CN113368610A

CN113368610A - Efficient progressive gas-liquid separation device

Info

Publication number: CN113368610A
Application number: CN202110692385.2A
Authority: CN
Inventors: 娄迎旦
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-06-22
Filing date: 2021-06-22
Publication date: 2021-09-10

Abstract

The invention discloses an efficient step-by-step gas-liquid separation device, and relates to the technical field of gas-liquid separation. This high-efficient type gas-liquid separation device step by step includes the supporting baseplate, the supporting baseplate top is fixed with a cylinder and driving motor, the cylinder is inside to be drawn empty and both ends are the opening form, driving motor sets up on the cylinder right side. This high-efficient type gas-liquid separation equipment step by step, can break the foam in the inside gas-liquid mixture of cylinder through setting up one-level broken foam net and second grade broken foam net, and simultaneously, the broken foam net of one-level that rotates the setting makes gas-liquid mixture near the drive sleeve inner wall under the effect of centrifugal force, in the mutual motion between gas-liquid mixture and one-level broken foam net, the broken foam that the one-level was netted not only can make the inside foam of gas-liquid mixture broken, can also make partial gas and the liquid separation in the gas-liquid mixture in order to produce more foams, recycle the second grade broken foam net and carry out the operation of secondary broken foam.

Description

Efficient progressive gas-liquid separation device

Technical Field

The invention relates to the technical field of gas-liquid separation, in particular to a high-efficiency step-by-step gas-liquid separation device.

Background

The gas-liquid separator adopts the principles of centrifugal separation and wire mesh filtration to realize a separation device for removing liquid. It is mainly composed of cylinder, cyclone separator, high-efficiency foam-breaking net and blow-off valve. It is generally installed in front of the drying device to realize coarse filtration to remove partial moisture in the air, so as to reduce the work load of the drying device.

The existing gas-liquid separator usually needs a large amount of time for separating gas and liquid, has low efficiency, can seriously influence the engineering progress when separating a large amount of gas-liquid mixture, and has great defects.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides an efficient progressive gas-liquid separation device, which solves the problems in the background technology.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: a high-efficiency progressive gas-liquid separation device comprises a supporting bottom plate, wherein a separation cylinder and a driving motor are fixed at the top of the supporting bottom plate, the separation cylinder is hollowed out, two ends of the separation cylinder are in an open shape, the driving motor is arranged on the right side of the separation cylinder, an output shaft of the driving motor is fixed with one end of a central driving shaft, the other end of the central driving shaft is positioned in the separation cylinder and fixed with the center of a primary foam breaking net, the part of the side surface of the central driving shaft positioned in the separation cylinder is movably connected with the center of a secondary foam breaking net, the secondary foam breaking net is movably sleeved on the central driving shaft and fixed with one end of a spring, the other end of the spring is rotatably connected with the central driving shaft, a plurality of foam breaking spiles are arranged on the secondary foam breaking net, a plurality of reinforcing grooves are arranged between two sides of the primary foam breaking net in a penetrating manner, two sides of the reinforcing grooves are both in a zigzag manner, one side of the reinforcing grooves close to the center of the primary foam breaking net is fixed with one end of a connecting rod, the other end of the connecting rod is fixed with the inner wall of the driving sleeve, and the outer wall of the driving sleeve is attached to the inner wall of the separating cylinder.

Foam in the inside gas-liquid mixture of cylinder can be broken through setting up broken foam net of one-level and second grade broken foam net, and simultaneously, the broken foam net of one-level that rotates the setting makes gas-liquid mixture paste near the drive sleeve inner wall under the effect of centrifugal force with the drive sleeve, in the mutual motion between gas-liquid mixture and the broken foam net of one-level, the broken foam that the broken foam net of one-level not only can make gas-liquid mixture inside is broken, can also make partial gas and the liquid separation in the gas-liquid mixture in order to produce more foam, recycle the broken foam net of second grade and carry out the operation of secondary broken foam, and the differential rotation setting between broken foam net of one-level and the broken foam net of second grade can improve the broken effect of the broken foam of second grade broken foam net to the foam.

Preferably, in order to improve the gas-liquid mixture along with drive sleeve pivoted speed and improve the gas-liquid separation effect, one side that second grade broken foam net was kept away from to the one-level broken foam net is fixed with the arc water conservancy diversion piece, the circulation groove has been seted up to the one end that the arc water conservancy diversion piece is close to drive sleeve inner wall, the protruding side of arc water conservancy diversion piece is close to circulation groove department and is fixed with multiunit reinforcing strip one and reinforcing strip two, the contained angle between reinforcing strip one and the reinforcing strip two is ninety degrees, and is crisscross form setting between reinforcing strip one and the reinforcing strip two.

Preferably, in order to improve the differential rotation effect between the secondary foam breaking net and the gas-liquid mixture, four variable-speed magnetic blocks are embedded between two sides of the secondary foam breaking net, four resistance bars matched with the variable-speed magnetic blocks are fixed on the outer wall of the separation cylinder, the resistance bars are made of iron, and the positions of the resistance bars correspond to the positions of the variable-speed magnetic blocks.

Preferably, in order to improve the foam crushing effect of the secondary foam crushing net, four auxiliary magnetic blocks are fixed on the side surface of the part of the central driving shaft, which is located between the primary foam crushing net and the secondary foam crushing net, the distance between the auxiliary magnetic blocks and the central driving shaft is equal to the distance between the variable speed magnetic blocks and the central driving shaft, and the magnetic poles of the auxiliary magnetic blocks and the variable speed magnetic blocks on the side close to each other are the same.

Preferably, in order to accurately discharge the separated gas and liquid and avoid secondary mixing of the gas and liquid in the discharge process, one end of the separation cylinder close to the driving motor is rotationally connected with one end of the rotary drainage cylinder, the other end of the rotary drainage cylinder is rotationally connected with the fixed drainage cylinder, the bottom of the fixed drainage cylinder is fixed with the supporting bottom plate, one end far away from the separating cylinder is provided with a drainage pipe, the driving sleeve is positioned in the rotating drainage cylinder and the fixed drainage cylinder, and the driving sleeve penetrates through the fixed drainage cylinder and is rotationally connected with the fixed drainage cylinder, a gap is arranged between the outer wall of the driving sleeve and the rotary drainage cylinder as well as between the outer wall of the driving sleeve and the fixed drainage cylinder, a plurality of separation channels are arranged on the partial side surface of the driving sleeve positioned in the rotary drainage cylinder, the central driving shaft is fixed with the inner wall of the rotary drainage cylinder through a linkage column, the part of the driving sleeve between the fixed drainage cylinder and the driving motor is conical, and an exhaust pipe is arranged at the top of the driving sleeve.

Preferably, in order to improve the broken foam effect of one-level broken foam net and second grade broken foam net, the drive sleeve outer wall is fixed with the hemisphere block rubber, fixed drainage cylinder inner wall is fixed with the impact rod with hemisphere block rubber looks adaptation.

(III) advantageous effects

The invention provides a high-efficiency progressive gas-liquid separation device. The method has the following beneficial effects:

(1) this high-efficient type gas-liquid separation equipment step by step, foam in can be to the inside gas-liquid mixture of cylinder through setting up one-level broken foam net and second grade broken foam net breaks away, and simultaneously, the broken foam net of one-level that rotates the setting makes gas-liquid mixture near the drive sleeve inner wall under the effect of centrifugal force, in the mutual motion between gas-liquid mixture and one-level broken foam net, the broken foam that the one-level was broken the net not only can make the inside foam of gas-liquid mixture break, can also make partial gas and the liquid separation in the gas-liquid mixture in order to produce more foams, recycle second grade broken foam net and carry out the operation of secondary broken foam, and differential rotation between one-level broken foam net and the second grade broken foam net sets up the broken effect that can improve second grade broken foam net to the foam.

(2) This high-efficient type gas-liquid separation device step by step can lead the inside gas-liquid mixture of drive sleeve through setting up the arc water conservancy diversion piece for gas-liquid mixture can be quick more press close to drive sleeve inner wall, not only can improve gas-liquid mixture along with drive sleeve pivoted speed, reinforcing strip one on the arc water conservancy diversion piece and reinforcing strip two can also and the collision between the gas-liquid mixture can also improve the gas-liquid separation effect.

(3) This high-efficient type gas-liquid separation equipment step by step, through the magnetic adsorption effect between variable speed magnetic block and the resistance column bar can improve the second grade broken foam net along with central drive shaft slow speed when rotating with the differential effect between the broken foam net of one-level, and then can improve the differential rotation effect between broken foam net of second grade and the gas-liquid mixture, and repulsion between supplementary magnetic path and the variable speed magnetic block can make the broken foam net of second grade produce the removal in stage at central drive shaft, with the collision effect between improvement broken foam net of second grade and the gas-liquid mixture, and then improve the crushing effect of broken foam net of second grade to the foam.

(4) This high-efficient type gas-liquid separation device step by step can utilize the centrifugal force variation in size when gas and liquid rotate to carry out gas-liquid separation through setting up separation channel, rotating a drain cylinder and a fixed drain cylinder for liquid passes through the fluid-discharge tube and discharges, and gaseous through the blast pipe discharge, and then realizes carrying out accurate discharge to the gas-liquid after the separation, can also avoid the secondary mixed condition of discharge in-process gas-liquid.

(5) This high-efficient type gas-liquid separation device step by step can utilize the rotation each other between drive sleeve and the fixed water drainage section of thick bamboo to make drive sleeve produce certain vibration through setting up hemisphere rubber ball and impact rod, and this vibration transmission can improve the broken foam effect of one-level broken foam net and second grade broken foam net after on one-level broken foam net and the second grade broken foam net.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a general partial cross-sectional view of the present invention;

FIG. 3 is an overall multi-angle partial cross-sectional view of the present invention;

FIG. 4 is a multi-angle partial cross-sectional view of a rotary drainage cartridge of the present invention;

fig. 5 is a schematic view of a multi-angle structure of an arc-shaped guide vane of the present invention.

In the figure: 1. a support base plate; 2. a separation cylinder; 21. resistance bars; 3. a drive motor; 4. a central drive shaft; 41. a first-stage foam breaking net; 411. a reinforcing groove; 412. a connecting rod; 42. a secondary foam breaking net; 421. a variable speed magnetic block; 43. an auxiliary magnetic block; 44. a linkage column; 5. a drive sleeve; 51. a separation channel; 52. an exhaust pipe; 53. a hemispherical rubber block; 6. an arc-shaped flow deflector; 61. a circulation tank; 62. a first reinforcing strip; 63. a second reinforcing strip; 7. rotating the drainage cylinder; 8. fixing a drainage cylinder; 81. a liquid discharge pipe; 82. a striker rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a high-efficiency progressive gas-liquid separation device comprises a supporting bottom plate 1, a separating cylinder 2 and a driving motor 3 are fixed at the top of the supporting bottom plate 1, the separating cylinder 2 is hollowed out, two ends of the separating cylinder 2 are in an open shape, the driving motor 3 is arranged on the right side of the separating cylinder 2, an output shaft of the driving motor is fixed with one end of a central driving shaft 4, the other end of the central driving shaft 4 is arranged inside the separating cylinder 2 and fixed with the center of a primary foam breaking net 41, the partial side surface of the central driving shaft 4 arranged inside the separating cylinder 2 is movably connected with the center of a secondary foam breaking net 42, the secondary foam breaking net 42 is movably sleeved on the central driving shaft 4 and fixed with one end of a spring, the other end of the spring is rotatably connected with the central driving shaft 4, a plurality of needle-shaped foam breaking thorns are arranged on the secondary foam breaking net 42, a plurality of reinforcing grooves 411 are arranged between two sides of the primary foam breaking net 41 in a penetrating manner, two sides of the reinforcing grooves 411 are both in a zigzag manner, one side close to the center of the primary foam breaking net 41 is fixed with one end of a connecting rod 412, the other end of the connecting rod 412 is fixed with the inner wall of the driving sleeve 5, and the outer wall of the driving sleeve 5 is attached to the inner wall of the separating cylinder 2.

Foam in the inside gas-liquid mixture of cylinder 2 can be broken through setting up one-level broken foam net 41 and second grade broken foam net 42, and simultaneously, the one-level broken foam net 41 that rotates the setting makes gas-liquid mixture press close to the 5 inner walls of drive sleeve under the effect of centrifugal force with drive sleeve 5, in the mutual motion between gas-liquid mixture and one-level broken foam net 41, one-level broken foam net 41 not only can make the inside foam of gas-liquid mixture broken, can also make partial gas and the liquid separation in the gas-liquid mixture in order to produce more foam, recycle second grade broken foam net 42 and carry out the operation of secondary broken foam, and the differential rotation between one-level broken foam net 41 and second grade broken foam net 42 sets up the broken effect that can improve second grade broken foam net 42 to the foam.

Preferably, in this embodiment, in order to improve the speed of the gas-liquid mixture rotating along with the driving sleeve 5 and improve the gas-liquid separation effect, one side of the first-stage defoaming net 41 away from the second-stage defoaming net 42 is fixed with an arc-shaped baffle 6, one end of the arc-shaped baffle 6 close to the inner wall of the driving sleeve 5 is provided with a circulation groove 61, the convex side of the arc-shaped baffle 6 close to the circulation groove 61 is fixed with a plurality of groups of first reinforcing strips 62 and second reinforcing strips 63, an included angle between the first reinforcing strips 62 and the second reinforcing strips 63 is ninety degrees, and the first reinforcing strips 62 and the second reinforcing strips 63 are arranged in a staggered manner.

Preferably, in this embodiment, in order to improve the differential rotation effect between the secondary defoaming net 42 and the gas-liquid mixture, four variable-speed magnetic blocks 421 are embedded between two sides of the secondary defoaming net 42, four resistance bars 21 adapted to the variable-speed magnetic blocks 421 are fixed on the outer wall of the separation cylinder 2, the resistance bars 21 are made of iron, and the positions of the resistance bars 21 correspond to the positions of the variable-speed magnetic blocks 421.

Preferably, in this embodiment, in order to improve the foam breaking effect of the secondary foam breaking net 42, four auxiliary magnetic blocks 43 are fixed on a side surface of the central driving shaft 4 between the primary foam breaking net 41 and the secondary foam breaking net 42, a distance between the auxiliary magnetic blocks 43 and the central driving shaft 4 is equal to a distance between the variable speed magnetic block 421 and the central driving shaft 4, and magnetic poles on sides of the auxiliary magnetic blocks 43 and the variable speed magnetic block 421 are the same.

Preferably, in this embodiment, in order to accurately discharge the separated gas-liquid and avoid the secondary mixing of the gas-liquid in the discharging process, one end of the separation cylinder 2 close to the driving motor 3 is rotatably connected with one end of the rotary drainage cylinder 7, the other end of the rotary drainage cylinder 7 is rotatably connected with the fixed drainage cylinder 8, the bottom of the fixed drainage cylinder 8 is fixed with the supporting base plate 1, one end far away from the separation cylinder 2 is provided with a liquid discharge pipe 81, the driving sleeve 5 is positioned inside the rotary drainage cylinder 7 and the fixed drainage cylinder 8, the driving sleeve 5 penetrates through the fixed drainage cylinder 8 and is rotatably connected with the fixed drainage cylinder 8, a gap is arranged between the outer wall of the driving sleeve 5 and the rotary drainage cylinder 7 and the fixed drainage cylinder 8, a plurality of separation channels 51 are arranged on the side surface of the part of the driving sleeve 5 positioned inside the rotary drainage cylinder 7, the central driving shaft 4 is fixed with the inner wall of the rotary drainage cylinder 7 through the linking column 44, the part of the driving sleeve 5 between the fixed drainage cylinder 8 and the driving motor 3 is conical and the top part is provided with an exhaust pipe 52.

Preferably, in the present embodiment, in order to improve the foam breaking effect of the primary foam breaking net 41 and the secondary foam breaking net 42, the hemispherical rubber block 53 is fixed on the outer wall of the driving sleeve 5, and the impact rod 82 matched with the hemispherical rubber block 53 is fixed on the inner wall of the fixed drainage tube 8.

The working principle is as follows: the switch of the driving motor 3 is turned on, the output shaft of the driving motor 3 drives the central driving shaft 4 to rotate, the central driving shaft 4 drives the first-stage foam breaking net 41 to rotate, the first-stage foam breaking net 41 drives the driving sleeve 5 to rotate in the separating cylinder 2 through the connecting rod 412, the gas-liquid mixture is input into the separating cylinder 2 through the left end of the separating cylinder 2, the gas-liquid mixture entering the separating cylinder 2 can enter the driving sleeve 5, the driving sleeve 5 can drive the gas-liquid mixture to rotate in the rotating process, the gas-liquid mixture can cling to the inner wall of the driving sleeve 5 under the action of centrifugal force and simultaneously rotate along with the driving sleeve 5, when the gas-liquid mixture passes through the first-stage foam breaking net 41, the first-stage foam breaking net 41 can break foam in the gas-liquid mixture, and the collision between the first-stage foam breaking net 41 and the gas-liquid mixture can improve the gas-liquid separation effect in the gas-liquid mixture and generate certain foam, the gas-liquid mixture on the primary foam breaking net 41 collides with the primary foam breaking net 41 in the process of moving towards the inner wall of the driving sleeve 5 so as to improve the foam breaking effect and the gas-liquid separation effect of the gas-liquid mixture, and meanwhile, the collision effect between the primary foam breaking net 41 and the gas-liquid mixture is improved by the reinforcing groove 411 and the connecting rod 412; when the gas-liquid mixture enters the driving sleeve 5, the driving sleeve 5 and the first-stage foam breaking net 41 rotate to drive the arc-shaped flow deflector 6 to rotate, the convex side of the arc-shaped flow deflector 6 guides the gas-liquid mixture, the gas-liquid mixture passes through the circulation groove 61 and is close to the inner wall of the driving sleeve 5, and meanwhile, the gas-liquid mixture collides with the first reinforcing strips 62 and the second reinforcing strips 63; because the secondary foam breaking net 42 is movably sleeved with the central driving shaft 4, the rotating speed of the secondary foam breaking net 42 under the action of the central driving shaft 4 and the gas-liquid mixture is far less than that of the primary foam breaking net 41, so that differential rotation exists between the primary foam breaking net 41 and the secondary foam breaking net 42 as well as the gas-liquid mixture, the differential effect can improve the collision effect of the secondary foam breaking net 42 on the gas-liquid mixture, the magnetic force between the variable-speed magnetic block 421 and the resistance column bar 21 can cause the deceleration motion of the secondary foam breaking net 42 within a certain range when the secondary foam breaking net 42 rotates, further the differential motion between the secondary foam breaking net 42 and the gas-liquid mixture within the range can be improved, when the position of the variable-speed magnetic block 421 corresponds to the auxiliary magnetic block 43, the repulsion force between the auxiliary magnetic block 43 and the variable-speed magnetic block 421 can enable the secondary foam breaking net 42 to move in the direction far away from the auxiliary magnetic block 43 and compress the spring, when the position of the variable speed magnetic block 421 is far away from the auxiliary magnetic block 43, the secondary foam breaking net 42 is reset under the action of the spring, so that the primary reciprocating motion of the secondary foam breaking net 42 is realized, and the foam breaking effect of needle-shaped foam breaking pricks on the secondary foam breaking net 42 is improved; since the centrifugal force applied to the gas during rotation is much smaller than the centrifugal force applied to the liquid during rotation, after the gas-liquid mixture passes through the primary defoaming net 41 and the secondary defoaming net 42, the liquid clings to the inner wall of the driving sleeve 5, the gas is located inside the driving sleeve 5 and is wrapped by the liquid, when the liquid moves to the separation channel 51, the liquid passes through the separation channel 51 under the action of the centrifugal force and enters the part between the driving sleeve 5 and the rotating drainage cylinder 7, and then moves to the fixed drainage cylinder 8, because the fixed drainage cylinder 8 is in a fixed state, the liquid stops rotating and descends under the action of gravity and is discharged through the liquid discharge pipe 81, and the gas continues to move inside the driving sleeve 5 and is discharged through the gas discharge pipe 52; when the driving sleeve 5 rotates, the hemispherical rubber block 53 collides with the impact rod 82 and vibrates, and the vibration is transmitted to the first-stage foam breaking net 41, the central driving shaft 4 and the second-stage foam breaking net 42 through the driving sleeve 5, so that the first-stage foam breaking net 41 and the second-stage foam breaking net 42 vibrate in a gas-liquid mixture, and the foam breaking and gas-liquid separation effects of the first-stage foam breaking net 41 and the second-stage foam breaking net 42 are improved.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a high-efficient type is gas-liquid separation device step by step, includes supporting baseplate (1), its characterized in that: the utility model discloses a foam breaking machine, including supporting baseplate (1), cylinder (2) and driving motor (3) are fixed at supporting baseplate (1) top, cylinder (2) is inside to be hollowed and both ends are the opening form, driving motor (3) set up cylinder (2) right side and output shaft and central drive shaft (4) one end fixed, the center drive shaft (4) other end is located cylinder (2) inside and fixed with one-level foam breaking net (41) center department, central drive shaft (4) are located the partial side that is located cylinder (2) inside still with second grade foam breaking net (42) center department swing joint, be provided with a plurality of needle-like foam breaking thorns on second grade foam breaking net (42), run through between one-level foam breaking net (41) both sides and seted up a plurality of reinforcing grooves (411), reinforcing groove (411) both sides all are the cockscomb structure, reinforcing groove (411) are close to one-level foam breaking net (41) center department one side fixed with connecting rod (412) one end, the other end of the connecting rod (412) is fixed with the inner wall of the driving sleeve (5), and the outer wall of the driving sleeve (5) is attached to the inner wall of the separating cylinder (2).

2. A high efficiency progressive gas-liquid separation device as recited in claim 1, wherein: one side that second grade broken foam net (42) was kept away from in one-level broken foam net (41) is fixed with arc water conservancy diversion piece (6), circulation groove (61) have been seted up to one end that arc water conservancy diversion piece (6) are close to drive sleeve (5) inner wall, arc water conservancy diversion piece (6) protruding side is close to circulation groove (61) department and is fixed with multiunit reinforcing strip (62) and reinforcing strip two (63), the contained angle between reinforcing strip (62) and reinforcing strip two (63) is ninety degrees, and is crisscross form setting between reinforcing strip (62) and the reinforcing strip two (63).

3. A high efficiency progressive gas-liquid separation device as recited in claim 1, wherein: it has four variable speed magnetism piece (421) to inlay between second grade foam breaker (42) both sides, separating cylinder (2) outer wall is fixed with four resistance column bars (21) with variable speed magnetism piece (421) looks adaptation, resistance column bar (21) are ironwork, the position of resistance column bar (21) corresponds with the position of variable speed magnetism piece (421).

4. A high efficiency progressive gas-liquid separation device according to claim 3, wherein: four auxiliary magnetic blocks (43) are fixed on the side face of the part, located between the primary foam breaking net (41) and the secondary foam breaking net (42), of the central driving shaft (4), the distance between each auxiliary magnetic block (43) and the central driving shaft (4) is equal to the distance between the variable speed magnetic block (421) and the central driving shaft (4), and the magnetic poles of the auxiliary magnetic blocks (43) and the variable speed magnetic block (421) on the side close to each other are the same.

5. A high efficiency progressive gas-liquid separation device as recited in claim 1, wherein: the water-saving drainage device is characterized in that one end of the separation cylinder (2) close to the driving motor (3) is rotationally connected with one end of the rotary drainage cylinder (7), the other end of the rotary drainage cylinder (7) is rotationally connected with the fixed drainage cylinder (8), the bottom of the fixed drainage cylinder (8) is fixed with the supporting base plate (1), one end far away from the separation cylinder (2) is provided with a drain pipe (81), the driving sleeve (5) is positioned inside the rotary drainage cylinder (7) and the fixed drainage cylinder (8), the driving sleeve (5) penetrates through the fixed drainage cylinder (8) and is rotationally connected with the fixed drainage cylinder (8), a gap is arranged between the outer wall of the driving sleeve (5) and the rotary drainage cylinder (7) and the fixed drainage cylinder (8), a plurality of separation channels (51) are arranged on the side face of the part of the driving sleeve (5) positioned inside the rotary drainage cylinder (7), and the central driving shaft (4) is fixed with the inner wall of the rotary drainage cylinder (7) through a linkage column (44), the part of the driving sleeve (5) between the fixed drainage cylinder (8) and the driving motor (3) is conical, and the top of the driving sleeve is provided with an exhaust pipe (52).

6. A high efficiency progressive gas-liquid separation device as recited in claim 5, wherein: the outer wall of the driving sleeve (5) is fixed with a hemispherical rubber block (53), and the inner wall of the fixed drainage cylinder (8) is fixed with a striking rod (82) matched with the hemispherical rubber block (53).