公开(公告)号：US20220290561A1

公开(公告)日：2022-09-15

申请号：US17394071

申请日：2021-08-04

Applicant: SOUTHWEST PETROLEUM UNIVERSITY

Inventor： Ping GUO ,  Zhouhua WANG ,  Yijian CHEN ,  Bowen SUN ,  Chao DONG ,  Yisheng HU ,  Shuoshi WANG

IPC: E21B49/08 ,  E21B49/00 ,  G01N30/02 ,  G01N33/28 ,  G01N33/24

Abstract: The invention relates to a device for testing the three-phase saturation of oil, gas and water in a high-temperature and high-pressure planar model, comprising a displacement pump 1, a confining pressure pump 2, a back pressure pump 3, containers, a planar model system 21, a data acquisition system 22, a back pressure valve 23 and an oil-gas separator 24. The planar model system includes a planar model 27, an autoclave body 31, a heating temperature-controlling system 34, a Y-axis direction stepping motor 35, a X-axis direction stepping motor 36 and an acoustoelectric detector 41. A method for testing the three-phase saturation of oil, gas and water by using the device includes: calibrating three-phase saturation of oil, gas and water to a rock core, preparing a formation water sample and a crude sample, regaining the original formation conditions of the planar model, simulating the depletion or displacement process of oil reservoirs, performing linear ultrasonic-and-resistivity-scanning test on planar model, determining the three-phase saturation distribution of oil, gas and water in the planar model. The invention has simple operation and intuitive measurement, and provides tools and means for testing the three-phase saturation of oil, gas and water during the depletion or displacement development of oil-gas reservoirs.

公开(公告)号：US20230366869A1

公开(公告)日：2023-11-16

申请号：US18130924

申请日：2023-04-05

Applicant: Southwest Petroleum University

Inventor： Shuoshi WANG ,  Wenhua ZHAO ,  Ping GUO ,  Zhouhua WANG ,  Jianfen DU ,  Yisheng HU ,  Huang LIU

IPC: G01N33/28

CPC classification number: G01N33/28

Abstract: A Hydrophilic-Lipophilic Deviation theory-based method is provided to prepare representative degassed oil with equivalent minimum miscible pressure to live oil. The method can reduce the number of trial and error type experiments during the representative degassed oil preparation process by measuring the MMP and EACN for dead and live oil. The representative degassed oil formulation could be easily predicted after determining the required MMP and EACN values. The prepared oil can reflect the key mechanism of multiple contact miscible mechanism in the process of gas flooding more accurately. It allows experiments that are inconvenient to use live oil to consider the mechanism of multiple contact miscibility easily.

公开(公告)号：US20240068923A1

公开(公告)日：2024-02-29

申请号：US18501936

申请日：2023-11-03

Applicant: Southwest Petroleum University

Inventor： Ping YUE ,  Hongnan YANG ,  Yuan LEI ,  Xu ZHENG ,  Peng SONG ,  Pengyu CHEN ,  Zhouhua WANG ,  Simin QU

IPC: G01N15/08 ,  G01N33/24

CPC classification number: G01N15/0806 ,  G01N33/24

Abstract: A device for simulating carbon dioxide storage in a deep saline aquifer, including a CO2 gas source, first and second valves, first and second pressure pumps, first, second and third pressure gauges, a water storage tank, a simulation box, a first flow meter, a gas-liquid separator, a recycling tank, a microcomputer-display assembly, a structure plate, core holders, an injection pipeline, a connection pipeline, a baffle, a piezometer, a second flow meter, a heater, a lifter and an acoustic logging tool. The CO2 gas source, the first valve, the first pressure pump and the first pressure gauge for gas injection. The water storage tank, a second pressure pump and a second pressure gauge for water injection. The second valve, the third pressure gauge, the first flow meter, the gas-liquid separator and the recycling tank form an output pipeline.

公开(公告)号：US20200340356A1

公开(公告)日：2020-10-29

申请号：US16839692

申请日：2020-04-03

Applicant: Southwest Petroleum University

Inventor： Yisheng HU ,  Xuan BAI ,  Ping GUO ,  Jianfen DU ,  Zhouhua WANG ,  Huang LIU

IPC: E21B49/00 ,  E21B47/06 ,  E21B43/16 ,  G01V99/00

Abstract: The invention discloses a method for evaluating the difference in gas injection effect of gas injection wells in a carbonate reservoir, aiming at solving the problem that the difference in effect characters of gas injection wells cannot be systematically evaluated in the prior art, and realizing the purposes of systematically and completely evaluating the difference in gas injection effect in the carbonate reservoir and finding out the reason of low efficiency. By means of the invention, reasons for low gas injection efficiency corresponding to different geological classifications are obtained, systematic classification and induction are carried out on the difference in gas injection effect, and gas injection effects are effectively evaluated, so that a sufficient gas injection scheme design basis is provided for subsequent development and production increase, and a significant guiding principle is provided for later-stage gas injection and production increase of the carbonate reservoir.

公开(公告)号：US20240219329A1

公开(公告)日：2024-07-04

申请号：US18167712

申请日：2023-02-10

Applicant: Southwest Petroleum University

Inventor： Ping GUO ,  Zheng GU ,  Shuoshi WANG ,  Zhouhua WANG ,  Qinglong XU ,  Shiyong HU ,  Wenhua ZHAO ,  Yisheng HU ,  Huang LIU ,  Hanmin TU

IPC: G01N24/08 ,  G01N1/42 ,  G01N1/44

CPC classification number: G01N24/081 ,  G01N1/42 ,  G01N1/44

Abstract: A method for determining a phase-state type and saturation of a fluid by an NMR technology includes putting a core to be measured to an NMR phase-state testing device, injecting a heavy water solution from both ends of a gripper at the same time until the core reaches the formation pressure, and stopping; scanning the core to obtain a two-dimensional NMR map, and determining whether the core contains a gas phase; reducing the temperature of the gripper, and collecting an oil phase volume, a gas phase volume and a water phase volume discharged from the core; purge the pipelines out with nitrogen, collecting a water phase volume and an oil phase volume in the pipelines; performing dry distillation on the core to obtain an oil phase volume and a water phase volume; and obtaining the saturations of various phases according to the fluid volumes of multiple phases in the core.

公开(公告)号：US20190002344A1

公开(公告)日：2019-01-03

申请号：US15749780

申请日：2017-02-14

Applicant: SOUTHWEST PETROLEUM UNIVERSITY

Inventor： Ping GUO ,  Shuai WU ,  Yijian CHEN ,  Huimin ZHANG ,  Wanbo ZHANG ,  Yuhong DU ,  Zhouhua WANG ,  Jianfen DU ,  Yisheng HU ,  Huang LIU ,  Hongmei REN

IPC: C04B20/10 ,  C04B28/04 ,  C04B14/04 ,  C04B14/06 ,  C09K8/46 ,  C04B40/00 ,  G01N1/28

CPC classification number: C04B20/1025 ,  B28B7/384 ,  C04B14/04 ,  C04B14/06 ,  C04B28/04 ,  C04B40/0067 ,  C04B2111/00991 ,  C09K8/46 ,  G01N1/286 ,  G01N2001/2866 ,  G01N2001/2893 ,  C04B20/008

Abstract: A manufacturing method of a big-model low-permeability microcrack core includes: (1) determining the size of a microcrack core to be manufactured; (2) placing stones in a baking oven to bake for 24 h under 120° C., placing the stones into a mixer, mixing and spraying oil, enabling the oil to seep into the stone, evenly forming a thin oil film on stone's surface; (3) mixing the oil sprayed stone with quartz sand and cement, adding water to mix evenly to obtain cement paste; (4) spreading butter on core mould's inner surface to form a thin butter film, pouring the cement paste into the core mould to obtain a cement sample; (5) loading confining pressure outside the core according to the requirements of porosity and permeability of the mould to adjust a pore permeability value; (6) obtaining the big-model core with microcrack after the cement sample is dried and formed.

公开(公告)号：US20180348105A1

公开(公告)日：2018-12-06

申请号：US15775391

申请日：2016-12-02

Applicant: SOUTHWEST PETROLEUM UNIVERSITY

Inventor： Ping GUO ,  Shuai WU ,  Wanbo ZHANG ,  Yisheng HU ,  Yijian CHEN ,  Huimin ZHANG ,  Zhouhua WANG ,  Jianfen DU ,  Huang LIU ,  Hongmei REN

IPC: G01N1/36 ,  G01N15/08

CPC classification number: G01N1/36 ,  G01N15/082 ,  G01N15/088 ,  G01N33/241 ,  G01N2001/2873 ,  G01N2001/366

Abstract: A direct method for manufacturing a large model fractured core and maintaining original oil-water saturation, including the following steps: (1) determining the volume V, porosity φ, permeability K, oil saturation So, water saturation Sw and the like of a fractured core to be manufactured; (2) preparing simulated oil, and determining the used oil mass mo=Vo×ρo; (3) under the circumstance of no consideration of oil saturation, acquiring the mass of the used water, cement and quartz sand; (4) while establishing oil saturation, acquiring the mass mw of water for manufacturing the core as mw=a−Vo×ρw; (5) mixing oil, water and an emulsifier evenly to prepare an oil-in-water emulsion; (6) adding cement and quartz sand into the emulsion and stirring evenly to obtain cement slurry; (7) when a cement sample is in a semi-solidified state, cutting the cement sample with a steel wire; and (8) solidifying the cement sample to the end.