中国大规模盐穴储氢需求与挑战

氢能是来源广泛且低碳清洁的能源,大力发展氢能产业是实现双碳目标和应对全球能源转型的重要举措。在氢能“制备―储存―运输―应用”全产业链中,储氢难问题长期制约着氢能产业高质量发展。盐穴储氢具有成本低、规模大、安全性高和储氢纯度高等突出优势,是未来氢能大规模储备的重要发展方向,也是我国能源低碳转型的重大战略需求。综合调研了我国制氢产业和氢能消费现状,分析了我国盐穴储氢的需求。调研了国外利用盐穴储存天然气和氢气的技术及工程现状,总结了我国盐穴储气库发展和建设历程。对比了利用盐穴储存天然气、氦气、压缩空气和氢气的异同点,提出我国盐穴储氢面临三大科技挑战:层状盐岩氢气渗透与生化反应、盐穴储氢库井筒完整性管控、储氢库群灾变孕育与防控。研究成果明确了我国氢气储备需求的快速增长趋势和大规模盐穴储氢的重点攻关方向。

地下盐穴储气库泄漏原因及防治措施研究

良好的密闭性能是盐穴储气库安全运营的基本前提,但地质赋存条件复杂、建库实践不足、理论体系不完备等均会导致盐腔遭遇各类泄漏风险。根据国内外的工程实践及事故统计,再结合盐穴储库特有的工程地质条件和运行工况,总结出三大泄漏因素(地质因素、工程因素、人为失误)和4种泄漏类型。地下盐穴储气库潜在的泄漏类型有夹层密闭性不足引起的气体近水平漏失、盖层被突破失效致使气体上窜、井筒完整性不足致使气体逃逸、夹层与断层连通致使气体流向断层。最终,依据各自的泄漏特征提出了相应的预防处置措施,以防止气体泄漏事故的发生和大范围的蔓延。由于我国盐穴储库的发展暂时处于上升期,研究结果对深部盐穴储气库的安全建设具有一定的借鉴和指导意义。

多夹层盐矿水采沉渣空隙特征与储气能力评价

在低品位、多夹层盐矿地层中建设地下储库,利用水采溶腔(盐穴)底部不溶物沉渣空隙储气有望较大幅度扩大储气库库容,但需要开展沉渣空隙储气可行性和适用性评估。首先,采用不溶物沉渣制备大尺寸CT扫描试样,构建了沉渣空隙三维重构模型,定性分析了沉渣空隙尺寸和空隙连通性,发现沉渣空隙尺寸大且连通性好;其次,采用自主研制的盐矿水采沉渣储气试验装置,利用不溶物小颗粒和夹层垮塌大尺寸块体混合堆积样品进行注气排卤试验,测定注气排卤前后沉渣空隙率,分析了沉渣空隙率变化的原因;最后,建立沉渣空隙体积预测模型,提出了盐腔采动空间和沉渣可排卤水体积的计算公式。通过考虑盐层不溶物小颗粒连续堆积,又考虑夹层垮塌大尺寸块体无序堆积,计算了沉渣堆积体积及可排卤储气体积,计算结果与现场采卤数据吻合较好。该研究可为评价低品位、多夹层盐矿沉渣空隙储气能力提供参考。

盐穴储气库微渗层注浆封堵试验研究

我国盐穴地下储气库大多建造在具有不同渗透性的层状盐岩地层中,因此保证储库拥有良好的密闭性至关重要。针对盐穴井筒“裸眼段”意外跨越微渗地层而导致储气库密闭性失效的问题,自主研发了渗漏地层注浆封堵试验平台,并结合现场地质渗漏情况设计了注浆封堵可行性试验方案。在确定了兼具流动性和填充密实性的浆液配合比后,开展了超细水泥封堵岩芯的试验研究。结果表明,超细水泥可以有效填充岩芯孔隙并降低其渗透率,注浆后岩芯孔隙率和渗透率降幅分别达到近16%和95%。封堵试验数据显示浆液封堵范围与注浆时间呈幂函数关系,浆液流型满足幂律流,而非牛顿流。该研究成果可为盐穴储气库微渗地层注浆封堵提供必要的理论和试验依据,对类似密闭性失效井筒的二次利用具有重要意义。

Experimental study on repair characteristics of damaged rock salt of underground gas storage

Damage in rock salt has significant implication on permeability, which affects the tightness of underground salt cavern gas storage in further. During the leaching of a salt cavern, the brine with formation temperature and pressure can promote the self-healing of rock salt in the excavation damage zone (EDZ). Laboratory tests were conducted to study the promoting effect. The permeability of two intact rock salt specimens was tested. Then they were damaged into two kinds of the state respectively through uniaxial compression. After that, they were put in saturated brine (with a temperature of 50℃ and pressure of 12 MPa, which we called the repair environment in this paper) for 7 d. Finally, the permeability and mechanical properties were obtained after the damaged specimens being repaired. The results show that the permeability of intact rock salt is below 10^-19 m^2;the permeability increases by more than two orders because of damage;the permeability decreases significantly after being repaired, which can be comparable to its intact state. Discussions of the repair mechanisms are presented (especially the mechanism of recrystallization), which may help to provide significant guidance for the study of the tightness and stability of gas storage facilities in China.