解决致密白云岩低产能问题的有效化学处理:蚓孔钻和水垢损害的修复

R. Nazari Moghaddam, M. Van Doorn, Auribel Dos Santos, F. Lopez, M. Ulloa, Bogdan Bocaneala, Michael Pitts
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引用次数: 0

摘要

包括致密白云岩在内的非常规储层的经济生产需要一些形式的增产技术来增加井筒与地层之间的有效接触面积。然而,利用常规技术(如酸增产)提高这些地层的产能是非常有限的,而且大多是不可行的。本文提出了一种有效的化学处理方法,通过虫孔机制和基于结垢的破坏去除来刺激致密白云岩的形成。致密储层由于孔喉尺寸较小,对地层的破坏更为严重。其中,由结垢引起的渗透率损害或相圈闭会造成严重的产量损失。在本研究中,所提出的处理液用于去除主要由钻井泥浆引起的水垢性地层损害。为此,研究了高温高压岩心注水处理后,被水垢沉淀人为破坏的白云岩岩心的损害去除效率。此外,该处理液的性能被评估为绕过水力裂缝周围受损区域(由液相捕获或显著的净应力引起)的平均值。为了验证这一点,还在未经处理的致密白云岩岩心上进行了一系列岩心驱替实验,并研究了虫孔机理的可行性。测定了处理前后致密白云岩的渗透率。为了可视化虫洞在岩心内的传播,进行了计算机CT扫描。通过ICP对流出样品进行分析,研究了岩石-流体相互作用。该处理技术的主要机理是岩石缓慢溶蚀作用扩大孔隙体/孔喉。从孔隙尺度分析发现,即使在较低浓度下,活性成分也会与岩石矿物发生反应。对损坏的白云石岩心也进行了处理,结果表明,即使在天然方解石或白云石矿物存在的情况下,也可以实现重晶石基垢的去除。此外,还发现虫洞只能在一定浓度(>10 w%)下才能实现。它还取决于注入速度和其他现场条件,如温度。即使在低浓度下,受损白云岩岩心的岩石渗透率也可以增加35倍(Kf/Ki=35)。最后,以低注入速率(0.08 ~ 0.1 ml/min)处理白云岩储层岩心(25 ~ 30 μD)。结果表明,尽管注入速率(与常规酸化相比)降低了一个数量级,但仍然需要一个最佳的注入速率来将虫孔延伸到岩心上。还验证了活性成分可用于特殊应用的醇基溶液,如致密气和凝析气藏。腐蚀速率远低于0.05 lb/ft2的公认腐蚀水平,并且与其他添加剂和高盐度盐水完全兼容。所提出的处理方法具有成本效益,实验证明是有效和持久的。建议采用该方法解决非常规致密储层的低产能问题。这种处理方法甚至可以用于消除常规增产措施(如水力压裂)中造成的额外地层损害。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An Efficient Chemical Treatment to Tackle Low Productivity of Challenging Tight Dolomite: Wormholing and Remediation of Scale-Based Damage
Economical production from unconventional reservoirs including tight dolomite require some forms of stimulation techniques to increase the effective contact areas between wellbore and formation. However, productivity improvement of these formations with conventional techniques (e.g. acid stimulation) is very limited and mostly unfeasible. In this paper, an efficient chemical treatment is proposed to stimulate tight dolomite formation through wormholing mechanism and scale-based damage removal. The formation damage in tight reservoirs are much more severe due to the smaller pore/throat size. Among them, the scale-based permeability impairment or phase trapping can cause significant production lost. In this study, the proposed treatment fluid is used to remove the scale-based formation damage, mostly caused by drilling mud. To this aim, the damage removal efficiencies of dolomite cores, artificially damaged by scale precipitation, were investigated after HPHT coreflood treatment. In addition, the performance of the treatment fluid was evaluated as a mean to bypass the damaged zones around hydraulic fractures (caused by liquid phase trapping or significant net stress). To evaluate this, a series of coreflooding experiments were also performed on untreated tight dolomite cores and the feasibility of the wormholing mechanism was studied. The permeabilities of tight dolomite rocks were measured before and after the treatment. To visualize the wormhole propagation inside the cores, computed CT scanning were performed. The rock-fluid interaction was also investigated by analyzing the effluent samples by ICP. The main mechanism of this treatment technique is pore body/pore throat enlargement by slow rock dissolution. From the pore scale analysis, it is found that even at lower concentrations, the active ingredient reacts with rock minerals. A damaged dolomite core was also treated, and the results showed that the removal of Barite-based scale can be achieved even in the presence of native calcite or dolomite minerals. Also, it is found that wormholing can be only achieved at certain concentrations (>10 w%). It also depends on the injection rate and other field conditions such as temperature. Even at low concentration, the rock permeability of the damaged dolomite core can be increased by a factor of 35 (Kf/Ki=35). Finally, dolomite reservoir cores (25-30 μD) were treated at low injection rates (0.08-0.1 ml/min) imposed from the well injectivity condition. It was shown that despite an order of magnitude lower injection rate (compared to those in conventional acidizing) still an optimum injection rate is needed to extend the wormhole across the core. It is also verified that the active ingredient can be used in alcohol-based solutions for special applications such as tight gas and gas condensate reservoirs. The corrosion rate is far below the accepted corrosion level of 0.05 lb/ft2 and it is fully compatible with other additives and high salinity brines. The proposed treatment method is cost effective and experimentally proven to be efficient and long-lasting. Such treatment is recommended to tackle the low productivity of unconventional tight reservoirs. This treatment can be even applied to remove the additional formation damages usually caused during conventional stimulations such as hydraulic fracturing to boost the production.
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