KR101970763B1 - Freezing protection apparatus for air conditioner and the method thereof - Google Patents

Abstract

The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a cooling device for an air conditioner that can perform an air conditioning function using heated water of a boiler, And a method of controlling the same. In order to accomplish this, the apparatus for preventing freezing of the air conditioner of the present invention includes at least one heat exchanger for exchanging heat between indoor air and outdoor air supplied from the boiler 2 for performing an air conditioning function of indoor air An air conditioner (1) including a heat exchange unit (150, 250); A frost sensing unit for sensing a condition capable of generating a frost in a pipe inside the air conditioner (1) through which the heating water flows; When the freeze detection condition is detected by the freeze detection unit, the boiler 2 is operated to supply the heated water to the heat exchangers 150 and 250 of the air conditioner 1, and then circulates the heated water to the boiler 2 And a control unit for controlling the control unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner,

The present invention relates to an apparatus and method for preventing freezing of an air conditioner, and more particularly, to an apparatus and method for preventing freezing of an air conditioner, which can prevent the occurrence of freezing within the air conditioner using heated water of a boiler will be.

The air conditioner is a device that adjusts the room temperature and humidity according to the user's demand or keeps the room pleasant by ventilating the room air. The boiler supplies the heating water heated by the heat of combustion of the burner to the heating facility, Device.

The air conditioner is provided with an indoor air passage through which indoor air flows and an outdoor air passage through which outdoor air flows. And a heater for heating indoor air by heating the air flowing through the indoor air channel when the air conditioner has a heating function. When the air conditioner has a dehumidifying function, a heater for heating the air flowing through the outdoor air passage to evaporate moisture dehumidified from the indoor air to regenerate the dehumidifying rotor is provided.

The heater can be a hot water heater that heats the air by the supply of hot water. In this case, there is a problem that not only an air conditioner but also a hot water generating device is required to perform the air conditioning function.

As an example of such a conventional air conditioner, Korean Utility Model Publication No. 2000-0006813 entitled " Air-conditioning unit for combined cooling and heating provided with heating means "

On the other hand, the boiler includes a circulation pump for circulating the heating water, a main heat exchanger for heat exchange with the combustion gas generated in the burner in the heating water pumped by the circulation pump, a hot water heat exchanger A three-way valve for supplying the heating water heated by the main heat exchanger to either the heating source or the hot water heat exchanger, a heating water supply pipe for supplying the heating water heated by the main heat exchanger to the heating facility, A heating water return pipe for allowing the heating water to flow to the main heat exchanger, and an expansion tank for storing heating water circulated by the circulation pump.

Korean Patent Laid-Open No. 10-2009-0102940 discloses a boiler capable of simultaneously supplying hot water and hot water.

Since the hot water generated by the main heat exchanger of the conventional boiler having the above structure is supplied only to the heat source or the hot water heat exchanger, it is necessary to connect the hot water heater to the hot water heater type air conditioner.

Further, water is filled in the hot water heater of the air conditioner, and if the air conditioner is not operated in winter, the water inside the hot water heater is frozen to generate frozen waves.

In order to prevent such a frost wave, Korean Utility Model Registration No. 20-0227935 entitled " Device for preventing freezing of a radiator for an air conditioner " has a heater operated by receiving a signal from a sensor. When the temperature sensed by the sensor is below a certain temperature, A technique for preventing freezing by operating is disclosed.

However, such a conventional technique requires a separate heater inside the air conditioner to prevent freezing, which complicates the structure of the air conditioner.

The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and method for preventing freezing of an air conditioner capable of performing an air conditioning function using heated water of a boiler, The present invention has been made to solve the above problems.

In order to achieve the above-mentioned object, the apparatus for preventing freezing of the air conditioner of the present invention performs heat exchange between indoor air or outdoor air and the heating water supplied from the boiler (2) An air conditioner (1) comprising at least one heat exchanging part (150, 250) for carrying out the heat exchanging operation; A frost sensing unit for sensing a condition capable of generating a frost in a pipe inside the air conditioner (1) through which the heating water flows; When the freeze detection condition is detected by the freeze detection unit, the boiler 2 is operated to supply the heated water to the heat exchangers 150 and 250 of the air conditioner 1, and then circulates the heated water to the boiler 2 And a control unit for controlling the control unit.

The freeze detection unit comprises an outdoor air temperature sensor 201 for measuring a temperature of the outdoor air flowing into the air conditioner 1; If the temperature measured by the outdoor air temperature sensor 201 is lower than the first predetermined temperature, the controller may operate the boiler 2.

The freeze detection unit comprises a heating water temperature sensor 202 for measuring the heating water temperature inside the pipe for supplying the heating water to the heat exchanging units 150 and 250 of the air conditioner 1 in the boiler 2; If the temperature measured by the heating water temperature sensor 202 is lower than the second set temperature, the control unit may operate the boiler 2.

A heater 260 is provided in a supply pipe through which the heating water is supplied from the boiler 2 to the heat exchanging units 150 and 250 of the air conditioner 1 and the heating heat from the boiler 2 to the heat exchanging units 150 and 250 The controller may operate the heater 260 to supply the heated water heated by the heat exchangers 150 and 250. In this case,

Circulation of the heating water between the boiler 2 and the air conditioner 1 is performed by a circulation pump 24 provided in the boiler 2; And the hot water supply valves 151 and 251 provided in the air conditioner 1 and circulating the hot water to the heat exchanging units 150 and 250 when the heating water is circulated may be opened.

The heating water heated in the boiler 2 is supplied to either one of the heat exchanging units 150 and 250 or the heating means 3 selectively or simultaneously to the heat exchanging units 150 and 250 and the heat requiring place 3 Way valve (4) is provided in which the direction of opening and closing is set so as to supply it; The three-way valve (4) may be controlled by the controller to open and close.

A heating supply pipe 6a for supplying the heating water heated in the main heat exchanger 21 of the boiler 2 to the heating destination 3 and a heating water supply pipe 6b for supplying the heating water, And a heat exchange unit supply pipe for supplying hot water heated in the main heat exchanger (10) to the heat exchanging units (150, 250), branched from the heating supply pipe (6a) And a heat exchange water pipe (6c) for flowing heat water exchanged in the heat exchange units (150, 250) to the main heat exchanger (10) through the heat return pipe (6d); The three-way valve 4 may be provided at the intersection of the heat exchange water pipe 6c and the heat return pipe 6d.

When the open / close direction of the three-way valve 4 is set so as to simultaneously supply the heating water heated in the boiler 2 to the heat exchanging units 150 and 250 and the heating target 3, the heat is transmitted through the heat exchanging units 150 and 250 The degree of opening of the three-way valve 4 may be set such that the flow rate of the heating water is smaller than the flow rate of the heating water passing through the heating target 3.

The control method of the air conditioner freeze prevention apparatus of the present invention is a control method of an air conditioner freeze prevention apparatus comprising at least one heat exchanging unit for performing heat exchange between indoor air or outdoor air and heating water supplied from a boiler (2) (1) comprising a plurality of heating units (150, 250), a freeze detection unit for detecting a freeze generation condition in a pipe inside the air conditioner (1) through which the heating water flows, Wherein the freeze prevention mode comprises: a) detecting a freeze generation condition in the freeze detection unit; b) receiving information sensed by the freeze detection unit and determining whether the freeze occurrence condition is present; c) When the control unit determines that the condition for generating the freezing can be generated, the boiler 2 is operated to circulate the heated heating water between the boiler 2 and the heat exchanging units 150 and 250 of the air conditioner 1 through the inside of the pipe .

The freeze detection unit comprises an outdoor air temperature sensor 201 for measuring a temperature of the outdoor air flowing into the air conditioner 1; If the temperature measured by the outdoor air temperature sensor 201 is lower than the first set temperature, the controller may perform the frost protection mode.

The freeze detection unit comprises a heating water temperature sensor 202 for measuring the heating water temperature inside the pipe for supplying the heating water to the heat exchanging units 150 and 250 of the air conditioner 1 in the boiler 2; If the temperature measured by the heating water temperature sensor 202 is lower than the second predetermined temperature, the controller may perform the freeze prevention mode.

The freeze detection unit includes an outdoor air temperature sensor 201 for measuring the temperature of the outdoor air flowing into the air conditioner 1 and a heat exchanger And a heating water temperature sensor (28) for measuring the temperature of the heating water inside the pipe for supplying the heating water to the heating water temperature sensor (150, 250); If the first condition that the temperature measured by the outdoor air temperature sensor 201 is equal to or lower than the first set temperature and the second condition that the temperature measured by the heating water temperature sensor 28 is equal to or lower than the second set temperature are all satisfied, May be one that performs the above-mentioned freeze prevention mode.

According to the present invention, the air conditioning function of the air conditioner can be implemented by using the hot water generated at the boiler, and the heating can be supplied to the heating destination. Also, It is possible to provide an efficient system and improve the reliability of the product.

In addition, when the expansion tank of the boiler is open type and the installation position of the air conditioner is higher than that of the boiler, a check valve is provided in the pipe between the air conditioner and the expansion tank so that the heating water remaining in the pipe of the air conditioner is discharged to the expansion tank It is possible to prevent backflow and to prevent the overflow of the expansion tank.

In addition, since the heating water supplied from the boiler can be simultaneously supplied to the air conditioner and the heating destination, the flow rate of the heating water to be supplied can be adjusted, and the air conditioner can be used simultaneously during heating in the heating area. .

1 is a view showing a system in which an air conditioner equipped with a freezing prevention device according to the present invention is connected to a boiler
Fig. 2 is a view showing the flow of heating water when the heating system is heated in the system of Fig. 1
Fig. 3 is a view showing the flow of the heating water when the air conditioner is operated in the system of Fig. 1
Fig. 4 is a view showing the flow of the heating water in the frost preventing mode in the system of Fig. 1
5 is a view showing the flow of heating water in a system in which an air conditioner and a boiler are connected according to another embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus and method for preventing freezing of an air conditioner according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a system in which an air conditioner equipped with a freezing prevention apparatus according to the present invention is connected to a boiler.

The air conditioner equipped with the device for preventing freezing of the present invention includes at least one heat exchanging part for performing heat exchange between the indoor air or outdoor air and the heating water supplied from the boiler 2 for performing the air conditioning function of the indoor air (1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12) And a control unit for operating the boiler 2 to supply the heated water to the heat exchanging units 150 and 250 of the air conditioner 1 and then circulating the heated water to the boiler 2 again.

The air conditioning function performed by the air conditioner 1 may be humidification, dehumidification, heating, cooling, ventilation, and air cleaning of the indoor air.

The air conditioner 1 includes first air passages 110a, 110b and 110c connected at both ends thereof to the room, second air passages 210a, 210b and 201c connected at both ends to the outside, A first region 310 provided on the air passage 110 and a second region 320 provided on the second air passage 210 are connected to the first region 310 and the second region 320 by rotation, The first air passage 110 and the second air passage 210 are provided at a position where the first air passage 110 and the second air passage 210 intersect with each other, And a flow path switching unit 400 for switching the flow direction of the air flow path 210.

The first air passage 110 includes an inlet 110a through which indoor air flows in one side, an intermediate portion 110b through the first region 310 of the rotor member 300, And an outlet 110c for discharging the room air back to the other side of the room.

The first air passage 110 is provided with a plurality of filters 120, 130 and 140, a first heat exchanger 150 and a first blower 160 in sequence.

The first heat exchanging part 150 is turned on when the room is heated or humidified and heats the air flowing in the first air flow path 110 so that heated air flows through the first area 310 of the rotor member 300 ).

The first heat exchanger (150) is configured such that hot water flows into the first heat exchanger (150). In this case, heat exchange occurs between the hot water and the room air, so that the room air is heated. A first hot water supply valve 151 is provided to regulate the supply of the hot water (heating water) supplied from the boiler 2. The hot water (heating water) supplied from the boiler 2 is supplied to the first heat exchanging unit 150 through the heat exchanging unit supply pipe 6b and the first hot water supply valve 151. In the first heat exchanging unit 150, The hot water (heating water) in which the temperature is lowered flows to the boiler 2 via the heat exchange water pipe 6c.

Water is supplied to the inside of the piping connected to the first heat exchanging unit 150 to supply the heating water from the boiler 2 and water does not flow when the air conditioner 1 is not operated. In winter, frost may occur. In the present invention, the boiler 2 is operated in order to prevent freezing. However, even if the boiler 2 fails to supply the heated water heated by the boiler 2 to the heat exchanging units 150 and 250, A heater 203 is provided on a pipe through which the heating water flows from the boiler 2 to the first heat exchanging unit 150 so as to prevent the occurrence of freezing of the inside of the unit 1. [

The first blower 160 provides a suction force to suck indoor air or outdoor air into the first air passage 110 and is provided on the outlet 110c side of the first air passage 110.

The second air passage 210 includes an inlet portion 210a through which outdoor air flows from one side, an intermediate portion 210b through the second region 320 of the rotor member 300, And an outlet portion 210c for discharging the outdoor air back to the other outdoor side.

An outdoor air temperature sensor 201, a plurality of filters 220 and 230, a second heat exchanger 250 and a second blower 260 are sequentially provided in the second air passage 210.

The outdoor air temperature sensor 201 constitutes the freeze detection unit and measures the temperature of the outdoor air flowing into the air conditioner 1 and detects the outdoor air temperature based on the measured outdoor air temperature Whether the operation is started or not is determined. If the measured temperature of the outdoor air is lower than a first set temperature (for example, 4 DEG C), the control unit controls the freezing prevention mode to be performed. Especially, since outdoor air temperature drops faster than water, it is effective to prevent frost from being controlled so that the frost prevention mode is performed quickly before freezing the water when the outdoor air temperature is low.

Like the first heat exchanging unit 150, the second heat exchanging unit 250 includes hot water flowing therein. In this case, heat exchange is performed between the hot water and the outdoor air, so that the outdoor air is heated. A second hot water supply valve 251 is provided to regulate the supply of the hot water (heating water) from the boiler 2. The hot water (heating water) supplied from the boiler 2 is supplied to the second heat exchanging unit 250 through the heat exchanging unit supply pipe 6b and the second hot water supply valve 251. The heat exchanged in the second heat exchanging unit 250 The hot water (heating water) in which the temperature is lowered flows to the boiler 2 via the heat exchange water pipe 6c.

The heating water temperature sensor 202 and the heater 203 are installed in the piping for supplying the heating water to the first heat exchanging unit 150 and the second heat exchanging unit 250.

The heating water temperature sensor 202 is provided on the pipe for supplying the heating water to the heat exchanging units 150 and 250 of the air conditioner 1 in the boiler 2, The temperature of the water inside the pipe is measured.

The temperature of the heating water inside the piping connected to the heat exchanging units 150 and 250 of the air conditioner 1 is measured and the operation of the freezing prevention mode is determined on the basis of the measured temperature of the heating water. If the measured temperature of the heating water is below the second set temperature, the controller controls the freezing prevention mode to be performed. Since the temperature of the heating water drops later than the temperature of the outdoor air, if the freezing prevention mode is performed based on the temperature of the heating water, the boiler 2 is operated only when the freeze prevention operation is absolutely necessary. The number of times can be minimized.

The outdoor air temperature sensor 201 and the heating water temperature sensor 202 may be configured to include only one or both of the outdoor air temperature sensor 201 and the heating water temperature sensor 202.

When both of the outdoor air temperature sensor 201 and the heating water temperature sensor 202 are provided, the first condition in which the outdoor air temperature is equal to or lower than the first set temperature and the second condition in which the heating water temperature is equal to or lower than the second set temperature It can be configured that the freeze prevention mode is performed. As described above, by performing the freezing prevention mode only when both the first condition and the second condition are satisfied, the number of times of operation of the boiler 2 can be minimized, and the freezing can be effectively prevented.

When the boiler 2 fails to supply heated water heated by the boiler 2 to the heat exchange units 150 and 250, the heater 203 and the circulation pump 24 are operated to heat the heat exchange units 150 and 250, It is possible to prevent freezing of the water inside the pipe connected to the pipe.

The second blower 260 provides a suction force for sucking outdoor air or room air into the second air passage 210 and is provided at the outlet 210c side of the second air passage 210. [

The rotor member 300 is provided with an adsorbent for adsorbing moisture of air therein. The first region 310 is connected to the first air passage 110 and the second region 320 is connected to the second air passage 210.

A third region 330 may be formed between the first region 310 and the second region 320 to supply moisture by the moisture supply unit 500.

In the dehumidifying mode, the adsorbent located in the first region 310 adsorbs moisture contained in the indoor air flowing in the first air flow path 110, and the adsorbent adsorbing moisture is rotated to be located in the second region 320 The indoor air is dehumidified by discharging moisture to the air flowing through the second air passage 210. On the contrary, in the humidifying mode, the adsorbent located in the third region 330 adsorbs moisture from the air flowing in the humidifying air passage 540, and when the adsorbent adsorbing moisture is rotated to be located in the first region 310 The indoor air is humidified by discharging moisture to the air flowing through the air flow path 110.

The first region 310, the second region 320 and the third region 330 are separated from each other, and the adsorbent of the rotor member 300 is driven by a driving unit (not shown) .

The flow path switching unit 400 includes a first inlet 410 through which indoor air flows, a second inlet 420 through which outdoor air flows, a first outlet 430 connected to the first region 310, A second outlet 440 connected to the second region 320 and a second outlet 420 connected to the first inlet 410 through a first outlet 430 or a second outlet 440, And a direction switching gate 450 for switching the connection direction to be connected to the first outlet 430 or the second outlet 440.

The directional switching gate 450 is located at a central portion where the first inlet 410 and the second inlet 420 intersect with the first outlet 430 and the second outlet 440. The first inlet 410 and the first outlet 430 are connected to each other and the second inlet 420 and the second outlet 440 are connected to each other when the direction switching gate 450 is positioned at the first position. When the direction switching gate 450 is rotated 90 degrees by the driving unit (not shown) at the first position, the first inlet 410 is connected to the second outlet 440, and the second inlet 420 are connected to the first outlet 430.

The water supply unit 500 includes a third blower 510 disposed on the humidifying air passage 540 to flow the humidifying air, a water supply unit 500 for supplying moisture when the air supplied by the third blower 510 passes, A water supply valve 550 for supplying water to the water tank 530, a water supply valve 550 for supplying water to the water tank 530, And a drain valve 560 for draining the water of the water pump 530.

In the water tank 530, water is filled at a predetermined water level, and the humidifying filter 520 is provided so that a part of the lower end of the water is immersed in the water.

When the air passes through the humidifying filter 520, the moisture adsorbed by the humidifying filter 520 evaporates and flows into the third region 330 along the humidifying air passage 540. The air that has been dried after the moisture adsorbed on the adsorbent of the third region 330 is again caused to flow to the humidifying filter 520 by the third blower 510. Thus, the humidifying air passage 540 may be a closed (closed) passage.

The water supply pipe 570 provided with the water supply valve 550 may be connected to supply tap water. The drain pipe 580 provided with the drain valve 560 is connected to the outside of the air conditioner and is configured to be able to drain the water of the water tank 530 to the outside.

The boiler 2 includes a main heat exchanger 21 for heating the heating water by the combustion heat of the burner 22, a circulation pump 24 for circulating the heating water, Way valve 26 that is opened to be supplied to the heating supply pipe 6a side in the hot water mode and to be supplied to the hot water heat exchanger 25 side in the hot water mode and heat exchange is performed between the heating water heated by the main heat exchanger 21 and the direct water A hot water heat exchanger 25 for supplying hot water, and an expansion tank 23 for storing heating water circulated by the circulation pump 24.

A main heat exchanger outlet pipe 27a for connecting the main heat exchanger 21 and the three-way valve 26, an expansion tank inlet pipe 27b for connecting the heating water return pipe 6d and the expansion tank 23, A main heat exchanging inlet pipe 27c connecting the main heat exchanger 23 and the main heat exchanger 21 and having a circulation pump 24 installed therebetween and a hot water heat exchanging inlet port 27c connecting the three-way valve 26 and the hot water heat exchanger 25, (27d) for connecting the hot water heat exchanger (25) to the hot water return pipe (27b), and a hot water heat exchanger outlet hole (27e) for connecting the hot water heat exchanger (25)

The hot water generated by the main heat exchanger 21 of the boiler 2 is supplied to the heat source 3 and the heat water whose temperature has dropped after the heat is exchanged in the heat source 3 is again supplied to the main heat exchanger 21).

The air conditioner 1, the boiler 2, and the heating destination 3 are connected by a plurality of pipes. The plurality of piping includes a heating supply pipe (6a) for supplying the heating water heated in the main heat exchanger (10) to the heating destination (3), a heating water supply pipe A heat exchange unit supply pipe 6b for supplying heating water heated by the main heat exchanger 10 to the heat exchanging units 150 and 250 while being branched from the heating supply pipe 6a, And a heat exchange water pipe 6c for flowing the heat water exchanged in the heat exchange units 150 and 250 to the main heat exchanger 10 through the heat return pipe 6d.

On the other hand, when the heating water heated in the main heat exchanger 21 is supplied to either of the heat exchanging units 150 and 250 or the heating requirement unit 3 alternatively, the heat exchanging units 150 and 250 and the heat demanding unit 3 Way valve (4) for setting the opening and closing direction so as to simultaneously supply the three-way valve (4) and the control unit controls the opening and closing direction of the three-way valve (4).

The three-way valve 4 is provided at the intersection of the heat exchange water pipe 6c and the heat return pipe 6d so that the heat exchange water in the heat exchange units 150 and 250 is transferred to the heat exchange water pipe 6c, The opening direction is set so as to flow to the boiler 2 via the heat recovery duct 6d or the heating direction in which the heat exchanged in the heating destination 3 flows through the heating water return pipe 6d to the boiler 2 . The heating water passing through the heat exchanging units 150 and 250 and the heating water passing through the heating destination 3 may be circulated to the boiler 2 at the same time to adjust the respective flow rates.

A check valve 5 is provided on the heat exchanging part supply pipe 6b to allow the heating water to flow in the direction of the heat exchanging part 150 and 250 from the main heat exchanger 21 but to prevent the heating water from flowing in the reverse direction. The heat exchanger portion supply pipe 6b and the heat exchanger portions 150 and 250 are always filled with heating water. When the boiler 2 is installed at a lower position than the air conditioner 1, the heating water inside the ducts of the heat exchange unit supply pipe 6b and the heat exchange units 150 and 250 can flow back to the boiler 2 have. Particularly when the expansion tank 23 of the boiler 2 is of the atmospheric air type and a small gap is formed in the connecting portion where the respective components of the heat exchanging portion supply pipe 6b and the heat exchanging portions 150 and 250 are connected, It may flow back to the boiler 2 and overflow may occur in the expansion tank 23. In the present invention, the check valve (5) prevents the heating water inside the pipe of the heat exchange unit supply pipe (6b) from flowing back toward the boiler (2).

FIG. 2 is a view showing the flow of heating water when the heating system is heated in the system of FIG. 1. FIG.

2, when the heating is performed in the heating destination 3, the heating water flows in the direction of the boiler 2 from the heating destination 3 of the three-way valve 4, and the heating water flows from the first heat exchanging unit 150 The opening direction is set so that the heating water does not flow in the direction of the boiler 2. When the burner 22 and the circulation pump 24 are operated, the heating water heated in the main heat exchanger 21 is supplied to the heating destination 3 through the heating supply pipe 6a, Is circulated to the expansion tank (23) and the main heat exchanger (21) after passing through the heat return pipe (6d).

FIG. 3 is a view showing the flow of heating water in operation of the air conditioner in the system of FIG. 1;

3, when the air conditioner 1 is operated in the indoor heating mode, the first hot water supply valve 151 is opened, the second hot water supply valve 251 is closed, the three-way valve 4 is closed, The opening direction is set so that the heating water flows in the direction of the boiler 2 from the first heat exchanging part 150. [ In this state, when the burner 22 is operated and the circulation pump 24 operates, the heating water heated in the main heat exchanger 21 flows through the heat supply pipe 6a and the heat exchange unit supply pipe 6b to the first heat exchange unit And the heat exchange water pipe 6c, the three-way valve 4, the heat return pipe 6d, and the heat exchange water pipe 6c are connected to the first heat exchanger 150 through the first heat exchanger 150, And then circulates through the expansion tank 23 and the main heat exchanger 21. The air heated by the heat exchange in the first heat exchanging part 150 is discharged to the room through the first area 310 of the rotor member 300 and the outlet part 110c of the first air flow path 110, Heating is done.

When the air conditioner 1 is operated in the indoor humidification mode, the first hot water supply valve 151 is opened, the second hot water supply valve 251 is closed, and the three-way valve 4 is closed by the first heat exchange The opening direction is set so that the heating water flows from the portion 150 toward the boiler 2. The moisture is supplied to the third region 330 from the water supply unit 500 and the moisture adsorbed in the third region 330 is located in the first region 310 when the rotor member 300 rotates. When the first heat exchanging part 150 and the first blowing fan 160 are turned on, the room air introduced through the inlet part 110a of the first air flow path 110 is heated by the first heat exchanging part 150 The moisture adsorbed on the adsorbent is evaporated by passing through the first region 310 to be humid and discharged to the room through the outlet portion 110c of the first air flow path 110 to perform indoor humidification.

When the air conditioner 1 is operated in the indoor dehumidification mode, the second hot water supply valve 251 is opened, the first hot water supply valve 151 is closed, and the three-way valve 4 is closed by the first heat exchange The opening direction is set so that the heating water flows from the portion 150 toward the boiler 2. When the first blower 160 is operated, the room air introduced into the first air passage 110 passes through the first area 310 of the rotor member 300, and moisture contained in the room air flows into the first area 310, Adsorbing material. The indoor air from which the moisture is removed in the first region 310 is discharged to the room through the outlet portion 110c of the first air flow path 110. When the second blower 260 is operated, the outdoor air introduced into the second air passage 210 is heated by heat exchange with the heating water in the second heat exchanger 250, and then the second region 320 of the rotor member 300 ). In this case, when the adsorbent of the rotor member 300 that absorbs the moisture of the indoor air in the first region 310 rotates to be located in the second region 320, the heated outdoor air passing through the second region 320 The outdoor air is humidified and discharged to the outside through the outlet 210c of the second air passage 210 to dehumidify the indoor air.

FIG. 4 is a view showing the flow of the heating water in the freezing prevention mode in the system of FIG. 1. FIG.

4, the temperature of the outdoor air / heating water is measured by the freeze detection units 201 and 202, and the controller receives the temperature information sensed by the freeze detection units 201 and 202, It is determined whether or not it is below the temperature.

In the case of the outdoor air temperature sensor 201, the freezing prevention mode is performed when the temperature of the outdoor air is lower than or equal to the first set temperature. In the case where the freeze detection unit is the heating water temperature sensor 202, Is below the second set temperature, the freeze prevention mode is performed.

When the outside air temperature sensor 201 and the heating water temperature sensor 202 are constituted by the outside air temperature sensor 201 and the outdoor air temperature is equal to or lower than the first set temperature and the heating water temperature is equal to or lower than the second set temperature, .

The first hot water supply valve 151 and the second hot water supply valve 251 are opened and the burner 22 is opened when the measured temperature is lower than the first set temperature and the second set temperature, And the circulation pump 24 are operated so that the heating water heated in the boiler 2 is supplied to the heat exchanging units 150 and 250 of the air conditioner 1 and then circulated to the boiler 2, It is possible to prevent freezing waves from occurring.

After the boiler 2 is operated to supply the heating water to the heat exchangers 150 and 250 of the air conditioner 1 as described above, the temperature measured by the outdoor air temperature sensor 201 and the heating water temperature sensor 202 is set When the temperature is exceeded, the freeze detection mode is terminated and the operation of the burner 22 and the circulation pump 24 is stopped.

5 is a view showing a flow of heating water in a system in which an air conditioner and a boiler are connected according to another embodiment of the present invention.

All the constitutions of this embodiment are the same as those of the embodiment of Fig. 1, and the first valve 4-2 and the second valve 4-3 are used instead of the three-way valve 4. [ The first valve (4-2) and the second valve (4-3) are constituted by a flow rate control valve capable of controlling the flow rate of the heating water flowing in the first valve (4-2) and the second valve (4-3).

The first valve 4-2 is controlled to be opened and closed by the control unit so as to supply the heating water heated in the main heat exchanger 10 to the heating destination 3, And the opening and closing are controlled by the control unit to supply the heated water heated in the exchanger 10 to the heat exchanging units 150 and 250.

In the case where only the first valve 4-2 is opened, the heating water is supplied only to the heating destination 3. When only the second valve 4-3 is opened, the heating water is supplied only to the heat exchanging units 150 and 250 When both the first valve 4-2 and the second valve 4-3 are opened, the heating water is supplied to both the heat source 3 and the heat exchangers 150 and 250, 3 and the operation of the air conditioner 1 can be performed at the same time.

When the heating of the heating destination 3 and the operation of the air conditioner 1 are simultaneously performed, the flow rate of the heating water supplied to the air conditioner 1 is smaller than the flow rate of the heating water supplied to the heating destination 3 It is preferable to adjust the opening degree of the first valve 4-2 and the second valve 4-3 so as to be small.

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 exemplary embodiments, but, on the contrary, And this also belongs to the present invention.

1: air conditioner 2: boiler
3: Heating Requirement 4: Three-way valve
4-2: first valve 4-3: second valve
5: Check valve 6a: Heating pipe
6b: Heat exchange portion supply pipe 6c: Heat exchange water pipe
6d: Heat recovery pipe 10: Main heat exchanger
21: main heat exchanger 22: burner
23: expansion tank 24: circulation pump
25: hot water heat exchanger 26: three-way valve
110: first air flow path 120,130,140,220,230: filter
150: first heat exchanger 160: first blower
201: outdoor air temperature sensor 202: heating water temperature sensor
203: heater 210: second air passage
250: second heat exchanger 260: second blower
300: rotor member 310: first region
320: second area 330: third area
400: flow path switching part 410: first inlet
420: second inlet port 430: first outlet port
440: second outlet 450: direction switching gate
500: water supply part 510: third blower
520: humidifying filter 530: water tank
540: Humidification air channel 550: Water supply valve
560: Drain valve 570: Water supply pipe
580: Water pipe

Claims (12)

An air conditioner (1) including at least one heat exchanging unit (150, 250) for performing an air conditioning function of indoor air by performing heat exchange between heated water supplied from a boiler (2) and indoor air or outdoor air;
A freeze detection unit for detecting a condition capable of generating a freeze within the air conditioner;
When the freeze detection condition is detected by the freeze detection unit, the boiler 2 is operated to supply the heated water to the heat exchangers 150 and 250 of the air conditioner 1, and then circulates the heated water to the boiler 2 A control unit for controlling the control unit;
Lt; / RTI >
A heating supply pipe 6a for supplying the heating water heated in the main heat exchanger 21 provided in the boiler 2 to the heating destination 3 and a heating water supply pipe 6b for heating the heat- A heat exchange pipe 6b for supplying the heating water heated by the main heat exchanger 21 to the heat exchangers 150 and 250, And a heat exchange water pipe (6c) for flowing the heat water exchanged in the units (150, 250) to the main heat exchanger (21);
The control unit supplies the heating water heated in the main heat exchanger 21 to the heat exchanging units 150 and 250 through the heat exchanging unit supply pipe 6b or to the heat demanding unit 3 through the heating supply pipe 6a And selectively supplies the heating water heated in the boiler 2 to either one of the heat exchanging units 150 and 250 or the heating requirement unit 3 or the heat exchanging units 150 and 250 and the heating requirement unit 3, In the air conditioner The method according to claim 1,
The freeze detection unit comprises an outdoor air temperature sensor 201 for measuring a temperature of the outdoor air flowing into the air conditioner 1;
Wherein the control unit operates the boiler (2) when the temperature measured by the outdoor air temperature sensor (201) is lower than a first set temperature. The method according to claim 1,
The freeze detection unit comprises a heating water temperature sensor 202 for measuring the heating water temperature inside the pipe for supplying the heating water to the heat exchanging units 150 and 250 of the air conditioner 1 in the boiler 2;
Wherein the control unit operates the boiler (2) when the temperature measured by the heating water temperature sensor (202) is lower than a second set temperature. The method according to claim 1,
A heater 203 is provided in a supply pipe through which the heating water is supplied from the boiler 2 to the heat exchanging units 150 and 250 of the air conditioner 1 and the heating heat from the boiler 2 to the heat exchanging units 150 and 250 Wherein the control unit operates the heater (203) to supply the heated water heated by the heat exchanging unit (150, 250) The method according to claim 1,
Circulation of the heating water between the boiler 2 and the air conditioner 1 is performed by a circulation pump 24 provided in the boiler 2;
Wherein the hot water supply valves (151, 251) provided in the air conditioner (1) when the heating water is circulated are opened to intermittently supply the heating water to the heat exchanging units (150, 250) The method according to claim 1,
The heating water heated in the boiler 2 is supplied to either one of the heat exchanging units 150 and 250 or the heating means 3 selectively or simultaneously to the heat exchanging units 150 and 250 and the heat requiring place 3 Way valve (4) is provided in which the direction of opening and closing is set so as to supply it;
Wherein the opening / closing direction of the three-way valve (4) is controlled by the control unit The method according to claim 6,
The heat exchange portion supply pipe 6b is branched from the heating supply pipe 6a and the heat exchange water pipe 6c is provided to connect between the heat exchange portions 150 and 250 and the heat return pipe 6d, (4) is provided at an intersection of the heat exchange water pipe (6c) and the heat return pipe (6d) The method according to claim 6,
When the open / close direction of the three-way valve 4 is set so as to simultaneously supply the heating water heated in the boiler 2 to the heat exchanging units 150 and 250 and the heating target 3, the heat is transmitted through the heat exchanging units 150 and 250 And the opening degree of the three-way valve (4) is set so that the flow rate of the heating water is smaller than the flow rate of the heating water passing through the heating destination (3) An air conditioner (1) including at least one heat exchanging unit (150, 250) for performing an air conditioning function of indoor air by allowing heat exchange between heated water supplied from a boiler (2) and indoor air or outdoor air, The apparatus according to claim 1, further comprising: a freeze detection unit for detecting a freeze generation condition in the air conditioner; and a controller for controlling the freeze prevention mode to be performed when the freeze detection unit detects that the freeze- A control method for an air conditioner freeze prevention device,
The freeze protection mode includes:
a) detecting a freeze generation condition in the freeze detection unit;
b) receiving information sensed by the freeze detection unit and determining whether the freeze occurrence condition is present;
c) When the control unit determines that the condition for generating the freezing can be generated, the boiler 2 is operated to circulate the heated heating water between the boiler 2 and the heat exchanging units 150 and 250 of the air conditioner 1 through the inside of the pipe ;
Lt; / RTI >
The control unit selectively supplies the heating water heated in the boiler 2 to either one of the heat exchanging units 150 and 250 or the heating requirement destination 3 or the heat exchanging units 150 and 250 and the heat- To be supplied to the air conditioner at the same time 10. The method of claim 9,
The freeze detection unit comprises an outdoor air temperature sensor 201 for measuring a temperature of the outdoor air flowing into the air conditioner 1;
Wherein the control unit performs the freeze prevention mode when the temperature measured by the outdoor air temperature sensor (201) is below the first set temperature 10. The method of claim 9,
The freeze detection unit comprises a heating water temperature sensor 202 for measuring the heating water temperature inside the pipe for supplying the heating water to the heat exchanging units 150 and 250 of the air conditioner 1 in the boiler 2;
And the control unit performs the freeze prevention mode when the temperature measured by the heating water temperature sensor 202 is lower than the second set temperature. 10. The method of claim 9,
The freeze detection unit includes an outdoor air temperature sensor 201 for measuring the temperature of the outdoor air flowing into the air conditioner 1 and a heat exchanger And a heating water temperature sensor (28) for measuring the temperature of the heating water inside the pipe for supplying the heating water to the heating water temperature sensor (150, 250);
If the first condition that the temperature measured by the outdoor air temperature sensor 201 is equal to or lower than the first set temperature and the second condition that the temperature measured by the heating water temperature sensor 28 is equal to or lower than the second set temperature are all satisfied, And a control method of the freezing prevention device

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