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MODEL OF SEPARATED-LAYER GAS INJECTION SYSTEM IN CO2 FLOODING AND ITS APPLICATION

卷 11, 册 3, 2020, pp. 221-237
DOI: 10.1615/SpecialTopicsRevPorousMedia.2020029564
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摘要

Separated-layer gas injection is an effective method to control CO2 channeling and improve the development effect in CO2 flooding. The selection and control of gas injection parameters is the key step in the application of CO2 flooding. In this paper, the physical models of single-tubing and double-concentric-tubing separated-layer gas injection technologies were established. And then, by analyzing CO2 flowing characteristics in pipeline, wellbore, gas nozzle, and formation, the mathematical models of separated-layer gas injection technologies were established. The mathematical models were solved with the nodal system analysis method. In addition, the impacts of tubing size, gas nozzle size, reservoir static pressure, and reservoir permeability on CO2 injection performance were analyzed with the simulation of mathematical models. The results show that reasonable CO2 injection rates increase proportionally with the increase of tubing size, gas nozzle size, and reservoir permeability, and reasonable CO2 injection rates decrease with the increase of reservoir static pressure. Finally, taking CO2 injection wells in the Jilin oil field of China as an example, the reasonable gas injection parameters were calculated. This paper can provide a theoretical basis and guidance for field application of separated-layer gas injection technologies in CO2 flooding.

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对本文的引用
  1. Qin Yong, Zhang Haochuan, Liu Chang, Ding Haifeng, Liu Tianyu, Sun Yu, Tang Yong, Liu Hao, Hydrocarbon Gas Flooding Optimization considering Complex Fracture Networks through Numerical Simulation in the Tight Oil Reservoirs, Lithosphere, 2021, Special 4, 2021. Crossref

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