
Article 1 
The technology used in 12 Volt efficient alternators intended for the conversion of mechanical energy into electrical energy is approved as an innovative technology within the meaning of Article 11 of Regulation (EU) 2019/631, taking into account that it is not covered by the standard test procedure set out in Regulation (EU) 2017/1151 and provided that the innovative technology conforms to the following conditions:

((a)) it is fitted in internal combustion engine powered passenger cars (M1) and light commercial vehicles (N1);
((b)) it is used solely to charge the vehicle battery and to power the electrical system of the vehicle when its combustion engine is running;
((c)) it has an efficiency, i.e. a conversion rate from mechanical into electric power, of at least:

((i)) 73,8 % for petrol-fuelled vehicles other than turbo-charged;
((ii)) 73,4 % for turbo-charged petrol-fuelled vehicles;
((iii)) 74,2 % for diesel-fuelled vehicles.
Article 2 

1. A manufacturer may apply to  the Secretary of State  for certification of the CO2 savings from the use of the technology approved in accordance with Article 1 (‘the technology’) in one or several 12 Volt efficient alternators by reference to this Decision.
2. The manufacturer shall ensure that the application for the certification is accompanied by a verification report from an independent and certified body confirming that the conditions set out in Article 1 have been met.
3. Where the savings have been certified in accordance with Article 3, the manufacturer shall ensure that the certified CO2 savings and the eco-innovation code referred to in Article 4(1) are recorded in the certificates of conformity of the vehicles concerned.
Article 3 

1. The  Secretary of State  shall ensure that CO2 savings achieved from the use of the innovative technology have been determined using the methodology set out in the Annex.
2. Where a manufacturer applies for the certification of the CO2 savings from the use of the technology in more than one 12 Volt efficient alternator in relation to one vehicle version, the  Secretary of State  shall determine which of the 12 Volt efficient alternators tested delivers the lowest CO2 savings. That value shall be used for the purposes of paragraph 3.
3. The  Secretary of State  shall record the certified CO2 savings determined in accordance with paragraph 1 or 2 and the eco-innovation code referred to in Article 4(1) in the relevant type-approval documentation.
4. The  Secretary of State  shall record all the elements considered for the certification in a test report and keep that together with the verification report referred to in Article 2(2) ....
5. The  Secretary of State  shall only certify CO2 savings, if  Secretary of State  finds that the technology used in the 12 Volt efficient alternator or alternators comply with the conditions set out in Article 1, and if the CO2 savings achieved are 0,5 g CO2/km or higher as specified in Article 9(1)(b) of Implementing Regulation (EU) No 725/2011 in the case of passenger cars or of Implementing Regulation (EU) No 427/2014 in the case of light commercial vehicles.
Article 4 

1. The innovative technology approved by this Decision is attributed with the eco-innovation code No 29.
2. The certified CO2 savings recorded by reference to that eco-innovation code may be taken into account for the calculation of the average specific emissions of manufacturers starting from the calendar year 2021.
Article 5 
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Done at Brussels, 6 February 2020.
For the Commission
The President
Ursula VON DER LEYEN
ANNEX
1. 
In order to determine the CO2 savings that can be attributed to the use of a 12 V efficient alternator in a passenger car and light commercial vehicle with internal combustion engine powertrain, it is necessary to specify the following:


((1)) the testing conditions;
((2)) the test equipment;
((3)) the procedure to determine the total efficiency;
((4)) the procedure to determine the CO2 savings;
((5)) the procedure to determine the uncertainty of the CO2 savings.

2. 

 - CO2 savings [g CO2/km]
CO2 - Carbon dioxide
CF - Conversion factor (l/100 km) - (g CO2/km) [gCO2/l] as defined in Table 3
h - Frequency as defined in Table 1
I - Current intensity at which the measurement shall be carried out [A]
m - Number of measurements of the sample
M - Torque [Nm]
n - Rotational frequency [min-1] as defined in Table 1
P - Power [W]
sηEI - Standard deviation of the eco-innovative alternator efficiency [%]
 - Standard deviation of the eco-innovative alternator efficiency mean [%]
 - Standard deviation of the total CO2 savings [g CO2/km]
U - Test voltage at which the measurement shall be carried out [V]
v - Mean driving speed of the Worldwide harmonised Light-duty vehicles Test Cycle (WLTC) [km/h]
VPe - Consumption of effective power [l/kWh] as defined in Table 2
 - Sensitivity of calculated CO2 savings related to the efficiency of the eco-innovative alternator


Δ - Difference
η - Baseline alternator efficiency [%]
ηEI - Efficient alternator efficiency [%]
 - Mean of the eco-innovative alternator efficiency at operating point i [%]

Index (i) refers to operating point

Index (j) refers to measurement of the sample


EI - Eco-innovative
m - Mechanical
RW - Real-world conditions
TA - Type-approval conditions
B - Baseline

3. 
The testing conditions shall fulfil the requirements specified in ISO 8854:2012.

4. 
The test equipment shall be in accordance with the specifications set out in ISO 8854:2012.

5. 
The efficiency of the 12 V efficient alternator shall be determined in accordance with ISO 8854:2012, with the exception of the elements specified in the present paragraph.

The measurements shall be conducted at different operating points i, as defined in Table 1. The alternator current intensity is defined as half of the rated current for all operating points. For each speed the voltage and the output current of the alternator are to be kept constant, the voltage at 14,3 V.


Operating pointi Holding time[s] Rotational frequencyni [min-1] Frequencyhi
1 1 200 1 800 0,25
2 1 200 3 000 0,40
3 600 6 000 0,25
4 300 10 000 0,10

The efficiency shall be calculated in accordance with Formula 1.



All efficiency measurements shall be performed consecutively at least five (5) times. The average of the measurements at each operating point () has to be calculated.

The efficiency of the eco-innovative alternator (ηEI) shall be calculated in accordance with Formula 2



The efficient alternator leads to saved mechanical power under real-world conditions (ΔPmRW) and type approval conditions (ΔPmTA) as defined in Formula 3.

Formula 3

ΔPm = ΔPmRW - ΔPmTA

where the saved mechanical power under real-world conditions (ΔPmRW) is calculated in accordance with Formula 4 and the saved mechanical power under type-approval conditions (ΔPmTA) in accordance with Formula 5.





Where:

PRWPower requirement under real-world conditions [W], which is 750WPTAPower requirement under type-approval conditions [W], which is 350WηBEfficiency of the baseline alternator [%], which is 67%

6. 
The CO2 savings of the efficient alternator are to be calculated with Formula 6.



Where:

vMean driving speed of the WLTC [km/h], which is 46,60 km/hVPeConsumption of effective power specified in the following Table 2:


Type of engine Consumption of effective power (VPe)[l/kWh]
Petrol 0,264
Petrol Turbo 0,280
Diesel 0,220

CF: Factor specified in the following Table 3:


Type of fuel Conversion factor (l/100 km) - (g CO2/km) (CF)[gCO2/l]
Petrol 2 330
Diesel 2 640

7. 
The statistical errors in the results of the testing methodology caused by the measurements shall be quantified. For each operating point the standard deviation shall be calculated in accordance with Formula 7:



The standard deviation of the efficiency value of the efficient alternator (sηEI) shall be calculated in accordance with Formula 8:



The standard deviation of the alternator efficiency (sηEI) leads to an error in the CO2 savings (). That error shall be calculated in accordance with Formula 9:



8. 
It has to be demonstrated for each type, variant and version of a vehicle fitted with the efficient alternator that the error in the CO2 savings calculated in accordance with Formula 9 is not greater than the difference between the total CO2 savings and the minimum savings threshold specified in Article 9(1) of Regulation (EU) No 725/2011 (see Formula 10).



Where:

MTMinimum threshold [gCO2/km]Total CO2 saving [gCO2/km]Standard deviation of the total CO2 saving [gCO2/km]CO2 correction coefficient due to the positive mass difference between the efficient alternator and the baseline alternator.  shall be calculated following Table 4:


CO2 correction coefficient due to the extra mass
Petrol () [g CO2/km kg] 0,0277•Δm
Diesel () [g CO2/km kg] 0,0383•Δm

In Table 4, ‘Δm’ is the extra mass due to the installation of the efficient alternator. It is the positive difference between the mass of the efficient alternator and the mass of baseline alternator. The mass of the baseline alternator is 7 kg. On the evaluation of the extra mass the manufacturer must hand over verified documentation to the type-approval authority.

9. 
The report shall include:


— Model and mass of the tested alternators
— Description of the bench
— Test results (measured values)
— Calculated results and corresponding formulae.

10. 
The type-approval authority shall certify the CO2 savings based on measurements of the efficient alternator and the baseline alternator using the test methodology set out in this Annex. Where the CO2 emission savings are below the threshold specified in Article 9(1), the second subparagraph of Article 11(2) of Regulation (EU) No 725/2011 shall apply.
