Risk evaluation model of deepwater drilling blowout accident based on risk entropy and complex network

doi:10.11949/j.issn.0438-1157.20180501

Abstract

Abstract:

To control the cascading risk of deepwater blowout, a quantitative evaluation method associated with risk uncertainty and evolution of deepwater drilling system was proposed, based on risk entropy theory and complex network theory. The complicated accident scenario was converted into an intuitive network computing. Firstly, according to the drilling process, a complex network that includes 59 nodes and 102 edges was constructed to represent the accident scene and calculate the clustering coefficient. Secondly, referring to the Shannon entropy theory, the risk entropy was introduced to characterize the uncertainty of risk transmission, in view of its randomness and fuzziness. Finally, the shortest path formulation of the blowout network was described, and the formulation was then converted into a liner programming and a solution of the shortest path of every initial event was provided by utilizing the Dijkstra algorithm. The results show that the clustering coefficient of deepwater drilling blowout network is 0.132. The evolutional structure has the characteristics of small world with low aggregation but high evolutionary of nodes. In addition, shallow gas during drilling has the greatest influence on the blowout accident. The blowout accident has the greatest impact, but the risk of all initial events can be caused by a few steps to cause the blowout accident to verify the feasibility of the method in the quantitative risk assessment of complex process systems.

Key words: deepwater drilling blowout, safety, process systems, uncertainty, entropy, complex network, shortest path

摘要：

针对深水钻井作业安全问题，基于风险熵和复杂网络理论，在考虑风险不确定性的基础上，提出深水钻井井喷事故风险演化量化评估方法。依据深水钻井流程，构建井喷事故场景复杂网络演化模型，判断节点聚类性；针对风险传递的随机性与模糊性，引入风险熵表征两类不确定性；给出风险传递路径最大可能性的表达式，并转化为线性规划问题，通过Dijkstra算法得出事故最短路径。结果表明：深水井喷事故复杂网络的聚类系数为0.132，节点聚集程度较低而演化性较强，具有小世界网络特征；以自然因素类的钻遇浅层气作为初始事件的风险传递路径对井喷事故的影响最大，但所有初始事件的风险经少数几步传递即可导致井喷事故的发生，验证该方法在复杂过程系统定量风险评估方面的可行性。

关键词: 深水钻井井喷, 安全, 过程系统, 不确定性, 熵, 复杂网络, 最短路径

CLC Number:

TE 58

Xiangkun MENG, Guoming CHEN, Chunliang ZHENG, Xiangfei WU, Gaogeng ZHU. Risk evaluation model of deepwater drilling blowout accident based on risk entropy and complex network[J]. CIESC Journal, 2019, 70(1): 388-397.

孟祥坤, 陈国明, 郑纯亮, 吴翔飞, 朱高庚. 基于风险熵和复杂网络的深水钻井井喷事故风险演化评估[J]. 化工学报, 2019, 70(1): 388-397.

Figures/Tables 8

References 30

1	TamimN, LaboureurD M, MentzerR A, et al. A framework for developing leading indicators for offshore drillwell blowout incidents[J]. Process Safety & Environmental Protection, 2017, 106: 256-262.
2	孙宝江, 王志远, 公培斌, 等. 深水井控的七组分多相流动模型[J]. 石油学报, 2011, 32(6): 1042-1049.
	SunB J, WangZ Y, GongP B, et al. Application of a seven-component multiphase flow model to deepwater well control[J]. Acta Petrolei Sinica, 2011, 32(6): 1042-1049.
3	褚道余. 深水井控工艺技术探讨[J]. 石油钻探技术, 2012, 40(1): 52-57.
	ChuD Y. Well control technology in deepwater well[J]. Petroleum Drilling Techniques, 2012, 40(1): 52-57.
4	BhandariJ, AbbassiR, GaraniyaV, et al. Risk analysis of deepwater drilling operations using Bayesian network[J]. Journal of Loss Prevention in the Process Industries, 2015, 38: 11-23.
5	PraneshV, PalanichamyK, SaidatO, et al. Lack of dynamic leadership skills and human failure contribution analysis to manage risk in deep water horizon oil platform[J]. Safety Science, 2017, 92: 85-93.
6	SkogdalenJ E, UtneI B, VinnemJ E. Developing safety indicators for preventing offshore oil and gas deepwater drilling blowouts[J]. Safety Science, 2011, 49(8): 1187-1199.
7	LiW, ZhangL, LiangW. An accident causation analysis and taxonomy (ACAT) model of complex industrial system from both system safety and control theory perspectives[J]. Safety Science, 2017, 92: 94-103.
8	MengX, ChenG, ShiJ, et al. STAMP-based analysis of deepwater well control safety[J]. Journal of Loss Prevention in the Process Industries, 2018, 55(5): 41-52.
9	XueL, FanJ, RausandM, et al. A safety barrier-based accident model for offshore drilling blowouts[J]. Journal of Loss Prevention in the Process Industries, 2013, 26(1): 164-171.
10	VenkatasubramanianV. Systemic failures: challenges and opportunities in risk management in complex systems[J]. AIChE Journal, 2011, 57(1): 2-9.
11	DengY, LiQ, LuY. A research on subway physical vulnerability based on network theory and FMECA[J]. Safety Science, 2015, 80: 127-134.
12	刘文颖, 王佳明, 谢昶, 等. 基于脆性风险熵的复杂电网连锁故障脆性源辨识模型[J]. 中国电机工程学报, 2012, 32(31): 142-149.
	LiuW Y, WangJ M, XieC, et al. Brittleness source identification model for cascading failure of complex power grid based on brittle risk entropy[J]. Proceedings of the CSEE, 2012, 32(31): 142-149.
13	蔡晔, 曹一家, 谭玉东, 等. 基于标准化结构熵的电网结构对连锁故障的影响[J]. 电工技术学报, 2015, 30(3): 36-43.
	CaiY, CaoY J, TanY D, et al. Influences of power grid structure on cascading failure based on standard structure entropy[J]. Transactions of China Electrotechnical Society, 2015, 30(3): 36-43.
14	苟竞, 刘俊勇, 刘友波, 等. 基于能量熵测度的电力系统连锁故障风险辨识[J]. 电网技术, 2013, 37(10): 2754-2761.
	GouJ, LiuJ Y, LiuY B, et al. Energy entropy measure based risk identification of power system cascading failures[J]. Power System Technology, 2013, 37(10): 2754-2761.
15	孟祥坤, 陈国明, 朱红卫. 海底管道泄漏风险演化复杂网络分析[J]. 中国安全生产科学技术, 2017, 13(4): 26-31.
	MengX K, ChenG M, ZhuH W. Complex network analysis on risk evolution of submarine pipeline leakage[J]. Journal of Safety Science and Technology, 2017, 13(4): 26-31.
16	陈长坤, 纪道溪. 基于复杂网络的台风灾害演化系统风险分析与控制研究[J]. 灾害学, 2012, 27(1): 1-4.
	ChenC K, JiD X. Risk analysis and control for the evolution disaster system of typhoon based on complex network[J]. Journal of Catastrophology, 2012, 27(1): 1-4.
17	付建民, 李成美, 东静波, 等. 数据不确定条件下安全仪表系统SIL等级验证方法研究[J]. 中国石油大学学报(自然科学版), 2017, 41(3): 129-135.
	FuJ M, LiC M, DongJ B, et al. Study on method of SIL verification of safety instrumented systems under data uncertainty[J]. Journal of China University of Petroleum (Edition of Natural Science), 2017, 41(3): 129-135.
18	魏心泉, 王坚. 基于熵的火灾场景介观人群疏散模型[J]. 系统工程理论与实践, 2015, 35(10): 2473-2483.
	WeiX Q, WangJ. A mesoscopic evacuation model based on multi-agent and entropy with leading behavior under fire conditions[J]. System Engineering- Theory & Practice, 2015, 35(10): 2473-2483.
19	胡瑾秋, 郭家洁. 基于尺度效应的过程安全事故概率估计[J]. 化工学报, 2017, 68(12): 4848-4856.
	HuJ Q, GuoJ J. Accident probability estimation of process safety based on scale effect[J]. CIESC Journal, 2017, 68(12): 4848-4856.
20	胡瑾秋, 张来斌, 王安琪. 炼化装置故障链式效应定量安全预警方法[J]. 化工学报, 2016, 67(7): 3091-3100.
	HuJ Q, ZhangL B, WangA Q. Quantitative safety early warning method of fault propagation for petrochemical plants[J]. CIESC Journal, 2016, 67(7): 3091-3100.
21	胡瑞敏, 吕海涛, 陈军. 基于风险熵和Neyman-Pearson准则的安防网络风险评估研究[J]. 自动化学报, 2014, 40(12): 2737-2746.
	HuR M, LüH T, ChenJ. Risk evaluation model of security and protection network based on risk entropy and Neyman- Pearson criterion[J]. Acta Automatica Sinica, 2014, 40(12): 2737-2746.
22	LevesonN. A new accident model for engineering safer systems[J]. Safety Science, 2004, 42(4): 237-270.
23	LevesonN G, StephanopoulosG. A system-theoretic, control-inspired view and approach to process safety[J]. AIChE Journal, 2014, 60(1): 2-14.
24	AbimbolaM, KhanF, KhakzadN, et al. Safety and risk analysis of managed pressure drilling operation using Bayesian network[J]. Safety Science, 2015, 76(1): 133-144.
25	AbimbolaM, KhanF, KhakzadN. Dynamic safety risk analysis of offshore drilling[J]. Journal of Loss Prevention in the Process Industries, 2014, 30(3): 74-85.
26	KhakzadN, KhanF, AmyotteP. Quantitative risk analysis of offshore drilling operations: a Bayesian approach[J]. Safety Science, 2013, 57: 108-117.
27	ZareiE, AzadehA, KharzadN, et al. Dynamic safety assessment of natural gas stations using Bayesian network[J]. Journal of Hazardous Materials, 2017, 321: 830-840.
28	董海波, 顾学康. 基于模糊故障树方法的钻井平台井喷概率计算[J]. 中国造船, 2013, 54(1): 155-165.
	DongH B, GuX K. Probability calculation of blowout of drilling platform based on fuzzy fault tree method[J]. Shipbuilding of China, 2013, 54(1): 155-165.
29	OnisawaT. An approach to human reliability in man-machine systems using error possibility[J]. Fuzzy Sets and Systems, 1988, 27(2): 87-103.
30	LavasaniS M, ZendeganiA, CelikM. An extension to fuzzy fault tree analysis (FFTA) application in petrochemical process industry[J]. Process Safety & Environmental Protection, 2015, 93(2): 75-88.

编号	风险因素	编号	风险因素	编号	风险因素
v₁	钻进操作因素	v₂₁	损坏固井质量	v₄₁	溢流进入隔水管
v₂	工艺因素	v₂₂	表层套管下沉	v₄₂	关闭环形BOP
v₃	自然因素	v₂₃	地层压力高于井底压力	v₄₃	环形BOP密封失效
v₄	设备因素	v₂₄	井底压力过大	v₄₄	环形BOP机械故障
v₅	固井质量差	v₂₅	压裂地层	v₄₅	液压系统故障
v₆	起钻过快	v₂₆	溢流	v₄₆	环形BOP操作失误
v₇	循环漏失	v₂₇	溢流流体进入井筒环空	v₄₇	环形BOP关闭失败
v₈	抽汲压力过大	v₂₈	早期溢流监测失效	v₄₈	关闭闸板BOP
v₉	钻井液密度过低	v₂₉	钻井液流量指示器失效	v₄₉	剪切闸板密封失效
v₁₀	气侵钻井液	v₃₀	气体流量传感器失效	v₅₀	闸板BOP机械故障
v₁₁	钻井液密度过大	v₃₁	随钻测压工具失效	v₅₁	闸板BOP操作失误
v₁₂	钻遇高渗地层	v₃₂	气体含量传感器失效	v₅₂	水合物阻塞BOP组
v₁₃	钻遇浅层气	v₃₃	控制电路失效	v₅₃	自动关断失效
v₁₄	钻遇浅层水流	v₃₄	钻井监督显示器故障	v₅₄	RCD密封失效
v₁₅	套管破裂	v₃₅	录井工对泥浆池增量判断失误	v₅₅	分流系统机械故障
v₁₆	钻杆失效	v₃₆	司钻与录井工协作失误	v₅₆	RCD操作失误
v₁₇	隔水管系统失效	v₃₇	误报警导致司钻判断失误	v₅₇	不压井起下作业装置失效
v₁₈	泥浆泵失效	v₃₈	未监测到井涌	v₅₈	分流失效
v₁₉	井口系统失效	v₃₉	井涌判断失误	v₅₉	井喷
v₂₀	动力故障	v₄₀	井涌后未停钻	—	—

编号	风险因素	编号	风险因素	编号	风险因素
v₁	钻进操作因素	v₂₁	损坏固井质量	v₄₁	溢流进入隔水管
v₂	工艺因素	v₂₂	表层套管下沉	v₄₂	关闭环形BOP
v₃	自然因素	v₂₃	地层压力高于井底压力	v₄₃	环形BOP密封失效
v₄	设备因素	v₂₄	井底压力过大	v₄₄	环形BOP机械故障
v₅	固井质量差	v₂₅	压裂地层	v₄₅	液压系统故障
v₆	起钻过快	v₂₆	溢流	v₄₆	环形BOP操作失误
v₇	循环漏失	v₂₇	溢流流体进入井筒环空	v₄₇	环形BOP关闭失败
v₈	抽汲压力过大	v₂₈	早期溢流监测失效	v₄₈	关闭闸板BOP
v₉	钻井液密度过低	v₂₉	钻井液流量指示器失效	v₄₉	剪切闸板密封失效
v₁₀	气侵钻井液	v₃₀	气体流量传感器失效	v₅₀	闸板BOP机械故障
v₁₁	钻井液密度过大	v₃₁	随钻测压工具失效	v₅₁	闸板BOP操作失误
v₁₂	钻遇高渗地层	v₃₂	气体含量传感器失效	v₅₂	水合物阻塞BOP组
v₁₃	钻遇浅层气	v₃₃	控制电路失效	v₅₃	自动关断失效
v₁₄	钻遇浅层水流	v₃₄	钻井监督显示器故障	v₅₄	RCD密封失效
v₁₅	套管破裂	v₃₅	录井工对泥浆池增量判断失误	v₅₅	分流系统机械故障
v₁₆	钻杆失效	v₃₆	司钻与录井工协作失误	v₅₆	RCD操作失误
v₁₇	隔水管系统失效	v₃₇	误报警导致司钻判断失误	v₅₇	不压井起下作业装置失效
v₁₈	泥浆泵失效	v₃₈	未监测到井涌	v₅₈	分流失效
v₁₉	井口系统失效	v₃₉	井涌判断失误	v₅₉	井喷
v₂₀	动力故障	v₄₀	井涌后未停钻	—	—

语言变量	梯形模糊数	定性描述	概率表征
非常低(VL)	(0, 0, 0.1, 0.2)	基本不可能发生	(0, 10^-6)
低(L)	(0.1, 0.25, 0.25, 0.4)	全寿命周期内可能发生	(10^-6, 10^-3)
中等(M)	(0.3, 0.5, 0.5, 0.7)	全寿命周期内有时发生	(10^-3, 10^-2)
高(H)	(0.6, 0.75, 0.75, 0.9)	全寿命周期内发生数次	(10^-2, 10^-1)
非常高(VH)	(0.8, 0.9, 1, 1)	经常会发生	(10^-1, 1)

语言变量	梯形模糊数	定性描述	概率表征
非常低(VL)	(0, 0, 0.1, 0.2)	基本不可能发生	(0, 10^-6)
低(L)	(0.1, 0.25, 0.25, 0.4)	全寿命周期内可能发生	(10^-6, 10^-3)
中等(M)	(0.3, 0.5, 0.5, 0.7)	全寿命周期内有时发生	(10^-3, 10^-2)
高(H)	(0.6, 0.75, 0.75, 0.9)	全寿命周期内发生数次	(10^-2, 10^-1)
非常高(VH)	(0.8, 0.9, 1, 1)	经常会发生	(10^-1, 1)

Parameter	Value
S_ij(E_i, E_j)	(1, 0.825, 0.825)
AA(E_i)	(0.913, 0.913, 0.825)
RA(E_i)	(0.344,0.344, 0.311)
CC(E_i)	(0.402, 0.369, 0.229)
R_AG	(0.646, 0.784, 0.807, 0.923)