JP3441406B2 - Area cooling and heating system thermal storage system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an area cooling / heating skeleton heat storage system in which a skeleton heat storage system, a convection air conditioning system, and a radiant air conditioning system are combined.

[0002]

2. Description of the Related Art Conventionally, as a cooling / heating skeleton heat storage system combining a skeleton heat storage system and a convection air conditioning system, a system as disclosed in Japanese Patent Laid-Open No. 10-9614 (floor blowout air conditioning system utilizing skeleton heat storage) There is. FIG. 17 shows an outline of this system.

In FIG. 17, reference numeral 1 is a floor skeleton, and this floor skeleton 1 is constituted by a structure having a hollow portion 2, for example, a void slab. Reference numeral 3 denotes a floor surface, and a floor frame 1 is provided below the floor surface 3 with the underfloor space 4 interposed therebetween. The floor frame 1 is provided with communication ports 5 and 5 between the hollow portion 2 and the underfloor space 4. An air conditioner 7 is arranged in a storage space 6 outside the air conditioning space 16, and a blowout side duct 8 of the air conditioner 7 is located in the underfloor space 4. The suction side of the air conditioner 7 is located above, and a communication port 9 communicating with the air conditioning space 16 is provided in the upper part of the storage space 6.

A large number of air outlets 10 are opened on the floor surface 3, and an air volume adjusting device such as a damper is provided on the air outlets 10. This air volume adjusting device is not shown in the figure. A fan coil 12 is installed in a perimeter area (area near the outer wall: in this case, near the window) 11 of the air-conditioned space 16. The fan coil 12 includes a fan 13 and a cold water coil or a hot water coil 14. A communication port with the underfloor space 4 is provided at the bottom of the fan coil 12, and a damper 15 is provided at this communication port.

[Heat Storage Operation in Summer (Winter)] In this system, nighttime electric power is used to store heat in the floor skeleton 1.
FIG. 17 shows the heat storage operation state at this time. At night when the unit price of the electricity price becomes low, the damper 15 of the fan coil 12 is closed, and the air conditioner 7 is cooled (heated) while the air flow rate adjusting device of the outlet 10 is closed.
As a result, cold air (warm air) from the blow-out side duct 8 flows through the underfloor space 4 and is supplied from the communication ports 5 and 5 into the hollow portion 2 of the floor skeleton 1 to cool (warm) the floor skeleton 1. As a result, cold heat (warm heat) is accumulated in the floor skeleton 1.

[Cooling Operation in Summer] When the time period during which air conditioning is required, the air conditioner 7 is cooled. In this case, as shown in FIG. 18, the air volume adjusting device of the air outlet 10 is opened to increase the air volume, and the fan coil 12 opens the damper 15 to operate only the fan 13. As a result, the cool air from the air conditioner 7 is supplied to the air conditioning space 16 from the outlet 10 and the fan coil 12 through the underfloor space 4, flows in the air conditioning space 16, and communicates from the upper communication port 9 to the air conditioning in the storage space 6. Return to machine 7. At this time, since the floor skeleton 1 is in a state of being cooled by the heat storage operation using the electric power at night, it is possible to supply a predetermined conditioned air to the room immediately after the cooling operation of the air conditioner 7 is started. Therefore, the air conditioning equipment is started before the time when air conditioning is required, that is, warming up is not required, and a comfortable indoor environment can be immediately obtained. If the amount of heat stored in the floor skeleton 1 is increased, it is possible to cool the inside of the air-conditioned space 16 from the morning to the daytime only by blowing air.

[Winter heating operation] When the time period during which air conditioning is required is reached, the air conditioner 7 is heated. In this case, as shown in FIG. 19, the air volume adjusting device of the air outlet 10 is opened to increase the air volume, and the fan coil 12 operates both the fan 13 and the hot water coil 14 with the damper 15 closed. . As a result, the warm air from the air conditioner 7 is supplied to the air conditioner space 16 from the outlet 10 through the underfloor space 4, flows through the air conditioner space 16 and flows from the upper communication port 9 to the air conditioner 7 in the storage space 6. Recycle. Also, the fan coil 12
Hot air circulates in the perimeter area 11. At this time, since the floor skeleton 1 is in a state of being warmed by the heat storage operation using the electric power at night, it is possible to supply a predetermined conditioned air to the room immediately after the heating operation of the air conditioner 7 is started. Therefore, the air conditioning equipment is started before the time when air conditioning is required, that is, warming up is not required, and a comfortable indoor environment can be immediately obtained. If the amount of heat stored in the floor frame 1 is increased, it is possible to heat the air-conditioned space 16 from the morning to the daytime only by blowing air.

[0008]

The heating / cooling body heat storage system, which is a combination of the body heat storage system and the convection air conditioning system, greatly contributes to the leveling of the electric power load by utilizing the nighttime electric power. Further, by storing heat in the floor frame at night, the air conditioning load can be leveled and the rated capacity of the air conditioning system can be reduced. Further, there are various advantages such as a small installation space, effective use of floor space, and a simple air conditioning facility because there is a heat storage material near the air conditioning space.

However, since it is a system that blows out cold air or warm air from a large number of air outlets provided on the floor, it is difficult to make the temperature airflow distribution in the air-conditioned space uniform, and the occupants are too hot or too cold. Claims often occur. In addition, there are problems such that air-conditioning air from the floor causes dust to wind up, and cold or warm air directly hits the skin. Further, a large amount of energy is consumed, and in the energy-saving room temperature setting (summer: 28 ° C, winter: 20 ° C), the thermal environment in the air-conditioned space cannot be kept comfortable. Further, in the perimeter area where the heat load increases in winter and summer, it is necessary to provide air conditioning equipment such as a fan coil to cover this heat load, which is a factor of increasing the cost of the entire system. Moreover, the heat radiation time zone cannot be adjusted, and the contribution to the peak cut of electric power is small.

The present invention has been made in order to solve such a problem, and an object of the present invention is not to require air conditioning equipment such as a fan coil in a perimeter area, and a complaint from a resident in an air conditioned space. An object of the present invention is to provide an area cooling / heating skeleton heat storage system that can create a comfortable thermal environment that does not frequently occur, and that can reduce operating costs by reducing energy consumption.

[0011]

[Means for Solving the Problems] In order to achieve such an object, the present invention uses night-time electric power to supply cold / hot air to the hollow part of the body to store heat in the body, and Exhaust air from the air-conditioned space is sent to the space below, and the heat stored in the body is transferred to the floor surface through this air to radiate heat from the floor surface to the air-conditioned space, and at the same time, to radiate from this floor surface. The air that has contributed to the heat transfer is sent out to the air-conditioned space through a communication opening formed at a floor surface position facing the perimeter area of the air-conditioned space. According to this invention, the exhaust air from the air-conditioned space is sent to the space below the floor surface, the heat stored in the body is transferred to the floor surface via this air, and is radiatively transmitted from the floor surface to the air-conditioned space. Be heated. That is, in the present invention, a large number of outlets are not formed on the floor surface, and the heat accumulated in the frame is radiated to the air-conditioned space with the floor surface serving as a radiant heat transfer surface. In addition, the air that contributed to the radiant heat transfer from the floor surface is sent from the floor surface to the perimeter area of the air-conditioned space, and after reducing the heat load in the perimeter area,
Convection and discharge from the air-conditioned space. Due to the convective heat transfer of the air sent to the perimeter area and the radiant heat transfer from the floor surface, the area cooling and heating (convective heat transfer + radiant heat transfer) is performed in combination with the body heat storage.

Further, according to the present invention, night-time electric power is used to supply cold / hot air to the hollow portion of the body and the space below the floor to store heat in the body and the floor. And the exhaust air from the air-conditioned space is sent to the hollow part of the body, and the heat stored in the body is transferred to the floor surface via the air sent to the space below the floor surface and radiated from the floor surface to the air-conditioned space. The air that contributes to the radiant heat transfer from this floor surface and the air that gets out of the heat accumulated from the body that has accumulated heat through the hollow part of the body to the floor position facing the perimeter area of the air-conditioned space It is designed to be sent out to the air-conditioned space through the communication port that has been opened. According to this invention, the exhaust air from the air-conditioned space is sent to the space below the floor and the hollow part of the body, and the heat accumulated in the body is transferred via the air sent below the floor to the floor. To the air-conditioned space from the floor surface. That is, in the present invention, a large number of outlets are not formed on the floor surface, and the heat accumulated in the frame is radiated to the air-conditioned space with the floor surface serving as a radiant heat transfer surface. Also, the air that contributes to the radiant heat transfer from the floor surface and the air that comes out through the hollow part of the body (the air that comes out by accumulating heat from the body that has accumulated heat) is the perimeter of the air-conditioned space from the floor surface. After being sent to the area and reducing the heat load in the perimeter area, it is convected and discharged from the conditioned space. Due to the convective heat transfer of the air sent to the perimeter area and the radiant heat transfer from the floor surface, the area cooling and heating (convective heat transfer + radiant heat transfer) is performed in combination with the body heat storage.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail based on embodiments. [Embodiment 1: Basic system] Fig. 1 is a system configuration diagram showing an outline of an embodiment (Embodiment 1) of an area cooling / heating body heat storage system according to the present invention. In the figure, 21 is a floor surface (hereinafter referred to as a region floor plate), 22 is a floor frame (hereinafter referred to as a floor slab) having a hollow portion 24 provided below the region floor plate 21 with a space (underfloor space) 23 interposed therebetween. And 25 are the hollow portion 24 of the floor slab 22 and the underfloor space 23.
And a communication port (first communication port) 26 which is opened at a floor surface position facing the perimeter area 28 of the air conditioning space 27 and which communicates the air conditioning space 27 and the underfloor space 23 (second communication port).
Communication port), 29 is an air conditioner having both cooling and heating functions, 30 is an electric valve provided in a supply passage of cold / hot water to the air conditioner 29, and 31-1 to 31-5 are to the air conditioner 29. , T1 to T4 provided in the air supply passages and distribution passages of the
Is a temperature sensor, and 32 is a control device.

The air conditioner 29 includes a fan 29-1 and a cold / hot water coil 29-2. The damper 31-1 is provided in a passage L1 that connects an air outlet (return port) 27-1 from the air-conditioned space 27 and an air inlet of the air conditioner 29. The damper 31-2 is provided in a passage L2 that connects an intake port for outside air (OA) and an intake port for air of the air conditioner 29. The damper 31-3 is provided in a passage L3 that connects the air outlet of the air conditioner 29 and the underfloor space 23. The damper 31-4 is provided in a passage L4 that connects the air outlet of the air conditioner 29 and the hollow portion 24 of the floor slab 22. The damper 31-5 is provided in a passage L5 that connects the air suction port of the air conditioner 29 and the underfloor space 23.

The communication port 25 is provided at the end portion (left end portion in the figure) of the floor slab 22. The floor slab 22 has a communication port 2
5, there is no communication port with the underfloor space 23.
The temperature sensor T1 detects the temperature of the end portion of the hollow portion 24. The temperature sensor T2 detects the temperature of the end portion of the underfloor space 23. The temperature sensor T3 detects the surface temperature of the area floor plate 21. The temperature sensor T4 detects the indoor temperature of the air-conditioned space 16. The temperature detected by the temperature sensors T1 to T4 is controlled by the control device 3
Given to 2.

Based on the detected temperatures from the temperature sensors T1 to T4 and various input / setting information, the control device 32 rotates the fan 29-1 of the air conditioner 29 and sends the cold / hot water coil 29-2 via the electric valve 30. Cold / hot water supply, damper 31-1
Control the opening and closing of 31-5. The control device 32 shown in FIG.
The main configuration of the above is shown. In FIG. 2, 32-1 is a CPU,
32-2 is a ROM, 32-3 is a RAM, 32-4, 32
-5 is an input / output interface. CPU 32-1
Obtains various input information given through the interface 32-4, and performs various processing operations while accessing the RAM 32-3 according to the program stored in the ROM 32-2.

[Night-time heat storage operation: use of night-time electric power] In this area cooling / heating body heat storage system, night-time heat storage operation is
It is carried out as follows by using nighttime electric power, which makes the unit price of electric power cheap. When the control device 32 is in the time zone of nighttime electric power, as shown in FIG. 3, the dampers 31-1, 31-
2, 31-3 are fully closed, dampers 31-4, 31-5 are fully opened, and the air conditioner 29 is operated to store heat in the floor slab 22 and the area floor plate 21.

In this case, the cold / hot water coil 29 of the air conditioner 29
Air cooled or heated by -2 (cold hot air)
Is blown out from the air conditioner 29 by the rotation of the fan 29-1, is sent to the hollow portion 24 of the floor slab 22 through the fully opened damper 31-4 (passage L4), and communicates with the end portion of the floor slab 22. It is discharged from the mouth 25 into the underfloor space 23. Heat is stored in the floor slab 22 by supplying cold and warm air to the hollow portion 24.

The cold / hot air discharged to the underfloor space 23, that is, the cold / hot air used for storing heat in the floor slab 22, passes through the underfloor space 23 and is fully opened to the damper 31-5 (passage L).
5) and is returned to the air conditioner 29. At this time, heat is further stored in the floor slab 22 from the outside and also in the area floor plate 21.

When storing heat in the floor slab 22 and the area floor plate 21, the fan 29-1 of the air conditioner 29 reduces the amount of air blown. As a result, the fan power is reduced, the amount of cold and warm air to the hollow portion 24 is reduced, and the output temperature is low in summer and high in winter to improve efficiency. In this embodiment, a variable air flow type fan 29-1 is used, but two fans may be provided and only one fan may be operated.

[Night-time heat storage operation: outside air cooling heat storage + indoor pre-cooling] Outside air is low temperature at night in spring and autumn and at dawn in summer. This cold air is used to store heat in the floor and pre-cool the room.

[Daytime Heat Dissipation Operation: Air Conditioner Blower] During the season or time when the air conditioning load is small, air conditioning is performed only by dissipating the stored heat.
In this case, the control device 32 fully closes the dampers 31-2 and 31-5, fully opens the damper 31-1, and half-opens the dampers 31-3 and 31-4 as shown in FIG. 29
Only the fan 29-1 of the above is operated.

In this case, the return port 27 of the air-conditioned space 27
The exhaust air from -1 is the damper 31-1 which is fully opened.
It is sucked into the air conditioner 29 through the (passage L1). This air is supplied to the air conditioner 29 by operating only the fan 29-1.
The damper 31-3 (path L
3) to the underfloor space 23, and the perimeter area 2 of the air-conditioned space 27 from the communication port 26 at the terminal end of the area floor plate 21.
Issued on 8. At this time, the air sent to the underfloor space 23 transfers the heat stored in the floor slab 22 to the area floor plate 21. As a result, the area floor plate 21 is cooled or heated, and the area floor plate 21 is used as a radiant heat transfer surface for the air-conditioned space 2
7, the heat stored in the floor slab 22 is radiatively transferred,
The air-conditioned space 27 is radiantly cooled or radiantly heated.

Further, the air blown out from the air conditioner 29 by the operation of only the fan 29-1 is sent to the hollow portion 24 of the floor slab 22 through the damper 31-4 (passage L4) which is half opened, and the air is blown into the floor. The communication port 26 of the area floor plate 21 is discharged from the communication port 25 at the terminal end of the slab 22 into the underfloor space 23 and merges with the air after cooling or heating the area floor plate 21.
Then, it is discharged to the perimeter area 28 of the air-conditioned space 27. In this case, the air from the hollow portion 24 of the floor slab 22 is cooled or heated by the heat storage in the floor slab 22,
The air obtained by joining the air cooled or heated by this heat storage with the air after cooling or heating the area floor plate 21 is blown to the perimeter area 28. This air reduces the heat load on the perimeter area 28, and then the air-conditioned space 27
After convection inside, it is discharged from the return port 27-1. At this time, ventilation in the air-conditioned space 27 is also performed.

When the air conditioner 29 performs the heat radiation operation using the air blow, the controller 32 controls the fan 29-1 based on the surface temperature of the area floor plate 21 detected by the temperature sensor T3 and the room temperature detected by the temperature sensor T4. Control the amount of rotation. In addition, since the area floor plate 21 is cooled in the morning of summer or the like, the air conditioner 29 may not need to be blown.
Similarly, even in winter, there may be a case where only the radiant heat from the area floor plate 21 is sufficient.

[Daytime heat dissipation operation: air conditioner operation] Floor slab 2
After the heat radiation of 2 and the area floor plate 21 is completed, the air conditioner 29 is operated to perform air conditioning. In this case, the controller 32 determines the floor slab 22 based on the temperatures detected by the temperature sensors T1 and T2.
Then, the completion of heat radiation of the area floor plate 21 is determined. When it is determined that the heat radiation is completed, the control device 32 fully opens the damper 31-3 and fully closes the damper 31-4, as shown in FIG.
Further, the supply of cold / hot water to the cold / hot water coil 29-2 is started, and the air conditioner 29 is changed from the blowing operation up to that point to the cooling / heating operation.

As a result, the air blow to the hollow portion 24 of the floor slab 22 is stopped, and the entire amount of the air cooled or heated by the air conditioner 29 is sent to the underfloor space 23, and the heat from this air is generated in the area. Heat is transferred to the floor plate 21 and the area floor plate 2
1 is cooled or heated. As a result, the air conditioner 2 is set in the air-conditioned space 27 by using the area floor plate 21 as a radiant heat transfer surface.
The heat from 9 is radiatively transferred, and radiant cooling or radiant heating of the air-conditioned space 27 is continued.

The air after cooling or heating the area floor plate 21 is blown out to the perimeter area 28 of the air-conditioned space 27 from the communication port 26 at the terminal end of the area floor plate 21 to reduce the heat load of the perimeter area 28, and then the air conditioning. The convection in the space 27 is carried out, and it is discharged from the return port 27-1. At this time, ventilation in the air-conditioned space 27 is also performed.

During heat dissipation operation by operating this air conditioner,
The control device 32 controls the area floor plate 2 detected by the temperature sensor T3.
1 based on the surface temperature of No. 1 and the room temperature detected by the temperature sensor T4, the supply amount of cold / hot water to the air conditioner 29 and the fan 2
The rotation amount of 9-1 is controlled.

The controller 32 may operate the air conditioner 29 even before the heat radiation of the floor slab 22 and the area floor plate 21 is completed. That is, the air conditioner 29 with the heat stored in the floor slab 22 is used for the purpose of cutting the peak of electric power.
May drive. As a result, the supply of cold / hot water to the air conditioner 29 is stopped during the peak power cut time, and the system can be radiated only by blowing heat to reduce the power load. Further, the air conditioning load can be leveled by controlling the operation of the air conditioner 29 and the heat radiation from the floor slab 22 and the area floor plate 21.

[Second Embodiment: System with Outside Air Processing Function] FIG. 6 is a system configuration diagram showing an outline of another embodiment (second embodiment) of the area cooling / heating body heat storage system according to the present invention. In addition to the air conditioner (indoor air side air conditioner) 29, this system includes an outside air processing air conditioner 33 to which a fan 34 is attached. Cold / hot water is supplied to the outside air processing air conditioner 33 via an electric valve 35.
Further, the damper 31-6 is provided in the passage L6 connecting the outside air (OA) intake port and the fan 34, the underfloor space 23 and the fan 3 are provided.
And a damper 31-7 and 31-8 in a passage L7 connecting with
However, a damper 31-9 is provided in a passage L8 connecting the air outlet of the air conditioner 29 and the underfloor space 23. Also,
In addition to the temperature sensors T1 to T4, a temperature sensor T5 that detects the outside air temperature, and a temperature sensor T6 that detects the blowing temperature from the outside air processing air conditioner 33 are provided.

[Night-time heat storage operation: use of night-time power] When the time of night-time power is reached, the control device 32 fully closes the dampers 31-6 and 31-9, as shown in FIG.
After fully opening 7, 31-8, the fan 34 and the outside air processing air conditioner 29 are operated to operate the floor slab 22 and the area floor plate 21.
Store heat in.

In this case, the air (cool and hot air) cooled or heated by the outside air processing air conditioner 33 is blown out from the outside air processing air conditioner 33 by the rotation of the fan 34, and the passage L
It is sent to the hollow part 24 of the floor slab 22 through 9 and is discharged to the underfloor space 23 from the communication port 25 at the terminal end of the floor slab 22. Heat is stored in the floor slab 22 by supplying cold and warm air to the hollow portion 24.

The cold / hot air discharged to the underfloor space 23, that is, the cold / hot air used to store heat in the floor slab 22, passes through the underfloor space 23 and is fully opened to the dampers 31-8, 31-7.
It is returned to the outside air processing air conditioner 33 via the fan 34 through the (passage L7). At this time, heat is further stored in the floor slab 22 from the outside and also in the area floor plate 21.

[Daytime heat radiation operation: air conditioning blower + outside air treatment air conditioning blower] In the season or time when the air conditioning load is small, air conditioning is performed only by radiating the heat storage amount. In this case, the control device 32 is shown in FIG.
As shown in FIG. 3, the dampers 31-7 and 31-8 are fully closed, the dampers 31-6 and 31-9 are fully opened, and the fan 29-1 of the air conditioner 29 and the fan attached to the outside air processing air conditioner 33 are installed. Drive 34.

In this case, the return port 27 of the air-conditioned space 27
The air discharged from -1 is supplied to the air conditioner 29 through the passage L10.
Is sucked into. This air is blown out from the air conditioner 29 by the operation of only the fan 29-1, is sent to the underfloor space 23 through the fully opened damper 31-9 (passage L8), and is a communication port at the end of the area floor plate 21. Air-conditioned space 2 from 26
7 to the perimeter area 28. At this time, the air sent to the underfloor space 23 transfers the heat stored in the floor slab 22 to the area floor plate 21. As a result, the area floor plate 21 is cooled or heated, and the heat stored in the floor slab 22 is radiatively transferred to the air conditioning space 27 by using the area floor plate 21 as a radiation heat transfer surface, and the air conditioning space 27 is radiantly cooled or radiantly heated. It

The outside air taken in through the fully opened damper 31-6 is sent to the outside air processing air conditioner 33 through the fan 34. The outside air that has passed through the outside air processing air conditioner 33 passes through the passage L9 and the hollow portion 24 of the floor slab 22.
Is sent to the underfloor space 23 through the communication port 25 at the terminal end of the floor slab 22, merges with the air after cooling or heating the area floor plate 21, and the communication port 26 of the area floor plate 21 causes the air conditioning space 27 to flow. It is output to the perimeter area 28. In this case, the air from the hollow portion 24 of the floor slab 22 is cooled or heated by the heat stored in the floor slab 22, and the cooled or heated air and the air after cooling or heating the area floor plate 21 are separated. The merged air is blown out to the perimeter area 28. This air is in the perimeter area 28
After the heat load is reduced, the air is convected in the air-conditioned space 27 and is discharged from the return port 27-1. At this time, the air-conditioned space 2
Ventilation inside 7 is also performed.

The air conditioner 29 and the outside air processing air conditioner 33
At the time of heat radiation operation as air blowing, the control device 32 determines the fan 29- based on the surface temperature of the area floor plate 21 detected by the temperature sensor T3 and the indoor temperature detected by the temperature sensor T4.
Control the amount of rotation of 1 and 34.

[Daytime heat dissipation operation: air conditioner operation + outside air treatment air conditioner operation] After the heat radiation of the floor slab 22 and the area floor plate 21 is completed, the air conditioner 29 and the outside air treatment air conditioner 33 are operated to perform air conditioning. In this case, the control device 32 determines the completion of heat radiation of the air conditioner 29 based on the temperatures detected by the temperature sensors T2, T3 and T4. Outside air processing air conditioner 33
With respect to, the completion of heat radiation is determined based on the temperatures detected by the temperature sensors T1, T5 and T6. When it is determined that the heat radiation has been completed, the control device 32 controls the air conditioner 2 as shown in FIG.
9 and the outside air processing air conditioner 33 are changed from the air blowing operation until then to the heating and cooling operation.

As a result, the air cooled or heated by the air conditioner 29 is sent to the underfloor space 23, and the outside air cooled, dehumidified or heated by the outside air treatment air conditioner 33 is supplied to the hollow portion 24 of the floor slab 22. Will be sent. In the underfloor space 23, the heat from the air sent from the air conditioner 29 is transferred to the area floor plate 21 to cool or heat the area floor plate 21. As a result, heat is radiatively transferred to the air-conditioned space 27 by using the area floor plate 21 as a radiant heat transfer surface, and the air-conditioned space 2
Radiant cooling or radiant heating of 7 is continued.

Further, the air after cooling or heating the area floor plate 21 joins with the cooled / dehumidified or heated outside air from the outside air processing air conditioner 33 coming out from the hollow portion 24 of the floor slab 22, and the area floor plate After being blown out from the communication port 26 of 21 into the perimeter area 28 of the air-conditioned space 27 to reduce the heat load of the perimeter area 28, it is convected in the air-conditioned space 27 and discharged from the return port 27-1. At this time, ventilation in the air-conditioned space 27 is also performed.

The air conditioner 29 and the outside air processing air conditioner 33
At the time of heat dissipation operation by operating the control unit 32, the control device 32 determines the supply amount of cold / hot water to the air conditioner 29 based on the surface temperature of the area floor plate 21 detected by the temperature sensor T3 and the indoor temperature detected by the temperature sensor T4. The rotation amount of the fan 29-1 is controlled. Further, the terminal temperature of the hollow portion 24 of the floor slab 22 detected by the temperature sensor T1, the temperature blown out from the outside air conditioning unit 33 detected by the temperature sensor T6, and the temperature sensor T5.
The amount of cold / hot water supplied to the outside air processing air conditioner 33 and the amount of rotation of the fan 34 are controlled based on the outside air temperature detected by.

The controller 32 may operate the air conditioner 29 and the outside air processing air conditioner 33 even before the heat radiation of the floor slab 22 and the area floor plate 21 is completed. That is, for the purpose of cutting the peak of electric power, the air conditioner 29 and the outside air processing air conditioner 33 in a state where heat is stored in the floor slab 22.
May drive. As a result, the supply of cold / hot water to the air conditioner 29 and the outside air processing air conditioner 33 is stopped during the peak power cut time, and the system can be radiated only by blowing heat to reduce the power load. Also,
By controlling the operation of the air conditioner 29 and the outside air treatment air conditioner 33 and controlling the heat radiation from the floor slab 22 and the area floor plate 21,
It is also possible to level the air conditioner load.

[Embodiment 2A: System with outside air processing function] FIG. 16 is a system configuration diagram showing an outline of another embodiment (Embodiment 2A) of the area cooling / heating body heat storage system according to the present invention. This system is provided with an outside air processing air conditioner 33 in parallel in addition to an air conditioner (indoor air side air conditioner) 29. The outside air processing air conditioner 33 has a blower 33-1.
And a coil 33 to which cold / hot water is supplied via the motor-operated valve 35
2 are installed. A damper 31-2 is provided in a passage L2 connecting the intake of outside air (OA) and the outside air processing air conditioner 33, and the return passage L1 from the room is the air conditioner 2
9. Connected to the outside air processing air conditioner 33, dampers 31-6 and 31-7 are installed respectively. The air discharged from the outside air processing unit air conditioner 33 is merged with the air discharged from the air conditioner 29. In addition to the temperature sensors T1 to T4, a temperature sensor T5 that detects the outside air temperature and a temperature sensor T6 that detects the blowout temperature from the outside air processing air conditioner 33 are provided.

[Night heat storage operation: use of night power] Air conditioner 2
9. The outside air processing air conditioner 33 is operated in the same manner as in the first embodiment, although there is a difference in whether it is operated independently or in parallel according to the required heat storage amount.

[Daytime heat radiation operation] As in the first embodiment,
The air conditioner 29 is operated according to the form of the load and the operation mode, but the outside air processing air conditioner 33 processes only the outside air with the damper 31-7 fully closed, and the indoor relative humidity supplies cold water even during heat dissipation operation to supply humidity. To maintain. In this way,
Although the load is light during the rainy season, it is possible to operate in cool breeze when the humidity is high.

[Embodiment 3: System with outside air cooling function + outside air processing function] FIG. 10 is a system configuration diagram showing the outline of another embodiment (Embodiment 3) of the area cooling / heating body heat storage system according to the present invention. Is. In this system, the basic configuration is the same as that of the second embodiment shown in FIG. 6, but the exhaust ports 27-2 and 27 are provided on the ceiling of the air-conditioned space 27.
7-3 is provided, and the exhaust from the exhaust ports 27-2 and 27-3 is exhausted to the outside through the exhaust duct 36 using the exhaust fan 37.

[Night heat storage operation (use of night power) Part 1:
Floor slab heat storage] The control device 32 controls the dampers 31-6 and 31-9 as shown in FIG.
Fully closed and dampers 31-7 and 31-8 fully open,
The fan 34 and the outside air processing air conditioner 33 are operated to store heat in the floor slab 22 and the area floor plate 21.

In this case, the air (cool / hot air) cooled or heated by the outside air processing air conditioner 33 is blown out from the outside air processing air conditioner 33 by the rotation of the fan 34, and the passage L
It is sent to the hollow part 24 of the floor slab 22 through 9 and is discharged to the underfloor space 23 from the communication port 25 at the terminal end of the floor slab 22. Heat is stored in the floor slab 22 by supplying cold and warm air to the hollow portion 24.

The cold / hot air delivered to the underfloor space 23, that is, the cold / hot air used to store heat in the floor slab 22, passes through the underfloor space 23 and is fully opened to the dampers 31-8, 31-7.
It is returned to the outside air processing air conditioner 33 via the fan 34 through the (passage L7). At this time, heat is further stored in the floor slab 22 from the outside and also in the area floor plate 21.

[Night heat storage operation (use of night power) Part 2:
Floor slab heat storage + indoor pre-cooling / pre-heating] In the above-mentioned "night heat storage operation (use of night electric power) No. 1", the outside air processing air conditioner 33
The air that has been cooled and heated in (1) is circulated through the hollow portion 23 of the floor slab 22 and the underfloor space 23 as a flow passage. In contrast,
In the "nighttime heat storage operation (use of nighttime electric power) No. 2" to be described below, as shown in FIG. 11, the air that has been cooled and heated by the outside air processing air conditioner 33 is circulated using the air conditioning space 27 instead of the underfloor space 23 as a flow passage. . However, in this case, the passage L connecting the air suction port of the air conditioner 29 and the fan 34
11 is provided with a damper 31-7, and a passage L12 that connects the air intake port of the air conditioner 29 and the outside air (OA) intake port
A damper 31-8 is provided on the.

At the time of nighttime electric power, the control device 32, as shown in FIG. 11, has dampers 31-6, 31-8,
31-9 is fully closed, the damper 31-7 is fully opened, and the fan 34 and the outside air processing air conditioner 33 are operated to store heat in the floor slab 22.

In this case, the air (cool / hot air) cooled or heated by the outside air processing air conditioner 33 is blown out from the outside air processing air conditioner 33 by the rotation of the fan 34, and the passage L
It is sent to the hollow part 24 of the floor slab 22 through 9 and is discharged to the underfloor space 23 from the communication port 25 at the terminal end of the floor slab 22. Heat is stored in the floor slab 22 by supplying cold and warm air to the hollow portion 24.

The cold / hot air discharged to the underfloor space 23, that is, the cold / hot air used for storing heat in the floor slab 22, is blown to the perimeter area 28 of the air-conditioned space 27 from the communication port 26 at the terminal end of the area floor plate 21. The air is convected in the air-conditioned space 27, discharged from the return port 27-1, and returned to the outside air treatment air conditioner 33 through the fully opened damper 31-7 (passages L10 and L11). In this way, the air-conditioned space 27
The air that has been cooled and heated by the outside air treatment air conditioner 33 circulates as a flow passage, and in addition to the heat stored in the floor slab 22, the air-conditioned space 2
Pre-cooling or pre-heating in 7 is performed.

[Night heat storage operation (use of night power) Part 3:
Floor slab heat storage increase + indoor pre-cooling / pre-heating] In the above-mentioned "night heat storage operation (use of night electric power) 2", the outside air processing air conditioner 3
The air cooled and heated in 3 is circulated through the hollow portion 24 of the floor slab 22 and the air-conditioned space 27 as a flow passage. On the other hand, “Night heat storage operation (using night power)”
In the "3", as shown in FIG. 12, the air that has been cooled and heated by the air conditioner 29 is circulated through the underfloor space 23 and the air conditioning space 27 as a flow passage to increase the heat storage amount.

At night time, the control device 32 fully closes the dampers 31-6 and 31-8 and fully opens the dampers 31-7 and 31-9 as shown in FIG. 34 and outside air processing air conditioner 33 and air conditioner 29
Is operated to store heat in the floor slab 22 and the area area floor plate 21.

In this case, the air (cool / warm air) cooled or heated by the outside air processing air conditioner 33 is blown out by the rotation of the fan 34 and passes through the passage L9 to the floor slab 22.
Of the floor slab 22 and is discharged to the underfloor space 23 through the communication port 25 at the end of the floor slab 22. Heat is stored in the floor slab 22 by supplying cold and warm air to the hollow portion 24.

The air cooled or heated by the air conditioner 29 is supplied to the air conditioner 2 by the rotation of the fan 29-1.
It is blown out from the blower 9 and is sent to the underfloor space 23 through the fully opened damper 31-9 (passage L8). By supplying cold and warm air to the underfloor space 23, heat is stored from the outside in the floor slab 22 and also in the area floor plate 21, and the amount of heat storage is increased.

Cold and warm air passing through the hollow portion 24 and the underfloor space 2
The cold and hot air that has passed through 3 merges, and the communication port 2 of the area floor plate 21
6 is blown into the perimeter area 28 of the air-conditioned space 27, convection in the air-conditioned space 27, discharged from the return port 27-1, and passed through the passage L10 to the air-conditioner 29 to the fully opened damper 31-7 ( It is returned to the outside air processing air conditioner 33 through the passage L11). In this way, the air-conditioned space 27
The air chilled and heated by the outside air treatment air conditioner 33 and the air chilled and heated by the air conditioner 29 circulate as a flow passage, and the floor slab 2
In addition to the heat storage in the 2 and area area floorboards 21, precooling or preheating in the air-conditioned space 27 is performed.

[Night heat storage operation (use of night power) Part 4:
Outside air cooling floor slab heat storage + indoor pre-cooling] The outside air temperature is low at the dawn of spring, autumn, and summer. In "night heat storage operation (use of night power) No. 4" which will be described below, heat is stored in the floor slab 22 by using the low temperature outside air.

At the time of nighttime electric power, the control device 32, as shown in FIG. 13, has dampers 31-7, 31-8,
31-9 is fully closed, the damper 31-6 is fully open, and the fan 34 and the exhaust fan 37 are operated to operate the floor slab 22.
Store heat in.

In this case, the low temperature outside air (cold air) taken in by the operation of the fan 34 is blown out from the outside air processing air conditioner 33, is sent to the hollow portion 24 of the floor slab 22 through the passage L9, and the floor slab 22 is It is discharged to the underfloor space 23 from the communication port 25 at the terminal end. By supplying cold air to the hollow portion 24, heat is stored in the floor slab 22.

The cold air blown into the underfloor space 23 is blown out from the communication port 26 at the terminal end of the area floor plate 21 into the perimeter area 28 of the air-conditioned space 27, convections in the air-conditioned space 27,
It is discharged to the outside through the exhaust duct 36 via the exhaust ports 27-2 and 27-3 provided on the ceiling. In this way, low-temperature outside air circulates through the air-conditioned space 27 as a flow passage, and in addition to the heat stored in the floor slab 22, the air-conditioned space 27 is pre-cooled.

[Daytime heat dissipation operation: cooling operation during rainy season (air-conditioner blowing + outside air processing air-conditioner operation)] During the rainy season, dehumidification-based operation (cooling operation) is performed. In this cooling operation, as shown in FIG. 14, only the fan 29-1 of the air conditioner 29 is operated,
The outside air processing air conditioner 33 is cooled and dehumidified to create a radiant cooling and low humidity environment that is easy to spend.

The controller 32 fully closes the damper 31-6,
The dampers 31-7, 31-8, 31-9 are fully opened, and the fan 29-1 of the air conditioner 29, the outside air processing air conditioner 33, and the fan 34 are operated.

In this case, the return port 27 of the air-conditioned space 27
A part of the exhaust air from -1 is the damper 31 which is fully opened.
It is mixed with the outside air from −8 and sucked into the air conditioner 29. This air is blown out from the air conditioner 29 by the operation of only the fan 29-1, and the damper 31-9 is fully opened.
It is sent to the underfloor space 23 through (passage L8) and is discharged to the perimeter area 28 of the air-conditioned space 27 from the communication port 26 at the terminal end of the area floor plate 21. At this time, the air sent to the underfloor space 23 transfers the heat (cold heat) stored in the floor slab 22 to the area floor plate 21. As a result, the area floor plate 21
Is cooled, and the heat stored in the floor slab 22 is radiatively transferred to the air conditioning space 27 by using the area floor plate 21 as a radiant heat transfer surface, and the air conditioning space 27 is radiatively cooled.

In addition, the return port 27-1 of the air-conditioned space 27
The rest of the exhaust air from the damper 31-7 is fully opened.
It is sent to the outside air processing air conditioner 33 through (passage L11),
It is cooled and dehumidified. The air cooled and dehumidified by the outside air conditioning unit 33 passes through the passage L9 and the floor slab 22.
Sent to the hollow part 24 of the floor slab 22 and discharged to the underfloor space 23 through the communication port 25 at the terminal end of the floor slab 22, and merges with the air after cooling the area floor plate 21 and the air conditioning space from the communication port 26 of the area floor plate 21. It is blown out to the perimeter area 28 of 27. This air is low-humidity air, and after reducing the heat load on the perimeter area 28, it convects in the air-conditioned space 27 and is discharged from the return port 27-1 to the air conditioner 29 and the outside air processing air conditioner 33. Will be returned. At this time, ventilation in the air-conditioned space 27 is also performed.

In the above-described embodiment, the structure of the floor slab 22 is well known as described in the conventional example, and therefore the details thereof will be omitted. However, the wiring pipes are arranged in one direction. There are two-way hollow slabs and two-way hollow slabs in which winding pipes are arranged in two directions orthogonal to each other (in some cases, in multiple directions). When the span of the hollow slab is short, a plurality of hollow slabs are connected to each other to have an appropriate length for heat storage.

Regarding the heat dissipation of the heat accumulated in the floor slab 22, a heat dissipation fan is provided to forcibly circulate the heat dissipation from the inside of the floor slab 22 to the area floor plate 21 to enhance the radiation heat transfer air conditioning effect. You may do it. For example, as shown in FIG. 15, a passage L0 is provided between the passages L3 and L4,
A heat radiation fan 38 and a damper 31-0 may be provided in the passage L0 to forcibly radiate heat from the inside of the floor slab 22 to the area floor plate 21 to enhance the radiation air conditioning effect.

As can be seen from the above description, the area cooling / heating body heat storage system according to the present invention is a system combining the body heat storage system, the convection air conditioning system, and the radiant air conditioning system, and includes the body heat storage system and the convection air conditioning system. The following effects that cannot be obtained from the combined conventional air conditioning and heating skeleton system are obtained.

That is, in the conventional cooling / heating skeleton system combining the skeleton heat storage system and the convection air-conditioning system, the temperature in the air-conditioned space is increased because cold air or warm air is blown out from a large number of outlets provided on the floor. It was difficult to make the air flow distribution uniform, and residents often complained that it was too hot or too cold. In addition, there are problems such that air-conditioning air from the floor causes dust to wind up, and cold or warm air directly hits the skin.

On the other hand, in the area cooling / heating skeleton heat storage system of the present invention, as can be seen from the embodiment, the area floor plate 21 is not provided with a large number of outlets, and the area floor plate 21 is used as a radiation heat transfer surface. Floor slab 22 in air-conditioned space 27
The heat stored in the area floor plate 21 is radiatively transferred.
As a result, it is possible to make the temperature airflow distribution in the air-conditioned space uniform, and to create a comfortable thermal environment in which there are few complaints from residents that they are too hot or too cold. In addition, the room temperature can be raised in the summer and lowered in the winter, that is, the energy-saving set temperature (summer: 28
Even when the temperature is 0 ° C. and the winter season is 20), it is possible to keep the indoor thermal environment comfortable and reduce operating costs. Moreover, since air is blown out only from the communication port 26 at the terminal end of the area floor plate 21, problems such as dust being rolled up in the air-conditioned space 27 and direct contact with cold or warm air on the skin are greatly improved. It Further, since the circulating air blown into the air-conditioned room 27 still has residual heat, it maintains the indoor environment during warming up. Furthermore, since air conditioning is performed mainly by radiant heat, there is little noise.

Further, in the conventional cooling / heating skeleton system in which the skeleton heat storage system and the convection air-conditioning system are combined, equipment such as a fan coil is required to cover this heat load in the perimeter region where the heat load becomes large in winter and summer. There was a factor that increased the cost of the entire system. On the other hand, in the area cooling and heating skeleton heat storage system of the present invention, as can be seen from the embodiment, in the perimeter area 28 of the air-conditioned space 27, the air that contributes to the radiant heat transfer from the area floor plate 21 (about the same temperature as room temperature). Since air) is blown out to reduce the heat load, it is not necessary to provide air conditioning equipment such as a fan coil in the perimeter area 28, and the cost of the entire system can be reduced. Further, the system has good ventilation (good air quality), and the thermal environment of the air-conditioned space 27 is further improved.

Further, since this system is an open type system that blows out the air that has contributed to radiant heat transfer from the perimeter zone, there is a large load fluctuation when the air conditioning is started up, which is seen in a closed type or water cooled type radiant cooling system. It is possible to prevent dew condensation on the cooling surface (ceiling, wall surface, floor surface).

Needless to say, in the present invention, by adopting the body heat storage system, the effect peculiar to the body heat storage can be obtained. That is, since the body heat is stored, the power leveling effect and the air conditioning load leveling effect can be obtained, so that the rated capacity of the heat source facility and the air conditioning facility can be reduced. This makes it possible to reduce the contracted power and reduce the equipment cost. Further, by using the floor skeleton, which is a building structure, as the heat storage structure, the system can be installed in a small space and the wiring space can be secured under the floor, so that the floor space can be effectively utilized. Also, since the underfloor is used as a duct,
It requires less blast power and can reduce operating costs. Further, since the heat storage material is located near the air-conditioned space, the air conditioning equipment is simple, and since air is used as the medium, the system has excellent safety, equipment cost, and workability.

Although the AHU air conditioner is used as the air conditioner in the above-described embodiment, the PAC method may be used in a small-scale system. In addition, in order to make it easier to correspond to the zoning of air conditioning,
The convection air conditioning system may be subdivided and installed. Floor surface temperature of radiant air conditioning is heating 21 ℃, cooling 23 ℃
It is said that if the floor temperature is in the meantime, zero energy control without cooling or heating may be performed.

[0077]

As is apparent from the above description, according to the present invention, the convective heat transfer of the air sent to the perimeter area and the radiant heat transfer from the floor surface combine with the body heat storage to achieve the area heating and cooling ( Since convective heat transfer + radiant heat transfer) is performed, it is possible to create a comfortable thermal environment in the air-conditioned space where frequent complaints from residents do not occur. Further, it is possible to reduce the operating cost by reducing the energy consumption, and it is also possible to obtain an excellent effect that it is not necessary to provide air conditioning equipment such as a fan coil in the perimeter area.

[Brief description of drawings]

FIG. 1 is a system configuration diagram showing an outline of an embodiment (Embodiment 1) of an area cooling / heating body heat storage system according to the present invention.

FIG. 2 is a diagram showing a main configuration of a control device in this area cooling / heating skeleton heat storage system.

FIG. 3 is a diagram illustrating a heat storage operation at night in this area cooling / heating skeleton heat storage system.

FIG. 4 is a diagram illustrating a daytime heat radiation operation only by heat radiation of a heat storage amount in the area cooling / heating body heat storage system.

FIG. 5 is a diagram illustrating daytime heat radiation operation by operating an air conditioner in this area cooling / heating skeleton heat storage system.

FIG. 6 is a system configuration diagram showing an outline of another embodiment (Embodiment 2) of the area cooling / heating body heat storage system according to the present invention.

FIG. 7 is a diagram illustrating a heat storage operation at night in this area cooling / heating skeleton heat storage system.

FIG. 8 is a diagram for explaining a daytime heat radiation operation in the area cooling / heating skeleton heat storage system only by radiating the heat storage amount.

FIG. 9 is a diagram illustrating a daytime heat radiation operation by operating an air conditioner and an outside air processing air conditioner in this area cooling / heating skeleton heat storage system.

FIG. 10 is a diagram illustrating a nighttime heat storage operation (No. 1) in another embodiment (Embodiment 3) of the area heating and cooling body heat storage system according to the present invention.

FIG. 11 is a diagram illustrating a nighttime heat storage operation (No. 2) in the area cooling / heating skeleton heat storage system.

FIG. 12 is a diagram illustrating a nighttime heat storage operation (No. 3) in the area cooling / heating skeleton heat storage system.

FIG. 13 is a diagram illustrating a nighttime heat storage operation (No. 4) in the area cooling / heating skeleton heat storage system.

[Fig. 14] Cooling operation during the rainy season in this area cooling / heating skeleton heat storage system (air-conditioner blow + outside air processing air-conditioner operation)
It is a figure explaining.

FIG. 15 is a diagram showing an example in which a heat dissipation fan is provided to forcibly radiate heat from the inside of the floor slab to the area floorboard to enhance the radiation air conditioning effect.

FIG. 16 is a system configuration diagram showing an outline of another embodiment (Embodiment 2A) of the area heating / cooling structure heat storage system according to the present invention.

FIG. 17 is a diagram showing an overview of a conventional cooling / heating skeleton heat storage system.

FIG. 18 is a diagram illustrating the cooling operation in the summer in this cooling / heating skeleton heat storage system.

FIG. 19 is a diagram illustrating a heating operation in winter in the cooling / heating skeleton heat storage system.

[Explanation of symbols]

21 ... Floor surface (area floor board), 22 ... Floor skeleton (floor slab),
23 ... Underfloor space, 24 ... Hollow part, 25 ... Communication port (first communication port), 26 ... Communication port (second communication port), 27 ... Air-conditioned space, 28 ... Perimeter area, 29 ... Air conditioner, 29 -1
… Fan, 29-2… Cold / hot water coil, 30… Electric valve, 3
1-0 to 31-9 ... Damper, T1 to T6 ... Temperature sensor,
32 ... Control device, L0-L12 ... Passage, 33 ... Outside air processing air conditioner, 34 ... Fan, 35 ... Electric valve, 36 ... Exhaust duct, 37 ... Exhaust fan, 38 ... Radiating fan.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification symbol FI F24F 13/068 F24F 13/068 A F28D 20/00 F28D 20/00 A (72) Inventor Mitsuo Hikosaka Takada Shinjuku-ku, Tokyo Baba 1-31-8 Incorporated Sato Design Research Institute Co., Ltd. (72) Inventor Yoshiteru Seki 4-2-8 Kanda Surugadai, Chiyoda-ku, Tokyo Takasago Thermal Engineering Co., Ltd. (72) Inventor Kazumoto Kazumoto Osaka 1-12-19 Kitahorie, Nishi-ku Kurimoto Iron Works Co., Ltd. (72) Inventor Kazuyuki Kamimura 4-3-4 Shibaura, Minato-ku, Tokyo Sanmu Bill System Co., Ltd. (56) Reference Japanese Patent Laid-Open No. 11- 83088 (JP, A) JP-A-1-184348 (JP, A) JP-A-9-292139 (JP, A) JP-A-55-89639 (JP, A) JP-A-10-9614 (JP, A) Japanese Patent Laid-Open No. 10-311565 (JP, A) (58) Fields surveyed (Int.Cl. ⁷ , DB name) F24F 5/00 F24F 5/00 102 F24D 5/02 F24D 11/00 F24F 3/00 F24F 13/068 F28D 20/00

Claims (10)

(57) [Claims] 1. A skeleton body having a hollow portion provided below the floor surface of an air-conditioned space with a space interposed between the skeleton body and a first communication port for communicating the hollow portion of the skeleton body with the space below the floor surface. A second communication opening that is provided at a floor surface position facing the perimeter area of the air-conditioned space and that connects the air-conditioned space with a space under the floor surface; A heat storage means for supplying heat to the skeleton to store heat in the skeleton, and sending exhaust air from the air-conditioned space to the space below the floor surface to transfer the heat stored in the skeleton to the floor surface via this air. And a radiant convection heat transfer means for radiatively transferring heat from the floor surface to the air-conditioned space and sending out air contributing to the radiant heat transfer from the floor surface to the air-conditioned space through the second communication port. An area cooling / heating body heat storage system characterized by the above. 2. A skeleton body having a hollow portion provided below the floor surface of the air-conditioned space with a space interposed between the skeleton body, and a first communication port for communicating the hollow portion of the skeleton body with the space below the floor surface. A second communication opening which is provided at a floor surface position facing the perimeter area of the air-conditioned space and which connects the air-conditioned space with a space below the floor surface; Heat storage means for supplying cold and warm air to the space below the surface to store heat in the skeleton and the floor surface, sending exhaust air from the air-conditioned space to the space below the floor surface and the hollow portion, of the floor surface The heat stored in the skeleton is transferred to the floor surface via the air sent to the space below to radiatively transfer the heat from the floor surface to the air-conditioned space and contribute to the radiant heat transfer from the floor surface. The first heat obtained from the body that has accumulated heat through the air and the hollow portion. Region Air skeleton heat storage system characterized by comprising a radiant convective heat transfer means for the air coming out of the through hole via the second communication port sends to the conditioned space. 3. The area cooling / heating skeleton heat storage system according to claim 1 or 2, wherein the heat storage means generates the cold / hot air using an indoor air side air conditioner. 4. The area cooling / heating skeleton heat storage system according to claim 1, wherein the heat storage means generates the cold / hot air using an outside air processing air conditioner. 5. The heat storage means according to claim 2, wherein the hot and cold air to the hollow portion is generated using an outside air processing air conditioner,
An area cooling / heating skeleton heat storage system, characterized in that cold / hot air to the space under the floor is generated using an indoor air side air conditioner. 6. The air-conditioning space according to claim 1, further comprising an exhaust fan for discharging the air in the air-conditioned space to the outside through an exhaust duct, and an outside-air processing air conditioner for processing the taken-in outside air. The outside air taken in by operating only the fan of the processing air conditioner is sent to the hollow part, and sent to the hollow part and sent to the air-conditioned space through the first communication port and the second communication port. The area cooling and heating skeleton heat storage system, characterized in that the exhaust fan is driven to be discharged to the outside. 7. The air discharged from the air-conditioned space as claimed in claim 1, which is heated or cooled and sent to a space below the floor surface, and heat from the air is sent to the floor surface. The heat is transferred to the air-conditioned space from the floor surface and the air that contributes to the radiation heat transfer from the floor surface is transferred to the second
An area cooling / heating body heat storage system comprising: heating / cooling radiant convection means for sending out to the air-conditioned space through the communication port. 8. The method according to claim 1, wherein the heat storage by the heat storage means and the radiative heat transfer / convective heat transfer by the radiant convective heat transfer means are switched by opening / closing a damper provided at each position. Area cooling and heating body heat storage system characterized by the above. 9. The method according to claim 7, wherein the heat storage by the heat storage means, the radiative heat transfer / convective heat transfer by the radiant convective heat transfer means, and the heating / cooling / radiant heat transfer / convective heat transfer by the heating / cooling radiative convection means. The area cooling / heating body heat storage system is characterized in that switching is performed by opening / closing dampers provided at various places. 10. An air flow path is provided with a space below the floor surface and a hollow part of the skeleton in parallel to change the amount of air flowing through these flow paths to adjust the heat storage amount and the heat radiation amount. Area cooling and heating body heat storage system capable of