A Classical Design Approach of Cascaded Controllers for a Traction Elevator

American Journal of Engineering and Applied Sciences Pub Date : 2023-03-01 DOI:10.3844/ajeassp.2023.92.105

Uko Victor Sorochi, Kamalu Ugochukwu Anamelechi, Nwokocha Doris Adaugo, Uko Ebenezer Ugochukwu

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Abstract

A traction elevator is a control system that can be driven by Direct Current (DC) motors. Premised on the reviewed literature, operations of control systems incorporated with DC motors are restrained by nonlinearities that deviate the controlled variables (position, speed, and torque) from the reference input. Controllers designed with appropriate gains annul the nonlinearities inhibiting the operation of a traction elevator. However, the literature did not account for detailed mathematical designs for the controller gains. Also, the modeled elevators had complex architectures. Hence, this research is aimed at modeling a simplified traction elevator and using the dynamics of its subsumes to mathematically design the gains of three controllers arranged in a cascaded topology to mitigate errors in the three control loops of the elevator. The Position of the elevator's car was controlled using a Proportional (P) controller while the Proportional-Integral (PI) controller controlled individually the speed and torque of the elevator’s cabin. A novel objective function which was based on Integral Time Absolute Error (ITAE) was incorporated into the elevator’s model to measure the deviation of the control variables from the input reference. The MATLAB Simulink environment was used in the modeling and simulation of the elevator system. The result obtained for the gain of the P controller for the elevator position, speed, and torque were 0.3652, 25.8, and 2.19, respectively. The gains of the integral controllers for the elevator speed and torque were 1372.3 and 219 respectively. A position reference of 100 m was used to verify the utilization of the controller gains. The result of the study improved existing literature because of the clarified elevator model and the output responses of the three controlled loops which were intuitive with lesser errors at steady state. For instance, steady-state errors of 3.54, 10.45, and 5% were obtained respectively in the position, speed, and current responses of the modeled elevator.

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牵引电梯级联控制器的经典设计方法

牵引电梯是一种由直流电机驱动的控制系统。根据所回顾的文献，与直流电机结合的控制系统的操作受到偏离参考输入的受控变量(位置，速度和转矩)的非线性的限制。采用适当增益设计的控制器消除了牵引力电梯运行中的非线性抑制。然而，文献没有说明控制器增益的详细数学设计。此外，模拟的电梯结构复杂。因此，本研究旨在对一个简化的牵引电梯进行建模，并利用其包含的动力学来数学地设计以级联拓扑排列的三个控制器的增益，以减轻电梯三个控制回路的误差。电梯轿厢的位置由比例(P)控制器控制，而比例积分(PI)控制器分别控制电梯轿厢的速度和扭矩。在电梯模型中引入一种基于积分时间绝对误差(ITAE)的目标函数来测量控制变量与输入参考的偏差。利用MATLAB Simulink环境对电梯系统进行建模与仿真。P控制器对电梯位置、速度和转矩的增益分别为0.3652、25.8和2.19。整体控制器对电梯速度和转矩的增益分别为1372.3和219。利用100 m的位置参考来验证控制器增益的利用。研究结果改进了现有文献，使升降机模型更清晰，三个被控回路的输出响应更直观，稳态误差更小。例如，模拟电梯的位置响应、速度响应和电流响应的稳态误差分别为3.54%、10.45%和5%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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American Journal of Engineering and Applied Sciences

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