CN111649383A - Building indoor air temperature regulating system - Google Patents

Abstract

The invention relates to a building indoor air temperature regulating system, which comprises an air conditioner outdoor unit and an air conditioner indoor unit, wherein the air conditioner indoor unit and the air conditioner outdoor unit form an air conditioner refrigerating system and an air conditioner heating system; the energy converter is connected with the outdoor unit of the air conditioner to form a second loop, the heat exchange tube is connected with the energy converter to form a third loop, a second control valve is arranged between the heat exchange tube and the energy converter, and the energy converter further comprises an outdoor temperature sensor, an indoor temperature sensor, a temperature analysis module, a temperature regulation module and a controller; the temperature analysis module compares and analyzes the outdoor temperature and the indoor temperature and transmits an analysis result to the controller; when refrigeration is needed, the controller controls the air conditioner refrigeration system, the first control valve, the second control valve and the third control valve to realize the common refrigeration of the air conditioner and the heat exchange tube to the indoor air; when heating is needed, the controller controls the air conditioner heating system, the first control valve, the second control valve and the third control valve to realize the common heating of the air conditioner and the heat exchanger to the indoor air.

Description

Building indoor air temperature regulating system

Technical Field

The invention relates to the technical field of intelligent home furnishing, in particular to a building indoor air temperature adjusting system.

Background

The mode of room air temperature regulation has air conditioner, ground heating, radiator etc. according to the difference in season, can select the air conditioner to cool down in summer, also can carry out indoor heating through air conditioner, ground heating, radiator etc. in winter.

Scientific research shows that: the indoor temperature should be set according to the comfortable temperature of human body; the human body senses the ambient temperature as a relative temperature, not an absolute temperature. For example, the temperature of the air conditioner used in summer is at the best 26 degrees, the indoor and outdoor temperature difference is kept at 5-8 degrees, and the temperature is lowered by about 3-4 degrees, so that a human body feels cool. In the winter indoor environment, people feel comfortable if the indoor temperature is controlled between 18 and 20 degrees. Since the clothes worn by people are much in nature in winter, if the indoor temperature is higher than 20 °, people feel a little hot. If the temperature of the air conditioner is set to be higher than 26 degrees in winter, the heating temperature is too high in winter, so that the indoor air is abnormally dry, body fluid and body fluid of a human body are damaged, and people feel muddy and dry, eyes, mouth, nose, skin and other places feel dry. Because of different indoor and outdoor environments, the body regulation capability is disordered when the air conditioner is kept at relatively extreme temperature for a long time, so that the immune function is reduced over time, and various uncomfortable symptoms appear, which is called as air conditioning disease in medicine.

Taking air conditioner temperature regulation as an example, most of air conditioners adopt a remote controller to regulate the temperature manually, and because the indoor illumination intensity is different in one day, the outdoor temperature changes, the indoor temperature also changes, so that the requirements of people on the temperature at different times and different temperatures are different. And the indoor temperature adjustment is more inconvenient in winter. In general, after a person adjusts the indoor temperature once, the temperature is not adjusted again due to a slight change in temperature, and thus, the person is likely to cause diseases such as cold or hot wind in the changed temperature.

Disclosure of Invention

In view of the above, the present invention is directed to a building indoor air temperature adjusting system, so as to solve the problem that the indoor temperature cannot be adjusted at any time along with the change of the outdoor temperature in the prior art.

In order to achieve the purpose, the technical scheme adopted by the building indoor air temperature regulating system is as follows:

a building indoor air temperature conditioning system comprising:

an air conditioner outdoor unit: a first medium is arranged;

an air-conditioning indoor unit: the first loop is connected with the air conditioner outdoor unit to form a first loop for circulating a first medium, and a first control valve is arranged between the air conditioner outdoor unit and the air conditioner indoor unit;

the air conditioner indoor unit and the air conditioner outdoor unit form an air conditioner refrigerating system and an air conditioner heating system;

the transducer: the energy converter is provided with a second medium which exchanges energy with the first medium, and a third control valve is arranged between the air conditioner outdoor unit and the energy converter;

a heat exchange tube: the heat exchange tube is arranged below the bottom plate and connected with the transducer to form a third loop for circulating a second medium so as to adjust the temperature of the floor, and a second control valve is arranged between the heat exchange tube and the transducer;

an outdoor temperature sensor: detecting the outdoor temperature;

an indoor temperature sensor: detecting the indoor temperature;

a temperature analysis module: is in signal connection with an outdoor temperature sensor and an indoor temperature sensor;

a temperature adjusting module: the temperature adjusting module is connected with the air-conditioning refrigeration system, the air-conditioning heating system, the first control valve, the second control valve and the third control valve in a controlling way;

a controller: the temperature control module is respectively connected with the temperature adjusting module and the temperature analysis module in a control way;

the temperature analysis module compares and analyzes temperature values detected by the outdoor temperature sensor and the indoor temperature sensor and transmits an analysis result to the controller; when refrigeration is needed, the controller controls the air conditioner refrigeration system, the first control valve, the second control valve and the third control valve to realize the common refrigeration of the air conditioner and the heat exchange tube to the indoor air; when heating is needed, the controller controls the air conditioner heating system, the first control valve, the second control valve and the third control valve to realize the common heating of the air conditioner and the heat exchanger to the indoor air.

Has the advantages that: firstly, the indoor temperature sensor is arranged indoors, the outdoor temperature sensor is arranged outdoors, the indoor temperature and the outdoor temperature are detected respectively, then the indoor temperature and the outdoor temperature are transmitted to the temperature analysis module, the temperature analysis module transmits an analysis result to the controller, the controller controls the temperature regulation module, the indoor temperature is regulated and controlled in real time according to the difference value of the indoor temperature and the outdoor temperature, the indoor temperature can be regulated at any time along with the change of the outdoor temperature, and therefore the comfort degree of a human body is improved. Secondly, when refrigerating or heating, the air conditioner and the heat exchange tube can both realize the regulation to the room air, can select to adopt the air conditioner or the heat exchange tube or air conditioner and heat exchange tube simultaneously cool down or heat up according to the room temperature, conveniently realize rapid heating up and rapid cooling, and can select to open wherein arbitrary mode and maintain room temperature convenient to use after the temperature reaches the requirement. And thirdly, the air conditioner and the heat exchange pipe adopt a common cold source or heat source, so that the structure of the whole indoor air temperature regulating system is simpler to set.

Furthermore, the controller is also respectively in control connection with the timing module, the human body induction module and the wireless communication module, and the wireless communication module is in wireless communication connection with the mobile terminal; the human body induction module is used for monitoring the human body activity condition in the monitoring range of the human body induction module and transmitting the monitored information to the controller, the controller judges whether a person exists in the detection range of the human body induction module according to the data information detected by the human body induction module, the maximum continuous unmanned time threshold value is preset in the controller, if the controller obtains that the time range exceeding the maximum continuous unmanned time threshold value in the monitoring range of the human body induction module is still unmanned according to the information returned by the human body induction module, the controller controls the first control valve and the second control valve to enable the air conditioner and the heat exchange tube to enter a sleep standby mode or a low power consumption mode.

Has the advantages that: when no person is in the detection range of the human body induction module, the human body detection module feeds detected information back to the controller, and the controller controls the first control valve and the second control valve to enable the air conditioner and the heat exchange tube to enter a dormant standby mode, so that energy loss is reduced.

Further, the human body induction module is an infrared detector.

Has the advantages that: the structure is simple.

The heat exchange tube comprises a liquid inlet tube, a liquid outlet tube and shunt tubes which are arranged between the liquid inlet tube and the liquid outlet tube at intervals in parallel, and two ends of the liquid diversion tube are respectively communicated with the liquid inlet tube and the liquid outlet tube.

Has the advantages that: the second medium can conveniently enter the heat exchange tube and flows out of the heat exchange tube after heat dissipation or refrigeration is completed in the heat exchange tube.

The first medium is freon, and the second medium is water.

Has the advantages that: the first medium and the second medium are made cheaper on the premise of meeting the use requirement.

Further, the bottom of heat exchange tube is provided with the heated board, and the top of heat exchange tube is provided with the sponge board, and the heated board is provided with the first recess of placing the shunt tubes on the side plane towards the heat exchange tube, sets up the second recess of placing the shunt tubes on the side plane towards the heat exchange tube of sponge board, and first recess sets up with the second recess is relative.

Has the advantages that: firstly, the method comprises the following steps: the heat preservation plate is arranged below the heat exchange tube, so that heat or cold air can be prevented from being dissipated, and the heat preservation time or the refrigeration time of the heat exchange tube is prolonged; secondly, the sponge plate is arranged at the top of the heat exchange tube, so that the problem of floor condensation caused by temperature reduction of natural water in the refrigeration process of the system can be avoided; and thirdly, the first groove and the second groove are arranged oppositely, so that the shunt pipe can be conveniently fixed.

Furthermore, the cross section of the first groove is semicircular, and the cross section of the second groove is semicircular.

Has the advantages that: the first groove and the second groove are both semicircular, so that the installation of the shunt tubes and the processing and manufacturing of the first groove and the second groove are facilitated.

And a waterproof layer is tightly attached to the lower side surface of the heat insulation plate.

The beneficial effects are that: the leakage of the heat exchange pipe and the leakage of the second medium during the energy exchange of the heat exchange pipe are prevented.

And a water storage tank is arranged in the third loop and used for supplementing water in the third loop.

Has the advantages that: and the water in the third loop is prevented from being reduced due to evaporation, and the medium of the third loop is supplemented in time.

Drawings

FIG. 1 is a control schematic view of an indoor air temperature adjusting system of a building according to the present invention;

FIG. 2 is a schematic view showing the construction of an indoor air temperature adjusting system for a building according to the present invention;

fig. 3 is a schematic view showing an installation structure of a heat exchange pipe in the indoor air temperature conditioning system of the building of fig. 2.

Reference numerals: 1-an air conditioner outdoor unit; 2-an indoor unit of an air conditioner; 3-a first control valve; 4-a transducer; 5-a first transducing pipe; 6-a second transducing pipe; 7-a second control valve; 8-heat exchange tube; 9-a liquid inlet pipe; 10-shunt tubes; 11-a liquid outlet pipe; 12-a water storage tank; 13-floor; 14-a sponge plate; 15-a second groove; 16-a heat-insulating plate; 17-a first groove; 18-a waterproof layer; 19-third control valve.

Detailed Description

An embodiment of the present invention will be described in further detail with reference to the accompanying drawings and embodiments:

as shown in fig. 1 and 2, the building indoor air temperature adjusting system of the present invention includes an outdoor air conditioner and an indoor air conditioner 2, a first medium is disposed in the outdoor air conditioner 1, the indoor air conditioner 2 is connected to the outdoor air conditioner 1 to form a first loop for circulating the first medium, and a first control valve 3 is disposed between the outdoor air conditioner 1 and the indoor air conditioner 2. The indoor unit 2 and the outdoor unit 1 form an air-conditioning refrigeration system and an air-conditioning heating system, so that the indoor air is cooled by the air-conditioning refrigeration system when the indoor temperature is high, and the indoor air is heated by the air-conditioning heating system when the indoor temperature is low. In this embodiment, the first medium is freon.

Furthermore, the outdoor unit 1 is connected to the transducer 4, so that the transducer 4 and the outdoor unit 1 form a second loop of the first medium, and a third control valve 19 is disposed between the outdoor unit 1 and the transducer 4. Specifically, a first zigzag tube 5 and a second zigzag tube 6 are arranged in the transducer 4, and the first zigzag tube 5 and the second zigzag tube 6 realize heat exchange through contact, wherein a liquid inlet and a liquid outlet of the first zigzag tube 5 are both arranged on the left side of the transducer 4, and a liquid inlet and a liquid outlet of the second zigzag tube 6 are both arranged on the lower side of the transducer 4, in this embodiment, the first zigzag tube 5 of the transducer 4 is communicated with the air conditioner outdoor unit 1, and a first medium flows in the first zigzag tube 5, in this embodiment, the first medium is freon; flowing in the second tube 6 of the transducer 4 is a second medium, in this embodiment water. In the transducer 4, freon in the first transduction pipe 5 exchanges heat with water in the second transduction pipe 6.

A heat exchange pipe 8 is arranged below the bottom plate, the heat exchange pipe 8 is communicated with the second transduction pipe 6 in the transducer 4 to form a third loop of a second medium, so that energy is taken into the heat exchange pipe 8 through the second medium in the second transduction pipe 6 of the transducer 4, and the temperature of the floor 13 is regulated, and a second control valve 7 is arranged between the heat exchange pipe 8 and the transducer 4; in order to avoid that the water in the third circuit decreases over time, a water storage tank 12 is also provided in the third circuit for replenishing the water in the third circuit.

Specifically, as shown in fig. 2 and 3, the heat exchange tube 8 includes a liquid inlet tube 9, a liquid outlet tube 11 and a shunt tube 10 arranged in parallel and at an interval between the liquid inlet tube 9 and the liquid outlet tube 11, and two ends of the shunt tube 10 are respectively communicated with the liquid inlet tube 9 and the liquid outlet tube 11. The bottom of the heat exchange tube 8 is provided with a heat insulation plate 16, the top of the heat exchange tube 8 is provided with a sponge plate 14, a first groove 17 for placing the shunt tubes 10 is formed in the plane of one side, facing the heat exchange tube 8, of the heat insulation plate 16, a second groove 15 for placing the shunt tubes 10 is formed in one side, facing the heat exchange tube 8, of the sponge plate 14, the first groove 17 and the second groove 15 are arranged oppositely, the cross section of the first groove 17 is semicircular, and the cross section of the second groove 15 is semicircular. With such an arrangement, first: the heat insulation plate 16 is arranged below the heat exchange tube 8, so that heat or cold air can be prevented from being dissipated, and the heat insulation time or refrigeration time of the heat exchange tube 8 is prolonged; secondly, the sponge plate 14 is arranged at the top of the heat exchange tube 8, and the sponge plate 14 can absorb dew, so that the problem of dew condensation on the floor 13 caused by the temperature reduction of natural water in the refrigeration process of the system is solved; thirdly, the first groove 17 and the second groove 15 are arranged oppositely, so that the shunt pipe 10 can be fixed conveniently.

In order to prevent leakage of the heat exchanger tube 8 and leakage of the second medium during energy exchange of the heat exchanger tube 8, a waterproof layer 18 is provided on the lower side of the heat insulating plate 16.

In order to conveniently realize the real-time control of the temperature of the indoor air, the building indoor air temperature regulating system also comprises an outdoor temperature sensor and an indoor temperature sensor, wherein the outdoor temperature sensor is used for detecting the outdoor temperature, the indoor temperature sensor is used for detecting the indoor temperature, and the outdoor temperature sensor and the indoor temperature sensor are respectively in signal connection with the temperature analysis module so as to transmit the detected indoor and outdoor temperatures to the temperature analysis module, thereby carrying out comparative analysis on the indoor temperature and the outdoor temperature. The building indoor air temperature regulating system also comprises a controller and a temperature regulating module, wherein the temperature analyzing module is in signal connection with the controller so as to transmit an analysis result to the controller, and the controller controls the temperature regulating module to regulate the indoor temperature; specifically, the temperature adjusting module is in control connection with an air-conditioning refrigeration system, an air-conditioning heating system, the first control valve 3, the second control valve 7 and the third control valve 19.

The temperature analysis module compares and analyzes temperature values detected by an outdoor temperature sensor and an indoor temperature sensor, an analysis result is transmitted to the controller, when indoor air needs to be refrigerated, the controller controls the air-conditioning refrigeration system to work, the air-conditioning outdoor unit 1 is adjusted to a refrigeration mode, and the opening degrees of the first loop and the third loop are controlled through the first control valve 3, the second control valve 7 and the third control method, so that the refrigeration degrees of the air-conditioning indoor unit 2 and the heat exchange tube 8 are adjusted, of course, only the air-conditioning indoor unit 2 is refrigerated or only the heat exchange tube 8 is refrigerated or the air-conditioning indoor unit 2 and the heat exchange tube 8 are refrigerated simultaneously by controlling the first control valve 3 and the third control valve 19; when the indoor air needs to be heated, the controller controls the air conditioner heating system to work, so that the air conditioner outdoor unit 1 is adjusted to the heating mode, and the opening degrees of the first loop and the third loop are controlled through the first control valve 3 and the third control valve 19, so that the heating degrees of the air conditioner indoor unit 2 and the heat exchange pipe 8 are adjusted, of course, only the air conditioner indoor unit 2 is heated, only the heat exchange pipe 8 is heated, or the air conditioner indoor unit 2 and the heat exchange pipe 8 are heated simultaneously by controlling the first control valve 3 and the third control valve 19.

The building indoor air temperature regulating system also comprises a timing module, a human body induction module and a wireless communication control module (not shown in the figure), wherein the timing module, the human body induction module and the wireless communication module are respectively in control connection with the controller, and the wireless communication module is in wireless communication connection with the mobile terminal; the human body induction module is used for detecting the human body activity condition in the monitoring range of the human body induction module and transmitting the detected information to the controller, the controller judges whether a person exists in the detection range of the human body induction module according to the data information detected by the human body induction module, a maximum continuous unmanned time threshold value is preset in the controller, if the controller obtains that the time range exceeding the maximum continuous unmanned time threshold value in the detection range of the human body induction module is still unmanned according to the information returned by the human body induction module, the controller controls the first control valve 3 and the second control valve 7 to enable the air conditioner and the heat exchange tube 8 to enter a dormant standby mode or a low power consumption mode, and in the embodiment, the human body induction module is an infrared detector.

When the air conditioner indoor unit 2 is used for refrigerating, the air conditioner outdoor unit 1 generates a low-temperature high-pressure liquid first medium, when the first medium enters the air conditioner indoor unit 2, the space is increased, the pressure is reduced, the received low-temperature high-pressure liquid first medium absorbs external heat to be vaporized and becomes a gaseous first medium, and meanwhile, the temperature of surrounding air is reduced, so that the refrigerating effect is achieved; meanwhile, the low-temperature high-pressure liquid first medium generated by the outdoor unit 1 of the air conditioner enters the first energy conversion pipe 5 of the energy converter 4 and exchanges energy with the second medium in the second energy conversion pipe 6 of the energy converter 4, so that the low-temperature first medium becomes the high-temperature first medium, the high-temperature second medium becomes the low-temperature second medium, and the second medium enters the heat exchange pipe 8 again, thereby realizing the refrigeration effect of the heat exchange pipe 8.

When heating, the air conditioner outdoor unit 1 generates a high-temperature high-pressure first medium, when the first medium enters the air conditioner indoor unit 2, the high-temperature high-pressure first medium releases heat to the outside and is changed into a liquid first medium, and meanwhile, the temperature of surrounding air is increased, so that the heating effect is achieved; meanwhile, the high-temperature and high-pressure first medium generated by the outdoor unit 1 of the air conditioner enters the first energy conversion pipe 5 of the energy converter 4 and exchanges energy with the second medium in the second energy conversion pipe 6 of the energy converter 4, so that the high-temperature first medium becomes the low-temperature first medium, the low-temperature second medium becomes the high-temperature second medium, and the second medium enters the heat exchange pipe 8, thereby realizing the heating effect of the heat exchange pipe 8.

In the above embodiment, the controller is further connected to the timing module, the human body sensing module and the wireless communication module respectively, and the wireless communication module is connected to the mobile terminal in a wireless communication manner; in other embodiments, the timing module, the human body sensing module and the wireless communication module may not be provided.

In the above embodiment, the human body sensing module is an infrared detector; in other embodiments, the human body sensing module may also be a sound detector.

In the above embodiment, the heat exchange tube includes a liquid inlet tube, a liquid outlet tube and a shunt tube arranged in parallel and at intervals between the liquid inlet tube and the liquid outlet tube, and two ends of the liquid shunt tube are respectively communicated with the liquid inlet tube and the liquid outlet tube; in other embodiments, the heat exchange tube can also be a folded tube.

In the above embodiment, the first medium is freon, and the second medium is water; in other embodiments, the first medium may also be lithium bromide and the second medium may also be an antifreeze liquid.

In the embodiment, the bottom of the heat exchange tube is provided with the heat insulation plate, the top of the heat exchange tube is provided with the sponge plate, a first groove for placing the shunt tube is formed in the plane of one side, facing the heat exchange tube, of the heat insulation plate, a second groove for placing the shunt tube is formed in the plane of one side, facing the heat exchange tube, of the sponge plate, and the first groove and the second groove are arranged oppositely; in other embodiments, the bottom of the heat exchange tube is provided with the heat insulation plate, a first groove for placing the shunt tube is formed in the plane of one side, facing the heat exchange tube, of the heat insulation plate, and the floor is directly paved on the shunt tube.

In the above embodiment, the cross-sectional shape of the first groove is a semicircle, and the cross-sectional shape of the second groove is a semicircle; in other embodiments, the cross-sectional shape of the first groove may also be a major arc, the cross-sectional shape of the second groove may also be a minor arc, and the first groove and the second groove are circular after being paired together.

In the above embodiment, the lower side surface of the insulation board is tightly attached with a waterproof layer; in other embodiments, the water barrier may not be provided.

In the above embodiment, the third loop is provided with a water storage tank for supplementing water in the third loop; other implementations; in an example, the third circuit may not be provided with a water storage tank, and the third circuit should be replenished with water at intervals.

Claims (9)

1. A building indoor air temperature conditioning system, comprising:

an air conditioner outdoor unit: a first medium is arranged;

an air-conditioning indoor unit: the first loop is connected with the air conditioner outdoor unit to form a first loop for circulating a first medium, and a first control valve is arranged between the air conditioner outdoor unit and the air conditioner indoor unit;

the air conditioner indoor unit and the air conditioner outdoor unit form an air conditioner refrigerating system and an air conditioner heating system;

the transducer: the energy converter is provided with a second medium which exchanges energy with the first medium, and a third control valve is arranged between the air conditioner outdoor unit and the energy converter;

a heat exchange tube: the heat exchange tube is arranged below the bottom plate and connected with the transducer to form a third loop for circulating a second medium so as to adjust the temperature of the floor, and a second control valve is arranged between the heat exchange tube and the transducer;

an outdoor temperature sensor: detecting the outdoor temperature;

an indoor temperature sensor: detecting the indoor temperature;

a temperature analysis module: is in signal connection with an outdoor temperature sensor and an indoor temperature sensor;

a temperature adjusting module: the temperature adjusting module is connected with the air-conditioning refrigeration system, the air-conditioning heating system, the first control valve, the second control valve and the third control valve in a controlling way;

a controller: the temperature control module is respectively connected with the temperature adjusting module and the temperature analysis module in a control way;

the temperature analysis module compares and analyzes temperature values detected by the outdoor temperature sensor and the indoor temperature sensor and transmits an analysis result to the controller; when refrigeration is needed, the controller controls the air conditioner refrigeration system, the first control valve, the second control valve and the third control valve to realize the common refrigeration of the air conditioner and the heat exchange tube to the indoor air; when heating is needed, the controller controls the air conditioner heating system, the first control valve, the second control valve and the third control valve to realize the common heating of the air conditioner and the heat exchanger to the indoor air.

2. The system as claimed in claim 1, wherein the controller is further connected to the timing module, the human body sensing module and the wireless communication module, respectively, and the wireless communication module is connected to the mobile terminal in a wireless communication manner; the human body induction module is used for monitoring the human body activity condition in the monitoring range of the human body induction module and transmitting the monitored information to the controller, the controller judges whether a person exists in the detection range of the human body induction module according to the data information detected by the human body induction module, the maximum continuous unmanned time threshold value is preset in the controller, if the controller obtains that the time range exceeding the maximum continuous unmanned time threshold value in the monitoring range of the human body induction module is still unmanned according to the information returned by the human body induction module, the controller controls the first control valve and the second control valve to enable the air conditioner and the heat exchange tube to enter a sleep standby mode or a low power consumption mode.

3. The system as claimed in claim 2, wherein the human body sensing module is an infrared detector.

4. A building indoor air temperature adjusting system as claimed in claim 1, 2 or 3, wherein the heat exchanging pipe comprises a liquid inlet pipe, a liquid outlet pipe and a shunt pipe arranged in parallel and at an interval between the liquid inlet pipe and the liquid outlet pipe, and both ends of the shunt pipe are respectively communicated with the liquid inlet pipe and the liquid outlet pipe.

5. A building air conditioning system as claimed in claim 1, 2 or 3, wherein said first medium is freon and said second medium is water.

6. The indoor air temperature regulating system for the building as claimed in claim 5, wherein the heat exchange pipe is provided with a heat insulation plate at the bottom, a sponge plate at the top, a first groove for placing the shunt pipe is arranged on a plane of one side of the heat insulation plate facing the heat exchange pipe, a second groove for placing the shunt pipe is arranged on a plane of one side of the sponge plate facing the heat exchange pipe, and the first groove and the second groove are arranged oppositely.

7. The air conditioning system for indoor air of building as claimed in claim 6, wherein the first groove has a semicircular sectional shape and the second groove has a semicircular sectional shape.

8. The indoor air temperature adjusting system for buildings as claimed in claim 6, wherein the insulation board has a waterproof layer adhered to the lower side thereof.

9. A building air conditioning system as claimed in claim 5, wherein a water reservoir is provided in the third circuit for replenishing water in the third circuit.

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