Benjamin Wu, Mahshid Firouzi, T. Rufford, B. Towler
{"title":"Mitigating the Failure of Downhole Pumps Due to Gas Interference in Coal Seam Gas Wells","authors":"Benjamin Wu, Mahshid Firouzi, T. Rufford, B. Towler","doi":"10.2118/191910-MS","DOIUrl":null,"url":null,"abstract":"\n Coal seam gas (CSG) well operators typically follow an industry rule of thumb 0.5 ft/s liquid velocity to prevent the onset of gas carryover during CSG dewatering operations. However, there is very little experimental data to validate this rule of thumb with only a publication by Sutton, Christiansen, Skinner and Wilson [1] available in the open literature. A review of more general studies on two-phase gas-water flows in vertical pipes and annuli revealed that experimental conditions, especially pipe and annuli diameters, can have a significant impact on development of two-phase flow phenomena. As such, the limited available data may not be applicable due to differences in experimental conditions. This study experimentally investigates the onset of gas carryover using an experimental setup intended specifically for the study of CSG wells.\n The University of Queensland Well Simulation Flow Facilities were designed to replicate as closely as possible the production zone of a typical vertical CSG well in Queensland, Australia in transparent acrylic pipes to observe two-phase flow behavior in simulated downhole conditions. The annular test section in the rig was constructed of a 7-in casing and 2¾-in tubing. Modification of the experimental setup to include a vertical separator allowed for the detection of gas carryover. Conceptual demonstrations of gas carryover were captured and have been illustrated. The experiments in this study validate the industry rule of thumb of 0.5 ft/s liquid velocity as an appropriate guideline for onset of gas carryover in a casing-tubing annulus dimension similar to a typical CSG well in Queensland.","PeriodicalId":11240,"journal":{"name":"Day 1 Tue, October 23, 2018","volume":"121 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2018-10-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Day 1 Tue, October 23, 2018","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.2118/191910-MS","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 2
Abstract
Coal seam gas (CSG) well operators typically follow an industry rule of thumb 0.5 ft/s liquid velocity to prevent the onset of gas carryover during CSG dewatering operations. However, there is very little experimental data to validate this rule of thumb with only a publication by Sutton, Christiansen, Skinner and Wilson [1] available in the open literature. A review of more general studies on two-phase gas-water flows in vertical pipes and annuli revealed that experimental conditions, especially pipe and annuli diameters, can have a significant impact on development of two-phase flow phenomena. As such, the limited available data may not be applicable due to differences in experimental conditions. This study experimentally investigates the onset of gas carryover using an experimental setup intended specifically for the study of CSG wells.
The University of Queensland Well Simulation Flow Facilities were designed to replicate as closely as possible the production zone of a typical vertical CSG well in Queensland, Australia in transparent acrylic pipes to observe two-phase flow behavior in simulated downhole conditions. The annular test section in the rig was constructed of a 7-in casing and 2¾-in tubing. Modification of the experimental setup to include a vertical separator allowed for the detection of gas carryover. Conceptual demonstrations of gas carryover were captured and have been illustrated. The experiments in this study validate the industry rule of thumb of 0.5 ft/s liquid velocity as an appropriate guideline for onset of gas carryover in a casing-tubing annulus dimension similar to a typical CSG well in Queensland.
煤层气(CSG)井运营商通常遵循行业经验规则,即0.5英尺/秒的液体速度,以防止在CSG脱水过程中发生气体携流。然而,只有Sutton, Christiansen, Skinner和Wilson[1]在公开文献中发表的一篇文章中,很少有实验数据来验证这一经验法则。对垂直管道和环空中气水两相流动的研究表明,实验条件,特别是管道和环空直径,对两相流动现象的发展有重要影响。因此,由于实验条件的差异,有限的可用数据可能不适用。本研究使用专门用于研究CSG井的实验装置,实验研究了气体携带的开始。昆士兰大学(University of Queensland)的井模拟流动设施旨在尽可能地复制澳大利亚昆士兰(Queensland)一口典型的垂直CSG井的生产区域,在透明丙烯酸管中观察模拟井下条件下的两相流动行为。钻机的环空测试部分由7英寸套管和2¾英寸油管组成。修改实验装置,包括一个垂直分离器,允许检测气体携带。捕获并说明了气体携带的概念演示。本研究的实验验证了行业经验法则,即0.5英尺/秒的液体速度是在类似于昆士兰典型的CSG井的套管-油管环空尺寸中气体携带开始的适当指导。