Preface
Page: ii-ii (1)
Author: Mikhail Pustovetov, Konstantin Shukhmin, Sergey Goolak, Jonas Matijošius and Kateryna Kravchenko
DOI: 10.2174/9789815124309123010002
A Use of Nonlinear Coefficients in Ordinary Differential Equations of Mathematical Models of Electrical Devices Describing Inductance vs Current or Magnetic Flux Linkage Relationships
Page: 1-9 (9)
Author: Mikhail Pustovetov* and Konstantin Shukhmin
DOI: 10.2174/9789815124309123010004
PDF Price: $15
Abstract
When mathematical models of electromagnetic devices are described by
ordinary differential equations, then the magnetization curves of their cores are often
expressed with a help of nonlinear coefficients. Sometimes such an approach is
considered questionable, and therefore, the purpose of this chapter is to prove its
admissibility.
Approximate Calculations of Induction Motor Equivalent T-Shaped Circuit Parameters with the Use of Catalogue Data
Page: 10-23 (14)
Author: Mikhail Pustovetov*, Konstantin Shukhmin, Sergey Goolak, Jonas Matijošius and Kateryna Kravchenko
DOI: 10.2174/9789815124309123010005
PDF Price: $15
Abstract
This chapter is dedicated to an algorithm of approximate calculations of
three-phase induction motor equivalent T-shaped circuit parameters such as resistances
and inductances. These calculations are conducted with the use of catalog or reference
book data containing information related to rated shaft power, angular speed or slip,
efficiency, power factor, line RMS voltage and the ratio of starting to rated currents.
The Shaft Load Simulations and Calculations of the IM Efficiency Using OrCAD PSpice Designer Software: Obtaining Static Characteristics Data Based on Dynamic Model Modifications of Electrical Machines
Page: 24-35 (12)
Author: Mikhail Pustovetov*, Konstantin Shukhmin, Sergey Goolak, Jonas Matijošius and Kateryna Kravchenko
DOI: 10.2174/9789815124309123010006
PDF Price: $15
Abstract
In this chapter, authors suggest an approach to the shaft load simulations and
calculations of the electrical machine efficiency with the use of OrCAD PSpice
Designer Software, and in particular, visual programming of analogue component
blocks. Also, a method for modifying the EM dynamic model is put forward. This
method enables researchers and designers to acquire data for plotting static mechanical,
electromechanical and performance curves vs the angular speed of the rotor. These data
are obtained by modifications to the block-diagram of the motion equation of the drive
where the instantaneous values of the electromagnetic torque of the motor and the load
torque are equal by absolute values and opposite to each direction.
Computer Simulation of Electric Drive with Induction Motor and Fluid Coupling
Page: 36-45 (10)
Author: Mikhail Pustovetov*, Konstantin Shukhmin, Sergey Goolak, Jonas Matijošius and Kateryna Kravchenko
DOI: 10.2174/9789815124309123010007
PDF Price: $15
Abstract
A new approach to the shaft load simulation with the different types of fluid
coupling is introduced herein. The presented simulation results are obtained for an
electrohydrodynamic drive at different load modes and types of fluid coupling such as:
with constant filling; static self-emptying (traction fluid coupling) and dynamic self-emptying (limiting fluid coupling). The chapter also provides an example of fluid
coupling parameters and characteristics as well as depicts the following operation
modes of the system: acceleration; no-load; load and overload on the turbine shaft.
An Improvement of the Induction Traction Motor's Mathematical Model at Asymmetry of Stator Windings
Page: 46-77 (32)
Author: Sergey Goolak*
DOI: 10.2174/9789815124309123010008
PDF Price: $15
Abstract
The author proposes an improved version of the mathematical and computer
model of a three-phase induction motor in the three-phase braked coordinates (in the
three-phase stator reference frame), which proves the correctness of the starter winding
asymmetry considerations in electrical machines. The chapter presents the parameters
and characteristics of an induction traction motor type STA-1200 manufactured in
Ukraine. A comparative analysis of the simulation results for intact and damaged
motors has been carried out.
Selected Information of the Auxiliary Electric Drive of an AC Electric Locomotive, Comprising Three-Phase Induction Motors, a Capacitive Phase Splitter and a Thyristor Frequency and Number of Phase Converted
Page: 78-91 (14)
Author: Mikhail Pustovetov*, Konstantin Shukhmin, Sergey Goolak, Jonas Matijošius and Kateryna Kravchenko
DOI: 10.2174/9789815124309123010009
PDF Price: $15
Abstract
This chapter provides an electrical schematic diagram of the power circuits
of an auxiliary electric drive with a capacitive phase splitter and 3-phase induction
motors onboard of an AC electric locomotive and the statistics and root causes of
typical failures of the induction motors operating as part of such a circuit. A conclusion
is made about the expediency of simulating thermal processes in the auxiliary induction
motors.
Starting Mode Computer Simulation of Auxiliary Induction Motor Onboard of an AC Electrical Locomotive Equipped with a Capacitive Phase Splitter
Page: 92-114 (23)
Author: Mikhail Pustovetov* and Konstantin Shukhmin
DOI: 10.2174/9789815124309123010010
PDF Price: $15
Abstract
This chapter discusses the start-up simulation results of auxiliary drives of
fan and piston-type air-compressor driven by three-phase induction motors. The
computer model described in this chapter simulates a relay-contactor type system of
auxiliary machines powered from the secondary winding of the traction transformer
through the capacitive phase-splitter. The authors make an analytical comparison of the
start-up process at different values of the grid voltages. Comparative assessments of the
simulation-based and experimental oscillograms of voltages, currents and the rotational
speed of the motor-fan and motor compressor during the start-up process are described.
Mathematical Modeling of Thermal Processes in an Auxiliary Three-Phase Induction Motor of an Electric Locomotive with Unbalanced Supply Voltages and Squirrel-Cage Defects
Page: 115-177 (63)
Author: Mikhail Pustovetov* and Konstantin Shukhmin
DOI: 10.2174/9789815124309123010011
PDF Price: $15
Abstract
This chapter is dedicated to the consideration of the possibility of building a
thermal computer model of an induction electric machine with a squirrel-cage rotor.
The thermal model is considered as an add-on to the computer model that describes
electrical and mechanical phenomena of the IM. Both models are included in a single
OrCAD project. The structure and components of the developed thermal model are
described. The thermal processes modeling results in an induction motor type NVA-55
as part of an auxiliary electric drive of a freight electrical locomotive are presented taking into account the unbalanced supply voltages and squirrel-cage defects.
Subject Index
Page: 178-181 (4)
Author: Mikhail Pustovetov, Konstantin Shukhmin, Sergey Goolak, Jonas Matijošius and Kateryna Kravchenko
DOI: 10.2174/9789815124309123010012
Introduction
This book is a compilation of knowledge about computer models in the three-phase stator reference frame. Chapters explore several aspects of the topic and build upon research previously presented by contributors. The book aims to provide interesting solutions to problems encountered in the design of railway and analysis in railway motors. The modeling approaches proposed by the authors in this book may become an incentive for readers and researchers to develop their ‘lifehacks’ to solve new problems in induction motor design and testing. Key topics presented in the book: - Approximate calculations of induction motor equivalent T-shaped circuit parameters with the use of catalogue data - Simulations of different types of shaft load, including fluid coupling - Receiving static characteristics of an electric machine during simulation by means of dynamic model - Simulation of the electric drive’s specific applications with three-phase induction motors building - Direct start of an induction motor as part of an auxiliary drive of an AC electric locomotive, containing a capacitor phase splitter, starting with different types of shaft loads (fan or compressor). Special attention has been given to the description of the thermal model of an induction motor with a squirrel-cage rotor, which makes it possible to simulate operating modes when powered by an unbalanced voltage, as well as with squirrel cage defects. The thermal model is presented as a detailed superstructure to the model of electromechanical processes of an induction electric machine. Other key features of the book include references for further reading, an appendix for the parameters of the equivalent thermal circuit of an NVA-55 induction motor. The material presented in the book is of interest to railway motor engineers, specialists in electromechanics and electric drives who use SPICE-compatible CAD applications in their work.