CO2驱油封存泄漏风险管理系统及应用研究

doi:10.13809/j.cnki.cn32-1825/te.2024.01.013

Abstract

Abstract:

CO₂ flooding and sequestration technology can significantly improve crude oil recovery rates while enge. However, the oil displaceabling large-scale CO₂ flooding and sequestration process is accompanied by various CO₂ leakage risks. In response to the lack of previous CO₂ leakage risk management systems, especially the absence of systems based on online monitoring that support dynamic risk management, research has been conducted on the construction of a CO₂ flooding and sequestration leakage risk management system. Based on the construction of CO₂ flooding and storage leakage risk management system, a dynamic CO₂ leakage risk management system integrating multi-environment real-time risk identification and assessment, multi-space risk prediction, multi-level risk early warning and whole process risk control was developed and applied to the CO₂ flooding and storage demonstration project of Yanchang Petroleum in Ordos Basin. Case studies demonstrate that the developed CO₂ leakage risk management system can dynamically identify various leakage risks throughout the CO₂ flooding and sequestration process across all spaces, effectively supporting the dynamic management of leakage risks. This provides comprehensive and timely safety assurance for CO₂ flooding and sequestration projects, ensuring that potential risks are managed and mitigated effectively to maintain the integrity and success of these projects.

Key words: CO₂ flooding and sequestration, CO₂ leakage, risk management, risk prediction, risk warning, decision support

CLC Number:

TE38

ZHANG Zhisheng, WU Xiangyang, WU Qian, WANG Jixing, LIN Hanchi, GUO Junhong, WANG Rui, LI Jinhua, LIN Qianguo. Risk management system and application of CO₂ flooding and sequestration leakage[J].Petroleum Reservoir Evaluation and Development, 2024, 14(1): 91-101.

Figures/Tables 10

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数据类型	内容
监测信息	深部地层地下水在线监测表
	取样分析数据表
	浅层地下水监测表
	地表水在线监测表
	土壤在线监测表
	大气在线监测表
	地表水水质监测表
风险预警	预警信息表
	风险等级表
	风险与预警映射表
方案措施	方案信息表
	方案措施表
	方案与风险映射表
	方案与措施映射表
系统管理	用户表
	角色表
	权限表
	功能模块表

监测对象	监测点数	监测层位	监测指标
浅层地下水	4	洛河组的地下水层	CO₂质量浓度、温度、pH值、电导率、压力
地表水	2	贺庄沟水库中间水域1.0 m和1.5 m	CO₂质量浓度、温度、pH值、电导率、压力
土壤	12	距离地面1.5 m和2.0 m深度	CO₂质量浓度、pH值、电导率、温度、土壤含水率
地表大气	12	距离地面1.0 m和1.5 m高度	CO₂体积分数、温度、湿度、风速、风向、压力

风险空间	指标	安全	基本不安全	不安全
盖层	长2+3层 CO₂质量浓度	小于等于背景值阈值	大于背景值阈值	大于背景值阈值
盖层	长1层CO₂质量浓度	小于等于背景值阈值	小于等于背景值阈值	大于背景值阈值
浅表地下水	CO₂质量浓度、pH值	pH值无明显改变	pH值改变不大于1个等级	pH值改变大于1个等级
土壤	土壤pH值	pH值相对背景值没有明显改变	pH值减小值不大于0.5	pH值减小值大于0.5
地表大气	CO₂体积分数阈值	≤0.10%	（0.10%，0.15%]	>0.15%

监测空间	安全性	预警对象	预警方式	预警信息
地下水	基本不安全	操作人员	弹窗发出声音	“XX站地下水泄漏风险”
	基本不安全	管理人员	短信发送到手机	地下水泄漏有风险
	不安全	操作人员	弹窗发出声音	“XX站地下水泄漏风险”
	不安全	管理人员	短信发送到手机	地下水泄漏有风险
土壤	基本不安全	操作人员	弹窗发出声音	“XX站土壤泄漏风险”
	基本不安全	管理人员	短信发送到手机	土壤泄漏有风险
	不安全	操作人员	弹窗发出声音	“XX站土壤泄漏风险”
	不安全	管理人员	短信发送到手机	土壤泄漏有风险
大气	基本不安全	操作人员	弹窗发出声音	“XX站大气泄漏风险”
	基本不安全	管理人员	短信发送到手机	大气泄漏有风险
	不安全	操作人员	弹窗发出声音	“XX站大气泄漏风险”
	不安全	管理人员	短信发送到手机	大气泄漏有风险

安全性	泄漏源	源头消减	途径控制	末端减缓
基本不安全	盖/断层泄漏	减少关联井CO₂注入	暂堵剂识别，永久封堵盖层泄漏通道	打开水源井，保持井水和大气联通以释放水中CO₂
基本不安全	井筒泄漏	减少关联井CO₂注入并修复井筒	暂堵剂识别，永久封堵井筒泄漏通道	打开水源井，保持井水和大气联通以释放水中CO₂
不安全	盖/断层突破上升	停止关联井CO₂注入	暂堵剂识别，永久封堵盖层泄漏通道	打开水源井，保持井水和大气联通以释放水中CO₂；抽气强化CO₂的释放
不安全	井筒泄漏	停止关联井CO₂注入并修复井筒	暂堵剂识别，永久封堵井筒泄漏通道	打开水源井，保持井水和大气联通以释放水中CO₂；抽气强化CO₂的释放

Risk management system and application of CO₂ flooding and sequestration leakage

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Risk management system and application of CO₂ flooding and sequestration leakage