Research on deviation coupling control of safety retractor of high bench cables for open pit mines

doi:10.16265/j.cnki.issn1003-3033.2023.S2.0023

Abstract

Abstract:

In order to optimize the cooperation and working accuracy of the internal motor assembly of the safety retractor of high bench cables used in open pit mines under a disturbed environment, a three-motor deviation coupling control method was proposed for the retractor. Firstly, a PI controller parameter setting model based on the SOA was constructed, with the ITEA as the objective function. Subsequently, the proposed method was compared with various algorithms by using three test functions, including Schaffer. Finally, three simulation models of permanent magnet synchronous motors (PMSMs) were built using MATLAB/Simulink, and the parameters were optimized through algorithms. The results show that the three-motor deviation coupling control method optimized by the SOA enables the motor assembly's speed to rapidly reach the set value with excellent stability. Moreover, even when disturbances are introduced, the motor assembly still exhibits good tracking and anti-interference capabilities. Additionally, this approach boasts advantages such as rapid convergence and lower error rates, providing robust support for the design and optimization of the safety retractor of high bench cables used in open pit mines.

Key words: retractor of high bench cables, deviation coupling control, seeker optimization algorithm (SOA), proportional-integral (PI) parameter setting, time multiplied by absolute error integration (ITAE)

CLC Number:

X948

LIU Lijie, ZHOU Yongli, TIAN Feng. Research on deviation coupling control of safety retractor of high bench cables for open pit mines[J]. China Safety Science Journal, 2023, 33(S2): 65-70.

Figures/Tables 8

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函数	算法	平均值	标准差
Schaffer	PSO	0.015 4	0.008 36
	GA	0.465	0.552
	SOA	0.0077 6	0.022 9
Rastrigin	PSO	4.608	3.419
	GA	1.012	0.6
	SOA	0.584	0.899
Sphere	PSO	278.8	121.734
	GA	1 320	1 930
	SOA	0.651	4.086