CN215539152U - Novel cyclone plate gas-liquid separator - Google Patents

Abstract

The utility model belongs to the technical field of gas-liquid separation, and particularly relates to a novel cyclone plate gas-liquid separator which comprises a tank body, wherein a cyclone assembly for gas-liquid separation is arranged in the tank body, porous sponge beneficial to air circulation is filled in a steel wire mesh groove, a pore block matched with the steel wire mesh groove is arranged on the top surface of the pore plate, and a lifting plate used for extruding the cyclone assembly is arranged below the cyclone assembly; stir inside gas-liquid and form the cyclone in jar internal portion when the whirl subassembly rotates behind the gas-liquid mixture of pouring into, liquid wherein is adsorbed by the inside porous sponge of filling when the gas-liquid passes through the steel wire gauze groove, filtration efficiency has been increased, whirl subassembly below is equipped with and is used for carrying out the extruded lifter plate to it, the pore piece that is equipped with on the pore plate can extrude the inside porous sponge of steel wire gauze groove at the upward movement in-process, can pass through a whirl subassembly again when the cyclone is from jar body bottom upward movement, thereby carry out secondary filter and promote the effect of water-gas separation.

Description

Novel cyclone plate gas-liquid separator

Technical Field

The utility model belongs to the technical field of gas-liquid separation, and particularly relates to a novel cyclone plate gas-liquid separator.

Background

The cyclone plate is a jet-type tower plate consisting of a middle blind plate and 24 windmill-blade-shaped cyclone blades which are distributed on the periphery, and the gas-liquid separator adopts the principles of centrifugal separation and wire mesh filtration to realize the 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.

SUMMERY OF THE UTILITY MODEL

Most of the cyclone flow gas-liquid separators used at present rotate to stir gas and liquid inside the cyclone flow plate fan blades to form cyclone, and under the action of gravity and centrifugal force, the centrifugal force borne by the liquid is larger than that of the gas, so that the liquid can be thrown to the inner wall of the separator and then drips.

The utility model provides the following technical scheme: the novel gas-liquid separation tank comprises a tank body, the internal portion of jar is equipped with the whirl subassembly that is used for gas-liquid separation, the whirl subassembly includes whirl flabellum, steel sheet and pore board, the steel wire net groove has been seted up to the steel sheet is inside, the steel wire net inslot intussuseption is favorable to the porous sponge of circulation of air, porous sponge below is equipped with the elasticity screen panel, the pore board top surface be equipped with steel wire net groove assorted pore piece, whirl subassembly below is equipped with and is used for carrying out the extruded lifter plate to it.

The gas-liquid filling device comprises a tank body, wherein a gas inlet for filling gas and liquid is formed in the side wall of the inner portion of the tank body, and a gas outlet is formed in the top of the inner wall of the tank body.

The cooling tank is characterized in that a cooling cavity is arranged inside the tank body, and a heat insulation layer used for heat insulation is wrapped outside the cooling cavity.

Wherein, the cooling chamber is internally provided with a water inlet pipe for filling cooling liquid and a drain pipe for discharging the cooling liquid.

The central position of the bottom of the tank body is provided with a driving rod, the rotational flow component is fixedly connected with the driving rod, and the driving rod is provided with a chute for the pore plate to slide up and down.

The lifting plate and the pore plate in contact with the lifting plate are inclined planes, the surface of the lifting plate is provided with a ball, and the lifting plate is lifted through an electric push rod.

The outer side of the bottom of the tank body is hinged with a sealing door, and the bottom of the tank body is provided with a water outlet hole for draining water.

Wherein, jar internal wall bottom surface is arc arch, and V-arrangement water drainage tank has all been seted up at both ends about the bottom surface.

The utility model has the beneficial effects that: when gas-liquid mixed gas is filled in, the cyclone assembly rotates to stir internal gas-liquid to form cyclone in the tank body, when the gas-liquid passes through the steel wire mesh groove, the gas-liquid contacts with the internally filled porous sponge, the porous sponge is provided with a plurality of air holes for the gas-liquid to pass through, the gas-liquid is adsorbed when colliding with the porous sponge in the high-speed rotation process, the filtering efficiency is increased, a lifting plate for extruding the gas-liquid is arranged below the cyclone assembly, the lifting plate drives the pore plate to move upwards when moving upwards, the pore block arranged on the pore plate can extrude the porous sponge in the steel wire mesh groove in the upwards moving process, the water adsorbed in the porous sponge can be extruded after the porous sponge is extruded and deformed, the water can be thrown to the inner wall of the tank body and slide down due to the centrifugal force in the rotation process, and can pass through the cyclone assembly once when the cyclone moves upwards from the bottom of the tank body, thereby carrying out secondary filtration and improving the effect of water-gas separation.

The parts of the device not involved are the same as or can be implemented using prior art.

Drawings

FIG. 1 is a schematic cross-sectional view of the present invention;

FIG. 2 is a schematic view of the lifter plate extrusion of the present invention;

FIG. 3 is a schematic top view of the cyclone assembly of the present invention;

FIG. 4 is a schematic side sectional view of the swirler assembly of the present invention;

FIG. 5 is a side view cross-sectional extrusion of the swirler assembly of the present invention;

in the figure: 1. a tank body; 2. a swirl assembly; 3. a lifting plate; 4. a drive rod; 11. a cooling chamber; 12. a heat-insulating layer; 13. an air inlet; 14. an exhaust port; 15. a water inlet pipe; 16. a drain pipe; 17. a sealing door; 18. a water outlet hole; 21. a swirl fan blade; 22. a steel plate; 23. a steel wire mesh groove; 24. a porous sponge; 25. an elastic mesh enclosure; 26. a pore block; 27. a pore plate; 31. a ball bearing; 41. a chute.

Detailed Description

Referring to fig. 1-4, the present invention provides the following technical solutions: including a jar body 1, jar internal portion is equipped with the whirl subassembly 2 that is used for gas-liquid separation, whirl subassembly 2 includes whirl flabellum 21, steel sheet 22 and pore plate 27, steel wire mesh groove 23 has been seted up to steel sheet 22 inside, the intussuseption of steel wire mesh groove 23 is filled the porous sponge 24 that is favorable to the circulation of air, porous sponge 24 below is equipped with elasticity screen panel 25, pore plate 27 top surface be equipped with steel wire mesh groove 23 assorted pore piece 26, whirl subassembly 2 below is equipped with and is used for carrying out extruded lifter plate 3 to it.

In this embodiment: the cyclone assembly 2 for gas-liquid separation is arranged inside the tank body 1, when the cyclone assembly 2 rotates after gas-liquid mixed gas is poured, gas-liquid inside is stirred to form cyclone inside the tank body 1, a steel plate 22 is arranged below the cyclone fan blade 21, a steel wire mesh groove 23 is formed inside the steel plate 22, when the gas-liquid passes through the steel wire mesh groove 23, the gas-liquid contacts with a porous sponge 24 filled inside, a plurality of air holes are formed in the porous sponge 24, the gas-liquid can conveniently pass through the porous sponge 24, the gas-liquid is adsorbed when colliding with the porous sponge 24 in the high-speed rotation process, the filtering efficiency is increased, an elastic mesh cover 25 is arranged below the porous sponge 24 and used for preventing the porous sponge 24 from falling and deforming after being extruded, a pore block 26 capable of being restored to match with the steel wire mesh groove 23 is arranged on the top surface of a pore plate 27 and used for extruding the porous sponge 24, and a lifting plate 3 used for extruding the cyclone assembly 2 is arranged below, the lifter plate 3 drives the pore plate 27 to move upwards when moving upwards, the pore block 26 arranged on the pore plate 27 can extrude the porous sponge 24 inside the steel wire mesh groove 23 in the upwards moving process, the porous sponge 24 can extrude the water absorbed therein after being extruded and deformed, the water can be thrown to the inner wall of the tank body 1 and can slide off due to the centrifugal force in the rotating process, and the cyclone can pass through the primary cyclone assembly 2 when moving upwards from the bottom of the tank body 1, so that the water-gas separation efficiency can be improved by secondary filtration.

The side wall of the inner part of the tank body 1 is provided with an air inlet 13 for filling gas and liquid, and the top of the inner wall of the tank body 1 is provided with an air outlet 14; the air inlet 13 is used for filling gas-liquid mixed gas, and the air outlet 14 is used for discharging gas after water vapor filtration and separation.

A cooling cavity 11 is arranged in the tank body 1, and a heat-insulating layer 12 for heat insulation is wrapped outside the cooling cavity 11; the cooling chamber 11 that jar body 1 inside was equipped with wherein can pour into the coolant liquid for make the moisture in the aqueous vapor condense fast with higher speed and filter, heat preservation 12 is used for avoiding outside temperature to its influence increase its cooling chamber 11's cooling effect, and when the gas that needs to use does not need the cooling for high temperature gas, because cooling chamber 11 is the double-wall and outside parcel has the heat preservation effect of heat preservation 12 multiplicable high temperature gas.

A water inlet pipe 15 for filling cooling liquid and a drain pipe 16 for discharging the cooling liquid are arranged in the cooling cavity 11; the inlet pipe 15 is used for filling the cooling liquid, and the outlet pipe 16 is used for discharging ineffective cooling liquid when the temperature of the cooling liquid rises.

A driving rod 4 is arranged at the center of the bottom of the tank body 1, the rotational flow component 2 is fixedly connected with the driving rod 4, and a chute 41 for the pore plate 27 to slide up and down is formed in the driving rod 4; the drive rod 4 drives the rotational flow component 2 to rotate, and the sliding groove 41 formed in the drive rod 4 is used for limiting the pore plate 27 and sliding up and down.

The lifting plate 3 and the pore plate 27 contacted with the lifting plate are both inclined planes, the surface of the lifting plate 3 is provided with a ball 31, and the lifting plate 3 is lifted by an electric push rod; the contact surfaces of the lifting plate 3 and the aperture plate 27 are inclined surfaces for increasing the contact area, and the balls 31 are used for reducing the friction generated when the lifting plate 3 contacts the aperture plate 27 rotating at a high speed.

A sealing door 17 is hinged to the outer side of the bottom of the tank body 1, and a water outlet hole 18 for draining water is formed in the bottom of the tank body 1; sealing door 17 is convenient for detect and maintain inside driving motor, and apopore 18 makes liquid recovery more convenient for the liquid that produces after being used for discharging gas-liquid separation.

The bottom surface of the inner wall of the tank body 1 is an arc-shaped bulge, and the left end and the right end of the bottom surface are both provided with V-shaped drainage grooves; the arc-shaped bulge on the bottom surface of the inner wall of the tank body 1 prevents liquid from being accumulated at the bottom of the inner wall of the tank body 1, the V-shaped water drainage grooves formed in the left end and the right end of the bottom surface of the tank body 1 are used for draining water generated by separation, and the driving motor is placed in the middle of the two V-shaped water drainage grooves.

The working principle and the using process of the utility model are as follows: the side wall of the inner part of the tank body 1 is provided with an air inlet 13 filled with gas-liquid mixed gas, the top of the inner wall of the tank body 1 is provided with an air outlet 14, the inner part of the tank body 1 is provided with a cooling cavity 11 in which cooling liquid can be filled for rapidly condensing and filtering water in water vapor, the outer part of the cooling cavity 11 is wrapped with a heat preservation layer 12 for heat preservation to avoid the influence of the external temperature on the cooling cavity 11 and increase the cooling effect of the cooling cavity 11, the inner part of the cooling cavity 11 is provided with a water inlet pipe 15 for filling the cooling liquid and a drain pipe 16 for discharging the cooling liquid with the cooling effect, the inner part of the tank body 1 is provided with a rotational flow component 2 for gas-liquid separation, when the rotational flow component 2 rotates after the gas-liquid mixed gas is filled, the gas is stirred to form a cyclone in the tank body 1, a steel plate 22 is arranged below the rotational flow fan blade 21, a steel wire mesh groove 23 is arranged in the steel plate 22, when the gas passes through the steel wire mesh groove 23, the porous sponge 24 filled in the inner part is contacted with the gas-liquid, the porous sponge 24 is provided with a plurality of air holes for facilitating the penetration of air and liquid, the air and liquid are adsorbed when colliding with the porous sponge 24 in the high-speed rotation process, the filtering efficiency is increased, an elastic mesh cover 25 is arranged below the porous sponge 24 for preventing the porous sponge 24 from falling off and being capable of recovering deformation after being extruded, a pore block 26 matched with the steel wire mesh groove 23 is arranged on the top surface of the pore plate 27 for extruding the porous sponge 24, a lifting plate 3 for extruding the porous sponge is arranged below the rotational flow component 2, the lifting plate 3 and the pore plate 27 in contact with the lifting plate 3 are inclined planes for increasing the contact area, the surface of the lifting plate 3 is provided with balls 31, the balls 31 are used for reducing the friction generated when the lifting plate 3 contacts with the pore plate 27 rotating at high speed, the lifting plate 3 is lifted through an electric push rod, the pore plate 27 is driven to move upwards when the lifting plate 3 moves upwards, the pore block 26 arranged on the pore plate 27 can extrude the porous sponge 24 in the steel wire mesh groove 23 in the upward moving process, when the porous sponge 24 is extruded and deformed, the adsorbed water can be extruded out, the water can be thrown to the inner wall of the tank body 1 and slide off due to the centrifugal force in the rotating process, when the cyclone moves upward from the bottom of the tank body 1, the water can pass through the primary cyclone assembly 2 for secondary filtration to improve the effect of water-gas separation, the driving rod 4 is arranged at the center of the bottom of the tank body 1, the cyclone assembly 2 is fixedly connected with the driving rod 4, the driving rod 4 drives the cyclone assembly 2 to rotate, the sliding groove 41 arranged on the driving rod 4 is used for limiting the pore plate 27 and sliding up and down, the bottom surface of the inner wall of the tank body 1 is an arc-shaped bulge to prevent liquid from being accumulated at the bottom of the inner wall of the tank body 1, and the left and right bottom surfaces are both provided with V-shaped drainage grooves for discharging water generated by separation, and two V type water drainage tank intermediate positions are in order to place driving motor, and 1 bottom outside of the jar body articulates there is sealing door 17 to be convenient for maintain inside driving motor, and 1 bottom of the jar body is equipped with apopore 18 and is used for the liquid that the discharge separation produced.

Claims (8)

1. A novel cyclone plate gas-liquid separator is characterized in that: the novel gas-liquid separation tank comprises a tank body, the internal portion of jar is equipped with the whirl subassembly that is used for gas-liquid separation, the whirl subassembly includes whirl flabellum, steel sheet and pore board, the steel wire net groove has been seted up to the steel sheet is inside, the steel wire net inslot intussuseption is favorable to the porous sponge of circulation of air, porous sponge below is equipped with the elasticity screen panel, the pore board top surface be equipped with steel wire net groove assorted pore piece, whirl subassembly below is equipped with and is used for carrying out the extruded lifter plate to it.

2. The novel swirl plate gas-liquid separator of claim 1, wherein: the side wall of the inner part of the tank body is provided with an air inlet for filling air and liquid, and the top of the inner wall of the tank body is provided with an air outlet.

3. The novel swirl plate gas-liquid separator of claim 1, wherein: the internal portion of jar is equipped with the cooling chamber, the outside parcel one deck heat preservation that is used for heat preservation of cooling chamber.

4. The novel swirl plate gas-liquid separator of claim 3, wherein: and a water inlet pipe for filling cooling liquid and a drain pipe for discharging the cooling liquid are arranged in the cooling cavity.

5. The novel swirl plate gas-liquid separator of claim 1, wherein: the central position of the bottom of the tank body is provided with a driving rod, the rotational flow component is fixedly connected with the driving rod, and the driving rod is provided with a chute for the pore plate to slide up and down.

6. The novel swirl plate gas-liquid separator of claim 1, wherein: the lifting plate and the pore plate contacted with the lifting plate are inclined planes, the surface of the lifting plate is provided with a ball, and the lifting plate is lifted through an electric push rod.

7. The novel swirl plate gas-liquid separator of claim 1, wherein: the outer side of the bottom of the tank body is hinged with a sealing door, and the bottom of the tank body is provided with a water outlet hole for draining water.

8. The novel swirl plate gas-liquid separator of claim 1, wherein: jar internal wall bottom surface is arc arch, and V-arrangement water drainage tank has all been seted up at both ends about the bottom surface.

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