JP6783610B2 - Indoor cooling device - Google Patents

Description

The present invention relates to an indoor cooling device for lowering the temperature of air in an indoor space by utilizing the cold heat of the underfloor space of a building.

Since the temperature of the air in the underfloor space in summer is lower than the temperature of the air in the indoor space, a technique for taking in the air in the underfloor space into the indoor space and cooling the indoor space is known.

For example, in Japanese Patent Application Laid-Open No. 2015-224485 (Patent Document 1), a basic ventilation port for introducing outside air into an underfloor space is arranged on the soil side of the underfloor space, and air can pass between the soil. A housing structure including a partition for forming a space on the soil side and a supply means for supplying air that has exchanged heat with the surface of the soil by passing through the space on the soil side to a living room space is disclosed.

Japanese Unexamined Patent Publication No. 2015-224485

The underfloor space is a space surrounded by a foundation made of reinforced concrete. In the case of a configuration in which the air in the underfloor space is directly supplied to the indoor space as in Patent Document 1, even an unpleasant odor (for example, concrete odor) in the underfloor space is sent into the indoor space. Therefore, in the case of such a configuration, it is necessary to separately adopt measures for reducing the odor of the supplied air.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to utilize the cold heat of the underfloor space without sending the unpleasant odor of the underfloor space into the indoor space. It is to provide an indoor cooling device which can lower a temperature.

The indoor cooling device according to a certain aspect of the present invention is an indoor cooling device for lowering the temperature of the air in the indoor space by utilizing the cold heat of the underfloor space of the building, and takes in the air in the indoor space and takes in the air taken in. An indoor circulation path that returns to the indoor space, an underfloor circulation path that takes in the air in the underfloor space of the building and returns the taken-in air to the underfloor space, and an underfloor space that circulates the air in the indoor space that circulates in the indoor circulation path and the underfloor circulation path. It is provided with a heat exchange unit that exchanges heat with the air.

Preferably, the indoor cooling device includes a fan for flowing air on the indoor circulation path, and the air volume of the fan is equal to or less than the volume (unit: m ³ ) of the indoor space to be air-conditioned multiplied by a coefficient k. The air volume (unit: m ³ / h). The coefficient k is preferably 2.70.

More preferably, the indoor cooling device further includes an air volume control unit for controlling the air volume of the fan according to the difference between the temperature of the underfloor space and the temperature of the indoor space.

Preferably, the underfloor circulation path is located downstream of the heat exchange section and branches from the downstream path for returning the air in the underfloor space after heat exchange to the underfloor space and the air in the underfloor space after heat exchange. Includes an exhaust path for exhausting air to the outside and a switching unit for switching the discharge destination of air in the underfloor space after heat exchange. In this case, it is desirable that the indoor cooling device further includes a switching control unit that controls switching of the switching unit so that the discharge destination is outdoors when a predetermined condition is satisfied.

Alternatively, the underfloor circulation path is located upstream of the heat exchange section, and one end is connected to the upstream path connected to the air intake port that takes in the air in the underfloor space and one end to the outdoor air intake port that takes in the outdoor air. It may also include an outside air suction path whose other end is connected to the upstream path and a switching section for switching the intake destination of the air sent to the heat exchange section. Even in this case, it is desirable that the indoor cooling device further includes a switching control unit that controls switching of the switching unit so that the intake destination is outdoors when a predetermined condition is satisfied.

Preferably, the switching control unit performs switching control of the switching unit according to the time zone.

Alternatively, the switching control unit performs switching control of the switching unit by comparing the temperature of the underfloor space with the outdoor temperature.

According to the present invention, the temperature of the indoor space can be lowered by utilizing the cold heat of the underfloor space without sending the unpleasant odor of the underfloor space into the indoor space.

It is a figure which shows typically the schematic structure of the heat exchange system which concerns on embodiment of this invention. FIG. 5 is a cross-sectional view schematically showing an indoor cooling device installed in an underfloor space of a house in an embodiment of the present invention. It is a functional block diagram which shows the functional structure of the room cooling apparatus which concerns on embodiment of this invention. It is a graph for demonstrating the air volume control method in embodiment of this invention. It is a graph which shows the transition of the temperature of the underfloor space and the outside air temperature in early summer. It is a top view which shows typically the piping structure arranged in the underfloor space in the modification of embodiment of this invention. It is a functional block diagram which shows the functional structure of the room cooling apparatus in the modification of embodiment of this invention.

Embodiments of the present invention will be described in detail with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated.

(About the outline configuration)
First, a schematic configuration of the indoor cooling device 10 according to the present embodiment will be described with reference to FIGS. 1 and 2.

With reference to FIG. 1, the heat exchange system 1 mounted on the house 9 includes an indoor cooling device 10. The indoor cooling device 10 cools the indoor space 92 by utilizing the cold heat of the underfloor space 80 of the house 9 in the summer. The underfloor space 80 is a space surrounded by an outer peripheral foundation 81 located under the outer wall 91 of the house 9. A vent 81a (FIG. 2) for ventilation of the underfloor space 80 is provided between the outer wall 91 and the outer peripheral foundation 81.

As shown in FIG. 2, the indoor cooling device 10 takes in the air in the indoor space 92 and returns it to the indoor space 92, and the underfloor circulation path 30 which takes in the air in the underfloor space 80 and returns it to the underfloor space 80. A heat exchange unit 40 that exchanges heat between the air flowing on the indoor circulation path 20 and the air flowing on the underfloor circulation path 30 is provided.

The indoor cooling device 10 is typically arranged in the underfloor space 80 and incorporates a heat exchange unit 40. The indoor cooling device 10 includes a first air passage 21 constituting the indoor circulation path 20 and a second air passage 31 forming the underfloor circulation path 30 inside the housing, and the first air passage 21 and the second air passage 21. The heat exchange unit 40 is arranged so as to straddle the 31. As the configuration of the heat exchange unit 40, a known configuration can be adopted. The indoor cooling device 10 includes a first fan 22 provided in the first air passage 21 and a second fan 32 provided in the second air passage 31.

The indoor circulation path 20 is an air circulation path of the indoor space 92 from the intake port 23 arranged in the indoor space 92 to the outlet 24 arranged in the indoor space 92. The indoor circulation path 20 typically includes an intake duct 25 that connects the intake port 23 and one end of the first air passage 21, and an outlet duct 26 that connects the other end of the first air passage 21 and the outlet 24. And include. The intake port 23 and the outlet port 24 are provided, for example, on the floor of the indoor space 92.

When the intake duct 25 and the outlet duct 26 are detachably attached to the main body of the indoor cooling device 10, the indoor circulation path as the configuration of the indoor cooling device 10 is composed of only the first air passage 21. You may. Further, both the intake duct 25 and the outlet duct 26 may be omitted by arranging the one end and the other end of the first air passage 21 of the indoor cooling device 10 so as to face the floor of the indoor space 92. In this case, the intake port 23 and the outlet port 24 are formed at one end and the other end of the first air passage 21 of the indoor cooling device 10.

The underfloor circulation path 30 is an air circulation path of the underfloor space 80 from the intake port 33 arranged in the underfloor space 80 to the outlet 34 arranged in the underfloor space 80. Similarly, the underfloor circulation path 30 includes an intake duct 35 that connects the intake port 33 and one end of the second air passage 31, and an outlet duct 36 that connects the other end of the second air passage 31 and the outlet 24. It may be.

In the present embodiment, since the indoor cooling device 10 is arranged in the underfloor space 80, both the intake duct 35 and the outlet duct 36 can be omitted. In this case, the intake port 33 and the outlet port 34 are formed at one end and the other end of the second air passage 31 of the indoor cooling device 10. Alternatively, similarly to the indoor circulation path 20, the intake duct 35 and the outlet duct 36 may be detachably configured to be attached to and detached from the main body of the indoor cooling device 10. In such a case, the underfloor circulation path as a configuration of the indoor cooling device 10 may be composed of only the second air passage 31.

Since the indoor cooling device 10 (heat exchange system 1) is configured in this way, the relatively high temperature air in the indoor space 92 is cooled by heat exchange with the air in the underfloor space 80, and the cooled air is cooled in the indoor space 92. Can be supplied to. Thereby, the temperature of the indoor space 92 in the summer can be reduced. As a result, it can contribute to the reduction of the cooling load.

Further, in the present embodiment, the indoor circulation path 20 and the underfloor circulation path 30 are individually provided, and the air in the indoor space 92 is returned as it is (by lowering the temperature), which is an unpleasant underfloor space. It is not necessary to supply the odor of 80 to the indoor space 92. Therefore, the resident can spend comfortably in the indoor space 92.

The intake port 23 and the outlet 24 of the indoor circulation path 20 are not limited to the example of being arranged in the common indoor space 92, and the intake port 23 and the outlet 24 may be arranged in different indoor spaces. .. The indoor space 92 in which the outlet 24 is arranged is an indoor space to be air-conditioned (cooled), and is typically a living room, a dining room, a private room (bedroom, a children's room), or the like. When the air intake port 23 and the air outlet port 24 are arranged in different indoor spaces, the indoor space in which the air intake port 23 is arranged may be an indoor space 93 of a non-living room such as a corridor or a staircase.

Further, the number of the intake port 23 and the outlet 24 of the indoor circulation path 20 is not limited to one, and may be a plurality. As shown in FIG. 1, for example, when two outlets 24 are provided in the indoor space 92 on the first floor and the indoor space 92 on the second floor, the above-mentioned outlet ducts 26 are provided according to the number of outlets 24. It may be branched. The duct 26a extending to the outlet 24 of the indoor space 92 on the second floor is arranged so as to pass through the air layer of the partition wall on the first floor and the attic space (neither shown).

(About target heat collection amount)
In the present embodiment, the target heat collection amount by one indoor cooling device 10 is 300 W. This is equivalent to three rooms (about 20 tatami mats) in a typical house. Assuming that the height of the indoor space 92 from the floor surface to the ceiling surface is 2.4 m, the volume of the indoor space 92 for 20 tatami mats is about 79.44 m ³ (33.1 m ² × 2.4 m = 79. It is 44m ³ ).

From the past actual measurement results, the temperature difference (indoor temperature-underfloor temperature) Δt between the underfloor space 80 and the indoor space 92 in summer is about 3.5 to 5.0 ° C. on average. When the air volume of the second fan 32 on the underfloor circulation path 30 side is constant, the air volume V of the first fan 22 on the indoor circulation path 20 side is calculated by the following equation. The volume ratio of air is about 0.33 to 0.35.

Air volume V = target heat collection volume / (Δt x air volume ratio)

When the temperature difference Δt is calculated as the average temperature (3.5 to 5.0 ° C.), the air volume V is 210 to 240 m ³ / h. Therefore, in order for the indoor cooling device 10 to achieve the target heat collection amount of 300 W, the first fan 22 needs to be a fan having a capacity of 210 m ³ / h or more. In the present embodiment, in consideration of energy saving, a fan having a maximum air volume (upper limit value of possible air volume) of 210 m ³ / h is adopted as the first fan 22. As a result, the temperature of the indoor space 92 can be reduced by about 1 to 3 ° C. The second fan 32 may be a fan having a lower capacity (air volume) than the first fan 22.

However, since the actual size (volume) of the indoor space 92 to be air-conditioned differs depending on each house, the maximum air volume of the first fan 22 may be determined according to the volume of the indoor space 92 to be air-conditioned. desirable. Specifically, the air volume (range of possible air volume) of the first fan 22 is determined by the following conditional expression.

Air volume (m ³ / h) ≤ k x room volume (m ³ )

That is, the air volume of the first fan 22 is equal to or less than the value obtained by multiplying the volume (room volume) of the indoor space 92 to be air-conditioned by the coefficient k. The room volume is a value obtained by adding the volumes of the plurality of indoor spaces 92 when there are a plurality of indoor spaces 92 to be air-conditioned. Here, the coefficient k is a coefficient for calculating the required heat collection amount in consideration of the temperature difference between the underfloor space 80 and the indoor space 92.

As described above, assuming that the volume of the indoor space 92 to be air-conditioned is about 79.44 m ³ for 20 tatami mats, the required air volume of the first fan 22 is 210 m ³ / h, so that the coefficient k is It can be calculated as 210 / 79.44 = 2.6435. From this calculation result, the coefficient k is determined as 2.70.

In this case, the maximum air volume (upper limit value of the air volume) of the first fan 22 is "k (2.70) x chamber volume (m ³ )", but when selecting the first fan 22, the maximum air volume is selected. May employ a fan that satisfies the following conditional expression.

l × chamber volume (m ³ ) <maximum air volume (m ³ / h) ≦ k × chamber volume (m ³ )

However, the coefficient l can be determined as, for example, 2.40 from the above calculation result (210 / 79.44 = 2.6435). By adopting a fan having such a capability, even when the temperature difference between the underfloor space 80 and the indoor space 92 is relatively small, the indoor space 92 can be effectively used by utilizing the cooling heat of the underfloor space 80. Can be cooled.

As described above, the average temperature difference Δt between the underfloor space 80 and the indoor space 92 is about 3.5 to 5.0 ° C., but in reality, there are times when the temperature difference Δt becomes 10 ° C. or more. .. Therefore, the air volume of the first fan 22 may be variable instead of fixed. The functional configuration of the indoor cooling device 10 and the air volume control method in this case will be described below.

(About functional configuration and air volume control method)
FIG. 3 is a functional block diagram showing a functional configuration of the indoor cooling device 10. With reference to FIG. 3, the indoor cooling device 10 includes a control unit 51 that controls the operation of the fans 22, 32 and the heat exchange unit 40, a storage unit 52 that records various information and programs, and a timekeeping unit that performs a timekeeping operation. 53, an underfloor temperature sensor 61 that detects the temperature of the underfloor space 80, and an indoor temperature sensor 62 that detects the temperature of the indoor space 92 to be air-conditioned are provided.

The control unit 51 operates the fans 22, 32 and the heat exchange unit 40, that is, the heat exchange system 1 only in the summer. The control unit 51 may determine the start / stop of the heat exchange system 1 according to the instruction from the user, or the heat exchange system 1 may determine the start / stop of the heat exchange system 1 according to the difference between the temperature of the indoor space 92 and the temperature of the underfloor space 80. You may decide to start / stop. Alternatively, the control unit 51 may determine the start / stop of the heat exchange system 1 according to the date measured by the time measuring unit 53.

As shown in FIG. 2, the underfloor temperature sensor 61 is arranged, for example, in a portion of the underfloor circulation path 30 upstream of the heat exchange portion 40. The indoor temperature sensor 62 is arranged, for example, in a portion of the indoor circulation path 20 upstream of the heat exchange section 40.

The control unit 51 includes an air volume control unit 54 as its function. The air volume control unit 54 controls the air volume of the first fan 22 according to the difference between the temperature of the underfloor space 80 and the temperature of the indoor space 92. The specific air volume control method of the air volume control unit 54 is as follows, for example.

The air volume control unit 54 detects the temperature difference Δt between the underfloor space 80 and the indoor space 92 based on the signals from the underfloor temperature sensor 61 and the indoor temperature sensor 62. The air volume control unit 54 determines whether or not the detected temperature difference Δt is 5.0 ° C. or less, which is the maximum value of the summer average.

If the detected temperature difference Δt is 5.0 ° C. or less, the air volume control unit 54 controls the rotation speed of the first fan 22 so that the air volume reaches the maximum air volume of 210 m ³ / h. On the other hand, when the detected temperature difference Δt exceeds 5.0 ° C., the air volume control unit 54 rotates the first fan 22 so that the air volume is smaller than the maximum air volume (210 m ³ / h). To control.

For example, when the detected temperature difference Δt is 5.0 ° C. or less, the air volume control unit 54 drives the first fan 22 in the strong operation mode, and the detected temperature difference Δt exceeds 5.0 ° C. In addition, the first fan 22 may be driven in the weak operation mode.

Alternatively, when the temperature difference Δt exceeds 5.0 ° C., the air volume control unit 54 may finely adjust the air volume V of the first fan 22 according to the temperature difference Δt. The relationship between the temperature difference Δt and the air volume V of the first fan 22 in such a control method is shown in the graph of FIG.

The graph of FIG. 4 plots the value of the air volume V when the temperature difference Δt is 7.0 ° C., 10.0 ° C., 15.0 ° C., and 20.0 ° C. by the above formula, and draws these plotted values. It is a graph connected by. Based on this graph, the air volume control unit 54 controls the first fan 22 so that the air volume V becomes about 80 m ³ / h when the temperature difference Δt is 10 ° C., and the air volume when the temperature difference Δt is 15 ° C. The first fan 22 is controlled so that V becomes about 60 m ³ / h.

As described above, when the temperature difference Δt is relatively large, the power consumption of the first fan 22 can be suppressed by setting the air volume of the first fan 22 to be small.

The operation of the air volume control unit 54 is realized by executing the software stored in the storage unit 52, but it may be realized by hardware.

Further, the air volume control unit 54 may similarly control the air volume of the second fan 32 according to the temperature difference Δt.

(Modification example)
As shown in FIG. 5, the temperature of the outside air may be lower than the temperature of the air in the underfloor space 80 depending on the time zone such as the nighttime (morning) in early summer. Therefore, in order to further improve the cooling effect of the indoor space 92, the heat exchange system may be provided with a mechanism capable of taking in outside air.

FIG. 6 is a plan view schematically showing a piping configuration arranged in the underfloor space 80 in the modified example of the present embodiment, and shows a schematic configuration of the heat exchange system 1A in the modified example.

The outlet duct 36 of the underfloor circulation path 30 is located downstream of the heat exchange section 40, and constitutes a downstream path 36a that returns the air in the underfloor space 80 after heat exchange to the underfloor space 80. In this modification, the underfloor circulation path 30 has an exhaust path 37a that branches from the downstream path 36a and exhausts the air after heat exchange to the outside, and a switching unit 38 that switches the discharge destination of the air after heat exchange. doing.

The exhaust path 37a is formed by an exhaust duct 37 branching from the outlet duct 36. The exhaust duct 37 is inserted into, for example, a vent 81a between the outer peripheral foundation 81 and the outer wall 91. The switching unit 38 is composed of, for example, dampers that open and close each path. Alternatively, the switching unit 38 may be composed of a three-way valve arranged at a branch point between the downstream path 36a and the exhaust path 37a.

FIG. 7 is a functional block diagram showing a functional configuration of the indoor cooling device 10A in this modified example. As shown in FIG. 7, the control unit 51 of the indoor cooling device 10A includes a switching control unit 55. In this modification as well, the air volume control unit 54 shown in FIG. 3 may be included in the control unit 51.

The switching control unit 55 and the switching unit 38 are electrically connected, and the switching control unit 55 switches the switching unit 38 so that the air discharge destination after heat exchange is outdoors only at a predetermined time at night. Take control. Specifically, the switching control unit 55 determines the current time based on the signal from the time measuring unit 53, opens the exhaust path 37a in a predetermined time zone at night (for example, from 0:00 to 6:00 am), and downstream. The switching unit 38 is controlled so that the path 36a is closed. The switching control unit 55 controls the switching unit 38 so that the exhaust path 37a is in the closed state and the downstream path 36a is in the open state in the remaining time zone (for example, from 7:00 am to 1:00 am) including the daytime.

In this way, the switching control unit 55 selectively switches the air discharge destination of the underfloor space 80 after heat exchange. The switching control unit 55 may be operated only in early summer (June to early July) and late summer (late September to October) in the summer.

When the air after heat exchange passing through the underfloor circulation path 30 is discharged to the outside through the exhaust path 37a, the underfloor space 80 becomes a negative pressure. When the underfloor space 80 becomes a negative pressure, the outside air is taken into the underfloor space 80 through the vent 81a. Since the temperature of the outside air is lower than that of the air in the underfloor space 80 at night in early summer and late summer, the temperature of the underfloor space 80 can be lowered by actively taking in the outside air. As a result, low-temperature air is taken into the underfloor circulation path 30 from the intake port 33, so that the indoor space 92 can be efficiently cooled.

On the other hand, during the daytime in summer, only air is circulated in the underfloor space 80, so that it is possible to prevent the relatively high temperature outside air from being taken into the underfloor space 80 more than necessary. As a result, it is possible to prevent the temperature of the underfloor space 80 from rising, so that the cooling effect of the indoor space 92 can be maintained.

The operation of the switching control unit 55 shown in FIG. 7 is also realized by executing the software stored in the storage unit 52, but it may also be realized by hardware.

In this modification, the switching control unit 55 performs switching control of the switching unit 38 according to the time zone, but the present invention is not limited to such an example. That is, the condition for the switching control unit 55 to determine the discharge destination of the air after heat exchange to the outside may be a condition other than the time zone. For example, the switching control unit 55 may perform switching control of the switching unit 38 by comparing the temperature of the underfloor space 80 with the outdoor temperature.

In this case, as shown in FIG. 7, the switching control unit 55 determines whether or not the temperature of the underfloor space 80 detected by the underfloor temperature sensor 61 is higher than the outside air temperature detected by the outside air temperature sensor 63. , The switching control of the switching unit 38 is performed according to the determination result. Specifically, when the switching control unit 55 determines that the temperature of the underfloor space 80 is higher than the outside air temperature (only), the switching control unit 55 controls the switching unit 38 so that the air discharge destination after heat exchange is outdoors. To do. Since the outside air temperature sensor 63 is arranged outdoors, for example, on the outer surface of the outer peripheral foundation 81, it may be outside the configuration of the indoor cooling device 10A. In this case, the indoor cooling device 10A may be provided with an input unit for inputting a detection signal from the outside air temperature sensor 63.

Alternatively, in this modification, the air discharge destination after heat exchange is set to the outside so that the underfloor space 80 is made a negative pressure and the outside air is taken into the underfloor space 80. However, the air intake destination of the heat exchange target air is taken in. May be configured to directly send the outside air to the heat exchange unit 40 by making the outside air.

In this case, the underfloor circulation path 30 includes an outside air suction path (not shown) that joins the upstream path formed by the intake duct 35. This outside air suction path is a path in which one end is connected to an outdoor intake port (not shown) for sucking outdoor air and the other end is connected to this upstream path. The outside air suction path is formed by an outside air suction duct (not shown) connected to the intake duct 35. In this case, the switching control unit 55 performs switching control of the switching unit (not shown) arranged at the branch point between the upstream path and the outside air suction path, for example, based on the same conditions as the above modification.

In the above-described embodiment and its modification, the indoor cooling device 10 (10A) is arranged in the underfloor space 80, but at least the intake port 33 and the outlet 34 of the underfloor circulation path 30 are provided. If it is arranged in the underfloor space 80, it may be arranged in another space such as the attic space on the first floor.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and it is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1,1A heat exchange system, 9 housing, 10,10A indoor cooling device, 20 indoor circulation path, 21 first air passage, 22,32 fan, 23,33 intake port, 24,34 outlet, 25,35 intake duct , 26, 26a, 36 outlet duct, 30 underfloor circulation path, 31 second air passage, 36a downstream path, 37 exhaust duct, 37a exhaust path, 38 switching section, 40 heat exchange section, 51 control section, 52 storage section, 53 Measuring unit, 54 air volume control unit, 55 switching control unit, 61 underfloor temperature sensor, 62 indoor temperature sensor, 63 outdoor temperature sensor, 80 underfloor space, 81 outer peripheral foundation, 81a vent, 91 outer wall, 92,93 indoor space.

Claims (7)

An indoor cooling device that uses the cold heat of the underfloor space of a building to lower the temperature of the air in the indoor space.
An indoor circulation path that takes in the air in the indoor space and returns the taken-in air to the indoor space.
An underfloor circulation path that takes in the air in the underfloor space of the building and returns the taken-in air to the underfloor space.
An indoor cooling device including a heat exchange unit that exchanges heat between the air in the indoor space that circulates in the indoor circulation path and the air in the underfloor space that circulates in the underfloor circulation path. A fan for flowing air on the indoor circulation path is provided.
The air volume of the fan is equal to or less than the value obtained by multiplying the volume of the indoor space to be air-conditioned by a coefficient k.
The indoor cooling device according to claim 1, wherein the coefficient k is 2.70. The indoor cooling device according to claim 2, further comprising an air volume control unit for controlling the air volume of the fan according to the difference between the temperature of the underfloor space and the temperature of the indoor space. The underfloor circulation path is located on the downstream side of the heat exchange portion, and branches from the downstream path to return the air in the underfloor space after heat exchange to the underfloor space and the underfloor space after the heat exchange. Includes an exhaust path that exhausts the air to the outside and a switching unit that switches the air discharge destination in the underfloor space after heat exchange.
The indoor cooling device according to any one of claims 1 to 3, further comprising a switching control unit that controls switching of the switching unit so that the discharge destination is outdoors when a predetermined condition is satisfied. The underfloor circulation path is located on the upstream side of the heat exchange section, and one end is connected to an intake port for sucking air in the underfloor space, and one end is connected to an outdoor intake port for sucking outdoor air. Includes an outside air suction path that is connected and the other end of which is connected to the upstream path, and a switching section that switches the intake destination of the air sent to the heat exchange section.
The indoor cooling device according to any one of claims 1 to 3, further comprising a switching control unit that controls switching of the switching unit so that the intake destination becomes outdoors when a predetermined condition is satisfied. The indoor cooling device according to claim 4 or 5, wherein the switching control unit performs switching control of the switching unit according to a time zone. The indoor cooling device according to claim 4 or 5, wherein the switching control unit controls switching of the switching unit by comparing the temperature of the underfloor space with the outdoor temperature.

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