一种新型ESP井下气体分离器

Qinghua Wang, Liu Yonghui, Junzheng Yang, M. Cui, Dan Qi
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引用次数: 2

摘要

对于高glr井的电潜泵(ESP)系统,ESP内部存在气体会导致液压头退化。井下气体分离器(DGS)作为一种提高气液混合处理能力的补救工具,具有至关重要的作用。然而,常规DGS对游离气的分离能力有限,最大分离效率仅为45%。它不能满足更大范围的流量条件和不同的泵型号的现场应用。因此,本文提出了提高DGS气体处理能力的解决方案,以扩大其应用范围。结合离心分离法和重力分离法,提出了三环形设计方案,解决了两级分离器长度较大的问题。在新设计中,采用了一种加速装置,使流体以更高的速度流入螺旋外管与中心管之间的环空。然后,环空中的螺旋叶片将气液混合物分离,导致气体附着在中心管的外壁上,随后通过排气孔排出到套管中。附着在螺旋外管内壁的液体在重力作用下发生反向流动。然后,液体通过排液孔强制进入中心管,流入电除尘器。为了提高分离效率,通过数值模拟对离心分离器螺旋叶片的结构进行优化,包括螺旋叶片的距离和螺纹数。另外,在不同的GLR和偏差下进行了实验研究。实验结果表明,该方法的分离效率在88% ~ 96%之间,而常规方法的分离效率在60%以下。分离效率随偏差的增大而降低,新分离器可应用的最大偏差为50°[1]。新型DGS具有低成本、低功耗的特点,为气层电潜泵的应用提供了经济可行的解决方案;由于新设计大大缩短了传统两级分离器的长度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Novel Downhole Gas Separator in ESP Systems
For Electrical Submersible Pump (ESP) systems in high-GLR wells, presence of gas inside ESP results in the degradation of hydraulic head. As a remedial tool to improve the ability of handling gas-liquid mixtures, Downhole Gas Separator (DGS) is of crucial importance. However, conventional DGS has limited capability in separating free gas and a maximum separating efficiency of 45%. It can't meet the field applications to a wider range of flow conditions and different pump models. Therefore, the paper proposed a solution to improve gas handling ability of DGS to expand its application. Combining centrifugal separation method and gravity separation method, three-annular design was proposed to address the problem of two-stage separator with fairly long length. In the new design, a device is used to accelerate the fluid for higher velocity flowing into the annular between the spiral outer pipe and the central pipe. Then, the helical blades in the annular separate the gas-liquid mixture, leading gas attaching on the out wall of the central pipe and subsequently discharge into casing through the vent holes. The liquid attached on the inner wall of the spiral outer pipe flows reversal because of gravity. Afterwards, liquid is forced into the central pipe through the drainage holes and then flow into the ESP. In order to improve separating efficiency, the structure of helical blades, including distance and number of thread for centrifugal separator was then optimized by numerical simulation. In addition, an experimental study was conducted in different GLR and deviation. The experimental results show separating efficiency ranges between 88% and 96% while the conventional is under 60%. Furthermore, the separation efficiency decreases with the increasing of deviation, and maximum deviation of the new separator can be applied is 50°[1]. The novel DGS provide an economic solution for ESP application in gassy reservoir with low cost and power; since the new design greatly shorten the length of traditional two-stage separator.
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