微型试样高温蠕变试验系统设计
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摘要
本文对国内外蠕变试验技术研究的发展作了全面的回顾,着重对微型试样蠕变试验方法进行了研究。在此基础上,对一台老式蠕变试验机进行了改造;对电流加热进行蠕变试验的可行性进行了多方面研究与论证;针对改造后的蠕变试验机,设计了一种板状蠕变微型试样;首次采用了电流加热的方式对12Cr1MoV微型试样进行了初步的蠕变试验。研究结果表明:
1.微型试样高温蠕变试验能够合理地反映出材料蠕变过程和蠕变规律,试验数据稳定;
2.蠕变试验过程中采用电流加热的方式,不仅降低了试验设备的结构复杂性和劳动强度,而且加热速度容易控制,热能利用率高,大大缩短试验周期,较电炉加热方式节省能量消耗约为59%,具有很高的经济价值。
Based on the sum-up of the research history and latest development of creep test technology, a new creep test method, namely minitype specimen creep testing method, is investigated in this paper. Design of minitype specimen, research of current heating method and design of minitype specimen creep test device are emphases of this paper. Creep test of 12Cr1MoV steel by this method proved that the method is feasible and available. Results of the research prove the following:
1. Minitype specimen high temperature creep test can reflect the course and rule of creep, and test data are stable.
2. Using the method of current heating in the course of creep, there are many excellences as following: Complexity of creep test device can be minished. Labor intension is weakening, speed of heating is easy to control. Period of test is reduced. Current heating method is economic than traditional heating method about 59%.
1.微型试样高温蠕变试验能够合理地反映出材料蠕变过程和蠕变规律,试验数据稳定;
2.蠕变试验过程中采用电流加热的方式,不仅降低了试验设备的结构复杂性和劳动强度,而且加热速度容易控制,热能利用率高,大大缩短试验周期,较电炉加热方式节省能量消耗约为59%,具有很高的经济价值。
Based on the sum-up of the research history and latest development of creep test technology, a new creep test method, namely minitype specimen creep testing method, is investigated in this paper. Design of minitype specimen, research of current heating method and design of minitype specimen creep test device are emphases of this paper. Creep test of 12Cr1MoV steel by this method proved that the method is feasible and available. Results of the research prove the following:
1. Minitype specimen high temperature creep test can reflect the course and rule of creep, and test data are stable.
2. Using the method of current heating in the course of creep, there are many excellences as following: Complexity of creep test device can be minished. Labor intension is weakening, speed of heating is easy to control. Period of test is reduced. Current heating method is economic than traditional heating method about 59%.
引文
[1] 郑修麟.材料的力学性能.西安:西北工业大学出版社,1991
[2] 穆霞英.蠕变力学.西安:西安交通大学出版社,1990
[3] 魏文光.金属力学性能测试.北京:科学出版社,1980
[4] 平修二(日).会属材料的高温强度理论、设计.北京:科学出版社 1983
[5] 张义同等.岛津试验机高温剪切蠕变试验装置的研制与试验研究.试验力学,1993.12(4):384
[6] 杨挺青.材料与结构蠕变研究近况.力学进展.2200.5
[7] 四川五局《金属材料机械性能试验》编写组.金属材料机械性能试验.北京:国防工业出版社,1983
[8] 纪延光.高温构件蠕变试验炉的研制.淮海工学院学报。1996.9
[9] 吴志涛,沈智慧,周罗轩.持久、蠕变试验机集散温控系统.株洲工学院学报.1994.9
[10] 徐梅泉,何伟康,朱月梅等.蠕变试验室的技术改造.理化检验-物理分册.2004.4
[11] 张赤心.金属机械性能的微型试验法.武汉:华中工学院出版社,1985
[12] B.Ule, T.Sustar, F.Dobes.Samll punch test method assessment for the determination of the residual creep life of service exposed components.nuclear engineering and design 192(1999) 1-11.
[13] 杨镇,王志文.蠕变现象的小冲杆试验研究—蠕变应力分析.试验研究.2002.9
[14] You Zhou, Kiyoushi Hirao. Effects of heating rate and particle size on pulse electic current sintering of alumina. Scripta materialia. 48(2003) 1631-1636
[15] T.A.Stuart, A.Hande. HEV battery heating using AC currents. Journal of Power Sources. 129 (2004) 368-378
[16] 王国韬,谢惠民,戴福隆.大电流快速加热条件下LY12铝板动态变形的云纹干涉法实验研究.试验力学.1997.9
[17] 周亦胄,郭敬东.脉冲电流对低碳微合金钢力学性能的影响.材料研究学报.2002.6
[18] 束得林.金属力学性能.北京:机械工业出版社,1987
[19] 黄明志,石得珂,金志浩.金属力学性能.西安:西安交通大学出版社,1986
[20] 哈宽富.金属力学性质的微观理论.北京:科学出版社,1983
[21] 杨宜科,吴天禄,江先美,朱景鹏等.金属高温强度及试验.上海:上海科学技术出版社,1986
[22] [美] E.R.G埃克特,R.J.戈尔茨坦.传热学测试方法.北京:国防工业出版社,1987
[23] 杨厚君,李正刚,林介东.电阻法在金属材料蠕变损伤检测中的应用.武汉水利电力大学学报,1999.12
[24] Blum W, Reppich B. Creep of particle-strengthened alloys. Creep Behavior of Crystalline Solids, 1985.83-135
[25] W.D.Nix, H.Gao, Indentation Size Effects in Crystalline Materials: A Law for Strain Gradient Plasticity
[26] 姚启均.会属力学性能试验常用数据手册.北京:机械工业出版社,1994
[27] 何肇基.金属的力学性质.北京:冶金工业出版社,1982
[28] 王启平.机床央具设计基础.哈尔滨:哈尔滨工业大学出版社,1996
[29] 会尧,孙训方等.考虑加载历史影响的蠕变律.机械强度.2001,23(2):206~208
[30] 范慕辉,李松年.蠕变分析的有限元方法.河北工学院学报.1995.4
[31] 孔宪仁,王本利,胡劲东.高温高压阀体的有限元分析.哈尔滨工业大学学报.1994.8
[32] ANSYS. inc., ANSYS mechanical analysis guide, ANSYS, inc., 1999
[33] ANSYS. inc., ANSYS nonlinear analysis guide, ANSYS, inc., 1999
[34] 陈国良,郭宏,孙继跃等.耐热钢12CrlMoV蠕变性能的描述和外推.北京科技大学学报.1997.4
[35] 金尧,孙亚芳,邓勇等.金属蠕变律及蠕变行为研究.材料工程.2000.11
[36] 上海锅炉厂.热强钢高温性能数据集.上海:上海人民出版社,1975.1
[37] Z.F.Yue, G.Eggeler, a creep finite element analysis of indentation creep testing in two phase microstructures. Computational materials science.21 (2001)37-56
[38] J.Cadek, V.Sustek, M.Pahutova. An analysis of a set of creep data for a 9Cr-1Mo-0.2V steel. Materials science and engineering.A225(1997)22-28
[39] 李静,周健龙,李春凤等.30Cr1MoV钢蠕变性能研究.理化检验-物理分册.2000.1
[40] Orlova. A, Bursik J, Kucharova K.Microsructural stability of creep resistant alloys for high temperature plant applications. London: the institute of materials, 1998. P.89-106
[41] J.Cadek. Creep in Metallic materials, Elsevier Amsterdam, 1988.P.90.
[42] A.A.Becker, T.H.Hyde, L.Xia.Numerical analysis of creep in components, J.Strain Analysis 29(3) (1994) 27-34
[43] 王国韬,谢惠民,戴福隆.大电流快速加热条件下LY12铝板动态变形的云纹干涉法试验研究.试验力学.1997.9
[44] 卢锦凤,许峰等.电器在恒电压、恒电流、恒功率加热方式下的温升数学模型.机电元件.1997.6
[45] 王武义,徐定杰,陈健翼.误差原理与数据处理.哈尔滨:哈尔滨工业大学出版社.2001.10
[46] 张韵华,奚梅成,陈长松.数值计算方法和算法.北京:科学出版社.2000.1
[47] 刘惠彬,刘玉刚.测试技术.北京:北京航空航天大学出版社.1989.6
[48] 李久林,梁新邦.GB/T2039—1997金属拉伸蠕变及持久试验方法国家标准编制说明.冶金标准化与质量.1998.3
[49] 《金相图谱》编写组.金相图谱.北京:水利水电出版社.1986.4
[50] 杨瑞成,王晖,郑丽平.12Cr1MoV钢高温长时加热过程中基体成分的变化.金属热处理.2002.4
[2] 穆霞英.蠕变力学.西安:西安交通大学出版社,1990
[3] 魏文光.金属力学性能测试.北京:科学出版社,1980
[4] 平修二(日).会属材料的高温强度理论、设计.北京:科学出版社 1983
[5] 张义同等.岛津试验机高温剪切蠕变试验装置的研制与试验研究.试验力学,1993.12(4):384
[6] 杨挺青.材料与结构蠕变研究近况.力学进展.2200.5
[7] 四川五局《金属材料机械性能试验》编写组.金属材料机械性能试验.北京:国防工业出版社,1983
[8] 纪延光.高温构件蠕变试验炉的研制.淮海工学院学报。1996.9
[9] 吴志涛,沈智慧,周罗轩.持久、蠕变试验机集散温控系统.株洲工学院学报.1994.9
[10] 徐梅泉,何伟康,朱月梅等.蠕变试验室的技术改造.理化检验-物理分册.2004.4
[11] 张赤心.金属机械性能的微型试验法.武汉:华中工学院出版社,1985
[12] B.Ule, T.Sustar, F.Dobes.Samll punch test method assessment for the determination of the residual creep life of service exposed components.nuclear engineering and design 192(1999) 1-11.
[13] 杨镇,王志文.蠕变现象的小冲杆试验研究—蠕变应力分析.试验研究.2002.9
[14] You Zhou, Kiyoushi Hirao. Effects of heating rate and particle size on pulse electic current sintering of alumina. Scripta materialia. 48(2003) 1631-1636
[15] T.A.Stuart, A.Hande. HEV battery heating using AC currents. Journal of Power Sources. 129 (2004) 368-378
[16] 王国韬,谢惠民,戴福隆.大电流快速加热条件下LY12铝板动态变形的云纹干涉法实验研究.试验力学.1997.9
[17] 周亦胄,郭敬东.脉冲电流对低碳微合金钢力学性能的影响.材料研究学报.2002.6
[18] 束得林.金属力学性能.北京:机械工业出版社,1987
[19] 黄明志,石得珂,金志浩.金属力学性能.西安:西安交通大学出版社,1986
[20] 哈宽富.金属力学性质的微观理论.北京:科学出版社,1983
[21] 杨宜科,吴天禄,江先美,朱景鹏等.金属高温强度及试验.上海:上海科学技术出版社,1986
[22] [美] E.R.G埃克特,R.J.戈尔茨坦.传热学测试方法.北京:国防工业出版社,1987
[23] 杨厚君,李正刚,林介东.电阻法在金属材料蠕变损伤检测中的应用.武汉水利电力大学学报,1999.12
[24] Blum W, Reppich B. Creep of particle-strengthened alloys. Creep Behavior of Crystalline Solids, 1985.83-135
[25] W.D.Nix, H.Gao, Indentation Size Effects in Crystalline Materials: A Law for Strain Gradient Plasticity
[26] 姚启均.会属力学性能试验常用数据手册.北京:机械工业出版社,1994
[27] 何肇基.金属的力学性质.北京:冶金工业出版社,1982
[28] 王启平.机床央具设计基础.哈尔滨:哈尔滨工业大学出版社,1996
[29] 会尧,孙训方等.考虑加载历史影响的蠕变律.机械强度.2001,23(2):206~208
[30] 范慕辉,李松年.蠕变分析的有限元方法.河北工学院学报.1995.4
[31] 孔宪仁,王本利,胡劲东.高温高压阀体的有限元分析.哈尔滨工业大学学报.1994.8
[32] ANSYS. inc., ANSYS mechanical analysis guide, ANSYS, inc., 1999
[33] ANSYS. inc., ANSYS nonlinear analysis guide, ANSYS, inc., 1999
[34] 陈国良,郭宏,孙继跃等.耐热钢12CrlMoV蠕变性能的描述和外推.北京科技大学学报.1997.4
[35] 金尧,孙亚芳,邓勇等.金属蠕变律及蠕变行为研究.材料工程.2000.11
[36] 上海锅炉厂.热强钢高温性能数据集.上海:上海人民出版社,1975.1
[37] Z.F.Yue, G.Eggeler, a creep finite element analysis of indentation creep testing in two phase microstructures. Computational materials science.21 (2001)37-56
[38] J.Cadek, V.Sustek, M.Pahutova. An analysis of a set of creep data for a 9Cr-1Mo-0.2V steel. Materials science and engineering.A225(1997)22-28
[39] 李静,周健龙,李春凤等.30Cr1MoV钢蠕变性能研究.理化检验-物理分册.2000.1
[40] Orlova. A, Bursik J, Kucharova K.Microsructural stability of creep resistant alloys for high temperature plant applications. London: the institute of materials, 1998. P.89-106
[41] J.Cadek. Creep in Metallic materials, Elsevier Amsterdam, 1988.P.90.
[42] A.A.Becker, T.H.Hyde, L.Xia.Numerical analysis of creep in components, J.Strain Analysis 29(3) (1994) 27-34
[43] 王国韬,谢惠民,戴福隆.大电流快速加热条件下LY12铝板动态变形的云纹干涉法试验研究.试验力学.1997.9
[44] 卢锦凤,许峰等.电器在恒电压、恒电流、恒功率加热方式下的温升数学模型.机电元件.1997.6
[45] 王武义,徐定杰,陈健翼.误差原理与数据处理.哈尔滨:哈尔滨工业大学出版社.2001.10
[46] 张韵华,奚梅成,陈长松.数值计算方法和算法.北京:科学出版社.2000.1
[47] 刘惠彬,刘玉刚.测试技术.北京:北京航空航天大学出版社.1989.6
[48] 李久林,梁新邦.GB/T2039—1997金属拉伸蠕变及持久试验方法国家标准编制说明.冶金标准化与质量.1998.3
[49] 《金相图谱》编写组.金相图谱.北京:水利水电出版社.1986.4
[50] 杨瑞成,王晖,郑丽平.12Cr1MoV钢高温长时加热过程中基体成分的变化.金属热处理.2002.4