CN112843933A - Gas-liquid mixing unit of dust removal system - Google Patents

Abstract

A gas-liquid mixing unit of a dust removal system comprises a water bath filtering device and a gas-liquid differentiation device; the water bath filtering device comprises a plurality of water bath filtering boxes which are arranged in parallel at intervals, the gas-liquid differentiation device comprises a plurality of groove-shaped box covers which are arranged in parallel at intervals and are provided with top walls and box cover side walls at two sides, and gas-liquid differentiation holes are formed in the box cover side walls; each two adjacent water bath filter boxes are covered with a groove type box cover in a buckling manner, and the side walls of the box covers at two sides of the groove type box cover are respectively inserted into the two adjacent water bath filter boxes, so that the water bath filter boxes and the groove type box cover form a structure in which rings are buckled with each other; an overflow port is formed between the upper edge of the side wall of the box body of the water bath filter box and the top wall, and the water bath filter device or the gas-liquid differentiation device is transversely connected. The invention installs at least one layer of gas-liquid mixing unit or a plurality of layers of gas-liquid mixing units in the flue to thoroughly adsorb dust in the gas. The gas discharged into the air is cleaner. The invention has simple structure, convenient processing and high working efficiency.

Description

Gas-liquid mixing unit of dust removal system

Technical Field

The invention relates to a gas-liquid mixing unit of a dust removal system, and belongs to the field of industrial environment-friendly dust removal.

Background

Along with the incessant emergence of multiple high-efficient wet dust collector, high-efficient wet dust collector utilizes screen pipe water bath filter equipment dust removal effect good, current metallurgical industry atmosphere pollution source has obtained fine control processing, the gas that purifies among the dust pelletizing system all finally discharges in the atmosphere through dehydration discharging equipment, however, still there is the problem that contains a small amount of steam and a small amount of dust owing to the gas that discharges in the atmosphere, this problem can not thoroughly be solved to current dehydration discharging equipment, the urgent need for a gas-liquid mixture unit who installs the high efficiency dust removal in purifying discharging equipment, adsorb dust and steam in the discharging gas once more at the stage of discharging, solve the gas emission's purification problem.

Disclosure of Invention

The invention provides a gas-liquid mixing unit of a dust removal system, and aims to solve the technical problem of adsorbing dust in discharged gas again in a discharge stage.

The technical scheme of the invention is as follows:

a gas-liquid mixing unit of a dust removal system comprises a water bath filtering device and a gas-liquid differentiation device; the water bath filtering device is characterized by comprising a plurality of water bath filtering boxes which are arranged in parallel at intervals, wherein the water bath filtering boxes are box bodies with upper parts open and peripheral and bottom surfaces closed and are provided with accommodating cavities; the gas-liquid differentiation device comprises a plurality of groove-shaped box covers which are arranged in parallel and at intervals and are provided with top walls and box cover side walls at two sides, and the box cover side walls are provided with densely arranged hollow through gas-liquid differentiation holes; each two adjacent water bath filter boxes are covered with one groove type box cover in a buckling manner, and the side walls of the box covers at two sides of the groove type box cover are respectively inserted into the two adjacent water bath filter boxes, so that the water bath filter boxes and the groove type box covers form a structure in which rings are buckled with each other; the top wall of the groove-shaped box cover is higher than the upper edge of the side wall of the box body of the water bath filter box; the side walls of the two box covers are inserted into each water bath filter box, and three differentiation chambers are separated from the inside of the box body of each water bath filter box; an overflow port is formed between the upper edge of the side wall of the box body of the water bath filter box and the top wall; a gap between two adjacent groove-shaped box covers, namely the differentiation cavity positioned in the middle of the water bath filter box, forms a liquid inlet; (ii) a The water bath filtering device or the gas-liquid differentiation device is transversely connected.

Preferably, the water bath filter box and the groove-shaped box cover are of rectangular structures.

Preferably, a plurality of the water bath filter boxes or the groove-shaped box covers are arranged at equal intervals.

Preferably, the water bath filter box and the groove-shaped box cover are embedded in length, namely two ends of the water bath filter box are arranged in a contact mode.

Preferably, the side wall of each water bath filter box positioned at the periphery of the water bath filter device is connected with a wall plate in a sealing manner to form a side coaming of the gas-liquid mixing unit.

Preferably, a strip-shaped support frame is arranged in the groove-shaped box cover and is a groove-shaped support frame with a downward opening, the support frame is formed by respectively welding two ends of a transverse lath with a screw hole at the top part and vertically arranging laths extending downwards, the support frame is supported and installed in the groove-shaped box cover, and the transverse lath is abutted against the top wall of the groove-shaped box cover and is in threaded connection with the top wall of the groove-shaped box cover after penetrating through the screw hole of the transverse lath and a through hole of the top wall of the groove-shaped; the vertical laths are respectively inserted into two adjacent water bath filter boxes to be supported at the box bottom and welded on the box body side walls of the two adjacent water bath filter boxes to form transverse connection; a water passing gap is reserved between the bottom edge of the side wall of the box cover and the box bottom of the water bath filter box; at least 2 support frames are arranged in each groove type box cover, and the support frames are transversely arranged in a row along the gas-liquid differentiation device.

Preferably, the gas-liquid separation hole is immersed in water in the water bath filter box.

Preferably, the transverse connection is that the water bath filtering device or the gas-liquid differentiation device is connected into a whole by welding connecting plates along the transverse direction, and the connecting plates are positioned at two ends of each water bath filtering box or the gas-liquid differentiation device.

The invention comprises a smoke dust discharge channel of a gas-liquid mixing unit of a dust removal system, which comprises a closed flue, an air inlet and the gas-liquid mixing unit, and is characterized in that one side surface of the flue is the air inlet, the bottom of the air inlet is hermetically connected with at least one gas-liquid mixing unit, and the gas-liquid mixing unit is communicated with the flue; a spraying device is arranged at the upper part of the flue or an overflow water receiving plate is arranged at the top of the flue; and gas is mixed with spray water through the air inlet and the flue and then enters the gas-liquid mixing unit 1, the filtered gas is discharged from an overflow port of a water bath filter box of the gas-liquid mixing unit, and redundant liquid is discharged from an overflow port of the water bath filter box of the gas-liquid mixing unit.

The smoke and dust discharge channel comprises a gas-liquid mixing unit of the dust removal system, wherein the edge of the front end of each overflow-shaped water receiving plate is upwards turned to form a transverse trap, the edge of the rear end of each overflow-shaped water receiving plate is downwards turned to form a transverse partition plate, the partition plates are inserted into the traps between two adjacent overflow-shaped water receiving plates to seal through water sealing, and a trap overflow port is formed between each trap and the adjacent water receiving plate.

The invention has the following effects:

the gas-liquid mixing unit has the advantages of simple structure, convenient processing, more uniform gas-liquid mixing and differentiation, less resistance, better treatment effect, more energy conservation and high efficiency. The invention installs at least one layer of gas-liquid mixing unit in the flue to further fully adsorb the dust in the gas, and can thoroughly adsorb the dust in the gas by installing the upper and lower layers of gas-liquid mixing units. The invention realizes that the gas discharged into the air is cleaner.

Description of the drawings:

FIG. 1 is a schematic top view of the structure of a gas-liquid mixing unit of the present invention,

figure 2 is a schematic cross-sectional view D-D of figure 1,

figure 3 is a schematic view of the side holes of the trough-shaped box cover in figure 1,

figure 4 is a schematic structural view of the support frame arranged in the groove type box cover of the invention,

figure 5 is a schematic left side view of figure 4,

figure 6 is a schematic top view of figure 4,

FIG. 7 is a schematic view showing the connection between the support frame arranged in the trough-shaped box cover and the water bath filter box and the trough-shaped box cover,

FIG. 8 is a longitudinal sectional view of the smoke discharging passage and a schematic view of the gas-liquid separation holes densely arranged on the side wall of the box cover,

figure 9 is a schematic cross-sectional view B-B of figure 8,

figure 10 is a schematic cross-sectional view a-a of figure 8,

FIG. 11 is a schematic view showing a connection structure of the purified exhaust apparatus of the present invention to a dust removing system,

figure 12 is a schematic cross-sectional view a-a of the dewatering box of figure 11,

figure 13 is a schematic cross-sectional view of figure 11 taken from the top B-B,

figure 14 is a schematic plan view of a dewatering plate grid construction,

FIG. 15 is a schematic top view of FIG. 14, a schematic top view of a dewatering plate grid formed by Z-shaped dewatering plates,

FIG. 16 is a schematic top view of FIG. 14, showing a dewatering plate grid having dewatering plates formed by grid plates

Figure 17 is a schematic view of a dewatering plate in the form of a grid plate,

figure 18 is a schematic top view of figure 17,

description of the figure numbering:

the device comprises a gas-liquid mixing unit 1, a water bath filter box 11, a groove-shaped box cover 12, a gas-liquid differentiation hole 121, a top wall 122, a box cover side wall 123, a liquid inlet 124, a differentiation chamber 13, a water bath filter box overflow port 14, a side wall plate 15, a support frame 16, a transverse lath 161, a vertical lath 162, a smoke discharge channel 2, a flue 21, an air inlet 22, a spraying device 23, an overflow-shaped water receiving plate 24, a trap 241, a partition plate 242, a trap overflow port 243, a dewatering box 3, a dewatering plate grating 31, a dewatering plate 32, a lath 321, a gap 322, a gap 323, a water receiving hopper 4, a water outlet 5 and a circulating water; the gas flows to A, the water flows to B, the dust removal system equipment Q and the dust removal system equipment purify a gas discharge pipeline S.

Detailed Description

Referring to fig. 1 to 3, the gas-liquid mixing unit of the present invention includes a water bath filtering device, a gas-liquid separating device; the water bath filtering device comprises a plurality of water bath filtering boxes 11 which are arranged in parallel at intervals, wherein the water bath filtering boxes are box bodies with upper parts open and peripheral and bottom surfaces closed and are provided with accommodating cavities; the gas-liquid differentiation device comprises a plurality of groove-shaped box covers 12 which are arranged in parallel and at intervals and are provided with top walls 122 and box cover side walls 123 at two sides, and the box cover side walls are provided with densely arranged hollow through gas-liquid differentiation holes 121; each two adjacent water bath filter boxes 11 are covered with one groove-shaped box cover 12 in a buckling manner, and the box cover side walls 123 on the two sides of the groove-shaped box cover are respectively inserted into the two adjacent water bath filter boxes 11, so that the water bath filter boxes and the groove-shaped box cover form a structure in which the water bath filter boxes and the groove-shaped box cover are buckled with each other in a ring manner; the top wall 122 of the groove-shaped box cover 12 is higher than the upper edge of the side wall of the water bath filter box 11; the two box cover side walls are inserted into each water bath filter box, and three differentiation chambers 13 are separated from the box body of each water bath filter box; an overflow port 14 is formed between the upper edge of the side wall of the box body of the water bath filter box and the top wall 122; a liquid inlet 124 is formed by a gap between two adjacent groove-shaped box covers 12, namely the differentiation cavity in the middle of the water bath filter box; (ii) a The water bath filtering device or the gas-liquid differentiation device is transversely connected.

Preferably, the water bath filter box and the trough box cover are rectangular structures; a plurality of the water bath filter boxes or the groove-shaped box covers are arranged at equal intervals; the water bath filter box and the groove-shaped box cover are embedded in length, namely two ends of the water bath filter box and the groove-shaped box cover are arranged in a contact mode.

Preferably, the side walls of the water bath filter boxes around the water bath filter device are connected with wall plates in a sealing manner to form side wall plates 15 of the gas-liquid mixing unit.

Referring to fig. 4-7, preferably, a strip-shaped support frame 16 is arranged in the groove-shaped box cover, and is a groove-shaped support frame with a downward opening, the support frame is formed by welding two ends of a transverse lath 161 with a screw hole at the top part respectively with a vertical lath 162 extending downwards, the support frame is supported and installed inside the groove-shaped box cover, and the transverse lath 161 abuts against the top wall of the groove-shaped box cover and is screwed after passing through the screw hole of the transverse lath and a through hole of the top wall of the groove-shaped box cover through a connecting bolt; the vertical laths are respectively inserted into two adjacent water bath filter boxes to be supported at the box bottom and welded on the box body side walls of the two adjacent water bath filter boxes to form transverse connection; a water gap is reserved between the bottom edge of the side wall 123 of the box cover and the box bottom of the water bath filter box; at least 2 support frames are arranged in each groove type box cover, and the support frames are transversely arranged in a row along the gas-liquid differentiation device. The support frame 16 connects the water bath filtering device and the gas-liquid differentiation device into a whole.

Preferably, the gas-liquid differentiation holes 121 are immersed in water in the water bath filter box, as shown in fig. 3, so that gas-water differentiation is more uniform, and dust adsorption is more thorough.

Preferably, the transverse connection is that the water bath filtering device or the gas-liquid differentiation device is connected into a whole by welding connecting plates along the transverse direction, and the connecting plates are positioned at two ends of each water bath filtering box or the gas-liquid differentiation device, and refer to the side coaming 15 in fig. 1.

Referring to fig. 8-10, the smoke exhaust channel 2 of the present invention includes a closed flue 21, an air inlet 22, and a gas-liquid mixing unit 1, wherein one side of the flue 21 is the air inlet 22, and the bottom of the flue is hermetically connected to at least one gas-liquid mixing unit 1; the gas-liquid mixing unit is communicated with the flue; a spraying device 23 is arranged at the upper part of the flue or an overflow water receiving plate is arranged at the top of the flue; the gas is mixed with spray water through the air inlet and the flue and then enters the gas-liquid mixing unit 1, the filtered gas is discharged from an overflow port 14 of a water bath filter box of the gas-liquid mixing unit, and redundant liquid is discharged from the overflow port 14 of the water bath filter box of the gas-liquid mixing unit; the air inlet 22 is arranged on the wall of one side of the dewatering box 3. The smoke discharge channel 2 can also be connected with a plurality of gas-liquid mixing units 1 in an up-and-down stacking manner to fully adsorb dust, and spray water (not shown in the figure) can be recycled up and down.

Referring to fig. 11, the purifying and discharging device of a dust removing system for installing the gas-liquid mixing unit and the smoke discharging channel 2 of the dust removing system of the present invention comprises a dewatering box 3, wherein the dewatering box comprises a dewatering plate 32, the smoke discharging channel 2, a water receiving hopper 4 and a water discharging opening 5; at least one layer of dewatering plate grating 31 is arranged on the top and the side wall of the dewatering box 3; the dewatering box in fig. 11-13 is provided with three layers of dewatering plate grilles 31, wherein two layers are used as box wall plates, and one layer of dewatering plate grilles 31 is respectively arranged at two sides of the smoke dust discharge channel 2, as shown in fig. 13 and 14; the dehydration plate grid is formed by connecting a plurality of dehydration plates 32 which are obliquely arranged and densely arranged at intervals into a whole through transverse connection, and a gas exhaust gap 323 is formed between the dehydration plates 32; at least one smoke dust discharge channel 2 is arranged in the dewatering box 3; the smoke and dust discharge channel is connected with a purified gas discharge pipeline S of the dust removal system; the bottom of the dewatering box is provided with a water receiving bucket 4, and the water receiving bucket is provided with a water outlet 5; the water receiving hopper 4 is provided with a slope-shaped bottom plate which is inclined and sunk towards the direction of the water receiving port so as to be beneficial to draining;

referring to fig. 11, a plurality of smoke and dust discharging channels 2 are arranged at intervals up and down and stacked, and three smoke and dust discharging channels 2 are arranged in fig. 11 and connected with a purified gas discharging pipeline S of a dust removing system; a spraying device 23 is arranged at the top of the smoke and dust discharging channel at the first layer, an overflow water receiving plate 24 is arranged on the top wall of the smoke and dust discharging channel at the lower layer of the first layer, and the smoke and dust discharging channel at the upper layer receives water discharged from an overflow port of a water bath filter box of the gas-liquid mixing unit; the edge of the front end of each overflow-shaped water receiving plate 24 is upwards folded to form a transverse trap 241, the edge of the rear end of each overflow-shaped water receiving plate is downwards folded to form a transverse partition plate 242, the partition plates are inserted into the traps between two adjacent overflow-shaped water receiving plates to seal water, a trap overflow port 243 is formed between each trap and the adjacent water receiving plates, water overflowing from the trap overflow port is distributed and mixed with gas to enter the gas-liquid mixing unit at the lower part, and so on, the top wall of each smoke discharge channel 2 at the lower layer is provided with an overflow-shaped water receiving plate 24 structure to receive overflow water at the upper layer, and water resources are saved for cyclic utilization.

Preferably, the dewatering plates 32 are slats with a Z-shaped cross-section, see fig. 15.

Preferably, the dewatering plate 32 is a grid plate, the grid plate is formed by a plurality of slats 321 with equal width and length, which are parallel to each other, stacked at intervals and transversely connected into an integral structure, and the grid plate body is provided with a plurality of parallel through exhaust gaps 322, see fig. 16-18.

The following examples of the invention are further illustrated as follows:

referring to fig. 11-13, which are specific application examples of the present invention, the filtered gas treated by the dust removal system equipment Q has a large water content and a small amount of dust, and the filtered gas enters the plurality of smoke discharge channels 2 of the dehydration box 3 of the purification and discharge device of the present invention through the purified gas discharge pipeline S, the first layer of the filtered gas entering the smoke discharge channels 2 is mixed with the shower water, and then enters the gas-liquid mixing unit 1, after gas-liquid differentiation, mixing, filtering and adsorption again, the dust in the filtered gas is fully adsorbed, finally, the clean gas is changed into clean gas and discharged from the overflow port at the bottom of the gas-liquid mixing unit, after entering the box body of the dehydration box of the purification and discharge device with a large space, the ascending speed of the clean gas is greatly reduced, preferably lower than 2m/S due to the large cross-sectional area box body, and after first-stage dehydration by the first-layer dehydration plate grid during the ascending, and continuously rising and diffusing, and then carrying out secondary dehydration on the second layer of dehydration plate grids, and so on, wherein according to actual needs, a plurality of layers of dehydration plate grids can be arranged for dehydration, and finally the dehydration is discharged into the air.

The spray water mixed gas of the top smoke and dust discharge channel 2 enters the gas-liquid mixing unit at the bottom of the spray water mixed gas, and then flows out from an overflow port of the gas-liquid mixing unit, and enters an overflow-shaped water receiving plate of the lower smoke and dust discharge channel, the water overflowing from the overflow port of the trap is sprayed to the gas-liquid mixing unit at the lower part to be further mixed with the filtered gas processed by the dust removal system equipment, the gas-liquid mixing unit performs gas-liquid differentiation again, and then is mixed, filtered and adsorbed with dust in the filtered gas, and then becomes clean gas to be discharged from the overflow port at the bottom of the gas-liquid mixing unit, and the clean gas enters a dehydration box body of a purification discharge device in a larger space and is dehydrated and discharged, so on, the dehydration box can be provided with a plurality of smoke and dust discharge channels 2. Finally, the filtered sewage flows into a reservoir through a water receiving hopper and a water outlet at the bottom of the dewatering box for sedimentation and recycling. The dehydration box can replace the existing chimney and prevent smoke dust from being discharged into the high altitude. The gas-liquid mixing unit structure of the invention has more uniform mixing, less resistance, better treatment effect and more energy saving. The gas-liquid mixing unit can be used by combining one or more units according to the amount of dust and gas.

Claims (10)

1. A gas-liquid mixing unit of a dust removal system comprises a water bath filtering device and a gas-liquid differentiation device; the water bath filtering device is characterized by comprising a plurality of water bath filtering boxes (11) which are arranged in parallel at intervals, wherein the water bath filtering boxes are box bodies with upper parts open and containing cavities which are sealed at the periphery and the bottom; the gas-liquid differentiation device comprises a plurality of groove-shaped box covers (12) which are arranged in parallel at intervals and are provided with top walls (122) and box cover side walls (123) at two sides, and the box cover side walls are provided with densely arranged hollow through gas-liquid differentiation holes (121); each two adjacent water bath filter boxes (11) are covered with one groove-shaped box cover (12) in a buckling manner, and the box cover side walls (123) on the two sides of the groove-shaped box cover are respectively inserted into the two adjacent water bath filter boxes (11), so that the water bath filter boxes and the groove-shaped box covers form a structure in which the water bath filter boxes and the groove-shaped box covers are buckled with each other in a ring manner; the top wall (122) of the groove-shaped box cover (12) is higher than the upper edge of the side wall of the box body of the water bath filter box (11); the two side walls of the box cover are inserted into each water bath filter box, and three differentiation chambers (13) are separated from the box body of each water bath filter box; an overflow port (14) is formed between the upper edge of the side wall of the box body of the water bath filter box and the top wall (122); a liquid inlet (124) is formed by a gap between two adjacent groove type box covers (12), namely the differentiation cavity chamber positioned in the middle of the water bath filter box; (ii) a The water bath filtering device and/or the gas-liquid differentiation device are transversely connected.

2. The gas-liquid mixing unit of a dedusting system as set forth in claim 1, wherein the water bath filter box and the tank box cover are rectangular.

3. The gas-liquid mixing unit of a dedusting system as set forth in claim 2, wherein a plurality of the water bath filter cassettes or the tank box covers are arranged at equal intervals.

4. The gas-liquid mixing unit of a dedusting system as set forth in claim 1, wherein the water bath filter box is embedded with the length of the trough box cover, namely, the two ends of the water bath filter box are in contact with each other.

5. The gas-liquid mixing unit of a dedusting system as set forth in claim 1, wherein the side wall of each water bath filter box located at the periphery of the water bath filter device is connected with a wall plate in a sealing manner to form a side wall plate (15) of the gas-liquid mixing unit.

6. The gas-liquid mixing unit of a dust-removing system as claimed in claim 1, wherein a bar-shaped support is arranged in the trough-type box cover, the bar-shaped support is a trough-type support with a downward opening, the support is formed by welding two ends of a transverse lath (161) with a screw hole at the top part with a vertical lath (162) extending downwards, the support is supported and installed in the trough-type box cover, the transverse lath (161) abuts against the top wall of the trough-type box cover, and is screwed after passing through the screw hole of the transverse lath and a through hole of the top wall of the trough-type box cover through a connecting bolt; the vertical laths are respectively inserted into two adjacent water bath filter boxes to be supported at the box bottom and welded on the box body side walls of the two adjacent water bath filter boxes to form transverse connection; a water passing gap is reserved between the bottom edge of the side wall (123) of the box cover and the box bottom of the water bath filtering box; at least 2 support frames are arranged in each groove type box cover, and the support frames are transversely arranged in a row along the gas-liquid differentiation device.

7. The gas-liquid mixing unit of a dedusting system as set forth in claim 1, wherein the gas-liquid separating hole is immersed in water in the water-bath filter cartridge.

8. The gas-liquid mixing unit of a dedusting system as set forth in claim 1, wherein the transverse connection is such that the water bath filtering device or the gas-liquid separating device are connected into a whole by welding connection plates along the transverse direction, the connection plates being located at both ends of each of the water bath filtering box or the gas-liquid separating device.

9. A smoke exhaust channel comprising the gas-liquid mixing unit of the dust removal system as claimed in any one of claims 1 to 7, comprising a closed flue, an air inlet and a gas-liquid mixing unit, wherein one side of the flue (21) is provided with the air inlet (22), the bottom of the flue is hermetically connected with at least one gas-liquid mixing unit (1), and the gas-liquid mixing unit is communicated with the flue; a spraying device (23) is arranged at the upper part of the flue or an overflow water receiving plate is arranged at the top of the flue; the gas is mixed with spray water through the air inlet, the flue and the gas-liquid mixing unit (1), the filtered gas is discharged from an overflow port (14) of a water bath filter box of the gas-liquid mixing unit, and redundant liquid is discharged from the overflow port (14) of the water bath filter box of the gas-liquid mixing unit.

10. The smoke and dust exhausting duct of the gas-liquid mixing unit of a dust removing system as claimed in claim 8, wherein said overflow-shaped water receiving plate (24) is folded upward at its front edge to form a transverse water trap (241), and folded downward at its rear edge to form a transverse partition plate (242), and two adjacent ones of said overflow-shaped water receiving plates are sealed by inserting said partition plate into said water trap for water sealing, and a water trap overflow port is formed between said water trap and adjacent ones of said water receiving plates.

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