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Kinematic Foundations of Scientific Classification of Gearing Read chapter Read first chapter

2022 | OriginalPaper | Chapter

8. Optimal Selection of the Structural Scheme of Compound Two-Carrier Planetary Gear Trains and Their Parameters

Authors : Dimitar P. Karaivanov, Sanjin Troha

Published in: Recent Advances in Gearing

Publisher: Springer International Publishing

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Abstract

The Torque Method is an easy way for kinematic and power analysis of planetary gear trains, both simple and compound ones. Moreover it gives possibility of optimal choice of a structural scheme (and its parameters) of compound planetary gear trains.
In this chapter most common ways of optimization of planetary gear trains are overviewed. Appropriate optimization criteria of the most common simple planetary gear train (with one external and one internal meshing) are discussed. Multi-objective choice of structural scheme and its parameters of two-carrier planetary gear trains is proposed. Two-carrier planetary gear trains with three and four external shafts are considered. The choice is made between all possible structural schemes of planetary gear trains in question through the torque method.

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previous chapter Hyperboloid-Type Hobs: Design, Manufacture, and Application
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Appendix
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Footnotes
1
At the end of the twentieth century, there was a tendency toward dismissing the optimization methods with weight coefficients as subjective. Modern computer technology with its advanced dialogue mode enables the rapid simulation of different variants (with different weight coefficients) and renders these methods more flexible and suitable for various tasks, which definitely compensates the shortcomings of subjectivism and even turns it into advantage.
 
2
Equivalent efficiency is calculated for two-speed PGTs on the base of efficiencies in work with both speeds (i1 and i2) considering relative working time of each of them.
 
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Metadata
Title
Optimal Selection of the Structural Scheme of Compound Two-Carrier Planetary Gear Trains and Their Parameters
Authors
Dimitar P. Karaivanov
Sanjin Troha
Copyright Year
2022
Book
Recent Advances in Gearing

Print ISBN: 978-3-030-64637-0

Electronic ISBN: 978-3-030-64638-7

Copyright Year: 2022

DOI
https://doi.org/10.1007/978-3-030-64638-7_8

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