KR101306903B1 - Unified compact type thermal energy storage and supply system for heating, cooling and hot water system - Google Patents

Abstract

The present invention relates to an integrated compact supply device for supplying heat required for cooling, heating, and hot water supply. More specifically, the solar heat collecting device and the geothermal heat pump device are provided through a buffer tank integrated with a hot water storage tank of a heat storage device. Combined to heat the hot water storage tank with a solar heat collector, and when the temperature of the hot water storage tank falls below the set temperature, the geothermal heat pump is operated to heat the hot water storage tank above the set temperature, so that hot water supply is always supplied from the hot water storage tank, The cooling and heating water required for heating is supplied from the buffer tank, so that the geothermal heat pump device is operated even at a small load in the past, and thus the efficiency is prevented from being lowered. In order to simultaneously supply hot water, cooling and heating from the formed hot water storage tank and buffer tank, The first geothermal heat exchanger and the geothermal water heat exchanger are built into the hot water storage tank, and the second geothermal heat exchanger is built into the buffer tank, so that cooling, heating water and hot water are not mixed, The heat storage capacity can be maximized. In particular, during the absence of heating load (summer season), the whole can be used for the hot water storage heat storage tank, so the solar storage capacity is increased. It has the characteristic of supplying heat for heating and hot water supply.

Description

Integrated compact type thermal energy storage and supply system for heating, cooling and hot water system

The present invention relates to an integrated compact supply device for supplying heat required for cooling, heating, and hot water supply. More specifically, the solar heat collecting device and the geothermal heat pump device are provided through a buffer tank integrated with a hot water storage tank of a heat storage device. Combined to heat the hot water storage tank with a solar heat collector, and when the temperature of the hot water storage tank falls below the set temperature, the geothermal heat pump is operated to heat the hot water storage tank above the set temperature, so that hot water supply is always supplied from the hot water storage tank, The cooling and heating water required for heating is supplied from the buffer tank, so that the geothermal heat pump device is operated even at a small load in the past, and thus the efficiency is prevented from being lowered. In order to simultaneously supply hot water, cooling and heating from the formed hot water storage tank and buffer tank, The first geothermal heat exchanger and the geothermal water heat exchanger are built into the hot water storage tank, and the second geothermal heat exchanger is built into the buffer tank, so that cooling, heating water and hot water are not mixed, The heat storage capacity can be maximized. In particular, during the absence of heating load (summer season), the whole can be used for the hot water storage heat storage tank, so the solar storage capacity is increased. The present invention relates to an integrated compact supply device for supplying heat for cooling, heating, and hot water supply for heating and hot water supply.

As is well known, solar power is semi-permanent self-sufficiency without additional costs if the facility is equipped with energy compared to coal, petroleum, natural gas, nuclear power, etc., in particular, there is an environment-friendly advantage.

Therefore, interest in eco-friendly houses using solar or sunlight is increasing.

However, solar system not only needs backup equipment, but also consists of various large and small parts such as heat storage tank, pump, piping, controller, heat exchanger, valve, etc., and most of these components are installed. As it is being constructed in the field, it requires not only a wide installation place, but also requires a lot of construction time and complicated system, which makes it difficult to follow-up management.

In addition, since backup facilities (boilers, heat pumps, etc.) have not been developed for solar systems, it is difficult to efficiently link with solar systems.

Among these, geothermal heat pumps are increasingly being used as high-efficiency devices, and are classified as renewable energy. However, when only geothermal heat pumps are used alone, a considerable amount of electric energy is consumed. In addition, the system configuration is similar to the solar system, and is composed of a buffer tank (a kind of heat storage tank), expansion tanks, various valves, and a heat exchanger.

Here, any device (boiler, heat pump, geothermal pump, etc.) is used as a backup facility, but there is no packaged device in which all components except the solar collector and the backup facility installed outside are compactly combined. It is pointed out as a disadvantage.

In addition, until now, solar or geothermal heat pump systems have a system in which systems are separately constructed and used, but there is no packaged product that is compactly combined into one heat storage tank.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems,

The solar heat collector and the geothermal heat pump are combined into one through a buffer tank integrated with the hot water storage tank of the heat storage device, and the hot water storage tank is heated by the solar heat collector, and when the temperature of the hot water storage tank falls below the set temperature, the geothermal heat pump device is By heating the hot water storage tank above the set temperature, the hot water is always supplied from the hot water storage tank, and the cooling and heating water required for cooling and heating is supplied from the buffer tank. The purpose of the present invention is to provide an integrated compact supply device for supplying heat required for cooling, heating, and hot water supply, which can prevent the efficiency from being lowered and immediately respond to a large instantaneous load.

In addition, a first geothermal heat exchanger and a geothermal water heat exchanger are built into the hot water storage heat storage tank to simultaneously supply hot water, cooling, and heating from the hot water storage heat storage tank and the buffer tank formed integrally, and a second geothermal heat exchanger is built into the buffer tank. It is possible to maximize the heat storage capacity of cold, heating water and hot water hot water supply by not mixing the hot, cold, heating water and hot water. It provides an integrated compact supply device that supplies heat required for cooling, heating, and hot water supply to provide heating and hot water for hot water supply even on days without overheating and solar radiation due to the increased storage capacity. There is another purpose.

To achieve the above object, the present invention provides a solar heat collecting device for supplying thermal energy by solar heat;

A heat storage device connected to each of the solar heat collecting device and the geothermal heat pump device, respectively, or at the same time for cooling, heating, and hot water supply in a state of receiving and storing thermal energy;

A geothermal heat pump that is connected to the heat storage device and heat-exchanges with an underground heat source to transfer heat energy required for cooling in summer and heat energy required for heating in winter;

And a control device for controlling the solar heat collecting device, the heat storage device, and the geothermal heat pump device. The present invention relates to an integrated compact supply device for supplying heat for cooling, heating, and hot water supply.

As described above, the integrated compact supply device for supplying heat required for cooling, heating and hot water supply of the present invention is a solar heat collector and a geothermal heat pump device through a buffer tank integrated with a hot water storage tank of a heat storage device. Combined to heat the hot water storage tank with a solar heat collector, and when the temperature of the hot water storage tank falls below the set temperature, the geothermal heat pump is operated to heat the hot water storage tank above the set temperature, so that hot water supply is always supplied from the hot water storage tank, The cooling and heating water required for heating is supplied from the buffer tank. Thus, the geothermal heat pump device is operated even at a small load in the related art, thereby preventing the efficiency from being lowered, and responding to a large instantaneous load immediately.

In addition, a first geothermal heat exchanger and a geothermal water heat exchanger are built into the hot water storage heat storage tank to simultaneously supply hot water, cooling, and heating from the hot water storage heat storage tank and the buffer tank formed integrally, and a second geothermal heat exchanger is built into the buffer tank. It is possible to maximize the heat storage capacity of cold, heating water and hot water hot water supply by not mixing the hot, cold, heating water and hot water. As storage capacity increases, it is effective to supply heat required for hot water supply and heating that can supply hot water as much as possible even when there is no overheating and solar radiation.

1 is a schematic view showing an integrated compact supply apparatus according to an embodiment of the present invention.

The present invention has the following features to achieve the above object.

The present invention provides a solar heat collecting device for supplying thermal energy by solar heat;

A heat storage device connected to each of the solar heat collecting device and the geothermal heat pump device, respectively, or at the same time for cooling, heating, and hot water supply in a state of receiving and storing thermal energy;

A geothermal heat pump that is connected to the heat storage device and heat-exchanges with an underground heat source to transfer heat energy required for cooling in summer and heat energy required for heating in winter;

And a controller for controlling the solar heat collecting device, the heat storage device, and the geothermal heat pump device.

The present invention having such characteristics can be more clearly described by the preferred embodiments thereof.

Before describing the various embodiments of the present invention in detail with reference to the accompanying drawings, it can be seen that the application is not limited to the details of the configuration and arrangement of the components described in the following detailed description or shown in the drawings. will be. The invention may be embodied and carried out in other embodiments and carried out in various ways. It should also be noted that the device or element orientation (e.g., "front," "back," "up," "down," "top," "bottom, Expressions and predicates used herein for terms such as "left," " right, "" lateral, " and the like are used merely to simplify the description of the present invention, Or that the element has to have a particular orientation. Also, terms such as " first "and" second "are used herein for the purpose of the description and the appended claims, and are not intended to indicate or imply their relative importance or purpose.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

1 is a schematic view showing an integrated compact supply apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the integrated compact supply device for supplying heat required for cooling, heating, and hot water supply of the present invention includes a solar heat collector 10 for supplying thermal energy by solar heat, and the solar heat collector ( 10) and the geothermal heat pump device 30 is connected to the heat storage device 20 and the heat storage device 20, respectively or simultaneously supplied to the place where cooling, heating and hot water is required in a state in which the heat energy is supplied and stored. Geothermal heat pump device 30 to heat exchange with the heat source in the underground to transfer the heat energy required for cooling in the summer, the heat energy required for heating in winter, the solar heat collector 10, the heat storage device 20 and the geothermal heat pump It consists of a control device 40 for controlling the device 30.

As shown in FIGS. 1 and 2, the solar collector 10 has a solar collector 11 which is in direct contact with the solar heat and transfers heat to the heat medium oil flowing therein, and the solar collector 11 of the solar collector 11 The heat medium oil (heat source) is transferred to the hot water storage tank 21 and the buffer tank 22 through a pipe, and the heat medium oil transferred from the solar heat collector 11 is heat-exchanged with the time water (hot water) in the hot water storage tank 21. A heat collecting heat exchanger (12) is formed inside the hot water storage tank (21), and the heat collecting oil of the solar heat collector (11) heat exchanged in the hot water storage tank (21) is heat-collected with the heating water in the buffer tank (22). The heat exchanger 15 is formed inside the buffer tank 22.

Here, the outlet side of the first heat collecting heat exchanger 12 and the inlet side of the second heat collecting heat exchanger 15 are connected to each other by a pipe, and a branch pipe is formed at one end of the connected pipe to supply the hot water storage heat storage tank 21. Is connected to the semi-sealed expansion tank 13 is provided on the outer surface of the, three-way valve (V2) is installed in the branched portion of the pipe is controlled by the control device 40 to control the conveying direction of the heat medium oil.

In addition, the semi-sealed expansion tank 13 is connected to the inlet side of the first heat collecting heat exchanger 12 and the outlet side of the second heat collecting heat exchanger 15 by a pipe, and the semi-sealed expansion tank 13 Is connected to the outlet side of the heat collecting circulation pump 14 is formed to transfer the heat medium oil. At this time, the heat collecting circulation pump 14 is installed in the pipe connected between the semi-sealed expansion tank 13 and the solar heat collector (11).

In addition, the semi-sealed expansion tank 13 prevents heat collection due to overheating of the solar heat collector 11 that absorbs thermal expansion of heat medium oil according to temperature change in summer, and the upper portion of the semi-sealed expansion tank 13 is a solar heat collector. A branch pipe is branched from the inlet side pipe of the first heat exchanger heat exchanger 12 connected to 11 and is connected to the solenoid to open and close the transfer of the heat medium oil of the solar heat collector 11 through the signal of the control device through the branch pipe. The valve V1 is further installed.

Here, the first heat collecting heat exchanger (12) is located at the lower end inside the hot water storage heat storage tank (21), and heat exchanges with the lower end time inside the hot water storage heat storage tank (21), and the first heat collecting heat exchanger (12) is a solar heat collector ( 11) is connected by a pipe, and the semi-sealed expansion tank 13 is also connected by a pipe.

The heat storage device 20, as shown in Figure 1, the heat energy supplied from the solar heat collector 10 and the geothermal heat pump device 30 and the time is transferred from the outside filled with the internal heat exchanged to receive heat energy It consists of the hot water storage tank 21 supplied to the hot water supply of a use place, and the buffer tank 22 integrally installed in the lower end part of the hot water storage tank 21.

Here, the hot water storage tank 21 is a pipe is installed so that the external time water flows into the lower end, the time water heat exchanged with the thermal energy of the solar heat collector 10 and the geothermal heat pump device 30 (after heat exchange, hot water furnace Hot water supply pipe is installed through so that the converted water is supplied to the place of use.

In addition, inside the hot water storage tank 21, temperature sensors T1 and T2 are installed to measure a temperature of the time water and transmit a signal to the control device 40, and the temperature sensor T1 is a hot water storage heat storage tank 21. The heat source of the heat medium oil is transmitted to the hot water storage heat storage tank 21 in the first geothermal heat exchanger 12 according to the measured temperature, and the temperature sensor T2 is formed in the middle portion of the hot water storage heat storage tank 21. Thus, the geothermal water heat source of the geothermal water heat exchanger 32 is transferred to the hot water storage tank 21 according to the measured temperature.

In addition, the buffer tank 22 is used to heat the heat energy supplied from the solar heat collector 10 and the geothermal heat pump device 30 and the heating water transferred from the use place 50 during the winter heat exchanged with each other to use heat energy (50). ), And in the summer, heat energy supplied from the geothermal heat pump device 30 and cooling water filled therein are heat-exchanged with each other to supply heat energy to the cooling of the use place 50.

As described above, the buffer tank 22 is a heat storage tank that can be used for cooling unlike the hot water storage heat storage tank 21, and the hot water storage heat storage tank 21 and the buffer tank () are connected to the lower end with the hot water storage heat storage tank 21. A cover (not shown) of a heat insulating material that can wrap 22 may be further installed to integrally form the hot water storage tank 21 and the buffer tank 22.

As shown in FIG. 1, the geothermal heat pump device 30 includes a geothermal heat pump 31 for temporarily storing geothermal water heat exchanged with an underground heat source, and a geothermal heat pump 31 and a pipe. A geothermal water heat exchanger 32 connected to the inside of the hot water storage tank 21 and transferred to the ground heat source and heat-exchanged with the underground heat source to exchange heat energy of the geothermal water and the time water in the hot water storage tank 21 with each other; Geothermal water circulation pump 33 for transferring the geothermal water heat exchanged with the heat source of the geothermal heat pump (31).

Here, the geothermal heat pump 31 is connected to the geothermal water heat exchanger 32, the branch is connected to the buffer tank 22, the three-way valve (V3) is installed in the branched geothermal heat pump 31 Geothermal water in the ()) can be simultaneously or separately transferred to the geothermal water heat exchanger 32 and the buffer tank 22 by the control device (40). At this time, the geothermal heat pump 31 is another pipe is connected to the buffer tank 22 so that the cooling and heating water in the buffer tank 22 is transferred to the geothermal heat pump 31.

In addition, the geothermal water heat exchanger (32) is connected to the outlet side of the geothermal water heat exchanger (32) so that the water in the hot water storage tank (21) flows the heat exchanged geothermal water into the buffer tank (22), The tube is connected to the buffer tank 22.

The control device 40 is a control device that controls all the devices described above by a value set by a user, and a separate technology is not further provided to a device that can be implemented by those skilled in the art.

10 solar collector 11 solar collector
12: first heat collecting heat exchanger 13: semi-sealed expansion valve
14 heat collecting circulation pump 15 second heat collecting heat exchanger
20: heat storage device 21: hot water storage tank
22: buffer tank 30: geothermal heat pump device
31: geothermal heat pump 32: geothermal water heat exchanger
33: geothermal water circulation pump 40: control device
50: Where to use

Claims (7)

A solar heat collector 10 for supplying thermal energy by solar heat;
A heat storage device 20 connected to each of the solar heat collector 10 and the geothermal heat pump device 30 respectively and simultaneously or at the same time where cooling, heating, and hot water are required while storing and receiving thermal energy;
A geothermal heat pump device 30 connected to the heat storage device 20 to heat exchange with a heat source in the ground so as to transfer heat energy required for cooling in summer and heat energy required for heating in winter;
And a controller 40 for controlling the solar heat collector 10, the heat storage device 20, and the geothermal heat pump device 30.
The heat storage device 20 is a hot water supply for supplying the hot water to the hot water supply of the use of the heat energy supplied from the solar heat collector 10 and the geothermal heat pump device 30 and the time is transferred from the outside and filled inside to receive heat energy A heat storage tank 21;
It is integrally installed at the lower end of the hot water storage tank 21, the heat energy supplied from the solar heat collecting device 10 and the geothermal heat pump device 30 and the cooling and heating water filled in the interior of the use 50 is heat exchanged in winter And supply heat energy to the heating at the use place 50, and in summer, the heat energy supplied from the geothermal heat pump device 30 and the cooling and heating water filled therein exchange heat to supply heat energy to the cooling use at the use place 50. 22, including;
The solar heat collecting device 10 includes: a solar heat collector 11 which directly transmits heat energy of the sun to the heat medium oil flowing in contact with the solar heat and delivers it to the hot water storage tank 21 and the buffer tank;
A first heat collection heat exchanger (12) formed inside the hot water storage tank (21) to transfer the heat medium oil of the solar heat collector (11), and to heat-exchange with heat energy of the heat medium oil and the time water in the hot water storage heat storage tank (21);
The heat medium oil of the solar heat collector 11 which is connected to the outlet side of the first geothermal heat exchanger 12 and formed in the buffer tank 22 and is primarily heat exchanged in the hot water storage tank 21 is transferred, A second heat collecting heat exchanger (15) which exchanges heat energy with cooling and heating water in the buffer tank (22);
The inlet side and the outlet side of the first heat exchanger heat exchanger 12 and the inlet side and the outlet side of the second heat exchanger heat exchanger 15 are respectively connected by pipes to collect heat due to overheating of the solar heat collector 11 in summer. A semi-sealed expansion tank 13 for absorbing thermal expansion of the heat medium oil according to the temperature change while preventing the gap;
Integrated compacted to supply heat required for cooling, heating and hot water supply, characterized in that it comprises a; a heat collecting circulation pump 14 is connected to the outlet side of the semi-sealed expansion tank 13 to transfer the heat medium oil Feeder. The method of claim 1,
The first heat collecting heat exchanger (12) is an integrated compact supply device for supplying heat required for cooling, heating and hot water, characterized in that provided in the lower end inside the hot water storage tank (21). The method of claim 1,
One end of the pipe connecting the first geothermal heat exchanger 12 and the second geothermal heat exchanger 15 is branched and connected to the semi-sealed expansion tank 13, and the three-way valve (V2) in the branched pipe portion Is installed, and after controlling the three-way valve (V2) by the control device 40, the heat medium oil of the solar heat collector (11) passes through the first geothermal heat exchanger (12), the second geothermal heat exchanger (15) or An integrated compact supply device for supplying heat required for cooling, heating and hot water supply, characterized in that divided and delivered to the semi-sealed expansion tank (13). According to claim 1, wherein the geothermal heat pump device 30,
A geothermal heat pump 31 for temporarily storing geothermal water heat exchanged with underground heat sources therein;
It is connected to the geothermal heat pump 31 and the pipe is provided in the hot water storage tank 21, the geothermal water heat exchanged with the heat source in the ground is transferred to the heat energy of geothermal water and the time water in the hot water storage heat storage tank 21 mutually heat exchange Geothermal water heat exchanger (32);
A geothermal water circulation pump 33 which transfers the geothermal water heat-exchanged with the underground heat source to the geothermal heat pump 31;
An integrated compact supply device for supplying heat required for cooling, heating and hot water, characterized in that comprising a. 5. The method of claim 4,
The geothermal heat pump 31 is connected to the geothermal water heat exchanger 32 is branched in the buffer tank 22, the three-way valve (V3) is installed in the branched portion of the geothermal heat pump 31 An integrated compact supply device for supplying the heat required for cooling, heating and hot water, characterized in that the geothermal water is delivered to the geothermal water heat exchanger (32) and the buffer tank (22) simultaneously or separately. delete delete

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