Best Practices and Lessons Learned in Deploying and Setting Dissolvable Frac Plugs in Middle East at HPHT Conditions

S. Muhammad, Mohammed Kurdi, A. Momin, Muzzammil Shakeel, Roberto Vega, Yvan Simmons
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Abstract

The multistage hydraulic fracturing technique is considered to be one of the most effective stimulation techniques used for exploiting unconventional plays. The use of dissolvable frac plugs in multistage hydraulic fracturing has the potential to reduce well intervention requirements. Applicability of dissolvable frac plugs, as an integral part of plug and perf operations, in Middle East unconventional plays presents a myriad of technical challenges associated with high-pressure and high-temperature (HPHT) well conditions. Two counteracting drivers coexist in dissolvable frac plug design: 1) The need for the frac plug to withstand well conditions during the entire frac stage operational cycle and 2) the requirement for the frac plug to dissolve as quickly as possible after the stimulation treatment has been placed. The HPHT conditions of the wells utilizing dissolvable frac plugs adds to the complexity of not only the plug design, but also its associated deployment operational procedures. The main premise of the functional methodology of dissolvable frac plugs involves a chain reaction being triggered in the presence of specific fluids under specific temperature conditions. After the commencement of the degradation/dissolution chain reaction process, the useful lifetime of the frac plug begins to deplete, where the degradation chain reaction accelerates with increasing temperature exposure. Site operations will then conform to expedited practices to minimize undesired exposure time. This would minimize the risks of degradation/dissolution before plug setting, plug test, and actual stimulation treatment placement. Based on the HPHT well conditions of Middle Eastern unconventional plays, a structured process was put in place to satisfy the define, assess, select, and execute phases of the initiative The inevitable occurrences of unforeseen complications during operational deployments served to accelerate the learning curve for the continued utilization of dissolvable frac plugs. Operational issues ranging from electric line unit complications to frac pump downtime during the initial frac plug deployments compromised the structural integrity and functionality of the dissolvable frac plugs. Recognizing that exposure time was critical to maintaining the structural integrity of the plug, best practices were derived and enforced to minimize said exposure time. In addition, slight design modifications were made to specific components of the plug to increase its robustness while not compromising the desired degradation rates. The adoption of these mitigating measures has resulted in the acceptance of the dissolvable frac plug as the standard plug option for all plug and perf operations. The vast experience gained during the deployment of more than 1,000 dissolvable frac plugs for hydraulic fracturing stages in a Middle Eastern country has served as a basis to conceive a list of best practices to address mitigating unforeseen complications. These best practices are enforced to minimize plug exposure time, which in turn maximizes the probability of plug utilization success.
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中东高温高压条件下可溶解压裂桥塞下入和坐封的最佳实践和经验教训
多级水力压裂技术被认为是开发非常规油气藏最有效的增产技术之一。在多级水力压裂中使用可溶解压裂桥塞有可能降低油井干预要求。可溶解压裂桥塞作为桥塞和射孔作业的重要组成部分,在中东非常规区块的适用性给高压高温(HPHT)井况带来了无数的技术挑战。在可溶解压裂桥塞的设计中,存在两个相互抵消的驱动因素:1)压裂桥塞需要在整个压裂阶段的作业周期内承受井况;2)压裂桥塞需要在增产作业完成后尽快溶解。使用可溶解压裂桥塞的井的高温高压条件不仅增加了桥塞设计的复杂性,而且增加了相关部署操作程序的复杂性。可溶解压裂桥塞功能方法的主要前提是在特定温度条件下存在特定流体时触发连锁反应。降解/溶解链式反应开始后,压裂桥塞的使用寿命开始耗尽,随着温度的升高,降解链式反应加速。然后,现场操作将符合快速实践,以最大限度地减少不必要的暴露时间。这可以在桥塞坐封、桥塞测试和实际增产作业之前将降解/溶解的风险降至最低。根据中东非常规油气区块的高温高压井条件,该公司制定了一套结构化的流程,以满足该计划的定义、评估、选择和执行阶段。在作业部署过程中,不可避免地会出现不可预见的复杂情况,这有助于加快可溶解压裂桥塞的持续使用。在压裂桥塞的初始部署过程中,从电缆单元的复杂性到压裂泵的停机等操作问题都会损害可溶解压裂桥塞的结构完整性和功能。认识到暴露时间对于保持桥塞的结构完整性至关重要,因此得出并实施了最佳实践,以最大限度地减少暴露时间。此外,对桥塞的特定部件进行了轻微的设计修改,以提高其坚固性,同时不影响预期的降解率。由于采用了这些缓解措施,可溶解压裂桥塞已成为所有桥塞和射孔作业的标准桥塞选择。在一个中东国家的水力压裂阶段,在部署了1000多个可溶解压裂桥塞的过程中,积累了丰富的经验,为制定一系列最佳实践奠定了基础,以解决不可预见的并发症。实施这些最佳实践可以最大限度地减少桥塞暴露时间,从而最大限度地提高桥塞成功利用的可能性。
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