有许多方法可以预测火烧油层工艺的开发参数。
There are a lot of methods of forecasting production parameters of in? Situ combustion technology.
火烧油层是热力开采稠油油藏的重要方法,其成功的关键是油层点火。
In situ combustion is an important method for thermal recovery of viscous oil reservoir, the key of success is sand face ignition.
利用室内实验和数值模拟研究火烧油层采油过程中的燃烧及传热机理。
With laboratory experiment and numerical simulation, the mechanisms of combustion and heat transfer during oil production of in-situ combustion are studied.
根据火烧油层室内燃烧管模拟实验台的条件,建立了一个一维数学模型。
A one-dimensional mathematical model was established to describe the experimental in-situ combustion process.
油藏初始温度对火烧油层驱油效果影响较大,而油藏初始压力则影响较小。
The influence of initial temperature of reservoir is fairly important, and the initial pressure of reservoir is little important.
通过湿式燃烧的实验研究,为火烧油层在现场进行湿式燃烧实验提供了设计参数。
Design parameters for putting formation wet combustion into site operation are also presented through experimental research.
利用火烧油层燃烧管物理模拟技术,对胜利油区河口油田稠油进行了湿式燃烧实验。
Incorporating physical simulation on pipe for formation combustion, heavy oil formation of Hekou oilfield, Shengli oil province has undergone wet combustion test.
在实验区沥青质采收率从使用循环气驱方法的15%增加到用火烧油层技术累计量的30%。
Bitumen recovery factor at the pilot increased from 15% with CSS to a cumulative of almost 30% with in-situ combustion.
从火烧油层的筛选标准、实际地质条件及室内物理模拟实验入手,对该油田火烧可行性进行了分析。
The feasibility of in situ combustion is analyzed by starting with the screening criteria, geological conditions and in-house physical modeling.
利用该模型可以对火烧油层注气井试井压降曲线进行解释,并求解流度比、扩散比以及各区的波及半径等参数。
With this model, the pressure drop curve of well testing is interpreted, and mobility ratio, diffusion ratio, sweep radius of each area and some other parameters are solved.
利用该模型可以对火烧油层注气井试井压降曲线进行解释,并求解流度比、扩散比以及各区的波及半径等参数。
With this model, the pressure drop curve of well testing is interpreted, and mobility ratio, diffusion ratio, sweep radius of each area and some other parameters are solved.
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