
Article 1 

1. The Daimler engine compartment encapsulation system is approved as an innovative technology within the meaning of Article 12 of Regulation (EC) No 443/2009.
2. The CO2 emissions reduction from the use of the Daimler engine compartment encapsulation system referred to in paragraph 1 shall be determined using the methodology set out in the Annex.
Article 2 
This Decision shall enter into force on the twentieth day following that of its publication in the Official Journal of the European Union.
Done at Brussels, 10 September 2013.
For the Commission
The President
José Manuel BARROSO
ANNEX
1. 
In order to determine the CO2 reductions that can be attributed to the use of the Daimler engine encapsulation system in an M1 vehicle, it is necessary to establish the following:


((a)) the testing procedure to be followed for determining the cool-down curves of the eco-innovation vehicle with and without an engine compartment encapsulation;
((b)) the testing procedure to be followed to determine the Hot Start Benefit (HSB) of the eco-innovation vehicle;
((c)) the formulae for calculating the variation coefficients;
((d)) the formulae for calculating the CO2 savings;
((e)) the determination of the CO2 savings for the certification by type-approval authorities.

2. 
The cool-down curves shall be determined experimentally for the baseline and the eco-innovation vehicle. The curves shall be applicable for vehicle variants with the same heat capacities, engine bay packaging and engine heat insulation as those available in the baseline and EI vehicle. The experimental test shall include continuous measurements of representative coolant temperatures by means of a thermocouple at a constant ambient temperature of at least 14 °C over 24 hours. The engine shall be heated up to the maximum coolant temperature before cut-off by a sufficient number of consecutive New European Driving Cycles (NEDC) as specified in point 3.

After preconditioning, for deactivation of all pumps and fans, the ignition shall be switched off and the dash key pulled out. The car’s bonnet shall be closed completely. Any artificial ventilation systems inside the test cell shall be switched off. The resulting measurement curves shall be converged by the mathematical approach described by formula 1.

Formula 1: Tt=T0− TA× e− d× t+ TA

with:

T(t)temperature over time [°C]TOtemperature of the operating engine [°C]TAambient temperature [°C]ddecay constant [1/h]

The least squares method shall be used for the fitting of the two curves. To do that, the temperature measurement data of the first 20 minutes after engine cut-off is not to be considered because of the untypical behaviour of the coolant temperature after switching off the coolant system.

3. 
The HSB of the EI vehicle shall be determined experimentally. This value describes the difference of CO2 emissions between a cold start and a hot start NEDC test in relation to the cold start result:

Formula 2: HSB=1−CO2hotCO214 °C

with:

HSBHot Start BenefitCO2 (hot)CO2 emissions of hot start NEDC test [g CO2/km]CO2 (14 °C)CO2 emissions of cold start NEDC test [g CO2/km]

The coolant temperature at the beginning of the cold start test and the ambient temperature in the test cell shall not be below 14 °C. The hot start NEDC test shall be conducted following the cold start NEDC test. It is possible to perform one or two preconditioning NEDC tests between the cold start and the hot start NEDC test. It shall be ensured and documented that the state of charge (SOC) variation (for example, using his Controller Area Network signal) of the starter battery after each test is within 5 %. The complete test procedure shall be repeated at least two times. Arithmetic means of the cold start and of the hot start CO2 results and the respective variation coefficients of the means shall be calculated. The complete test procedure shall be repeated as long as the variation coefficients of both arithmetic means are below 1 % (see point 4).

4. 
The variation coefficients of the arithmetic means shall be calculated using the following formulae:

Formula 3: cv=sx-–∕x-–

cvvariation coefficient;sx-–standard deviation of arithmetic mean [g CO2/km];x-–arithmetic mean [g CO2/km];

and

Formula 4: sx-–=∑i= 1nxi− x-–2nn− 1

sx-–standard deviation of arithmetic mean [g CO2/km];ximeasurement value [g CO2/km];x-–arithmetic mean [g CO2/km];nnumber of measurements.

5. 
The relative CO2 reduction potential ΔCO2(t) for different parking times shall be calculated using formula 5 with the following input data:


— decay constant of the eco-innovation vehicle without an engine compartment encapsulation (baseline vehicle): dB [1/h]. This value shall be calculated with formula 1;
— decay constant of eco-innovation vehicle with an engine compartment encapsulation: dE [1/h]. This value shall be calculated with formula 1;
— Hot Start Benefit: HSB. This value shall be calculated with formula 2;
— parking time distribution (share of vehicle stops): SVS. Table 2 (below) shall be used;
— CO2 type-approval value: TACO2 [g CO2/km], i.e. CO2 mass emissions combined.

Formula 5: ΔCO2=1,443× lne− dE× t+ 1e− dB× t+ 1× HSB

The calculation results shall be given in the following Table 1:


Parking time [h] 0,5 1,5 2,5 3,5 4,5 5,5 6,5 7,5 8,5 9,5 10,5 11,5
ΔCO2(t) [%]            
Parking time [h] 12,5 13,5 14,5 15,5 16,5 17,5 18,5 19,5 20,5 21,5 22,5 23,5
ΔCO2(t) [%]            

The total CO2 savings, weighted by the parking times (pt) shall be calculated using formula 6.

Formula 6: CCO2=TACO2×∑pt= 124ΔCO2tpt× SVSpt

Where the values for parking time [h] and SVS [%] shall be those in Table 2:


Parking time [h] 0,5 1,5 2,5 3,5 4,5 5,5 6,5 7,5 8,5 9,5 10,5 11,5
SVS [%] 36 13 6 4 2 2 1 1 3 4 3 1
Parking time [h] 12,5 13,5 14,5 15,5 16,5 17,5 18,5 19,5 20,5 21,5 22,5 23,5
SVS [%] 1 3 3 2 1 1 1 1 1 1 1 1

The CO2 savings shall be the type-approval value (CO2 mass emissions combined) multiplied by a factor of x. The value of x is equal to the term ∑ΔCO2tpt× SVSpt of formula 6.

Where an existing vehicle type is equipped with the innovative technology the following formula shall be used:

Formula 7: CCO2=x * TACO2 baseline vehicle

with:

CCO2CO2 savings [g CO2/km]TACO2 baseline vehicletype-approval value of the eco-innovation vehicle without an engine compartment encapsulation [g CO2/km]

Where the innovative technology is installed on a new vehicle type and the type-approval CO2 value has been determined with the innovative technology installed, the following formula for calculating the CO2 savings shall be used:

Formula 8: CCO2=x∕1− x*TACO2 new vehicle type

with:

CCO2CO2 savings [g CO2/km]TACO2 new vehicle typetype-approval value of the new vehicle type equipped with the innovative technology [g CO2/km]

6. 
For the purposes of determining the general eco-innovation code to be used in the relevant type-approval documents in accordance with Annexes I, VIII and IX to Directive 2007/46/EC of the European Parliament and of the Council, the individual code to be used for the innovative technology approved through this Decision shall be ‘3’.

For example, the code of the eco-innovation in the case of eco-innovation savings certified by the German type-approval authority shall be ‘e1 3’.
