KR102236823B1 - Air purification device having combined functions for reduction of ultrafine dust and carbon dioxide and sterilization in multi-use facilities - Google Patents

Abstract

The present invention relates to an air purifying device which can be automatically controlled according to a one-touch-type or touch-type setting mode so as to collect ultrafine dust and purify air in a multi-use facility, reduce a concentration of carbon dioxide in the multi-use facility, and kill harmful bacteria or viruses, thereby performing sterilization and disinfection. To this end, the present invention comprises: a scrubber unit (100) which purifies air introduced through an air inlet (101) connected to a first indoor duct (110) communicating with one side of the multi-use facility indoors (R); a water tank (200) which is installed on a lower portion of the scrubber unit (100) and stores washing water for purifying air and accommodates washing water falling from the scrubber unit (100); an intake/exhaust unit (300) which is installed on an upper portion of the scrubber unit (100), provided on an inner side of a blower (311), introduces air into the scrubber unit (100) via the air inlet (101), and includes an exhaust port (301) provided on an upper portion thereof and connected to a second indoor duct (310) communicating with the other side of the multi-use facility indoors (R); and a controller (700) which controls the washing water stored in the water tank (200) to be supplied to the scrubber unit (100), controls an operation of the blower (311) such that air is introduced into the scrubber unit (100), and controls opening and closing of a first air valve unit (400), a second air valve unit (500), and a third air valve unit (600) according to one mode selected from among a circulation mode, a discharge mode, a reduction mode, and a disinfection mode through a touch-type control panel (710).

Description

Air purification device having combined functions for reduction of ultrafine dust and carbon dioxide and sterilization in multi-use facilities}

The present invention relates to an air purifying apparatus for both reducing and sterilizing and sterilizing ultrafine dust and carbon dioxide indoors in a multi-use facility, and is automatically controlled according to a one-touch or touch-type setting mode to collect and purify ultra-fine dust in multiple facilities and It reduces the concentration and relates to a device capable of sterilizing and sterilizing harmful bacteria or viruses.

Recently, the interest in indoor air purification and sterilization is increasing rapidly due to the coronavirus infection outbreak worldwide. In particular, since the probability of spreading coronavirus infection in multi-use facilities is very high, air purification in multi-use facilities is indispensable.

In general, air purifiers are designed to purify dust and harmful elements by introducing indoor air into the interior and then discharge them back into the room where the user resides. Therefore, in order to maximize the effect of air purification, the indoor air must be sealed before use. There is this.

In this case, if indoor ventilation is not performed for a long period of time, even if the air purifier is operated, the indoor carbon dioxide concentration rises and has adverse effects such as virus transmission, so periodic indoor ventilation is essential.

However, most of the air purifier users are aware of the need for indoor ventilation as described above, but they are concerned about the introduction of polluted air and fine dust into the room during indoor ventilation, and are cumbersome to ventilate the room, so they hesitate to ventilate the room. There is a situation.

Accordingly, there is a need to develop an air purification device that removes and purifies indoor air in a multi-use facility by removing ultra-fine dust and harmful viruses in an automatic control method, and ventilating to reduce carbon dioxide.

Registered Patent No. 10-2116381

The present invention was conceived to solve the above problems, and an object of the present invention is automatically controlled according to a one-touch or touch-type setting mode to collect and purify ultrafine dust in multiple facilities, and to ventilate the indoor carbon dioxide with purified outdoor air. It is to provide an air purification device for reducing the concentration and sterilizing and sterilizing and sterilizing ultrafine dust indoors in a multi-use facility that can sterilize and sterilize harmful bacteria or viruses.

In order to achieve the above object, the air purifier for ultra-fine dust and carbon dioxide reduction and sterilization and disinfection in a multi-use facility indoors according to the present invention is installed in a multi-use facility to reduce ultra-fine dust and carbon dioxide, and sterilize and disinfect the air. An air purification device for reducing ultrafine dust, carbon dioxide and sterilizing and disinfecting indoors of a multi-use facility, comprising: a scrubber unit for purifying air introduced through an air inlet connected to a first indoor duct communicated with one side of the indoor of a multi-use facility; A water tank installed under the scrubber unit, storing washing water for purifying air, and accommodating washing water falling from the scrubber unit; It is installed on the top of the scrubber unit, and has a blower inside to inflow air into the scrubber unit through the air inlet, and has an exhaust port connected to the second indoor duct in communication with the other side of the room of the multi-use facility at the top. Intake and exhaust; A first air valve unit installed in the second indoor duct to control the flow of air; A first outdoor duct communicating with the first indoor duct and introducing external air; A second air valve unit installed in the first outdoor duct to control the flow of air; A second outdoor duct communicating with the second indoor duct and exhausting air inside the multi-use facility; A third air valve unit installed in the second outdoor duct to control the flow of air; And controlling the washing water stored in the water tank to be supplied to the scrubber unit, controlling the drive of the blower so that air is introduced into the scrubber unit, and controlling the circulation mode, the discharge mode, the reduction mode, and the disinfection mode through a touch control panel. And a controller for controlling opening/closing of the first air valve part, the second air valve part, and the third air valve part according to a mode set to any one of them.

In one embodiment of the present invention, the scrubber portion has a plurality of through holes and a perforated plate installed in a horizontal direction inside the scrubber portion, a plurality of polling members stacked on the perforated plate, and a mesh installed on the upper side of the polling member A mesh, a washing water injection unit installed on the upper side of the mesh network and spraying the washing water supplied from the washing water supply pipe connected to the water tank downward, and a plurality of vertically installed on the air inlet side while being under the perforated plate An air guiding member having an arc-shaped longitudinal section and being installed at a certain distance from each other, a viewing window provided on one side to check the state of the polling member or the internal state of the scrubber unit, and a scrubber installed on the inner side of the scrubber unit And a spray nozzle connected to the disinfectant spray unit installed on the outer surface of the unit to spray the disinfectant solution into the scrubber unit, and a demister installed above the washing water injection unit and below the intake/exhaust unit.

In addition, the washing water spraying unit is connected to the washing water supply pipe and disposed above the mesh net inside the scrubber unit, and a plurality of washing water is installed in the washing water branch pipe to inject the washing water supplied downward. Includes a spiral nozzle.

In one embodiment of the present invention, the disinfectant spray unit is installed on the outer surface of the scrubber unit and the disinfectant container is stored, the disinfectant supply pipe is installed outside the scrubber unit to connect the disinfectant container and the spray nozzle, and the controller is electrically A spray pump installed on the disinfectant supply pipe while being connected to the disinfectant supply pipe to supply the disinfectant solution stored in the disinfectant solution container at high pressure to the spray nozzle, and the disinfectant supply pipe being electrically connected to the controller and installed on the disinfectant supply pipe to open/close the disinfectant supply pipe It includes a first solenoid valve.

In addition, as an embodiment of the present invention, the water tank is disposed inside the water tank while being electrically connected to the controller to measure the pH of the washing water, and the water tank is disposed inside the water tank while being electrically connected to the controller. A temperature sensor for measuring the temperature of the washing water, and a heater electrically connected to the controller and disposed inside the water tank to heat the washing water.

In addition, a water supply pump for supplying the washing water from the water tank to the washing water injection unit is installed on the washing water supply pipe, and the water supply pump is electrically connected to the controller and is controlled by the controller.

In addition, as a preferred embodiment, a solution container in which sodium hydroxide solution is stored is provided on an outer surface of the scrubber, and the solution container is connected to the water tank through a solution supply pipe, and the solution is electrically connected to the controller on the solution supply pipe. A second solenoid valve for controlling opening and closing of the supply pipe is installed.

In one embodiment, the first air valve unit is rotatably installed inside the second interior duct by a first rotation shaft to open and close the flow path of the second interior duct, and an outer side of the second interior duct. And a first motor unit connected to the first rotation shaft while being installed in the first rotation shaft to rotate the first opening/closing hole through the first rotation shaft.

In addition, the second air valve unit is rotatably installed inside the first outdoor duct by a second rotation shaft to open and close the flow path of the first outdoor duct, and the second air valve unit is installed outside the first outdoor duct. It includes a second motor connected to the second rotation shaft to rotate the second opening and closing through the second rotation shaft.

In addition, the third air valve unit is rotatably installed inside the second outdoor duct by a third rotation shaft to open and close the flow path of the second outdoor duct, and the third air valve unit is installed outside the second outdoor duct. It includes a third motor connected to the third rotation shaft to rotate the third opening and closing through the third rotation shaft.

In one embodiment, the first opening, the second opening, and the third opening and closing are formed in a circular shape, but to reliably seal the flow path of the second indoor duct, the flow path of the first outdoor duct, and the flow path of the second outdoor duct, respectively. For this reason, sealing members made of rubber are provided on the outer periphery of each.

In addition, as an embodiment, the first motor unit, the second motor unit, and the third motor unit are each electrically connected to the controller to control rotational driving by the controller, and the second motor unit is When the flow path is opened, the rotation angle of the second opening and closing may be adjusted according to the setting through the touch control panel so that the amount of external air introduced through the first outdoor duct can be adjusted.

In a preferred embodiment of the present invention, in the circulation mode, the first opening and closing of the first air valve unit is opened under the control of the controller, so that the flow path of the second indoor duct is communicated, and at the same time, the second opening and closing of the second air valve unit and the third opening are opened. The third opening and closing of the air valve part is closed to block the flow path of the first outdoor duct and the flow path of the second outdoor duct, so that the air in the multi-use facility enters the scrubber through the first indoor duct and is purified. Control is to be discharged back into the room of the multi-use facility through the duct.

In addition, in the discharge mode, the third opening and closing of the third air valve unit is opened by the control of the controller, so that the flow path of the second outdoor duct is communicated, and at the same time, the first opening and closing of the first air valve unit and the second opening and closing of the second air valve unit are Is closed and the flow path of the second indoor duct and the flow path of the first outdoor duct are blocked, so that the air in the multi-use facility flows into the scrubber through the first indoor duct, is purified, and then discharged to the outside through the second outdoor duct. Control it as much as possible.

In addition, in the reduction mode, the first opening and closing ports of the first air valve unit and the second opening and closing ports of the second air valve unit are opened under the control of the controller, so that the flow path of the second indoor duct and the flow path of the first outdoor duct are communicated. The third opening and closing of the 3 air valve unit is closed to block the flow path of the second outdoor duct, so that the air in the multi-use facility is mixed with the outside air introduced through the first outdoor duct through the first indoor duct, and then in the scrubber unit. After purification, it is discharged to the interior of the multi-use facility through the second indoor duct, so that the concentration of carbon dioxide in the interior of the multi-use facility is reduced.

In the disinfection mode, the first solenoid valve opens the disinfectant supply pipe under the control of the controller, and the spray pump is driven so that the disinfectant solution of the disinfectant container is sprayed from the spray nozzle, and the first opening and closing of the first air valve part is When the flow path of the second indoor duct is opened and communicates with the flow path of the second indoor duct, the second opening and closing of the second air valve part and the third opening and closing of the third air valve part are closed to block the flow path of the first outdoor duct and the flow path of the second outdoor duct. The control is to allow the air in the indoor of the use facility to flow into the scrubber through the first indoor duct, be purified and sterilized, and then discharged back to the indoor of the multi-use facility through the second indoor duct.

In addition, as an embodiment, the polling member has a purification layer formed on an outer surface or an inner surface thereof, and the purification layer includes mordenite, talc, pearlite, diatomaceous earth, sericite, cryolite, peat moss, silvite, vermiculite, bentonite, zeolite, and tourmaline. Contains ingredients.

In addition, as a preferred embodiment, in order to achieve a safer and more reliable dust collection and air purification effect, a carbon filter or a HEPA filter may be installed on the air inlet side or on the upper side of the demister.

When the air purification device of the present invention is installed in a multi-use facility where multiple people gather, such as school classrooms, gymnasiums, auditoriums, libraries, catering rooms, daycare centers, churches, indoor golf driving ranges, etc., the concentration of ultrafine dust and carbon dioxide in the air in the multi-use facility Since the concentration can be reliably reduced, not only can the indoor air quality be managed economically and conveniently, but also the spread of coronavirus in multi-use facilities can be effectively blocked.

In particular, the present invention has a function of collecting and purifying ultrafine dust in multiple facilities, a function of reducing the concentration of carbon dioxide in the facility by ventilating it with purified outdoor air, and sterilizing and disinfecting harmful bacteria or viruses through indoor disinfection when circulating indoor air. The function can be performed complexly in one device in an automatic control method through the one-touch control mode, so that the device user can conveniently and effectively operate various functions.

1 shows the appearance of an air purification apparatus according to an embodiment of the present invention.
2 is a view for explaining a state of use of the air purification apparatus according to the present invention.
3 is a view for explaining the configuration of an air purification apparatus according to the present invention.
4A and 4B are views showing an air inlet, a perforated plate, and an air guiding member of the present invention.
5A to 5C are views showing the configuration of a scrubber unit according to an embodiment of the present invention.
6 is a view for explaining a configuration connected to the water tank of the present invention.
7 is a view showing a washing water supply pipe, a feed pump, and the like according to an embodiment of the present invention.
8A and 8B are views showing the configuration of a first air valve part, a second air valve part, and a third valve part of the present invention.
9 is a diagram for explaining the control relationship of the controller of the present invention.
10 is a view for explaining the outline of the operation when setting the circulation mode of the present invention for indoor air purification in a multi-use facility.
11 is a view for explaining the outline of the operation when setting the discharge mode of the present invention to discharge indoor air in a multi-use facility.
12 is a view for explaining an overview of the operation when setting the reduction mode of the present invention to reduce indoor carbon dioxide in a multi-use facility.
13 is a view for explaining the outline of the operation when setting the disinfection mode of the present invention for sterilization and sterilization of indoor air in a multi-use facility.
14 is a view showing a touch-type control panel according to an embodiment of the present invention.

The present invention reduces ultrafine dust in a multi-use facility indoor (R), ventilates indoor air, reduces indoor carbon dioxide concentration, and can perform a complex function of sterilizing and sterilizing harmful viruses existing in the indoor air. It relates to an air purification device.

In particular, the present invention is a device that enables a user to conveniently set a control mode in a one-touch manner, and to collect and purify ultrafine dust indoors in a multi-use facility using washing water.

In addition, it is possible to reliably purify indoor polluted air in multi-use facilities by mounting a filter-free cleaning dust collection and safety carbon filter or HEPA filter, and airborne bacteria, coronavirus, etc. are removed by the disinfection mode, and indoor carbon dioxide And a device for reliably removing toxic gases while reducing radon.

Hereinafter, the configuration of the present invention will be described with reference to the accompanying drawings.

The present invention collects, purifies, and disinfects air introduced through the scrubber unit 100 in a wet manner. As shown in Figs. 1 and 2, a first indoor duct in communication with one side of the indoor R of a multi-use facility ( A scrubber unit 100 that purifies, collects, and disinfects the air introduced through the air inlet 101 connected to 110, and is installed under the scrubber unit 100 and stores washing water to purify the air, and the scrubber A water tank 200 accommodating the washing water falling from the unit 100 and installed on the upper portion of the scrubber unit 100, and a blower 311 are provided inside to allow the air to flow through the air inlet 101 It flows into the interior of the scrubber unit 100, and includes an intake and exhaust unit 300 having an exhaust port 301 connected to the second indoor duct 310 in communication with the other side of the multi-use facility room (R) at the top.

The scrubber unit 100 of the present invention is a space for collecting and purifying and disinfecting harmful air, fine dust or ultrafine dust indoors in a multi-use facility, and a wet method using washing water is adopted.

The scrubber part 100 is a perforated plate 111, a polling member 120, a mesh net 130, a washing water spraying part 140, an air guiding member 150, a viewing window 160, as shown in FIG. 3 and the like. , A spray nozzle 170, and a demister 190.

The perforated plate 111 has a plurality of through-holes 111A, as shown in FIGS. 3 and 4B, and is installed while partitioning in the horizontal direction inside the scrubber unit 100. When the device is driven, the perforated plate 111 A water film layer having a predetermined height is formed on the perforated plate 111 and the polling member 120 is stacked on the perforated plate 111.

The through-hole 111A serves as a passage through which air can pass, and the number of through-holes 111A formed in the perforated plate 111 is a water film layer having a predetermined height on the perforated plate 111 when the device is driven. In consideration of the discharge amount (supply amount) of the washing water falling from the upper side to the lower side and the wind speed, air volume, wind pressure, etc. of the air flowing from the lower side to the upper side, a predetermined plurality is formed by the matlab design. Accordingly, the number and diameter of the through holes 111A may be formed differently as shown in (A) and (B) of FIG. 4B depending on the location of the multi-use facility. Meanwhile, the through hole 111A also serves as a passage through which washing water can fall.

The polling member 120 is a known pall ring member stacked in plural on the perforated plate 111, and in the present invention, bubbles or droplets (or bubbles) in the washing water or water film layer by rising air when the device is driven , Blisters, liquid film) is generated, and the area in which air is in contact with the polling member 120 by the generated bubbles or droplets (bubbles, liquid film) is maximized [that is, air actively contacts the polling member 120] As a result] the efficiency of collecting and purifying air by the polling member 120 is remarkably improved. The material of the polling member 102 applied in the present invention may be a metal or synthetic resin material, and is not particularly limited.

In a preferred embodiment of the present invention, a purification layer 121 is formed on the outer or inner surface of the polling member 120 in order to maximize the efficiency of purifying the collected air of the polling member 120, but the purification layer 121 has a mode Knight, talc, perlite, diatomaceous earth, sericite, cryolite, peat moss, silvite, vermiculite, bentonite, zeolite, and tourmaline components may be included.

All of the above components are excellent in purifying function as well as excellent adsorption power of heavy metals or harmful bacteria. After stirring the mixed solution containing the ingredients in the form of fine particles, the polling member 120 is immersed in the mixed solution or the mixed solution is applied to the polling member 120 in a known manner. The purification layer 121 may be formed, and the purification layer 121 may be formed by various other known methods.

Therefore, since the purification layer 121 is formed on the polling member 120, the purifying and dust collecting functions, heavy metals or harmful bacteria removal functions can be performed more reliably in the scrubber unit 100 of the present invention.

The mesh net 130 may be installed on the upper side of the polling member 120 to prevent the polling member 120 from splashing upward due to air introduced and rising when the device is driven.

The washing water spraying unit 140 is installed on the upper side of the mesh network 130 and sprays the washing water supplied from the washing water supply pipe 210 connected to the water tank 200 downward.

In a preferred embodiment of the present invention, the washing water spraying unit 140 is connected to the washing water supply pipe 210 as shown in FIGS. 5A to 5C and the mesh net 130 inside the scrubber unit 100 It includes a washing water branch pipe 141 disposed on the upper side, and a spiral nozzle 142 installed in a plurality of washing water branch pipes 141 and spraying the supplied washing water downward.

The washing water branch pipe 141 has a structure in which the washing water is branched into a plurality of rows as shown in FIGS. 5A to 5C so that the washing water is evenly sprayed into the scrubber unit 100, and the washing water is evenly sprayed downward radially. It is preferable that a plurality of spiral nozzles 142 are spaced apart from each other in the washing water branch pipe 141 so as to be installed.

A known spiral nozzle of the spiral nozzle 142 may be adopted.

As shown in Figs. 4A and 4B, a plurality of air induction members 150 are installed in the vertical direction on the air inlet 101 side while being under the perforated plate 111, and have an arc-shaped longitudinal section and have a certain distance from each other. It is a member that is installed to be spaced apart from each other and guides the incoming air to spread and rise evenly throughout the perforated plate 111.

When the air induction member 150 is described in more detail, when air is introduced into the air inlet 101 of the scrubber unit 100 by the suction force generated by the drive of the blower 311, the flow direction or movement of the inlet air A plurality of arc-shaped air guiding members 150 that are concave inward while facing the direction are arranged vertically, so that the flow of air is changed to turbulent flow near the air guiding member 150 and located at a close distance from the air inlet 101. Inflow air flows smoothly from the through hole 111A of the perforated plate 111 to the through hole 111A of the perforated plate 111 located at a long distance.

Although the direction of movement of the air flowing into the air inlet 101 is a horizontal direction, the movement direction of the air inside the scrubber unit 100 is a vertical direction, so the through hole of the perforated plate 111 located at a close distance from the air inlet 101 ( Turbulence is generated from the lower side of the perforated plate 111 by using the air guide member 150 so that uniform air flow occurs in the through hole 111A of the perforated plate 111 located at a distance from 111A) or at a distance.

The viewing window 160 is a known transparent member provided on one side so as to check the state of the polling member 120 or the internal state of the scrubber unit 100, and the scrubber unit 100 through the viewing window 160 In addition to being able to visually check the internal dust collection and purification process, it is easy to determine the replacement timing of the polling member 120.

The spray nozzle 170 is installed on the inner side of the scrubber unit 100 and connected to the disinfectant spray unit 800 installed on the outer surface of the scrubber unit 100 to spray the disinfectant solution into the interior of the scrubber unit 100 As shown in FIG. 3, any nozzle having various known structures may be adopted as long as it is a nozzle capable of evenly supplying the disinfectant solution S into the scrubber unit 100 in a spray form.

The disinfectant spray unit 800 is installed on the outer surface of the scrubber unit 100 and is installed on the outer surface of the disinfectant solution container 810 in which the disinfectant is stored, and the disinfectant solution container is installed outside the scrubber unit 100 as shown in FIG. A disinfectant supply pipe 820 connecting the 810 and the spray nozzle 170, and the disinfectant solution installed on the disinfectant supply pipe 820 while being electrically connected to the controller 700 and stored in the disinfectant container 810 A spray pump 830 for supplying high pressure to the spray nozzle 170, and a first installed on the disinfectant supply pipe 820 while electrically connected to the controller 700 to open and close the disinfectant supply pipe 820 It includes a solenoid valve 840.

The disinfectant spray unit 800 causes the spray nozzle 170 to spray the disinfectant when the apparatus of the present invention is set to the disinfection mode, and a detailed driving relationship will be described later.

The demister 190 is installed on the upper side of the washing water injection unit 140 and below the intake/exhaust unit 300, and a scrubber unit 100 using a known demister that can be adopted in a wet dust collecting device. ) To finally remove the droplets from the air while collecting dust.

The water tank 200 of the present invention includes a pH sensor 201, a temperature sensor 202, and a heater 203 as shown in FIG. 6.

The pH sensor 201 is disposed inside the water tank 200 while being electrically connected to the controller 700 to measure the pH concentration (a value) of the washing water and transmit it to the controller 700.

The temperature sensor 202 is disposed inside the water tank 200 while being electrically connected to the controller 700 to measure the temperature of the washing water and transmit it to the controller 700.

Each of the pH sensor 201 and the temperature sensor 202 may be a known sensor.

The heater 203 is electrically connected to the controller 700 and is disposed inside the water tank 200 to heat the washing water, and a known technique is adopted.

Meanwhile, as an embodiment according to the present invention, as shown in FIG. 6, a solution container 181 in which sodium hydroxide solution is stored is provided on the outer surface of the scrubber unit 100, and the solution container 181 is a solution A second solenoid valve 183 is connected to the water tank 200 through a supply pipe 182, and is electrically connected to the controller 700 on the solution supply pipe 182 to open and close the solution supply pipe 182. Is installed.

As a preferred embodiment, the controller 700 of the present invention opens the second solenoid valve 183 to open the solution container ( The sodium hydroxide solution stored in 181 is controlled to be injected into the water tank 200 through the solution supply pipe 182 in a predetermined amount.

In more detail, as the device operation time elapses, the pH value of the washing water is lowered by the dust collection and purification treatment, so that the pH value of the washing water detected by the pH sensor 201 is less than or equal to the preset pH value set in the controller 700. When it reaches to the controller 700 opens the second solenoid valve 183 in the closed state in order to maintain the proper pH of the washing water, the sodium hydroxide solution stored in the solution container 181 through the solution supply pipe 182 A predetermined amount is put into the water tank 200.

In addition, when the temperature of the washing water detected by the temperature sensor 202 is less than or equal to a preset set temperature t1, the controller 700 operates the heater until the temperature of the washing water reaches a preset set temperature t2 or higher. By driving 203, the washing water is controlled to be heated.

In more detail, when the temperature of the washing water detected by the temperature sensor 202 reaches a preset temperature t1 or less in the controller 700 due to a decrease in the ambient temperature in winter, the controller 700 is a heater ( 203 is operated to maintain the temperature of the washing water equal to or higher than a preset temperature t2 in the controller 700. Here, the set temperature t2 is higher than the set temperature t1.

6 and 7, a water supply pump 220 for supplying the washing water of the water tank 200 to the washing water spraying unit 140 on the washing water supply pipe 210 is installed. The water supply pump 220 is electrically connected to the controller 700 and is controlled by the controller 700. In addition, an opening/closing valve 230 having a ball valve structure may be further provided on the washing water supply pipe 210 to adjust the flow rate of the supplied washing water.

Therefore, when the water supply pump 220 is driven by the control of the controller 700, the washing water is supplied through the washing water supply pipe 210 and the washing water branch pipe 141, and the washing water is sprayed downward from the plurality of spiral nozzles 142. It will be.

In a preferred embodiment of the present invention, the controller 700 first drives the water supply pump 220 so that a water film layer having a predetermined height is first formed on the perforated plate 111 at the beginning of driving the device, and then after a predetermined time elapses, the The blower 311 is driven.

If the water supply pump 220 and the blower 311 are driven at the same time, air is introduced into the scrubber unit 100 before the water film layer is formed on the perforated plate 111, and the exhaust port ( 320), it is necessary to first drive the water supply pump 220 to inject the washing water from the spiral nozzle 142 first to create a water film layer having a predetermined height on the perforated plate 111 before air is introduced. There is.

Accordingly, according to a preferred embodiment of the present invention, when the device is started, the controller 700 first drives the water supply pump 220 to inject the washing water first, so that only the washing water falls into the scrubber unit 100 for a predetermined time. During this time, when the blower 311 is not driven and a water film layer having a predetermined height is formed on the perforated plate 111 after an initial predetermined time elapses, the controller drives the blower 311 to allow air to flow into the scrubber unit 100. Control.

The intake/exhaust part 300 of the present invention is installed on the upper part of the scrubber part 100 as shown in FIGS. 2 and 3 and provided with a blower 311 on the inner side to pass air through the air inlet 101 to the scrubber. After the air is introduced into the interior of the unit 100, the air purified by the scrubber unit 100 is discharged to an exhaust port 301 formed on the upper side.

The blower 311 is electrically connected to the controller 700 and is driven by the control of the controller 700 to generate a suction force to allow air to flow into the scrubber unit 100. A known blower or ring blower technology Is adopted. In order for the suction force generated by the blower 311 to work effectively, it is preferable that the device of the present invention is kept sealed.

As shown in FIG. 2, in the air purification apparatus according to the present invention, the air inlet 101 is connected to the first indoor duct 110 communicating with one side of the indoor R of the multi-use facility, and the exhaust port 301 ) Is connected to the second indoor duct 310 communicating with the other side of the multi-use facility indoor R.

Meanwhile, the first outdoor duct 410 has one end in communication with the first indoor duct 110 and the other end is open to the outside, and the second outdoor duct 510 has one end in communication with the second indoor duct 310 and the other end. It is open to the outside.

The first indoor duct 110, the second indoor duct 310, the first outdoor duct 410, and the second outdoor duct 510 are all passages through which air flows. Accordingly, the flow of air is controlled by selectively opening and closing the flow paths of the ducts 110, 310, 410, and 510.

The present invention includes a first air valve part 400, a second air valve part 500, and a third air valve part 600 to control opening and closing of the flow path of the duct. This will be described in detail with reference to FIGS. 8A and 8B. In FIGS. 8A and 8B, structures identical to or corresponding to each other with respect to the first air valve unit 400, the second air valve unit 500, and the third air valve unit 600 are indicated by reference numerals.

The first air valve unit 400 is installed in the second indoor duct 310 to control the flow of air, and can be rotated inside the second indoor duct 310 by a first rotation shaft 402 The first opening 401 is installed to open and close the flow path of the second indoor duct 310, and is connected to the first rotary shaft 402 while being installed outside the second indoor duct 310 to open and close the flow path of the second indoor duct 310. It includes a first motor unit 403 for rotating the first opening 401 through (402).

The first opening 401 is formed in a circular shape to correspond to the longitudinal section of the second indoor duct 310 and is coupled to the first rotating shaft 402 passing through the center of the first opening 401 so that the first rotating shaft 402 By passing through the second indoor duct 310, it is rotatably installed in the second indoor duct 310.

In a preferred embodiment, in order to reliably seal the flow path of the second indoor duct 310, as shown in FIG. 8A, sealing members 401A made of rubber material are provided on the outer circumference along the circumferential direction, respectively, so that the second indoor duct ( 310) When closing, the sealing member 401A contacts the inner circumferential surface of the second indoor duct 310 to reliably seal the flow path.

The first motor part 403 is connected to the first rotation shaft 402 through the second interior duct 310 by a built-in motor (not shown) as shown in FIG. 8B, and the first rotation shaft 402 It is to rotate the first opening 401 by rotating.

The second air valve part 500 is installed in the first outdoor duct 410 to control the flow of air, and can be rotated inside the first outdoor duct 410 by a second rotation shaft 502 A second opening/closing hole 501 that is installed to open and close the flow path of the first outdoor duct 410, and is connected to the second rotation shaft 502 while being installed outside the first outdoor duct 410 to open and close the flow path of the first outdoor duct 410. It includes a second motor unit 503 for rotating the second opening 501 through 502.

The second opening 501, the second rotating shaft 502, the second motor part 503, and the sealing member 501A provided on the outer periphery of the second opening 501 is the first opening 401, Since the first rotation shaft 402, the first motor part 403, and the sealing member 401A have the same structure, a description thereof will be omitted.

The third air valve part 600 is installed in the second outdoor duct 510 to control the flow of air, and can be rotated inside the second outdoor duct 510 by a third rotation shaft 602 A third opening and closing hole 601 that is installed to open and close the flow path of the second outdoor duct 510 and is connected to the third rotation shaft 602 while being installed outside the second outdoor duct 510 to open and close the flow path of the second outdoor duct 510. It includes a third motor unit 603 for rotating the third opening 601 through 602.

Likewise, the third opening 601, the third rotating shaft 602, the third motor part 603, and the sealing member 601A provided on the outer periphery of the third opening 601 is the first opening 401 ), the first rotation shaft 402, the first motor part 403, and the sealing member 401A and the same structure, so a description thereof will be omitted.

In a preferred embodiment, the first motor unit 403, the second motor unit 503, and the third motor unit 603 are each electrically connected to the controller 700 and rotated by the controller 700. The driving is controlled, but the second motor unit 503 controls the amount of external air introduced through the first outdoor duct 410 when the flow path of the first outdoor duct 410 is opened, that is, when the reduction mode is set. The rotation angle of the second opening/closing hole 501 may be adjusted according to the setting through the touch control panel 710.

When the rotation angle adjustment of the second opening/closing hole 501 is described in detail, for example, when the second opening/closing hole 501 is closing the flow path of the first outdoor duct 410 at a rotation angle of 90 degrees in a vertical state The flow path of the first outdoor duct 410 may be completely opened by rotating the second opening/closing hole 501 at a rotation angle of 0 degrees, which is a horizontal state, through the control of the second motor unit 503, or at a rotation angle of 45 degrees. It may be rotated to partially open the flow path of the first outdoor duct 410. Accordingly, the amount of external air introduced can be adjusted according to the degree of opening of the flow path of the first outdoor duct 410.

In the present invention, as described above, the user may set the amount of external air introduced through the flow path of the first outdoor duct 410 through the touch control panel 710, and the second motor unit 503 according to the setting. ) Is to rotate the second opening and closing 501 only by a predetermined angle. This will be described again when the reduction mode is described.

The controller 700 of the present invention includes a touch-type control panel 710 for input by a user in a touch pad method as shown in FIG. 14, and is shown in FIGS. 10 to 13 through the touch-type control panel 710. The device is driven and controlled according to a mode set to one of a circulation mode, a discharge mode, a reduction mode, and a disinfection mode.

This will be described in detail with reference to the accompanying drawings.

10 is a diagram for explaining the flow of air in the circulation mode. The circulation mode of the present invention can be selected when the air in the multi-use facility is circulated and purified by the apparatus of the present invention on a day when there is a lot of fine dust. .

When the device driving relationship in the circulation mode is described in detail, the circulation mode of the device D according to the present invention is the first opening and closing of the first air valve part 400 by the control of the controller 700 as shown in FIG. 10. As 401 opens the flow path of the second indoor duct 310, the second opening 501 of the second air valve part 500 and the third opening 601 of the third air valve part 600 are By closing the flow path of the first outdoor duct 410 and the flow path of the second outdoor duct 510, air from the indoor R of the multi-use facility flows into the scrubber unit 100 through the first indoor duct 110 This is a mode for controlling to be discharged into the multi-use facility room R again through the second indoor duct 310 after being purified.

11 is a view for explaining the flow of air in the exhaust mode, and the exhaust mode of the present invention may be selected when the air in the multi-use facility is discharged and ventilated on a day when there is little fine dust.

When the device driving relationship in the discharge mode is described in detail, in the discharge mode of the device D according to the present invention, the third opening/closing port 601 of the third air valve part 600 is controlled by the controller 700. At the same time as opening the flow path of the outdoor duct 510, the first opening 401 of the first air valve unit 400 and the second opening 501 of the second air valve unit 500 are connected to the second indoor duct 310. ) And the flow path of the first outdoor duct 410 are closed, so that the air in the indoor R of the multi-use facility flows into the scrubber unit 100 through the first indoor duct 110 and is purified. This is a mode for controlling to be discharged to the outside through the outdoor duct 510.

12 is a view for explaining the flow of air in the reduction mode, in the reduction mode of the present invention, while circulating air in the multi-use facility indoors on a day with a lot of fine dust, the outside air is purified and mixed to reduce the carbon dioxide concentration in the multi-use facility Can be selected when reducing.

When the device driving relationship in the reduction mode is described in detail, the reduction mode of the device (D) according to the present invention is controlled by the controller 700, the first opening 401 and the second opening of the first air valve 400. The second opening 501 of the air valve unit 500 opens the flow path of the second indoor duct 310 and the flow path of the first outdoor duct 410, and at the same time, the third opening and closing of the third air valve unit 600 By closing the flow path of the second outdoor duct 510 (601), the air in the indoor R of the multi-use facility passes through the outside air and the first indoor duct 110 introduced through the first outdoor duct 410. After being mixed and purified by the scrubber unit 100, it is discharged into the multi-use facility room R through the second indoor duct 310 to control the carbon dioxide concentration in the multi-use facility room R to be reduced.

13 is a diagram for explaining the flow of air in the disinfection mode, and the disinfection mode of the present invention may be selected when sterilizing and disinfecting indoor air during air circulation in a multi-use facility.

When the device driving relationship in the disinfection mode is described in detail, in the disinfection mode of the device (D) according to the present invention, the first solenoid valve 840 opens the disinfectant supply pipe 820 by the control of the controller 700. The spray pump 830 is driven so that the disinfectant solution in the disinfectant container 810 is sprayed from the spray nozzle 170, so that the first opening and closing opening 401 of the first air valve unit 400 is At the same time as opening the flow path, the second opening 501 of the second air valve unit 500 and the third opening 601 of the third air valve unit 600 are connected to the flow path of the first outdoor duct 410 and the second opening and closing. By closing the flow path of the outdoor duct 510, the air of the indoor R of the multi-use facility flows into the scrubber unit 100 through the first indoor duct 110, is purified and sterilized, and then the second indoor duct ( This mode is to control the discharge to the indoor of the multi-use facility again through 310).

As an embodiment, the controller 700 may control the driving of the spray pump 830 so that the disinfectant may be sprayed for a predetermined time.

Although the embodiments of the present invention have been described above, it is obvious to those skilled in the art that the present invention can be variously modified without departing from the scope of the technical idea. Therefore, the above contents do not limit the scope of the present invention defined by the following claims.

100: scrubber part, 101: air inlet, 110: first indoor duct,
111: perforated plate, 111A: through hole, 120: polling member,
130: mesh net, 140: washing water injection unit, 141: washing water branch pipe,
142: spiral nozzle, 150: air guiding member, 160: viewing window,
170: spray nozzle, 181: solution container, 182: solution supply pipe,
183: second solenoid valve, 190: demister, 200: water tank,
201: pH sensor, 202: temperature sensor, 203: heater,
210: washing water supply pipe, 220: feed pump, 300: intake and exhaust,
301: exhaust port, 310: second indoor duct, 311: blower,
400: first air valve portion, 401: first opening and closing, 401A: sealing member,
402: first rotating shaft, 403: first motor unit, 410: first outdoor duct,
500: second air valve portion, 501: second opening and closing, 501A: sealing member,
502: second rotation shaft, 503: second motor unit, 510: second outdoor duct,
600: third air valve portion, 601: third opening and closing, 601A: sealing member,
602: third rotation shaft, 603: third motor unit, 700: controller,
710: touch control panel, 800: disinfectant spray unit, 810: disinfectant container,
820: disinfectant supply pipe, 830: spray pump, 840: first solenoid valve.

Claims (2)

In a multi-use facility that is installed in a multi-use facility and uses washing water to reduce ultra-fine dust and carbon dioxide and sterilize and disinfect the air, an indoor ultra-fine dust and carbon dioxide reduction and sterilization and sterilization air purification device,
A scrubber unit 100 for purifying the air introduced through the air inlet 101 connected to the first indoor duct 110 in communication with one side of the multi-use facility room R;
A water tank 200 installed under the scrubber unit 100, storing washing water for purifying air, and accommodating washing water falling from the scrubber unit 100;
It is installed on the upper part of the scrubber part 100, and has a blower 311 therein to introduce air into the interior of the scrubber part 100 through the air inlet 101, and the multi-use facility indoor ( An intake/exhaust part 300 having an exhaust port 301 connected to the second indoor duct 310 in communication with the other side of R);
A first air valve unit 400 installed in the second indoor duct 310 to control the flow of air;
A first outdoor duct 410 communicating with the first indoor duct 110 and introducing external air;
A second air valve part 500 installed in the first outdoor duct 410 to control the flow of air;
A second outdoor duct 510 communicating with the second indoor duct 310 and exhausting air inside the multi-use facility;
A third air valve part 600 installed in the second outdoor duct 510 to control the flow of air; And
The washing water stored in the water tank 200 is controlled to be supplied to the scrubber unit 100, and the blower 311 is controlled so that air is introduced into the scrubber unit 100, and the touch type control panel 710 ) Through the first air valve unit 400, the second air valve unit 500, and the third air valve unit 600 according to a mode set to one of a circulation mode, a discharge mode, a reduction mode, and a disinfection mode. Including; a controller 700 for controlling the opening and closing)
The scrubber part 100,
A perforated plate 111 having a plurality of through holes 111A and installed in a horizontal direction inside the scrubber unit 100,
A plurality of polling members 120 stacked on the perforated plate 111,
A mesh net 130 installed on the upper side of the polling member 120,
A washing water spraying unit 140 installed on the upper side of the mesh network 130 and spraying the washing water supplied from the washing water supply pipe 210 connected to the water tank 200 downward,
An air guiding member 150 which is a lower side of the perforated plate 111 and installed in a vertical direction on the air inlet 101 side, but has an arc-shaped longitudinal section and is installed spaced apart from each other by a predetermined distance,
A viewing window 160 provided on one side of the polling member 120 or the internal state of the scrubber unit 100,
A spray nozzle 170 installed on one side of the inside of the scrubber unit 100 and connected to the disinfectant spray unit 800 installed on the outer surface of the scrubber unit 100 to spray the disinfectant solution into the interior of the scrubber unit 100,
It includes a demister 190 installed above the washing water spraying part 140 and below the intake/exhaust part 300,
The washing water spraying unit 140,
A washing water branch pipe 141 connected to the washing water supply pipe 210 and disposed above the mesh network 130 inside the scrubber unit 100,
It includes a spiral nozzle 142 installed in a plurality of the washing water branch pipe 141 and spraying the supplied washing water downward,
The disinfectant spraying unit 800,
A disinfectant container 810 installed on the outer surface of the scrubber unit 100 and storing the disinfectant solution,
A disinfectant supply pipe 820 installed outside the scrubber unit 100 to connect the disinfectant container 810 and the spray nozzle 170,
A spray pump 830 that is electrically connected to the controller 700 and installed on the disinfectant supply pipe 820 so that the disinfectant stored in the disinfectant container 810 is supplied to the spray nozzle 170 at high pressure,
And a first solenoid valve 840 installed on the disinfectant supply pipe 820 while being electrically connected to the controller 700 to open/close the disinfectant supply pipe 820,
A HEPA filter is installed above the air inlet 101 or the demister 190,
The water tank 200,
A pH sensor 201 that is electrically connected to the controller 700 and disposed inside the water tank 200 to measure the pH of the washing water,
A temperature sensor 202 that is electrically connected to the controller 700 and disposed inside the water tank 200 to measure the temperature of the washing water,
And a heater 203 that is electrically connected to the controller 700 and disposed inside the water tank 200 to heat the washing water,
A water supply pump 220 for supplying the washing water of the water tank 200 to the washing water spraying unit 140 is installed on the washing water supply pipe 210, and the water supply pump 220 is the controller 700. Is electrically connected to and controlled by the controller 700,
A solution container 181 in which sodium hydroxide solution is stored is provided on the outer surface of the scrubber part 100, and the solution container 181 is connected to the water tank 200 through a solution supply pipe 182, and the solution supply pipe On the 182, a second solenoid valve 183 is installed that is electrically connected to the controller 700 and controls the opening and closing of the solution supply pipe 182,
The first air valve part 400,
A first opening/closing opening 401 which is rotatably installed inside the second indoor duct 310 by a first rotation shaft 402 to open and close the flow path of the second indoor duct 310,
A first motor part 403 installed outside the second indoor duct 310 and connected to the first rotation shaft 402 to rotate the first opening and closing hole 401 through the first rotation shaft 402 Including,
The second air valve part 500,
A second opening/closing opening 501 which is rotatably installed inside the first outdoor duct 410 by a second rotation shaft 502 to open and close the flow path of the first outdoor duct 410,
A second motor part 503 which is installed outside the first outdoor duct 410 and is connected to the second rotation shaft 502 to rotate the second opening/closing hole 501 through the second rotation shaft 502. Including,
The third air valve part 600,
A third opening and closing port 601 that is rotatably installed inside the second outdoor duct 510 by a third rotation shaft 602 to open and close the flow path of the second outdoor duct 510,
A third motor part 603 which is installed outside the second outdoor duct 510 and is connected to the third rotation shaft 602 to rotate the third opening/closing hole 601 through the third rotation shaft 602. Including,
The first opening 401, the second opening 501, and the third opening 601 are formed in a circular shape, but the flow path of the second indoor duct 310, the flow path of the first outdoor duct 410, and the second Sealing members 401A, 501A, and 601A made of rubber are provided on the outer periphery to reliably seal the flow paths of the outdoor duct 510, respectively,
The first motor unit 403, the second motor unit 503, and the third motor unit 603 are electrically connected to the controller 700, respectively, and rotation driving is controlled by the controller 700, The second motor unit 503 controls the amount of external air introduced through the first outdoor duct 410 when the flow path of the first outdoor duct 410 is opened. It is possible to adjust the rotation angle of the second opening and closing hole 501,
The circulation mode,
Under the control of the controller 700, the first opening 401 of the first air valve unit 400 opens the flow path of the second indoor duct 310 and at the same time, the second air valve unit 500 is The opening 501 and the third opening 601 of the third air valve part 600 close the flow path of the first outdoor duct 410 and the flow path of the second outdoor duct 510, ) Air flows into the scrubber unit 100 through the first indoor duct 110 and is purified, and then is controlled to be discharged into the multi-use facility room R again through the second indoor duct 310,
The discharge mode is,
Under the control of the controller 700, the third opening 601 of the third air valve part 600 opens the flow path of the second outdoor duct 510 and at the same time, the first air valve part 400 is The opening 401 and the second opening 501 of the second air valve part 500 close the flow path of the second indoor duct 310 and the flow path of the first outdoor duct 410, ) Of the air flows into the scrubber unit 100 through the first indoor duct 110, is purified, and then is controlled to be discharged to the outside through the second outdoor duct 510,
The reduction mode,
Under the control of the controller 700, the first opening 401 of the first air valve unit 400 and the second opening 501 of the second air valve unit 500 are connected to the flow path of the second indoor duct 310 And the flow path of the first outdoor duct 410 is opened, and at the same time, the third opening/closing port 601 of the third air valve part 600 closes the flow path of the second outdoor duct 510. ) Of the outside air introduced through the first outdoor duct 410 and the first indoor duct 110 are mixed and purified by the scrubber unit 100 and then used for multiple use through the second indoor duct 310 It is controlled so that the carbon dioxide concentration in the multi-use facility room (R) is reduced by being discharged into the facility indoors (R).
The disinfection mode,
Under the control of the controller 700, the first solenoid valve 840 opens the disinfectant supply pipe 820 and the spray pump 830 is driven so that the disinfectant in the disinfectant container 810 is discharged to the spray nozzle for a predetermined time. As sprayed from 170, the first opening 401 of the first air valve unit 400 opens the flow path of the second indoor duct 310 and at the same time, the second opening and closing opening 501 of the second air valve unit 500 ) And the third opening and closing port 601 of the third air valve part 600 closes the flow path of the first outdoor duct 410 and the flow path of the second outdoor duct 510, thereby Is controlled to be introduced into the scrubber unit 100 through the first indoor duct 110, purified and sterilized, and then discharged into the room of the multi-use facility again through the second indoor duct 310,
The polling member 120 has a purification layer 121 formed on an outer or inner surface thereof, and the purification layer 121 includes mordenite, talc, pearlite, diatomaceous earth, sericite, cryolite, peat moss, silbyte, vermiculite, bentonite, zeolite, And a tourmaline component, characterized in that the multi-use facility indoor ultra-fine dust, carbon dioxide reduction and sterilization and sterilization combined air purification device. delete

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