ANNEX to the Commission Regulation (EU) .../... implementing Regulation (EU) No 595/2009 of the European Parliament and of the Council as regards the determination of the CO2 emissions and fuel consumption of heavy-duty vehicles and amending Directive 2007/46/EC of the European Parliament and of the Council and Commission Regulation (EU) No 582/2011

Council of the European Union Brussels, 6 September 2017 (OR. en)

11880/17 ADD 2

ENV 726 CLIMA 227 ENT 185 MI 606

COVER NOTE

From: European Commission date of receipt: 31 August 2017

To: General Secretariat of the Council

No. Cion doc.: D051106/03 - Annex 6

Subject: ANNEX to the Commission Regulation (EU) .../... implementing Regulation (EU) No 595/2009 i of the European Parliament and of the Council as

regards the determination of the CO2 emissions and fuel consumption of heavy-duty vehicles and amending Directive 2007/46/EC i of the European Parliament and of the Council and Commission Regulation (EU) No 582/2011 i

Delegations will find attached document D051106/03 - Annex 6.

Encl.: D051106/03 - Annex 6

EUROPEAN COMMISSION

Brussels, XXX D051106/03 […] (2017) XXX draft

ANNEX 6

ANNEX

to the

Commission Regulation (EU) .../...

implementing Regulation (EU) No 595/2009 i of the European Parliament and of the

Council as regards the determination of the CO 2 emissions and fuel consumption of

heavy-duty vehicles and amending Directive 2007/46/EC i of the European Parliament

and of the Council and Commission Regulation (EU) No 582/2011 i

ANNEX

to the

Commission Regulation (EU) .../...

implementing Regulation (EU) No 595/2009 i of the European Parliament and of the Council as regards the determination of the CO 2 emissions and fuel consumption of heavy-duty

vehicles and amending Directive 2007/46/EC i of the European Parliament and of the Council and Commission Regulation (EU) No 582/2011 i

ANNEX VI

VERIFYING TRANSMISSION, TORQUE CONVERTER, OTHER TORQUE TRANSFERRING COMPONENT AND ADDITIONAL DRIVELINE COMPONENT

DATA

• 1. 

  Introduction

This annex describes the certification provisions regarding the torque losses of

transmissions, torque converter (TC), other torque transferring components (OTTC) and

additional driveline components (ADC) for heavy duty vehicles. In addition it defines

calculation procedures for the standard torque losses.

Torque converter (TC), other torque transferring components (OTTC) and additional

driveline components (ADC) can be tested in combination with a transmission or as a

separate unit. In the case that those components are tested separately the provisions of

section 4, 5 and 6 apply. Torque losses resulting from the drive mechanism between the

transmission and those components can be neglected.

• 2. 

  Definitions

For the purposes of this Annex the following definitions shall apply:

• (1) 

  “Transfer case” means a device that splits the engine power of a vehicle and directs

it to the front and rear drive axles. It is mounted behind the transmission and both

front and rear drive shafts connect to it. It comprises either a gearwheel set or a

chain drive system in which the power is distributed from the transmission to the

axles. The transfer case will typically have the ability to shift between standard

drive mode (front or rear wheel drive), high range traction mode (front and rear

wheel drive), low range traction mode and neutral;

• (2) 

  “Gear ratio” means the forward gear ratio of the speed of the input shaft (towards

prime mover) to the speed of the output shaft (towards driven wheels) without slip

(i = n in /n out );

• (3) 

  “Ratio coverage” means the ratio of the largest to the smallest forward gear ratios

in a transmission: ϕ tot = i max /i min ;

• (4) 

  “Compound transmission” means a transmission, with a large number of forward

gears and/or large ratio coverage, composed of sub-transmissions, which are

combined to use most power-transferring parts in several forward gears;

• (5) 

  “Main section” means the sub-transmission that has the largest number of forward

gears in a compound transmission;

• (6) 

  “Range section” means a sub-transmission normally in series connection with the

main section in a compound transmission. A range section usually has two

shiftable forward gears. The lower forward gears of the complete transmission are

embodied using the low range gear. The higher gears are embodied using the high

range gear;

• (7) 

  “Splitter” means a design that splits the main section gears in two (usually)

variants, low- and high split gears, whose gear ratios are close compared to the

ratio coverage of the transmission. A splitter can be a separate sub-transmission, an

add-on device, integrated with the main section or a combination thereof;

• (8) 

  “Tooth clutch” means a clutch where torque is transferred mainly by normal forces

between mating teeth. A tooth clutch can either be engaged or disengaged. It is

operated in load-free conditions, only (e.g., at gear shifts in a manual transmission);

• (9) 

  “Angle drive” means a device that transmits rotational power between non-parallel

shafts, often used with transversely oriented engine and longitudinal input to driven

axle;

• (10) 

  “Friction clutch” means clutch for transfer of propulsive torque, where torque is

sustainably transferred by friction forces. A friction clutch can transmit torque

while slipping, it can thereby (but does not have to) be operated at start-offs and at

powershifts (retained power transfer during a gear shift);

• (11) 

  “Synchroniser” means a type of tooth clutch where a friction device is used to

equalise the speeds of the rotating parts to be engaged;

• (12) 

  “Gear mesh efficiency” means the ratio of output power to input power when

transmitted in a forward gear mesh with relative motion;

• (13) 

  “Crawler gear” means a low forward gear (with speed reduction ratio that is larger

than for the non-crawler gears) that is designed to be used infrequently, e.g., at

low-speed manoeuvres or occasional up-hill start-offs;

• (14) 

  “Power take-off (PTO)” means a device on a transmission or an engine to which an

auxiliary driven device, e.g., a hydraulic pump, can be connected;

• (15) 

  “Power take-off drive mechanism” means a device in a transmission that allows the

installation of a power take-off (PTO);

• (16) 

  “Lock-up clutch” means a friction clutch in a hydrodynamic torque converter; it

can connect the input and output sides, thereby eliminating the slip;

• (17) 

  “Start-off clutch” means a clutch that adapts speed between engine and driven

wheels when the vehicle starts off. The start-off clutch is usually located between

engine and transmission;

• (18) 

  “Synchronised Manual Transmission (SMT)” means a manually operated

transmission with two or more selectable speed ratios that are obtained using

synchronisers. Ratio changing is normally achieved during a temporary

disconnection of the transmission from the engine using a clutch (usually the

vehicle start-off clutch);

• (19) 

  “Automated Manual Transmission or Automatic Mechanically-engaged

Transmission (AMT)” means an automatically shifting transmission with two or

more selectable speed ratios that are obtained using tooth clutches (un/synchronised).

Ratio changing is achieved during a temporary disconnection of the

transmission from the engine. The ratio shifts are performed by an electronically

controlled system managing the timing of the shift, the operation of the clutch

between engine and gearbox and the speed and torque of the engine. The system

selects and engages the most suitable forward gear automatically, but can be

overridden by the driver using a manual mode;

• (20) 

  “Dual Clutch Transmission (DCT)” means an automatically shifting transmission

with two friction clutches and several selectable speed ratios that are obtained by

the use of tooth clutches. The ratio shifts are performed by an electronically

controlled system managing the timing of the shift, the operation of the clutches

and the speed and torque of the engine. The system selects the most suitable gear

automatically, but can be overridden by the driver using a manual mode;

• (21) 

  "Retarder” means an auxiliary braking device in a vehicle powertrain; aimed for

permanent braking;

• (22) 

  “Case S” means the serial arrangement of a torque converter and the connected

mechanical parts of the transmission;

• (23) 

  “Case P” means the parallel arrangement of a torque converter and the connected

mechanical parts of the transmission (e.g. in power split installations);

• (24) 

  “Automatic Powershifting Transmission (APT)” means an automatically shifting

transmission with more than two friction clutches and several selectable speed

ratios that are obtained mainly by the use of those friction clutches. The ratio shifts

are performed by an electronically controlled system managing the timing of the

shift, the operation of the clutches and the speed and torque of the engine. The

system selects the most suitable gear automatically, but can be overridden by the

driver using a manual mode. Shifts are normally performed without traction

interruption (friction clutch to friction clutch);

• (25) 

  ”Oil conditioning system” means an external system that conditions the oil of a

transmission at testing. The system circulates oil to and from the transmission. The

oil is thereby filtered and/or temperature conditioned;

• (26) 

  ”Smart lubrication system” means a system that will affect the load independent

losses (also called spin losses or drag losses) of the transmission depending on the

input torque and/or power flow through the transmission. Examples are controlled

hydraulic pressure pumps for brakes and clutches in an APT, controlled variable oil

level in the transmission, controlled variable oil flow/pressure for lubrication and

cooling in the transmission. Smart lubrication can also include control of the oil

temperature of the transmission, but smart lubrication systems that are designed

only for controlling the temperature are not considered here, since the transmission

testing procedure has fixed testing temperatures;

• (27) 

  “Transmission electric auxiliary” means an electric auxiliary used for the function

of the transmission during running steady state operation. A typical example is an

electric cooling/lubrication pump (but not electric gear shift actuators and

electronic control systems including electric solenoid valves, since they are low

energy consumers, especially at steady state operation);

• (28) 

  “Oil type viscosity grade” means a viscosity grade as defined by SAE J306;
• (29) 

  “Factory fill oil” means the oil type viscosity grade that is used for the oil fill in the

factory and which is intended to stay in the transmission, torque converter, other

torque transferring component or in an additional driveline component for the first

service interval;

• (30) 

  ”Gearscheme” means the arrangement of shafts, gearwheels and clutches in a

transmission;

• (31) 

  “Powerflow” means the transfer path of power from input to output in a

transmission via shafts, gearwheels and clutches.

• 3. 

  Testing procedure for transmissions

For testing the losses of a transmission the torque loss map for each individual

transmission type shall be measured. Transmissions may be grouped into families with

similar or equal CO 2 -relevant data following the provisions of Appendix 6 to this Annex.

For the determination of the transmission torque losses, the applicant for a certificate

shall apply one of the following methods for each single forward gear (crawler gears

excluded).

• (1) 

  Option 1: Measurement of the torque independent losses, calculation of the

torque dependent losses.

• (2) 

  Option 2: Measurement of the torque independent losses, measurement of the

torque loss at maximum torque and interpolation of the torque dependent losses

based on a linear model

• (3) 

  Option 3: Measurement of the total torque loss.

3.1 Option 1: Measurement of the torque independent losses, calculation of the torque

dependent losses.

The torque loss T l , in on the input shaft of the transmission shall be calculated by

𝑇 𝑙,𝑖𝑛 (𝑛 𝑖𝑛 , 𝑇 𝑖𝑛 , 𝑔𝑒𝑎𝑟)

• = 

  𝑇

  𝑙,𝑖𝑛,min _𝑙𝑜𝑠𝑠 + 𝑓 𝑇 ∗ 𝑇 𝑖𝑛 + 𝑓 𝑙𝑜𝑠𝑠_𝑐𝑜𝑟𝑟 ∗ 𝑇 𝑖𝑛 + 𝑇 𝑙,𝑖𝑛,min_𝑒𝑙 + 𝑓 𝑒𝑙_𝑐𝑜𝑟𝑟 ∗ 𝑇 𝑖𝑛

The correction factor for the torque dependent hydraulic torque losses shall be calculated by

𝑓 (𝑇 𝑙,𝑖𝑛,𝑚𝑎𝑥_𝑙𝑜𝑠𝑠 − 𝑇 𝑙,𝑖𝑛,𝑚𝑖𝑛_𝑙𝑜𝑠𝑠 )

𝑙𝑜𝑠𝑠_𝑐𝑜𝑟𝑟 = 𝑇

𝑚𝑎𝑥,𝑖𝑛

The correction factor for the torque dependent electric torque losses shall be calculated by

𝑓 (𝑇 𝑙,𝑖𝑛,𝑚𝑎𝑥_𝑒𝑙 − 𝑇 𝑙,𝑖𝑛,𝑚𝑖𝑛_𝑒𝑙 )

𝑒𝑙_𝑐𝑜𝑟𝑟 = 𝑇

𝑚𝑎𝑥,𝑖𝑛

The torque loss at the input shaft of the transmission caused by the power consumption of transmission electric auxiliary shall be calculated by

𝑇 𝑒𝑙

𝑙,𝑖𝑛,𝑒𝑙 =

𝑃

(0.7 ∗ 𝑛 𝑖𝑛 ∗ 2𝜋 60)

where: T l,in = Torque loss related to input shaft [Nm] T l,in,min_loss = Torque independent loss at minimum hydraulic loss level (minimum main pressure, cooling/lubrication flows etc.), measured with free rotating output shaft from testing without load [Nm] T l,in,max_loss = Torque independent loss at maximum hydraulic loss level (maximum main pressure, cooling/lubrication flows etc.), measured with free rotating output shaft from testing without load [Nm] f loss_corr = Loss correction for hydraulic loss level depending on input torque [-] n in = Speed at the transmission input shaft (downstream of torque converter, if applicable) [rpm] f T = Torque loss coefficient = 1-η T T in = Torque at the input shaft [Nm] η T = Torque dependent efficiency (to be calculated); for a direct gear f T = 0.007 (η T =0.993) [-] f el_corr = Loss correction for electric power loss level depending on input torque [-] T l,in, el = Additional torque loss on input shaft by electric consumers [Nm] T l,in,min_el = Additional torque loss on input shaft by electric consumers corresponding to minimum electric power [Nm] T l,in,max_el = Additional torque loss on input shaft by electric consumers corresponding to maximum electric power [Nm] P el = Electric power consumption of electric consumers in transmission measured during transmission loss testing [W] T max,in = Maximum allowed input torque for any forward gear in the transmission [Nm]

3.1.1. The torque dependent losses of a transmission system shall be determined as described in the following:

In case of multiple parallel and nominally equal power flows, e.g., twin countershafts or several planet gearwheels in a planetary gear set, that can be treated as one power flow in this section.

3.1.1.1. For each indirect gear g of common transmissions with a non-split power flow and ordinary, non-planetary gear sets, the following steps shall be performed:

3.1.1.2. For each active gear mesh, the torque dependent efficiency shall be set to constant values of ηm:

external – external gear meshes: η m = 0.986 external – internal gear meshes: η m = 0.993 angle drive gear meshes: η m = 0.97 (Angle drive losses may alternatively be determined by separate testing as described in paragraph 6. of this Annex)

3.1.1.3. The product of these torque dependent efficiencies in active gear meshes shall be multiplied with a torque dependent bearing efficiency ηb = 99.5%.

3.1.1.4. The total torque dependent efficiency for the gear g shall be calculated by:

η 𝑇𝑔 = η 𝑏 ∗ η 𝑚,1 ∗ η 𝑚,2 ∗ [… ] ∗ η 𝑚,𝑛

3.1.1.5. The torque dependent loss coefficient for the gear g shall be calculated by:

𝑓 𝑇𝑔 = 1– η 𝑇𝑔

3.1.1.6. The torque dependent loss on the input shaft for gear g shall be calculated by:

𝑇

𝑙,𝑖𝑛𝑇𝑔 = 𝑓 𝑇𝑔 ∗ 𝑇 𝑖𝑛

3.1.1.7. The torque dependent efficiency of the planetary range section in low range state for the special case of transmissions consisting of a countershaft-type main section in series with a planetary range section (with non-rotating ring gearwheel and the planet carrier connected to the output shaft) may, alternatively to the procedure described in 3.1.1.8., be calculated by:

1 + η ring m , ring * η m , sun * z

η = z sun lowrange

1 + z ring z

sun

where: η m,ring = Torque dependent efficiency of the ring-to-planet gear mesh = 99.3% [-] η m,sun = Torque dependent efficiency of the planet-to-sun gear mesh = 98.6% [-] z sun = Number of teeth of the sun gearwheel of the range section [-] z ring = Number of teeth of the ring gearwheel of the range section [-] The planetary range section shall be regarded as an additional gear mesh within the countershaft main section, and its torque dependent efficiency η lowrange shall be included in the determination of the total torque dependent efficiencies η Tg for the low-range gears in the calculation in 3.1.1.4.

3.1.1.8. For all other transmission types with more complex split power flows and/or planetary gear sets (e.g. a conventional automatic planetary transmission), the following simplified method shall be used to determine the torque dependent efficiency. The method covers transmission systems composed of ordinary, non-planetary gear sets and/or planetary gear sets of ring-planet-sun type. Alternatively the torque dependent efficiency may be calculated based on VDI Regulation No. 2157. Both calculations shall use the same constant gear mesh efficiency values defined in 3.1.1.2.

In this case, for each indirect gear g, the following steps shall be performed: 3.1.1.9. Assuming 1 rad/s of input speed and 1 Nm of input torque, a table of speed (N i ) and

torque (T i ) values for all gearwheels with a fix rotational axis (sun gearwheels, ring gearwheels and ordinary gearwheels) and planet carriers shall be created. Speed and torque values shall follow the right-hand rule, with engine rotation as the positive

direction. 3.1.1.10. For each planetary gear set, the relative speeds sun-to-carrier and ring-to-carrier

shall be calculated by: 𝑁

𝑠𝑢𝑛−𝑐𝑎𝑟𝑟𝑖𝑒𝑟 = 𝑁 𝑠𝑢𝑛 − 𝑁 𝑐𝑎𝑟𝑟𝑖𝑒𝑟

𝑁

𝑟𝑖𝑛𝑔−𝑐𝑎𝑟𝑟𝑖𝑒𝑟 = 𝑁 𝑟𝑖𝑛𝑔 − 𝑁 𝑐𝑎𝑟𝑟𝑖𝑒𝑟

where:

N sun = Rotational speed of sun gearwheel [rad/s] N ring = Rotational speed of ring gearwheel [rad/s] N carrier = Rotational speed of carrier [rad/s]

3.1.1.11. The loss-producing powers in the gear meshes shall be computed in the following way:

For each ordinary, non-planetary gear set, the power P shall be calculated by: 𝑃

1 = 𝑁 1 ∙ 𝑇 1

𝑃

2 = 𝑁 2 ∙ 𝑇 2

where: P = Power of gear mesh [W] N = Rotational speed of gearwheel [rad/s] T = Torque of gearwheel [Nm] For each planetary gear set, the virtual power of sun P v,sun and ring gearwheels P v,ring shall be calculated by: 𝑃

𝑣,𝑠𝑢𝑛 = 𝑇 𝑠𝑢𝑛 ∙ (𝑁 𝑠𝑢𝑛 − 𝑁 𝑐𝑎𝑟𝑟𝑖𝑒𝑟 ) = 𝑇 𝑠𝑢𝑛 ∙ 𝑁 𝑠𝑢𝑛/𝑐𝑎𝑟𝑟𝑖𝑒𝑟

𝑃

𝑣,𝑟𝑖𝑛𝑔 = 𝑇 𝑟𝑖𝑛𝑔 ∙ (𝑁 𝑟𝑖𝑛𝑔 − 𝑁 𝑐𝑎𝑟𝑟𝑖𝑒𝑟 ) = 𝑇 𝑟𝑖𝑛𝑔 ∙ 𝑁 𝑟𝑖𝑛𝑔/𝑐𝑎𝑟𝑟𝑖𝑒𝑟

where: P v,sun = Virtual power of sun gearwheel [W] P v,ring = Virtual power of ring gearwheel [W] T sun = Torque of sun gearwheel [Nm] T carrier = Torque of carrier [Nm] T ring = Torque of ring gearwheel [Nm] Negative virtual power results shall indicate power leaving the gear set, positive virtual power results shall indicate power going into the gear set. The loss-adjusted powers P adj of the gear meshes shall be computed in the following way: For each ordinary, non-planetary gear set, the negative power shall be multiplied by the appropriate torque dependent efficiency η m : 𝑃

𝑖 > 0 ⇒ 𝑃 𝑖,𝑎𝑑𝑗 = 𝑃 𝑖

𝑃

𝑖 < 0 ⇒ 𝑃 𝑖,𝑎𝑑𝑗 = 𝑃 𝑖 ∙ η 𝑚𝑖

where: P adj = Loss-adjusted powers of the gear meshes [W] η m = Torque dependent efficiency (appropriate to gear mesh; see 3.1.1.2.) [-] For each planetary gear set, the negative virtual power shall be multiplied by the torquedependent efficiencies of sun-to-planet η msun and ring-to-planet η mring : 𝑃

𝑣,𝑖 ≥ 0 ⇒ 𝑃 𝑖,𝑎𝑑𝑗 = 𝑃 𝑣,𝑖

𝑃 𝑣,𝑖 < 0 ⇒ 𝑃 𝑖,𝑎𝑑𝑗 = 𝑃 𝑖 ∙ η 𝑚𝑠𝑢𝑛 ∙ η 𝑚𝑟𝑖𝑛𝑔

where: η msun = Torque dependent efficiency of sun-to-planet [-] η mring = Torque dependent efficiency of ring-to-planet [-]

3.1.1.12. All loss-adjusted power values shall be added up to the torque dependent gear mesh power loss P m,loss of the transmission system referring to the input power:

𝑃

𝑚,𝑙𝑜𝑠𝑠 = Σ𝑃 𝑖,𝑎𝑑𝑗

where: i = All gearwheels with a fix rotational axis [-] P m,loss = Torque dependent gear mesh power loss of the transmission system [W]

3.1.1.13. The torque dependent loss coefficient for bearings,

and the torque dependent loss coefficient for the gear mesh

𝑓 𝑃 𝑚,𝑙𝑜𝑠𝑠

𝑇,𝑔𝑒𝑎𝑟𝑚𝑒𝑠ℎ = 𝑃 =

𝑃 𝑚,𝑙𝑜𝑠𝑠

𝑖𝑛 (1 𝑁𝑚 ∗ 1 𝑟𝑎𝑑 𝑠 )

shall be added to receive the total torque dependent loss coefficient f T for the

transmission system:

𝑓

𝑇 = 𝑓 𝑇,𝑔𝑒𝑎𝑟𝑚𝑒𝑠ℎ + 𝑓 𝑇,𝑏𝑒𝑎𝑟 where: f T = Total torque dependent loss coefficient for the transmission system [-] f T,bear = Torque dependent loss coefficient for the bearings [-] f T,gearmesh = Torque dependent loss coefficient for the gear meshes [-] P in = Fixed input power of the transmission; P in = (1 Nm * 1 rad/s) [W] 3.1.1.14. The torque dependent losses on the input shaft for the specific gear shall be

calculated by: 𝑇

𝑙,𝑖𝑛𝑇 = 𝑓 𝑇 ∗ 𝑇 𝑖𝑛

where: T l,inT = Torque dependent loss related to input shaft [Nm] T in = Torque at the input shaft [Nm]

3.1.2. The torque independent losses shall be measured in accordance with the procedure described in the following.

3.1.2.1. General requirements

The transmission used for the measurements shall be in accordance with the drawing specifications for series production transmissions and shall be new. Modifications to the transmission to meet the testing requirements of this Annex, e.g. for the inclusion of measurement sensors or adaption of an external oil conditioning system are permitted.

The tolerance limits in this paragraph refer to measurement values without sensor

uncertainty.

Total tested time per transmission individual and gear shall not exceed 2.5 times the

actual testing time per gear (allowing re-testing of transmission if needed due to

measuring or rig error).

The same transmission individual may be used for a maximum of 10 different tests, e.g.

for tests of transmission torque losses for variants with and without retarder (with

different temperature requirements) or with different oils. If the same transmission

individual is used for tests of different oils, the recommended factory fill oil shall be

tested first.

It is not permitted to run a certain test multiple times to choose a test series with the

lowest results.

Upon request of the approval authority the applicant for a certificate shall specify and

prove the conformity with the requirements defined in this Annex.

3.1.2.2. Differential measurements

To subtract influences caused by the test rig setup (e.g. bearings, clutches) from the

measured torque losses, differential measurements are permitted to determine these

parasitic torques. The measurements shall be performed at the same speed steps and same

test rig bearing temperature(s) ±3 K used for the testing. The torque sensor measurement

uncertainty shall be below 0.3 Nm.

3.1.2.3. Run-in

On request of the applicant a run-in procedure may be applied to the transmission. The

following provisions shall apply for a run-in procedure.

3.1.2.3.1. The procedure shall not exceed 30 hours per gear and 100 hours in total.

3.1.2.3.2. The application of the input torque shall be limited to 100% of maximum input

torque.

3.1.2.3.3. The maximum input speed shall be limited by the specified maximum speed for the

transmission.

3.1.2.3.4. The speed and torque profile for the run-in procedure shall be specified by the

manufacturer.

3.1.2.3.5. The run-in procedure shall be documented by the manufacturer with regard to runtime,

speed, torque and oil temperature and reported to the Approval authority.

3.1.2.3.6. The requirements for the ambient temperature (3.1.2.5.1.), measurement accuracy

(3.1.4.), test set-up (3.1.8.) and installation angle (3.1.3.2) shall not apply for the run-in

procedure.

3.1.2.4. Pre-conditioning

3.1.2.4.1. Pre-conditioning of the transmission and the test rig equipment to achieve correct

and stable temperatures before the run-in and testing procedures is allowed.

3.1.2.4.2. The pre-conditioning shall be performed on the direct drive gear without applied

torque to the output shaft. If the transmission is not equipped with a direct drive gear, the

gear with the ratio closest to 1:1 shall be used.

3.1.2.4.3. The maximum input speed shall be limited by the specified maximum speed for the

transmission.

3.1.2.4.4. The maximum combined time for the pre-conditioning shall not exceed 50 hours in total for one transmission. Since the complete testing of a transmission may be divided into multiple test sequences (e.g. each gear tested with a separate sequence), the preconditioning may be split into several sequences. Each of the single pre-conditioning sequences shall not exceed 60 minutes.

3.1.2.4.5. The pre-conditioning time shall not be accounted to the time span allocated for the run-in or test procedures.

3.1.2.5. Test conditions

3.1.2.5.1. Ambient temperature

The ambient temperature during the test shall be in a range of 25 °C ± 10 K. The ambient temperature shall be measured 1 m laterally from the transmission. The ambient temperature limit shall not apply for the run-in procedure.

3.1.2.5.2. Oil temperature

Except for the oil, no external heating is allowed. During measurement (except stabilization) the following temperature limits shall apply: For SMT/AMT/DCT transmissions, the drain plug oil temperature shall not exceed 83°C when measuring without retarder and 87°C with retarder mounted to the transmission. If measurements of a transmission without retarder are to be combined with separate measurements of a retarder, the lower temperature limit shall apply to compensate for the retarder drive mechanism and step-up gear and for the clutch in case of a disengageable retarder. For torque converter planetary transmissions and for transmissions having more than two friction clutches, the drain plug oil temperature shall not exceed 93 °C without retarder and 97 °C with retarder. To apply the above defined increased temperature limits for testing with retarder, the retarder shall be integrated in the transmission or have an integrated cooling or oil system with the transmission. During the run-in, the same oil temperature specifications as for regular testing shall apply. Exceptional oil temperature peaks up to 110 °C are allowed for the following conditions: (1) during run-in procedure up to maximum of 10% of the applied run-in time, (2) during stabilization time. The oil temperature shall be measured at the drain plug or in the oil sump.

3.1.2.5.3. Oil quality

New, recommended first fill oil for the European market shall be used in the test. The same oil fill may be used for run-in and torque measurement.

3.1.2.5.4. Oil viscosity

If multiple oils are recommended for first fill, they are considered to be equal if the oils have a kinematic viscosity within 10% of each other at the same temperature (within the specified tolerance band for KV100). Any oil with lower viscosity than the oil used in the test shall be considered to result in lower losses for the tests performed within this option.

Any additional first fill oil must fall either in the 10% tolerance band or have lower viscosity than the oil in the test to be covered by the same certificate.

3.1.2.5.5. Oil level and conditioning

The oil level shall meet the nominal specifications for the transmission. If an external oil conditioning system is used, the oil inside the transmission shall be kept to the specified volume that corresponds to the specified oil level. To guarantee that the external oil conditioning system is not influencing the test, one test point shall be measured with the conditioning system both on and off. The deviation between the two measurements of the torque loss (=input torque) shall be less than 5%. The test point is specified as follows: (1) gear = highest indirect gear, (2) input speed = 1600 rpm, (3) temperatures as specified under 3.1.2.5. For transmissions with hydraulic pressure control or a smart lubrication system, the measurement of torque independent losses shall be performed with two different settings: first with the transmission system pressure set to at least the minimum value for conditions with engaged gear and a second time with the maximum possible hydraulic pressure (see 3.1.6.3.1).

3.1.3. Installation

3.1.3.1. The electric machine and the torque sensor shall be mounted to the input side of the transmission. The output shaft shall rotate freely.

3.1.3.2. The installation of the transmission shall be done with an angle of inclination as for installation in the vehicle according to the homologation drawing ±1° or at 0°±1°.

3.1.3.3. The internal oil pump shall be included in the transmission.

3.1.3.4. If an oil cooler is either optional or required with the transmission, the oil cooler may be excluded in the test or any oil cooler may be used in the test.

3.1.3.5 Transmission testing can be done with or without power take-off drive mechanism and/or power take-off. For establishing the power losses of power take-offs and /or power takeoff drive mechanism, the values in Annex VII to this regulation are applied. These values assume that the transmission is tested without power take-off drive mechanism and /or power take-off.

3.1.3.6. Measuring the transmission may be performed with or without single dry clutch (with one or two plates) installed. Clutches of any other type shall be installed during the test.

3.1.3.7. The individual influence of parasitic loads shall be calculated for each specific test rig setup and torque sensor as described in 3.1.8.

3.1.4. Measurement equipment

The calibration laboratory facilities shall comply with the requirements of either ISO/TS 16949, ISO 9000 series or ISO/IEC 17025. All laboratory reference measurement equipment, used for calibration and/or verification, shall be traceable to national (international) standards.

3.1.4.1. Torque

The torque sensor measurement uncertainty shall be below 0.3 Nm.

The use of torque sensors with higher measurement uncertainties is allowed if the part of the uncertainty exceeding 0.3 Nm can be calculated and is added to the measured torque loss as described in 3.1.8. Measurement uncertainty.

3.1.4.2. Speed

The uncertainty of the speed sensors shall not exceed ± 1 rpm. 3.1.4.3. Temperature

The uncertainty of the temperature sensors for the measurement of the ambient

temperature shall not exceed ± 1.5 K.

The uncertainty of the temperature sensors for the measurement of the oil temperature

shall not exceed ± 1.5 K.

3.1.4.4. Pressure

The uncertainty of the pressure sensors shall not exceed 1% of the maximum measured

pressure.

3.1.4.5. Voltage

The uncertainty of the voltmeter shall not exceed 1% of the maximum measured voltage.

3.1.4.6. Electric current

The uncertainty of the amperemeter shall not exceed 1% of the maximum measured

current.

3.1.5. Measurement signals and data recording

At least the following signals shall be recorded during the measurement:

• (1) 

  Input torques [Nm]
• (2) 

  Input rotational speeds [rpm]
• (3) 

  Ambient temperature [°C]
• (4) 

  Oil temperature [°C]

If the transmission is equipped with a shift and/or clutch system that is controlled by

hydraulic pressure or with a mechanically driven smart lubrication system, additionally

to be recorded:

• (5) 

  Oil pressure [kPa]

If the transmission is equipped with transmission electric auxiliary, additionally to be

recorded:

• (6) 

  Voltage of transmission electric auxiliary [V]
• (7) 

  Current of transmission electric auxiliary [A]

For differential measurements for the compensation of influences caused by the test rig

setup, additionally shall be recorded:

• (8) 

  Test rig bearing temperature [°C]

The sampling and recording rate shall be 100 Hz or higher.

A low pass filter shall be applied to reduce measurement errors.

3.1.6. Test procedure

3.1.6.1. Zero torque signal compensation:

The zero-signal of the torque sensor(s) shall be measured. For the measurement the sensor(s) shall be installed in the test rig. The drivetrain of the test rig (input & output) shall be free of load. The measured signal deviation from zero shall be compensated.

3.1.6.2. Speed range:

The torque loss shall be measured for the following speed steps (speed of the input shaft): 600, 900, 1200, 1600, 2000, 2500, 3000, […] rpm up to the maximum speed per gear according to the specifications of the transmission or the last speed step before the defined maximum speed. The speed ramp (time for the change between two speed steps) shall not extend 20 seconds.

3.1.6.3. Measurement sequence:

3.1.6.3.1. If the transmission is equipped with smart lubrication systems and/or transmission electric auxiliaries, the measurement shall be conducted with two measurement settings of of these systems:

A first measurement sequence (3.1.6.3.2. to 3.1.6.3.4.) shall be performed with the lowest power consumption by hydraulical and electrical systems when operated in the vehicle (low loss level). The second measurement sequence shall be performed with the systems set to work with the highest possible power consumption when operated in the vehicle (high loss level).

3.1.6.3.2. The measurements shall be performed beginning with the lowest up to the highest speed.

3.1.6.3.3. For each speed step a minimum of 5 seconds stabilization time within the temperature limits defined in 3.1.2.5 is required. If needed, the stabilization time may be extended by the manufacturer to maximum 60 seconds. Oil and ambient temperatures shall be recorded during the stabilization.

3.1.6.3.4. After the stabilization time, the measurement signals listed in 3.1.5. shall be recorded for the test point for 05-15 seconds.

3.1.6.3.5. Each measurement shall be performed two times per measurement setting.

3.1.7. Measurement validation

3.1.7.1. The arithmetic mean values of torque, speed, (if applicable) voltage and current for the 05-15 seconds measurement shall be calculated for each of the measurements.

3.1.7.2. The averaged speed deviation shall be below ± 5 rpm of the speed set point for each measured point for the complete torque loss series.

3.1.7.3. The mechanical torque losses and (if applicable) electrical power consumption shall be calculated for each of the measurements as followed:

𝑇

𝑙𝑜𝑠𝑠 = 𝑇 𝑖𝑛

𝑃

𝑒𝑙 = 𝐼 ∗ 𝑈

It is allowed to subtract influences caused by the test rig setup from the torque losses (3.1.2.2.).

3.1.7.4. The mechanical torque losses and (if applicable) electrical power consumption from the two sets shall be averaged (arithmetic mean values).

3.1.7.5. The deviation between the averaged torque losses of the two measurement points for each setting shall be below ± 5% of the average or ± 1 Nm, whichever value is larger. Then, the arithmetic average of the two averaged power values shall be taken.

3.1.7.6. If the deviation is higher, the largest averaged torque loss value shall be taken or the test shall be repeated for the gear.

3.1.7.7. The deviation between the averaged electric power consumption (voltage*current) values of the two measurements for each measurement setting shall be below ± 10% of the average or ± 5 W, whichever value is larger. Then, the arithmetic average of the two averaged power values shall be taken.

3.1.7.8. If the deviation is higher, the set of averaged voltage and current values giving the largest averaged power consumption shall be taken, or the test shall be repeated for the gear.

3.1.8. Measurement uncertainty

The part of the calculated total uncertainty U T,loss exceeding 0.3 Nm shall be added to T loss for the reported torque loss T loss,rep . If U T,loss is smaller than 0.3 Nm, then T loss,rep = T loss . T loss,rep = T loss + MAX (0 , (U T,loss – 0.3 Nm)) The total uncertainty U T,loss of the torque loss shall be calculated based on the following parameters: (1) Temperature effect (2) Parasitic loads (3) Calibration error (incl. sensitivity tolerance, linearity, hysteresis and repeatability) The total uncertainty of the torque loss (U T,loss ) is based on the uncertainties of the sensors at 95% confidence level. The calculation shall be done as the square root of the sum of squares (“Gaussian law of error propagation”).

𝑈 2 𝑇,𝑙𝑜𝑠𝑠 = 𝑈 2 𝑇,𝑖𝑛 = 2 ∗ �𝑢 𝑇𝐾𝐶 + 𝑢 𝑇𝐾0 + 𝑢 2 2 𝑐𝑎𝑙 + 𝑢 𝑝𝑎𝑟𝑎

𝑢 𝑤 𝑡𝑘𝑐 𝑇𝐾𝐶 = 1 √3 ∗ 𝐾 ∗ ∆𝐾 ∗ 𝑇 𝑐

𝑟𝑒𝑓

𝑢 𝑤 𝑡𝑘0 𝑇𝐾0 = 1 √3 ∗ 𝐾 ∗ ∆𝐾 ∗ 𝑇 𝑛

𝑟𝑒𝑓

𝑢 𝑊 𝑐𝑎𝑙 𝐶𝑎𝑙 = 1 ∗ 𝑘 ∗ 𝑇 𝑛

𝑐𝑎𝑙

𝑢 𝑝𝑎𝑟𝑎 = 1 √3 ∗ 𝑤 𝑝𝑎𝑟𝑎 ∗ 𝑇 𝑛

𝑤

𝑝𝑎𝑟𝑎 = 𝑠𝑒𝑛𝑠 𝑝𝑎𝑟𝑎 ∗ 𝑖 𝑝𝑎𝑟𝑎

where:

T loss = Measured torque loss (uncorrected) [Nm]

T loss,rep = Reported torque loss (after uncertainty correction) [Nm]

U T,loss = Total expanded uncertainty of torque loss measurement at 95% confidence level [Nm]

U T,in = Uncertainty of input torque loss measurement [Nm] u TKC = Uncertainty by temperature influence on current torque signal [Nm] w tkc = Temperature influence on current torque signal per K ref , declared by

sensor manufacturer [%] u TK0 = Uncertainty by temperature influence on zero torque signal (related to

nominal torque) [Nm] w tk0 = Temperature influence on zero torque signal per K ref (related to

nominal torque), declared by sensor manufacturer [%] K ref = Reference temperature span for u TKC and u TK0 , w tk0 and w tkc , declared

by sensor manufacturer [K] ∆K = Difference in sensor temperature between calibration and measurement

[K]. If the sensor temperature cannot be measured, a default value of ∆K = 15 K shall be used.

T c = Current / measured torque value at torque sensor [Nm]

T n = Nominal torque value of torque sensor [Nm] u cal = Uncertainty by torque sensor calibration [Nm] W cal = Relative calibration uncertainty (related to nominal torque) [%] k cal = Calibration advancement factor (if declared by sensor manufacturer,

otherwise = 1) u para = Uncertainty by parasitic loads [Nm] w para = sens para * i para

Relative influence of forces and bending torques caused by

misalignment

sens para = Maximum influence of parasitic loads for specific torque sensor

declared by sensor manufacturer [%]; if no specific value for parasitic

loads is declared by the sensor manufacturer, the value shall be set to

1.0%

i para = Maximum influence of parasitic loads for specific torque sensor

depending on test setup (A/B/C, as defined below).

• = 

  A) 10% in case of bearings isolating the parasitic forces in front of and

behind the sensor and a flexible coupling (or cardan shaft) installed

functionally next to the sensor (downstream or upstream); furthermore,

these bearings can be integrated in a driving/braking machine (e.g.

electric machine) and/or in the transmission as long as the forces in the

machine and/or transmission are isolated from the sensor. See figure 1.

Figure 1 Test setup A for Option 1

Test setup A

INPUT

B E T F TM

E : Electric machine T : Torque sensor F : Flexible coupling B : Bearing TM : Transmission

• = 

  B) 50% in case of bearings isolating the parasitic forces in front of and behind the sensor and no flexible coupling installed functionally next to the sensor; furthermore, these bearings can be integrated in a driving/braking machine (e.g. electric machine) and/or in the transmission as long as the forces in the machine and/or transmission are isolated from the sensor. See figure 2.

Figure 2 Test setup B for Option 1

Test setup B

INPUT

B E T TM

E : Electric machine T : Torque sensor B : Bearing TM : Transmission

• = 

  C) 100% for other setups 3.2. Option 2: Measurement of the torque independent losses, measurement of the torque loss

at maximum torque and interpolation of the torque dependent losses based on a linear model Option 2 describes the determination of the torque loss by a combination of measurements and linear interpolation. Measurements shall be performed for the torque independent losses of the transmission and for one load point of the torque dependent losses (maximum input torque). Based on the torque losses at no load and at maximum input torque, the torque losses for the input torques in between shall be calculated with the torque loss coefficient f Tlimo . The torque loss T l,in on the input shaft of the transmission shall be calculated by 𝑇

𝑙,𝑖𝑛 (𝑛 𝑖𝑛 , 𝑇 𝑖𝑛 , 𝑔𝑒𝑎𝑟) = 𝑇 𝑙,𝑖𝑛,𝑚𝑖𝑛_𝑙𝑜𝑠𝑠 + 𝑓 𝑇𝑙𝑖𝑚𝑜 ∗ 𝑇 𝑖𝑛 + 𝑇 𝑙,𝑖𝑛,min_𝑒𝑙 + 𝑓 𝑒𝑙_𝑐𝑜𝑟𝑟 ∗ 𝑇 𝑖𝑛

The torque loss coefficient based on the linear model f Tlimo shall be calculated by

𝑓 𝑙,𝑚𝑎𝑥𝑇 − 𝑇 𝑙,𝑖𝑛,𝑚𝑖𝑛_𝑙𝑜𝑠𝑠 )

𝑇𝑙𝑖𝑚𝑜 =

(𝑇 𝑇

𝑖𝑛,𝑚𝑎𝑥𝑇

where: T l,in = Torque loss related to input shaft [Nm] T l,in,min_loss = Drag torque loss at transmission input, measured with free rotating output shaft from testing without load [Nm] n in = Speed at the input shaft [rpm] f Tlimo = Torque loss coefficient based on linear model [-] T in = Torque at the input shaft [Nm]

T in,maxT = Maximum tested torque at the input shaft (normally 100% input torque, refer to 3.2.5.2. and 3.4.4.) [Nm]

T l,maxT = Torque loss related to input shaft with T in = T in,maxT f el_corr = Loss correction for electric power loss level depending on input torque [-] T l,in,el = Additional torque loss on input shaft by electric consumers [Nm] T l,in,min_el = Additional torque loss on input shaft by electric consumers corresponding to minimum electric power [Nm] The correction factor for the torque dependent electric torque losses f el_corr and the torque loss at the input shaft of the transmission caused by the power consumption of transmission electric auxiliary T l,in,el shall be calculated as described in paragraph 3.1.

3.2.1. The torque losses shall be measured in accordance with the procedure described in the following.

3.2.1.1. General requirements:

As specified for Option 1 in 3.1.2.1. 3.2.1.2. Differential measurements:

As specified for Option 1 in 3.1.2.2. 3.2.1.3. Run-in

As specified for Option 1 in 3.1.2.3. 3.2.1.4. Pre-conditioning

As specified for Option 3 in 3.3.2.1. 3.2.1.5. Test conditions

3.2.1.5.1. Ambient temperature

As specified for Option 1 in 3.1.2.5.1. 3.2.1.5.2. Oil temperature

As specified for Option 1 in 3.1.2.5.2. 3.2.1.5.3. Oil quality / Oil viscosity

As specified for Option 1 in 3.1.2.5.3 and 3.1.2.5.4. 3.2.1.5.4. Oil level and conditioning

As specified for Option 3 in 3.3.3.4. 3.2.2. Installation

As specified for Option 1 in 3.1.3. for the measurement of the torque independent losses. As specified for Option 3 in 3.3.4. for the measurement of the torque dependent losses.

3.2.3. Measurement equipment

As specified for Option 1 in 3.1.4. for the measurement of the torque independent losses. As specified for Option 3 in 3.3.5. for the measurement of the torque dependent losses.

3.2.4. Measurement signals and data recording

As specified for Option 1 in 3.1.5 for the measurement of the torque independent losses. As specified for Option 3 in 3.3.7 for the measurement of the torque dependent losses.

3.2.5. Test procedure

The torque loss map to be applied to the simulation tool contains the torque loss values of a transmission depending on rotational input speed and input torque. To determine the torque loss map for a transmission, the basic torque loss map data shall be measured and calculated as specified in this paragraph. The torque loss results shall be complemented in accordance with 3.4 and formatted in accordance with Appendix 12 for the further processing by the simulation tool.

3.2.5.1. The torque independent losses shall be determined by the procedure described in 3.1.1. for the torque independent losses for Option 1 only for the low loss level setting of electric and hydraulic consumers.

3.2.5.2. Determine the torque dependent losses for each of the gears using the procedure described for Option 3 in 3.3.6., diverging in the applicable torque range:

Torque range: The torque losses for each gear shall be measured at 100% of the maximum transmission input torque per gear. In the case the output torque exceeds 10 kNm (for a theoretical loss free transmission) or the input power exceeds the specified maximum input power, point 3.4.4. shall apply.

3.2.6. Measurement validation

As specified for Option 3 in 3.3.8. 3.2.7. Measurement uncertainty

As specified for Option 1 in 3.1.8. for the measurement of the torque independent losses. As specified for Option 3 in 3.3.9. for the measurement of the torque dependent loss.

3.3. Option 3: Measurement of the total torque loss.

Option 3 describes the determination of the torque loss by full measurement of the torque dependent losses including the torque independent losses of the transmission.

3.3.1. General requirements

As specified for Option 1 in 3.1.2.1. 3.3.1.1 Differential measurements:

As specified for Option 1 in 3.1.2.2. 3.3.2. Run-in

As specified for Option 1 in 3.1.2.3. 3.3.2.1 Pre-conditioning

As specified for Option 1 in 3.1.2.4. with an exception for the following: The pre-conditioning shall be performed on the direct drive gear without applied torque to the output shaft or target torque on the output shaft set to zero. If the transmission is not equipped with a direct drive gear, the gear with the ratio closest to 1:1 shall be used. or The requirements as specified in 3.1.2.4. shall apply, with an exception for the following: The pre-conditioning shall be performed on the direct drive gear without applied torque to the output shaft or the torque on the output shaft being within +/- 50 Nm. If the transmission is not equipped with a direct drive gear, the gear with the ratio closest to 1:1 shall be used. or, if the test rig includes a (master friction) clutch at the input shaft: The requirements as specified in 3.1.2.4. shall apply, with an exception for the following: The pre-conditioning shall be performed on the direct drive gear without applied torque to the output shaft or without applied torque to the input shaft. If the transmission is not equipped with a direct drive gear, the gear with the ratio closest to 1:1 shall be used. The transmission would then be driven from the output side. Those proposals could also be combined.

3.3.3. Test conditions

3.3.3.1. Ambient temperature

As specified for Option 1 in 3.1.2.5.1. 3.3.3.2. Oil temperature

As specified for Option 1 in 3.1.2.5.2. 3.3.3.3. Oil quality / Oil viscosity

As specified for Option 1 in 3.1.2.5.3 and 3.1.2.5.4. 3.3.3.4. Oil level and conditioning

The requirements as specified in 3.1.2.5.5. shall apply, diverging in the following: The test point for the external oil conditioning system is specified as follows: (1) highest indirect gear, (2) input speed = 1600 rpm, (3) input torque = maximum input torque for the highest indirect gear

3.3.4. Installation

The test rig shall be driven by electric machines (input and output). Torque sensors shall be installed at the input and output side of the transmission. Other requirements as specified in 3.1.3. shall apply.

3.3.5. Measurement equipment

For the measurement of the torque independent losses, the measurement equipment

requirements as specified for Option 1 in 3.1.4. shall apply.

For the measurement of the torque dependent losses, the following requirements shall

apply:

The torque sensor measurement uncertainty shall be below 5% of the measured torque

loss or 1 Nm (whichever value is larger).

The use of torque sensors with higher measurement uncertainties is allowed if the parts

of the uncertainty exceeding 5% or 1 Nm can be calculated and the smaller of those parts

is added to the measured torque loss.

The torque measurement uncertainty shall be calculated and included as described under

3.3.9.

Other measurement equipment requirements as specified for Option 1 in 3.1.4. shall

apply.

3.3.6. Test procedure

3.3.6.1. Zero torque signal compensation:

As specified in 3.1.6.1.

3.3.6.2. Speed range

The torque loss shall be measured for the following speed steps (speed of the input

shaft): 600, 900, 1200, 1600, 2000, 2500, 3000, […] rpm up to the maximum speed per

gear according to the specifications of the transmission or the last speed step before the

defined maximum speed.

The speed ramp (time for the change between two speed steps) shall not exceed 20

seconds.

3.3.6.3. Torque range

For each speed step the torque loss shall be measured for the following input torques: 0

(free rotating output shaft), 200, 400, 600, 900, 1200, 1600, 2000, 2500, 3000, 3500,

4000, […] Nm up to the maximum input torque per gear according to the specifications

of the transmission or the last torque step before the defined maximum torque and / or the

last torque step before the output torque of 10 kNm.

In the case the output torque exceeds 10 kNm (for a theoretical loss free transmission) or

the input power exceeds the specified maximum input power, point 3.4.4. shall apply.

The torque ramp (time for the change between two torque steps) shall not exceed 15

seconds (180 seconds for option 2).

To cover the complete torque range of a transmission in the above defined map, different

torque sensors with limited measurement ranges may be used on the input/output side.

Therefore the measurement may be divided into sections using the same set of torque

sensors. The overall torque loss map shall be composed of these measurement sections.

3.3.6.4. Measurement sequence

3.3.6.4.1. The measurements shall be performed beginning with the lowest up to the highest speed.

3.3.6.4.2. The input torque shall be varied according to the above defined torque steps from the lowest to the highest torque which is covered by the current torque sensors for each speed step.

3.3.6.4.3. For each speed and torque step a minimum of 5 seconds stabilization time within the temperature limits defined in 3.3.3. is required. If needed, the stabilization time may be extended by the manufacturer to maximum 60 seconds (maximum 180 seconds for option 2). Oil and ambient temperatures shall be recorded during the stabilization.

3.3.6.4.4. The measurement set shall be performed two times in total. For that purpose, sequenced repetition of sections using the same set of torque sensors is allowed.

3.3.7. Measurement signals and data recording

At least the following signals shall be recorded during the measurement: (1) Input and output torques [Nm] (2) Input and output rotational speeds [rpm] (3) Ambient temperature [°C] (4) Oil temperature [°C] If the transmission is equipped with a shift and/or clutch system that is controlled by hydraulic pressure or with a mechanically driven smart lubrication system, additionally to be recorded: (5) Oil pressure [kPa] If the transmission is equipped with transmission electric auxiliary, additionally to be recorded: (6) Voltage of transmission electric auxiliary [V] (7) Current of transmission electric auxiliary [A] For differential measurements for compensation of influences by test rig setup, additionally to be recorded: (8) Test rig bearing temperature [°C] The sampling and recording rate shall be 100 Hz or higher. A low pass filter shall be applied to avoid measurement errors.

3.3.8. Measurement validation

3.3.8.1. The arithmetic mean values of torque, speed, if applicable voltage and current for the 05- 15 seconds measurement shall be calculated for each of the two measurements.

3.3.8.2. The measured and averaged speed at the input shaft shall be below ± 5 rpm of the speed set point for each measured operating point for the complete torque loss series. The measured and averaged torque at the input shaft shall be below ± 5 Nm or ± 5 % of the torque set point whichever value is larger for each measured operating point for the complete torque loss series.

3.3.8.3. The mechanical torque losses and (if applicable) electrical power consumption shall be calculated for each of the measurements as followed:

𝑇 𝑜𝑢𝑡

𝑙𝑜𝑠𝑠 = 𝑇 𝑖𝑛 −

𝑇 𝑖

𝑔𝑒𝑎𝑟

𝑃

𝑒𝑙 = 𝐼 ∗ 𝑈

It is allowed to subtract influences caused by the test rig setup from the torque losses (3.3.2.2.).

3.3.8.4. The mechanical torque losses and (if applicable) electrical power consumption from the two sets shall be averaged (arithmetic mean values).

3.3.8.5. The deviation between the averaged torque losses of the two measurement sets shall be below ± 5% of the average or ± 1 Nm (whichever value is larger). The arithmetic average of the two averaged torque loss values shall be taken. If the deviation is higher, the largest averaged torque loss value shall be taken or the test shall be repeated for the gear.

3.3.8.6. The deviation between the averaged electric power consumption (voltage*current) values of the two measurement sets shall be below ± 10% of the average or ± 5 W, whichever value is larger. Then, the arithmetic average of the two averaged power values shall be taken.

3.3.8.7. If the deviation is higher, the set of averaged voltage and current values giving the largest averaged power consumption shall be taken, or the test shall be repeated for the gear.

3.3.9. Measurement uncertainty

The part of the calculated total uncertainty U T,loss exceeding 5% of T loss or 1 Nm (ΔU T,loss ), whichever value of ΔU T,loss is smaller, shall be added to T loss for the reported torque loss T loss,rep . If U T,loss is smaller than 5% of T loss or 1 Nm, then T loss,rep = T loss . T loss,rep = T loss +MAX (0 , ΔU T,loss ) ΔU T,loss = MIN ((U T,loss - 5% * T loss ), (U T,loss – 1 Nm)) For each measurement set, the total uncertainty U T,loss of the torque loss shall be calculated based on the following parameters: (1) Temperature effect (2) Parasitic loads (3) Calibration error (incl. sensitivity tolerance, linearity, hysteresis and repeatability) The total uncertainty of the torque loss (U T,loss ) is based on the uncertainties of the sensors at 95% confidence level. The calculation shall be done as the square root of the sum of squares (“Gaussian law of error propagation”).

𝑈 2 2 2 𝑇,𝑖𝑛/𝑜𝑢𝑡 = 2 ∗ �𝑢 2 𝑇𝐾𝐶 + 𝑢 𝑇𝐾0 + 𝑢 𝑐𝑎𝑙 + 𝑢 𝑝𝑎𝑟𝑎

𝑢 𝑇𝐾𝐶 = 1 √3 ∗ 𝑤 𝑡𝑘𝑐 𝐾 ∗ ∆𝐾 ∗ 𝑇 𝑐

𝑟𝑒𝑓

𝑢 𝑇𝐾0 = 1 ∗ 𝑤 𝑡𝑘0

√3 𝐾

∗ ∆𝐾 ∗ 𝑇

𝑛 𝑟𝑒𝑓

𝑢 𝑐𝑎𝑙 𝐶𝑎𝑙 = 1 ∗ 𝑊 𝑘 ∗ 𝑇 𝑛

𝑐𝑎𝑙

𝑢 1 𝑝𝑎𝑟𝑎 = ∗ 𝑤 ∗ 𝑇

√3 𝑝𝑎𝑟𝑎 𝑛

𝑤

𝑝𝑎𝑟𝑎 = 𝑠𝑒𝑛𝑠 𝑝𝑎𝑟𝑎 ∗ 𝑖 𝑝𝑎𝑟𝑎

where:

T loss = Measured torque loss (uncorrected) [Nm]

T loss,rep = Reported torque loss (after uncertainty correction) [Nm]

U T,loss = Total expanded uncertainty of torque loss measurement at 95% confidence level [Nm]

u T,in/out = Uncertainty of input / output torque loss measurement separately for input and output torque sensor[Nm]

i gear = Gear ratio [-] u TKC = Uncertainty by temperature influence on current torque signal [Nm] w tkc = Temperature influence on current torque signal per K ref , declared by

sensor manufacturer [%] u TK0 = Uncertainty by temperature influence on zero torque signal (related to

nominal torque) [Nm] w tk0 = Temperature influence on zero torque signal per K ref (related to

nominal torque), declared by sensor manufacturer [%] K ref = Reference temperature span for u TKC and u TK0 , w tk0 and w tkc , declared

by sensor manufacturer [K] ∆K = Difference in sensor temperature between calibration and measurement

[K]. If the sensor temperature cannot be measured, a default value of ∆K = 15 K shall be used.

T c = Current / measured torque value at torque sensor [Nm]

T n = Nominal torque value of torque sensor [Nm] u cal = Uncertainty by torque sensor calibration [Nm] W cal = Relative calibration uncertainty (related to nominal torque) [%] k cal = calibration advancement factor (if declared by sensor manufacturer,

otherwise = 1) u para = Uncertainty by parasitic loads [Nm] w para = sens para * i para

Relative influence of forces and bending torques caused by

misalignment [%]

sens para = Maximum influence of parasitic loads for specific torque sensor

declared by sensor manufacturer [%]; if no specific value for parasitic

loads is declared by the sensor manufacturer, the value shall be set to

1.0%

i para = Maximum influence of parasitic loads for specific torque sensor

depending on test setup (A/B/C, as defined below).

• = 

  A) 10% in case of bearings isolating the parasitic forces in front of and

behind the sensor and a flexible coupling (or cardan shaft) installed

functionally next to the sensor (downstream or upstream); furthermore,

these bearings can be integrated in a driving/braking machine (e.g.

electric machine) and/or in the transmission as long as the forces in the

machine and/or transmission are isolated from the sensor. See figure 3.

Figure 3 Test setup A for Option 3

• = 

  B) 50% in case of bearings isolating the parasitic forces in front of and behind the sensor and no flexible coupling installed functionally next to the sensor; furthermore, these bearings can be integrated in a driving/braking machine (e.g. electric machine) and/or in the transmission as long as the forces in the machine and/or transmission are isolated from the sensor. See figure 4.

Figure 4 Test setup B for Option 3

• = 

  C) 100% for other setups 3.4. Complement of input files for the simulation tool

For each gear a torque loss map covering the defined input speed and input torque steps shall be determined with one of the specified testing options or standard torque loss values. For the input file for the simulation tool, this basic torque loss map shall be complemented as described in the following:

3.4.1. In the cases the highest tested input speed was the last speed step below the defined maximum permissible transmission speed, an extrapolation of the torque loss shall be applied up to the maximum speed with linear regression based on the two last measured speed steps.

3.4.2. In the cases the highest tested input torque was the last torque step below the defined maximum permissible transmission torque, an extrapolation of the torque loss shall be applied up to the maximum torque with linear regression based on the two last measured torque steps for the corresponding speed step. In order to handle engine torque tolerances, etc., the simulation tool will, if required, perform an extrapolation of the torque loss for input torques up to 10% above said defined maximum permissible transmission torque.

3.4.3. In the case of extrapolation of the torque loss values for maximum input speed and maximum input torque at the same time, the torque loss for the combined point of highest speed and highest torque shall be calculated with two-dimensional linear extrapolation.

3.4.4. If the maximum output torque exceeds 10 kNm (for a theoretical loss free transmission), and/or for all speed and torque points with input power higher than the specified maximum input power, the manufacturer may choose to take the torque loss values for all torques higher than 10 kNm, and/or for all speed and torque points with input power higher than the specified maximum input power, respectively, from one of:

• (1) 

  Calculated fallback values (Appendix 8) (2) Option 1 (3) Option 2 or 3 in combination with a torque sensor for higher output torques (if required) For cases (i) and (ii) in Option 2, the torque losses at load shall be measured at the input torque that corresponds to output torque 10 kNm and/or the specified maximum input power.

3.4.5. For speeds below the defined minimum speed and the additional input speed step of 0 rpm, the reported torque losses determined for the minimum speed step shall be copied.

3.4.6. To cover the range of negative input torques during vehicle coasting conditions, the torque loss values for positive input torques shall be copied for the related negative input torques.

3.4.7. Upon agreement of an approval authority, the torque losses for the input speeds below 1000 rpm may be replaced by the torque losses at 1000 rpm when the measurement is technically not possible.

3.4.8. If the measurement of speed points is technically not possible (e.g. due to natural frequency), the manufacturer may, in agreement with the approval authority, calculate the torque losses by interpolation or extrapolation (limited to max. 1 speed step per gear).

3.4.9. The torque loss map data shall be formatted and saved as specified in Appendix 12 to this Annex.

• 4. 

  Torque converter (TC)

  The torque converter characteristics to be determined for the simulation tool input consist of T pum 1000 (the reference torque at 1000 rpm input speed) and µ (the torque ratio of the torque converter). Both are depending on the speed ratio v (= output (turbine) speed / input (pump) speed for the torque converter) of the torque converter. For determination of the characteristics of the TC, the applicant for a certificate shall apply the following method, irrespective of the chosen option for the assessment of the transmission torque losses. To take the two possible arrangements of the TC and the mechanical transmission parts into account, the following differentiation between case S and P shall apply: Case S: TC and mechanical transmission parts in serial arrangement Case P: TC and mechanical transmission parts in parallel arrangement (power split installation) For case S arrangements the TC characteristics may be evaluated either separate from the mechanical transmission or in combination with the mechanical transmission. For case P arrangements the evaluation of TC characteristic is only possible in combination with the mechanical transmission. However, in this case and for the hydromechanical gears subject to measurement the whole arrangement, torque converter and mechanical transmission, is considered as a TC with similar characteristic curves as a sole torque converter. For the determination of the torque converter characteristics two measurement options may be applied: (i) Option A: measurement at constant input speed (ii) Option B: measurement at constant input torque according to SAE J643 The manufacturer may choose option A or B for case S and case P arrangements. For the input to the simulation tool, the torque ratio µ and reference torque T pum of the torque converter shall be measured for a range of v ≤ 0.95 (= vehicle propulsion mode). The range of v ≥ 1.00 (= vehicle coasting mode) may either be measured or covered by using the standard values of Table 1. In case of measurements together with a mechanical transmission the overrun point may be different from v = 1.00 and therefor the range of measured speed ratios shall be adjusted accordingly. In case of use of standard values the data on torque converter characteristics provided to the simulation tool shall only cover the range of v ≤ 0.95 (or the adjusted speed ratio). The simulation tool automatically adds the standard values for overrun conditions.

  Table 1: Default values for v ≥ 1.00 v µ T pum1000 1.000 1.0000 0.00 1.100 0.9999 -40.34 1.222 0.9998 -80.34 1.375 0.9997 -136.11 1.571 0.9996 -216.52 1.833 0.9995 -335.19 2.200 0.9994 -528.77

2.500 0.9993 -721.00

3.000 0.9992 -1122.00

3.500 0.9991 -1648.00

4.000 0.9990 -2326.00

4.500 0.9989 -3182.00

5.000 0.9988 -4242.00

4.1. Option A: Measured torque converter characteristics at constant speed

4.1.1. General requirements

The torque converter used for the measurements shall be in accordance with the drawing specifications for series production torque converters. Modifications to the TC to meet the testing requirements of this Annex, e.g. for the inclusion of measurement sensors are permitted. Upon request of the approval authority the applicant for a certificate shall specify and prove the conformity with the requirements defined in this Annex.

4.1.2. Oil temperature

The input oil temperature to the TC shall meet the following requirements: The oil temperature for measurements of the TC separate from the transmission shall be 90 °C +7 / -3 K. The oil temperature for measurements of the TC together with the transmission (case S and case P) shall be 90 °C +20 / -3 K. The oil temperature shall be measured at the drain plug or in the oil sump. In case the TC characteristics are measured separately form the transmission, the oil temperature shall be measured prior to entering the converter test drum/bench.

4.1.3. Oil flow rate and pressure

The input TC oil flow rate and output oil pressure of the TC shall be kept within the specified operational limits for the torque converter, depending on the related transmission type and the tested maximum input speed.

4.1.4. Oil quality / Oil viscosity

As specified for transmission testing in 3.1.2.5.3 and 3.1.2.5.4. 4.1.5. Installation

The torque converter shall be installed on a testbed with a torque sensor, speed sensor and an electric machine installed at the input and output shaft of the TC.

4.1.6. Measurement equipment

The calibration laboratory facilities shall comply with the requirements of either ISO/TS 16949, ISO 9000 series or ISO/IEC 17025. All laboratory reference measurement equipment, used for calibration and/or verification, shall be traceable to national (international) standards.

4.1.6.1. Torque

The torque sensor measurement uncertainty shall be below 1% of the measured torque value. The use of torque sensors with higher measurement uncertainties is allowed if the part of the uncertainty exceeding 1% of the measured torque can be calculated and is added to the measured torque loss as described in 4.1.7.

4.1.6.2. Speed

The uncertainty of the speed sensors shall not exceed ± 1 rpm. 4.1.6.3. Temperature

The uncertainty of the temperature sensors for the measurement of the ambient temperature shall not exceed ± 1.5 K. The uncertainty of the temperature sensors for the measurement of the oil temperature shall not exceed ± 1.5 K.

4.1.7. Test procedure

4.1.7.1. Zero torque signal compensation

As specified in 3.1.6.1. 4.1.7.2. Measurement sequence 4.1.7.2.1. The input speed n pum of the TC shall be fixed to a constant speed within the range

of: 1000 rpm ≤ n pum ≤ 2000 rpm

4.1.7.2.2. The speed ratio v shall be adjusted by increasing the output speed n tur from 0 rpm up to the set value of n pum .

4.1.7.2.3. The step width shall be 0.1 for the speed ratio range of 0 to 0.6 and 0.05 for the range of 0.6 to 0.95.

4.1.7.2.4. The upper limit of the speed ratio may be limited to a value below 0.95 by the manufacturer. In this case at least seven evenly distributed points between v = 0 and a value of v < 0.95 have to be covered by the measurement.

4.1.7.2.5. For each step a minimum of 3 seconds stabilization time within the temperature limits defined in 4.1.2. is required. If needed, the stabilization time may be extended by the manufacturer to maximum 60 seconds. The oil temperature shall be recorded during the stabilization.

4.1.7.2.6. For each step the signals specified in 4.1.8. shall be recorded for the test point for 3-15 seconds.

4.1.7.2.7. The measurement sequence (4.1.7.2.1. to 4.1.7.2.6.) shall be performed two times in total.

4.1.8. Measurement signals and data recording

At least the following signals shall be recorded during the measurement: (1) Input (pump) torque T c,pum [Nm] (2) Output (turbine) torque T c,tur [Nm] (3) Input rotational (pump) speed n pum [rpm] (4) Output rotational (turbine) speed n tur [rpm] (5) TC input oil temperature K TCin [°C] The sampling and recording rate shall be 100 Hz or higher. A low pass filter shall be applied to avoid measurement errors.

4.1.9. Measurement validation

4.1.9.1. The arithmetic mean values of torque and speed for the 03-15 seconds measurement shall be calculated for each of the two measurements.

4.1.9.2. The measured torques and speeds from the two sets shall be averaged (arithmetic mean values).

4.1.9.3. The deviation between the averaged torque of the two measurement sets shall be below ± 5% of the average or ± 1 Nm (whichever value is larger). The arithmetic average of the two averaged torque values shall be taken. If the deviation is higher, the following value shall be taken for point 4.1.10. and 4.1.11. or the test shall be repeated for the TC.

• - 

  for the calculation of ∆U T,pum/tur : smallest averaged torque value for T c,pum/tur - for the calculation of torque ratio μ: largest averaged torque value for T c,pum - for the calculation of torque ratio μ: smallest averaged torque value for Tc,tur - for the calculation of reference torque T pum1000 : smallest averaged torque value for T c,pum

4.1.9.4. The measured and averaged speed and torque at the input shaft shall be below ± 5 rpm and ± 5 Nm of the speed and torque set point for each measured operating point for the complete speed ratio series.

4.1.10. Measurement uncertainty

The part of the calculated measurement uncertainty U T,pum/tur exceeding 1% of the measured torque T c,pum/tur shall be used to correct the characteristic value of the TC as defined below. ∆U T,pum/tur = MAX ( 0 , (U T,pum/tur - 0.01 * T c,pum/tur )) The uncertainty U T,pum/tur of the torque measurement shall be calculated based on the following parameter: (i) Calibration error (incl. sensitivity tolerance, linearity, hysteresis and repeatability) The uncertainty U T,pum/tur of the torque measurement is based on the uncertainties of the sensors at 95% confidence level.

𝑈 𝑇,𝑝𝑢𝑚/𝑡𝑢𝑟 = 2 ∗ 𝑢 𝑐𝑎𝑙

𝑢 𝑐𝑎𝑙 𝐶𝑎𝑙 = 1 ∗ 𝑊 𝑘 ∗ 𝑇 𝑛

𝑐𝑎𝑙

where:

T c,pum/tur = Current / measured torque value at input/output torque sensor (uncorrected) [Nm]

T pum = Input (pump) torque (after uncertainty correction) [Nm] U T,pum/tur = Uncertainty of input / output torque measurement at 95% confidence level separately for input and output torque sensor[Nm] T n = Nominal torque value of torque sensor [Nm] u cal = Uncertainty by torque sensor calibration [Nm] W cal = Relative calibration uncertainty (related to nominal torque) [%] k cal = Calibration advancement factor (if declared by sensor manufacturer, otherwise = 1)

4.1.11. Calculation of TC characteristics

For each measurement point, the following calculations shall be applied to the measurement data: The torque ratio of the TC shall be calculated by

The speed ratio of the TC shall be calculated by

The reference torque at 1000 rpm shall be calculated by

2

𝑇

𝑝𝑢𝑚1000 = (𝑇 𝑐,𝑝𝑢𝑚 − ∆𝑈

1000 𝑟𝑝𝑚

𝑇,𝑝𝑢𝑚 ) ∗ � 𝑛 �

𝑝𝑢𝑚

where: µ = Torque ratio of the TC [-] v = Speed ratio of the TC [-] T c , pum = Input (pump) torque (corrected) [Nm] n pum = Input rotational (pump) speed [rpm] n tur = Output rotational (turbine) speed [rpm] T pum1000 = Reference torque at 1000 rpm [Nm]

4.2. Option B: Measurement at constant input torque (in accordance with SAE J643)

4.2.1. General requirements

As specified in 4.1.1. 4.2.2. Oil temperature

As specified in 4.1.2. 4.2.3. Oil flow rate and pressure

As specified in 4.1.3. 4.2.4. Oil quality

As specified in 4.1.4. 4.2.5. Installation

As specified in 4.1.5. 4.2.6. Measurement equipment

As specified in 4.1.6. 4.2.7. Test procedure

4.2.7.1. Zero torque signal compensation

As specified in 3.1.6.1. 4.1.7.2. Measurement sequence 4.2.7.2.1. The input torque T pum shall be set to a positive level at n pum = 1000 rpm with the

output shaft of the TC held non-rotating (output speed n tur = 0 rpm). 4.2.7.2.2. The speed ratio v shall be adjusted by increasing the output speed n tur from 0 rpm

up to a value of n tur covering the usable range of v with at least seven evenly distributed speed points.

4.2.7.2.3. The step width shall be 0.1 for the speed ratio range of 0 to 0.6 and 0.05 for the range of 0.6 to 0.95.

4.2.7.2.4. The upper limit of the speed ratio may be limited to a value below 0.95 by the manufacturer.

4.2.7.2.5. For each step a minimum of 5 seconds stabilization time within the temperature limits defined in 4.2.2. is required. If needed, the stabilization time may be extended by the manufacturer to maximum 60 seconds. The oil temperature shall be recorded during the stabilization.

4.2.7.2.6. For each step the values specified in 4.2.8. shall be shall be recorded for the test point for 05-15 seconds.

4.2.7.2.7. The measurement sequence (4.2.7.2.1. to 4.2.7.2.6.) shall be performed two times in total.

4.2.8. Measurement signals and data recording

As specified in 4.1.8. 4.2.9. Measurement validation

As specified in 4.1.9. 4.2.10. Measurement uncertainty

As specified in 4.1.9. 4.2.11. Calculation of TC characteristics

As specified in 4.1.11.

• 5. 

  Other torque transferring components (OTTC)

The scope of this section includes engine retarders, transmission retarders, driveline retarders, and components that are treated in the simulation tool as a retarder. These

components include vehicle starting devices like a single wet transmission input clutch or hydro-dynamic clutch.

5.1. Methods for establishing retarder drag losses

The retarder drag torque loss is a function of the retarder rotor speed. Since the retarder can be integrated in different parts of the vehicle driveline, the retarder rotor speed depends on the drive part (= speed reference) and step-up ratio between drive part and retarder rotor as shown in Table 2. Table 2: Retarder rotor speeds Configuration Speed reference Retarder rotor speed calculation

• A. 

  Engine Retarder Engine Speed n retarder = n engine * i step-up

• B. 

  Transmission Transmission n retarder = n transm.input * i step-up Input Retarder Input Shaft Speed = n transm.output * i transm * i step-up

• C. 

  Transmission Output Retarder Transmission

  or Propshaft Output Shaft Speed n retarder = n transm.output * i step-up

  Retarder

where: i step-up = step-up ratio = retarder rotor speed / drive part speed i transm = transmission ratio = transmission input speed/ transmission output speed Retarder configurations that are integrated in the engine and cannot be separated from the engine shall be tested in combination with the engine. This section does not cover these non-separable engine integrated retarders. Retarders that can be disconnected from the driveline or the engine by any kind of clutch are considered to have zero rotor speed in disconnected condition and therefore have no power losses. The retarder drag losses shall be measured with one of the following two methods: (1) Measurement on the retarder as a stand-alone unit (2) Measurement in combination with the transmission

5.1.1. General requirements

In case the losses are measured on the retarder as stand-alone unit, the results are affected by the torque losses in the bearings of the test setup. It is permitted to measure these bearing losses and subtract them from the retarder drag loss measurements. The manufacturer shall guarantee that the retarder used for the measurements is in accordance with the drawing specifications for series production retarders.

Modifications to the retarder to meet the testing requirements of this Annex, e.g. for the inclusion of measurement sensors or the adaption of an external oil conditioning systems are permitted. Based on the family described in Appendix 6 to this Annex, measured drag losses for transmissions with retarder can be used for the same (equivalent) transmission without retarder. The use of the same transmission unit for measuring the torque losses of variants with and without retarder is permitted. Upon request of the approval authority the applicant for a certificate shall specify and prove the conformity with the requirements defined in this Annex.

5.1.2. Run-in

On request of the applicant a run-in procedure may be applied to the retarder. The following provisions shall apply for a run-in procedure.

5.1.2.1 If the manufacturer applies a run-in procedure to the retarder, the run-in time for the retarder shall not exceed 100 hours at zero retarder apply torque. Optionally a share of a maximum of 6 hours with retarder apply torque may be included.

5.1.3. Test conditions

5.1.3.1. Ambient temperature

The ambient temperature during the test shall be in a range of 25°C ± 10 K. The ambient temperature shall be measured 1 m laterally from the retarder.

5.1.3.2. Ambient pressure

For magnetic retarders the minimum ambient pressure shall be 899 hPa according to International Standard Atmosphere (ISA) ISO 2533.

5.1.3.3. Oil or water temperature

For hydrodynamic retarders: Except for the fluid, no external heating is allowed. In case of testing as stand-alone unit, the retarder fluid temperature (oil or water) shall not exceed 87°C. In case of testing in combination with transmission, the oil temperature limits for transmission testing shall apply.

5.1.3.4. Oil or water quality

New, recommended first fill oil for the European market shall be used in the test. For water retarders the water quality shall meet the specifications set out by the manufacturer for the retarder. The water pressure shall be set to a fixed value close to vehicle condition (1 ± 0.2 bar relative pressure at retarder input hose).

5.1.3.5. Oil viscosity

If several oils are recommended for first fill, they are considered to be equal if the oils have a kinematic viscosity within 50% of each other at the same temperature (within the specified tolerance band for KV100).

5.1.3.6. Oil or water level

The oil/water level shall meet the nominal specifications for the retarder.

5.1.4. Installation

The electric machine, the torque sensor, and speed sensor shall be mounted at the input side of the retarder or transmission. The installation of the retarder (and transmission) shall be done with an inclination angle as for installation in the vehicle according to the homologation drawing ± 1° or at 0° ± 1°.

5.1.5. Measurement equipment

As specified for transmission testing in 3.1.4. 5.1.6. Test procedure

5.1.6.1. Zero torque signal compensation:

As specified for transmission testing in 3.1.6.1. 5.1.6.2. Measurement sequence

The torque loss measurement sequence for the retarder testing shall follow the provisions for the transmission testing defined in 3.1.6.3.2. to 3.1.6.3.5.

5.1.6.2.1. Measurement on the retarder as stand-alone unit

When the retarder is tested as stand-alone unit, torque loss measurements shall be conducted using the following speed points: 200, 400, 600, 900, 1200, 1600, 2000, 2500, 3000, 3500, 4000, 4500, 5000, continued up to the maximum retarder rotor speed.

5.1.6.2.2. Measurement in combination with the transmission

5.1.6.2.2.1. In case the retarder is tested in combination with a transmission, the selected transmission gear shall allow the retarder to operate at its maximum rotor speed.

5.1.6.2.2. The torque loss shall be measured at the operating speeds as indicated for the related transmission testing.

5.1.6.2.2.3. Measurement points may be added for transmission input speeds below 600 rpm if requested by the manufacturer.

5.1.6.2.2.4. The manufacturer may separate the retarder losses from the total transmission losses by testing in the order as described below:

• (1) 

  The load-independent torque loss for the complete transmission including retarder shall be measured as defined in point 3.1.2. for transmission testing in one of the higher transmission gears

  • = 

    T l,in,withret (2) The retarder and related parts shall be replaced with parts required for the

  equivalent transmission variant without retarder. The measurement of point (1) shall be repeated. = T l,in,withoutret

• (3) 

  The load-independent torque loss for the retarder system shall be determined by calculating the differences between the two test data sets

  • = 

    T l,in,retsys = T l,in,withret – T l,in,withoutret 5.1.7. Measurement signals and data recording

As specified for transmission testing in 3.1.5. 5.1.8. Measurement validation

All recorded data shall be checked and processed as defined for transmission testing in 3.1.7.

5.2. Complement of input files for the simulation tool

5.2.1 Retarder torque losses for speeds below the lowest measurement speed shall be set equal to the measured torque loss at this lowest measurement speed.

5.2.2 In case the retarder losses were separated out from the total losses by calculating the difference in data sets of testing with and without a retarder (see 5.1.6.2.2.4.), the actual retarder rotor speeds depend on the retarder location, and/or selected gear ratio and retarder step-up ratio and thereby may differ from the measured transmission input shaft speeds. The actual retarder rotor speeds relative to the measured drag loss data shall be calculated as described in 5.1. Table 2.

5.2.3 The torque loss map data shall be formatted and saved as specified in Appendix 12 to this Annex.

• 6. 

  Additional driveline components (ADC) / angle drive

6.1. Methods for establishing angle drive losses

The angle drive losses shall be determined using one of the following cases: 6.1.1. Case A: Measurement on a separate angle drive

For the torque loss measurement of a separate angle drive, the three options as defined for the determination of the transmission losses shall apply: Option 1: Measured torque independent losses and calculated torque dependent losses (Transmission test option 1) Option 2: Measured torque independent losses and measured torque dependent losses at full load (Transmission test option 2) Option 3: Measurement under full load points (Transmission test option 3) The measurement of the angle drive losses shall follow the procedure described for the related transmission test option in paragraph 3 diverging in the following requirements:

6.1.1.1 Applicable speed range:

From 200 rpm (at the shaft to which the angle drive is connected) up to the maximum speed according to specifications of the angle drive or the last speed step before the defined maximum speed.

6.1.1.2 Speed step size: 200 rpm

6.1.2. Case B: Individual measurement of an angle drive connected to a transmission

In case the angle drive is tested in combination with a transmission, the testing shall follow one of the defined options for transmission testing: Option 1: Measured torque independent losses and calculated torque dependent losses (Transmission test option 1) Option 2: Measured torque independent losses and measured torque dependent losses at full load (Transmission test option 2) Option 3: Measurement under full load points (Transmission test option 3)

6.1.2.1 The manufacturer may separate the angle drive losses from the total transmission losses by testing in the order as described below:

• (1) 

  The torque loss for the complete transmission including angle drive shall be measured as defined for the applicable transmission testing option

  • = 

    T l,in,withad (2) The angle drive and related parts shall be replaced with parts required for the

  equivalent transmission variant without angle drive. The measurement of point (1) shall be repeated. = T l,in,withoutad

• (3) 

  The torque loss for the angle drive system shall be determined by calculating the differences between the two test data sets

  • = 

    T l,in,adsys = T l,in,withad – T l,in,withoutad 6.2. Complement of input files for the simulation tool

6.2.1. Torque losses for speeds below the above defined minimum speed shall be set equal to the torque loss at the minimum speed.

6.2.2. In the cases the highest tested angle drive input speed was the last speed step below the defined maximum permissible angle drive speed, an extrapolation of the torque loss shall be applied up to the maximum speed with linear regression based on the two last measured speed steps.

6.2.3. To calculate the torque loss data for the input shaft of the transmission the angle drive is to be combined with, linear interpolation and extrapolation shall be used.

• 7. 

  Conformity of the certified CO 2 emissions and fuel consumption related properties

7.1. Every transmission, torque converter (TC), other torque transferring components (OTTC) and additional driveline components (ADC) shall be so manufactured as to conform to the approved type with regard to the description as given in the certificate and its annexes. The conformity of the certified CO 2 emissions and fuel consumption related properties procedures shall comply with those set out in Article 12 of Directive 2007/46/EC i.

7.2 Torque converter (TC), other torque transferring components (OTTC) and additional driveline components (ADC) shall be excluded from the production conformity testing provisions of section 8 to this annex.

7.3 Conformity of the certified CO 2 emissions and fuel consumption related properties shall be checked on the basis of the description in the certificates set out in Appendix 1 to this Annex.

7.4 Conformity of the certified CO 2 emissions and fuel consumption related properties shall be assessed in accordance with the specific conditions laid down in this paragraph.

7.5 The manufacturer shall test annually at least the number of transmissions indicated in Table 3 based on the total annual production number of the transmissions produced by the manufacturer. For the purpose of establishing the production numbers, only transmissions which fall under the requirements of this Regulation shall be considered.

7.6 Each transmission which is tested by the manufacturer shall be representative for a specific family. Notwithstanding provisions of the point 7.10., only one transmission per family shall be tested.

7.7 For the total annual production volumes between 1001 and 10,000 transmissions, the choice of the family for which the tests shall be performed shall be agreed between the manufacturer and the approval authority.

7.8 For the total annual production volumes above 10,000 transmissions, the transmission family with the highest production volume shall always be tested. The manufacturer shall justify (ex. by showing sales numbers) to the approval authority the number of tests which has been performed and the choice of the families. The remaining families for which the tests are to be performed shall be agreed between the manufacturer and the approval authority.

Table 3: Sample size conformity testing

Total annual production

of transmissions Number of tests

0 – 1000 0

>1000-10.000 1

>10.000 – 30.000 2

>30.000 3

>100.000 4

7.9. For the purpose of the conformity of the certified CO 2 emissions and fuel consumption related properties testing the approval authority shall identify together with the manufacturer the transmission type(s) to be tested. The approval authority shall ensure that the selected transmission type(s) is manufactured to the same standards as for serial production..

7.10 If the result of a test performed in accordance with point 8 is higher than the one specified in point 8.1.3., 3 additional transmissions from the same family shall be tested. If at least one of them fails, provisions of Article 23 shall apply.

• 8. 

  Production conformity testing

  For conformity of the certified CO 2 emissions and fuel consumption related properties testing the following method shall apply upon prior agreement between an approval authority and the applicant for a certificate:

8.1 Conformity testing of transmissions

8.1.1 The transmission efficiency shall be determined following the simplified procedure described in this paragraph.

8.1.2.1 All boundary conditions as specified in this Annex for the certification testing shall apply.

If other boundary conditions for oil type, oil temperature and inclination angle are used, the manufacturer shall clearly show the influence of these conditions and those used for certification regarding efficiency.

8.1.2.2 For the measurement the same testing option shall be used as for the certification testing, limited to the operating points specified in this paragraph.

8.1.2.2.1. In the case Option 1 was used for certification testing, the torque independent losses for the two speeds defined in point 3 of 8.1.2.2.2. shall be measured and used for the calculation of the torque losses at the three highest torque steps.

In the case Option 2 was used for certification testing, the torque independent losses for the two speeds defined in point 3 of 8.1.2.2.2. shall be measured. The torque dependent losses at maximum torque shall be measured at the same two speeds. The torque losses at the three highest torque steps shall be interpolated as described by the certification procedure. In the case Option 3 was used for certification testing, the torque losses for the 18 operating points defined in 8.1.2.2.2. shall be measured.

8.1.2.2.2. The efficiency of the transmission shall be determined for 18 operating points defined by the following requirements:

• (1) 

  Gears to use: The 3 highest gears of the transmission shall be used for testing. (2) Torque range: The 3 highest torque steps as reported for certification shall be tested. (3) Speed range: The two transmission input speeds of 1200 rpm and 1600 rpm shall be tested.

8.1.2.3 For each of the 18 operating points, the efficiency of the transmission shall be calculated with:

η 𝑖 = 𝑇 𝑜𝑢𝑡 ∙ 𝑛 𝑜𝑢𝑡 𝑇

𝑖𝑛 ∙ 𝑛 𝑖𝑛 where:

η 𝑖 = Efficiency of each operation point 1 to 18

𝑇

𝑜𝑢𝑡 = Output torque [Nm]

𝑇

𝑖𝑛 = Input torque [Nm]

n in = Input speed [rpm] n out = Output speed [rpm]

8.1.2.4 The total efficiency during conformity of the certified CO 2 emissions and fuel consumption related properties testing η A,CoP shall be calculated by the arithmetic mean value of the efficiency of all 18 operating points.

η η 1 + η 2 + [… ] + η 18 𝐴,𝐶𝑜𝑃 = 18

8.1.3 The conformity of the certified CO 2 emissions and fuel consumption related properties test is passed when the following condition applies:

The efficiency of the tested transmission during conformity of the certified CO 2 emissions and fuel consumption related properties test η A,CoP shall not be lower than X% of the type approved transmission efficiency η A,TA .

𝜂 𝐴,𝑇𝐴 − 𝜂 𝐴,𝐶𝑜𝑃 ≤ 𝑿

X shall be replaced by 1,5% for MT/AMT/DCT transmissions and 3% for AT transmissions or transmission with more than 2 friction shift clutches.

Appendix 1

MODEL OF A CERTIFICATE OF A COMPONENT, SEPARATE TECHNICAL UNIT OR SYSTEM

Maximum format: A4 (210 x 297 mm) CERTIFICATE ON CO 2 EMISSIONS AND FUEL CONSUMPTION RELATED PROPERTIES OF A TRANSMISSON / TORQUE CONVERTER / OTHER TORQUE

TRANSFERRING COMPONENT/ ADDITIONAL DRIVELINE COMPONENT (1)

FAMILY

Communication concerning: Administration stamp

– granting (1)

– extension (1)

– refusal (1)

– withdrawal (1)

of a certificate with regard to Regulation (EC) No 595/2009 i as implemented by Regulation No … [this Regulation].

Regulation (EC) No XXXXX and Regulation No … [this Regulation] as last amended by …………….. certification number:

Hash:

Reason for extension:

________

• (1) 

  Delete where not applicable (there are cases where nothing needs to be deleted when more than one entry is applicable)

  SECTION I 0.1 Make (trade name of manufacturer):

0.2 Type:

0.3 Means of identification of type, if marked on the component

0.3.1 Location of the marking:

0.4 Name and address of manufacturer:

0.5 In the case of components and separate technical units, location and method of affixing of the EC approval mark:

0.6 Name(s) and address(es) of assembly plant(s):

0.7 Name and address of the manufacturer's representative (if any)

SECTION II 1. Additional information (where applicable): see Addendum 1.1. Option used for the determination of the torque losses 1.1.1 In case of transmission: specify for both output torque ranges 0-10 kNm and >10 kNm

separately for each transmission gear 2. Approval authority responsible for carrying out the tests: 3. Date of test report

• 4. 

  Number of test report

• 5. 

  Remarks (if any): see Addendum

• 6. 

  Place

• 7. 

  Date

• 8. 

  Signature

Attachments:

• 1. 

  Information document

• 2. 

  Test report

  Appendix 2

  Transmission information document

Information document no.: Issue:

Date of issue: Date of Amendment:

pursuant to …

Transmission type:

… 0. GENERAL

0.1. Name and address of manufacturer

0.2. Make (trade name of manufacturer):

0.3. Transmission type:

0.4. Transmission family:

0.5. Transmission type as separate technical unit / Transmission family as separate technical unit

0.6. Commercial name(s) (if available):

0.7. Means of identification of model, if marked on the transmission:

0.8. In the case of components and separate technical units, location and method of affixing of the EC approval mark:

0.9. Name(s) and address(es) of assembly plant(s):

0.10. Name and address of the manufacturer's representative:

PART 1

ESSENTIAL CHARACTERISTICS OF THE (PARENT) TRANSMISSION AND THE TRANSMISSION

TYPES WITHIN A TRANSMISSION FAMIL Y

|Parent transmission |Family members |or transmission type | | | #1 | #2 | #3 |

0.0 GENERAL

0.1 Make (trade name of manufacturer)

0.2 Type

0.3 Commercial name(s) (if available)

0.4 Means of identification of type

0.5 Location of that marking

0.6 Name and address of manufacturer

0.7 Location and method of affixing of the approval mark

0.8 Name(s) and address (es) of assembly plant(s)

0.9 Name and address of the manufacturer’s representative (if any)

1.0 SPECIFIC TRANSMISSION / TRANSMISSION FAMILY INFORMATION

1.1 Gear ratio. Gearscheme and powerflow

1.2 Center distance for countershaft transmissions

1.3 Type of bearings at corresponding positions (if fitted)

1.4 Type of shift elements (tooth clutches, including synchronisers or friction clutches) at corresponding positions (where fitted)

1.5 Single gear width for Option 1 or Single gear width ± 1 mm for Option 2 or Option 3 1.6 Total number of forward gears

1.7 Number of tooth shift clutches

1.8 Number of synchronizers

1.9 Number of friction clutch plates (except for single dry clutch with 1 or 2 plates)

1.10 Outer diameter of friction clutch plates (except for single dry clutch with 1 or 2 plates)

1.11 Surface roughness of the teeth (incl. drawings)

1.12 Number of dynamic shaft seals

1.13 Oil flow for lubrication and cooling per transmission input shaft revolution

1.14 Oil viscosity at 100°C (± 10%)

1.15 System pressure for hydraulically controlled gearboxes

1.16 Specified oil level in reference to central axis and in accordance with the drawing specification (based on average value between lower and upper tolerance) in static or running condition. The oil level is considered as equal if all rotating transmission parts (except for the oil pump and the drive thereof) are located above the specified oil level

1.17 Specified oil level (± 1mm)

1.18 Gear ratios [-] and maximum input torque [Nm], maximum input power (kW) and maximum input speed [rpm]

1 gear 2 gear 3 gear 4 gear 5 gear 6 gear 7 gear 8 gear 9 gear 10 gear 11 gear

n gear LIST OF ATTACHMENTS

No.: Description: Date of issue:

1 Information on Transmission test conditions …

2 …

Attachment 1 to Transmission information document

Information on test conditions (if applicable) 1.1 Measurement with retarder yes / no 1.2 Measurement with angle drive yes / no 1.3 Maximum tested input speed [rpm]

1.4 Maximum tested input torque [Nm]

Appendix 3

Hydrodynamic torque converter (TC) information document

Information document no.: Issue:

Date of issue: Date of Amendment:

pursuant to …

TC type:

… 0. GENERAL

0.1 Name and address of manufacturer

0.2 Make (trade name of manufacturer):

0.3 TC type:

0.4 TC family:

0.5 TC type as separate technical unit / TC family as separate technical unit

0.6 Commercial name(s) (if available):

0.7 Means of identification of model, if marked on the TC:

0.8 In the case of components and separate technical units, location and method of affixing of the EC approval mark:

0.9 Name(s) and address(es) of assembly plant(s):

0.10 Name and address of the manufacturer's representative:

PART 1

ESSENTIAL CHARACTERISTICS OF THE (PARENT) TC AND THE TC TYPES WITHIN A TC FAMILY

|Parent TC or |Family members | |TC type | #1 | #2 | #3 |

| | | | | 0.0 GENERAL

0.1 Make (trade name of manufacturer)

0.2 Type

0.3 Commercial name(s) (if available)

0.4 Means of identification of type

0.5 Location of that marking

0.6 Name and address of manufacturer

0.7 Location and method of affixing of the approval mark

0.8. Name(s) and address (es) of assembly plant(s)

0.9. Name and address of the manufacturer’s representative (if any)

1.0 SPECIFIC TORQUE CONVERTER / TORQUE CONVERTER FAMILY INFORMATION

1.1 For hydrodynamic torque converter without mechanical transmission (serial arrangement).

1.1.1 Outer torus diameter

1.1.2 Inner torus diameter

1.1.3 Arrangement of pump (P), turbine (T) and stator (S) in flow direction

1.1.4 Torus width

1.1.5 Oil type according to test specification

1.1.6 Blade design

1.2 For hydrodynamic torque converter with mechanical transmission (parallel arrangement).

1.2.1 Outer torus diameter

1.2.2 Inner torus diameter

1.2.3 Arrangement of pump (P), turbine (T) and stator (S) in flow direction

1.2.4 Torus width

1.2.5 Oil type according to test specification

1.2.6 Blade design

1.2.7 Gear scheme and power flow in torque converter mode

1.2.8 Type of bearings at corresponding positions (if fitted)

1.2.9 Type of cooling/lubrication pump (referring to parts list)

1.2.10 Type of shift elements (tooth clutches (including synchronisers) OR friction clutches) at corresponding positions where fitted

1.2.11 Oil level according to drawing in reference to central axis

LIST OF ATTACHMENTS

No.: Description: Date of issue:

1 Information on Torque Converter test conditions …

2 …

Attachment 1 to Torque Converter information document

Information on test conditions (if applicable) 1. Method of measurement

1.1 TC with mechanical transmission yes /no

1.2 TC as separate unit yes / no

Appendix 4

Other torque transferring components (OTTC) information document

Information document no.: Issue:

Date of issue: Date of Amendment:

pursuant to …

OTTC type:

… 0. GENERAL

0.1 Name and address of manufacturer

0.2 Make (trade name of manufacturer):

0.3 OTTC type:

0.4 OTTC family:

0.5 OTTC type as separate technical unit / OTTC family as separate technical unit

0.6 Commercial name(s) (if available):

0.7 Means of identification of model, if marked on the OTTC:

0.8 In the case of components and separate technical units, location and method of affixing of the EC approval mark:

0.9 Name(s) and address(es) of assembly plant(s):

0.10 Name and address of the manufacturer's representative:

PART 1

ESSENTIAL CHARACTERISTICS OF THE (PARENT) OTTC AND THE OTTC TYPES WITHIN AN OTTC FAMILY

|Parent OTTC|Family member| | | #1 | #2 | #3 |

0.0 GENERAL

0.1 Make (trade name of manufacturer)

0.2 Type

0.3 Commercial name(s) (if available)

0.4 Means of identification of type

0.5 Location of that marking

0.6 Name and address of manufacturer

0.7 Location and method of affixing of the approval mark

0.8. Name(s) and address (es) of assembly plant(s)

0.9. Name and address of the manufacturer’s representative (if any)

1.0 SPECIFIC OTTC INFORMATION

1.1 For hydrodynamic torque transferring components (OTTC) / retarder

1.1.1 Outer torus diameter

1.1.2 Torus width

1.1.3 Blade design

1.1.4 Operating fluid

1.1.5 Outer torus diameter - inner torus diameter (OD-ID)

1.1.6 Number of blades

1.1.7 Operating fluid viscosity

1.2 For magnetic torque transferring components (OTTC) / Retarder

1.2.1 Drum design (electro magnetic retarder or permanent magnetic retarder)

1.2.2 Outer rotor diameter

1.2.3 Cooling blade design

1.2.4 Blade design

1.2.5 Operating fluid

1.2.6 Outer rotor diameter - inner rotor diameter (OD-ID)

1.2.7 Number of rotors

1.2.8 Number of cooling blades / blades

1.2.9 Operating fluid viscosity

1.2.10 Number of arms

1.3 For torque transferring components (OTTC) / hydrodynamic clutch 1.3.1 Outer torus diameter

1.3.2 Torus width

1.3.3 Blade design.

1.3.4 Operating fluid viscosity

1.3.5 Outer torus diameter - inner torus diameter (OD-ID)

1.3.6 Number of blades

LIST OF ATTACHMENTS

No.: Description: Date of issue:

1 Information on OTTC test conditions …

2 …

Attachment 1 to OTTC information document

Information on test conditions (if applicable) 1. Method of measurement

with transmission yes / no with engine yes / no drive mechanism yes / no direct yes / no

• 2. 

  Maximum test speed of OTTC main torque absorber e.g. retarder rotor [rpm] Appendix 5

Additional driveline components (ADC) information document

Information document no.: Issue:

Date of issue: Date of Amendment:

pursuant to …

ADC type:

… 0. GENERAL

0.1 Name and address of manufacturer

0.2 Make (trade name of manufacturer):

0.3 ADC type:

0.4 ADC family:

0.5 ADC type as separate technical unit / ADC family as separate technical unit

0.6 Commercial name(s) (if available):

0.7 Means of identification of model, if marked on the ADC:

0.8 In the case of components and separate technical units, location and method of affixing of the EC approval mark:

0.9 Name(s) and address(es) of assembly plant(s):

0.10 Name and address of the manufacturer's representative:

PART 1

ESSENTIAL CHARACTERISTICS OF THE (PARENT) ADC AND THE ADC TYPES WITHIN AN ADC FAMILY

|Parent-ADC |Family member|

| | #1 | #2 | #3 |

0.0 GENERAL

0.1 Make (trade name of manufacturer)

0.2 Type

0.3 Commercial name(s) (if available)

0.4 Means of identification of type

0.5 Location of that marking

0.6 Name and address of manufacturer

0.7 Location and method of affixing of the approval mark

0.8. Name(s) and address (es) of assembly plant(s)

0.9. Name and address of the manufacturer’s representative (if any)

1.0 SPECIFIC ADC / ANGLE DRIVE INFORMATION

1.1 Gear ratio and gearscheme

1.2 Angle between input/output shaft

1.3 Type of bearings at corresponding positions

1.4 Number of teeth per gearwheel

1.5 Single gear width

1.6 Number of dynamic shaft seals

1.7 Oil viscosity (± 10%)

1.8 Surface roughness of the teeth

1.9 Specified oil level in reference to central axis and in accordance with the drawing specification (based on average value between lower and upper tolerance) in static or running condition. The oil level is considered as equal if all rotating transmission parts (except for the oil pump and the drive thereof) are located above the specified oil level

1.10 Oil level within (± 1mm).

LIST OF ATTACHMENTS

No.: Description: Date of issue: 1 Information on ADC test conditions … 2 … Attachment 1 to ADC information document

Information on test conditions (if applicable) 1. Method of measurement

with transmission yes / no drive mechanism yes / no direct yes / no

• 2. 

  Maximum test speed at ADC input [rpm] Appendix 6

Family Concept

• 1. 

  General

  A transmission, torque converter, other torque transferring components or additional driveline components family is characterized by design and performance parameters. These shall be common to all members within the family. The manufacturer may decide which transmission, torque converter, other torque transferring components or additional driveline components belong to a family, as long as the membership criteria listed in this Appendix are respected. The related family shall be approved by the Approval Authority. The manufacturer shall provide to the Approval Authority the appropriate information relating to the members of the family.

1.1 Special cases

In some cases there may be interaction between parameters. This shall be taken into consideration to ensure that only transmissions, torque converter, other torque transferring components or additional driveline components with similar characteristics are included within the same family. These cases shall be identified by the manufacturer and notified to the Approval Authority. It shall then be taken into account as a criterion for creating a new transmission, torque converter, other torque transferring components or additional driveline components family. In case of devices or features, which are not listed in paragraph 9. and which have a strong influence on the level of performance, this equipment shall be identified by the manufacturer on the basis of good engineering practice, and shall be notified to the Approval Authority. It shall then be taken into account as a criterion for creating a new transmission, torque converter, other torque transferring components or additional driveline components family.

1.2 The family concept defines criteria and parameters enabling the manufacturer to group transmission, torque converter, other torque transferring components or additional driveline components into families and types with similar or equal CO 2 -relevant data.

• 2. 

  The Approval Authority may conclude that the highest torque loss of the transmission, torque converter, other torque transferring components or additional driveline components family can best be characterized by additional testing. In this case, the manufacturer shall submit the appropriate information to determine the transmission, torque converter, other torque transferring components or additional driveline components within the family likely to have the highest torque loss level.

  If members within a family incorporate other features which may be considered to affect the torque losses, these features shall also be identified and taken into account in the selection of the parent.

• 3. 

  Parameters defining the transmission family

3.1 The following criteria shall be the same to all members within a transmission family.

(a) Gear ratio, gearscheme and powerflow (for forward gears only, crawler gears excluded);

(b) Center distance for countershaft transmissions; (c) Type of bearings at corresponding positions (if fitted); (d) Type of shift elements (tooth clutches, including synchronisers or friction clutches) at corresponding positions (where fitted).

3.2 The following criteria shall be common to all members within a transmission family. The application of a specific range to the parameters listed below is permitted after approval of the Approval Authority

(a) Single gear width ± 1mm ; (b) Total number of forward gears; (c) Number of tooth shift clutches; (d) Number of synchronizers; (e) Number of friction clutch plates (except for single dry clutch with 1 or 2 plates); (f) Outer diameter of friction clutch plates (except for single dry clutch with 1 or 2 plates); (g) Surface roughness of the teeth; (h) Number of dynamic shaft seals; (i) Oil flow for lubrication and cooling per input shaft revolution; (j) Oil viscosity (± 10%); (k) System pressure for hydraulically controlled gearboxes; (l) Specified oil level in reference to central axis and in accordance with the drawing specification (based on average value between lower and upper tolerance) in static or running condition. The oil level is considered as equal if all rotating transmission parts (except for the oil pump and the drive thereof) are located above the specified oil level; (m) Specified oil level (± 1mm).

• 4. 

  Choice of the parent transmission

  The parent transmission shall be selected using the following criteria listed below. (a) Highest single gear width for Option 1 or highest Single gear width ± 1 mm for Option 2 or Option 3; (b) Highest total number of gears; (c) Highest number of tooth shift clutches; (d) Highest number of synchronizers; (e) Highest number of friction clutch plates (except for single dry clutch with 1 or 2 plates); (f) Highest value of the outer diameter of friction clutch plates (except for single dry clutch with 1 or 2 plates); (g) Highest value for the surface roughness of the teeth ; (h) Highest number of dynamic shaft seals; (i) Highest oil flow for lubrication and cooling per input shaft revolution; (j) Highest oil viscosity; (k) Highest system pressure for hydraulically controlled gearboxes; (l) Highest specified oil level in reference to central axis and in accordance with the drawing specification (based on average value between lower and upper tolerance) in static or running condition. The oil level is considered as equal if all rotating transmission parts (except for the oil pump and the drive thereof) are located above the specified oil level; (m) Highest specified oil level (± 1mm).

• 5. 

  Parameters defining the torque converter family

5.1 The following criteria shall be the same to all members within a torque converter (TC) family.

5.1.1 For hydrodynamic torque converter without mechanical transmission (serial arrangement).

(a) Outer torus diameter; (b) Inner torus diameter; (c) Arrangement of pump (P), turbine (T) and stator (S) in flow direction; (d) Torus width; (e) Oil type according to test specification; (f) Blade design;

5.1.2 For hydrodynamic torque converter with mechanical transmission (parallel arrangement).

(a) Outer torus diameter; (b) Inner torus diameter; (c) Arrangement of pump (P), turbine (T) and stator (S) in flow direction; (d) Torus width; (e) Oil type according to test specification; (f) Blade design (g) Gear scheme and power flow in torque converter mode (h) Type of bearings at corresponding positions (if fitted) (i) Type of cooling/lubrication pump (referring to parts list) (j) Type of shift elements (tooth clutches (including synchronisers) or friction clutches) at corresponding positions where fitted

5.1.3 The following criteria shall be common to all members within a hydrodynamic torque converter with mechanical transmission (parallel arrangement) family. The application of a specific range to the parameters listed below is permitted after approval of the Approval Authority

(a) Oil level according to drawing in reference to central axis. 6. Choice of the parent torque converter

6.1 For hydrodynamic torque converter without mechanical (serial arrangement) transmission.

As long as all criteria listed in 5.1.1 are identical every member of the torque converter without mechanical transmission family can be selected as parent.

6.2 For hydrodynamic torque converter with mechanical transmission.

The parent hydrodynamic torque converter with mechanical transmission (parallel arrangement) shall be selected using the following criteria listed below. (a) Highest oil level according to drawing in reference to central axis.

• 7. 

  Parameters defining the other torque transferring components (OTTC) family

7.1 The following criteria shall be the same to all members within a hydrodynamic torque transferring components / retarder family.

(a) Outer torus diameter; (b) Torus width; (c) Blade design; (d) Operating fluid.

7.2 The following criteria shall be the same to all members within a magnetic torque transferring components / retarder family.

(a) Drum design (electro magnetic retarder or permanent magnetic retarder);

(b) Outer rotor diameter; (c) Cooling blade design; (d) Blade design.

7.3 The following criteria shall be the same to all members within a torque transferring components / hydrodynamic clutch family.

(a) Outer torus diameter; (b) Torus width; (c) Blade design.

7.4 The following criteria shall be common to all members within a hydrodynamic torque transferring components / retarder family. The application of a specific range to the parameters listed below is permitted after approval of the Approval Authority.

(a) Outer torus diameter - inner torus diameter (OD-ID); (b) Number of blades; (c) Operating fluid viscosity (± 50%).

7.5 The following criteria shall be common to all members within a magnetic torque transferring components / retarder family. The application of a specific range to the parameters listed below is permitted after approval of the Approval Authority.

(a) Outer rotor diameter - inner rotor diameter (OD-ID); (b) Number of rotors; (c) Number of cooling blades / blades; (d) Number of arms.

7.6 The following criteria shall be common to all members within a torque transferring components / hydrodynamic clutch family. The application of a specific range to the parameters listed below is permitted after approval of the Approval Authority.

(a) Operating fluid viscosity (± 10%); (b) Outer torus diameter - inner torus diameter (OD-ID); (c) Number of blades.

• 8. 

  Choice of the parent torque transferring component

8.1 The parent hydrodynamic torque transferring component / retarder shall be selected using the following criteria listed below.

(a) Highest value: outer torus diameter – inner torus diameter (OD- ID);

(b) Highest number of blades; (c) Highest operating fluid viscosity.

8.2 The parent magnetic torque transferring component / retarder shall be selected using the following criteria listed below.

(a) Highest outer rotor diameter – highest inner rotor diameter (OD- ID);

(b) Highest number of rotors; (c) Highest number of cooling blades / blades; (d) Highest number of arms.

8.3 The parent torque transferring component / hydrodynamic clutch shall be selected using the following criteria listed below.

(a) Highest operating fluid viscosity (± 10%); (b) Highest outer torus diameter – highest inner torus diameter (OD- ID); (c) Highest number of blades.

• 9. 

  Parameters defining the additional driveline components family

  9.1 The following criteria shall be the same to all members within an additional driveline components / angle drive family family. (a) Gear ratio and gearscheme; (b) Angle between input/output shaft; (c) Type of bearings at corresponding positions

9.2 The following criteria shall be common to all members within an additional driveline components / angle family. The application of a specific range to the parameters listed below is permitted after approval of the Approval Authority.

(a) Single gear width; (b) Number of dynamic shaft seals; (c) Oil viscosity (± 10%); (d) Surface roughness of the teeth; (e) Specified oil level in reference to central axis and in accordance with the drawing specification (based on average value between lower and upper tolerance) in static or running condition. The oil level is considered as equal if all rotating transmission parts (except for the oil pump and the drive thereof) are located above the specified oil level.

• 10. 

  Choice of the parent additional driveline component

10.1 The parent additional driveline component / angle drive shall be selected using the following criteria listed below.

(a) Highest single gear width; (a) Highest number of dynamic shaft seals; (c) Highest oil viscosity (± 10%); (d) Highest surface roughness of the teeth; (e) Highest specified oil level in reference to central axis and in accordance with the drawing specification (based on average value between lower and upper tolerance) in static or running condition. The oil level is considered as equal if all rotating transmission parts (except for the oil pump and the drive thereof) are located above the specified oil level.

Appendix 7 Markings and numbering

• 1. 

  Markings

  In the case of a component being certified in accordance with this Annex, the component shall bear:

1.1 The manufacturer’s name and trade mark

1.2 The make and identifying type indication as recorded in the information referred to in paragraph 0.2 and 0.3 of Part 1 of Appendices 2 - 5 to this Annex

1.3 The certification mark (if applicable) as a rectangle surrounding the lower-case letter ‘e’ followed by the distinguishing number of the Member State which has granted the certificate:

1 for Germany; 19 for Romania; 2 for France; 20 for Poland; 3 for Italy; 21 for Portugal; 4 for the Netherlands; 23 for Greece; 5 for Sweden; 24 for Ireland; 6 for Belgium; 25 for Croatia; 7 for Hungary; 26 for Slovenia; 8 for the Czech Republic; 27 for Slovakia; 9 for Spain; 29 for Estonia; 11 for the United Kingdom; 32 for Latvia; 12 for Austria; 34 for Bulgaria; 13 for Luxembourg; 36 for Lithuania; 17 for Finland; 49 for Cyprus;

1.4 The certification mark shall also include in the vicinity of the rectangle the ‘base approval number’ as specified for Section 4 of the type-approval number set out in Annex VII to Directive 2007/46/EC i, preceded by the two figures indicating the sequence number assigned to the latest technical amendment to this Regulation and by an alphabetical character indicating the part for which the certificate has been granted.

For this Regulation, the sequence number shall be 00. For this Regulation, the alphabetical character shall be the one laid down in Table 1. Table 1

T Transmission

C Torque Converter (TC)

O Other torque transferring component (OTTC)

D Additional driveline component (ADC)

1.5 Example of the certification mark

a e 20 2a a ≥ 3mm

00T 0004 a

The above certification mark affixed to a transmission, torque converter (TC), other torque transferring component (OTTC) or additional driveline component (ADC) shows that the type concerned has been certified in Poland (e20), pursuant to this Regulation. The first two digits (00) are indicating the sequence number assigned to the latest technical amendment to this Regulation. The following digit indicates that the certification was granted for a transmission (T). The last four digits (0004) are those allocated by the type-approval authority to the transmission, as the base approval number.

1.6 On request of the applicant for certificate and after prior agreement with the approval authority other type sizes than indicated in 1.5 may be used. Those other type sizes shall remain clearly legible.

1.7 The markings, labels, plates or stickers must be durable for the useful life of the transmission, torque converter (TC), other torque transferring components (OTTC) or additional driveline components (ADC) and must be clearly legible and indelible. The manufacturer shall ensure that the markings, labels, plates or sticker cannot be removed without destroying or defacing them.

1.8 In the case separate certifications are granted by the same approval authority for a transmission, a torque converter, other torque transferring components or additional driveline components and those parts are installed in combination, the indication of one certification mark referred to in point 1.3 is sufficient. This certification mark shall be followed by the applicable markings specified in point 1.4 for the respective transmission, torque converter, other torque transferring component or additional driveline component separated by '/'.

1.9. The certification mark shall be visible when the transmission, torque converter, other torque transferring component or additional driveline component is installed on the vehicle and shall be affixed to a part necessary for normal operation and not normally requiring replacement during component life.

1.10 In the case that torque converter or other torque transferring components are constructed in such a way that they are not accessible and / or visible after being assembled with a transmission the certification mark of the torque converter or other torque transferring component shall be placed on the transmission.

In the case described in first paragraph, if a torque converter or other torque

transferring component have not been certified, ‘– ‘ instead of the certification

number shall be indicated on the transmission next to the alphabetical character

specified in point 1.4.

• 2. 

  Numbering

2.1. Certification number for transmissions, torque converter, other torque transferring

component and additional driveline component shall comprise the following:

eX*YYY/YYYY*ZZZ/ZZZZ*X*0000*00

section 1 section 2 section 3 Additional letter section 4 section 5 to section 3

Indication of CO 2 Latest amending See Table 1 of Base Extension

country issuing certificatio act (zzz/zzzz) this appendix certification

the certificate n act 00

(…/2017) number

0000 Appendix 8

Standard torque loss values - Transmission

Calculated fallback values based on the maximum rated torque of the transmission:

The torque loss T l,in related to the input shaft of the transmission shall be calculated by

T = ( T in l,in d 0 + T add 0 ) + ( T d 1000 + T n add 1000 ) * 1000 rpm + ( f T + f T _ add ) * T in

where:

T l,in = Torque loss related to the input shaft [Nm] T dx = Drag torque at x rpm [Nm] T addx = Additional angle drive gear drag torque at x rpm [Nm] (if applicable) n in = Speed at the input shaft [rpm] f T = 1-η η = efficiency f T = 0.01 for direct gear, 0.04 for indirect gears f T_add = 0.04 for angle drive gear (if applicable) T in = Torque at the input shaft [Nm]

For transmissions with tooth shift clutches (Synchronised Manual Transmissions (SMT), Automated Manual Transmissions or Automatic Mechanically engaged Transmissions (AMT) and Dual Clutch Transmissions (DCT)) the drag torque T dx is calculated by

T = T = T = 10 Nm * T max in dx d 0 d 1000 Nm = 0 . 005 * T

2000 max in where:

T max,in = Maximum allowed input torque in any forward gear of transmission [Nm]

max(T max,in,gear ) T max,in,gear = Maximum allowed input torque in gear, where gear = 1, 2, 3,…top gear). For transmissions with hydrodynamic torque converter this input torque shall be the torque at transmission input before torque converter.

For transmissions with friction shift clutches (> 2 friction clutches) the drag torque T dx is calculated by

T = T = T = 30 Nm * T max in dx d 0 d 1000 2000 Nm = 0 . 015 * T max in

Here, ‘friction clutch’ is used in the context of a clutch or brake that operates with friction, and is required for sustained torque transfer in at least one gear.

For transmissions including an angle drive (e.g. bevel gear), the additional angle drive drag torque T addx shall be included in the calculation of T dx :

T = T = T = 10 * max in addx add 0 add 1000 Nm T Nm = 0 . 005 * T

2000 max in (only if applicable)

Appendix 9 Generic model – torque converter

Generic torque converter model based on standard technology:

For the determination of the torque converter characteristics a generic torque converter model depending on specific engine characteristics may be applied. The generic TC model is based on the following characteristic engine data:

n rated = Maximum engine speed at maximum power (determined from the engine full-load curve as calculated by the engine pre-processing tool) [rpm]

T max = Maximum engine torque (determined from the engine full-load curve as calculated by the engine pre-processing tool) [Nm]

Thereby the generic TC characteristics are valid only for a combination of the TC with an engine sharing the same specific characteristic engine data. Description of the four-point model for the torque capacity of the TC: Generic torque capacity and generic torque ratio:

Figure 1 Generic torque capacity

Figure 2 Generic torque ratio

where:

T P1000 = Pump reference torque;

v = Speed ratio; [-]

μ = Torque ratio; [-]

v s = Speed ratio at overrun point; [-] For TC with rotating housing (Trilock-Type) v s typically is 1. For other TC concepts, especially power split concepts, v s may have values different from 1.

v c = Speed ratio at coupling point; 𝑣 𝑐 = 𝑛2 𝑛1 [-]

v 0 = Stall point; [rpm]

v m = Intermediate speed ratio; [-] The model requires the following definitions for the calculation of the generic torque capacity:

Stall point:

• Stall point at 70% nominal engine speed. • Engine torque in stall point at 80% maximum engine torque. • Engine/Pump reference torque in stall point:

𝑇 1000𝑟𝑝𝑚

2

𝑃1000 (𝑣 0 ) = 𝑇 𝑚𝑎𝑥 ∗ 0.80 ∗ � 0.70 ∗ 𝑛 �

𝑛

Intermediate point:

• Intermediate speed ratio 𝑣 𝑚 = 0.6 ∗ 𝑣 𝑠

• Engine/pump reference torque in intermediate point at 80% of reference torque in stall point:

𝑇

𝑃1000 (𝑣 𝑚 ) = 0.8 ∗ 𝑇 𝑃1000 (𝑣 0 )

Coupling point:

• Coupling point at 90% overrun conditions: • Engine/pump reference torque in clutch point at 50% of reference torque in stall point:

𝑇 𝑃1000 (𝑣 𝑐 ) = 0.5 ∗ 𝑇 𝑃1000 (𝑣 0 )

Overrun point:

• Reference torque at overrun conditions :

𝑇 𝑃1000 (𝑣 𝑠 ) = 0

The model requires the following definitions for the calculation of the generic torque ratio:

Stall point:

• Torque ratio at stall point :

Intermediate point:

• Linear interpolation between stall point and coupling point

Coupling point:

• Torque ratio at coupling point :

Overrun point:

• Torque ratio at overrun conditions :

Efficiency:

Linear interpolation between the calculated specific points shall be used.

Appendix 10

Standard torque loss values – other torque transferring components

Calculated standard torque loss values for other torque transferring components:

For hydrodynamic retarders (oil or water), the retarder drag torque shall be calculated by

2

𝑇 𝑟𝑒𝑡𝑎𝑟𝑑𝑒𝑟 = 10 𝑖 + � 2 � ∗ � 𝑛 𝑟𝑒𝑡𝑎𝑟𝑑𝑒𝑟

𝑠𝑡𝑒𝑝−𝑢𝑝 �𝑖 𝑠𝑡𝑒𝑝−𝑢𝑝 � 3 1000 �

For magnetic retarders (permanent or electro-magnetic), the retarder drag torque shall be calculated by:

𝑇 15

3

𝑟𝑒𝑡𝑎𝑟𝑑𝑒𝑟 = 𝑖 + �

2 � ∗ � 𝑛 𝑟𝑒𝑡𝑎𝑟𝑑𝑒𝑟

𝑠𝑡𝑒𝑝−𝑢𝑝 �𝑖 𝑠𝑡𝑒𝑝−𝑢𝑝 � 4 1000 �

where:

T retarder = Retarder drag loss [Nm] n retarder = Retarder rotor speed [rpm] (see paragraph 5.1 of this Annex) i step-up = Step-up ratio = retarder rotor speed / drive component speed (see paragraph 5.1 of this Annex) Appendix 11 Standard torque loss values – geared angle drive

Consistent with the standard torque loss values for the combination of a transmission with a geared angle drive in Appendix 8, the standard torque losses of a geared angle drive without transmission shall be calculated from:

𝑇 𝑙,𝑎𝑑,𝑖𝑛 = 𝑇 𝑎𝑑𝑑0 + 𝑇 𝑎𝑑𝑑1000 ∗ 𝑛 𝑖𝑛 1000𝑟𝑝𝑚 + 𝑓 𝑇 _𝑎𝑑𝑑 ∗ 𝑇 𝑖𝑛

where:

T l,in = Torque loss related to the input shaft of transmission [Nm] T addx = Additional angle drive gear drag torque at x rpm [Nm] (if applicable) n in = Speed at the input shaft of transmission [rpm] f T = 1-η; η = efficiency f T_add = 0.04 for angle drive gear T in = Torque at the input shaft of transmission [Nm] T max,in = Maximum allowed input torque in any forward gear of transmission [Nm] = max(T max,in,gear ) T max,in,gear = Maximum allowed input torque in gear, where gear = 1, 2, 3,…top gear)

T in addx = T add 0 = T add = 10 Nm * T max 1000 2000 Nm = 0 . 005 * T max in

The standard torque losses obtained by the calculations above may be added to the torque losses of a transmission obtained by Options 1-3 in order to obtain the torque losses for the combination of the specific transmission with an angle drive.

Appendix 12

Input parameters for the simulation tool

Introduction

This Appendix describes the list of parameters to be provided by the transmission, torque converter (TC), other torque transferring components (OTTC) and additional driveline components (ADC) manufacturer as input to the simulation tool. The applicable XML schema as well as example data are available at the dedicated electronic distribution platform.

Definitions

• (1) 

  “Parameter ID”: Unique identifier as used in “Simulation tool” for a specific input parameter or set of input data

• (2) 

  “Type”: Data type of the parameter string …….. sequence of characters in ISO8859-1 encoding token …….. sequence of characters in ISO8859-1 encoding, no leading/trailing whitespace

  date ……… date and time in UTC time in the format: YYYY-MM-DDTHH:MM:SSZ with italic letters denoting fixed characters e.g. “2002-05-30T09:30:10Z”

  integer …… value with an integral data type, no leading zeros, e.g. “1800” double, X .... fractional number with exactly X digits after the decimal sign (“.”) and no leading zeros e.g. for “double, 2”: “2345.67”; for “double, 4”: “45.6780”

• (3) 

  “Unit” … physical unit of the parameter Set of input parameters

Table 1: Input parameters “Transmission/General”

Parameter name Parameter Type Unit Description/Reference ID

Manufacturer P205 token [-]

Model P206 token [-]

TechnicalReportId P207 token [-]

Date P208 dateTime [-] Date and time when the component-hash is created AppVersion P209 token [-]

TransmissionType P076 string [-] Allowed values: "SMT", "AMT", "APT-S", "APT- P" MainCertificationMethod P254 string [-] Allowed values: "Option 1", "Option 2", "Option 3", "Standard values"

Table 2: Input parameters “Transmission/Gears” per gear

Parameter name Parameter Type Unit Description/Reference ID

GearNumber P199 integer [-]

Ratio P078 double, 3 [-]

MaxTorque P157 integer [Nm] optional

MaxSpeed P194 integer [1/min] optional

Table 3: Input parameters “Transmission/LossMap” per gear and for each grid point in the loss map

Parameter name Parameter Type Unit Description/Reference ID

InputSpeed P096 double, 2 [1/min]

InputTorque P097 double, 2 [Nm]

TorqueLoss P098 double, 2 [Nm]

Table 4: Input parameters “TorqueConverter/General”

Parameter name Parameter Type Unit Description/Reference ID

Manufacturer P210 token [-]

Model P211 token [-]

TechnicalReportId P212 token [-]

Date P213 dateTime [-] Date and time when the component-hash is created

AppVersion P214 string [-]

CertificationMethod P257 string [-] Allowed values: "Measured", "Standard values"

Table 5: Input parameters “TorqueConverter/Characteristics” for each grid point in the characteristic curve

Parameter name Parameter Type Unit Description/Reference ID

SpeedRatio P099 double, 4 [-]

TorqueRatio P100 double, 4 [-]

InputTorqueRef P101 double, 2 [Nm]

Table 6: Input parameters “Angledrive/General” (only required if component applicable)

Parameter name Parameter Type Unit Description/Reference ID

Manufacturer P220 token [-]

Model P221 token [-]

TechnicalReportId P222 token [-]

Date P223 dateTime [-] Date and time when the component-hash is created

AppVersion P224 string [-]

Ratio P176 double, 3 [-]

CertificationMethod P258 string [-] Allowed values: "Option 1", "Option 2", "Option 3", "Standard values"

Table 7: Input parameters “Angledrive/LossMap” for each grid point in the loss map (only required if component applicable)

Parameter name Parameter Type Unit Description/Reference ID

InputSpeed P173 double, 2 [1/min]

InputTorque P174 double, 2 [Nm]

TorqueLoss P175 double, 2 [Nm]

Table 8: Input parameters “Retarder/General” (only required if component applicable)

Parameter name Parameter Type Unit Description/Reference ID

Manufacturer P225 token [-]

Model P226 token [-]

TechnicalReportId P227 token [-]

Date P228 dateTime [-] Date and time when the component-hash is created

AppVersion P229 string [-]

CertificationMethod P255 string [-] Allowed values: "Measured", "Standard values"

Table 9: Input parameters “Retarder/LossMap” for each grid point in the characteristic curve (only required if component applicable)

Parameter name Parameter Type Unit Description/Reference ID

RetarderSpeed P057 double, 2 [1/min]

TorqueLoss P058 double, 2 [Nm]