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    • 11. 发明申请
    • VISUALIZATIONS OF RESERVOIR SIMULATIONS WITH FRACTURE NETWORKS
    • 用裂缝网络进行储层模拟的可视化
    • WO2017222509A1
    • 2017-12-28
    • PCT/US2016/038591
    • 2016-06-22
    • SCHLUMBERGER TECHNOLOGY CORPORATIONSCHLUMBERGER CANADA LIMITEDSERVICES PETROLIERS SCHLUMBERGERGEOQUEST SYSTEMS B.V.
    • MUSTAPHA, Hussein
    • G06F17/50E21B43/26E21B43/17
    • E21B44/00E21B43/26E21B47/09G06F17/16G06F17/5009
    • Systems and methods are described for generating visualizations of reservoir simulations with embedded fracture networks by using data representing a subterranean formation to obtain a matrix grid with an embedded fracture network. The matrix grid can be separated into matrix grid control volumes, and the fracture network can be separated into fracture network control volumes. Locations of fracture-fracture intersections between the fracture network control volumes and locations of matrix-fracture intersections between the matrix grid control volumes and the fracture network control volumes can be identified. Based on the identified intersections, shapes of the fracture network control volumes can be determined and a visualization of the matrix grid with the embedded fracture network can be generated with a grid representing the matrix grid and an embedded plane within the gird, where the embedded plane is based on the shapes of each fracture network control volume.
    • 描述了系统和方法,用于通过使用表示地下地层的数据来获得具有嵌入式裂缝网络的矩阵网格来生成具有嵌入式裂缝网络的储层模拟的可视化。 矩阵网格可以分为矩阵网格控制体积,裂缝网络可以分为裂缝网络控制体积。 可以识别裂缝网络控制体积与矩阵网格控制体积与裂缝网络控制体积之间的矩阵 - 裂缝相交位置之间的裂缝 - 裂缝交点的位置。 基于所识别的交点,可以确定裂缝网络控制体积的形状,并且可以利用表示矩阵网格的网格和网格内的嵌入平面来生成具有嵌入的裂缝网络的矩阵网格的可视化,其中嵌入的平面 是基于每个裂缝网络控制体积的形状。
    • 12. 发明申请
    • FRACTURING A SUBTERRANEAN FORMATION
    • 破坏一个地下构造
    • WO2017213624A1
    • 2017-12-14
    • PCT/US2016/036070
    • 2016-06-06
    • HALLIBURTON ENERGY SERVICES, INC.
    • GULLICKSON, Geoffrey WedellRUHLE, William Owen AlexanderSTABENAU, John Dean
    • E21B43/25E21B43/26E21B43/17
    • E21B43/26E21B33/13E21B43/14E21B43/267E21B47/06
    • A method of fracturing a subterranean formation to produce fluid from a reservoir through a wellbore includes flowing a treating fluid into the wellbore to create fractures in the formation, selectively flowing a flow constraint material (FCM) into the wellbore simultaneously with the treating fluid, pausing the flow of the FCM while maintaining the flow of the treating fluid, monitoring a parameter of the formation to determine whether the parameter is within a range, resuming the flow of the FCM when the parameter of the formation is out of the range, ceasing the flow of the FCM when the parameter of the formation is in the range, where a system strain increase is about 0.0003 or less when the parameter of the formation is in range, and where the flow of the flow constraint material partially constrains the treating fluid from entering at least one of the fractures.
    • 压裂地下地层以从储层通过井筒产生流体的方法包括使处理流体流入井筒中以在地层中产生裂缝,选择性地使流动约束材料(FCM)流入 在保持处理流体的流动的同时暂停FCM的流动,监测地层的参数以确定参数是否在一个范围内,当地层的参数时重新开始FCM的流动 超出范围时,当地层的参数处于范围内时,停止FCM的流动,当地层的参数处于范围内时,系统应变增加大约为0.0003或更小,并且流动的流动 约束材料部分限制处理流体进入至少一个裂缝。
    • 16. 发明申请
    • HYDRAULIC FRACTURING USING SUPER ABSORBENT POLYMER HAVING CONTROLLED PARTICLE SIZE
    • 使用具有可控颗粒尺寸的超吸收性聚合物的液压破裂
    • WO2017120276A1
    • 2017-07-13
    • PCT/US2017/012244
    • 2017-01-05
    • BAKER HUGHES INCORPORATED
    • SUN, HongCARMAN, Paul S.VOLK, Alyssa MichelleCHAPMAN, Johnny
    • C09K8/62E21B43/26E21B43/17
    • C09K8/685C09K8/80C09K8/88C09K8/887
    • A hydraulic fracturing process comprises combining an aqueous carrier with a superabsorbent polymer and a plurality of proppant particles to form a fracturing fluid; and disposing the fracturing fluid in a downhole environment. When the aqueous carrier has a total dissolved solid content of equal to or less than 400 parts per million and a hardness of less than 100 parts per million as calcium carbonate, the superabsorbent polymer comprises particles having a size of about 145 microns to about 600 microns. When the aqueous carrier has a total dissolved solid content of greater than 400 parts per million to less than 8,000 parts per million and a hardness of greater than 100 parts per million to less than 2,500 parts per million as calcium carbonate, the superabsorbent polymer comprises particles having a size of about 145 microns to about 300 microns.
    • 水力压裂工艺包括将含水载体与超吸收性聚合物和多个支撑剂颗粒结合以形成压裂液; 并将该压裂流体置于井下环境中。 当含水载体具有等于或小于百万分之400份的总溶解固体含量和以碳酸钙计小于百万分之100的硬度时,超吸收性聚合物包含尺寸为约145微米至约600微米 。 当含水载体的总溶解固体含量大于百万分之400至小于8,000份/百万且硬度大于百万分之100至小于2500ppm(以碳酸钙计)时,超吸收性聚合物包含颗粒 具有约145微米至约300微米的尺寸。
    • 18. 发明申请
    • SIMULATING HYDRAULIC FRACTURE PROPAGATION USING DYNAMIC MESH DEFORMATION
    • 利用动态网格变形模拟水力裂缝扩展
    • WO2017082909A1
    • 2017-05-18
    • PCT/US2015/060356
    • 2015-11-12
    • HALLIBURTON ENERGY SERVICES, INC.
    • FRENO, Brian, A.MADASU, SrinathLIN, Avi
    • E21B43/17E21B43/26G06F9/455G05B17/02
    • E21B43/26
    • An illustrative hydraulic fracturing simulation method includes: creating an initial mesh representation of a subterranean formation, the mesh including mesh nodes; determining one or more fracture paths in the formation; for each of the one or more fracture paths, displacing a subset of the mesh nodes into alignment with the fracture path; interpolating from displacements of the aligned mesh nodes to obtain displacements for each non-aligned mesh node in the mesh, thereby obtaining a deformed mesh representation of the formation; using the deformed mesh to construct a linear set of equations representing fracture creation and propagation caused by injection of a hydraulic fracturing fluid; deriving one or more fracture path extensions from the linear set of equations; and displaying the one or more fracture paths with the one or more fracture path extensions accurately representing the fracture propagation path. The interpolation may be performed using radial basis functions.
    • 示例性的水力压裂模拟方法包括:创建地下地层的初始网格表示,所述网格包括网格节点; 确定地层中的一个或多个裂缝路径; 对于所述一个或多个断裂路径中的每一个,将所述网格节点的子集移位成与所述断裂路径对齐; 根据对齐的网格节点的位移进行插值以获得网格中每个未对齐的网格节点的位移,从而获得地层的变形网格表示; 使用变形网格来构建代表由注入水力压裂液引起的裂缝产生和扩展的线性方程组; 从线性方程组导出一个或多个裂缝路径延伸; 以及使用所述一个或多个骨折路径延伸准确地表示所述骨折传播路径来显示所述一个或多个骨折路径。 插值可以使用径向基函数来执行。
    • 19. 发明申请
    • POLYMER HYDRATION SYSTEM AND METHOD
    • 聚合物水合系统和方法
    • WO2017078685A1
    • 2017-05-11
    • PCT/US2015/058808
    • 2015-11-03
    • HALLIBURTON ENERGY SERVICES, INC.
    • FISHER, Chad, A.LUCAS, Bryan, ChapmanSTEGEMOELLER, Calvin, L.
    • E21B43/17E21B43/26C09K8/62
    • E21B21/062
    • A system and method for hydrating a hydratable material are provided in which a first hydration fluid is heated prior to mixing with the hydratable material to produce a hydration mixture. The hydration mixture is subsequently mixed with a second hydration fluid to produce a well injection fluid having a hydrated hydratable material. Generally, the first hydration fluid will be at about ambient temperature before it is heated and the second hydration fluid will be at about at about ambient temperature when it is mixed with the hydration mixture. Typically, the first hydration fluid will be a minor part of the hydration fluid content of the well injection fluid and the second hydration fluid will be a major part of the hydration fluid content of the well injection fluid.
    • 提供了用于水合可水合材料的系统和方法,其中第一水合流体在与可水合材料混合之前被加热以产生水合混合物。 随后将水合混合物与第二水合流体混合以产生具有水合可水合材料的井注入流体。 通常,第一水合流体在加热之前将处于大约环境温度,并且当第二水合流体与水合混合物混合时,第二水合流体将处于大约环境温度。 通常,第一水合流体将是井注入流体的水合流体含量的一小部分,第二水合流体将是井注入流体的水合流体含量的主要部分。