Jasbindra Singh, Mohammed Harthi, Mohamed Siyabi, Marya Al Salmi, Carmen Hamm, Omar Riyami, Safiya Hatmi, Rady Abdel Samiee, Mohammed Hinai, Anas Mazroui, Yousuf Sinani, I. Mahruqi, Nasser Al Azri
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引用次数: 0
Abstract
Produced water is an inextricable part of the hydrocarbon recovery processes, yet it is by far the largest volume waste stream associated with hydrocarbon recovery. In a C-field in South Oman, the produced water has been disposed in the aquifer zone of the producing formation. The feasibility of alternative ways to dispose water at surface using alternative options is being evaluated with the objective of reducing (or completely stopping) this water disposal which has shown benefits in maximizing the recovery by reversing the pressure decline. A simple model has been used to quantify the benefits of produced water re-injection into the deep aquifer zone.
Deep water disposal (DWD) has been on-going for over 20 years in the aquifer zone in the B-formation in this field in South Oman. All the produced water from the surrounding fields is sent for disposal near the field via the C-Field Processing Station DWD system. This DWD activity has provided important energy to the system as evident in the reversing reservoir pressure trend in field. However, due to various reasons, efforts are being put forward with the aim of replacing DWD with alternative ways of disposing produced water at surface.
An integrated model has been built and calibrated to the field response and used to predict the field performance. The calibrated model recommends to continue pressure to the field through water disposal or injection system. The study predicts the complete discontinuation of DWD will put significant reserves at risk eroding the field value and has quantified the amount of water available for the alternative options for surface disposal. The study has also identified an opportunity to further optimize the solution for pressure maintenance and thereby, potentially improving the recovery from the field.
采出水是油气回收过程中不可分割的一部分,也是迄今为止与油气回收相关的最大的废水流。在阿曼南部的一个c型油田,采出水已被处理到生产地层的含水层中。为了减少(或完全停止)这种水处理方式,正在评估使用替代方案在地表处理水的替代方法的可行性,这种处理方式已经显示出通过扭转压力下降来最大限度地提高采收率的好处。一个简单的模型被用来量化采出水回注到深层含水层的效益。在阿曼南部该油田的b层含水层中,深水处理(DWD)已经进行了20多年。周围油田的所有采出水都通过C-Field Processing Station DWD系统送到油田附近处理。这一DWD活动为系统提供了重要的能量,这一点在现场的油藏压力逆转趋势中得到了体现。然而,由于种种原因,人们正在努力用其他的地表采出水处理方法来取代直接钻井。建立了一个集成模型,并根据现场响应进行了校准,用于预测现场性能。校准后的模型建议通过水处理或注入系统继续向现场施加压力。该研究预测,完全停止DWD将使大量储量面临侵蚀油田价值的风险,并量化了可供地面处理替代方案的水量。该研究还发现了进一步优化压力维持解决方案的机会,从而有可能提高油田的采收率。