Research on Secondary Cable Wiring Across Switchgear Door Based on Arc-Shaped Buffer Transition

doi:10.16628/j.cnki.2095-8188.2025.07.003

Abstract

Abstract:

The mechanical fatigue issue of door-crossing secondary cables during the opening and closing of instrument compartment doors is addressed by proposing an optimized wiring scheme based on an arc-shaped buffer transition.By increasing the reserved length of door-crossing cables and implementing pre-bending treatment, a arc-shaped flexible structure is constructed, achieving a 20% reduction in tensile strain and a 34% decrease in stress concentration values during cable movement.Cable harness flexibility is effectively enhanced and insulation layer lifespan is extended.Simulation experiments and prototype verification results demonstrate that the proposed solution significantly improves the uniformity of strain distribution in cable harnesses, providing both theoretical foundations and practical guidance for ensuring the reliable operation of intelligent switchgear.

Key words: switchgear instrument compartment, secondary cable, arc-shaped buffer transition, mechanical fatigue, wiring optimization

CLC Number:

TM591

JIN Tianran, CAI Ning, XUE Huan, DAI Dongyun, WANG Fumin. Research on Secondary Cable Wiring Across Switchgear Door Based on Arc-Shaped Buffer Transition[J]. LOW VOLTAGE APPARATUS, 2025, 0(7): 18-24.

Figures/Tables 16

References 18

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功能划分	线缆横截面积/mm²	电缆类型
计量(电压)	2.5	单芯铜导线
计量(电流)	4.0	单芯铜导线
装置电源	2.5	黑色多股软铜导线
控制、信号回路	2.5	黑色多股软铜导线
通信回路	2.0×1.0	屏蔽双绞线
接地线	4.0	黄绿多股软铜导线

过门方式	最大应力集中值/MPa	拉伸应变ε	疲劳寿命/次
直接过门	4.50	0.020	32 000
弧形缓冲过渡过门	2.86	0.016	50 000+

对比项	直接过门布线	编织套管保护过门	本文方案
单柜布线人工工时/h	2.5	3.8	2.7
电缆相关物料成本	基准值	+12%	+5%