目的:研究喷丸工艺对AZ91 D镁合金表面残余应力场的影响。方法基于有限元平台建立喷丸强化AZ91 D镁合金的有限元模型,从残余压应力层的厚度、残余压应力的峰值及其深度等方面探讨弹丸速度、弹丸直径和弹丸入射角对AZ91 D镁合金表面残余应力场的影响,并通过喷丸强化AZ91 D镁合金的实验与有限元模拟结果进行对比。结果增大弹丸速度对残余压应力层的厚度、残余压应力的峰值提高效果明显,但对残余压应力峰值的深度影响不大;增加弹丸直径,残余压应力层的厚度、残余压应力的峰值及其深度均有明显提高;增大入射角,残余压应力层的厚度、残余压应力的峰值有明显提高,但是残余压应力峰值的深度基本不变。有限元模拟结果中,残余压应力层的厚度比实验值小7%,残余压应力的峰值比实验值大5%,残余压应力峰值的深度比实验值小11%。结论残余应力的实验结果与有限元模拟结果具有较好的一致性,模型合理。
Objective To study the impact of the shot peening process on surface residual stress field of AZ91D magnesium al-loy. Methods This paper established a finite element model of shot peening AZ91D magnesium alloy based on finite element plat-form and discussed the influence of pellet shot velocity, shot pellet diameter and incidence angle on the surface residual stress field of AZ91D magnesium alloy mainly from the aspects of the compressive residual stress layer thickness, the compressive residual stress peak and the depth of compressive residual stress peak. Besides, results of shot peening test and finite element simulation were compared. Results The compressive residual stress layer thickness and compressive residual stress peak increased significantly with the increase of shot velocity, but the increase of shot velocity had little influence on the depth of compressive residual stress. The compressive residual stress layer thickness, the compressive residual stress peak and the depth of compressive residual stress peak increased significantly with the increase of shot pellet diameter. By increasing the incidence angle, the compressive residual stress layer thickness and the compressive residual stress peak increased significantly, but the depth of the compressive residual stress peak value basically remained unchanged. The compressive residual stress layer thickness of finite element simulation was 7% smaller than the test results, the compressive residual stress of finite element simulation was 5% higher than the test results, and the depth of compressive residual stress of finite element simulation was 11% smaller than the test results. Conclusion Residu-al stress test results have good consistency with finite element simulation results, verifying the validity of the finite element model.
参考文献
| [1] | 李玉青;吴殿杰.汽车轻量化以及铝镁铸件的应用[J].中国铸造装备与技术,2005(4):48-50. |
| [2] | 王新印;周亚茹;张鉴清;曹发和.镁及其合金腐蚀析氢的研究现状[J].装备环境工程,2015(4):129-136,141. |
| [3] | 慕伟意;李争显;杜继红;奚正平.镁合金的应用及其表面处理研究进展[J].表面技术,2011(2):86-91. |
| [4] | 梁春林;刘宜汉;韩变华;李红兵;吉海滨;姚广春.镁合金表面处理研究现状及发展趋势[J].表面技术,2006(6):57-60,64. |
| [5] | 高玉魁.表面强化对A-100钢带孔构件疲劳性能的影响[J].材料热处理学报,2014(05):160-164. |
| [6] | Y.K. Gao;X.R. Wu.Experimental investigation and fatigue life prediction for 7475-T7351 aluminum alloy with and without shot peening-induced residual stresses[J].Acta materialia,20119(9):3737-3747. |
| [7] | 何少杰;杨文玉;郭步鹏;周瑞虎.机加工表面残余应力及其疲劳寿命评价的研究进展[J].表面技术,2015(6):120-126,132. |
| [8] | 何柏林;邓海鹏.表面完整性研究现状及发展趋势[J].表面技术,2015(9):140-146,152. |
| [9] | 赵艳丽;王强;杨庆祥;高玉魁.喷丸工艺参数对A-100高强度钢残余应力场的影响[J].金属热处理,2013(8):10-14. |
| [10] | 李鹏;刘道新;关艳英;成书民;赵远兴;曹亮;李欢.喷丸强化对新型7055-T7751铝合金疲劳性能的影响[J].机械工程材料,2015(1):86-89,93. |
| [11] | 刘道新;何家文.喷丸强化因素对Ti合金微动疲劳抗力的作用[J].金属学报,2001(2):156-160. |
| [12] | 刘飞宏;王建明;余丰;张刚.基于SPH耦合有限元法的喷丸残余应力场数值模拟[J].山东大学学报(工学版),2010(6):67-71. |
| [13] | 刘海英;轧刚;路会龙.超声喷丸强化产生残余应力的有限元分析[J].新技术新工艺,2008(1):25-28. |
| [14] | Gariépy, A.;Larose, S.;Perron, C.;Lévesque, M..Shot peening and peen forming finite element modelling-towards a quantitative method[J].International Journal of Solids and Structures,201120(20):2859-2877. |
| [15] | Baskaran Bhuvaraghan;Sivakumar M. Srinivasan;Bob Maffeo;Robert D. McCLain;Yogesh Potdar;Om Prakash.Shot peening simulation using discrete and finite element methods[J].Advances in engineering software,201012(12):1266-1276. |
| [16] | 周霞;赵昌美;李利;黄宏军.基于SHPB实验的挤压AZ91D镁合金动态力学行为数值模拟[J].中国有色金属学报,2014(8):1968-1975. |
| [17] | Miao, H. Y.;Larose, S.;Perron, C.;Levesque, Martin.On the potential applications of a 3D random finite element model for the simulation of shot peening[J].Advances in engineering software,200910(10):1023-1038. |
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