CN117379836A - Crude oil gas water three-phase separation sled dress supercharging device - Google Patents

Abstract

The invention discloses a crude oil gas water three-phase separation skid-mounted supercharging device, which particularly relates to the oil gas water separation field, and comprises a base, wherein a tank body is arranged on the base, one end of the tank body is provided with an inlet, a baffle is fixedly arranged at the top of the inner side of the tank body, the baffle is opposite to the inlet, a mixture of oil gas water enters the tank body from the inlet and impacts the baffle, and oil phase, gas phase and water phase are separated after the mixture flows into the tank body; the inside of the tank body is provided with a collecting hopper, the inlet and the baffle are both positioned above the collecting hopper, and the bottom of the collecting hopper is provided with a first water outlet. According to the invention, through the arrangement of the buffer tank and the buffer plate, on one hand, the mixture of oil, gas and water is decelerated when impacting the buffer plate, and on the other hand, the mixture can downwards flow into the oil phase in the buffer tank along the side wall of the buffer tank, so that the impact force on the oil phase is smaller, the fluctuation of the oil phase in the buffer tank is smaller, and the fluctuation is basically positioned in the buffer tank, so that the influence on the oil phase in the tank is smaller.

Description

Crude oil gas water three-phase separation sled dress supercharging device

Technical Field

The invention relates to the technical field of oil-gas-water separation, in particular to a three-phase separation skid-mounted supercharging device for crude oil, gas and water.

Background

In the oil and gas exploitation process, oil, gas and water three-phase separators are key equipment for oil and gas gathering and transportation due to the change of temperature and pressure, have the function of separating oil well products into oil, gas and water three-phase, and crude oil separated by the three-phase separators only contains a small amount of free water, so that the crude oil can be deeply dehydrated in the later period.

The common oil-gas-water three-phase separator mainly comprises a vertical three-phase separator, a horizontal three-phase separator and a spherical three-phase separator, and the spherical three-phase separator is unusual, and the horizontal three-phase separator has good separation performance under the same static flow condition, so that the use of the horizontal three-phase separator is more common. When the horizontal oil-gas-water three-phase separator is used, the oil-gas-water mixture enters the separator and impacts the inlet baffle, a part of gas is separated from liquid, oil flows upwards under the action of gravity, water flows downwards, and is discharged from the corresponding outlet after layering, so that oil-water separation is realized.

The current horizontal oil-gas-water three-phase separator is used for impacting an inlet baffle after an oil-gas-water mixture enters, so that a part of gas can be separated, and the speed of the mixture is reduced, however, as the mixture directly impacts the liquid in the tank body after impacting the inlet baffle, larger waves can be generated, the larger waves can cause unbalance of an oil-water interface, turbulence occurs, and the turbulence has the effect of promoting oil-water mixing and is unfavorable for oil-water separation.

Disclosure of Invention

The invention provides a crude oil, gas and water three-phase separation skid-mounted supercharging device, which aims to solve the problems that: the mixture of oil, gas and water directly rushes into the liquid in the tank body, and larger waves can be generated, so that the oil-water interface is unbalanced and disturbed.

In order to achieve the above purpose, the present invention provides the following technical solutions: the three-phase separation skid-mounted supercharging device for crude oil, gas and water comprises a base, wherein a tank body is arranged on the base, an inlet is formed in one end of the tank body, a baffle is fixedly arranged at the top of the inner side of the tank body, the baffle is arranged opposite to the inlet, a mixture of oil, gas and water enters the tank body from the inlet and impacts the baffle, and oil phase, gas phase and water phase are separated after the mixture flows into the tank body; the inside of the tank body is provided with the collection bucket, the import and the baffle are all located the top of collecting the bucket, the bottom of collecting the bucket has delivery port one, be provided with the buffer tank under delivery port one, the downside of buffer tank has delivery port two, delivery port two is located the inside of oil phase, the inside of buffer tank is provided with the buffer board, the buffer board is located the oil phase liquid level above, have the clearance between the inside wall of buffer board's peripheral edge and buffer tank, the mixture flows downwards along the inside wall of buffer tank from the position in clearance.

In a preferred embodiment, the crude oil gas water three-phase separation sled dress supercharging device still includes buffer unit, and buffer unit includes the urceolus, and the urceolus is installed in the upper end of the jar body, and the inside vertical movable mounting of urceolus has the connecting axle, rotates on the connecting axle to be connected with the swivel, and the cover is equipped with spring one on the connecting axle, and the both ends of spring one are pressed together with swivel and the inboard bottom of connecting axle respectively, the bottom of connecting axle and the middle part fixed connection of buffer plate.

In a preferred embodiment, a liquid level sensor is mounted on the side wall of the buffer tank, the liquid level sensor is used for detecting the liquid level of the oil phase, and a power assembly is mounted on the tank body and is used for driving the connecting shaft to move vertically.

In a preferred embodiment, one side of the upper end of the buffer tank is provided with a slag outlet, one end of the tank body is provided with a slag discharging component, the slag discharging component is communicated with the slag outlet, the power component is further used for driving the buffer plate to rotate, so that the buffer plate throws sediment at the edge of the buffer plate from the slag outlet to the inside of the slag discharging component, the inside of the outer cylinder is provided with a pressure sensor, and the pressure sensor is used for detecting the pressure of the first spring.

In a preferred embodiment, the slag discharging assembly comprises a slag discharging pipe, the slag discharging pipe is communicated with the slag outlet, the slag discharging pipe is provided with a first channel and a second channel, the first channel is arranged in a downward inclined mode, the second channel is located at the front end of the first channel, the second channel is provided with an opening at the bottom, and a plugging part is arranged at the position of the opening at the bottom.

In a preferred embodiment, the plugging member comprises a plugging body for plugging the bottom opening of the slag discharging channel II, a guide rod I is arranged on one side of the plugging body, the guide rod I is inserted on the slag discharging pipe, and a spring II is sleeved on the guide rod I.

In a preferred embodiment, the upper end of the slag discharging channel II is opened, a pushing block is movably inserted in the position of the upper end opening of the slag discharging channel II, one side of the pushing block is fixedly connected with a guide rod II, the guide rod II is movably inserted in the slag discharging pipe, and a spring III is sleeved on the outer side of the guide rod II.

In a preferred embodiment, the power assembly comprises an outer connecting sleeve and an inner shaft, the outer connecting sleeve is movably sleeved on the outer side of the inner shaft, the outer connecting sleeve is fixedly connected with the upper end of the outer cylinder, the connecting shaft is axially and slidably inserted into the inner shaft, and the power assembly further comprises a transmission part, and the transmission part is used for driving the inner shaft to rotate and driving the outer connecting sleeve to vertically move.

In a preferred embodiment, the transmission part comprises a shell, the shell is fixedly arranged at the upper end of the tank body, a driving part is fixedly arranged on the shell, the output end of the driving part is fixedly connected with a main shaft, the end part of the main shaft is fixedly connected with a worm, the shell is rotationally connected with a short shaft, the short shaft is provided with a worm wheel, the worm is meshed with the worm wheel, the end part of the short shaft is fixedly connected with a swing arm, an outer sleeve is rotationally sleeved on the outer connecting sleeve, a side wall of the outer sleeve is provided with a side shaft, one end of the swing arm, which is far away from the short shaft, is provided with a sliding groove, the side shaft slides in the sliding groove, and the inner shaft is in transmission connection with the main shaft through a gear set.

In a preferred embodiment, the bottom of the tank body is provided with an oil drain port and a water drain port, the upper end of the tank body is provided with an exhaust port, after the oil-gas-water mixture is separated, the oil phase is discharged from the oil drain port, the water phase is discharged from the water drain port, the gas phase is discharged from the exhaust port, and a delivery pump is arranged at the position of the oil drain port.

The invention has the technical effects and advantages that: according to the invention, through the arrangement of the buffer tank and the buffer plate, on one hand, the mixture of oil, gas and water is slowed down when impacting the buffer plate, on the other hand, the mixture can downwards flow into the oil phase in the buffer tank along the side wall of the buffer tank, so that the impact force on the oil phase is smaller, the fluctuation of the oil phase in the buffer tank is smaller, and the fluctuation is basically positioned in the buffer tank, so that the influence on the oil phase in the tank is smaller, and the problems that the oil-water interface is unbalanced and disturbed due to the fact that the mixture of oil, gas and water directly rushes into the liquid in the tank are solved.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a partial cross-sectional view of the present invention.

Fig. 3 is a schematic view of a partial structure of fig. 2 according to the present invention.

Fig. 4 is a schematic view of a partial structure of fig. 3 according to the present invention.

FIG. 5 is a schematic view showing the buffer plate of the present invention moved up to the slag hole position.

Fig. 6 is a schematic structural view of a transmission component according to the present invention.

Fig. 7 is a schematic structural diagram of a transmission component of the present invention.

Fig. 8 is a partial schematic view of the transmission member of the present invention.

The reference numerals are: 1. a tank body; 11. an inlet; 12. an oil drain port; 13. a water outlet; 14. an exhaust port; 15. a baffle; 2. a collection bucket; 21. a first water outlet; 22. an air outlet; 3. a buffer tank; 31. a second water outlet; 32. a slag outlet; 4. a buffer plate; 41. a gap; 5. a buffer assembly; 51. an outer cylinder; 52. a connecting shaft; 53. a swivel; 54. a first spring; 6. a liquid level sensor; 7. a power assembly; 71. an outer connecting sleeve; 72. an inner shaft; 73. a transmission member; 730. a gear set; 731. a housing; 732. a driving member; 733. a main shaft; 734. a worm; 735. a short shaft; 736. a worm wheel; 737. swing arms; 7371. a chute; 738. a jacket; 7381. a side shaft; 8. a slag discharging component; 80. a pressure sensor; 81. a slag discharge pipe; 811. a first channel; 812. a slag discharging channel II; 82. a blocking member; 821. a blocking body; 822. a first guide rod; 823. a second spring; 831. pushing the block; 832. a second guide rod; 833. a third spring; 9. and a transfer pump.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-8 of the specification, a three-phase separation skid-mounted pressurizing device for crude oil, gas and water comprises a base, wherein a tank body 1 is arranged on the base, one end of the tank body 1 is provided with an inlet 11, the top of the inner side of the tank body 1 is fixedly provided with a baffle 15, the baffle 15 is arranged opposite to the inlet 11, a mixture of oil, gas and water enters the tank body 1 from the inlet 11 and impacts the baffle 15, and after flowing into the tank body 1, the mixture is separated into an oil phase, a gas phase and a water phase; the bottom of the tank body 1 is provided with an oil drain port 12 and a water drain port 13, the upper end of the tank body 1 is provided with an exhaust port 14, after the oil-gas-water mixture is separated, an oil phase is discharged from the oil drain port 12, a water phase is discharged from the water drain port 13, a gas phase is discharged from the exhaust port 14, and a delivery pump 9 is arranged at the position of the oil drain port 12 and is used for delivering the oil phase to an oil delivery pipeline after being pressed.

The inside of jar body 1 is provided with collects fill 2, import 11 and baffle 15 all are located the top of collecting fill 2, the bottom of collecting fill 2 has delivery port one 21, be provided with buffer tank 3 under delivery port one 21, buffer tank 3's downside has delivery port two 31, delivery port two 31 are located the inside of oil phase, buffer tank 3's inside is provided with buffer board 4, buffer board 4 is located the oil phase liquid level above, have clearance 41 between buffer board 4's the circumference edge and buffer tank 3's the inside wall, the mixture flows downwards along buffer tank 3's inside wall from the position of clearance 41.

In the above technical solution, the second water outlet 31 may be disposed on a side wall of the buffer tank 3, or may be disposed at the bottom of the buffer tank 3, and should be as large as possible when disposed at the bottom, so as to reduce the flow rate of the mixture. During normal use, the bottom of the baffle 4 should be as close as possible to the level of the oil phase in the buffer tank 3, typically 5-10cm, to reduce the rate of flow of the mixture into the oil phase. The edge of the buffer plate 4 is provided with a tapered surface from which the mixture flows down along the inner wall of the buffer tank 3 after flowing toward the inner wall of the buffer tank 3.

In this embodiment, the implementation manner is specifically as follows: the mixture of oil, gas and water is conveyed from the inlet 11 to the inside of the tank body 1, when the mixture flows out from the inlet 11, the speed is high, the impact force is high, firstly, the mixture impacts the baffle 15 to reduce the speed, and a part of gas phase is separated, and the gas phase flows from the gas outlet 22 to the inside of the tank body 1 at the right side of the upper end of the collecting hopper 2. After the mixture is slowed down, it flows down from the first water outlet 21 to the inside of the buffer tank 3 along the collecting hopper 2 and impacts the buffer plate 4 to further slow down, at this time, the flow direction of the mixture is changed to be substantially horizontal and spread around, and after passing through the position of the gap 41, it can flow into the oil phase inside the buffer tank 3 along the inner wall of the buffer tank 3. Through the setting of buffer tank 3 and buffer board 4, the mixture of oil gas water is slowed down when making on the one hand impact buffer board 4, on the other hand the mixture can flow into the oil phase in the buffer tank 3 downwards along the lateral wall of buffer tank 3, and is less to the impact force of oil phase, makes the fluctuation of oil phase in the buffer tank 3 less, and because this fluctuation is located buffer tank 3 basically, so influence less to the oil phase in jar body 1 to the direct liquid of entering jar body 1 of mixture of oil gas water, can produce great wave, causes the oil-water interface unbalance, takes place the problem of disorder.

Referring to fig. 1-4 of the specification, the embodiment further provides a buffer assembly 5, specifically, the buffer assembly 5 includes an outer cylinder 51, the outer cylinder 51 is installed at the upper end of the tank body 1, a connecting shaft 52 is vertically movably installed in the outer cylinder 51, a swivel 53 is rotatably connected to the connecting shaft 52, a first spring 54 is sleeved on the connecting shaft 52, two ends of the first spring 54 are respectively pressed with the swivel 53 and the bottom of the inner side of the connecting shaft 52, and the bottom end of the connecting shaft 52 is fixedly connected with the middle of the buffer plate 4.

When the oil-gas-water mixture impacts the buffer plate 4, the first spring 54 may serve as a buffer, that is, a part of kinetic energy and potential energy of the mixture is converted into kinetic energy of the buffer plate 4, the connecting shaft 52 and the swivel 53, and elastic potential energy of the first spring 54, so that the flow rate of the mixture can be further reduced.

Further, a liquid level sensor 6 is installed on the side wall of the buffer tank 3, the liquid level sensor 6 is used for detecting the liquid level of the oil phase, a power assembly 7 is installed on the tank body 1, and the power assembly 7 is used for driving the connecting shaft 52 to move vertically.

It should be noted that, since the liquid level of the oil phase in the tank 1 is dynamically changed and the buffer plate 4 can move up and down, if the buffer plate 4 contacts with the oil phase in the buffer tank 3, a large fluctuation occurs, and therefore, the liquid level of the oil phase in the buffer tank 3 is detected by the liquid level sensor 6, when the liquid level of the oil phase is higher than a set value, the power assembly 7 needs to drive the buffer plate 4 to move up a distance to prevent the buffer plate 4 from contacting with the oil phase in the buffer tank 3, wherein the power assembly 7 can use a cylinder, and the power assembly 6 can also be installed at the bottom of the buffer plate 4.

Referring to fig. 2-5 of the specification, a slag outlet 32 is formed in one side of the upper end of the buffer tank 3, a slag discharging component 8 is arranged at one end of the tank body 1, the slag discharging component 8 is communicated with the slag outlet 32, the power component 7 is further used for driving the buffer plate 4 to rotate, so that the buffer plate 4 throws sediment at the edge of the buffer plate from the slag outlet 32 to the inside of the slag discharging component 8, a pressure sensor 80 is arranged in the outer cylinder 51, and the pressure sensor 80 is used for detecting the pressure of the first spring 54.

Since the outer tube 51 is slidably mounted vertically to the tank 1 and the mixture is required to flow from the gap 41 to the inner wall of the buffer tank 3, the gap 41 has a small width, and when sand or stones are present in the mixture, the sand or stones remain at the edge of the buffer plate 4, and cannot be discharged, or cannot enter the bottom of the tank 1. The slag discharge assembly 8 is thus designed. When there are more sand and stones at the edge of the buffer plate 4, the amount of the mixture flowing downwards is reduced, so that more mixture is remained on the buffer plate 4, at this time, the pressure detected by the pressure sensor 80 is obviously increased, at this time, the buffer plate 4 can be driven to move upwards by the power assembly 7 and rotate the buffer plate 4, and when the buffer plate 4 moves upwards to the position of the slag hole 32, the sand and stones can be thrown out to the slag discharging assembly 8 for collection. Wherein, power pack 7 still includes the motor for drive buffer board 4 rotation.

In the above technical solution, the pressure sensor 80 may not be provided, and at this time, the power assembly 7 may drive the buffer plate 4 to move up and rotate at intervals to remove sand and stones.

It should be noted that during the sand removal process, the addition of the hydrocarbon-water mixture is preferably stopped to avoid excessive entry of the mixture into the slag removal assembly 8.

Further, the slag discharging assembly 8 comprises a slag discharging pipe 81, the slag discharging pipe 81 is communicated with the slag outlet 32, the slag discharging pipe 81 is provided with a first channel 811 and a second channel 812, the first channel 811 is arranged in a downward inclined mode, the second channel 812 is located at the front end of the first channel 811, the bottom of the second channel 812 is open, and a blocking part 82 is arranged at the position of the bottom opening.

Further, the plugging member 82 includes a plugging body 821, the plugging body 821 is used for plugging the bottom opening of the slag discharging channel two 812, a first guide rod 822 is installed on one side of the plugging body 821, the first guide rod 822 is inserted on the slag discharging pipe 81, and a second spring 823 is sleeved on the first guide rod 822.

Still further, the upper end of the second slag discharging channel 812 is opened, the pushing block 831 is movably inserted in the position of the upper end opening of the second slag discharging channel 812, one side of the pushing block 831 is fixedly connected with the second guide rod 832, the second guide rod 832 is movably inserted in the slag discharging pipe 81, and the third spring 833 is sleeved outside the second guide rod 832.

It should be noted that, the slag discharging pipe 81 is obliquely arranged, the first channel 811 and the second slag discharging channel 812 are vertically arranged, sand and stone can gather at the bottom of the second slag discharging channel 812 after entering the second slag discharging channel 812, when the treatment is needed, the pushing block 831 is pressed, the pushing block 831 moves downwards to close the first channel 811, then the pushing block 831 presses the blocking body 821 downwards, the bottom of the second slag discharging channel 812 is opened by the blocking body 821, and then the sand and stone can be directly discharged. After the discharging is completed, the pushing block 831 is loosened, the pushing block 831 is reset under the action of the elastic force of the spring III 833, the blocking body 821 is reset under the action of the spring II 823, in the resetting process, the bottom of the slag discharging channel II 812 is closed by the blocking body 821, and then the channel I811 is opened by the pushing block 831. Through the setting of sediment subassembly 8, in the in-process of discharging sand and stone, can prevent jar body 1 and outside intercommunication to guarantee operational environment's safety.

Referring to fig. 2-3 and 6-8 of the drawings, a power assembly 7 is provided for rotating and vertically moving the dampening plate 4. Specifically, the power assembly 7 includes an outer connecting sleeve 71 and an inner shaft 72, the outer connecting sleeve 71 is movably sleeved on the outer side of the inner shaft 72, the outer connecting sleeve 71 is fixedly connected with the upper end of the outer cylinder 51, the connecting shaft 52 is axially slidably inserted in the inner shaft 72, the power assembly 7 further includes a transmission part 73, and the transmission part 73 is used for driving the inner shaft 72 to rotate and for driving the outer connecting sleeve 71 to vertically move.

Further, the transmission part 73 includes a casing 731, the casing 731 is fixedly installed at the upper end of the tank 1, a driving member 732 is fixedly installed on the casing 731, an output end of the driving member 732 is fixedly connected with a main shaft 733, an end portion of the main shaft 733 is fixedly connected with a worm 734, a short shaft 735 is rotatably connected to the casing 731, a worm wheel 736 is installed on the short shaft 735, the worm 734 is meshed with the worm wheel 736, an end portion of the short shaft 735 is fixedly connected with a swing arm 737, an outer sleeve 738 is rotatably sleeved on the outer sleeve 71, a side shaft 7381 is provided on a side wall of the outer sleeve 738, a chute 7371 is provided at one end of the swing arm 737 far away from the short shaft 735, the side shaft 7381 slides in the chute 7371, and the inner shaft 72 is in transmission connection with the main shaft 733 through the gear set 730.

Working principle: the driving member 732 drives the main shaft 733 to rotate, the main shaft 733 drives the worm 734 to rotate, the worm 734 drives the short shaft 735 to rotate and the worm wheel 736 to rotate, it should be noted that the driving member 732 is intermittently rotated forward and backward, so that the swing arm 737 can swing reciprocally, and the swing arm 737 can drive the outer connecting sleeve 71 to move up and down through the outer sleeve 738, during which the side shaft 7381 slides inside the sliding groove 7371. The worm 734 drives the inner shaft 72 to rotate through the gear set 730, and the inner shaft 72 is slidably connected to the connecting shaft 52 through splines. Therefore, the connecting shaft 52 and the buffer plate 4 can be driven to rotate by the rotation of the inner shaft 72, the outer cylinder 51 can be driven to vertically move by the vertical movement of the outer connecting sleeve 71, and the outer cylinder 51 can drive the connecting shaft 52 and the buffer plate 4 to vertically move by the first spring 54. In the above description, the gear set 730 is composed of three spur gears, and the driving member 732 is a gear motor, and the upper end of the inner shaft 72 is rotatably connected to the housing 731.

Finally: the foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims (10)

1. The utility model provides a crude oil gas water three-phase separation sled dress supercharging device which characterized in that: the oil-gas-water separator comprises a base, wherein a tank body (1) is arranged on the base, an inlet (11) is formed in one end of the tank body (1), a baffle (15) is fixedly arranged at the top of the inner side of the tank body (1), the baffle (15) is opposite to the inlet (11), a mixture of oil gas and water enters the tank body (1) from the inlet (11) and impacts the baffle (15), and oil phase, gas phase and water phase are separated after the mixture flows into the tank body (1);

the inside of jar body (1) is provided with collects fill (2), and import (11) and baffle (15) all are located the top of collecting fill (2), the bottom of collecting fill (2) has delivery port one (21), be provided with buffer tank (3) under delivery port one (21), the downside of buffer tank (3) has delivery port two (31), delivery port two (31) are located the inside of oil phase, the inside of buffer tank (3) is provided with buffer board (4), buffer board (4) are located oil phase liquid level more, have clearance (41) between the inside wall of buffer board (4) peripheral edge and buffer tank (3), the mixture flows down along the inside wall of buffer tank (3) from the position of clearance (41).

2. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 1, wherein: the three-phase separation sled dress supercharging device of crude oil gas water still includes buffer module (5), buffer module (5) include urceolus (51), the upper end at jar body (1) is installed to urceolus (51), the inside vertical movable mounting of urceolus (51) has connecting axle (52), it is connected with swivel (53) to rotate on connecting axle (52), the cover is equipped with spring one (54) on connecting axle (52), the both ends of spring one (54) presss from both sides mutually with swivel (53) and the inboard bottom of connecting axle (52) respectively, the bottom of connecting axle (52) is connected with the middle part fixed connection of buffer plate (4).

3. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 2, wherein: the side wall of the buffer box (3) is provided with a liquid level sensor (6), the liquid level sensor (6) is used for detecting the liquid level of the oil phase, the tank body (1) is provided with a power assembly (7), and the power assembly (7) is used for driving the connecting shaft (52) to move vertically.

4. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 3, wherein: slag notch (32) have been seted up to one side of buffer tank (3) upper end, the one end of jar body (1) is provided with sediment subassembly (8), sediment subassembly (8) and slag notch (32) intercommunication, power pack (7) still are used for driving buffer board (4) and rotate to make buffer board (4) get rid of sediment at self edge from slag notch (32) to the inside of sediment subassembly (8), the inside of urceolus (51) is provided with pressure sensor (80), pressure sensor (80) are used for detecting the pressure of spring one (54).

5. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 4, wherein: the slag discharging assembly (8) comprises a slag discharging pipe (81), the slag discharging pipe (81) is communicated with a slag discharging hole (32), the slag discharging pipe (81) is provided with a first channel (811) and a second channel (812) for discharging slag, the first channel (811) is arranged in a downward inclined mode, the second channel (812) for discharging slag is located at the front end of the first channel (811), the bottom of the second channel (812) for discharging slag is provided with an opening, and a plugging part (82) is arranged at the position of the opening at the bottom.

6. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 5, wherein: the plugging part (82) comprises a plugging body (821), the plugging body (821) is used for plugging the bottom opening of the slag discharging channel II (812), a guide rod I (822) is arranged on one side of the plugging body (821), the guide rod I (822) is inserted on the slag discharging pipe (81), and a spring II (823) is sleeved on the guide rod I (822).

7. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 6, wherein: the slag discharging device is characterized in that an upper end of the slag discharging channel II (812) is provided with an opening, a pushing block (831) is movably inserted in the position of the opening at the upper end of the slag discharging channel II (812), one side of the pushing block (831) is fixedly connected with a guide rod II (832), the guide rod II (832) is movably inserted on the slag discharging pipe (81), and a spring III (833) is sleeved on the outer side of the guide rod II (832).

8. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 7, wherein: the power assembly (7) comprises an outer connecting sleeve (71) and an inner shaft (72), the outer connecting sleeve (71) is movably sleeved on the outer side of the inner shaft (72), the outer connecting sleeve (71) is fixedly connected with the upper end of the outer cylinder (51), the connecting shaft (52) is axially and slidably inserted into the inner shaft (72), the power assembly (7) further comprises a transmission part (73), and the transmission part (73) is used for driving the inner shaft (72) to rotate and driving the outer connecting sleeve (71) to vertically move.

9. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 8, wherein: the transmission part (73) comprises a shell (731), shell (731) fixed mounting is in the upper end of jar body (1), fixed mounting has driving piece (732) on shell (731), the output fixedly connected with main shaft (733) of driving piece (732), the tip fixedly connected with worm (734) of main shaft (733), rotate on shell (731) and be connected with minor axis (735), worm wheel (736) are installed to minor axis (735), worm (734) meshes with worm wheel (736), the tip fixedly connected with swing arm (737) of minor axis (735), rotate on outer adapter sleeve (71) and overlap and be equipped with overcoat (738), have sideshaft (7381) on the lateral wall of overcoat (738), the one end that swing arm (737) kept away from minor axis (735) has spout (7371), sideshaft (7381) are in the inside slip of spout (7371), interior axle (72) are connected through gear train (730) transmission with main shaft (733).

10. The crude oil, gas and water three-phase separation skid-mounted supercharging device according to claim 1, wherein: the bottom of the tank body (1) is provided with an oil discharge port (12) and a water discharge port (13), the upper end of the tank body (1) is provided with an exhaust port (14), after the oil-gas-water mixture is separated, the oil phase is discharged from the oil discharge port (12), the water phase is discharged from the water discharge port (13), the gas phase is discharged from the exhaust port (14), and the position of the oil discharge port (12) is provided with a conveying pump (9).