{"title":"高压井射孔系统的开发与应用比较","authors":"R. E. Robey, David Francis Suire, B. Grove","doi":"10.4043/29582-MS","DOIUrl":null,"url":null,"abstract":"\n This paper presents an outline for the development and deployment of three perforating systems to address several needs of high pressure (HP) US Gulf of Mexico wells. A case study is presented, highlighting the key differences between systems, and includes comparisons between data obtained during engineering development and field deployment phases\n During the development phase rigorous testing was conducted in line with API RP 19B sections 2, 3.14, and 5 to characterize the perforating systems' performance. These tests were executed to assess charge performance, system pressure rating at downhole conditions, and debris characteristics at surface conditions. Following the development testing, the systems were fielded with wellbore pressure being captured on downhole gauges to assess the perforating event response comparing to pre-deployment models. Additionally, wellbore debris recovered post-perforating was evaluated on surface.\n The first system was to support an HP application that requires high flow area in heavy wall casing. This was the platform for other less traditional systems to expand upon. Utilizing high shot density and big hole (BH) charges, this system was tested to provide a system rating of up to 30 ksi at 425°F while retaining fishability in heavy wall casing. For this system, wellbore effects from perforating, such as dynamic underbalance and recovered debris, are qualitatively aligned with existing perforators.\n The second system was optimized to control dynamic transient loading on the perforating string and minimize debris in HP environments. This meant the system was required to fit into a strategy of lowering dynamic structural loads on the workstring created during perforating. The system was designed to affect the pressure interactions among the gun internals, wellbore, and the formation, and control the amount of formation material inflow and debris produced by perforating. This perforating system was developed, qualified, and successfully fielded in multiple wells without any operational issues.\n The third system provides increased formation penetration depth without sacrificing shot density. By using deep penetrating (DP) charges, this system is can provide penetration past drilling damage or mitigate higher formation strengths encountered at greater depths in some HP US GoM reservoirs, thus providing operators improved connectivity to the formation.\n Evaluating perforating system performance, not only with lab testing but with field-gathered data, is crucial to closing the development loop for HP applications where testing is not practical due to both scale and replication of wellbore conditions. In deployment, the well conditions for the systems were analogous, highlighting the differences in data, thus providing a more complete background for operators to assess the suitability of these systems in HP applications and evaluate their perforating method to maximize production.","PeriodicalId":10968,"journal":{"name":"Day 3 Wed, May 08, 2019","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2019-04-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Developing and Fielding Perforating Systems: A Comparison in High-Pressure Wells\",\"authors\":\"R. E. Robey, David Francis Suire, B. Grove\",\"doi\":\"10.4043/29582-MS\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"\\n This paper presents an outline for the development and deployment of three perforating systems to address several needs of high pressure (HP) US Gulf of Mexico wells. A case study is presented, highlighting the key differences between systems, and includes comparisons between data obtained during engineering development and field deployment phases\\n During the development phase rigorous testing was conducted in line with API RP 19B sections 2, 3.14, and 5 to characterize the perforating systems' performance. These tests were executed to assess charge performance, system pressure rating at downhole conditions, and debris characteristics at surface conditions. Following the development testing, the systems were fielded with wellbore pressure being captured on downhole gauges to assess the perforating event response comparing to pre-deployment models. Additionally, wellbore debris recovered post-perforating was evaluated on surface.\\n The first system was to support an HP application that requires high flow area in heavy wall casing. This was the platform for other less traditional systems to expand upon. Utilizing high shot density and big hole (BH) charges, this system was tested to provide a system rating of up to 30 ksi at 425°F while retaining fishability in heavy wall casing. For this system, wellbore effects from perforating, such as dynamic underbalance and recovered debris, are qualitatively aligned with existing perforators.\\n The second system was optimized to control dynamic transient loading on the perforating string and minimize debris in HP environments. This meant the system was required to fit into a strategy of lowering dynamic structural loads on the workstring created during perforating. The system was designed to affect the pressure interactions among the gun internals, wellbore, and the formation, and control the amount of formation material inflow and debris produced by perforating. This perforating system was developed, qualified, and successfully fielded in multiple wells without any operational issues.\\n The third system provides increased formation penetration depth without sacrificing shot density. By using deep penetrating (DP) charges, this system is can provide penetration past drilling damage or mitigate higher formation strengths encountered at greater depths in some HP US GoM reservoirs, thus providing operators improved connectivity to the formation.\\n Evaluating perforating system performance, not only with lab testing but with field-gathered data, is crucial to closing the development loop for HP applications where testing is not practical due to both scale and replication of wellbore conditions. 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引用次数: 0
摘要
本文概述了三种射孔系统的开发和部署,以满足美国墨西哥湾高压井的几种需求。介绍了一个案例研究,突出了系统之间的主要差异,并比较了工程开发和现场部署阶段获得的数据。在开发阶段,根据API RP 19B第2、3.14和5部分进行了严格的测试,以表征射孔系统的性能。这些测试的目的是评估井下条件下的装药性能、系统额定压力以及地面条件下的碎屑特性。在开发测试之后,系统被投入使用,通过井下测量仪捕获井筒压力,与部署前的模型相比,评估射孔事件的响应。此外,对射孔后回收的井筒碎屑进行了地面评估。第一个系统用于支持高压应用,该应用需要在厚壁套管中实现高流道面积。这是其他不太传统的系统扩展的平台。该系统利用高射孔密度和大射孔(BH)装药,在425°F下提供了高达30 ksi的系统额定值,同时保持了在厚壁套管中的可打捞性。对于该系统,射孔对井筒的影响,如动态欠平衡和回收的碎屑,与现有的射孔器定性一致。第二个系统进行了优化,以控制射孔管柱上的动态瞬态载荷,并最大限度地减少高压环境中的碎屑。这意味着该系统需要适应降低射孔过程中产生的工作串动态结构载荷的策略。该系统旨在影响射孔枪内部、井筒和地层之间的压力相互作用,并控制射孔产生的地层物质流入和碎屑量。该射孔系统经过开发、验证并成功应用于多口井,没有出现任何操作问题。第三种系统在不牺牲射孔密度的情况下增加了地层穿透深度。通过使用深穿透(DP)装药,该系统可以穿透钻井损害,或减轻一些高强度的美国墨西哥湾油藏在更深的深度遇到的地层强度,从而为作业者提供更好的与地层的连通性。评估射孔系统的性能,不仅要通过实验室测试,还要通过现场收集的数据,这对于关闭高压应用的开发循环至关重要,因为高压应用由于井眼条件的规模和重复性而无法进行测试。在部署过程中,系统的井况是相似的,突出了数据的差异,从而为作业者评估这些系统在高压应用中的适用性和评估射孔方法以实现产量最大化提供了更完整的背景资料。
Developing and Fielding Perforating Systems: A Comparison in High-Pressure Wells
This paper presents an outline for the development and deployment of three perforating systems to address several needs of high pressure (HP) US Gulf of Mexico wells. A case study is presented, highlighting the key differences between systems, and includes comparisons between data obtained during engineering development and field deployment phases
During the development phase rigorous testing was conducted in line with API RP 19B sections 2, 3.14, and 5 to characterize the perforating systems' performance. These tests were executed to assess charge performance, system pressure rating at downhole conditions, and debris characteristics at surface conditions. Following the development testing, the systems were fielded with wellbore pressure being captured on downhole gauges to assess the perforating event response comparing to pre-deployment models. Additionally, wellbore debris recovered post-perforating was evaluated on surface.
The first system was to support an HP application that requires high flow area in heavy wall casing. This was the platform for other less traditional systems to expand upon. Utilizing high shot density and big hole (BH) charges, this system was tested to provide a system rating of up to 30 ksi at 425°F while retaining fishability in heavy wall casing. For this system, wellbore effects from perforating, such as dynamic underbalance and recovered debris, are qualitatively aligned with existing perforators.
The second system was optimized to control dynamic transient loading on the perforating string and minimize debris in HP environments. This meant the system was required to fit into a strategy of lowering dynamic structural loads on the workstring created during perforating. The system was designed to affect the pressure interactions among the gun internals, wellbore, and the formation, and control the amount of formation material inflow and debris produced by perforating. This perforating system was developed, qualified, and successfully fielded in multiple wells without any operational issues.
The third system provides increased formation penetration depth without sacrificing shot density. By using deep penetrating (DP) charges, this system is can provide penetration past drilling damage or mitigate higher formation strengths encountered at greater depths in some HP US GoM reservoirs, thus providing operators improved connectivity to the formation.
Evaluating perforating system performance, not only with lab testing but with field-gathered data, is crucial to closing the development loop for HP applications where testing is not practical due to both scale and replication of wellbore conditions. In deployment, the well conditions for the systems were analogous, highlighting the differences in data, thus providing a more complete background for operators to assess the suitability of these systems in HP applications and evaluate their perforating method to maximize production.