通过水泥监测动态油藏压力响应

Elias Garcia, Gerald Stutes, Christoffer Nåden, K. Borgersen
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引用次数: 0

摘要

在过去的五年中,永久性井下仪表的使用在行业中激增。真实井底压力(BHP)的可用性对于验证/改进油藏模型至关重要。与从地面读数推断BHP类似,使用BHP推断地层压力可能会导致油藏模型出现重大误差,无法为作业者提供当前市场所需的竞争优势。因此,有一种动力是通过将压力和温度计直接与地层接触来监测地层压力。近年来,作业者一直在钻更大的井眼,在套管外部部署测量系统,并将测量系统固井,用于多种用途。在人工举升应用中,当作业公司需要维修电潜泵(ESP)时,或者当作业公司想要将观测井转换为生产井时,固井计量系统可以帮助作业者避免在油管上拆卸和重新安装计量系统的成本。在非常规油气藏中,包括石英压力和温度计、定向射孔和井况调节在内的技术可以使作业者在井筒的长水平段的套管上部署多个实时井下压力和温度计。反过来,这可以提供有价值的生产数据,用于了解簇的生产性能、井间通信、裂缝方位、井距和段长生产影响。固井压力表使作业者能够了解覆盖层、盖层或储层段的压力动态。永久安装的套管式仪表通过电缆或无线感应耦合技术连接到地面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Monitoring Dynamic Reservoir Pressure Responses Through Cement
During the last five years, the use of permanent downhole gauges has proliferated in the industry. The availability of true bottomhole pressure (BHP) is imperative in validating/improving reservoir models. Similarly to the extrapolation of BHP from surface readings, the use of BHP to extrapolate formation pressure may lead to significant errors in reservoir models that do not provide operators with the competitive edge needed in the current market. Consequently, there is a drive to monitor formation pressure in-situ by placing pressure and temperature gauges in direct contact with the formation. In recent years, operators have been drilling larger holes, deploying gauge systems on the exterior of the casing, and cementing the gauge systems in place for multiple purposes. In artificial lift applications, cemented gauge systems have helped operators to avoid costs of decompleting and redeploying gauge systems on tubing whenever the electric submersible pumps (ESP) must be serviced, or perhaps whenever operators want to convert an observation well to a producing well. In unconventional plays, technologies involving quartz pressure and temperature gauges, oriented perforating, and well conditioning practices can enable operators to deploy multiple real-time downhole pressure and temperature gauges on casing across long horizontal sections of a wellbore. This, in turn, can provide valuable production data with which to understand cluster production performance, cross-well communication, fracture azimuth, well spacing, and stage-length production implications. Cemented gauges enable operators to understand pressure dynamics in the overburden, cap rock, or reservoir sections. The permanently installed, casing-deployed gauges connect to the surface through cable or through deployment of wireless inductive coupling technology.
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