JP2022189202A - Air purification device and air purification system - Google Patents

Abstract

To provide an air purification device capable of improving deactivation performance of virus by ultraviolet radiation, and automatically coping with deterioration of a pollution situation of a space to be purified, by a device side, and an air purification system comprising the same device.SOLUTION: There is provided an air purification system 100 comprising: a partition part 130 partitioning, an internal space 131 and an external space 132, and comprising: an air purification device 1 for sucking air from one of the internal space 131 and the external space 132 and discharging the air to the other thereof. The air purification device 1 comprises: an ultraviolet radiation part for radiating ultraviolet to a HEPA filter; a first particle sensor and a second particle sensor for detecting particles with different particle diameter; and a fan control part for increasing a blowing amount of the fan on the basis of a difference of the diameter number detected by the first and second particle sensors.SELECTED DRAWING: Figure 1

Description

The present invention relates to an air purifying device using ultraviolet light and an air purifying system provided with this air purifying device.

As an air purifying device using ultraviolet light, there is known one in which a filter, an ultraviolet sterilizer, and a blower fan are sequentially provided from the inlet side in a main body having an inlet and an outlet (for example, , see Patent Document 1). The ultraviolet sterilizer includes a housing having an inlet on the front and an outlet on the rear, an ultraviolet lamp arranged in the housing, and a polygonal cylindrical cell continuously formed, and the inlet and the outlet. It consists of an ultraviolet ray shielding member attached to each of the . According to the air purifier of Patent Document 1, the air that has flowed into the ultraviolet sterilizer through the ultraviolet light shielding member on the front side is killed by the ultraviolet rays irradiated from the ultraviolet lamp. Alternatively, it is said that by disappearing, it becomes purified air and flows out to the outside through the ultraviolet light shielding member on the rear surface side.

JP-A-2005-6771

However, in the configuration of irradiating ultraviolet light to the air in circulation, such as the air purifying device described in Patent Document 1, the irradiation time of the ultraviolet light to the virus is short, and the effect of inactivating the virus is insufficient. is. Moreover, when the contamination condition of the space to be cleaned becomes worse, the apparatus cannot automatically cope with it.

The present invention has been made in view of the above circumstances, and its object is to improve the virus inactivation performance by ultraviolet light, and to improve the contamination of the space to be purified. The present invention relates to an air purifying device capable of automatically responding to air pressure and an air purifying system equipped with this air purifying device.

In the present invention,
a housing in which an intake port and an exhaust port are formed;
a fan disposed within the housing for circulating air within the housing;
a fan control unit that controls the amount of air blown by the fan;
a virus inactivating part that is arranged in the housing and inactivates viruses in the air;
a first particle sensor that detects the number of particles larger than a preset first particle size in the air outside the housing;
a second particle sensor that detects the number of particles larger than a second particle size set larger than the first particle size in the air outside the housing;
The virus inactivating section has a HEPA filter that captures viruses in the air and an ultraviolet light irradiation section that irradiates ultraviolet light toward the HEPA filter,
The fan control unit increases the amount of air blown by the fan based on the difference between the number of first particles detected by the first particle sensor and the number of second particles detected by the second particle sensor. A purification device is provided.

In the above air purification device,
A virus decomposition unit that is arranged in the housing and decomposes a virus,
The virus decomposition part is
a virus capturing body made of a photocatalyst material that captures viruses in the air;
It is preferable to have an excitation light irradiation unit that irradiates excitation light toward the virus capturing body.

In the above air purification device,
A carbon dioxide detection sensor that detects the concentration of carbon dioxide in the air outside the housing,
It is preferable that the fan control unit increases the amount of air blown by the fan based on the carbon dioxide concentration detected by the carbon dioxide detection sensor.

Moreover, in the present invention,
a partition that separates the internal space and the external space;
The air purifying device arranged to draw air from one of the internal space and the external space and discharge air to the other;
An air purification system is provided in which the first particle sensor and the second particle sensor of the air purification device respectively detect the number of particles in the air in the interior space.

Furthermore, in the present invention,
a partition that separates the internal space and the external space;
The air purifying device arranged to draw air from one of the internal space and the external space and discharge air to the other;
the first particle sensor and the second particle sensor of the air purification device respectively detect the number of particles in the air in the internal space;
An air purification system is provided in which the carbon dioxide detection sensor of the air purification device detects the concentration of carbon dioxide in the air in the internal space.

In the above air purification system,
The internal space is a space inside a negative pressure room formed in a building,
The external space is preferably a space outside the negative pressure room in the building.

ADVANTAGE OF THE INVENTION According to this invention, the virus inactivation performance by ultraviolet light can be improved, and when the contamination condition of the space to be purified becomes worse, the apparatus can automatically respond.

BRIEF DESCRIPTION OF THE DRAWINGS It is a structure explanatory drawing of the air purification system which shows one Embodiment of this invention. It is a front view of an air cleaner. It is a rear view of an air cleaner. 1 is an exploded perspective view of an air purification device; FIG. 1 is a schematic cross-sectional view of an air purification device; FIG. It is a schematic cross section of an upstream irradiation panel, (a) shows the cross section between each LED mounting part, (b) shows the cross section of an outer frame. It is a schematic cross section of a downstream irradiation panel. (a) shows the cross section of the upper end side and the lower end side between the LED mounting portions, (b) mainly shows the center side cross section between the LED mounting portions, and (c) shows the cross section of the outer frame. FIG. 4 is a schematic cross-sectional view showing how each filter lower portion and each irradiation panel lower portion are attached to a housing. FIG. 4 is a schematic cross-sectional view of a decomposition filter; It is a rear view of the decomposition filter, (a) shows the entire decomposition filter, (b) shows an enlarged portion surrounded by a dashed line A in (a). It is a schematic control block diagram of an air purifier. It is a configuration explanatory diagram of an air purification system showing a modification. It is a configuration explanatory diagram of an air purification system showing a modification. It is a configuration explanatory diagram of an air purification system showing a modification.

1 to 11 show one embodiment of the present invention, FIG. 1 is a configuration explanatory diagram of an air purification system showing one embodiment of the present invention, FIG. 2 is a front view of an air purification device, and FIG. 4 is an exploded perspective view of the air purifier, FIG. 5 is a schematic cross-sectional view of the air purifier, FIG. 6 is a schematic cross-sectional view of the upstream irradiation panel, and FIG. 7 is a schematic of the downstream irradiation panel. 8 is a schematic cross-sectional view showing how the lower part of each filter and the lower part of each irradiation panel are attached to the housing, FIG. 9 is a schematic cross-sectional view of the decomposition filter, FIG. 10 is a rear view of the decomposition filter, and FIG. 11 is air. It is a schematic control block diagram of a purifier.

As shown in FIG. 1 , this air purification system 100 is used in a negative pressure room 120 formed inside a building 110 . The negative pressure chamber 120 is formed by partitioning the inside and outside with a partition wall 130 as a partition part, and the pressure inside the partition wall 130 is kept lower than that of the outside space 132 . The air purification system 100 includes an introduction-side air purification device 1 that introduces air from an external space 132 outside a negative pressure room 120 in a building 110 into an internal space 131 inside the negative pressure room 120, and an internal space 131 and an outlet-side air purifier 1 that guides air from the outlet to the outer space 132 . The inlet-side air purifier 1 introduces air through an inlet 133 formed in the partition wall 130 , and the outlet-side air purifier 1 discharges air through an outlet 134 formed in the partition wall 130 .

As shown in FIGS. 2 and 3, the air purifying device 1 includes a housing 2 whose vertical dimension is larger than its horizontal dimension, an intake port 21 formed on the lower side of the front surface 23 of the housing 2, and the housing 2. and an exhaust port 22 formed on the upper side of the rear surface 24 , and after the air taken in from the intake port 21 is purified in the housing 2 , it is discharged from the exhaust port 22 . The housing 2 is made of metal such as iron or aluminum, for example. As shown in FIG. 1, in the present embodiment, the inlet 133 and the intake port 21 of the air purifier 1 on the inlet side are connected by an inlet duct 135, and the outlet 134 and the exhaust of the air purifier 1 on the outlet side are connected. The port 22 is connected with an outlet side duct 136 .

In this embodiment, as shown in FIG. 4, the front surface 23 of the housing 2 extends vertically. In addition, the rear surface 24 of the housing 2 extends in the vertical direction on the lower side and slopes forward upward on the upper side. As shown in FIG. 2, the intake port 21 is formed in a vertically long rectangular shape on the lower side of the front surface 23 . Further, as shown in FIG. 3, two exhaust ports 22 are formed side by side with an interval in the inclined portion of the back surface 24 . As shown in FIG. 2, the front surface 23 is provided with a detachable lid 25 that closes the intake port 21 and has a large number of ventilation holes 25a. In addition, in each figure, the ventilation hole 25a is shown typically. As shown in FIG. 3, the rear surface 24 is provided with nozzles 26 that are provided in the respective exhaust ports 22 and that can adjust the direction of the discharged air. As shown in FIG. 4, the housing 2 is formed such that the front-rear dimension is smaller than the left-right dimension. That is, the air purifying device 1 is thin in the front-rear direction and vertically long as a whole.

The air purification device 1 has a first particle sensor 1a, a second particle sensor 1b and a carbon dioxide detection sensor 1c provided on the upper side of the front surface 23 . The first particle sensor 1a detects the number of particles larger than a preset first particle size in the air outside the housing 2 . In this embodiment, the first particle sensor 1a detects the number of particles with a particle size of 0.1 μm or more. The second particle sensor 1b detects the number of particles larger than a second particle size set larger than the first particle size in the air outside the housing 2 . In this embodiment, the second particle sensor 1b detects the number of particles with a particle size of 1.0 μm or more. The carbon dioxide detection sensor 1 c detects the concentration of carbon dioxide in the air outside the housing 2 .

In addition, the air purifier 1 has an operation section 1d provided on the front surface 23. As shown in FIG. The user can turn ON/OFF the fan 8, which will be described later, and set the blowing volume of the fan 8 from the operation unit 1d. Specifically, the operation unit 1d is of a touch panel type including a liquid crystal screen, and the operating state of the air purifier 1 is displayed. Thereby, the user can confirm the operating state of the air purifier 1 through the operation unit 1d. In the present embodiment, the blowing amount of the fan 8 can be changed in six steps, but in normal operation the maximum blowing amount is not used and the fan 8 is adjusted in five small blowing steps. The air purifying device 1 on the inlet side and the air purifying device 1 on the outlet side have the same basic configuration, but the maximum air blow amount of the fan 8 is changed so that the maximum air blow amount on the inlet side is the maximum air blow amount on the outlet side. It is adjusted to be smaller than the air flow rate.

As shown in FIG. 4, the air purifier 1 has a plurality of filters 3, 4, 5, 6 for purifying air. In the present embodiment, the pre-filter 3, the carbon filter 4, the HEPA filter 5, and the decomposition filter 6 are arranged in this order in the air circulation direction near the intake port 21. FIG. The pre-filter 3 mainly removes hair and relatively large dust particles in the air. The carbon filter 4 mainly adsorbs and removes chemical substances such as formaldehyde in the air. The HEPA filter 5 is made of glass wool, for example, and mainly removes relatively small dust such as viruses, PM2.5, and pollen in the air. The decomposition filter 6 as a virus decomposition unit contains a photocatalyst material, mainly captures airborne bacteria, viruses, organic matter, etc., and decomposes them mainly into water and carbon dioxide.

In addition, the air purifier 1 is arranged in the vicinity of the upstream side of the HEPA filter 5 with an interval in the air circulation direction, and has an upstream irradiation panel 10 that irradiates the HEPA filter 5 with ultraviolet light, and a downstream side of the HEPA filter 5. and a downstream irradiation panel 15 which is arranged in the vicinity at a distance and irradiates the HEPA filter 5 with ultraviolet light. A downstream illumination panel 15 is arranged between the HEPA filter 5 and the decomposition filter 6 . In this embodiment, the HEPA filter 5 and the irradiation panels 10 and 15 constitute a virus inactivating section that inactivates viruses.

Further, the downstream irradiation panel 15 irradiates the decomposition filter 6 with the excitation light of the photocatalyst from the downstream side in the air circulation direction. In this embodiment, the downstream irradiation panel 15 and an LED 62, which will be described later, constitute an excitation light irradiation unit, and the decomposition filter 6, the downstream irradiation panel 15, and the LED 62 constitute a virus decomposition unit that decomposes viruses.

Furthermore, as shown in FIG. 5, the air purification device 1 has an ion generator 7 that emits ions. In this embodiment, the ion generator 7 is arranged downstream of each filter 3, 4, 5, 6 and upstream of each exhaust port 22 with respect to the direction of air flow.

In the air purifier 1, a fan 8 for circulating the air inside the housing 2 is arranged at the lower rear side inside the housing 2. As shown in FIG. Inside the housing 2, an internal partition wall 27 forms a filter chamber 101 on the lower front side in which the filters 3, 4, 5, and 6 are arranged and formed continuously with the intake port 21, and continuously with the exhaust ports 22. and an ejection preparation chamber 102 in which the ion generator 7 is arranged. In this embodiment, the internal partition wall 27 includes a vertically extending portion 27a that partitions the interior of the housing 2 into the front and rear, an upper wall portion 27b that extends forward from the upper end of the vertically extending portion 27a, and a vertically extending portion 27a. and a lower wall portion 27c extending forward from the lower end. The filter chamber 101 and the ejection preparation chamber 102 communicate with each other through a communication hole 27d formed in the vertically extending portion 27a. An air guide passage 27e extending rearward from the communication hole 27d of the internal partition wall 27 is formed, and the fan 8 is arranged at the rear end of the air guide passage 27e. In the present embodiment, the communication hole 27d and the air guide passage 27e are formed in a circular shape when viewed from the front.

As shown in FIG. 6A, an upstream irradiation panel 10 as an upstream ultraviolet light irradiation section has a plate-shaped base 11 and a plurality of LEDs 12 mounted on the base 11 . Specifically, the base 11 is made of an insulating material, and includes a plurality of vertically extending LED mounting portions 11a, and an outer frame portion 11b connecting the upper and lower ends of each LED mounting portion 11a and forming the outer edge of the irradiation portion. have. A plurality of LEDs 12 are mounted vertically at intervals on the surface of each LED mounting portion 11a on the HEPA filter 5 side. Each LED mounting part 11a is arranged at equal intervals in the left and right direction. In this embodiment, the peak wavelength of each LED 12 is 385 nm.

As shown in FIG. 6B, the upstream irradiation panel 10 has a wiring portion 13 made of a conductive material inside the base 11 . A connection connector 14 that is detachably connected to a power connector 28 of the housing 2 is provided on the surface of the substrate 11 opposite to the HEPA filter 5 . The wiring portion 13 electrically connects the connector 14 and each LED 12 . The power connector 28 is connected to a power supply board (not shown) of the housing 2 .

As shown in FIG. 7( a ), the downstream irradiation panel 15 as an upstream ultraviolet light irradiation section has a plate-like substrate 16 and a plurality of LEDs 17 mounted on the substrate 16 . Specifically, the base 16 is made of an insulating material and includes a plurality of vertically extending LED mounting portions 16a and an outer frame portion 16b connecting the upper and lower ends of each LED mounting portion 16a and forming the outer edge of the irradiation portion. have. A plurality of LEDs 17 are mounted vertically at intervals on the surface of each LED mounting portion 16a on the HEPA filter 5 side. Further, as shown in FIG. 7(b), a plurality of LEDs 17 are also mounted vertically at intervals on the surface of the decomposition filter 6 side on the vertical center side of each LED mounting portion 16a. The LED mounting portions 16a are arranged at equal intervals in the left and right direction. In this embodiment, the peak wavelength of each LED 17 is 385 nm.

As shown in FIG. 7(c), the downstream irradiation panel 15 has a wiring portion 18 made of a conductive material inside the base 16. As shown in FIG. A connection connector 19 that is detachably connected to a power connector 29 of the housing 2 is provided on the surface of the base 11 on the decomposition filter 6 side. The wiring portion 18 electrically connects the connector 19 and each LED 17 . The power connector 29 is connected to a power supply board (not shown) of the housing 2 .

As shown in FIG. 8, the lower wall portion 27c of the internal partition wall 27 of the housing 2 has a first groove portion 27c1, a second groove portion 27c2, and a second groove portion 27c1 for receiving the filters 3, 4 and 5 and the irradiation panels 10 and 15, respectively. A third groove portion 27c3 and a fourth groove portion 27c4 are formed. Each filter 3, 4, 5 and each irradiation panel 10, 15 can be freely inserted into and removed from the grooves 27c1, 27c2, 27c3, 27c4. 15 is detachable from the housing 2 . In this embodiment, a first groove portion 27c1 for receiving the pre-filter 3 and the carbon filter 4, a second groove portion 27c2 for receiving the upstream irradiation panel 10, a third groove portion 27c3 for receiving the HEPA filter 5, and a downstream irradiation panel 15 are formed in this order from the upstream side. That is, the first groove portion 27c31 serves as a filter positioning portion for the pre-filter 3 and the carbon filter 4, the second groove portion 27c2 serves as a panel positioning portion for the upstream irradiation panel 10, and the third groove portion 27c3 serves as a filter positioning portion for the HEPA filter 5. , and the fourth groove portion 27 c 4 serves as a panel positioning portion for the downstream irradiation panel 15 .

The decomposition filter 6 is arranged immediately before the communication hole 27 a and fixed to the partition wall 27 via a plurality of brackets 9 . As shown in FIG. 9, the decomposition filter 6 has a plurality of substantially spherical virus trapping bodies 61 that trap viruses in the air. and a plurality of LEDs 62 that irradiate ultraviolet light toward. Moreover, the decomposition filter 6 has a decomposition part main body 64 formed with a plurality of holes 63 penetrating in the direction of air flow.

Although the material of the decomposition part main body 64 is arbitrary, it is preferably made of metal in order to increase the reflectance with respect to ultraviolet light, and is made of aluminum in this embodiment. As shown in FIG. 10A, the disassembly unit main body 64 is formed in a horizontally long rectangular shape when viewed from the front, and each hole 63 is arranged so as to extend in the front-rear direction, which is the air circulation direction. As shown in FIG. 10(b), in the present embodiment, the decomposition section main body 64 has a so-called honeycomb structure, and each hole 63 has a regular hexagonal shape when viewed from the front.

Each virus capturing body 61 is produced by compressing adsorbent particles 61a with a particle size of 20 nm or more and 50 nm or less into a spherical shape with a diameter of 3.0 mm or more and 10.0 mm or less while heating as necessary. . In addition, in FIG.10(b), each virus trapping body 61 and each adsorption particle 61a are shown typically. In this embodiment, each virus trapping body 61 has a diameter of 3.0 mm and is housed in each regular hexagonal hole 63 having a side of 6.0 mm when viewed from the front. Thus, by setting the diameter of each virus-capturing body 61 to 1/2 or more of the length of one side of the regular hexagon of the hole 63, it is possible to sufficiently secure the air flow path in the hole 63. can.

In this embodiment, each adsorption particle 61a is titanium oxide, which is a photocatalyst material, and each virus capturer 61 does not contain an organic binder. Each virus capturing body 61 has an uneven surface due to the shape of each adsorbing particle 61a that constitutes it. Since each adsorption particle 61a is titanium oxide, it can be excited as a photocatalytic reaction with light having a wavelength of 410 nm or less. In this embodiment, the peak wavelength of each LED 62 is 385 nm.

Moreover, as shown in FIG. 9, the decomposition filter 6 has a net member 65 that covers the front and rear surfaces of the decomposition portion main body 64 . That is, the net member 65 covers the upstream side and the downstream side of the decomposer main body 64 with respect to the air circulation direction. The mesh member 65 has meshes larger than the diameter of each virus-trapping body 61, and prevents each virus-trapping body 61 from moving to the outside of the hole 63 while allowing air to flow. In the present embodiment, the mesh member 65 is made of metal and is relatively less susceptible to deterioration by ultraviolet light.

The decomposition filter 6 also has a frame 66 that supports the outer edge of the decomposition section main body 64 in a front view. In this embodiment, the frame 66 is made of an insulating material, and each bracket 9 is connected. The frame 66 has a pair of front and rear LED mounting portions 66a extending vertically downstream of the disassembly portion main body 64 in the air circulation direction. A plurality of LEDs 62 are mounted on each LED mounting portion 66a at intervals in the vertical direction. The LED mounting portions 66a are arranged at equal intervals in the left and right direction.

As shown in FIG. 9, the decomposition filter 6 has a wiring portion 67 made of a conductive material inside the frame 66 . As shown in FIG. 10( a ), a connection connector 68 to be connected to a power connector (not shown) of the housing 2 is provided on the surface of the frame 66 opposite to the disassembly main body 64 . The wiring portion 67 electrically connects the connector 68 and each LED 62 .

As shown in FIG. 10, the air purification device 1 includes a fan control unit 200 that controls the amount of air blown by the fan 8 based on the number of particles detected by the first particle sensor 1a and the second particle sensor 1b. there is The fan control unit 200 has a computing unit 210 and a storage unit 220 which are interconnected via a system bus, and controls the blowing volume of the fan 8 according to a fan control program 230 stored in the storage unit 220 . In this embodiment, the fan control units 200 of the air purifiers 1 are linked, and each fan controls the amount of air introduced into the internal space 131 so as not to exceed the amount of air discharged into the external space 132. 8 is adjusted.

As shown in FIG. 11, the fan control unit 200 normally controls the blowing amount of the fan 8 so as to achieve the blowing amount set by the operation unit 1d. In the present embodiment, the fan control unit 200 controls the operation unit 1d if the amount of air blown by the fan 8 on the lead-in side exceeds the amount of air blown by the fan 8 on the outlet side. A message to that effect is displayed on the liquid crystal screen of 1d, and the blowing volume of the fan 8 is not changed.

Further, the fan control unit 200 presets the amount of change per predetermined time in the difference between the number of first particles detected by the first particle sensor 1a and the number of second particles detected by the second particle sensor 1b. When the allowable particle change amount 240 stored in the storage unit 220 is exceeded, a message to that effect is displayed on the liquid crystal screen of the operation unit 1d, and the blowing amount of the fan 8 is increased. In this embodiment, the predetermined time for monitoring the amount of change is set to 1 second, and the allowable particle amount of change 240 is set to 0 as initial settings. The predetermined time for monitoring the change amount and the allowable particle change amount 240 can be changed by the operation unit 1d. Here, the difference between the number of the first particles and the number of the second particles is the number of particles with a relatively large particle size detected by the second particle sensor 1b, out of the total number of particles detected by the first particle sensor 1a. It has been deducted. That is, this difference means the number of particles contained in the air having a first particle size or more and less than a second particle size. Since it is 1.0 μm, the number of particles is 0.1 μm or more and less than 1.0 μm. Regular respiratory droplets of COVID-19 coronavirus patients are mostly 1.0 μm or less, and since the particle size of COVID-19 coronavirus is 0.1 μm, the first particle By monitoring the difference between the number of particles and the number of the second particles, it is possible to evaluate whether or not there is a viral patient in the negative pressure chamber 120 . In the present embodiment, the fan control unit 200 sets the blowing amount of the fan 8 to the maximum blowing amount when the change amount per predetermined time of the difference between the first particle number and the second particle number exceeds the allowable particle change amount 240. do. In this embodiment, the fan control unit 200 of each air purifying device 1 cooperates, and if the amount of change in the difference in the number of particles in any one of the air purifying devices 1 exceeds the allowable particle change amount 240, both Let the amount of air blown by the fan 8 of the air cleaner 1 be the maximum amount of air blown.

Furthermore, when the concentration of carbon dioxide detected by the carbon dioxide detection sensor 1c exceeds the permissible concentration 250 preset and stored in the storage unit 220, the fan control unit 200 displays the liquid crystal screen of the operation unit 1d. The effect is displayed and the blowing volume of the fan 8 is increased. In this embodiment, as an initial setting, the permissible concentration 250 is set to 1000 ppm. It should be noted that the permissible density 250 can be changed by the operation unit 1d. By monitoring the concentration of carbon dioxide in the air, it can be evaluated whether the number of people in the negative pressure room 120 has increased. In this embodiment, when the detected concentration of carbon dioxide exceeds the permissible concentration 250, the fan control unit 200 sets the blowing amount of the fan 8 to the maximum blowing amount. In this embodiment, the fan control unit 200 of each air purifying device 1 is linked, and when the concentration of carbon dioxide detected by one of the air purifying devices 1 exceeds the allowable concentration 250, both air purifying devices Let the blowing amount of the fan 8 of No. 1 be the maximum blowing amount.

The air purification system 100 configured as described above introduces air from the external space 132 to the internal space 131 of the negative pressure chamber 120 by operating the fan 8 of each air purifying device 1, and introduces air into the internal space 131. to the external space 132 is performed. As described above, the fan control units 200 of the air purifiers 1 are linked, and each fan 8 is controlled so that the amount of air introduced into the internal space 131 does not exceed the amount of air discharged into the external space 132. is adjusted. As a result, the pressure inside the negative pressure chamber 120 is kept lower than the outside.

Each air cleaner 1 captures bacteria, viruses, etc. in the air with the HEPA filter 5 and the decomposition filter 6 when the fan 8 is operated. Bacteria, viruses, and the like captured by the HEPA filter 5 and the decomposition filter 6 are inactivated by ultraviolet light emitted from each LED 12, each LED 17, and each LED 62. FIG. As a result, unlike conventional air purifiers that irradiate the air with ultraviolet light without using a filter, virus inactivation is not insufficient.

In this embodiment, since the irradiation units 10 and 15 are arranged both upstream and downstream of the HEPA filter 5, the HEPA filter 5 is irradiated with ultraviolet light from the upstream and downstream sides, and the HEPA filter 5 is wide. A range of virus inactivation effects can be obtained. As for the decomposition filter 6, the LEDs 17 and 62 are arranged both upstream and downstream of the decomposition unit main body 64 in which the virus trapping bodies 61 are accommodated. You can make sure the light spreads.

Moreover, since each virus trapping body 61 is a photocatalyst material, it functions as a photocatalyst when excited by ultraviolet light. As a result, the inactivated bacteria, viruses, etc. trapped on the surface of each virus trapping body 61 are decomposed into water and carbon dioxide and diffused into the air. Therefore, the ability of each virus trapping body 61 to trap bacteria, viruses, etc. can be maintained for a long period of time without replacing the decomposition filter 6 . That is, the inactivated virus does not accumulate on the surface of each trapping body 61 and does not require periodical removal work, so maintainability is excellent.

Therefore, according to the air purification device 1 of the present embodiment, the air taken in from the intake port 21 is purified by the filters 3, 4, 5, and 6, and the inactivated bacteria, viruses, and organic matter are mainly removed with water. It can be discharged from each exhaust port 22 in a state of being decomposed into carbon dioxide. In addition, by operating the ion generator 7, air containing ions can be discharged. In other words, purified air is introduced into the internal space 131 of the negative pressure chamber 120 by the air purifying device 1 on the inlet side, and purified to the external space 132 of the negative pressure chamber 120 by the air purifying device 1 on the outlet side. Air can be drawn out.

Further, in the present embodiment, the fan control unit 200 causes the fan 8 to rotate when the amount of change per predetermined time in the difference between the first particle count and the second particle count exceeds the allowable particle change amount 240. Since the air volume is increased, when the number of particles of the first particle size or more and less than the second particle size in the internal space 131 exceeds the allowable amount, the negative pressure room 120 is automatically ventilated and air cleaned. can be promoted to That is, when the contamination condition of the internal space 131 to be cleaned becomes worse, the apparatus can automatically cope with it. As a result, when the amount of coronavirus contained in the air in the negative pressure room 120 increases due to the coronavirus discharged from the viral patient, the ventilation and air purification of the negative pressure room 120 are promoted, and the negative pressure room The amount of coronavirus exposure to humans other than viral patients within 120 can be reduced. In this embodiment, by setting the allowable particle change amount 240 to 0, ventilation and air purification of the negative pressure chamber 120 can be performed immediately when the difference between the first particle number and the second particle number increases even slightly. can. At this time, the fan control unit 200 maximizes the amount of air blown by the fan 8, so that the ventilation capacity of each air cleaner 1 can be maximized.

Furthermore, in the present embodiment, the fan control unit 200 increases the blowing volume of the fan 8 when the detected carbon dioxide concentration exceeds the allowable concentration 250, so the number of people in the internal space 131 increases. As a result, the ventilation and air purification of the negative pressure room 120 can be automatically promoted when the carbon dioxide contained in the air increases beyond the allowable amount. As a result, even if the person who entered the negative pressure room 120 includes a person with a virus disease, it is possible to reduce the exposure of people other than the person with a virus disease in the negative pressure room 120 to the coronavirus. . At this time, the fan control unit 200 maximizes the amount of air blown by the fan 8, so that the ventilation capacity of each air cleaner 1 can be maximized.

Further, according to the air purifier 1 of the present embodiment, when the HEPA filter 5 is clogged and the performance is lowered, the performance can be restored by replacing the HEPA filter 5 . In addition, since the irradiation panels 10 and 15 are detachable from the housing 2, the irradiation panels 10 and 15 near the HEPA filter 5 can be removed when the HEPA filter 5 is replaced. does not interfere with At this time, the irradiation panels 10 and 15 near the HEPA filter 5 are positioned by the grooves 27c2, 27c3 and 27c4, so that the HEPA filter 5 and the irradiation panels 10 and 15 do not shift from their predetermined positions.

In this embodiment, since each virus-trapping body 61 is formed in a substantially spherical shape, the flow of air around each virus-trapping body 61 is disturbed. In particular, in this embodiment, the unevenness of the surface of each virus trapping body 61 also disturbs the air flow and increases the surface area to trap more bacteria, viruses, organic matter, and the like. As a result, an air flow occurs not only near the surface on the upstream side of each virus-trapping body 61 but also near the surface on the downstream side, allowing the air to circulate near the surface of the entire virus-trapping body 61 . Therefore, each virus capturer 61 can accurately capture bacteria, viruses, and the like.

In the present embodiment, each virus trapping body 61 is made of only a photocatalyst material and does not contain an organic binder. does not deteriorate. This also makes it possible to maintain the ability of each virus trapping body 61 to trap bacteria, viruses, and the like over a long period of time.

In this embodiment, since each exhaust port 22 is formed smaller than the intake port 21, the flow velocity of the air discharged from each exhaust port 22 can be relatively increased. Therefore, the air purified in the housing 2 can be delivered to a place relatively distant from the air purification device 1, and the air in a relatively wide range of space can be purified.

In this embodiment, by arranging the ion generator 7 on the downstream side of each filter 3, 4, 5, 6, each filter 3, 4, 5, 6 completely captures, decomposes, etc. bacteria, viruses, etc. Even if not, remaining bacteria, viruses, etc. can be inactivated by ions. Here, since the ion generator 7 is smaller than the filters 3, 4, 5, and 6, it can be installed at a relatively free position within the housing 2 without increasing air flow resistance. can be done.

Further, in the present embodiment, since the wall surface of each hole 63 is made of aluminum, it is possible to efficiently reflect the ultraviolet light incident on the wall surface. As a result, the amount of ultraviolet light incident on each virus capturer 61 can be increased, and the performance of the decomposition filter 6 can be improved.

In the above embodiment, the amount of change per predetermined time in the difference between the number of first particles and the number of second particles is compared with the allowable amount of change in particles 240. and the second particle number difference, for example, the difference between the first particle number and the second particle number is compared with a preset allowable particle number. may In the above embodiment, the first particle sensor 1a detects the number of particles of 0.1 μm or more, and the second particle sensor 1b detects the number of particles of 1.0 μm or more. The size of the target particles can be changed as appropriate, for example, the first particle sensor may detect the number of particles of 0.05 μm or larger. Further, in the above embodiment, the detected carbon dioxide concentration and the permissible concentration 250 are compared, but the fan control unit 200 increases the blowing volume of the fan 8 based on the detected carbon dioxide concentration. For example, the amount of change in the detected carbon dioxide concentration per predetermined period of time may be compared with a preset permissible amount of change in concentration.

Further, in the above-described embodiment, the fan control units 200 of the air cleaners 1 cooperate to control the fans 8, but the fans 8 may be controlled independently of each other. Further, the sensors 1a, 1b, 1c of one air purifying device 1 of the air purifying devices 1 are omitted, and based on the information obtained from the sensors 1a, 1b, 1c of the other air purifying device 1, one The amount of air blown by the fan 8 of the air cleaner 1 may be controlled.

In the above embodiment, the air purifying device 1 is arranged on both the air inlet side and the air outlet side of the negative pressure chamber 120, but it may be arranged on at least one side. may be arranged only on the lead-out side as shown in FIG. 13, or may be arranged only on the introduction side as shown in FIG. In the air purification system 300 of FIG. 12, a ventilation fan 310 is provided instead of the air purification device 1 on the introduction side. In the air purification system 400 of FIG. 13, a ventilation fan 410 is provided in place of the air purification device 1 on the lead-out side. The fan control unit 200 of the inlet-side or outlet-side air purification device 1 can control the fan 8 and the ventilation fans 310 and 410 inside the device in cooperation.

In the above embodiment, the air purifier 1 is installed in the negative pressure chamber 120, but for example, as shown in FIG. It can also be installed on the ceiling forming the partition part 530 of. In the air purification system 500 of FIG. 14, the air introduced from the ceiling into the internal space 531 flows downward through the vent formed in the floor, and then flows into the external space 532 by the ventilation fan 510 provided at the outlet 534. derived.

Thus, in the air purification system, the air purification device may be arranged to draw air from one of the internal space and the external space and discharge the air to the other. Even if the air purifying device performs intake and exhaust in the internal space regardless of the external space, the air purifying effect can be obtained although the ventilation effect cannot be obtained, and the air in the internal space is purified. be.

Further, in the above embodiment, the irradiation units 10 and 15 are arranged on both the upstream side and the downstream side of the HEPA filter 5, but the irradiation units may be arranged on either side. . Also, with respect to the decomposition filter 6, each LED 17 and each LED 62 are shown arranged on both the upstream side and the downstream side of the decomposition section main body 64 in which each virus trapping body 61 is accommodated, but they are arranged on either one side. It may be Further, the ultraviolet light emitters of the HEPA filter 5 and the decomposition filter 6 may be other light emitting devices such as a black light instead of LEDs. Furthermore, the wavelength of the light emitter can be changed arbitrarily as long as it is in the ultraviolet region, and may be, for example, 250 nm, 270 nm, or the like.

In the above embodiment, the filters 3, 4, 5 and the irradiation panels 10, 15 are positioned by the grooves 27c1, 27c2, 27c3, 27c4. can be In addition, although the HEPA filter 5 and the irradiation panels 10 and 15 are arranged independently, it is also possible to construct a unit in which these are integrally provided so as to be detachable from the housing 2. is. Furthermore, if the HEPA filter 5 is replaceable, there is no problem even if the irradiation panels 10 and 15 are non-detachably mounted on the housing 2 .

Further, in the above-described embodiment, the surface of each virus capturing body 61 is formed with unevenness, but the surface may not be uneven. Moreover, although each virus trapping body 61 is shown to be formed in a substantially spherical shape, it may be formed in a polyhedral shape, for example. The point is that the flow of air flowing through each hole 63 should be disturbed.

Further, in the above-described embodiment, each hole 63 of the decomposition filter 6 is formed in a regular hexagonal shape when viewed from the front. can. Also, although the decomposing portion main body 64 of the decomposing filter 6 is shown to be made of aluminum, it may be made of other metals, ceramics, resins, or the like.

In the above-described embodiment, the net member 65 covering the upstream side and the downstream side of the decomposer main body 64 is provided, but each virus trapping body 61 is fixed to the wall surface of each hole 63, etc. The net member 65 may be omitted if there is no risk that each virus trapping body 61 will move out of the hole 63 due to this.

In the above embodiment, the virus is decomposed by providing the decomposition filter 6. However, even if the decomposition filter is not provided, the HEPA filter and the irradiation unit for irradiating it with ultraviolet light are provided. Virus inactivation can be obtained.

Although the embodiments of the present invention have been described above, the embodiments described above do not limit the invention according to the scope of claims. Also, it should be noted that not all combinations of features described in the embodiments are essential to the means for solving the problems of the invention.

REFERENCE SIGNS LIST 1 air cleaner 1a first particle sensor 1b second particle sensor 1c carbon dioxide detection sensor 2 housing 5 HEPA filter 6 decomposition filter 8 fan 10 upstream irradiation panel 12 LED
15 downstream irradiation panel 17 LED
21 intake port 22 exhaust port 27c2 groove 27c3 groove 27c4 groove 61 virus capturing body 62 LED
63 hole 64 main body 65 net member 100 air purification system 110 building 120 negative pressure chamber 130 partition wall 131 internal space 132 external space 200 fan controller 300 air purification system 400 air purification system 500 air purification system 501 air purification device

Claims (6)

a housing in which an intake port and an exhaust port are formed;
a fan disposed within the housing for circulating air within the housing;
a fan control unit that controls the amount of air blown by the fan;
a virus inactivating part that is arranged in the housing and inactivates viruses in the air;
a first particle sensor that detects the number of particles larger than a preset first particle size in the air outside the housing;
a second particle sensor that detects the number of particles larger than a second particle size set larger than the first particle size in the air outside the housing;
The virus inactivating section has a HEPA filter that captures viruses in the air and an ultraviolet light irradiation section that irradiates ultraviolet light toward the HEPA filter,
The fan control unit increases the amount of air blown by the fan based on the difference between the number of first particles detected by the first particle sensor and the number of second particles detected by the second particle sensor. purifier. A virus decomposition unit that is arranged in the housing and decomposes a virus,
The virus decomposition part is
a virus capturing body made of a photocatalyst material that captures viruses in the air;
2. The air purifier according to claim 1, further comprising an excitation light irradiation unit that irradiates excitation light toward the virus trapping body. A carbon dioxide detection sensor that detects the concentration of carbon dioxide in the air outside the housing,
3. The air purifier according to claim 1, wherein the fan controller increases the amount of air blown by the fan based on the concentration of carbon dioxide detected by the carbon dioxide detection sensor. a partition that separates the internal space and the external space;
3. The air purifying device according to claim 1 or 2 arranged to draw air from one of the internal space and the external space and discharge air to the other,
The air purification system, wherein the first particle sensor and the second particle sensor of the air purification device respectively detect the number of particles in the air in the internal space. a partition that separates the internal space and the external space;
4. The air purifier according to claim 3 arranged to draw air from one of the internal space and the external space and discharge air to the other;
the first particle sensor and the second particle sensor of the air purification device respectively detect the number of particles in the air in the internal space;
The air purification system, wherein the carbon dioxide detection sensor of the air purification device detects the concentration of carbon dioxide in the air in the internal space. The internal space is a space inside a negative pressure room formed in a building,
6. The air purification system according to claim 4, wherein the external space is a space outside the negative pressure room in the building.

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