多能伽马射线风险式多相流量计在卡拉恰甘纳克巨型凝析气田的多重应用

Aidyn Kartamyssov, Beibit Bissakayev, Bolat Zhumabayev, Raziya Shektebayeva, M. Durekovic, B. Akbayev, Y. Kaipov
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引用次数: 0

摘要

为了验证多能伽马射线风险型多相流量计(MPFM)在KPO B.V.运营的Karachaganak凝析巨型碳酸盐岩气田的多重应用,将MPFM纳入地面试井范围的结果与便携式测试分离器、工厂生产测试设备(控制分离器、流量计)和人工采样结果进行了比较,以验证其性能。以往,由于Karachaganak油田储层流体的复杂性,其他供应商的MPFM未能提供准确的产量测量。为了确保MPFM考虑到这种复杂性,我们采集了PVT样本,为MPFM的PVT模型提供实验室数据,以保证PVT数据的足够质量,并与MPFM内部的PVT模型进行比较。MPFM的第一次应用是在油井移交生产之前的清理过程中。使用MPFM有助于提高数据采集的质量。这些信息对于该井所连接的处理设施的接受以及确定最佳操作方案至关重要。MPFM在不稳定(发泡、结转)和瞬态生产阶段的BS&W、GOR和速率验证显示出实际优势。另一个应用是水采样回路,以测量含水率和产量。由于现有测试分离器的限制,KPO在含水测量方面存在不准确的挑战。最近在井口进行流体采样(采样环路)的方法被证明是可靠的测量来源。此外,MPFM与测试分离器结合使用,进一步提高了各相测量的质量。MPFM的第三个应用是高气体积分数(HGVF)泵,它有助于从低储层压力、低GOR和高含水井中进行生产。HGVF泵的工作范围限制在气体体积分数(GVF)的75-80%。MPFM实时测量GVF,通过管理地面流动条件,确保HGVF泵在最佳运行范围内运行。由于Karachaganak油田目前测试分离器的局限性,以及凝析液的复杂性,MPFM的使用为测量(速率、含水率和GOR)带来了额外的质量,这对油田生产优化、油藏管理以及短期和长期预测至关重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multiple Application of Multi-Energy Gamma Ray Venture Type Multiphase Flowmeter in Giant Karachaganak Gas Condensate Field
The objective of this paper is to demonstrate multiple application of multi-energy gamma ray venture type multiphase flowmeter (MPFM) trial campaign in Karachaganak gas condensate giant carbonate field, operated by KPO B.V. The results of MPFM that was included into surface well test spread, to verify its performance, was compared against portable test separator and plant production testing facilities (control separator, flowmeters) and manual sampling results. MPFM from other vendors historically failed to deliver accurate production measurement mainly due to complexity of reservoir fluid in Karachaganak field. To ensure the MPFM considers this complexity, PVT samples were taken to provide laboratory data for PVT model of the MPFM to ensure sufficient quality of PVT data and compare against PVT model inside MPFM. First application of MPFM was during clean-up of the well prior handover well to production. Using MPFM helped to improve the quality during data acquisition. This information was critical for the well to be accepted by processing facility it is hooked-up to and to define optimal operating regime. Validation of BS&W, GOR and rates in unstable (foaming, carry over) and transient phase of production using MPFM has shown practical advantages. Another application was for water sampling loops to measure water cut and production rates. KPO has had challenges with inaccurate water cut measurement due to the limitations of existing test separators. A recent approach of performing fluid sampling (sampling loop) at the well head proved to be reliable source of measurements. In addition, the MPFM in combination with the test separator has been used to further improve the quality of the measurements of each phase. The third MPFM application had been with high gas-volume-fraction (HGVF) pumps, that helped to produce from low reservoir pressure, low GOR and high water cut wells. The operational range of HGVF pump was limited to maximum 75-80% of gas-volume-fraction (GVF). MPFM measures GVF in real-time to ensure HGVF pump operates in optimum operational range by managing the surface flow conditions. With current limitations of test separators in Karachaganak field and due to complexity of the gas-condensate fluid, the use of MPFM brings additional quality in the measurements (rates, water cut and GOR) which is crucial for field production optimization, reservoir management and short and long term forecasting.
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