KR101095410B1 - Air sterilizing device - Google Patents

Abstract

It is an object of the present invention to provide an air sterilization apparatus which can ensure a chlorine concentration that can be electrolyzed regardless of the region of use, without causing users to feel inconvenience.

In order to solve the said subject, the air disinfection apparatus 1 of this invention divides the inside of the case 11 up and down by the support plate 21, and it is an electrolytic unit in the upper chamber 22 of the case 11. (46), the gas-liquid contact member 53 to which the electrolyzed water generated by the electrolytic unit 46 is supplied, and the electrolyzed water flowing from the gas-liquid contact member 53 while storing electrolyzed water generated by the electrolytic unit 46. And a circulating pump 44 for pumping up the electrolytic water stored in the drip member 42 and supplying it to the gas-liquid contact member 53 again. The lower chamber 23 of the case 11 is provided. In the air sterilizing apparatus 1 having the blowing fan 31 which sends indoor air to the gas-liquid contact member 53, the upper chamber 22 of the case 11 and the drip member 42 are provided. It is set as the structure which arrange | positions the saline tank 90 which stored the saline to supply.

Air sterilizer, case, support plate, electrolytic unit, gas-liquid contact member, circulation pump

Description

Air Sterilizer {AIR STERILIZING DEVICE}

The present invention relates to an air sterilization apparatus capable of removing airborne microorganisms (hereinafter, simply referred to as "viruses") such as bacteria, viruses, and fungi.

Background Art Conventionally, an air sterilization apparatus is proposed in which electrolytic water containing hypochlorous acid is produced by electrolysis of tap water, and the removal of viruses and the like suspended in the air using the electrolytic water (see Patent Document 1, for example). The air sterilizer is intended to sterilize air by supplying electrolyzed water to a humidifying element made of a nonwoven fabric or the like, contacting a virus or the like in the air with the electrolyzed water on the humidifying element to inactivate the virus or the like.

[Patent Document 1] Japanese Unexamined Patent Publication No. 2002-181358

The electrolysis mentioned above is performed using chlorine ion contained in tap water. However, depending on the area of use of the air sterilizer, the concentration of chlorine in the tap water is low, which may make electrolysis difficult. Conventionally, there is a method of performing electrolysis by allowing a larger current to flow through an electrolytic unit, but there is a problem that the load on the electrode is large and the frequency of replacing the electrode by maintenance is increased. There is also a method of electrolyzing by supplying salt (that is, salt) to the tap water to be supplied, but it is cumbersome to supply salt every time the user drives.

Accordingly, it is an object of the present invention to provide an air sterilization apparatus which can ensure a chlorine concentration that can be electrolyzed regardless of the region of use without causing any inconvenience to the user.

In order to solve the above-mentioned problem, the air disinfection apparatus of this invention divides the inside of a case up and down by the support plate, and the electrolytic unit and the electrolytic water produced | generated by the said electrolytic unit are supplied to the upper chamber of the said case. The gas-liquid contact member, the drip member which receives the electrolyzed water produced by the said electrolytic unit, and receives the electrolyzed water which flows from the said gas-liquid contact member, and the electrolyzed water stored in the said drip member is spun up again to the said gas-liquid contact member. An air sterilization apparatus having a circulation pump for supplying and having a blower fan for sending indoor air to the gas-liquid contact member to a lower chamber of the case, the apparatus for supplying to the drip tray member to the upper chamber of the case. Characterized in that the saline tank in which the saline is stored.

According to this configuration, the saline solution is automatically supplied to the electrolyzed water in the drip tray member.

In the air sterilizing apparatus, the present invention provides a pump for pumping up the saline solution of the saline tank, and connects the suction port of the pump to the saline tank via a one-touch joint, and the discharge port of the pump is connected to the saline solution. It is connected to the supply nozzle of the, It is characterized by arrange | positioning this supply nozzle on the said drip member.

According to this structure, since the saline tank can be detached from the suction port of the pump with one touch, taking out (taking out) of the saline tank becomes easy. Further, by arranging the supply nozzle above the drip tray member having a relatively high humidity, precipitation of salt from the supply nozzle can be prevented.

In the air sterilization apparatus, the upper chamber is partitioned into a sterilization space accommodating the gas-liquid contact member and a water circulation space accommodating the circulation pump by a partition wall. And a saline tank and a supply nozzle at the same time, and the pump is arranged in a space having low humidity adjacent to the water circulation space.

According to this configuration, by providing a saline tank and a supply nozzle in a water circulation space where humidity is higher than that of the sterilization space, the evaporation of water in the saline tank can be delayed, and the saline solution in the saline tank can be accommodated at a predetermined salinity concentration. In addition, precipitation of salt in the supply nozzle can be prevented. In addition, by disposing the pump in a space with low humidity, it is not necessary to perform a moisture proof treatment or the like on the pump.

In addition, the present invention is characterized in that in the air sterilizing apparatus, a holder for mounting the saline tank is provided above the drip member, and the feed nozzle for the saline solution is supported on the holder.

According to this configuration, there is no need to separately prepare a member for supporting the supply nozzle.

[0019] The present invention is also characterized in that, in the air sterilization apparatus, a check valve is provided at a supply nozzle for supplying saline to the drip member, and the supply nozzle is separated from the water surface of the electrolytic water of the drip member. .

According to this configuration, it is possible to prevent the electrolytic water of the drip member from flowing back into the saline tank by the check valve. In addition, it is possible to reliably prevent backflow of the electrolytic water by disposing the supply nozzle away from the water surface. In addition, it is possible to prevent corrosion inside the check valve caused by the check valve being in contact with the electrolyzed water.

In addition, the present invention is characterized in that in the air sterilization device, a valve device for adjusting the internal pressure in the tank is provided in the saline tank.

According to this configuration, the pressure in the saline tank can be maintained in a constant state, and the saline solution can be stored at a predetermined salinity concentration.

The present invention relates to a water gutter member for storing electrolyzed water generated by an electrolytic unit and receiving electrolyzed water flowing down from the gas-liquid contact member, a circulation pump for pumping up the electrolyzed water stored in the drip member and supplying it to the gas-liquid contact member again. Since a saline tank is provided to supply the saline solution to the drip tray member, the saline water is automatically supplied to the electrolyzed water in the drip member, so that the user does not have to feel any inconvenience. Can be secured.

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described with reference to drawings.

1 is a perspective view of an air sterilization apparatus 1 according to the present embodiment, and FIG. 2 is a rear side perspective view of this air sterilization apparatus 1. The air sterilizer 1 electrolyzes water to generate electrolyzed water containing predetermined active oxygen species, and sterilizes the air in the room sucked into the air sterilizer 1 using the electrolyzed water. It is a device that blows clean air indoors.

As shown in FIG. 1, the air sterilization apparatus 1 is provided with the box-shaped case 11 formed longitudinally long, and is installed, for example at intervals at the bottom. In the case 11, the suction grille 12 is formed in the lower part of the both sides of this case 11, and the suction port 15 is formed in the lower end part of the front surface of this case 11. As shown in FIG.

In addition, a jet port 13 is formed on the upper surface of the case 11, and an auto louver 20 for changing the direction in which air is jetted is provided in the jet port 13. The auto louver 20 is configured to close the jet port 13 when the operation stops.

On the upper surface of the case 11, an operation lid 16 is disposed on the front side of the jet port 13, and when the operation lid 16 is opened, an operation panel for performing various operations of the air sterilizer 1 (not shown) ) Is exposed. In addition, an opening / closing lid 29 for opening and closing the saline tank 90 to be described later is provided on one side of the upper surface of the case 11 (right side from the front). Moreover, the holding part 17 is formed in the upper part of the both sides of the case 11, respectively. These gripping portions 17 are recesses for holding hands when the case 11 is lifted by hand, and can be lifted and moved by the air sterilizer 1 alone during transportation.

In addition, the upper cover member 18 and the lower cover member 19 arranged in the up-down direction are detachably arranged in the front surface of the case 11, and these upper cover member 18 and the lower cover member 19 are detachable. The internal structure of the air sterilization apparatus 1 is exposed by removing it. The lower cover member 19 is provided at the lower end of the lower cover member 19 with an arc portion 19A curved toward the back side of the case 11, and the suction port 15 is provided on the arc portion 19A. ) Is formed.

In addition, as shown in FIG. 2, a connection port 14 for supplying water to the air disinfection device 1 is formed in the upper rear side of the case 11, and an external water supply source (for example, a water supply is provided in the connection port 14). Is connected to the water supply pipe 27. Further, a drain pipe 28 for discharging the water in the air sterilizer 1 to the outside is provided at the lower rear side of the case 11.

Next, the internal structure of the air sterilization apparatus 1 is demonstrated with reference to FIG. 3 and FIG.

3 is a perspective view showing a main configuration of the inside of the air sterilization apparatus 1, and FIG. 4 is a side cross-sectional view. As shown in FIG. 3 and FIG. 4, the case 11 is provided with a supporting plate 21 for dividing the inside of the case 11 up and down to the upper chamber 22 and the lower chamber 23. Are separated.

The lower side chamber 23 is divided into left and right sides by the partition plate 24, and in one chamber 23A, a blowing fan 31 and a fan motor (not shown) for driving the blowing fan 31 are accommodated. At the same time, the drain portion 57 having the drain pipe 28 is housed in the other chamber 23B. On the front side of one chamber 23A, a prefilter 34 is disposed at a position facing the lower cover member 19 (FIG. 1). This pre-filter 34 is formed in the magnitude | size corresponding to the opening part of 23 A of one chambers, and is inserted in this opening part, and is arrange | positioned. When the lower cover member 19 is removed, the prefilter 34 is exposed, and the prefilter 34 can be easily detached.

The pre-filter 34 passes through the coarse dust filter 25 which collects large particle diameters, such as dust in the air sucked in through the intake grill 12 and the inlet 15, and this coarse dust filter 25, For example, it is comprised by providing the intermediate | middle performance filter 26 which collects the thing of particle size 10 (micrometer) or more (for example, pollen). By this pre-filter 34, pollen, dust, etc. which float in the air sucked from the suction grill 12 and the suction port 15 are removed.

In the upper chamber 22, the electrical equipment box 39 is disposed on the supporting plate 21 above the one chamber 23A, and the gas-liquid contact member 53 is disposed above the electrical equipment box 39. There is. Moreover, the drip member 42 which receives the electrolyzed water which flowed out from this gas-liquid contact member 53 is arrange | positioned between these electrical equipment boxes 39 and the gas-liquid contact member 53. As shown in FIG. Although not shown in the electronic device box 39, various electric components such as a control board on which various devices constituting a control unit for controlling the air sterilization device 1 are mounted, and a power supply circuit for supplying a power voltage to a fan motor are provided. It is accepted.

Moreover, as shown in FIG. 4, the upper side chamber 22 is provided with the back side space 1A and the front side space 1B divided by the gas-liquid contact member 53. As shown in FIG. The back side space 1A communicates with the air vent 31A of the blower fan 31 via the opening 21A formed in the support plate 21. Moreover, above the back side space 1A, the guiding plates 32A and 32B which inclined downward toward the front side from the back side of the case 11 differ in the position of a height direction, Two sheets are provided, and these two guide plates 32A and 32B are supported by the frame member 32C. For this reason, the air blown out from the blower port 31A of the blower fan 31 touches these two guide plates 32A, 32B, and the gas-liquid contact member (through the path | route shown by the arrow in FIG. 53 is sprayed on the back side.

The gas-liquid contact member 53 is a member for contacting the electrolyzed water with air injected into the gas-liquid contact member 53. When the air sucked into the case 11 in the gas-liquid contact member 53 comes into contact with the electrolyzed water containing the predetermined active oxygen species, air is sterilized by deactivation of a virus or the like contained in the air. .

The housing 33 is arrange | positioned at the front surface side of the gas-liquid contact member 53, and the front-side space 1B is formed by this housing 33 and the gas-liquid contact member 53. As shown in FIG. This housing 33 has a function of guiding air in the front space 1B to the jet port 13 and receiving water (so-called splash water) jetted from the gas-liquid contact member 53. Specifically, in the housing 33, the bottom surface 33A of the inner side of the housing 33 is formed in a downward gradient toward the gas-liquid contact member 53, and the tip portion of the bottom surface 33A is the drip member 42. Extends above). As a result, water jetted into the front space 1B returns to the drip member 42 through the bottom surface 33A.

Between the housing 33 and the blower outlet 13, the blower filter 36 is arrange | positioned in order to prevent entry of the foreign material from inside this blower outlet 13 into the case 11 inside. It is preferable that this jet filter 36 is appropriately coarse so as not to significantly increase the ventilation resistance of the air passing through the gas-liquid contact member 53.

The gas-liquid contact member 53 is a filter member having a honeycomb structure, and has a structure for supporting an element part in contact with gas by a frame. Although the element part is not shown in figure, a corrugated board member and a flat plate member are laminated | stacked, and many triangular opening part is formed between these corrugated board member and a flat plate member. Therefore, the gas contact area at the time of passing air through the urea part is secured, the electrolytic water can be dropped, and the structure is difficult to be clogged.

In the urea part, a material with little deterioration due to electrolytic water, for example, polyolefin resin (polyethylene resin, polypropylene resin, etc.), PET (polyethylene terephthalate) resin, vinyl chloride resin, fluorine resin (PTFE, PFA, ETFE) Or the like, or a ceramic material, and PET resin is used in this configuration. In addition, the urea portion is subjected to a hydrophilic treatment to increase the affinity for the electrolyzed water, thereby maintaining the water retention (wetting property) of the electrolytic water of the gas-liquid contact member 53, thereby making active oxygen species (active) Oxygen substance) and contact with indoor air last a long time.

In addition, a watering box 51 for distributing the electrolytic water uniformly on the gas-liquid contact member 53 is incorporated in the upper portion of the gas-liquid contact member 53. The sprinkling box 51 includes a tray member for temporarily storing electrolyzed water, and a plurality of sprinkling holes (not shown) are opened in the side of the tray member, and the sprinkling hole is connected to the gas-liquid contact member 53. Electrolyzed water is added dropwise.

In addition, a sorting sheet (not shown) is provided on the upper surface of the gas-liquid contact member 53 in order to efficiently disperse the electrolyzed water dropped from the sprinkling box 51. This sorting sheet is a sheet (fabric, nonwoven fabric, etc.) made of a fibrous material having liquid permeability, and one or more sheets are provided along the thickness direction cross section of the gas-liquid contact member 53.

As shown in FIG. 3, the drip member 42 includes a drip tray 42A positioned below the gas-liquid contact member 53 and a storage 42B extending above the other chamber 23B. It is provided and is integrally formed. Water flowing from the drip tray 42A is stored in the reservoir 42B. Further, the reservoir 42B is formed with a bottom first deep bottom portion 42B1 deeper than the drip tray 42A, and a second bottom bottom 42B2 shallower than the first bottom bottom 42B1. have.

The first float switch 42B1 is provided with a first float switch 43A and a second float switch 43B for detecting the water level. The first float switch 43A is a switch which is operated when the water level of the reservoir 42B is lower than the predetermined lower limit level, and the second float switch 43B is a predetermined upper limit water level of the reservoir 42B. This switch is operated when it exceeds.

Moreover, the circulation pump 44 is provided in the 1st core bottom part 42B1. This circulation pump 44 operates under the control of the control part 100, and the water stored in the 1st core bottom part 42B1 (storage part 42B) is pumped up to the discharge port of this circulation pump 44, The supply pipe 71 for supplying to the gas-liquid contact member 53 via the sprinkling box 51 is connected. An electrolytic cell (electrolytic unit) 46 is connected to the supply pipe 71 via a branch pipe 72 branched between the circulation pump 44 and the watering box 51.

As described later, the electrolytic cell 46 incorporates a plurality of electrodes and applies electrolytic voltage supplied from the control unit 100 between these electrodes to electrolyze water to generate electrolytic water. A discharge port 46A for discharging the electrolyzed water generated in the electrolytic cell 46 is formed on the upper surface of the electrolytic cell 46, and the discharge pipe 46 for conveying the electrolytic water to the storage portion 42B is provided at the discharge port 46A. Connected.

In addition, at the inlet portion of the reservoir 42B, that is, at the junction of the reservoir 42B and the drip tray 42A, a filter member for collecting solids mixed in the water flowing into the reservoir 42B. 74 is arrange | positioned. The outlet 73A of the conveyance pipe 73 is provided above this filter member 74, and collects the solid substance (for example, the scale component formed in the electrode surface) discharged with water from the electrolytic cell 46. It is possible. Since this filter member 74 is arrange | positioned in the inlet part of the storage part 42B in the state which can be visually confirmed from the upper side, the replacement time of the filter member 74 can be judged easily visually. In addition, when the filter member 74 is replaced, the filter member 74 may be removed by replacing with a finger, so that maintenance and repair can be performed easily without using a tool or the like.

In this embodiment, a part of the water pumped up by the circulation pump 44 is supplied to the gas-liquid contact member 53 via the sprinkling box 51, and the remaining water is supplied to the electrolytic cell 46. The electrolyzed water generated in the electrolytic cell 46 is supplied to the reservoir 42B via the filter member 74, and the electrolyzed water stored in the first core bottom 42B1 of the reservoir 42B is a circulation pump 44. The dispersion is supplied again to the gas-liquid contact member 53 and the electrolytic cell 46 by the above. As described above, in the electrolytic cell 46, electrolysis water is repeatedly performed using electrolyzed water, so that electrolytic water having a high concentration of active oxygen species can be generated. In addition, by circulating and utilizing the electrolyzed water discharged from the gas-liquid contact member 53, the water resource can be effectively utilized.

Moreover, as shown in FIG. 3, the water supply part 60 which supplies the tap water from the said water supply piping 27 to the drip member 42 is provided above the 1st core bottom part 42B1. This water supply part 60 is connected to the water supply piping 27 via the connection port 14 formed in the back surface of the case 11. As shown in FIG. The water supply part 60 is connected to the water supply valve 61 which opens and closes according to the water level of the storage part 42B, one end is connected to the connection port 14, and the other end is 61A of the upstream side of the water supply valve 61. The first water supply pipe 62 connected to the second water supply pipe, the second water supply pipe 63 connected to the downstream end portion 61B of the water supply valve 61, and the water supply opened downward at the distal end of the second water supply pipe 63; A sphere 64 is provided.

The water supply valve 61 is an electromagnetic valve that is opened and closed by the control of the control unit 100 in accordance with the water level detected by the first float switch 43A and the second float switch 43B. This water supply valve 61 is arrange | positioned so that the upstream end 61A may be lower and the downstream end 61B may be upper. That is, the water supplied to the water supply part 60 is arrange | positioned so that the inside of the water supply valve 61 may flow up from the bottom. According to this, even when the water supply valve 61 is closed, even if water leaks from the connection part of the upstream end 61A of the water supply valve 61, and the 1st water supply pipe 62, the said water leaks It does not concern with the water supply valve 61, and it can prevent generation | occurrence | production of problems, such as an earth leakage, by this.

In addition, the water supply port 64 of the second water supply pipe 63 has a sufficient distance from the water surface of the water stored in the drip member 42 not to contact the water surface (in this embodiment, the upper end of the drip member 42). 35 mm) away from the surface. According to this, even when the inside of the water supply part 60 and the water supply pipe 27 becomes a negative pressure, the water stored in the water receiving member 42 is supplied through the water supply port 60 and the water supply pipe ( 27) is prevented from flowing back.

In addition, this water supply port 64 is arrange | positioned above the filter member 74 mentioned above. According to this, since the water supplied through the water supply port 64 is dripped on the filter member 74, this dropping sound can be reduced and the quietness at the time of water supply can be aimed at.

In this embodiment, the water stored in the drip tray member 42 is configured to be properly discharged. Specifically, below the reservoir 42B, a drain valve unit 81 for discharging water stored in the drip member 42 to the drain 57 is disposed. The drain valve unit 81 includes a first drain pipe 82 connected to the bottom of the first core bottom 42B1 of the reservoir 42B, and a drain valve 83 connected to the first drain pipe 82. And a second drain pipe 84 connected to the drain valve 83, and the second drain pipe 84 is connected to the drain 57. The drain valve 83 is opened and closed by the control of the controller 100. This control unit is used whenever the cumulative operation time of the air sterilization operation (normal operation) of the air sterilization apparatus 1 reaches a predetermined time, or whenever the operation stop time of the air sterilization apparatus 1 reaches a predetermined time. Alternatively, at a predetermined time, the drain valve 83 is opened to discharge water accumulated in the first core bottom portion 42B1 to the outside via the drain portion 57.

In addition, an overflow pipe 85 is connected to the bottom of the second core bottom 42B2 of the storage part 42B, and the overflow pipe 85 includes a drain valve 83 and a drain part. It is connected to the said 2nd drain pipe 84 between (57). For this reason, even if the water level in the 1st core bottom part 42B1 rises and this water reached | attained the 2nd core bottom part 42B2, this water is still provided in the overflow pipe 85, the 2nd drain pipe 84, and the drain part. It is discharged to the outside through (57).

In addition, an air bleeding pipe 86 having a diameter smaller than that of the second drain pipe 84 is connected to the second drain pipe 84. The air bleeding pipe 86 is for discharging the air in the drain valve unit 81 to the outside at the time of drainage, and is arranged such that the tip portion of the air bleed pipe 86 is higher than the drip member 42. have.

The drain portion 57 includes a trap pipe 58 connected to the second drain pipe 84 and a drain pipe 28 connected to the trap pipe 58. The trap piping 58 collects water in the trap piping 58. For this reason, the water accumulated in the trap piping 58 isolate | separates the drain piping 28 and the drain valve unit 81, and the odor of waste water is prevented from floating in the air disinfection apparatus 1. As shown in FIG.

The air sterilization apparatus 1 of this embodiment is equipped with the detachable saline tank 90 which supplies a saline solution to the drip member 42, as shown in FIG.

The upper chamber 22 is further divided up and down by the drip member 42 and the plate-shaped member 55, and a high humidity space 22A having a relatively high humidity above the drip member 42 and the drip member. Below the 42, a low humidity space (space) 22B having a relatively low humidity is provided. The electrical equipment box 39 mentioned above is arrange | positioned in the low humidity space 22B. In the high humidity space 22A, a partition wall 30A partitioning the high humidity space 22A from side to side is provided, and the high humidity space 22A includes a sterilization space 22A1 for accommodating the gas-liquid contact member 53, and a circulation pump ( It is partitioned into the water circulation space 22A2 containing 44. 22 A2 of water circulation spaces are isolate | separated by these drip tray members 42 and partition walls 30A, and the water circulation part covers 30B-30D which cover the side surface of water circulation space 22A2, and air is isolated. The humidity is higher than that of the blowing sterilization space 22A1.

The saline tank 90 storing the saline is disposed in the humid water circulation space 22A2. As a result, the evaporation of the water in the saline tank 90 can be slowed down, and the saline solution in the tank can be accommodated at a predetermined salt concentration.

5 is a perspective view of the saline tank 90. 6 is a longitudinal sectional view of the air sterilizing apparatus 1 showing the periphery of the saline tank 90.

The saline tank 90 is formed using a raw material with little deterioration due to saline, for example, polypropylene resin or the like. The saline tank 90 is formed in a size capable of storing an amount of saline in a sufficiently long period of time with respect to the maintenance / repair period (for example, one year) of the air sterilizer 1. In the saline solution tank 90 of the present embodiment, the volume is 1 liter (l), thereby making the maintenance and repair period of the saline solution tank 90 two years.

The salt concentration (weight percent) of the saline solution stored in the saline tank 90 is 20% or more at which germ propagation is suppressed, and preferably 26% (saturation concentration) or less at which salt starts to precipitate. In the saline solution tank 90 of the present embodiment, saline with a salt concentration of 20% is stored using a saline solution having a sodium chloride of 99% or more in purity.

On the upper surface of the saline tank 90, as shown in FIG. 5, a water supply port 90A for supplying saline to the saline tank 90 is provided. A valve device 90B for adjusting the internal pressure in the saline tank 90 can be attached to the water inlet 90A. The valve device 90B can maintain the pressure in the saline tank 90 in a constant state, and can store the saline solution at a predetermined salt concentration.

In addition, a suction port 90C is provided on an upper surface of the saline tank 90, and a suction nozzle 90D extends from the suction port 90C into the saline tank 90. The one-touch bonding part 90E is attached to the suction port 90C.

The saline tank 90 is mounted on a holding table 91 disposed above the drip tray member 42 (see FIG. 6). The holder 91 is fixed to the water circulation portion cover 30B disposed on the front surface of the air sterilizer 1. Therefore, since the saline tank 90 is arranged on the front side of the air sterilizer 1, the saline tank 90 is easily accessible from the opening and closing cover 29 (see FIG. 1).

The holder 91 has a rectangular bottom surface 91A horizontally fixed to the water circulation portion cover 30B and a side surface standing from the bottom surface 91A and fixed perpendicularly to the water circulation portion cover 30B ( 91B), 91C and the side surface 91D which stands from 91A of base surfaces in parallel with water circulation part cover 30B are provided. When the saline tank 90 is disposed on the bottom surface 91A, the saline tank 90 is surrounded by the side surfaces 91B to 91D, so that the air sterilizing apparatus 1 does not fall off from the holding table 91 even when the air sterilizer 1 is slightly shaken during transportation. It is.

The saline tank 90 is simply fixed to the bottom surface 91A without being fastened to the holding table 91 by bolting or the like, and the tube 92 made of polyurethane is connected to the one-touch joint 90E. When the saline tank 90 is taken out, the tube 92 can be easily detached from the one-touch junction 90E with a finger, so that maintenance and repair can be easily performed without using a tool or the like. .

The tube 92 is connected to the tube 93, which is connected to the supply nozzle 94 attached to the bottom surface 91A of the holder 91. In this way, by supporting the supply nozzle 94 on the holding table 91 on which the saline tank 90 is mounted, there is no need to provide a member for supporting the supply nozzle 94 separately, and the cost increase can be suppressed.

The supply nozzle 94 is provided with the check valve 94A which prevents a backflow. Moreover, as shown in FIG. 6, this supply nozzle 94 is sufficient distance from the water surface of the water stored in the drip member 42 not to contact this water surface (in this embodiment of the drip member 42). The distance H from the bottom surface is arranged at a distance of 62 mm. According to this, even when the inside of the tubes 92, 93 and the saline tank 90 becomes negative pressure, the electrolyzed water stored in the drip member 42 is passed through the tube 92, ( 93 and backflow in the saline tank 90 are reliably prevented. For this reason, it is unnecessary to use expensive material which is hard to deteriorate with electrolytic water in the check valve 94A, and can raise the cost of the check valve 94A.

Since the supply nozzle 94 is disposed above the electrolyzed water stored in the drip member 42 in the high water circulation space 22A2, the supply nozzle 94 is always in a high humidity state, and the salt is supplied to the supply nozzle 94. This precipitation is prevented.

Moreover, the supply nozzle 94 is arrange | positioned above the 1st core bottom part 42B1 (storage part 42B) of the bottom deeper than the 2nd core bottom part 42B2 of the drip member 42. Therefore, even if the water level of the reservoir 42B of the drip member 42 is at a predetermined lower limit level, the saline solution is supplied directly to the electrolytic water of the reservoir 42B, and the salt is deposited on the drip member 42. Is prevented.

The saline solution stored in the saline tank 90 can be pumped up by the pump 95 operating under the control of the control part 100. A tube 92 connected to the saline tank 90 is connected to the suction port 95A of the pump 95. On the other hand, the tube 93 connected to the supply nozzle 94 is connected to the discharge port 95B of the pump 95. These tubes 92 and 93 penetrate through the water circulation portion cover 30B from the water circulation space 22A2 and extend to the low humidity space 22B adjacent to the water circulation space 22A2. The pump 95 is arrange | positioned in the space 22B. Thus, since the pump 95 is arrange | positioned in the low humidity space 22B with comparatively low humidity, the pump 95 which does not perform moisture proof processing etc. can be used.

FIG. 7 is a view for explaining the supply state of electrolyzed water, FIG. 7 (A) is a schematic diagram showing the configuration of the air disinfection mechanism, and FIG. 7 (B) is a diagram showing the configuration of the electrolytic cell 46 in detail.

With reference to FIG. 7, the supply of the electrolytic water to the gas-liquid contact member 53 is demonstrated.

When the operation operation of the air sterilizer 1 is performed, the water level of the reservoir 42B is detected, and when the water level does not reach the predetermined water level, the water supply valve 61 is opened and the drip member 42 Tap water is supplied to the water level, and the water level of the reservoir 42B of the drip tray member 42 reaches a predetermined water level.

Water in the reservoir 42B is pumped up by the circulation pump 44, and a part thereof is supplied to the electrolytic cell 46. As shown in Fig. 7B, the electrolytic cell 46 is provided with a pair of electrodes 47 and 48, one of which is positive and the other of which is negative. These electrodes 47, 48 By applying a voltage between), the tap water introduced into the electrolytic cell 46 is electrolyzed to produce electrolyzed water containing active oxygen species. Here, the active oxygen species is oxygen having an oxidation activity higher than that of ordinary oxygen, and related substances, and so-called narrow-range active oxygen such as superoxide anion, singlet oxygen, hydroxyl radical or hydrogen peroxide, ozone, It is assumed that a so-called wide active oxygen such as halogen acid or the like is contained.

The electrodes 47 and 48 are, for example, electrode plates made of titanium (Ti) and a coating layer made of iridium (Ir) and platinum (Pt).

If the electrode 47 is used as an anode electrode and the electrode 48 is a cathode electrode, and a voltage is applied between the electrode 47 and the electrode 48 from an external power source, and energized, in the electrode 48 as a cathode electrode, Hydrogen ions (H ⁺ ) and hydroxide ions (OH ⁻ ) in water react as shown in the following formula [1]:

^{4H + + 4e - + (4OH} -) → 2H 2 + (4OH -) ... [1].

On the other hand, in the electrode 47 as the anode electrode (anode), water is electrolyzed as shown in the following formula [2]:

^{_{2H 2 O → 4H + + O}} 2 + 4e - ... [2].

In addition, in the electrode 47, chlorine ions (chloride ions: Cl ⁻ ) contained in the water react as shown in the following formula [3] to generate chlorine (Cl ₂ ):

_{^{2Cl - → Cl 2 + 2e -}} ... [3].

This chlorine also reacts with water to generate hypochlorous acid (HClO) and hydrogen chloride (HCl), as shown in the following formula [4]:

Cl ₂ + H ₂ O → HClO + HCl... [4].

Hypochlorite generated at the electrode 47 is contained in a broad range of active oxygen species, and has a strong oxidation action and a bleaching action. The aqueous solution in which hypochlorous acid is dissolved, that is, the electrolyzed water produced by the air sterilizing apparatus 1 exhibits various air cleaning effects such as inactivation of viruses, sterilization, decomposition of organic compounds, and the like.

When hypochlorous acid having a high sterilizing power is produced by the electrodes 47 and 48, when the electrolytic water containing the hypochlorous acid is dropped from the water spray box 51 to the gas-liquid contact member 53, the blower fan 31 The air blown out by the < RTI ID = 0.0 >) < / RTI > As a result, viruses floating in the air and the like are deactivated, and the malodorous substances contained in the air are reacted with hypochlorous acid to decompose or ionize and dissolve. Therefore, the air is sterilized and deodorized, and the purified air is discharged from the gas-liquid contact member 53.

An influenza virus is mentioned as a functional mechanism of inactivation, such as a virus by active oxygen species. The above-mentioned reactive oxygen species have an action of destroying and eliminating (removing) surface proteins (spikes) of influenza virus which are essential for influenza infection. When this surface protein is destroyed, the influenza virus and the receptor (receptor) required for infection by the influenza virus do not bind, and infection is prevented. For this reason, the influenza virus suspended in the air contacts the electrolyzed water containing active oxygen species in the gas-liquid contact member 53, so as to lose the infectivity, so that infection is prevented.

Therefore, even if this air sterilization apparatus 1 is installed in a so-called large space such as a kindergarten, elementary, middle, high school, nursing health facility, or hospital, the air purified by electrolyzed water (sterilization, deodorization, etc.) It becomes possible to spread | disperse | distribute in large space, and air disinfection and deodorization in large space can be performed efficiently.

In addition, the concentration of active oxygen species in the electrolyzed water is adjusted to a concentration for inactivating the virus or the like to be sterilized. The adjustment of the concentration of the active oxygen species is performed by adjusting the voltage applied between the electrode 47 and the electrode 48, and adjusting the current value flowing between the electrode 47 and the electrode 48.

For example, if a positive potential is applied to the electrode, and the current value flowing between the electrode 47 and the electrode 48 is 20 mA (milliampere) / cm 2 (square centimeter) as the current density, the predetermined free residual chlorine concentration (Eg, 1 mg (milligrams) / liter (liters)). In addition, by changing the voltage applied between the electrode 47 and the electrode 48 and increasing the current value, it is possible to make the concentration of hypochlorous acid in the electrolytic water high.

The electrolyzed water dropped from the sprinkling box 51 to the gas-liquid contacting member 53 moves downward through the gas-liquid contacting member 53 and falls to the drip tray 42A of the drip member 42. Electrolyzed water dropped on the drip tray 42A flows into the reservoir 42B via the filter member 74. Then, it is again pumped by the circulation pump 44 and supplied to the gas-liquid contact member 53 via the electrolytic cell 46. Thus, in the structure in this Example, water is circulating and an air can be sterilized efficiently for a long time by using a small amount of water effectively. In addition, when the water level of the storage part 42B is reduced by evaporation etc., the water supply valve 61 is opened and the tap water is supplied from the water supply port 64 with an appropriate amount.

In addition, in order to exchange the electrolyzed water circulated and used, the electrolyzed water stored in the drip tray 42 is discharged every predetermined time, and the tap water 42 is supplied with an appropriate amount of tap water. When the electrolytic water of the drip member 42 is exchanged, the pump 95 is driven, and the saline solution stored in the saline tank 90 is drawn out from the suction nozzle 90D, and the tubes 92 and 93 are discharged. After passing through, the feed nozzle 94 is automatically supplied to the drip member 42. The saline solution is supplied to the dripping member 42 until the salt concentration (chlorine concentration) of the water supplied to the electrolytic cell 46 becomes a predetermined value. In addition, the chlorine concentration is determined by measuring the electrical conductivity of the water supplied to the electrolytic cell 46.

When supplying the saline solution, the pump 95 is controlled by the control unit so that the dropwise amount of the saline solution per turn becomes 1 to 2 ml. Since the supply nozzle 94 is provided with a check valve 94A, the saline solution is easily dropped and the saline solution can be supplied in an appropriate amount according to the chlorine concentration of the water supplied to the electrolytic cell 46.

Since the chlorine ions increase by supplying the saline solution containing chlorine ions, the water supplied to the electrolytic cell 46 reacts as shown in the formulas [3] and [4] when electrolyzed. Hypochlorous acid and hydrochloric acid are produced. For this reason, the air sterilization apparatus 1 can generate active oxygen species stably even when used in an area with low chlorine concentration in tap water, and can exhibit sufficient air cleaning effects (inactivation, sterilization, deodorization of viruses, etc.).

In the air sterilization apparatus 1 of the present embodiment, by increasing the chlorine ions of water to be electrolyzed, the current flowing between the electrode 47 and the electrode 48 at the time of electrolysis is at least reduced, so that active oxygen species can be efficiently generated. At the same time, the load generated on the electrodes 47 and 48 is reduced, and the frequency of exchanging the electrodes 47 and 48 can be reduced.

As described above, according to the embodiment, the drip member 42 is provided in the air sterilization device 1 through which water is circulated, and by providing the saline tank 90 for supplying the stored saline to the drip member 42. Saline water is automatically supplied to the electrolyzed water in the interior. This makes it possible to secure a chlorine concentration that can be electrolyzed regardless of the region of use without causing the user to feel any inconvenience.

In addition, according to the embodiment, the saline tank 90 is simply placed on the holding table 91 without being fixed, and the suction port 95A of the pump 95 passes through the one-touch joint 90E and the tube 92. Since the saline tank 90 can be detached from the tube 92 with a single touch, the saline tank 90 can be easily taken out. Further, by arranging the supply nozzle 94 above the drip member 42 having a relatively high humidity, precipitation of the salt in the supply nozzle 94 can be prevented.

In addition, according to the above embodiment, the saline tank 90 and the supply nozzle 94 are disposed in the water circulation space 22A2 having a higher humidity than the germicidal space 22A1 to evaporate the water in the saline tank 90. By slowing down, the saline solution in the tank can be accommodated at a predetermined salinity concentration, and at the same time, precipitation of the saline salt in the supply nozzle 94 can be prevented. In addition, since the pump 95 is not required to be subjected to moisture proof treatment or the like by disposing the pump 95 in the low humidity space 22B having low humidity, the increase in the cost of the pump 95 can be suppressed, and The choice of the pump becomes wider.

Moreover, according to the said embodiment, by providing the supply nozzle 94 in the holding stand 91 which mounts the saline tank 90, it is unnecessary to prepare the member which supports the supply nozzle 94 separately, and it costs The rise can be suppressed.

Further, according to the above embodiment, by providing the check valve 94A in the supply nozzle 94 for supplying the saline solution to the drip member 42, the electrolytic water of the drip member 42 flows back into the saline tank (90). You can prevent it. In addition to this, it is possible to reliably prevent backflow of the electrolytic water by disposing it away from the water surface. In addition, corrosion of the inside of the check valve 94A due to the check valve 94A coming into contact with the electrolyzed water can be prevented.

Further, according to the above embodiment, by providing the valve device 90B for adjusting the internal pressure in the saline tank 90, the pressure in the saline tank 90 can be maintained in a constant state, and the saline solution has a predetermined salt concentration. I can accept it.

As mentioned above, although the best form for implementing this invention was described, this invention is not limited to the Example mentioned above, A various deformation | transformation and a change are possible based on the technical idea of this invention.

For example, in the above embodiment, the air sterilizer 1 is configured to supply tap water, but may be configured to supply water (including pure water, purified water, and well water) in which ionic species other than tap water is supplied. Also in this case, by supplying the saline solution from the saline tank 90, a sufficient air cleaning effect (inactivation, sterilization, deodorization of viruses or the like) can be exhibited.

In addition, in the said Example, although the supply nozzle 94 was arrange | positioned apart from the water surface of the electrolytic water stored in the drip member 42, you may install the supply nozzle 94 in the electrolytic water stored in the drip member 42. . In this case, the check valve 94A may be made of a material resistant to electrolyzed water (for example, Hastelloy). Also in this structure, since the check valve 94A is provided in the supply nozzle 94, even if the inside of the tube 92, 93, and the saline tank 90 becomes a negative pressure, the drip member 42 Water stored in the water is prevented from flowing back into the tubes 92, 93 and the saline tank 90 through the supply nozzle 94.

In the above embodiment, the saline solution that can be handled inexpensively and safely is stored in the saline tank 90. However, the saline solution is not limited to saline, and water containing halide ions such as chloride ions may be stored. do. In this case, reactive oxygen species containing halogen are produced by the reaction as described in [3] and formula [4].

1 is a perspective view showing the appearance of an air sterilizing apparatus according to the present embodiment;

2 is a rear side perspective view of the air sterilizing apparatus;

3 is a perspective view showing the main configuration of the inside of the air sterilization apparatus;

Figure 4 is a side cross-sectional view showing the main configuration of the inside of the air sterilization apparatus.

5 is a perspective view of a saline tank;

6 is a longitudinal sectional view of the air sterilizing apparatus showing the periphery of the saline tank;

7 is a view for explaining the supply state of the electrolytic water, (A) is a schematic diagram showing the configuration of the air sterilization mechanism, (B) is a diagram showing the configuration of the electrolytic cell in detail.

<Explanation of symbols for the main parts of the drawings>

1: air sterilizer 11: case

21: support plate 22: upper chamber

22A1: Sterilization Space 22A2: Water Circulation Space

22B: low humidity space 23: lower chamber

30A: bulkhead 31: blower fan

42: drip member 44: circulation pump

46: electrolytic cell (electrolytic unit) 53: gas-liquid contact member

90: saline tank 90B: valve unit

90E: One touch junction 91: Retention stand

94: supply nozzle 94A: check valve

95: pump 95A: inlet

95B: discharge port

Claims (6)

The inside of the case is divided up and down by a support plate, and an electrolytic unit, a gas-liquid contact member to which electrolytic water generated by the electrolytic unit is supplied, and electrolytic water generated by the electrolytic unit are stored in an upper chamber of the case. Iv) a drip tray member receiving the electrolyzed water flowing down from the gas-liquid contact member, and a circulation pump for pumping the electrolyzed water stored in the drip member to supply the gas-liquid contact member to the gas-liquid contact member again. In the air sterilization device having a blower fan for sending indoor air to the gas-liquid contact member, a saline tank storing the saline to be supplied to the drip member in the upper chamber of the case, A pump for sprinkling saline of the saline tank is provided, the inlet of the pump is connected to the saline tank via a one-touch junction, the outlet of the pump is connected to a supply nozzle of saline, and the supply nozzle is connected to the drip tray. An air sterilizer, which is disposed above the member. delete The water chamber according to claim 1, wherein the upper chamber is partitioned into a sterilization space for accommodating the gas-liquid contact member and a water circulation space for accommodating the circulation pump by a partition wall. And disposing the pump in a space having a low humidity adjacent to the water circulation space. The air sterilizing apparatus according to claim 1, further comprising a holding table for mounting the saline tank above the drip tray member, wherein the holding nozzle is supplied to the holding table. The air disinfecting apparatus according to claim 1, wherein a check valve is provided at a supply nozzle for supplying saline to the drip member, and the supply nozzle is separated from the surface of the electrolytic water of the drip member. The air sterilization apparatus according to claim 1, wherein a valve device for adjusting the internal pressure in the tank is provided in the saline tank.

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