Design of an Electromechanical Ratio and Clamping

Slide 1:Design of an Electromechanical Ratio and Clamping Force Actuator for a Metal V-belt Type CVT

Koen van de Meerakker, Nick Rosielle, Bram Bonsen, Tim Klaassen Technische Universiteit Eindhoven

Slide 2:Related sessions

Low level control of CVT�s 1 (4) Bram Bonsen Low level control of CVT�s 2 (13) Tim Klaassen (49) Bram Veenhuizen Theory in CVT applications (3) Bram Bonsen

Slide 3:Belt CVT basics

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Slide 4:Variator actuation tasks

Sheave position -> Transmission ratio Belt clamping force 4

Slide 5:Typical CVT layout

Slide 6:CVT driveline efficiency

With CVT, efficient IC engine use 6

Slide 7:However: Car with MT often more fuel-efficient Power loss in CVT

Slide 8:Power loss sources

Bearings, gears, seals Torque converter Variator efficiency Hydraulic actuation 8

Slide 9:Actuation power loss

Pump efficiency Superfluous oil flow Leak -> larger pump Overclamping -> high oil pressure 9

Slide 10:Variator actuation alternatives

Two stage pump Electro-hydraulics Electromechanical actuation

Slide 11:EMconcept

Slide 13:EMconcept

Slide 14:Prototype approach

Modification of existing transmission Actuators only in and on new outer cover Separate electric oil pump for accessories

Slide 19:

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Slide 23:Features

Pri-sec mechanisms on same transmission side Energy exchange pri-sec Separate ratio and clamping force motors No adjustment = no thrust bearing or el. motor rotation Electric motors outside transmission housing Stiff in comparison to low pressure hydraulics 23

Slide 24:Next

- Prototype assembly - Assessment on test rig Assessment in Vehicle Redesign of research proto 24 Picture: Audi AG

Slide 25:Conclusions

Efficiency potential EM actuation proposed Prototype evaluation coming soon