Mikhail Tcibulskii, M. Akhmetov
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引用次数: 2

摘要

Vostochno-Messoyakhskoe油田是俄罗斯联邦最北端的活跃大陆油田(图1),该油田位于北极气候带,距离北极圈250公里。由于该油田地质复杂且缺乏运输结构,2015年才开始全面生产钻井。天气条件,如强风和极低的温度,可能对人员和设备造成危险。此外,该油田有永久冻土带(距地表400米),生产区地层温度较低。此外,由于存在永久冻土带,井口地层解冻的风险很高。这些条件极大地影响了钻井和完井过程中所采用的技术。因此,特殊的水泥设计是必要的,以帮助降低与Vostochno-Messoyakhskoe油田低温和永久冻土带相关的风险。在720 ~ 820m的真垂深(TVD)处存在气层,地层孔隙压力高,使生产更加复杂。这可能会使生产套管的固井作业变得困难。虽然套管落地的TVD并不深,但大位移钻井(ERD)井的测量深度(MD)非常显著(图2)。大位移钻井(ERD)井可以挑战水泥置换效率(Sabins, 1990)。泥浆的清除效率可能不足以形成高质量的水泥屏障,并将地层与气体运移隔离开来。泥浆去除效果差会影响油井未来的使用寿命和原油产量。为了进行补救工作,有必要停产几天。由于在messoakhskoe油田进行补救作业的经验,通常需要进行几次补救固井作业的尝试,以达到积极的效果。因此,作业者决定利用液压封隔器在地面和生产套管之间建立第二个屏障,以帮助防止气体运移到地面,节省修复作业的时间,并延长未来油井的使用寿命。
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Effect of Low Pumping Rate on Mud Displacement Efficiency and Pumping Pressure During Cementing of Oil Wells
The Vostochno-Messoyakhskoe field is the northernmost active continental field in the Russian Federation (Fig. 1). This field is located 250 km from the Arctic Circle, in the arctic climatic zone. Full production drilling only began in 2015 because of the field's geological complexity and lack of transportation structure. Weather conditions, such as strong winds and extremely low temperatures, can be hazardous to personnel and equipment. Additionally, this oil field has permafrost zones (400m from the surface) and low formation temperatures at the production zone. Also, because of permafrost zones, there is a high risk of thawing the wellhead formation. These conditions significantly affect which technologies can be applied during drilling and completion of the wells. Therefore, special cement designs are necessary to help reduce risks associated with low temperatures and permafrost zones in the Vostochno-Messoyakhskoe field. Production is further complicated by a gas layer at 720 to 820m true vertical depth (TVD) and high formation pore pressure. This can make the cement operations with the production casings difficult. While the TVD of the casing landing is not relatively deep, the measured depth (MD) in extended reach drilling (ERD) wells is significant (Fig. 2). ERD wells can challenge cement displacement efficiency (Sabins, 1990). Mud removal efficiency may not be enough to create a high-quality cement barrier and isolate formations from gas migration. Poor mud removal can affect future life of the wells and crude oil production. To perform remedial jobs, it is necessary to stop production for several days. Due to experience in performing remedial jobs in the Messoyakhskoe field, it is usually necessary to perform a few attempts of the remedial cementing operation to reach positive results. Therefore, the operator decided to utilize hydraulic packers to create a second barrier between the surface and production casings to help prevent gas migration to the surface, save time associated with remedial operations, and extend the life of future wells.
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