KR101606531B1 - Hybrid Heat Pump Boiler System - Google Patents

Abstract

The present invention relates to a hybrid heat pump boiler system which improves installation efficiency by modulating a main function and enables multipurpose use. To achieve this, the present invention comprises: an outdoor unit module (200) which has a compressor (210) and an outdoor heat exchanger (230); an indoor unit module (100) which has an indoor heat exchanger (110) and an indoor unit expansion valve (120) and heats and cools indoor air; a hydro module (300) which has a heat exchanger (310) for heat storage water; a water tank module (400) which has a heat storage tank (410) for storing a heat source; and a boiler module (500) which selectively heats heating water and the water supplied through a water supply pipe (413).

Description

[0001] Hybrid Heat Pump Boiler System [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hybrid heat pump boiler system, and more particularly, to a hybrid heat pump boiler system in which main functions are modularized to maximize installation efficiency and to enable multi-purpose construction.

Generally, a heat pump system is a cooling / heating device that transfers a low-temperature heat source to a high temperature or transfers a high-temperature heat source to a low temperature by using heat of a refrigerant or condensation heat.

The heat pump system includes a compressor, an outdoor unit having an outdoor heat exchanger, and an indoor unit having an expansion valve and an indoor heat exchanger.

In the conventional hybrid system, there is a problem that the boiler, the heat storage tank, the hydro unit, and the like are integrally formed, the structure is complicated, and it is inconvenient for movement and installation.

Also, the conventional boiler system has a problem that the floor heating is interrupted when hot water is used.

Korean Patent No. 10-877055 Korean Patent No. 10-877056

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above problems and provides a hybrid heat pump boiler system that maximizes mobility and installability by modularizing an outdoor unit, an indoor unit, a hydro unit, a storage tank, .

It is another object of the present invention to provide a system and method for heat exchange using heat from a heat source, thereby enabling hot water use and floor heating at the same time.

Another object of the present invention is to reduce the amount of gas consumption and save energy by raising the temperature by exchanging the water coming from the heating water and the water in the water storage tank with water in the case of using hot water and heating the floor, To be able to do so.

It is a further object of the present invention to enable spatial cooling and space heating operation even if a failure of the hydro unit or the heat storage tank occurs, and to enable heat storage operation even if a failure of the indoor unit occurs.

In order to achieve the above object, a hybrid heat pump boiler system according to an embodiment of the present invention includes an outdoor unit module 200 including a compressor 210 and an outdoor heat exchanger 230; An indoor unit module (100) including an indoor heat exchanger (110) and an indoor unit expansion valve (120) and performing a space cooling and a space heating operation to cool / heat air in an indoor space; A hydro module (300) including a heat storage water heat exchanger (310) for exchanging heat between the refrigerant supplied from the outdoor module (200) and water in the storage tank (410); A water tank module 400 including a storage tank 410 through which circulation water is stored by passing through the storage water heat exchanger 310 by circulation pipes 311 and 312; And a boiler module 500 for selectively heating the water supplied through the water supply pipe and the water supply pipe 413. The water tank module 400 is installed in the water tank module 400 so that the heating water passing through the floor heating part 600, Circulation pipes 411 and 412 that pass through the heat storage tank 410 to obtain a heat source and then flow into the bottom heating unit 600 through the boiler module 500 and supply pipes 411 and 412 through the water supply pipe 413 when hot water is used. And a circulation pipe 414 for allowing the water to pass through the heat storage tank 410 to obtain a heat source and to discharge the water through the boiler module 500.

According to the hybrid heat pump boiler system of the present invention, the outdoor unit, the indoor unit, the hydro unit, the heat storage tank, the boiler, and the like are modularized according to functions to maximize mobility and installation.

And heat-exchanged heat is used for heat exchange so that hot water use and floor heating are possible at the same time.

In addition, when hot water is used and the floor is heated, the water coming in through the heating water and the water pipe is heat-exchanged with the water in the storage tank, and the temperature is raised to pass through the boiler module.

Also, even if a failure occurs in the hydro unit or the heat storage tank, space cooling and space heating operation can be performed, and heat storage operation can be performed even if a failure of the indoor unit occurs.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a configuration of a hybrid heat pump boiler system according to an embodiment of the present invention; FIG.
2 is a view showing flows of water and refrigerant in a space heating and floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention.
FIG. 3 is a view showing flows of water and refrigerant in a space heating and heat storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention. FIG.
4 illustrates flows of water and refrigerant in a space heating and heat storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention.
5 illustrates flows of water and refrigerant in a space heating and storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating the flow of water and refrigerant in a space heating and storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention. FIG.
FIG. 7 is a view showing flows of water and refrigerant in a heat storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention; FIG.

Hereinafter, a hybrid heat pump boiler system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic view showing a configuration of a hybrid heat pump boiler system according to an embodiment of the present invention.

1, a hybrid heat pump boiler system according to an embodiment of the present invention includes an indoor unit module 100, an outdoor unit module 200, and an indoor unit module 100. The outdoor unit, the indoor unit, the hydro unit, A hydro module 300, a water tank module 400, and a boiler module 500.

The indoor module 100 includes a room heat exchanger 110 for performing a space cooling and a space heating operation to cool and heat the indoor space and to exchange heat with indoor air, And an indoor expansion valve (120) for lowering the temperature and pressure of the indoor expansion valve (120).

The indoor unit module 100 is connected to the outdoor unit module 200 by the connection pipes 111 and 112.

The outdoor unit module 200 includes a compressor 210 for compressing the refrigerant circulating through the indoor heat exchanger 110 and the outdoor heat exchanger 230 at a high temperature and a high pressure and a compressor 210 for changing the flow rate of the refrigerant discharged from the compressor 210 The indoor heat exchanger 110 and the outdoor heat exchanger 230. The outdoor heat exchanger 230 exchanges heat with the outdoor air through the indoor heat exchanger 110 and the outdoor heat exchanger 230, A receiver tank 240 for storing the refrigerant, and an accumulator 290 for separating the liquid refrigerant from the refrigerant recovered by the compressor 210.

The compressor 210 and the outdoor heat exchanger 230 are connected by the connection pipe 221 so that the refrigerant discharged from the compressor 210 is supplied to the outdoor heat exchanger 230 through the four- On the piping 221, a motor-operated ball valve is provided as the first opening / closing valve 222.

The outdoor heat exchanger 230 and the receiver tank 240 are connected to each other by a connection pipe 231 so that the refrigerant passing through the outdoor heat exchanger 230 passes through the receiver tank 240. On the connection pipe 231, A valve 232 and an expansion valve 233 are branched.

A first bypass pipe 250 branched from a connection pipe 221 connected to the four-way valve 220 and connected to the heat storage water heat exchanger 310 so that the refrigerant passes through the heat storage water heat exchanger 310 On the first bypass pipe 250, a motor-operated ball valve is provided as a second on-off valve 251.

The connection pipe 221 connected to the four-way valve 220 and the connection pipe 331 connected to the storage heat water heat exchanger 310 are connected to the receiver tank 240 so that the refrigerant passing through the storage heat water heat exchanger 310 is transferred to the receiver tank 240. And a third on-off valve 261 is provided on the second bypass pipe 260 to provide an electric ball valve.

A connection pipe 270 is provided between the connection pipe 112 connecting the indoor heat exchanger 110 and the four-way valve 220 and the first bypass pipe 250. On the connection pipe 270, The fourth on-off valve 271 is provided with a motorized ball valve.

The third bypass pipe (330) is branched from the connection pipe (331) connected to the storage water heat exchanger (310) and joined to the connection pipe (111) connecting between the indoor heat exchanger (110) and the receiver tank 280 is provided on the third bypass pipe 280. The fifth on-off valve 281 is provided on the third bypass pipe 280 with a motorized ball valve.

The hydro module 300 includes a heat storage water heat exchanger 310 connected to the heat storage tank 410 by circulation pipes 311 and 312 so that the refrigerant supplied from the outdoor module 200 is exchanged with the water of the storage tank 410 ).

The heat storage water heat exchanger 310 is connected to the outdoor unit module 200 by the first bypass pipe 250 and the connection pipe 331 and is connected to the outdoor unit module 200 through the first bypass pipe 250, And the refrigerant that has passed through the heat storage water heat exchanger 310 is supplied to the outdoor unit module 200 through the connection pipe 331. In this way, the refrigerant passes through the heat storage water heat exchanger 310 by the first bypass pipe 250 and the connection pipe 331, and the water of the heat storage tank 410 is circulated through the circulation pipes 311, The refrigerant is returned to the heat storage tank 410 via the heat exchanger 310 so that the refrigerant and the water in the heat storage tank 410 are heat-exchanged in the heat storage water heat exchanger 310.

The hydro module 300 includes a circulation pump 320 installed on the circulation pipe 311 for circulating the water in the storage tank 410 through the storage water heat exchanger 310 during the storage heat operation, 311 so as to keep the temperature and volume of the water constant and the pressure change inside the storage tank 410 according to the operation of the circulation pump 320 constant.

The circulation pipe 311 is branched from the water supply pipe 413 and is connected to a branch water supply pipe 313 for supplying water to the water storage tank 410 and an automatic filling water valve 314 is provided on the branch water supply pipe 313.

The water tank module 400 includes a heat storage tank 410 that circulates water through the heat storage water heat exchanger 310 by the circulation pipes 311 and 312 to obtain a heat source.

The water tank module 400 is connected to the circulation pipe 411 so that the heating water passing through the bottom heating part 600 flows into the heat storage tank 410 when the floor is heated and circulated through the heat storage tank 410, The circulation pipe 412 is connected to the bottom heating unit 600 through the first heat exchanger 510 of the boiler module 500.

When the hot water is used, the water supplied through the water supply pipe 413 passes through the heat storage tank 410 to obtain a heat source, and then the circulation pipe 414 is connected to the second heat exchanger 520 of the boiler module 500, do.

A drain pipe 420 for discharging the water in the heat storage tank 410 is provided in the thermal storage tank 410 and a connection pipe 315 connected to the heating water supply pipe 521 is provided on the water supply pipe 413 On the connection pipe 315, a mixing valve 316 and a check valve 317 for preventing a backflow are provided to mix the hot water and the cold water through the control of the mixing valve 316 to allow the consumer to supply hot water of a desired temperature .

In addition, a relief valve 430 is disposed in the heat storage tank 410 so that the pressure can be discharged when a high pressure is formed in the heat storage tank 410.

The boiler module 500 includes a first heat exchanger 510 for heating water circulating through the heat storage tank 410 and heating the circulating warm water so that the floor is heated to a target temperature, And a second heat exchanger (520) for exchanging heat to raise the temperature of the water to use it as hot water.

The first heat exchanger 510 serves as a heating water heat exchanger for allowing the heating water passing through the bottom heating unit 600 to obtain a heat source by the burner 530. In the present invention, The heating water passes through the heat storage tank 410 to obtain a heat source and then flows into the first heat exchanger 510 so that the use of the burner 530 can be reduced and energy can be saved.

The second heat exchanger 520 serves as a heat storage water heat exchanger for exchanging heat with the water passing through the heat storage tank 410. In the present invention, water supplied through the water supply pipe 413 flows into the heat storage tank 410 And then flows into the second heat exchanger 520. Therefore, the use of the burner 530 can be reduced and energy can be saved.

The second heat exchanger 520 is connected to a heating water supply pipe 521 through which the water passing through the second heat exchanger 520 is discharged.

When the hot water is used, the water supplied through the water supply pipe 413 passes through the heat storage tank 410 to obtain a heat source, and then the circulation pipe 414 is connected to the second heat exchanger 520 of the boiler module 500, do.

The boiler module 500 is constructed such that the heating water passing through the bottom heating unit 600 passes through the heat storage tank 410 with the heat storage tank 410 to obtain a heat source and then flows through the first heat exchanger 510 to the floor heating unit 600 And a heating water supply pump 540 is provided on the circulation pipe 412 in the boiler module 500. The heating water supply pump 540 is connected to the heating water supply pump 540,

The boiler module 500 may further include a three-way valve 550 provided on a circulation pipe 411 through which the heating water passing through the first heat exchanger 510 is supplied to the bottom heating unit 600 A bypass pipe 551 is connected to the three-way valve 550 for bypassing the heated water obtained through the first heat exchanger 510 to the second heat exchanger 520.

As described above, the bypass pipe 551 branched from the three-way valve 550 is joined to the circulation pipe 412 after passing through the second heat exchanger 520.

The three-way valve 550 described above supplies the heating water obtained from the heat source to the floor heating part 600 while passing through the first heat exchanger 510 or the heating water obtained through the first heat exchanger 510, To the second heat exchanger (520).

The heating water bypassed by the second heat exchanger 520 is heat-exchanged through the circulation pipe 414 so that the temperature of the water flowing into the second heat exchanger 520 is used as hot water and then circulated through the circulation pipe 412, And circulated.

The floor heating unit 600 circulates the heating water from the boiler module 500 to allow floor heating.

In the embodiment of the present invention, the electric ball valve is applied as the opening / closing valve, but it can be replaced with a solenoid valve.

The operation of the hybrid heat pump boiler system according to an embodiment of the present invention will be described below.

[Space cooling and floor heating or hot water mode]

FIG. 2 is a view showing flows of water and refrigerant in the space heating and floor heating or hot water mode in the hybrid heat pump boiler system according to the embodiment of the present invention.

2, when the boiler (floor heating or hot water) is operated while performing the space cooling, the high temperature and high pressure refrigerant discharged through the compressor 210 flows through the four-way valve 220 and the first on- 222 of the indoor unit 100 through the outdoor heat exchanger 230 and then flows into the receiver tank 240 via the check valve 232 and is cooled down through the indoor unit expansion valve 120, Cooling air is supplied to the room through the heat exchanger (110) so that space cooling is performed.

The refrigerant passing through the indoor heat exchanger 110 passes through the accumulator 290 through the four-way valve 220 through the connection pipe 112 and is then recovered to the compressor 210.

The expansion valve 233 passes through the check valve 232 and flows into the receiver tank 240 in a closed state in order to allow the refrigerant passing through the outdoor heat exchanger 230 to flow into the receiver tank 240.

At this time, the second on-off valve 251 provided on the first bypass pipe 250, the third on-off valve 261 provided on the second bypass pipe 260, The fifth on-off valve 281 provided on the fourth on-off valve 271 and the third on-off pipe 280 is closed and the first on-off valve 222 provided on the connection pipe 221 is closed It is open.

In the case where floor heating is desired in a state where the space cooling is performed as described above, the boiler module 500 is operated to circulate the heating water through the floor heating part 600. [

That is, the heating water fed through the bottom heating unit 600 by the operation of the heating water supply pump 540 provided in the boiler module 500 enters the storage tank 410 through the circulation pipe 411 in a state where the temperature is decreased, The heat source is obtained through the heat exchange in the heat storage tank 410 and the heat is supplied to the bottom heating unit 600 through the circulating pipe 412 through the heating water supply pump 540 of the boiler module 500 and the first heat exchanger 510 Lt; / RTI >

In the above-described first heat exchanger 510, a heat source is obtained by heating by the burner 530 so that the heating water is heated to the target temperature.

In the hot water mode, the water in the heat storage tank 410 is supplied through the water supply pipe 413 to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 to obtain a heat source, And is supplied with hot water through a pipe 521.

At this time, the heating water obtained through the first heat exchanger 510 is obtained by the three-way valve 550 and is bypassed to the second heat exchanger 520. The heating water bypassed to the second heat exchanger 520 The temperature of the water flowing into the second heat exchanger 520 through the circulation pipe 414 is increased to be used as the hot water, and then the heat is recovered to the circulation pipe 412 and circulated.

As described above, when the user wants to use the floor heating and hot water during the space cooling, the boiler module 500 is operated.

[Space cooling and storage mode and floor heating or hot water mode] -1

FIG. 3 is a view showing flows of water and refrigerant in a space heating and heat storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention.

3, the high-temperature and high-pressure refrigerant discharged through the compressor 210 is supplied to the four-way valve 220 and the first bypass pipe 250 And then flows into the heat storage water heat exchanger 310 via the second on-off valve 251.

The refrigerant passing through the storage water heat exchanger 310 passes through the connecting pipe 331 and the fifth opening and closing valve 281 and the connecting pipe 111 provided on the third bypass pipe 280 and then flows through the indoor unit expansion valve 120 to cool the room through the indoor heat exchanger 110 of the indoor unit module 100 to cool the room.

The refrigerant passing through the indoor heat exchanger 110 passes through the accumulator 290 through the four-way valve 220 through the connection pipe 112 and is then recovered to the compressor 210.

The water in the heat storage tank 410 is returned to the heat storage tank 410 through the circulation pipe 312 via the heat storage water heat exchanger 310 via the circulation pipe 311 by the operation of the circulation pump 320 for the heat storage do.

In the heat storage water heat exchanger 310, the water from the heat storage tank 410 is heat-exchanged by the high-temperature refrigerant passing through the first bypass pipe 250, and is recovered into the heat storage tank 410 with the heat source being obtained.

At this time, the first opening / closing valve 222 provided on the connection pipe 221, the third opening / closing valve 261 provided on the second bypass pipe 260, the fourth opening / closing valve 262 provided on the connecting pipe 270, The valve 271 is closed and the second on-off valve 251 provided on the first bypass pipe 250 and the fifth on-off valve 281 provided on the third bypass pipe 280 are closed It is open.

As described above, in the present embodiment, the heat is stored by using only the regenerating water heat exchanger 310 without using the outdoor heat exchanger 230.

When the floor heating is desired in a state where the space cooling and the heat storage are performed as described above, the boiler module 500 is operated to circulate the heating water through the floor heating unit 600. In the heat storage mode operation, The heated water having a low temperature while passing through the bottom heating unit 600 is heated in the heat storage tank 410 to obtain a heat source and then circulated through the circulation pipe 412 to the boiler module 500, The heating water supply pump 540 and the first heat exchanger 510 are circulated to the floor heating unit 600.

In the hot water mode, water is supplied through the water pipe 413 to the heat storage tank 410 through heat exchange, and then the heat water is supplied through the circulation pipe 414 to the second heat exchanger 520 of the boiler module 500, And is supplied with hot water through a pipe 521.

As described above, in the present invention, while the heating water passing through the floor heating part 600 and the water coming in through the water supply pipe 413 pass through the inside of the storage tank 410 and are heated by heat exchange, The amount of gas consumption of the boiler module 500 can be reduced.

In addition, when the heat accumulated in the heat storage tank 410 is considerably high, the water that is heat-exchanged in the heat storage tank 410 and passes therethrough may supply hot water desired by the consumer without operating the boiler module 500.

[Space cooling and storage mode and floor heating or hot water mode] -2

FIG. 4 is a view showing a flow of water and a refrigerant in a space heating / heating mode and a floor heating / hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention. In this embodiment, When the temperature is high, the indoor heat exchanger (310) as well as the outdoor heat exchanger (230) are used to store heat in order to increase the efficiency.

4, the high-temperature and high-pressure refrigerant discharged through the compressor 210 is supplied to the four-way valve 220 and the first bypass pipe 250 And then flows into the heat storage water heat exchanger 310 via the second on-off valve 251.

The refrigerant having passed through the heat storage water heat exchanger 310 passes through the outdoor heat exchanger 230 through the third on-off valve 261 provided on the second bypass pipe 260.

The refrigerant passing through the outdoor heat exchanger 230 flows into the receiver tank 240 through the check valve 232 and then flows into the indoor heat exchanger 100 of the indoor unit module 100 in a state of being lowered through the indoor unit expansion valve 120 110 to cool the indoor space so that space cooling is performed.

At this time, the first opening / closing valve 222 provided on the connection pipe 221, the fourth opening / closing valve 271 provided on the connection pipe 270, the fifth opening / closing valve 271 provided on the third bypass pipe 280, The valve 281 is closed and the second on-off valve 251 provided on the first bypass pipe 250 and the third on-off valve 261 provided on the second bypass pipe 260 are closed It is open.

The refrigerant passing through the indoor heat exchanger 110 passes through the accumulator 290 through the four-way valve 220 through the connection pipe 112 and is then recovered to the compressor 210.

The operation for storing heat and the operation for operating in the floor heating mode or the hot water mode are the same as the operation description in FIG. 3, so a detailed description thereof will be omitted.

[Space heating and floor heating or hot water mode]

FIG. 5 is a view showing flows of water and refrigerant in a space heating and storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention.

5, the high-temperature and high-pressure refrigerant discharged through the compressor 210 passes through the four-way valve 220 and the connecting pipe 112 and is directly heated through the indoor heat exchanger 110 Respectively.

The refrigerant flowing through the indoor heat exchanger 110 flows into the receiver tank 240 via the indoor expansion valve 120 and the connection pipe 111 and the refrigerant flowing through the receiver tank 240 flows through the outdoor expansion valve 233, The refrigerant is passed through the outdoor heat exchanger 230 in a low temperature state while being passed through the accumulator 290 through the first opening and closing valve 222 and the four-way valve 220 and then is recovered to the compressor 210.

At this time, the second on-off valve 251 provided on the first bypass pipe 250, the third on-off valve 261 provided on the second bypass pipe 260, The fifth on-off valve 281 provided on the fourth on-off valve 271 and the third on-off pipe 280 is closed and the first on-off valve 222 provided on the connection pipe 221 is closed It is open.

Description of the operation at the time of the floor heating and the hot water mode operation is the same as that of the operation descriptions in FIGS. 2 and 3, and thus a detailed description thereof will be omitted.

[Space heating and storage mode and floor heating or hot water mode]

FIG. 6 is a view showing flows of water and refrigerant in a space heating and storage mode and a floor heating or hot water mode in a hybrid heat pump boiler system according to an embodiment of the present invention.

As shown in FIG. 6, the space heating and heat storage modes are operated at the same time. The high temperature and high pressure refrigerant discharged through the compressor 210 is branched after passing through the four-way valve 220, Off valve 271 provided on the heat storage water heat exchanger 310.

The refrigerant passing through the storage water heat exchanger 310 flows into the receiver tank 240 through the connection pipe 331 and the fifth open / close valve 281 provided on the third bypass pipe 280.

Meanwhile, the remaining refrigerant passes through the connection pipe 112 and passes through the indoor heat exchanger 110 to perform space heating.

The refrigerant passing through the indoor heat exchanger 110 flows into the reactor tank 240 via the indoor expansion valve 120 and the connection pipe 111.

The refrigerant passing through the connecting pipe 111 and the refrigerant passing through the fifth opening and closing valve 281 are combined in the receiver tank 240. The refrigerant combined in the receiver tank 240 flows through the outdoor expansion valve 233, The refrigerant is passed through the outdoor heat exchanger 230 in a low temperature state while being passed through the accumulator 290 through the first opening and closing valve 222 and the four-way valve 220 and then is recovered to the compressor 210.

At this time, the second on-off valve 251 provided on the first bypass pipe 250 and the third on-off valve 261 provided on the second bypass pipe 260 are closed, and the connection pipe 221 A fourth on-off valve 271 provided on the connection pipe 270 and a fifth on-off valve 281 provided on the third bypass pipe 280 It is open.

The operation for storing heat and the operation for operating in the floor heating mode or the hot water mode are the same as the operation description in FIG. 3, so a detailed description thereof will be omitted.

[Heat storage mode and floor heating or hot water mode]

7 is a view showing flows of water and refrigerant in the heat storage mode and the floor heating or hot water mode in the hybrid heat pump boiler system according to the embodiment of the present invention.

7, the high-temperature, high-pressure refrigerant discharged through the compressor 210 flows through the four-way valve 220 and then flows through the fourth on-off valve (not shown) provided on the connection pipe 270, (271) to the regenerating water heat exchanger (310).

The refrigerant passing through the storage water heat exchanger 310 flows into the receiver tank 240 through the connection pipe 331 and the fifth open / close valve 281 provided on the third bypass pipe 280.

The refrigerant flowing into the receiver tank 240 passes through the outdoor expansion valve 233 and then passes through the outdoor heat exchanger 230 in a low temperature state and then flows through the first opening and closing valve 222 and the four- Through the accumulator 290 and then to the compressor 210.

At this time, the second on-off valve 251 provided on the first bypass pipe 250 and the third on-off valve 261 provided on the second bypass pipe 260 are closed, and the connection pipe 221 A fourth on-off valve 271 provided on the connection pipe 270 and a fifth on-off valve 281 provided on the third bypass pipe 280 It is open.

The water in the heat storage tank 410 is returned to the heat storage tank 410 through the circulation pipe 312 via the heat storage water heat exchanger 310 via the circulation pipe 311. [

At this time, in the heat storage water heat exchanger 310, the water from the heat storage tank 410 is heat-exchanged by the high-temperature refrigerant passing through the connection pipe 270 and the first bypass pipe 250, Is recovered in.

Description of the operation at the time of the floor heating and the hot water mode operation is the same as that of the operation descriptions in FIGS. 2 and 3, and thus a detailed description thereof will be omitted.

The hybrid heat pump boiler system of the present invention is not limited to the above-described embodiments but can be variously modified and embodied within the scope of the technical idea of the present invention.

100. An indoor unit module, 110. An indoor heat exchanger,
111, 112. Connection piping, 120. Indoor unit expansion valve,
200. An outdoor unit module, 210. A compressor,
220. Four-way valve, 221. Connection piping,
222. First open / close valve, 230. Outdoor heat exchanger,
231. Connection piping, 232. Check valve,
233. Outdoor expansion valve, 240. Receiver tank,
250. First bypass piping, 251. Second open / close valve,
260. Second bypass pipe, 261. Third open / close valve,
270. Connecting piping, 271. Fourth opening closing valve,
280. Third bypass piping, 281. Fifth open / close valve,
290. Accumulator, 300. Hydro module,
310. Heat storage water heat exchanger, 311, 312. Circulating piping,
313. Branch water pipe, 314. Auto filling water valve,
315. Connecting piping, 316. Mixing valves,
317. Check valve, 320. Circulating pump,
330. Flash tank, 400. Water tank module,
410. Heat storage tank, 411, 412, 414. Circulating piping,
413. Supply pipe, 420. Drain pipe,
430. Relief valve, 500. Boiler module,
510. A first heat exchanger, 520. A second heat exchanger,
521. Heating water supply piping, 530. Burner,
540. Heating water supply pump, 550. 3-way valve,
551. Bypass piping, 600. Floor heating section

Claims (16)

An outdoor unit module (200) including a compressor (210) and an outdoor heat exchanger (230);
An indoor unit module (100) including an indoor heat exchanger (110) and an indoor unit expansion valve (120) and performing a space cooling and a space heating operation to cool / heat air in an indoor space;
A hydro module (300) including a heat storage water heat exchanger (310) for exchanging heat between the refrigerant supplied from the outdoor module (200) and water in the storage tank (410);
A water tank module 400 including a storage tank 410 through which circulation water is stored by passing through the storage water heat exchanger 310 by circulation pipes 311 and 312; And
And a boiler module (500) for selectively heating the water supplied through the water supply pipe (413) and the heating water,
The water tank module 400 may be configured such that the heating water passing through the bottom heating portion 600 when the floor heating is performed passes through the thermal storage tank 410 to obtain a heat source and then passes through the boiler module 500 to the floor heating portion 600 And water supplied through the water supply pipe 413 when hot water is used passes through the heat storage tank 410 to obtain a heat source and then discharged through the boiler module 500 And a circulation line (414). The method according to claim 1,
The outdoor unit module 200 includes a compressor 210 for compressing refrigerant circulating through the indoor heat exchanger 110 and the outdoor heat exchanger 230 at a high temperature and a high pressure, An outdoor heat exchanger 230 for allowing the refrigerant passing through the four-way valve 220 and the first opening and closing valve 222 to be heat-exchanged with the outdoor air, an outdoor heat exchanger 230 for exchanging heat between the indoor heat exchanger 110 and the outdoor A receiver tank (240) for storing surplus refrigerant in the refrigerant circulating through the heat exchanger (230), and an accumulator (290) for separating the liquid refrigerant from the refrigerant recovered by the compressor (210)
The indoor unit module 100 includes an indoor heat exchanger 110 for exchanging heat with room air and an indoor unit expansion valve 120 for decreasing the temperature and pressure of the refrigerant supplied to the indoor heat exchanger 110,
The hydro module 300 includes a heat storage water heat exchanger 310 for exchanging heat between refrigerant supplied from the outdoor module 200 and water in the storage tank 410,
The water tank module 400 includes a heat storage tank 410 that circulates water through the heat storage water heat exchanger 310 by circulation pipes 311 and 312 to obtain a heat source,
The boiler module 500 includes a first heat exchanger 510 for heating heating water circulating to achieve bottom heating at a target temperature and a second heat exchanger 510 for heating the temperature of the water passing through the heat storage tank 410, 2 heat exchanger (520). 3. The method of claim 2,
The outdoor unit module (200)
A first bypass pipe 250 connected to the heat storage water heat exchanger 310 so as to be branched from a connection pipe 221 connected to the four-way valve 220 so that the refrigerant passes through the heat storage water heat exchanger 310, ),
Wherein the first bypass pipe (250) includes a second open / close valve (251). 3. The method of claim 2,
The outdoor unit module (200)
A connection pipe 221 connected to the four-way valve 220 to allow the refrigerant passing through the storage water heat exchanger 310 to move to the receiver tank 240 and a connection pipe 221 connected to the storage water heat exchanger 310, And a second bypass pipe (260) provided between the first bypass pipe (331)
And the second bypass pipe (260) includes a third open / close valve (261). 3. The method of claim 2,
The outdoor unit module (200)
Further comprising a connecting pipe (112) connecting between the indoor heat exchanger (110) and the four-way valve (220) and a connecting pipe (270) provided between the first bypass pipe (250)
And the connection pipe (270) includes a fourth opening / closing valve (271). 3. The method of claim 2,
The outdoor unit module (200)
A third bypass pipe 330 branched from the connection pipe 331 connected to the storage water heat exchanger 310 and joined to the connection pipe 111 connecting between the indoor heat exchanger 110 and the receiver tank 240, 280)
And the third bypass piping (280) includes a fifth open / close valve (281). 3. The method of claim 2,
The outdoor unit module (200)
Further comprising a check valve (232) branched from a connection pipe (231) connecting between the outdoor heat exchanger (230) and the receiver tank (240) and an outdoor expansion valve (233) . 3. The method of claim 2,
The hydro module (300)
Further comprising a circulation pump (320) for circulating the water in the heat storage tank (410) through the heat storage water heat exchanger (310) during the heat storage operation on the circulation pipe (311) system. 9. The method of claim 8,
The hydro module (300)
And a flash tank 330 for uniformly maintaining the temperature and volume of the water and the pressure change in the storage tank 410 according to the operation of the circulation pump 320 on the circulation pipe 311 Wherein the boiler system is a hybrid heat pump boiler system. 3. The method of claim 2,
The boiler module (500)
A three-way valve (550) provided on a circulation pipe (412) through which the heating water passing through the first heat exchanger (510) is sent to the bottom heating unit (600); And
Exchanges heat from the three-way valve 550 through the second heat exchanger 520 so that the temperature of the water coming out of the heat storage tank 410 is increased to be used as hot water. Thereafter, the heat is recovered to the circulation pipe 412, And a bypass pipe (551) for supplying the heat to the boiler. 3. The method of claim 2,
The refrigerant discharged from the compressor 210 passes through the four-way valve 220 and the outdoor heat exchanger 230 and the refrigerant passed through the outdoor heat exchanger 230 flows into the receiver tank 240 and the indoor expansion valve 120 Through the indoor heat exchanger 110 and then through the four-way valve 220 and the accumulator 290 to the compressor 210 to thereby perform space cooling,
In a state where space cooling is performed,
When the floor heating operation is selected, the heating water supply pump 540 is driven so that the heating water passing through the floor heating unit 600 passes through the heat storage tank 410 through the circulation pipe 411 and then flows through the circulation pipe 412, Through the first heat exchanger (510) of the module (500), to the bottom heating section (600)
The water flowing through the water pipe 413 is supplied to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 after passing through the heat storage tank 410, And a heat source is obtained by heat exchange in the heat exchanger (520) to supply hot water through the discharge pipe. 3. The method of claim 2,
The refrigerant discharged from the compressor 210 passes through the storage heat exchanger 310 via the four-way valve 220 and then passes through the indoor heat exchanger 110 via the indoor expansion valve 120, The refrigerant passing through the compressor 110 is passed through the four-way valve 220 and the accumulator 290 and is then returned to the compressor 210,
The circulation pump 320 is driven so that the water in the heat storage tank 410 passes through the heat storage water heat exchanger 310 and is recovered to the heat storage tank 410 while obtaining a heat source by heat exchange, Respectively,
In a state where space cooling and storage heat are performed,
When the floor heating operation is selected, the heating water supply pump 540 is driven so that the heating water passing through the floor heating unit 600 passes through the heat storage tank 410 through the circulation pipe 411 and then flows through the circulation pipe 412, Through the first heat exchanger (510) of the module (500), to the bottom heating section (600)
The water flowing through the water pipe 413 is supplied to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 after passing through the heat storage tank 410, And a heat source is obtained by heat exchange in the heat exchanger (520) to supply hot water through the discharge pipe. 3. The method of claim 2,
The refrigerant discharged from the compressor 210 is passed through the regenerating water heat exchanger 310 via the four-way valve 220 and then passed through the outdoor heat exchanger 230 and the refrigerant passed through the outdoor heat exchanger 230 After passing through the indoor heat exchanger 110 via the receiver tank 240 and the indoor expansion valve 120 and then through the four-way valve 220 and the accumulator 290 to the compressor 210 On the other hand,
The circulation pump 320 is driven so that the water in the heat storage tank 410 passes through the heat storage water heat exchanger 310 and is recovered to the heat storage tank 410 while obtaining a heat source by heat exchange, Respectively,
In a state where space cooling and storage heat are performed,
When the floor heating operation is selected, the heating water supply pump 540 is driven so that the heating water passing through the floor heating unit 600 passes through the heat storage tank 410 through the circulation pipe 411 and then flows through the circulation pipe 412, Through the first heat exchanger (510) of the module (500), to the bottom heating section (600)
The water flowing through the water pipe 413 is supplied to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 after passing through the heat storage tank 410, And a heat source is obtained by heat exchange in the heat exchanger (520) to supply hot water through the discharge pipe. 3. The method of claim 2,
The refrigerant discharged from the compressor 210 flows through the four-way valve 220, the indoor heat exchanger 110, the indoor expansion valve 120, the receiver tank 240, and the outdoor expansion valve The refrigerant is recovered to the compressor 210 via the four-way valve 220 and the accumulator 290 via the outdoor heat exchanger 230,
In a state where space heating is performed,
When the floor heating operation is selected, the heating water supply pump 540 is driven so that the heating water passing through the floor heating unit 600 passes through the heat storage tank 410 through the circulation pipe 411 and then flows through the circulation pipe 412, Through the first heat exchanger (510) of the module (500), to the bottom heating section (600)
The water flowing through the water pipe 413 is supplied to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 after passing through the heat storage tank 410, And a heat source is obtained by heat exchange in the heat exchanger (520) to supply hot water through the discharge pipe. 3. The method of claim 2,
The refrigerant discharged from the compressor 210 is branched after passing through the four-way valve 220 and a part of the refrigerant flows into the receiver tank 240 through the heat storage water heat exchanger 310 and the remainder passes through the indoor heat exchanger 110 And then flows into the receiver tank 240 through the indoor expansion valve 120. The refrigerant combined in the receiver tank 240 passes through the outdoor expansion valve 233 and the outdoor heat exchanger 230, The heat exchanger 220 and the accumulator 290 to be returned to the compressor 210 so that the space heating and the heat storage are simultaneously performed,
In a state where space heating and heat storage are performed,
When the floor heating operation is selected, the heating water supply pump 540 is driven so that the heating water passing through the floor heating unit 600 passes through the heat storage tank 410 through the circulation pipe 411 and then flows through the circulation pipe 412, Through the first heat exchanger (510) of the module (500), to the bottom heating section (600)
The water flowing through the water pipe 413 is supplied to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 after passing through the heat storage tank 410, And a heat source is obtained by heat exchange in the heat exchanger (520) to supply hot water through the discharge pipe. 3. The method of claim 2,
After the refrigerant discharged from the compressor 210 passes through the regenerating water heat exchanger 310 via the four-way valve 220 and the refrigerant passed through the regenerating water heat exchanger 310 flows into the receiver tank 240 and the outdoor unit expansion Through the valve 233 to the outdoor heat exchanger 230 and then to the compressor 210 via the four-way valve 220 and the accumulator 290,
The circulation pump 320 is driven so that the water in the heat storage tank 410 passes through the regenerating water heat exchanger 310 and a heat source is obtained by heat exchange so that the water is recovered to the heat storage tank 410, and,
In a state in which heat storage is performed,
When the floor heating operation is selected, the heating water supply pump 540 is driven so that the heating water passing through the floor heating unit 600 passes through the heat storage tank 410 through the circulation pipe 411 and then flows through the circulation pipe 412, Through the first heat exchanger (510) of the module (500), to the bottom heating section (600)
The water flowing through the water pipe 413 is supplied to the second heat exchanger 520 of the boiler module 500 through the circulation pipe 414 after passing through the heat storage tank 410, And a heat source is obtained by heat exchange in the heat exchanger (520) to supply hot water through the discharge pipe.

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