KR101939586B1 - Air conditioner - Google Patents

Abstract

An air conditioner capable of implementing various air conditioning operation modes such as cooling, heating, humidifying, dehumidifying, air cleaning and ventilation while minimizing the number of heat exchangers is disclosed. The air conditioner includes a main body having a first flow path for blowing air into the room and a second flow path for blowing air out of the room, A dehumidifying rotor rotatably installed in the first flow path and the second flow path; And a humidification module provided in the first flow path downstream of the dehumidification rotor in the air flow direction to humidify the air passing through the humidification rotor, wherein the compressor, the condenser, the expansion means and the evaporator are sequentially provided in the refrigerant line, And one refrigerant cycle in this one direction; A third flow path accommodating the condenser on the upstream side of the dehumidification rotor in the air flow direction and a fourth flow path accommodating the evaporator on the downstream side of the dehumidification rotor in the air flow direction; And a plurality of dampers for selectively communicating the first flow path and the second flow path with the third flow path and the fourth flow path.

Description

AIR CONDITIONER

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner and a control method thereof, and more particularly to an air conditioner that performs cooling, heating, dehumidification, humidification, air cleaning, will be.

Generally, the air conditioner is composed of a refrigeration cycle in which a compressor, a condenser, an expansion valve, and an evaporator are connected by a refrigerant line. The compressor sucks and compresses the low-temperature, low-pressure gaseous refrigerant and discharges it to the condenser in a state of high temperature and high pressure. The condenser condenses the refrigerant by heat exchange with the air. The expansion valve throttles the refrigerant to a low-temperature and low-pressure state. The evaporator evaporates the refrigerant by heat exchange with the air.

Korean Patent Registration No. 10-1229676 (2013.01.29), which was filed on Jan. 19, 2013, discloses a method of producing cold water while reducing energy consumption by utilizing hot water, which is suitable for household use, and also, when condensation occurs on the surface during radiative cooling, There has been disclosed a hybrid cooling apparatus for preventing condensation on a floor or a ceiling without installing a cooling fan or the like.

An air conditioning system using a desiccant dehumidification rotor requires a heat source for regeneration. The heat source may be a condenser heat source (condensation heat) of the refrigeration cycle described above, or a separate electric heater may be used.

The air conditioner using the conventional refrigeration cycle includes an opening / closing means such as a reversing valve (4-way valve) circulating the refrigerant in the forward direction during cooling in the refrigeration cycle and circulating the refrigerant in the reverse direction during heating in cooling and heating, And the like.

On the other hand, the cooling and heating structure of the ventilating apparatus includes a plurality of heat exchangers (a cooling evaporator and a heating condenser) and a plurality of heat exchangers (a heating evaporator and a cooling condenser) on the indoor side in order to perform cooling and heating, By constructing the cycle in the diagonal direction, cooling and heating can be performed.

The air conditioning structure of the conventional ventilating apparatus has a disadvantage in that a plurality of heat exchangers must be provided. Compared with the cooling and heating capacities, a plurality of heat exchangers are applied to reduce the size of the heat exchanger, There is a problem.

Korean Registered Patent No. 10-1229676 (Feb.

In order to solve the above problems, the present invention provides an air conditioner capable of implementing various air conditioning operation modes such as cooling, heating, humidification, dehumidification, air cleaning and ventilation while minimizing the number of heat exchangers.

An air conditioner according to the present invention includes a main body having a first flow path for selectively flowing air into the room and a second flow path for blowing air out to the room, A dehumidifying rotor rotatably installed in the first flow path and the second flow path; And a humidification module provided in the first flow path downstream of the dehumidification rotor in the air flow direction to humidify the air passing through the humidification rotor, wherein the compressor, the condenser, the expansion means and the evaporator are sequentially provided in the refrigerant line, And one refrigerant cycle in this one direction; A third flow path accommodating the condenser on the upstream side of the dehumidification rotor in the air flow direction and a fourth flow path accommodating the evaporator on the downstream side of the dehumidification rotor in the air flow direction; And a plurality of dampers for selectively communicating the first flow path and the second flow path with the third flow path and the fourth flow path.

The air conditioner according to the present invention eliminates the reverse cycle related configuration of the refrigerant, constitutes a single unidirectional refrigerant cycle, and efficiently controls opening and closing of the air flow path through a plurality of dampers to perform cooling, heating, humidification, dehumidification, air cleaning, Various air-conditioning operation modes can be realized, and the size of the heat exchanger can be sufficiently secured to improve the air conditioning performance, and the overall package can be reduced to make a compact design.

FIG. 1 schematically shows a configuration of an air conditioner according to an embodiment of the present invention,
2 shows an air conditioner according to an embodiment of the present invention,
3 and 4 are sectional views taken along the line AA in Fig. 2,
5 to 14 show various operation modes of the air conditioner according to the embodiment of the present invention,
Fig. 15 shows a part of the air conditioner according to the modification of Fig. 2;

Hereinafter, the technical configuration of the air conditioner will be described in detail with reference to the accompanying drawings.

FIG. 1 schematically shows the configuration of an air conditioner according to an embodiment of the present invention. Referring to FIG.

1, an air conditioner according to an embodiment of the present invention includes a main body 10, a dehumidification rotor 30, a humidification module 40, a refrigerant cycle, and a plurality of dampers.

The main body 10 may be installed outdoors or indoors, or may be embedded in a ceiling, an outer wall, or the like as an outdoor unit. The main body 10 is configured to selectively inflow the inside air and the outside air. A first flow path 61 and a second flow path 62, which are air passages, are provided in the main body 10. The first flow path 61 is for blowing air into the room and the second flow path 62 is for blowing air outdoors.

The main body 10 is provided with an air inflow inlet 11 for inflowing indoor air, an outdoor air inflow opening 12 for inflowing outdoor air, an indoor air supply opening 13 for supplying air to the indoor space, An outdoor outlet 14 is provided. FIG. 1 schematically shows an air conditioner. The indoor air introduced through the indoor air inlet 11 is supplied to the indoor supply port 13 through the first flow path 61 and flows into the outdoor air inlet 12 through the outdoor air inlet 12 And the outside air is discharged to the outdoor discharge port 14 through the second flow path 62.

The gist of the present invention is not limited to the configuration of the present embodiment but is also applied to an embodiment in which the inside air and the outside air are selectively introduced so that the inside air is discharged to the outside through the second flow path and the outside air is supplied into the room through the first flow path It is possible. A detailed description thereof will be described later with reference to the other drawings.

The dehumidification rotor (30) is rotatably provided over the first flow path (61) and the second flow path (62). The dehumidification rotor 30 is disposed on the downstream side of the condenser 21 to be described later in the air flow direction. The dehumidification rotor 30 may be constructed in a desiccant structure, and a dehumidifying material is built in and performs moisture absorption, dehumidification, endothermic, and heat dissipation by air passing therethrough.

The humidification module 40 is provided in the first flow path 61 on the downstream side of the dehumidification rotor 30 in the air flow direction. The humidification module 40 humidifies air passing therethrough. The first flow path 61 is provided with an indoor fan 51 and the second flow path 62 is provided with an outdoor fan 52.

The refrigerant cycle is composed of one unit and the compressor 20, the condenser 21, the expansion unit 22 and the evaporator 23 are sequentially provided in the refrigerant line 24. The refrigerant flow direction of the refrigerant cycle is made in a single direction. That is, the refrigerant cycle circulates the refrigerant only in the normal direction, and does not require a reversing valve for redirecting the refrigerant in forward and reverse directions.

The compressor 20 sucks and compresses the gaseous refrigerant at a low temperature and a low pressure and discharges it to the condenser 21 in a state of high temperature and high pressure. In the condenser (21), the refrigerant is heat-exchanged with the air and condensed. The expansion valve 22 throttles the refrigerant to expand to a low-temperature and low-pressure state. In the evaporator 23, the refrigerant is heat-exchanged with the air and evaporated.

A third flow path (63) and a fourth flow path (64) are provided in the body (10). The third flow path (63) is formed on the upstream side of the dehumidification rotor (30) in the air flow direction and accommodates the condenser (21). The fourth flow path (64) is formed on the downstream side of the dehumidification rotor (30) in the air flow direction and accommodates the evaporator (23).

The third flow path 63 and the fourth flow path 64 are provided on the partition wall which is the boundary between the first flow path 61 and the second flow path 62. Accordingly, it is possible to intensively design the main body 10, thereby reducing the overall package.

The plurality of dampers selectively opens or closes the flow path by rotating or sliding the flow path to selectively communicate the first flow path 61 and the second flow path 62 with the third flow path 63 and the fourth flow path 64. A more detailed configuration of the dampers will be described later with reference to the other drawings.

FIG. 2 shows an air conditioner according to an embodiment of the present invention, and FIGS. 3 and 4 are sectional views taken along the line A-A of FIG. A more detailed configuration of the air conditioner will be described with reference to Figs. 2 to 4. Fig.

The main body 10 is provided with an inflow inlet 11 for introducing return air, that is, return air circulated in the room, and an outside air inlet 12 for introducing outside air. A first flow path 61 and a second flow path 62 are defined in the main body 10 and a fifth flow path 65 is connected to the second flow path 11. The sixth flow path 65 is connected to the outside air inlet 12, (66). The first flow path 61, the second flow path 62, the fifth flow path 65 and the sixth flow path 66 are connected to each other by a four-way damper 70.

The four-way damper 70 functions to selectively flow the indoor air introduced through the indoor air inlet 11 and the outdoor air introduced through the outdoor air inlet 12 into the first flow path 61 and the second flow path 62 . That is, the air introduced through the inflow inlet 11 flows into one of the first flow path 61 and the second flow path 62 by way of the four-way damper 70 through the fifth flow path 65, 12 flows through the sixth flow path 66 to the other of the first flow path 61 and the second flow path 62 by the four-way damper 70.

3 and 4 are plan views of the four-way damper 70 as viewed from above. When the four-way damper 70 is rotated as shown in FIG. 3, the inner air flowing into the inner air inlet 11 flows into the second flow path 62 And the outside air flowing into the outside air inflow port 12 flows toward the first flow path 61 side. 4, when the four-way damper 70 is rotated, the inner air flowing into the indoor air inflow port 11 flows to the first flow path 61 side, and the outdoor air flowing into the outdoor air inflow port 12 flows into the second Flows to the flow path 62 side.

In addition, the main body 10 is provided with an indoor supply port 13 for supplying air to the room and an outdoor discharge port 14 for discharging air to the outside. The fifth flow path 65 is provided with a first filter 15 composed of at least one of a prefilter, a deodorization filter and a heparin filter. The sixth flow path 66 is provided with at least one of a prefilter and a medium filter. 2 filter 16 so as to filter the air passing therethrough.

The dehumidification rotor 30 is formed in a circular plate shape having a predetermined thickness and is made to be rotatable around the rotary shaft 33 with a dehumidifying material such as a nonwoven fabric material incorporated therein. It is preferable that the dehumidification rotor 30 is rotated at a relatively low speed of about 0.5 rpm or less. The dehumidification rotor 30 occupies 1/2 the first flow path 61 and the second flow path 62 with respect to the partition wall between the first flow path 61 and the second flow path 62, A humidifying region 31 for humidifying the air passing through the humidifier 61 and a humidifying region 32 for dehumidifying the air passing through the humidifier 61 in the second flow path.

The third flow path 63 is partitioned by the partition wall relative to the first flow path 61 and the second flow path 62 and is formed between the first flow path 61 and the second flow path 62. The condenser 21 is provided in the third flow path 63 and the air flowing in the third flow path 63 is arranged to pass through the condenser 21.

The fourth flow path 64 is partitioned by the partition wall relative to the first flow path 61 and the second flow path 62 and is formed between the first flow path 61 and the second flow path 62. The evaporator 23 is provided in the fourth flow path 64 and the air flowing through the fourth flow path 64 is arranged to pass through the evaporator 23.

The compressor (20), the expansion means (22) and the refrigerant line (24) may be disposed within the body (10). In this case, the compressor 20 may be disposed in the second flow path 62, and the expansion means 22 may be disposed in the first flow path 61. The high-temperature, high-pressure refrigerant discharged from the compressor (20) dissipates heat in the condenser (20), and the condenser (20) functions as a heating heat exchanger. The low-temperature low-pressure refrigerant that has passed through the expansion means 22 evaporates in the evaporator 23, and the evaporator 23 functions as a cooling heat exchanger.

The humidification module 40 includes a water supply section 41 for supplying water and a humidifying filter 43 for humidifying the water supplied by the water supply section 41 to supply moisture to air passing therethrough, And a drainage part 42 provided at a lower part of the drainage part 42 for draining water. The first flow path 61 is provided with an indoor fan 51 and the second flow path 62 is provided with an outdoor fan 52.

The air conditioner includes a first damper 71, a second damper 72, a third damper 73, a fourth damper 74, a fifth damper 75 and a sixth damper 76 do. The air conditioner includes a seventh damper 77, an eighth damper 78, a ninth damper 79, a tenth damper 80, an eleventh damper 81 and a twelfth damper 82, Respectively.

The first damper 71 is provided in the first flow path 61 to adjust the opening of the flow path bypassing the condenser 21. The second damper 72 regulates the opening between the first flow path 61 and the third flow path 63 on the upstream side of the condenser 21. The air can flow only when the first flow path 61 is blocked by the partition and the first damper 71 is opened. The second damper 72 opens and closes the flow path so that the air in the first flow path 61 selectively passes through the condenser 21.

The third damper 73 is provided in the second flow path 62 to adjust the opening of the flow path for bypassing the condenser 21. The fourth damper 74 regulates the opening between the second flow path 62 and the third flow path 63 on the upstream side of the condenser 21. The air can flow only when the second flow path 62 is blocked by the partition wall and the third damper 73 is opened. The fourth damper 74 opens and closes the flow path so that the air in the second flow path 62 selectively passes through the condenser 21.

The fifth damper 75 regulates the opening degree between the first flow path 61 and the third flow path 63 on the downstream side of the condenser 21. The sixth damper 76 regulates the opening degree between the second flow path 62 and the third flow path 63 on the downstream side of the condenser 21. The air in the third flow path 63 that has passed through the condenser 21 must flow through the first flow path 61 or the sixth damper 76 to open the second flow path 62, Lt; / RTI >

The seventh damper 77 is provided in the first flow path 61 on the downstream side of the dehumidification rotor 30 to regulate the opening of the flow path for bypassing the evaporator 23. The eighth damper 78 regulates the opening between the downstream first flow path 61 of the dehumidification rotor 30 and the upstream fourth flow path 64 of the evaporator 23. The air can flow only when the first flow path 61 on the downstream side of the dehumidification rotor 30 is blocked by the partition and the seventh damper 77 is opened. The eighth damper 78 opens and closes the flow path so that air in the first flow path 61 selectively passes through the evaporator 23.

The ninth damper 79 is provided in the second flow path 62 on the downstream side of the dehumidification rotor 30 to regulate the opening of the flow path for bypassing the evaporator 23. The tenth damper 80 regulates the opening between the second flow path 62 on the downstream side of the dehumidification rotor 30 and the fourth flow path 64 on the upstream side of the evaporator 23. The air can flow only when the second flow path 62 on the downstream side of the dehumidification rotor 30 is blocked by the partition wall and the ninth damper 79 is opened. The tenth damper 80 opens and closes the flow path so that air in the second flow path 62 selectively passes through the evaporator 23.

The eleventh damper 81 regulates the opening degree between the first flow path 61 and the fourth flow path 64 on the downstream side of the evaporator 23. The twelfth damper 82 regulates the opening degree between the second flow path 62 and the fourth flow path 64 on the downstream side of the evaporator 23. The air in the fourth flow path 64 that has passed through the evaporator 23 must be discharged through the first flow path 61 or the twelfth damper 82 by opening the eleventh damper 81, Lt; / RTI >

The humidification module 40 is disposed on the downstream side of the seventh damper 77 and the eleventh damper 81 in the air flow direction.

15, a part of the air conditioner according to the modification of FIG. 2 is shown. Referring to FIG. 15, the air passage passing through the condenser 21 and the air passage bypassing the condenser 21 are connected to two doors It is also possible to open and close them by one door without opening and closing them respectively.

That is, the thirteenth damper 85 opens and closes between the flow path to the condenser 21 and the first flow path 61 to bypass the condenser 21. The thirteenth damper 85 performs the functions of the first damper and the second damper of the embodiment of FIG. The thirteenth damper 85 may be in the form of a dome, or may be embodied in other forms.

The fourteenth damper 86 opens and closes between the flow path for the condenser 21 and the second flow path 62 for bypassing the condenser 21. The fourteenth damper 86 performs the functions of the third damper and the fourth damper of the embodiment of FIG. The fourteenth damper 85 may be in the form of a dome, or may be embodied in other forms.

Although not shown, the fifth damper to the twelfth damper of FIG. 2 may be appropriately integrated into one door to perform the same function.

In addition, the air conditioner according to an embodiment of the present invention may include a non-humidifying mode, a total heat exchange ventilation mode, and a bypass ventilation mode, among various operation modes. 5 to 14 illustrate various operation modes of the air conditioner according to an embodiment of the present invention, and an operation example of each operation mode will be described in detail with reference to the drawings.

Referring to FIG. 5, in the cooling mode, the refrigerant cycle is turned on, the dehumidification rotor 30 is stopped, and the humidification module 40 is turned off. The air introduced into the air inlet 11 flows into the first flow path 61 by the four-way damper 70 to bypass the condenser 21 and pass the dehumidification rotor 30 through the evaporator 23 for heat exchange . The air exchanged with the evaporator 23 is cooled and supplied to the room through the indoor supply port 13.

On the other hand, the outside air flowing into the outside air inlet 12 flows into the second flow path 62 by the four-way damper 70 and exchanges heat with the condenser 21. Exchanged air with the condenser 21 is heated and passed through the dehumidifying rotor 30 to bypass the evaporator 23 and then discharged to the outside through the outdoor outlet 14. [

Referring to FIG. 6, in the heating mode, the refrigerant cycle is turned on, the dehumidification rotor 30 stops rotating, and the humidification module 40 is turned off. The inner air introduced into the air inlet 11 flows into the first flow path 61 through the four-way damper 70 and passes through the condenser 21 to perform heat exchange. The air exchanged with the condenser 21 is heated and passed through the dehumidifying rotor 30 to bypass the evaporator 23 and then is supplied to the room through the humidification module 40 and the indoor supply port 13.

The outside air introduced into the outside air inlet 12 flows into the second flow path 62 by the four direction damper 70 to bypass the condenser 21 and then flows through the dehumidifying rotor 30 to the evaporator 23 And is discharged to the outside through the outdoor outlet 14.

Referring to FIG. 7, in the cooling and dehumidification mode, the refrigerant cycle is turned on, the dehumidification rotor 30 is driven to rotate, and the humidification module 40 is turned off. The air introduced into the air inlet 11 flows into the first flow path 61 by the four-way damper 70 to bypass the condenser 21 and pass the dehumidification rotor 30 through the evaporator 23 for heat exchange . The air exchanged with the evaporator 23 is cooled and supplied to the room through the indoor supply port 13.

On the other hand, the outside air flowing into the outside air inlet 12 flows into the second flow path 62 by the four-way damper 70 and exchanges heat with the condenser 21. Exchanged air with the condenser 21 is heated and passed through the dehumidifying rotor 30 to bypass the evaporator 23 and then discharged to the outside through the outdoor outlet 14. [

The warm air of the second flow path 62 heated by the condenser 21 is dehumidified while passing through the dehumidification rotor 30 so that the air passing through the dehumidification rotor 30 of the first flow path 61 Is dehumidified and then flows to the evaporator (23).

8, in the heating and humidifying mode, the refrigerant cycle is turned on, the dehumidifying rotor 30 is stopped rotating, and the humidification module 40 is turned on. The inner air introduced into the air inlet 11 flows into the first flow path 61 through the four-way damper 70 and passes through the condenser 21 to perform heat exchange. The air exchanged with the condenser 21 is heated and passed through the dehumidifying rotor 30 to bypass the evaporator 23 and then is supplied to the room through the humidification module 40 and the indoor supply port 13. The warm air passing through the humidification module 40 is humidified by the humidification module 40.

The outside air introduced into the outside air inlet 12 flows into the second flow path 62 by the four direction damper 70 to bypass the condenser 21 and then flows through the dehumidifying rotor 30 to the evaporator 23 And is discharged to the outside through the outdoor outlet 14.

Referring to FIG. 9, in the dehumidification mode, the refrigerant cycle is turned on, the dehumidification rotor 30 is driven to rotate, and the humidification module 40 is turned off. The inner air introduced into the air inlet 11 flows into the first flow path 61 by the four-way damper 70 to bypass the condenser 21 and bypass the evaporator 23 through the dehumidification rotor 30 And is supplied to the room through the indoor supply port (13) through the humidification module (40).

On the other hand, the outside air flowing into the outside air inlet 12 flows into the second flow path 62 by the four-way damper 70 and exchanges heat with the condenser 21. The air exchanged with the condenser 21 is heated and discharged to the outside through the dehumidifying rotor 30 through the evaporator 23 and the outdoor outlet 14.

The warm air of the second flow path 62 heated by the condenser 21 is dehumidified while passing through the dehumidification rotor 30 so that the air passing through the dehumidification rotor 30 of the first flow path 61 Is dehumidified and then supplied to the room.

Referring to FIG. 10, in the humidification mode, the refrigerant cycle is turned off, the dehumidification rotor 30 is stopped, and the humidification module 40 is turned on. The inner air introduced into the air inlet 11 flows into the first flow path 61 by the four-way damper 70 to bypass the condenser 21 and then bypasses the evaporator 23 through the dehumidification rotor 30 And then is supplied to the room through the indoor supply port (13) through the post-humidifying module (40). The air passing through the humidification module 40 is humidified by the humidification module 40.

On the other hand, the outside air fan 52 is turned off and air does not flow into the second flow path 62.

Referring to FIG. 11, in the no-humid humidification mode, the refrigerant cycle is turned on and the humidification module 30 is driven to rotate, and the humidification module is turned off. The inner air introduced into the air inlet 11 flows into the first flow path 61 through the four-way damper 70 and passes through the condenser 21 to perform heat exchange. The air exchanged with the condenser 21 is heated and passed through the dehumidifying rotor 30 to bypass the evaporator 23 and then supplied to the room through the humidification module 40 and the indoor supply port 13.

The outside air introduced into the outside air inlet 12 flows into the second flow path 62 by the four direction damper 70 to bypass the condenser 21 and then flows through the dehumidifying rotor 30 to the evaporator 23 And is discharged to the outside through the outdoor outlet 14.

The unprivileged humidification mode is suitable for outdoor environments such as wet, spring, and autumn, where the relative humidity is high. That is, in the no-humid humidification mode, the water supply of the humidification module 40 is stopped so that the humidification module 40 can not substantially provide moisture, The dehumidification rotor 30 is absorbed by the outside air and humidified by providing the moisture to the high temperature air passing through the first flow path 61. [ In this unprivileged humidification mode, since the humidification module 40 is not driven separately, power consumption is reduced and water supply is omitted, so that consumption of water can be reduced.

Referring to FIG. 12, in the air cleaning mode, the refrigerant cycle is turned off, the dehumidification rotor 30 stops rotating, and the humidification module 40 is turned off. The inner air introduced into the air inlet 11 flows into the first flow path 61 by the four-way damper 70 to bypass the condenser 21 and then bypasses the evaporator 23 through the dehumidification rotor 30 And then is supplied to the room through the indoor supply port (13) through the post-humidifying module (40).

On the other hand, the outside air fan 52 is turned off and air does not flow into the second flow path 62.

In the air cleaning mode, the air in the room passes through the first filter (15) of the fifth flow path (63) without being subjected to rotation power or water supply of a separate heat source or dehumidification rotor, and is repeatedly circulated.

Referring to FIG. 13, in the total heat exchange ventilation mode, the refrigerant cycle is turned off and the dehumidification rotor 30 is driven to rotate, and the humidification module is turned off. The inner air flowing into the air inlet 11 flows into the second flow path 62 by the four direction damper 70 to bypass the condenser 21 and then bypasses the evaporator 23 through the dehumidifying rotor 30 And is discharged to the outside through the outdoor outlet (14).

The outside air flowing into the outside air inlet 12 flows into the first flow path 61 by the four direction damper 70 to bypass the condenser 21 and then flows through the dehumidifying rotor 30 to the evaporator 23 Passes through the humidification module (40), and is supplied to the room through the indoor supply port (13).

The total heat exchange ventilation mode is an air conditioning mode for discharging contaminated air in the room to outside and introducing fresh air outdoors into the room. The total heat exchange ventilation mode is advantageous when the indoor and outdoor temperature difference is about 3 ° C or more. In the total heat exchange ventilation mode, the relatively warm air in the room is heated and dehumidified after the dehumidification rotor 30 passes through the dehumidification rotor 30 by rotating the dehumidification rotor 30, And is then supplied to the room through the dehumidifying rotor 30 through the dehumidified heat absorption and dehumidification. Therefore, there is an advantage that the room air can be heated up to a predetermined temperature and dehumidified without any additional heat source.

Referring to FIG. 14, in the bypass ventilation mode, the refrigerant cycle is turned off, the dehumidification rotor 30 is stopped, and the humidification module is turned off. The inner air flowing into the air inlet 11 flows into the second flow path 62 by the four direction damper 70 to bypass the condenser 21 and then bypasses the evaporator 23 through the dehumidifying rotor 30 And is discharged to the outside through the outdoor outlet (14).

The outside air flowing into the outside air inlet 12 flows into the first flow path 61 by the four direction damper 70 to bypass the condenser 21 and then flows through the dehumidifying rotor 30 to the evaporator 23 Passes through the humidification module (40), and is supplied to the room through the indoor supply port (13).

The bypass ventilation mode is an air conditioning mode for discharging contaminated air in the room to the outside and introducing fresh air out of the room to the room in the same manner as the above-mentioned total heat exchange ventilation mode. The bypass ventilation mode is advantageous when the indoor and outdoor temperature differences are about 3 ° C or less.

Although the air conditioner according to the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that various modifications and equivalents may be made by those skilled in the art without departing from the scope of the present invention. Accordingly, the scope of the true technical protection should be determined by the technical idea of the appended claims.

10: main body 11:
12: outdoor air inlet 13: indoor air inlet
14: outdoor outlet 15: first filter
16: second filter 20: compressor
21: condenser 22: expansion means
23: evaporator 24: refrigerant line
30: dehumidification rotor 31: humidification zone
32: dehumidifying area 33: rotating shaft
40: Humidification module 41: Water supply section
42: drainage part 43: humidifying filter
51: indoor fan 52: outdoor fan
61: first flow path 62: second flow path
63: third euro 64: fourth euro
65: 5th EURO 66: 6th EURO
70: Four-way damper 71: First damper
72: second damper 73: third damper
74: fourth damper 75: fifth damper
76: Sixth damper 77: Seventh damper
78: eighth damper 79: ninth damper
80: tenth damper 81: eleventh damper
82: the twelfth damper

Claims (9)

A main body having a first flow path for blowing air into the room and a second flow path for blowing air out of the room; And a dehumidification rotor rotatably installed in the first flow path and the second flow path,
A refrigerant cycle in which a compressor, a condenser, an expansion means, and an evaporator are sequentially provided in a refrigerant line, and a refrigerant flow direction is one direction;
A third flow path accommodating the condenser on the upstream side of the dehumidification rotor in the air flow direction and a fourth flow path accommodating the evaporator on the downstream side of the dehumidification rotor in the air flow direction; And a plurality of dampers for selectively communicating the first flow path and the second flow path with the third flow path and the fourth flow path,
The dehumidifying rotor is disposed between the third flow path and the fourth flow path. A condenser is disposed upstream of the dehumidification rotor in the direction of air flow so that air selectively passes through the condenser. Wherein an evaporator is disposed on the downstream side of the evaporator so that air selectively passes through the evaporator. The method according to claim 1,
Wherein the third flow path and the fourth flow path are provided on a partition wall which is a boundary between the first flow path and the second flow path. The method according to claim 1,
A second damper provided in the first flow path to adjust the opening degree of the flow path for bypassing the condenser; a second damper for adjusting the opening degree between the first flow path and the third flow path on the upstream side of the condenser; A third damper provided in the flow path to adjust the opening degree of the flow path for bypassing the condenser; a fourth damper for adjusting the opening degree between the second flow path and the third flow path on the upstream side of the condenser; A fifth damper for adjusting the degree of opening between the third flow path on the downstream side of the condenser and a sixth damper for adjusting the opening degree between the second flow path and the third flow path on the downstream side of the condenser, . The method according to claim 1,
An eighth damper provided in the first flow path to adjust an opening degree of a flow path for bypassing the evaporator, an eighth damper for adjusting an opening degree between the first flow path and a fourth flow path on the upstream side of the evaporator, A tenth damper provided in the flow path to adjust the opening degree of the flow path for bypassing the evaporator, a tenth damper for adjusting the opening degree between the second flow path and the fourth flow path on the upstream side of the evaporator, An eleventh damper for adjusting the degree of opening between the fourth flow path on the downstream side of the evaporator and a twelfth damper for adjusting the opening degree between the second flow path and the fourth flow path on the downstream side of the evaporator, . 5. The method of claim 4,
And a humidification module provided in the first flow path on the downstream side of the dehumidification rotor in the air flow direction to humidify the air passing through the first flow path,
Wherein the humidification module is disposed downstream of the seventh damper and the eleventh damper in the air flow direction. The method according to claim 1,
Said body comprising:
An inflow inlet for inflowing the bet;
An outside air inlet for introducing outside air; And
And a four-way damper for selectively flowing the outdoor air flowing through the indoor air inlet port and the outdoor air inlet port to the first flow path and the second flow path. The method according to claim 1,
The refrigerant cycle is turned on and the dehumidification rotor is driven to rotate. After the inflow air flows into the first flow path, the refrigerant passes through the condenser and the dehumidification rotor, bypasses the evaporator, passes through the humidification module, And the humidification module is provided with a non-humidifying humidifying mode in which the water supply is turned off after the outside air flows into the second flow path, bypasses the condenser, passes through the dehumidifying rotor and is discharged to the outside through the evaporator The air conditioner comprising: The method according to claim 1,
The refrigerant cycle is turned off and the dehumidifying rotor is driven to rotate. After the introduced air flows to the second flow path, the condenser is bypassed, and then the dehumidified air passes through the dehumidifying rotor to bypass the evaporator, After the introduced outside air flows to the first flow path, the condenser is bypassed, and then the evaporator is bypassed after passing through the dehumidifying rotor. The evaporator is then supplied to the room through the humidifying module. In the humidifying module, And an exchange ventilation mode. The method according to claim 1,
The refrigerant cycle is turned off and the dehumidifying rotor is stopped to rotate. After the inflowing air flows to the second flow path, the condenser is bypassed, and then the dehumidified air is passed through the dehumidifying rotor to bypass the evaporator, After the outdoor air flows into the first flow path, the outdoor air bypasses the condenser, passes through the dehumidifying rotor, bypasses the evaporator, passes through the humidification module and is supplied to the room. And a pass ventilation mode.

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