JP4908871B2 - Air sanitizer - Google Patents

Description

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.

In general, for the purpose of removing viruses and the like, an air sterilization apparatus has been proposed in which electrolyzed water mist is diffused in air, the electrolyzed water mist is brought into direct contact with viruses and the like to inactivate these viruses and the like ( For example, see Patent Document 1).
JP 2002-181358 A

  However, the above-mentioned sterilization apparatus is effective in a use environment where fine particulate electrolyzed water mist easily reaches, that is, in a use environment where electrolyzed water mist is difficult to reach while being effective in a relatively small space, ie, large There is a problem that it is difficult to exert its effect in a space such as a kindergarten, elementary, middle, and high school, a nursing care insurance facility, a hospital, and the like.

In order to solve this problem, a gas-liquid contact member with high water retention is arranged in the housing, and electrolyzed water obtained by electrolyzing tap water is dropped onto the gas-liquid contact member, and The applicant has proposed an air sterilizing apparatus that blows indoor air and discharges air sterilized by the electrolytic water again into the room (large space) when passing through the gas-liquid contact member.
In this air sterilization apparatus, in order to infiltrate electrolyzed water throughout the gas-liquid contact member, a diversion sheet that divides the dropped electrolyzed water over the gas-liquid contact member above the gas-liquid contact member ( A sheet member) is disposed, and the electrolyzed water is diffused by the flow-dividing sheet so that the electrolyzed water is dropped almost uniformly onto the upper edge of the gas-liquid contact member.

However, since the hardness component (for example, calcium ions) is contained in the electrolyzed water, when this hardness component is deposited as a scale, the scale is deposited on the flow dividing sheet, thereby allowing the water flow of the flow dividing sheet. Is inhibited. In this case, the electrolyzed water cannot be permeated throughout the gas-liquid contact member, and there is a concern that the sterilization efficiency of the air is reduced.
Therefore, an object of the present invention is to provide an air sterilization apparatus that can prevent a decrease in sterilization efficiency by ensuring the water permeability of the flow dividing sheet even when the hardness component in the electrolyzed water is deposited as a scale. There is.

The present invention provides a gas-liquid contact member disposed in a housing, an electrolyzed water supply pipe for dropping electrolyzed water onto the gas-liquid contact member, and air is blown to the gas-liquid contact member into which electrolyzed water has permeated. and a blowing fan for blowing in, placing a first sheet member the electrolytic water dropped from the electrolytic water supply pipe above the element portion of the gas-liquid contact member having water retentivity diverting the whole area of the element portion In order to discharge the scale deposited from the electrolyzed water from the first sheet member together with the electrolyzed water, a large number of discharge holes having a diameter of about 1 mm are formed on the substantially entire surface of the first sheet member, and the element A second sheet member having water retention property is disposed on the upper end surface of the portion in contact with the end surface .

In this case Te smell, a plurality of water spray holes are formed at substantially equal pitch before Symbol electrolytic water supply pipe may be configured to pitch of the discharge hole of the first sheet member than the pitch of the nozzle holes is finely set . A watering box containing the electrolyzed water supply pipe is disposed at the upper part of the gas-liquid contact member, and the first sheet member is held inside the watering box and positioned below the electrolyzed water supply pipe, It is good also as a structure which has arrange | positioned the said 2nd sheet | seat member with the clearance gap below this 1st sheet | seat member. The discharge holes may have substantially the same diameter. Moreover, it is good also as a structure by which the pitch of the said discharge hole is formed at substantially equal intervals.

  According to the present invention, since a large number of discharge holes through which the scale deposited from the electrolyzed water is discharged are formed on substantially the entire surface of the first sheet member, it is possible to prevent the scale from being deposited on the first sheet member. Thus, the water permeability of the first sheet member can be secured, the life of the first sheet member can be extended, and consequently the sterilization efficiency can be prevented from being lowered.

Embodiments of the present invention will be described below with reference to the drawings.
In FIG. 1, the code | symbol 1 shows a floor-standing type air sanitizer. This floor-mounted air sterilization apparatus 1 includes a box-shaped housing 2, which includes a leg piece 2A, a front panel 2B, and a top panel 2C, on both sides of the top panel 2C. The operation lid 2D and the opening / closing lid 2E are arranged side by side.

  As shown in FIG. 2, two partition plates 51 and 52 extending in the vertical direction are provided inside the housing 2, and the interior of the housing 2 is divided into three parts by the partition plates 51 and 52. It is divided into chambers (sterilization chamber 60, electrical component chamber 61, water supply chamber 62). A horizontally long suction port 3 is formed in the lower part of the sterilization chamber 60 formed in the center of the housing 2, and a prefilter 3 </ b> A is disposed above the suction port 3. Above the prefilter 3 </ b> A, the blower fan 7 is supported by the partition plates 51 and 52 via the support plate 8. Above the support plate 8, the gas-liquid contact member 5 with high water retention is disposed obliquely so as to drop from the back side to the front side of the housing 2 as shown in FIG. 3. In this embodiment, the gas-liquid contact member 5 is formed in a rectangular shape, and the contact area of the gas-liquid contact member 5 is reduced by arranging the gas-liquid contact member 5 obliquely in the housing 2. Therefore, the height and depth of the housing 2 can be reduced, and the housing 2 can be downsized.

  The inclination angle θ of the gas-liquid contact member 5 is desirably 30 ° or more. In the case of the inclination angle θ smaller than that, the dropped electrolyzed water does not flow along the inclination of the gas-liquid contact member 5 but falls downward. Further, when the inclination angle θ approaches 90 °, the air blowing path passing through the gas-liquid contact member 5 becomes nearly horizontal, and it is difficult to blow upward by that much. When this blowing direction is brought close to the horizontal, the blown air cannot be blown far away, and the device is not suitable for sterilizing a large space. The inclination angle θ is preferably 30 ° <θ <80 °, more preferably 55 ° <θ <75 °, and about 57 ° in this configuration.

  Further, a water receiving tray 9 that receives the electrolyzed water that has passed through the gas-liquid contact member 5 is disposed between the gas-liquid contact member 5 and the blower fan 7. An outlet 4 is formed.

  Although not shown, an electrical component 61 such as a printed circuit board that controls the operation of the air conditioner 1 is accommodated in the electrical compartment 61 formed on the left side of the housing 2. On the other hand, in the water supply chamber 62 formed on the right side of the housing 2, as shown in FIG. 2, the water supply tank support tray 10 for storing the electrolyzed water received by the water tray 9 and the water supply tank support tray 10 for storage. A circulating pump 13 that pumps out the electrolyzed water, and an electrolysis tank 31 that electrolyzes the water pumped out by the circulating pump 13 to generate electrolyzed water are accommodated.

4A to 4B show an electrolyzed water supply mechanism for dropping electrolyzed water onto the gas-liquid contact member 5.
A water tray 9 is disposed below the gas-liquid contact member 5, and a water supply tank support tray 10 is connected to the water tray 9. The water supply tank support tray 10 is provided with a water supply tank 11 for supplying tap water containing chlorine ions into the support tray 10 and a circulation pump 13. An electrolytic tank 31 is connected to the circulation pump 13, and an electrolytic water supply pipe 17 is connected to the electrolytic tank 31. The electrolyzed water supply pipe 17 includes a large number of water spray holes 77 formed at substantially equal intervals along the axial direction. Each of the water spray holes 77 is formed at a position corresponding to each element portion E (described later) of the gas-liquid contact member 5.

  As shown in FIG. 4A, the electrolysis tank 31 is disposed above the water receiving tray 9 and the water supply tank support tray 10, and is sucked up from the water supply tank support tray 10 when the circulation pump 13 starts operation. When water is stored and the circulation pump 13 stops operating, the water in the electrolytic cell 31 naturally falls onto the water supply tank support tray 10 due to gravity, and the electrolytic cell 31 becomes empty.

  As shown in FIG. 4B, this electrolytic cell 31 is alternately provided with a pair of electrodes 32 and 33, one of which is positive and the other of which is negative, and the electrodes 32 and 33 flow into the electrolytic cell 31 when energized. The tap water is electrolyzed to generate active oxygen species. Here, the reactive oxygen species are oxygen having higher oxidation activity than normal oxygen and related substances, such as superoxide anion, singlet oxygen, hydroxyl radical, or hydrogen peroxide, in a narrow sense. The active oxygen includes so-called broad active oxygen such as ozone and hypohalous acid (hypochlorous acid). The electrolytic cell 31 is arranged close to the gas-liquid contact member 5 and is configured to be able to immediately supply the active oxygen species generated by electrolyzing tap water to the gas-liquid contact member 5.

The electrodes 32 and 33 are, for example, electrode plates in which the base is made of Ti (titanium) and the coating layer is made of Ir (iridium) or Pt (platinum), and the current value flowing through the electrodes 32 and 33 is several in terms of current density. It is set to be mA (milliampere) / cm ² (square centimeter) to several tens of mA / cm ² to generate a predetermined free residual chlorine concentration (for example, 1 mg (milligram) / l (liter)).

More specifically, when the tap water is energized by the electrodes 32 and 33, the cathode electrode
4H ⁺ + 4e ⁻ + (4OH ⁻ ) → 2H ₂ + (4OH ⁻ )
And the anode electrode
2H ₂ O → 4H ⁺ + O ₂ + 4e ⁻
As soon as the reaction of
Chlorine ions contained in water (pre-added to tap water)
2Cl ⁻ → Cl ₂ + 2e ⁻
In addition, this Cl ₂ reacts with water,
Cl ₂ + H ₂ O → HClO + HCl
It becomes.

  Therefore, by supplying electricity to the electrodes 32 and 33, HClO (hypochlorous acid) having a high sterilizing power is generated, and by passing air through the gas-liquid contact member 5 supplied with this hypochlorous acid, It is possible to prevent germs from growing on the gas-liquid contact member 5 and to inactivate viruses floating in the air passing through the gas-liquid contact member 5. Further, when the odor in the air also passes through the gas-liquid contact member 5, it reacts with hypochlorous acid and is ionized and dissolved, so that the air is deodorized.

Next, the gas-liquid contact member 5 will be described.
As shown in FIG. 5, the gas-liquid contact member 5 includes a plurality of (five in the present embodiment) element portions E that allow electrolytic water to permeate and allow air to pass through, and a frame portion F that supports these element portions E, It is configured with. The frame portion F includes a lower frame 71, a pair of vertical frames 72 and 73 fixed to both ends of the lower frame 71, and an upper frame 74 spanned between the upper ends of the vertical frames 72 and 73. . In this configuration, the electrolyzed water supply pipe 17 is housed inside the upper frame (watering box) 74 so that electrolyzed water is dropped from above the element portion E. The electrolyzed water supply pipe 17 penetrates the upper part of one vertical frame 72 and extends along the longitudinal direction of the upper frame 74, and the tip is fixed to the upper part of the other vertical frame 73.

As shown in FIG. 6, the upper frame 74 is formed in a substantially U-shaped cross section having an upper plate 74A, a front plate 74B, and a back plate 74C. On the inner surfaces of the front plate 74B and the back plate 74C, A pair of support members 75, 75 extending substantially parallel to the upper plate 74A are formed. These support members 75 and 75 are formed lower than the electrolyzed water supply pipe 17, and between the support members 75 and 75, a first flow-dividing sheet (first flow sheet) disposed above the element portion E is provided. Sheet member) 76 is inserted and supported.
The first diversion sheet 76 has water retention, and by diffusing the electrolyzed water dropped from a large number of water spray holes 77 formed in the electrolyzed water supply pipe 17 to the entire area of the first diversion sheet 76, Electrolyzed water can be supplied uniformly to the upper surface of the element portion E. A pair of guide pieces 79A and 79B are formed on the inner surface of the upper plate 74A so as to extend substantially parallel to the front plate 74B and the back plate 74C and guide the electrolytic water supply pipe 17. Further, on the lower surface of the lower frame 71, a drain port 71 </ b> A that discharges excess electrolyzed water dropped on the element portion E to the water receiving tray 9 is formed.

In the electrolyzed water supply pipe 17, as shown in FIG. 6, water spray holes 77 are formed in a substantially lateral direction toward the front side of the housing 2 in order to supply electrolyzed water substantially uniformly to the entire surface of the first flow dividing sheet 76. Has been. In this specification, the substantially horizontal direction includes not only the horizontal direction but also an angle at which electrolyzed water can be supplied uniformly to the first flow dividing sheet 76.
Specifically, as shown in FIG. 6, the water spray hole 77 is formed at a position facing the guide piece 79 </ b> A formed on the front plate 74 </ b> B side of the upper frame 74, and the inclination angle of the gas-liquid contact member 5. Is θ (degrees), the sprinkling hole 77 is formed at a position where the elevation angle with respect to the horizontal plane is 90-θ (degrees). Further, the water spray holes 77 are formed on a substantially straight line at every predetermined interval in the axial direction of the electrolyzed water supply pipe 17.

  According to this configuration, the electrolyzed water discharged from the water spray hole 77 of the electrolyzed water supply pipe 17 hits the guide piece 79 </ b> A formed on the inner surface of the upper frame 74 and is dropped onto the upper part 76 </ b> A side of the first flow dividing sheet 76. . The dropped electrolyzed water permeates the entire first diverted sheet 76 by moving from the upper 76A side to the lower 76B side of the first diverted sheet 76 using the inclination of the first diverted sheet 76. Spread. Further, the total water spray amount corresponding to the hole diameter from the water spray hole 77 is set to be smaller than the discharge amount of the circulation pump 13. For this reason, the electrolyzed water pressure in the electrolyzed water supply pipe 17 is increased, and the electrolyzed water is supplied all the way to the sprinkling holes 77 at the end, whereby the electrolyzed water reaches every corner in the longitudinal direction of the gas-liquid contact member 5. Can penetrate evenly.

By the way, since the electrolyzed water contains hardness components such as calcium ions and magnesium ions, in the configuration in which the electrolyzed water is circulated by the circulation pump 13 as in the present embodiment, the concentration of the hardness component increases with time. This hardness component may be deposited as a scale on the first flow dividing sheet 76. Since this scale is larger than the joint diameter (mesh diameter) of the first flow dividing sheet 76, the scale is deposited on the first flow dividing sheet 76 without passing through the first flow dividing sheet 76. In this case, since the electrolyzed water does not easily permeate the first diverter sheet 76 in the portion where the scale is deposited, the electrolyzed water does not diffuse throughout the first diverter sheet 76, so that the electrolyzed water permeates the entire element portion E substantially evenly. I can't let you.
Therefore, as shown in FIG. 7, the first flow dividing sheet 76 is formed with a large number of discharge holes 90 on substantially the entire surface of the first flow dividing sheet 76. These discharge holes 90 discharge the scale from the first flow dividing sheet 76 together with the electrolyzed water, and are formed to have substantially the same diameter D (about 1 mm in this embodiment). Further, the pitch L of the discharge holes 90 is formed at substantially equal intervals, and this pitch L is set finer than the pitch of the water spray holes 77 formed in the electrolyzed water supply pipe 17. These diameter D and pitch L are set to appropriate values by experiments or the like in order to maintain the diffusion function of the first flow dividing sheet 76 and to reliably discharge the deposited scale.

  According to this configuration, even if the hardness component in the electrolyzed water is deposited as a scale, the scale is discharged together with the electrolyzed water to the upper surface of the element portion E through the discharge hole 90. Therefore, it is possible to ensure the water permeability of the electrolyzed water to the first flow dividing sheet 76 and to extend the life of the first flow dividing sheet 76. Further, in this configuration, the electrolyzed water is dripped mainly into the element portion E through the discharge hole 90 having a small water flow resistance. Even in this case, the pitch L of the discharge hole 90 is the supply of the electrolyzed water. Since the pitch is set to be finer than the pitch of the water spray holes 77 formed in the pipe 17, the electrolyzed water supplied to the element portion E through the first flow diverting sheet 76 is diverted compared to that discharged from the water spray holes 77. Will be.

  On the other hand, as shown in FIG. 8, the element portion E is configured by laminating a corrugated plate member 81 and a flat plate member 82, and the corrugated plate member 81 and the flat plate member 82 are laminated. A pair of frame members 83 constituting a vertical frame of the element portion are arranged at both ends. The frame member 83 is formed of a resin such as plastic, and by disposing the frame member 83 at both ends of the laminated corrugated plate member 81 and the flat plate member 82, the element portion E can be easily handled. Become. Further, the element portion E is formed by laminating the corrugated plate member 81 and the flat plate member 82, thereby forming a large number of substantially triangular openings 85 between the corrugated plate member 81 and the flat plate member 82. Is widely secured, electrolyzed water can be dripped, and it is difficult to clog.

Each element portion E is arranged between the vertical frames 72 and 73 of the frame portion F, and a plurality of second diversion sheets (second sheets) are substantially in contact with the upper end surfaces of the element portions E. Member) 84 are arranged. The second diversion sheet 84 has water retention, and diffuses the electrolyzed water supplied to the upper surface of each element part E over the entire upper surface of the element part E via the first diversion sheet 76. The first sheet member is disposed with a gap below it.
In the present embodiment, the second branch sheet 84 includes three branch sheets (an upper branch sheet 84A, a middle branch sheet 84B, and a lower branch sheet 84C). The middle diversion sheet 84B and the lower diversion sheet 84C are set to be substantially the same as the lengths of the laminated corrugated plate member 81 and flat plate member 82 in the width direction. The upper flow dividing sheet 84A includes a base portion 84A1 having substantially the same length as the middle flow dividing sheet 84B and the lower flow dividing sheet 84C, and bent portions 84A2 provided at both ends of the base portion 84A1, and these bent portions. 84A2 is inserted into an insertion port 83A formed in the frame member 83, so that the three flow dividing sheets 84A to 84C can be stacked and attached to the upper surface of the element portion E.

  The corrugated plate material 81, the flat plate material 82, the first flow dividing sheet 76 and the second flow dividing sheet 84 have a liquid permeability and are less deteriorated by electrolyzed water, for example, polyolefin resins (polyethylene resin, polypropylene, etc. Resin), PET (polyethylene terephthalate) resin, vinyl chloride resin, fluorine-based resin (PTFE, PFA, ETFE, etc.) or ceramic material, etc., and in this configuration, PET resin is used. In addition, since electrolyzed water exhibits antifungal properties, it is not necessary to apply an antifungal agent to the gas-liquid contact member 5.

Next, the operation | movement at the time of the air sterilization of the floor-standing type air sterilizer 1 is demonstrated.
In FIG. 1, when the operation lid 2D is opened, an operation panel (not shown) is provided on the inner side, and the operation of the floor-standing air sterilizer 1 is started by operating this operation panel. When this operation is started, as shown in FIG. 4A, the circulation pump 13 is driven, and the tap water accumulated in the water supply tank support tray 10 is supplied to the electrolytic cell 31.
In the electrolytic bath 31, when the electrodes 32 and 33 are energized, tap water is electrolyzed to generate electrolytic water containing active oxygen species. The electrolyzed water is discharged from the water spray holes 77 (FIG. 6) of the electrolyzed water supply pipe 17, hits the guide piece 79 formed on the upper frame 74, and is dropped onto the first flow dividing sheet 76. As a result, the electrolyzed water diffuses throughout the first diverted sheet 76, and the electrolyzed water falls onto the second diverted sheet 84. The dropped electrolyzed water penetrates into the second diverted sheet 84, diffuses throughout the second diverted sheet 84, and supplies electrolyzed water to the entire upper part of the element part E. The corrugated plate material 81 and the flat plate material 82 penetrate into every corner.

  Excess electrolyzed water dropped on the gas-liquid contact member 5 is discharged to the water receiving tray 9 through the drain port 71A (FIG. 6) formed in the lower frame 71, and the water tank 9 is supplied to the water receiving tray 9 through the descending slope. Flows into and is stored there. In this configuration, the water is circulating, and when the amount of water is reduced by evaporation or the like, an appropriate amount of tap water in the water supply tank 11 is supplied to the water supply tank support tray 10. The water supply tank 11 is disposed so that it can be taken out by opening the opening / closing lid 2E (see FIG. 1), and the water supply tank 11 can be taken out to supply tap water.

  Indoor air is supplied to the gas-liquid contact member 5 into which the electrolytic water has permeated through the blower fan 7. The indoor air comes into contact with the active oxygen species soaked in the element part E of the gas-liquid contact member 5 and is blown out again into the room. This reactive oxygen species has the function of destroying and eliminating (removing) the surface protein (spike) of the virus essential for infection when, for example, influenza virus floats in the indoor air. Influenza virus and the receptor (receptor) necessary for the virus to become infected do not bind, thereby preventing infection. As a result of the verification test, it was found that 99% or more of the virus can be removed when the air in which the influenza virus is suspended is passed through the gas-liquid contact member 5 having this configuration.

According to the present embodiment, the gas-liquid contact member 5 disposed in the housing 2, the electrolyzed water supply pipe 17 that drops electrolyzed water onto the gas-liquid contact member 5, and the gas-liquid contact member into which the electrolyzed water has permeated. 5 is provided with a blower fan 13 that blows air into the room and blows the air into the room, and the water holding capacity for diverting the electrolyzed water dropped from the electrolyzed water supply pipe 17 above the gas-liquid contact member 5 to the entire area of the gas-liquid contact member 5. The first flow dividing sheet 76 having a large number of discharge holes 90 for discharging the scale deposited from the electrolyzed water is formed on substantially the entire surface of the first flow diverting sheet 76, so that the hardness component in the electrolyzed water is used as the scale. Even if it is deposited, the scale is discharged to the upper end surface of the element portion E through the discharge hole 90.
For this reason, by preventing the scale from being deposited on the first flow dividing sheet 76, it is possible to ensure the water permeability of the electrolytic water to the first flow dividing sheet 76, and the length of the first flow dividing sheet 76. Life can be extended. Further, since the electrolyzed water can be diffused throughout the first flow dividing sheet 76, the electrolyzed water can be permeated substantially uniformly throughout the element portion E, and the element portion E can be made to pass through the air by passing the air through the element portion E. A reduction in the sterilization efficiency of the air passing through the portion E can be prevented.

Moreover, according to this embodiment, the gas-liquid contact member 5 consists of the element part E divided | segmented into plurality, The 2nd branch sheet which has the water retention property in the upper end surface of each element part E in contact with the said end surface substantially 84, the scale discharged from the first flow dividing sheet 76 accumulates on the second flow dividing sheet, so that the scale is directly supplied to the element portion E, and the opening 85 of the element portion E is clogged. I will not let you.
In this case, if the scale accumulates on the second flow dividing sheet 84, the water flow of the second flow dividing sheet 84 is hindered. However, the second flow dividing sheet 84 is disposed on the upper end surface of each element portion E. Therefore, the width is narrower than that of the first flow dividing sheet 76. Further, in the second diversion sheet 84, three diversion sheets 84A to 84C are arranged in an overlapping manner. For this reason, even if the scale is deposited on a part of the upper flow dividing sheet 84A, the electrolyzed water can permeate substantially the entire area of the middle flow dividing sheet 84B and the lower flow dividing sheet 84C through the other parts. By allowing air to pass through E, it is possible to prevent a reduction in the sterilization efficiency of the air passing through the element portion E.

  Further, according to the present embodiment, a plurality of water spray holes 77 are formed in the electrolyzed water supply pipe 17 at a substantially equal pitch, and the pitch L of the discharge holes 90 of the first flow dividing sheet 76 is larger than the pitch of the water spray holes 77. Since it is finely set, the electrolyzed water supplied to the element portion E through the discharge hole 90 is diverted compared to that discharged from the water spray hole 77.

  Further, according to the present embodiment, the water spray box 74 that houses the electrolyzed water supply pipe 17 is disposed above the gas-liquid contact member 5, and the water spray box 74 is positioned below the electrolyzed water supply pipe 17 inside the water spray box 74. Since the first flow dividing sheet 76 is held and the second flow dividing sheet 84 is disposed with a gap below the first flow dividing sheet 76, the scale is deposited on the second flow dividing sheet 84. This scale does not block the discharge hole 90 of the first flow dividing sheet 76. Further, since the second diverting sheet 84 is disposed with a gap below the first diverting sheet 76, the electrolyzed water discharged through the discharge holes 90 of the first diverting sheet 76 is the second diverting sheet 84. The shunt flow is realized by being diffused by hitting the surface.

  Moreover, according to this embodiment, since the diameter D of each discharge hole 90 is formed in the substantially same diameter, the amount of scale and electrolyzed water discharged through this discharge hole 90 can be maintained substantially uniform. Thus, the electrolyzed water can penetrate substantially uniformly throughout the element portion E, and the sterilization efficiency of the air passing through the element portion E can be prevented from being lowered.

  Moreover, according to this embodiment, since the pitch L of the discharge holes 90 is formed at substantially equal intervals, even when the electrolyzed water is discharged through each discharge hole 90, Since it can permeate | transmit substantially uniformly throughout E, the fall of the sterilization efficiency of the air which passes this element part E can be prevented.

As mentioned above, although this invention was demonstrated based on one Embodiment, this invention is not limited to this. For example, ozone (O ₃ ) or hydrogen peroxide (H ₂ O ₂ ) may be generated as the active oxygen species. In this case, when a platinum tantalum electrode is used as an electrode, active oxygen species can be stably generated with high efficiency by electrolysis from water having a small ion species.
At this time, in the anode electrode,
2H ₂ O → 4H ⁺ + O ₂ + 4e ⁻
At the same time as
3H ₂ O → O ₃ + 6H ⁺ + 6e ⁻
2H ₂ O → O ₃ + 4H ⁺ + 4e ⁻
This reaction occurs and ozone (O ₃ ) is generated. In the cathode electrode,
4H ⁺ + 4e ⁻ + (4OH ⁻ ) → 2H ₂ + (4OH ⁻ )
O ₂ ⁻ + e ⁻ + 2H ⁺ → H ₂ O ₂
Thus, O ₂ ⁻ produced by the electrode reaction and H ⁺ in the solution are combined to produce hydrogen peroxide (H ₂ O ₂ ).

In this construction, by supplying current to the electrodes, a large ozone sterilizing power (O ₃₎ and hydrogen peroxide (H ₂ O ₂₎ is generated, these ozone (O ₃₎ and hydrogen peroxide (H ₂ O ₂₎ Electrolyzed water containing can be made. The concentration of ozone or hydrogen peroxide in the electrolyzed water is adjusted to a concentration that inactivates the target virus and the like, and air is passed through the gas-liquid contact member 5 supplied with the electrolyzed water of this concentration. It is possible to inactivate floating target viruses and the like. Further, when the odor passes through the gas-liquid contact member 5, it reacts with ozone or hydrogen peroxide in the electrolytic water, and is ionized and dissolved to be removed from the air and deodorized.

When scale is deposited on the electrode (cathode) by electrolyzing tap water, the electrical conductivity is lowered, and continuous electrolysis becomes difficult.
In this case, it is effective to reverse the polarity of the electrode (switch between positive and negative of the electrode). By electrolysis using the cathode electrode as the anode electrode, the scale deposited on the cathode electrode can be removed. In this polarity reversal control, for example, it may be reversed periodically using a timer, or may be reversed irregularly, such as reversed every time the operation is started. Further, an increase in electrolytic resistance (decrease in electrolysis current or increase in electrolysis voltage) may be detected, and the polarity may be reversed based on this result.

  In the above embodiment, the water supply system using the water supply / removal tank 11 that can be freely taken in and out is used. However, instead of the water supply tank 11, for example, a water pipe supply system that directly connects city water by connecting a water pipe may be used. Nor.

Moreover, in the said embodiment, although it was set as the structure provided with the guide piece 79 which the watering hole 77 opposes to the upper frame 74, it is not restricted to this. In the case where the guide piece 79 is not provided, the front plate 74 </ b> B of the upper frame 74 corresponds to the inner wall of the upper frame 74.
Moreover, in the said embodiment, although it was set as the structure which piles up three sheets 84A-84C as the 2nd diversion sheet | seat 84 in each element part E, it is not restricted to this, You may change this number suitably. . For example, when the amount of air passing through the gas-liquid contact member is the largest in the central portion of the gas-liquid contact member and decreases as it moves to both ends, the second shunt sheet is set to 1 in the element portion E in the central portion where the air volume is large. It is desirable to increase the number of sheets to 2 and 3 as the sheet moves to both ends. According to this configuration, since the water flow resistance in the central portion is reduced, the supply amount of the electrolyzed water is increased in the central portion where the air volume is large. For this reason, the virus which floats in the air which passes a gas-liquid contact member can be inactivated effectively by supplying the electrolyzed water according to an air volume. Further, not only the number of the second diverted sheets is changed, but also the joint diameter (mesh diameter) of the second diverted sheet is changed (specifically, the joint diameter of the central portion is increased, and as it moves to both ends) It is good also as a structure which makes it small.
Moreover, although the said embodiment demonstrated the structure which provides many discharge holes 90 in the substantially whole surface of the 1st flow dividing sheet 76, it is good also as a structure which provides many discharge holes in the substantially whole surface of the 2nd flow separation sheet. However, when a large number of discharge holes are formed in the second flow dividing sheet, if water droplets of the electrolyzed water supplied to the element portion E through the discharge holes are large, the water drops are blown into the room by the blower fan 13 (so-called water jumps). ) The phenomenon may occur. Therefore, when the discharge hole is formed in the second diverting sheet, it is desirable to reduce the diameter of the discharge hole so that water splash does not occur.

It is a perspective view which shows one Embodiment of this invention. It is a perspective view which shows an internal structure. It is a longitudinal cross-sectional view of a housing | casing. It is a systematic diagram which shows the mechanism in which electrolyzed water is dripped at a gas-liquid contact member, A is a side view, B is a block diagram of an electrolytic vessel. It is a perspective view of a gas-liquid contact member. It is a longitudinal cross-sectional view of a gas-liquid contact member. It is a top view of the 1st diversion sheet. It is a partial cross-sectional view of a gas-liquid contact member.

Explanation of symbols

1 Floor-mounted air sanitizer (air sanitizer)
5 Gas-liquid contact member 17 Electrolyzed water supply pipe 74 Upper frame (watering box)
76 First shunt sheet (first sheet member)
77 Sprinkling holes 84 Second diversion sheet (second sheet member)
90 Discharge hole E Element part F Frame part

Claims (5)

A gas-liquid contact member disposed in the housing, an electrolyzed water supply pipe for dropping electrolyzed water to the gas-liquid contact member, and a blower fan that blows air into the gas-liquid contact member permeated with electrolyzed water and blows the air into the room with the door, the electrolytic water dropped from the electrolytic water supply pipe is arranged a first sheet member having water retentivity diverting the whole area of the element portion above the element portion of the gas-liquid contact member, the electrolytic In order to discharge the scale deposited from water together with the electrolyzed water from the first sheet member, a large number of discharge holes having a diameter of about 1 mm are formed on the substantially entire surface of the first sheet member, and the upper end surface of the element portion. The air sterilizer is characterized in that a second sheet member having water retention property is disposed in contact with the end face . The electrolytic water plurality of nozzle holes in substantially equal pitch in the supply tube is formed, according to claim 1, characterized in that the pitch of the discharge hole of the first sheet member is finely set than the pitch of the nozzle holes Air sterilizer. A watering box containing the electrolyzed water supply pipe is disposed at the upper part of the gas-liquid contact member, and the first sheet member is held inside the watering box and positioned below the electrolyzed water supply pipe, The air disinfection device according to claim 1 or 2, wherein the second sheet member is disposed with a gap below the first sheet member. The air sterilizer according to any one of claims 1 to 3 , wherein the discharge holes are formed to have substantially the same diameter. The air disinfection device according to any one of claims 1 to 4 , wherein the pitches of the discharge holes are formed at substantially equal intervals.

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