案例研究:针对三个含水地层的单井设计

Hamad Al-Qattan, Emad Al-Jassam, Magdy Mansour, Mahmoud Morcey
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引用次数: 0

摘要

设计一口陆上试验井,作为水处理井,针对三个潜在地层中的一个进行测试和评估其注入能力。根据评估结果,将选择一个新的、更深的地层来处理不需要的伴生采出水,而不是目前被当局认为是天然含水层的浅层地层。该井的设计目标是在一个斜角到达第一个目标,之后将开始赤脚注入测试的评估。决定是继续钻探到第二个目标还是完成井在很大程度上取决于注入性测试结果。将钻井斜角降至第二目标的垂直位置,在此位置下入最后一尾尾管并射孔,然后进行地层测试。如果在第二次注入测试中遇到失败,将继续钻至最深的目标,并进行最后的赤脚测试。试验处置井的最终优化设计旨在以最小的钻井风险满足油藏和地质团队。这口井与其他深邻井之间的距离是主要的挑战,因为在处置地点,计划的总深度从未达到。此外,该设计还针对目标之间的分离和长间隔的钻井段进行了定制。此外,除了地层压力和地层破裂压力的不确定性外,最深层地层流体的不确定性在准备钻井液方案时也是一个很大的争议,特别是在使用水基泥浆作为钻井液的目标层中,为了不破坏地层,也不影响注入测试的结果。试验处理井成功钻穿了两个目标,而无需钻到第三层。因此,在油藏团队评估了两次注入性测试后,将确定用于处理产出但不需要的水的新地层。注入能力评估的结果还提供了能够处理所有预期产出水的所需井数,并为地面设施提供了必要的升级,以适应注入压力。这种独特的具有挑战性的井设计,结合了斜井和垂直轨迹,可以在预算有限的情况下使用,同时你有多个不同的目标需要勘探。此外,由独立承包商进行的一项专门的环境影响研究证实,注入水对地下水没有危害。
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Case Study: Single Well Design Targeting Three Water Bearing Formations
Designing an onshore pilot well to be drilled and functioning as water disposal well targeting one of three potential formations to test and evaluate their injectivity. Based on evaluation results, an alternative new and deeper formation will be selected to dispose the unwanted associated produced water, instead of the current shallow formation that is considered as a natural aquifer by authorities. The well is designed to reach the first target in a deviated angle after which evaluation of the barefoot injectivity testing will begin. The decision whether to continue drilling to a secondary target or complete the well depends heavily on the injectivity testing results. The deviated angle of drilling will be dropped to reach a vertical position for the secondary target upon which the last liner will be run and perforated, then the formation testing will be conducted. In case of encounterg failure in the second injectivity testing, drilling to the deepest target will continue and final barefoot testing will be performed. A final optimal design for the pilot disposal well is intended to meet the reservoir and geological team with minimal drilling risks. The distance between this well and the other deep offset wells was the main challenge where the planned total depth was never reached in the disposal location. Also, the design was tailored to accommodate the drilling sections with the separation and long intervals between the targets. Furthermore, the uncertainty of the deepest formation fluid in addition to the uncertainties of formations pressure and formations fracture pressure were a big dispute while preparing the drilling fluids programs particularly across the target in which a water based mud was used as drilling fluid not to damage the formations nor to jeopardize the results of the injectivity tests. The pilot disposal well is drilled successfully penetrating two targets without the need to drill to the third formation. Hence, the new formation that will be used to dispose of the produced but unwanted water is defined after the reservoir team have evaluated the two injectivity tests. The results of the injectivity evaluation also provided the required number of wells that can handle all the expected produced water, and provided the required upgrade for the surface facilities to accommodate the injection pressure. This unique challenging well design, combining slanted and vertical trajectories, can be utilized whenever the budget is limited to one well, while you have multiple different targets to explore. Moreover, a specialized environmental impact study, conducted by independent contractor, confirms that there was no harm from the injected water to the groundwater.
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