钎焊接头对铝制板翅结构热应力影响规律
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摘要
为保证LNG铝制板翅式换热器安全可靠运行,基于热弹性理论,建立铝制板翅结构热应力分析模型,采用热-固耦合方法,模拟研究实际运行过程中,钎焊接头对铝制板翅结构热应力的影响.结果表明,LNG铝制板翅式换热器,钎焊角曲率半径r=0. 5 mm、融合距离l=0. 137 5 mm时,在靠近翅片侧和隔板侧钎焊接头处最大等效应力达到峰值,并且最大正应力是引起该位置等效应力达到峰值的主要原因;钎料层等效应力、最大正应力和最大剪应力均变化平缓;在实际运行过程中,靠近翅片侧和隔板侧钎焊接头处,等效应力随钎焊角曲率半径增加而增大;减小钎焊角曲率半径,将降低钎焊接头处热应力变化梯度,从而降低其应力集中程度.靠近隔板侧钎焊接头处等效应力,随融合距离增加而减小,靠近翅片侧的反之;当钎焊角融合距离小于0. 08 mm时,靠近隔板侧钎焊接头处等效应力大于靠近翅片侧的,反之靠近翅片侧的大于靠近隔板侧的.上述研究成果为大型LNG工厂用铝制板翅式换热器的设计、制造以及运行操作提供理论依据.
To improve the structural safety of LNG plate-fin heat exchanger,the analysis model on stress of platefin structures was established based on thermal-elastic theory. The stress characteristics of plate-fin structures at different brazed joints were analyzed by thermal-stress coupling method. Results showed that the maximum equivalent stress reached the peak value at the brazed joint near fin and plate side when the curvature radius of the brazing angle was 0. 5 mm and the fusion distance was 0. 137 5 mm,which was mainly induced by the maximum normal stress. The equivalent stress,the maximum normal stress,and the maximum shear stress changed steadily at the brazing seam. The equivalent stress of the brazed joints near fin and plate side increased with the increment of curvature radius on brazing arc. The stress concentration at brazed joints was reduced with the decrease of the curvature radius. The equivalent stress at the brazed joints near plate side decreased when the fusion distance on brazing arc increased,while it was opposite at the brazed joints near fin side. The equivalent stress of the brazed joints near plate side was larger than that near the fin side when the fusion distance on brazing arc was less than0. 08 mm. The above research results provide theoretical basis for the design,manufacture,and operation of LNG plate-fin heat exchangers in large LNG plants.
To improve the structural safety of LNG plate-fin heat exchanger,the analysis model on stress of platefin structures was established based on thermal-elastic theory. The stress characteristics of plate-fin structures at different brazed joints were analyzed by thermal-stress coupling method. Results showed that the maximum equivalent stress reached the peak value at the brazed joint near fin and plate side when the curvature radius of the brazing angle was 0. 5 mm and the fusion distance was 0. 137 5 mm,which was mainly induced by the maximum normal stress. The equivalent stress,the maximum normal stress,and the maximum shear stress changed steadily at the brazing seam. The equivalent stress of the brazed joints near fin and plate side increased with the increment of curvature radius on brazing arc. The stress concentration at brazed joints was reduced with the decrease of the curvature radius. The equivalent stress at the brazed joints near plate side decreased when the fusion distance on brazing arc increased,while it was opposite at the brazed joints near fin side. The equivalent stress of the brazed joints near plate side was larger than that near the fin side when the fusion distance on brazing arc was less than0. 08 mm. The above research results provide theoretical basis for the design,manufacture,and operation of LNG plate-fin heat exchangers in large LNG plants.
引文
[1]KHOSHVAGHT-ALIABADI M,HORMOZI F,ZAMZAMIAN A.Effects of geometrical parameters on performance of plate-fin heat exchanger:Vortex-generator as core surface and nanofluid as working media[J]. Applied Thermal Engineering,2014,70(1):565. DOI:10. 1016/j. applthermaleng. 2014. 04. 026
[2]GE L,JIANG W,ZHANG Y,et al. Analytical evaluation of the homogenized elastic constants of plate-fin structures[J].International Journal of Mechanical Sciences,2017,134:51. DOI:10. 1016/j. ijmecsci. 2017. 09. 041
[3]JIANG W C,GONG J M,CHEN H,et al. Finite element analysis of creep of stainless steel plate-fin structure[J]. Acta Metallurgica Sinica,2007,43(5):539
[4]JIANG W,GONG J,CHEN H,et al. The effect of filler metal thickness on residual stress and creep for stainless-steel plate-fin structure[J]. International Journal of Pressure Vessels and Piping,2008,85(8):569. DOI:10. 1016/j. ijpvp. 2008. 02. 007
[5]陈虎,巩建鸣,耿鲁阳,等.板翅结构钎焊残余应力与热变形的有限元分析[J].焊接学报,2006,27(11):29CHEN Hu,GONG Jianming,GENG Luyang,et al. Finite element analysis of brazing residual stress and thermal deformation of plate-fin structure[J]. Transactions of the China Welding Institution,2006,27(11):29
[6]肖笛,朱单单,冯学文.氧含量对铝制板翅式散热器真空钎焊的影响[J].现代机械,2017(3):33XIAO Di,ZHU Dandan,FENG Xuewen. The influence of oxygen content on the vacuum brazing of aluminum plate fin radiator[J].Modern Machinery,2017(3):33. DOI:10. 13667/j. cnki. 52-1046/th. 2017. 03. 009
[7]XIE Q Y,LING X A. Numerical analysis of residual stress for copper base brazed stainless steel plate-fin structure[J]. Journal of Materials Engineering and Performance,2010,19(5):611. DOI:10. 1007/s11665-009-9530-7
[8]MA H,CHEN J,CAI W,et al. The influence of operation parameters on stress of plate-fin structures in LNG heat exchanger[J]. Journal of Natural Gas Science and Engineering,2015,26:216. DOI:10. 1016/j. jngse. 2015. 06. 011
[9]MA H,HOU C,YANG R,et al. The influence of structure parameters on stress of plate-fin structures in LNG heat exchanger[J]. Journal of Natural Gas Science&Engineering,2016,34:85.DOI:10. 1016/j. jngse. 2016. 06. 050
[10]MA H,CAI W,ZHENG W,et al. Stress characteristics of plate-fin structures in the cool-down process of LNG heat exchanger[J].Journal of Natural Gas Science and Engineering,2014,21:1113.DOI:10. 1016/j. jngse. 2014. 10. 019
[11]麻宏强,陈杰,蔡伟华,等.降温过程中LNG板翅结构应力耦合模拟[J].哈尔滨工业大学学报,2015,47(6):21MA Hongqiang, CHEN Jie, CAI Weihua, et al. Numerical investigation on stress of plate-fin structures during cool-down of LNG heat exchanger[J]. Journal of Harbin Institute of Technology,2015,47(6):21. DOI:10. 11918/j. issn0367-6234. 2015. 06. 004
[12]MA H,CAI W,YAO Y,et al. Investigation on stress characteristics of plate-fin structures in the heat-up process of LNG heat exchanger[J].Journal of Natural Gas Science and Engineering,2016,30:256. DOI:10. 1016/j. jngse. 2016. 02. 029
[2]GE L,JIANG W,ZHANG Y,et al. Analytical evaluation of the homogenized elastic constants of plate-fin structures[J].International Journal of Mechanical Sciences,2017,134:51. DOI:10. 1016/j. ijmecsci. 2017. 09. 041
[3]JIANG W C,GONG J M,CHEN H,et al. Finite element analysis of creep of stainless steel plate-fin structure[J]. Acta Metallurgica Sinica,2007,43(5):539
[4]JIANG W,GONG J,CHEN H,et al. The effect of filler metal thickness on residual stress and creep for stainless-steel plate-fin structure[J]. International Journal of Pressure Vessels and Piping,2008,85(8):569. DOI:10. 1016/j. ijpvp. 2008. 02. 007
[5]陈虎,巩建鸣,耿鲁阳,等.板翅结构钎焊残余应力与热变形的有限元分析[J].焊接学报,2006,27(11):29CHEN Hu,GONG Jianming,GENG Luyang,et al. Finite element analysis of brazing residual stress and thermal deformation of plate-fin structure[J]. Transactions of the China Welding Institution,2006,27(11):29
[6]肖笛,朱单单,冯学文.氧含量对铝制板翅式散热器真空钎焊的影响[J].现代机械,2017(3):33XIAO Di,ZHU Dandan,FENG Xuewen. The influence of oxygen content on the vacuum brazing of aluminum plate fin radiator[J].Modern Machinery,2017(3):33. DOI:10. 13667/j. cnki. 52-1046/th. 2017. 03. 009
[7]XIE Q Y,LING X A. Numerical analysis of residual stress for copper base brazed stainless steel plate-fin structure[J]. Journal of Materials Engineering and Performance,2010,19(5):611. DOI:10. 1007/s11665-009-9530-7
[8]MA H,CHEN J,CAI W,et al. The influence of operation parameters on stress of plate-fin structures in LNG heat exchanger[J]. Journal of Natural Gas Science and Engineering,2015,26:216. DOI:10. 1016/j. jngse. 2015. 06. 011
[9]MA H,HOU C,YANG R,et al. The influence of structure parameters on stress of plate-fin structures in LNG heat exchanger[J]. Journal of Natural Gas Science&Engineering,2016,34:85.DOI:10. 1016/j. jngse. 2016. 06. 050
[10]MA H,CAI W,ZHENG W,et al. Stress characteristics of plate-fin structures in the cool-down process of LNG heat exchanger[J].Journal of Natural Gas Science and Engineering,2014,21:1113.DOI:10. 1016/j. jngse. 2014. 10. 019
[11]麻宏强,陈杰,蔡伟华,等.降温过程中LNG板翅结构应力耦合模拟[J].哈尔滨工业大学学报,2015,47(6):21MA Hongqiang, CHEN Jie, CAI Weihua, et al. Numerical investigation on stress of plate-fin structures during cool-down of LNG heat exchanger[J]. Journal of Harbin Institute of Technology,2015,47(6):21. DOI:10. 11918/j. issn0367-6234. 2015. 06. 004
[12]MA H,CAI W,YAO Y,et al. Investigation on stress characteristics of plate-fin structures in the heat-up process of LNG heat exchanger[J].Journal of Natural Gas Science and Engineering,2016,30:256. DOI:10. 1016/j. jngse. 2016. 02. 029