KR101523374B1 - A boiler module for district or central heating without a combustion structure considering desiccant cooling operation - Google Patents

Abstract

The present invention relates to a boiler module for district or central heating without a combustion structure considering desiccant cooling operation, the module comprising: a desiccant cooling unit including a housing, a heating unit arranged in a first channel of the housing, a desiccant rotor arranged in the housing, and a cooling unit arranged in a second channel of the housing; a heat exchanger exchanging heat of warm water heated by heat sources provided from the outside; a water supply pipe and a hot water supply pipe connected to the heat exchanger; and a heated water supply pipe supplying warm water heated by heat sources provided from the outside, wherein water for hot-water supply exchanges heat with warm water passing the heat exchanger, and is heated, and hot water is supplied, and warm water heated by heat sources provided from the outside is used as heat sources needed in the heating unit of the desiccant cooling unit.

Description

[0001] The present invention relates to a boiler module for a central heating or a district heating without a combustion section considering dehumidification cooling operation, a desiccant cooling operation,

The present invention relates to a household boiler module, a household boiler module for central heating or central heating without a combustion section that utilizes a heat source provided by district heating or central heating as a heat source for heating and hot water supply and as a heat source for a dehumidification cooling device.

Central heating is a method in which a heat source such as a boiler is installed in a complex including a plurality of buildings such as an apartment complex, and a heat medium is transported to and supplied to a plurality of buildings by steam, hot water, , Which uses only fuel to make hot water and supplies it to each household.

District heating is a system that supplies high-pressure steam or high-pressure hot water to a large number of buildings scattered over a large area as a heat source for heating in one or several central heating machine rooms. For example, heat managed by Korea District Heating Corporation Heated water supplied from the production facility is used as a heat source, and hot water is produced and supplied to a plurality of buildings.

To be more specific about district heating, district heating is the heat generated by the heat production facilities such as the cogeneration power plant that generates electricity and heat at the same time, and the heat production facility such as the garbage incinerator. It is a heating system that supplies hot water and hot water in a lump and can make heating.

Such a heating method has a merit of high energy utilization efficiency during the winter season, but there is a problem that the energy utilization efficiency is lowered due to an increase in surplus heat in the summer season.

On the other hand, dehumidification cooling technology has recently been applied as a technique for cooling an indoor space. The dehumidification cooling technology is a technology for performing cooling by using a latent heat load treatment by a dehumidifier and a temperature decrease due to the heat of evaporation.

More specifically, the dehumidification cooling technology is to remove the latent heat load by removing the moisture contained in the air by using a dehumidifier and to reduce the air temperature by the evaporation heat by causing water to be supplied to the dehumidified dry air to cause evaporation. The circulation cycle is configured to perform the cooling process repeatedly.

An example of a specific device using dehumidification cooling technology is Korean Patent Laid-Open No. 10-2012-0022684 entitled "Dehumidification cooling device ".

Dehumidification cooling technology is attracting attention as a renewable energy technology because it has low energy consumption and is environment friendly. However, in order to reduce the electricity consumption in the summer, it is necessary to improve the energy consumption efficiency.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a household boiler module without combustion by utilizing heat generated by central heating or district heating, And to provide a household boiler module that can increase energy utilization efficiency and reduce electricity consumption by utilizing generated heat as a heat source of a dehumidifying cooling device.

A boiler module according to an embodiment of the present invention includes a housing including a first channel through which a first air passes and a second channel through which a second air passes; A dehumidification rotor disposed in the second channel and configured to be drivable by the first air heated by the heating section and to be able to absorb moisture from the second air; And a cooling unit for cooling the second air passing through the rotor.

A second supply pipe branched from the first supply pipe and connected to the heat exchanger to supply the hot water to the heat exchanger; a second supply pipe branched from the first supply pipe, A heating water discharge pipe connected to the heating unit and the third supply pipe so that the hot water passed through the heating unit is supplied to the second supply pipe, A third supply pipe passing through the hot water passing through the heat exchanger, a three-way valve provided in the third supply pipe, and a third valve connected to the three-way valve, A heating water supply pipe to which the hot water is selectively supplied according to the control of the valve, And a water supply pipe connected to the heat exchanger for exchanging heat with the hot water in the heat exchanger to supply hot water to the outside, Tube.

In the boiler module according to the embodiment of the present invention, the hot water may be hot water heated by a district heating or a heat source provided by central heating.

The boiler module may further include a drain pipe connected to the heating water supply pipe and having a drain valve.

In the boiler module according to the embodiment of the present invention, the second air is disposed between the dehumidification rotor and the cooling section in the second channel, and water passing through the water pipe is supplied to the heat exchanger And a water supply preheating unit connected to the water supply pipe.

The boiler module according to an embodiment of the present invention may further include a branch pipe branched from the hot water supply pipe and connected to the water supply pipe, a check valve provided in the branch pipe, and a pump provided in the branch pipe.

BRIEF DESCRIPTION OF THE DRAWINGS The above features of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

According to the present invention, by utilizing the heat generated by the district heating or the central heating system as the heat source required for the dehumidification cooling unit, energy utilization efficiency can be improved and electric consumption can be reduced.

Further, by discharging the heating water staying in the heating water supply pipe, the heating unit, and the heating water discharge pipe through the drain pipe to the outside, it is possible to prevent the pipe from being frozen in the winter season.

In addition, by further including the water supply preheating portion, it is possible to effectively heat the water for hot water supply with a small energy and further improve the cooling performance of the dehumidifying cooling portion.

In addition, the indoor heat can be heated by circulating the heated water heat-exchanged in the heat exchanger through the branch pipe so as to be re-introduced into the water supply preheating unit, thereby using the dehumidifying cooling unit.

1 is a schematic view of a boiler module according to an embodiment of the present invention;
FIG. 2 is a schematic view showing the operation state of the module shown in FIG. 1 in the heating mode. FIG.
3 is a schematic view showing the operation state of the module shown in FIG. 1 in a cooling mode.
Fig. 4 is a schematic view showing the operation state of the module shown in Fig. 1 in the cooling and hot-water supply mode; Fig.
5 is a schematic view showing an operating state in the heating mode using the dehumidification cooling unit of the module shown in Fig.

Hereinafter, a boiler module according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a schematic view showing a boiler module according to an embodiment of the present invention.

The boiler module 1 according to the embodiment of the present invention includes a dehumidifying cooling unit 100, a first supply pipe 201, a second supply pipe 202, a heating water supply pipe 301, The first water supply pipe 303, the opening and closing valves 204, 302 and 304, the heat exchanger 203, the third supply pipe 205, the heating water supply pipe 207, the return pipe 209, the water supply pipe 401, .

The dehumidification cooling section 100 includes a housing 110, a heating section 111, a dehumidification rotor 104, and a cooling section 122, which are constructed by dehumidification cooling technology.

The housing 110 includes a first channel 101 and a second channel 102. The first channel 101 and the second channel 102 are passages through which air is passed and may be defined by the partition walls 103 in the housing 110.

The air passing through the first channel 101 may be defined as the first air. The first air may be, for example, air introduced into the first channel 101 from outside the room, and may be discharged out of the room after passing through the first channel 101.

A heating section 111 is disposed in the first channel 101. At this time, the heating unit 111 is disposed closer to the inlet side of the first air, that is, to the left side of the first channel 101, with reference to the illustrated bar than the dehumidification rotor 104 to be described later. The first air passing through the first channel 101 passes through the heating unit 111 and then through the dehumidification rotor 104, which will be described later.

The heating section 111 can provide heat by electrical resistance, for example, by including a heat coil. Or a hot water coil to provide heat by hot water.

When the heating unit 111 includes a hot water coil, a hot water supply pipe 301 is connected to the hot water coil. The heated water supply pipe 301 receives hot water from a first supply pipe 201 to be described later. Hereinafter, the hot water passing through the heated water supply pipe 301 will be referred to as 'heated water'. The heated water is supplied to the second supply pipe 202 through the heated water discharge pipe 303 connected to the hot water coil after flowing the hot water coil through the hot water coil through the heated water supply pipe 301.

The first air passing through the heating unit 111 is heated while exchanging heat with the heating water flowing through the hot water coil. The first air heated by the heating unit 111 passes through the dehumidification rotor 104 and dries the dehumidification rotor 104.

The dehumidification rotor 104 is rotatably disposed within the housing 110. And is disposed over the first channel 101 and the second channel 102.

An adsorbent such as silica gel or zeolite may be formed on the surface of the dehumidification rotor 104 on the contact with the air to absorb moisture from the air passing through the dehumidification rotor 104.

The air passing through the second channel 102 may be defined as the second air. The second air may be, for example, air introduced from the inside. The second air is dehumidified by the dehumidification rotor 104 in the process of passing through the dehumidification rotor 104.

The cooling portion 122 is disposed in the second channel 102. At this time, the cooling part 122 is disposed closer to the exhaust side of the second air than the dehumidification rotor 104, that is, to the left side of the second channel 102 with respect to the illustrated bar. The second air passing through the second channel 102 passes through the dehumidification rotor 104 and then through the cooling section 122.

The cooling unit 122 cools the dehumidified second air while passing through the dehumidification rotor 104. The cooling unit 122 may be, for example, an evaporative cooler for spraying water into the second air flowing through the cooling unit 122 to cool the second air during evaporation of the sprayed water.

The second air passing through the cooling unit 122 is supplied to the room to cool the room.

Meanwhile, in order to increase the dehumidification and cooling efficiency, the condenser and the condenser included in the refrigerant circuit may be disposed in the first channel 101, and the evaporator may be disposed in the second channel 102 .

More specifically, the condenser may be disposed in the first channel 101 closer to the inlet side of the first air than the heating section 111, and the evaporator may be located within the second channel 102, And may be disposed closer to the discharge side of the second air.

The first air passes through the condenser before passing through the heating unit 111, and can be heated while exchanging heat with the refrigerant passing through the condenser. Therefore, the efficiency of drying the dehumidification rotor 104 can be further improved by including the condenser in the first channel 101. [

The second air is cooled by the cooling part 122, and then passes through the evaporator, and further cools while exchanging heat with the refrigerant passing through the evaporator. The second air cooled by the evaporator is supplied to the room, so that the cooling performance of the dehumidifying cooling unit 100 can be further improved.

The air passing through the second channel 102 may be a mixed air of indoor air and outdoor air. At this time, the housing 110 may have an exhaust side for the indoor supply of the second air, and may have an additional outlet 123 to allow some of the air passing through the second channel 102 to be discharged outdoors.

The outdoor air is mixed with the air flowing into the second channel 102 and a part of the mixed air passing through the second channel 102 is discharged to the outside through the outlet 123 so that the room can be ventilated have.

The dehumidification cooling unit 100 may be arranged in the second channel 102, as a condenser constituting the refrigerant circuit, unlike the above. Specifically, the condenser may be located closer to the discharge side of the second air than the cooling portion 122 in the second channel 102. [ At this time, the air passing through the second channel 102 may be air introduced from the outside, and the outdoor air passing through the second channel 102 may be discharged again to the outside. In the dehumidifying and cooling unit 100, the second air cooled through the cooling unit 122 is heat-exchanged with the refrigerant passing through the condenser, thereby condensing the refrigerant.

The refrigerant thus condensed is circulated through the refrigerant tube, and the refrigerant in the room can be cooled by utilizing the refrigerant tube through which the refrigerant circulates.

Specifically, the refrigerant tube may be buried in a floor, a wall, or a ceiling of a room, and may be used for radiative cooling of the room. Alternatively, a part of the refrigerant pipe may be disposed in a fan coil unit (FCU) disposed in the room, and the room may be cooled by operating the fan coil unit.

Or the refrigerant pipe passes through the evaporator of the air conditioner indoor unit arranged in the room, so that the room can be cooled by the air conditioner. In this case, the cooling efficiency of the air conditioner is improved, and the electric consumption consumed by the air conditioner can be reduced.

The dehumidifying cooling section 100 of the module 1 according to the present embodiment includes the housing 110, the heating section 111, the dehumidification rotor 104, and the cooling section 122, May be applied.

On the other hand, the passage of the first air in the first channel 101 can be forced by the operation of the first blower 115 disposed in the first channel 101. Similarly, passage of the second air within the second channel 102 may be forced by operation of the second blower 125 disposed within the second channel 102.

The first supply pipe 201 is a pipe through which hot water heated by a heat source provided from the outside passes. At this time, the heat source provided from the outside may be a heat source provided by district heating or central heating.

Specifically, the water heated by the heat produced by the district heating or the central heating system can be supplied to the main heat exchanger 10 of the machine room provided in the complex.

The main heat exchanger 10 is connected to the recovery pipe 210. The water recovered through the recovery pipe 210 is supplied to the main heat exchanger 10 and is supplied through the district heating or central heating And can be heat-exchanged with heated water to become hot water. The hot water thus heated is supplied to the second supply pipe 202 or the heating water supply pipe 301 through the first supply pipe 201.

The second supply pipe 202 branches from the first supply pipe 201 and is connected to the heat exchanger 203. The hot water supplied through the first supply pipe 201 is supplied to the heat exchanger 203 through the second supply pipe 202 and connected to the second supply pipe 202.

The heating water supply pipe 301 is branched from the first supply pipe 201 and connected to the heating unit 111. The heating water discharge pipe 303 is connected to the heating unit 111 and the second supply pipe 202. The heating water supplied to the heating water supply pipe 301 through the first supply pipe 201 passes through the heating unit 111 and then flows through the heating water discharge pipe 303 connected to the heating unit 111 to the second supply pipe 202 ).

Off valves 204, 302, and 304 may be provided in the second supply pipe 202, the heating water supply pipe 301, and the heating water discharge pipe 303, respectively. The hot water supplied through the first supply pipe 201 is supplied to the heat exchanger 203 through the second supply pipe 202 after passing through the heating unit 111 according to the operation of the open / close valves 204, 302, 304, Can be supplied to the heat exchanger (203) via the second supply pipe (202) without passing through the heat exchanger (111).

At this time, the on-off valves 204, 302 and 304 are connected to the first on-off valve 204 provided on the second supply pipe 202, the second on-off valve 302 provided on the heated water supply pipe 301, And a third opening / closing valve 304 provided on the second opening / closing valve. The first opening and closing valve 204 may be provided on the second supply pipe 202 between a point where the first supply pipe 201 is branched from the first supply pipe 201 and a point where the heating water discharge pipe 303 is joined.

The module 1 according to the present embodiment may further include a drain pipe 305 connected to the heating water supply pipe 301. The drain pipe 305 may be provided with a drain valve 306. The water staying in the heating water supply pipe 301, the heating part 111 and the heating water discharge pipe 303 can be discharged to the outside through the drain pipe 305 according to the opening and closing of the drain valve 306. When the dehumidifying cooling unit 100 is stopped because the dehumidifying cooling unit 100 is not required to be operated during the winter season, the water staying in the heating water supply pipe 301, the heating unit 111, Can be frozen. Therefore, by discharging water to the outside through the drain pipe 305, it is possible to prevent the pipe from being frozen.

On the other hand, the water supply pipe 401 is connected to the heat exchanger 203. The water supply pipe (401) allows, for example, water supplied as water for hot water supply through a water supply pipe to the heat exchanger (203). The water for hot water passing through the heat exchanger 203 is heated while exchanging heat with the hot water supplied to the heat exchanger 203 through the second supply pipe 202.

The hot water supply pipe 402 is connected to the heat exchanger 203 and is heat-exchanged in the heat exchanger 203 so that the heated hot water is passed through the hot water supply pipe to the outside.

The present embodiment may further include a water supply preheating unit 121 disposed between the dehumidification rotor 104 and the cooling unit 122 in the second channel 102. The water supply preheating unit 121 may be connected to the water supply pipe 401.

In this case, the water for hot water passing through the water pipe 401 passes through the water preheating unit 121 before being supplied to the heat exchanger 203. The water for hot water supply via the water supply preheating section 121 is heat-exchanged with the second air passing through the water supply preheating section 121.

The second air introduced from the inside or outside the room in the summer season may be somewhat high temperature and may be heated while passing through the dehumidification rotor 104 heated by the first air. When the second air of high temperature and low humidity passes through the water supply preheating unit 121, heat is exchanged with the water for hot water passing through the water supply preheating unit 121, and the water for hot water is heat-exchanged in the heat exchanger 203 Can be preheated. And the second air may be precooled prior to being cooled by the cooling portion 122. [

Accordingly, in the case where the water supply preheating unit 121 is further included, the present embodiment can more effectively heat water for hot water supply and hot water supply, and at the same time, the indoor cooling performance of the dehumidification cooling unit 100 can be further improved.

The boiler module 1 according to the present embodiment includes a branch pipe 501 branched from the hot water supply pipe 402 and connected to the water supply pipe 401, a check valve 502 provided in the branch pipe 501, And a pump 503 provided in the pump 501.

The branch pipe 501 branches from the hot water supply pipe 402 and is connected to the water supply pipe 401. The branch pipe 501 is connected to the water supply pipe 401 in a flow direction of the water supplied to the water supply pipe 401 (Direction toward the water supply pipe 203) is a point of the water supply pipe 401 in which water flows before passing through the water supply preheating portion 121.

The supply of water from the outside to the water supply pipe 401 is stopped and the discharge of the heated water supplied through the hot water supply pipe 402 is stopped so that the water already supplied to the water supply pipe 401 passes through the water supply preheating portion 121 After passing through the after-heat exchanger 203, is again circulated in such a manner that the water is fed back to the water supply preheating section 121 again via the branch pipe 501.

The branch pipe 501 may be provided with a pump 503 to enable such circulation. The branch pipe 501 may be provided with a check valve 502 so that the water circulates only in the above-mentioned direction.

As the water circulates in this way, the heated water in the heat exchanger 203 is supplied to the water supply preheating section 121. The second air flowing into the second channel 102 is further heated while exchanging heat with the heated water passing through the water supply preheating unit 121 in the process of passing through the water supply preheating unit 121. At this time, the cooling unit 122 can be stopped.

The second air passing through the second channel 102 is supplied to the room in the heated state, whereby the room can be heated.

On the other hand, the hot water supplied from the second supply pipe 202 and passed through the heat exchanger 203 passes through the third supply pipe 205 connected to the heat exchanger 203.

At this time, the third supply pipe 205 is provided with a three-way valve 206. A three-way valve 206 is connected to a heating water supply pipe 207. The three-way valve 206 may be connected to a return pipe 209, 210.

The hot water passing through the third supply pipe 205 can be selectively supplied to the heating water supply pipe 207 or the return pipes 209 and 210 under the control of the three-way valve 206.

The heating water supply pipe 207 may be connected to the heating distributor 20 included in the indoor heating equipment and the hot water passing through the heating distributor 20 may be connected to the heating distributor 20 and the return pipes 208 and 210 connected to the main heat exchanger 10 ) To the main heat exchanger (10).

The hot water supplied to the recovery pipes 209 and 210 is recovered to the main heat exchanger 10 without going through the heating distributor 20.

Hereinafter, operation modes of each mode of the boiler module 1 according to an embodiment of the present invention will be described with reference to FIGS. 2 to 5. FIG.

Fig. 2 is a schematic diagram showing the operating state of the module 1 shown in Fig. 1 in the heating mode, Fig. 3 is a schematic diagram showing the operating state of the module 1 in the cooling mode shown in Fig. 5 is a schematic diagram showing the operating state in the heating mode using the dehumidifying cooling unit of the module 1 shown in Fig. 1 .

As shown in Fig. 2, in the heating mode, the module 1 according to the present embodiment first stops the operation of the dehumidifying cooling section. Then, the first on-off valve 204 is opened and the second on-off valve 302 and the third on-off valve 304 are closed.

Therefore, the hot water supplied by the first supply pipe 201 can not be supplied to the heating unit, passes through the heat exchanger 203 through the second supply pipe 202, And is supplied to the heating water supply pipe 207 under the control of the three-way valve 206 through the supply pipe 205.

The hot water is supplied to the heating distributor 20 through the heating water supply pipe 207 and is recovered to the main heat exchanger 10 through the recovery pipes 208 and 210. Indoor heating is achieved by this circulation process of hot water.

3, in the cooling mode, the module 1 according to the present embodiment is configured such that the first on-off valve 204 is closed and the second on-off valve 302 and the third on-off valve 304 are opened . The heating water supplied to the heating water supply pipe 301 through the first supply pipe 201 is supplied to the heating unit 111 through the heating water supply pipe 301 and is supplied to the heating unit 111 through the heating water discharge pipe 303, (202).

The first air flowing into the first channel 101 from outside the room and passing through the heating unit 111 is heated by heat exchange with the heating water passing through the heating unit 111 and heated by the dehumidifying rotor 104 104). The first air having passed through the dehumidification rotor 104 is discharged to the outside of the room.

As the second air, mixed air of indoor air or indoor and outdoor air flows into the second channel 102, passes through the dehumidification rotor 104, and is dehumidified by the dehumidification rotor 104. The second air having passed through the dehumidification rotor 104 is cooled while passing through the cooling section 122 and flows through the evaporator (not shown) which can be disposed in the second channel 102 after the cooling section 122 It can be cooled and supplied to the room.

Or the second air may be outdoor air and the dehumidified and cooled air through the dehumidification rotor 104 and the cooling section 122 may be cooled in the second channel 102 by a condenser (Not shown), the refrigerant in the condenser can be condensed. The second air passing through the condenser can be discharged outdoors.

The hot water supplied to the second supply pipe 202 through the heated water discharge pipe 303 is supplied to the return pipe 209 under the control of the three-way valve 206 via the heat exchanger 203, And recovered to the main heat exchanger (10).

As shown in FIG. 4, the module 1 according to the present embodiment is substantially the same as the operating state in the cooling mode described above in the cooling and hot-water supply mode. However, water for hot water supply is additionally supplied through the water supply pipe (401).

The water for hot water supplied through the water supply pipe 401 passes through the water supply preheating unit 121 and is heat-exchanged with the second air of high temperature and low humidity in the process of passing through the water supply preheating unit 121 to be preheated. The preheated water for hot water is heat-exchanged with hot water through the heat exchanger 203 and heated. The heated water is heated to the outside through the hot water supply pipe (402).

 The second air passing through the second channel (102) is precooled by heat exchange in the water supply preheating section (121) before being cooled by the cooling section (122). The pre-cooled second air is cooled through the cooling part 122 and supplied to the room.

As shown in FIG. 5, the module 1 according to the present embodiment is capable of heating operation using the dehumidification cooling unit 100. In the heating mode using the dehumidifying cooling unit 100, the water already supplied to the water supply pipe 401 is heat-exchanged while passing through the heat exchanger 203. The heated water is supplied to the hot water supply pipe 402, And then re-introduced into the water supply preheating unit 121 through the water supply pipe 501. This circulation is made by the pump 503, and is made only in one direction by the check valve 502.

The second air passing through the second channel 102 enters the high temperature and low humidity state through the dehumidification rotor 104. The second air passes through the water supply preheating section 121 and exchanges heat with the heated water passing through the water supply preheating section 121 Resulting in a higher temperature state. The cooling unit 122 is shut down.

The second air thus heated is supplied to the room so that the room is heated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious that the modification or the modification is possible by the person.

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 invention as defined by the appended claims.

1: boiler module 100: dehumidification cooling section
101: first channel 102: second channel
103: partition wall 104: dehumidification rotor
110: housing 111: heating part
115: first blower 121: water supply preheating unit
122: cooling section 123: outlet
125: second blower 201: first supply pipe
202: second supply pipe 203: heat exchanger
204: first opening / closing valve 205: third supply pipe
206: Three-way valve 207: Heating water supply pipe
208, 209, 210: recovery pipe 301: heating water supply pipe
302: second opening / closing valve 303: heating water outlet pipe
304: third open / close valve 305: drain pipe
306: drain valve 401: water supply pipe
402: Hot water supply pipe 501: Branch pipe
502: Check valve 503: Pump

Claims (5)

A housing including a first channel through which the first air passes and a second channel through which the second air passes; a heating unit disposed in the first channel for heating the first air; A dehumidification rotor installed in the housing so as to be rotatable to be drivable by the first air and to absorb moisture from the second air, and a second dehumidifying rotor disposed in the second channel to cool the second air passing through the dehumidification rotor A dehumidifying cooling unit including a cooling unit;
A first supply pipe through which hot water heated by an externally provided heat source passes;
A second supply pipe branched from the first supply pipe and connected to the heat exchanger to supply the hot water to the heat exchanger;
A heating water supply pipe branched from the first supply pipe and connected to the heating unit to supply the hot water to the heating unit;
A heating water discharge pipe connected to the heating unit and the third supply pipe so that the hot water passed through the heating unit is supplied to the second supply pipe;
An open / close valve provided in the second supply pipe, the heating water supply pipe, and the heating water discharge pipe;
A third supply pipe through which the hot water passed through the heat exchanger passes;
A three-way valve provided in the third supply pipe;
A heating water supply pipe connected to the three-way valve and selectively supplying the hot water under the control of the three-way valve;
A water supply pipe connected to the heat exchanger for supplying water for hot water supply to the heat exchanger to exchange heat with the hot water;
And a hot water supply line connected to the heat exchanger, wherein the hot water is heat-exchanged with the hot water in the heat exchanger to supply hot water to the outside. The method according to claim 1,
Wherein the hot water is hot water heated by a heat source provided by district heating or central heating. The method according to claim 1,
And a drain pipe connected to the heating water supply pipe and having a drain valve. The method according to claim 1,
And a water supply preheating unit disposed between the dehumidification rotor and the cooling unit in the second channel to allow the second air to pass therethrough and to be connected to the water supply pipe before the water passing through the water supply pipe is supplied to the heat exchanger Wherein the boiler module is a boiler module. The method of claim 4,
A branch pipe branched from the hot water supply pipe and connected to the water supply pipe;
A check valve provided in the branch pipe; And
Further comprising a pump provided in the branch pipe.

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