通过优化井结构设计和轻型机械E-Line作业,最大限度地减少俄罗斯和哈萨克斯坦上游地区的温室气体排放

Saltanat Koishymanova, Danil Kayashev, B. Schwanitz, Tolegen Sadvakassov, Y. Ponomarenko
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引用次数: 0

摘要

向气候中性社会的过渡既是一项紧迫的技术挑战,也是一项长期的资本支出,需要行业和政府的巨额投资。全球主要的石油和天然气运营商已经制定了脱碳目标,尽管上游的排放量占石油工业总排放量的三分之二,但新的钻井设计和改进的修井作业都被证明是减少温室气体(GHG)排放的有效措施,同时在经济上可行。自2018年以来,俄罗斯已经在114口井中安装了一种新型完井技术,以消除井在整个生命周期内持续的环空套管压力(SAP),并防止二氧化碳和甲烷释放到大气中。由于甲烷比二氧化碳更强大,在数百年的时间里,其全球变暖潜力是二氧化碳的28-34倍,在20年的时间内,其潜力分别是二氧化碳的84-86倍,因此这些简单而高效的解决方案对运营商在减少碳税的同时应对气候变化具有巨大的好处。此外,采用该技术后,传统问题井的井下完整性得到了可靠保证,无需后续的挤压固井作业。这些类型的完井解决方案既适用于裸眼井,也适用于套管井,不仅使作业者能够定制固井方案,满足监管部门的批准,而且还大大减少了报告的碳排放。本文将简要介绍这些装置的效果和效率,并与传统技术进行比较。此外,自2011年以来,在俄罗斯和哈萨克斯坦进行了15,000多次轻型电子电缆修井作业,与传统的连续油管作业相比,减少了有害温室气体的排放。这些类型的轻型干预措施使用较少的柴油,较少的人员和设备,在每个井位留下更小的碳足迹,从而在减少温室气体排放方面发挥作用。将对连续油管与电缆机械干预进行统计分析。本文将说明这些新技术如何有助于减少温室气体排放,以及与传统方法相比,如何通过减少钻机时间和加快作业执行速度,在完井和干预活动中同时实现经济效益。它还将审查该地区使用这些装置的各个领域的案例历史,并分析每种方法。现场数据将展示开发、安装和操作顺序,并解释每种设置是如何定制的,以满足特定的操作需求,并减少温室气体排放,主要是通过减少天然气燃除。这些技术的广泛应用将有助于运营商实现其排放目标,并有助于减少地球的气候变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Minimization of Greenhouse Emissions in Russia and Kazakhstan Upstream Sector Through Optimized Well Construction Designs and Lightweight Mechanical E-Line Operations
The transition to a climate-neutral society is both an urgent technical challenge and yet long-term CAPEX heavy requiring huge investments from industry and governments. Major oil and gas (O&G) operators around the globe have already established their decarbonization targets and even though upstream accounts for two-thirds of total emissions in the petroleum industry, both new well construction designs, and improved workover operations are proving to be effective measures in minimizing greenhouse gas (GHG) emissions while being economically viable. A novel completion technology has been installed in 114 wells in Russia since 2018 to eliminate sustained annular casing pressure (SAP) throughout the lives of wells and combat the associated release of carbon dioxide (CO2) and methane into the atmosphere. Since methane is much more powerful and has a 28-34 times more global warming potential compared to CO2 over the hundreds of years, and 84-86 times more potent over a 20-year timeframe respectively, these types of simple, yet efficient solutions represents enormous benefits to operators in reducing their carbon taxes while tackling climate change. Moreover, the installation of this technology resulted in reliable downhole well integrity of traditionally problematic wells, without the need for subsequent squeeze cementing operations. These types of completion solutions set both in an open and cased hole, allow operators not just to customize their cementing program and meet regulatory approvals, but also greatly reduce their reported carbon emissions. A summary of the results and efficiencies achieved with these installations will be presented and will be compared to conventional technologies. In addition, more than 15,000 lightweight e-line intervention operations have been performed both in Russia and Kazakhstan since 2011 which contributed to fewer emissions of hazardous greenhouse gases into the air versus conventional coiled tubing operations. These types of light interventions use less diesel to operate and with fewer people and equipment, leave a smaller carbon footprint on each well location which in turn makes a difference when it comes to GHG emission reduction. A comparison breakdown of coiled tubing versus e-line mechanical interventions will be statistically analyzed. This paper will illustrate how these newer technologies contributed to GHG emission reduction and how simultaneously economical efficiencies were achieved during well completion and intervention activities through reduced rig time and faster job execution compared to conventional methods. It will also review case histories from fields across the region using these installations and analyze each method. The field data will present the development, installation, and operational sequence and explain how each setup was tailored to meet both specific operational needs and to reduce greenhouse emissions, mainly by minimizing gas flaring. Widespread implementation of such technologies would help operators meet their emission targets and contribute to the reduction of the earth's climate change.
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