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Effects of zinc on static and dynamic mechanical properties of copper-zinc alloy 被引量:1

Effects of zinc on static and dynamic mechanical properties of copper-zinc alloy
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摘要 The effects of adding alloy element zinc on the static and dynamic mechanical properties of copper-zinc alloy were investigated. Tensile and low cycle fatigue behaviors of the C11000 copper and H63 copper-zinc alloy were obtained by using a miniature tester that combined the functions of in situ tensile and fatigue testing. A piezoelectric actuator was adopted as the actuator for the fatigue testing, and the feasibility of the fatigue actuator was verified by the transient harmonic response analysis based on static tensile preload and dynamic sinusoidal load. The experimental results show that the yield strength and tensile strength of the C11000 copper are improved after adding 37%(mass fraction) zinc, and H63 copper-zinc alloy presents more obvious cyclic hardening behavior and more consumed irreversible plastic work during each stress cycle compared with C11000 copper for the same strain controlled cycling. Additionally, based on the Manson-Coffin theory, the strain-life equations of the two materials were also obtained. C11000 copper and H63 copper-zinc alloy show transition life of 16832 and 1788 cycles, respectively. The effects of adding alloy element zinc on the static and dynamic mechanical properties of copper-zinc alloy were investigated. Tensile and low cycle fatigue behaviors of the C11000 copper and H63 copper-zinc alloy were obtained by using a miniature tester that combined the functions of in situ tensile and fatigue testing. A piezoelectric actuator was adopted as the actuator for the fatigue testing, and the feasibility of the fatigue actuator was verified by the transient harmonic response analysis based on static tensile preload and dynamic sinusoidal load. The experimental results show that the yield strength and tensile strength of the C11000 copper are improved after adding 37%(mass fraction) zinc, and H63 copper-zinc alloy presents more obvious cyclic hardening behavior and more consumed irreversible plastic work during each stress cycle compared with C11000 copper for the same strain controlled cycling. Additionally, based on the Manson-Coffin theory, the strain-life equations of the two materials were also obtained. C11000 copper and H63 copper-zinc alloy show transition life of 16832 and 1788 cycles, respectively.
出处 《Journal of Central South University》 SCIE EI CAS CSCD 2015年第7期2440-2445,共6页 中南大学学报(英文版)
基金 Projects(51275198,51422503)supported by the National Natural Science Foundation of China Project(2012YQ030075)supported by Special Funds for Development of National Major Scientific Instruments and Equipments,China Project(NECT-12-0238)supported by Program for New Century Excellent Talents in University,China Project(20150520108JH)supported by Young Scientist Fund of Jilin Province of China
关键词 tensile behavior low cycle fatigue copper alloy in situ test piezoelectric actuator 动态力学性能 铜锌合金 低周疲劳性能 瞬态响应分析 抗拉强度 压电作动器 合金元素 疲劳测试
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