在南阿曼,膨胀封隔器锚定系统实现了可插入螺杆泵的无钻机安装

Alejandro Osorio, F. Ford, B. Montilla
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摘要

目前石油行业的市场状况要求采用具有成本效益的油井干预方法,以优化使用可插入螺杆泵(i - pcp)完井的产量。传统上,I-PCP的无钻机输送依赖于泵座管(PSN),或者在没有PSN的井中使用机械坐封I-PCP锚固装置。虽然在PSN上安装I-PCP是一种可靠的方法,但它要求PSN最初安装在生产油管内,这将I-PCP的坐封深度限制在PSN的位置。机械坐封I- PCP锚固装置的杆柱传输受到杆柱将所需轴向载荷传递到坐封深度的有效性的限制,这在大位移工况下变得越来越具有挑战性。I-PCP安装面临的其他挑战包括,之前安装的PSN的位置和正锚定,以便在不拆卸I-PCP进行冲洗作业的情况下脱离转子。该公司开发了一种可膨胀封隔器锚定装置,简化了I-PCP的无钻机安装,无需安装座节。该装置仅依赖于液压,而在其设置过程中不需要轴向载荷。采用膨胀封隔器的抽油杆柱I-PCP锚固装置结合了膨胀封隔器技术和液压驱动滑块机构。它配备了密封杯和可剪切进气短节,以获得所需的压力能力,以确认油管的完整性,并确保其坐封顺序,同时最大化坐封后的通过能力。系统可以通过拉伸来剪切其释放销来回收,从而使膨胀封隔器放气,机械卡瓦收回。在阿曼Sadad油田的一口直井中,该系统的首次安装成功将I-PCP安装在3-1/2”生产油管上,证明了该系统的最佳功能。I-PCP与膨胀封隔器锚定装置一起部署在抽油杆柱上,以确定井深。该系统通过抽油杆环空通过冲洗泵施加压力,并立即投入生产。本文的目的是对这项创新而独特的技术进行技术解释,分享从首次安装中获得的经验教训,并讨论其在提高I-PCP技术当前能力的同时,降低运营成本并优化PCP/I-PCP完井设计的潜力。
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Inflatable Packer Anchor System Enables Rigless Installation of an Insertable Progressing Cavity Pump in South Oman
Current market conditions in the oil industry call for cost effective well intervention methods to optimize production in wells completed with Insertable Progressing Cavity Pumps (I-PCPs). Rigless rod-string conveyance of I-PCP's traditionally rely on Pump Seating Nipples (PSNs) or mechanical-set I-PCP anchoring devices in wells without PSN's. Although the installation of an I-PCP on a PSN is a reliable method, it requires a PSN to be originally installed within the production tubing, which limits the I-PCP setting depth to the location of the PSN. Rod-string conveyance of mechanical-set I- PCP anchoring devices is limited by the rod string's effectiveness to transmit the required axial loads to setting depth, which becomes increasingly challenging in extended-reach conditions. Other challenges with I-PCP installations include location of previously installed PSN's and positive anchoring to facilitate disengagement of the rotor without unseating the I-PCP for flush-by operations. An inflatable packer anchoring device has been developed to simplify rigless installation of an I-PCP without the need of a seating nipple. The device relies only on hydraulic pressure while eliminating the need for axial loads during its setting sequence. The rod string deployed inflatable packer I-PCP anchoring device incorporates inflatable packer technology in conjunction with a hydraulically-actuated slip mechanism. It is equipped with seal cups and a shearable intake sub to obtain the required pressure competence to confirm tubing integrity and enable its setting sequence while maximizing flow-through capability after it is set. The system can be retrieved by applying overpull to shear its release pins allowing the inflatable packers to deflate and the mechanical slips to retract. The first installation of this system proved its optimal functionality by successfully setting an I-PCP in 3-1/2" production tubing in a vertical well in Oman's Sadad field. The I-PCP was deployed on rod string in conjunction with the inflatable packer anchoring device to setting depth. The system was set by applying pressure with a flush-by unit pump via the tubing-rod annulus, and the well was immediately placed into production. The objective of this paper is to provide a technical explanation of this innovative and unique technology, share the lessons learned from its first installation, and discuss its potential to improve the current capabilities of I-PCP technology while reducing operational cost and optimizing PCP/I-PCP completion design.
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