Journal of Shanghai Jiaotong University >
Structural Impact Dynamic Response Characteristics of Offshore Platform Blast Wall in High Temperature Environment
Received date: 2019-08-29
Online published: 2021-08-31
The blast wall is an important protection facility for offshore platforms, whose anti-explosion performance needs to be focused on. Based on the nonlinear finite element method, the structural dynamic response of the blast wall under the explosion at normal temperature was studied. The applicability of the quasi-static and dynamic algorithms was compared with the experimental data, and the structural impact deformation forms at room temperature were analyzed. Considering the effects of high temperature on materials and structures, the structural dynamic response characteristics of the blast wall were analyzed. The study shows that the high temperature has a significant aggravating effect on structural response. That is, given the load level, the maximum displacement can reach 5 times of that at normal temperature. Under the impact of normal temperature load, the structural strain is elastic with no permanent deformation or with small deformation, but it may aggravate to huge permanent deformation at a high temperature. The effect of high temperature will change the response pattern of the structure. This research can provide reference for the design of blast wall.
Key words: blast wall; high temperature; explosion; impact; structural dynamic response
WANG Rui, XUE Hongxiang, YUAN Yuchao, TANG Wenyong . Structural Impact Dynamic Response Characteristics of Offshore Platform Blast Wall in High Temperature Environment[J]. Journal of Shanghai Jiaotong University, 2021 , 55(8) : 968 -975 . DOI: 10.16183/j.cnki.jsjtu.2019.249
| [1] | SOLEIMAN-FALLAH A, NWANKWO E, LANG-DON G S, et al. Inelastic deformation and failure of partially strengthened profiled blast walls[J]. The Journal of the Acoustical Society of America, 2013, 134(5):4196. |
| [2] | SYED Z I, MOHAMED O A, RAHMAN S A. Non-linear finite element analysis of offshore stainless steel blast wall under high impulsive pressure loads[J]. Procedia Engineering, 2016, 145:1275-1282. |
| [3] | RAHMAN S A, SYED Z I, KURIAN J V, et al. Structural response of offshore blast walls under accidental explosion[J]. Advanced Materials Research, 2014, 1043:278-282. |
| [4] | SKLEYER G K, LANGDON G S. Pulse pressure testing of 1/4 scale blast wall panels with connections[R]. Norwich, UK: Health and Safety Executive, 2003. |
| [5] | 徐文晶. 约束钢梁在火灾和爆炸共同作用下的响应分析[D]. 上海: 上海交通大学, 2013. |
| [5] | XU Wenjing. Research on response of restricted steel beam under elevated temperature and blast loading[D]. Shanghai: Shanghai Jiao Tong University, 2013. |
| [6] | KIM D K, NG W C K, HWANG O J, et al. Recommended finite element formulations for the analysis of offshore blast walls in an explosion[J]. Latin American Journal of Solids and Structures, 2018, 15(10):e115. |
| [7] | Fire and Blast Information Group (FABIG). Design guide for stainless steel blast walls[R]. Berkshire, UK: Steel Construction Institute, 1999. |
| [8] | MOHAMED ALI R M, LOUCA L A. Performance based design of blast resistant offshore topsides. Part I: Philosophy[J]. Journal of Constructional Steel Research, 2008, 64(9):1030-1045. |
| [9] | 韩鹏程, 田荣, 沈寅忠, 等. 316L奥氏体不锈钢高温拉伸时的动态应变时效[J]. 热加工工艺, 2012, 41(16):1-5. |
| [9] | HAN Pengcheng, TIAN Rong, SHEN Yinzhong, et al. Dynamic strain aging in 316L austenitic stainless steel during tensile test at high temperature[J]. Hot Working Technology, 2012, 41(16):1-5. |
/
| 〈 |
|
〉 |
