油浆蒸汽发生器热应力计算及密封性能研究
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摘要
油浆蒸汽发生器是石化企业的重要设备之一,其主要功能是使用低温介质水降低高温油浆的温度。对油浆蒸汽发生器进行温度场和应力场的耦合分析,有助于改善换热器的结构和操作工艺;调查换热器的密封情况,对节约材料和能源、实现安全连续生产具有重要作用。
油浆蒸汽发生器属于管板式换热器,结构复杂,几何尺寸庞大,如果采用实体单元建模,得到的有限元模型和求解矩阵规模非常大,几乎不能应用于PC机上。本文对油浆蒸汽发生器的管板换热管和法兰—垫片—螺栓分别进行了热应力耦合场分析计算,并对换热器密封性能进行研究。
具体而言,应用通用商业有限元软件ANSYS,灵活应用ANSYS提供的各种结构单元和热单元进行建模,在保证计算精度的基础上,减小了计算规模。采用SOLID70热分析单元,对热影响区内的管板、换热管进行对流换热条件下的稳态温度场分析,应力场采用SOLID45实体单元,施加压力载荷,同时加载温度场的计算结果作为载荷得到管板换热管的应力场分析计算结果;采用SOLID70热分析单元,对法兰—垫片—螺栓进行对流换热条件下的稳态温度场分析,应力场采用SOLID45实体单元,同时引入接触目标面分析单元TARGE170,接触接触面分析单元CONTA174和预紧力单元PREST179,施加预紧力、压力载荷和温度场计算结果,计算得到法兰—垫片—螺栓的应力场分析计算结果。最后对法兰密封性能进行研究,提出螺栓拆卸困难的解决方案。
Oil slurry heat exchanger is one of the most important equipments in chemical industry. Its function is to lower the temperature of oil slurry by using cooling water. It is necessary and significant for the economic and security to analysis both temperature field and stress field of the oil slurry heat exchanger. It is also very important to analysis for sealed used in oil slurry heat exchanger, for the sake of saving materials and energy.
Oil slurry heat exchanger belongs to tube-sheet heat exchanger. Due to its complex structure and large geometry size, it is too complicated to calculate on PC by using the finite elements of the whole equipment model. So tubesheet-pipes' temperature stress field and flange-gasket-bolts' temperature stress field are respectively analyzed, and seal function of the exchanger is also researched.
Specifically speaking, use suitable stress analysis elements and thermal analysis elements applied by the ANSYS software to establish the suitable FEA model for calculating on PC. Use thermal analysis element SOLID 70, load convection heat transfer coefficient, calculate and obtain the temperature field of tubesheet-pipes of oil slurry heat exchanger, then use stress analysis element SOLID 45, bring pressure and temperature results to bear on areas of tubesheet and pipes, calculate and obtain the stress field of tubesheet-pipes of oil slurry heat exchanger; Use thermal analysis element SOLID 70, load convection heat transfer coefficient, calculate and obtain the temperature field of flange-gasket-bolts of oil slurry heat exchanger, then use stress analysis element SOLID 45, contact analysis element TARGE 170 CONTA174 and pre-tightened element PRETS179, bring pressure and temperature results to bear on areas of flange-gasket-bolts, calculate and obtain the stress field of flange-gasket-bolts of oil slurry heat exchanger. Lastly the seal function of the exchanger will be researched.
油浆蒸汽发生器属于管板式换热器,结构复杂,几何尺寸庞大,如果采用实体单元建模,得到的有限元模型和求解矩阵规模非常大,几乎不能应用于PC机上。本文对油浆蒸汽发生器的管板换热管和法兰—垫片—螺栓分别进行了热应力耦合场分析计算,并对换热器密封性能进行研究。
具体而言,应用通用商业有限元软件ANSYS,灵活应用ANSYS提供的各种结构单元和热单元进行建模,在保证计算精度的基础上,减小了计算规模。采用SOLID70热分析单元,对热影响区内的管板、换热管进行对流换热条件下的稳态温度场分析,应力场采用SOLID45实体单元,施加压力载荷,同时加载温度场的计算结果作为载荷得到管板换热管的应力场分析计算结果;采用SOLID70热分析单元,对法兰—垫片—螺栓进行对流换热条件下的稳态温度场分析,应力场采用SOLID45实体单元,同时引入接触目标面分析单元TARGE170,接触接触面分析单元CONTA174和预紧力单元PREST179,施加预紧力、压力载荷和温度场计算结果,计算得到法兰—垫片—螺栓的应力场分析计算结果。最后对法兰密封性能进行研究,提出螺栓拆卸困难的解决方案。
Oil slurry heat exchanger is one of the most important equipments in chemical industry. Its function is to lower the temperature of oil slurry by using cooling water. It is necessary and significant for the economic and security to analysis both temperature field and stress field of the oil slurry heat exchanger. It is also very important to analysis for sealed used in oil slurry heat exchanger, for the sake of saving materials and energy.
Oil slurry heat exchanger belongs to tube-sheet heat exchanger. Due to its complex structure and large geometry size, it is too complicated to calculate on PC by using the finite elements of the whole equipment model. So tubesheet-pipes' temperature stress field and flange-gasket-bolts' temperature stress field are respectively analyzed, and seal function of the exchanger is also researched.
Specifically speaking, use suitable stress analysis elements and thermal analysis elements applied by the ANSYS software to establish the suitable FEA model for calculating on PC. Use thermal analysis element SOLID 70, load convection heat transfer coefficient, calculate and obtain the temperature field of tubesheet-pipes of oil slurry heat exchanger, then use stress analysis element SOLID 45, bring pressure and temperature results to bear on areas of tubesheet and pipes, calculate and obtain the stress field of tubesheet-pipes of oil slurry heat exchanger; Use thermal analysis element SOLID 70, load convection heat transfer coefficient, calculate and obtain the temperature field of flange-gasket-bolts of oil slurry heat exchanger, then use stress analysis element SOLID 45, contact analysis element TARGE 170 CONTA174 and pre-tightened element PRETS179, bring pressure and temperature results to bear on areas of flange-gasket-bolts, calculate and obtain the stress field of flange-gasket-bolts of oil slurry heat exchanger. Lastly the seal function of the exchanger will be researched.
引文
[1] 赵克勤,王秀珍,王正.石油化工容器及设备.武汉:华中理工大学出版社,1990.
[2] 李黎明.有限元分析实用教程.北京:清华大学出版社,2005:1—3.
[3] 余伟炜,高炳军等.ANSYS在机械与化工装备中的应用.北京:中国水利水电出版社,2006:48.
[4] 小飒工作室.最新经典ANSYS及Workbench教程.北京:电子工业出版社,2004.
[5] 余国琮.化工容器及设备.北京:化学工业出版社,1980.
[6] 赵海峰,蒋迪.ANSYS8.0工程结构分析实例分析.北京:中国铁道出版社,2004.
[7] 董大勤,袁风隐.压力容器设计手册.北京:化学工业出版社,2006.
[8] 徐定耿,叶维娟.核电站蒸汽发生器管板三维有限元应力分析及其工程应用.核科学与工程,1990.6:160—167.
[9] Malkin. Notes on a Theoretical Basis for the Design of tubesheets of Triangular Layout. ASME Journal of Applied Mechanics, 1952, 19(74):387-396.
[10] Terakawa. Stiffening Effects of Tubes in Heat Exchanger Tubesheet. Journal of Pressure Vessel Technology, 1984, 106(237).
[11] Peterson R E. Stress Concentration Factors. New YorK, 1974.
[12] Weiya Jin. Comparison of Two FEA Models for Calculating Stresses in Shell-and-tube Heat Exchanger. International Journal of Pressure Vessels and Piping, 2002(81): 563-567.
[13] Gardener K A. Heat Exchanger Tubesheet Design. Journal of Applied Mechanics, 1948(15): 377-385.
[14] Horvay. The Plane-Stress Problem of Perforated Plates. ASME Journal of Applied Mechanics, 1952(17):317-325.
[15] Kasahara N, Iwata K. Simplified 2-dimensional Thermal Analysis Method Considering 3-dimensional Heat Transfer. Computational Mechanism 86, Spring Verlag, 1986, 2:127-137.
[16] 刘海亮,于洪杰,徐鸿,钱才富.采用实体模型的厚管板的有限元分析.石油化工设备技术,2005,26(3):1-5.
[17] 薛明德,吴强胜.对流换热条件下换热器管板的应力分析.核动力工程,1998,19(6):519-524.
[18] 冷纪桐,吕洪,章姚辉,赵军.某固定管板换热器的温度场与热应力分析.北京化工大学学报,2004(2):104—107.
[19] 钱颂文.换热器设计手册.北京:化学工业出版社,2002.
[20] 季维英.管壳式换热器管板应力的三维有限元分析:(硕士学位论文).南京:南京理工大学,2006.
[21] 马永其.换热器固定管板有限元应力分析的进一步研究:(博士学位论文).北京:北京化工大 学,2000.
[22] 王泳,薛小强.油浆蒸汽发生器内漏原因分析及改进措施.石油化工设备,2007,36(1):91—93.
[23] 郭晶.油浆蒸汽发生器的密封改造.化工机械,2003,30(3):185-186.
[24] 单利.油浆蒸汽发生器泄漏原因分析及预防措施.焊接与切割,2007,3:54—55.
[25] 刘玉英,宋天民,张国福等.重催油浆换热器管板开裂的应力腐蚀失效.石油化工高等学校学报,2005,18(4):58—61.
[26] 夏致云,唐志云.油浆换热器密封实效分析.化工设备设计,1999,36(2):32—35
[27] 孙毅,郭建,乔文山.催化裂化油浆蒸汽发生器换热器的技术改造.石油化工设备技术,2000,21(5):9—11.
[28] 安维峥.考虑垫片时滞效应的管板—法兰—垫片—螺栓连接系统的非线性有限元分析:(硕士学位论文).北京:北京化工大学,2005.
[29] JB4700—4707—92.压力容器法兰,1992.
[30] 刘玉法,徐永昌等.大型国产化硫磺冷凝装置运行与改造.齐鲁石油化工,2006,34(2):125-129.
[2] 李黎明.有限元分析实用教程.北京:清华大学出版社,2005:1—3.
[3] 余伟炜,高炳军等.ANSYS在机械与化工装备中的应用.北京:中国水利水电出版社,2006:48.
[4] 小飒工作室.最新经典ANSYS及Workbench教程.北京:电子工业出版社,2004.
[5] 余国琮.化工容器及设备.北京:化学工业出版社,1980.
[6] 赵海峰,蒋迪.ANSYS8.0工程结构分析实例分析.北京:中国铁道出版社,2004.
[7] 董大勤,袁风隐.压力容器设计手册.北京:化学工业出版社,2006.
[8] 徐定耿,叶维娟.核电站蒸汽发生器管板三维有限元应力分析及其工程应用.核科学与工程,1990.6:160—167.
[9] Malkin. Notes on a Theoretical Basis for the Design of tubesheets of Triangular Layout. ASME Journal of Applied Mechanics, 1952, 19(74):387-396.
[10] Terakawa. Stiffening Effects of Tubes in Heat Exchanger Tubesheet. Journal of Pressure Vessel Technology, 1984, 106(237).
[11] Peterson R E. Stress Concentration Factors. New YorK, 1974.
[12] Weiya Jin. Comparison of Two FEA Models for Calculating Stresses in Shell-and-tube Heat Exchanger. International Journal of Pressure Vessels and Piping, 2002(81): 563-567.
[13] Gardener K A. Heat Exchanger Tubesheet Design. Journal of Applied Mechanics, 1948(15): 377-385.
[14] Horvay. The Plane-Stress Problem of Perforated Plates. ASME Journal of Applied Mechanics, 1952(17):317-325.
[15] Kasahara N, Iwata K. Simplified 2-dimensional Thermal Analysis Method Considering 3-dimensional Heat Transfer. Computational Mechanism 86, Spring Verlag, 1986, 2:127-137.
[16] 刘海亮,于洪杰,徐鸿,钱才富.采用实体模型的厚管板的有限元分析.石油化工设备技术,2005,26(3):1-5.
[17] 薛明德,吴强胜.对流换热条件下换热器管板的应力分析.核动力工程,1998,19(6):519-524.
[18] 冷纪桐,吕洪,章姚辉,赵军.某固定管板换热器的温度场与热应力分析.北京化工大学学报,2004(2):104—107.
[19] 钱颂文.换热器设计手册.北京:化学工业出版社,2002.
[20] 季维英.管壳式换热器管板应力的三维有限元分析:(硕士学位论文).南京:南京理工大学,2006.
[21] 马永其.换热器固定管板有限元应力分析的进一步研究:(博士学位论文).北京:北京化工大 学,2000.
[22] 王泳,薛小强.油浆蒸汽发生器内漏原因分析及改进措施.石油化工设备,2007,36(1):91—93.
[23] 郭晶.油浆蒸汽发生器的密封改造.化工机械,2003,30(3):185-186.
[24] 单利.油浆蒸汽发生器泄漏原因分析及预防措施.焊接与切割,2007,3:54—55.
[25] 刘玉英,宋天民,张国福等.重催油浆换热器管板开裂的应力腐蚀失效.石油化工高等学校学报,2005,18(4):58—61.
[26] 夏致云,唐志云.油浆换热器密封实效分析.化工设备设计,1999,36(2):32—35
[27] 孙毅,郭建,乔文山.催化裂化油浆蒸汽发生器换热器的技术改造.石油化工设备技术,2000,21(5):9—11.
[28] 安维峥.考虑垫片时滞效应的管板—法兰—垫片—螺栓连接系统的非线性有限元分析:(硕士学位论文).北京:北京化工大学,2005.
[29] JB4700—4707—92.压力容器法兰,1992.
[30] 刘玉法,徐永昌等.大型国产化硫磺冷凝装置运行与改造.齐鲁石油化工,2006,34(2):125-129.