JP2017048658A - Oil production facility and oil production method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an oil production facility and an oil production method that can materialize increase in efficiency of production of an oil content contained in an oil layer such as an underground oil sand layer.SOLUTION: An oil production facility 1 for collecting an oil content contained in an underground oil sand layer 5 comprises: a separator 11 that is provided in the oil sand layer 5 and makes an oil content contained in the oil sand layer 5 flow into the inside of the separator and separates the oil content into gas and liquid in the inside of the separator; an oil pump 31 for pumping up the liquid inside the separator 11; and a pressure adjustment valve 42 for performing pressure reduction so that pressure inside the separator 11 becomes lower than that outside the separator 11.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an oil production facility and an oil production method for recovering oil contained in an underground oil reservoir.

  Conventionally, a gas recovery system that recovers gas from a gas hydrate layer is known (see, for example, Patent Document 1). This gas recovery system has a double pipe structure of an outer cylinder and an inner cylinder, and the inner side of the inner cylinder is a gas recovery pipe that recovers the gas hydrate layer gas. A supply pipe for supplying water that becomes superheated steam to the gas hydrate layer. The gas recovery system is connected to a gas tank connected to a gas recovery pipe. In the gas tank, moisture, mud, sand and gravel are separated, and the purified gas is stored. Further, in the gas recovery system, a thermal energy generation device is provided inside a double pipe composed of an outer cylinder and an inner cylinder, and the thermal energy generation apparatus heats supplied water to form superheated steam. The gas recovery system injects superheated steam into the gas hydrate layer to separate and recover the gas from the gas hydrate layer. The gas recovery system can be applied to an oil recovery system that recovers oil from the oil sand layer.

JP 2014-145229 A

  By the way, when collecting oil (oil) from an oil layer such as an oil sand layer or a heavy oil layer formed in the ground, a production well for collecting the oil is provided in the ground oil layer. The production well is configured using a steel pipe, and oil flows in a state where the inside of the steel pipe is filled with bitumen. For this reason, the pressure inside the production well is the same as the pressure inside the oil reservoir outside the production well. The oil in the oil layer flows from the oil layer to the production well by gravity (self-weight).

  Here, in patent document 1, the fluidity | liquidity of the oil from an oil sand layer to a production well is improved by injecting superheated steam into an oil sand layer, and reducing the viscosity of oil. As such a production method, for example, a SAGD (Steam Assisted Gravity Drainage) method is known. On the other hand, for oil in the heavy oil layer where the oil viscosity is lower than that of the oil sand layer, there is a case where heavy oil is produced without injecting superheated steam due to the fluidity of the oil. .

  It is an object of the present invention to provide an oil production facility and an oil production method capable of improving the production efficiency of oil contained in an underground oil reservoir.

  The oil production facility of the present invention is an oil production facility that collects oil contained in an underground oil reservoir, and is provided in the oil reservoir, allowing the oil contained in the oil reservoir to flow into the interior, and gas and liquid therein. A separator that separates the liquid into the separator, an oil pump that pumps up the liquid inside the separator, and a pressure reducing device that reduces the pressure inside the separator to be lower than the pressure outside the separator. Features.

  The oil production method of the present invention is an oil production method for recovering oil contained in an underground oil reservoir, wherein the oil contained in the oil reservoir is caused to flow into a separator provided in the oil reservoir, Inside, a gas-liquid separation step for separating gas and liquid, an oil recovery step for recovering the liquid inside the separator, recovering the gas inside the separator, and a pressure inside the separator And a gas recovery step of reducing the pressure so that the pressure is lower than the pressure outside the separator.

  According to this configuration, a pressure difference can be generated between the pressure in the oil layer that is outside the separator and the pressure inside the separator. For this reason, since the fluidity of the oil component from the oil layer to the separator can be improved by the pressure difference, it is possible to improve the production efficiency of the oil component contained in the underground oil layer. Examples of the oil layer include an oil sand layer, a super heavy oil layer containing orinocotal, and a heavy oil layer. Further, as the pressure reducing device, for example, a pressure regulating valve such as a relief valve may be applied.

  Moreover, it is preferable that the said pressure reduction apparatus pressure-reduces so that the gauge pressure inside the said separator may be set to 1 Mpa or less.

  According to this configuration, the gauge pressure inside the separator can be 1 MPa or less. For this reason, since the pressure difference of the pressure in an oil layer and the pressure in a separator can be made into a sufficient pressure difference, the flow of the oil component from an oil layer to a separator can be produced suitably. Preferably, the gauge pressure is in the range from 10 kPa to 50 kPa, and more preferably the gauge pressure is about 30 kPa.

  Moreover, it is preferable that the said separator has a cylindrical-shaped surrounding wall and the extraction hole which penetrates the said surrounding wall and the said oil component contained in the said oil layer distribute | circulates.

  According to this configuration, by making the peripheral wall of the separator cylindrical, it is possible to withstand the internal pressure of the separator and the external pressure, and the oil component is preferably allowed to flow into the separator through the extraction hole. be able to.

  Moreover, it is preferable that the diameter of the said surrounding wall is 1 m or more.

  According to this configuration, the internal space of the separator can be made large enough to perform gas-liquid separation.

  The peripheral wall is preferably a shield tunnel.

  According to this configuration, since the shield tunnel formed by the shield method can be used as the peripheral wall, the peripheral wall can be appropriately formed by utilizing the shield method.

  Further, it is preferable to further include a liquid level meter that detects a liquid level inside the separator, and a liquid level control device that controls the oil pump based on the liquid level detected by the liquid level meter. .

  According to this configuration, since the liquid level in the separator can be maintained at a predetermined liquid level, gas-liquid separation by the separator can be performed appropriately.

  Moreover, it is preferable to further include a pressure gauge that detects a pressure inside the separator, and a pressure control device that controls the pressure reducing device based on the pressure detected by the pressure gauge.

  According to this configuration, since the pressure in the separator can be maintained at a predetermined pressure, the pressure difference can be appropriately maintained, and the inflow of oil from the oil layer to the inside of the separator can be appropriately maintained. it can.

  Moreover, it is preferable to further include a steam generating device that generates steam, and a steam injection well that is connected to the steam generating device and injects the generated steam into the oil layer.

  According to this configuration, when the oil layer is an oil sand layer, the viscosity of the oil in the oil sand layer can be reduced by injecting steam into the oil sand layer. For this reason, since the fluidity of the oil component from the oil sand layer to the separator can be improved by reducing the viscosity of the oil component, it is possible to improve the production efficiency of the oil component contained in the underground oil sand layer. it can.

FIG. 1 is a schematic configuration diagram relating to an oil production facility according to the first embodiment. FIG. 2 is a cross-sectional view of the separator of the oil production facility according to the first embodiment. FIG. 3 is a block diagram relating to the control device for the oil production facility according to the first embodiment. FIG. 4 is a flowchart of an oil production method by the oil production facility according to the first embodiment. FIG. 5 is a schematic configuration diagram relating to the separator of the oil production facility according to the second embodiment.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same. Furthermore, the constituent elements described below can be appropriately combined, and when there are a plurality of embodiments, the embodiments can be combined.

[Embodiment 1]
FIG. 1 is a schematic configuration diagram relating to an oil production facility according to the first embodiment. As shown in FIG. 1, the oil production facility 1 according to Embodiment 1 is a facility that recovers oil contained in an oil sand layer 5, which is an oil layer having a high oil content (oil) viscosity. The oil production facility 1 injects steam into the oil sand layer 5 to reduce the viscosity of the oil to increase fluidity, and to collect the oil by flowing it. In the first embodiment, the description is applied to the oil production facility 1 that recovers the oil contained in the oil sand layer 5, but it may be applied to a super heavy oil layer or a heavy oil layer containing orinocotal or the like. When the oil production facility 1 is provided in the heavy oil layer, the oil production facility 1 has a configuration in which steam is injected into the heavy oil layer because the oil viscosity of the heavy oil layer is lower than that of the oil sand layer 5. May be. Moreover, the oil production facility 1 according to Embodiment 1 is intended for a relatively shallow oil layer formed at a depth within 1000 m from the ground surface.

  As shown in FIG. 1, the oil production facility 1 includes a counter 10, a separator 11, an oil recovery facility 12, a gas recovery facility 13, and a steam injection facility 14, and each facility 12, 13, A control device 15 (see FIG. 3) 15 for controlling 14 is provided.

  The ridge 10 is a vertical hole dug down from the ground surface to the lower side in the vertical direction, and has a depth reaching the oil sand layer 5 from the ground surface. The shaft 10 is formed in a cylindrical shape, and a space is formed therein. In the space of the shaft 10, a part of an oil recovery line 32 and a gas recovery line 41, which will be described later, are arranged along the vertical direction.

  FIG. 2 is a cross-sectional view of the separator of the oil production facility according to the first embodiment. The separator 11 is provided in the oil sand layer 5. The separator 11 allows oil contained in the oil sand layer 5 to flow into the interior, and is separated into liquid and gas containing oil inside. The separator 11 has a peripheral wall 21 formed in a cylindrical shape and a side plate 22 that closes an opening formed in the peripheral wall 21.

  The peripheral wall 21 is a shield tunnel formed by a shield method, and extends from the shaft 10 in the horizontal direction. The peripheral wall 21 is open on the horizontal shaft 10 side, and is closed on the opposite side to the horizontal shaft 10. Further, the peripheral wall 21 has a diameter of 1 m or more, and has a size that functions as the separator 11. Specifically, the peripheral wall 21 has a size necessary for adjusting the liquid level of the separated liquid inside the separator 11. The peripheral wall 21 is formed with a plurality of extraction holes 25 through which oil contained in the oil sand layer 5 flows. The opening diameter of the extraction hole 25 is such that the gravel contained in the oil sand layer 5 cannot flow, while the oil contained in the oil sand layer 5 can flow. The plurality of extraction holes 25 are formed on the upper side of the peripheral wall 21 and are formed above the liquid level.

  The side plate 22 is formed in a hollow hemispherical shape protruding outward from the inside of the peripheral wall 21, and closes the opening on the shaft 10 side of the peripheral wall 21, thereby providing a space for gas-liquid separation inside the peripheral wall 21. Partition. That is, the space defined by the peripheral wall 21 and the side plate 22 functions as a gas-liquid separation tank that performs gas-liquid separation. The shape of the side plate 22 may be a disc shape and is not particularly limited.

  The oil recovery facility 12 is a facility for recovering the oil by recovering the liquid separated in the separator 11, separating the oil from the recovered liquid. As shown in FIG. 1, the oil recovery facility 12 includes an oil pump 31, an oil recovery line 32, an oil separator 33, and a liquid level gauge 34.

  The oil pump 31 is provided inside the separator 11 and is installed at the bottom of the separator 11 so as to be immersed in the liquid in the separator 11. The oil pump 31 sends the liquid in the separator 11 toward the downstream side. Further, the oil pump 31 is connected to the control device 15, and the liquid level in the separator 11 is adjusted by being driven and controlled by the control device 15.

  The oil recovery line 32 has one end connected to the oil pump 31 and the other end connected to the oil separator 33. That is, the oil recovery line 32 is provided so as to penetrate the inside and outside of the separator 11. The oil recovery line 32 extends from the oil pump 31 through the shaft 10 to the ground surface. For this reason, the oil recovery line 32 circulates the liquid from the inside of the separator 11 to the outside, and circulates the liquid from the inside of the shaft 10 toward the ground surface.

  The oil separator 33 separates the liquid supplied from the oil pump 31 via the oil recovery line 32 into oil, moisture, and gas components. The separated oil is discharged from the oil separator 33 toward the equipment for performing the refining process. Further, the separated moisture and gas components are discharged from the oil separator 33 toward another processing facility. At this time, the separated water may be discharged from the oil separator 33 toward the steam injection facility 14.

  The liquid level meter 34 is provided inside the separator 11 and detects the interface between the gas and the liquid in the separator 11, that is, the liquid level. The liquid level meter 34 is connected to the control device 15, and outputs the liquid level detected toward the control device 15, so that the control device 15 performs control based on the liquid level detected by the liquid level meter 34. Can be executed.

  The gas recovery facility 13 is a facility that recovers the gas separated in the separator 11, separates the gas from the recovered gas, and recovers the gas. As shown in FIG. 1, the gas recovery facility 13 includes a gas recovery line 41, a pressure regulating valve (decompression device) 42, a heat exchanger 43, a gas separator 44, and a pressure gauge 45. .

  The gas recovery line 41 has one end connected to the separator 11 and the other end connected to the gas separator 44. That is, the gas recovery line 41 is provided so as to penetrate the inside and outside of the separator 11 and is connected to the upper portion of the separator 11 in order to recover the gas in the separator 11. The gas recovery line 41 extends from the separator 11 through the shaft 10 to the ground surface. For this reason, the gas recovery line 41 circulates the gas from the inside of the separator 11 toward the outside, and circulates the gas from the inside of the shaft 10 toward the ground surface.

  The pressure regulating valve 42 is provided in a gas recovery line 41 provided on the ground surface, and for example, a relief valve is used. The pressure adjustment valve 42 reduces pressure so that the pressure (atmospheric pressure) inside the separator 11 is lower than the pressure outside the separator 11. Further, the pressure adjusting valve 42 is connected to the control device 15, and when the valve opening degree is controlled by the control device 15, the pressure on the primary side (upstream side) of the gas recovery line 41 becomes a predetermined pressure. It is adjusted to become.

  The heat exchanger 43 is provided in the gas recovery line 41 on the downstream side of the decompression device 42. The heat exchanger 43 condenses the gas by cooling the gas flowing through the gas recovery line 41 as necessary. The gas containing the condensed condensate flows toward the gas separator 44 on the downstream side.

  The gas separator 44 separates the gas containing the condensate supplied from the separator 11 via the gas recovery line 41 into a gas component, moisture, and a condensate. The separated gas component, moisture and condensate are discharged from the gas separator 44 to other processing equipment. At this time, the separated water may be discharged from the gas separator 44 toward the steam injection facility 14.

  The pressure gauge 45 is provided in the gas recovery line 41 on the upstream side of the pressure regulating valve 42 and detects the pressure in the gas recovery line 41, that is, the pressure inside the separator 11. The pressure gauge 45 is connected to the control device 15, and by outputting the pressure detected toward the control device 15, the control device 15 can execute control based on the pressure detected by the pressure gauge 45. Become. The pressure gauge 45 detects, for example, a gauge pressure as the pressure.

  The steam injection facility 14 is a facility that injects steam into the oil sand layer 5 to reduce the viscosity of the oil contained in the oil sand layer 5. As shown in FIG. 1, the steam injection facility 14 includes a steam generator 51 and a steam injection well 52.

  The steam generator 51 heats moisture to generate steam to be injected into the oil sand layer 5, and supplies the generated steam toward the steam injection well 52. In addition, as the moisture, moisture discharged from the oil recovery facility 12 and the gas recovery facility 13 may be used.

  One end of the steam injection well 52 is connected to the steam generating device 51, and the other end extends into the oil sand layer 5 and is disposed above the separator 11. The other end portion of the steam injection well 52 disposed above the separator 11 extends in the horizontal direction, and is branched into a plurality of portions, and is arranged side by side in the vertical direction so as to be parallel to the separator 11. And the other end part of the steam injection well 52 arrange | positioned in the oil sand layer 5 is formed with a plurality of steam ejection holes (not shown) through which steam is ejected, and the steam supplied from the steam generator 51 is a plurality of steam. It is injected into the oil sand layer 5 through the ejection holes.

  The control device 15 controls the oil recovery facility 12, the gas recovery facility 13, and the steam injection facility 14. FIG. 3 is a block diagram relating to the control device for the oil production facility according to the first embodiment. As shown in FIG. 3, the control device 15 includes a liquid level control unit (liquid level control device) 55 that controls the liquid level in the separator 11 and a pressure control unit (pressure control device) that controls the pressure in the separator 11. 56. In the first embodiment, the control device 15 includes the liquid level control unit 55 and the pressure control unit 56. However, the liquid level control unit 55 and the pressure control unit 56 have independent device configurations. There is no particular limitation.

  The liquid level control unit 55 controls the oil pump 31 based on the detection result of the liquid level meter 34 connected to the control device 15 so that the liquid level in the separator 11 becomes a predetermined liquid level. It is adjusted to.

  The pressure control unit 56 controls the valve opening degree of the pressure regulating valve 42 based on the detection result of the pressure gauge 45 connected to the control device 15 so that the pressure in the separator 11 becomes a predetermined pressure. It is adjusted to. Here, the predetermined pressure is a pressure at which the gauge pressure inside the separator 11 is 1 MPa or less. Specifically, the gauge pressure is in a range from 10 kPa to 50 kPa, and more specifically, the gauge pressure is about 30 kPa.

Here, when a fluid having a viscosity μ flows in a porous body having a cross-sectional area A and a length L, if the pressure difference between the upstream side and the downstream side in the fluid flow direction is ΔP, the fluid flow rate Q Is represented by the following formula (1). Note that K is a permeability, and the equation (1) is generally called a Darcy equation.
Q = K · (A / μ) · (ΔP / L) (1)

  In the oil production facility 1 of the first embodiment, the oil flow rate Q is improved by reducing the oil viscosity μ by the steam injection facility 14, and the pressure in the separator 11 is changed to the pressure in the oil sand layer 5. The oil flow rate Q is improved by increasing the pressure difference ΔP.

  Next, with reference to FIG. 4, the operation | movement which produces oil in said oil production equipment 1 is demonstrated. FIG. 4 is a flowchart of an oil production method by the oil production facility according to the first embodiment. First, the steam injection facility 14 of the oil production facility 1 generates steam in the steam generator 51 and supplies the generated steam toward the steam injection well 52. The steam supplied to the steam injection well 52 is injected into the oil sand layer 5 from a steam ejection hole formed at the other end of the steam injection well 52 (step S1: steam injection process). When steam is injected into the oil sand layer 5, the oil in the oil sand layer 5 is heated and the viscosity of the oil decreases, so that the oil flows in the oil sand layer 5.

  The oil in the oil sand layer 5 flows toward the separator 11 in the oil sand layer 5 and flows into the separator 11 from the outside through the extraction hole 25 of the separator 11. At this time, in addition to oil, moisture condensed from the steam injected into the oil sand layer 5, gas components generated in the oil sand layer 5, and the like flow into the separator 11. And the extract containing the oil which flowed in the inside of the separator 11 is isolate | separated into a gas and a liquid in the inside of the separator 11 (step S2: gas-liquid separation process).

  The liquid separated in the separator 11 flows from the inside of the separator 11 through the oil recovery line 32 and flows into the oil separator 33 by the oil pump 31 of the oil recovery facility 12 (step S3: oil recovery step). ). At this time, the liquid level control unit 55 of the control device 15 adjusts the liquid level in the separator 11 to be a predetermined liquid level by controlling the oil pump 31 based on the detection result of the liquid level gauge 34. ing.

  The gas separated inside the separator 11 flows from the inside of the separator 11 through the gas recovery line 41 and flows into the gas separator 44 (step S4: gas recovery step). At this time, the pressure control unit 56 of the control device 15 controls the pressure adjustment valve 42 based on the detection result of the pressure gauge 45, so that the pressure in the separator 11 is lower than the pressure in the oil sand layer 5. The pressure is reduced so that As a result, the gas recovery facility 13 increases the pressure difference ΔP between the inside and outside of the separator 11.

  In FIG. 4, each step is described in order, but the above steps are performed in parallel, and oil is continuously collected from the oil sand layer 5.

  As described above, according to the first embodiment, the pressure difference ΔP can be generated between the pressure in the oil sand layer 5 that is outside the separator 11 and the pressure inside the separator 11. For this reason, since the fluidity of oil from the oil sand layer 5 to the separator 11 can be improved by increasing the pressure difference ΔP, the production efficiency of oil contained in the underground oil sand layer 5 is improved. Can be planned.

  Moreover, according to Embodiment 1, the gauge pressure inside the separator 11 can be 1 MPa or less. For this reason, since the pressure difference between the pressure in the oil sand layer 5 and the pressure in the separator 11 can be a sufficient pressure difference, the flow of oil from the oil sand layer 5 to the separator 11 is preferably generated. be able to.

  In addition, according to the first embodiment, the peripheral wall 21 of the separator 11 is formed in a cylindrical shape so that it can withstand the pressure inside the separator 11 and the pressure outside the separator 11, while being separated from the oil sand layer 5 through the extraction hole 25. Oil can be suitably flowed into the separator 11.

  Moreover, according to Embodiment 1, since the diameter of the peripheral wall 21 of the separator 11 can be 1 m or more, the internal space of the separator 11 can be made necessary and sufficient to perform gas-liquid separation.

  Further, according to the first embodiment, since the shield tunnel formed by the shield method can be used as the peripheral wall 21, the peripheral wall 21 can be appropriately formed by utilizing the shield method.

  Further, according to the first embodiment, the liquid level control unit 55 can maintain the liquid level in the separator 11 at a predetermined liquid level, so that the gas-liquid separation by the separator 11 can be appropriately performed.

  Further, according to the first embodiment, the pressure in the separator 11 can be maintained at a predetermined pressure, so that the pressure difference ΔP can be appropriately maintained, and the oil from the oil sand layer 5 to the inside of the separator 11 can be maintained. Inflow can be properly maintained.

  According to the first embodiment, the viscosity of the oil in the oil sand layer 5 can be lowered by injecting steam into the oil sand layer 5. For this reason, since the fluidity of the oil from the oil sand layer 5 to the separator 11 can be improved by reducing the viscosity of the oil, the production efficiency of oil contained in the underground oil sand layer 5 can be improved. Further efforts can be made.

  In the first embodiment, the pressure adjustment valve 42 is used to reduce the pressure inside the separator 11, but the present invention is not limited to this configuration. Any configuration may be used as long as the pressure reducing device reduces the pressure inside the separator 11. For example, an air release valve may be provided in the gas recovery line 41 to release the pressure inside the separator 11. . Further, a vacuum pump may be connected to the gas recovery line 41 so that the pressure inside the separator 11 is negative.

[Embodiment 2]
Next, an oil production facility 60 according to the second embodiment will be described with reference to FIG. FIG. 5 is a schematic configuration diagram relating to the separator of the oil production facility according to the second embodiment. In the second embodiment, parts that are different from the first embodiment will be described in order to avoid redundant descriptions, and parts that are the same as those in the first embodiment will be described with the same reference numerals. In FIG. 5, only the parts different from the first embodiment are shown.

  As shown in FIG. 5, an oil production facility 60 according to the second embodiment is configured as a slope 61 instead of the shaft 10 according to the first embodiment. The slope 61 is a tunnel formed obliquely from the ground surface toward the lower side in the vertical direction, and is formed by a shield method. The slope 61 is formed to be continuous with the peripheral wall 21 of the separator 11. That is, the slope 61 and the peripheral wall 21 of the separator 11 are shield tunnels that are continuously formed by a shield method.

  As described above, according to the second embodiment, the shield 61 and the peripheral wall 21 of the separator 11 can be continuously formed by the shield method, so that the construction period of the shield 61 and the separator 11 can be shortened. it can.

DESCRIPTION OF SYMBOLS 1 Oil production equipment 5 Oil sand layer 10 Resistant 11 Separator 12 Oil recovery equipment 13 Gas recovery equipment 14 Steam injection equipment 15 Control device 21 Perimeter wall 22 Side plate 25 Extraction hole 31 Oil pump 32 Oil recovery line 33 Oil separator 34 Liquid level meter 41 Gas Recovery Line 42 Pressure Control Valve 43 Heat Exchanger 44 Gas Separator 45 Pressure Gauge 51 Steam Generator 52 Steam Injection Well 55 Liquid Level Control Unit 56 Pressure Control Unit 60 Oil Production Facility (Embodiment 2)
61.

Claims (9)

In an oil production facility that collects oil contained in the underground oil reservoir,
A separator that is provided in the oil layer, allows the oil contained in the oil layer to flow into the interior, and separates into gas and liquid in the interior;
An oil pump that pumps up the liquid inside the separator;
An oil production facility comprising: a pressure reducing device that reduces pressure so that the pressure inside the separator is lower than the pressure outside the separator.   The oil production facility according to claim 1, wherein the pressure reducing device reduces pressure so that a gauge pressure inside the separator is 1 MPa or less. The separator is
A cylindrical peripheral wall;
The oil production facility according to claim 1, further comprising an extraction hole formed through the peripheral wall and through which the oil contained in the oil layer flows.   The oil production facility according to claim 3, wherein a diameter of the peripheral wall is 1 m or more.   The oil production facility according to claim 3 or 4, wherein the peripheral wall is a shield tunnel. A liquid level meter for detecting the liquid level inside the separator;
The oil production according to any one of claims 1 to 5, further comprising: a liquid level control device that controls the oil pump based on the liquid level detected by the liquid level gauge. Facility. A pressure gauge for detecting the pressure inside the separator;
The oil production facility according to claim 1, further comprising: a pressure control device that controls the pressure reducing device based on the pressure detected by the pressure gauge. A steam generator for generating steam;
The oil production facility according to any one of claims 1 to 7, further comprising a steam injection well connected to the steam generation device and injecting the generated steam into the oil reservoir. In an oil production method for recovering oil contained in an underground oil reservoir,
A gas-liquid separation step of allowing the oil contained in the oil layer to flow into a separator provided in the oil layer, and separating the gas into a liquid and a liquid inside the separator;
An oil recovery step for recovering the liquid inside the separator;
And a gas recovery step of recovering the gas inside the separator and reducing the pressure so that the pressure inside the separator is lower than the pressure outside the separator. .

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