激光焊蜂窝夹套的结构强度研究
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摘要
蜂窝夹套设备是广泛应用于轻工、化工、食品等行业的新型换热设备。激光焊蜂窝夹套是先进制造技术和新型结构相结合的产物,具有制造方便、传热效果好、经济效益明显等优点,应用前景广阔。对其进行结构强度分析,具有重要的工程开发意义。
由于激光焊蜂窝夹套的特殊制造工艺及其新颖结构,需对其进行一个系统的实验研究和理论分析(主要是有限元数值模拟分析)。
本文所开展的主要工作如下:
(1) 对夹套材料的弹性、塑性性能进行研究,为有限元分析打下基础。
(2) 对激光焊的焊缝进行金相分析和剖面放大观察,从焊缝组织和结构上来分析其对整个夹套结构的影响。
(3) 对夹套的制造关键—压力鼓胀过程进行分析,解决压力鼓胀过程中的鼓胀压力—鼓胀高度关系的盲目性问题。
(4) 对夹套壳体进行结构强度分析,求出夹套的安全使用压力。
(5) 通过以上的实验研究和有限元分析,提出一套比较适合激光焊蜂窝夹套从生产制造到使用安全校核的系列有限元分析方法。
Honeycomb jacket is an efficient heat-exchange component, which is widely used in light industry, chemical industry and food industry. Laser welded dimple-plate jacket is a new type of honeycomb jacket, which is the product combined advanced manufacture technology with new structure. And it has some merit, such as easy manufacture, good heat-exchange effect and great economic effect and so on. So it has wide application foreground. Therefore it is of importance to study the analysis of structure strength for application of engineering.
Due to the special manufacture craft and the new structure of laser welded dimple-plate jacket, it is necessary to be studied by experimental and theory analysis (mainly finite element analysis).
In this paper, the main study items are as follows:
(1) The elastic and plastic performances of laser welded dimple-plate jacket's material are studied. And it is the groundwork of later jacket structure finite element analysis.
(2) The metallographs of laser welding seam are tested. Through them, the welding seam's structure is studied, which help us finding out the welding seam's influence to jacket.
(3) The key manufacture step-jacket's pressure distention process is analyzed. It mainly analyzes the relation of distention pressure and distention height. Through it. the jacket's pressure distention process becomes controllable.
(4) The strength analysis is done with jacket's shell. Through the analysis, jacket's safe-used pressure is obtained. So it should verify jacket safe use.
(5) Through above four items' experimental studies and finite element analysis, a series of jacket structure finite element analysis method is obtained, which fits jacket manufacture and jacket using processes analysis.
由于激光焊蜂窝夹套的特殊制造工艺及其新颖结构,需对其进行一个系统的实验研究和理论分析(主要是有限元数值模拟分析)。
本文所开展的主要工作如下:
(1) 对夹套材料的弹性、塑性性能进行研究,为有限元分析打下基础。
(2) 对激光焊的焊缝进行金相分析和剖面放大观察,从焊缝组织和结构上来分析其对整个夹套结构的影响。
(3) 对夹套的制造关键—压力鼓胀过程进行分析,解决压力鼓胀过程中的鼓胀压力—鼓胀高度关系的盲目性问题。
(4) 对夹套壳体进行结构强度分析,求出夹套的安全使用压力。
(5) 通过以上的实验研究和有限元分析,提出一套比较适合激光焊蜂窝夹套从生产制造到使用安全校核的系列有限元分析方法。
Honeycomb jacket is an efficient heat-exchange component, which is widely used in light industry, chemical industry and food industry. Laser welded dimple-plate jacket is a new type of honeycomb jacket, which is the product combined advanced manufacture technology with new structure. And it has some merit, such as easy manufacture, good heat-exchange effect and great economic effect and so on. So it has wide application foreground. Therefore it is of importance to study the analysis of structure strength for application of engineering.
Due to the special manufacture craft and the new structure of laser welded dimple-plate jacket, it is necessary to be studied by experimental and theory analysis (mainly finite element analysis).
In this paper, the main study items are as follows:
(1) The elastic and plastic performances of laser welded dimple-plate jacket's material are studied. And it is the groundwork of later jacket structure finite element analysis.
(2) The metallographs of laser welding seam are tested. Through them, the welding seam's structure is studied, which help us finding out the welding seam's influence to jacket.
(3) The key manufacture step-jacket's pressure distention process is analyzed. It mainly analyzes the relation of distention pressure and distention height. Through it. the jacket's pressure distention process becomes controllable.
(4) The strength analysis is done with jacket's shell. Through the analysis, jacket's safe-used pressure is obtained. So it should verify jacket safe use.
(5) Through above four items' experimental studies and finite element analysis, a series of jacket structure finite element analysis method is obtained, which fits jacket manufacture and jacket using processes analysis.
引文
[1] 化工设备设计全书编委会.搅拌设备设计,上海科技出版社,1985:144-146
[2] HG/T20569-94 机械搅拌设备,化工部工程建设标准编辑中心,北京,1995
[3] 林逢生.大型发酵设备的传热和强度研究[硕士学位论文],杭州,浙江大学,1998
[4] 肖国基.蜂窝夹套设备强度设计的改进.化工机械,1989,2:28-30
[5] 蒋家羚,林兴华,杨火生.螺旋蜂窝点冷却夹套反应器的开发.压力容器,1994,21(1):31-33
[6] 蒋家羚,林兴华.新型螺旋蜂窝夹套设备的强度设计.压力容器,1990,7(3):33-36
[7] 林兴华,林逢生,蒋家羚.大型生化发酵设备的新型蜂窝夹套结构及其强度计算.化工机械,1999,26(2):74-77
[8] 刘慧颖.新型蜂窝夹套换热器的结构优化和强度设计[硕士学位论文],上海,华东理工大学,2001
[9] 杨火生.螺旋蜂窝结构夹套反应器结构强度分析和换热性能研究[学位论文],杭州,浙江大学,1991
[10] 蒋家羚,林兴华.新型分片式蜂窝夹套结构冷却夹套反应器.化工装备技术,1993,14(4):1-3
[11] 洪学立,裴峰.蜂窝夹套容器的焊接制造,压力容器,2001,18(2):53-55
[12] 关正中.激光加工工艺手册,北京,中国计量出版社,1998
[13] 张其枢,堵耀庭.不锈钢焊接,北京,机械工业出版社,2000:326-331
[14] 江海河.激光加工技术应用的发展及展望.光电子技术与信息,2001,14(4):1-10
[15] 丁建军,吴腾飞.我国激光加工技术发展的现状和前景.机械工人(热加工),2002,1:16-17
[16] Hera News-Innovation in Metals(Laser Welding of Refrigeration Jackets).Hera News May 2002:Page 6
[17] Buco Plate(Laser or Resistance Welded)(产品说明书)
[18] The Design of Large Tanks. Brewing Technology Conference 1978
[19] 王国强.实用工程数值模拟技术及其在ANSYS上的实践,西安,西北工业大学出版社,1999
[20] GB150-1998 钢制压力容器,国家技术监督局分布,1998:1
[21] 刘鸿文.材料力学(上册),北京,高等教育出版社,1992:23-33
[22] 姜伟之,赵时熙,王春生,张峥.工程材料的力学性能,北京,北京航空航天大学出版社,2000:4-27
[23] 工程材料实用手册编辑委员会.工程材料实用手册(1),北京,中国标准出版社,1988:800-807
[24] JB4732-95钢制压力容器-分析设计标准,北京,技术标准出版社,1995
[25] 戴枝荣.工程材料及机械制造基础(Ⅰ)-工程材料(机械类各专业适用),北京,高等教育出版社,1992:117-119
[26] 岑汉钊.化工机械测试技术,北京,化学工业出版社,1991:56-66
[27] ANSYS中国.ANSYS非线性分析指南,2000
[28] 谭建国.使用ANSYS6.0进行有限元分析,北京,北京大学出版社,2002
[29] 万正权,徐秉汉,朱邦俊.弹塑性板壳结构非线性有限元分析.船舶力学,1997,1(1):32-39
[30] 周传月,李桂英,马云翔.某舰用锅炉过热器胀接接头弹塑性有限元分析.热能动力工程,2001,16(1):77-79
[31] Z. Sanal. Nonlinear Analysis of Pressure Vessels: Some Examples, InternatiOn Journal of. Pressure Vessels and Piping 77(2000):705-709
[32] 张兵,王心丰.用非线性有限元分析波纹管的稳定性.压力容器,2001,18(1):40-44
[33] 王仁,黄文彬,黄筑平.塑性力学引论(修订版),北京,北京大学出版社,1999:88-101
[34] 化学工业部设备技术中心站.ASME 锅炉及压力容器规范-压力容器第一册,北京,1983
[35] 魏祖健,李明瑞,黄文彬.板弹塑性有限元分析的有限载荷增量牛顿迭代一
致性算法.北京农业工程大学学报,1989,9(1):81-89
[36] 曾凡林,林洪书,王萌成.锅炉汽包的三维有限元应力分析.压力容器,1992,9(5):42-46
[37] 刘俊明,陈绪.高压厚管板的有限元分析设计计算.压力容器,1997,14(2):115-119
[38] 丁窘果.化工容器及设备设计,杭州,浙江大学出版社,1997:196-203
[39] 李建国.压力容器分析设计的力学基础-第一讲(分析设计中的力学概念).压力容器,1985,2(1):71-77
[40] JB4732-95 钢制压力容器-分析设计标准 标准释义,北京,技术标准出版社,1995
[41] 丁伯民.美国压力容器规范分析-ASMEⅧ-1和Ⅷ-2,上海,华东理工大学出版社,1995
[42] 龚曙光,谢桂兰.压力容器分析设计中的应力分类方法.化工装备技术,2000,21(3):27-31
[43] 李国成,赵正修.以应力分类法为依据的数据处理.压力容器,1990,7(2):27-34
[44] 李永生,沈讯伟,於孝春.受压圆筒矩形大开孔的三维有限元分析与强度评定.压力容器,1996,13(4):314-320
[45] 周昌玉,吴宝绢,沈士明.带凹坑双向试板的实验应力分析及实验极限载荷研究.化工容器,1996,13(1):23-28
[46] M Save. Experimental Verification of PlastiC Limit Analysis of Torispherical and Toriconical Hards. Pressure Vessel and Piping Design and Analysis, ASME, 1972: 382-416
[2] HG/T20569-94 机械搅拌设备,化工部工程建设标准编辑中心,北京,1995
[3] 林逢生.大型发酵设备的传热和强度研究[硕士学位论文],杭州,浙江大学,1998
[4] 肖国基.蜂窝夹套设备强度设计的改进.化工机械,1989,2:28-30
[5] 蒋家羚,林兴华,杨火生.螺旋蜂窝点冷却夹套反应器的开发.压力容器,1994,21(1):31-33
[6] 蒋家羚,林兴华.新型螺旋蜂窝夹套设备的强度设计.压力容器,1990,7(3):33-36
[7] 林兴华,林逢生,蒋家羚.大型生化发酵设备的新型蜂窝夹套结构及其强度计算.化工机械,1999,26(2):74-77
[8] 刘慧颖.新型蜂窝夹套换热器的结构优化和强度设计[硕士学位论文],上海,华东理工大学,2001
[9] 杨火生.螺旋蜂窝结构夹套反应器结构强度分析和换热性能研究[学位论文],杭州,浙江大学,1991
[10] 蒋家羚,林兴华.新型分片式蜂窝夹套结构冷却夹套反应器.化工装备技术,1993,14(4):1-3
[11] 洪学立,裴峰.蜂窝夹套容器的焊接制造,压力容器,2001,18(2):53-55
[12] 关正中.激光加工工艺手册,北京,中国计量出版社,1998
[13] 张其枢,堵耀庭.不锈钢焊接,北京,机械工业出版社,2000:326-331
[14] 江海河.激光加工技术应用的发展及展望.光电子技术与信息,2001,14(4):1-10
[15] 丁建军,吴腾飞.我国激光加工技术发展的现状和前景.机械工人(热加工),2002,1:16-17
[16] Hera News-Innovation in Metals(Laser Welding of Refrigeration Jackets).Hera News May 2002:Page 6
[17] Buco Plate(Laser or Resistance Welded)(产品说明书)
[18] The Design of Large Tanks. Brewing Technology Conference 1978
[19] 王国强.实用工程数值模拟技术及其在ANSYS上的实践,西安,西北工业大学出版社,1999
[20] GB150-1998 钢制压力容器,国家技术监督局分布,1998:1
[21] 刘鸿文.材料力学(上册),北京,高等教育出版社,1992:23-33
[22] 姜伟之,赵时熙,王春生,张峥.工程材料的力学性能,北京,北京航空航天大学出版社,2000:4-27
[23] 工程材料实用手册编辑委员会.工程材料实用手册(1),北京,中国标准出版社,1988:800-807
[24] JB4732-95钢制压力容器-分析设计标准,北京,技术标准出版社,1995
[25] 戴枝荣.工程材料及机械制造基础(Ⅰ)-工程材料(机械类各专业适用),北京,高等教育出版社,1992:117-119
[26] 岑汉钊.化工机械测试技术,北京,化学工业出版社,1991:56-66
[27] ANSYS中国.ANSYS非线性分析指南,2000
[28] 谭建国.使用ANSYS6.0进行有限元分析,北京,北京大学出版社,2002
[29] 万正权,徐秉汉,朱邦俊.弹塑性板壳结构非线性有限元分析.船舶力学,1997,1(1):32-39
[30] 周传月,李桂英,马云翔.某舰用锅炉过热器胀接接头弹塑性有限元分析.热能动力工程,2001,16(1):77-79
[31] Z. Sanal. Nonlinear Analysis of Pressure Vessels: Some Examples, InternatiOn Journal of. Pressure Vessels and Piping 77(2000):705-709
[32] 张兵,王心丰.用非线性有限元分析波纹管的稳定性.压力容器,2001,18(1):40-44
[33] 王仁,黄文彬,黄筑平.塑性力学引论(修订版),北京,北京大学出版社,1999:88-101
[34] 化学工业部设备技术中心站.ASME 锅炉及压力容器规范-压力容器第一册,北京,1983
[35] 魏祖健,李明瑞,黄文彬.板弹塑性有限元分析的有限载荷增量牛顿迭代一
致性算法.北京农业工程大学学报,1989,9(1):81-89
[36] 曾凡林,林洪书,王萌成.锅炉汽包的三维有限元应力分析.压力容器,1992,9(5):42-46
[37] 刘俊明,陈绪.高压厚管板的有限元分析设计计算.压力容器,1997,14(2):115-119
[38] 丁窘果.化工容器及设备设计,杭州,浙江大学出版社,1997:196-203
[39] 李建国.压力容器分析设计的力学基础-第一讲(分析设计中的力学概念).压力容器,1985,2(1):71-77
[40] JB4732-95 钢制压力容器-分析设计标准 标准释义,北京,技术标准出版社,1995
[41] 丁伯民.美国压力容器规范分析-ASMEⅧ-1和Ⅷ-2,上海,华东理工大学出版社,1995
[42] 龚曙光,谢桂兰.压力容器分析设计中的应力分类方法.化工装备技术,2000,21(3):27-31
[43] 李国成,赵正修.以应力分类法为依据的数据处理.压力容器,1990,7(2):27-34
[44] 李永生,沈讯伟,於孝春.受压圆筒矩形大开孔的三维有限元分析与强度评定.压力容器,1996,13(4):314-320
[45] 周昌玉,吴宝绢,沈士明.带凹坑双向试板的实验应力分析及实验极限载荷研究.化工容器,1996,13(1):23-28
[46] M Save. Experimental Verification of PlastiC Limit Analysis of Torispherical and Toriconical Hards. Pressure Vessel and Piping Design and Analysis, ASME, 1972: 382-416