CN116747682A

CN116747682A - Gas-water separation device for spray tower

Info

Publication number: CN116747682A
Application number: CN202310813915.3A
Authority: CN
Inventors: 丁厚平; 武贤峰; 王帮训; 晋华杰
Original assignee: Anhui Yikesai Equipment Technology Co ltd
Current assignee: Anhui Yikesai Equipment Technology Co ltd
Priority date: 2023-07-05
Filing date: 2023-07-05
Publication date: 2023-09-15

Abstract

The invention discloses a gas-water separation device for a spray tower, which relates to the technical field of gas-water separation and comprises the following components: the utility model discloses a dust collection device, including casing, the inside of casing has seted up flow tank, adsorption tank and buffer tank, and adsorption tank and buffer tank all are linked together with the flow tank, the positive surface fixed intercommunication of casing has the outlet pipe, the fixed intercommunication inlet pipe in top of casing, the interior table wall fixed mounting of flow tank has drying mechanism, drying mechanism's input is provided with filler mechanism, buffer tank's inner wall bottom fixed mounting has sealing mechanism to reached even the air velocity of flow is too fast, also can carry out the effect of quick separation to moisture in the air, simultaneously, if the air velocity of flow still is fast when the dust of current volume also can't be perfect adsorption scene yet, also only need increase the length of drying pipe, can reach the time of extension air and hydrophilic dust contact, can not waste too much time and expense, maintenance is also convenient very much.

Description

Gas-water separation device for spray tower

Technical Field

The invention relates to the technical field of gas-water separation, in particular to a gas-water separation device used on a spray tower.

Background

The gas-water separation means that the water and the air in the air are separated, the existing gas-water separation devices all use different densities of gas-water two-phase substances, and adopt the technologies of gravity sedimentation, baffling separation, centrifugal separation and the like, wherein the gravity sedimentation is to adopt the gravity difference between the gas and the water, the separation is carried out through static, the centrifugal separation is to use the gas-water density difference, the separation is carried out through the centrifugal force, the baffling separation is to use the inertia of the water for separation, the methods have various characteristics, and different separation methods can be selected according to different use scenes.

In the prior art, after the tail gas of air is purified by a spray tower in industry, the flowing air is often too fast, so that the method has insufficient time for separating air from water, and finally has poor air-water separation effect, and if the separation time is prolonged, a large field is required to be expanded, so that the method is very time-consuming and cost-effective.

We have therefore proposed a gas-water separation device for use on a spray tower in order to solve the problems set out above.

Disclosure of Invention

The invention aims to provide a gas-water separation device for a spray tower, which aims to solve the problems that after the tail gas of air is purified by the spray tower in the industry, the flowing air is usually too fast, so that the method has insufficient time for separating gas from water, and finally has poor gas-water separation effect, and if the separation time needs to be prolonged, a large field needs to be expanded, so that the problems of time consumption, cost and low cost performance are solved.

In order to achieve the above purpose, the present invention provides the following technical solutions: a gas-water separation device for use on a spray tower, comprising: the device comprises a shell, wherein a flow groove, an adsorption groove and a buffer groove are formed in the shell, the adsorption groove and the buffer groove are all communicated with the flow groove, an outlet pipe is fixedly communicated with the front surface of the shell, an inlet pipe is fixedly communicated with the top of the shell, a drying mechanism is fixedly arranged on the inner surface wall of the flow groove, a filling mechanism is arranged at the input end of the drying mechanism, and a sealing mechanism is fixedly arranged at the bottom of the inner wall of the buffer groove;

the drying mechanism comprises a flow tube, a feeding tube is fixedly communicated with one side of the outer wall of the flow tube, a drying tube is fixedly communicated with the bottom of the flow tube, the output end of an inlet tube is positioned at the bottom of the drying tube, and a buffer tube is fixedly communicated with the bottom of the flow tube.

Preferably, the inner surface wall of the flow tube is fixedly inserted with a first filter frame, the inner surface wall of the first filter frame is fixedly provided with a first filter screen, the inner surface wall of the buffer tube is fixedly inserted with a second filter frame, and the inner surface wall of the second filter frame is fixedly provided with a second filter screen.

Preferably, the filling mechanism comprises an electromagnetic valve A, the output end of the electromagnetic valve A is fixedly arranged at the input end of the feeding pipe through a flange plate, the input end of the electromagnetic valve A is fixedly communicated with a feeding pipe through the flange plate, the input end of the feeding pipe is fixedly communicated with a material pumping pump through the flange plate, the input end of the material pumping pump is fixedly communicated with a material storage box, and one side of the outer wall of the material storage box is fixedly communicated with a material supplementing pipe.

Preferably, an observation port is formed in one side of the outer wall of the storage box, a sealing frame is fixedly mounted on one side of the outer wall of the storage box through screws, glass is fixedly mounted on the inner surface of the sealing frame, and scale marks are arranged on the front surface of the glass.

Preferably, the bottom of the drying pipe is fixedly communicated with a discharging pipe, the output end of the discharging pipe is fixedly communicated with an electromagnetic valve B through a flange plate, and the output end of the electromagnetic valve B is fixedly communicated with a connecting pipe through the flange plate.

Preferably, the sealing mechanism comprises a hydraulic rod, an installation block is fixedly arranged at the output end of the hydraulic rod, a sealing block is fixedly arranged at the top of the installation block, and the outer surface wall of the sealing block is meshed with the inner surface wall of the buffer tube.

Preferably, the maintenance port is formed in one side of the outer wall of the shell, the maintenance port is communicated with the buffer groove, the cover plate is fixedly mounted on one side of the outer wall of the shell through screws, the sealing plate is arranged on one side of the inner wall of the cover plate, and the inner surface wall of the sealing plate is movably inserted into the inner surface wall of the maintenance port.

Preferably, the front surface of the shell is provided with a humidity sensor, the detection part of the humidity sensor is positioned in the outlet pipe, and the humidity sensor is electrically connected with the material sucking pump.

Preferably, the output end of the outlet pipe is fixedly provided with a mounting frame through a screw, and the inner surface wall of the mounting frame is fixedly inserted with a sponge block.

Preferably, an alarm is arranged on the front surface of the shell, and the output end of the alarm is electrically connected with the humidity sensor.

Compared with the prior art, the invention has the beneficial effects that:

1. when the invention is used, the output end of the inlet pipe is inserted into the drying mechanism below the interior of the drying pipe, and hydrophilic dust is filled in the drying pipe through the feeding pipe, so that when the purified air of the spray tower is transported into the interior of the drying pipe through the inlet pipe, even if the flow rate of the air is fast, the air is in contact with the hydrophilic dust in the drying pipe, so that after moisture is adsorbed by the characteristic of the hydrophilic dust, the separated air is left in the drying pipe through self gravity, and flows out of the drying mechanism through the flow pipe and the buffer pipe in sequence, thereby achieving the effect of quickly separating the moisture in the air even if the flow rate of the air is too fast, and meanwhile, if the flow rate of the air is still fast enough to perfectly adsorb the dust in the current volume, the contact time of the air and the hydrophilic dust is prolonged, so that the time and the cost are not wasted, and the maintenance is also particularly convenient.

2. When the device is used, the water absorption of the hydrophilic dust is reduced after the hydrophilic dust is adsorbed to water, so that the gas-water separation effect is reduced, a humidity sensor and a probe are installed near an outlet pipe, so that the dried air can pass through the outlet pipe and is detected by the probe, once the humidity sensor detects that the air humidity is not up to the standard, the output end of a connecting pipe is connected with a dust collecting device, then an electromagnetic valve A and an electromagnetic valve B are opened simultaneously, the hydrophilic dust with weakened adsorptivity is pumped out of the drying pipe through a discharging mechanism, and new hydrophilic dust is refilled through a feeding mechanism, so that the gas-water separation effect can be recovered, the air is continuously dried, and the circulating effect is achieved.

Drawings

FIG. 1 is a front perspective view of a gas-water separation device for use on a spray tower in accordance with the present invention;

FIG. 2 is an expanded perspective view showing the structure of the inside of a buffer tank in a gas-water separator for a spray tower according to the present invention;

FIG. 3 is a cross-sectional expanded perspective view of the interior of a housing in a gas-water separation device for use on a spray tower in accordance with the present invention;

FIG. 4 is a structural development perspective view of a cross-section of the interior of a housing in a gas-water separation device for use on a spray tower in accordance with the present invention;

FIG. 5 is a structural expanded perspective view of a portion of a drying mechanism for use in a gas-water separation device on a spray tower in accordance with the present invention;

FIG. 6 is a structural expanded perspective view of a packing mechanism portion of a gas-water separation device for use on a spray tower according to the present invention;

FIG. 7 is a structural expanded perspective view of a seal mechanism portion of a gas-water separation device for use on a spray tower in accordance with the present invention;

fig. 8 is an expanded perspective view showing the structure of a cover plate portion in a gas-water separation device for a spray tower according to the present invention.

In the figure: 1. a housing; 2. a flow channel; 3. an adsorption tank; 4. a buffer tank; 5. an outlet tube; 6. an inlet pipe; 7. a drying mechanism; 701. a flow tube; 702. a feeding pipe; 703. a drying tube; 704. a buffer tube; 705. a first filter frame; 706. a first filter screen; 707. a second filter frame; 708. a second filter screen; 709. a discharge pipe; 710. an electromagnetic valve B; 711. a connecting pipe; 8. a filler mechanism; 801. an electromagnetic valve A; 802. a material conveying pipe; 803. a material pump; 804. a storage bin; 805. a material supplementing pipe; 806. an observation port; 807. a sealing frame; 808. glass; 809. scale marks; 9. a sealing mechanism; 901. a hydraulic rod; 902. a mounting block; 903. a sealing block; 10. a maintenance port; 11. a sealing plate; 12. a cover plate; 13. a humidity sensor; 14. an alarm; 15. a mounting frame; 16. sponge block.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. 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, the present invention provides a technical solution: a gas-water separation device for use on a spray tower, comprising: the device comprises a shell 1, wherein a flow groove 2, an adsorption groove 3 and a buffer groove 4 are formed in the shell 1, the adsorption groove 3 and the buffer groove 4 are communicated with the flow groove 2, an outlet pipe 5 is fixedly communicated with the front surface of the shell 1, an inlet pipe 6 is fixedly communicated with the top of the shell 1, a drying mechanism 7 is fixedly arranged on the inner surface wall of the flow groove 2, a filling mechanism 8 is arranged at the input end of the drying mechanism 7, and a sealing mechanism 9 is fixedly arranged at the bottom of the inner wall of the buffer groove 4;

the drying mechanism 7 comprises a flow tube 701, wherein one side of the outer wall of the flow tube 701 is fixedly communicated with a feeding tube 702, the bottom of the flow tube 701 is fixedly communicated with a drying tube 703, the output end of the inlet tube 6 is positioned at the bottom of the drying tube 703, and the bottom of the flow tube 701 is fixedly communicated with a buffer tube 704.

According to the illustration shown in fig. 5, the inner surface wall of the flow tube 701 is fixedly inserted with a first filter frame 705, the inner surface wall of the first filter frame 705 is fixedly provided with a first filter screen 706, the inner surface wall of the buffer tube 704 is fixedly inserted with a second filter frame 707, the inner surface wall of the second filter frame 707 is fixedly provided with a second filter screen 708, so that dust is filtered through the first filter screen 706, and then the second filter screen 708 is arranged to prevent the first filter screen 706 from leaking, so that the leaked dust can be blocked for the second time.

According to the illustration of fig. 5-6, the filling mechanism 8 comprises an electromagnetic valve a801, the output end of the electromagnetic valve a801 is fixedly arranged at the input end of a feeding pipe 702 through a flange plate, the input end of the electromagnetic valve a801 is fixedly communicated with a feeding pipe 802 through the flange plate, the input end of the feeding pipe 802 is fixedly communicated with a material pumping pump 803 through the flange plate, the input end of the material pumping pump 803 is fixedly communicated with a material storage box 804, one side of the outer wall of the material storage box 804 is fixedly communicated with a material supplementing pipe 805, and when the dust in the drying pipe 703 needs to be supplemented again, the dust in the material storage box 804 can be transported through the material pumping pump 803.

According to the view shown in fig. 6, an observation port 806 is formed on one side of the outer wall of the storage box 804, a sealing frame 807 is fixedly mounted on one side of the outer wall of the storage box 804 through screws, glass 808 is fixedly mounted on the inner surface of the sealing frame 807, scale marks 809 are arranged on the front surface of the glass 808, a worker can observe the dust condition in the storage box 804 through the glass 808 on the observation port 806, and meanwhile, the volume of the dust is observed through the scale marks 809 to judge whether the dust needs to be replenished or not.

According to the embodiment shown in fig. 5, a discharging pipe 709 is fixedly connected to the bottom of the drying pipe 703, an electromagnetic valve B710 is fixedly connected to the output end of the discharging pipe 709 through a flange, and a connecting pipe 711 is fixedly connected to the output end of the electromagnetic valve B710 through a flange, so that when the dust in the drying pipe 703 is replaced, a device for storing the dust can be connected to the connecting pipe 711, and therefore the dust with low water absorption can be collected.

According to the illustration shown in fig. 7, the sealing mechanism 9 comprises a hydraulic rod 901, a mounting block 902 is fixedly mounted at the output end of the hydraulic rod 901, a sealing block 903 is fixedly mounted at the top of the mounting block 902, and the outer surface wall of the sealing block 903 is meshed with the inner surface wall of the buffer tube 704, so that the output end of the buffer tube 704 is conveniently sealed, and therefore, only the feeding tube 702 and the discharging tube 709 in the drying mechanism 7 are in a ventilation state, and dust in the drying tube 703 is conveniently replaced.

According to the embodiment shown in fig. 1-2 and 8, a maintenance port 10 is formed on one side of the outer wall of the casing 1, the maintenance port 10 is communicated with the buffer tank 4, a cover plate 12 is fixedly mounted on one side of the outer wall of the casing 1 through screws, a sealing plate 11 is arranged on one side of the inner wall of the cover plate 12, and an inner surface wall of the sealing plate 11 is movably inserted into an inner surface wall of the maintenance port 10, so that when the second filter screen 708 needs to be replaced, the second filter screen 708 can be replaced through the maintenance port 10, and the filtering effect of the second filter screen 708 is prevented from being reduced.

According to the illustration in fig. 4, the front surface of the housing 1 is provided with a humidity sensor 13, the detection part of the humidity sensor 13 is located in the outlet pipe 5, and the humidity sensor 13 is electrically connected with the material pump 803, so that the humidity sensor 13 can detect the moisture condition of the air after drying, if the moisture is still out of standard, it is indicated that the water absorption of the hydrophilic dust is weakened, and the material pump 803 is triggered to timely supplement new hydrophilic dust.

According to the figure 2, the output end of the outlet pipe 5 is fixedly provided with a mounting frame 15 through screws, and the inner surface wall of the mounting frame 15 is fixedly inserted with a sponge block 16, so that air which is not completely dried can absorb moisture in the air through the water absorption of the sponge block 16, the air which comes out is ensured to be dry, and meanwhile, the sponge block 16 is positioned at the output end of the outlet pipe 5, so that the replacement is convenient.

According to the illustration in fig. 4, the front surface of the housing 1 is provided with an alarm 14, and the output end of the alarm 14 is electrically connected with the humidity sensor 13, so that when the humidity sensor 13 detects that the air humidity does not reach the standard, the alarm 14 is triggered to sound an alarm, and the staff is reminded to check and repair.

The whole mechanism achieves the following effects: firstly, the drying tube 703 is filled with dry hydrophilic dust, then the output end of the spray tower is connected with the input end of the inlet tube 6, and air to be dried is conveyed to the inlet tube 6, the air is positioned below the interior of the drying tube 703 after passing through the output end of the inlet tube 6, so that the air contacts with the hydrophilic dust in the drying tube 703, the hydrophilic dust absorbs water due to the adsorption of the hydrophilic dust to water, gravity is increased and remains at the bottom of the drying tube 703, the dried air flows into the buffer tank 4 of the shell 1 through the flow tube 701 and the buffer tube 704 in sequence, and flows out of the shell 1 through the buffer tank 4 and the outlet tube 5, in the flowing process, the gravity is not changed due to too fast flow rate or some hydrophilic dust is not contacted with water, and flows together with the air, when flowing into the flow tube 701, the dust is filtered for the first time by the first filter screen 706 in the first filter frame 705, stays in the flow tube 701 and finally falls back into the drying tube 703 by self gravity, if some dust enters the buffer tube 704 through the first filter screen 706, the dust is filtered by the second filter screen 708 in the second filter frame 707 in the buffer tube 704, the dust is prevented from flowing out of the drying mechanism 7 and polluting the air, when the second filter screen 708 needs to be replaced or cleaned, the cover plate 12 can be opened by screws, and the sealing plate 11 is pulled out from the maintenance port 10, the second filter frame 707 and the second filter screen 708 can be replaced or cleaned by the maintenance port 10, and moisture is adsorbed for a long time, the water absorption of hydrophilic dust can be reduced, so that the drying effect of the whole device becomes, at this moment, the air flow inlet and outlet pipe 5 with moisture can be detected by the probe of the humidity sensor 13, after moisture exceeds standard, the humidity sensor 13 can trigger the alarm 14 to send alarm sound and red light to remind workers, and when the air with moisture flows out of the outlet pipe 5, moisture can be adsorbed by the sponge block 16 outside the outlet pipe 5, thereby guaranteeing that the humidity of the air flowing out of the air can be reduced, when the humidity sensor 13 detects that the moisture exceeds standard, a spray tower is required to stop conveying the air, and the outlet pipe 5 is sealed, then the electromagnetic valve A801 and the electromagnetic valve B710 are started, the hydraulic rod 901 drives the mounting block 902 and the sealing block 903 to rise, thereby the sealing block 903 seals the outlet of the buffer pipe 704, so that the drying mechanism 7 only has the inlet pipe 702 and the outlet pipe 709 to flow air, for example, the drying mechanism 701 is connected with the inside of an outlet machine box of the connecting pipe 711, then the drying dust side in the storage box 804 is guaranteed to be reduced, when the humidity sensor 13 detects that moisture exceeds standard, the spray tower is required to stop conveying the air, and the outlet pipe 5 is sealed, then the electromagnetic valve A801 and the electromagnetic valve B710 are started, the hydraulic rod 901 drives the mounting block 902 and the sealing block 903 to rise, thereby the sealing block 903 seals the outlet of the buffer pipe 704, and the drying mechanism is only has the inlet pipe 702 and the outlet pipe 709 to flow air, and the drying mechanism can store dust, and then the drying dust can be filled into the drying mechanism through the outlet pipe through the drying mechanism, and the drying mechanism through the drying mechanism.

The material pump 803, the hydraulic rod 901, the electromagnetic valve a801 and the electromagnetic valve B710 are all in the prior art, and the components and the use principle thereof are all in the disclosed technology, and are not explained herein too much.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims

1. A gas-water separation device for a spray tower, comprising: the device comprises a shell (1), wherein a flow groove (2), an adsorption groove (3) and a buffer groove (4) are formed in the shell (1), the adsorption groove (3) and the buffer groove (4) are communicated with the flow groove (2), an outlet pipe (5) is fixedly communicated with the front surface of the shell (1), an inlet pipe (6) is fixedly communicated with the top of the shell (1), a drying mechanism (7) is fixedly arranged on the inner surface wall of the flow groove (2), a packing mechanism (8) is arranged at the input end of the drying mechanism (7), and a sealing mechanism (9) is fixedly arranged at the bottom of the inner wall of the buffer groove (4);

the drying mechanism (7) comprises a flow tube (701), a feeding tube (702) is fixedly communicated with one side of the outer wall of the flow tube (701), a drying tube (703) is fixedly communicated with the bottom of the flow tube (701), the output end of the inlet tube (6) is positioned at the bottom of the drying tube (703), and a buffer tube (704) is fixedly communicated with the bottom of the flow tube (701).

2. The gas-water separation device for a spray tower according to claim 1, wherein: the inner surface wall of the flow pipe (701) is fixedly inserted with a first filter frame (705), the inner surface wall of the first filter frame (705) is fixedly provided with a first filter screen (706), the inner surface wall of the buffer pipe (704) is fixedly inserted with a second filter frame (707), and the inner surface wall of the second filter frame (707) is fixedly provided with a second filter screen (708).

3. The gas-water separation device for a spray tower according to claim 1, wherein: the packing mechanism (8) comprises an electromagnetic valve A (801), the output end of the electromagnetic valve A (801) is fixedly arranged at the input end of a feeding pipe (702) through a flange plate, the input end of the electromagnetic valve A (801) is fixedly communicated with a feeding pipe (802) through the flange plate, the input end of the feeding pipe (802) is fixedly communicated with a material pumping pump (803) through the flange plate, the input end of the material pumping pump (803) is fixedly communicated with a material storage box (804), and one side of the outer wall of the material storage box (804) is fixedly communicated with a material supplementing pipe (805).

4. A gas-water separation device for use on a spray tower according to claim 3, wherein: an observation port (806) is formed in one side of the outer wall of the storage box (804), a sealing frame (807) is fixedly arranged on one side of the outer wall of the storage box (804) through screws, glass (808) is fixedly arranged on the inner surface of the sealing frame (807), and graduation marks (809) are arranged on the front surface of the glass (808).

5. The gas-water separation device for a spray tower according to claim 1, wherein: the bottom of drying tube (703) is fixed to be linked together and is had discharging pipe (709), the output of discharging pipe (709) is fixed to be linked together through the ring flange and is had solenoid valve B (710), the output of solenoid valve B (710) is fixed to be linked together through the ring flange and is had connecting pipe (711).

6. The gas-water separation device for a spray tower according to claim 1, wherein: the sealing mechanism (9) comprises a hydraulic rod (901), a mounting block (902) is fixedly arranged at the output end of the hydraulic rod (901), a sealing block (903) is fixedly arranged at the top of the mounting block (902), and the outer surface wall of the sealing block (903) is meshed with the inner surface wall of the buffer tube (704).

7. The gas-water separation device for a spray tower according to claim 1, wherein: the novel sealing device is characterized in that a maintenance opening (10) is formed in one side of the outer wall of the shell (1), the maintenance opening (10) is communicated with the buffer groove (4), a cover plate (12) is fixedly mounted on one side of the outer wall of the shell (1) through screws, a sealing plate (11) is arranged on one side of the inner wall of the cover plate (12), and an inner surface wall of the sealing plate (11) is movably inserted into an inner surface wall of the maintenance opening (10).

8. The gas-water separation device for a spray tower according to claim 4, wherein: the front surface of the shell (1) is provided with a humidity sensor (13), the detection part of the humidity sensor (13) is positioned in the outlet pipe (5), and the humidity sensor (13) is electrically connected with the material pumping pump (803).

9. The gas-water separation device for a spray tower according to claim 1, wherein: the output end of the outlet pipe (5) is fixedly provided with a mounting frame (15) through a screw, and a sponge block (16) is fixedly inserted into the inner surface wall of the mounting frame (15).

10. The gas-water separation device for a spray tower according to claim 8, wherein: an alarm (14) is arranged on the front surface of the shell (1), and the output end of the alarm (14) is electrically connected with the humidity sensor (13).