JP2023183273A - Whole building air conditioning system - Google Patents

Abstract

To provide a whole building air conditioning system capable of suppressing germs and viruses dispersing in a building.SOLUTION: A whole building air conditioning system 30 includes an indoor unit 32 for generating air-conditioning air and for supplying the air-conditioning air to each room. The air-conditioning air supplied to each room refluxes to the indoor unit 32 as return air, and the return air is taken into the indoor unit 32 from an intake port 37 formed in the indoor unit 32. Then, the indoor unit 32 generates air-conditioning air using the return air. At the indoor unit 32, a cover member 51 is provided so as to cover the intake port 37. The cover member 51 is formed in a substantially box-like shape, and the return air is taken in from the intake port 37 through an inside space 57. At the inside space 57 of the cover member 51, two air filters 61, 62 are provided so as to prevent foreign objects such as dust from entering the inside of the indoor unit 32 from the intake port 37. Out of these air filters 61, 62, at the air filter 62 on the downstream side, a photocatalyst 71 is provided.SELECTED DRAWING: Figure 3

Description

The present invention relates to a central air conditioning system.

BACKGROUND ART In a building such as a residence, a whole-house air conditioning system is known that air-conditions a plurality of rooms using a common air conditioner (for example, Patent Document 1). In a whole-house air conditioning system, an air conditioner generates conditioned air and supplies the conditioned air to each room through ducts to air-condition each room.

In addition, in a central air conditioning system, the conditioned air supplied to each room is returned to the air conditioner through the building. Then, the air conditioner takes the recirculated air (return air) into the air conditioner, and generates conditioned air based on the taken in return air. Therefore, the whole building air conditioning system air-conditions each room while circulating conditioned air within the building.

JP2020-085328A

By the way, in a central air conditioning system, each room is air-conditioned while circulating the air within the building, so if there are bacteria or viruses in the air, the bacteria or viruses will spread to each room. There is a risk that

Furthermore, if bacteria or viruses are taken into the air conditioner, there is a risk that the bacteria or virus will adhere to the inside of the air conditioner. In that case, there is a risk that bacteria and viruses may spread from the attached bacteria and viruses.

The present invention has been made in view of the above circumstances, and its main purpose is to provide a whole-building air conditioning system that can suppress the spread of bacteria and viruses within a building.

In order to solve the above problems, a whole building air conditioning system according to a first aspect of the invention includes an air conditioner that generates conditioned air and supplies the generated conditioned air to a plurality of indoor spaces in a building. The supplied conditioned air is configured to flow back to the air conditioner as return air, and the air conditioner has an intake port that takes in the return air, and the air conditioner also has an intake port that takes in the return air from the intake port. A whole-house air conditioning system that generates conditioned air, comprising: an air filter that prevents foreign matter such as dust from entering the air conditioner through the intake port; and a photocatalyst provided in the air filter. Be prepared.

In a central air conditioning system, an air conditioner generates conditioned air based on return air taken in through its intake. In addition, in the whole building air conditioning system, an air filter is provided to prevent foreign matter such as dust from entering the air conditioner through the intake port. Therefore, in the first invention, attention is paid to this air filter, and a photocatalyst is provided in the air filter. According to this configuration, bacteria and viruses contained in the return air passing through the air filter can be removed by irradiating the photocatalyst with light to cause a photocatalytic action. Thereby, it is possible to suppress bacteria and viruses from being taken into the air conditioner through the intake port, and as a result, it is possible to suppress bacteria and viruses from spreading into the building from the air conditioner.

A whole building air conditioning system according to a second aspect of the invention includes a passage forming section that forms a return air passage through which the return air flows toward the intake port, and the return air passage includes the air filter. A first air filter provided with the photocatalyst and a second air filter not provided with the photocatalyst are provided, and the second air filter is arranged upstream of the first air filter. has been done.

According to the second invention, the first air filter provided with a photocatalyst and the second air filter not provided with a photocatalyst are provided in the return air passage formed in the passage forming portion. The second air filter is arranged upstream of the first air filter. In this case, by collecting foreign matter such as dust with the second air filter on the upstream side, it is possible to prevent foreign matter from adhering to the first air filter on the downstream side. Therefore, it is possible to use the second air filter for foreign matter collection and the first air filter for sterilization to remove bacteria and viruses.

In such a configuration, the second air filter, where foreign matter tends to accumulate, has to be washed with water or the like more frequently, but since the second air filter is not provided with a photocatalyst, there is no particular problem even if the second air filter is washed frequently. do not have. On the other hand, the first air filter, to which foreign matter is less likely to adhere, can be cleaned less frequently, such as by washing with water. Therefore, it is possible to prevent the photocatalyst from being removed from the first air filter due to cleaning, thereby preventing the sterilization effect from decreasing.

In the whole building air conditioning system of a third aspect of the invention, in the second aspect of the invention, the first air filter has a coarser mesh than the second air filter.

According to the third invention, since the first air filter has coarser mesh than the second air filter, it is possible to further suppress foreign matter from adhering to the first air filter. Thereby, the frequency of cleaning the first air filter can be further reduced, and as a result, a decrease in the sterilization effect due to cleaning can be further suppressed.

In the whole building air conditioning system of a fourth aspect of the invention, in the second aspect of the invention, the first air filter and the second air filter are arranged to overlap with each other.

According to the fourth invention, since the first air filter and the second air filter are arranged so as to overlap each other, the sterilization effect caused by the photocatalyst produced in the first air filter is also exerted on the second air filter. becomes possible. Therefore, it becomes possible to remove bacteria and viruses attached to the second air filter, and as a result, it becomes possible to enhance the sterilization effect.

In the whole building air conditioning system of a fifth invention, in any one of the second to fourth inventions, the return air passage is provided with a frame-shaped support part provided with a plurality of light sources that irradiate the photocatalyst with light. The support portion is arranged to face the first air filter.

According to the fifth invention, a frame-shaped support section provided with a plurality of light sources that irradiates the photocatalyst with light is provided in the return air passage, and the support section is disposed facing the first air filter. ing. In this case, when the photocatalyst is provided over a wide area of the first air filter (for example, over the entire filter surface), it is possible to easily irradiate the entire photocatalyst with light. Therefore, the sterilizing effect of the photocatalyst can be enhanced. Further, since the support portion is formed in a frame shape, the above effects can be obtained while suppressing the flow of return air from being obstructed by the support portion.

The figure which shows the first floor part of the building in which the central air conditioning system in 1st Embodiment was provided. FIG. 2 is an exploded perspective view showing the configuration of an indoor unit and its surroundings. FIG. 3 is a vertical cross-sectional view showing the configuration around the intake port of the indoor unit. The figure which shows the second floor part and roof part of the building in which the central air conditioning system in 2nd Embodiment was provided. FIG. 3 is an exploded perspective view showing the suction chamber and each member provided therein in an exploded state. FIG. 3 is a vertical cross-sectional view showing the internal configuration of a suction chamber.

(First embodiment)
As shown in FIG. 1, a building 10 such as a residence is provided above a foundation 11. The building 10 has a first floor portion 12. The first floor portion 12 is provided with a plurality of rooms 14 to 17. Among these rooms 14 to 17, rooms 14 to 16 include, for example, a living room, a dining room, a Japanese-style room, and a bedroom. The room 17 is a machine room in which an indoor unit 32 of a whole-house air conditioning system 30, which will be described later, is installed, and may be referred to as the machine room 17 hereinafter. The rooms 14 to 17 are separated from each other by a partition wall 18. Adjacent rooms 14 to 17 can be constantly ventilated through vents 19 and the like provided in the partition wall 18.

A floor portion 21 is provided in the first floor portion 12, and this floor portion 21 forms the floor surfaces of the rooms 14 to 17. An underfloor space 22 is provided below the floor portion 21 . The underfloor space 22 is vertically partitioned from the rooms 14 to 17 by the floor 21. The underfloor space 22 is surrounded by the foundation 11.

The building 10 is provided with a whole-house air conditioning system 30 that air-conditions the rooms 14 to 16 (corresponding to indoor spaces) on the first floor 12. The configuration of the whole building air conditioning system 30 will be described below.

The whole building air conditioning system 30 is a heat pump type air conditioning system, and is capable of performing at least cooling operation and heating operation. The whole building air conditioning system 30 includes an indoor unit 32 provided indoors and an outdoor unit 33 provided outdoors. The indoor unit 32 and the outdoor unit 33 are connected via a refrigerant pipe 34, and in FIG. 1, the refrigerant pipe 34 is shown by a dotted line for convenience. Note that the indoor unit 32 corresponds to an air conditioner.

The indoor unit 32 is provided in the machine room 17. The indoor unit 32 is formed into a substantially rectangular parallelepiped shape, and an intake port 37 is provided in a side surface 32a (see FIG. 2). The indoor unit 32 takes in air (return air RA) in the machine room 17 through the intake port 37, and generates conditioned air (cold air and warm air) by adjusting the temperature of the taken air.

The indoor unit 32 is connected to an air conditioning chamber 41 installed in the underfloor space 22. A plurality of air conditioning ducts 42 are connected to the air conditioning chamber 41. Each of these air conditioning ducts 42 is arranged in the underfloor space 22 and connected to an air outlet 43 provided in the floor 21. Each air outlet 43 is provided in each of the rooms 14 to 16 on the first floor portion 12.

Conditioned air (cold air or warm air) generated by the indoor unit 32 is supplied to each outlet 43 through an air conditioning chamber 41 and each air conditioning duct 42, and is blown out from each outlet 43 into each room 14 to 16. Each of the rooms 14 to 16 is air-conditioned (cooled or heated) by the conditioned air blown out.

In the first floor portion 12 of the building 10, the conditioned air supplied to each of the rooms 14 to 16 returns (refluxes) to the machine room 17 through the vents 19 and the like as return air RA. Then, the indoor unit 32 takes in the return air RA that has returned to the machine room 17 through the intake port 37, and generates conditioned air again based on the taken in return air RA. In this way, the whole building air conditioning system 30 is an air circulation type air conditioning system.

Next, the configuration of the vicinity of the intake port 37 of the indoor unit 32 will be described based on FIGS. 2 and 3.

As shown in FIGS. 2 and 3, a cover member 51 is provided on the side surface 32a of the indoor unit 32 so as to cover the intake port 37. As shown in FIGS. The cover member 51 is formed of a metal plate into a substantially box shape. The cover member 51 includes a front plate portion 52 facing away from the intake port 37, a pair of side plate portions 53 extending from each side portion of the front plate portion 52 to the side portion 32a of the indoor unit 32, and a front plate portion 52. It has a bottom plate part 54 extending from the lower side part to the side part 32a of the indoor unit 32. An opening 55 that opens upward is formed in the top surface of the cover member 51, and an opening 56 that opens toward the indoor unit 32 is formed in the back surface of the cover member 51. The opening 56 communicates with the intake port 37 .

Return air RA in the machine room 17 flows into the inner space 57 of the cover member 51 through the opening 55. Thereafter, the return air RA is taken into the interior of the indoor unit 32 from the inner space 57 through the opening 56 and the intake port 37. Therefore, the return air RA in the machine room 17 is taken into the interior of the indoor unit 32 through the inner space 57 of the cover member 51. In this case, the inner space 57 corresponds to a return air passage through which the return air RA flows toward the intake port 37. Further, the cover member 51 corresponds to a passage forming portion.

Two air filters 61 and 62 are provided in the inner space 57 of the cover member 51. These air filters 61 and 62 are for collecting foreign matter such as dust contained in the return air RA flowing through the inner space 57. This prevents foreign matter from entering the interior of the indoor unit 32 through the intake port 37. Each of the air filters 61 and 62 is formed of a nonwoven fabric, and is made of, for example, a medium-high performance filter. Further, each of the air filters 61 and 62 has a rectangular shape with the same size.

Each of the air filters 61 and 62 is supported by a filter support portion 59 provided on the inner surface of each side plate portion 53 of the cover member 51. The filter support portion 59 extends in the vertical direction along the side plate portion 53, and more specifically, extends upward so as to be inclined toward the indoor unit 32 side. Air filters 61 and 62 are placed on the upper surface of each filter support section 59 (specifically, on the inclined surface) so as to straddle both of the filter support sections 59 . In this case, the air filters 61 and 62 are placed on the filter support portion 59 in an overlapping state. Thereby, each of the air filters 61 and 62 is supported in an inclined state toward the indoor unit 32 side (in other words, toward the intake port 37 side). Moreover, by supporting each air filter 61, 62 in this way, each air filter 61, 62 is made removable.

In the inner space 57 of the cover member 51, return air RA passes through each air filter 61, 62 and flows to the intake port 37. Among the air filters 61 and 62, the air filter 61 is arranged on the upstream side, and the air filter 62 is arranged on the downstream side. The air filter 61 on the upstream side has a finely woven nonwoven fabric, and the air filter 62 on the downstream side has a coarsely woven nonwoven fabric. Therefore, most of the foreign matter in the return air RA is collected by the air filter 61 on the upstream side.

A photocatalyst 71 is provided in the air filter 62 on the downstream side. The photocatalyst 71 is supported on substantially the entire filter surface of the air filter 62 . The photocatalyst 71 includes a photocatalyst activating substance such as titanium oxide (TiO2). When the photocatalyst 71 is irradiated with light, it is activated and a photocatalytic action occurs. Due to this photocatalytic action, bacteria and viruses contained in the return air RA are removed when it passes through the air filter 62. Further, in this embodiment, a visible light responsive photocatalyst activated by visible light is used as the photocatalyst 71. The photocatalyst 71 is made of, for example, V-CAT (registered trademark).

Note that the downstream air filter 62 provided with the photocatalyst 71 corresponds to a first air filter. Further, the upstream air filter 61 is not provided with a photocatalyst, and therefore the air filter 61 corresponds to a second air filter. In this configuration, the air filter 61 is mainly used for collecting foreign matter such as dust, and the air filter 62 is used for sterilization to remove bacteria and viruses contained in the return air RA after collecting foreign matter. used for purposes.

A light emitting unit 73 is provided in the inner space 57 of the cover member 51 on the downstream side of the air filter 62. The light emitting unit 73 has a plurality of LEDs 74 and a rectangular frame-shaped base portion 75 to which each LED 74 is attached. Each LED 74 is a light source that irradiates light toward the photocatalyst 71 of the air filter 62, and in this embodiment, one that irradiates visible light is used. Note that the base portion 75 corresponds to a support portion.

The base portion 75 is disposed close to the air filter 62 and facing the air filter 62 . The base portion 75 has an outer frame portion 76 and a plurality of inner frame portions 77 arranged within the frame of the outer frame portion 76. Each inner frame portion 77 extends in the horizontal direction, and both ends thereof are connected to the outer frame portion 76, respectively. Moreover, each inner frame part 77 is arranged at equal intervals, and a plurality of LEDs 74 (for example, three each) are arranged in each inner frame part 77. These plurality of LEDs 74 are arranged at equal intervals in the inner frame portion 77.

In the above configuration, in the inner space 57 of the cover member 51, the return air RA that has passed through each of the air filters 61 and 62 flows downstream through the frame of the base portion 75 of the light emitting unit 73. Thereafter, it is taken into the interior of the indoor unit 32 through the intake port 37.

According to the present embodiment described in detail above, the following excellent effects can be obtained.

An air filter 62 is provided to prevent foreign matter such as dust from entering the interior of the indoor unit 32 through the intake port 37 of the indoor unit 32, and a photocatalyst 71 is provided on the air filter 62. According to this configuration, bacteria and viruses contained in the return air RA passing through the air filter 62 can be removed by irradiating the photocatalyst 71 with light to cause a photocatalytic action. Thereby, it is possible to suppress bacteria and viruses from being taken into the interior of the indoor unit 32 through the intake port 37, and as a result, it is possible to suppress the bacteria and viruses from spreading from the indoor unit 32 into the building 10. I can do it.

Further, if bacteria or viruses enter the indoor unit 32, there is a risk that the bacteria or viruses will adhere to the interior of the indoor unit 32. In that case, there is a risk that bacteria and viruses that adhere to the building 10 may be used as a starting point to spread into the building 10. In this regard, according to the above configuration in which the air filter 62 is provided with the photocatalyst 71, it is possible to suppress the entry of bacteria and viruses into the interior of the indoor unit 32, so that bacteria and viruses do not adhere to the inside of the indoor unit 32. It is possible to suppress the spread of bacteria and viruses due to adhesion.

An air filter 62 provided with a photocatalyst 71 and an air filter 61 not provided with a photocatalyst are provided in the inner space 57 of the cover member 51, and the air filter 61 is arranged upstream of the air filter 62. In this case, by collecting foreign matter such as dust with the air filter 61 on the upstream side, it is possible to prevent foreign matter from adhering to the air filter 62 on the downstream side. Therefore, it is possible to use the air filter 61 for foreign matter collection, and the air filter 62 for sterilization to remove bacteria and viruses.

In such a configuration, the air filter 61 on the upstream side where foreign matter tends to accumulate will be cleaned more frequently, such as by washing with water, but since the air filter 61 is not provided with a photocatalyst, even if the cleaning frequency is high, There are no particular problems. On the other hand, the frequency of cleaning such as washing with water can be reduced for the air filter 62 on the downstream side, where foreign matter is less likely to adhere. Therefore, it is possible to prevent the photocatalyst 71 from being removed from the air filter 62 due to cleaning, thereby reducing the sterilization effect.

Since the air filter 62 has coarser mesh than the air filter 61, it is possible to further suppress the attachment of foreign matter to the air filter 62. Thereby, the frequency of cleaning the air filter 62 can be further reduced, and as a result, the deterioration of the sterilization effect due to cleaning can be further suppressed.

Since the air filters 61 and 62 are arranged so as to overlap with each other, the sterilizing effect of the photocatalyst 71 generated in the air filter 62 can also be exerted on the air filter 61. Therefore, it becomes possible to remove bacteria and viruses attached to the air filter 61, and as a result, it becomes possible to enhance the sterilization effect.

A plurality of LEDs 74 for irradiating light onto the photocatalyst 71 and a frame-shaped base portion 75 to which each of the LEDs 74 is attached are provided in the inner space 57 of the cover member 51, and the base portion 75 is opposed to the air filter 62. Placed. In this case, the entire photocatalyst 71 can be easily irradiated with light, and as a result, the sterilizing effect of the photocatalyst 71 can be enhanced. Furthermore, since the base portion 75 is formed in a frame shape, the above effects can be obtained while suppressing the flow of return air RA from being obstructed by the base portion 75.

When the base portion 75 provided with the LED 74 is arranged upstream of the air filters 61 and 62, the light emitted from the LED 74 is blocked by the air filter 61, and the light is suitably applied to the photocatalyst 71 on the air filter 62. There is a possibility that you may not be able to do so. In that case, the sterilizing effect of the photocatalyst 71 may be reduced. In this regard, in the above embodiment, since the base portion 75 provided with the LED 74 is arranged downstream of the air filter 62, the photocatalyst 71 can be suitably irradiated with light, and as a result, the photocatalyst 71 has a sterilization effect. can be suitably demonstrated.

- The cover member 51 has an inner space 57 surrounded by a front plate part 52 and a pair of side plate parts 53, and each LED 74 is arranged in the inner space 57. Thereby, it is possible to suppress the light emitted from each LED 74 from leaking to the surroundings.

- The air filters 61 and 62 are supported diagonally by the filter support portion 59. Specifically, the air filters 61 and 62 were supported so as to be oriented obliquely to the opening surface of the intake port 37. In this case, since the area of the air filter 62 can be increased, the photocatalyst 71 can be provided in a wider area. Thereby, the sterilization effect of the photocatalyst 71 can be enhanced.

- Since the photocatalyst 71 is a visible light responsive photocatalyst, each LED 74 can be one that emits visible light. This provides peace of mind for users and the like when performing maintenance on the air filters 61 and 62.

(Second embodiment)
Next, a second embodiment will be described. Hereinafter, differences from the first embodiment will be mainly explained.

As shown in FIG. 4, the building 10 has a second floor portion 81. The second floor portion 81 is provided with a plurality of living rooms 83 and 84 and a hallway 85. The living rooms 83 and 84 and the hallway 85 are separated by a partition wall 86. Each partition wall 86 is provided with a vent 89. The living rooms 83 and 84 and the hallway 85 can be constantly ventilated through the ventilation holes 89. Note that a veranda 92 is provided next to the living room 83.

The building 10 has a roof section 91 above the second floor section 81. Further, a ceiling portion 93 is provided in the second floor portion 81. The ceiling part 93 is configured with a ceiling surface material, and the ceiling part 93 forms the ceiling surfaces of the living rooms 83, 84 and the hallway 85. An attic space 95 of the roof section 91 is formed above the ceiling section 93. The attic space 95 is separated from the living rooms 83 and 84 and the hallway 85 by the ceiling 93.

The building 10 is provided with a whole-building air conditioning system 100 that air-conditions the living rooms 83 and 84 (corresponding to indoor spaces) on the second floor 81. The whole building air conditioning system 100 will be explained below.

The whole building air conditioning system 100 has an indoor unit 101 and an outdoor unit 102, like the whole building air conditioning system 30 of the first floor part 12, and the indoor unit 101 and the outdoor unit 102 are connected via a refrigerant pipe 103. In FIG. 4, the refrigerant pipe 103 is shown by a dotted line for convenience.

The indoor unit 101 is installed in the attic space 95. A plurality of air conditioning ducts 108 are connected to the indoor unit 101 via an air conditioning chamber 107. Each air conditioning duct 108 is arranged in the attic space 95 and is connected to an air outlet 109 provided in the ceiling 93 of each living room 83, 84, respectively. Conditioned air generated by the indoor unit 101 is supplied to each air outlet 109 through each air conditioning duct 108, and is blown out from each air outlet 109 to each living room 83, 84, respectively. As a result, each living room 83, 84 is air-conditioned (cooled/heated).

The conditioned air (supply air SA) supplied to each of the living rooms 83 and 84 is configured to flow back into the hallway 85 as return air RA through each vent 89. A suction chamber 111 is provided in the ceiling 93 of the hallway 85 to suck in the return air RA that has returned to the hallway 85. A return air duct 112 is connected to the suction chamber 111 . The return air duct 112 is arranged in the attic space 95 and connected to the side surface of the indoor unit 101. Specifically, an opening 113 is provided in the side surface of the indoor unit 101, and a return air duct 112 is connected to the opening 113.

In the above configuration, when the return air RA in the hallway 85 is sucked into the suction chamber 111, the return air RA is taken into the indoor unit 101 through the return air duct 112. In this case, the return air RA is taken into the interior of the indoor unit 101 from the return air duct 112 through the opening 113 of the indoor unit 101. Therefore, in this case, the opening 113 corresponds to the intake port, and since the return air RA flows toward the opening 113 through the inside of the suction chamber 111 and the inside of the return air duct 112, in this case, the suction The inside of the chamber 111 and the inside of the return air duct 112 constitute a return air passage. Further, the suction chamber 111 and the return air duct 112 constitute a passage forming section.

Next, the configuration around the suction chamber 111 will be described based on FIGS. 5 and 6. Note that in FIGS. 5 and 6, illustration of the ceiling portion 93 is omitted for convenience.

As shown in FIGS. 5 and 6, the suction chamber 111 is provided with a housing recess 117 that opens downward and a connection port 118 that is formed at the bottom of the housing recess 117 and is connected to the return air duct 112. It is being A suction grill 119 is attached to the housing recess 117 so as to close the opening thereof. The suction grill 119 is formed with a grid-like ventilation section.

An air filter 121 is attached to the upper surface of the suction grill 119. Air filter 121 is arranged in accommodation recess 117 of suction chamber 111 . An air filter 122 is further provided above the air filter 121 in the accommodation recess 117 . The air filter 122 is arranged to overlap the air filter 121. Each of these air filters 121 and 122 collects foreign matter such as dust contained in the return air RA sucked into the suction chamber 111 (in other words, the return air RA flowing inside the suction chamber 111). In this case, among the air filters 121 and 122, the air filter 121 is arranged on the upstream side (lower side), and the air filter 122 is arranged on the downstream side (upper side).

Of the air filters 121 and 122, the downstream air filter 122 is provided with a photocatalyst 126. On the other hand, the upstream air filter 121 is not provided with a photocatalyst. Therefore, the air filter 122 corresponds to a first air filter, and the air filter 121 corresponds to a second air filter. Further, the air filter 121 has coarser mesh than the air filter 122.

A light emitting unit 128 is provided in the housing recess 117 of the suction chamber 111 above the air filter 122 . In this case, the light emitting unit 128 is arranged downstream with respect to the air filter 122. The light emitting unit 128 has the same configuration as the light emitting unit 73 of the first embodiment, and includes a plurality of LEDs 129 as a light source and a base portion 131 as a support portion.

According to the above configuration, the return air RA sucked into the suction chamber 111 flows through the accommodation recess 117 toward the downstream side. At this time, the return air RA passes through each air filter 121, 122 in order. First, foreign matter in the return air RA is collected in the air filter 121 on the upstream side, and then bacteria and viruses in the return air RA are removed by the photocatalytic action of the photocatalyst 126 in the air filter 122 on the downstream side. Thereafter, the return air RA is taken into the indoor unit 101 through the opening 113 through the return air duct 112.

As described above, according to the configuration of this embodiment, the same effects as in the first embodiment can be obtained.

(Other embodiments)
The present invention is not limited to the embodiments described above, and may be implemented as follows, for example.

- In each of the above embodiments, the photocatalyst 71 is provided only in the air filter 62 among the air filters 61 and 62, but in addition to this, the photocatalyst 71 may also be provided in the air filter 61.

- In each of the above embodiments, two air filters 61 and 62 are provided, but this may be changed to provide only the air filter 62 provided with the photocatalyst 71. In this case, the air filter 62 will be used for both foreign matter collection and sterilization. However, considering that the sterilization effect of the photocatalyst 71 decreases due to cleaning of the air filter 62, it is recommended to provide two air filters 61 and 62 and use them for foreign matter collection and sterilization, as in the above embodiment. is preferred.

Further, in a case where only the air filter 62 is provided as an air filter, the air filter 62 may be attached to the intake port 37 of the indoor unit 32. In that case, the LED 74 may be placed inside the indoor unit 32, for example.

- The two air filters 61 and 62 do not necessarily need to be arranged one on top of the other, and may be arranged apart from each other. However, in order for the sterilizing effect of the photocatalyst 71 to be exerted on the air filter 61 that does not have a photocatalyst, it is preferable to arrange the air filters 61 and 62 one on top of the other as in the above embodiment.

- The material of the air filter does not need to be limited to non-woven fabric; for example, an activated carbon filter or the like may be used.

- As a light source for irradiating light to the photocatalyst 71, it is not necessarily necessary to use the LED 74, and it is also possible to use something other than an LED, such as an incandescent lamp. Further, as a light source for the photocatalyst 71, it is not necessarily necessary to provide a light source exclusively for the photocatalyst, and for example, a lighting fixture such as a light bulb provided in the machine room 17 may be used as the light source.

- In each of the above embodiments, a visible light-responsive photocatalyst is used as the photocatalyst, but an ultraviolet light-responsive photocatalyst may also be used. In that case, it is conceivable to use an ultraviolet lamp or the like as a light source for the photocatalyst.

- The whole building air conditioning system is not limited to one that air-conditions one floor, but may be one that air-conditions the entire building 10.

DESCRIPTION OF SYMBOLS 10... Building, 30... Whole building air conditioning system, 32... Indoor unit as an air conditioner, 37... Intake port, 51... Cover member as a passage forming part, 57... Inner space as a return air passage, 61... Second air Air filter as a filter, 62... Air filter as a first air filter, 71... Photocatalyst, 74... LED as a light source, 75... Base part as a support part, 100... Whole building air conditioning system, 101... Indoor as an air conditioner 113...Opening as an intake port, 121...Air filter as a second air filter, 122...Air filter as a first air filter, 126...Photocatalyst, 129...LED as a light source, 131...As a support part base part.

Claims (5)

Equipped with an air conditioner that generates conditioned air and supplies the generated conditioned air to multiple indoor spaces within the building,
The conditioned air supplied to the plurality of indoor spaces is configured to flow back to the air conditioner as return air,
The air conditioner is a whole-house air conditioning system that has an intake port that takes in the return air, and generates conditioned air based on the return air taken in from the intake port,
an air filter that prevents foreign matter such as dust from entering the air conditioner through the intake port;
A whole building air conditioning system comprising: a photocatalyst provided in the air filter. comprising a passage forming part forming a return air passage through which the return air flows toward the intake port,
The return air passage is provided with, as the air filter, a first air filter provided with the photocatalyst and a second air filter not provided with the photocatalyst,
The whole building air conditioning system according to claim 1, wherein the second air filter is arranged upstream of the first air filter. The whole building air conditioning system according to claim 2, wherein the first air filter has coarser mesh than the second air filter. The whole building air conditioning system according to claim 2, wherein the first air filter and the second air filter are arranged so as to overlap each other. The return air passage is provided with a frame-shaped support section provided with a plurality of light sources that irradiate the photocatalyst with light,
The whole building air conditioning system according to any one of claims 2 to 4, wherein the support part is arranged to face the first air filter.

Images