Abstract
An important part of the overall task of social and economic development of many developed countries is the creation of a unique transport infrastructure or improvement of transport services for the population.
 The cumulative solution to many problems is to improve the quality and reliability of elements and equipment in any vehicle design. This determines its efficient operation and the safety of passengers.
 A common urban electric transport in megacities is a trolleybus, the reliability of which depends on individual components and assemblies, power supply systems and traffic control.
 But this type of transport requires modern scientific and technical solutions for the design of individual components and assemblies, for example, steering, which is directly related to the safe and comfortable transportation of passengers.
 An innovative technical solution has been proposed that will increase the energy efficiency of the trolleybus steering system through the use of an electric power steering based on a rolling rotor electric motor. The analysis of the design is carried out and the principle of control of the rolling rotor motor is determined. Functional diagrams of the components of the trolleybus steering system with an electric power steering based on a rolling rotor motor are developed. The electromagnetic and mechanical connections of the motor with the rolling rotor are determined and mathematically described. Factors affecting the steering system when turning the steered wheels are reasoned. A mathematical model of a trolleybus steering system with an electric booster based on an electric rolling rotor motor has been developed. The mathematical model is based on the differential equations of the electrical and mechanical parts. Algebraic equations were used to characterize the electromagnetic connections of the rolling rotor motor. The proposed solution will allow simulating dynamic processes in the trolleybus steering system and evaluating the results. Determination of the efficiency of the steering system was carried out by comparative analysis of the following factors: the control action created by the driver, the condition of the road surface, dynamic and transient electromechanical processes of the system, and the like
Highlights
In the modern world, the design of the rolling stock of urban electric transport, in particular trolleybuses, is constantly being improved
The aim of research is to develop a mathematical model of a trolleybus steering system using a steering amplifier based on a rolling rotor motor
To study the transient processes of the trolleybus steering system with an electric power steering based on a rolling rotor motor, a mathematical model has been developed
Summary
The design of the rolling stock of urban electric transport, in particular trolleybuses, is constantly being improved. They promote the rotation of the motor after it is turned off, and the continuation of the operation of the hydraulic pump to maintain the required pressure of the hydraulic booster [3, 4] This amount of equipment leads to an increase in the overall compartments of the trolleybus and constant driver control over its performance. The aim of research is to develop a mathematical model of a trolleybus steering system using a steering amplifier based on a rolling rotor motor. To study the transient processes of the trolleybus steering system with an electric power steering based on a rolling rotor motor, a mathematical model has been developed. The centrifugal force (11) and the variable component of gravity (12) act towards the minimum air gap [4,5,6]
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