稠油井井下电加热技术

J. Karanikas, G. Pastor, S. Penny
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摘要

井下电加热一直以来都不可靠,或者仅限于短井段,通常是垂直井段。经过过去几年的技术改进,现在可以实现适用于大位移水平井的可靠、长长度、相对大功率的井下电加热。介绍了该井下电加热技术在加拿大Alberta某稠油水平井冷采井中的应用情况。现场实例证明了应用井下电加热的效益和有效性,特别是在油井生产周期的早期应用。早期生产数据显示,在同一油藏中,加热井的产油率比冷产基准井高4 -6倍。事实上,经过几周的运行,基准井已经无法在纯冷采模式下运行,因为它已经被水淹了,而加热井已经生产了20个月,而出水量没有任何增加。能量比,即增量产出的石油与注入的热量的热值,超过20.0,导致二氧化碳足迹低于40 kgCO2/桶,低于美国平均消耗的原油的温室气体强度。根据现场数据,开发并校准了一个数值模拟模型,该模型包含了考虑产出油泡沫性质和井下注入热量的反应。该模型可用于规定最佳储层和流体性质的范围,以选择最有希望的目标(油田、井)进行井下电加热,作为生产优化方法。同样的模型也可以在项目的执行过程中使用,以探索最佳的操作条件和操作程序。长水平井的井下电加热技术目前已成为一种商业化的技术,可以可靠地应用于稠油油藏的生产优化方案。了解最佳储层条件,在哪些条件下应用井下电加热可以获得最大的经济效益,这将有助于在全球范围内确定有机会增加稠油储层储量和产量的区域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Downhole electric heating of heavy-oil wells
Downhole electric heating has historically been unreliable or limited to short, often vertical, well sections. Technology improvements over the past several years now allow for reliable, long length, relatively high-powered, downhole electric heating suitable for extended-reach horizontal wells. The application of this downhole electric heating technology in a horizontal cold-producing heavy oil well in Alberta, Canada is presented in this paper. The field case demonstrates the benefits and efficacy of applying downhole electric heating, especially if it is applied early in the production life of the well. Early production data showed 4X-6X higher oil rates from the heated well than from a cold-producing benchmark well in the same reservoir. In fact, after a few weeks of operation, it was no longer possible to operate the benchmark well in pure cold-production mode as it watered out, whereas the heated well has been producing for twenty (20) months without any increase in water rate. The energy ratio, defined as the heating value of the incremental produced oil to the injected heat, is over 20.0, resulting in a carbon-dioxide footprint of less than 40 kgCO2/bbl, which is lower than the greenhouse gas intensity of the average crude oil consumed in the US. A numerical simulation model that includes reactions that account for the foamy nature of the produced oil and the downhole injection of heat, has been developed and calibrated against field data.  The model can be used to prescribe the range of optimal reservoir and fluid properties to select the most promising targets (fields, wells) for downhole electric heating as a production optimization method. The same model can also be used during the execution of the project to explore optimal operating conditions and operating procedures. Downhole electric heating in long horizontal wells is now a commercially available technology that can be reliably applied as a production optimization recovery scheme in heavy oil reservoirs. Understanding the optimum reservoir conditions where the application of downhole electric heating maximizes economic benefits will assist in identifying areas of opportunity to meaningfully increase reserves and production in heavy oil reservoirs around the world.
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