Analysis of Riser Gas Pressure from Full-Scale Gas-in-Riser Experiments with Instrumentation

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
Mahendra R. Kunju, Mauricio A. Almeida
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引用次数: 1

Abstract

Summary Because the use of adaptive drilling processes, such as managed pressure drilling (MPD), facilitate drilling of otherwise nondrillable wells with faster corrective action, the drilling industry should include the effect of gas dispersion, bubble suspension, fluid compressibility, and riser ballooning to avoid the overestimation of riser pressure and to produce more efficient well control methods. The IADC Deepwater Well Control Guideline recommends always addressing riser gas first, before proceeding to control the well in a well control situation. The intent is to remove the risk of gas reaching the surface and the rig floor, putting personnel and assets at risk. However, with the availability of equipment on the rig dedicated to handling riser gas and the fact that the riser is isolated from the wellbore, the atmosphere reduces the level of risk of gas in the riser, whereas the well below the subsea blowout preventer (SSBOP) poses a greater risk. In this paper, we discuss the results from full-scale experiments recently conducted in an extensively instrumented test well (LSU Well-2) and demonstrate that the riser pressures resulting from upward transport or aggregation of riser gas are much lower than the values estimated using the single-bubble model and industry thumb rules. We explain the danger of using an open-top riser top during the monitoring of gas-in-riser and how the situation can get out of control due to the potential dynamic unloading situation. Our research also demonstrates the minimal fluid bleedoff volumes required to reduce pressure buildup consequences of free gas migration in a fully closed riser containing low-compressibility liquid. A differential pressure methodology used in this paper for analysis was also used for detecting the presence, position, void fraction, and lead and tail velocity of the gas column in real time during each of the tests to make decisions during the tests. The results from a successful application of the fixed choke constant outflow (FCCO) method as a new method for circulating out gas from the riser by staying within the gas-handling capacity of the existing mud gas separator (MGS) on the rig are presented. This is the industry’s first test of the FCCO method.
全尺寸立管内气体压力仪器分析
由于使用自适应钻井工艺,如控压钻井(MPD),可以通过更快的纠正措施来促进非钻井的钻井,因此钻井行业应该考虑气体分散、气泡悬浮、流体压缩性和隔水管膨胀的影响,以避免高估隔水管压力,并产生更有效的井控方法。IADC深水井控指南建议,在进行井控作业之前,首先要解决立管气体问题。目的是消除天然气到达地面和钻井平台的风险,使人员和资产处于危险之中。然而,随着钻井平台上专门处理立管气体的设备的可用性,以及立管与井筒隔离的事实,大气降低了立管中气体的风险水平,而水下防喷器(SSBOP)下方的井则带来了更大的风险。在本文中,我们讨论了最近在LSU井2中进行的全尺寸实验结果,并证明了由立管气体向上输送或聚集引起的立管压力远低于使用单泡模型和行业经验法则估计的值。我们解释了在监测立管内气体时使用开顶立管顶的危险,以及由于潜在的动态卸载情况而导致的情况如何失控。我们的研究还表明,在含有低压缩性液体的全封闭立管中,为了减少自由气体运移造成的压力累积,需要最小的流体泄出量。在每次测试过程中,本文还使用了压差法进行分析,实时检测气柱的存在、位置、空隙率以及导尾速度,以便在测试过程中做出决策。本文介绍了固定节流恒流出法(FCCO)作为一种新的方法,在不超过钻机上现有泥浆气分离器(MGS)的气体处理能力的情况下,从立管中循环排出气体的成功应用结果。这是业界首次对FCCO方法进行测试。
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来源期刊
SPE Drilling & Completion
SPE Drilling & Completion 工程技术-工程:石油
CiteScore
4.20
自引率
7.10%
发文量
29
审稿时长
6-12 weeks
期刊介绍: Covers horizontal and directional drilling, drilling fluids, bit technology, sand control, perforating, cementing, well control, completions and drilling operations.
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