KR101255760B1 - Hybrid heat pump boiler system - Google Patents

Abstract

PURPOSE: A hybrid heat pump boiler system is provided to overcome mechanical limits on the performance degradation of a boiler and a heat pump by integrating the heat pump, a boiler unit, and a water tank unit. CONSTITUTION: A hybrid heat pump boiler system comprises an outdoor unit(200), a water tank unit(300), and a boiler unit(400). The outdoor unit comprises a compressor(210), a 4-way valve(220), a hot-water heat exchanger(230), first and second expansion valves(240,280), and a fan coil unit(250). The compressor compresses a refrigerant at high temperature and high pressure. The 4-way valve changes the flow of the refrigerant discharged from the compressor. The hot-water heat exchanger heat-exchanges the water in the water tank unit with the refrigerant passing through the 4-way valve. The first and second expansion valves decrease the pressure and temperature of the refrigerant passing through the hot-water heat exchanger. The fan coil unit makes the refrigerant pass, which passes through the first expansion valve for heat-exchanging. The water tank unit comprises a heat storage tank(310) and a heating water heat exchanger(320). The boiler unit comprises an exhaust gas recovery heat exchanger(401) arranged at a position where exhaust gas is exhausted; and a heat pipe(470). [Reference numerals] (AA) Gas supply;

Description

Hybrid Heat Pump Boiler System

The present invention relates to a hybrid heat pump boiler system, and more particularly, to solve the winter's problem of frost by recovering the waste heat of the boiler unit while allowing space cooling, heating, floor heating, and four season hot water supply in one system. It is to enable a multipurpose high efficiency system.

In general, a heat pump system is a cooling and heating device that transfers a low temperature heat source to a high temperature or a high temperature heat source to a low temperature by using heat of a refrigerant or heat of condensation.

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.

However, when the heat pump system is used for heating, in the winter when the temperature of the outdoor air is lowered, in most cases, the heating efficiency is sharply reduced or sufficient heating or hot water supply operation cannot be provided due to the problem of implantation.

In order to solve the problem of the heat pump system, a heating and cooling system in which hot water is provided has been proposed.

In the conventional heating and cooling heat pump to supply hot water, the usability is greatly improved by additionally supplying hot water along with heating and cooling. However, supply of hot water is not made smoothly and cooling efficiency is lowered during hot water supply or hot water efficiency when cooling Problems such as deterioration occurred.

Republic of Korea Patent No. 10-877055 Republic of Korea Patent No. 10-877056

Accordingly, the present invention has been made to solve the above-described problems, and an object of the present invention is to integrally configure the heat pump, the boiler unit and the water tank unit to deteriorate the performance of the boiler and defrost of the bottom pump and low temperature. To overcome the technical limitations and combine the advantages of boilers and heat pumps to provide optimal efficiency by using various heat sources (indoor / outdoor air heat, boiler exhaust gas waste heat) to provide floor heating and hot water supply. And floor heating can be performed selectively or simultaneously, and the exhaust gas waste heat of the boiler unit can be recovered to solve the problem of the concept of heat exchanger in the fan coil unit of the outdoor unit in winter.

Solution to Problem The present invention for achieving the above object is a hybrid heat pump boiler system in which the outdoor unit, the water tank unit and the boiler unit are integrally associated with the indoor unit to form a heat pump,

The outdoor unit includes a compressor for compressing a refrigerant at high temperature and high pressure; Four-way valve for changing the flow path of the refrigerant discharged from the compressor; A hot water heat exchanger configured to exchange heat with water of the water tank unit while the refrigerant passing through the four-way valve passes; First and second expansion valves configured to reduce the pressure and reduce the refrigerant passing through the hot water heat exchanger; A fan coil unit configured to allow heat exchange to pass through the refrigerant passing through the first expansion valve;

The water tank unit may include: a heat storage tank having a circulation pipe for circulating water through the hot water heat exchanger of the outdoor unit; It is provided with a connection pipe for heating is made, the heating water heat exchanger is connected to the connection pipe connected to the connection pipe and the heating water to be returned to the boiler unit,

The boiler unit has a structure in which a heat pipe is connected to an exhaust gas recovery heat exchanger provided at a position at which exhaust gas is discharged so as to exchange heat with the exhaust gas discharged so that a heat source is transferred to a fan coil unit of the outdoor unit.

In addition, the first expansion valve is provided in the connection pipe connected to the fan coil unit through the hot water heat exchanger from the four-way valve, the second expansion valve is provided on the connection pipe connected to the indoor unit.

Two three-way valves are provided on the connection pipe between the four-way valve and the hot water heat exchanger. One of the three-way valves is connected to the connection pipe passing through the indoor heat exchanger of the indoor unit, and the other three-way valve is connected to the connection pipe. It is connected to the bypass pipe which is bypassed from and connected to the 4-way valve.

In addition, the connection pipe is bypassed to have a structure in which a bypass pipe connected to a connection pipe connected to the fan coil unit part is formed.

In addition, the bypass pipe is provided with a three-way valve located at the tip of the fan coil unit portion, the three-way valve is connected to the connection pipe passing through the indoor unit and the connection pipe passing through the hot water heat exchanger through the branch pipe to the fan coil unit unit It is a structure that passes through.

In addition, the bypass pipe is bypassed from the connecting pipe and connected to the four-way valve, and the bypass pipe connected to the connecting pipe bypassed from the connecting pipe and connected to the fan coil unit, are connected to each other through the connecting pipe. The refrigerant is moved to the compressor in the heating mode.

In addition, the bypass pipe is connected between the connection pipe connected to the indoor unit while being connected to the three-way valve of the bypass pipe.

In addition, the boiler unit has a structure that is connected to the floor heating unit for circulating the heating water is made to the floor heating.

In addition, the three-way valve is provided on the circulation pipe, the three-way valve is a structure that is provided with a bypass pipe that is bypassed from the circulation pipe is connected via a heating water heat exchanger.

At the branch point to the circulation pipe and the bypass pipe, the water flow from the heat storage tank has a three-way valve for selectively or simultaneously allowing the water from the heat storage tank to flow into the heating water heat exchanger or the heat storage tank.

In addition, the three-way valve is provided on the return pipe, the bypass pipe connected to the three-way valve to supply the heating water to the structure is provided with a structure.

In addition, the boiler unit has a structure in which the inlet pipe and the discharge pipe are connected to the heat storage tank and discharged through the second heat exchanger in the boiler unit.

In addition, the inlet pipe is provided with a three-way valve connected to the discharge pipe is a structure that can be used to directly take out the water of the heat storage tank to hot water without passing through the boiler unit.

In addition, the boiler unit is provided with an exhaust gas recovery heat exchanger, the heat pipe is connected to the exhaust gas recovery heat exchanger is provided with a heat pipe to be delivered to the fan coil unit of the outdoor unit.

In addition, a branch pipe is provided at the point where the connecting pipe of the outdoor unit meets the connecting pipe of the indoor unit, and the flow control valve is provided on all or one of the flow control valves on the connecting pipe of the indoor unit and the connecting pipe after the branch pipe, respectively. The floor heating is performed at the same time.

A secondary tank is connected to the exhaust gas recovery heat exchanger formed in the boiler unit, and is connected to a heat pipe for recovering the heat source of the exhaust gas generated from the boiler unit. The auxiliary tank is branched from the bypass pipe to The connection pipe passing through the heat exchanger of the fan coil unit is connected, and one side of the auxiliary tank is connected to the return pipe so that the hot water is joined to the inside of the boiler unit.

As described above, the present invention can be miniaturized by integrally configuring the heat pump and the boiler unit and the water tank unit, which can be utilized in space, easy to install in an existing house, and hassle of installing the boiler unit and the heat pump separately. Will be avoided.

In addition, the present invention can provide space cooling, heating, floor heating and four seasons hot water supply, it is possible to improve the optimal overall efficiency by the optimum operating combination of the heat pump and the boiler according to the outside temperature.

In addition, the present invention has the effect that can be carried out selectively or simultaneously with space heating and floor heating.

In addition, the present invention by maximizing the performance of the heat pump by recovering the waste heat from the exhaust gas generated from the boiler, solve the winter problem, can reduce the operating time of the boiler using only conventional fossil fuel, accordingly CO2 emissions can also be reduced, making it an environmentally friendly system.

In addition, the present invention can recover the heat of condensation in the cooling mode can be used as hot water.

In addition, the hybrid heat pump boiler system according to the present invention is configured in a parallel module type can be fully utilized even in a large capacity.

In addition, the present invention is capable of smart operation functions such as comprehensive energy priority operation, carbon dioxide emission priority operation, energy cost priority operation, power peak avoidance operation and the like.

1 is a block diagram showing a hybrid heat pump boiler system according to an embodiment of the present invention, it shows the heating mode and the use of hot water.
2 is a configuration diagram showing a case of the cooling mode in the state of FIG.
3 is a configuration diagram showing another embodiment of the present invention, which is configured to allow space heating and floor heating at the same time.
4 is a configuration diagram when the cooling mode in the state of FIG.
5 is a configuration diagram showing still another embodiment of the present invention, showing a connection structure between the heat pipe and the auxiliary tank.
6 is a configuration diagram showing a state in the cooling mode in the state of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

In describing the details of the invention, it is to be understood that the system used is a term that refers to an apparatus, not a method.

1 is a block diagram showing a hybrid heat pump boiler system according to an embodiment of the present invention, it shows a heating mode and when using hot water (hot water).

As shown in the figure, the hybrid heat pump boiler system 1 according to an embodiment of the present invention, the outdoor unit 200, the water tank unit 300 and the boiler associated with the indoor unit 100 constituting the heat pump It is composed of a unit 400.

The indoor unit 100 is provided with an indoor heat exchanger 110 and a blower 120.

In addition, the outdoor unit 200 includes a compressor 210 for compressing a refrigerant at high temperature and high pressure, a four-way valve 220 for changing a flow path of the refrigerant discharged from the compressor 210, and the four-way valve 220. And a hot water heat exchanger 230 for exchanging heat with the water in the water tank unit 300 while passing through the refrigerant, and a first expansion valve 240 for reducing the pressure and temperature of the refrigerant passing through the hot water heat exchanger 230. In addition, the refrigerant passing through the first expansion valve 240 is made of a fan coil unit 250 to allow heat exchange.

The refrigerant passing through the fan coil unit 250 forms a cycle while allowing the refrigerant to flow back into the compressor 210 through the four-way valve 220.

The fan coil unit 250 is a heat exchanger made of a blower 251 and a heat exchanger 252, the heat exchange is performed while the refrigerant passing through the first expansion valve 240 passes.

The indoor heat exchanger 110 of the indoor unit 100 is connected to the outdoor unit 200 through the connection pipes 111 and 112 to achieve indoor cooling and heating.

In addition, the present invention is connected to the fan coil unit 250 and the connection pipe 260, 270 via the hot water heat exchanger 230 from the four-way valve 220, the four-way valve 220 and hot water heat exchange On the connection pipe 260 between the two groups 230 is provided with two three-way valve (261, 262), one three-way valve (261) is connected to pass through the indoor heat exchanger 110 of the indoor unit (100) Is connected to the pipe 111, the other three-way valve 262 is bypassed from the connection pipe 260 is connected to the bypass pipe 263 is connected to the four-way valve 220.

The three-way valve 262 selectively changes the flow path of the refrigerant toward the hot water heat exchanger 230 and the four-way valve 220.

In addition, the connection pipe 270 is bypassed and the bypass pipe 271 is connected to the connection pipe 112 connected to the fan coil unit 250 is formed.

The bypass pipe 271 is provided with a three-way valve 272 located at the tip of the fan coil unit 250, the three-way valve 272 and the connection pipe 112 for passing the indoor unit 100 and The connection pipe 270 passing through the hot water heat exchanger 230 is combined through the branch pipe 273 and connected through the fan coil unit 250.

In addition, the bypass pipe 271 is provided with a valve 271a for controlling the movement path of the refrigerant.

In addition, the connection pipe 270 is provided with a check valve 274 in the next position of the first expansion valve 240.

In addition, the three-way valve 272 of the bypass pipe (271) has a structure provided with a bypass pipe (277) connected to the connection pipe 111 is connected to the indoor unit (100).

In addition, the bypass pipe 263 and the bypass pipe 271 are connected to each other through the connection pipe 275. A check valve 276 is provided on the connection pipe 275 to control whether the refrigerant passes.

In addition, the connection pipe 112 that passes through the indoor heat exchanger 110 of the indoor unit 100 is connected to the fan coil unit 250 of the outdoor unit 200, the second expansion valve on the connection pipe 112 280 is provided.

In addition, an accumulator 290 is provided between the four-way valve 220 and the compressor 210.

In addition, the water tank unit 300 has a structure consisting of a heat storage tank 310 and a heating water heat exchanger (320).

In addition, the boiler unit 400 includes a burner 410, first and second heat exchangers 420 and 430, and an expansion tank 440.

In addition, the present invention is provided with a floor heating unit 500 for circulating the heating water from the boiler unit 400 to the floor heating.

In addition, in addition to the floor heating unit 500 may be configured to circulate the heating water by connecting to a radiator (not shown).

In addition, the heat storage tank 310 of the water tank unit 300 is connected to the heat storage tank 310 again through the hot water heat exchanger 230 of the outdoor unit 200, and the circulation pipes 330 and 340 to circulate water. It is provided.

In addition, a three-way valve 331 is provided on the circulation pipe 330, and the three-way valve 331 is bypassed from the circulation pipe 340 and connected through a heating water heat exchanger 320. 341 and 342 are provided.

In addition, a three-way valve 343 is provided at the branch point of the circulation pipe 340 and the bypass pipe 341.

The three-way valve (343) sends the water moving the circulation pipe 340 only to the heating water heat exchanger 320, or a portion of the water to the heating water heat exchanger 320, a portion of the remaining heat storage tank again. Can be introduced to (310).

In other words, hot water passing through the hot water heat exchanger 230 in the three-way valve 343 heats the heated water and the heated water returned from the heating water heat exchanger 320 or flows into the heat storage tank 310 to accumulate hot water. You can proceed to the operation at the same time or selectively.

In addition, in the drawing, the relief valve 344 is provided at an upper portion of the heat storage tank 310, so that when a high pressure is formed in the heat storage tank 310, pressure discharge is possible.

In addition, a water supply pipe 311 is connected to a lower portion of the heat storage tank 310, a pressure reducing valve 312 is provided on the water supply pipe 311, and a drain pipe 313 for draining water in the heat storage tank 310. ) Is connected.

In addition, the circulation pipe 330 is provided with a circulation pump 332 to circulate the water in the heat storage tank (310).

In addition, the heating water heat exchanger 320 is provided with a connection pipe 510 connected to the floor heating unit 500, the connection pipe 510 is a boiler unit 400 via the heating water heat exchanger 320. ) Is connected to the return pipe 520 to return the heating water.

In addition, the connection pipe 510 has a structure provided with a pump 512.

In addition, a three-way valve 521 is provided on the return pipe 520, and the three-way valve 521 is provided with a bypass pipe 522 connected to the floor heating part 500.

In addition, the boiler unit 400 is connected to the heat storage tank 310 and the inlet pipe 450 and the discharge pipe 460 to be discharged through the second heat exchanger 430 in the boiler unit 400 is connected.

The three-way valve 451 is provided on the inflow pipe 450, and the three-way valve 451 is connected to the discharge pipe 460.

In addition, the expansion tank 440 in the boiler unit 400 is connected to the heating water inlet pipe 441 so that the heating water is returned through the return pipe 520, the supply pipe via the first heat exchanger (420) ( 523 and supply pipes 442 and 443 for supplying heating water to the floor heating part 500 through the bypass pipe 522 are connected.

The supply pipe 442 is equipped with a pump 444 for supplying heating water.

In addition, the supply pipe 443 is provided with a three-way valve 445, the three-way valve 445 is connected to the return pipe 520 via the second heat exchanger 430, bypass pipe 446 Is provided.

In addition, a branch pipe 447 is placed at the point where the return pipe 520 and the bypass pipe 446 meet to be joined.

In addition, according to an embodiment of the present invention, the waste heat of the exhaust gas discharged from the boiler unit 400 may be recovered and utilized, the position where the exhaust gas of the boiler unit 400 is discharged (of the boiler unit 400) Side or upper portion), an exhaust gas recovery heat exchanger 401 is provided, and the exhaust gas discharged by being connected to the exhaust gas recovery heat exchanger 401 is transferred to the fan coil unit 250 of the outdoor unit 200. The heat pipe 470 is provided.

The heat pipe 470 is coupled to the heat exchanger 252 provided in the fan coil unit 250 of the outdoor unit 200.

On the other hand, the present invention as another embodiment, as shown in Figure 3 and 4, the three-way valve installed at the point where the connection pipe 260 of the outdoor unit 200 and the connection pipe 111 of the indoor unit 100 meets Instead of the 261, a branch pipe 264 is provided, and a flow control valve 113 is provided on the connection pipe 111 of the indoor unit 100.

As a result, not only space cooling but also floor heating and space heating can be simultaneously performed.

In addition, the position is connected to the hot water heat exchanger 230 through the branch pipe 264 on the connecting pipe 260 has a structure having a flow control valve 114.

In addition, as another embodiment of the present invention, as shown in Fig. 5 and 6, the boiler unit 400 is connected to the exhaust gas recovery heat exchanger 401 formed at the position where the exhaust gas of the boiler unit 400 is discharged ( The auxiliary tank 480 is connected to the heat pipe 470 for recovering the heat source of the exhaust gas generated from 400 and receives the heat source. The auxiliary tank 480 is branched from the bypass pipe 522 to the outdoor unit. Connection pipes 481 and 482 through the heat exchanger 252 of the fan coil unit 250 of the 200 are connected, and one side of the auxiliary tank 480 is connected to the return pipe 520 to join the hot water. Is provided with a connection pipe (483) to be introduced into the boiler unit 400.

The valve 484 is provided on the connection pipe 481, and the drain pipe 485 is connected.

In the embodiment of the present invention, both of the flow control valve 113, 114 may be installed, or only one of them can be selectively installed.

The present invention having such a configuration will be described the operation divided into the heating mode and the cooling mode and the use of hot water.

[Heating Mode]

As shown in FIG. 1, according to an embodiment of the present invention, space heating and floor heating may be selectively or simultaneously performed. First, when the indoor heating unit 100 is not operated, the outdoor unit 200 is not operated. And the water tank unit 300 and the boiler unit 400 is to operate.

When the outdoor unit 200 operates, the high temperature and high pressure refrigerant discharged from the compressor 210 moves to the hot water heat exchanger 230 through the four-way valve 220 through the connection pipe 260.

Passing through the first expansion valve 240 through the connecting pipe 270 while passing through the hot water heat exchanger 230, passing through the fan coil unit 250 and the three-way valve 272, connecting pipe 275 and After passing through the four-way valve 220, it is introduced back into the compressor 210 via the accumulator 290 to form a cycle.

At this time, the valve 271a provided on the bypass pipe 271 is in a closed state.

Here, the hot water heat exchanger 230 allows the heat from the heat storage tank 310 of the water tank unit 300 to circulate through the circulation pipes (330, 340).

In other words, since the high-temperature, high-pressure refrigerant passes through the hot water heat exchanger 230 through the connection pipe 260 by the operation of the outdoor unit 200, the heat exchanger with the water from the heat storage tank 310 to exchange heat with the circulation pipe 330 The temperature of the water passing through the circulating pipe 340 is elevated, the water (hot water) in this state passes through the heating water heat exchanger 320 through the bypass pipe 341 via the three-way valve (343) , And performs a circulation operation of moving to the circulation pipe 330 through the three-way valve 331 again through the bypass pipe 342.

In addition, the heating water coming out after passing through the first heat exchanger 420 from the expansion tank 440 of the boiler unit 400 is supplied to the floor heating unit 500 through the supply pipe 523 and the bypass pipe 522. The heating water is passed through the floor heating unit 500 passes through the heating water heat exchanger 320 through the connecting pipe 510, and then again through the return pipe 520, the boiler unit ( It is reflowed into the expansion tank 440 of 400.

At this time, the temperature of the heating water passing through the bottom heating section 500 is lowered, and the temperature is raised while passing through the heating water heat exchanger 320.

In other words, the water from the heat storage tank 310 passes through the heating water heat exchanger 320 in a heated state by obtaining a heat source while passing through the hot water heat exchanger 230 of the outdoor unit 200, thereby reducing the floor heating unit 500. Heat exchanged with the coarse heating water is introduced into the boiler unit 400 through the return pipe 520 in a state where the low-temperature heating water is elevated.

In addition, the hot water passing through the hot water heat exchanger 230 on the outdoor unit 200 side forming the heat pump is heat-exchanged in the heating water heat exchanger 320, the connection pipe 510 by the pump 512 in the state that the heat amount of hot water is sufficient. Heating water flowing through) does not flow into the boiler unit 400, and moves directly to the bottom heating unit 500 through the bypass pipe 522 through the three-way valve 521 so that the floor heating is performed.

In addition, when the hot water passing through the hot water heat exchanger 230 is insufficient heat in the process of heat exchange in the heating water heat exchanger 320, the heating water flowing through the connection pipe 510 flows into the boiler unit 400. After the heating, and then to come out again to pass through the floor heating unit 500 through the supply pipe 523 is to make the floor heating.

Therefore, it is possible to reduce the gas consumption consumed in heating the water by the boiler unit 400 for floor heating or hot water supply.

On the other hand, if you want to use hot water, the water flows from the heat storage tank 310 to the inside of the boiler unit 400 through the inlet pipe 450, after passing through the second heat exchanger 430, the boiler unit 400 again High temperature hot water is discharged through the discharge pipe 460 connected to the outside of the hot water is enabled.

When the hot water temperature of the heat storage tank 310 is sufficient, the water in the heat storage tank 310 is bypassed from the inlet pipe 450 directly to the discharge pipe 460 through the three-way valve 451 without passing through the boiler unit 400. It may be used as hot water.

In the second heat exchanger 430, the water, which has been heated while passing through the first heat exchanger 420, is supplied to the floor heating unit 500 through the supply pipe 443 and branched through the three-way valve 445. Then, while passing through the second heat exchanger 430 through the bypass pipe 446 through the branch pipe 447 again joins the heating water inlet pipe 441 and enters the expansion tank 440, in the process The water from the heat storage tank 310 is heated through the two heat exchanger 430 to become hot water.

In addition, the present invention may use the waste heat of the exhaust gas generated during operation of the boiler unit 400, the exhaust gas discharged from the boiler unit 400 is the heat pipe 470 and the exhaust gas recovery heat exchanger (401) The heat pipe 470 that is heat-exchanged and obtains a heat source provides a heat source to the heat exchanger 252 of the fan coil unit unit 250 of the outdoor unit 200.

Therefore, when the outside air intake air temperature drops below zero in the wintertime, and the fins of the heat exchanger 252 are implanted, they become free of heat through the heat pipe 470 that exchanges heat with the waste heat of the exhaust gas of the boiler unit 400. will be.

On the other hand, when the space is to be heated, by changing the flow path of the three-way valve 261 on the connecting pipe 260 so that the refrigerant is sent to the connecting pipe 111 on the indoor unit 100 side, to the indoor unit 100 Provides warmth from the included indoor heat exchanger 110 to provide space heating, four-way valve via the heat exchanger 252 of the fan coil unit 250 of the outdoor unit 200 through the connection pipe 112 It is introduced to the compressor 210 through the 220 again.

In addition, in one embodiment of the present invention shown in Figure 1, through the three-way valve 261, a part of the refrigerant is circulated through the hot water heat exchanger 230 via the three-way valve 262, the remaining part Is introduced into the indoor unit 100 through the connection pipe 111 to allow the space heating

Therefore, in the embodiment according to FIG. 1, the refrigerant may be selectively sent to one desired path through the three-way valve 261, or the refrigerant may be sent to two places so that the space heating and the floor heating may be simultaneously performed. .

[Cooling mode]

Meanwhile, in the cooling mode, as shown in FIG. 2, the high temperature and high pressure refrigerant discharged from the compressor 210 in the outdoor unit 200 moves toward the bypass pipe 263 while passing through the four-way valve 220. By passing through the hot water heat exchanger 230 by the three-way valve (262).

The refrigerant passing through the hot water heat exchanger 230 passes through the heat exchanger 252 of the fan coil unit 250 while passing through the three-way valve 272 through the bypass pipe 271 to the second expansion valve 280. Through the connection pipe 112 is passed through the indoor heat exchanger 110 of the indoor unit (100).

At this time, the high temperature and high pressure refrigerant passing through the heat exchanger 252 and the second expansion valve 280 of the fan coil unit 250 is converted into a low temperature and low pressure refrigerant to the indoor heat exchanger 110 of the indoor unit 100. It provides a cold air through the room, and then the refrigerant is passed through the four-way valve 220 and the accumulator 290 through the connection pipe 260 through the three-way valve 261 through the connecting pipe 111. It forms a process flowing into the compressor (21).

In the case of the cooling mode, mainly in the summer, the boiler unit 400 is not operating.

However, by receiving a part of the refrigerant heat source of the outdoor unit 200 in the heat storage tank 310 of the water tank unit 300 can be utilized as hot water.

In other words, in the hot water heat exchanger 230 provided on the outdoor unit 200 side, the high-temperature and high-pressure refrigerant discharged from the compressor 210 passes, and at this time, water is transferred from the heat storage tank 310 to the circulation pump 332. By taking the heat source (condensation heat) from the high-temperature, high-pressure refrigerant through the hot water heat exchanger 230 through the circulation pipe 330 by the operation and re-supplied to the heat storage tank 310 again through the circulation pipe 340 in a heated state. It can be used as hot water.

In other words, hot water can provide a system that can be used all four seasons.

In addition, in the cooling mode according to an embodiment of the present invention, when the refrigerant is sufficiently condensed in the hot water heat exchanger 230, the refrigerant is transferred from the three-way valve 272 to the heat exchanger of the fan coil unit 250. By bypassing without passing to 252, the air conditioner is cooled by passing the indoor heat exchanger 110 of the indoor unit 100 through the connection pipe 112 through the second expansion valve 280 through the bypass pipe 277. You can lose.

Meanwhile, as shown in FIG. 3, the present invention may simultaneously perform floor heating and space heating.

More specifically, a branch pipe 264 is installed at a point where the connecting pipe 260 on the outdoor unit 200 side and the connecting pipe 111 on the indoor unit 100 side meet and are separated from the branch pipe 264. Flow control valve 113 is provided on the connecting pipe 111, the high-temperature, high-pressure refrigerant discharged from the compressor 210 through the four-way valve 220 and the connecting pipe 260 through the branch pipe (264) Pass through the hot water heat exchanger 230 and at the same time, through the flow control valve 113 passes through the indoor heat exchanger 110 of the indoor unit 100 through the connection pipe 111.

Therefore, the heat source of the outdoor unit 100 can be sent to the bottom heating unit 500 and the indoor unit 100 at the same time, so that the floor heating by the floor heating unit 500 and the space heating by the indoor unit 100 can be simultaneously performed. will be.

Of course, during the cooling operation is performed in the same manner as the embodiment shown in FIG.

In addition, as another embodiment of the present invention, as shown in Figure 5, the waste heat of the exhaust gas from the boiler unit 400 in the process of supplying the heating water by the boiler unit 400 exhaust gas recovery heat exchanger The temperature of the water in the auxiliary tank 480 is recovered by the heat pipe 470 from the 401, and the outdoor unit 200 is connected to the water in the auxiliary tank 480 having a high temperature through the connection pipes 481 and 482. After passing through the fan coil unit 250 of the, and then introduced into the boiler unit 400 again through the connection pipe 483 and the return pipe 520, the fan coil unit unit forming the winter outdoor unit 200 In addition to solving the problem of defrosting the heat exchanger 252 of (250) (defrosting function), water having a certain heat source is sent back into the boiler unit 400, thereby reducing the gas consumption of the boiler unit 400. Can be.

In other words, in the embodiment illustrated in FIG. 5, as in the embodiment illustrated in FIG. 1, only the heat source of the waste gas waste heat of the boiler unit 400 is received through the heat pipe 470, and the fan coil unit unit 250 may be provided. When the defrosting operation is performed when the defrosting operation is performed, the amount of heat of the waste gas waste heat delivered is insufficient, as shown in FIG. Through 482), the heating water circulates to be supplied with some heat source of the heating water to perform the defrost function.

On the other hand, according to the present invention, the heat pump and the boiler unit can be optimally operated according to the outside temperature. For example, when the outside temperature is 3 ° C or higher, the heat pump is operated alone, and the outside temperature is -12 ° C to 2 ° C. The combined operation is performed and the boiler is operated alone at an outside temperature of -13 ℃.

The operating conditions for each outside temperature are not limited thereto, and the outside temperature conditions may vary depending on the situation.

In addition, the present invention is capable of a smart driving function. General energy priority operation, carbon dioxide emission priority operation, energy cost priority operation, and power peak avoidance operation can be performed.

In other words, the integrated energy priority operation compares the operating efficiency of the heat pump and the boiler unit according to the outside temperature. For example, when the outside temperature is 3 ° C or higher, the heat pump is operated alone. The heat pump is operated first, and in case of insufficient load, the combined operation of auxiliary operation of the boiler unit is performed.

In addition, the boiler is operated alone at an outside temperature of −13 ° C. or lower.

In addition, carbon dioxide emission preferential operation is to operate a heat pump that emits less carbon dioxide in a region that regulates carbon dioxide generation.

In addition, the energy cost priority operation is to selectively operate the boiler and the heat pump so as to minimize the cost per calorie by comparing the electricity and gas bill per unit calories.

In addition, the power peak avoidance operation is to perform the boiler priority operation to avoid the power peak when there is a power peak restriction.

According to the present invention, the heat pump, the boiler unit, and the water tank unit may be integrally formed to reduce the size of the heat pump. If the installation space is restricted, the heat storage tank of the water tank unit may be separately installed.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. It will be possible. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

1: hybrid heat pump boiler system
100: indoor unit
110: indoor heat exchanger
111,112: Connection piping
113,114: Flow control valve
120: blower
200: outdoor unit
210: compressor
220: 4-way valve
230: hot water heat exchanger
240: first expansion valve
250: fan coil unit
251 blower
252: heat exchanger
260 connection pipe
261,262: 3-way valve
263: Bypass piping
264: branch pipe
270 connection pipe
271: bypass piping
271a: valve
272: 3-way valve
273: branch pipe
274: check valve
275: Connection piping
276: check valve
280: second expansion valve
290: Accumulator
300: water tank unit
310: heat storage tank
311: water supply pipe
312: pressure reducing valve
313: drain pipe
320: heating water heat exchanger
330: circulation piping
331: 3-way valve
332: circulation pump
340: circulation piping
341,342: bypass piping
343: 3-way valve
400: boiler unit
401: exhaust gas recovery heat exchanger
410: burner
420: first heat exchanger
430: second heat exchanger
440: expansion tank
441: heating water inlet pipe
442,443: Supply piping
444: Pump
445: 3-way valve
446: bypass piping
447: branch pipe
450: inlet pipe
451: 3-way valve
460: discharge piping
470: heat pipe
480: auxiliary tank
481,482,483: Connection piping
484: Valve
485: drain pipe
500: floor heating unit
510: connecting pipe
512 pump
520: connecting pipe
521: 3-way valve
522: bypass piping
523: supply piping

Claims (15)

As a hybrid heat pump boiler system in which the outdoor unit 200 and the water tank unit 300 and the boiler unit 400 are integrally connected to the indoor unit 100 to form a heat pump,
The outdoor unit 200,
A compressor 210 for compressing the refrigerant at high temperature and high pressure;
Four-way valve 220 for changing the flow path of the refrigerant discharged from the compressor 210;
A hot water heat exchanger 230 for exchanging heat with water in the water tank unit 300 while the refrigerant passing through the four-way valve 220 passes;
First and second expansion valves 240 and 280 for reducing the pressure and temperature of the refrigerant passing through the hot water heat exchanger 230;
And a fan coil unit unit 250 through which the refrigerant passing through the first expansion valve 240 passes through to perform heat exchange.
The water tank unit 300,
A heat storage tank 310 provided with circulation pipes 330 and 340 for circulating water through the hot water heat exchanger 230 of the outdoor unit 200;
A heating water heat exchanger 320 provided with a connection pipe 510 for heating, and connected with a return pipe 520 for connecting the connection pipe 510 and returning the heating water to the boiler unit 400; It consists of
The boiler unit 400 is connected to an exhaust gas recovery heat exchanger 401 provided at a position at which exhaust gas is discharged, and heat-exchanges with the exhaust gas discharged to supply a heat source to the fan coil unit 250 of the outdoor unit 200. Hybrid heat pump boiler system characterized in that the heat pipe 470 is provided to be delivered.
The method according to claim 1,
The first expansion valve 240 is provided in the connection pipe 270 connected to the fan coil unit 250 through the hot water heat exchanger 230 from the four-way valve 220, the second expansion valve 280 The hybrid heat pump boiler system, characterized in that provided on the connection pipe 112 is connected to the indoor unit (100).
The method according to claim 2,
Two three-way valves 261 and 262 are provided on the connection pipe 260 between the four-way valve 220 and the hot water heat exchanger 230, and one of the three-way valves 261 includes an indoor unit 100. Is connected to the connection pipe 111 passing through the indoor heat exchanger 110 of the other, and the other three-way valve 262 is bypassed from the connection pipe 260 and connected to the four-way valve 220 Hybrid heat pump boiler system, characterized in that connected to (263).
The method according to claim 3,
Hybrid heat pump boiler system, characterized in that the bypass pipe 271 is bypassed is connected to the connection pipe 112 connected to the fan coil unit 250 is bypassed.
The method of claim 4,
The bypass pipe 271 is provided with a three-way valve 272 located at the tip of the fan coil unit 250, the three-way valve 272 and the connection pipe 112 for passing the indoor unit 100 and The connection pipe 270 passing through the hot water heat exchanger 230 is combined through the branch pipe (273) is connected through the fan coil unit 250, characterized in that the hybrid heat pump boiler system.
The method according to claim 5,
Bypass pipe 263 is bypassed from the connecting pipe 260 is connected to the four-way valve 220, and the connecting pipe is bypassed from the connecting pipe 270 and connected to the fan coil unit 250 ( Bypass piping 271 connected to 112,
Are connected to each other through a connection pipe (275), so that the refrigerant is allowed to move to the compressor (210) in the heating mode.
The method of claim 6,
Hybrid heat pump boiler system, characterized in that the bypass pipe (277) is connected between the connection pipe 111 and the indoor unit 100 is connected to the three-way valve 272 of the bypass pipe (271). .
The method of claim 7,
Boiler unit 400 is a hybrid heat pump boiler system, characterized in that connected to the floor heating unit 500 to circulate the heating water to achieve the floor heating.
The method according to claim 8,
A three way valve 331 is provided on the circulation pipe 330, and the three way valve 331 is bypassed from the circulation pipe 340 and is connected through a heating water heat exchanger 320 to the bypass pipe 341. Hybrid heat pump boiler system, characterized in that the 342 is provided.
The method according to claim 9,
At the branch point to the circulation pipe 340 and the bypass pipe 341, water from the heat storage tank 310 passes through the hot water heat exchanger 230 and then flows into the heating water heat exchanger 320 or the heat storage tank 310. Hybrid heat pump boiler system characterized in that it comprises a three-way valve (343) to be made selectively or simultaneously.
The method of claim 10,
The three-way valve 521 is provided on the return pipe 520, and the bypass pipe 522 connected to the three-way valve 521 to supply heating water to the floor heating unit 500 is provided. Hybrid Heat Pump Boiler System.
The method of claim 11,
The boiler unit 400 is connected to the heat storage tank 310, characterized in that the inlet pipe 450 and the discharge pipe 460 to be discharged through the second heat exchanger 430 in the boiler unit 400 is connected. Hybrid heat pump boiler system.
The method of claim 12,
The inlet pipe 450 is provided with a three-way valve 451 is connected to the discharge pipe 460 is characterized in that the water from the heat storage tank 310 can be used to directly take out the hot water without passing through the boiler unit 400 Hybrid heat pump boiler system.
The method according to claim 2,
A branch pipe 264 is provided at a point where the connection pipe 260 of the outdoor unit 200 and the connection pipe 111 of the indoor unit 100 meet, and the connection pipe 111 and the branch pipe 264 of the indoor unit 100 are provided. Hybrid heat pump boiler system, characterized in that the space heating and floor heating is carried out at the same time by having at least one of the flow control valve 113, 114 on each of the connecting pipe (260).
As a hybrid heat pump boiler system in which the outdoor unit 200 and the water tank unit 300 and the boiler unit 400 are integrally connected to the indoor unit 100 to form a heat pump,
The outdoor unit 200,
A compressor 210 for compressing the refrigerant at high temperature and high pressure;
Four-way valve 220 for changing the flow path of the refrigerant discharged from the compressor 210;
A hot water heat exchanger 230 for exchanging heat with water in the water tank unit 300 while the refrigerant passing through the four-way valve 220 passes;
First and second expansion valves 240 and 280 for reducing the pressure and temperature of the refrigerant passing through the hot water heat exchanger 230;
And a fan coil unit unit 250 through which the refrigerant passing through the first expansion valve 240 passes through to perform heat exchange.
The water tank unit 300,
A heat storage tank 310 provided with circulation pipes 330 and 340 for circulating water through the hot water heat exchanger 230 of the outdoor unit 200;
A heating water heat exchanger 320 provided with a connection pipe 510 for heating, and connected with a return pipe 520 for connecting the connection pipe 510 and returning the heating water to the boiler unit 400; It consists of
The heat source is connected to a heat pipe 470 which is connected to an exhaust gas recovery heat exchanger 401 formed at a position where the exhaust gas of the boiler unit 400 is discharged and recovers a heat source of the exhaust gas generated from the boiler unit 400. The auxiliary tank 480 is provided, which is connected to the auxiliary tank 480 branched from the bypass pipe 522 to pass through the heat exchanger 252 of the fan coil unit 250 of the outdoor unit 200 ( 481) and 482 are connected, one side of the auxiliary tank 480 is connected to the return pipe 520 is characterized in that the connection pipe 483 is provided so that the hot water is joined to enter the boiler unit 400. Hybrid heat pump boiler system.

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