CN116221860B

CN116221860B - Purification workshop air inlet is with accuse wet dust remover

Info

Publication number: CN116221860B
Application number: CN202310502911.3A
Authority: CN
Inventors: 武斌
Original assignee: Jiangsu Landian Environmental Protection Co ltd
Current assignee: Jiangsu Landian Environmental Protection Co ltd
Priority date: 2023-05-06
Filing date: 2023-05-06
Publication date: 2023-08-01
Anticipated expiration: 2043-05-06
Also published as: CN116221860A

Abstract

The invention discloses a humidity control dust remover for air intake of a purification workshop, which relates to the technical field of purification workshops and comprises a humidity control dust removing mechanism, wherein the humidity control dust removing mechanism is provided with a temperature control degassing mechanism, the temperature control degassing mechanism comprises a liquid storage shell, a first ventilating pipe, a formaldehyde sensor, a cylindrical hole, a fan, a radiating fin, an infrared temperature sensor and a controller, the input end of the first ventilating pipe is provided with a one-way valve, the input end of the one-way valve is provided with a suction fan, and the front surface of the radiating fin is provided with a refrigerating fin.

Description

Purification workshop air inlet is with accuse wet dust remover

Technical Field

The invention relates to the technical field of purification workshops, in particular to a humidity control dust remover for air inlet of a purification workshop.

Background

The clean shop is also called a dust-free shop, a clean room, a dust-free room and the like, and is a room constructed by removing particles, harmful gases, bacteria and other pollutants in the air within a certain space range, controlling indoor medium temperature, cleanliness, indoor pressure, air flow speed, air flow distribution, noise vibration, illumination and static electricity within a certain requirement range, so that an air inlet part of the clean shop is required to be provided with a humidity control dust remover, dust, germs, high-humidity gases and the like in the air can be effectively prevented from entering the clean shop, and the clean shop is mainly applied to industries such as medicine and sanitation, precision manufacturing, photoelectrons, aerospace, food industry, cosmetics, automobile paint and the like.

In the actual use process, the existing wet dust remover for the air inlet part of the purification workshop can filter and remove dust and bacteria in the air, meanwhile, the use effect of the purification workshop is guaranteed by controlling the moisture content of the air, but the temperature of the air with the temperature generated after the wet control cannot be controlled, so that the situation that formaldehyde volatilizes on the surface of part of materials used in the purification workshop is possibly caused by the fact that the air enters the purification workshop to be too high in temperature, namely the use of the purification workshop is influenced, the physical health of the air can be influenced by the inhalation of people, and meanwhile, the concentration of formaldehyde gas in the purification workshop cannot be monitored and the formaldehyde gas in the workshop can be processed, so that the use efficiency of the wet dust remover is reduced.

Therefore, a new type of humidity control dust collector for air intake in a cleaning plant needs to be proposed so as to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide a humidity control dust remover for air intake of a purification workshop, which aims to solve the problems that the humidity control dust remover cannot perform temperature control operation on gas with temperature generated after humidity control, and cannot monitor the concentration of formaldehyde gas in the purification workshop and process the formaldehyde-containing gas in the workshop, so that the use efficiency of the humidity control dust remover is reduced.

In order to achieve the above purpose, the present invention provides the following technical solutions: the wet-control dust remover for the air intake of the purification workshop comprises a wet-control dust removing mechanism, wherein the wet-control dust removing mechanism is provided with a temperature-control degassing mechanism; the temperature control degassing mechanism comprises a liquid storage shell, a first vent pipe, a formaldehyde sensor, a cylindrical hole, a fan, a radiating fin, an infrared temperature sensor and a controller, wherein the input end of the first vent pipe is provided with a one-way valve, the input end of the one-way valve is provided with a suction fan, the input end of the suction fan is provided with a second vent pipe, the input end of the second vent pipe is provided with a funnel-shaped pipe, the front surface of the radiating fin is provided with a refrigerating fin, and the front surface of the refrigerating fin is provided with a hollow block.

Preferably, the controller is electrically connected with the suction fan, the controller is electrically connected with the formaldehyde sensor, the controller is electrically connected with the fan, the controller is electrically connected with the refrigerating sheet, the controller is electrically connected with the infrared temperature sensor, and the output end of the first ventilation pipe extends to a position, close to the bottom, inside the liquid storage shell.

Preferably, the humidity control and dust removal mechanism comprises a shell, the bottom of the liquid storage shell is slidably embedded in the bottom of the inner wall of the shell, the input end of the first ventilation pipe movably penetrates through the outer wall of the shell, the formaldehyde sensor is mounted on the outer wall of the shell, the detection head of the formaldehyde sensor is mounted on the funnel-shaped pipe, and the detection end of the formaldehyde sensor extends to the inside of the funnel-shaped pipe.

Preferably, the infrared temperature sensor is installed on the upper side of the inner wall of the shell, the detecting head of the infrared temperature sensor is installed on the upper side of the inner part of the shell, the detecting end of the infrared temperature sensor is installed on the lower side of the inner part of the shell, the shell plates are installed on the front surface and the rear surface of the shell, the cylindrical hole is formed in the front surface of one of the shell plates, the fan is installed on the rear surface of one of the shell plates, the air outlet end of the fan is communicated with the input end of the cylindrical hole, the first fan is installed on one side of the shell, and the two liquid collecting tanks are formed in the inner wall of the shell.

Preferably, the bottom of casing is fixed with the slide rail, the internally mounted of slide rail has the collection box, and the inner wall bottom of two collecting tanks is all fixed to run through has the outlet pipe, two the inside of collecting tank all is provided with the separation blade, the inside of casing is fixed with four sets of rectangular pieces, and the quantity of every rectangular piece of group is two, and wherein two sets of install the evaporimeter between the inside of rectangular piece, two sets of install the condenser between the inside of rectangular piece.

Preferably, the top of two the separation blades is fixed with the bottom of the evaporator and the bottom of the condenser respectively, the output end of the condenser is connected with the input end of the evaporator through a first round pipe, an L-shaped partition plate is fixed in the shell, the cooling fin is arranged between one side of the L-shaped partition plate and one side of the inner wall of the shell, the hollow block is arranged between one side of the L-shaped partition plate and one side of the inner wall of the shell, a rectangular hole is formed in the inner wall of the shell, a porous plate is fixed in the rectangular hole, and an air inlet pipe is arranged at the input end of the first fan.

Preferably, the bottom of the casing is fixed to run through to the input of intake pipe, the outlet duct is installed to the output of intake pipe, humidity transducer is installed to the inside upside of casing, the inside upside of casing is provided with the processing box, the inner wall of the fixed casing that runs through of input of processing box, a plurality of spacing holes have been seted up to the inner wall top equidistance distribution of processing box, every the filter screen is all installed to the inside in spacing hole, every the bottom of filter screen is all slided and is inlayed and establish in the inner wall bottom of processing box.

Preferably, the inside of processing box is fixed with the rectangle grid, the opposite side of processing box is fixed to run through has the multi-pass pipe, the outer wall of processing box is provided with the stopper, the stopper is installed in the inside upside of casing, the connecting pipe is installed to the output of multi-pass pipe, the second fan is installed to the inside upside of casing, the input of second fan is connected with the output of connecting pipe.

Preferably, the output of second fan is installed L type pipe, the output activity of L type pipe runs through the inside upside of casing to the output of L type pipe extends to the inside of casing and is close to the bottom position, the tube cap is installed to the output of L type pipe, a plurality of air vents have been seted up to the inner wall equidistance distribution of L type pipe, the outer wall of casing has been seted up the inlet port near the top position.

Preferably, the metal mesh is installed at the air inlet of inlet port, the compressor is installed to the inside downside of casing, the output of evaporimeter is connected through the second pipe with the input of compressor, the input of condenser is connected with the input of compressor, first fan and controller electric connection, evaporimeter, condenser, humidity transducer, second fan and compressor all with controller electric connection.

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

1. the invention can regulate the temperature of the dried gas by arranging the temperature control degassing mechanism so as to prevent the condition that the temperature of the gas entering the interior of the purification workshop is too high, and formaldehyde is volatilized in materials used in the interior of the purification workshop, and simultaneously can detect the concentration of formaldehyde in the interior of the purification workshop, and can absorb the gas mixed with formaldehyde in the interior of the purification workshop, thereby effectively improving the service efficiency of the moisture control dust remover, under the action of the interior of the liquid storage shell, the brine absorbing the formaldehyde gas can be contained, under the cooperation of the formaldehyde sensor and the funnel-shaped pipe, the concentration of the formaldehyde gas in the interior of the purification workshop can be detected, and under the cooperation of the cylindrical hole, the fan, the cooling fin and the cooling fin, the gas with temperature after drying can be cooled, and the heat is guided away.

2. According to the invention, through arranging the humidity control dust removing mechanism, temperature control dust removing operation can be carried out on gas entering the interior of the purification workshop in the environment, the evaporator and the condenser can be stably fixed in the interior of the shell under the cooperation of the rectangular block and the L-shaped partition board, the gas subjected to humidity control dust removing can be conveyed into the interior of the purification workshop under the cooperation of the first fan, the air inlet pipe and the air outlet pipe, the gas subjected to dust removing in the interior of the processing box can be guided into the interior of the L-shaped pipe under the cooperation of the second fan and the connecting pipe, and the gas entering the L-shaped pipe can be uniformly distributed in the space formed by the shell plate, the shell and the L-shaped partition board under the cooperation of the vent hole and the pipe cover.

Drawings

FIG. 1 is a partial perspective view of a moisture control dust collector for cleaning shop air intake of the present invention;

FIG. 2 is another perspective view of an alternative angle section of a moisture control dust collector for cleaning shop air intake according to the present invention;

FIG. 3 is a top view perspective view of a moisture control dust collector for cleaning shop air intake according to the present invention;

FIG. 4 is an enlarged perspective view of the humidity control dust collector of FIG. 2A for cleaning shop air intake according to the present invention;

FIG. 5 is an enlarged perspective view of the moisture control dust collector of FIG. 3 for cleaning shop air intake according to the present invention;

FIG. 6 is a perspective view of a moisture control dust collector for cleaning shop air intake according to the present invention;

FIG. 7 is a schematic perspective view of a second vent pipe and a funnel of the humidity control dust collector for air intake in a clean room;

FIG. 8 is a perspective view, partially in section, of a moisture control dust collector for cleaning shop air intake of the present invention;

fig. 9 is a schematic diagram of a part of the structure of a humidity control dust collector for air intake in a purification plant.

In the figure: 1. a humidity control and dust removal mechanism; 101. a housing; 102. a shell plate; 103. a first fan; 104. a liquid collecting tank; 105. a slide rail; 106. a collection box; 107. a water outlet pipe; 108. a baffle; 109. rectangular blocks; 110. an evaporator; 111. a condenser; 112. an L-shaped partition; 113. a rectangular hole; 114. a porous plate; 115. an air inlet pipe; 116. an air outlet pipe; 117. a humidity sensor; 118. a process cartridge; 119. a limiting hole; 120. a filter screen; 121. rectangular grid plates; 122. a multi-way pipe; 123. a limiting block; 124. a connecting pipe; 125. a second fan; 126. an L-shaped tube; 127. a tube cover; 128. a vent hole; 129. an air inlet hole; 130. a metal mesh; 131. a compressor; 2. a temperature control degassing mechanism; 201. a liquid storage shell; 202. a first vent pipe; 203. a suction fan; 204. a second vent pipe; 205. a funnel-type tube; 206. a formaldehyde sensor; 207. a one-way valve; 208. a cylindrical hole; 209. a fan; 210. a heat sink; 211. a cooling sheet; 212. a hollow block; 213. an infrared temperature sensor; 214. and a controller.

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 to 9, the present invention provides a technical solution: the wet-control dust remover for the air intake of the purification workshop comprises a wet-control dust removing mechanism 1, wherein the wet-control dust removing mechanism 1 is provided with a temperature-control degassing mechanism 2; the temperature control degassing mechanism 2 comprises a liquid storage shell 201, a first breather pipe 202, a formaldehyde sensor 206, a cylindrical hole 208, a fan 209, a cooling fin 210, an infrared temperature sensor 213 and a controller 214, wherein the input end of the first breather pipe 202 is provided with a one-way valve 207, the input end of the one-way valve 207 is provided with a suction fan 203, the input end of the suction fan 203 is provided with a second breather pipe 204, the input end of the second breather pipe 204 is provided with a funnel-shaped pipe 205, the front surface of the cooling fin 210 is provided with a cooling fin 211, and the front surface of the cooling fin 211 is provided with a hollow block 212.

According to fig. 2-4 and 6, the controller 214 is electrically connected with the suction fan 203, the controller 214 is electrically connected with the formaldehyde sensor 206, the controller 214 is electrically connected with the fan 209, the controller 214 is electrically connected with the refrigerating plate 211, the controller 214 is electrically connected with the infrared temperature sensor 213, the output end of the first ventilation pipe 202 extends to a position near the bottom inside the liquid storage shell 201, so that the brine absorbing formaldehyde gas can be conveniently contained under the action of the inside of the liquid storage shell 201.

According to the embodiments shown in fig. 1-4, 6 and 7, the humidity-controlling and dust-removing mechanism 1 includes a housing 101, the bottom of a liquid storage housing 201 is slidably embedded in the bottom of the inner wall of the housing 101, the input end of a first ventilation pipe 202 movably penetrates through the outer wall of the housing 101, a formaldehyde sensor 206 is mounted on the outer wall of the housing 101, a probe of the formaldehyde sensor 206 is mounted on a funnel-shaped pipe 205, and the probe end of the formaldehyde sensor 206 extends to the inside of the funnel-shaped pipe 205, so that the concentration detection of formaldehyde gas in a purification workshop can be conveniently performed under the cooperation of the formaldehyde sensor 206 and the funnel-shaped pipe 205.

According to the embodiment shown in fig. 3 to 6, the infrared temperature sensor 213 is installed on the upper side of the inner wall of the housing 101, the detecting head of the infrared temperature sensor 213 is installed on the upper side of the inner part of the housing 101, the detecting end of the infrared temperature sensor 213 is installed on the lower side of the inner part of the housing 101, the front surface and the rear surface of the housing 101 are both provided with the shell plates 102, the cylindrical hole 208 is formed on the front surface of one of the shell plates 102, the fan 209 is installed on the rear surface of one of the shell plates 102, the air outlet end of the fan 209 is communicated with the input end of the cylindrical hole 208, the first fan 103 is installed on one side of the housing 101, and the inner wall of the housing 101 is provided with two liquid collecting grooves 104, so that the water condensed into water drops can be conveniently distributed to the inner part of the water outlet pipe 107 under the action of the liquid collecting grooves 104.

According to the embodiment shown in fig. 2-6 and 9, the bottom of the housing 101 is fixed with a slide rail 105, the inside of the slide rail 105 is provided with a collecting box 106, the bottoms of the inner walls of the two liquid collecting tanks 104 are respectively and fixedly provided with a water outlet pipe 107, the interiors of the two liquid collecting tanks 104 are respectively provided with a baffle 108, four groups of rectangular blocks 109 are fixed in the housing 101, the number of the rectangular blocks 109 in each group is two, an evaporator 110 is arranged between the interiors of the two groups of rectangular blocks 109, and a condenser 111 is arranged between the interiors of the other two groups of rectangular blocks 109, so that the evaporator 110 and the condenser 111 can be stably fixed in the housing 101 under the cooperation of the rectangular blocks 109 and the L-shaped partition 112.

According to the embodiments shown in fig. 2-6 and 9, the top of the two baffle plates 108 are respectively fixed with the bottom of the evaporator 110 and the bottom of the condenser 111, the output end of the condenser 111 is connected with the input end of the evaporator 110 through a first round tube, the L-shaped partition plate 112 is fixed inside the housing 101, the heat sink 210 is installed between one side of the L-shaped partition plate 112 and one side of the inner wall of the housing 101, the hollow block 212 is installed between one side of the L-shaped partition plate 112 and one side of the inner wall of the housing 101, the rectangular hole 113 is provided in the inner wall of the housing 101, the perforated plate 114 is fixed inside the rectangular hole 113, the air inlet pipe 115 is installed at the input end of the first fan 103, and the air outlet pipe 116 are convenient to convey the air after moisture control and dust removal to the inside of the purification workshop.

According to the embodiment shown in fig. 2-6 and 8, the input end of the air inlet pipe 115 is fixedly penetrating through the bottom of the casing 101, the air outlet pipe 116 is installed at the output end of the air inlet pipe 115, the humidity sensor 117 is installed at the upper side of the inside of the casing 101, the processing box 118 is arranged at the upper side of the inside of the casing 101, the input end of the processing box 118 is fixedly penetrating through the inner wall of the casing 101, a plurality of limiting holes 119 are distributed at the top of the inner wall of the processing box 118 at equal intervals, the filter screen 120 is installed in each limiting hole 119, the bottom of each filter screen 120 is slidably embedded at the bottom of the inner wall of the processing box 118, and dust mixed in gas can be filtered conveniently under the cooperation of the processing box 118 and the filter screen 120.

According to the embodiments shown in fig. 2 to 6 and 8, a rectangular grid plate 121 is fixed inside the process cartridge 118, a multi-way pipe 122 is fixedly penetrated through the other side of the process cartridge 118, a limiting block 123 is arranged on the outer wall of the process cartridge 118, the limiting block 123 is arranged on the upper side inside the casing 101, a connecting pipe 124 is arranged at the output end of the multi-way pipe 122, a second fan 125 is arranged on the upper side inside the casing 101, the input end of the second fan 125 is connected with the output end of the connecting pipe 124, and the air after dust removal inside the process cartridge 118 can be conveniently guided into the L-shaped pipe 126 under the cooperation of the second fan 125 and the connecting pipe 124.

According to the embodiment shown in fig. 2 to 6, the output end of the second fan 125 is provided with an L-shaped pipe 126, the output end of the L-shaped pipe 126 movably penetrates through the upper side of the interior of the housing 101, the output end of the L-shaped pipe 126 extends to a position close to the bottom of the interior of the housing 101, the output end of the L-shaped pipe 126 is provided with a pipe cover 127, the inner wall of the L-shaped pipe 126 is equidistantly distributed to form a plurality of ventilation holes 128, the outer wall of the housing 101 is provided with an air inlet 129 close to the top, and air in the environment can conveniently enter the interior of the housing 101 under the action of the air inlet 129, and meanwhile, under the cooperation of the ventilation holes 128 and the pipe cover 127, the air entering the L-shaped pipe 126 can be uniformly distributed in the space formed by the shell plate 102, the housing 101 and the L-shaped partition 112.

According to the embodiments shown in fig. 2-6 and 9, the metal mesh 130 is installed at the air inlet of the air inlet 129, the compressor 131 is installed at the lower side of the interior of the housing 101, the output end of the evaporator 110 is connected with the input end of the compressor 131 through the second round tube, the input end of the condenser 111 is connected with the input end of the compressor 131, the first fan 103 is electrically connected with the controller 214, the evaporator 110, the condenser 111, the humidity sensor 117, the second fan 125 and the compressor 131 are electrically connected with the controller 214, and the moisture in the air can be removed conveniently under the cooperation of the evaporator 110, the condenser 111 and the compressor 131, so as to achieve the purpose of drying the air.

The whole mechanism achieves the following effects: when the purification workshop needs air intake, the output end of the air outlet pipe 116 is directly connected with the air inlet of the purification workshop, the input end of the funnel-shaped pipe 205 is simultaneously connected with the air outlet of the purification workshop, saline water is poured into the liquid storage shell 201, the controller 214, namely the PLC controller, is started, the external power supply is connected, the humidity threshold value, the temperature threshold value and the gas concentration threshold value are set on the controller 214, when all the materials are ready, the first fan 103 and the second fan 125 are directly started, the started first fan 103 directly obtains suction force at the input end of the air inlet pipe 115, the started second fan 125 directly obtains suction force at the air inlet of the air inlet hole 129 under the cooperation of the connecting pipe 124, the processing box 118 and the shell 101, the air inlet hole 129 obtaining suction force directly sucks air in the environment, when the air enters from the inlet of the air inlet 129, the air can be prevented from entering from the inlet of the air inlet 129 by the metal net 130, then the filtered air can directly enter the inside of the processing box 118 under the cooperation of the shell 101 and the shell plate 102, meanwhile, the humidity sensor 117 can directly detect the humidity of the air entering from the air inlet 129 and transmit the detected humidity data to the inside of the controller 214 in an electric signal mode, when the controller 214 receives the humidity data transmitted by the humidity sensor 117, the controller 214 can directly analyze and compare the received humidity data with the humidity threshold value set in advance on the controller 214, when the air enters the inside of the processing box 118, the speed of the rectangular grid plate 121 flowing in the inside of the processing box 118 can be reduced under the action of the rectangular grid plate 121, the gas with reduced speed can sequentially pass through the meshes of the three filter screens 120, dust in the gas can be filtered and left under the action of the filter screens 120, the filtered gas can directly enter the inside of the connecting pipe 124, then the gas is directly guided into the L-shaped pipe 126 through the cooperation of the second fan 125, the gas entering the inside of the L-shaped pipe 126 can be directly guided into a space formed by the shell plate 102, the shell 101 and the L-shaped partition 112 under the cooperation of the pipe cover 127 and the plurality of vent holes 128, when the humidity data received by the controller 214 is smaller than the humidity data preset by the controller 214, the gas after dust removal can sequentially pass through the evaporator 110 and the condenser 111, then pass through the through holes of the porous plate 114, then enter the inside of the air inlet pipe 115, finally the gas is uniformly guided into the space formed by the shell plate 102, the shell 101 and the L-shaped partition 112 through the cooperation of the first fan 103 and the air outlet pipe 116, the air after temperature control and dust removal is directly guided into the purification workshop, when the humidity data received by the controller 214 is greater than the humidity data set by the controller 214 in advance, the controller 214 directly starts the evaporator 110, the condenser 111 and the compressor 131 at the moment, the started evaporator 110, the started condenser 111 and the started compressor 131 directly remove water vapor in the air under the cooperation of the two baffle plates 108, then the water in the air coming out of the condenser 111 is removed, the water in the removed air is condensed into water drops, the water drops directly slide into the liquid collecting tank 104, then the water condensed into the water drops is directly guided into the collection box 106 through the cooperation of the water outlet pipe 107 for dust removal, the dried air passes through the through holes of the porous plate 114 at the moment, under the action of the infrared temperature sensor 213, the temperature measurement operation can be performed on the dry gas passing through the through hole of the perforated plate 114, meanwhile, the infrared temperature sensor 213 can directly transmit the detected temperature data to the inside of the controller 214, at this time, the controller 214 can analyze and compare the received temperature data with the temperature threshold value set in advance by the controller 214, when the temperature data received by the controller 214 is smaller than the temperature threshold value set in advance by the controller 214, at this time, the dried gas can directly feed the dry gas into the inside of the purification workshop through the cooperation of the first fan 103, the air inlet pipe 115 and the air outlet pipe 116, when the temperature data received by the controller 214 is larger than the temperature threshold value set in advance by the controller 214, at this time, the controller 214 can directly start the refrigerating sheet 211 and the fan 209, at this time, one end of the started refrigerating sheet 211 contacted with the radiating sheet 210 can become cold, whereas the other end can become hot, at this time, the fan 209 is started to transfer the heat from the cold end to the hot end of the cooling fin 211, and then the heat is directly blown out from the interior of the temperature-controlled dust collector through the cooperation of the cylindrical hole 208, meanwhile, the cold end of the cooling fin 211 directly transfers the heat carried in the dry gas passing through the through hole of the porous plate 114 to the hot end of the cooling fin 211 under the cooperation of the cooling fin 210, so as to realize the cooling operation of the dry gas, and then the cooled gas is directly sent into the interior of the purification workshop under the cooperation of the air inlet pipe 115, the air outlet pipe 116 and the first fan 103, namely, the gas with higher temperature is effectively prevented from entering the interior of the purification workshop, so that partial materials used in the purification workshop with higher temperature can be effectively prevented from volatilizing formaldehyde gas, polluting the environment and being inhaled by people can also affect the health of the purification workshop, at this time, the formaldehyde sensor 206 also detects the formaldehyde gas concentration in the purification workshop at any time, directly transmits the detected data to the controller 214 in an electric signal manner, then the controller 214 directly compares the received concentration data with the concentration data set in advance by the controller 214, when the concentration data received by the controller 214 is smaller than the concentration threshold set in advance by the controller 214, the suction fan 203 will not be started at this time, when the concentration data received by the controller 214 is larger than the concentration threshold set in advance by the controller 214, the suction fan 203 will be started at this time, and simultaneously, under the cooperation of the funnel-shaped pipe 205, the first breather pipe 202, the one-way valve 207 and the second breather pipe 204, the gas absorbed from the purification workshop is directly guided into the brine in the liquid storage shell 201, at this time, the brine can directly absorb the formaldehyde contained in the guided gas, and then the treated gas can directly pass through the through hole on one of the shell plates 102 to be discharged.

The first fan 103, the evaporator 110, the condenser 111, the humidity sensor 117, the second fan 125, the compressor 131, the suction fan 203, the formaldehyde sensor 206, the check valve 207, the fan 209, the cooling sheet 211, the infrared temperature sensor 213, and the controller 214 are all of the prior art, and are not explained here 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. The utility model provides a purification workshop air inlet is with accuse wet dust remover which characterized in that: the device comprises a humidity control and dust removal mechanism (1), wherein a temperature control and degassing mechanism (2) is arranged on the humidity control and dust removal mechanism (1);

the temperature control degassing mechanism (2) comprises a liquid storage shell (201), a first ventilating pipe (202), a formaldehyde sensor (206), a cylindrical hole (208), a fan (209), a radiating fin (210), an infrared temperature sensor (213) and a controller (214), wherein a one-way valve (207) is arranged at the input end of the first ventilating pipe (202), a suction fan (203) is arranged at the input end of the one-way valve (207), a second ventilating pipe (204) is arranged at the input end of the suction fan (203), a funnel-shaped pipe (205) is arranged at the input end of the second ventilating pipe (204), a refrigerating sheet (211) is arranged on the front surface of the radiating fin (210), and a hollow block (212) is arranged on the front surface of the refrigerating sheet (211);

the humidity control and dust removal mechanism (1) comprises a shell (101), wherein the bottom of a liquid storage shell (201) is embedded at the bottom of the inner wall of the shell (101) in a sliding manner, the input end of a first ventilation pipe (202) movably penetrates through the outer wall of the shell (101), a formaldehyde sensor (206) is arranged on the outer wall of the shell (101), a detection head of the formaldehyde sensor (206) is arranged on a funnel-shaped pipe (205), and the detection end of the formaldehyde sensor (206) extends into the funnel-shaped pipe (205);

the infrared temperature sensor (213) is installed on the upper side of the inner wall of the shell (101), the detection head of the infrared temperature sensor (213) is installed on the upper side of the inner part of the shell (101), the detection end of the infrared temperature sensor (213) is installed on the lower side of the inner part of the shell (101), the shell plates (102) are installed on the front surface and the rear surface of the shell (101), the cylindrical hole (208) is formed in the front surface of one of the shell plates (102), the fan (209) is installed on the rear surface of one of the shell plates (102), the air outlet end of the fan (209) is communicated with the input end of the cylindrical hole (208), the first fan (103) is installed on one side of the shell (101), and two liquid collecting grooves (104) are formed in the inner wall of the shell (101);

the bottom of the shell (101) is fixedly provided with a sliding rail (105), the inside of the sliding rail (105) is provided with a collecting box (106), the bottoms of the inner walls of the two liquid collecting grooves (104) are fixedly penetrated with a water outlet pipe (107), the interiors of the two liquid collecting grooves (104) are respectively provided with a baffle (108), the interiors of the shell (101) are fixedly provided with four groups of rectangular blocks (109), the number of each group of rectangular blocks (109) is two, an evaporator (110) is arranged between the interiors of two groups of rectangular blocks (109), and a condenser (111) is arranged between the interiors of the other two groups of rectangular blocks (109);

the top of the two baffle plates (108) is respectively fixed with the bottom of the evaporator (110) and the bottom of the condenser (111), the output end of the condenser (111) is connected with the input end of the evaporator (110) through a first circular tube, an L-shaped partition plate (112) is fixed in the shell (101), a radiating fin (210) is arranged between one side of the L-shaped partition plate (112) and one side of the inner wall of the shell (101), a hollow block (212) is arranged between one side of the L-shaped partition plate (112) and one side of the inner wall of the shell (101), a rectangular hole (113) is formed in the inner wall of the shell (101), a porous plate (114) is fixed in the rectangular hole (113), and an air inlet pipe (115) is arranged at the input end of the first fan (103);

the utility model discloses a humidity sensor, including casing (101), inlet tube (115), filter screen (120) are all installed to the bottom of casing (101), inlet tube (115), outlet duct (116) are installed to the output of inlet tube (115), humidity transducer (117) are installed to the inside upside of casing (101), the inside upside of casing (101) is provided with processing box (118), the inner wall that runs through casing (101) is fixed to the input of processing box (118), a plurality of spacing holes (119) have been seted up to the inner wall top equidistance distribution of processing box (118), every filter screen (120) are all installed to the inside of spacing hole (119), every the bottom of filter screen (120) is all slided and is inlayed and establish in the inner wall bottom of processing box (118).

2. The moisture-control dust collector for air intake of a clean room of claim 1, wherein: the controller (214) is electrically connected with the suction fan (203), the controller (214) is electrically connected with the formaldehyde sensor (206), the controller (214) is electrically connected with the fan (209), the controller (214) is electrically connected with the refrigerating sheet (211), the controller (214) is electrically connected with the infrared temperature sensor (213), and the output end of the first ventilation pipe (202) extends to a position, close to the bottom, inside the liquid storage shell (201).

3. The moisture-control dust collector for air intake of a clean room of claim 1, wherein: the inside of handling box (118) is fixed with rectangle grid (121), the opposite side of handling box (118) is fixed to be run through has multi-way pipe (122), the outer wall of handling box (118) is provided with stopper (123), stopper (123) are installed in inside upside of casing (101), connecting pipe (124) are installed to the output of multi-way pipe (122), second fan (125) are installed to the inside upside of casing (101), the input of second fan (125) is connected with the output of connecting pipe (124).

4. A moisture control dust collector for cleaning shop air intake as set forth in claim 3, wherein: the output of second fan (125) is installed L type pipe (126), the inside upside of casing (101) is run through in the output activity of L type pipe (126) to the inside that the output of L type pipe (126) extends to casing (101) is close to the bottom position, tube cap (127) are installed to the output of L type pipe (126), a plurality of air vents (128) have been seted up to the inner wall equidistance distribution of L type pipe (126), inlet port (129) have been seted up near top position to the outer wall of casing (101).

5. The moisture-controlled dust collector for air intake of a clean room of claim 4, wherein: the utility model discloses a compressor, including casing (101), air inlet (129), air inlet, first fan (103), second fan (125), humidity transducer (117), compressor (131) are installed to metal mesh (130) in the air inlet department of inlet port (129), compressor (131) are installed to the inside downside of casing (101), the output of evaporator (110) is connected through the second pipe with the input of compressor (131), the input of condenser (111) is connected with the input of compressor (131), first fan (103) and controller (214) electric connection, evaporator (110), condenser (111), humidity transducer (117), second fan (125) and compressor (131) all with controller (214) electric connection.