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    • 1. 发明授权
    • Sand and fluid production and injection modeling methods
    • 砂和流体生产和注射造型方法
    • US08666717B2
    • 2014-03-04
    • US13120115
    • 2009-09-21
    • Ganeswara R. DasariDavid P. YaleJianlin Wang
    • Ganeswara R. DasariDavid P. YaleJianlin Wang
    • G06G7/48G06G7/50
    • E21B43/00G06F17/5018G06F2217/16
    • Methods for modeling subsurface reservoirs are provided. In at least one embodiment, the process includes building a numerical model of a reservoir having at least one injection well and at least one producing well, and incorporating at least one of an Eulerian boundary condition (EBC) into each of the at least one injection well and at least one producing well, an advanced constitutive model (ACM) int the reservoir, and an adaptive re-meshing technique (ART) into the reservoir model. Then generating a simulation result from the integrated reservoir model, wherein the simulation result includes at least a volume of produced fluids and produced particulate solids from the reservoir, a volume of injected fluids and injected particulate solids into the reservoir, and a simulation of movement of at least a volume of particulate solids and fluids in the reservoir.
    • 提供了地下储层建模方法。 在至少一个实施例中,该方法包括建立具有至少一个注入井和至少一个生产井的储层的数值模型,并将欧拉边界条件(EBC)中的至少一个纳入至少一个注入 井和至少一个生产井,水库中的先进本构模型(ACM),以及水库模型中的自适应再啮合技术(ART)。 然后从所述综合储层模型产生模拟结果,其中所述模拟结果包括产生的流体的体积和从储层产生的颗粒固体,注入的流体体积和注入的颗粒固体进入储层,以及模拟运动 储存器中至少一定体积的固体颗粒和流体。
    • 2. 发明申请
    • Sand and Fluid Production and Injection Modeling Methods
    • 砂和流体生产和注射建模方法
    • US20110213602A1
    • 2011-09-01
    • US13120115
    • 2009-09-21
    • Ganeswara R. DasariDavid P. YaleJianlin Wang
    • Ganeswara R. DasariDavid P. YaleJianlin Wang
    • G06G7/48
    • E21B43/00G06F17/5018G06F2217/16
    • Methods for modeling subsurface reservoirs are provided. In at least one embodiment, the process includes building a numerical model of a reservoir having at least one injection well and at least one producing well, and incorporating at least one of an Eulerian boundary condition (EBC) into each of the at least one injection well and at least one producing well, an advanced constitutive model (ACM) int the reservoir, and an adaptive re-meshing technique (ART) into the reservoir model. Then generating a simulation result from the integrated reservoir model, wherein the simulation result includes at least a volume of produced fluids and produced particulate solids from the reservoir, a volume of injected fluids and injected particulate solids into the reservoir, and a simulation of movement of at least a volume of particulate solids and fluids in the reservoir.
    • 提供了地下储层建模方法。 在至少一个实施方案中,该方法包括建立具有至少一个注入井和至少一个生产井的储层的数值模型,并将欧拉边界条件(EBC)中的至少一个纳入至少一个注入 井和至少一个生产井,水库中的先进本构模型(ACM),以及水库模型中的自适应再啮合技术(ART)。 然后从所述综合储层模型产生模拟结果,其中所述模拟结果包括产生的流体的体积和从储层产生的颗粒固体,注入的流体体积和注入的颗粒固体进入储层,以及模拟运动 储存器中至少一定体积的固体颗粒和流体。
    • 6. 发明申请
    • Artificial Lift Modeling Methods and Systems
    • 人工提升建模方法与系统
    • US20120211228A1
    • 2012-08-23
    • US13384312
    • 2010-07-09
    • Andrey A. TroshkoDavid P. Yale
    • Andrey A. TroshkoDavid P. Yale
    • E21B43/12G06F7/60E21B43/16G06F17/10
    • E21B43/124
    • Methods for modeling, configuring, and controlling artificial lift processes are provided as well as systems for controlling artificial lift and hydrocarbon production systems. In particular, the methods and systems include the use of computation solid-liquid slurry models and reservoir inputs configured to provide inputs to configure parameters of an artificial lift system. The methods and systems may also incorporate fluid lift computational models and volume of fluid (VOF) models for verifying the numerical results. The disclosed methods and systems may beneficially be used in combination with hydrocarbon production processes such as fluidized in-situ reservoir extraction (FIRE) process; a SRBR process; an enhanced CHOPS process; and any combination thereof.
    • 提供了建模,配置和控制人造电梯过程的方法以及用于控制人造电梯和碳氢化合物生产系统的系统。 特别地,所述方法和系统包括使用计算固体 - 液体浆料模型和储存器输入,其被配置为提供用于配置人造举升系统的参数的输入。 方法和系统还可以包括流体提升计算模型和流体体积(VOF)模型,用于验证数值结果。 所公开的方法和系统可有利地与烃生产过程如流化原位油藏提取(FIRE)方法结合使用; SRBR过程; 增强的CHOPS过程; 及其任何组合。
    • 9. 发明申请
    • Dense Slurry Production Methods and Systems
    • 密集浆料生产方法与系统
    • US20120175127A1
    • 2012-07-12
    • US13384307
    • 2010-07-09
    • David P. YaleAndrey A. TroshkoBennett D. Woods
    • David P. YaleAndrey A. TroshkoBennett D. Woods
    • E21B43/00
    • E21B43/124
    • Methods and systems for producing a dense oil sand slurry from subsurface reservoirs are provided. The methods include reducing pressure at a producer pipe inlet to draw a dense slurry into the producer pipe using a jet pump, generating a diluted dense slurry using the jet pump, and lifting the diluted dense slurry through the producer pipe utilizing a slurry lift apparatus, which may be a fluid lift apparatus. The systems include a producer pipe into an oil sand reservoir, a jet pump configured to generate a low pressure region around the opening of the producer pipe to draw the dense slurry into the producer pipe and dilute the dense slurry to form a diluted dense slurry; and a gas lift apparatus configured to lift the diluted dense slurry through the producer pipe towards the surface of the earth.
    • 提供了从地下储层生产稠油砂浆的方法和系统。 所述方法包括:使用喷射泵将制造管入口处的压力降低到生产管中,使用喷射泵产生稀释的致密浆料,以及使用浆料提升装置通过生产管道提升稀释的稠浆料, 其可以是流体提升装置。 这些系统包括一个进入油砂储存器的生产管,一个喷射泵,其构造成在生产管的开口附近产生一个低压区,以将致密的浆料吸入生产管中,并稀释稠浆以形成稀释的稠浆; 以及气体提升装置,其构造成将稀释的致密浆料通过生产管道提升到地球表面。
    • 10. 发明授权
    • Method for calibrating a model of in-situ formation stress distribution
    • 校准原位地层应力分布模型的方法
    • US07941307B2
    • 2011-05-10
    • US11250804
    • 2005-10-14
    • William A. SymingtonDavid P. Yale
    • William A. SymingtonDavid P. Yale
    • G06G7/48
    • E21B49/006
    • A method for producing a substantially calibrated numerical model, which can be used for calculating a stress on any point in a formation, accounts for a formation's geologic history using at least one virtual formation condition to effectively “create” the present-day, virgin stress distribution that correlates, within acceptable deviation limits, to actual field stress measurement data obtained for the formation. A virtual formation condition may describe an elastic rock property (e.g., Poisson ratio, Young's modulus), a plastic rock property (e.g., friction angle, cohesion) and/or a geologic process (e.g., tectonics, erosion) considered pertinent to developing a stratigraphic model suitable for performing the desired stress analysis of the formation.
    • 用于产生可用于计算地层中任何点的应力的基本上校准的数值模型的方法考虑到地层的地质历史,使用至少一个虚拟地层条件来有效地“创造”当今的原始应力 分布在可接受的偏差范围内与为形成获得的实际场应力测量数据相关。 虚拟形成条件可以描述与发展中的岩石相关的弹性岩石性质(例如,泊松比,杨氏模量),塑性岩石性质(例如摩擦角,内聚力)和/或地质过程(例如,构造,侵蚀) 地层模型适用于对地层进行所需的应力分析。