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首页> 外文期刊>Fuel >Testing the injection of air with methane as a new approach to reduce the cost of cold heavy oil recovery: An experimental analysis to determine optimal application conditions
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Testing the injection of air with methane as a new approach to reduce the cost of cold heavy oil recovery: An experimental analysis to determine optimal application conditions

机译:测试以甲烷注入空气作为降低冷重油回收成本的新方法:确定最佳应用条件的实验分析

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We propose a new approach to reduce the associated cost of CSI (cyclic solvent injection) by using air with methane to pressurize the reservoir and improve the foaminess process. This reduces the cost as the amount of methane injected is curtailed, but the process needs to be optimized by determining the optimal application conditions by maximizing final heavy oil recovery. To study the use of air for a technical and economic improvement of CSI with methane, pressure depletion tests were performed at a pressure depletion rate of -0.51 psi/min in a cylindrical sandpack, placed in a 150 cm long and 5 cm diameter sandpack holder supplied with eight evenly distributed pressure transducers and three thermocouples. Production profiles (pressure at every port, pressure differences, and pressure gradient) and saturation distributions were studied to determine the conditions yielding the best sweep and the highest oil and gas recovery factor with minimal use of gas injected. Different injection/production schemes (alternate or co-injection of an air-methane pair and different injector-producer alignments), depletion rates, and soaking times were tested to determine the conditions to maximize the recovery factor. Furthermore, observational experiments at a macroscopic and microscopic scale after the PVT tests were performed by recombining the heavy oil sample with sole air, sole methane, and a mixture of air and methane at a volume ratio of 1. Using a mixture of air and methane not only expanded the volume of oil (gas bubbles trapped into the oil) by 2.5 but also delayed the defoaming process at both macroscopic and microscopic scales. Numerous tiny gas bubbles were initially observed, which kept its size and number for more time than the methane case, which is an indication of restraining fast bubble growth and subsequent coalescence. The best injection strategy for a single-well injection scheme was the simultaneous injection of air and methane on a soaking period of 2-3 days, whereas for a multi-well injection scheme an alternating injection strategy on a soaking period of 4-5 days offered the best performance. Cumulative oil and gas recovery factors were as high as 27.46% and 76.68%, respectively, when air was accompanied by methane. Using air as a foamy oil ameliorative was observed to save up to 26% on methane use in single-well injection schemes and up to 51% on multi-well injection schemes.
机译:我们提出了一种新方法,通过使用含甲烷的空气对储层加压并改善泡沫过程来降低CSI(循环溶剂注入)的相关成本。由于减少了注入的甲烷量,因此降低了成本,但是需要通过最大限度地提高最终重油回收率来确定最佳应用条件,从而优化工艺。为了研究使用空气对甲烷进行CSI技术上和经济上的改进,在放置在150厘米长,直径5厘米的沙袋架中的圆柱形沙袋中以-0.51 psi / min的压力消耗速率进行了压力消耗测试。提供八个均匀分布的压力传感器和三个热电偶。研究了生产剖面图(每个端口的压力,压差和压力梯度)和饱和度分布,以确定在不使用最少注气量的情况下能够产生最佳吹扫和最高油气回收率的条件。测试了不同的注入/生产方案(空气-甲烷对的交替或共注入以及不同的注入器-生产器排列),消耗率和浸泡时间,以确定使回收率最大化的条件。此外,通过将重油样品与唯一的空气,唯一的甲烷以及空气和甲烷的体积比为1的混合物重新混合,在PVT测试之后进行了宏观和微观的观察性实验。不仅使油的体积(捕获在油中的气泡)扩大了2.5,而且在宏观和微观尺度上都延迟了消泡过程。最初观察到许多微小的气泡,与甲烷相比,气泡的大小和数量得以保持更多的时间,这表明抑制了气泡的快速生长和随后的聚结。对于单井注入方案,最佳注入策略是在2-3天的浸泡时间内同时注入空气和甲烷,而对于多井注入方案,在4-5天的浸泡期内交替注入策略提供了最佳性能。当空气伴有甲烷时,油气的累计采收率分别高达27.46%和76.68%。在单井注入方案中,使用空气作为泡沫油改善剂可节省多达26%的甲烷使用,在多井注入方案中可节省多达51%的甲烷使用。

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