A LOAD DISTRIBUTION MODEL OF PLANETARY GEAR SETS

Hu, Yong, Hu

January 2017

No description available.

Mechanical Engineering

A Dynamic Load Distribution Model of Planetary Gear Sets

Ryali, Lokaditya

January 2021

No description available.

Aerospace Engineering

Mechanical Engineering

A Method for Systematic Design of Planetary Gear Meshes

Dharap, Gaurang Satish

January 2020

No description available.

Mechanical Engineering

Planetary Gear Sets

Mechanical Design

Run Many Cases

Optimization

An Experimental Study of Spin Power Losses of a High-Speed Gearbox

McDonald, Kyler

31 July 2018

No description available.

Mechanical Engineering

Gears

Planetary Gear Sets

High-Speed

Spin Power Loss

Experimental

Dynamic modeling and feedback control with mode-shifting of a two-mode electrically variable transmission

Katariya, Ashish Santosh

31 August 2012

This thesis develops dynamic models for the two-mode FWD EVT, develops a control system based on those models that is capable of meeting driver torque demands and performing synchronous mode shifts between different EVT modes while also accommodating preferred engine operating points. The two-input two-output transmission controller proposed herein incorporates motor-generator dynamics, is based on a general state-space integral control structure, and has feedback gains determined using linear quadratic regulator (LQR) optimization. Dynamic modeling of the vehicle is categorized as dynamic modeling of the mechanical and electrical subsystems where the mechanical subsystem consists of the planetary gear sets, the transmission and the engine whereas the electrical subsystem consists of the motor-generator units and the battery pack. A discussion of load torque is also considered as part of the mechanical subsystem. With the help of these derived dynamic models, a distinction is made between dynamic output torque and steady-state output torque. The overall control system consisting of multiple subsystems such as the human driver, power management unit (PMU), friction brakes, combustion engine, transmission control unit (TCU) and motor-generator units is designed. The logic for synchronous mode shifts between different EVT modes is also detailed as part of the control system design. Finally, the thesis presents results for responses in individual operating modes, EVT mode shifting and a full UDDS drive cycle simulation.

Hybrid electric vehicles

EVT-2

EVT-1

Two-mode EVT

Output torque

Motor-generator units

Battery pack

Supervisory controller

Transmission control

Planetary gear sets

Transmission

Engine

Load torque

Power balance

Powertrain

Power management

UDDS

Synchronous mode shifting

Drive cycle

Simulations

LQR

Hybrid electric cars

Prius automobile