KR20130130265A - Hybrid system combined boiler and heat pump - Google Patents

Abstract

The present invention relates to a hybrid system combining a boiler and a heat pump, and more specifically to a hybrid system combining a boiler and a heat pump that not only has advantages of both boiler and heat pump by mutual linkage while being simultaneously equipped with a boiler and a heat pump allowing supplementation of boiler's disadvantages with a heat pump and supplementation of heat pump's disadvantages with a boiler but also guarantees plenty of hot water and heating water reserves. [Reference numerals] (124) Indoor unit;(AA) Hot water;(BB) Water supply;(CC) Heating;(Ct) Controller

Description

[0001] The present invention relates to a hybrid system combining a boiler and a heat pump,

The present invention relates to a hybrid system in which a boiler and a heat pump are connected to each other. More particularly, the present invention relates to a hybrid system in which a boiler and a heat pump are provided at the same time, The disadvantages of the heat pumps, which are supplemented by pumps, are that they complement the boiler, as well as a hybrid system that combines a boiler and a heat pump to ensure a sufficient amount of hot water or heating water.

Boiler is a device that uses fossil fuel and uses heat generated by burning in burner. It is convenient to use and can instantly provide hot water or heating water at high temperature. On the other hand, efficiency can not exceed 100% Technology has reached the limit of increasing efficiency, and greenhouse gas emissions and energy savings are also insignificant.

On the other hand, since the heat pump absorbs heat from a low-temperature heat source (air, hydrothermal, geothermal, and other waste heat sources) during circulation of the refrigerant cycle, it supplies more energy in the form of heat using less energy (COP), which means the ratio of energy required (heating and cooling) to the energy required, has a value of 3 or more.

However, since such a heat pump has a lower outgoing water temperature, lower outdoor temperature, reduced ability in defrosting operation, higher noise during operation, and higher power consumption than the above-described boiler, It is practically difficult to replace existing boilers.

In Europe and Japan, for example, a hybrid system having a boiler and a heat pump at the same time is provided. For example, as shown in FIG. 1, in Japan, a heat pump, a water heater and a heat storage tank .

Therefore, hot water can be stored in the heat storage tank by using a heat pump, or heated water or hot water can be discharged by using a water heater, or hot water can be stored in the heat storage tank for use.

However, in the conventional hybrid system as described above, the interconnectivity (or interlockability) between the boiler and the heat pump is very small, and the boiler and the heat pump are merely separated from each other.

Therefore, even if the boiler and the heat pump are driven independently of each other or used in conjunction with each other, hot water is stored in the heat storage tank using both the boiler and the heat pump, and only the level of hot water is used.

The present invention has been proposed in order to solve the above-mentioned problems. The boiler and the heat pump are provided at the same time, but they are connected to each other so that the advantage of the boiler and the advantage of the heat pump are complemented by the heat pump. The disadvantage of the heat pump is to provide a hybrid system that combines a boiler and a heat pump to ensure a sufficient amount of hot water or heating water.

To this end, a hybrid system in which a boiler and a heat pump according to the present invention are combined includes a heat exchange tank having a space for storing water therein, a burner for burning fuel and ejecting a flame and a combustion gas into the heat exchange tank, And a first condenser installed in the heat exchange tank and connected to discharge the combustion gas generated when the burner is burned and a tube installed inside the heat exchange tank and circulating the refrigerant therein, ; A first refrigerant cycle including a compressor, a second condenser, an evaporator, and an indoor unit, wherein the refrigerant circulates the compressor, the first condenser of the boiler, the second condenser, and the evaporator; A heat pump for selectively forming a second refrigerant cycle circulating through the first condenser and the indoor unit of the boiler; An auxiliary tank for receiving and temporarily storing the heating circulation water stored in the heat exchange tank of the boiler by operating at least one of the boiler and the heat pump; And the heating coil and the main circulating coil are respectively installed in the heating coil and the heating coil, the inlet side of the heating coil is connected to the outlet side of the heating device, the outlet side of the heating coil is connected to the inlet side of the heating device, The water supply side is connected to a water supply device, the water supply side of the main circulation coil is connected to a hot water supply device, and a low water tank inlet through which water stored in the auxiliary tank is introduced into the one side through a first circulation pipe, And a low-temperature tank in which water stored in the low-temperature tank is discharged to the heat-exchange tank of the boiler through a second circulation pipe.

At this time, it is preferable that the auxiliary tank is provided with an auxiliary circulation coil, the inlet side of the auxiliary circulation coil is commonly connected to the water supply device, and the outlet side of the auxiliary circulation coil is connected to the hot water supply device in common.

The auxiliary port is connected to the common port of the three-way valve, and the first branch port of the three-way valve is connected to the auxiliary port of the three- And the second branch port of the three-way valve is connected to the inlet side of the heat exchange tank through the second circulation pipe.

The first circulation pipe is extended so as to be commonly connected to the inlet side of the heating device so that the circulation water flowing through the first circulation pipe can be supplied to the low- The first circulation pipe is provided with a first selection valve,

The second circulation pipe is connected to the outflow side of the heating device such that the circulation water exiting from the heating device can be supplied to the heat exchange tank of the boiler through the second circulation pipe or to the heating coil of the low- And the second circulation pipe is provided with a second selection valve.

It is preferable that the auxiliary tank is a wall-mounted type.

In addition, it is preferable that a condensate water reservoir for storing condensation water generated when the combustion gas generated during the burning of the burner is lowered to a dew point temperature or less after heat exchange is installed in the lower part of the boiler.

In addition, a condensate water guide plate for guiding the condensed water to be collected into the condensed water storage tank is installed in a lower portion of the boiler, and the condensed water guide plate is sealed so that the high temperature combustion gas generated from the boiler is discharged only through the exhaust gas outlet .

Also, the heat pump is exposed to a combustion gas exhaust port through which the high temperature combustion gas generated in the boiler is discharged, recovers latent heat of the combustion gas, recovers the latent heat recovery heat exchanger adjacent to the evaporator, and the heat recovered from the latent heat recovery heat exchanger And a blower for blowing heat to the evaporator so as to be discharged toward the evaporator.

The latent heat recovery heat exchanger includes a heat exchange body having one side connected to the combustion gas exhaust port, a plurality of heat exchange fins formed in the heat exchange body, and a flow guide plate extending from the combustion gas exhaust port to the inside of the heat exchange body, It is preferable that the combustion gas being discharged through the exhaust port is discharged after circulating the inside of the heat exchange body by the flow guide plate.

The heat pump blower may include a first air outlet and a second air outlet for blowing air toward the latent heat recovery heat exchanger through the first air outlet or through the second air outlet, It is preferable that the air is blown.

In addition, an indoor air supply port is provided at one side of the second condenser, and the air blown by the blower for the heat pump flows through the second condenser to the other side of the second condenser, It is preferable to provide the above-

In addition, it is preferable that the combustion blower of the boiler and the boiler pump for circulating the water in the burner and the heat exchange tank are independently operated by the controller.

In the present invention as described above, the refrigerant of the heat pump circulates through the boiler and absorbs or dissipates heat, stores the hot water supplied from the boiler and the heat pump through the auxiliary tank, and provides the hot water as well as the hot water. The heat of the boiler is recovered through the latent heat recovery heat exchanger and the hot water supply or heating can be selectively provided by the boiler and the heat pump through the three-way valve or the like.

Therefore, the boiler and the heat pump are connected to each other to have both the merit of the boiler and the advantage of the heat pump. At the same time, the disadvantage of the boiler is complemented by the heat pump and the disadvantage of the heat pump is complemented by the boiler, The temperature also has various effects such as height.

In addition, the present invention includes both a heat exchange tank of a boiler, an auxiliary tank connected to the heat exchange tank, and a low-temperature tank connected to the auxiliary tank, and can store hot water or heating water, respectively, A hybrid system in which a boiler and a heat pump can be guaranteed.

1 is a block diagram showing a boiler and a heat pump hybrid system according to the prior art.
Figure 2 is a block diagram showing a hybrid system in conjunction with a boiler and a heat pump according to the present invention.
3 is a view showing a heat pump heating state of a hybrid system in which a boiler and a heat pump are connected according to the present invention.
Figure 4 is a view showing a heat pump hot water supply state of the hybrid system in conjunction with the boiler and the heat pump according to the present invention.
5 is a view showing a boiler + heat pump heating state of a hybrid system in which a boiler and a heat pump in accordance with the present invention.
6 is a view showing a boiler + heat pump hot water supply state of a hybrid system in which a boiler and a heat pump are connected according to the present invention.
7 is a view showing a boiler heating state of a hybrid system in which a boiler and a heat pump are connected according to the present invention.
8 is a view illustrating a boiler hot water supply state of a hybrid system in which a boiler and a heat pump according to the present invention are connected.
FIG. 9 is a view illustrating a heat pump cooling state of a hybrid system in which a boiler and a heat pump are connected in accordance with the present invention.

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

As shown in FIG. 2, the hybrid system in which the boiler according to the present invention is combined with the heat pump includes a boiler (not shown) for supplying and heating fossil fuel to supply hot water, A heat pump 120 for circulating a refrigerant with electric energy to supply hot water and heating the hot circulation water; an auxiliary circulating unit 120 for temporarily storing and supplying the hot circulation water provided by the boiler 110 and the heat pump 120; And a storage tank 140 for receiving heat circulation water supplied from the tank 130 and the auxiliary tank 130 and performing heat exchange for supplying hot water or heat exchange for supplying hot water.

Particularly, since the refrigerant of the heat pump 120 circulates through the boiler 110 and absorbs or dissipates heat, the boiler 110 and the heat pump 120 are completely connected to each other, and the boiler 110 and the heat pump 120 The hot circulation water is stored in the auxiliary tank 130 and the low-temperature bath 140 as hot water or heating water, and the heat of the combustion gas in the boiler 110 being discharged is passed through the latent heat recovery heat exchanger 125 Side valve 3W_V and the like to selectively supply hot water or heating water through the boiler 110 and the heat pump 120. [

The boiler 110 and the heat pump 120 are connected to each other to have both the merits of the boiler 110 and the advantages of the heat pump 120 while the disadvantage of the boiler 110 is complemented by the heat pump 120 And the disadvantage of the heat pump 120 is that it can be supplemented by the boiler 110, so that it is highly efficient, environmentally friendly, and also has a high outgoing temperature. In addition, an enriched amount of hot water or heating water can always be stored and supplied through the heat exchange tank 111 of the boiler 110, the auxiliary tank 130 and the low-temperature bath 140.

To this end, the boiler 110 includes a heat exchange tank 111 having a space in which water is stored, a burner 112 for burning the fuel to blow out the flame and the combustion gas into the heat exchange tank 111, A combustion air blower 113 for supplying combustion air to the combustion chamber 112, an association 114 installed in the heat exchange tank 111 for discharging the combustion gas generated when the burner 112 is burned, And a first condenser 115 formed of a tube through which refrigerant circulates.

A condensate water reservoir 116 is installed in the lower part of the boiler 110 to store condensed water generated when the combustion gas generated during combustion of the burner 112 is cooled to a temperature below the dew point temperature after heat exchange.

A condensate water guide plate 117 for guiding the condensed water to be collected into the condensate water reservoir 116 is installed in the lower portion of the boiler 110. The condensate water reservoir 116 and the condensate water guide plate 117 are connected to each other at a high temperature Is exhausted only through the combustion gas exhaust port (G).

The combustion blower 113 of the boiler 110 and the boiler pump P_B for circulating the water in the burner 112 and the heat exchange tank 111 are independently operated by the controller Ct. Therefore, only the blower 113 for cooling during the cooling operation is operated to cool the first condenser 115 of the boiler 110 with the cool outside air or the boiler pump P_B to operate the heat exchange tank 111, So that the first condenser 115 can be cooled by the circulating water through at least one of the first condenser 130 and the low-temperature bath.

Of course, when the hot water or the heating water is supplied, the burner 112 as well as the combustion blower 113 and the boiler pump P_B are also operated to heat and circulate the water.

The heat pump 120 includes a compressor 121 connected to the refrigerant pipe P via a refrigerant pipe P, a second condenser 122, an evaporator 123, and an indoor unit 124. The first solenoid valve SV1, The first refrigerant cycle through which the refrigerant circulates through the compressor 121, the first condenser 115 of the boiler 110, the second condenser 122 and the evaporator 123 via the fourth solenoid valve SV4, The refrigerant is configured to selectively form a second refrigerant cycle in which the refrigerant circulates through the compressor 121, the second condenser 122, the first condenser 115 of the boiler 110, and the indoor unit 124.

The first refrigerant cycle is used to supply hot water or heating water to the heat pump 120 alone or together with the boiler 110. The first solenoid valve SV1 and the second solenoid valve SV2 in the controller Ct, And the third solenoid valve SV3 and the fourth solenoid valve SV4 are closed.

The first solenoid valve SV1 and the second solenoid valve SV2 are closed in the controller Ct and the third solenoid valve SV2 is closed in the controller Ct. The third solenoid valve SV3 and the fourth solenoid valve SV4 are opened.

The heat pump 120 is exposed to the combustion gas exhaust port G where the high temperature combustion gas generated in the boiler 110 is discharged to recover the latent heat of the combustion gas and is disposed adjacent to the evaporator 123 of the heat pump 120 And a heat pump blower 126 for blowing heat recovered from the latent heat recovery heat exchanger 125 and the latent heat recovery heat exchanger 125 toward the evaporator 123.

The latent heat recovery heat exchanger 125 includes a heat exchange body 125a having one side exposed to the combustion gas exhaust port G and a plurality of heat exchange fins 125b and a combustion gas exhaust port G formed on the heat exchange body 125a. And a flow guide plate 125c extending to the inside of the heat exchange body 125a. Therefore, the combustion gas discharged through the combustion gas exhaust port G is circulated in the zigzag direction by the flow guide plate 125c and then discharged inside the heat exchange body 125a.

The blower 126 for the heat pump includes a first air outlet 126a and a second air outlet 126b as exhaust ports in addition to the intake port so that the latent heat is recovered through the first air outlet 126a when hot water is supplied or heated. Air is blown toward the heat exchanger 125 and air is blown toward the second condenser 122 through the second air outlet 126b during cooling.

The method of selectively supplying air through the first air outlet 126a and the second air outlet 126b may be performed by switching the direction of rotation of the blower fan or by switching the first air outlet 126a and the second air outlet 126b, And a shutter (not shown) may be respectively installed on the shutter unit and selectively opened and closed. Of course, two blowers may be provided separately if the size and cost of the installation are not taken into consideration.

An indoor air supply port 122a is provided at one side of the second condenser 122 and air blown by the heat pump blower 126 is supplied to the other side of the second condenser 122 through the second condenser 122 And an air outlet 122b for discharging the air to the outside.

Therefore, when hot water or heating water is supplied, the air introduced into the boiler room through the indoor air inlet I passes through the indoor air supply port 122a, the first air outlet 126a of the heat pump blower 126, , The evaporator (123), and the blower outlet (A).

On the other hand, at the time of cooling, the air introduced through the room air inlet I passes through the indoor air supply port 122a, the second air outlet 126b of the heat pump blower 126, the second condenser 122, And is discharged to the outside through the air outlet 122b.

The auxiliary tank 130 is supplied with the heating circulation water stored in the heat exchange tank 111 of the boiler 110 by operating at least one of the boiler 110 and the heat pump 120, Temporarily stored and then supplied to the low-temperature bath (140) or directly supplied with hot water.

To this end, an auxiliary circulation coil 131 is installed in the auxiliary tank 130. The inlet side of the auxiliary circulation coil 131 is commonly connected to the water supply unit 160 through a water supply pipe 161, 131 are commonly connected to the hot water supply unit 170 through a hot water pipe 171. [

One side of the auxiliary tank 130 is provided with an auxiliary inlet IN_T connected to the outlet side of the heat exchange tank 111 and an auxiliary outlet OUT_T connected to the common port c of the three- ). The first branch port n1 of the remaining three-way valve 3W_V is connected to the first circulation pipe CP1 to be described later and the second branch port n2 is connected to the heat exchange tank CP2 via the second circulation pipe CP2, (111).

Therefore, the heating circulation water supplied from the heat exchange tank 111 of the boiler 110 is supplied through the auxiliary inlet IN_T of the auxiliary tank 130, and the supplied heating circulation water is supplied to the auxiliary outlet 130 of the auxiliary tank 130, The hot-water tank 140 is supplied to the boiler 110 through the outdoor heat exchanger OUT_T and is returned to the heat-exchanging tank 111 of the boiler 110, so that a sufficient amount of the heat-circulating water can be stored.

In addition, when it is desired to supply the hot water for hot water supply, the hot water supplied from the water supply unit 160 is passed through the auxiliary circulation coil 131, and hot water having a high temperature through the heat exchange in this process passes through the hot water tank 140, To be supplied directly to the feeder 170.

It is preferable that the auxiliary tank 130 is a wall-mounted type having a relatively small size and a thinner thickness than the low-temperature tank 140. If the auxiliary tank 130 is a wall- The hybrid system according to the present invention can be used in ordinary households as in the past.

The low-temperature bath 140 is provided for significantly increasing the amount of the hot water or the heating water when it is supplied. The heating coil 141 and the main circulation coil 142 are installed in the interior of the low- The heating coil 141 is connected to the outlet side of the heating device 150 through a water outlet pipe 151. The outlet side of the heating coil 141 is connected to the inlet side of the heating device 150 through a heating water inlet pipe 152, The inlet side of the coil 142 is connected to the water supply unit 160 through a water supply pipe 161 and the water discharge side of the main circulation coil 142 is connected to the hot water supply unit 170 through a hot water pipe 171.

In addition, a low-temperature tank inlet 140a through which the water stored in the auxiliary tank 130 is introduced through the first circulation pipe CP1 is installed at one side of the low-temperature tank 140, And a low-flood tank outlet 140b through which the water exits to the heat-exchange tank 111 of the boiler 110 through the second circulation pipe CP2.

The first circulation pipe CP1 is connected to the heating device 150 so that the circulation water flowing through the first circulation pipe CP1 can be supplied to the hot water tank inlet 140a or to the heating device 150 The first circulation pipe CP1 is provided with a first selection valve SELV1 which is opened and closed by the controller Ct.

The circulation water taken out from the heating device 150 is supplied to the heat exchange tank 111 of the boiler 110 through the second circulation pipe CP2 or to the heating coil 141 of the low- The second circulation pipe CP2 is extended to be commonly connected to the outflow side of the heating device 150. At this time, the second circulation pipe CP2 is provided with a second circulation pipe CP2, A selector valve SELV2 is provided.

Therefore, when it is desired to ensure an abundant storage amount by using the low-temperature bath 140, the heating circulation water supplied from the auxiliary tank 130 is supplied to the low-temperature bath 140, and the heating coil 141 is circulated Or heat exchange with the water circulating through the main circulation coil 142 so as to supply the hot water.

On the other hand, when it is desired to supply hot water at a high temperature without using the low-temperature bath (140), the heating circulation water supplied from the auxiliary tank (130) is circulated directly to the heating device (150) .

Hereinafter, various operation modes of the hybrid system in which the boiler and the heat pump according to the present invention constructed as described above are combined will be described.

Hereinafter, the heating and hot water supply using the heat pump 120, the heating and hot water supply using the boiler 110 and the heat pump 120, the heating and hot water supply using the boiler 110, Although the cooling using the boiler 110 is described as an example, the present invention can be operated in various other operation modes.

The circulation of water, the circulation of the refrigerant, and the circulation of the water and the refrigerant, which are described below, are examples of preferable circulation paths. The present invention is characterized in that the water and the refrigerant can circulate along more various circulation paths Do.

3, the refrigerant is circulated through the compressor 121, the first condenser 115 installed in the boiler 110, the heat pump 120, And a second solenoid valve SV1 and a second solenoid valve SV2.

Accordingly, the refrigerant compressed at high temperature and high pressure in the compressor 121 heats the direct water filled in the heat exchange tank 111 of the boiler 110 through heat exchange to make the heating circulation water, and the heating circulation water is supplied to the boiler water outlet pipe 110a And is supplied to the auxiliary tank 130 through the auxiliary inlet IN_T of the auxiliary tank 130.

The heating circulation water stored in the auxiliary tank 130 is circulated through the auxiliary outlet port OUT_T, the common port c of the three-way valve 3W_V, the first branch port n1, the first circulation pipe CP1, And the hot water circulating along the heating coil 141 and the hot circulation water at the high temperature stored in the low-temperature bath 140 are heat-exchanged with each other through the low-temperature bath inlet 140a, Thereby heating the area where the water channel heating device 150 is installed.

The heating circulation water whose temperature has been lowered after the heat exchange with the heating water circulating in the heating coil 141 is circulated through the lower circulation pipe outlet 140b and the second circulation pipe CP2 and the boiler inlet pipe 110b, Is recovered to the heat exchange tank 111, and at this time, the boiler pump P_B is continuously operated to maintain the heating state.

Also, by operating the blower 126 for the heat pump while circulating the refrigerant as described above, the relatively warm room air introduced through the indoor air inlet I is supplied to the evaporator 123 through the indoor air inlet 122a Thereby preventing the supercooling of the refrigerant and increasing the COP (coefficient of performance).

The cooled air after passing through the evaporator 123 is discharged to the outside through the air blowing exhaust port (A), thereby preventing cold air from entering the room.

4, when hot water is supplied using only the exciter heat pump 120, the refrigerant is supplied to the compressor 121, the first condenser 115 installed in the boiler 110, the heat pump 120 and the second solenoid valve SV1 and the second solenoid valve SV2.

Accordingly, the refrigerant compressed at high temperature and high pressure in the compressor 121 heats the direct water filled in the heat exchange tank 111 of the boiler 110 through heat exchange to make the heating circulation water, and the heating circulation water is supplied to the boiler water outlet pipe 110a And is supplied to the auxiliary tank 130 through the auxiliary inlet IN_T of the auxiliary tank 130.

The heating circulation water stored in the auxiliary tank 130 is circulated through the auxiliary outlet port OUT_T, the common port c of the three-way valve 3W_V, the first branch port n1, the first circulation pipe CP1, The water circulated through the main circulation coil 142 is supplied to the low-temperature bath 140 through the low-temperature bath inlet 140a and the water supplied from the water supply 160 to the water supply side of the main circulation coil 142 passes through the main circulation coil 142 And the hot water whose temperature has been raised is supplied to the hot water supplier 170 through the water outlet side of the main circulation coil 142.

The heating circulation water whose temperature has been lowered after completion of the heat exchange with the direct circulating coil 142 is circulated through the low flow circulation outlet 140b and the second circulation pipe CP2 and the boiler inlet pipe 110b, And is returned to the heat exchange tank 111. At this time, the boiler pump P_B is continuously operated to maintain the hot water supply state.

Of course, as described above, since the circulation path of the water varies as described above, the present invention can be applied to a case where, for example, a direct water supplied through the water dispenser 160 circulates the auxiliary circulation coil 131, It is obvious that a cycle for directly supplying the gas to the feeder 170 may be formed at the same time.

By operating the blower 126 for the heat pump while circulating the refrigerant as described above, the room air introduced through the room air inlet I is supplied to the evaporator 123 through the room air inlet 122a, To prevent the supercooling of COP and increase the COP.

The cooled air after passing through the evaporator 123 is discharged to the outside through the air blowing exhaust port (A), thereby preventing cold air from entering the room.

5, when heating is performed using the winter boiler 110 and the heat pump 120, the refrigerant is circulated through the compressor 121, the first condenser 115 installed in the boiler 110, The second condenser 122 installed in the boiler 110 and the water stored in the heat exchange tank 111 of the boiler 110 in the process of circulating along the first solenoid valve SV1 and the second solenoid valve SV2 .

In addition, by operating the combustion blower 113 of the boiler 110 and simultaneously combusting the fuel in the burner 112, the flame generated in the burner 112 is heat-exchanged with the hot combustion gas discharged along the association 114 The water stored in the tank 111 is heated and the temperature of the water together with the heat pump 120 is quickly raised to a high temperature.

The heating circulating water supplied to the auxiliary tank 130 in the heat exchange tank 111 is supplied to the auxiliary outlet port OUT_T, the common port c of the three-way valve 3W_V, the first branch port n1, The hot water circulating through the heating coil 141 and the hot circulating water at a high temperature stored in the low-temperature bath 140 are supplied to the low-temperature bath 140 through the first circulation pipe CP1 and the low- And heat the area where the heating device 150 is installed with the heated water having a higher temperature because of the heat exchange.

The heating circulation water whose temperature has been lowered after the heat exchange with the heating water circulating in the heating coil 141 is circulated through the lower circulation pipe outlet 140b and the second circulation pipe CP2 and the boiler inlet pipe 110b, Is recovered to the heat exchange tank 111, and at this time, the boiler pump P_B is continuously operated to maintain the heating state.

The high temperature combustion gas discharged through the association 114 of the boiler 110 passes through the latent heat recovery heat exchanger 125 of the heat pump 120 in the zigzag direction and the heat pump blower 126 is operated The latent heat of the combustion gas recovered in the latent heat recovery heat exchanger 125 is supplied to the evaporator 123. Therefore, not only the defrosting effect which prevents the refrigerant from being supercooled in the winter season but also the COP is improved by raising the temperature of the refrigerant.

The cooled air after passing through the evaporator 123 is discharged to the outside through the air blowing exhaust port A so that cold air is prevented from flowing into the room and the air discharged through the combustion gas exhaust port G is discharged outdoors Thereby preventing the harmful combustion gas from flowing into the room.

6, when hot water is supplied using the winter boiler 110 and the heat pump 120, the refrigerant is supplied to the compressor 121, the first condenser 115 installed in the boiler 110, The second condenser 122 installed in the pump 120 heats the water stored in the heat exchange tank 111 of the boiler 110 in the process of circulating along the first solenoid valve SV1 and the second solenoid valve SV2 do.

In addition, by operating the combustion blower 113 of the boiler 110 and simultaneously combusting the fuel in the burner 112, the flame generated in the burner 112 is heat-exchanged with the hot combustion gas discharged along the association 114 The water stored in the tank 111 is heated and the temperature of the water together with the heat pump 120 is quickly raised to a high temperature.

The heating circulation water supplied from the heat exchange tank 111 to the auxiliary tank 130 is supplied to the auxiliary port OUT_T, the common port c of the three-way valve 3W_V, the first branch port n1, The water circulated through the main circulation coil 142 is supplied to the water supply tank 140 through the first circulation pipe CP1 and the low water tank inlet 140a, The hot water having a high temperature is supplied to the hot water supplier 170 through the water outlet side of the main circulation coil 142. [

The heating circulation water whose temperature has been lowered after completion of the heat exchange with the direct circulating coil 142 is circulated through the low flow circulation outlet 140b and the second circulation pipe CP2 and the boiler inlet pipe 110b, And is returned to the heat exchange tank 111. At this time, the boiler pump P_B is continuously operated to maintain the hot water supply state.

The high temperature combustion gas discharged through the association 114 of the boiler 110 passes through the latent heat recovery heat exchanger 125 of the heat pump 120 in the zigzag direction and the heat pump blower 126 is operated The latent heat of the combustion gas recovered in the latent heat recovery heat exchanger 125 is supplied to the evaporator 123, thereby achieving the COP improvement effect as well as the cold defrosting effect.

After passing through the evaporator 123, the cooled air and the air discharged through the combustion gas exhaust port (G) are discharged to the outside of the room.

7, when the heating is performed rapidly using only the winter boiler 110, the combustion blower 113 of the boiler 110 is operated and the fuel is burned in the burner 112, so that the burner 112 And the flame generated in the heat exchange tank 111 and the hot combustion gas discharged along the association 114. The temperature of the water in the heat exchange tank 111 is raised to a high temperature as soon as possible.

The high temperature heating circulation water supplied from the heat exchange tank 111 of the boiler 110 to the auxiliary tank 130 is supplied to the auxiliary outlet port OUT_T, the common port c of the three-way valve 3W_V, When the refrigerant is supplied to the heating device 150 through the branch port n1, the first circulation pipe CP1, the first selection valve SELV1 opened by the controller Ct and the heating water inlet pipe 152, The apparatus 150 heats the corresponding zone using the heating circulation water.

The heating water that has been heated is discharged through the heating water outlet pipe 151, the second selection valve SELV2 opened by the controller Ct, the second circulation pipe CP2 and the boiler inlet pipe 110b, 110, and the heating state is maintained as the water circulation as described above is continued by the boiler pump P_B.

At this time, since the heat pump 120 is in the operation stop state, the heat pump blower 126 is kept in a stopped state, and the exhaust gas passes through the latent heat recovery heat exchanger 125, .

8, when hot water is rapidly supplied using only the winter boiler 110, the combustion blower 113 of the boiler 110 is operated and the fuel is burned in the burner 112, The flame generated in the heat exchange tank 112 and the flue gas discharged along the connection 114 heat the water stored in the heat exchange tank 111 and raise the temperature of the water to a high temperature as soon as possible.

The high temperature heating circulation water supplied from the heat exchange tank 111 of the boiler 110 is stored in the auxiliary tank 130 and the direct water supplied through the water supply device 160 is directly circulated without passing through the main circulation coil 142 The circulation of the auxiliary circulation coil 131 is performed and then discharged to the hot water supply unit 170 so that the heating circulation water and the direct water heat exchange in the auxiliary tank 130 and the hot water is supplied to the hot water supply unit 170.

The heating circulation water that has undergone direct heat exchange with the water in the auxiliary tank 130 is supplied to the auxiliary port OUT_T, the common port c of the three-way valve 3W_V, the second branch port n2 and the boiler inlet pipe 110b And the hot water supply is maintained as the water circulation is continued by the pump P_B for the boiler.

At this time, since the heat pump 120 is in operation stop, the blower 126 for the heat pump is kept in a stopped state, the exhaust gas passes through the latent heat recovery heat exchanger 125 and is discharged to the outside through the combustion gas exhaust port G do.

9, when cooling is performed using the summer heat pump 120 and the boiler 110, the first solenoid valve SV1 and the second solenoid valve SV2 are closed by the controller Ct, The third solenoid valve SV3 and the fourth solenoid valve SV4 are opened to allow the refrigerant to flow through the compressor 121 and the second condenser 122 of the heat pump 120 and the first condenser 122 of the boiler 110 115) sequentially.

Therefore, since the refrigerant having a lower temperature passes through the second condenser 122 and the first condenser 115 and absorbs the heat of the room during the passage through the indoor unit 124, the room where the indoor unit 124 is installed is cooled And the circulation of the refrigerant is continued through the cooling pump P_C to maintain the cooling state.

Particularly, in the present invention, since the combustion blower 113 of the boiler 110, the burner 112 and the boiler pump P_B are independently operated by the controller Ct, the operation of the burner 112 is stopped The combustion blower 113 can be operated or the boiler pump P_B can be operated.

Therefore, the cold wind blown by the combustion blower 113 or the cool cold water circulated through the heat exchange tank 111 and the auxiliary tank 130 and the low-temperature bath 140 by the boiler pump P_B And the refrigerant passing through the first condenser 115 is cooled through at least one of them to increase the cooling efficiency.

In addition, since the direct water circulated by the boiler pump P_B is slightly warmed in the course of heat exchange with the first condenser 115, it becomes lukewarm water, so that lukewarm water can be used in the lukewarm season.

In the present invention, the blower 126 for the heat pump is used to blow the air to the second condenser 122 of the heat pump 120 to cool the second condenser 122, and then to discharge the air to the outside through the air outlet 122b , The refrigerant is cooled together with the above-described combustion blower 113 and the boiler pump P_B to further enhance the cooling efficiency.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

110: burner 111: heat exchange tank
112: burner 113: blower for combustion
114: Associated 115: First condenser
116: Condensate reservoir 117: Condensate water guide plate
120: Heat pump 121: Compressor
122: second condenser 123: evaporator
124: indoor unit 125: latent heat recovery heat exchanger
126: blower for heat pump 130: auxiliary tank
131: auxiliary circulation coil 140: low-
141: Heating coil 142: Main circulation coil
150: Heating device 160: Water dispenser
170: hot water supply

Claims (12)

A burner 112 for burning a fuel to blow flames and a combustion gas into the heat exchange tank 111 and a burner 112 for burning combustion air to the burner 112. [ A connection 114 installed inside the heat exchange tank 111 for discharging the combustion gas generated when the burner 112 is burned and a connection pipe 114 installed inside the heat exchange tank 111, (110) having a first condenser (115) composed of a tube through which a refrigerant circulates;
The compressor 121, the second condenser 122, the evaporator 123 and the indoor unit 124 are connected to the compressor 121, the first condenser 115 of the boiler 110, 2 condenser 122 and the evaporator 123 and a second refrigerant cycle in which the refrigerant is circulated through the compressor 121, the second condenser 122, the first condenser 115 of the boiler 110, and the indoor unit A heat pump (120) for selectively forming a second refrigerant cycle circulating the refrigerant cycle (124);
An auxiliary tank 130 for receiving and temporarily storing the heating circulation water stored in the heat exchange tank 111 of the boiler 110 by operating at least one of the boiler 110 and the heat pump 120; And
A heating coil 141 and a main circulation coil 142 are provided inside the heating coil 141 and the inlet side of the heating coil 141 is connected to the outlet side of the heating device 150, The main circulation coil 142 is connected to the water supply side and the water supply side of the main circulation coil 142 is connected to the water supply device 160. The water discharge side of the main circulation coil 142 is connected to the hot water supply device 170, Water tank inlet 140a into which the water stored in the auxiliary tank 130 flows is installed through the first circulation pipe CP1 and the water stored in the other side is supplied to the second circulation pipe CP2 And a low-boiling tank (140) provided with a low-boiling water outlet (140b) to be discharged to a heat-exchange tank (111) of the boiler (110) through a low-boiling tank (140). The method of claim 1,
The auxiliary circulation coil 131 is installed in the auxiliary tank 130. The inlet side of the auxiliary circulation coil 131 is commonly connected to the water supply unit 160 and the outlet side of the auxiliary circulation coil 131 is connected And is connected to the hot water supplier (170) in common. 3. The method of claim 2,
One side of the auxiliary tank 130 is provided with an auxiliary inlet IN_T connected to the outlet side of the heat exchange tank 111 and an auxiliary inlet OUT_T connected to the common port c of the three- A first branch port n1 of the three-way valve 3W_V is connected to the first circulation pipe CP1 and a second branch port n2 of the three-way valve 3W_V is connected to the first circulation pipe CP1, Is connected to the inlet side of the heat exchange tank (111) through the second circulation pipe (CP2). The method of claim 1,
The first circulation pipe CP1 is connected to the heating device 150 so that the circulating water flowing through the first circulation pipe CP1 can be supplied to the heating device 150 or supplied to the low- The first circulation pipe CP1 is provided with a first selection valve SELV1,
The circulation water discharged from the heating device 150 is supplied to the heat exchange tank 111 of the boiler 110 through the second circulation pipe CP2 or supplied to the heating coil 141 of the low- The second circulation pipe CP2 is extended to be commonly connected to the outflow side of the heating device 150 and the second selection valve SELV2 is installed in the second circulation pipe CP2 A hybrid system that combines a boiler and a heat pump. The method of claim 1,
Wherein the auxiliary tank (130) is a wall-mounted type. The method of claim 1,
And a condensate water reservoir 116 for storing condensed water generated when the combustion gas generated during the combustion of the burner 112 is lowered to a dew point temperature or less after heat exchange is provided in the lower portion of the boiler 110 Hybrid system that connects boiler and heat pump. The method according to claim 6,
A condensate water guide plate 117 for guiding the condensed water to be collected into the condensate water reservoir 116 is installed in a lower portion of the boiler 110. The condensate water reservoir 116 and the condensate water guide plate 117 are connected to the boiler 110, And the high-temperature combustion gas generated in the combustion gas exhaust port (G) is discharged only through the combustion gas exhaust port (G). The method of claim 1,
The heat pump 120 is exposed to a combustion gas exhaust port G through which a high temperature combustion gas generated in the boiler 110 is discharged to recover latent heat of the combustion gas and is supplied to a latent heat recovery heat exchanger Further comprising a heat pump blower (126) for blowing heat recovered by the heat recovery heat exchanger (125) and the latent heat recovery heat exchanger (125) toward the evaporator (123) system. 9. The method of claim 8,
The latent heat recovery heat exchanger 125 includes a heat exchange body 125a having one side connected to the combustion gas exhaust port G and a plurality of heat exchange fins 125b formed in the heat exchange body 125a and the combustion gas exhaust port G, And a flow guide plate 125c extending to the inside of the heat exchange body 125a so that the combustion gas being discharged through the combustion gas exhaust port G circulates in the heat exchange body 125a by the flow guide plate 125c And the heat pump is connected to the boiler and the heat pump. 9. The method of claim 8,
The heat pump blower 126 includes a first air outlet 126a and a second air outlet 126b to direct air toward the latent heat recovery heat exchanger 125 through the first air outlet 126a , And blows air or blows air toward the second condenser (122) through the second air outlet (126b). The method of claim 10,
An indoor air supply port 122a is provided at one side of the second condenser 122 and air blown by the blower 126 for the heat pump is supplied to the other side of the second condenser 122, And an air discharge port (122b) for discharging the air to the outside after passing through the discharge port (122). 12. The method according to any one of claims 1 to 11,
The combustion blower 113 of the boiler 110 and the boiler pump P_B for circulating the water in the burner 112 and the heat exchange tank 111 are independently operated by the controller Ct Hybrid system that connects boiler and heat pump.

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