JP2015004467A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the costs for reheating in an air conditioner that cools air taken therein for dehumidifying it and heats (re-heats) the cooled air for supplying it into an indoor space.SOLUTION: An air conditioner unit 16 takes in air from an indoor space and an outdoor space, cools the air taken therein by using a cooler 32, and heats the cooled air by using a heater 34. The heated air is sent to the indoor space. A fluid heated by heat collected by a solar heat collection device 14 is sent to the heater 34. The air to be sent to the indoor space is heated by heat of the fluid.

Description

  The present invention relates to an air conditioner, and more particularly, to an air conditioner including a cooler and a heater that heats air cooled by the cooler.

  There is known an air conditioner including a cooler and a heater. The cooler cools the air by exchanging heat between the low-temperature heat medium and the taken-in air, and also performs dehumidification. The temperature of the cooled air may be too low. In this case, the air is heated (reheated) by a heater. In the heater, heat is exchanged between the air once cooled and the high-temperature heat medium to heat the air. Thereby, the air of the appropriate temperature dehumidified can be supplied indoors.

  Paragraphs 0077 to 0086 of Patent Document 1 below describe that indoor air is dehumidified by a heat exchanger for dehumidification, heated by a heat exchanger for reheating, and then supplied indoors.

JP 2007-212085 A

  In an air conditioner equipped with a heater for reheating, a boiler for heating a medium supplied to the heater is necessary, and costs are increased for the equipment. In addition, the boiler needs fuel for heating, which increases the cost of the fuel.

  An object of the present invention is to enable reheating of air supplied to a room with a simple configuration or low cost.

  An air conditioner according to the present invention includes a cooler that cools captured air, a heater that heats the air cooled by the cooler, a fan that sends air heated by the heater into a room, and solar heat. A solar heat collector that heats and heats the fluid, and uses the fluid heated by the solar heat collector as a heat source of the heater.

  The solar heat collecting apparatus can include a heat collector that heats a fluid by receiving sunlight, and the fluid heated by the heat collector can be sent to the heater.

  Moreover, a solar-heat collector can have a heat collector which receives sunlight and heats a fluid, and a storage container which stores the heated fluid.

  In addition, the solar heat collector can include a heat collector that heats the heat storage body with sunlight, and the fluid can be heated with one or both of sunlight and heat of the heat storage body.

  In addition, the solar heat collecting apparatus can include a heat collector that heats a fluid by receiving sunlight and a heat storage body that stores heat by being heated by the heated fluid. The fluid can be heated by one or both.

  The fluid used as the heat source of the heater can be air. It can also be liquid.

  By using solar heat, there is no boiler or the like, and it becomes a simple facility. Moreover, the cost of fuel can also be suppressed.

It is a figure which shows an example of the air conditioning apparatus which concerns on this invention. It is a figure which shows an example of the air conditioning apparatus which concerns on this invention. It is a figure which shows an example of the air conditioning apparatus which concerns on this invention. It is a figure which shows an example of the air conditioning apparatus which concerns on this invention. It is a figure which shows an example of the air conditioning apparatus which concerns on this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating an example of an air conditioner using solar heat. The illustrated air conditioner 10 includes a cold heat source 12 that generates a low-temperature heat medium, a heat source 14 that generates a high-temperature heat medium, and heat between the low-temperature heat medium and the high-temperature heat medium and indoor or outdoor air. The air conditioning unit 16 to be replaced is included. Hereinafter, indoor air is referred to as inside air, and outdoor air is referred to as outside air. The cold heat source machine 12 may be a known device that generates a low-temperature heat medium by a refrigeration cycle. The heat source machine 14 is a solar heat collector that heats a fluid using solar heat. Hereinafter, the heat source machine will be described as a solar heat collector. The fluid heated by the solar heat collector 14 becomes a high-temperature heat medium.

  The air conditioning unit 16 includes an introduction duct 18 that takes in outside air and introduces it into the room, and a discharge duct 20 that takes in inside air and discharges it outside the room. The introduction duct 18 and the discharge duct 20 are provided with fans 22 and 24 for sending air, respectively. A communication opening 26 is provided between the introduction duct 18 and the discharge duct 20 to communicate these. The communication opening 26 is opened and closed by the first damper 28. The first damper 28 also has a function of closing the discharge duct 20 at a position outside the communication opening 26 on the outdoor side. The introduction duct 18 is provided with a second damper 30 for closing the introduction duct on the outdoor side from the communication opening 26. The first damper 28 is in a state in which the communication opening 26 is opened and the discharge duct 20 is closed (indicated by a one-dot chain line in the figure), and the second damper 30 is in a state in which the introduction duct 18 is closed (in the figure, one-dot chain line). ), The indoor air can be taken into the air conditioning unit 16 and sent out into the room again. In order to open / close the communication opening 26 and open / close the discharge duct 20, separate dampers may be provided instead of the first damper 28.

  A cooler 32 is disposed on the indoor side of the communication opening 26 in the introduction duct 18, and a heater 34 is disposed on the indoor side. The cooler 32 is supplied with a low-temperature heat medium from the cold heat source unit 12, exchanges heat with air passing through the cooler 32, and cools the air. When the air is cooled, water vapor in the air aggregates to perform dehumidification. On the other hand, the temperature of the cooled air may become too low, and if it is sent to the room as it is, the room temperature becomes too low. In order to prevent this, the air once cooled is heated by the heater 34. A high temperature heat medium is supplied to the heater 34 from the solar heat collector 14.

  The solar heat collecting apparatus 14 includes a heat collector 36 that receives light from the sun S and heats an internal fluid. The illustrated heat collector 36 takes in air from the lower part and heats the air with sunlight inside the heat collector 36. This air is used as a high-temperature heat medium. By opening the heat collector damper 38 and operating the heat collector fan 40, the air heated by the heat collector 36 is sent directly to the heater 34. The air flowing in the introduction duct 18 and passing through the heater 34 is heated (reheated) by the heater 34 and sent into the room.

  The high temperature heat medium may be a liquid such as water. In this case, the heat collector damper 38 is replaced with a valve, and the heat collector fan 40 is replaced with a pump. The liquid that has passed through the heater 34 may be discharged, but may be returned to the heat collector 36 and circulated.

  FIG. 2 is a diagram illustrating an example of an air conditioner using solar heat. The air conditioner 50 shown in the figure is different from the heat source machine 14 of the air conditioner 10 described above in the configuration of the heat source machine (solar heat collector) 52. The same components as those already described are denoted by the same reference numerals and description thereof is omitted. The solar heat collector 52 includes a storage container (chamber) 54 that stores the fluid heated by the heat collector 36. As the fluid, air can be used, and heated air is used as a high-temperature heat medium. The heat collector 36 can take in outside air, and air can be circulated between the heat collector 36 and the storage container 54. Whether air is taken in from outside air or circulated can be controlled by providing a damper in the air flow path. Between the heat collector 36 and the storage container 54, air may be naturally circulated by convection, or may be forcibly circulated using a fan or the like. The air heated by the heat collector 36 goes to the storage container 54, and that much air goes from the storage container 54 to the heat collector 36. By opening the heat collector damper 38 and operating the heat collector fan 40, the air heated by the heat collector 36 and stored in the storage container 54 is sent to the heater 34. The air flowing in the introduction duct 18 and passing through the heater 34 is heated (reheated) by the heater 34 and sent into the room. The amount of air sent from the storage container 54 to the heater 34 can be taken into the heat collector 36 from the outside air.

  When the capacity of the heat collector 36 cannot be increased, the heated air can be stored in the storage container 54 so that the heated air can be supplied even after the sunlight has decreased.

  In the air conditioner 50, as in the case of the air conditioner 10 described above, a liquid such as water can be used as the high-temperature heat medium. In this case, the heat collector damper 38 is replaced with a valve, the heat collector fan 40 is replaced with a pump, and the storage container is replaced with a tank. The liquid that has passed through the heater 34 may be discharged, but may be returned to the heat collector 36 or the storage container (tank) 54 and circulated.

  FIG. 3 is a diagram illustrating an example of an air conditioner using solar heat. The air conditioner 60 shown in the figure is different from the heat source machine 14 of the air conditioner 10 described above in the configuration of the heat source machine (solar heat collector) 62. The same components as those already described are denoted by the same reference numerals and description thereof is omitted. The solar heat collecting device 62 is disposed in the heat collector 64 and has a heat storage body 66 that is heated by receiving sunlight and stores heat. The heat storage body 66 is, for example, a brick-like solid. A plurality of the heat accumulators 66 may be arranged with a gap in order to increase the surface area. As the fluid, air can be used, and heated air is used as a high-temperature heat medium. The air in the heat collector 64 and the heat storage body 66 are heated by sunlight. The air is heated by sunlight before the heat storage body 66 is warmed, and is also heated by the heat storage body 66 after the heat storage body 66 is warmed. The air is heated by the heat accumulator 66 until the heat accumulator 66 cools even after the sunlight is reduced.

  By opening the heat collector damper 38 and operating the heat collector fan 40, the air heated by the heat collector 64 is sent to the heater 34. The air flowing in the introduction duct 18 and passing through the heater 34 is heated (reheated) by the heater 34 and sent into the room.

  When the air in the heat collector 64 decreases, outside air is taken in from the lower part of the heat collector 64 so as to compensate for it. The taken-in air is heated by one or both of sunlight and the heat storage body 66. Since heat is stored in the heat accumulator 66, the taken-in air can be heated even after sunlight is reduced.

  In the air conditioner 60, as in the case of the air conditioners 10 and 50 described above, a liquid such as water can be used as the high-temperature heat medium. In this case, the heat collector damper 38 is replaced with a valve, and the heat collector fan 40 is replaced with a pump. The liquid that has passed through the heater 34 may be discharged or returned to the heat collector 64 for circulation.

  FIG. 4 is a diagram illustrating an example of an air conditioner using solar heat. The air conditioner 70 shown in the figure is different from the heat source machine 14 of the air conditioner 10 described above in the configuration of the heat source machine (solar heat collector) 72. The same components as those already described are denoted by the same reference numerals and description thereof is omitted. The solar heat collector 72 includes a storage container (chamber) 74 that stores the fluid heated by the heat collector 36. A heat storage body 76 that stores heat is disposed in the storage container 74. The heat storage body 76 is, for example, a brick-like solid. A plurality of the heat accumulators 76 may be arranged with a gap in order to increase the surface area. As the fluid, air can be used, and heated air is used as a high-temperature heat medium. The heat collector 36 can take in outside air, and air can be circulated between the heat collector 36 and the storage container 74. Whether air is taken in from outside air or circulated can be controlled by providing a damper in the air flow path. Between the heat collector 36 and the storage container 74, air may be circulated naturally by convection or forcibly circulated using a fan or the like. The air heated by the heat collector 36 is directed to the storage container 74, and the corresponding air is directed from the storage container 74 to the heat collector 36. The heat storage body 76 is heated by the air sent from the heat collector 36 and stores heat. The air is heated by sunlight before the heat accumulator 76 is warmed, and is also heated by the heat accumulator 76 after the heat accumulator 76 is warmed. The air is heated by the heat accumulator 76 until the heat accumulator 76 cools even after the sunlight has decreased.

  By opening the heat collector damper 38 and operating the heat collector fan 40, the air heated by the heat collector 36 and stored in the storage container 74 is sent to the heater 34. The air flowing in the introduction duct 18 and passing through the heater 34 is heated (reheated) by the heater 34 and sent into the room. The amount of air sent from the storage container 74 to the heater 34 can be taken into the heat collector 36 from the outside air.

  The air that has passed through the heater 34 can be returned to the storage container 74. By circulating air between the heater 34 and the storage container 74, the air can be heated by the heat stored in the heat storage body 76. Thereby, even after the amount of sunlight is reduced, high-temperature air can be sent to the heater 34.

  In the air conditioner 70, as in the case of the air conditioners 10, 50, 60 described above, a liquid such as water can be used as the high-temperature heat medium. In this case, the heat collector damper 38 is replaced with a valve, the heat collector fan 40 is replaced with a pump, and the storage container is replaced with a tank. The liquid that has passed through the heater 34 may be discharged, but may be returned to the storage container (tank) 74 and circulated.

  FIG. 5 is a diagram illustrating an example of an air conditioner using solar heat. The air conditioner 80 shown in the figure is different from the heat source machine 14 of the air conditioner 10 described above in the configuration of the heat source machine (solar heat collector) 82. About the above-mentioned component, the same code | symbol is attached | subjected and description is abbreviate | omitted. The solar heat collector 82 has a heat collector 36 that receives sunlight and heats the air. The heat collector 36 heats the air taken in from the lower part with sunlight and sends it out. A fan can be provided to pump air from the collector 36. The air sent out from the heat collector 36 is sent to the heat collector heat exchanger 84. A liquid such as water is also sent from the storage container (tank) 86 to the heat collector heat exchanger 84, heat exchange is performed between this liquid and the above-mentioned air, and the liquid is heated. The air after the heat exchange is discharged, and the liquid returns to the storage container 86. Thereby, solar heat is stored in the liquid in the storage container 86. A pump can be provided to circulate the liquid between the reservoir 86 and the heat collector heat exchanger 84.

  The high-temperature liquid stored in the storage container 86 circulates between the heater 34. By opening the heat collector valve 88 and operating the heat collector pump 90, the liquid stored in the storage container 86 is sent to the heater 34. The air flowing in the introduction duct 18 and passing through the heater 34 is heated (reheated) by the heater 34 and sent into the room. The liquid that has passed through the heater 34 returns to the storage container 86 through the piping. Since the heated liquid can be stored in the storage container 86, the high-temperature liquid can be sent to the heater 34 even after the sunlight is reduced.

  As described above, the solar heat collecting apparatus 82 includes a heat collector that receives sunlight and heats the air, a heat exchanger that performs heat exchange between the heated air and the liquid, and the heat exchanger. And a high-temperature fluid stored in the storage container is sent to the heater.

  In the above embodiment, the high-temperature heat medium is generated using sunlight, but the medium sent to the heater may be heated using the exhaust heat of other devices. As an example of another apparatus, the cold heat source machine 12 of the air conditioning apparatus of each embodiment is mentioned. Moreover, the exhaust heat of the air conditioning apparatus installed independently of the air conditioning apparatus of each embodiment can also be utilized.

  10, 50, 60, 70, 80 Air conditioner, 12 Cooling heat source machine, 14, 52, 62, 72, 82 Heat source machine (solar heat collector), 16 Air conditioning unit, 18 Introduction duct, 32 Cooler, 34 heater, 36, 64 heat collector, 54, 74, 86 storage container, 66, 76 heat storage.

Claims (7)

A cooler for cooling the air taken in;
A heater for heating the air cooled by the cooler;
A fan that sends air heated by a heater into the room;
A solar heat collector that collects solar heat and heats the fluid;
Have
An air conditioner that uses a fluid heated by a solar heat collector as a heat source of a heater.   The air conditioner according to claim 1, wherein the solar heat collector has a heat collector that heats fluid by receiving sunlight, and the fluid heated by the heat collector is sent to the heater. Air conditioner.   It is an air conditioning apparatus of Claim 1, Comprising: A solar thermal collector is an air conditioning apparatus which has the heat collector which receives sunlight and heats a fluid, and the storage container which stores the heated fluid.   It is an air conditioning apparatus of Claim 1, Comprising: A solar-heat collector has a heat collector which heats a thermal storage body with sunlight, and heats fluid by one or both of sunlight and the heat of a thermal storage body , Air conditioner.   2. The air conditioner according to claim 1, wherein the solar heat collector has a heat collector that heats a fluid by receiving sunlight and a heat storage body that is heated by the heated fluid and stores heat. An air conditioner that heats a fluid by one or both of sunlight and heat of a heat storage body.   The air conditioner according to any one of claims 1 to 5, wherein the fluid is air.   The air conditioner according to any one of claims 1 to 5, wherein the fluid is a liquid.

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