Sen Transformer Differential Protection Scheme Based on Magnetic Circuit Coupling

doi:10.11930/j.issn.1004-9649.202311125

Abstract

Abstract:

As a power flow control device, Sen transformer changes the amplitude and phase of voltage and current at both ends of the access line through gear adjustment to achieve power flow regulation. However, due to its complex and compact wiring form and internal structure, Sen transformers have more complex fault characteristics than ordinary power transformers, which brings difficulties to their ontology protection configuration. In order to solve this problem, this paper analyzes the topology of Sen transformer and establishes a differential protection scheme based on physical principles such as Kirchhoff's current law and electromagnetic induction law. The scheme installs TA at the input end, output end of Sen transformer and the end section of the winding of the excitation unit, and by configuring the Sen transformer with balance differential protection and magnetic balance differential protection, it can reflect the turn-to-turn fault and turn-to-turn fault of each winding of Sen transformer, as well as the short circuit fault of the leads between the windings, which effectively solves the problem of difficult protection configuration for Sen transformer body. Finally, the PSCAD/EMTDC simulation platform is used to verify the feasibility of the proposed scheme, which provides a theoretical support for the subsequent in-depth research and engineering application of Sen transformer.

Key words: Sen transformer, magnetic balance differential protection, electric balance differential protection

Tao ZHENG, Jiaxu YU, Chengxi SUI, You SHEN, Yushi XUE, Jian WU. Sen Transformer Differential Protection Scheme Based on Magnetic Circuit Coupling[J]. Electric Power, 2025, 58(3): 108-118.

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URL: https://www.electricpower.com.cn/EN/10.11930/j.issn.1004-9649.202311125

https://www.electricpower.com.cn/EN/Y2025/V58/I3/108

Figures/Tables 21

References 26

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参数名称		数值
额定电压/kV		10.5
额定电流/kA		0.275
容量/(MV•A)		5
额定电压比/V		6062/2398
移相角/(°)		–20~+20
变压器短路阻抗/Ω		0.7718

参数名称		数值
额定电压/kV		10.5
额定电流/kA		0.275
容量/(MV•A)		5
额定电压比/V		6062/2398
移相角/(°)		–20~+20
变压器短路阻抗/Ω		0.7718

保护方式	参数	数值
电平衡差动保护	基准电流/kA	0.245
	可靠系数 $ {k_{{\text{rel}}}} $	1.2
	电流互感器同型系数 $ {K_{{\text{st}}}} $	0.5
	非周期分量系数 $ {K_{{\text{np}}}} $	2
	外部故障最大短路电流 $ {I_{{\text{k}}{\text{.max}}}} $(p.u.)	6.126
	动作电流整定值(p.u.)	0.735
磁平衡差动保护	基准电流/kA	0.275
	制动特性斜率 K	1
	最小动作电流 $ {I_{{\text{op}}{\text{.min}}}} $(p.u.)	0.5
	起始制动电流$ {I_{{\text{res}}{\text{.0}}}} $(p.u.)	0.8

保护方式	参数	数值
电平衡差动保护	基准电流/kA	0.245
	可靠系数 $ {k_{{\text{rel}}}} $	1.2
	电流互感器同型系数 $ {K_{{\text{st}}}} $	0.5
	非周期分量系数 $ {K_{{\text{np}}}} $	2
	外部故障最大短路电流 $ {I_{{\text{k}}{\text{.max}}}} $(p.u.)	6.126
	动作电流整定值(p.u.)	0.735
磁平衡差动保护	基准电流/kA	0.275
	制动特性斜率 K	1
	最小动作电流 $ {I_{{\text{op}}{\text{.min}}}} $(p.u.)	0.5
	起始制动电流$ {I_{{\text{res}}{\text{.0}}}} $(p.u.)	0.8

故障类型			电平衡差动KD1			磁平衡差动KD2
故障类型			差动电流(p.u.)	动作阈值(p.u.)	动作情况	动作电流(p.u.)	制动电流(p.u.)	动作情况
无故障			0	0.735	×	0	0.979	×
区外故障K1		两相短路	0	0.735	×	0	1.478	×
区外故障K1		三相短路	0	0.735	×	0	2.971	×
区内故障	调压单元引线K2	两相短路	5.816	0.735	√	0	1.584	×
	调压单元引线K2	三相短路	6.344	0.735	√	0	3.016	×
	励磁单元绕组K3	匝间50%	0	0.735	×	5.671	2.031	√
		匝间12.5%	0	0.735	×	4.436	1.893	√
		匝间10%	0	0.735	×	3.745	1.527	√
		匝间5%	0	0.735	×	2.473	1.011	√
		匝间3%	0	0.735	×	2.031	0.979	√
	调压单元绕组K4	匝间50%	0	0.735	×	5.402	1.981	√
		匝间12.5%	0	0.735	×	3.871	1.610	√
		匝间10%	0	0.735	×	3.497	1.401	√
		匝间5%	0	0.735	×	2.210	1.029	√
		匝间3%	0	0.735	×	1.980	0.979	√