JP5102579B2 - Air conditioning system - Google Patents

Description

  The present invention relates to an air conditioning system, and more particularly to an air conditioning system that improves heat storage efficiency and air conditioning efficiency to reduce energy consumption.

With the recent increase in awareness of global environmental conservation, reduction of energy consumption has become an increasingly important issue. As one of energy saving measures when cooling or heating a room, there is a housing heat storage air conditioning system. As an example of a frame thermal storage air conditioning system, during thermal storage at night, air-conditioning air sent from an air conditioner through an air supply duct is branched in the middle of the supply duct in the direction of the upper floor slab. To store heat by blowing to the upper floor slab from the heat storage outlet, and in the daytime the next day, the air-conditioning air supply destination is near the air-conditioning air outlet of the supply duct and the heat-storage spray duct Switched by a switching damper provided near the blowing port, conditioned air is supplied into the room from an air supply duct connected to an air-conditioned air outlet provided in the ceiling of the air-conditioned room, and supplied to the room Air conditioned air enters the ceiling chamber from the room through the return air opening provided in the ceiling, and heat exchange is performed with the upper floor slab stored at night while passing through the ceiling chamber. Low By (cooling operation) or elevated (during heating), there is one that enables the reduction of the processing load of the day of the air conditioner as compared with the time of non-heat storage (e.g., see Patent Document 1.).
JP 2003-279071 A (paragraph 0002, FIG. 5 etc.)

  However, since the above-mentioned enclosure heat storage air conditioning system stores air in the slab by blowing conditioned air onto the upper floor slab, the heat storage efficiency has to be lower than the heat storage in the slab using liquid such as cold water or hot water. . In addition, when performing indoor air conditioning, air conditioning air is supplied to the room from the air-conditioned air outlet provided in the ceiling in both cases of cooling and heating, resulting in low indoor heating efficiency during heating. It was.

  In view of the above problems, an object of the present invention is to provide a cooling / heating system that improves heat storage efficiency during heat storage, room cooling efficiency during room cooling, and room heating efficiency during room heating.

  In order to achieve the above object, an air conditioning system according to the first aspect of the present invention is a cold / hot liquid pipe 21 embedded in a concrete slab S, for example, as shown in FIG. LC) is flowed during cold storage, and the heated liquid L (LH) is flown during warm storage; the concrete slab S in which the cold liquid pipe 21 is embedded, and the cooling / heating target room R in which cooling and heating are performed A chamber 38 that is formed between the chamber 38 and is capable of circulating the air A on the section screen P with the air-conditioning target room R; and the temperature control device 11 that introduces the air A and regulates and derives the temperature of the introduced air A; The flow of the air A that introduces the air A in the air conditioning target room R into the temperature control device 11 and supplies the air A to the chamber 38, and the air A in the chamber 38 that is introduced into the temperature control device 11 Flow of air A supplied to chamber R Switching means 40 for switching between the air conditioning chamber R and the air conditioning chamber R to cool the air conditioning chamber 11 by introducing the air A in the chamber 38 into the temperature control device 11 and supplying the temperature A to the air conditioning chamber R. When the inside of the air-conditioning target room R is heated, the air A in the air-conditioning target room R is introduced into the temperature control device 11 and the temperature-adjusted air A is supplied to the chamber 38.

  When configured in this way, a cold / hot liquid pipe embedded in the concrete slab is provided with a cold / hot liquid pipe for flowing the cooled liquid during cold heat storage and flowing the heated liquid during the thermal heat storage. Efficiency can be improved. “Heat storage efficiency” is the ratio of the amount of heat stored in the concrete slab to the energy consumed. In addition, when the air in the air conditioning target room is cooled, the air in the chamber is introduced into the temperature control device to supply the air whose temperature is adjusted to the air conditioning target room, and when the air in the air conditioning target room is heated, Is introduced into the temperature control device and the temperature-adjusted air is supplied to the chamber, so that the air flow in the air-conditioning target room is from above to below during cooling and from below to above during heating. Therefore, both the cooling efficiency during cooling and the heating efficiency during heating can be improved.

  Moreover, the air conditioning system which concerns on the 2nd aspect of this invention is an air A to the chamber 38 at the time of a cold storage, in the air conditioning system 1 which concerns on the said 1st aspect of the said invention, for example as shown to Fig.2 (a). Is configured to be supplied.

  Conventionally, liquid housing heat storage that uses liquid to store heat in the housing has been used exclusively as a heat storage method during heating because the housing has often condensed when attempting to store the cold energy during cooling. However, when configured as in the cooling / heating system according to the second aspect of the present invention, an air flow can be created in the chamber at the time of cold heat storage, and an air chamber having a high dew point temperature with a positive pressure in the chamber. Intrusion into the interior can be prevented, and condensation of the concrete slab can be suppressed.

  Moreover, when the air conditioning system which concerns on the 3rd aspect of this invention is shown with reference to Fig.2 (a), for example, in the air conditioning system 1 which concerns on the said 2nd aspect of this invention, the temperature control apparatus 11 introduce | transduces The humidity of the air A is adjusted to be adjustable; the air A in the air conditioning target room R is introduced into the temperature control device 11 and the temperature A and the humidity A are adjusted to be supplied to the chamber 38 during the heat storage. Has been.

  With this configuration, air in the air conditioning target room is introduced into the temperature control device during cold heat storage, and the air whose temperature and humidity are adjusted is supplied to the chamber, so that the concrete slab can be more reliably prevented from condensing during cold heat storage. can do.

  Moreover, as the air conditioning system which concerns on the 4th aspect of this invention, as shown, for example in FIG. 1, in the air conditioning system 1 which concerns on the said 2nd aspect or the 3rd aspect of this invention, the air conditioning target room R and the chamber 38 are shown. A plurality of vents 39 provided on the section screen P for circulating the air A between the air conditioning target room R and the chamber 38 and having a blocking mechanism capable of blocking the flow of the air A. Provided: During cold heat storage, the total opening area of the plurality of vents 39 is adjusted by the shut-off mechanism, and the flow rate of the air A supplied to the chamber 38 is a minimum flow rate capable of preventing condensation in the chamber 38. You may be comprised so that it may become.

  If comprised in this way, the flow volume of the temperature-controlled air supplied to a chamber at the time of cold heat storage will decrease, and the energy consumption in a temperature control apparatus can be suppressed.

  Moreover, as the air conditioning system which concerns on the 5th aspect of this invention, as shown, for example in FIG. 1, in the air conditioning system 1 which concerns on any one aspect of the said 2nd aspect thru | or 4th aspect of this invention, The conditioning device 11 has an air flow rate variable mechanism 14 that can change the flow rate of the derived air A at any time; the flow rate of the air A supplied to the chamber 38 prevents condensation in the chamber 38 during cold heat storage. You may adjust the air flow variable mechanism 14 so that it may become the minimum possible flow volume.

  If comprised in this way, the amount of air supplied to a chamber at the time of cold heat storage will be adjusted appropriately, and conveyance power can be reduced.

  Moreover, as the air conditioning system which concerns on the 6th aspect of this invention, as shown, for example in FIG. 1, in the air conditioning system 1 which concerns on any one aspect of the said 2nd aspect thru | or the 5th aspect of this invention, switching The means 40 has a bypass mechanism for returning a part of the air A derived from the temperature control device 11 to the temperature control device 11 without supplying it to the chamber 38 and the air conditioning target room R; Part of the air A led out from the temperature control device 11 by adjusting the bypass mechanism so that the flow rate of the air A is a minimum flow rate that can prevent condensation in the chamber 38. You may return to the temperature control apparatus 11 without supplying.

  With this configuration, it is possible to suppress an increase in the temperature of the air that is returned to the temperature control device while operating the temperature control device at full load during cold heat storage, thereby increasing the operating efficiency of the temperature control device and suppressing energy consumption. be able to.

  According to the present invention, a cold / hot liquid pipe embedded in a concrete slab is provided with a cold / hot liquid pipe for flowing a cooled liquid during cold heat storage and for flowing the heated liquid during hot heat storage. Efficiency can be improved. In addition, when the air in the air conditioning target room is cooled, the air in the chamber is introduced into the temperature control device to supply the air whose temperature is adjusted to the air conditioning target room, and when the air in the air conditioning target room is heated, Is introduced into the temperature control device and the temperature-adjusted air is supplied to the chamber, so that the air flow in the air-conditioning target room is from above to below during cooling and from below to above during heating. Therefore, both the cooling efficiency during cooling and the heating efficiency during heating can be improved.

  Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the same or similar members are denoted by the same or similar reference numerals, and redundant description is omitted.

  First, referring to FIG. 1, an air conditioning system 1 according to an embodiment of the present invention will be described. FIG. 1 is a system diagram of an air conditioning system 1. The cooling / heating system 1 includes a cold / hot water buried pipe 21 serving as a cold / hot liquid pipe, an air conditioner 11 serving as a temperature control device, a heat source device 16 that generates cold or warm heat, a chamber 38, and a flow direction of air A for cooling / heating. Switching means 40 for switching between and the control device 2 for controlling the cooling and heating system 1.

  The cold / hot water buried pipe 21 is a pipe that is buried in a concrete slab S (hereinafter, simply referred to as “slab S”), and flows medium water L as a heat medium for cooling or heating the slab S. The medium water L is a generic name for the cold water LC when the slab S is cooled and the hot water LH when the slab S is heated. The cold water LC is medium water L that flows through the cold / hot water buried pipe 21 during the cooling season of the cooling / heating target room R (hereinafter simply referred to as “target room R”) and is cooler than the outside air during the cooling season. The hot water LH is medium water L that flows in the cold / hot water buried pipe 21 during the heating season of the target room R and is hotter than the outside air during the heating season. From the viewpoint of increasing the heat transfer area per unit area of the slab S, the cold / hot water buried pipe 21 is arranged to meander. Moreover, from the viewpoint of preventing water leakage in the slab S, the cold / hot water buried pipe 21 is preferably made of a material that has flexibility and can be meandered without using a joint. The cold / hot water buried pipe 21 is typically a cross-linked polyethylene pipe or a polybuden pipe.

  The air conditioner 11 is a device that can adjust the temperature of the air A, and a general-purpose air handling unit is typically used. The air conditioner 11 is configured so that the humidity of the air A can also be adjusted. The air conditioner 11 includes a coil 12 that cools or heats the introduced air A, a fan 13 that pumps the air A whose temperature is adjusted by the coil 12, and an air that adjusts the rotational speed of the fan 13 and adjusts the air flow rate. And an inverter 14 as a variable flow rate mechanism. The inverter 14 is actually disposed in a power panel (not shown) that transmits electric power to the fan 13, but is shown as a component of the air conditioner 11 in FIG. 1 for convenience of explanation. The air conditioner 11 includes a humidifier (not shown) and an eliminator (not shown).

  The heat source device 16 is a device that manufactures the cold water LC and the hot water LH supplied to the cold / hot water buried pipe 21 and the coil 12 of the air conditioner 11. The heat source device 16 is typically a general-purpose heat pump chiller, but may be a cold / hot water generator or the like. Moreover, it is good also as providing separately cold-heat-source equipment, such as a refrigerator which manufactures cold water LC, and hot-heat source machines, such as a boiler which manufactures hot water LH.

  The chamber 38 is formed as a space between the floor surface P of the target room R provided above the slab S and the slab S. The floor surface P is a section screen that partitions the target room R and the chamber 38. The floor surface P is typically composed of a free access floor, but may be composed of wood or the like.

  On the floor surface P, a plurality of shutters 39 as vent holes having a blocking mechanism are disposed. The shutter 39 is configured, for example, by stacking two flat plates each having a plurality of slits spaced apart from each other. By shifting the surfaces of the two flat plates from each other, the shutter 39 is opened when the slits of the two flat plates communicate with each other. One flat plate slit is closed when the other flat plate is closed. By opening the shutter 39, air A can be circulated on the floor surface P between the chamber 38 and the target room R. By closing the shutter 39, the chamber 38 and the target room R can be connected. The flow of air A on the floor surface P can be blocked. The shutter 39 is configured such that the opening area can be arbitrarily changed by shifting the two flat plates. The opening of the shutter 39 is typically configured to be adjusted by an actuator (not shown), but may be configured to be manually adjusted.

  One end of the cold / hot water buried pipe 21 is connected to the medium water outlet 16 a of the heat source machine 16 by the cold / hot water outgoing pipe 22, and the other end is connected to the medium water inlet 16 b of the heat source machine 16 by the cold / hot water return pipe 23. Yes. The cold / hot water outgoing pipe 22 is provided with a cold / hot water pump 25 for pumping the medium water L. The cold / hot water pump 25 is configured such that the rotation speed can be adjusted by an inverter (not shown) and the discharge amount of the medium water L can be changed. One end of a coil outgoing pipe 28 is connected to the cold / hot water outgoing pipe 22 downstream of the cold / hot water pump 25, and the other end of the coil outgoing pipe 28 is connected to the coil 12 of the air conditioner 11. One end of a coil return pipe 29 is connected to the cold / hot water return pipe 23, and the other end of the coil return pipe 29 is connected to the coil 12. Further, the cold / hot water return pipe 23 is provided with a cold / hot water return valve 23v, and the coil return pipe 29 is provided with a coil return valve 29v, respectively, for interrupting the flow of the medium water L or adjusting the flow rate of the medium water L. It is configured to be able to.

  The air introduction port 11 b of the air conditioner 11 is connected to an outside air duct 31 that conveys outside air, and a letter duct 32 that guides the air returned from the chamber 38 or the target room R to the air conditioner 11. A supply duct 33 is connected to the air outlet 11a of the air conditioner 11 so as to convey the temperature-controlled air A. Above the target chamber R, a chamber duct 34 that supplies air A to the target chamber R or receives air A in the target chamber R is connected. A chamber duct 35 is connected to the chamber 38 to supply air A to the chamber 38 or to receive air A in the chamber 38. The letter duct 32, the supply duct 33, the chamber duct 34, and the chamber duct 35 are connected to a switching mechanism 40 as switching means for switching the flow direction of the air A. The outside air duct 31 is provided with an outside air damper 49 that can block the circulation of outside air.

  The switching mechanism 40 includes a first duct 41 that connects the let duct 32 and the chamber duct 35, a second duct 42 that connects the chamber duct 35 and the supply duct 33, and a first duct that connects the supply duct 33 and the chamber duct 34. 3 ducts 43, and a fourth duct 44 that connects the chamber duct 34 and the letter duct 32. The first duct 41 is provided with a first damper 41d. Similarly, the second duct 42 is provided with a second damper 42d, the third duct 43 is provided with a third damper 43d, and the fourth duct 44 is provided with a second damper 42d. Four dampers 44d are respectively provided. Each of the dampers 41d to 44d is opened to allow the air A to flow through the first duct 41 to the fourth duct 44, and is closed to close the air A in the first duct 41 to the fourth duct 44. Each flow can be blocked.

  The control device 2 is connected to the air conditioner 11 through a signal cable, and is configured to be able to control the rotational speed of the fan 13 by adjusting the start / stop of the fan 13 or the inverter 14. Further, the control device 2 is connected to the heat source device 16 by a signal cable, and is configured to be able to control the temperature of the medium water L to be derived including which of the cold water LC and the hot water LH is to be produced. Yes. Moreover, the control apparatus 2 is connected with the cold / hot water pump 25 by the signal cable, and is comprised so that the flow volume of the medium water L by the start / stop and adjustment of a rotational speed can be controlled. The control device 2 is connected to the cold / hot water return valve 23v and the coil return valve 29v by signal cables, respectively, and is configured to be able to block the flow of the medium water L or adjust the flow rate of the medium water L. ing. The control device 2 is connected to each of a plurality of shutters 39 by signal cables, and is configured to be able to open and close each shutter 39 remotely. In addition, the control device 2 is connected to each of the dampers 41d to 44d, 49 via a signal cable, and is configured to be able to open and close each of the dampers 41d to 44d remotely.

Then, the effect | action of the air conditioning system 1 is demonstrated. In addition, suppose the code | symbol of the member which comprises the air conditioning system 1 mentioned in the following description shall refer FIG.
(Cooling season)
2A and 2B are diagrams showing the flow of the medium water L and the air A of the air conditioning system 1 during the cooling season, where FIG. It is. In FIG. 2, each valve 23v, 29v, each damper 41d to 44d, 49, and each shutter 39 (39E) white indicates “open”, and black paint indicates “closed”. First, with reference to Fig.2 (a), the effect | action of the air conditioning system 1 at the time of a thermal storage driving | operation (at the time of cold heat storage) is demonstrated. The heat storage operation is typically performed at night when the target room R is not cooled. When performing cold heat storage, the control device 2 closes the outside air damper 49, the first damper 41d and the third damper 43d, opens the second damper 42d and the fourth damper 44d, and connects the chamber duct 35 to the chamber 38. The farthest shutter 39 is opened, and the remaining shutters 39 are closed. Further, the valves 23v and 29v are opened. And the control apparatus 2 starts the heat source machine 16 and the cold / hot water pump 25. FIG.

  When the cold / hot water pump 25 is activated, the medium water L is led out from the heat source unit 16, flows in the cold / hot water outgoing pipe 22, the cold / hot water buried pipe 21, and the cold / hot water return pipe 23 in this order and flows into the heat source unit 16 again. . On the other hand, a part of the medium water L flowing through the cold / hot water outgoing pipe 22 is diverted and flows through the coil outgoing pipe 28, the coil 12, and the coil return pipe 29 in this order and flows into the cold / hot water return pipe 23. When the heat source device 16 is activated, the medium water L introduced into the heat source device 16 is cooled, and cold water LC having a temperature capable of storing cold heat in the slab S is manufactured. That is, the cold water LC flowing through the cold / hot water buried pipe 21 has a temperature at which cold energy can be stored in the slab S.

  When the cold water LC flows through the cold / hot water buried pipe 21, the cold heat of the cold water LC is transmitted to the slab S, and the slab S is cooled. Since the concrete constituting the slab S is a material having a relatively low thermal conductivity, the slab S takes time to cool the whole as compared to cooling a material having a high thermal conductivity such as a metal. Once cooled, it is difficult to release heat naturally. As the temperature of the slab S decreases as a result of cooling, the cold heat storage amount increases. On the other hand, when the slab S is cooled below the dew point temperature, dew condensation occurs on the surface of the slab S, which may cause deterioration of the casing and generation of mold. In order to avoid such inconvenience, it is preferable not to cause dew condensation on the slab S. (Conventionally, in order to avoid such inconvenience, cold housing heat storage using the medium water L has not been performed.) .

  In the air conditioning system 1 which concerns on this Embodiment, the air conditioner 11 is also started at the time of the cold heat storage to the slab S. When the air conditioner 11 is activated, the air A is led out from the air conditioner 11, flows through the supply duct 33, the second duct 42, and the chamber duct 35 and flows into the chamber 38. When the air A flows into the chamber 38, the air A existing in the chamber 38 passes through the open shutter 39E and flows into the target room R. For this reason, the flow of air A is generated in the chamber 38, and this flow of air A prevents the air from being cooled below the dew point temperature due to the stagnation of the air, and suppresses the occurrence of condensation on the surface of the slab S. Will be. Further, when air flows into the chamber 38, the inside of the chamber 38 becomes positive pressure, and air having a high dew point temperature can be prevented from entering the chamber 38, thereby preventing the occurrence of dew condensation on the surface of the slab S. The positive pressure in the chamber 38 is preferably set to a small positive pressure that prevents the air having a high dew point temperature from entering and prevents the water vapor partial pressure in the chamber 38 from increasing. The air A that has flowed into the target chamber R flows through the rear chamber duct 34, the fourth duct 44, and the return duct 32 and then flows into the air conditioner 11.

  The flow rate of the air A led out from the air conditioner 11 is controlled so as to be a minimum flow rate necessary to prevent condensation in the chamber 38. At this time, by reducing the opening area of the shutter 39E (area through which air A passes) as much as possible to increase the air density in the chamber 38, the supply amount of air A for preventing condensation in the chamber 38 is minimized. The conveyance power of the air A can be reduced. Moreover, it is preferable that the temperature and humidity of the air A led out from the air conditioner 11 are adjusted so that condensation does not occur in the chamber 38 while assisting cold heat storage in the slab S. In the present embodiment, since the cold water LC derived from the heat source device 16 is supplied to the cold / hot water buried pipe 21 and the coil 12, it is possible to minimize the flow rate of the air A supplied to the chamber 38. Thus, both the slab S cooled by the cold water CL and the air A derived from the air conditioner 11 have the same temperature, and the air A having the same temperature as the cooled slab S is supplied into the chamber 38. Thus, the occurrence of condensation in the chamber 38 can be effectively suppressed. If the temperature of the air A supplied to the chamber 38 is close to the temperature of the slab S when the cold energy is stored, the cold heat storage is not hindered. If the humidity is low, the water vapor partial pressure of the air A in contact with the slab S is low. It becomes small and the generation | occurrence | production of the dew condensation on the surface of slab S is suppressed. At this time, the smaller the flow rate of the air A derived from the air conditioner 11, the smaller the energy consumption when adjusting the temperature and humidity, which is more preferable. Thus, since the cooling / heating system 1 supplies the air A into the chamber 38 while flowing cold water LC through the slab S and storing cold energy in the housing (slab S), the cooling / heating system 1 efficiently cools and stores the heat in the chamber 38. It is possible to prevent the occurrence of condensation.

  Next, with reference to FIG.2 (b), the effect | action of the air conditioning system 1 at the time of the air_conditionaing | cooling operation of the target room R is demonstrated. The cooling operation is typically performed in the daytime. When performing the cooling operation, the control device 2 opens the outside air damper 49, the first damper 41d and the third damper 43d, closes the second damper 42d and the fourth damper 44d, and opens each shutter 39. Moreover, the control apparatus 2 closes the cold / hot water return valve 23v, and opens the coil return valve 29v. And the control apparatus 2 starts the heat source machine 16 and the cold / hot water pump 25. FIG. Then, the cold water LC is supplied to the coil 12 without being supplied to the cold / hot water buried pipe 21.

  The control device 2 also activates the air conditioner 11. When the air conditioner 11 is activated, air A that can cool the target room R (typically air A having a temperature lower by about 10 ° C. than the set temperature of the target room R) is led out from the air conditioner 11 and supplied to the supply duct 33. , Flows through the third duct 43 and the chamber duct 34 and is supplied to the upper portion of the target chamber R. When the cooled air A is supplied to the target room R, the air A that has already been used for cooling and has risen in temperature flows into the chamber 38 from each shutter 39 so as to be pushed out by the newly supplied air A. . The air A that has flowed into the chamber 38 flows through the chamber duct 35, the first duct 41, and the return duct 32 and then flows into the air conditioner 11 again. At this time, a part of the air A flowing through the return duct 32 is discharged to the outdoors via an exhaust duct (not shown). In addition to the air A guided from the chamber 38, outside air corresponding to the amount discharged outside is introduced into the air conditioner 11 through the outside air duct 31. In the air conditioner 11, the introduced letin air A and outside air are mixed, adjusted to a temperature and humidity suitable for cooling the target room R, and then supplied toward the target room R.

  When the air A flowing into the chamber 38 from the target room R flows in the chamber 38 toward the chamber duct 35, the air A receives the cold from the slab S cooled during the cold heat storage, and the temperature decreases (strictly speaking, The air A is cooled by moving the heat of the air A to the slab S. However, it is expressed that the heat A is received for the sake of convenience in view of the fact that what is useful here is the cold heat. Thereby, the temperature of the air A flowing into the chamber duct 35 is higher than the air supplied from the chamber duct 34 to the target room R and lower than the temperature flowing into the chamber 38 from the target room R. And the temperature of the air A which flows in into the air conditioner 11 via the return duct 32 becomes lower than the case where the slab S is not heat-accumulated. If the temperature of the air A flowing into the air conditioner 11 is lowered, less energy is required to adjust the temperature to be suitable for cooling the target room R. The air conditioning system 1 can reduce power consumption in the daytime and contribute to leveling of power usage, coupled with the fact that cold heat storage is generally performed at night when the amount of power consumption is low. Become. In addition, since the switching mechanism 40 is set in the cooling / heating system 1 so that the cooled air A having a high density flows from the upper side to the lower side of the target room R when the target room R is cooled, efficient cooling is performed. It can be carried out.

(Heating season)
Next, with reference to FIG. 3, the effect | action of the air conditioning system 1 at the time of a heating is demonstrated. 3A and 3B are diagrams illustrating the flow of the medium water L and the air A of the air conditioning system 1 during the heating season, where FIG. 3A is a flow diagram during a heat storage operation, and FIG. It is. Also in FIG. 3, each valve 23 v, 29 v, each damper 41 d to 44 d, 49, and each shutter 39 white indicates “open” and black indicates “close”. First, with reference to Fig.3 (a), the effect | action of the air conditioning system 1 at the time of a thermal storage driving | operation (at the time of thermal storage) is demonstrated. The heat storage operation is typically performed at night when the target room R is not heated. When performing heat storage, the control device 2 closes the dampers 41d to 44d and 49 and the shutters 39. Moreover, the control apparatus 2 opens the cold / hot water return valve 23v, and closes the coil return valve 29v. And the control apparatus 2 starts the heat source machine 16 and the cold / hot water pump 25. FIG.

  When the cold / hot water pump 25 is activated, the medium water L is led out from the heat source unit 16, flows in the cold / hot water outgoing pipe 22, the cold / hot water buried pipe 21, and the cold / hot water return pipe 23 in this order and flows into the heat source unit 16 again. . On the other hand, the medium water L is not supplied to the coil 12. When the heat source device 16 is activated, the medium water L introduced into the heat source device 16 is heated, and hot water LH having a temperature capable of storing hot heat in the slab S is manufactured. That is, the hot water LH flowing through the cold / hot water buried pipe 21 has a temperature at which the slab S can store hot heat. When the hot water LH flows through the cold / hot water buried pipe 21, the heat of the hot water LH is transmitted to the slab S, and the slab S is warmed. Thus, warm heat is stored in the slab S. At this time, since each shutter 39 is closed, there is no flow of air in the chamber 38 and heat dissipation from the slab S is suppressed.

  Next, with reference to FIG.3 (b), the effect | action of the air conditioning system 1 at the time of the heating operation of the object room R is demonstrated. Heating operation is typically performed during the day. When performing the heating operation, the control device 2 opens the outside air damper 49, the second damper 42d, and the fourth damper 44d, closes the first damper 41d and the third damper 43d, and opens each shutter 39. Moreover, the control apparatus 2 closes the cold / hot water return valve 23v, and opens the coil return valve 29v. And the control apparatus 2 starts the heat source machine 16 and the cold / hot water pump 25. FIG. Then, the hot water LH is supplied to the coil 12 without being supplied to the cold / hot water buried pipe 21.

  The control device 2 also activates the air conditioner 11. When the air conditioner 11 is activated, the heated air A is led out from the air conditioner 11, flows through the supply duct 33, the second duct 42, and the chamber duct 35 and flows into the chamber 38. The air A that has flowed into the chamber 38 receives the heat from the slab S heated during the heat storage, and the temperature rises. By receiving heat from the slab S before the air A is supplied to the target chamber R, the temperature of the air A derived from the air conditioner 11 can be made lower than the temperature of the air A when the air A is supplied to the target chamber R. The energy consumption in the air conditioner 11 can be reduced. The air conditioning system 1 is capable of reducing daytime power consumption and contributing to leveling of power usage, coupled with the fact that heat storage is performed at night when the amount of power consumption is generally low. Become.

  Air A that has further increased in temperature in the chamber 38 and has reached a temperature suitable for heating the target room R is supplied to the target room R from the opening of each shutter 39. When the air A whose temperature has been increased is supplied to the target room R, the room duct from the upper part of the target room R is used so that the air A whose temperature has already been reduced for heating is pushed out to the newly supplied air A. 34 flows in. The air A that has flowed into the chamber duct 34 flows through the fourth duct 44 and the return duct 32 and again flows into the air conditioner 11. At this time, a part of the air A flowing through the return duct 32 is discharged to the outdoors via an exhaust duct (not shown). In addition to the air A guided from the target room R, outside air corresponding to the amount discharged outside is introduced into the air conditioner 11 through the outside air duct 31. In the air conditioner 11, the introduced letin air A and the outside air are mixed and adjusted to a temperature suitable for heating the target room R (preferably the humidity is also adjusted in this case), and then supplied to the chamber 38. Is done. The heating / cooling system 1 can perform efficient heating because the switching mechanism 40 is set so that the heated air A having a low density flows from the lower side to the upper side of the target room R when the target room R is heated. it can.

  In the above description, the liquid flowing through the cold / hot water buried pipe 21 serving as the cold / hot liquid pipe during the heat storage operation is the medium water L (water that is the cold water LC and the hot water LH), but a liquid other than water (for example, an antifreeze liquid). It may be.

  In the above description, the air conditioner 11 is an air handling unit, but it may be another device capable of adjusting the temperature, such as a fan coil. In addition, although the air conditioner 11 can adjust the humidity of the air A, it may be a device that cannot adjust the humidity. However, it is preferable that the humidity can be adjusted because the water vapor partial pressure of the air A in the chamber 38 can be reliably reduced during cold heat storage, and condensation in the chamber 38 can be prevented.

  In the above description, the air A supplied to the chamber 38 at the time of cold heat storage is cooled by the air conditioner 11. However, if the condensation in the chamber 38 at the time of cold heat storage can be suppressed, the air is not cooled. A may be supplied. However, it is preferable that air A having a temperature close to the temperature of the cooled slab S is supplied into the chamber 38 from the viewpoint of reliably suppressing dew condensation in the chamber 38.

  In the above description, the third damper 43d is closed at the time of cold heat storage. However, by opening the third damper 43d at a predetermined opening and bypassing part of the air A supplied to the chamber 38 to the return duct 32. The supply amount of air A to the chamber 38 may be minimized. At this time, the “predetermined opening degree” is typically the remaining amount obtained by subtracting the minimum flow rate of air A supplied to the chamber 38 from the air A derived from the air conditioner 11 in order to prevent condensation in the chamber 38. It is an opening degree through which air A having a flow rate can pass. When the third damper 43d is opened at a predetermined opening and a part of the air A supplied to the chamber 38 is bypassed to the return duct 32, the temperature of the air A flowing into the air conditioner 11 from the return duct 32 is not bypassed. It becomes low, the load of the air conditioner 11 becomes still smaller, and the consumption of energy in the air conditioner 11 becomes smaller.

  In the above description, the cold water LC is not supplied to the cold / hot water buried pipe 21 during the cooling operation. However, the slab S may be cooled by supplying the cold water LC to the cold / hot water buried pipe 21 during the cooling operation. Although the hot water LH is not supplied to the cold / hot water buried pipe 21 during the heating operation, the hot water LH may be supplied to the cold / hot water buried pipe 21 during the heating operation to heat the slab S.

1 is a system diagram of an air conditioning system according to an embodiment of the present invention. It is a figure which shows the flow of the medium water and the air at the time of air conditioning of the air conditioning system which concerns on embodiment of this invention. (A) is a flowchart at the time of heat storage operation, (b) is a flowchart at the time of air_conditionaing | cooling operation of a target room. It is a figure which shows the flow of the medium water and the air at the time of the heating season of the air conditioning system which concerns on embodiment of this invention. (A) is a flowchart at the time of heat storage operation, (b) is a flowchart at the time of heating operation of a target room.

Explanation of symbols

1 Air conditioning system 11 Air conditioner (temperature control equipment)
14 Inverter (Air flow variable mechanism)
21 Cold / Hot Water Buried Pipe (Cold / Hot Liquid Pipe)
38 Chamber 39 Shutter (ventilated vent)
40 Switching means A Air P Floor (ward screen)
L Medium water (liquid)
LC Cold water LH Hot water R Air conditioning room S Concrete slab

Claims (4)

A cold / hot liquid pipe embedded in the concrete slab, wherein the cooled liquid is allowed to flow during cold storage, and the heated liquid is allowed to flow during thermal storage;
A chamber formed between the concrete slab in which the cold / hot liquid pipe is embedded and a cooling / heating target room in which cooling / heating is performed, and a chamber capable of air circulation on a section screen with the cooling / heating target room;
A temperature control device for introducing air and adjusting and deriving the temperature of the introduced air;
An air flow for introducing the air in the air conditioning target room into the temperature control device and supplying the air to the chamber, and an air in the chamber for introducing the air into the temperature control device and supplying the air to the air conditioning target room. Switching means for switching to air flow;
The air in the chamber is introduced into the temperature control device when the air in the air-conditioning target room is cooled, the air whose temperature is adjusted is supplied to the air-conditioning target room, and the air-conditioning is performed in the air-conditioning target room. An air in a target room is introduced into the temperature control device, and the temperature-adjusted air is supplied to the chamber ;
Configured to supply air to the chamber during the cold storage ;
A plurality of vents provided on the section screen for circulating air between the air-conditioning target room and the chamber and having a blocking mechanism capable of blocking the flow of air;
During the cold heat storage, the total opening area of the plurality of vents is adjusted by the shut-off mechanism so that the flow rate of air supplied to the chamber becomes a minimum flow rate that can prevent condensation in the chamber. Composed of;
Air conditioning system. A cold / hot liquid pipe embedded in the concrete slab, wherein the cooled liquid is allowed to flow during cold storage, and the heated liquid is allowed to flow during thermal storage;
A chamber formed between the concrete slab in which the cold / hot liquid pipe is embedded and a cooling / heating target room in which cooling / heating is performed, and a chamber capable of air circulation on a section screen with the cooling / heating target room;
A temperature control device for introducing air and adjusting and deriving the temperature of the introduced air;
An air flow for introducing the air in the air conditioning target room into the temperature control device and supplying the air to the chamber, and an air in the chamber for introducing the air into the temperature control device and supplying the air to the air conditioning target room. Switching means for switching to air flow;
The air in the chamber is introduced into the temperature control device when the air in the air-conditioning target room is cooled, the air whose temperature is adjusted is supplied to the air-conditioning target room, and the air-conditioning is performed in the air-conditioning target room. An air in a target room is introduced into the temperature control device, and the temperature-adjusted air is supplied to the chamber ;
Configured to supply air to the chamber during the cold storage ;
The temperature control device has a variable air flow rate mechanism capable of changing the flow rate of the derived air at any time;
Adjusting the air flow rate variable mechanism so that the flow rate of air supplied to the chamber becomes a minimum flow rate capable of preventing condensation in the chamber during the cold heat storage;
Air conditioning system. A cold / hot liquid pipe embedded in the concrete slab, wherein the cooled liquid is allowed to flow during cold storage, and the heated liquid is allowed to flow during thermal storage;
A chamber formed between the concrete slab in which the cold / hot liquid pipe is embedded and a cooling / heating target room in which cooling / heating is performed, and a chamber capable of air circulation on a section screen with the cooling / heating target room;
A temperature control device for introducing air and adjusting and deriving the temperature of the introduced air;
An air flow for introducing the air in the air conditioning target room into the temperature control device and supplying the air to the chamber, and an air in the chamber for introducing the air into the temperature control device and supplying the air to the air conditioning target room. Switching means for switching to air flow;
The air in the chamber is introduced into the temperature control device when the air in the air-conditioning target room is cooled, the air whose temperature is adjusted is supplied to the air-conditioning target room, and the air-conditioning is performed in the air-conditioning target room. An air in a target room is introduced into the temperature control device, and the temperature-adjusted air is supplied to the chamber ;
Configured to supply air to the chamber during the cold storage ;
The switching means has a bypass mechanism for returning a part of the air derived from the temperature control device to the temperature control device without supplying a part of the air to the chamber and the air conditioning target room;
Air derived from the temperature control device by adjusting the bypass mechanism so that the flow rate of air supplied to the chamber at the time of cold heat storage is the minimum flow rate that can prevent condensation in the chamber. Configured to return a portion of to the temperature control device without supplying to the chamber;
Air conditioning system. The temperature control device is configured to be able to adjust the humidity of the introduced air;
At the time of the cold heat storage, the air in the air conditioning target room is introduced into the temperature control device, and the air whose temperature and humidity are adjusted is supplied to the chamber;
The air conditioning system of any one of Claim 1 thru | or 3 .

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