扫 描 看 全 文
戴玲,姜永正,杨国平,等.焊接工艺参数对Q345厚板L形接头焊接温度场的影响[J].电焊机,2023,53(6):62-69.
DAI Ling, JIANG Yongzheng, YANG Guoping, et al.Effect of Welding Parameters on Welding Temperature Field of L-Joint of Q345 Thick Plate[J].Electric Welding Machine, 2023, 53(6): 62-69.
以Q345厚板L形接头焊接过程为研究对象,提取厚板的V形焊道结构进行分析,基于双椭球功率密度分布体热源模型为输入热源,利用Visual Environment有限元软件建立其网格模型,并建立焊接热过程的计算文件。通过数值模拟焊接一段直板结构的V形焊道焊接热过程,模拟并分析不同焊接工艺参数下的厚板温度场,研究了不同有效热功率和焊接速度对焊接温度场的影响;并结合V形板焊接试验的红外激光测试数据,对比仿真结果温度云图截面,证明了温度场数据的仿真效果与实际吻合,数值模拟的数据准确;同时分析了不同热效率和焊接速度下,焊接温度场的不同温度区间的尺寸变化。计算结果表明,低温区的尺寸变小,证明厚板的散热效果比薄板好;由仿真的几组数据表明,加大焊道的热输入量,高温区下移,证实V形焊道对热输入的要求比双V形焊道高;焊接速度越大,高温区和低温区的体积越小,对比不同焊接速度的焊道温度场截面,高温区宽度的减小比率大于深度减小比率,即焊接速度对低温区的影响效果比高温区明显。
The welding process of L-joint of Q345 thick plate is taken as the research object, and the V-bead structure of thick plate is extracted for analysis. Based on the double ellipsoidal power density distribution body heat source model as the input heat source, the mesh model is established by using the visual environment finite element software, and the calculation file of welding heat process is established. The temperature field of thick plate under different welding parameters was simulated and analyzed by numerical simulation of the welding thermal process of V bead of a straight plate structure, and the influence of different effective heat power and welding speeds on the welding temperature field was studied. Combined with the infrared laser test data of V-shaped plate welding test, the simulation results of temperature cloud section are compared to prove that the simulation effect of temperature field data is consistent with the actual, and the data of numerical simulation are accurate. At the same time, the size changes of different temperature ranges of the welding temperature field under different thermal efficiencies and welding speeds are analyzed. The calculation results show that the size of low temperature zone becomes smaller, which proves that the heat dissipation effect of thick plate is better than that of thin plate. Several sets of simulation data show that increasing the heat input of the weld decreases in the high temperature region, confirming that the requirement of the V bead for heat input is higher than that of the double V bead. The larger the welding speed is, the smaller the volume of the high-temperature zone and the low-temperature zone is. Compared with the temperature field cross-section of the weld with different welding speeds, the reduction ratio of the width of the high-temperature zone is greater than that of the depth, that is, the influence of the welding speed on the low-temperature zone is more obvious than that on the high-temperature zone.
V形焊道焊接速度温度场热源模型数值模拟
V beadwelding speedtemperature fieldheat source modelnumerical simulation
汪建华.焊接数值模拟技术及其应用[M].上海:上海交通大学出版社,2003.
张清华. 双椭球热源模型参数标定及其在多道焊模拟中的应用[D]. 上海:中国石油大学(华东),2018.
ZHANG Q H. Determination of the Parameters of Double Ellipsoid Heat Source Model and Its Application in Simulation of Multi-pass Welding[D]. Shanghai:China University of Petroleum (East China),2018.
李娅娜,刘嘉浩. 基于焊接质量双椭球热源形状参数的简化模型[J]. 焊接,2021(08):7-11,62.
LI Y N,LIU J H. Simplified model of heat source shape parameters of double ellipsoid based on welding quality [J]. Welding & Joining,2021(08):7-11,62.
John A,Goldak,Mehdi Akhlag Computational welding mechanics[M]. New York:Springer,2005.
朱志明,符平坡,杨中宇,等. 电弧焊接数值模拟中热源模型的研究与发展[J]. 工程科学学报,2018,40(04):389-396.
ZHU Z M,FU P P,YANG Z Y,et al. Research and development of a heat-source model in numerical simulations for the arc welding process[J]. Chinese Journal of Engineering,2018,40(04):389-396.
李培麟. 多丝埋弧焊热源模型与焊缝成形的模拟研究[D]. 上海:上海交通大学,2012.
LI P L. Study on the Simulation of Multi-Wire Submerged Arc Welding Heat Source Model and Appearance of Weld[D]. Shanghai:Shanghai Jiaotong University,2012.
王薇,金成,史春元. 网格尺寸对双椭球热源模型作用下焊接温度场计算的影响[J]. 焊接学报,2016,37(07):39-43.
WANG W,JIN C,SHI C Y. Effect of mesh size on weld temperature field of double ellipsoidal power density distribution heat source model[J]. Transactions of the China Welding Institution,2016,37(07):39-43.
邹德敏,齐锦刚,赵琳,等. 焊接速度对激光-电弧复合焊接焊缝成形和低温冲击韧性的影响[J]. 中国激光,2022,49(08):151-160.
ZOU D M,QI J G,ZHAO L,et al. Effect of Welding Speed on Bead Appearance and Low-Temperature Impact Toughness in Laser-Arc Hybrid Welding[J]. Chinese Journal of Lasers,2022,49(08):151-160.
周祥曼,王礴允,袁有录,等. 焊接速度对电弧增材熔池流动及焊道形貌影响的数值模拟研究[J]. 机械工程学报,2022,58(10):103-111.
ZHOU X M,WANG M Y,YUAN Y L,et al. Numerical Simulation Study of the Effects of Travel Speed on the Molten Pool Flow and Weld Bead Morphology of WAAM[J]. Mechanical Engineering Journal,2022,58(10):103-111.
王传财,高作文,权力伟. 薄壁铝合金T形结构MIG焊接热源复合模型的构建与模拟[J]. 电焊机,2023,53(01):25-30.
WANG C C,GAO Z W,QUAN L W. Construction and Simulation of Heat Source Composite Model for MIG Welding of T-shaped Thin Wall Aluminum Alloy[J].Electric Welding Machine,2023,53(01):25-30.
王煜,赵海燕,吴甦,等. 高能束焊接双椭球热源模型参数的确定[J]. 焊接学报,2003(02):67-70.
WANG Y,ZHAO H Y,WU S,et al. Shape parameter determination of double ellipsoid heat source model in numerical simulation of high energy beam welding[J].Transactions of the China Welding Institution,2003(02):67-70.
卫亮,张乐乐,王鹏. 高速列车框架焊接的双椭圆柱高斯分布热源模型[J]. 焊接学报,2016,37(12):95-100,133.
WEI L,ZHANG L L,WANG P. Numerical simulation on welding process of high-speed train’s frame structure based on double elliptical cylinder Gaussian distribution heat source model[J]. Transactions of the China Welding Institution, 2016,37(12):95-100,133.
董文超,文明月,庞辉勇,等.Fe-Cr-Ni-Mo系高强钢焊接热影响区特征热循环曲线的建立与组织[J].金属热处理,2017,42(12):207-212..
DONG W C,WEN M Y,PANG H Y,et al. Microstructure and characterized thermal cycle curve of heat-affected zone of a Fe-Cr-Ni-Mo high-strength steel[J]. Heat Treatment of Metals,2017,42(12):207-212.
阮梦婷. 基于多信号焊接热源模型优化的焊接数值模拟与试验[D]. 黑龙江:哈尔滨工程大学,2021.
RUAN M T. Welding numerical simulation and testt based on multi-signal welding heat source model optimization[D]. Heilongjiang: Harbin Engineering University,2021.
徐洲,李晓延,吴奇,等. 基于组合热源模型的中厚板MIG焊模拟[J]. 电焊机,2021,51(11):44-49.
XU Z,LI X Y,WU Q, et al. MIG welding simulation of medium plate based on combined heat source model[J]. Electric Welding machine,2021,51(11):44-49.
乔及森,芮正雷,高振云,等. 组合热源模型下焊剂片约束电弧焊温度场预测[J]. 兰州理工大学学报,2020,46(04):27-32.
QIAO J S,RUI Z L,GAO Z Y,et al. Prediction on flux bands constrained arc welding process based on a hybrid heating source model[J]. Journal of Lanzhou University of Technology,2020,46(04):27-32.
Mahapatra M M,Datta G L,Pradhan B,et al. Modeling of angular distortion of double pass butt-welded plate[J]. Journal of Engineering Manufacture,2007,222;391-401.
李红涛,宋绪丁. 不同热源模型对Q345中厚板焊接温度场的影响[J]. 热加工工艺,2017,46(23):205-209.
LI H T,SONG X D. Influence of Different Heat Source Models on Welding Temperature Field of Q345 Medium Plate[J]. Hot working process, 2017,46(23):205-209.
李小兵. 基于不同热源模型的Q345钢中厚板焊接温度场数值模拟[J]. 焊接技术,2020,49(10):19-21.
LI X B. Numerical Simulation of Welding Temperature Field of Q345 Steel Plate Based on Different Heat Source Models[J]. Hot Working Technology,2020,49(10):19-21.
李培麟,陆皓. 双椭球热源参数的敏感性分析及预测[J]. 焊接学报,2011,32(11):89-91,95,117-118.
LI P L, LU H. Sensitivity analysis and prediction of double ellipsoid heat source parameters[J]. Transactions of the China Welding Institution,2011,32(11):89-91,95,117-118.
郭宁生,徐胜利,王辉,等. 焊接角度对焊接结构疲劳性能的影响[J]. 热加工工艺,2009,38(23):163-165.
GUO N S,XU S L,WANG H,et al. Effect of Welding Angle on Fatigue Performance of Welded Structure[J]. Hot Working Technology,2011,32(11):89-91,95,117-118.
LV J X,Yang W,Wu S K,et. A. Microstructure and mechanical properties of galvanized steel/AA6061 joints by laser fusion brazing welding[J]. Acta Metallurgica Sinica,2014,27(4):670-676.
相关作者
相关机构
公网安备11010802024621