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直流小型断路器触头分离金属液桥过程研究OA

Research on Metal Liquid Bridge During Contact Separation in DC Miniature Circuit Breaker

中文摘要英文摘要

为明确直流小型断路器(MCB)触头分离过程中金属液桥演化规律及双液桥诱发机理,搭建含高倍电子显微镜的慢速断开实验平台,以Cu及CuCr0.5合金为触头材料,在直流13 V负载下,系统研究16~22 A电流、0.4~1.0 mm/s分断速度下的金属液桥特性,同步采集几何参数与电压波形数据.研究表明,液桥演化呈加热熔化、稳定存在、破裂不稳定3个阶段,稳定态为圆柱形,断裂后阴极形成针尖状残余,材料从阳极定向迁移;液桥尺寸随电流增大而增加、随分断速度提升而减小,电流增加易出现双液桥且断裂易引发电弧;CuCr0.5合金触头完全抑制双液桥现象,抗液桥与抗电弧性能显著优于纯Cu.

To clarify the evolution law of metallic liquid bridges and the inducing mechanism of double liquid bridges during the contact separation process of DC miniature circuit breakers(MCB),a slow-breaking experimental platform equipped with a high-power electron microscope is established.Taking copper(Cu)and CuCr0.5 alloy as contact materials,the characteristics of metallic liquid bridges are systematically investigated under the conditions of DC 13 V load,current ranging from 16 A to 22 A,and breaking speed between 0.4 mm/s and 1.0 mm/s,with the synchronous collection of geometric parameters and waveform data.The results show that the evolution of liquid bridges undergoes three stages:heating and melting,stable existence,and unstable rupture.The stable liquid bridge presents a cylindrical shape;after rupture,a needle-shaped residue forms on the cathode,and the material migrates directionally from the anode to the cathode.The size of liquid bridges increases with the rise of current and decreases with the increase of breaking speed.An increase in current tends to induce double liquid bridges,and their rupture is prone to trigger arc discharge.The CuCr0.5 alloy contacts completely suppress the occurrence of double liquid bridges,exhibiting significantly superior resistance to liquid bridges and arc discharge compared with pure copper contacts.

薛渊;李静;段薇;黄翀阳;付思

沈阳工业大学电器新技术与应用研究所,辽宁沈阳 110870沈阳工业大学电器新技术与应用研究所,辽宁沈阳 110870沈阳工业大学电器新技术与应用研究所,辽宁沈阳 110870沈阳工业大学电器新技术与应用研究所,辽宁沈阳 110870沈阳工业大学电器新技术与应用研究所,辽宁沈阳 110870

信息技术与安全科学

直流小型断路器金属液桥慢速断开CuCr0.5合金双液桥

DC miniature circuit breakermetallic liquid bridgeslow breakingCuCr0.5 alloydouble liquid bridge

《电器与能效管理技术》 2026 (4)

1-7,7

国家自然科学基金(51407120)辽宁省科技计划联合计划(技术攻关计划项目)(2024JH2/102600224)辽宁省科技计划联合计划(自然科学基金-面上项目)(2024-MSLH-366)

10.16628/j.cnki.2095-8188.2026.04.001

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