Flow-Through Experiments of Reactive Ba-Sr-Mg Brines in Mons Chalk at North Sea Reservoir Temperature at Different Injection Rates

IF 2.1 4区 工程技术 Q3 ENERGY & FUELS SPE Reservoir Evaluation & Engineering Pub Date : 2023-08-28 DOI:10.2118/214367-pa
Pål Østebø Andersen, Sander Sunde Herlofsen, Reidar Inge Korsnes, Mona Wetrhus Minde
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Abstract

Summary North Sea Chalk reservoirs in Norway are potential candidates for enhanced hydrocarbon recovery by modifying the injected brine composition. This work investigates how barium (Ba), strontium (Sr), and magnesium (Mg) brines interact when injected into chalk. Ba and Sr are often associated with mineral precipitation and occur in formation water, while Mg is present in seawater, commonly injected in chalk. Relatively clean (>99% calcite) outcrop chalk cores from Mons, Belgium, were flooded at 130°C in triaxial cells with four brines containing 0.12 mol/L divalent cations, either 0.06 mol/L Sr and Ba, 0.06 mol/L Sr and Mg, or 0.12 mol/L Ba or Sr. Each brine was injected in a separate core, with 100–150 pore volumes (PV). The injection rate varied between 0.5 and 8 PV/D. Produced brine was analyzed continuously and compared with the injected composition. After flooding, the cores flooded with only Ba or only Sr were cut into slices and analyzed locally in terms of scanning electron microscopy (SEM), matrix density, specific surface area (SSA), and X-ray diffraction (XRD). In all experiments, the produced divalent cation concentration was reduced compared with the injected value. The total reduction of injected cation concentration closely equaled the produced Ca concentration (from calcite dissolution). When flooding 0.12 mol/L Sr, the Sr concentration depleted 55%, while when flooding 0.12 mol/L Ba, 15% Ba depleted. When injecting equal concentrations of Ba and Sr, 40% Sr and 7% Ba depleted, while with equal concentrations of Mg and Sr injected, ~50% Sr was retained and almost no Mg depleted. Sr appeared to dominate and suppress other reactions. There was less sensitivity in steady-state concentrations with variation in injection rate. The similar modification of the brine regardless of residence time suggests the reactions reached equilibrium. Cutting the cores revealed a visually clear front a few centimeters from the inlet. The material past the front was indistinguishable from unflooded chalk in terms of density, SSA, microscale structure, porosity, and composition [XRD and SEM-energy-dispersive spectroscopy (EDS)]. The material near the inlet was clearly altered. Images, XRD, SEM-EDS, and geochemical simulations indicated that BaCO3 and SrCO3 formed during BaCl2 and SrCl2 flooding, respectively. Geochemical simulations also predicted an equal exchange of cations to occur. The matrix densities, porosities, and the distance traveled by the front corresponded with these minerals and suggested that the chalk was completely converted to these minerals behind the front. It was demonstrated that Ba, Sr, and Mg brines and their mixtures can be highly reactive in chalk without clogging the core, even after 100 + PV. This is because the precipitation of minerals bearing these ions is associated with simultaneous dissolution of calcite. The Ca-, Ba-, and Sr-mineral reactions are effectively in equilibrium. Previous investigations with MgCl2 (in pure and less pure chalk, at 130°C) show injection rate-dependent results (Andersen et al. 2022) and smoother alterations [Mg precipitation was seen from inlet to outlet (Zimmerman et al. 2015)], indicating that Mg-mineral reactions at same conditions have a longer time scale. The limited distance mineral alteration has occurred, suggesting that adsorption processes, happening in parallel, can explain previous observations (Korsnes and Madland 2017) of Ba and Sr injection strengthening chalk. Flushing out formation water with these ions during injection may be a new water-weakening mechanism.
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北海蒙斯白垩系不同注入速率下反应性Ba-Sr-Mg卤水渗流实验
挪威北海白垩油藏是通过改变注入盐水成分来提高油气采收率的潜在候选油藏。这项工作研究了钡(Ba),锶(Sr)和镁(Mg)盐水注入白垩时如何相互作用。Ba和Sr通常与矿物沉淀有关,出现在地层水中,而Mg则存在于海水中,通常注入到白垩中。来自比利时Mons的露头白垩岩心相对清洁(99%方解石),在130°C的三轴槽中注入四种含0.12 mol/L二价阳离子的盐水,分别为0.06 mol/L Sr和Ba, 0.06 mol/L Sr和Mg,或0.12 mol/L Ba或Sr。每种盐水注入到一个单独的岩心中,孔隙体积为100-150。注入速率在0.5 ~ 8pv /D之间。对采出盐水进行了连续分析,并与注入盐水进行了对比。驱替后,将纯Ba或纯Sr驱替岩心切成薄片,进行扫描电镜(SEM)、基体密度、比表面积(SSA)和x射线衍射(XRD)等局部分析。在所有实验中,生成的二价阳离子浓度与注入值相比都有所降低。注入阳离子的总还原浓度与(方解石溶解产生的)Ca浓度接近。当注入0.12 mol/L Sr时,Sr浓度下降55%;注入0.12 mol/L Ba时,Ba浓度下降15%。当注入等浓度的Ba和Sr时,40% Sr和7% Ba会消失;当注入等浓度的Mg和Sr时,约50% Sr会被保留,几乎没有Mg消失。Sr似乎主导并抑制了其他反应。随着注射速率的变化,稳态浓度的敏感性较低。无论停留时间如何,卤水的类似改性表明反应达到了平衡。切割核心显示了一个视觉上清晰的前沿从入口几厘米。通过前缘的物质在密度、SSA、微观结构、孔隙度和成分[XRD和sem能量色散光谱(EDS)]方面与未淹水的白垩没有区别。入口附近的材料明显发生了变化。XRD、SEM-EDS和地球化学模拟结果表明,BaCl2和SrCl2驱油过程中分别形成了BaCO3和SrCO3。地球化学模拟也预测了一个相等的阳离子交换的发生。基质密度、孔隙度和锋面移动的距离与这些矿物相对应,表明白垩完全转化为锋面后面的这些矿物。结果表明,即使在100 + PV下,Ba、Sr和Mg盐水及其混合物也能在白垩中发生高活性反应,而不会堵塞岩心。这是因为含有这些离子的矿物的沉淀与方解石的同时溶解有关。钙、钡和锶矿物反应有效地处于平衡状态。先前对MgCl2的研究(在纯和不纯的白垩中,在130°C下)显示了注射速率相关的结果(Andersen et al. 2022)和更平滑的变化[从入口到出口可见Mg沉淀(Zimmerman et al. 2015)],表明相同条件下的Mg-矿物反应具有更长的时间尺度。有限距离的矿物蚀变已经发生,表明平行发生的吸附过程可以解释先前对Ba和Sr注入强化白垩的观察(Korsnes和Madland 2017)。这些离子在注入过程中冲刷地层水可能是一种新的减水机制。
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来源期刊
CiteScore
5.30
自引率
0.00%
发文量
68
审稿时长
12 months
期刊介绍: Covers the application of a wide range of topics, including reservoir characterization, geology and geophysics, core analysis, well logging, well testing, reservoir management, enhanced oil recovery, fluid mechanics, performance prediction, reservoir simulation, digital energy, uncertainty/risk assessment, information management, resource and reserve evaluation, portfolio/asset management, project valuation, and petroleum economics.
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The Role of Diffusion on Reservoir Performance in Underground Hydrogen Storage Experimental Measurements and Molecular Simulation of Carbon Dioxide Adsorption on Carbon Surface Measurement of Effective Hydrogen-Methane Gas Diffusion Coefficients in Reservoir Rocks Flow-Through Experiments of Reactive Ba-Sr-Mg Brines in Mons Chalk at North Sea Reservoir Temperature at Different Injection Rates Evaluation of Effects of Waterflooding-Induced Bilayer Fractures on Tight Reservoir Using Pressure-Transient Analysis Method
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