Hydrodynamic Reservoir Physical Simulation Experimental Device and Experimental Method

A technology of physical simulation and experimental methods, applied in the direction of earthwork drilling, production fluid, wellbore/well components, etc., can solve the problem that the formation process of hydrodynamic reservoirs is complicated, and the formation process, mechanism and other aspects of hydrodynamic reservoirs cannot be deeply understood. The main control factors, the formation process and mechanism of hydrodynamic reservoirs have not yet been discovered, and the effect of convenient operation and reasonable structure is achieved

Inactive Publication Date: 2018-05-22
CHINA UNIV OF PETROLEUM (EAST CHINA) +1
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  • Application Information

AI Technical Summary

Problems solved by technology

[0008] Due to the complex formation process of hydrodynamic reservoirs, the current understanding of hydrodynamic reservoirs is limited to the static knowledge obtained from geological anatomy and analysis of discovered reservoirs. However, under the action of hydrodynamic forces, the process of hydrocarbon accumulation is a dynamic one. The process and flow rate of hydrodynamic force play an important role in controlling hydrodynamic reservoirs, so the existing technologies cannot deeply understand the formation process, mechanism and main controlling factors of hydrodynamic reservoirs
[0009] The existing physical simulations of oil and gas migration and accumulation mechanisms are basically carried out in a large sandbox. Different geological models are constructed in the sandbox to simulate or verify the laws of oil and gas migration and accumulation in a certain area. Experimental equipment and experimental methods for the formation process and mechanism of hydrodynamic oil and gas reservoirs

Method used

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  • Hydrodynamic Reservoir Physical Simulation Experimental Device and Experimental Method
  • Hydrodynamic Reservoir Physical Simulation Experimental Device and Experimental Method
  • Hydrodynamic Reservoir Physical Simulation Experimental Device and Experimental Method

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Embodiment 1

[0060] Embodiment 1: as Figures 1 to 5As shown, a hydrodynamic reservoir physical simulation experiment device includes a hydrodynamic oil migration and accumulation simulation box, a water injection system, a water output system, and a water supply pool 2 connected to a pressure pump 1. The hydrodynamic oil migration and accumulation simulation box passes through water The injection system and the water output system are connected to the water supply pool 2 to form a closed loop; the hydrodynamic oil migration and accumulation simulation box includes a box body 3, and a formation body simulator 4, a first storage tank, and a formation body simulator 4 are arranged in the box body 3. The water tank 5 and the second water storage tank 6, the first water storage tank 5 and the second water storage tank 6 are respectively located on both sides of the formation body simulator 4, and are detachably connected with the formation body simulator 4; the formation body simulation The tw...

Embodiment 2

[0068] Embodiment 2: as Figures 2 to 7 As shown, a hydrodynamic reservoir physical simulation experiment device includes a hydrodynamic oil migration and accumulation simulation box, a water injection system, a water output system, and a water supply pool 2 connected to a pressure pump 1. The hydrodynamic oil migration and accumulation simulation box passes through water The injection system and the water output system are connected to the water supply pool 2 to form a closed loop; the hydrodynamic oil migration and accumulation simulation box includes a box body 3, and a formation body simulator 4, a first storage tank, and a formation body simulator 4 are arranged in the box body 3. The water tank 5 and the second water storage tank 6, the first water storage tank 5 and the second water storage tank 6 are respectively located on both sides of the formation body simulator 4, and are detachably connected with the formation body simulator 4; the formation body simulation The t...

Embodiment 3

[0077] Embodiment 3: The experimental method of the present invention is described by taking a simulated hydrodynamic reservoir with a dip angle of 30 degrees as an example. The experimental setup described in Example 2 was used for the experiments. During the experiment, according to Figure 8 The shown hydrodynamic reservoir physical simulation experiment model configures the formation body simulator, Figure 8 The model shown is filled with quartz sand with a particle size of 500 microns, which represents coarse sandstone, and the water injection rate is 100ml / min. In the experiment, kerosene dyed red was used instead of oil.

[0078] A kind of hydrodynamic reservoir physical simulation experimental method, its specific experimental steps are as follows:

[0079] (1) Prepare the simulated materials, test the simulated device, detect and analyze the oil components before the experiment, and collect the experimental data before the experiment.

[0080] (2) Open the box, t...

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Abstract

The invention relates to a physical simulation experiment device and method for a hydrodynamic petroleum reservoir. The physical simulation experiment device comprises a hydrodynamic petroleum migration and accumulation simulation box, wherein the hydrodynamic petroleum migration and accumulation simulation box is connected with a water supply pool through a water injection system and a water output system to form a closed loop; the hydrodynamic petroleum migration and accumulation simulation box comprises a box body, wherein the box body is internally provided with a stratum body simulator and two water storage tanks located at two sides of the stratum body simulator; sand-proof infiltration screens are arranged at two sides of the stratum body simulator and the sides, connected with the stratum body simulator, of the water storage tanks; and a petroleum injection hole is formed in the lower end of the stratum body simulator, a water injection hole connected with the water injection system is formed in the lower end of the first water storage tank, a water outlet connected with the water output system is formed in the lower end of the second water storage tank, and a petroleum injection hole, a water injection hole and a water outlet are respectively formed in corresponding positions on the box body. By using the physical simulation experiment device for the hydrodynamic petroleum reservoir, the aims of simulating the influencing process of a hydrodynamic force to a petroleum reservoir, analyzing the formation mechanism and control factor of the hydrodynamic petroleum reservoir and deepening the comprehension on formation factors of the hydrodynamic oil reservoir are achieved, and the basis is provided for the petroleum exploration of petroleum-containing basins.

Description

technical field [0001] The invention relates to an experimental device and an experimental method for oil migration and accumulation, in particular to a hydrodynamic reservoir physical simulation device and an experimental method for simulating the influence of hydrodynamics on the reservoir. Background technique [0002] The formation and evolution of groundwater dynamics in sedimentary basins are closely related to oil migration and accumulation, while hydrodynamics are dominated by fluid dynamics and their driving mechanisms. In recent years, many scholars have studied the relationship between fluid dynamics, fluid driving mechanism and oil accumulation from different perspectives. Chen Heli et al. (1988, 1990, 1993) used mudstone compaction to study fluid pressure, and believed that oil is generally distributed in parts with low residual pressure. Kang Yongshang et al. (1998) proposed the concept of hydrodynamic system for oil and gas accumulation, and proposed the divi...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): E21B49/00E21B43/20
CPCE21B43/20E21B49/00
Inventor 陈中红宋明水王新征邱隆伟刘鹏飞谭雯靖孙令印
Owner CHINA UNIV OF PETROLEUM (EAST CHINA)
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