基于油藏模拟的溶剂浓度对结垢丁烷溶剂强化采油过程的影响

S. Lorimer, G. Kumar, S. Abdelkareem
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引用次数: 0

摘要

了解提高石油/沥青采收率过程的规模是将实验室规模的实验结果推广到现场规模的关键。热过程的标度理论很好理解,并已应用于蒸汽过程。然而,混合蒸汽(热)/溶剂(传质)过程的结垢仍然没有很好地定义和理解。利用储层模拟(商用热成分模拟器CMG STARSTM)研究了蒸汽/丁烷混合重力排水过程的结垢行为。之前的研究使用油藏模拟来确定水驱的垢群。本研究采用了类似的策略,通过在三种不同的油藏规模(实验室规模、半现场规模和现场规模)进行油藏模拟,研究了混合(蒸汽)溶剂采油过程的可扩展性,以研究扩散和分散的传质机制对该过程可扩展性的影响。特别研究了丁烷溶剂浓度对蒸汽/丁烷重力排水工艺结垢的影响,考虑了注入蒸汽的丁烷摩尔分数浓度(1%、2%、5%、7%、10%、15%、21%、25%和50%)。在不同的溶剂注入浓度下,研究了油气相中丁烷的温度曲线和摩尔分数曲线,以检验其可扩展性。数值结果分为无扩散和扩散、仅扩散、仅扩散和同时加入扩散和扩散的情况。当模拟结果无量纲化时,结果证实了该过程的可扩展性,没有毛细管效应,尽管在一些模拟结果中存在一些物质平衡误差问题,特别是在高溶剂浓度下。在低注射浓度的情况下,对于所研究的操作条件,三个尺度的轮廓几乎相同(表明可扩展性)。此外,还研究了毛细效应,与结垢热过程类似,毛细效应在研究条件下影响了过程的可扩展性,特别是在较高的注入浓度下。油藏模拟通常在低注入浓度下保持可扩展性,但在高注入浓度(>5%)下观察到异常行为。为了在三个尺度之间进行比较,对采油曲线进行了无量纲化处理。当考虑到毛细管效应时,在较高的注入浓度下,采收率曲线呈现出不同寻常的s形行为,尤其是在实验室和半油田规模下。在所有情况下,当包括所有机制(扩散、分散和毛细效应)时,量表1显示的回收率比量表3快得多,这表明实验室量表可能暂时高估了该特定工艺场景的现场规模回收率。
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Effect of Solvent Concentration on Scaling Butane Solvent Enhanced Oil Recovery Processes Using Reservoir Simulation
Understanding scaling of enhanced oil/bitumen recovery processes is essential in moving laboratory scale experimental results to field scale. Scaling theory for thermal processes is well understood and has been applied to steam processes. However, scaling of hybrid steam (thermal) /solvent (mass transfer) processes is still not well defined nor well understood. This paper investigates the scaling behavior of hybrid steam/butane gravity drainage processes using reservoir simulation (commercial thermal compositional simulator CMG STARSTM). Previous research has used reservoir simulation to confirm scaling groups for waterflooding. A similar strategy was used in this study whereby the scaling of a hybrid (steam) solvent oil recovery process was examined using reservoir simulations at three different reservoir scales: lab scale, semi-field scale and field scale to examine the influence of the mass transfer mechanisms of diffusion and dispersion on the scalability of the process. In particular, the influence of butane solvent concentration on scaling a steam/butane gravity drainage process was investigated by considering several butane mole fraction concentrations injected with steam (1%, 2%, 5%, 7%, 10%, 15%, 21%, 25% and 50%). Temperature contours, and mole fraction contours of butane in both the oil and gas phases were examined for various solvent injection concentrations to examine scalability. Numerical results are provided with no diffusion and dispersion, diffusion only, dispersion only and with both diffusion and dispersion added to the simulations. Results confirmed scalability of the process with no capillary effects when the simulation results were non-dimensionalized, although there were some issues with material balance errors in some of the simulation results particularly at high solvent concentrations. For low injection concentrations, the contours were almost identical (indicating scalability) for the three scales for the operating condition studied. In addition, capillary effects were also studied, and similar to scaling thermal processes, the capillarity effects influenced scalability of the process under the conditions studied particularly at higher injection concentrations. Scalability using reservoir simulation was generally preserved with low injection concentrations, but unusual behavior was observed at higher injection concentrations (>5%). Oil recovery curves were non-dimensionalized to make comparisons amongst the three scales. The oil recovery curves displayed an unusual S-shaped behavior at higher injection concentrations when capillary effects were included especially for the lab and semi-field scales. In all cases when all of the mechanisms are included (diffusion, dispersion and capillary effects), Scale 1 shows a much faster recovery than Scale 3 which suggests that the lab scale might temporally overestimate the field scale recovery for this particular process scenario.
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