В.А. Корсунский

14

Инженерный журнал: наука и инновации

# 7·2017

Analysis of double-flow transmissions and selection

of a rational design to be used in the flywheel energy

storage drive of a vehicle

© V.A. Korsunskiy

Bauman Moscow State Technical University, Moscow, 105005, Russia

Using the methodology suggested, we compared double-flow transmission designs with a

single three-link differential and a hydrostatic path that are to be used in the flywheel

energy storage drive of a vehicle equipped with a combined power plant comprising an

internal combustion engine and a secondary power source. We developed an algorithm

and calculated power flow parameters for a double-flow flywheel drive. We analysed

double-flow transmissions and selected a rational design to be implemented in a vehicle.

We estimated the effect that the operating speed range of a flywheel energy storage sys-

tem and the internal gear ratio of a three-link differential may have on the power trans-

mitted by a hydrostatic mechanical drive. We provide an assessment of how limiting the

gear ratio of a hydrostatic transmission may affect the power transmitted and the speed

range of a double-flow drive.

Keywords:

combined power plant, flywheel energy storage, hydromechanical drive, fly-

wheel, operating speed range, transmission, vehicle

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