95% torque reference Torque and/or power
Wide open throttle, and speed feedback < 95% speed reference Speed and/or power
Closed throttle, speed feedback > idle speed + 50 min-1, and torque feedback > 105% torque reference Torque and/or power
Closed throttle, speed feedback = idle speed + 50 min-1, and torque feedback = Manufacturer defined/measured idle torque ± 2% of max torque Speed and/or power
Closed throttle and speed feedback > 105% speed reference Speed and/or power
”
5)) Appendix 1 shall be replaced by the following:
 "APPENDIX 1  1. 
Gaseous and particulate components emitted by the engine submitted for testing shall be measured by the methods described in Annex VI. The methods of Annex VI describe the recommended analytical systems for the gaseous emissions (Section 1.1) and the recommended particulate dilution and sampling systems (Section 1.2).
 1.1. 
An engine dynamometer with adequate characteristics to perform the test cycle described in Annex III, Section 3.7.1 shall be used. The instrumentation for torque and speed measurement shall allow the measurement of the power within the given limits. Additional calculations may be necessary. The accuracy of the measuring equipment must be such that the maximum tolerances of the figures given in point 1.3 are not exceeded.
 1.2. 
The exhaust gas flow shall be determined by one of the methods mentioned in sections 1.2.1 to 1.2.4.
 1.2.1. 
Direct measurement of the exhaust flow by flow nozzle or equivalent metering system (for detail see ISO 5167:2000).
NOTE: Direct gaseous flow measurement is a difficult task. Precautions must be taken to avoid measurement errors that will impact emission value errors. 1.2.2. 
Measurement of the airflow and the fuel flow.

Air flow-meters and fuel flow-meters with the accuracy defined in Section 1.3 shall be used.

The calculation of the exhaust gas flow is as follows:

GEXHW = GAIRW + GFUEL (for wet exhaust mass)
 1.2.3. 
Exhaust mass calculation from fuel consumption and exhaust gas concentrations using the carbon balance method (Annex III, Appendix 3).
 1.2.4. 
This method involves measurement of the concentration of a tracer gas in the exhaust.

A known amount of an inert gas (e.g. pure helium) shall be injected into the exhaust gas flow as a tracer. The gas is mixed and diluted by the exhaust gas, but must not react in the exhaust pipe. The concentration of the gas shall then be measured in the exhaust gas sample.

In order to ensure complete mixing of the tracer gas, the exhaust gas sampling probe shall be located at least 1 m or 30 times the diameter of the exhaust pipe, whichever is larger, downstream of the tracer gas injection point. The sampling probe may be located closer to the injection point if complete mixing is verified by comparing the tracer gas concentration with the reference concentration when the tracer gas is injected upstream of the engine.

The tracer gas flow rate shall be set so that the tracer gas concentration at engine idle speed after mixing becomes lower than the full scale of the trace gas analyzer.

The calculation of the exhaust gas flow is as follows:

GEXHW = GT × ρEXH60 × concmix - conca

where

GEXHWinstantaneous exhaust mass flow (kg/s)GTtracer gas flow (cm3/min)concmixinstantaneous concentration of the tracer gas after mixing, (ppm)ρEXHdensity of the exhaust gas (kg/m3)concabackground concentration of the tracer gas in the intake air (ppm)

The background concentration of the tracer gas (conca) may be determined by averaging the background concentration measured immediately before and after the test run.

When the background concentration is less than 1% of the concentration of the tracer gas after mixing (concmix.) at maximum exhaust flow, the background concentration may be neglected.

The total system shall meet the accuracy specifications for the exhaust gas flow and shall be calibrated according to Appendix 2, Section 1.11.2
 1.2.5. 
This method involves exhaust mass calculation from the air flow and the air to fuel ratio. The calculation of the instantaneous exhaust gas mass flow is as follows:

GEXHW = GAIRW × 1 + 1A/Fst × λ

with A / Fst = 14,5

λ = 100 - concCO × 10-42 - concHC × 10-4 + 0,45 · 1 - 2 × concCO × 10-43,5 × concCO21 + concCO × 10-43,5 × concCO2 × concCO2 + concCO × 10-46,9078 × concCO2 + concCO × 10-4 + conHC × 10-4

whereA/Fststoichiometric air/fuel ratio (kg/kg)λrelative air /fuel ratioconcCO2dry CO2 concentration (%)concCOdry CO concentration (ppm)concHCHC concentration (ppm)
NOTE: The calculation refers to a diesel fuel with a H/C ratio equal to 1.8.The air flowmeter shall meet the accuracy specifications in Table 3, the CO2 analyzer used shall meet the specifications of clause 1.4.1, and the total system shall meet the accuracy specifications for the exhaust gas flow.Optionally, air to fuel ratio measurement equipment, such as a zirconia type sensor, may be used for the measurement of the relative air to fuel ratio in accordance with the specifications of clause 1.4.4. 1.2.6. 
When using a full flow dilution system, the total flow of the dilute exhaust (GTOTW) shall be measured with a PDP or CFV or SSV (Annex VI, Section 1.2.1.2.) The accuracy shall conform to the provisions of Annex III, Appendix 2, Section 2.2.
 1.3. 
The calibration of all measurement instruments shall be traceable to national or international standards and comply with the requirements listed in Table 3.


No. Measuring Instrument Accuracy
1 Engine speed ± 2% of reading or ± 1% of engine's max. value whichever is larger
2 Torque ± 2% of reading or ± 1% of engine's max. value whichever is larger
3 Fuel consumption ± 2% of engine's max. value
4 Air consumption ± 2% of reading or ± 1% of engine's max. value whichever is larger
5 Exhaust gas flow ± 2,5% of reading or ± 1,5% of engine's max. value whichever is larger
6 Temperatures ≤ 600 K + 2 K absolute
7 Temperatures > 600 K ± 1% of reading
8 Exhaust gas pressure ± 0,2 kPa absolute
9 Intake air depression ± 0,05 kPa absolute
10 Atmospheric pressure ± 0,1 kPa absolute
11 Other pressures ± 0,1 kPa absolute
12 Absolute humidity ± 5% of reading
13 Dilution air flow ± 2% of reading
14 Diluted exhaust gas flow ± 2% of reading
 1.4.  1.4.1. 
The analysers shall have a measuring range appropriate for the accuracy required to measure the concentrations of the exhaust gas components (section 1.4.1.1). It is recommended that the analysers be operated in such a way that the measured concentration falls between 15% and 100% of full scale.

If the full scale value is 155 ppm (or ppm C) or less or if read-out systems (computers, data loggers) that provide sufficient accuracy and resolution below 15% of full scale are used, concentrations below 15% of full scale are also acceptable. In this case, additional calibrations are to be made to ensure the accuracy of the calibration curves - Annex III, Appendix 2, section 1.5.5.2.

The electromagnetic compatibility (EMC) of the equipment shall be on a level as to minimize additional errors.
 1.4.1.1. 
The analyzer shall not deviate from the nominal calibration point by more than ± 2% of the reading or ± 0.3% of full scale, whichever is larger.
NOTE: For the purpose of this standard, accuracy is defined as the deviation of the analyzer reading from the nominal calibration values using a calibration gas (≡ true value) 1.4.1.2. 
The repeatability, defined as 2,5 times the standard deviation of 10 repetitive responses to a given calibration or span gas, must be no greater than ± 1% of full scale concentration for each range used above 155 ppm (or ppm C) or ± 2% of each range used below 155 ppm (or ppm C).
 1.4.1.3. 
The analyser peak-to-peak response to zero and calibration or span gases over any 10-second period shall not exceed 2% of full scale on all ranges used.
 1.4.1.4. 
The zero drift during a one-hour period shall be less than 2% of full scale on the lowest range used. The zero response is defined as the mean response, including noise, to a zero gas during a 30-second time interval.
 1.4.1.5. 
The span drift during a one-hour period shall be less than 2% of full scale on the lowest range used. Span is defined as the difference between the span response and the zero response. The span response is defined as the mean response, including noise, to a span gas during a 30-second time interval.
 1.4.2. 
The optional gas drying device must have a minimal effect on the concentration of the measured gases. Chemical dryers are not an acceptable method of removing water from the sample.
 1.4.3. 
Sections 1.4.3.1 to 1.4.3.5 of this Appendix describe the measurement principles to be used. A detailed description of the measurement systems is given in Annex VI.

The gases to be measured shall be analysed with the following instruments. For non-linear analysers, the use of linearizing circuits is permitted.
 1.4.3.1. 
The carbon monoxide analyser shall be of the non-dispersive infra-red (NDIR) absorption type.
 1.4.3.2. 
The carbon dioxide analyser shall be of the non-dispersive infra-red (NDIR) absorption type.
 1.4.3.3. 
The hydrocarbon analyser shall be of the heated flame ionization detector (HFID) type with detector, valves, pipework, etc, heated so as to maintain a gas temperature of 463 K (190oC) ± 10 K.
 1.4.3.4. 
The oxides of nitrogen analyser shall be of the chemiluminescent detector (CLD) or heated chemiluminescent detector (HCLD) type with a NO2/NO converter, if measured on a dry basis. If measured on a wet basis, a HCLD with converter maintained above 328 K (55oC) shall be used, provided the water quench check (Annex III, Appendix 2, section 1.9.2.2) is satisfied.

For both CLD and HCLD, the sampling path shall be maintained at a wall temperature of 328 K to 473 K ( 55oC to 200oC) up to the converter for dry measurement, and up to the analyzer for wet measurement.
 1.4.4. 
The air to fuel measurement equipment used to determine the exhaust gas flow as specified in section 1.2.5 shall be a wide range air to fuel ratio sensor or lambda sensor of Zirconia type.

The sensor shall be mounted directly on the exhaust pipe where the exhaust gas temperature is high enough to eliminate water condensation.

The accuracy of the sensor with incorporated electronics shall be within:


± 3% of reading λ < 2
± 5% of reading 2 ≤ λ < 5
± 10% of reading 5 ≤ λ

To fulfil the accuracy specified above, the sensor shall be calibrated as specified by the instrument manufacturer.
 1.4.5. 
The gaseous emissions sampling probes must be fitted at least 0,5 m or three times the diameter of the exhaust pipe - whichever is the larger - upstream of the exit of the exhaust gas system as far as applicable and sufficiently close to the engine as to ensure an exhaust gas temperature of at least 343 K (70oC) at the probe.

In the case of a multi-cylinder engine with a branched exhaust manifold, the inlet of the probe shall be located sufficiently far downstream so as to ensure that the sample is representative of the average exhaust emissions from all cylinders. In multi-cylinder engines having distinct groups of manifolds, such as in a 'V'-engine configuration, it is permissible to acquire a sample from each group individually and calculate an average exhaust emission. Other methods which have been shown to correlate with the above methods may be used. For exhaust emissions calculation the total exhaust mass flow of the engine must be used.

If the composition of the exhaust gas is influenced by any exhaust after-treatment system, the exhaust sample must be taken upstream of this device in the tests of stage I and downstream of this device in the tests of stage II. When a full flow dilution system is used for the determination of the particulates, the gaseous emissions may also be determined in the diluted exhaust gas. The sampling probes shall be close to the particulate sampling probe in the dilution tunnel (Annex VI, section 1.2.1.2, DT and Section 1.2.2, PSP). CO and CO2 may optionally be determined by sampling into a bag and subsequent measurement of the concentration in the sampling bag.
 1.5. 
The determination of the particulates requires a dilution system. Dilution may be accomplished by a partial flow dilution system or a full flow dilution system. The flow capacity of the dilution system shall be large enough to completely eliminate water condensation in the dilution and sampling systems, and maintain the temperature of the diluted exhaust gas between 315 K (42oC) and 325 K (52oC) immediately upstream of the filter holders. De-humidifying the dilution air before entering the dilution system is permitted, if the air humidity is high. Dilution air pre-heating above the temperature limit of 303 K (30 oC) is recommended, if the ambient temperature is below 293 K (20oC). However, the diluted air temperature must not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel.
NOTE: For steady-state procedure, the filter temperature may be kept at or below the maximum temperature of 325 K (52oC) instead of respecting the temperature range of 42oC - 52oC.
For a partial flow dilution system, the particulate sampling probe must be fitted close to and upstream of the gaseous probe as defined in Section 4.4 and in accordance with Annex VI, section 1.2.1.1, figure 4-12 EP and SP.

The partial flow dilution system has to be designed to split the exhaust stream into two fractions, the smaller one being diluted with air and subsequently used for particulate measurement. From that it is essential that the dilution ratio be determined very accurately. Different splitting methods can be applied, whereby the type of splitting used dictates to a significant degree the sampling hardware and procedures to be used (Annex VI, section 1.2.1.1).

To determine the mass of the particulates, a particulate sampling system, particulate sampling filters, a microgram balance and a temperature and humidity controlled weighing chamber are required.

For particulate sampling, two methods may be applied:


— the single filter method uses one pair of filters (1.5.1.3. of this Appendix) for all modes of the test cycle. Considerable attention must be paid to sampling times and flows during the sampling phase of the test. However, only one pair of filters will be required for the test cycle,
— the multiple filter method dictates that one pair of filters (section 1.5.1.3. of this Appendix) is used for each of the individual modes of the test cycle. This method allows more lenient sample procedures but uses more filters.
 1.5.1.  1.5.1.1. 
Fluorocarbon coated glass fibre filters or fluorocarbon based membrane filters are required for certification tests. For special applications different filter materials may be used. All filter types shall have a 0,3 µm DOP (di-octylphthalate) collection efficiency of at least 99% at a gas face velocity between 35 and 100 cm/s. When performing correlation tests between laboratories or between a manufacturer and an approval authority, filters of identical quality must be used.
 1.5.1.2. 
Particulate filters must have a minimum diameter of 47 mm (37 mm stain diameter). Larger diameter filters are acceptable (section 1.5.1.5.).
 1.5.1.3. 
The diluted exhaust shall be sampled by a pair of filters placed in series (one primary and one back-up filter) during the test sequence. The back-up filter shall be located no more than 100 mm downstream of, and shall not be in contact with, the primary filter. The filters may be weighed separately or as a pair with the filters placed stain side to stain side.
 1.5.1.4. 
A gas face velocity through the filter of 35 to 100 cm/s shall be achieved. The pressure drop increase between the beginning and the end of the test shall be no more than 25 kPa.
 1.5.1.5. 
The recommended minimum filter loadings for the most common filter sizes are shown in the following table. For larger filter sizes, the minimum filter loading shall be 0,065 mg/1000 mm2 filter area.


Filter Diameter (mm) Recommended stain diameter (mm) Recommended minimum loading (mg)
47 37 0,11
70 60 0,25
90 80 0,41
110 100 0,62

For the multiple filter method, the recommended minimum filter loading for the sum of all filters shall be the product of the appropriate value above and the square root of the total number of modes.
 1.5.2.  1.5.2.1. 
The temperature of the chamber (or room) in which the particulate filters are conditioned and weighed shall be maintained to within 295 K (22oC) ± 3K during all filter conditioning and weighing. The humidity shall be maintained to a dew point of 282,5 (9,5oC) ± 3K and a relative humidity of 45 ± 8%.
 1.5.2.2. 
The chamber (or room) environment shall be free of any ambient contaminants (such as dust) that would settle on the particulate filters during their stabilisation. Disturbances to weighing room specifications as outlined in section 1.5.2.1 will be allowed if the duration of the disturbances does not exceed 30 minutes. The weighing room should meet the required specifications prior to personnel entrance into the weighing room. At least two unused reference filters or reference filter pairs shall be weighed within four hours of, but preferably at the same time as the sample filter (pair) weighing. They shall be the same size and material as the sample filters.

If the average weight of the reference filters (reference filter pairs) changes between sample filter weighing by more than 10 μg, then all sample filters shall be discarded and the emissions test repeated.

If the weighing room stability criteria outlined in section 1.5.2.1 is not met, but the reference filter (pair) weighing meet the above criteria, the engine manufacturer has the option of accepting the sample filter weights or voiding the tests, fixing the weighing room control system and re-running the test.
 1.5.2.3. 
The analytical balance used to determine the weights of all filters shall have a precision (standard deviation) of 2 (μg and a resolution of 1 μg (1 digit = 1 μg) specified by the balance manufacturer.
 1.5.2.4. 
To eliminate the effects of static electricity, the filters shall be neutralized prior to weighing, for example, by a Polonium neutralizer or a device of similar effect.
 1.5.3. 
All parts of the dilution system and the sampling system from the exhaust pipe up to the filter holder, which are in contact with raw and diluted exhaust gas, must be designed to minimize deposition or alteration of the particulates. All parts must be made of electrically conductive materials that do not react with exhaust gas components, and must be electrically grounded to prevent electrostatic effects.
 2.  2.1. 
Gaseous and particulate components emitted by the engine submitted for testing shall be measured by the methods of Annex VI. The methods of Annex VI describe the recommended analytical systems for the gaseous emissions (Section 1.1) and the recommended particulate dilution and sampling systems (Section 1.2).
 2.2. 
The following equipment shall be used for emission tests of engines on engine dynamometers:
 2.2.1. 
An engine dynamometer shall be used with adequate characteristics to perform the test cycle described in Appendix 4 to this Annex. The instrumentation for torque and speed measurement shall allow the measurement of the power within the given limits. Additional calculations may be necessary. The accuracy of the measuring equipment must be such that the maximum tolerances of the figures given in Table 3 are not exceeded.
 2.2.2. 
Measuring instruments for fuel consumption, air consumption, temperature of coolant and lubricant, exhaust gas pressure and intake manifold depression, exhaust gas temperature, air intake temperature, atmospheric pressure, humidity and fuel temperature shall be used, as required. These instruments shall satisfy the requirements given in Table 3:


No. Measuring Instrument Accuracy
1 Engine speed ± 2% of reading or ± 1% of engine's max. value, whichever is larger
2 Torque ± 2% of reading or ± 1% of engine's max. value, whichever is larger
3 Fuel consumption ± 2% of engine's max. value
4 Air consumption ± 2% of reading or ± 1% of engine's max. value, whichever is larger
5 Exhaust gas flow ± 2,5% of reading or ± 1,5% of engine's max. value, whichever is larger
6 Temperatures ≤ 600 K + 2K absolute
7 Temperatures > 600 K ± 1% of reading
8 Exhaust gas pressure ± 0,2 kPa absolute
9 Intake air depression ± 0,05 kPa absolute
10 Atmospheric pressure ± 0,1 kPa absolute
11 Other pressures ± 0,1 kPa absolute
12 Absolute humidity ± 5% of reading
13 Dilution air flow ± 2% of reading
14 Diluted exhaust gas flow ± 2% of reading
 2.2.3. 
For calculating the emissions in the raw exhaust gas and for controlling a partial flow dilution system, it is necessary to know the exhaust gas mass flow rate. For determinating the exhaust mass flow rate, either of the methods described below may be used.

For the purpose of emissions calculation, the response time of either method described below shall be equal to or less than the requirement for the analyzer response time, as defined in Appendix 2, Section 1.11.1.

For the purpose of controlling a partial flow dilution system, a faster response is required. For partial flow dilution systems with online control, a response time of ≤ 0,3 s is required. For partial flow dilution systems with look ahead control based on a pre-recorded test run, a response time of the exhaust flow measurement system of ≤ 5 s with a rise time of ≤ 1 s is required. The system response time shall be specified by the instrument manufacturer. The combined response time requirements for exhaust gas flow and partial flow dilution system are indicated in Section 2.4.

Direct measurement method

Direct measurement of the instantaneous exhaust flow may be done by systems, such as:


— pressure differential devices, like flow nozzle, (for details see ISO 5167: 2000)
— ultrasonic flowmeter
— vortex flowmeter.

Precautions shall be taken to avoid measurement errors, which will impact emission value errors. Such precautions include the careful installation of the device in the engine exhaust system according to the instrument manufacturers' recommendations and to good engineering practice. Especially, engine performance and emissions must not be affected by the installation of the device.

The flowmeters shall meet the accuracy specifications of Table 3.

Air and fuel measurement method

This involves measurement of the airflow and the fuel flow with suitable flowmeters. The calculation of the instantaneous exhaust gas flow is as follows:

GEXHW = GAIRW + GFUEL (for wet exhaust mass)

The flowmeters shall meet the accuracy specifications of Table 3, but shall also be accurate enough to also meet the accuracy specifications for the exhaust gas flow.

Tracer measurement method

This involves measurement of the concentration of a tracer gas in the exhaust.

A known amount of an inert gas (e.g. pure helium) shall be injected into the exhaust gas flow as a tracer. The gas is mixed and diluted by the exhaust gas, but must not react in the exhaust pipe. The concentration of the gas shall then be measured in the exhaust gas sample.

In order to ensure complete mixing of the tracer gas, the exhaust gas sampling probe shall be located at least 1 m or 30 times the diameter of the exhaust pipe, whichever is larger, downstream of the tracer gas injection point. The sampling probe may be located closer to the injection point if complete mixing is verified by comparing the tracer gas concentration with the reference concentration when the tracer gas is injected upstream of the engine.

The tracer gas flow rate shall be set so that the tracer gas concentration at engine idle speed after mixing becomes lower than the full scale of the trace gas analyzer.

The calculation of the exhaust gas flow is as follows:

GEXHW = GT × ρEXH60 × concmix - conca

where

GEXHWinstantaneous exhaust mass flow (kg/s)GTtracer gas flow (cm3/min)concmixinstantaneous concentration of the tracer gas after mixing (ppm)ρEXHdensity of the exhaust gas (kg/m3)concabackground concentration of the tracer gas in the intake air (ppm)

The background concentration of the tracer gas (conca) may be determined by averaging the background concentration measured immediately before the test run and after the test run.

When the background concentration is less than 1% of the concentration of the tracer gas after mixing (concmix.) at maximum exhaust flow, the background concentration may be neglected.

The total system shall meet the accuracy specifications for the exhaust gas flow, and shall be calibrated according to Appendix 2, paragraph 1.11.2

Air flow and air to fuel ratio measurement method

This involves exhaust mass calculation from the airflow and the air to fuel ratio. The calculation of the instantaneous exhaust gas mass flow is as follows:

GEXHW = GAIRW × 1 + 1A/Fst × λ

with A / Fst = 14,5

λ = 100 - concCO × 10-42 - concHC × 10-4 + 0,45 · 1 - 2 × concCO × 10-43,5 × concCO21 + concCO × 10-43,5 × concCO2 × concCO2 + concCO × 10-46,9078 × concCO2 + concCO × 10-4 +concHC × 10-4

whereA/Fststoichiometric air/fuel ratio (kg/kg)λrelative air /fuel ratioconcCO2dry CO2 concentration (%)concCOdry CO concentration (ppm)concHCHC concentration (ppm)
NOTE: The calculation refers to a diesel fuel with a H/C ratio equal to 1.8.The air flowmeter shall meet the accuracy specifications in Table 3, the CO2 analyzer used shall meet the specifications of section 2.3.1, and the total system shall meet the accuracy specifications for the exhaust gas flow.Optionally, air to fuel ratio measurement equipment, such as a zirconia type sensor, may be used for the measurement of the excess air ratio in accordance with the specifications of section 2.3.4. 2.2.4. 
For calculation of the emissions in the diluted exhaust gas, it is necessary to know the diluted exhaust gas mass flow rate. The total diluted exhaust gas flow over the cycle (kg/test) shall be calculated from the measurement values over the cycle and the corresponding calibration data of the flow measurement device (V0 for PDP, KV for CFV, Cd for SSV): the corresponding methods described in Appendix 3, section 2.2.1 shall be used. If the total sample mass of particulates and gaseous pollutants exceeds 0,5% of the total CVS flow, the CVS flow shall be corrected or the particulate sample flow shall be returned to the CVS prior to the flow measuring device.
 2.3.  2.3.1. 
The analysers shall have a measuring range appropriate for the accuracy required to measure the concentrations of the exhaust gas components (section 1.4.1.1). It is recommended that the analysers be operated in such a way that the measured concentration falls between 15% and 100% of full scale.

If the full scale value is 155 ppm (or ppm C) or less, or if read-out systems (computers, data loggers) that provide sufficient accuracy and resolution below 15% of full scale are used, concentrations below 15% of full scale are also acceptable. In this case, additional calibrations are to be made to ensure the accuracy of the calibration curves - Annex III, Appendix 2, section 1.5.5.2.

The electromagnetic compatibility (EMC) of the equipment shall be of a level such as to minimize additional errors.
 2.3.1.1. 
The analyzer shall not deviate from the nominal calibration point by more than ± 2% of the reading or ± 0,3% of full scale, whichever is larger.
NOTE: For the purpose of this standard, accuracy is defined as the deviation of the analyzer reading from the nominal calibration values using a calibration gas (≡ true value). 2.3.1.2. 
The repeatability, defined as 2,5 times the standard deviation of 10 repetitive responses to a given calibration or span gas, must be no greater than ± 1% of full scale concentration for each range used above 155 ppm (or ppm C) or ± 2% for each range used below 155 ppm (or ppm C).
 2.3.1.3. 
The analyser peak-to-peak response to zero and calibration or span gases over any 10-second period shall not exceed 2% of full scale on all ranges used.
 2.3.1.4. 
The zero drift during a one-hour period shall be less than 2% of full scale on the lowest range used. The zero response is defined as the mean response, including noise, to a zero gas during a 30-second time interval.
 2.3.1.5. 
The span drift during a one-hour period shall be less than 2% of full scale on the lowest range used. Span is defined as the difference between the span response and the zero response. The span response is defined as the mean response, including noise, to a span gas during a 30-second time interval.
 2.3.1.6. 
For raw exhaust gas analysis, the rise time of the analyzer installed in the measurement system shall not exceed 2,5 s.
NOTE: Only evaluating the response time of the analyzer alone will not clearly define the suitability of the total system for transient testing. Volumes, and especially dead volumes, through out the system will not only affect the transportation time from the probe to the analyzer, but also affect the rise time. Also transport times inside of an analyzer would be defined as analyzer response time, like the converter or water traps inside of a NOx analyzers. The determination of the total system response time is described in Appendix 2, Section 1.11.1. 2.3.2. 
Same specifications as for NRSC test cycle apply (Section 1.4.2) as described here below.

The optional gas drying device must have a minimal effect on the concentration of the measured gases. Chemical dryers are not an acceptable method of removing water from the sample.
 2.3.3. 
Same specifications as for NRSC test cycle apply (Section 1.4.3) as described here below.

The gases to be measured shall be analysed with the following instruments. For non-linear analysers, the use of linearizing circuits is permitted.
 2.3.3.1. 
The carbon monoxide analyser shall be of the non-dispersive infra-red (NDIR) absorption type.
 2.3.3.2. 
The carbon dioxide analyser shall be of the non-dispersive infra-red (NDIR) absorption type.
 2.3.3.3. 
The hydrocarbon analyser shall be of the heated flame ionization detector (HFID) type with detector, valves, pipework, etc, heated so as to maintain a gas temperature of 463 K (190oC) ± 10 K.
 2.3.3.4. 
The oxides of nitrogen analyser shall be of the chemiluminescent detector (CLD) or heated chemiluminescent detector (HCLD) type with a NO2/NO converter, if measured on a dry basis. If measured on a wet basis, a HCLD with converter maintained above 328 K (55oC shall be used, provided the water quench check (Annex III, Appendix 2, section 1.9.2.2) is satisfied.

For both CLD and HCLD, the sampling path shall be maintained at a wall temperature of 328 K to 473 K ( 55oC to 200oC) up to the converter for dry measurement, and up to the analyzer for wet measurement.
 2.3.4. 
The air to fuel measurement equipment used to determine the exhaust gas flow as specified in section 2.2.3 shall be a wide range air to fuel ratio sensor or lambda sensor of Zirconia type.

The sensor shall be mounted directly on the exhaust pipe where the exhaust gas temperature is high enough to eliminate water condensation.

The accuracy of the sensor with incorporated electronics shall be within:


± 3 % of reading λ < 2
± 5 % of reading 2 ≤ λ < 5
± 10% of reading 5 ≤ λ

To fulfil the accuracy specified above, the sensor shall be calibrated as specified by the instrument manufacturer.
 2.3.5.  2.3.5.1. 
For calculation of the emissions in the raw exhaust gas the same specifications as for NRSC test cycle apply (Section 1.4.4), as described here below.

The gaseous emissions sampling probes must be fitted at least 0,5 m or three times the diameter of the exhaust pipe -whichever is the larger - upstream of the exit of the exhaust gas system as far as applicable and sufficiently close to the engine as to ensure an exhaust gas temperature of at least 343 K (70oC) at the probe.

In the case of a multicylinder engine with a branched exhaust manifold, the inlet of the probe shall be located sufficiently far downstream so as to ensure that the sample is representative of the average exhaust emissions from all cylinders. In multicylinder engines having distinct groups of manifolds, such as in a 'V'-engine configuration, it is permissible to acquire a sample from each group individually and calculate an average exhaust emission. Other methods which have been shown to correlate with the above methods may be used. For exhaust emissions calculation the total exhaust mass flow of the engine must be used.

If the composition of the exhaust gas is influenced by any exhaust after-treatment system, the exhaust sample must be taken upstream of this device in the tests of stage I and downstream of this device in the tests of stage II.
 2.3.5.2. 
If a full flow dilution system is used, the following specifications apply.

The exhaust pipe between the engine and the full flow dilution system shall conform to the requirements of Annex VI.

The gaseous emissions sample probe(s) shall be installed in the dilution tunnel at a point where the dilution air and exhaust gas are well mixed, and in close proximity to the particulates sampling probe.

Sampling can generally be done in two ways:


— the pollutants are sampled into a sampling bag over the cycle and measured after completion of the test;
— the pollutants are sampled continuously and integrated over the cycle; this method is mandatory for HC and NOx.

The background concentrations shall be sampled upstream of the dilution tunnel into a sampling bag, and shall be subtracted from the emissions concentration according to Appendix 3, Section 2.2.3.
 2.4. 
Determination of the particulates requires a dilution system. Dilution may be accomplished by a partial flow dilution system or a full flow dilution system. The flow capacity of the dilution system shall be large enough to completely eliminate water condensation in the dilution and sampling systems, and maintain the temperature of the diluted exhaust gas between 315 K (42oC) and 325 K (52oC) immediately upstream of the filter holders. De-humidifying the dilution air before entering the dilution system is permitted, if the air humidity is high. Dilution air pre-heating above the temperature limit of 303 K (30 oC) is recommended if the ambient temperature is below 293 K (20 C). However, the diluted air temperature must not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel.

The particulate sampling probe shall be installed in close proximity to the gaseous emissions sampling probe, and the installation shall comply with the provisions of Section 2.3.5.

To determine the mass of the particulates, a particulate sampling system, particulate sampling filters, microgram balance, and a temperature and humidity controlled weighing chamber, are required.

Partial flow dilution system specifications

The partial flow dilution system has to be designed to split the exhaust stream into two fractions, the smaller one being diluted with air and subsequently used for particulate measurement. For this it is essential that the dilution ratio be determined very accurately. Different splitting methods can be applied, whereby the type of splitting used dictates to a significant degree the sampling hardware and procedures to be used (Annex VI, section 1.2.1.1).

For the control of a partial flow dilution system, a fast system response is required. The transformation time for the system shall be determined by the procedure described in Appendix 2, Section 1.11.1.

If the combined transformation time of the exhaust flow measurement (see previous Section) and the partial flow system is less than 0,3 s, online control may be used. If the transformation time exceeds 0,3 s, look ahead control based on a pre-recorded test run must be used. In this case, the rise time shall be ≤ 1 s and the delay time of the combination ≤ 10 s.

The total system response shall be designed as to ensure a representative sample of the particulates, GSE, proportional to the exhaust mass flow. To determine the proportionality, a regression analysis of GSE versus GEXHW shall be conducted on a minimum 5 Hz data acquisition rate, and the following criteria shall be met:


— The correlation coefficient r2 of the linear regression between GSE and GEXHW shall be not less than 0,95.
— The standard error of estimate of GSE on GEXHW shall not exceed 5% of GSE maximum.
— GSE intercept of the regression line shall not exceed ± 2% of GSE maximum.

Optionally, a pre-test may be run, and the exhaust mass flow signal of the pre-test be used for controlling the sample flow into the particulate system ("look-ahead control"). Such a procedure is required if the transformation time of the particulate system, t50,P or/and the transformation time of the exhaust mass flow signal, t50,F are > 0,3 s. A correct control of the partial dilution system is obtained, if the time trace of GEXHW,pre of the pre-test, which controls GSE, is shifted by a "look-ahead" time of t50,P + t50,F.

For establishing the correlation between GSE and GEXHW the data taken during the actual test shall be used, with GEXHW time aligned by t50,F relative to GSE (no contribution from t50,P to the time alignment). That is, the time shift between GEXHW and GSE is the difference in their transformation times that were determined in Appendix 2, Section 2.6.

For partial flow dilution systems, the accuracy of the sample flow GSE is of special concern, if not measured directly, but determined by differential flow measurement:

GSE = GTOTW - GDILW

In this case an accuracy of ± 2% for GTOTW and GDILW is not sufficient to guarantee acceptable accuracies of GSE. If the gas flow is determined by differential flow measurement, the maximum error of the difference shall be such that the accuracy of GSE is within ± 5% when the dilution ratio is less than 15. It can be calculated by taking root-mean-square of the errors of each instrument.

Acceptable accuracies of GSE can be obtained by either of the following methods:


((a)) The absolute accuracies of GTOTW and GDILW are ± 0,2% which guarantees an accuracy of GSE of ≤ 5% at a dilution ratio of 15. However, greater errors will occur at higher dilution ratios.
((b)) Calibration of GDILW relative to GTOTW is carried out such that the same accuracies for GSE as in (a) are obtained. For the details of such a calibration see Appendix 2, Section 2.6.
((c)) The accuracy of GSE is determined indirectly from the accuracy of the dilution ratio as determined by a tracer gas, e.g. CO2. Again, accuracies equivalent to method (a) for GSE are required.
((d)) The absolute accuracy of GTOTW and GDILW is within ± 2% of full scale, the maximum error of the difference between GTOTW and GDILW is within 0,2%, and the linearity error is within ± 0.2% of the highest GTOTW observed during the test.
 2.4.1.  2.4.1.1. 
Fluorocarbon coated glass fibre filters or fluorocarbon based membrane filters are required for certification tests. For special applications different filter materials may be used. All filter types shall have a 0,3 µm DOP (di-octylphthalate) collection efficiency of at least 99% at a gas face velocity between 35 and 100 cm/s. When performing correlation tests between laboratories or between a manufacturer and an approval authority, filters of identical quality must be used.
 2.4.1.2. 
Particulate filters must have a minimum diameter of 47 mm (37 mm stain diameter). Larger diameter filters are acceptable (section 2.4.1.5.).
 2.4.1.3. 
The diluted exhaust shall be sampled by a pair of filters placed in series (one primary and one back-up filter) during the test sequence. The back-up filter shall be located no more than 100 mm downstream of, and shall not be in contact with, the primary filter. The filters may be weighed separately or as a pair with the filters placed stain side to stain side.
 2.4.1.4. 
A gas face velocity through the filter of 35 to 100 cm/s shall be achieved. The pressure drop increase between the beginning and the end of the test shall be no more than 25 kPa.
 2.4.1.5. 
The recommended minimum filter loadings for the most common filter sizes are shown in the following table. For larger filter sizes, the minimum filter loading shall be 0,065 mg/1000 mm2 filter area.


Filter Diameter (mm) Recommended stain diameter (mm) Recommended minimum loading (mg)
47 37 0,11
70 60 0,25
90 80 0,41
110 100 0,62
 2.4.2.  2.4.2.1. 
The temperature of the chamber (or room) in which the particulate filters are conditioned and weighed shall be maintained to within 295 K (22oC) ±3K during all filter conditioning and weighing. The humidity shall be maintained to a dewpoint of 282,5 (9,5oC) ± 3 K and a relative humidity of 45 ± 8%.
 2.4.2.2. 
The chamber (or room) environment shall be free of any ambient contaminants (such as dust) that would settle on the particulate filters during their stabilisation. Disturbances to weighing room specifications as outlined in section 2.4.2.1 will be allowed if the duration of the disturbances does not exceed 30 minutes. The weighing room should meet the required specifications prior to personnel entrance into the weighing room. At least two unused reference filters or reference filter pairs shall be weighed within four hours of, but preferably at the same time as the sample filter (pair) weighing. They shall be the same size and material as the sample filters.

If the average weight of the reference filters (reference filter pairs) changes between sample filter weighing by more than 10µg, then all sample filters shall be discarded and the emissions test repeated.

If the weighing room stability criteria outlined in section 2.4.2.1 are not met, but the reference filter (pair) weighing meet the above criteria, the engine manufacturer has the option of accepting the sample filter weights or voiding the tests, fixing the weighing room control system and re-running the test.
 2.4.2.3. 
The analytical balance used to determine the weights of all filters shall have a precision (standard deviation) of 2 (µg and a resolution of 1 µg (1 digit = 1 µg) specified by the balance manufacturer.
 2.4.2.4. 
To eliminate the effects of static electricity, the filters shall be neutralized prior to weighing, for example, by a Polonium neutralizer or a device having similar effect.
 2.4.3. 
All parts of the dilution system and the sampling system from the exhaust pipe up to the filter holder, which are in contact with raw and diluted exhaust gas, must be designed to minimize deposition or alteration of the particulates. All parts must be made of electrically conductive materials that do not react with exhaust gas components, and must be electrically grounded to prevent electrostatic effects.”

6)) Appendix 2 shall be amended as follows:

((a)) The title shall be amended as follows:
“”
((b)) Section 1.2.2 shall be amended as follows:
After the current text the following shall be added:
“This accuracy implies that primary gases used for blending shall be known to have an accuracy of at least ± 1%, traceable to national or international gas standards. The verification shall be performed at between 15 and 50% of full scale for each calibration incorporating a blending device. An additional verification may be performed using another calibration gas, if the first verification has failed.Optionally, the blending device may be checked with an instrument which by nature is linear, e.g. using NO gas with a CLD. The span value of the instrument shall be adjusted with the span gas directly connected to the instrument. The blending device shall be checked at the used settings and the nominal value shall be compared to the measured concentration of the instrument. This difference shall in each point be within ± 1% of the nominal value.Other methods may be used based on good engineering practice and with the prior agreement of the parties involved.NOTE: A precision gas divider of accuracy is within ± 1%, is recommended for establishing the accurate analyzer calibration curve. The gas divider shall be calibrated by the instrument manufacturer.”
((c)) section 1.5.5.1 shall be amended as follows:

((i)) the first sentence shall be replaced by the following:
“The analyser calibration curve is established by at least six calibration points (excluding zero) spaced as uniformly as possible”.
((ii)) the third indent shall be replaced by the following:
“The calibration curve must not differ by more than ± 2% from the nominal value of each calibration point and by more than ±0,3% of full scale at zero.”
((d)) in section 1.5.5.2, the last indent shall be replaced by the following:
“The calibration curve must not differ by more than ± 4% from the nominal value of each calibration point and by more than ± 0,3% of full scale at zero.”
((e)) the text under section 1.8.3 shall be replaced by the following:
“The oxygen interference check shall be determined when introducing an analyser into service and after major service intervals.A range shall be chosen where the oxygen interference check gases will fall within the upper 50%. The test shall be conducted with the oven temperature set as required. 1.8.3.1. 
Oxygen interference check gases shall contain propane with 350 ppmC ÷ 75 ppmC hydrocarbon. The concentration value shall be determined to calibration gas tolerances by chromatographic analysis of total hydrocarbons plus impurities or by dynamic blending. Nitrogen shall be the predominant diluent with the balance oxygen. Blends required for Diesel engine testing are:


O2 concentration Balance
21 (20 to 22) Nitrogen
10 (9 to 11 Nitrogen
5 (4 to 6) Nitrogen
 1.8.3.2. 

((a)) The analyzer shall be zeroed.
((b)) The analyzer shall be spanned with the 21% oxygen blend.
((c)) The zero response shall be rechecked. If it has changed more than 0,5% of full scale clauses (a) and (b) shall be repeated.
((d)) The 5% and 10% oxygen interference check gases shall be introduced.
((e)) The zero response shall be rechecked. If it has changed more than ± 1 % of full scale, the test shall be repeated.
((f)) The oxygen interference (%O2I) shall be calculated for each mixture in (d) as follows:
O2I = B-CB · 100Ahydrocarbon concentration (ppmC) of the span gas used in (b)Bhydrocarbon concentration (ppmC) of the oxygen interference check gases used in (d)Canalyzer response
(ppmC) = ADDpercent of full scale analyzer response due to A.
((g)) The % of oxygen interference (%O2I) shall be less than ± 3,0% for all required oxygen interference check gases prior to testing.
((h)) If the oxygen interference is greater than ± 3,0%, the air flow above and below the manufacturer's specifications shall be incrementally adjusted, repeating clause 1.8.1 for each flow.
((i)) If the oxygen interference is greater than ± 3,0% after adjusting the air flow, the fuel flow and thereafter the sample flow shall be varied, repeating clause 1.8.1 for each new setting.
((j)) If the oxygen interference is still greater than ± 3,0%, the analyzer, FID fuel, or burner air shall be repaired or replaced prior to testing. This clause shall then be repeated with the repaired or replaced equipment or gases.
”
((f)) Current paragraph 1.9.2.2 shall be amended as follows:

((i)) the first subparagraph shall be replaced by the following:
“This check applies to wet gas concentration measurements only. Calculation of water quench must consider dilution of the NO span gas with water vapour and scaling of water vapour concentration of the mixture to that expected during testing. A NO span gas having a concentration of 80 to 100% of full scale to the normal operating range shall be passed through the (H)CLD and the NO value recorded as D. The NO gas shall be bubbled through water at room temperature and passed through the (H)CLD and NO value recorded as C. The water temperature shall be determined and recorded as F. The mixture's saturation vapour pressure that corresponds to the bubbler water temperature (F) shall be determined and recorded as G. The water vapour concentration (in %) of the mixture shall be calculated as follows:”
((ii)) The third subparagraph shall be replaced by the following:
"and recorded as De. For diesel exhaust, the maximum exhaust water vapour concentration (in %) expected during testing shall be estimated, under the assumption of a fuel atom H/C ratio of 1,8 to 1, from the maximum CO2 concentration in the exhaust gas or from the undiluted CO2 span gas concentration (A, as measured in section 1.9.2.1) as follows:
((g)) the following section shall be inserted:
“ 1.11.  1.11.1. 
The system settings for the response time evaluation shall be exactly the same as during measurement of the test run (i.e. pressure, flow rates, filter settings on the analyzers and all other response time influences). The response time determination shall be done with gas switching directly at the inlet of the sample probe. The gas switching shall be done in less than 0,1 second. The gases used for the test shall cause a concentration change of at least 60% FS.

The concentration trace of each single gas component shall be recorded. The response time is defined as the difference in time between the gas switching and the appropriate change of the recorded concentration. The system response time (t90) consists of the delay time to the measuring detector and the rise time of the detector. The delay time is defined as the time from the change (t0) until the response is 10% of the final reading (t10). The rise time is defined as the time between 10% and 90% response of the final reading (t90 - t10).

For time alignment of the analyzer and exhaust flow signals in the case of raw measurement, the transformation time is defined as the time from the change (t0) until the response is 50% of the final reading (t50).

The system response time shall be = 10 seconds with a rise time = 2,5 seconds for all limited components (CO, NOx, HC) and all ranges used.
 1.11.2. 
The analyzer for measurement of the tracer gas concentration, if used, shall be calibrated using the standard gas.

The calibration curve shall be established by at least 10 calibration points (excluding zero) spaced so that a half of the calibration points are placed between 4% to 20% of analyzer's full scale and the rest are in between 20% to 100% of the full scale. The calibration curve is calculated by the method of least squares.

The calibration curve shall not differ by more than ± 1% of the full scale from the nominal value of each calibration point, in the range from 20% to 100% of the full scale. It shall also not differ by more than ± 2% from the nominal value in the range from 4% to 20% of the full scale.

The analyzer shall be set at zero and spanned prior to the test run using a zero gas and a span gas whose nominal value is more than 80% of the analyzer full scale.
”
((h)) paragraph 2.2 shall be replaced by the following:
“ 2.2. 
The maximum error of the measured value shall be within ± 2% of reading.

For partial flow dilution systems, the accuracy of the sample flow GSE is of special concern, if not measured directly, but determined by differential flow measurement:

GSE = GTOTW - GDILW

In this case an accuracy of ± 2% for GTOTW and GDILW is not sufficient to guarantee acceptable accuracies of GSE If the gas flow is determined by differential flow measurement, the maximum error of the difference shall be such that the accuracy of GSE is within ± 5% when the dilution ratio is less than 15. It can be calculated by taking root-mean-square of the errors of each instrument.
”
((i)) the following section shall be added:
“ 2.6.  2.6.1. 
If the sample gas flow is determined by differential flow measurement the flow meter or the flow measurement instrumentation shall be calibrated by one of the following procedures, such that the probe flow GSE into the tunnel fulfils the accuracy requirements of Appendix I section 2.4:

The flow meter for GDILW is connected in series to the flow meter for GTOTW, the difference between the two flow meters is calibrated for at least 5 set points with flow values equally spaced between the lowest GDILW value used during the test and the value of GTOTW used during the test The dilution tunnel may be bypassed.

A calibrated mass flow device is connected in series to the flowmeter for GTOTW and the accuracy is checked for the value used for the test. Then the calibrated mass flow device is connected in series to the flow meter for GDILW, and the accuracy is checked for at least 5 settings corresponding to the dilution ratio between 3 and 50, relative to GTOTW used during the test.

The transfer tube TT is disconnected from the exhaust, and a calibrated flow measuring device with a suitable range to measure GSE is connected to the transfer tube. Then GTOTW is set to the value used during the test, and GDILW is sequentially set to at least 5 values corresponding to dilution ratios q between 3 and 50. Alternatively, a special calibration flow pathmay be provided, in which the tunnel is bypassed, but the total and dilution air flow through the corresponding meters are maintained as in the actual test.

A tracer gas is fed into the transfer tube TT. This tracer gas may be a component of the exhaust gas, like CO2 or NOx. After dilution in the tunnel the tracer gas component is measured. This shall be carried out for 5 dilution ratios between 3 and 50. The accuracy of the sample flow is determined from the dilution ration q:

GSE = GTOTW/q

The accuracies of the gas analyzers shall be taken into account to guarantee the accuracy of GSE
 2.6.2. 
A carbon flow check using actual exhaust is strongly recommended for detecting measurement and control problems and verifying the proper operation of the partial flow dilution system. The carbon flow check should be run at least each time a new engine is installed, or something significant is changed in the test cell configuration.

The engine shall be operated at peak torque load and speed or any other steady-state mode that produces 5% or more of CO2. The partial flow sampling system shall be operated with a dilution factor of about 15 to 1.
 2.6.3. 
A pre-test check shall be performed within 2 hours before the test run in the following way:

The accuracy of the flow meters shall be checked by the same method as used for calibration for at least two points, including flow values of GDILW that correspond to dilution ratios between 5 and 15 for the GTOTW value used during the test.

If it can be demonstrated by records of the calibration procedure described above that the flow meter calibration is stable over a longer period of time, the pre-test check may be omitted.
 2.6.4. 
The system settings for the transformation time evaluation shall be exactly the same as during measurement of the test run. The transformation time shall be determined by the following method:

An independent reference flowmeter with a measurement range appropriate for the probe flow shall be put in series with and closely coupled to the probe. This flow meter shall have a transformation time of less than 100 ms for the flow step size used in the response time measurement, with flow restriction sufficiently low not to affect the dynamic performance of the partial flow dilution system, and consistent with good engineering practice.

A step change shall be introduced to the exhaust flow (or air flow if exhaust flow is calculated) input of the partial flow dilution system, from a low flow to at least 90% of full scale. The trigger for the step change should be the same one as that used to start the look-ahead control in actual testing. The exhaust flow step stimulus and the flowmeter response shall be recorded at a sample rate of at least 10 Hz.

From this data, the transformation time shall be determined for the partial flow dilution system, which is the time from the initiation of the step stimulus to the 50% point of the flowmeter response. In a similar manner, the transformation times of the GSE signal of the partial flow dilution system and of the GEXHW signal of the exhaust flow meter shall be determined. These signals are used in the regression checks performed after each test (Appendix I section 2.4).

The calculation shall be repeated for at least 5 rise and fall stimuli, and the results shall be averaged. The internal transformation time (<100 ms) of the reference flowmeter shall be subtracted from this value. This is the "look-ahead" value of the partial flow dilution system, which shall be applied in accordance with Appendix I section 2.4.
”
7)) the following section shall be added:
“ 3.  3.1. 
The CVS system shall be calibrated by using an accurate flowmeter and means to change operating conditions.

The flow through the system shall be measured at different flow operating settings, and the control parameters of the system shall be measured and related to the flow.

Various type of flowmeters may be used, e.g. calibrated venturi, calibrated laminar flowmeter, calibrated turbinemeter.
 3.2. 
All the parameters related to the pump shall be simultaneously measured along with the parameters related to a calibration venturi which is connected in series with the pump. The calculated flow rate (in m3/min at pump inlet, absolute pressure and temperature) shall be plotted against a correlation function which is the value of a specific combination of pump parameters. The linear equation which relates the pump flow and the correlation function shall be determined. If a CVS has a multiple speed drive, the calibration shall be performed for each range used.

Temperature stability shall be maintained during calibration.

Leaks in all the connections and ducting between the calibration venturi and the CVS pump shall be maintained lower than 0,3% of the lowest flow point (highest restriction and lowest PDP speed point).
 3.2.1. 
The air flowrate (Qs) at each restriction setting (minimum 6 settings) shall be calculated in standard m3/min from the flowmeter data using the manufacturer's prescribed method. The air flow rate shall then be converted to pump flow (V0) in m3/rev at absolute pump inlet temperature and pressure as follows:

V0 = Qsn x T273 x 101.3pA

where,

Qsair flow rate at standard conditions (101,3 kPa, 273 K) (m3/s)Ttemperature at pump inlet (K)pAabsolute pressure at pump inlet (pB- p1) (kPa)npump speed (rev/s)

To account for the interaction of pressure variations at the pump and the pump slip rate, the correlation function (X0) between pump speed, pressure differential from pump inlet to pump outlet and absolute pump outlet pressure shall be calculated as follows:

X0 = 1n x ΔpppA

where,

Δpppressure differential from pump inlet to pump outlet (kPa)pAabsolute outlet pressure at pump outlet (kPa)

A linear least-square fit shall be performed to generate the calibration equation as follows:

V0 = D0 - m x X0

D0 and m are the intercept and slope constants, respectively, describing the regression lines.

For a CVS system with multiple speeds, the calibration curves generated for the different pump flow ranges shall be approximately parallel, and the intercept values (D0) shall increase as the pump flow range decreases.

The values calculated by the equation shall be within ± 0,5% of the measured value of V0. Values of m will vary from one pump to another. Particulate influx over time will cause the pump slip to decrease, as reflected by lower values for m. Therefore, calibration shall be performed at pump start-up, after major maintenance, and if the total system verification (section 3.5) indicates a change in the slip rate.
 3.3. 
Calibration of the CFV is based upon the flow equation for a critical venturi. Gas flow is a function of inlet pressure and temperature, as shown below:

Qs = Kv x pAT

where,

Kvcalibration coefficientpAabsolute pressure at venturi inlet (kPa)Ttemperature at venturi inlet (K)
 3.3.1. 
The air flow rate (Qs) at each restriction setting (minimum 8 settings) shall be calculated in standard m3/min from the flowmeter data using the manufacturer's prescribed method. The calibration coefficient shall be calculated from the calibration data for each setting as follows:

Kv = Qs x TpA

where,

Qsair flow rate at standard conditions (101,3 kPa, 273 K) (m3/s)Ttemperature at the venturi inlet (K)pAabsolute pressure at venturi inlet (kPa)

To determine the range of critical flow, Kv shall be plotted as a function of venturi inlet pressure. For critical (choked) flow, Kv will have a relatively constant value. As pressure decreases (vacuum increases), the venturi becomes unchoked and Kv decreases, which indicates that the CFV is operated outside the permissible range.

For a minimum of eight points in the region of critical flow, the average KV and the standard deviation shall be calculated. The standard deviation shall not exceed ± 0,3% of the average KV
 3.4. 
Calibration of the SSV is based upon the flow equation for a subsonic venturi. Gas flow is a function of inlet pressure and temperature, pressure drop between the SSV inlet and throat, as shown below:

QSSV = A0d2CdPA1Tr1.4286 - r1.714311- ß4r1.4286

where,

A0collection of constants and units conversions
= 0,006111 in SI units m3minK12kPa1mm2ddiameter of the SSV throat (m)Cddischarge coefficient of the SSVPAabsolute pressure at venturi inlet (kPa)Ttemperature at the venturi inlet (K)rratio of the SSV throat to inlet absolute, static pressure = 1 - ΔPPAßratio of the SSV throat diameter, d, to the inlet pipe inner diameter = dD
 3.4.1. 
The air flow rate (QSSV) at each flow setting (minimum 16 settings) shall be calculated in standard m3/min from the flowmeter data using the manufacturer's prescribed method. The discharge coefficient shall be calculated from the calibration data for each setting as follows:

Cd = QSSVA0d2PA1Tr1.4286 - r1.7174311-ß4r1.4286

where,

QSSVair flow rate at standard conditions (101,3 kPa, 273 K), m3/sTtemperature at the venturi inlet, Kddiameter of the SSV throat, mrratio of the SSV throat to inlet absolute, static pressure = 1 - ΔPPAßratio of the SSV throat diameter, d, to the inlet pipe inner diameter = dD

To determine the range of subsonic flow, Cd shall be plotted as a function of Reynolds number, at the SSV throat. The Re at the SSV throat is calculated with the following formula:

Re = A1QSSVdμ

where,

A1a collection of constants and units conversions= 25,55152 1m3minsmmmQSSVair flow rate at standard conditions (101,3 kPa, 273 K) (m3/s)ddiameter of the SSV throat (m)μabsolute or dynamic viscosity of the gas, calculated with the following formula:µ = bT3/2S + T = bT1/21+ ST kg/m-s

where:

bempirical constant = 1,458 · 106kgmsK12Sempirical constant = 110,4 K

Because QSSV is an input to the Re formula, the calculations must be started with an initial guess for QSSV or Cd of the calibration venturi, and repeated until QSSV converges. The convergence method must be accurate to 0,1% or better.

For a minimum of sixteen points in the subsonic flow region, the calculated values of Cd from the resulting calibration curve fit equation must be within ± 0,5% of the measured Cd for each calibration point.
 3.5. 
The total accuracy of the CVS sampling system and analytical system shall be determined by introducing a known mass of a pollutant gas into the system while it is being operated in the normal manner. The pollutant is analysed, and the mass calculated according to Annex III, Appendix 3, section 2.4.1 except in the case of propane where a factor of 0,000472 is used in place of 0,000479 for HC. Either of the following two techniques shall be used.
 3.5.1. 
A known quantity of pure gas (propane) shall be fed into the CVS system through a calibrated critical orifice. If the inlet pressure is high enough, the flow rate, which is adjusted by means of the critical flow orifice, is independent of the orifice outlet pressure (critical flow). The CVS system shall be operated as in a normal exhaust emission test for about 5 to 10 minutes. A gas sample shall be analysed with the usual equipment (sampling bag or integrating method), and the mass of the gas calculated. The mass so determined shall be within ± 3% of the known mass of the gas injected.
 3.5.2. 
The weight of a small cylinder filled with propane shall be determined with a precision of ± 0,01 g. For about 5 to 10 minutes, the CVS system shall be operated as in a normal exhaust emission test, while carbon monoxide or propane is injected into the system. The quantity of pure gas discharged shall be determined by means of differential weighing. A gas sample shall be analysed with the usual equipment (sampling bag or integrating method), and the mass of the gas calculated. The mass so determined shall be within ± 3% of the known mass of the gas injected.
”
8)) Appendix 3 shall be amended as follows:

((a)) The following title for this Appendix shall be inserted: "DATA EVALUATION AND CALCULATIONS"
((b)) the title of section 1 shall read "DATA EVALUATION AND CALCULATIONS - NRSC TEST"
((c)) section 1.2 shall be replaced by the following:
“ 1.2 
For the evaluation of the particulates, the total sample masses (MSAM,i) through the filters shall be recorded for each mode. The filters shall be returned to the weighing chamber and conditioned for at least one hour, but not more than 80 hours, and then weighed. The gross weight of the filters shall be recorded and the tare weight (see section 3.1, Annex III) subtracted. The particulate mass (Mf for single filter method; Mf,i for the multiple filter method) is the sum of the particulate masses collected on the primary and back-up filters. If background correction is to be applied, the dilution air mass (MDIL) through the filters and the particulate mass (Md) shall be recorded. If more than one measurement was made, the quotient Md/MDIL must be calculated for each single measurement and the values averaged.
”
((d)) section 1.3.1 shall be replaced by the following:
“ 1.3.1. 
The exhaust gas flow rate (GEXHW,) shall be determined for each mode according to Annex III, Appendix 1, sections 1.2.1 to 1.2.3.

When using a full flow dilution system, the total dilute exhaust gas flow rate (GTOTW,) shall be determined for each mode according to Annex III, Appendix 1, section 1.2.4.
”
((e)) sections 1.3.2 -1.4.6 shall be replaced by the following:
“ 1.3.2. Dry/wet correction (GEXHW,) shall be determined for each mode according to Annex III, Appendix 1, sections 1.2.1 to 1.2.3.
When applying GEXHW the measured concentration shall be converted to a wet basis according to the following formulae, if not already measured on a wet basis:
conc (wet) = kw × conc (dry)
For the raw exhaust gas:
KW,r,1 = 11 + 1,88 × 0,005 × %CO[dry] + %CO2 [dry] + Kw2
For the diluted gas:
KW,e,1 = 1 - 1,88 × CO2 %(wet)200 - KW1
or:
KW,e,1 = 1 - KW11+ 1,88 × CO2 %(dry)200
For the dilution air:
kW,d = 1 - kW1
kW1 = 1,608 × Hd × 1 - 1 / DF + Ha × 1 / DF1000 + 1,608 × Hd × 1 - 1 / DF + Ha × 1 / DF
Hd = 6,22 × Rd × pdpB - pd × Rd × 10-2
For the intake air (if different from the dilution air):
kW,a = 1 - kW2
kW2 = 1,608 × Ha1000 + 1,608 × Ha
Ha = 6,22 × Ra × papB - pa × Ra × 10-2
where:
Haabsolute humidity of the intake air (g water per kg dry air)Hdabsolute humidity of the dilution air (g water per kg dry air)Rdrelative humidity of the dilution air (%)Rarelative humidity of the intake air (%)pdsaturation vapour pressure of the dilution air (kPa)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa).
NOTE: Ha and Hd may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 1.3.3. 
As the NOx emission depends on ambient air conditions, the NOx concentration shall be corrected for ambient air temperature and humidity by the factors KH given in the following formula:

kH = 11 - 0,0182 × Ha - 10,71 + 0,0045 × Ta - 298

where:

Tatemperatures of the air in (K)Hahumidity of the intake air (g water per kg dry air):Ha = 6,220 × Ra × papB - pa × Ra × 10-2

where:

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa).
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 1.3.4. 
The emission mass flow rates for each mode shall be calculated as follows:


((a)) For the raw exhaust gas:Gasmass = u × conc × GEXHW
((b)) For the dilute exhaust gas:
Gasmass = u × concc × GTOTWwhere:
concc is the background corrected concentration
concc = conc - concd × 1-1 / DFDF = 13,4/concCO2 + concCO + concHC × 10-4or:
DF=13,4/concCO2
The coefficients u - wet shall be used according to Table 4:

Gas u conc
NOx 0,001587 ppm
CO 0,000966 ppm
HC 0,000479 ppm
CO2 15,19 percent
The density of HC is based upon an average carbon to hydrogen ratio of 1:1,85.
 1.3.5. 
The specific emission (g/kWh) shall be calculated for all individual components in the following way:

Individual gas = Σi = 1nGasmassi × WFiΣi = 1nPi × WFi

where Pi = Pm,i + PAE,i.

The weighting factors and the number of modes (n) used in the above calculation are according to Annex III, section 3.7.1.
 1.4. 
The particulate emission shall be calculated in the following way:
 1.4.1. 
As the particulate emission of diesel engines depends on ambient air conditions, the particulate mass flow rate shall be corrected for ambient air humidity with the factor Kp given in the following formula:

Kp = 1/1 + 0,0133 × Ha - 10,71

where:

Hahumidity of the intake air, gram of water per kg dry air

Ha = 6,220 × Ra × papB - pa × Ra × 10-2

where:

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa)
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae 1.4.2. 
The final reported test results of the particulate emission shall be derived through the following steps. Since various types of dilution rate control may be used, different calculation methods for equivalent diluted exhaust gas mass flow rate GEDF apply. All calculations shall be based upon the average values of the individual modes (i) during the sampling period.
 1.4.2.1. 
GEDFW,i = GEXHW,i × qi

qi = GDILW,i + GEXHW,i × rGEXHW,i × r

where r corresponds to the ratio of the cross sectional areas of the isokinetic probe Ap and exhaust pipe AT:

r = ApAT
 1.4.2.2. 
GEDFW,i = GEXHW,i × qi

qi = ConcE,i - ConcA,iConcD,i - ConcA,i

where:

ConcEwet concentration of the tracer gas in raw exhaustConcDwet concentration of the tracer gas in the diluted exhaustConcAwet concentration of the tracer gas in the dilution air

Concentrations measured on a dry basis shall be converted to a wet basis according to section 1.3.2..
 1.4.2.3. 
GEDFW,i = 206,6 × GFUEL,iCO2D,i - CO2A,i

where:

CO2DCO2 concentration of the diluted exhaustCO2ACO2 concentration of the dilution air

(concentrations in volume % on wet basis)

This equation is based upon the carbon balance assumption (carbon atoms supplied to the engine are emitted as CO2) and derived through the following steps:

GEDFW,i = GEXHW,i × qi

and:

qi = 206,6 × GFUEL,iGEXHW,i × CO2D,i - CO2A,i
 1.4.2.4. 
GEDFW,i = GEXHW,i × qi

qi = GTOTW,iGTOTW,i - GDILW,i
 1.4.3. 
The final reported test results of the particulate emission shall be derived through the following steps.

All calculations shall be based upon the average values of the individual modes (i) during the sampling period.

GEDFW,i = GTOTW,i
 1.4.4. 
The particulate mass flow rate shall be calculated as follows:

For the single filter method:

PTmass = MfMSAM × GEDFWaver1000

where:

(GEDFW)aver over the test cycle shall be determined by summation of the average values of the individual modes during the sampling period:

GEDFWaver = Σi = 1nGEDFW,i × WFi

MSAM = Σi = 1nMSAM,i

where i = 1,... n

For the multiple filter method:

PTmass = Mf,iMSAM,i × GEDFW,iaver1000

where i = 1,...n

The particulate mass flow rate may be background corrected as follows:

For single filter method:

PTmass = MfMSAM - MdMDIL × Σi = 1i = n1-1DFi × WFi × GEDFWaver1000

If more than one measurement is made, (Md/MDIL) shall be replaced with (Md/MDIL)aver

DF = 13,4/concCO2 + concCO + concHC × 10-4

or:

DF = 13,4/concCO2

For multiple filter method:

PTmass,i = Mf,iMSAM,i - MdMDIL × 1 - 1DFi × GEDFW,i1000

If more than one measurement is made, (Md/MDIL) shall be replaced with (Md/MDIL)aver

DF = 13,4/concCO2 + concCO + concHC × 10-4

or:

DF=13,4/concCO2
 1.4.5. 
The specific emission of particulates PT (g/kWh) shall be calculated in the following way:

For the single filter method:

PT = PTmassΣi = 1nPi × WFi

For the multiple filter method:

PT = Σi = 1nPTmass,i × WFiΣi = 1nPi × WFi
 1.4.6. 
For the single filter method, the effective weighting factor WFE,i for each mode shall be calculated in the following way:

WFE,i = MSAM,i × GEDFWaverMSAM × GEDFW,i

where i = 1,... n.

The value of the effective weighting factors shall be within ± 0,005 (absolute value) of the weighting factors listed in Annex III, section 3.7.1.
”
((f)) The following section shall be inserted:
“ 2. 
The two following measurement principles that can be used for the evaluation of pollutant emissions over the NRTC cycle are described in this section:


— the gaseous components are measured in the raw exhaust gas on a real time basis, and the particulates are determined using a partial flow dilution system;
— the gaseous components and the particulates are determined using a full flow dilution system (CVS system).
 2.1.  2.1.1. 
The instantaneous concentration signals of the gaseous components are used for the calculation of the mass emissions by multiplication with the instantaneous exhaust mass flow rate. The exhaust mass flow rate may be measured directly, or calculated using the methods described in Annex III, Appendix 1, section 2.2.3 (intake air and fuel flow measurement, tracer method, intake air and air/fuel ratio measurement). Special attention shall be paid to the response times of the different instruments. These differences shall be accounted for by time aligning the signals.

For particulates, the exhaust mass flow rate signals are used for controlling the partial flow dilution system to take a sample proportional to the exhaust mass flow rate. The quality of proportionality is checked by applying a regression analysis between sample and exhaust flow as described in Annex III, Appendix 1, section 2.4.
 2.1.2.  2.1.2.1. 
The mass of the pollutants Mgas (g/test) shall be determined by calculating the instantaneous mass emissions from the raw concentrations of the pollutants, the u values from Table 4 (see also Section 1.3.4) and the exhaust mass flow, aligned for the transformation time and integrating the instantaneous values over the cycle. Preferably, the concentrations should be measured on a wet basis. If measured on a dry basis, the dry/wet correction as described here below shall be applied to the instantaneous concentration values before any further calculation is done.


Gas u conc
NOx 0,001587 ppm
CO 0,000966 ppm
HC 0,000479 ppm
CO2 15,19 percent

The density of HC is based upon an average carbon to hydrogen ratio of 1:1,85.

The following formula shall be applied:

Mgas = Σi = 1i = nu × conci × GEXHW,i × 1f(in/g/test)

where

uratio between density of exhaust component and density of exhaust gasconciinstantaneous concentration of the respective component in the raw exhaust gas (ppm)GEXHW,iinstantaneous exhaust mass flow (kg/s)fdata sampling rate (Hz)nnumber of measurements

For the calculation of NOx, the humidity correction factor kH, as described here below, shall be used.

The instantaneously measured concentration shall be converted to a wet basis as described here below, if no1 already measured on a wet basis
 2.1.2.2. 
If the instantaneously measured concentration is measured on a dry basis, it shall be converted to a wet basis according to the following formulae:

concwet = kw × concdry

where

KW,r,1 = 11 + 1,88 × 0,005 × concCO + concCO2 + KW2

with

Kw2 = 1,608 × Ha1000 + 1,608 * Ha

where

concCO2dry CO2 concentration (%)concCOdry CO concentration (%)Haintake air humidity, (g water per kg dry air)

Ha = 6,220 × Ra × papB - pa × Ra × 10-2

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa)
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 2.1.2.3. 
As the NOx emission depends on ambient air conditions, the NOx concentration shall be corrected for humidity and ambient air temperature with the factors given in the following formula:

kH = 11 - 0,0182 × Ha - 10,71 + 0,0045 × Ta - 298

with:

Tatemperature of the intake air, KHahumidity of the intake air,g water per kg dry air

Ha = 6,220 × Ra × papB - pa × Ra × 10-2

where:

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air ( kPa)pBtotal barometric pressure (kPa)
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 2.1.2.4. 
The specific emissions (g/kWh) shall be calculated for each individual component in the following way:

Individual gas = Mgas/Wact

where

Wactactual cycle work as determined in Annex III Section 4.6.2 (kWh)
 2.1.3.  2.1.3.1. 
The mass of particulates MPT (g/test) shall be calculated by either of the following methods:


((a)) MPT = MfMSAM × MEDFW1000
where
Mfparticulate mass sampled over the cycle (mg)MSAMmass of diluted exhaust gas passing the particulate collection filters (kg)MEDFWmass of equivalent diluted exhaust gas over the cycle (kg)
The total mass of equivalent diluted exhaust gas mass over the cycle shall be determined as follows:
MEDFW = Σi = 1i = nGEDFW,i × 1fGEDFW,i = GEXHW,i × qiqi = GTOTW,iGTOTW,i - GDILW,iwhere
GEDFW,iinstantaneous equivalent diluted exhaust mass flow rate (kg/s)GEXHW,iinstantaneous exhaust mass flow rate (kg/s)qiinstantaneous dilution ratioGTOTW,Iinstantaneous diluted exhaust mass flow rate through dilution tunnel (kg/s)GDILW,iinstantaneous dilution air mass flow rate (kg/s)fdata sampling rate (Hz)nnumber of measurements
((b)) MPT = Mfrs x 1000
where
Mfparticulate mass sampled over the cycle (mg)rsaverage sample ratio over the test cycle
where
rs = MSEMEXHW × MSAMMTOTWMSEsampled exhaust mass over the cycle (kg)MEXHWtotal exhaust mass flow over the cycle (kg)MSAMmass of diluted exhaust gas passing the particulate collection filters (kg)MTOTWmass of diluted exhaust gas passing the dilution tunnel (kg)NOTE: In case of the total sampling type system, MSAM and MTOTW are identical.
 2.1.3.2. 
As the particulate emission of diesel engines depends on ambient air conditions, the particulate concentration shall be corrected for ambient air humidity with the factor Kp given in the following formula.

kP = 11 + 0,0133 × Ha -10,71

where

Hahumidity of the intake air in g water per kg dry air

Ha = 6,220 × Ra × papB - pa × Ra × 10-2

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa)
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 2.1.3.3. 
The particulate emission (g/kWh) shall be calculated in the following way:

PT = MPT × Kp / Wact

where

Wactactual cycle work as determined in Annex III Section 4.6.2(kWh)
 2.2. 
For calculation of the emissions in the diluted exhaust gas, it is necessary to know the diluted exhaust gas mass flow rate. The total diluted exhaust gas flow over the cycle MTOTW (kg/test) shall be calculated from the measurement values over the cycle and the corresponding calibration data of the flow measurement device (V0 for PDP, KV for CFV, Cd for SSV): the corresponding methods described in section 2.2.1 may be used. If the total sample mass of particulates (MSAM) and gaseous pollutants exceeds 0,5% of the total CVS flow (MTOTW), the CVS flow shall be corrected for MSAM or the particulate sample flow shall be returned to the CVS prior to the flow measuring device.
 2.2.1. 
PDP-CVS system

The calculation of the mass flow over the cycle, if the temperature of the diluted exhaust is kept within ±6K over the cycle by using a heat exchanger, is as follows:

MTOTW = 1,293 x V0 x NP x (pB - p1) x 273/(101,3 x T)

where

MTOTWmass of the diluted exhaust gas on wet basis over the cycleV0volume of gas pumped per revolution under test conditions (m3/rev)Nptotal revolutions of pump per testpBatmospheric pressure in the test cell (kPa)p1pressure drop below atmospheric at the pump inlet (kPa)Taverage temperature of the diluted exhaust gas at pump inlet over thecycle (K)

If a system with flow compensation is used (i.e. without heat exchanger), the instantaneous mass emissions shall be calculated and integrated over the cycle. In this case, the instantaneous mass of the diluted exhaust gas shall be calculated as follows:

MTOTW,i = 1,293 x V0 x NP,i x pB - p1 x 273 / 101,3 x T

where

NP,itotal revolutions of pump per time interval

CFV-CVS system

The calculation of the mass flow over the cycle, if the temperature of the diluted exhaust gas is kept within ± 11K over the cycle by using a heat exchanger, is as follows:

MTOTW = 1,293 x t x Kv x pA / T0,5

where

MTOTWmass of the diluted exhaust gas on wet basis over the cycletcycle time (s)KVcalibration coefficient of the critical flow venturi for standard conditions,pAabsolute pressure at venturi inlet (kPa)Tabsolute temperature at venturi inlet (K)

If a system with flow compensation is used (i.e. without heat exchanger), the instantaneous mass emissions shall be calculated and integrated over the cycle. In this case, the instantaneous mass of the diluted exhaust gas shall be calculated as follows:

MTOTW,i = 1,293 x Δti x KV x pA / T0,5

where

Δtitime interval(s)

SSV-CVS system

The calculation of the mass flow over the cycle is as follows if the temperature of the diluted exhaust is kept within ± 11 K over the cycle by using a heat exchanger:

MTOTW = 1,293 × QSSV

where

QSSV = A0d2CdPA1Tr1.4286 - r1.7143 · 11 - β4r1.4286

A0collection of constants and units conversions
= 0,006111 in SI units of m3minK12kPa1mm2ddiameter of the SSV throat (m)Cddischarge coefficient of the SSVPAabsolute pressure at venturi inlet (kPa)Ttemperature at the venturi inlet (K)rratio of the SSV throat to inlet absolute, static pressure = 1 - ΔPPAßratio of the SSV throat diameter, d, to the inlet pipe inner diameter = dD

If a system with flow compensation is used (i.e. without heat exchanger), the instantaneous mass emissions shall be calculated and integrated over the cycle. In this case, the instantaneous mass of the diluted exhaust gas shall be calculated as follows:

MTOTW = 1,293 x QSSV x Δti

where

QSSV = A0d2CdPA x 1Tr1.4286 - r1.714311 - ß4r1.4286

Δtitime interval (s)

The real time calculation shall be initialized with either a reasonable value for Cd, such as 0.98, or a reasonable value of Qssv. If the calculation is initialized with Qssv, the initial value of Qssv shall be used to evaluate Re.

During all emissions tests, the Reynolds number at the SSV throat must be in the range of Reynolds numbers used to derive the calibration curve developed in Appendix 2 section 3.2.
 2.2.2. 
As the NOx emission depends on ambient air conditions, the NOx concentration shall be corrected for ambient air humidity with the factors given in the following formulae.

KH = 11 - 0,0182 × Ha - 10,71 + 0,0045 × Ta - 298

where

Tatemperature of the air (K)Hahumidity of the intake air (g water per kg dry air)

in which,

Ha = 6,220 x Ra x papB - pa x Ra x 10-2

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa)
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 2.2.3.  2.2.3.1. 
For systems with heat exchanger, the mass of the pollutants MGAS (g/test) shall be determined from the following equation:

MGAS = u x conc x MTOTW

where

uratio between density of the exhaust component and density of diluted exhaust gas, as reported in Table 4, point 2.1.2.1concaverage background corrected concentrations over the cycle from integration (mandatory for NOx and HC) or bag measurement (ppm)MTOTWtotal mass of diluted exhaust gas over the cycle as determined in section 2.2.1 (kg)

As the NOx emission depends on ambient air conditions, the NOx concentration shall be corrected for ambient air humidity with the factor kH, as described in section 2.2.2.

Concentrations measured on a dry basis shall be converted to a wet basis in accordance with section 1.3.2
 2.2.3.1.1. 
The average background concentration of the gaseous pollutants in the dilution air shall be subtracted from measured concentrations to get the net concentrations of the pollutants. The average values of the background concentrations can be determined by the sample bag method or by continuous measurement with integration. The following formula shall be used.

conc = conce - concd x 1 - 1/DF

where,

concconcentration of the respective pollutant in the diluted exhaust gas, corrected by the amount of the respective pollutant contained in the dilution air (ppm)conceconcentration of the respective pollutant measured in the diluted exhaust gas (ppm)concdconcentration of the respective pollutant measured in the dilution air (ppm)DFdilution factor

The dilution factor shall be calculated as follows:

DF = 13,4conce CO2 + conce HC + conceCO x 10-4
 2.2.3.2. 
For systems without heat exchanger, the mass of the pollutants MGAS (g/test) shall be determined by calculating the instantaneous mass emissions and integrating the instantaneous values over the cycle. Also, the background correction shall be applied directly to the instantaneous concentration value. The following formulae shall be applied:

MGAS = Σi = 1nMTOTW,i × conce,i × u - MTOTW × concd × 1 - 1 / DF × u

where

conce,iinstantaneous concentration of the respective pollutant measured in the diluted exhaust gas (ppm)concdconcentration of the respective pollutant measured in the dilution air (ppm)uratio between density of the exhaust component and density of diluted exhaust gas, as reported in Table 4, point 2.1.2.1MTOTW,iinstantaneous mass of the diluted exhaust gas (section 2.2.1) (kg)MTOTWtotal mass of diluted exhaust gas over the cycle (section 2.2.1) (kg)DFdilution factor as determined in point 2.2.3.1.1.

As the NOx emission depends on ambient air conditions, the NOx concentration shall be corrected for ambient air humidity with the factor kH, as described in section 2.2.2.
 2.2.4. 
The specific emissions (g/kWh) shall be calculated for each individual component in the following way:

Individual gas = Mgas/Wact

where

Wactactual cycle work as determined in Annex III Section 4.6.2 (kWh)
 2.2.5.  2.2.5.1. 
The particulate mass MPT (g/test) shall be calculated as follows:

MPT = MfMSAM x MTOTW1000

Mfparticulate mass sampled over the cycle (mg)MTOTWtotal mass of diluted exhaust gas over the cycle as determined in section 2.2.1 (kg)MSAMmass of diluted exhaust gas taken from the dilution tunnel for collecting particulates (kg)

and,

MfMf,p + Mf,b, if weighed separately (mg)Mf,pparticulate mass collected on the primary filter (mg)Mf,bparticulate mass collected on the back-up filter (mg)

If a double dilution system is used, the mass of the secondary dilution air shall be subtracted from the total mass of the double diluted exhaust gas sampled through the particulate filters.

MSAM = MTOT - MSEC

where

MTOTmass of double diluted exhaust gas through particulate filter (kg)MSECmass of secondary dilution air (kg)

If the particulate background level of the dilution air is determined in accordance with Annex III, section 4.4.4, the particulate mass may be background corrected. In this case, the particulate mass (g/test) shall be calculated as follows:

MPT = MfMSAM - MdMDIL x 1 - 1DF x MTOTW1000

where

Mf, MSAM, MTOTWsee aboveMDILmass of primary dilution air sampled by background particulate sampler (kg)Mdmass of the collected background particulates of the primary dilution air (mg)DFdilution factor as determined in section 2.2.3.1.1
 2.2.5.2. 
As the particulate emission of diesel engines depends on ambient air conditions, the particulate concentration shall be corrected for ambient air humidity with the factor Kp given in the following formula.

kp = 11 + 0,0133 × Ha - 10,71

where

Hahumidity of the intake air in g water per kg dry air

Ha = 6,220 × Ra × papB - pa × Ra × 10-2

where:

Rarelative humidity of the intake air (%)pasaturation vapour pressure of the intake air (kPa)pBtotal barometric pressure (kPa)
NOTE: Ha may be derived from relative humidity measurement, as described above, or from dewpoint measurement, vapour pressure measurement or dry/wet bulb measurement using the generally accepted formulae. 2.2.5.3. 
The particulate emission (g/kWh) shall be calculated in the following way:

PT = MPT × Kp / Wact

where

Wactactual cycle work, as determined in Annex III Section 4.6.2 (kWh)
”
9)) The following Appendices shall be added:
" APPENDIX 4 
Time(s) Norm. Speed(%) Norm. Torque(%)
1 0 0
2 0 0
3 0 0
4 0 0
5 0 0
6 0 0
7 0 0
8 0 0
9 0 0
10 0 0
11 0 0
12 0 0
13 0 0
14 0 0
15 0 0
16 0 0
17 0 0
18 0 0
19 0 0
20 0 0
21 0 0
22 0 0
23 0 0
24 1 3
25 1 3
26 1 3
27 1 3
28 1 3
29 1 3
30 1 6
31 1 6
32 2 1
33 4 13
34 7 18
35 9 21
36 17 20
37 33 42
38 57 46
39 44 33
40 31 0
41 22 27
42 33 43
43 80 49
44 105 47
45 98 70
46 104 36
47 104 65
48 96 71
49 101 62
50 102 51
51 102 50
52 102 46
53 102 41
54 102 31
55 89 2
56 82 0
57 47 1
58 23 1
59 1 3
60 1 8
61 1 3
62 1 5
63 1 6
64 1 4
65 1 4
66 0 6
67 1 4
68 9 21
69 25 56
70 64 26
71 60 31
72 63 20
73 62 24
74 64 8
75 58 44
76 65 10
77 65 12
78 68 23
79 69 30
80 71 30
81 74 15
82 71 23
83 73 20
84 73 21
85 73 19
86 70 33
87 70 34
88 65 47
89 66 47
90 64 53
91 65 45
92 66 38
93 67 49
94 69 39
95 69 39
96 66 42
97 71 29
98 75 29
99 72 23
100 74 22
101 75 24
102 73 30
103 74 24
104 77 6
105 76 12
106 74 39
107 72 30
108 75 22
109 78 64
110 102 34
111 103 28
112 103 28
113 103 19
114 103 32
115 104 25
116 103 38
117 103 39
118 103 34
119 102 44
120 103 38
121 102 43
122 103 34
123 102 41
124 103 44
125 103 37
126 103 27
127 104 13
128 104 30
129 104 19
130 103 28
131 104 40
132 104 32
133 101 63
134 102 54
135 102 52
136 102 51
137 103 40
138 104 34
139 102 36
140 104 44
141 103 44
142 104 33
143 102 27
144 103 26
145 79 53
146 51 37
147 24 23
148 13 33
149 19 55
150 45 30
151 34 7
152 14 4
153 8 16
154 15 6
155 39 47
156 39 4
157 35 26
158 27 38
159 43 40
160 14 23
161 10 10
162 15 33
163 35 72
164 60 39
165 55 31
166 47 30
167 16 7
168 0 6
169 0 8
170 0 8
171 0 2
172 2 17
173 10 28
174 28 31
175 33 30
176 36 0
177 19 10
178 1 18
179 0 16
180 1 3
181 1 4
182 1 5
183 1 6
184 1 5
185 1 3
186 1 4
187 1 4
188 1 6
189 8 18
190 20 51
191 49 19
192 41 13
193 31 16
194 28 21
195 21 17
196 31 21
197 21 8
198 0 14
199 0 12
200 3 8
201 3 22
202 12 20
203 14 20
204 16 17
205 20 18
206 27 34
207 32 33
208 41 31
209 43 31
210 37 33
211 26 18
212 18 29
213 14 51
214 13 11
215 12 9
216 15 33
217 20 25
218 25 17
219 31 29
220 36 66
221 66 40
222 50 13
223 16 24
224 26 50
225 64 23
226 81 20
227 83 11
228 79 23
229 76 31
230 68 24
231 59 33
232 59 3
233 25 7
234 21 10
235 20 19
236 4 10
237 5 7
238 4 5
239 4 6
240 4 6
241 4 5
242 7 5
243 16 28
244 28 25
245 52 53
246 50 8
247 26 40
248 48 29
249 54 39
250 60 42
251 48 18
252 54 51
253 88 90
254 103 84
255 103 85
256 102 84
257 58 66
258 64 97
259 56 80
260 51 67
261 52 96
262 63 62
263 71 6
264 33 16
265 47 45
266 43 56
267 42 27
268 42 64
269 75 74
270 68 96
271 86 61
272 66 0
273 37 0
274 45 37
275 68 96
276 80 97
277 92 96
278 90 97
279 82 96
280 94 81
281 90 85
282 96 65
283 70 96
284 55 95
285 70 96
286 79 96
287 81 71
288 71 60
289 92 65
290 82 63
291 61 47
292 52 37
293 24 0
294 20 7
295 39 48
296 39 54
297 63 58
298 53 31
299 51 24
300 48 40
301 39 0
302 35 18
303 36 16
304 29 17
305 28 21
306 31 15
307 31 10
308 43 19
309 49 63
310 78 61
311 78 46
312 66 65
313 78 97
314 84 63
315 57 26
316 36 22
317 20 34
318 19 8
319 9 10
320 5 5
321 7 11
322 15 15
323 12 9
324 13 27
325 15 28
326 16 28
327 16 31
328 15 20
329 17 0
330 20 34
331 21 25
332 20 0
333 23 25
334 30 58
335 63 96
336 83 60
337 61 0
338 26 0
339 29 44
340 68 97
341 80 97
342 88 97
343 99 88
344 102 86
345 100 82
346 74 79
347 57 79
348 76 97
349 84 97
350 86 97
351 81 98
352 83 83
353 65 96
354 93 72
355 63 60
356 72 49
357 56 27
358 29 0
359 18 13
360 25 11
361 28 24
362 34 53
363 65 83
364 80 44
365 77 46
366 76 50
367 45 52
368 61 98
369 61 69
370 63 49
371 32 0
372 10 8
373 17 7
374 16 13
375 11 6
376 9 5
377 9 12
378 12 46
379 15 30
380 26 28
381 13 9
382 16 21
383 24 4
384 36 43
385 65 85
386 78 66
387 63 39
388 32 34
389 46 55
390 47 42
391 42 39
392 27 0
393 14 5
394 14 14
395 24 54
396 60 90
397 53 66
398 70 48
399 77 93
400 79 67
401 46 65
402 69 98
403 80 97
404 74 97
405 75 98
406 56 61
407 42 0
408 36 32
409 34 43
410 68 83
411 102 48
412 62 0
413 41 39
414 71 86
415 91 52
416 89 55
417 89 56
418 88 58
419 78 69
420 98 39
421 64 61
422 90 34
423 88 38
424 97 62
425 100 53
426 81 58
427 74 51
428 76 57
429 76 72
430 85 72
431 84 60
432 83 72
433 83 72
434 86 72
435 89 72
436 86 72
437 87 72
438 88 72
439 88 71
440 87 72
441 85 71
442 88 72
443 88 72
444 84 72
445 83 73
446 77 73
447 74 73
448 76 72
449 46 77
450 78 62
451 79 35
452 82 38
453 81 41
454 79 37
455 78 35
456 78 38
457 78 46
458 75 49
459 73
460 79 58
461 79 71
462 83 44
463 53 48
464 40 48
465 51 75
466 75 72
467 89 67
468 93 60
469 89 73
470 86 73
471 81 73
472 78 73
473 78 73
474 76 73
475 79 73
476 82 73
477 86 73
478 88 72
479 92 71
480 97 54
481 73 43
482 36 64
483 63 31
484 78 1
485 69 27
486 67 28
487 72 9
488 71 9
489 78 36
490 81 56
491 75 53
492 60 45
493 50 37
494 66 41
495 51 61
496 68 47
497 29 42
498 24 73
499 64 71
500 90 71
501 100 61
502 94 73
503 84 73
504 79 73
505 75 72
506 78 73
507 80 73
508 81 73
509 81 73
510 83 73
511 85 73
512 84 73
513 85 73
514 86 73
515 85 73
516 85 73
517 85 72
518 85 73
519 83 73
520 79 73
521 78 73
522 81 73
523 82 72
524 94 56
525 66 48
526 35 71
527 51 44
528 60 23
529 64 10
530 63 14
531 70 37
532 76 45
533 78 18
534 76 51
535 75 33
536 81 17
537 76 45
538 76 30
539 80 14
540 71 18
541 71 14
542 71 11
543 65 2
544 31 26
545 24 72
546 64 70
547 77 62
548 80 68
549 83 53
550 83 50
551 83 50
552 85 43
553 86 45
554 89 35
555 82 61
556 87 50
557 85 55
558 89 49
559 87 70
560 91 39
561 72 3
562 43 25
563 30 60
564 40 45
565 37 32
566 37 32
567 43 70
568 70 54
569 77 47
570 79 66
571 85 53
572 83 57
573 86 52
574 85 51
575 70 39
576 50 5
577 38 36
578 30 71
579 75 53
580 84 40
581 85 42
582 86 49
583 86 57
584 89 68
585 99 61
586 77 29
587 81 72
588 89 69
589 49 56
590 79 70
591 104 59
592 103 54
593 102 56
594 102 56
595 103 61
596 102 64
597 103 60
598 93 72
599 86 73
600 76 73
601 59 49
602 46 22
603 40 65
604 72 31
605 72 27
606 67 44
607 68 37
608 67 42
609 68 50
610 77 43
611 58 4
612 22 37
613 57 69
614 68 38
615 73 2
616 40 14
617 42 38
618 64 69
619 64 74
620 67 73
621 65 73
622 68 73
623 65 49
624 81 0
625 37 25
626 24 69
627 68 71
628 70 71
629 76 70
630 71 72
631 73 69
632 76 70
633 77 72
634 77 72
635 77 72
636 77 70
637 76 71
638 76 71
639 77 71
640 77 71
641 78 70
642 77 70
643 77 71
644 79 72
645 78 70
646 80 70
647 82 71
648 84 71
649 83 71
650 83 73
651 81 70
652 80 71
653 78 71
654 76 70
655 76 70
656 76 71
657 79 71
658 78 71
659 81 70
660 83 72
661 84 71
662 86 71
663 87 71
664 92 72
665 91 72
666 90 71
667 90 71
668 91 71
669 90 70
670 90 72
671 91 71
672 90 71
673 90 71
674 92 72
675 93 69
676 90 70
677 93 72
678 91 70
679 89 71
680 91 71
681 90 71
682 90 71
683 92 71
684 91 71
685 93 71
686 93 68
687 98 68
688 98 67
689 100 69
690 99 68
691 100 71
692 99 68
693 100 69
694 102 72
695 101 69
696 100 69
697 102 71
698 102 71
699 102 69
700 102 71
701 102 68
702 100 69
703 102 70
704 102 68
705 102 70
706 102 72
707 102 68
708 102 69
709 100 68
710 102 71
711 101 64
712 102 69
713 102 69
714 101 69
715 102 64
716 102 69
717 102 68
718 102 70
719 102 69
720 102 70
721 102 70
722 102 62
723 104 38
724 104 15
725 102 24
726 102 45
727 102 47
728 104 40
729 101 52
730 103 32
731 102 50
732 103 30
733 103 44
734 102 40
735 103 43
736 103 41
737 102 46
738 103 39
739 102 41
740 103 41
741 102 38
742 103 39
743 102 46
744 104 46
745 103 49
746 102 45
747 103 42
748 103 46
749 103 38
750 102 48
751 103 35
752 102 48
753 103 49
754 102 48
755 102 46
756 103 47
757 102 49
758 102 42
759 102 52
760 102 57
761 102 55
762 102 61
763 102 61
764 102 58
765 103 58
766 102 59
767 102 54
768 102 63
769 102 61
770 103 55
771 102 60
772 102 72
773 103 56
774 102 55
775 102 67
776 103 56
777 84 42
778 48 7
779 48 6
780 48 6
781 48 7
782 48 6
783 48 7
784 67 21
785 105 59
786 105 96
787 105 74
788 105 66
789 105 62
790 105 66
791 89 41
792 52 5
793 48 5
794 48 7
795 48 5
796 48 6
797 48 4
798 52 6
799 51 5
800 51 6
801 51 6
802 52 5
803 52 5
804 57 44
805 98 90
806 105 94
807 105 100
808 105 98
809 105 95
810 105 96
811 105 92
812 104 97
813 100 85
814 94 74
815 87 62
816 81 50
817 81 46
818 80 39
819 80 32
820 81 28
821 80 26
822 80 23
823 80 23
824 80 20
825 81 19
826 80 18
827 81 17
828 80 20
829 81 24
830 81 21
831 80 26
832 80 24
833 80 23
834 80 22
835 81 21
836 81 24
837 81 24
838 81 22
839 81 22
840 81 21
841 81 31
842 81 27
843 80 26
844 80 26
845 81 25
846 80 21
847 81 20
848 83 21
849 83 15
850 83 12
851 83 9
852 83 8
853 83 7
854 83 6
855 83 6
856 83 6
857 83 6
858 83 6
859 76 5
860 49 8
861 51 7
862 51 20
863 78 52
864 80 38
865 81 33
866 83 29
867 83 22
868 83 16
869 83 12
870 83 9
871 83 8
872 83 7
873 83 6
874 83 6
875 83 6
876 83 6
877 83 6
878 59 4
879 50 5
880 51 5
881 51 5
882 51 5
883 50 5
884 50 5
885 50 5
886 50 5
887 50 5
888 51 5
889 51 5
890 51 5
891 63 50
892 81 34
893 81 25
894 81 29
895 81 23
896 80 24
897 81 24
898 81 28
899 81 27
900 81 22
901 81 19
902 81 17
903 81 17
904 81 17
905 81 15
906 80 15
907 80 28
908 81 22
909 81 24
910 81 19
911 81 21
912 81 20
913 83 26
914 80 63
915 80 59
916 83 100
917 81 73
918 83 53
919 80 76
920 81 61
921 80 50
922 81 37
923 82 49
924 83 37
925 83 25
926 83 17
927 83 13
928 83 10
929 83 8
930 83 7
931 83 7
932 83 6
933 83 6
934 83 6
935 71 5
936 49 24
937 69 64
938 81 50
939 81 43
940 81 42
941 81 31
942 81 30
943 81 35
944 81 28
945 81 27
946 80 27
947 81 31
948 81 41
949 81 41
950 81 37
951 81 43
952 81 34
953 81 31
954 81 26
955 81 23
956 81 27
957 81 38
958 81 40
959 81 39
960 81 27
961 81 33
962 80 28
963 81 34
964 83 72
965 81 49
966 81 51
967 80 55
968 81 48
969 81 36
970 81 39
971 81 38
972 80 41
973 81 30
974 81 23
975 81 19
976 81 25
977 81 29
978 83 47
979 81 90
980 81 75
981 80 60
982 81 48
983 81 41
984 81 30
985 80 24
986 81 20
987 81 21
988 81 29
989 81 29
990 81 27
991 81 23
992 81 25
993 81 26
994 81 22
995 81 20
996 81 17
997 81 23
998 83 65
999 81 54
1000 81 50
1001 81 41
1002 81 35
1003 81 37
1004 81 29
1005 81 28
1006 81 24
1007 81 19
1008 81 16
1009 80 16
1010 83 23
1011 83 17
1012 83 13
1013 83 27
1014 81 58
1015 81 60
1016 81 46
1017 80 41
1018 80 36
1019 81 26
1020 86 18
1021 82 35
1022 79 53
1023 82 30
1024 83 29
1025 83 32
1026 83 28
1027 76 60
1028 79 51
1029 86 26
1030 82 34
1031 84 25
1032 86 23
1033 85 22
1034 83 26
1035 83 25
1036 83 37
1037 84 14
1038 83 39
1039 76 70
1040 78 81
1041 75 71
1042 86 47
1043 83 35
1044 81 43
1045 81 41
1046 79 46
1047 80 44
1048 84 20
1049 79 31
1050 87 29
1051 82 49
1052 84 21
1053 82 56
1054 81 30
1055 85 21
1056 86 16
1057 79 52
1058 78 60
1059 74 55
1060 78 84
1061 80 54
1062 80 35
1063 82 24
1064 83 43
1065 79 49
1066 83 50
1067 86 12
1068 64 14
1069 24 14
1070 49 21
1071 77 48
1072 103 11
1073 98 48
1074 101 34
1075 99 39
1076 103 11
1077 103 19
1078 103 7
1079 103 13
1080 103 10
1081 102 13
1082 101 29
1083 102 25
1084 102 20
1085 96 60
1086 99 38
1087 102 24
1088 100 31
1089 100 28
1090 98 3
1091 102 26
1092 95 64
1093 102 23
1094 102 25
1095 98 42
1096 93 68
1097 101 25
1098 95 64
1099 101 35
1100 94 59
1101 97 37
1102 97 60
1103 93 98
1104 98 53
1105 103 13
1106 103 11
1107 103 11
1108 103 13
1109 103 10
1110 103 10
1111 103 11
1112 103 10
1113 103 10
1114 102 18
1115 102 31
1116 101 24
1117 102 19
1118 103 10
1119 102 12
1120 99 56
1121 96 59
1122 74 28
1123 66 62
1124 74 29
1125 64 74
1126 69 40
1127 76 2
1128 72 29
1129 66 65
1130 54 69
1131 69 56
1132 69 40
1133 73 54
1134 63 92
1135 61 67
1136 72 42
1137 78 2
1138 76 34
1139 67 80
1140 70 67
1141 53 70
1142 72 65
1143 60 57
1144 74 29
1145 69 31
1146 76 1
1147 74 22
1148 72 52
1149 62 96
1150 54 72
1151 72 28
1152 72 35
1153 64 68
1154 74 27
1155 76 14
1156 69 38
1157 66 59
1158 64 99
1159 51 86
1160 70 53
1161 72 36
1162 71 47
1163 70 42
1164 67 34
1165 74 2
1166 75 21
1167 74 15
1168 75 13
1169 76 10
1170 75 13
1171 75 10
1172 75 7
1173 75 13
1174 76 8
1175 76 7
1176 67 45
1177 75 13
1178 75 12
1179 73 21
1180 68 46
1181 74 8
1182 76 11
1183 76 14
1184 74 11
1185 74 18
1186 73 22
1187 74 20
1188 74 19
1189 70 22
1190 71 23
1191 73 19
1192 73 19
1193 72 20
1194 64 60
1195 70 39
1196 66 56
1197 68 64
1198 30 68
1199 70 38
1200 66 47
1201 76 14
1202 74 18
1203 69 46
1204 68 62
1205 68 62
1206 68 62
1207 68 62
1208 68 62
1209 68 62
1210 54 50
1211 41 37
1212 27 25
1213 14 12
1214 0 0
1215 0 0
1216 0 0
1217 0 0
1218 0 0
1219 0 0
1220 0 0
1221 0 0
1222 0 0
1223 0 0
1224 0 0
1225 0 0
1226 0 0
1227 0 0
1228 0 0
1229 0 0
1230 0 0
1231 0 0
1232 0 0
1233 0 0
1234 0 0
1235 0 0
1236 0 0
1237 0 0
1238 0 0
A graphical display of the NRTC dynamometer schedule is shown below
 APPENDIX 5  1. 
This appendix shall apply to CI engines Stage IIIA and IIIB and IV only.
 1.1. Manufacturers shall determine a Deterioration Factor (DF) value for each regulated pollutant for all Stage IIIA and IIIB engine families. Such DFs shall be used for type approval and production line testing.
 1.1.1. 

1.1.1.1. The manufacturer shall conduct durability tests to accumulate engine operating hours according to a test schedule that is selected on the basis of good engineering judgement to be representative of in-use engine operation in respect to characterizing emission performance deterioration. The durability test period should typically represent the equivalent of at least one quarter of the Emission Durability Period (EDP).
Service accumulation operating hours may be acquired through running engines on a dynamometer test bed or from actual in-field machine operation. Accelerated durability tests can be applied whereby the service accumulation test schedule is performed at a higher load factor than typically experienced in the field. The acceleration factor relating the number of engine durability test hours to the equivalent number of EDP hours shall be determined by the engine manufacturer based on good engineering judgement.
During the period of the durability test, no emission sensitive components can be serviced or replaced other than to the routine service schedule recommended by the manufacturer.
The test engine, subsystems, or components to be used to determine exhaust emission DF's for an engine family, or for engine families of equivalent emission control system technology, shall be selected by the engine manufacturer on the basis of good engineering judgement. The criteria is that the test engine should represent the emission deterioration characteristic of the engine families that will apply the resulting DF values for certification approval. Engines of different bore and stroke, different configuration, different air management systems, different fuel systems can be considered as equivalent in respect to emissions deterioration characteristics if there is a reasonable technical basis for such determination.
DF values from another manufacturer can be applied if there is a reasonable basis for considering technology equivalence with respect to emissions deterioration, and evidence that the tests have been carried according to the specified requirements.
Emissions testing will be performed according to the procedures defined in this Directive for the test engine after initial run-in but before any service accumulation, and at the completion of the durability. Emission tests can also be performed at intervals during the service accumulation test period, and applied in determining the deterioration trend.
1.1.1.2. The service accumulation tests or the emissions tests performed to determine deterioration must not be witnessed by the approval authority.
1.1.1.3. Determination of DF values from Durability Tests
An additive DF is defined as the value obtained by subtraction of the emission value determine at the beginning of the EDP, from the emissions value determined to represent the emission performance at the end of the EDP.
A multiplicative DF is defined as the emission level determined for the end of the EDP divided by the emission value recorded at the beginning of the EDP.
Separate DF values shall be established for each of the pollutants covered by the legislation. In the case of establishing a DF value relative to the NOx+HC standard, for an additive DF, this is determined based on the sum of the pollutants notwithstanding that a negative deterioration for one pollutant may not offset deterioration for the other. For a multiplicative NOx+HC DF, separate HC and NOx DF's shall be determined and applied separately when calculating the deteriorated emission levels from an emissions test result before combining the resultant deteriorated NOx and HC values to esatablish compliance with the standard.
In cases where the testing is not conducted for the full EDP, the emission values at the end of the EDP is determined by extrapolation of the emission deterioration trend established for the test period, to the full EDP.
When emissions test results have been recorded periodically during the service accumulation durability testing, standard statistical processing techniques based on good practice shall be applied to determine the emission levels at the end of the EDP; statistical significance testing can be applied in the determination of the final emissions values.
If the calculation results in a value of less than 1.00 for a multiplicative DF, or less than 0.00 for an additive DF, then the DF shall be 1.0 or 0.00, respectively.
1.1.1.4. A manufacturer may, with the approval of the type approval authority, use DF values established from results of durability tests conducted to obtain DF values for certification of on-road FID CI engines. This will be allowed if there is technological equivalency between the test on-road engine and the non-road engine families applying the DF values for certification. The DF values derived from on-road engine emission durability test results, must be calculated on the basis of EDP values defined in section 2.
1.1.1.5. In the case where an engine family uses established technology, an analysis based on good engineering practices may be used in lieu of testing to determine a deterioration factor for that engine family subject to approval of the type approval authority.
 1.2. 

1.2.1. Additive DF's shall be specified for each pollutant in an engine family certification application for CI engines not using any aftertreatment device.
1.2.2. Multiplicative DF's shall be specified for each pollutant in an engine family certification application for CI engines using an aftertreatment device.
1.2.3. The manufacture shall furnish the Type Approval agency on request with information to support the DF values. This would typically include emission test results, service accumulation test schedule, maintenance procedures together with information to support engineering judgements of technological equivalency, if applicable.
 2.  2.1. 

Category (power band) Useful life (hours)EDP
≤ 37 kW(constant speed engines) 3.000
≤ 37 kW(not constant speed engines) 5.000
> 37 kW 8.000
Engines for the use in inland waterway vessels 10.000
Railcar engines 10.000


3. 

1)) The heading shall be replaced by the following:
“TECHNICAL CHARACTERISTICS OF REFERENCE FUEL PRESCRIBED FOR APPROVAL TESTS AND TO VERIFY CONFORMITY OF PRODUCTIONNON-ROAD MOBILE MACHINERY REFERENCE FUEL FOR CI ENGINES TYPE APPROVED TO MEET STAGE I and II LIMIT VALUES AND FOR ENGINES TO BE USED IN INLAND WATERWAY VESSELS.”
2)) The following text shall be inserted after the current table on reference fuel for diesel as follows:
“
Parameter Unit Limits Test Method
  Minimum Maximum 
Cetane number  52 54,0 EN-ISO 5165
Density at 15oC kg/m3 833 837 EN-ISO 3675
Distillation:    
50% point oC 245 - EN-ISO 3405
95% point oC 345 350 EN-ISO 3405
- Final boiling point oC - 370 EN-ISO 3405
Flash point oC 55 - EN 22719
CFPP oC - -5 EN 116
Viscosity at 40oC mm2/s 2,5 3,5 EN-ISO 3104
Polycyclic aromatic hydrocarbons % m/m 3,0 6,0 IP 391
Sulphur content mg/kg - 300 ASTM D 5453
Copper corrosion  - class 1 EN-ISO 2160
Conradson carbon residue (10% DR) %m/m - 0,2 EN-ISO 10370
Ash content %m/m - 0,01 EN-ISO 6245
Water content %m/m - 0,05 EN-ISO 12937
Neutralisation (strong acid) number mg KOH/g - 0,02 ASTM D 974
Oxidation stability mg/ml - 0,025 EN-ISO 12205





NON-ROAD MOBILE MACHINERY REFERENCE FUEL FOR CI ENGINES TYPE APPROVED TO MEET STAGE IIIB AND IV LIMIT VALUES.
Parameter Unit Limits Test Method
Minimum Maximum
Cetane number   54,0 EN-ISO 5165
Density at 15oC kg/m3 833 837 EN-ISO 3675
Distillation:    
50% point oC 245 - EN-ISO 3405
95% point oC 345 350 EN-ISO 3405
- Final boiling point oC - 370 EN-ISO 3405
Flash point oC 55 - EN 22719
CFPP oC - -5 EN 116
Viscosity at 40oC mm2/s 2,3 3,3 EN-ISO 3104
Polycyclic aromatic hydrocarbons % m/m 3,0 6,0 IP 391
Sulphur content mg/kg - 10 ASTM D 5453
Copper corrosion  - class 1 EN-ISO 2160
Conradson carbon residue (10% DR) % m/m - 0,2 EN-ISO 10370
Ash content % m/m - 0,01 EN-ISO 6245Parameter Unit Limits Test Method
Minimum maximum
Water content % m/m - 0,02 EN-ISO 12937
Neutralisation (strong acid) number mg KOH/g - 0,02 ASTM D 974
Oxidation stability mg/ml - 0,025 EN-ISO 12205
Lubricity (HFRR wear scar diameter at 60oC) µm - 400 CEC F-06-A-96
FAME prohibited



”

4. 
APPENDIX 1 SHALL BE REPLACED BY THE FOLLOWING:

 "Appendix 1 

5. 
The following section shall be added:

“ 3. For engines categories H, I, and J (stage IIIA) and engines category K, L and M (stage IIIB) as defined in Article 9 section 3, the following type-approvals and, where applicable, the pertaining approval marks are recognised as being equivalent to an approval to this Directive;
 3.1. Type-approvals to Directive 88/77/EEC, as amended by Directive 99/96/EC, which are in compliance with stages B1, B2 or C provided for in Article 2 and section 6.2.1 of Annex I.
 3.2. UN-ECE Regulation 49.03 series of amendments which are in compliance with stages B1, B2 and C provided for in paragraph 5.2.
”

ANNEX II


"Annex VI  1. 

Figure Number Description
2 Exhaust gas analysis system for raw exhaust
3 Exhaust gas analysis system for dilute exhaust
4 Partial flow, isokinetic flow, suction blower control, fractional sampling
5 Partial flow, isokinetic flow, pressure blower control, fractional sampling
6 Partial flow, CO2 or NOx control, fractional sampling
7 Partial flow, CO2 or carbon balance, total sampling
8 Partial flow, single venturi and concentration measurement, fractional sampling
9 Partial flow, twin venturi or orifice and concentration measurement, fractional sampling
10 Partial flow, multiple tube splitting and concentration measurement, fractional sampling
11 Partial flow, flow control, total sampling
12 Partial flow, flow control, fractional sampling
13 Full flow, positive displacement pump or critical flow venturi, fractional sampling
14 Particulate sampling system
15 Dilution system for full flow system
 1.1. 
Section 1.1.1 and Figures 2 and 3 contain detailed descriptions of the recommended sampling and analysing systems. Since various configurations can produce equivalent results, exact conformance with these figures is not required. Additional components such as instruments, valves, solenoids, pumps and switches may be used to provide additional information and coordinate the functions of the component systems. Other components which are not needed to maintain the accuracy on some systems, may be excluded if their exclusion is based upon good engineering judgement.
 1.1.1. 
An analytical system for the determination of the gaseous emissions in the raw or diluted exhaust gas is described based on the use of:


— HFID analyser for the measurement of hydrocarbons,
— NDIR analysers for the measurement of carbon monoxide and carbon dioxide,
— HCLD or equivalent analyser for the measurement of nitrogen oxide.

For the raw exhaust gas (Figure 2), the sample for all components may be taken with one sampling probe or with two sampling probes located in close proximity and internally split to the different analysers. Care must be taken that no condensation of exhaust components (including water and sulphuric acid) occurs at any point of the analytical system.

For the diluted exhaust gas (Figure 3), the sample for the hydrocarbons shall be taken with another sampling probe than the sample for the other components. Care must be taken that no condensation of exhaust components (including water and sulphuric acid) occurs at any point of the analytical system.

Figure 2
Figure 3
General statement:

All components in the sampling gas path must be maintained at the temperature specified for the respective systems.


— SP1 raw exhaust gas sampling probe (Figure 2 only)
A stainless steel straight closed and multihole probe is recommended. The inside diameter shall not be greater than the inside diameter of the sampling line. The wall thickness of the probe shall not be greater than 1 mm. There shall be a minimum of three holes in three different radial planes sized to sample approximately the same flow. The probe must extend across at least 80% of the diameter of the exhaust pipe.
— SP2 dilute exhaust gas HC sampling probe (Figure 3 only)
The probe shall:
— be defined as the first 254 mm to 762 mm of the hydrocarbon sampling line (HSL3),
— have a 5 mm minimum inside diameter,
— be installed in the dilution tunnel DT (section 1.2.1.2) at a point where the dilution air and exhaust gas are well mixed (i.e. approximately 10 tunnel diameters downstream of the point where the exhaust enters the dilution tunnel),
— be sufficiently distant (radially) from other probes and the tunnel wall so as to be free from the influence of any wakes or eddies,
— be heated so as to increase the gas stream temperature to 463 K (190oC) ± 10 K at the exit of the probe.
— SP3 dilute exhaust gas CO, CO2, NOx sampling probe (Figure 3 only)
The probe shall:
— be in the same plane as SP2,
— be sufficiently distant (radially) from other probes and the tunnel wall so as to be free from the influence of any wakes or eddies,
— be heated and insulated over its entire length to a minimum temperature of 328 K (55oC) to prevent water condensation.
— HSL1 heated sampling line
The sampling line provides gas sampling from a single probe to the split point(s) and the HC analyser.
The sampling line shall:
— have a 5 mm minimum and a 13,5 mm maximum inside diameter,
— be made of stainless steel or PTFE,
— maintain a wall temperature of 463 (190oC) ± 10 K as measured at every separately controlled heated section, if the temperature of the exhaust gas at the sampling probe is equal or below 463 K (190oC),
— maintain a wall temperature greater than 453 K (180oC) if the temperature of the exhaust gas at the sampling probe is above 463 K (190oC),
— maintain a gas temperature of 463 K (190oC) ± 10 K immediately before the heated filter (F2) and the HFID.
— HSL2 heated NOx sampling line
The sampling line shall:

— maintain a wall temperature of 328 to 473 K (55 to 200oC) up to the converter when using a cooling bath, and up to the analyser when a cooling bath is not used,
— be made of stainless steel or PTFE.Since the sampling line need only be heated to prevent condensation of water and sulphuric acid, the samplingline temperature will depend on the sulphur content of the fuel.
— SL sampling line for CO (CO2)
The line shall be made of PTFE or stainless steel. It may be heated or unheated.

— BK background bag (optional; Figure 3 only)
For the measurement of the background concentrations.
— BG sample bag (optional; Figure 3 CO and CO2 only)
For the measurement of the sample concentrations.
— F1 heated pre-filter (optional)
The temperature shall be the same as HSL1.
— F2 heated filter
The filter shall extract any solid particles from the gas sample prior to the analyser. The temperature shall be the same as HSL1. The filter shall be changed as needed.
— P heated sampling pump
The pump shall be heated to the temperature of HSL1.
— HC
Heated flame ionization detector (HFID) for the determination of the hydrocarbons. The temperature shall be kept at 453 to 473 K (180 to 200oC).
— CO, CO2
NDIR analysers for the determination of carbon monoxide and carbon dioxide.
— NO2
(H)CLD analyser for the determination of the oxides of nitrogen. If a HCLD is used it shall be kept at a temperature of 328 to 473 K (55 to 200oC).
— C converter
A converter shall be used for the catalytic reduction of NO2 to NO prior to analysis in the CLD or HCLD.
— B cooling bath
To cool and condense water from the exhaust sample. The bath shall be maintained at a temperature of 273 to 277 K (0 to 4oC) by ice or refrigeration. It is optional if the analyser is free from water vapour interference as determined in Annex III, Appendix 2, sections 1.9.1 and 1.9.2.
Chemical dryers are not allowed for removing water from the sample.
— T1, T2, T3 temperature sensor
To monitor the temperature of the gas stream.
— T4 temperature sensor Temperature of the NO2-NO converter.
— T5 temperature sensor
To monitor the temperature of the cooling bath.
— G1, G2, G3 pressure gauge
To measure the pressure in the sampling lines.
— R1, R2 pressure regulator
To control the pressure of the air and the fuel, respectively, for the HFID.
— R3, R4, R5 pressure regulator
To control the pressure in the sampling lines and the flow to the analysers.
— FL1, FL2, FL3 flow meter
To monitor the sample bypass flow.
— FL4 to FL7 flow meter (optional)
To monitor the flow rate through the analysers.
— V1 to V6 selector valveSuitable valving for selecting sample, span gas or zero gas flow to the analyser.
— V7, V8 solenoid valve
To bypass the NO2-NO converter.
— V9 needle valve
To balance the flow through the NO2-NO converter and the bypass.
— V10, V11 needle valve
To regulate the flows to the analysers.
— V12, V13 toggle valve
To drain the condensate from the bath B.
— V14 selector valve
Selecting the sample or background bag.
 1.2. 
Sections 1.2.1 and 1.2.2 and Figures 4 to 15 contain detailed descriptions of the recommended dilution and sampling systems. Since various configurations can produce equivalent results, exact conformance with these figures is not required. Additional components such as instruments, valve, solenoids, pumps and switches may be used to provide additional information and coordinate the functions of the component systems. Other components which are not needed to maintain the accuracy on some systems, may be excluded if their exclusion is based on good engineering judgement.
 1.2.1.  1.2.1.1. 

— isokinetic systems (Figures 4 and 5)
With these systems, the flow into the transfer tube is matched to the bulk exhaust flow in terms of gas velocity and/or pressure, thus requiring an undisturbed and uniform exhaust flow at the sampling probe. This is usually achieved by using a resonator and a straight approach tube upstream of the sampling point. The split ratio is then calculated from easily measurable values like tube diameters. It should be noted that isokinesis is only used for matching the flow conditions and not for matching the size distribution. The latter is typically not necessary, as the particles are sufficiently small as to follow the fluid streamlines,
— flow controlled systems with concentration measurement (Figures 6 to 10)
With these systems, a sample is taken from the bulk exhaust stream by adjusting the dilution air flow and the total dilution exhaust flow. The dilution ratio is determined from the concentrations of tracer gases, such as CO2 or NOx, naturally occurring in the engine exhaust. The concentrations in the dilution exhaust gas and in the dilution air are measured, whereas the concentration in the raw exhaust gas can be either measured directly or determined from fuel flow and the carbon balance equation, if the fuel composition is known. The systems may be controlled by the calculated dilution ratio (Figures 6 and 7) or by the flow into the transfer tube (Figures 8, 9 and 10),
— flow controlled systems with flow measurement (Figures 11 and 12)
With these systems, a sample is taken from the bulk exhaust stream by setting the dilution air flow and the total dilution exhaust flow. The dilution ratio is determined from the difference of the two flow rates. Accurate calibration of the flow meters relative to one another is required, since the relative magnitude of the two flow rates can lead to significant errors at higher dilution ratios. Flow control is very straightforward by keeping the dilute exhaust flow rate constant and varying the dilution air flow rate, if needed.
In order to realise the advantages of the partial flow dilution systems, attention must be paid to avoiding the potential problems of loss of particulates in the transfer tube, ensuring that a representative sample is taken from the engine exhaust, and determination of the split ratio.
The systems described pay attention to these critical areas.

Figure 4Raw exhaust gas is transferred from the exhaust pipe to EP to the dilution tunnel DT through the transfer tube TT by the isokinetic sampling probe ISP. The differential pressure of the exhaust gas between exhaust pipe and inlet to the probe is measured with the pressure transducer DPT. This signal is transmitted to the flow controller FC1 that controls the suction blower SB to maintain a differential pressure of zero at the tip of the probe. Under these conditions, exhaust gas velocities in EP and ISP are identical, and the flow through ISP and TT is a constant fraction (split) of the exhaust gas flow. The split ratio is determined from the cross sectional areas of EP and ISP. The dilution air flow rate is measured with the flow measurement device FM1. The dilution ratio is calculated from the dilution air flow rate and the split ratio.
Figure 5Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the transfer tube TT by the isokinetic sampling probe ISP. The differential pressure of the exhaust gas between exhaust pipe and inlet to the probe is measured with the pressure transducer DPT. This signal is transmitted to the flow controller FC1 that controls the pressure blower PB to maintain a differential pressure of zero at the tip of the probe. This is done by taking a small fraction of the dilution air whose flow rate has already been measured with the flow measurement device FM1, and feeding it to TT by means of a pneumatic orifice. Under these conditions, exhaust gas velocities in EP and ISP are identical, and the flow through ISP and TT is a constant fraction (split) of the exhaust gas flow. The split ratio is determined from the cross sectional areas of EP and ISP. The dilution air is sucked through DT by the suction blower SB, and the flow rate is measured with FM1 at the inlet to DT. The dilution ratio is calculated from the dilution air flow rate and the split ratio.
Figure 6Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the sampling probe SP and the transfer tube TT. The concentrations of a tracer gas (CO2 or NOx) are measured in the raw and diluted exhaust gas as well as in the dilution air with the exhaust gas analyser(s) EGA. These signals are transmitted to the flow controller FC2 that controls either the pressure blower PB or the suction blower SB to maintain the desired exhaust split and dilution ratio in DT. The dilution ratio is calculated from the tracer gas concentrations in the raw exhaust gas, the diluted exhaust gas, and the dilution air.
Figure 7Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the sampling probe SP and the transfer tube TT. The CO2 concentrations are measured in the diluted exhaust gas and in the dilution air with the exhaust gas analyser(s) EGA. The CO2 and fuel flow GFUEL signals are transmitted either to the flow controller FC2, or to the flow controller FC3 of the particulate sampling system (Figure 14). FC2 controls the pressure blower PB, while FC3 controls the particulate sampling system (Figure 14), thereby adjusting the flows into and out of the system so as to maintain the desired exhaust split and dilution ratio in DT. The dilution ratio is calculated from the CO2 concentrations and GFUEL using the carbon balance assumption.
Figure 8Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the sampling probe SP and the transfer tube TT due to the negative pressure created by the venturi VN in DT. The gas flow rate through TT depends on the momentum exchange at the venturi zone, and is therefore affected by the absolute temperature of the gas at the exit of TT. Consequently, the exhaust split for a given tunnel flow rate is not constant, and the dilution ratio at low load is slightly lower than at high load. The tracer gas concentrations (CO2 or NOx) are measured in the raw exhaust gas, the diluted exhaust gas, and the dilution air with the exhaust gas analyser(s) EGA, and the dilution ratio is calculated from the values so measured.
Figure 9Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the sampling probe SP and the transfer tube TT by a flow divider that contains a set of orifices or venturis. The first one (FD1) is located in EP, the second one (FD2) in TT. Additionally, two pressure control valves (PCV1 and PCV2) are necessary to maintain a constant exhaust split by controlling the backpressure in EP and the pressure in DT. PC VI is located downstream of SP in EP, PCV2 between the pressure blower PB and DT. The tracer gas concentrations (CO2 or NOx) are measured in the raw exhaust gas, the diluted exhaust gas, and the dilution air with the exhaust gas analyser(s) EGA. They are necessary for checking the exhaust split, and may be used to adjust PCV1 and PCV2 for precise split control. The dilution ratio is calculated from the tracer gas concentrations.
Figure 10Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the transfer tube TT by the flow divider FD3 that consists of a number of tubes of the same dimensions (same diameter, length and bed radius) installed in EP. The exhaust gas through one of these tubes is lead to DT, and the exhaust gas through the rest of the tubes is passed through the damping chamber DC. Thus, the exhaust split is determined by the total number of tubes. A constant split control requires a differential pressure of zero between DC and the outlet of TT, which is measured with the differential pressure transducer DPT. A differential pressure of zero is achieved by injecting fresh air into DT at the outlet of TT. The tracer gas concentrations (CO2 or NOx) are measured in the raw exhaust gas, the diluted exhaust gas, and the dilution air with the exhaust gas analyser(s) EGA. They are necessary for checking the exhaust split and may be used to control the injection air flow rate for precise split control. The dilution ratio is calculated from the tracer gas concentrations.
Figure 11Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the sampling probe SP and the transfer tube TT. The total flow through the tunnel is adjusted with the flow controller FC3 and the sampling pump P of the particulate sampling system (Figure 16).The dilution air flow is controlled by the flow controller FC2, which may use GEXH, GAIR or GFUEL as command signals, for the desired exhaust split. The sample flow into DT is the difference of the total flow and the dilution air flow. The dilution air flow rate is measured with flow measurement device FM1, the total flow rate with the flow measurement device FM3 of the particulate sampling system (Figure 14). The dilution ratio is calculated from these two flow rates.
Figure 12Raw exhaust gas is transferred from the exhaust pipe EP to the dilution tunnel DT through the sampling probe SP and the transfer tube TT. The exhaust split and the flow into DT is controlled by the flow controller FC2 that adjusts the flows (or speeds) of the pressure blower PB and the suction blower SB, accordingly. This is possible since the sample taken with the particulate sampling system is returned into DT. GEXH, GAIR or GFUEL may be used as command signals for FC2. The dilution air flow rate is measured with the flow measurement device FM1, the total flow with the flow measurement device FM2. The dilution ratio is calculated from these two flow rates.

— EP exhaust pipe
The exhaust pipe may be insulated. To reduce the thermal inertia of the exhaust pipe a thickness to diameter ratio of 0,015 or less is recommended. The use of flexible sections shall be limited to a length to diameter ratio of 12 or less. Bends will be minimised to reduce inertial deposition. If the system includes a test bed silencer, the silencer may also be insulated.
For an isokinetic system, the exhaust pipe must be free of elbows, bends and sudden diameter changes for at least six pipe diameters upstream and three pipe diameters downstream of the tip of the probe. The gas velocity at the sampling zone must be higher than 10 m/s except at idle mode. Pressure oscillations of the exhaust gas must not exceed ± 500 Pa on the average. Any steps to reduce pressure oscillations beyond using a chassis-type exhaust system (including silencer and after-treatment device) must not alter engine performance nor cause the deposition of particulates.
For systems without isokinetic probes, it is recommended to have a straight pipe of six pipe diameters upstream and three pipe diameters downstream of the tip of the probe.
— SP sampling probe (Figures 6 to 12)
The minimum inside diameter shall be 4 mm. The minimum diameter ratio between exhaust pipe and probe shall be four. The probe shall be an open tube facing upstream on the exhaust pipe centre-line, or a multiple hole probe as described under SP1 in section 1.1.1.
— ISP isokinetic sampling probe (Figures 4 and 5)
The isokinetic sampling probe must be installed facing upstream on the exhaust pipe centre-line where the flow conditions in section EP are met, and designed to provide a proportional sample of the raw exhaust gas. The minimum inside diameter shall be 12 mm.
A control system is necessary for isokinetic exhaust splitting by maintaining a differential pressure of zero between EP and ISP. Under these conditions exhaust gas velocities in EP and ISP are identical and the mass flow through ISP is a constant fraction of the exhaust gas flow. The ISP has to be connected to a differential pressure transducer. The control to provide a differential pressure of zero between EP and ISP is done with blower speed or flow controller.
— FD1, FD2 flow divider (Figure 9)
A set of venturis or orifices is installed in the exhaust pipe EP and in the transfer tube TT, respectively, to provide a proportional sample of the raw exhaust gas. A control system consisting of two pressure control valves PCV1 and PCV2 is necessary for proportional splitting by controlling the pressures in EP and DT.
— FD3 flow divider (Figure 10)
A set of tubes (multiple tube unit) is installed in the exhaust pipe EP to provide a proportional sample of the raw exhaust gas. One of the tubes feeds exhaust gas to the dilution tunnel DT, whereas the other tubes exit exhaust gas to a damping chamber DC. The tubes must have the same dimensions (same diameter, length, bend radius), so that the exhaust split depends on the total number of tubes. A control system is necessary for proportional splitting by maintaining a differential pressure of zero between the exit of the multiple tube unit into DC and the exit of TT. Under these conditions, exhaust gas velocities in EP and FD3 are proportional, and the flow TT is a constant fraction of the exhaust gas flow. The two points have to be connected to a differential pressure transducer DPT. The control to provide a differential pressure of zero is done with the flow controller FC1.
— EGA exhaust gas analyser (Figures 6 to 10)
CO2 or NOx analysers may be used (with carbon balance method CO2 only). The analysers shall be calibrated like the analysers for the measurement of the gaseous emissions. One or several analysers may be used to determine the concentration differences.
The accuracy of the measuring systems has to be such that the accuracy of GEDFW,i is within ± 4%.
— TT transfer tube (Figures 4 to 12)
The particulate sample transfer tube shall be:

— as short as possible, but not more than 5 m in length,
— equal to or greater than the probe diameter, but not more than 25 mm in diameter,
— exiting on the centre-line of the dilution tunnel and pointing down-stream.If the tube is 1 metre or less in length, it is to be insulated with material with a maximum thermal conductivity of 0,05 W/(m · K) with a radial insulation thickness corresponding to the diameter of the probe. If the tube is longer than 1 metre, it must be insulated and heated to a minimum wall temperature of 523 K (250oC).
Alternatively, the transfer tube wall temperatures required may be determined through standard heat transfer calculations.
— DPT differential pressure transducer (Figures 4, 5 and 10)
The differential pressure transducer shall have a range of ± 500 Pa or less.
— FC1 flow controller (Figures 4, 5 and 10)
For the isokinetic systems (Figures 4 and 5) a flow controller is necessary to maintain a differential pressure of zero between EP and ISP. The adjustment can be done by:

((a)) controlling the speed or flow of the suction blower (SB) and keeping the speed of the pressure blower (PB) constant during each mode (Figure 4);
or
((b)) adjusting the suction blower (SB) to a constant mass flow of the diluted exhaust and controlling the flow of the pressure blower PB, and therefore the exhaust sample flow in a region at the end of the transfer tube (TT) (Figure 5).In the case of a pressure controlled system the remaining error in the control loop must not exceed ± 3 Pa. The pressure oscillations in the dilution tunnel must not exceed ± 250 Pa on average.
For a multi-tube system (Figure 10) a flow controller is necessary for proportional exhaust splitting to maintain a differential pressure of zero between the outlet of the multi-tube unit and the exit of TT. The adjustment can be done by controlling the injection air flow rate into DT at the exit of TT.
— PCV1, PCV2 pressure control valve (Figure 9)
Two pressure control valves are necessary for the twin venturi/twin orifice system for proportional flow splitting by controlling the backpressure of EP and the pressure in DT. The valves shall be located downstream of SP in EP and between PB and DT.
— DC damping chamber (Figure 10)
A damping chamber shall be installed at the exit of the multiple tube unit to minimize the pressure oscillations in the exhaust pipe EP.
— VN venturi (Figure 8)
A venturi is installed in the dilution tunnel DT to create a negative pressure in the region of the exit of the transfer tube TT. The gas flow rate through TT is determined by the momentum exchange at the venturi zone, and is basically proportional to the flow rate of the pressure blower PB leading to a constant dilution ratio. Since the momentum exchange is affected by the temperature at the exit of TT and the pressure difference between EP and DT, the actual dilution ratio is slightly lower at low load than at high load.
— FC2 flow controller (Figures 6, 7, 11 and 12; optional)
A flow controller may be used to control the flow of the pressure blower PB and/or the suction blower SB. It may be connected to the exhaust flow or fuel flow signal and/or to the CO2 or NOx differential signal.
When using a pressurized air supply (Figure 11) FC2 directly controls the air flow.
— FM1 flow measurement device (Figures 6, 7, 11 and 12)
Gas meter or other flow instrumentation to measure the dilution air flow. FM1 is optional if PB is calibrated to measure the flow.
— FM2 flow measurement device (Figure 12)
Gas meter or other flow instrumentation to measure the diluted exhaust gas flow. FM2 is optional if the suction blower SB is calibrated to measure the flow.
— PB pressure blower (Figures 4, 5, 6, 7, 8, 9 and 12)
To control the dilution air flow rate, PB may be connected to the flow controllers FC1 or FC2. PB is not required when using a butterfly valve. PB may be used to measure the dilution air flow, if calibrated.
— SB suction blower (Figures 4, 5, 6, 9, 10 and 12)
For fractional sampling systems only. SB may be used to measure the dilute exhaust gas flow, if calibrated.
— DAF dilution air filter (Figures 4 to 12)
It is recommended that the dilution air be filtered and charcoal scrubbed to eliminate background hydrocarbons. The dilution air shall have a temperature of 298 K (25oC) ± 5 K.
At the manufacturer's request the dilution air shall be sampled according to good engineering practice to determine the background particulate levels, which can then be subtracted from the values measured in the diluted exhaust.
— PSP particulate sampling probe (Figures 4, 5, 6, 8, 9, 10 and 12)
The probe is the leading section of PTT and
— shall be installed facing upstream at a point where the dilution air and exhaust gas are well mixed, i.e. on the dilution tunnel DT centre-line of the dilution systems approximately 10 tunnel diameters downstream of the point where the exhaust enters the dilution tunnel,
— shall be 12 mm in minimum inside diameter,
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air preheating, provided the air temperature does not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel,
— may be insulated.
— DT dilution tunnel (Figures 4 to 12)
The dilution tunnel:
— shall be of a sufficient length to cause complete mixing of the exhaust and dilution air under turbulent flow conditions,
— shall be constructed of stainless steel with:
— a thickness to diameter ratio of 0,025 or less for dilution tunnels of greater than 75 mm inside diameter,
— a nominal wall thickness of not less than 1,5 mm for dilution tunnels of equal to or less than 75 mm inside diameter,
— shall be at least 75 mm in diameter for the fractional sampling type,
— is recommended to be at least 25 mm in diameter for the total sampling type.
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air preheating, provided the air temperature does not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel.
— may be insulated.

The engine exhaust shall be thoroughly mixed with the dilution air. For fractional sampling systems, the mixing quality shall be checked after introduction into service by means of a CO2 profile of the tunnel with the engine running (at least four equally spaced measuring points). If necessary, a mixing orifice may be used.
NOTE: If the ambient temperature in the vicinity of the dilution tunnel (DT) is below 293 K (20oC), precautions should be taken to avoid particle losses onto the cool walls of the dilution tunnel. Therefore, heating and/or insulating the tunnel within the limits given above is recommended.
At high engine loads, the tunnel may be cooled by a non-aggressive means such as a circulating fan, as long as the temperature of the cooling medium is not below 293 K (20oC).


— HE heat exchanger (Figures 9 and 10)

The heat exchanger shall be of sufficient capacity to maintain the temperature at the inlet to the suction blower SB within ± 11 K of the average operating temperature observed during the test.
 1.2.1.2. 
A dilution system is described based upon the dilution of the total exhaust using the constant volume sampling (CVS) concept. The total volume of the mixture of exhaust and dilution air must be measured. Either a PDP or a CFV or a SSV system may be used.

For subsequent collection of the particulates, a sample of the dilute exhaust gas is passed to the particulate sampling system (section 1.2.2, Figures 14 and 15). If this is done directly, it is referred to as single dilution. If the sample is diluted once more in the secondary dilution tunnel, it is referred to as double dilution. This is useful, if the filter face temperature requirement cannot be met with single dilution. Although partly a dilution system, the double dilution system is described as a modification of a particulate sampling system in section 1.2.2, (Figure 15), since it shares most of the parts with a typical particulate sampling system.

The gaseous emissions may also be determined in the dilution tunnel of a full flow dilution system. Therefore, the sampling probes for the gaseous components are shown in Figure 13 but do not appear in the description list. The respective requirements are described in section 1.1.1.

Descriptions (Figure 13)


— EP exhaust pipe
The exhaust pipe length from the exit of the engine exhaust manifold, turbocharger outlet or after-treatment device to the dilution tunnel is required to be not more than 10 m. If the system exceeds 4 m in length, then all tubing in excess of 4 m shall be insulated, except for an in-line smoke-meter, if used. The radial thickness of the insulation must be at least 25 mm. The thermal conductivity of the insulating material must have a value no greater than 0,1 W/(m · K) measured at 673 K (400oC). To reduce the thermal inertia of the exhaust pipe a thickness to diameter ratio of 0,015 or less is recommended. The use of flexible sections shall be limited to a length to diameter ratio of 12 or less.

Figure 13
The total amount of raw exhaust gas is mixed in the dilution tunnel DT with the dilution air. The diluted exhaust gas flow rate is measured either with a positive displacement pump PDP or with a critical flow venturi CFV or with a sub-sonic venturi SSV. A heat exchanger FIE or electronic flow compensation EFC may be used for proportional particulate sampling and for flow determination. Since particulate mass determination is based on the total diluted exhaust gas flow, the dilution ratio is not required to be calculated.


— PDP positive displacement pump
The PDP meters total diluted exhaust flow from the number of the pump revolutions and the pump displacement. The exhaust system back pressure must not be artificially lowered by the PDP or dilution air inlet system. Static exhaust back pressure measured with the CVS system operating shall remain within ± 1,5 kPa of the static pressure measured without connection to the CVS at identical engine speed and load.
The gas mixture temperature immediately ahead of the PDP shall be within ± 6 K of the average operating temperature observed during the test, when no flow compensation is used.
Flow compensation can only be used if the temperature at the inlet of the PDP does not exceed 50oC (323 K).
— CFV critical flow venturi
CFV measures total diluted exhaust flow by maintaining the flow at choked conditions (critical flow). Static exhaust backpressure measured with the CFV system operating shall remain within ± 1,5 kPa of the static pressure measured without connection to the CFV at identical engine speed and load. The gas mixture temperature immediately ahead of the CFV shall be within ± 11 K of the average operating temperature observed during the test, when no flow compensation is used.
— SSV sub-sonic venturi
SSV measures total diluted exhaust flow as a function of inlet pressure, inlet temperature, pressure drop between the SSV inlet and throat. Static exhaust backpressure measured with the SSV system operating shall remain within ± 1,5 kPa of the static pressure measured without connection to the SSV at identical engine speed and load. The gas mixture temperature immediately ahead of the SSV shall be within ± 11 K of the average operating temperature observed during the test, when no flow compensation is used.
— HE heat exchanger (optional if EFC is used)
The heat exchanger shall be of sufficient capacity to maintain the temperature within the limits required above.
— EFC electronic flow compensation (optional if HE is used)
If the temperature at the inlet to either the PDP or CFV or SSV is not kept within the limits stated above, a flow compensation system is required for continuous measurement of the flow rate and control of the proportional sampling in the particulate system. To that purpose, the continuously measured flow rate signals are used to correct the sample flow rate through the particulate filters of the particulate sampling system (Figures 14 and 15), accordingly.
— DT dilution tunnel
The dilution tunnel:

— shall be small enough in diameter to cause turbulent flow (Reynolds number greater than 4000) of sufficient length to cause complete mixing of the exhaust and dilution air. A mixing orifice may be used,
— shall be at least 75 mm in diameter,
— may be insulated.The engine exhaust shall be directed downstream at the point where it is introduced into the dilution tunnel, and thoroughly mixed.
When using single dilution, a sample from the dilution tunnel is transferred to the particulate sampling system (section 1.2.2, Figure 14). The flow capacity of the PDP or CFV or SSV must be sufficient to maintain the diluted exhaust at a temperature of less than or equal to 325 K (52oC) immediately before the primary particulate filter.
When using double dilution, a sample from the dilution tunnel is transferred to the secondary dilution tunnel where it is further diluted, and then passed through the sampling filters (section 1.2.2, Figure 15). The flow capacity of the PDP or CFV or SSV must be sufficient to maintain the diluted exhaust stream in the DT at a temperature of less than or equal to 464 K (191oC) at the sampling zone. The secondary dilution system must provide sufficient secondary dilution air to maintain the doubly-diluted exhaust stream at a temperature of less than or equal to 325 K (52oC) immediately before the primary particulate filter.
— DAF dilution air filter
It is recommended that the dilution air be filtered and charcoal scrubbed to eliminate background hydrocarbons. The dilution air shall have a temperature of 298 K (25oC) ± 5 K. At the manufacturer's request the dilution air shall be sampled according to good engineering practice to determine the background particulate levels, which can then be subtracted from the values measured in the diluted exhaust.
— PSP particulate sampling probe
The probe is the leading section of PTT and
— shall be installed facing upstream at a point where the dilution air and exhaust gas are well mixed, i.e. on the dilution tunnel DT centre-line of the dilution systems approximately 10 tunnel diameters downstream of the point where the exhaust enters the dilution tunnel,
— shall be 12 mm in minimum inside diameter,
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air preheating, provided the air temperature does not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel,
— may be insulated.
 1.2.2. 
The particulate sampling system is required for collecting the particulates on the particulate filter. In the case of total sampling partial flow dilution, which consists of passing the entire dilute exhaust sample through the filters, dilution (section 1.2.1.1, Figures 7 and 11) and sampling system usually form an integral unit. In the case of fractional sampling partial flow dilution or full flow dilution, which consists of passing through the filters only a portion of the diluted exhaust, the dilution (section 1.2.1.1, Figures 4, 5, 6, 8, 9, 10 and 12 and section 1.2.1.2, Figure 13) and sampling systems usually form different units.

In this Directive, the double dilution system DDS (Figure 15) of a full flow dilution system is considered as a specific modification of a typical particulate sampling system as shown in Figure 14. The double dilution system includes all important parts of the particulate sampling system, like filter holders and sampling pump, and additionally some dilution features, like a dilution air supply and a secondary dilution tunnel.

In order to avoid any impact on the control loops, it is recommended that the sample pump be running throughout the complete test procedure. For the single filter method, a bypass system shall be used for passing the sample through the sampling filters at the desired times. Interference of the switching procedure on the control loops must be minimized.

Descriptions - Figures 14 and 15


— PSP particulate sampling probe (Figures 14 and 15)
The particulate sampling probe shown in the figures is the leading section of the particulate transfer tube PTT. The probe:
— shall be installed facing upstream at a point where the dilution air and exhaust gas are well mixed, i.e. on the dilution tunnel DT centre-line of the dilution systems (section 1.2.1), approximately 10 tunnel diameters downstream of the point where the exhaust enters the dilution tunnel),
— shall be 12 mm in minimum inside diameter,
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air pre-heating, provided the air temperature does not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel,
— may be insulated.

Figure 14A sample of the diluted exhaust gas is taken from the dilution tunnel DT of a partial flow or full flow dilution system through the particulate sampling probe PSP and the particulate transfer tube PTT by means of the sampling pump P. The sample is passed through the filter holders(s) FH that contain the particulate sampling filters. The sample flow rate is controlled by the flow controller FC3. If electronic flow compensation EFC (Figure 13) is used, the diluted exhaust gas flow is used as command signal for FC3.
Figure 15A sample of the diluted exhaust gas is transferred from the dilution tunnel DT of a full flow dilution system through the particulate sampling probe PSP and the particulate transfer tube PTT to the secondary dilution tunnel SDT, where it is diluted once more. The sample is then passed through the filter holder(s) FH that contain the particulate sampling filters. The dilution air flow rate is usually constant whereas the sample flow rate is controlled by the flow controller FC3. If electronic flow compensation EFC (Figure 13) is used, the total diluted exhaust gas flow is used as command signal for FC3.

— PTT particulate transfer tube (Figures 14 and 15)
The particulate transfer tube must not exceed 1 020 mm in length, and must be minimised in length whenever possible.
The dimensions are valid for:

— the partial flow dilution fractional sampling type and the full flow single dilution system from the probe tip to the filter holder,
— the partial flow dilution total sampling type from the end of the dilution tunnel to the filter holder,
— the full flow double dilution system from the probe tip to the secondary dilution tunnel.The transfer tube:
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air preheating, provided the air temperature does not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel,
— may be insulated.
— SDT secondary dilution tunnel (Figure 15)
The secondary dilution tunnel should have a minimum diameter of 75 mm and should be sufficient length so as to provide a residence time of at least 0,25 seconds for the doubly-diluted sample. The primary filter holder, FH, shall be located within 300 mm of the exit of the SDT. The secondary dilution tunnel:
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air preheating, provided the air temperature does not exceed 325 K (52oC) prior to the introduction of the exhaust in the dilution tunnel,
— may be insulated.
— FH filter holder(s) (Figures 14 and 15)
For primary and back-up filters one filter housing or separate filter housings may be used. The requirements of Annex III, Appendix 1, section 1.5.1.3 have to be met.
The filter holder(s):
— may be heated to no greater than 325 K (52oC) wall temperature by direct heating or by dilution air preheating, provided the air temperature does not exceed 325 K (52oC),
— may be insulated.
— P sampling pump (Figures 14 and 15)
The particulate sampling pump shall be located sufficiently distant from the tunnel so that the inlet gas temperature is maintained constant (± 3 K), if flow correction by FC3 is not used.
— DP dilution air pump (Figure 15) (full flow double dilution only)
The dilution air pump shall be located so that the secondary dilution air is supplied at a temperature of 298 K (25oC) ± 5 K.
— FC3 flow controller (Figures 14 and 15)
A flow controller shall be used to compensate the particulate sample flow rate for temperature and backpressure variations in the sample path, if no other means are available. The flow controller is required if electronic flow compensation EFC (Figure 13) is used.
— FM3 flow measurement device (Figures 14 and 15) (particulate sample flow)
The gas meter or flow instrumentation shall be located sufficiently distant from the sample pump so that the inlet gas temperature remains constant (± 3 K), if flow correction by FC3 is not used.
— FM4 flow measurement device (Figure 15) (dilution air, full flow double dilution only)
The gas meter or flow instrumentation shall be located so that the inlet gas temperature remains at 298 K (25 oC) ± 5K.
— BV ball valve (optional)
The ball valve shall have a diameter not less than the inside diameter of the sampling tube and a switching time of less than 0,5 seconds.NOTE: If the ambient temperature in the vicinity of PSP, PTT, SDT, and FH is below 239 K (20oC), precautions should be taken to avoid particle losses onto the cool wall of these parts. Therefore, heating and/or insulating these parts within the limits given in the respective descriptions is recommended. It is also recommended that the filter face temperature during sampling be not below 293 K (20oC).At high engine loads, the above parts may be cooled by a non-aggressive means such as a circulating fan, as long as the temperature of the cooling medium is not below 293 K (20oC).


ANNEX III


"Annex XIII 
PROVISIONS FOR ENGINES PLACED ON THE MARKET UNDER A "FLEXIBLE SCHEME"
On the request of an equipment manufacturer (OEM), and permission being granted by an approval authority, an engine manufacturer may during the period between two successive stages of limit values place a limited number of engines on the market that only comply with the previous stage of emission limit values in accordance with the following provisions:
 1.  1.1. An OEM that wishes to make use of the flexibility scheme shall request permission from any approval authority to purchase from his engine suppliers, in the period between two emissions stages, the quantities of engines described in sections 1.2 and 1.3, that do not comply with the current emission limit values, but are approved to the nearest previous stage of emission limits.
 1.2. The number of engines placed on the market under a flexibility scheme shall, in each engine category, not exceed 20% of the OEM's annual sales of equipment with engines in that engine category (calculated as the average of the latest 5 years sales on the EU market). Where an OEM has marketed equipment in the EU for a period of less than 5 years the average will be calculated based on the period for which the OEM has marketed equipment in the EU.
 1.3. 

Engine Category Number of Engines
19-37kW 200
37-75kW 150
75-130kW 100
130-560kW 50
 1.4. 

((a)) a sample of the labels to be affixed to each piece of non-road mobile machinery in which an engine placed on the market under the flexibility scheme will be installed. The labels shall bear the following text: "MACHINE NO ... (sequence of machines) OF ... (total number of machines in respective power band) WITH ENGINE No ... WITH TYPE APPROVAL (Dir. 97/68/EC) No ..."; and
((b)) a sample of the supplementary label to be affixed on the engine bearing the text referred to in section 2.2 of this Annex.
 1.5. The OEM shall notify the approval authorities of each Member State of the use of the flexibility scheme.
 1.6. The OEM shall provide the approval authority with any information connected with the implementation of the flexibility scheme that the approval authority may request as necessary for the decision.
 1.7. The OEM shall file a report every six months to the approval authorities of each Member State on the implementation of the flexibility schemes he is using. The report shall include cumulative data on the number of engines and NRMM placed on the market under the flexibility scheme, engine and NRMM serial numbers, and the Member States where the NRMM have been placed on the market. This procedure shall be continued as long as a flexibility scheme is still in progress.
 2.  2.1. An engine manufacturer may place on the market engines under a flexible scheme covered by an approval in accordance with Section 1 of this Annex.
 2.2. The engine manufacturer must put a label on those engines with the following text: "Engine placed on the market under the flexibility scheme".
 3.  3.1. The approval authority shall evaluate the content of the flexibility scheme request and the enclosed documents. As a consequence it will inform the OEM of its decision as to whether or not to allow use of the flexibility scheme.


ANNEX IV


Annex XIV 
PN(kW) CO(g/kWh) HC(g/kWh) NOx(g/k/Wh) PT(g/kWh)
37 ≤ PN < 75 6,5 1,3 9,2 0,85
75 ≤ PN < 130 5,0 1,3 9,2 0,70
P ≥ 130 5,0 1,3 n ≥ 2800 tr/min = 9.2500 ≤ n < 2800 tr/min = 45 x n (-0.2) 0,54

Annex XV 
PN(kW) CO(g/kWh) HC(g/kWh) NOx(g/kWh) PT(g/kWh)
18 ≤ PN < 37 5,5 1,5 8,0 0,8
37 ≤ PN < 75 5,0 1,3 7,0 0,4
75 ≤ PN < 130 5,0 1,0 6,0 0,3
130 ≤ PN < 560 3,5 1,0 6,0 0,2
PN ≥ 560 3,5 1,0 n ≥ 3150 min-1 = 6,0343 ≤ n < 3150 min-1 = 45 x n(-0,2) - 3n < 343 mm-1 =11,0 0,2

