JP4145701B2 - Air purification device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to an air purification device that holds an inside of a device aseptically in a wet air purification device.
[0002]
[Prior art]
Conventionally, in a clean room provided in a liquid crystal factory or the like, a method of purifying polluted air in the clean room through an air purifier and circulatingly using it is generally used. Under such circumstances, the air purification apparatus is often provided with a wet purification method. As shown in Patent Document 1, the wet purification method is a method of purifying contaminated air by removing a specific pollutant present in the contaminated air in a clean room in contact with a liquid agent. Air is circulated into the clean room as purified air.
[0003]
[Patent Document 1]
JP 2000-33221 A (see p4, FIG. 1)
[0004]
[Problems to be solved by the invention]
However, in an air purification apparatus equipped with such a wet purification method, there are many cases where microorganisms enter the apparatus from contaminated air taken in from a clean room or a liquid agent brought into contact with contaminants in the contaminated air and further propagate.
[0005]
In view of the above circumstances, an object of the present invention is to provide an air purification device capable of suppressing the invasion of microorganisms into the apparatus and the growth of microorganisms and maintaining a sterile condition.
[0006]
[Means for Solving the Problems]
  The air purification device according to claim 1 is a wet air purification device main body for purifying the contaminated air by absorbing a pollutant in the contaminated air into the liquid agent, and an air outlet provided at a lower side of the air purification device main body. Is connected to the inside of the air purification device main body, and the air purification device main body is connected to the air purification device main body, and the air purification device main body is cleaned by the air purification device main body. An air purification apparatus including an exhaust device that exhausts air as purified air to the outside, wherein the air purification device main body horizontally covers the inner side toward the opening from above the air blowing port. Arranged in order are a filler, a first watering nozzle that sprinkles the liquid agent into the filler, a demister that removes droplets in the contaminated air, and a bottom of the air purification device main body to store the liquid agent It consists of a liquid tankCleaning sectionThe first watering nozzle is provided with a water filtration filter for sterilizing the liquid agent, and each of the blower device and the exhaust device has an antibacterial filter so as to block an inner cross section. A sterile space is formed inside the air purification deviceIn addition, the air purification apparatus main body is provided with a second watering nozzle for spraying sterilizing water from a position further above the demister located above the cleaning unit, and the first watering The spraying of the liquid agent by the nozzle and the spraying of the sterilizing water by the second watering nozzle can be switched.It is characterized by that.
[0007]
The air purification device according to claim 2, wherein the filler is detachably attached to the air purification device main body, and an upper and lower end surface is open, and a state where the filler is erected on the inside of the unit case It is characterized by comprising a plurality of filler main bodies filled in.
[0008]
The air purifier according to claim 3, wherein the filler main body is fixed to the front and back surfaces of a stainless steel wire net having a 45 ° ripple in one direction from the horizontal axis by fixing means on the entire surface of the stainless steel wire mesh. It is composed of a surface material with a large surface area having durability, chemical resistance and hydrophilicity, and the outer shape is molded in the same manner as the vertical inner cross section of the unit case, and is 45 ° from the horizontal axis. A filler main body with ripples formed in one direction and a filler main body with ripples formed in a direction perpendicular thereto are in contact with the inner surface of the unit case with the surfaces facing in the same direction. It is characterized by being arranged alternately.
[0009]
The air purification device according to claim 4, wherein the filler body is formed by fixing the surface material to the front and back surfaces of the stainless steel wire mesh through fixing means, and is unidirectional at 45 ° from the horizontal axis. The plurality of filler main bodies having ripples formed thereon are alternately arranged on the front and back surfaces so that the surfaces are in contact with the inside of the unit case.
[0011]
  Claim 5The air purification device described aboveLiquid tankThe drainage pipe for draining the stored liquid stored in the tank is equipped with a microorganism monitoring device for measuring particles in the stored liquid according to particle size.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
The air purification device of the present invention includes an antibacterial filter in a blower that supplies clean room contaminated air into the air purification device body, and is used when removing contaminants in the contaminated air within the air purification device body. By providing a water filtration filter in the spray nozzle for spraying the liquid agent, an aseptic space is formed in the main body of the air purification device, and the invasion and propagation of microorganisms are suppressed.
[0013]
As shown in FIG. 1, the air purification device 1 includes an air purification device main body 2, a blower device 16, and an exhaust device 15. The air purification device main body 2 includes a cleaning unit 7 in accordance with a wet purification method for removing contaminants contained in the contaminated air 21 in the clean room using a liquid agent, and is a cylinder similar to that generally used. It is covered with an outer shell 3 having a tower shape.
An opening 4 is provided at the top end of the outer shell 3, and the opening 4 communicates with an exhaust device 15 that discharges the purified air 22 purified by the cleaning unit 7 to a clean room. The exhaust device 15 includes an exhaust blower fan 15a, a heating coil 15b, and an antibacterial filter 15c. The antibacterial filter 15c removes the microorganism when the purified air 22 that passes through the microorganism contains the microorganism. The heating coil 15b heats the passing purified air 22 to a predetermined temperature required for the clean room, and the exhaust blower fan 15a uniformly exhausts the purified air 22 after the post-treatment into the clean room. It is.
[0014]
  In the middle part of the outer shell 3, a demister 8 is disposed horizontally so as to close the inside, and in order downward, a first water spray nozzle 9, a filler 10, and a rectifying hole. An open plate 13 is arranged at the bottom of the outer shell 3Liquid tank6 is provided to constitute the cleaning unit 7.
  The demister 8 is generally used as a member for removing droplets in a processing gas that accompanies the generation of fine droplets. For example, stainless steel fibers or glass fibers are stacked in a mesh pattern, or polypropylene fibers or the like are used. It is formed by processing such as weaving into a filter cloth.
[0015]
The first water spray nozzle 9 sprays the liquid 18 that absorbs pollutants contained in the contaminated air 21 to the inside of the outer shell 3, and the sprayed liquid 18 is contaminated air 21. Water, an alkaline solution, an acidic solution, or the like is used depending on the type of contaminant contained in the. These liquid agents 18 are stored in a water storage tank 14 directly connected to the first watering nozzle 9, and after being sterilized through the water filter 9a provided in the first watering nozzle 9, It is supplied to the outer shell 3.
Here, the water filtration filter 9a generally has a function of removing microorganisms remaining in the liquid. In the present embodiment, a plurality of water filtration filters 9a having a gradually reduced filtration diameter are provided in the first step. One watering nozzle 9 is provided. At this time, since bacteria and fungi are generally known as substances having a particle size of 0.5 μm or more, if the final filtration diameter of the water filtration filter 9a is set to 0.1 μm, the microorganism of the liquid 18 Can be completely removed.
The first watering nozzle 9 is configured to spray only the liquid 18 supplied from the water storage tank 14 without circulating the liquid 18.
[0016]
Next, the filler 10 is used for the purpose of improving the contact efficiency between the liquid 18 and the contaminated air 21, and is filled in the unit case 11 and the unit case 11 as shown in FIG. A plurality of filler main bodies 12. The unit case 11 has a frame shape in which the upper surface and the lower surface are opened, and has a plan view shape that matches the inner side of the outer shell 3, and a part of the unit case 11 that can be opened and filled inwardly. The material main body 12 can be freely inserted and removed.
Further, the filler main body 12 is hydrophilic and has a large surface area so that the liquid agent 18 having a particle size sprayed from the first watering nozzle 9 located above is easily attached to the surface. Any material that has durability that does not decompose or become brittle when exposed to acids, alkalis, or organic gases, is not only resistant to chemicals, but also does not generate contaminants from itself. May be. Furthermore, it is more preferable if the filler main body 12 has antibacterial properties.
[0017]
In the present embodiment, as shown in FIG. 3A, the filler main body 12 is made of a hydrophilic polyester cloth woven in a honeycomb shape for the purpose of increasing the surface area as a surface material 12a. For the purpose of increasing the width, the plate is formed by integrally fixing to the entire surface of the plate-like stainless steel wire mesh 12b having ripples formed on the front and back surfaces through fixing means such as fusion or sewing. In addition, the outer shape of the filler main body 12 is the same as the inner cross-sectional shape of the unit case 11 in plan view, and the ripples are arranged on the front and back surfaces with a ripple inclined in one direction of 45 ° from the horizontal axis. Molded.
[0018]
As shown in FIG. 2 (a), the filler main body 12 described above has ripples arranged in a direction inclined by 45 ° from the horizontal axis when viewed from the surface, and ripples in a direction perpendicular thereto. There are two types of products. The filler body 12a and the filler body 12b are alternately stacked such that the surfaces are in contact with each other with the surfaces facing in the same direction, and the interior of the unit case 11 is filled by placing them vertically. The material 10 is constituted.
The filler 10 configured in this way is arranged so as to horizontally block the inside of the outer shell 3 with a predetermined layer thickness, so that washing and sterilization operations can be performed when microorganisms propagate. The outer shell 3 is detachable.
[0019]
In the present embodiment, the filler main body 12 has a configuration in which the surface material 12a is fixed only to the surface of the stainless wire mesh 12b. However, this is not necessarily limited to this, and as shown in FIG. In addition, the surface material 12a may be fixed to both the front and back surfaces of the stainless wire mesh 12b. In this case, when the inside of the unit case 11 is filled, the plurality of filler main bodies 12 may be arranged vertically so that the surfaces contact each other after the front and back surfaces are alternately arranged.
Further, in the present embodiment, the unit case 11 is formed in a rectangular parallelepiped shape. However, the unit case 11 is not necessarily limited to this, and can be arranged so as to horizontally close the inner side of the outer shell 3 and be detachable. If possible, it may be produced in any shape. Accordingly, the shape of the filler main body 12 is also changed in accordance with the inner cross-sectional shape of the unit case 11.
[0020]
As shown in FIG. 2B, the filler 10 having the above-described configuration is configured such that adjacent filler main bodies 12 abut on each other in the form of dots at the tops of ripples arranged orthogonally. For this reason, when the liquid agent 18 is sprayed from the first watering nozzle 9, the liquid agent 18 flowing on the top of a certain ripple is advected at the contact point and diffused to the adjacent top, and spreads over the entire surface of the filler body 12. A water film can be formed uniformly.
Further, when the surface material 12a is fixed to the stainless wire mesh 12b by sewing, the filler body 12 is sewn along the ripples 12c as shown in FIGS. 3 (a) and 3 (b). The liquid agent 18 flowing through the ripple groove can be diffused over the entire filler body 12 to form a water film over a wide range, and the water film can be formed more uniformly over the entire surface of the filler body 12.
[0021]
  next,Cleaning sectionThe liquid tank 6 that constitutes 7 absorbs contaminants contained in the contaminated air 21, and the liquid agent 18 that has flowed down according to gravity on the front and back surfaces of the filler body 12 that constitutes the filler 10 serves as a primary liquid storage agent 19. It is to be stored. The liquid tank 6 is provided with a drain pipe 6a for draining the stored liquid agent 19, and the drained stored liquid agent 19 is processed in an organic waste water treatment tank (not shown).
[0022]
On the other hand, a blower port 5 is provided below the outer shell 3 and slightly above the liquid tank 6, and the blower device 16 communicates with the blower port 5. The blower 16 has one end fixed to the blower opening 5 of the outer shell 3, and is provided inside the blower pipe 17 and the blower pipe 17 communicating with the outer shell 3 so as to block the inner cross section. The cooling coil 17a and the antibacterial filter 17b are arranged.
Such an air blower 16 takes the contaminated air 21 in the clean room into the inside of the air duct 17, cools it via the cooling coil 17a, and then removes microorganisms in the contaminated air 21 via the antibacterial filter 17b. Above, the polluted air 21 is sent inward of the air purification apparatus main body 2.
[0023]
As described above, in the air purification device 1, the antibacterial filter 17 b is provided in the blower 16 that communicates with the blower opening 5 of the outer shell 3 that constitutes the air purification device main body 2, and communicates with the opening 4 of the outer shell 3. Since the exhaust device 15 is provided with an antibacterial filter 15c, and the first watering nozzle 9 is provided with a water filtration filter 9a, a completely sterile space is formed inside the air purification device main body 2. The Rukoto.
[0024]
  A procedure for purifying the contaminated air 21 using the air purification apparatus 1 having the above-described configuration will be described in detail below with reference to FIG. The polluted air 21 discharged at factories or the likeBlower 16The air flow is taken into the blast pipe 17 to become a horizontal flow, cooled by the cooling coil 17a, and after passing through the antibacterial filter 17b to remove microorganisms, below the outer shell 3 constituting the air purification device main body 2. It is sent inward from the air blowing port 5 provided.
[0025]
The polluted air 21 sent inward of the outer shell 3 rises and is rectified by passing through the rectifying hole opening plate 13 and then passes through the filler 10. At this time, the granular liquid 18 sprayed from the first watering nozzle 9 adheres to the surface of the filler main body 12 constituting the filler 10, and a water film is formed on the surface. The contaminated air 21 passing through the gas efficiently makes gas-liquid contact with the water film, and the pollutants in the contaminated air 21 are transferred to the liquid agent 18 forming the water film.
Further, the contaminated air 21 that has passed through the filler 10 and has risen again comes into direct gas-liquid contact with the granular liquid 18 sprayed from the first sprinkling nozzle 9, and contaminants remaining in the contaminated air 21 migrate. The contaminated air 21 is purified.
[0026]
The purified air 22 purified through these steps collects droplets of the liquid 18 in the demister 8 and then exhausts it to the exhaust device 15 through the opening 4 provided above the outer shell 3 for antibacterial action. After passing through the filter 15c and sterilizing again, it is heated to a desired temperature via the heating coil 15b, and then exhausted to the outside using the exhaust fan 15a.
[0027]
Incidentally, as shown in FIG. 1, the drain pipe 6 a provided in the liquid tank 6 is provided with a monitoring device 24 for monitoring the stored liquid agent 19 in the liquid tank 6. The monitoring device 24 is provided with a measuring device 24a capable of measuring particles in water according to particle size, a drain tank 24b, and a nutrient tank 24c, and primarily stores the liquid storage agent 19 flowing down the drain pipe 6a into the drain tank 24b. Then, in a state where aseptic nutrient is added from the nutrient tank 24c, sterilized air is blown off, oxygen is supplied, and the mixture is left for a certain period of time. Thereafter, the turbidity of the stored liquid agent 19 primarily stored in the drain tank 24b is measured by the measuring device 24a, whereby the particles in the water are measured for each particle size. By such a method, bacteria and fungi known as substances generally having a particle size of 0.5 μm or more are detected.
Note that the monitoring device 24 is not necessarily limited to this, and any configuration may be used as long as the device can measure the particles remaining in the liquid storage agent 19 for each particle size and detect bacteria and fungi.
[0028]
A second watering nozzle 23 is provided in the outer shell 3 and above the demister 8. The second water spray nozzle 23 sprays the sterilizing water 20 over the entire inside of the outer shell 3 and kills microorganisms that flow into or propagate inside the outer shell 3. Here, the sterilizing water 20 is generated by being mixed with the liquid agent 18 by supplying the sterilizing agent 20a to the water storage tank 14 from the tank 14a for the sterilizing agent provided in the water storage tank 14, The second watering nozzle 23 is connected to the water storage tank 14. In this embodiment, 1.0 to 5.0% hydrogen peroxide solution is used as the sterilizing water 20.
[0029]
A method of sterilizing the air purification device main body 2 using the second watering nozzle 23 and the monitoring device 24 will be described below.
First, the monitoring device 24 confirms microorganisms in the stored liquid agent 19, and if it is confirmed, the purification operation of the contaminated air 21 is promptly interrupted, and the water storage tank 14 is filled with a sterilizing agent tank 14a. The sterilizing water 20 is generated from the liquid 18 by supplying the sterilizing drug 20 a. Thereafter, the connection with the water storage tank 14 is switched from the first watering nozzle 9 to the second watering nozzle 23, and the sterilized water 20 is sprayed to the inside of the outer shell 3 through the second watering nozzle 23. .
[0030]
The sprayed sterilizing water 20 flows down not only the inner wall of the outer shell 3 but also the demister 8, the first watering nozzle 9, the filler 10, and the rectifying hole opening plate 13 while sterilizing the liquid tank 6. And is drained through the drain pipe 6a. The drained stored liquid agent 19 is monitored using the monitoring device 24, and when it is confirmed that the microorganism has been sterilized, the spraying of the sterilizing water 20 by the second watering nozzle 23 is stopped.
Thereafter, the sterilizing water 20 in the water storage tank 14 is discarded and switched back to the liquid 18, and the connection with the water storage tank 14 is switched from the second water spray nozzle 23 to the first water spray nozzle 9. 3 is sprayed with the liquid 18 through the first watering nozzle 9 and the purification operation of the contaminated air 21 is resumed.
[0031]
Note that the operation of spraying the sterilizing water 20 on the outer shell 3 using the second watering nozzle 23 is not necessarily performed only after microorganisms are confirmed by the monitoring device 24 as described above. The operation of the apparatus 1 may be performed in advance, and the prior sterilization work can further suppress the propagation of microorganisms inside the outer shell 3.
[0032]
In order to grasp these effects, the removal rate of the pollutant in the polluted air 21 was calculated using the air purification apparatus 1 shown in the present embodiment. In addition, as conditions, the inflow wind speed of the contaminated air 21 is 1.5 m / s, the cross-sectional area of the outer shell 3 provided in the air purification device main body 2 is 0.3 × 0.3 m, and the member thickness of the filler 10 is 1.0 m. The liquid gas ratio of liquid 18 is 0.12kg / m³ It is assumed that it is set as.
As a result, the air purification apparatus 1 can remove these pollutants up to about 89.2 to 99.0% with respect to the polluted air 21 containing the mixed gas of propylene glycol monomethyl ether and propylene glycol monomethyl ether acetate as the pollutants. confirmed.
In addition, at this time, the air purification apparatus main body 2 spreads the sterilizing water 20 in the inner part of the outer shell 3 from the 2nd watering nozzle 23 in advance, and is working after sterilization work is complete | finished. The first watering nozzle 9 is provided with a three-stage water filtration filter 9a of 10 μm, 0.5 μm, and 0.2 μm, and the liquid 18 passes through these in order to remove microorganisms in advance. Yes. For this reason, although the air purification apparatus 1 was continuously operated for 2 weeks under the above-described conditions, the monitoring apparatus 24 did not detect microorganisms.
[0033]
According to the configuration described above, the air purification apparatus 1 includes the first watering nozzle 9 provided with the water filtration filter 9a for removing microorganisms contained in the liquid agent 18 in advance, and the contaminated air 21 Since the air blower 16 that is the supply port is provided with an antibacterial filter 17b that removes microorganisms contained in the contaminated air 21 in advance, the invasion of microorganisms from the outside to the inside of the air purification device main body 2 is performed in advance. A sterile space to be prevented can be formed, and it is possible to suppress the invasion and propagation of microorganisms into the air purification device main body 2.
In addition, even when microorganisms are generated in the air purification device main body 2, the exhaust device 15 is provided with the antibacterial filter 15c. Therefore, the purified air 22 passes through the antibacterial filter 15c to remove the microorganisms, and then clean room. The clean room will not be polluted.
Further, the cleaning unit 7 of the air purification device 1 sprays the liquid agent 18 from above, forms a water film on the surface of the filler 10, and passes contaminated air upward from below the filler 10. This is a so-called wet surface removal method that allows contaminant air to come into contact with the water film to absorb the pollutant, thus maintaining high removal efficiency when removing the contaminant because the contaminated air and water contact each other in a counterflow. It becomes possible to do.
[0034]
The filler 10 provided in the air purification device main body 2 is composed of a plurality of filler main bodies 12 and a unit case 11 for storing them, and is configured to be detachable from the air purification device main body 2. Therefore, since the cleaning can be easily carried out up to the filler main body 12 even when the growth of microorganisms is observed, the complexity of maintenance can be avoided and the cost related to maintenance can be greatly reduced. Is possible.
[0035]
In the filler main body 12, a surface material 12a having a large surface area having durability, chemical resistance, and hydrophilicity is integrally fixed to a surface of a stainless steel wire mesh 12b having ripples formed on the front and back surfaces thereof through a fixing means. In the unit case 11, the filler main body 12 in which ripples are arranged in one direction of a horizontal axis of 45 ° and the filler main body 12 in which ripples are arranged so as to be orthogonal to the horizontal direction are manufactured. The surfaces were alternately arranged in the same direction so that the surfaces contact each other. As a result, the adjacent filler main bodies 12 abut the tops of the ripples at points, so that the liquid 18 that has flowed down from the top to the bottom of the ripples is transferred and diffused at the contact parts, and the filler A uniform water film can be formed on the entire body 12.
[0036]
Moreover, if the surface material 12a is fixed to the front and back surfaces of the stainless steel wire mesh 12b of the filler main body 12, the ripples are arranged in one of the 45 ° directions from the upper and lower end surfaces, and the ripples are arranged in a direction orthogonal thereto. Therefore, it is not necessary to manufacture two types of materials, and the manufacturing of the filler main body 12 can be simplified.
[0037]
Further, a second watering nozzle 23 is provided above the cleaning portion 7 in the outer shell 3, and the sterilizing water 20 is sprinkled inside the outer shell 3. Sterilization can be easily carried out even when microorganisms invade or propagate inside. In addition, by carrying out the sterilization work using the second watering nozzle 23 in advance of the purification work of the contaminated air 21, the propagation of microorganisms inside the outer shell 3 can be more effectively suppressed. Is possible.
[0038]
    Also, provided at the bottom of the air purification device body 2Liquid tank6 is provided with a monitoring device 24 for measuring particles in water according to particle size.Liquid tank6 can detect the presence or absence of microorganisms that propagate in the stored liquid agent 19 primarily stored, and can easily determine the necessity of cleaning the air purification device main body 2.
[0039]
【The invention's effect】
  According to the air purification device of the first aspect, the wet air purification device main body for purifying the contaminated air by absorbing the pollutant in the contaminated air into the liquid agent, and the lower portion of the side surface of the air purification device main body are provided. The air purification device main body communicates with the air blowing device, and the air purification device main body communicates with the air blowing device that feeds the contaminated air into the inside of the air purification device main body, and the opening provided in the upper portion of the air purification device main body. An air purifier including an exhaust device that exhausts the contaminated air outward as purified air, and the air purifier main body horizontally covers the inside from the top of the blower opening to the opening. Disposed in order, a filler, a first watering nozzle for sprinkling the liquid agent on the filler, a demister for removing droplets in the contaminated air, and a bottom part of the air purification device main body. It consists of a reservoirCleaning sectionThe first watering nozzle is provided with a water filtration filter for sterilizing the liquid agent, and each of the blower device and the exhaust device has an antibacterial filter so as to block an inner cross section. A sterile space is formed inside the air purification deviceThe air purification device main body is provided with a second watering nozzle for spraying sterilizing water from a further upper position of the demister located at the uppermost part of the cleaning unit. It is comprised so that switching of spraying of the liquid agent by a watering nozzle and spraying of sterilizing water by the 2nd watering nozzle is possible..
[0040]
  Thereby, it is possible to form an aseptic space for preventing microorganisms from entering the inside of the air purification device main body from the outside in advance, and it is possible to suppress the propagation of microorganisms into the air purification device main body.
  In addition, even when microorganisms are generated in the air purification device main body, the exhaust device is equipped with an antibacterial filter, so that the purified air passes through the antibacterial filter and is removed into the clean room after removing the microorganisms. And will not pollute the clean room.
  Further, the cleaning unit of the air purifying device sprays the liquid agent from above, forms a water film on the surface of the filler, and passes the contaminated air from below to below the filler, thereby forming a water film This is a so-called wet surface removal method that allows contaminant air to contact with water and absorbs the pollutant, so that the contaminated air and water come in contact with each other in a counterflow, so that it is possible to maintain high removal efficiency when removing contaminants. Become.
In addition, since the sterilizing water can be sprayed from the second watering nozzle to the air purification device main body, the sterilization work can be easily performed even when microorganisms enter or propagate inside the air purification device main body. Is possible. In addition, by performing the sterilization work using the second watering nozzle in advance of the purification work of the contaminated air, it is possible to more effectively suppress the growth of microorganisms inside the outer shell. is there.
[0041]
According to the air purification device of claim 2, the filler is detachable from the air purification device main body and has an upper and lower end surface open, and a unit case standing on the inside of the unit case Since it is composed of a plurality of filler bodies that are filled in a clean state, cleaning up to the filler body can be easily performed even when microbial growth is observed, reducing the complexity of maintenance. This can be avoided and the cost for maintenance can be greatly reduced.
[0042]
According to the air purification device of claim 3, the filler main body is formed of a stainless steel wire net having a 45 ° ripple in one direction from the horizontal axis on the front and back surfaces, and a fixing means on the entire surface of the stainless steel wire mesh. It is composed of a surface material with a large surface area that has durability, chemical resistance and hydrophilicity, and has an outer shape molded in the same manner as the inner cross section in the vertical direction of the unit case. ° The filler body with ripples formed in one direction and the filler body with ripples formed in the direction perpendicular to the inner surface of the unit case with the surfaces facing in the same direction Arrange them alternately so that they touch each other.
As a result, the adjacent filler main bodies abut the tops of the ripples at the points, so the liquid agent that has flowed down the top of the ripples from the upper direction to the lower side is transferred and diffused at the contact parts, and the filler main body A uniform water film can be formed throughout.
[0043]
According to the air purification device of claim 4, the main body of the filler is formed by fixing the surface material to the front and back surfaces of the stainless steel wire mesh through fixing means, and is 45 ° from the horizontal axis. Since the front and back surfaces are alternately arranged so that the surfaces are in contact with the inner side of the unit case, the plurality of filler main bodies having ripples formed in one direction, and the ripples are in one 45 ° direction from the upper and lower end surfaces. There is no need to produce two types of filler bodies, i.e., a filler body with ripples arranged in a direction perpendicular thereto, and the production of the filler body can be simplified.
[0045]
    Claim 5According to the air purification device described above,Liquid tankThe drainage pipe that drains the stored liquid stored in the tank is equipped with a microbial monitoring device that measures particles in the stored liquid according to particle size,Liquid tankTherefore, it is possible to detect the presence or absence of microorganisms that propagate in the stored liquid agent that is primarily stored, and to easily determine the necessity of cleaning the air purification device main body.
[Brief description of the drawings]
FIG. 1 is a diagram showing an outline of an air purification device of the present invention.
FIG. 2 is a diagram showing details of the filler of the air purification device of the present invention.
FIG. 3 is a view showing details of a filler main body of the air purification apparatus of the present invention.
[Explanation of symbols]
1 Air purification device
2 Air purifier body
3 outer shell
4 openings
5 Blower
6 Liquid tank
6a Drain pipe
7 Cleaning section
8 Demister
9 First watering nozzle
9a Water filtration filter
10 Filler
11 Unit case
12 Filler body
12a Surface material
12b stainless steel wire mesh
13 Opening plate for rectification
14 Water tank
14a Tank for disinfectant drug
15 Exhaust device
15a Exhaust fan
15b Heating coil
15c Antibacterial filter
16 Blower
17 Air duct
17a Cooling coil
17b Antibacterial filter
18 liquids
19 Reservoir
20 Bactericidal water
21 Contaminated air
22 Purified air
23 Second watering nozzle
24 Monitoring device
24a Measuring equipment
24b Drain tank
24c nutrient tank

Claims (5)

A wet air purification device main body that purifies the contaminated air by absorbing the pollutants in the contaminated air into the liquid agent;
A blower connected to the blower opening provided at the lower side of the side surface of the air purification device main body, and for sending contaminated air into the inside of the air purification device main body;
An air purification device comprising an exhaust device that communicates with an opening provided in an upper portion of the air purification device main body and exhausts the contaminated air purified by the air purification device main body outward as purified air,
The air purification device main body is arranged in order from the upper side of the air blowing port toward the opening so as to horizontally block the inside, and a first watering nozzle that sprinkles the filling material and the liquid agent into the filling material. and a demister to remove droplets of pollution in the air, is disposed at the bottom of the air cleaner main body, it comprises a cleaning unit for liquid is composed of a liquid tank for storing,
The first watering nozzle is provided with a water filter for sterilizing the liquid agent, and each of the blower and the exhaust device is provided with an antibacterial filter so as to close an inner cross section, Aseptic space is formed inside the purification device body ,
And in the said air purification apparatus main body, the 2nd watering nozzle for spraying sterilizing water from the further upper position of the said demister located in the upper part of the said washing | cleaning part is installed, and the said 1st watering nozzle An air purifier configured to be able to switch between spraying of a liquid agent and spraying of sterilizing water by the second watering nozzle . The air purification device according to claim 1,
A unit case in which the filler is detachable from the air purification device main body and whose upper and lower end surfaces are open, and a plurality of filler main bodies filled in a standing manner in the unit case An air purifier characterized by comprising. The air purification apparatus according to claim 2,
The filler main body is fixed on the front and back surfaces of a stainless steel wire mesh having a 45 ° ripple in one direction from the horizontal axis by fixing means on the entire surface of the stainless steel wire mesh, and has durability, chemical resistance and hydrophilicity. The outer shape is formed in the same manner as the inner cross section in the vertical direction of the unit case.
A filler main body with ripples formed in one direction of 45 ° from the horizontal axis and a filler main body with ripples formed in a direction perpendicular thereto are directed inward of the unit case and in the same direction. An air purification device characterized by being alternately arranged so that the surfaces touch each other. In the air purification apparatus of Claim 3,
The filler main body is formed by fixing the surface material to the front and back surfaces of the stainless steel wire mesh through fixing means,
A plurality of the filler main bodies having ripples formed in one direction of 45 ° from the horizontal axis are alternately arranged on the front and back surfaces of the unit case so that the surfaces are in contact with each other. apparatus. In the air purifying device according to any one of claims 1 to 4 ,
An air purification apparatus, wherein a drainage pipe for draining a stored liquid stored in the liquid tank is provided with a microorganism monitoring apparatus that measures particles in the stored liquid according to particle size.

Images