KR102237686B1 - Air sterilizer - Google Patents

Abstract

An air sterilizer according to the present invention comprises: an air intake unit for sucking the air of an indoor space; a sterilizing liquid spraying unit for spraying the sterilizing liquid into the air intake unit; a mixing unit connected to the air intake unit and mixing the air and the sterilizing liquid; a separation unit connected to the mixing unit and removing the sterilizing liquid from the mixture of air and sterilizing liquid; an air discharge unit for discharging the air from which the sterilizing liquid has been removed to the indoor space; and a control unit for controlling an operation thereof. In this case, the mixing unit has a stator connected to the air intake unit, and a rotor installed at the bottom of the stator to face the stator and rotating at a preset speed, and the air supplied to the mixing unit through the air intake unit and the sterilizing liquid pass through a space between the stator and the rotor and move to the separation unit.

Description

Air sterilization device {AIR STERILIZER}

The present invention relates to an air sterilization device. More specifically, the present invention relates to an air sterilization apparatus capable of removing viruses and the like in the air by uniformly mixing a sterilizing solution with indoor air, and then separating the sterilizing solution to reduce only purified air to the room.

Due to the recent global pandemic of coronavirus infection-19 (COVID-19), various methods have been attempted to block the transmission of the causative agent that causes respiratory diseases. The causative agent includes bacteria, Influenza Virus, Corona Virus, Respiratory Syncytial Virus, etc., and is mainly spread through small droplets (splash and aerosol) floating in the air. . Therefore, in a closed indoor space such as a building, the risk of infection of respiratory diseases is inevitably increased, and a technology capable of effectively removing viruses in the air is required.

Meanwhile, a sterilization device using an electrostatic filter, a sterilization device using plasma or ultraviolet rays, and the like have been proposed as techniques for removing viruses and the like in the air.

However, in the case of a sterilization device using an electrostatic filter, there is a problem that the effect of removing biological contaminants such as viruses is insignificant, and the filter performance is bound to deteriorate depending on the use, so it is difficult to expect a continuous sterilization effect.

In the case of a plasma sterilization device, the sterilization effect is not sufficient due to the low concentration of ionic reaction in the air, and even in the case of an ultraviolet sterilization device, a sufficient sterilization effect is obtained by blocking ultraviolet rays irradiated by fine dust particles relatively larger than the virus. It may not be possible. In addition, since plasma or ultraviolet rays ionize oxygen to _{form ozone (O 3} ), which is harmful to the human body, there is a disadvantage that separate filters for removing ozone are required. In particular, if the intensity of plasma or ultraviolet rays is increased in order to improve the sterilization effect, the amount of ozone generated is inevitably increased, which is not preferable because it increases the emission of substances harmful to the human body. In addition, there is a problem in that the ozone removal ability also decreases when the filter performance in the front end is deteriorated.

Accordingly, a liquid sterilization method in which viruses and the like are removed by spraying a sterilizing solution of a chlorine-based component into the air is drawing attention. In the case of the liquid sterilization method, there is an advantage that a very high sterilization effect can be expected because the sterilizing liquid directly contacts the air. However, in order to further improve the sterilization effect, it is necessary to mix the air and the sterilizing solution quickly and evenly. Prior to returning the sterilized air to the room, the technology to recover the sterilizing solution component so that the sterilization solution does not enter the room is required. It is a necessary situation.

An object of the present invention is to provide an air sterilization device that removes harmful substances from air by mixing a sterilizing solution with indoor air. In particular, the sterilization performance is maximized by allowing the air and the sterilizing solution to be quickly and uniformly mixed, and by separating the sterilizing solution component and circulating only inside the air sterilization device, only the air from which the sterilizing solution has been removed is returned to the room for continuous real-time sterilization It is to provide a possible air sterilization device.

However, the problem to be solved by the present invention is not limited to the above-described problems, and may be variously expanded within a range not departing from the spirit and scope of the present invention.

In order to achieve the above-described object of the present invention, the air sterilization apparatus according to exemplary embodiments includes an air intake unit for inhaling air in an indoor space, a sterilization liquid injection unit for injecting a sterilization solution into the air intake unit, A mixing unit connected to the air intake unit and mixing air and sterilizing solution, a separation unit connected to the mixing unit and removing sterilizing solution from a mixture of air and sterilizing solution, and discharging the air from which the sterilizing solution has been removed to the indoor space And a control unit for controlling the air discharge unit and the operation thereof.

At this time, the mixing unit has a stator connected to the air intake unit, and a rotor installed at the lower end of the stator to face the stator and rotating at a preset speed, and sterilizes with air supplied to the mixing unit through the air intake unit. The liquid passes through the space between the stator and the rotor and moves to the separation unit.

In addition, the stator includes a disk-shaped fixing disk, a mixture introduction pipe passing through the center of the fixing disk and connected to the air intake, and a plurality of fixing blades protruding from the fixing disk toward the rotor. I can. The rotor includes a disk-shaped rotating disk facing the fixed disk, a drive motor for rotating the rotating disk, a plurality of stirring blades protruding from the rotating disk toward the stator, and air provided on the side of the rotating disk. It may include a mixture discharge pipe for transferring the mixture of and the sterilizing liquid to the separation unit.

In one embodiment, the fixed blades are spaced apart from each other on a virtual circumference having a first radius at the center of the fixed disk, and may have a rectangular column shape.

In one embodiment, the stirring blades are spaced apart from each other on an imaginary circumference of a second radius having a size different from the first radius at the center of the rotating disk, and may have a blade shape.

In one embodiment, the fixed blades are a first fixed blade row composed of a plurality of fixed blades spaced apart from each other on a virtual circumference having the first radius, and a third radius greater than the first radius It may be composed of a second fixed blade row consisting of a plurality of fixed blades spaced apart from each other on the virtual circumference of the. The stirring blades are arranged on a virtual circumference having the second radius, a first stirring blade row composed of a plurality of stirring blades spaced apart from each other, and on a virtual circumference of a fourth radius greater than the second radius. A second stirring blade row consisting of a plurality of spaced apart stirring blades, and a third stirring blade row consisting of a plurality of stirring blades spaced apart from each other on an imaginary circumference of a fifth radius larger than the fourth radius Can be configured.

In this case, the first radius may be larger than the second radius and smaller than the fourth radius, and the third radius may be larger than the fourth radius and smaller than the fifth radius.

In one embodiment, when the stirring blade draws a tangent line to the virtual circumference at a point in contact with the imaginary circumference, the stirring blade may form a predetermined angle with the tangent line.

Meanwhile, the separation unit collects a demister that selectively collects a sterilizing liquid in a liquid state, a separation duct connecting the mixture discharge pipe and the demister, and a sterilization liquid falling from the demister provided inside the separation duct. It may include a collector that does.

In this case, the cross-sectional area of the demister may be larger than the cross-sectional area of the mixture discharge pipe.

The air sterilization apparatus according to the present invention may further include a sterilizing liquid circulation part connected to the collector and supplying the collected sterilizing liquid to the sterilizing liquid spraying part.

In this case, the sterilizing liquid circulation unit includes a collection tank for storing the sterilizing liquid delivered from the collector, a filter for removing at least one of fine dust, bacteria, and viruses contained in the sterilizing liquid, and a sterilizing liquid having a preset concentration. The storage tank stored, the circulation passage directly connecting the collecting tank and the sterilizing liquid spraying unit, and the sterilizing liquid stored in the collecting tank are supplied to the sterilizing liquid spraying unit after sequentially passing through the filter and the storage tank And a supplemental flow path connecting the sterilizing liquid injection unit, and the control unit may selectively open the circulation flow path and the supplemental flow path.

In addition, the air sterilization apparatus according to the present invention may further include a cooling unit for supplying a cooling medium into the fixed disk and the fixed blades.

The air sterilization apparatus according to exemplary embodiments of the present invention collects, sterilizes, and removes harmful substances such as bacteria, viruses, and fine dust by inhaling air in the indoor space, and then returns it to the indoor space, thereby reducing the air in the indoor space. It can be sterilized in real time.

In addition, the air sterilization apparatus according to the present invention removes harmful substances by contacting contaminated air with the sterilizing solution, but by applying a unique mixing unit that maximizes shear force to atomize the air particles and the sterilizing solution particles, The degree of mixing can be maximized. Accordingly, the effect of trapping and removing harmful substances contained in the air can be greatly improved at the same time.

In addition, the air sterilization apparatus according to the present invention may separate the sterilizing liquid used after removing harmful substances from the air from the air, and reduce only the gaseous air from which the sterilizing liquid has been removed back to the indoor space. Accordingly, it is possible to prevent the sterilizing liquid component from flowing into the indoor space.

In addition, the air sterilization apparatus according to the present invention manages the sterilization liquid to maintain a constant quantity and concentration, and, if necessary, can remove harmful substances contained in the sterilization liquid using a filter. Accordingly, it is possible to always maintain the best air sterilization performance.

1 is a block diagram showing an air sterilization apparatus according to an embodiment of the present invention.
2 is a cross-sectional view showing the air sterilization device of FIG. 1.
3 is a diagram for explaining the functions of an air intake unit and an air discharge unit in FIG. 1.
4 is a cross-sectional view showing the mixing unit of FIG. 1.
5 is a view showing the stator of FIG. 4.
6 is a view showing the rotor of FIG. 4.
7 is a view showing a state in which the stator of FIG. 5 and the rotor of FIG. 6 are combined.
FIG. 8 is a diagram illustrating a separating part of FIG. 1.
9 is a view showing a sterilizing liquid circulation unit of FIG. 1.

With respect to the embodiments of the present invention disclosed in the text, specific structural or functional descriptions have been exemplified for the purpose of describing the embodiments of the present invention only, and the embodiments of the present invention may be implemented in various forms. It should not be construed as being limited to the embodiments described in.

In the present invention, various modifications may be made and various forms may be applied, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, it should be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

Terms such as first and second may be used to describe various elements, but the elements should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element.

When a component is referred to as being "connected" or "connected" to another component, it is understood that it may be directly connected or connected to the other component, but other components may exist in the middle. It should be. On the other hand, when a component is referred to as being "directly connected" or "directly connected" to another component, it should be understood that there is no other component in the middle. Other expressions describing the relationship between components, such as "between" and "directly between" or "adjacent to" and "directly adjacent to" should be interpreted as well.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the existence of a specified feature, number, step, action, component, part, or combination thereof, but one or more other features or numbers. It is to be understood that the possibility of addition or presence of, steps, actions, components, parts, or combinations thereof is not preliminarily excluded.

Unless otherwise defined, all terms used herein including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. .

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same elements in the drawings, and duplicate descriptions for the same elements are omitted.

Meanwhile, the present invention relates to an air sterilization device 10 capable of removing not only substances harmful to the human body such as bacteria or viruses contained in the air, but also fine dust. Collectively, dust, etc. will be referred to as'hazardous substances'.

1 is a block diagram showing an air sterilization apparatus according to an embodiment of the present invention. 2 is a cross-sectional view showing the air sterilization device of FIG. 1. 3 is a diagram for explaining the functions of an air intake unit and an air discharge unit in FIG. 1. 4 is a cross-sectional view showing the mixing unit of FIG. 1. FIG. 5 is a view showing the stator of FIG. 4, FIG. 6 is a view showing the rotor of FIG. 4, and FIG. 7 is a view showing a state in which the stator of FIG. 5 and the rotor of FIG. 6 are combined. FIG. 8 is a diagram illustrating a separating part of FIG. 1. 9 is a view showing a sterilizing liquid circulation unit of FIG. 1.

1 to 9, the air sterilization device 10 includes an air intake unit 100 for inhaling air from an indoor space, a sterilizing solution spraying unit 200 for injecting a sterilizing solution to the inhaled air, and sterilizing with air. The mixing unit 300 to maximize the sterilization effect by increasing the degree of mixing of the liquid, the cooling unit 400 to cool the mixing unit 300, the separation to separate the air from which harmful substances have been removed and the sterilizing solution The unit 500, a sterilizing liquid circulating part 600 that circulates the separated sterilizing liquid and supplies it to the sterilizing liquid spraying part 200, an air discharge part 700 that reduces the air from which harmful substances have been removed back to the indoor space, And a control unit 800 for controlling their operation. In this case, the indoor space refers to a space having a certain size, such as a room or living room of a home, various indoor business spaces and cultural sports spaces, a classroom of a school, and an office of a company.

First, the air intake unit 100 sucks air from the indoor space and provides it to the mixing unit 300, and the suction duct 110 connecting the indoor space and the mixing unit 300, and the mixing unit in the indoor space It may include a suction fan 120 for generating air flow in the direction of the unit 300.

One side of the suction duct 110 is provided with a suction port 111 communicating with the indoor space, and the other side may be connected to a mixture introduction pipe 311 (see FIG. 4) of the mixing unit 300. Meanwhile, a plurality of suction ports 111 may be formed as necessary.

The suction fan 120 is operated under the control of the controller 800 and may generate air flow from the suction port 111 toward the mixture introduction pipe 311. Therefore, when the control unit 800 operates the suction fan 120, the air in the indoor space is introduced into the suction duct 110 through the suction port 111, and the air introduced into the suction duct 110 is a mixture introduction pipe ( It may be supplied to the mixing unit 300 through 311).

In one embodiment, in order to block virus propagation in real time, the inlet 111 may be provided above the indoor space, for example, around a ceiling.

As shown in FIG. 3, assuming that the average height of an adult male is the third height H3, the inlet 111 may be formed at a first height H1 higher than the third height H3. have. That is, the suction port 111 is provided at a position higher than the height of a person. For example, since the average height of adult males in Korea is about 173cm, the suction port 111 is preferably installed at a height of at least 180cm from the ground (G). In this case, it is possible to block the spread of viruses in the indoor space in real time.

Specifically, when the suction fan 120 is operated, the air above the indoor space moves toward the suction port 111 at a constant speed (Vs). However, if the rotational speed of the suction fan 120 increases, the suction speed Vs of the indoor air also increases, so if the rotational speed of the suction fan 120 is sufficiently large, the upward airflow F in the indoor space increases. Can be formed. Therefore, because the breath (V1) of the person (A) discharged in the direction parallel to the ground (G) is guided to the upper direction (V2) by the rising air flow (F), it cannot be transmitted to the other person (B) and immediately sterilizes the air. It can be sucked into the device 10. Accordingly, it is possible to have an effect of blocking the spread of viruses between people in an indoor space in real time.

For example, assuming that a person's breathing discharge rate is 0.3cm/s, increasing the suction speed (Vs) to 0.96cm/s or more by increasing the rotational speed of the suction fan 120 Breathing may not be propagated to others (B) and may be directly inhaled into the air sterilization device 10. Accordingly, it is possible to block the spread of the breathing flow between people, and it can have the effect of preventing the spread of the virus in an enclosed indoor space in real time.

A sterilizing liquid injection part 200 may be provided inside the suction duct 110. The sterilizing liquid injection unit 200 is mounted inside the sterilizing liquid introduction pipe 210 and the suction duct 110 extending from the sterilizing liquid circulation part 600 to the inside of the suction duct 110 to spray the sterilizing liquid. It may include nozzles 220. The nozzles 220 may inject the sterilizing liquid into the air introduced through the suction duct 110, and the air containing the sterilizing liquid may be supplied to the mixing unit 300.

At this time, the sterilizing solution may be an aqueous solution of hypochlorous acid (HClO), an aqueous citric acid solution, or an aqueous phenoxyethanol (C ₈ H ₁₀ O ₂ ) solution, and the concentration may be appropriately selected as needed.

The mixing unit 300 may more evenly mix the air and the sterilizing solution to maximize the effect of removing harmful substances.

As shown in FIG. 4, the mixing unit 300 includes a stator 310 and a rotor 320 rotating at a constant speed.

The stator 310 does not rotate and maintains a fixed state, and the mixture introduction pipe 311 connected to the suction duct 110, a disk-shaped fixing disk 312, a rotating disk 321 to be described later in the fixing disk 312 A plurality of fixed blades 313 protruding toward ), and cooling medium passages 314 and 316 may be included.

The mixture introduction pipe 311 extends vertically and passes through the center of the fixed disk 312, and may supply air and a sterilizing solution to the space between the fixed disk 312 and the rotating disk 321.

A manifold 315 for storing and distributing a cooling medium is formed inside the fixed disk 312, and a cooling medium inlet 314 and a cooling medium outlet 316 may be provided on the side of the fixed disk 312, respectively. . That is, the cooling medium supplied from the cooling unit 400 flows into the manifold 315 through the cooling medium inlet 314, and the manifold 315 supplies the cooling medium into each of the fixed blades 313. The air and the sterilizing liquid mixture is cooled, and the cooling medium whose temperature has risen thereafter may be recovered to the cooling unit 400 through the cooling medium outlet 316.

On the other hand, when the sterilizing liquid is sprayed from the sterilizing liquid spraying unit 200, some of the air is dissolved in the sterilizing liquid, thereby generating heat of dissolution. However, when the temperature of the mixture of air and the sterilizing liquid increases due to the heat of dissolution, the solubility of the air decreases, and the sterilization effect may decrease. In order to prevent this, in the present invention, the cooling medium is supplied into the fixed blade 313. That is, the cooling medium may increase the solubility of air by cooling the mixture of air and the sterilizing liquid, and may further increase the effect of removing harmful substances contained in the air. In this case, the cooling medium may be maintained below a preset temperature while continuously circulating the cooling unit 400.

As shown in FIG. 5, the fixed blade 313 may include a first fixed blade row 313a and a second fixed blade row 313b in which a plurality of fixed blades 323 are circularly spaced apart. . The first fixed blade row 313a is disposed on a virtual circumference having a first radius R1 at the center of the fixed disk 312, and the second fixed blade row 313b is greater than the first radius R1. It may be disposed on an imaginary circumference having a larger second radius R2. In addition, each of the fixed blades 313 constituting the first fixed blade row 313a and the second fixed blade row 313b may be a rectangular pillar having a rectangular cross-sectional shape. That is, a plurality of square pillar-shaped fixed blades protrude from the center of the fixed disk 312 on a virtual circumference having a first radius R1 to form a first fixed blade row 313a, and a second radius R2 ) To form a second fixed wing row (313b) by protruding a plurality of square pillar-shaped fixed wings on the virtual circumference.

Meanwhile, in FIG. 5, it is shown that the fixed wing 313 has two pairs of fixed wing rows 313a and 313b, and the cross-section of each fixed wing is a square, but this is for convenience of description and the present invention is It is not limited. For example, a third fixed wing row (not shown) is additionally disposed outside the second fixed wing row 313b, or composed of only one fixed wing row 313a without the second fixed wing row 313b It could be. In addition, each of the fixed blades may have a cross-sectional shape of a circular, elliptical, polygonal shape, etc., and may be changed into various shapes as necessary. That is, the distance from the center of the fixed disk to the fixed blade row (R1, R2), the number of fixed blade rows, the distance between the fixed blades, and the shape of the fixed blades are the flow rate of air, the rotational speed of the rotor 320 , The design may be appropriately changed according to the type and concentration of the sterilizing solution, the temperature inside the mixing unit 300, and the like.

The rotor 320 is located under the stator 310 so as to face the stator 310 and rotates at a constant speed to increase the degree of mixing of the air and the sterilizing solution.

Specifically, the rotor 320 includes a disk-shaped rotating disk 321 facing the fixed disk 312, a plurality of stirring blades 323 protruding from the rotating disk 321 toward the fixed disk 312, A driving motor 324 for rotating the rotating disk 321, and a mixture discharge pipe 325 provided on the side of the rotating disk 321 to deliver a mixture of air and sterilizing liquid to the separation unit 500 may be included.

As shown in Fig. 6, the stirring blade 323 includes a first stirring blade row 323a, a second stirring blade row 323b, and a third stirring blade in which a plurality of stirring blades 323 are spaced apart in a circle. It may include a blade row (323c). The first stirring blade row 323a is disposed on a virtual circumference having a third radius R3 at the center of the rotating disk 312, and the second stirring blade row 323b is greater than the third radius R3. It is disposed on an imaginary circumference having a larger fourth radius (R4), and the third stirring blade row (323c) is on a imaginary circumference having a fifth radius (R5) larger than the fourth radius (R4). Can be placed. In addition, each of the stirring blades 323 constituting the first to third stirring blade rows 323a, 323b, and 323c may have a blade shape. That is, a plurality of blade-shaped stirring blades protrude on a virtual circumference having a third radius R3 from the center of the rotating disk 321 to form the first stirring blade row 323a, and the fourth radius R4 A plurality of blade-shaped stirring blades protrude on a virtual circumference having a second agitation blade row (323b), and a plurality of blade-shaped stirring blades protrude on a virtual circumference with a fifth radius (R5). It is to form a third stirring blade row (323c).

In one embodiment, each of the stirring blades 323 may be arranged to be inclined at a certain angle (θ) with respect to the tangent (n) of the virtual circumference. This is to guide the air and sterilizing liquid mixture supplied to the center of the rotating disk 321 to move in the direction of the mixture discharge pipe 325 located outside the rotating disk 321. That is, the stirring blade 323 performs the same role as a blower so that the air and sterilizing liquid mixture moves from the center of the rotating disk 321 in the outer direction.

On the other hand, in Figure 6, the stirring blade 323 has three pairs of stirring blade rows 323a, 323b, 323c, and it is shown that each stirring blade 323 is inclined at a certain angle (θ). It is for convenience of description and the present invention is not limited thereto. For example, a fourth stirring blade row (not shown) is additionally disposed outside the third stirring blade row (323c), or the stirring blade 323 consists of only two pairs of stirring blade rows (323a, 323b) It could be. In addition, the angle θ of the stirring blades 323 may also be appropriately changed as necessary. That is, the distance from the center of the rotating disk 321 to the stirring blade row (R3, R4, R5), the number of stirring blade rows, the distance between each stirring blade, and the angle of each stirring blade are determined by the flow rate of air, the rotor ( The design may be appropriately changed according to the rotation speed of 320), the type and concentration of the sterilizing solution, and the temperature inside the mixing unit 300.

Meanwhile, the fixed blades 313 and the stirring blades 323 may be alternately disposed from the center of the disks 312 and 321 in the outer direction. For example, a first stirring blade row 323a is disposed at the closest to the center of the disks 312 and 321, and a first fixed blade row 313a, a second stirring blade row 323b, The second fixed blade row 313b and the third stirring blade row 323c may be sequentially disposed (R3<R1<R4<R2<R5). This is illustrated in FIG. 7. In contrast, when the fixed blade 313 has three pairs of blade rows and the stirring blade 323 has two pairs of blade rows, the first fixed blade row from the center of the disks 312 and 321 in the outer direction , The first stirring blade row, the second fixed blade row, the second stirring blade row, and the third fixed blade row may be sequentially arranged. By alternately arranging the fixed blades 313 and the stirring blades 323 in this way, it is possible to increase the moving distance of the air and the sterilizing solution mixture, and to maximize the sterilization effect.

The mixing unit 300 of the present invention having the above-described structure can maximize the sterilization effect by increasing the degree of mixing of air and the sterilizing solution.

Specifically, the mixture of air and the sterilizing liquid is introduced between the fixing part 310 and the rotating part 320 through the mixture introduction pipe 311 penetrating the center of the fixing disk 312, and the fixing blade 313 and the fixing blade 313 by centrifugal force. It moves in an annular direction between the stirring blades 323. At this time, a high shear force is generated between the rotating rotor 320 and the fixed stator 310, and the air and the sterilizing liquid particles may be pulverized to a very small size due to the shearing force to be atomized. . Therefore, in the process of passing through the mixing unit 300, the effective collision value between the atomized air particles and the sterilizing solution particles increases, which increases the degree of mixing of the air and the sterilizing solution to maximize the sterilization effect. I can.

The mixture moved in the outer direction of the disks 312 and 321 along the gap between the fixed blades 313 and the gap between the stirring blades 323 is a mixture discharge pipe 325 provided on the side of the rotor 320 It can be moved to the separation unit 500 through.

As described above, the mixing unit 300 of the present invention generates a high shear force to atomize the air particles and the sterilizing liquid particles, thereby increasing the degree of mixing to the limit. In addition, a plurality of fixed blades 313 and agitation blades 323 are arranged to increase the movement time by interfering with the air flow, thereby ensuring a sufficient reaction time between the air and the sterilizing solution. Accordingly, harmful substances such as viruses contained in the air can be more reliably removed. Thereafter, the separating unit 500 separates the sterilizing solution from the air from which the harmful substances have been removed. This is because a large amount of the sterilizing liquid component may be harmful to the human body, and this is to reduce only the air from which the sterilizing liquid component has been removed to the indoor space.

The separation unit 500 collects the first separation duct 510 connecting the mixture discharge pipe 325 and the demister 520, the demister 520 to remove droplets, and the droplets separated from the demister 520 A collector 530 provided to the sterilizing liquid circulation unit 600, and a second separation duct supplying the air from which the sterilizing liquid has been removed to the discharge duct 710 by connecting the demister 520 and the discharge duct 710 are provided. Includes.

Alternatively, the first separation duct 510 and the second separation duct are integrally manufactured, and the demister 520 may be accommodated in the integrally manufactured separation duct. However, if the separation duct is manufactured as an integral type, since maintenance of the demister 520 may be difficult, it is preferable to be manufactured as a separate type. Hereinafter, only an embodiment in which the separation duct is separated on both sides of the demister 520 will be described, and for convenience of description, the first separation duct 510 will be simply referred to as a separation duct 510.

One end of the separation duct 510 may be connected to the mixture discharge pipe 325 of the mixing unit 300, and the other end may be connected to the demister 520. For example, as shown in FIG. 8, the separation duct 510 may be connected to the demister 520 by extending upward from the end of the mixture discharge pipe 325.

In one embodiment, the demister 520 may be a filter in which a fibrous object is overlapped in a net shape. The demister 520 may pass air in a gaseous state from a mixture of air and a sterilization liquid and selectively collect only the sterilization liquid in a liquid state.

Specifically, the cross-sectional area of the demister 520 may be larger than the cross-sectional area of the mixture discharge pipe 325. Accordingly, the mixture introduced into the demister 520 may be rapidly decelerated compared to when discharged from the mixture discharge pipe 325. In this case, since the attractive force between the sterilizing liquid particles is stronger than that of the air particles, the sterilizing liquid particles become larger and larger while forming droplets, and can be separated into a liquid sterilizing liquid.

Meanwhile, the size of the demister 520 may be appropriately selected according to the amount of air flow, and if necessary, the demister 520 may be installed in multiple stages or a plurality of demisters 520 may be installed in parallel.

The liquid sterilizing solution separated from the demister 520 may fall to the collector 530 located below. The collector 530 has a funnel shape with a convex downward in the center, and may be connected to the collecting pipe 610 of the sterilizing liquid circulation unit 600.

As described above, the separating unit 500 of the present invention can reduce the mixture of air and the sterilizing liquid to separate the sterilizing liquid in a droplet state from the air. Accordingly, the air from which the sterilizing solution has been removed can be reduced to the indoor space through the air discharge unit 700. Accordingly, the sterilizing liquid can be recovered and reused while preventing the sterilizing liquid harmful to the human body from being discharged into the indoor space.

The sterilizing liquid collected by the separating part 500 may be supplied to the sterilizing liquid spraying part 200 again through the sterilizing liquid circulating part 600. The sterilizing liquid circulating part 600 forms different circulation paths depending on the situation, an example of which is shown in FIG. 9.

As shown in FIG. 9, the sterilizing liquid circulation unit 600 includes a collecting pipe 610 for transporting the sterilizing liquid collected by the separating unit 500, a collecting tank 620 for storing the collected sterilizing liquid, and a collecting tank A circulation flow path 630 for directly supplying the sterilizing solution stored in 620 to the sterilizing solution spraying unit 200, a supplemental flow path 640 for removing impurities from the sterilizing solution stored in the collecting tank 620 and replenishing the sterilizing solution, And pumps 601 and 602 selectively opening and closing the circulation flow path 630 and the supplementary flow path 640 under the control of the controller 800, and opening/closing valves 603, 604, 605, and 606. .

On the other hand, a filter 650 for removing impurities from the sterilization liquid, a storage tank 660 in which a sterilization liquid of a preset concentration is stored, and a stock solution tank 670 in which the sterilization liquid stock solution is stored are further provided on the supplementary passage 640 I can.

The collecting tank 620 is connected to the separating unit 500 through a collecting pipe 610 and may store the sterilizing liquid recovered from the separating unit 500. A water level sensor (not shown) and/or a concentration sensor (not shown) are provided inside the water collecting tank 620, and measurement information of the sensors may be transmitted to the controller 800. When the level and concentration of the sterilizing liquid are within a preset reference range, the controller 800 may open the circulation passage 630 to circulate the sterilizing liquid.

Specifically, when both the level and concentration of the sterilizing liquid in the water collecting tank 620 are within a preset range, the controller 800 may operate the first pump 601 and open the first valve 603. In this case, the sterilizing liquid of the water collecting tank 620 may be connected to the sterilizing liquid introduction pipe 210 through the circulation passage 630. Accordingly, the sterilizing liquid stored in the water collecting tank 620 is directly supplied to the sterilizing liquid spraying unit 200 and can be recovered again from the separating unit 500.

In contrast, when the water level inside the collecting tank 620 does not reach a preset range or the concentration of the sterilizing solution stored in the collecting tank 620 does not reach a preset range, the control unit 800 opens the circulation passage 630. It can be closed and the replenishment flow path 640 can be opened.

Specifically, the control unit 800 operates the first pump 601 and the second pump 602, the second valve 604 and the third valve 605 are open, and the first valve 603 is closed. can do. In this case, the sterilizing liquid of the collecting tank 620 passes through the filter 650 and the storage tank 660 sequentially through the replenishment flow path 640, and then may be connected to the sterilizing liquid introduction pipe 210.

Alternatively, even if the water level or concentration inside the water collecting tank 620 is within a preset range, the control unit 800 may open the supplemental passage 640 as necessary. For example, the control unit 800 may open the replenishment flow path 640 at a specific time or whenever the operating time of the air sterilization device 10 reaches a certain period to filter and replenish the sterilizing solution.

The filter 650 may collect harmful substances such as bacteria, viruses, and fine dust collected in the sterilizing solution.

In one embodiment, the filter 650 may include a first filter 651 and a second filter 653 connected in parallel with each other, and a backwashing device (not shown). In this case, even if one of the first filter 651 or the second filter 653 is clogged with fine dust, the other one has the advantage of being able to continuously perform a filtration function, and the clogged filter operates the backwashing device. Can be washed. Accordingly, it is possible to maintain the filter with constant performance at all times. Meanwhile, the filters 651 and 653 may be hollow fiber membrane filters.

The storage tank 660 stores a sterilizing liquid of a certain concentration, supplements the sterilization liquid of the collecting tank 620 or increases the concentration of the sterilization liquid.

Specifically, the separating unit 500 separates the sterilizing liquid from air and transfers the sterilizing liquid to the collecting tank 620, and the sterilizing liquid in a droplet state does not fall to the collector 530 and the demister 520 or the collecting duct 510 It may remain on the wall. In this case, the level of the sterilizing liquid in the water collecting tank 620 is inevitably lowered. In this case, the sterilizing liquid in the storage tank 660 can be replenished by circulating the sterilizing liquid through the replenishment flow path 640.

In addition, the sterilizing liquid mainly contains a chlorine component such as hypochlorous acid, and the chlorine component may be converted into chlorine gas and discharged to an indoor space together with air. However, the sterilization solution has a chlorine component concentration of 30 ppm to 50 ppm, which is only a trace amount, and the chlorine gas discharged into the air is only a trace amount, but if this continues for a long time, the concentration of the sterilization solution in the collection tank 620 is bound to be lowered. It can lead to a decrease in sterilization performance. In order to prevent this, by circulating the sterilizing liquid through the supplementary flow path 640, the concentration of the sterilizing liquid can always be maintained in a certain range.

Meanwhile, a water level sensor (not shown) and/or a concentration sensor (not shown) are provided inside the storage tank 660, and measurement information of the sensors may be transmitted to the controller 800. When the level and concentration of the sterilizing solution in the storage tank 660 falls below a preset value, the control unit 800 replenishes water or an undiluted solution of the sterilizing solution. For example, when the concentration of the sterilization solution in the storage tank 660 is less than the reference value, the controller 800 opens the fourth valve 606 to supply the sterilization solution undiluted solution in the stock solution tank 670 to the storage tank 660. I can. Accordingly, the sterilizing liquid in the storage tank 660 can always maintain a constant concentration.

The air separated from the sterilizing liquid in the separation unit 500 may be supplied to the indoor space through the air discharge unit 700. The air discharge unit 700 may include a discharge duct 710 connecting the separation unit 500 and the indoor space, and a discharge fan 720 for generating air flow in the direction of the indoor space from the separation unit 500. have.

One end of the discharge duct 710 may be connected to the separating part 500, and an outlet 711 communicating with the indoor space may be provided at the other end. Meanwhile, a plurality of discharge ports 711 may be formed as necessary.

The exhaust fan 720 operates under the control of the controller 800 and may generate air flow from the inside of the exhaust duct 710 in the direction of the exhaust port 711. Accordingly, when the control unit 800 operates the discharge fan 720, the air separated from the sterilizing solution in the separation unit 500 may be introduced into the indoor space through the discharge port 711.

Alternatively, the exhaust fan 720 may be removed as needed. This is because only the blowing action of the suction fan 120 and the stirring blade 323 is sufficient to reduce the exhaust air to the room. However, for smoother circulation, a discharge fan 720 may be additionally installed, and whether or not the discharge fan 720 is operated or its rotation speed may be adjusted by the controller 800.

In one embodiment, the height H2 of the discharge port 711 may be lower than the height H1 of the suction port 111. As shown in FIG. 2, it has been described above that the inlet 111 is provided at a high position, such as near the ceiling, in order to block the propagation of breathing between people. In order to prevent the exhaust air through the outlet 711 from interfering with the air intake through the inlet 111, the installation height H2 of the outlet 711 is a different installation height H1 of the inlet 111, It is more preferable to install the discharge port 711 at a lower position than the suction port 111.

In one embodiment, the inlet 111 and the outlet 711 may be installed in different directions. For example, when the air sterilization apparatus 10 according to the present invention has a rectangular parallelepiped housing, the inlet 111 and the outlet 711 may be provided on different surfaces. This is to prevent the intake air flow and the exhaust air flow from interfering with each other.

The controller 800 controls the operation of each part, and may include a display device (not shown) or a control panel 810.

The display device displays the operating state of the air sterilization device 10, and may be configured with a touch panel or the like as necessary to directly receive a user's control command.

The control panel 810 is a means for a user to input a control command. In this case, the control command may include selection of power on and off of the air sterilization device 10, rotation speed of the fans 120 and 720, selection of the circulation flow path 630 and the supplementary flow path 640, and the like.

As described above, the air sterilization apparatus 10 according to the present invention absorbs air from the indoor space to remove harmful substances such as bacteria, viruses, and fine dust, and then returns it to the indoor space in real time. Can be sterilized.

In particular, by changing the specifications of the fans 120 and 720, the size of the mixing unit 300, etc., it is possible to easily change the design to a small capacity or a large capacity. Therefore, it can be applied regardless of the size of the indoor space.

In addition, the air sterilization apparatus 10 according to the present invention removes harmful substances by contacting contaminated air with the sterilizing solution, but by applying a unique mixing unit 300 composed of a fixing unit 310 and a rotating unit 320 By maximizing the degree of mixing of air and sterilizing liquid, the effect of removing harmful substances contained in the air can be greatly improved.

In addition, the air sterilization apparatus 10 according to the present invention may separate the sterilizing liquid used after removing harmful substances from the air from the air, and reduce only the gaseous air from which the sterilizing liquid has been removed back to the indoor space. That is, since the sterilizing liquid only circulates inside the air sterilizing device 10, it is possible to prevent the sterilizing liquid component from flowing into the indoor space.

In addition, the air sterilization apparatus 10 according to the present invention manages the sterilization liquid to maintain a constant quantity and concentration, and, if necessary, can remove harmful substances contained in the sterilization liquid using the filter 650. Accordingly, it is possible to always maintain the best air sterilization performance.

Although the above has been described with reference to embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. You will understand that you can.

10: air sterilization device
100: air intake part 200: sterilizing liquid injection part
300: mixing unit 400: cooling unit
500: separation unit 600: sterilization liquid circulation unit
700: air exhaust unit 800: control unit

Claims (10)

An air intake unit for inhaling air in the indoor space;
A sterilizing liquid spraying part for spraying a sterilizing liquid into the air intake part;
A mixing unit connected to the air intake unit and mixing air and a sterilizing solution;
A separation unit connected to the mixing unit and configured to remove the sterilizing solution from the mixture of air and the sterilizing solution;
An air discharge unit for discharging the air from which the sterilizing liquid has been removed to an indoor space; And
And a control unit for controlling the operation of the air intake unit, the sterilization liquid injection unit, the mixing unit, the separation unit, and the air discharge unit,
The mixing unit has a stator connected to the air intake unit, and a rotor installed at a lower end of the stator to face the stator and rotating at a preset speed,
The air and the sterilizing liquid supplied to the mixing unit through the air intake unit pass through the space between the stator and the rotor and move to the separation unit,
The stator,
A disk-shaped fixed disk;
A mixture introduction pipe passing through the center of the fixed disk and connected to the air intake unit; And
It includes a plurality of fixed blades protruding from the fixed disk toward the rotor,
The rotor is,
A disk-shaped rotating disk facing the fixed disk;
A drive motor that rotates the rotating disk;
A plurality of stirring blades protruding from the rotating disk toward the stator; And
And a mixture discharge pipe provided on a side of the rotating disk and transferring a mixture of air and a sterilizing liquid to the separation unit. delete The air sterilizing apparatus according to claim 1, wherein the fixed blades are spaced apart from each other on a virtual circumference having a first radius at the center of the fixed disk, and have a rectangular column shape. The air according to claim 3, wherein the stirring blades are spaced apart from each other on an imaginary circumference of a second radius different in size from the first radius at the center of the rotating disk, and have a blade shape. Sterilization device. The method of claim 4,
The fixed wings,
A first fixed blade row comprising a plurality of fixed blades spaced apart from each other on an imaginary circumference having the first radius; And
It is composed of a second fixed blade row consisting of a plurality of fixed blades spaced apart from each other on an imaginary circumference of a third radius greater than the first radius,
The stirring blades,
A first stirring blade row consisting of a plurality of stirring blades spaced apart from each other on a virtual circumference having the second radius;
A second stirring blade row comprising a plurality of stirring blades spaced apart from each other on an imaginary circumference of a fourth radius greater than the second radius; And
A third stirring blade row comprising a plurality of stirring blades spaced apart from each other on an imaginary circumference of a fifth radius greater than the fourth radius; Consists of,
The first radius is larger than the second radius and smaller than the fourth radius, and the third radius is larger than the fourth radius and smaller than the fifth radius. The method of claim 4, wherein when a tangent line is drawn with respect to the virtual circumference at a point where the stirring blade contacts the imaginary circumference, the stirring blade forms a predetermined angle with the tangent line. Air sterilization device. The method of claim 1, wherein the separation unit,
A demister that selectively collects a liquid sterilizing solution;
A separation duct connecting the mixture discharge pipe and the demister; And
And a collector provided inside the separation duct and collecting the sterilizing liquid falling from the demister. The air sterilization apparatus according to claim 7, wherein the cross-sectional area of the demister is larger than the cross-sectional area of the mixture discharge pipe. The method of claim 7, further comprising a sterilizing liquid circulation part connected to the collector and supplying the collected sterilizing liquid to the sterilizing liquid spraying part,
The sterilizing liquid circulation unit,
A collection tank for storing the sterilizing liquid delivered from the collector;
A filter that removes at least one of fine dust, bacteria, and viruses contained in the sterilizing solution;
A storage tank in which a sterilizing solution of a preset concentration is stored;
A circulation passage directly connecting the water collecting tank and the sterilizing liquid injection unit; And
And a supplemental flow path connecting the water collecting tank and the sterilizing liquid spraying part so that the sterilizing liquid stored in the water collecting tank is supplied to the sterilizing liquid spraying part after sequentially passing through the filter and the storage tank,
The control unit selectively opens the circulation flow path and the supplementary flow path. The air sterilization apparatus according to claim 1, further comprising a cooling unit supplying a cooling medium into the fixed disk and the fixed blades.

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