CN112495691A

CN112495691A - Material deep coating device for gas purification

Info

Publication number: CN112495691A
Application number: CN202011161066.0A
Authority: CN
Inventors: 罗玉湘; 孟祥宇
Original assignee: Nanjing Kohor Technique Co ltd
Current assignee: Nanjing Kohor Technique Co ltd
Priority date: 2020-10-27
Filing date: 2020-10-27
Publication date: 2021-03-16
Anticipated expiration: 2040-10-27
Also published as: CN112495691B

Abstract

The invention discloses a deep coating device for a material for gas purification, which comprises an upper box body, a middle box body, a lower box body, a pattern plate, a locking device, a fan, a differential pressure gauge, a connecting shaft and an air outlet pipe, wherein the lower box body is a cone, one side of the lower box body is provided with a coating liquid inlet, the coating liquid inlet is connected with an atomizing device through a pipeline, a clean air inlet is arranged below the coating liquid inlet, the bottom of the lower box body is provided with a coating liquid outlet, and the coating liquid outlet is connected with a valve through a pipeline. The filter bag deep coating device for flue gas purification can atomize coating liquid, and the atomized nano-micron particles enter the filter bag material under the action of negative pressure suction to coat the filter bag fibers from outside to inside. The coating device disclosed by the invention is used for coating the filter bag, so that the coating is more uniform, the coating efficiency is accelerated, and the production efficiency is improved.

Description

Material deep coating device for gas purification

Technical Field

The invention belongs to the technical field of environmental protection, and particularly relates to a deep coating device for a material for gas purification.

Background

In industrial production, a large amount of exhaust gas in which solid particles are mixed with air is generated, and if the exhaust gas is directly discharged to the atmosphere, the exhaust gas pollutes the environment and affects the health of people or other living things. The dust remover is a common device which can effectively purify waste gas containing solid particles and remove dust in the gas, and the filter bag is a core component of the dust remover and determines the operation stability and the dust removal efficiency of the dust remover. However, the smoke components are complex, and besides solid particles, the smoke components also contain pollution components such as water vapor, oily aerosol, nitrogen oxides and the like, and the filter bag is required to stably operate under different complex working conditions. However, the prior filter bag has the problems of poor high temperature resistance, poor corrosion resistance and the like, and the filter bag needs to be further treated. The film coating of the inner and outer layers of the filter material of the filter bag is a commonly used technical means at present. Most of the coating methods used at present are filter material dip coating, a filter bag or a filter material of the filter bag is directly immersed in coating liquid, the coating liquid is difficult to permeate and immerse into the filter material or the filter bag, internal fibers cannot be coated, and the problems of uneven coating, easy blockage of filter pores and the like exist.

Disclosure of Invention

In order to solve the technical problems, the invention discloses a deep coating device for a material for gas purification, which can atomize coating liquid, and the atomized nano-micron particles enter the interior of a filter bag material under the action of negative pressure suction to coat the fibers of the filter bag from outside to inside. The coating device disclosed by the invention is used for coating the filter bag, so that the coating is more uniform, the coating efficiency is accelerated, and the production efficiency is improved.

In order to achieve the technical purpose, the invention adopts the following technical scheme:

a deep coating device for a material for gas purification comprises an upper box body, a middle box body, a lower box body, a pattern plate, a locking device, a fan, a differential pressure gauge, a connecting shaft and an air outlet pipe, wherein the lower box body is a cone, one side of the lower box body is provided with a coating liquid inlet, the coating liquid inlet is connected with an atomizing device through a pipeline, a clean air inlet is arranged below the coating liquid inlet, the bottom of the lower box body is provided with a coating liquid outlet, the coating liquid outlet is connected with a valve through a pipeline, the middle box body is positioned at the upper part of the lower box body, the outer wall of the middle box body is provided with a heat preservation heating device, a temperature sensor is arranged in the middle box body, the pattern plate is positioned between the middle box body and the upper box body, the pattern plate is provided with pattern plate holes, one sides of the upper box body and the middle box body are connected through the connecting shaft, the other sides are connected through, the coating liquid sensor is arranged in the upper box body, the fan is arranged on one side of the upper box body and is connected with the upper box body through a pipeline, and the air outlet pipe is arranged at the air outlet of the fan.

Furthermore, the number of the atomization devices is 1 or more, and the atomization devices are uniformly distributed on the cross section of the lower box body.

Furthermore, the temperature sensor and the heat preservation heating device are in linkage control, the heat preservation heating temperature is set through the temperature sensor, and the temperature sensor feeds back and adjusts the starting and heating power of the heat preservation heating device.

Further, the locking device is a bolt or a hoop, and the number of the locking devices is 1 or more for each surface.

Furthermore, the coating liquid sensor is a VOC sensor, a humidity sensor or an aerosol laser sensor.

Furthermore, the temperature sensor, the differential pressure sensor and the coating liquid sensor are connected with the PLC control cabinet through signal lines.

Furthermore, a coating liquid control and metering device is arranged at the coating liquid inlet.

Furthermore, a clean air metering and adjusting device is arranged at the clean air inlet in a dry mode.

When the filter bag deep coating device is used for coating a filter bag, the filter bag is hung on a pattern plate of the coating device and is supported by a cage, coating liquid is atomized by the atomizing device and then enters the middle box body from bottom to top under the action of the fan, the coating liquid is infiltrated into the interior of a filter bag material under the action of negative pressure suction, the atomized coating liquid penetrates through the filter bag and is detected by the coating liquid detection device, the supply of the coating liquid is stopped, the middle box body heating and heat preservation device is started, the temperature solidification of the coating liquid is accelerated at high temperature, and redundant coating liquid in the coating device can be discharged at the bottom of the coating device for recycling.

Drawings

FIG. 1 is a schematic view of a coating apparatus according to the present invention.

The device comprises a box body, a locking device, a fan, a pressure difference meter, a connecting shaft, a gas outlet pipe, a heat-preservation heating device, a temperature sensor, a coating liquid inlet, an atomizing device, a clean air inlet, a coating liquid outlet, a valve 305 and a flower plate hole 401, wherein the box body comprises an upper box body, a middle box body, a lower box body, a 4-flower plate, a 5-locking device, a 6-fan, a 7-pressure difference meter, a 8-connecting shaft.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, unless otherwise specified and limited, it is to be understood that the terms "mounted," "connected," and "connected" are used broadly and can be, for example, mechanically or electrically connected, or can be internal to two elements, directly connected, or indirectly connected through an intermediate medium. The specific meaning of the above terms can be understood by those of ordinary skill in the art as appropriate.

As shown in fig. 1, a deep coating device for a material for gas purification comprises an upper box body 1, a middle box body 2, a lower box body 3, a pattern plate 4, a locking device 5, a fan 6, a differential pressure gauge 7, a connecting shaft 8 and an air outlet pipe 9, wherein the lower box body 3 is a cone, one side of the lower box body is provided with a coating liquid inlet 301, the coating liquid inlet 301 is connected with an atomizing device 302 through a pipeline, a clean air inlet 303 is arranged below the coating liquid inlet 301, the bottom of the lower box body 3 is provided with a coating liquid outlet 304, the coating liquid outlet 304 is connected with a valve 305 through a pipeline, a coating liquid control and metering device is arranged at the coating liquid inlet 301, and a clean air metering and adjusting device is arranged at the clean air inlet 303; the middle box body 2 is positioned at the upper part of the lower box body 3, the outer wall of the middle box body 2 is provided with a heat preservation heating device 201, a temperature sensor 202 is arranged in the middle box body 2, the temperature sensor 202 and the heat preservation heating device 201 are controlled in a linkage mode, the heat preservation heating temperature is set through the temperature sensor 202, and the temperature sensor 202 feeds back and adjusts the starting and heating power of the heat preservation heating device 201; the temperature sensor 202, the differential pressure sensor 7 and the coating liquid sensor are connected with the PLC control cabinet through signal lines;

the flower plate 4 is located between the middle box body 2 and the upper box body 1, the flower plate 4 is provided with a flower plate hole 401, one side of the upper box body 1 and one side of the middle box body 2 are connected through a connecting shaft 8, other side surfaces are connected through a locking device 5, a pressure difference sensor 7 is installed between the upper box body 1 and the middle box body 2, the upper box body 1 and the middle box body 2 are connected through a pressure leading pipe respectively, a coating liquid sensor 101 is installed inside the upper box body 1, a fan 6 is installed on one side of the upper box body 1 and is connected with the upper box body 1 through a pipeline, and a wind outlet pipe 9 is installed at the gas.

In this embodiment, the number of the atomization devices 302 is 1 or more, and the atomization devices are uniformly distributed on the cross section of the lower box body.

In this embodiment, the locking device 5 is a bolt or a clamp, and the number of the locking devices is 1 or more per surface.

In this embodiment, the coating liquid sensor 101 is one of a VOC sensor, a humidity sensor, or an aerosol laser sensor.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims

1. A deep coating device for a material for gas purification is characterized by comprising an upper box body (1), a middle box body (2), a lower box body (3), a pattern plate (4), a locking device (5), a fan (6), a differential pressure gauge (7), a connecting shaft (8) and an air outlet pipe (9), wherein the lower box body (3) is a cone, one side of the lower box body is provided with a coating liquid inlet (301), the coating liquid inlet (301) is connected with an atomizing device (302) through a pipeline, a clean air inlet (303) is arranged below the coating liquid inlet (301), the bottom of the lower box body (3) is provided with a coating liquid outlet (304), the coating liquid outlet (304) is connected with a valve (305) through a pipeline, the middle box body (2) is positioned at the upper part of the lower box body (3), the outer wall of the middle box body (2) is provided with a heat-preserving and heating device (201), a temperature sensor (202) is arranged in the middle box body (2), the pattern plate (4) is positioned between, pattern plate (4) are equipped with pattern plate hole (401), go up box (1) and well box (2) one side and connect through connecting axle (8), other sides are passed through locking device (5) and are connected, go up and install pressure differential sensor (7) between box (1) and well box (2), link to each other in last box (1) and well box (2) respectively through drawing the pressure pipe, it has coating liquid sensor (101) to go up box (1) internally mounted, goes up box (1) one side and installs fan (6), links to each other with last box (1) through the pipeline, and fan (6) gas outlet is installed out tuber pipe (9).

2. The deep coating device for gas purification material as claimed in claim 1, wherein the number of said atomization device (302) is 1 or more, and said atomization device is uniformly distributed on the cross section of the lower box.

3. The deep coating device for the gas purification material as claimed in claim 1, wherein the temperature sensor (202) is interlocked with the heat-preservation heating device (201), the heat-preservation heating temperature is set through the temperature sensor (202), and the temperature sensor (202) feeds back and adjusts the starting and heating power of the heat-preservation heating device (201).

4. The apparatus for deep coating of gas purifying material as claimed in claim 1, wherein the locking means (5) is a bolt or a band, and the number is 1 or more per surface.

5. The apparatus for deep coating of gas purifying material as claimed in claim 1, wherein the coating liquid sensor (101) is a VOC sensor, a humidity sensor or an aerosol laser sensor.

6. The deep coating device for gas purification materials as claimed in claim 1, wherein the temperature sensor (202), the differential pressure sensor (7) and the coating liquid sensor are connected with the PLC control cabinet through signal lines.

7. The apparatus for deep coating of gas purifying material as claimed in claim 1, wherein the coating liquid inlet (301) is provided with a coating liquid control and metering device.

8. The deep coating device for gas purifying material as claimed in claim 1, wherein the clean air inlet (303) is dry-equipped with a clean air metering and adjusting device.