KR101046540B1 - Cooling and heating system using geothermal - Google Patents

Abstract

PURPOSE: A cooling and heating system using geothermal energy is provided to circulate cold water saved in an ice storage tank to an air conditioning space to promote dehumidification and circulate hot water saved in a thermal storage tank to control the temperature of the air conditioning space. CONSTITUTION: A cooling and heating system using geothermal energy includes a geothermal heat exchanger(110), an ice storage tank, a heat pump(120), a thermal storage tank, a cold and hot water supply pipe, cold and hot water collecting pipe(161), a hot water circulation pipe(166) for temperature compensation, a fan coil, a temperature regulating valves. The geothermal heat exchanger is installed in underground and collects the geothermal energy. The ice storage tank is connected to the geothermal heat exchanger through a geothermal collecting pipe and stores heat collected by the geothermal heat exchanger. The heat pump is connected to the ice storage tank through a cold water circulating pipe and includes a first heat exchanger that exchanges heat with cold water stored in the ice storage tank. The thermal storage tank is connected to a second heat exchanger included in the heat pump through a hot water circulation pipe and stores hot water heat-exchanged with the second heat exchanger. The cold and hot water supply pipe supplies cold water or hot water to the air conditioning space. The fan coil is connected to a temperature control circulating pipe through a connecting pipe. The temperature regulating valves are included in the hot water circulation pipe, the cold water circulating pipe, the cold and hot water supply pipe, and the hot water circulation pipe for temperature compensation.

Description

Cooling And Heating System Using Geothermal

The present invention relates to a cooling and heating system using geothermal heat, and more particularly, to maintain the stratification by constantly controlling the temperature of the cold and hot water flowing into the heat storage tank and the heat storage cooling tank to increase the heating and cooling efficiency of the system and reduce operating costs. It relates to a cooling and heating system using geothermal heat.

Due to the danger of fossil fuels and the limitation of reserves, development of alternative energy to replace them has been actively conducted in recent years.

Representative studies on natural energy such as wind, solar, and geothermal heat are being conducted. These natural energy have an advantage of obtaining infinite energy with little effect on environmental pollution and climate change.

A system that performs air-conditioning using geothermal heat is known as one of such natural energy, and this is a technology of cooling and heating by installing a heat exchanger so as to recover or discharge heat in the ground. The ground temperature remains almost constant with seasonal changes, so the geothermal heat exchange system can be used as a cooling device in summer and as a heating device in winter.

However, in the conventional heating and cooling system using geothermal heat, the temperature of the hot water introduced into the heat storage tank is not constant because of heat exchange in the heat pump during the winter heating operation. Since it is supplied to the air conditioning space, there was a problem that a separate boiler must be operated to control the temperature of the air conditioning space.

The present invention is to solve the above problems, geothermal heat to improve the performance of the heat pump by having a heat storage tank and a cold storage tank for storing cold water and hot water, respectively, and heat exchange with the heat pump along the circulation pipe It is to provide a cooling and heating system using.

In addition, the present invention is to provide a cooling and heating system using geothermal heat that can be stratified by the heat storage tank and the cold storage tank by constantly adjusting the temperature of the cold and hot water flowing into the heat storage tank and the heat storage cooling tank through the control of the temperature control valve.

Furthermore, the present invention is to provide a cooling and heating system using geothermal heat to reduce the operating cost by allowing the heat pump to operate in accordance with the set temperature of the heat storage tank and the heat storage cooling tank.

In addition, the present invention is to provide a cooling and heating system using geothermal heat to circulate the cold water stored in the cold storage tank to the air conditioning space to achieve dehumidification and to circulate the hot water stored in the heat storage tank to control the temperature of the air conditioning space to build a comfortable environment. There is.

In order to achieve the above object, the present invention is installed in the ground geothermal heat exchanger to recover the geothermal heat; A cold storage tank connected to the geothermal heat exchanger through a geothermal heat recovery tube to store heat recovered by the geothermal heat exchanger; A heat pump having a first heat exchanger connected to the cold storage tank and the cold water circulation pipe to exchange heat with cold water stored in the cold storage tank; A heat storage tank connected to the second heat exchanger and the hot water circulation pipe provided in the heat pump to store hot water exchanged with the second heat exchanger; A cold / hot water supply pipe for supplying cold water or hot water to the air-conditioning space by connecting a hot water supply pipe to which hot water is supplied from the heat storage tank and a cold water supply pipe to which cold water is supplied from the cold storage tank via a second valve; And a hot water recovery pipe for recovering hot water to the heat storage tank and a cold water recovery pipe for recovering cold water to the heat storage tank via a first valve, and adjusting the internal temperature of the air conditioning space to recover the cold / hot water. And a cold / hot water recovery pipe connected to the first valve to be recovered to the heat storage tank and the heat storage tank, wherein the cold / hot water stored in the heat storage tank and the heat storage tank have different temperatures through control of a temperature control valve. It is characterized in that the cold and hot water are mixed with each other to be introduced at a constant temperature.

Preferably, the temperature control valve may be provided in any one or more of the hot water circulation pipe, the cold water circulation pipe and the cold and hot water supply pipe.

Preferably, the hot water circulation pipe, the cold water circulation pipe and the cold and hot water recovery pipe is provided with a temperature sensor to measure the temperature of the cold and hot water recovered may be to operate the temperature control valve.

Preferably, the heat storage tank and the heat storage tank may be stored so that the cold and hot water stored therein are formed in two layers having different temperatures.

Preferably, the heat storage tank and the heat storage tank may be provided with a temperature sensor so as to measure the temperature of the two layers having different temperatures.

Preferably, the geothermal heat exchanger may be selectively operated according to the temperature of the cold water stored in the cold storage tank.

Preferably, the air conditioning space may be provided with a temperature control circulation pipe connected to the cold and hot water supply pipe to control the temperature inside and a fan coil connected through the temperature control circulation pipe and the connection pipe.

Preferably, the connecting pipe may be directly connected to the cold and hot water supply pipe through the opening and closing operation of the third valve.

Preferably, the connecting pipe may be directly connected to the cold and hot water collection pipe through the opening and closing operation of the fourth valve.

Preferably, the geothermal heating and cooling system is provided with a temperature compensation hot water circulation pipe connected through the hot water supply pipe and the temperature control valve may be recovered to the heat storage tank after the hot water is circulated to the air conditioning space. .

Preferably, the temperature control valve may be connected to the supply side line and the recovery side line of the temperature compensation hot water circulation pipe to each other to maintain a constant temperature of the hot water flowing into the heat storage tank.

According to the present invention as described above, it is possible to improve the performance of the heat pump by having a heat storage tank and a cold storage tank in which cold water and hot water are stored and heat exchange with the heat pump along the circulation pipe.

In addition, the present invention has the effect of improving the performance of the heat pump by stratifying the heat storage tank and the cold storage tank by adjusting the temperature of the cold and hot water flowing into the heat storage tank and the heat storage cooling tank through the control of the temperature control valve.

Furthermore, the present invention has the effect of reducing the operating cost by allowing the heat pump to operate in accordance with the set temperature of the heat storage tank and the heat storage cooling tank.

In addition, the present invention is effective to build a comfortable environment by circulating the cold water stored in the heat storage tank to the air conditioning space to promote dehumidification and circulating the hot water stored in the heat storage tank to adjust the temperature of the air conditioning space.

1 is a schematic system configuration of a cooling and heating system using geothermal heat according to the present invention.
Figure 2 is a schematic diagram during the winter and winter season heating operation of the heating and cooling system using the geothermal heat of the present invention.
Figure 3 is a schematic diagram during the winter and winter season cooling operation of the air-conditioning system using the geothermal heat of the present invention.
Figure 4 is a schematic diagram of the winter season and the winter season dehumidification operation of the air conditioning system using the geothermal heat of the present invention.
Figure 5 is a schematic diagram during the summer and summer season dehumidification operation of the heating and cooling system using the geothermal heat of the present invention.
Figure 6 is a schematic diagram during the summer and summer season cooling operation of the cooling and heating system using the geothermal heat of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

In the following description, the same reference numerals will be used to refer to the same elements, although the same reference numerals are used to refer to the present invention.

In the air-conditioning and heating system 100 using geothermal heat according to the present invention so that the cold and hot water heat exchanged in the heat pump 120 is introduced into the heat storage tank 140 and the heat storage cooling tank 130 at a constant temperature through the control of the temperature control valves (181,182). 1, the geothermal heat exchanger 110, the heat storage tank 130, the heat pump 120, the heat storage tank 140, a cold / hot water supply pipe 160, and a cold / hot water recovery pipe 161.

The geothermal heat exchanger 110 is composed of a plurality of pipes buried in the ground, the pump to circulate the cold or hot water to the heat storage tank 140 or the cold storage tank 130 along the geothermal recovery pipe 111 extending therefrom. Is provided.

Cold water or hot water is circulated along the geothermal recovery pipe 111 by the pump as described above, so that the geothermal heat exchanger 110 absorbs heat from the ground through heat exchange with the ground to recover the ground heat or store it in the cold storage tank 130. To produce cold water.

The geothermal recovery pipe 111 is connected to the cold water supply pipe 165, the cold water recovery pipe 164, the hot water supply pipe 162 and the hot water recovery pipe 163 and the opening and closing valves (191,192,193,194) or heat exchanged with the ground Hot water is allowed to flow into the heat storage tank 130 and the heat storage tank 140.

The cold storage tank 130 is a place where the cold water produced by the geothermal heat exchanger 110 is stored or the cold water heat exchanged by the heat pump 120 is stored, as described above, through the geothermal recovery pipe 111. It is connected to the heat exchanger 110 and at the same time is connected to the first heat exchanger 121 provided in the heat pump 120 through the cold water circulation pipe (131a, 131b), to the air conditioning space 150 side during the cooling and dehumidification operation The cold water supply pipe 165 and the cold water recovery pipe 164 are connected to recover the cold water after supplying the cold water.

That is, the heat storage tank 130 and the first heat exchanger 121 of the heat pump 120 are connected through the cold water circulation pipes 131a and 131b to the storage cooling tank 130 when the heat pump 120 is operated. The stored cold water is introduced into the first heat exchanger 121 side by a pump along the cold water circulation pipes 131a and 131b (hereinafter, referred to as 'upper cold water circulation pipes') connected to the upper portion of the heat storage tank 130, and the heat pump After the heat is desorbed through heat exchange with the refrigerant circulated along the refrigerant circulation line 125 of 120, the cold storage tank 130 is referred to as a cold water circulation tube 131a and 131b (hereinafter, referred to as a 'lower cold water circulation tube'). It will flow into the bottom of).

In this case, a temperature control valve 182 is provided on the upper cold water circulation pipe 131a so that the upper cold water circulation pipe 131a and the lower cold water circulation pipe 131b are connected to each other, and on the lower cold water circulation pipe 131b. The temperature sensor 134 is provided to allow the cold water flowing into the lower portion of the cold storage tank to flow at a constant temperature.

In addition, the temperature control valve 182 and the temperature sensor 134 is electrically connected to each other via a cable to be connected to each other and connected to a separate control unit (not shown) via a cable control of the control unit, respectively. Through the temperature control valve 182 is to be operated.

That is, the temperature of the cold water that is heat-exchanged in the heat pump 120 and flows into the lower portion of the cold storage tank 130 through the lower cold water circulation pipe 131b is preset by the user after detecting the temperature of the cold water. If different from the temperature, the control unit operates the temperature control valve 182 to allow the cold water flowing along the upper cold water circulation pipe 131a and the cold water flowing along the lower cold water circulation pipe 131b to mix with each other cold water having a constant temperature Is to be introduced into the storage tank 130.

Thus, the cold water stored in the cold storage tank 130 is the cold water cooled after heat exchange in the heat pump 120 is always introduced into the cold storage tank 130 at a constant temperature, so that the cold water stored in the cold storage tank 130 is The lower part is kept at different temperatures to achieve stratification.

On the other hand, the upper and lower portions of the cold storage tank 130 is provided with a temperature sensing sensor 135 to measure the temperature of the cold water stored at different temperatures, respectively, so as to be electrically connected to the controller and the heat pump 120. When the operation of the heat pump 120 is unnecessary, it is not operated more than necessary.

The heat pump 120 is a heat pump commonly used and includes a first heat exchanger 121, a second heat exchanger 122, a compressor 123, and an expansion valve 124, each of which is a refrigerant. It is connected to the circulation line 125 and may be provided with four sides (not shown) to perform the heating and cooling at the same time.

The heat pump 120 configured as described above is connected to the cold water circulation pipes 131a and 131b in which the first heat exchanger 121 is connected to the cold storage tank 130, and the second heat exchanger 122 is the heat storage tank 140. Is connected to the hot water circulation pipe (141a, 141b) is connected to the first heat exchanger 121 and the second heat exchanger 122 by the cold water and hot water to the heat exchange with the refrigerant circulated along the refrigerant circulation line, respectively The heat taken from the cold water is supplied to the hot water side so that the heat is stored in the heat storage tank 140.

Since the heat transfer process in the heat pump 120 is the same as a known technique, a detailed description thereof will be omitted.

The heat storage tank 140 stores hot water whose temperature is increased by using heat produced through heat exchange with a refrigerant in the second heat exchanger 122 of the heat pump 120, and hot water circulation pipes 141a and 141b. Is connected to the second heat exchanger 122 provided in the heat pump 120 and supplies hot water to the air conditioning space 150 side during the heating or dehumidification operation and recovers the hot water supply pipe 162 and the hot water recovery. Pipe 163 is connected, and is connected to the ground heat recovery pipe 111 to recover the geothermal heat during the summer cooling operation.

That is, the heat storage tank 140 and the second heat exchanger 122 of the heat pump 120 are connected through the hot water circulation pipes 141a and 141b so that the hot water stored in the heat storage tank 140 when the heat pump 120 is operated. The refrigerant of the heat pump 120 is introduced into the second heat exchanger 122 by a pump along a hot water circulation pipe 141b (hereinafter, referred to as a 'bottom hot water circulation pipe') connected to a lower portion of the heat storage tank 140. After absorbing heat through the heat exchange with the refrigerant circulated along the circulation line 125 is introduced into the upper portion of the heat storage tank 140 through the hot water circulation pipe (141a) (hereinafter referred to as the 'upper cold water circulation pipe'). .

At this time, a temperature control valve 181 is provided on the lower hot water circulation pipe 141b so that the upper hot water circulation pipe 141a and the lower hot water circulation pipe 141b are connected to each other, and on the upper hot water circulation pipe 141a. A temperature sensor 144 is provided to allow the hot water flowing into the heat storage tank 140 to be introduced at a constant temperature.

In addition, the temperature control valve 181 and the temperature sensor 144 is electrically connected to each other via a cable to be connected to each other and connected to a separate control unit (not shown) via a cable control of the control unit, respectively. Through the temperature control valve 181 is to be operated.

That is, after the heat exchange in the heat pump 120 detects the temperature of the hot water flowing into the upper portion of the heat storage tank 140 through the upper hot water circulation pipe (141a) in the temperature sensor 144, the temperature preset by the user If different from the control unit, the temperature control valve 181 operates the hot water flowing along the upper hot water circulation pipe (141a) and the hot water flowing along the lower hot water circulation pipe (141b) to mix with each other hot water having a constant temperature It is to be introduced into the heat storage tank 140.

Because of this, the hot water stored in the heat storage tank 140 is the hot water heated up after the heat exchange in the heat pump 120 is always introduced into the heat storage tank 140 at a constant temperature, so that the hot water stored in the heat storage tank 140 is upper and lower each other It is maintained at different temperatures to achieve stratification.

On the other hand, the upper and lower portions of the heat storage tank 140 is provided with a temperature sensor 145 to measure the temperature of the hot water stored at different temperatures, respectively, and is electrically connected to the controller and the heat pump 120 to heat If the operation of the pump 120 is unnecessary, it is not to be operated more than necessary.

The hot water supply pipe 162 connected to the heat storage tank 140 to supply hot water to the air conditioning space 150 and the cold water supply pipe 165 connected to the cold storage tank 130 to supply cold water to the air conditioning space 150 are electrically connected. The cold and hot water supply pipe 160 is connected to each other via a second valve 172 that is operated as a medium and connected to an air conditioning space 150 at one side of the second valve 172 to store the cold storage tank 130 and the heat storage tank 140. Cold water or hot water sent from the) is delivered to the air conditioning space 150 side to control the temperature or humidity of the air conditioning space.

In addition, the air conditioning space 150 is connected to the cold and hot water recovery pipe 161 on one side thereof, circulates inside the air conditioning space, and adjusts the temperature or humidity therein to recover the cold water or hot water from the heat storage tank 140 and the heat storage tank. Allow 130 to be recovered.

In addition, the cold and hot water recovery pipe 161 is provided with a first valve 171 that can adjust the flow path similar to the cold and hot water supply pipe 160, the cold water or hot water recovered from the air conditioning space 150 side heat storage tank 140 And a hot water collecting pipe 163 and a cold water collecting pipe 164 to be recovered to the cold storage tank 130, respectively.

That is, the hot water stored in the heat storage tank 140 moves along the hot water supply pipe 162 and then moves to the cold / hot water supply pipe 160 through the second valve 172 to be introduced into the air conditioning space to control the temperature inside the air conditioning space. do.

Then, after moving along the cold / hot water recovery pipe 161, the hot and hot water recovery pipe 163 is moved through the first valve 171, and then flows back to the lower portion of the heat storage tank 140.

Similarly, the cold water stored in the cold storage tank 130 is moved along the cold water supply pipe 165 and then moved to the cold and hot water supply pipe 160 through the second valve 172 to enter the air conditioning space to adjust the temperature of the air conditioning space. do.

Thereafter, after moving along the cold and hot water recovery pipe 161, the cold and hot water recovery pipe 164 is moved to the cold water recovery pipe 164 through the first valve 171, and then flows back into the upper portion of the cold storage tank 130.

In this case, a temperature control valve 183 is provided on the cold / hot water supply pipe 160 such that the cold / hot water supply pipe 160 and the cold / hot water recovery pipe 161 are connected to each other, and the temperature sensor 185 on the cold / hot water recovery pipe 161. Is provided so that the hot water flowing into the lower portion of the heat storage tank 140 and the cold water flowing into the upper portion of the heat storage tank 130 at a constant temperature.

In addition, the temperature control valve 183 and the temperature sensor 185 is electrically connected to each other via a cable to be connected to each other and connected to the control unit via a cable respectively, the temperature control valve through the control of the control unit 183 is adapted to operate.

That is, the temperature of the cold water or hot water that is heat-exchanged in the air conditioning space 150 and recovered to the lower portion of the heat storage tank 140 or the upper portion of the heat storage cooling tank 130 through the cold and hot water recovery pipe 161 in the temperature detection sensor 185. After the detection is different from the temperature preset by the user, by operating the temperature control valve 183 in the control unit cold water or hot water flowing along the cold and hot water supply pipe 160 and cold water or hot water flowing along the cold and hot water recovery pipe 161 is It is to be mixed with each other so that cold water or hot water having a constant temperature is introduced into the heat storage tank 140 and the heat storage tank 130, respectively.

Thus, the cold water or hot water stored in the heat storage tank 140 and the heat storage tank 130 is to ensure that the cold water or hot water heat exchanged in the air conditioning space is always recovered to the heat storage tank 140 and the heat storage tank 130 at a constant temperature. 140 and the cold storage tank 130 to maintain the stratification.

On the other hand, the hot water supply pipe 162 in the upper portion of the heat storage tank 140 to control the humidity in the air conditioning space by supplying hot water to the air conditioning space side separately from the second valve 172 and the cold and hot water supply pipe 160. The temperature compensation hot water circulation pipe 166 supplied and recovered to the lower portion of the heat storage tank 140 may be connected.

The hot water circulation pipe 166 for temperature compensation is connected to the hot water supply pipe 162 and the temperature control valve 184 to supply hot water to the air conditioning space by a pump, and the hot water supplied to the air conditioning space is temperature compensated. After circulating inside the air conditioning space along the hot water circulation pipe 166, it is connected to the hot water recovery pipe 163 is connected to be recovered to the lower portion of the heat storage tank 140.

In this case, the temperature control valve 184 provided in the supply side line of the hot water circulation pipe for temperature compensation is such that the recovery side line of the hot water circulation pipe for temperature compensation and the supply side line of the hot water circulation pipe for temperature compensation are connected to each other. It is electrically connected to the temperature sensor 186 provided in the recovery side line of the hot water circulation pipe for temperature compensation to circulate the interior of the air conditioning space to recover the hot water recovered to the lower portion of the heat storage tank 140 to a predetermined temperature.

On the other hand, the inside of the air conditioning space 150 is connected to the cold and hot water supply pipe 160, the temperature control circulation pipe 151 for controlling the temperature inside the air conditioning space, the temperature control circulation pipe 151 and the connection pipe 152 Fan coil 153 is provided in series through ().

At this time, the connection pipe 152 is directly connected through the temperature control circulation pipe 151 and the third valve 173 through the opening and closing operation of the third valve 173 directly from the cold and hot water supply pipe 160 Cold water can also be introduced.

In addition, the connection pipe 152 is directly connected to the cold and hot water supply pipe 160 and the fourth valve 174 through the opening and closing operation of the fourth valve 174 cold water or hot water that circulates in the air conditioning space The fan coil 153 may be moved directly from the connecting pipe 152 to the cold and hot water collection pipe 161 side.

That is, during the heating operation of the air conditioning space 150, the third valve 173 is closed to allow the hot water flowing from the cold / hot water supply pipe 160 to flow into the temperature control circulation pipe 151 to adjust the temperature inside the air conditioning space. In the cooling operation, the third valve 173 is opened so that the cold water flowing from the cold / hot water supply pipe 160 does not flow into the temperature control circulation pipe 151 and flows directly to the fan coil 153 through the connection pipe 152. To make it possible.

On the other hand, the opening and closing of the fourth valve 174 during the heating operation is to be opened and closed according to the heating load to be able to properly adjust the temperature inside the air conditioning space.

That is, when there is a large heating load, the fourth valve 174 is closed so that hot water is supplied to the fan coil 153 through the connection pipe 152 so that the temperature control circulation pipe 151 and the inside of the air conditioning space are installed. By adjusting the temperature to increase the heating efficiency, when the heating load is small, by opening the fourth valve 174 so that the hot water flows to the cold and hot water recovery pipe 161 without passing through the fan coil 153, unnecessary waste of energy It can be prevented.

In addition, the temperature control circulation pipe 151 and the fan coil 153 are connected in series through the connection pipe 152 to the fan coil 153 using hot water that is primarily heat exchanged in the temperature control circulation pipe 151. By heat exchange in the secondary) to increase the heat exchange efficiency and at the same time it is possible to maintain a constant temperature of the hot water recovered through the cold and hot water collection pipe 161.

According to the present invention as described above, it is possible to improve the performance of the heat pump by having a heat storage tank and a cold storage tank in which cold water and hot water are stored and heat exchange with the heat pump along the circulation pipe.

In addition, the present invention has the effect of improving the performance of the heat pump by stratifying the heat storage tank and the cold storage tank by adjusting the temperature of the cold and hot water flowing into the heat storage tank and the heat storage cooling tank through the control of the temperature control valve.

Furthermore, the present invention has the effect of reducing the operating cost by allowing the heat pump to operate in accordance with the set temperature of the heat storage tank and the heat storage cooling tank.

In addition, the present invention has the effect of circulating the cold water stored in the heat storage tank to the air conditioning space to achieve dehumidification and to circulate the hot water stored in the heat storage tank to control the temperature of the air conditioning space to build a comfortable environment.

Hereinafter, the operation of the air-conditioning system 100 using geothermal heat will be described in detail with reference to FIGS. 2 to 6. (The pipe portion indicated by a dotted line in FIGS. 2 to 6 does not flow cold water or hot water. That's part of it.)

1. Winter and season heating operation (see Fig. 2)

The hot water stored in the heat storage tank 140 is moved along the hot water supply pipe 162 connected to the top of the heat storage tank, and is moved to the air conditioning space through the cold and hot water supply pipe 160 through the second valve 172.

In addition, since the third valve 173 is in a closed state, the hot water is moved to the temperature control circulation pipe 151 to heat the internal air of the air conditioning space, and then moves to the fan coil 153 through the connection pipe 152. Then, the internal air of the air conditioning space is heated again and then moved to the cold and hot water collection pipe 161.

On the other hand, the fan coil 153 is to be turned on / off according to the temperature of the air conditioning space to eliminate unnecessary waste of energy.

At this time, when the heating load of the air conditioning space is small, the hot water passing through the temperature control circulation pipe 151 by opening the fourth valve 174 is not passed through the fan coil 153 through the connection pipe 152 through the cold and hot water. It is to be moved directly to the recovery pipe (161).

The hot water introduced into the cold and hot water collection pipe 161 is provided on the cold and hot water supply pipe 160 when the temperature is different from the preset temperature after the temperature is measured by the temperature sensor 185 provided on the cold and hot water collection pipe 161. The temperature control valve 183 operates to make the temperature of the hot water recovered and consistent with a predetermined temperature, and then to the lower portion of the heat storage tank 140 through the hot water recovery pipe 163 through the first valve 171. It will flow in.

Meanwhile, the heat storage tank 140 circulates hot water along the lower hot water circulation pipe 141b connected to the lower side to the first heat exchanger 121 side of the heat pump to absorb heat from the first heat exchanger 121 to circulate the upper hot water. Hot water heated along the pipe (141a) is introduced into the upper portion of the heat storage tank 140 to be stored.

At this time, the hot water flowing into the upper portion of the heat storage tank 140 is the temperature detected by the temperature sensor 144 provided in the upper hot water circulation pipe (141a) as described above is different from the predetermined temperature lower hot water circulation pipe The temperature control valve 181 provided at 141b is operated to coincide with the preset temperature so as to flow into the lower portion of the heat storage tank 140 at a constant temperature.

The heat transferred from the first heat exchanger 121 to the hot water side is supplied by cold water circulated along the cold water circulation pipes 131a and 131b and heat exchange occurring in the second heat exchanger 122.

That is, the cold water moved to the second heat exchanger 122 side of the heat pump along the upper cold water circulation tube 131a in the storage tank 130 releases heat from the second heat exchanger 122 and then the lower cold water circulation tube. Along the 131b is introduced into the lower portion of the cold storage tank 130.

At this time, the cold water flowing into the lower portion of the cold storage tank 130 is the temperature detected by the temperature sensor 134 provided in the lower cold water circulation pipe (131b) as described above and the upper cold water circulation when different from the preset temperature The temperature control valve 182 provided in the pipe 131a is operated to coincide with the preset temperature so as to flow into the lower portion of the cold storage tank 130 at a constant temperature.

As described above, the cold water stored in the cold storage tank and the hot water stored in the heat storage tank are circulated to the heat pump to exchange heat, so that the cold storage tank stores cold water having a constant temperature, and the heat storage tank stores hot water having a constant temperature. To ensure that the heating is done.

At this time, when the temperature of the cold water and the hot water is sensed by the temperature sensing sensors 135 and 145 installed in the heat storage tank 140 and the heat storage cooling tank 130, and operation of the heat pump is unnecessary, the information is transmitted to the control unit of the heat pump 120. Shutting down allows you to save on operating costs.

On the other hand, if it is determined that it is difficult to maintain a predetermined temperature through heat exchange with the heat pump 120, the cold water of the cold storage tank 130, the cold water of the cold storage tank 130 is the geothermal heat as shown in FIG. It is circulated in the direction of the arrow (D) along the recovery pipe 111 to recover heat from the ground to maintain a constant cold water temperature of the cold storage tank (130).

2. Cooling operation during winter and season (see Fig. 3)

Cold water stored in the cold storage tank 130 is moved along the cold water supply pipe 165 connected to the lower portion of the cold storage tank is moved to the air conditioning space side through the cold and hot water supply pipe 160 via the second valve (172).

At this time, since the third valve 173 is in an open state, the cold water is moved to the fan coil 153 through the connecting pipe 152 without passing through the temperature control circulation pipe 151 to cool the air conditioning space, and then cool and hot water. It is moved to the recovery pipe 161.

On the other hand, the fan coil 153 is to be turned on / off according to the temperature inside the air conditioning space to eliminate the waste of unnecessary energy.

Cold water introduced into the cold and hot water recovery pipe 161 is measured on the temperature and temperature sensor by the temperature sensor 185 provided on the cold and hot water recovery pipe 161 and is different from the predetermined temperature is provided on the cold and hot water supply pipe 160 The temperature control valve 183 operates to make the temperature of the cold water recovered to be consistent with a predetermined temperature, and then the upper portion of the cold storage tank 130 through the cold water recovery pipe 164 via the first valve 171. Will flow into.

At this time, the cold water stored in the cold storage tank 130 through the cooling process as described above is stored in the cold storage tank 130 to increase the temperature due to the waste heat obtained during cooling in the air conditioning space during the heat storage process of the heat storage tank 140. It is possible to secure the necessary heat to obtain the advantage that the performance in the heat pump 120 is improved.

On the other hand, the heat storage process in which hot water is stored in the heat storage tank 140 through heat exchange between the heat storage tank 140 and the heat storage tank 130 and the heat pump 120 is performed in the same process as the heating operation of the winter season and the season change. The detailed description will be omitted.

At this time, the operation of the geothermal heat exchanger 110 is operated by selecting the cold water production and geothermal recovery operation according to the temperature of the cold water stored in the cold storage tank 130. (Cold water circulation of the geothermal recovery pipe 111 in FIG. See path.)

Then, when the heat storage process is completed in the heat storage tank 140, the operation of the heat pump 120 is stopped and cooling is required in the air conditioning space when the cold water production is stopped, as shown in FIG. By adjusting the geothermal recovery pipe 111 is connected to the cold water supply pipe 165 and the cold water recovery pipe 164, the cold water produced in the geothermal heat exchanger 110 may be circulated to the air conditioning space to cool the air conditioning space.

On the other hand, when the humidity of the air-conditioning space is higher than the set humidity value suitable for life in winter and seasons, it is possible to control the humidity of the air-conditioning space to the set temperature by performing the cooling operation as described above.

In addition, when the temperature and humidity of the air-conditioning space is high in the summer, it is possible to control the humidity inside the air-conditioning space to the set temperature through the cooling operation as described above.

At this time, when the cooling operation for the purpose of dehumidification as described above, the case where the temperature of the air conditioning space falls below the set value in the dehumidification process.

As such, when the temperature of the air conditioning space drops by cooling during the dehumidification process, the air conditioning and heating system 100 using geothermal heat according to the present invention compensates the temperature of the air conditioning space as shown in FIGS. 4 and 5. The hot water circulation pipe 166 is connected to the heat storage tank 140 to supply hot water.

That is, the hot water stored in the heat storage tank 140 is opened through the temperature control valve 184 along the hot water supply pipe 162 by opening the temperature control valve 184 provided on the temperature compensation hot water circulation pipe 166. It is to be introduced into the temperature compensation hot water circulation pipe 166. (B 'direction of Figs. 4 and 5)

As a result, the hot water circulates the air conditioning space to compensate for the temperature of the air conditioning space, thereby maintaining a comfortable temperature for living.

3. Cooling operation of summer and season (see Fig. 6)

The process of cooling the inside of the air conditioning space by supplying the cold water stored in the storage tank 130 to the air conditioning space 150 is the same as the flow of cold water circulated during the cooling operation of the winter season and the season change, and the heat pump 120 The process of heat storage and heat storage in the heat storage tank 140 and the heat storage tank 130 by operation is also the same, so a detailed description thereof will be omitted.

Meanwhile, the difference between the cooling operation of the winter season and the cooling operation of the summer season is that the operation of the geothermal heat exchanger 110 during the cooling operation of the winter season is operated according to the cold water temperature of the cold storage tank 130. The operation of the machine 110 is determined according to the temperature of the hot water stored in the heat storage tank 140.

That is, as shown in Figure 6 stored in the heat storage tank 140 during the heat storage heat storage process in the heat storage tank 140 and the heat storage cooling tank 130 by cooling and supplying the cold water to the air conditioning space by the operation of the heat pump 120. When the temperature of the hot water is increased, the hot water is circulated through the geothermal recovery pipe 111 connected to the heat storage tank 140 (arrow 'F' direction) to lower the temperature of the hot water stored in the heat storage tank.

100: geothermal heating and cooling system
110: geothermal heat exchanger 111: geothermal recovery tube
120: heat pump 121: the first heat exchanger
122: second heat exchanger 123: compressor
124: expansion valve 125: refrigerant circulation line
130: cold storage tank 131a: upper cold water circulation pipe
131b: lower cold water circulation pipe 134, 135: temperature sensor
140: heat storage tank 141a: upper hot water circulation pipe
141b: lower hot water circulation pipe 144,145: temperature sensor
150: air conditioning space 151: temperature control circulation tube
152: connector 153: fan coil
160: cold and hot water supply pipe 161: cold and hot water recovery pipe
162: hot water supply pipe 163: hot water recovery pipe
164: cold water recovery pipe 165: cold water supply pipe
166: hot water circulation pipe for temperature compensation 171: first valve
172: second valve 173: third valve
174: fourth valve
181, 182, 183, 184: temperature control valve 185, 186: temperature sensor
191,192,193,194: On-off valve

Claims (11)

A geothermal heat exchanger installed in the ground to recover geothermal heat;
A cold storage tank connected to the geothermal heat exchanger through a geothermal heat recovery tube to store heat recovered by the geothermal heat exchanger;
A heat pump having a first heat exchanger connected to the cold storage tank and the cold water circulation pipe to exchange heat with cold water stored in the cold storage tank;
A heat storage tank connected to the second heat exchanger and the hot water circulation pipe provided in the heat pump to store hot water exchanged with the second heat exchanger;
A cold / hot water supply pipe for supplying cold water or hot water to an air-conditioning space by connecting a hot water supply pipe through which hot water is supplied from the heat storage tank and a cold water supply pipe through which cold water is supplied from the heat storage cold tank to a second valve; And
The hot water recovery pipe for recovering hot water to the heat storage tank and the cold water recovery pipe for recovering cold water to the heat storage cooling tank are connected to each other via a first valve, and the cold / hot water recovered after adjusting the internal temperature of the air conditioning space is the shaft. A cold / hot water recovery pipe connected to the first valve so as to be recovered into a cold tank and a heat storage tank;
A hot water circulation pipe for temperature compensation connected to the hot water supply pipe so that hot water is additionally circulated into the air conditioning space and then recovered to the heat storage tank;
Is connected to the cold and hot water supply pipe to control the temperature inside the temperature control circulation pipe and the temperature control circulation pipe and the connection pipe, the connection pipe is directly connected to the cold and hot water supply pipe through the opening and closing operation of the third valve Fan coil directly connected to the cold and hot water recovery pipe through the opening and closing operation of the four valves;
And a temperature control valve provided in the hot water circulation pipe, the cold water circulation pipe, the cold / hot water supply pipe, and the hot water circulation pipe for temperature compensation.
Cold and hot water stored in the heat storage tank and the cold storage tank is cooled and heated system using geothermal heat, characterized in that the cold / hot water having a different temperature is mixed with each other through the control of the temperature control valve to flow into a constant temperature. delete The method of claim 1,
On the hot water circulation pipe, the cold water circulation pipe and the cold and hot water recovery pipe, a temperature sensing sensor is provided to measure the temperature of the collected cold and hot water so that the temperature control valve is operated. . The method of claim 1,
The heat storage tank and the heat storage tank are geothermal heat cooling and heating system that is stored so that the cold and hot water is stored in two layers having different temperatures. delete delete delete delete delete delete delete

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