KR100975201B1 - Integration heating, cooling and ventilation system in energy saving house - Google Patents

Abstract

PURPOSE: Heating, cooling and ventilation system and method of an energy saving house using ground heat is provided to prevent overcooling by performing cooling operation by the cold water sent to a radiation panel. CONSTITUTION: A cooling and heating system of an energy saving house comprise a radiation heating/cooling system(10), a ventilation-convection system(20), and a ground heat exchange system(30). The radiation heating/cooling system performs cooling or heating operation by the floor radiation. The radiation heating/cooling system comprise a radiation panel(12) and a first water storage tank(13). The first water storage tank store a first circulated water which circulated a pipe(11). The ventilation-convection system performs ventilation operation using external air and performs cooling or heating operation by convection. The ventilation-convection system comprises an indoor ventilation pipe(21), a discharge pipe(22), an underground duct(23), a heat transfer/exchange/ ventilation device(24), and a second water storage tank(25). While passing through the underground duct, the sucked external air is first pre-cooled or pre-heated. The ground heat exchange system performs heat exchange on the first circulated water used for the radiation heating/cooling system and the second circulated water used for the ventilation-convection system by the ground heat. The ground heat exchange system comprises a ground-heat heat exchanger(31) and a heat pump(32). The heat pump cools or heats the first circulated water and the second circulated water.

Description

Integral Heating, Cooling and Ventilation System in energy saving house

The present invention relates to a cooling and heating system and an air-conditioning method applied to a super-energy saving house. More specifically, in an ultra-energy saving house having an energy consumption of 3 liters or less on kerosene basis, for example, heat exchange is performed by a geothermal heat exchanger. By creating the optimal temperature and humidity environment by using the circulated water and ventilation in parallel, the air-conditioning and ventilation system for the geothermal utilization ventilation of the ultra-energy-saving house of the new structure that can save the energy required for heating and cooling the house and ventilation and It relates to a heating and cooling method.

Innovative thermal insulation structure, that is, ultra-heat-saving house with less than 0.15W / m2K heat permeability of the outer wall and air-tightness 1.5 times / hr (50Pa) or less, and consumes less than 3 liters per year on kerosene. Is developed. An ultra-energy-saving house means a house with a building energy efficiency rating of 1st or higher as defined in Article 21 of the current Energy Use Rationalization Act, which has an energy saving rate of 33.5% or more compared to a standard house. These ultra-energy-saving houses have a breakthrough insulation structure, which is characterized by a lower level of energy consumption than existing houses.

In the Korean housing structure, floor radiant heating (for example, underfloor heating) is generally used. In the case of the ultra-energy-saving house defined above, the conventional floor radiant heating is generally required because the load required for cooling or heating is low. Is applied to the super-energy-saving house, it is not suitable to apply to the super-energy-saving house as defined above because the problem of overcooling occurs in the summer and the problem of overheating in the winter. There is no proposed floor radiant heating and cooling system suitable for small, ultra-energy saving homes.

The present invention was developed to meet the problems and needs of the prior art as described above, as a system for radiant heating and heating of the above-described super-energy-saving house, to create an optimal heating environment and humidity environment and innovatively save energy An object of the present invention is to provide a floor radiant heating and cooling system and a cooling and heating method.

In the present invention, in order to achieve the above object, as a system for heating and cooling the floor radiation of the ultra-energy-saving house, in the winter when the outside temperature is 0 ℃ or less in the winter by heating the water in the floor panel 35 ~ 40 ℃, in the summer The radiant floor is cooled by circulating water at about 20 ℃, and the outside air (“outside air”) is supplied through the underground duct, but is supplied to the room by supplying the humidified air to the room by dehumidifying it by using a cooling coil. A floor radiant heating and cooling system and a heating / cooling method for geothermal utilization ventilation of ultra-energy-saving houses that prevent condensation and maintain a comfortable temperature throughout the year are provided.

Specifically, in order to achieve the above object, in the present invention, a radiant air-conditioning system that uses radiant heat for geothermal energy-saving houses and performs air conditioning and heating by ventilation and convection. A cooling and heating system, a ventilation-convection system that ventilates the room using outside air, and cools or heats it by convection, a first circulation water used for the radiative air conditioning system, and a second circulation water used for the ventilation-convection system. Geothermal heat exchange system for heat exchange by geothermal heat; The radiant air-conditioning system includes a radiant panel installed indoors and having a pipe embedded therein, the first circulation water being supplied to the pipe to cool or heat by radiation, and supplying the first circulation water to the pipe and circulating the pipe. A first water storage tank in which one first circulating water is stored; The ventilation-convection system includes an indoor ventilation pipe installed in the room and introducing outdoor air into the room, a discharge pipe discharging the indoor air to the outside, and a first preheating or primary precooling while the outdoor air sucked in the ground is passed through. A heat exchange ventilation device for controlling the moisture and temperature of the outside air introduced from the underground duct and sending it to the indoor ventilation pipe by means of the underground duct, the discharge air discharged through the discharge pipe from the room, and the second circulating water; A second water storage tank for supplying a second circulation water to the exchange ventilator and for recovering the circulated second circulation water; The geothermal heat exchange system includes a geothermal heat exchanger configured to circulate first and second circulation water stored in the first water storage tank and the second water storage tank to perform heat exchange by geothermal heat, and the first circulation water and the first water storage tank. Two heat pumps for heating or cooling the circulating water; Cooling or heating the room is performed by radiation of the radiation panel by circulating the pipe with a first circulation water; Outside air enters the room through the indoor ventilation pipe and is discharged to the outside through the discharge pipe, whereby indoor ventilation is performed, while outdoor air passes through the electrothermal exchange ventilation device through the underground duct, humidity and temperature of the outside air are controlled and introduced into the room. Thereby, the cooling and heating system of the ultra-energy saving house, characterized in that the cooling or heating by convection is further provided.

In the system of the present invention as described above, the pre-heat exchange ventilator, the second circulating water flows and may be provided with a circulating water coil for pre-cooling or preheating the outside air by heat exchange in contact with the outside air, the pre-heat exchange ventilator, discharge pipe A heat exchanger includes heat exchange of the air discharged from the interior of the house through the air duct and heat exchange of the outside air introduced through the ground duct, and the heat exchanger is performed before the outside air entering the electrothermal exchange ventilator contacts the circulating water coil. It may be precooled or preheated through the group.

In addition, in the present invention, in order to achieve the above object, by using the above-mentioned radiant air-conditioning system, ventilation-convection system and geothermal heat exchange system to radiate air-conditioning by using geothermal heat for super-energy-saving house and cooling and heating by ventilation and convection A cooling and heating method comprising: circulating a first circulating water through the pipe so as to cool or heat a room by radiation of the radiation panel; The outside air is supplied to the room through the indoor duct through the underground duct and the outside is discharged through the discharge pipe to ventilate the room, but the outside air enters the electrothermal exchange ventilator through the underground duct, and passes through the heat exchange device. Heat exchange is performed, and the air is subsequently brought into contact with the circulating water coil to remove humidity and additional heat exchange to the room through the indoor ventilation pipe, thereby further cooling or heating by convection. There is provided a heating and cooling method for an ultra-energy-saving house, characterized in that the building.

According to the present invention, the super-energy-saving house can be cooled by using cold water flowing through the radiation panel, thereby preventing the risk of overcooling. In addition, the present invention has a simple structure without the additional device, such as a flow rate control or bypass device, there is an advantage that the maintenance and maintenance is convenient. In particular, the present invention does not require the installation of a separate package air conditioner (PAC) or fan coil (FCU) unit for preventing condensation of the radiation panel, controlling humidity in the room, and dehumidifying the ultra energy-saving house. The external air compensation control, dew point temperature control, fine flow control valve and three-way valve is not required, and a simple on / off control can maintain a comfortable indoor environment with proper humidity and cooling temperature.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The present invention has been described with reference to the embodiments shown in the drawings, which are described as one embodiment by which the technical spirit of the present invention and its core configuration and operation are not limited.

Figure 1 is a schematic diagram showing the configuration of a cooling and heating system for geothermal utilization ventilation bottle (hereinafter, referred to as "integrated cooling and heating system") of a super-energy saving house according to the present invention.

The integrated heating and cooling system according to the present invention is a super-energy-saving house defined above, that is, a building having an energy efficiency rating of 1st class or higher as defined in Article 21 of the current Energy Utilization Rationalization Act, which is provided in a house having an energy saving rate of 33.5% or more compared to a standard house. And a radiant heating and cooling system 10, a ventilation-convection system 20, and a geothermal heat exchange system 30.

First, the radiant cooling and heating system 10 according to the present invention is to cool or heat the inside of an ultra energy saving house by floor radiation. The radiant heating and cooling system 10 is installed in the ultra energy saving house, and the pipe 11 is embedded and the pipe 11 is installed. A first panel in which a first circulating water is supplied to the radiant panel 12 for cooling and heating by radiation, and a first circulating water for supplying the first circulating water to the pipe 11 and circulating the pipe 11 is stored. It is configured to include a storage tank (13).

Ventilation-convection system 20 according to the present invention, by introducing the outside air into the ultra-energy-saving house and exhausting the air inside the ultra-energy-saving house to the outside to ventilate the interior of the super-energy-saving house and at the same time convection as necessary Super energy-saving system through the cooling or heating system inside. The ventilation-convection system 20 includes an indoor ventilation pipe 21 installed in a house to introduce external air into the house, a discharge pipe 22 for discharging air in the house, and a direct suction of the outdoor air. By controlling the moisture and temperature of the outside air introduced from the underground duct 23 by the underground duct 23 and the discharge air and the second circulating water discharged from the room through the discharge pipe 22, the indoor ventilation pipe ( And a second water storage tank 25 for supplying a second circulation water to the total heat exchange ventilation device 24 and recovering the circulated second circulation water. .

In the geothermal heat exchange system 30 according to the present invention, the first circulation water and the second circulation water stored in the first water storage tank 13 and the second water storage tank 25 are circulated to perform heat exchange by geothermal heat. And a heat pump 32 for applying heat to or cooling the first circulating water and the second circulating water.

First, the radiation cooling and heating operation by the radiant heating and cooling system 10 will be described. The first circulation water stored in the first water storage tank 13 is supplied to the pipe 11 and circulated to radiate through the radiation panel 12. If the temperature of the first circulating water is lower or higher than the appropriate temperature for the season, the first circulating water is heat-exchanged by the geothermal heat exchanger 31 and then back to the first water storage tank 13. Supplied and stored.

For example, in the summer, the first water storage tank 13 stores first circulation water of about 19 ° C. to about 21 ° C., and the first circulation water circulates through the pipe 11 while radiating the panel 12. After cooling the inside of the super-energy-saving house (1), it is returned to the first water storage tank (13) again. While repeating such a process, the inside of the super-energy saving house 1 is cooled. When the first circulating water temperature in the first water storage tank 13 rises above a predetermined temperature, the geothermal heat exchanger 31 is circulated. While the heat exchange is made and the temperature is lowered again, the heat is supplied to the first water storage tank 13 and stored.

In winter, the radiant heating by the radiation panel 12 requires a first circulation water of about 40 ° C. If the temperature of the first circulating water in the first water storage tank 13 is required for radiant heating as described above, If not, the first circulation water is heated via the heat pump 32. As such, the first circulating water is stored in the first water storage tank 13 by being maintained at a temperature suitable for radiant cooling or radiant heating through the geothermal heat exchanger 31 and the heat pump 32.

At this time, the heat pump 32 may use air or other known ones, and as the power source, an environmentally friendly power source such as wind or solar power may be used, or existing power may be used. That is, there is no restriction | limiting in the kind of heat pump 32, and its power source in this invention, It is sufficient to use a well-known thing.

On the other hand, the radiant cooling and heating operation by the radiant heating and cooling system 10 of the present invention may be performed whenever necessary by the user on / off operation (manual control by the user), the desired cooling temperature or heating temperature If the indoor temperature reaches the desired cooling temperature by the above cooling and heating operation, the circulation of the first circulating water is stopped to turn off the cooling or heating operation, and when the indoor temperature rises or falls again, the first The circulation of the circulating water may be started to turn on the cooling or heating operation so that the circulation stop and start of the first circulating water may be automatically repeated to maintain the room at a desired temperature (automatic control).

Next look at the specific configuration and operation of the ventilation-convection system 20 according to the present invention.

The indoor ventilation pipe 21 of the ventilation-convection system 20 is installed in the house to introduce outside air into the house, and the air in the house is discharged to the outside of the house through the discharge pipe 22, thereby making indoor ventilation and convection. . The underground duct 23 is buried in the ground, and the sucked outside air is first precooled (when the temperature of the ground is lower than outside air / for example in summer) or primary preheated while passing through the underground duct 23 (underground) If the temperature is higher than outside air / for example in winter). When the outdoor air is first pre-cooled while passing through the underground duct 23, the condensation water is condensed in the underground duct 23, thereby partially removing the humidity of the outside air.

 The total heat exchange ventilator 24 controls the moisture and temperature of the outside air introduced from the underground duct 23 by the discharge air and the second circulating water discharged through the discharge pipe 22 from the room, and then the indoor ventilation pipe ( 21). In detail, the electrothermal exchange ventilator 24 includes a heat exchanger in which heat exchange of the exhaust air discharged from the interior of the house through the discharge pipe 22 is performed, and heat exchange of external air introduced through the underground duct 23 is performed. 242 and a circulation water coil 241 through which the second circulation water flows.

The second circulation water circulating in the circulation water coil 241 is stored in the second water storage tank 25. When the temperature of the second circulating water stored in the second water storage tank 25 is lower or higher than the appropriate temperature for the season, heat is exchanged by the geothermal heat exchanger 31 and the heat pump 32 as necessary. After being heated through) is supplied to the second water storage tank 25 and stored again.

In the ventilation-convection system 20 according to the present invention having such a configuration, when the outside air is to be supplied and ventilated in the room of the ultra-energy-saving house, the outside air is sucked and first passes through the underground duct 23. At this time, the outside air is pre-cooled while passing through the underground duct 23 and at the same time, the humidity is partially removed or preheated, and the outside air enters the total heat exchange ventilator 24. The outside air entering the total heat exchange ventilator 24 is subjected to heat exchange through the heat exchanger 242 to perform secondary preheating or secondary precooling, and to be in contact with the circulating water coil 241 to control humidity, and to preheat or tertiary. After pre-cooling, it is supplied to the room through an indoor ventilation pipe 21 connected to the total heat exchange ventilation device 24.

On the other hand, the indoor air is discharged through the discharge pipe 22, the discharge pipe 22 is connected to the total heat exchange ventilator 24, the exhaust air from the room enters the total heat exchange ventilator (24). The exhaust air entering the total heat exchange ventilator 24 is discharged to the outside of the total heat exchange ventilator 24 after heat exchange is performed in the following manner through the heat exchanger 242.

In the summer, the indoor air discharged through the discharge pipe 22 from the room where the cooling is made has a relatively low temperature compared to the outside air outside the house. Therefore, the indoor air discharged through the discharge pipe 22 and introduced into the total heat exchange ventilator 24 undergoes heat exchange while passing through the heat exchanger 242. The total heat exchange ventilated in the primary precooled state through the underground duct 23. Outside air entering the device 24 is also subjected to the second pre-cooling while passing through the heat exchanger (242). In other words, the discharged indoor air is passed through the heat exchanger 242, the temperature of the heat exchanger 242 is lowered, and the outside air is secondarily cooled while passing through the heat exchanger 242 where the temperature is lowered.

On the other hand, in the summer season, since a considerable humidity is included in the outside air when the radiation cooling operation of the radiation cooling and heating system 10 of the present invention as described above for cooling the interior of the house, condensation on the radiation panel 12 of the cold temperature May occur. In the present invention, the condensation is prevented from occurring by allowing the outside air to enter the room in a dehumidified state through the following operation of the ventilation-convection system 20.

In summer, the underground duct 23 embedded in the ground maintains a relatively lower temperature than the ground, so that the sucked outside air is first pre-cooled while passing through the ground duct 23, and condensation in the ground duct 23 Humidity is somewhat eliminated by this. The outside air passing through the underground duct 23 flows into the total heat exchange ventilator 24, passes through the heat exchanger 242, contacts the circulating water coil 241, and is supplied to the room through the indoor ventilation pipe 21. . At this time, the second circulation water circulates in the circulation water coil 241, and the second circulation water is stored in the second water storage tank 25, and the heat exchange is performed in the geothermal heat exchanger 31 to about 10 ° C. Maintain a temperature of about 13 ° C. As described above, since the cold second circulating water having a temperature of about 10 ° C. to about 13 ° C. flows in the circulation water coil 241, most of the moisture contained in the outside air due to condensation while the outside air contacts the circulation water coil 241. Is removed, and the outside air from which the moisture is removed is supplied to the interior of the house through the indoor ventilation pipe 21. Therefore, it is possible to prevent the condensation phenomenon in the radiation panel 12 due to the high humidity outside air just introduced into the room. Of course, by adjusting the temperature of the second circulating water, it is also possible to adjust the humidity contained in the outside air to be supplied to the indoor ventilation pipe (21). In addition, while the outside air is in contact with the cold circulating water coil 241, an additional third pre-cooling is performed. When the pre-cooled outdoor air is supplied through the indoor ventilation pipe 21, additional cooling is performed through convection of the cooled air. That is, while the outdoor air is supplied to the room through the indoor ventilation pipe 21 in a pre-cooled state through the underground duct 23 and the total heat exchange ventilator 24, additional cooling is achieved through convection.

On the other hand, when heating is required, that is, in winter, the underground duct 23 embedded in the ground maintains a relatively higher temperature than the ground. Therefore, the outdoor air is first preheated while passing through the underground duct 23. On the other hand, in the winter, the indoor air discharged through the discharge pipe 22 from the room where the heating is made has a relatively high temperature compared to the outside air outside the house. Therefore, the indoor air discharged through the discharge pipe 22 and introduced into the total heat exchange ventilator 24 undergoes heat exchange while passing through the heat exchanger 242. That is, as the discharged indoor air passes through the heat exchanger 242, the temperature of the heat exchanger 242 increases. The outside air entering the total heat exchange ventilator 24 receives the heat from the heat exchanger 242 while passing through the heat exchanger 242, and is preheated to the second stage. As described above, the second air preheated while passing through the heat exchanger 242 is subsequently further contacted with the circulating water coil 241 to further preheat.

In a state in which heating is required, the second circulation water stored in the second water storage tank 25 is maintained to have a temperature of about 40 ° C. Since the second circulating water of about 40 ° C. flows in the circulating water coil 241, the outdoor air entering the electrothermal exchange ventilator 24 is preheated in the third while contacting the circulating water coil 241. As the outside air preheated through the above process is supplied to the room through the indoor ventilation pipe 21, additional heating is performed through convection.

The operation of the ventilation-convection system 20 according to the invention may be made whenever necessary by manual on / off control of the user (manual control), while setting the desired room humidity ("desired humidity"), Until the humidity in the room reaches the set desired humidity, the operation of removing the moisture from the outside air and supplying it to the room may be automatically performed.

When arranging the typical operation method of the cooling system of the integrated air conditioning system according to the present invention as described above, the radiant cooling by operating the radiant air conditioning system 10 as described above for cooling the room. In addition, as described above, by operating the ventilation-convection system 20, the outside air in a cooled and dehumidified state is supplied to the room to ventilate the room and perform cooling by convection. When the indoor humidity reaches the desired humidity, the radiation-heating system 10 is turned on / off according to the desired cooling temperature of the room while the operation of the ventilation-convection system 20 is stopped and only the radiant air conditioning system 10 is operated. Controlled to maintain proper room cooling temperature and room humidity.

As described above, according to the present invention, the cold panel is allowed to flow through the radiation panel 12 to be cooled using the same, thereby preventing the risk of overcooling. In addition, the present invention has a simple structure without the additional device, such as a flow rate control or bypass device, there is an advantage that the maintenance and maintenance is convenient. In particular, the present invention does not require the installation of a separate package air conditioner (PAC) or fan coil (FCU) unit for condensation prevention of the radiation panel 12, humidity control of the room, and dehumidification. This eliminates the need for dew point temperature control, microflow control valves and three-way valves, and enables simple indoor on / off control to maintain a comfortable indoor environment with adequate humidity and cooling temperature.

Next, when the typical heating operation method of the integrated air conditioning system according to the present invention as described above, the radiant heating by operating the radiant air conditioning system 10 as described above for the heating of the room. In addition, as described above, the ventilation-convection system 20 is operated to supply the outside air in the preheated state to the room to ventilate the room and perform heating by convection.

When the indoor humidity reaches the desired humidity, the operation of the ventilation-convection system 20 is stopped and only the radiant heating and cooling system 10 is operated while turning on / off the radiant heating and cooling system 10 according to the desired heating temperature of the room. Controlled to maintain proper room heating temperature and room humidity.

On the other hand, in the mid-stage (early winter, early summer, temporarily cold or hot, etc.), the operation of the radiant air conditioning system 10 is stopped, and only the ventilation-convection system 20 is operated to provide indoor air and heat environment through ventilation and convection air conditioning. I can keep it comfortable.

Figure 1 is a schematic diagram showing the configuration of the floor radiation heating and cooling system for the ultra-energy-saving geothermal utilization ventilation bottle according to the present invention.

<Description of the symbols for the main parts of the drawings>

11 Piping 12 Copy Panel

13 1st water storage tank 21 Indoor ventilation pipe

22 Exhaust Pipe 23 Underground Duct

24 Total heat exchange ventilator 25 Second water storage tank

31 geothermal exchanger 32 heat pump

Claims (4)

As an air-conditioning system that radiates and heats superheat-saving houses using geothermal heat and heats them by ventilation and convection, Radiant air-conditioning system (10) for cooling or heating the room by floor radiation, ventilation-convection system (20) for ventilating the room using outside air and cooling or heating by convection, and the radiant air-conditioning system (10) A geothermal heat exchange system (30) for heat exchange by geothermal heat to the first circulating water used and the second circulating water used in the ventilation-convection system (20); The radiation cooling and heating system 10 is installed in the room, the pipe 11 is embedded, the radiation panel 12 is supplied with the first circulation water to the pipe 11 to cool or heat by radiation, and the A first water storage tank 13 for supplying the first circulation water to the pipe 11 and storing the first circulation water circulated through the pipe 11; The ventilation-convection system 20 includes an indoor ventilation pipe 21 installed indoors to introduce external air into the interior, a discharge pipe 22 for discharging indoor air to the outside, and outdoor air sucked into the ground Moisture of the outside air introduced from the underground duct 23 by the underground duct 23 which is first preheated or firstly precooled while being discharged, and the discharge air and the second circulating water discharged from the room through the discharge pipe 22. After the temperature is adjusted, the total heat exchange ventilator 24 which is sent to the indoor ventilation pipe 21 and the second water storage which supplies the second circulation water to the total heat exchange ventilator 24 and recovers the circulated second circulation water. A tank 25; The geothermal heat exchange system 30, the geothermal heat exchange to circulate the first circulating water and the second circulating water stored in the first water storage tank 13 and the second water storage tank 25 to perform heat exchange by geothermal heat And a heat pump (32) for heating or cooling the first and second circulation waters; Cooling or heating the room is performed by radiation of the radiation panel 12 by circulating the pipe 11 with the first circulating water; The outside air enters the room through the indoor ventilation pipe 21 and is discharged to the outside through the discharge pipe 22 to perform the indoor ventilation, and the outdoor air passes through the electrothermal exchange ventilation device 24 through the underground duct 23. While the humidity and temperature of the outside air is controlled to enter the room, the cooling or heating system of the ultra-energy-saving house, characterized in that further cooling or heating by convection. The method according to claim 1, The pre-heat exchange ventilation device (24) has a circulation water coil (241) for precooling or preheating the outside air by contacting and exchanging heat with the second circulation water. The method according to claim 2, The total heat exchange ventilator 24 includes a heat exchanger 242 which performs heat exchange of air discharged from the interior of the house through the discharge pipe 22 and at the same time performs heat exchange of external air introduced through the underground duct 23. There is, Cooling or heating system of the super-energy saving house, characterized in that the pre-heating or preheating of the outside air entering the total heat exchange ventilator (24) passing through the heat exchanger (242) before contacting the circulating water coil (241). Radiant air-conditioning system (10) for cooling or heating the room by floor radiation, ventilation-convection system (20) for ventilating the room using outside air and cooling or heating by convection, and the radiant air-conditioning system (10) By using the geothermal heat exchange system 30 to heat exchange by geothermal heat to the first circulating water used and the second circulating water used in the ventilation-convection system 20, As an air-conditioning method that radiates air-conditioning and air-conditioning by ventilation and convection, The radiant air conditioning system 10 is installed in a room, and a pipe 11 is embedded, and a radiation panel 12 and a first water storage tank 13 in which first circulation water circulating through the pipe 11 is stored. ), Including; The ventilation-convection system 20 includes an indoor ventilation pipe 21 installed indoors to introduce external air into the interior, a discharge pipe 22 for discharging indoor air to the outside, and outdoor air sucked into the ground The underground duct 23 to be passed through, the heat exchanger 242 through which heat exchange is performed while the discharge air discharged through the discharge pipe 22 from the room passes, and the circulation water coil 241 through which the second circulation water circulates are provided. And a second heat storage tank (25) for storing the second circulation water and the total heat exchange ventilation device (24) flowing outside air from the underground duct (23) to the indoor ventilation pipe (21); The geothermal heat exchange system 30, the geothermal heat exchange to circulate the first circulating water and the second circulating water stored in the first water storage tank 13 and the second water storage tank 25 to perform heat exchange by geothermal heat And a heat pump (32) for heating or cooling the first and second circulation waters; Circulating the first circulating water through the pipe (11) so that cooling or heating of the room is achieved by radiation of the radiation panel (12); The outside air is supplied to the room through the indoor duct 23 through the underground duct 23 and discharged to the outside through the discharge pipe 22 to ventilate the room, but the outdoor air is ventilated through the underground duct 23. Entering the device 24, through the heat exchange device 242 to the heat exchange of the outside air is made, and then to the outside air in contact with the circulating water coil 241 to remove the humidity and further heat exchange Cooling or heating method of the ultra-energy-saving house, characterized in that the cooling or heating by convection is further made to be introduced into the room through the indoor ventilation pipe (21) in a state.

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