Downhole Heating Technology – New Solution for Paraffinic Wells

Mihaela Vlaicu, Vasile Marius Nae, P. Buerssner, Stefan Liviu Firu, N. Logashova
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Abstract

Paraffin represents one of the main case of failures and production losses which facing the entire oil industry. Prevention of paraffin deposition on the subsurface/surface equipment can be achieved by keeping the paraffin dissolved in crude oil or minimizing the adhesion or aggregation process of wax crystals. The paraffin problems which occur, conduct to gradual reduction of the tubular and pipelines internal diameter, restriction or valves blockages, and reduce the equipment capacity until the production is stop. Problems due to paraffin deposition varies and is different according with each commercial field, sometime the difference is from a well to well which producing from the same reservoir with different consistency. How we shall proceed? Before or after paraffin is field on the equipment? How could be avoid the future paraffin deposition? How long the selected method is proper for well ? The decision represents a combination based on oil's chemical & physical characteristics, well's behavior, method selected for prevention or elimination and combined with economic analysis and field experience. The paraffin inhibition applying is a common practice in OMV Petrom, which cover majority of the production wells. For the special wells, which the paraffin inhibition didn't provided satisfying results (multiple intervention due to paraffin deposition) was selected the Down Hole Heating technology (DHH) which was successfully tested in our company since 2014 thanks according with the yearly New Technology Program. The operating principle consists in heating the fluid volume from tubing using the heating cable which can be installed inside tubing, for NF and ESP wells or outside tubing for SRP or PCP wells. The cable is designed and located at the interval of wax crystallization appearance and heats the fluid to the temperature higher than the wax crystallization point (WAT). Since then, the DHH technology had an upward course, proven by high run life (highest value 2500 days / average 813 days) of the technology at the total 47 wells equipped, until this moment. Based on the successful results, recorded of 64% of old production wells equipped, it was decided to apply the technology at first completion of the new wells (36%), thus ensuring the protection of the new equipment. The paper offers an overview of DHH technology implementation, achievements, benefits and online monitoring of technology implementation starting with 2014 until today. The total impact shown a decreasing of no.of failures with 73,8%, the cost of intervention with 76,5%. The production losses decreased only with 5%, which certifies the fact that the technology helping production maintaining during the exploitation in comparison with production losses due paraffin issues recorded at wells without equipped with DHH technology. During 6 years of down hole heating technology application were developed candidate selection decision tree, monitoring the electrical efficiency, using the adaptability capacity of the technology from one well to another and integrate the temperature parameters in online monitoring system as part of digitalization concept of OMV Petrom, aspects which will be present in this article.
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井下加热技术——石蜡井的新解决方案
石蜡是整个石油工业面临的主要故障和生产损失之一。防止石蜡沉积在地下/地面设备上可以通过保持石蜡溶解在原油中或尽量减少蜡晶体的粘附或聚集过程来实现。出现的结蜡问题,导致管材和管道内径逐渐减小,限制或阀门堵塞,降低设备容量,直至停止生产。石蜡沉积问题因油田的不同而不同,有时在同一稠度油藏生产的不同井之间也存在差异。我们该如何进行呢?在设备上涂石蜡之前还是之后?如何避免今后的石蜡沉积?选择的方法适合油井多长时间?该决策综合考虑了石油的化学和物理特性、井的行为、预防或消除方法的选择,并结合了经济分析和现场经验。在OMV Petrom,应用防石蜡是一种常见的做法,覆盖了大多数生产井。对于阻蜡效果不理想的特殊井(因结蜡导致多次干预),根据年度新技术计划,选择了自2014年起在我公司测试成功的井下加热技术(DHH)。其工作原理是利用加热电缆从油管中加热流体体积。对于NF和ESP井,加热电缆可以安装在油管内,对于SRP或PCP井,加热电缆可以安装在油管外。该电缆设计并位于蜡结晶外观区间,将流体加热至高于蜡结晶点(WAT)的温度。从那时起,DHH技术一直在不断发展,直到目前为止,该技术在总共47口井的运行寿命(最高2500天/平均813天)中得到了证明。根据成功的结果,记录了64%的旧生产井的安装,决定在新井的首次完井时应用该技术(36%),从而确保了新设备的保护。本文概述了从2014年至今的DHH技术实施、成果、效益和技术实施的在线监测。总影响呈下降趋势。失败率为73.8%,干预成本为76.5%。生产损失仅下降了5%,这证明了在开发过程中,与未配备DHH技术的井记录的因石蜡问题造成的生产损失相比,该技术有助于维持生产。在6年的井下加热技术应用中,开发了候选选择决策树,监测电效率,利用该技术从一口井到另一口井的适应能力,并将温度参数集成到在线监测系统中,作为OMV石油公司数字化概念的一部分,本文将介绍这些方面。
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Incorporation of Neutrally Buoyant Proppants in Horizontal Unconventional Wells to Increase Propped Fracture Area Results for Substantially Improved Well Productivity and Economics Simplified Solution for Managed Pressure Drilling - System that Drillers Can Operate The Case for Combining Well Intervention Solutions to Optimize Production and Reduce Risk Exposure Application of Digital Well Construction Planning Tool During Well Conceptualization Phase Downhole Heating Technology – New Solution for Paraffinic Wells
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