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Abstrakty
The high temperature and thermal radiation caused by generator fire accidents on the offshore platform lead to the destruction of equipment and facilities and threaten the structural safety of the offshore platform. Based on the background of a crude oil generator fire accident on an offshore platform, KFX software was used to conduct a numerical simulation of the fire process and explore the spatial-temporal variation characteristics of smoke, temperature and heat radiation within the scope of the fire room. The influence ranges of 12.5 kW/m2, 25 kW/m2 and 35 kW/m2 were obtained according to the thermal radiation criterion. Researchers examined the temperature variation and heat flow at the room’s ceiling and floor near the primary steel support. The results show that: 1) The surface temperatures of partial steel supports exceed 550°C, and the heat flux of partial steel supports exceeds 37.5 kW/m2. 2) In the ignition position, the maximum temperature at the ceiling reaches 2299°C when t = 24 s, and the maximum temperature at the flooring reaches 701°C when t = 79 s. The heat radiation flux at the ceiling and flooring both exceeds 25 kW/m2. The maximum temperature of partial crude oil generators can reach 1299°C. 3) The heat radiation flux of partial generators can reach 105 kW/m2, and the heat radiation flux at the adjacent point of partial generators never exceeds 20 kW/m2. The above research results can provide a reference for checking the response time of flame detectors and the strength of the supporting structure.
Wydawca
Czasopismo
Rocznik
Tom
Strony
267--283
Opis fizyczny
Bibliogr. 20 poz., fot., rys., tab., wykr.
Twórcy
autor
- Department of Engineering Design and Research, CNOOC Research Institute Co., Ltd. 100028 Beijing, China
autor
- Department of Engineering Design and Research, CNOOC Research Institute Co., Ltd. 100028 Beijing, China
autor
- College of Safety and Ocean Engineering, China University of Petroleum (Beijing), Beijing 102249, China
- Key Laboratory of Oil and Gas Safety and Emergency Technology, Ministry of Emergency Management, Beijing 102249, China
Bibliografia
- [1] X.F. Song, J.H. Lu, An overview of pool fire models applicable to offshore platforms. Petroleum Engineering Construction 37 (2), 1-5, 83 (2011).
- [2] Z.S. Luo, J.C. Xu, N.N. Zhang, Analysis of thermal radiation hazard of fire disaster based on offshore oil and gas platforms leakage. Fire Science and Technology 35 (1), 6-10 (2016).
- [3] X.F. Song, Structural analysis of a jacket platform on fire. Ocean University of China. 2011.
- [4] T. Hu, Research on the fire control system design of organic liquid storage tank area. master thesis. Southwest Petroleum University. 2015.
- [5] J. Guo, Y. Zhu, G. Chen, Fire hazard analysis on oil & gas processing systems on the offshore platform based on FDS. China Offshore Oil and Gas 23 (2), 126-130 (2017).
- [6] C.Y. Chen, Numerical simulation of fire heat flow field and evacuation analysis in an ocean platform. Master thesis, Jiangsu University of Science and Technology. 2018.
- [7] F. Tong, Y.N. Xiang, H. Shen, Temperature field and structure response of offshore platform room under local fire. Urbanism and Architecture 18 (403), 130-132 (2021).
- [8] T.X. Niu, K.Q. Zhu, Y.F. Mao, Analysis of FPSO pool fire. Ship Engineering 39 (9), 64-70 (2017).
- [9] J.Y. Yoon, S.H. Kim, G.C. Yu, Effects of wind on the heat flow of FPSO topsides subject to fire: an experimental and numerical study. ASME 2010 International Conference on Ocean 949-958 (2010).
- [10] X.L. Xie, Y. Zhu, Z.Y. Zhang, et al. Performance evaluation and improvement for fire protection systems of FPSO pump cabins. China Offshore and Gas 29 (4), 175-181 (2017).
- [11] G.H. Xu, esearch on the fire risk assessment and simulation of generator room in the offshore oil platform. Master thesis, South China University of Technology. 2017.
- [12] D.P. Yang, G.M. Chen, C.Q. Niu, etc. Simulation and evaluation of oil and gas fire accidents on the shallow sea platform. Safety Health & Environment 19 (1), 19-25 (2019).
- [13] Y.L. Chen, Further development of the eddy dissipation model for turbulent non-premixed flame. Xiamen University 2020.
- [14] S.Y. Ge, H.Y. Na, Thermal radiation properties and measurement. Beijing, Science Press 1989.
- [15] J.D. Yao, W.C. Fan, Theory and numerical simulation of 3D discrete transfer radiation model. Journal of Combustion Science and Technology (3), 264-267 (1995).
- [16] Y.D. Shi, The simulation analysis on buried pipeline fire consequence. Safety Health & Environment 16 (3), 21-24 (2016).
- [17] DNV-GL. KFX-EXISM V.3.4 User Manual, Technical Manual; DNV-GL: Berum, Norway, 2019.
- [18] E.F. Du, Experimental and theoretical research on the structural behavior of large space steel structures subjected to natural fires. Master thesis, Southeast University 2016.
- [19] Z.M. Fu, J.Y. Huang, M. Fu, Quantitative analysis of the radiation damaging effects caused by liquid or gaseous hydrocarbon fires. China Safety Science Journal (9), 29-36 (2008).
- [20] AQT. Guidelines for quantitative risk assessment of chemical enterprises. 3046 (2013).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-41009252-29ce-4cad-8e6a-d31fbe94ac10