| LI Jia-dong,LIN Bing,ZHANG Shi-gui,WANG Ying-ying,ZHU Yuan-qiang,NIE Zhen,TANG Jun-lei.Study on Finite Element Simulation of Pitting Behavior of 304L Stainless Steel under Elastic Tensile Stress[J],50(2):327-337 |
| Study on Finite Element Simulation of Pitting Behavior of 304L Stainless Steel under Elastic Tensile Stress |
| Received:October 15, 2020 Revised:December 28, 2020 |
| View Full Text View/Add Comment Download reader |
| DOI:10.16490/j.cnki.issn.1001-3660.2021.02.035 |
| KeyWord:finite element elastic tensile stress 304L stainless steel pitting stress concentration maximum equivalent stress |
| Author | Institution |
| LI Jia-dong |
School of Chemistry and Chemical Engineering, Southwest Petroleum University, Chengdu , China |
| LIN Bing |
School of Chemistry and Chemical Engineering, Southwest Petroleum University, Chengdu , China |
| ZHANG Shi-gui |
AECC AERO Science and Technology Co., Ltd, Chengdu , China |
| WANG Ying-ying |
School of Chemistry and Chemical Engineering, Southwest Petroleum University, Chengdu , China |
| ZHU Yuan-qiang |
School of Chemistry and Chemical Engineering, Southwest Petroleum University, Chengdu , China |
| NIE Zhen |
Research Institute of Science and Technology Co., Ltd, PetroChina Group, Beijing , China |
| TANG Jun-lei |
School of Chemistry and Chemical Engineering, Southwest Petroleum University, Chengdu , China |
|
| Hits: |
| Download times: |
| Abstract: |
| Through the idealized finite element modeling and simulation calculation, four point bending stress loading method was used to obtain the maximum equivalent stress and the change of pitting pit geometry in 304L stainless steel sheet under different elastic tensile stress conditions, and the axial tensile stress loading method was used to obtain the change law of maximum equivalent stress with the change of shape and size in the pitting pit on 304L stainless steel pipe under different elastic tensile stress conditions, . The models of 304L stainless steel sheet and pipe with hemispherical, cone or cylinder pitting defects are constructed by using finite element method. The stress distribution in pitting pits of 304L stainless steel sheet and pipe model under different elastic tensile stress is systematically studied by using finite element simulation method, and the change of maximum equivalent stress in pitting pit is obtained by simulation calculation in order to analyze the growth and propagation mechanism of pitting under the influence of mechanics. With the increase of elastic tensile stress, the maximum equivalent stress in the hemispherical pit of 304L stainless steel model increases from 68.508 MPa to 328 MPa, that in the cone pit increases from 115.960 MPa to 554.610 MPa, and that in the cylinder pit increases from 97.244 MPa to 466.200 MPa. The maximum equivalent stress growth slopes of the hemisphere, cone and cylinder are 2.01, 3.40 and 2.86, respectively. Moreover, with the increase of the elastic tensile stress, the pitting pits on the surface of 304L stainless steel gradually extend from the stress concentration area, resulting in the shape change. In addition, under the condition of similar pit size, the maximum equivalent stress of the hemisphere and cone of 304L stainless steel pipe model is 26.421 MPa and 49.029 MPa without axial elastic tensile stress, and 135.920 MPa and 300.850 MPa under the action of axial elastic tensile stress. However, with the increase of pit size, the maximum equivalent stress of cone pit decreases from 49.029 MPa to 36.355 MPa without axial elastic tensile stress, and decreases from 212.140 MPa to 135.920 MPa under the action of axial elastic tensile stress. It can be concluded that with the increase of elastic tensile stress, the maximum equivalent stress in the pitting pits of hemisphere, cone and cylinder on 304L stainless steel sheet model increases gradually, with the highest in the cone pit. Moreover, with the increase of elastic tensile stress, the pitting pit shape on the surface of 304L stainless steel gradually changes from the round hole to the strip under the influence of stress concentration. Under different elastic tensile stress conditions, the stress concentration and maximum equivalent stress of the cone pitting on 304L stainless steel pipe model are higher than that of the hemispherical pitting. However, the maximum equivalent stress in the pit decreases with the increase of the pit size. |
| Close |
|
|
|