KR102216718B1 - Air conditioner - Google Patents

Abstract

An object of the present invention is to provide an air conditioner capable of improving efficiency by allowing indoor air and outdoor air passing through a dehumidifying rotor to form a counter flow. An air conditioner for implementing this includes: a dehumidifying rotor for adsorbing moisture or discharging the adsorbed moisture while alternately passing through a first area and a second area by rotation; A first space part and a second space part respectively positioned on one side of the air passage passing through the second area, which is an indoor side and the other side of an outdoor side; And a third space part and a fourth space part respectively located on one side of the air passage through the first area, which is an indoor side and the other side, which is an outdoor side, and includes air passing through the first area and the second area. Air passing through it forms a counter flow.

Description

Air conditioner {AIR CONDITIONER}

The present invention relates to an air conditioner, and more particularly, to an air conditioner configured such that air passing through a dehumidifying rotor forms a counter flow.

In general, an air conditioner is a device that adjusts indoor temperature and humidity according to a user's request or ventilates indoor air to keep the room comfortable.

Recently, technologies have been developed to keep indoor air comfortable according to seasonal changes according to the user's selection by adding various functions such as dehumidification, humidification, cooling, heating, air purification, and ventilation to the air conditioner.

As a conventional air conditioner, Korean Patent Registration No. 10-1782838 "Air conditioner and its control method" is disclosed.

In the air conditioner of the prior art, a first air flow path having both ends connected to the room, a second air flow path connected to the outdoors, a first area provided on the first air flow path, and a second air flow path provided on the second air flow path. A dehumidifying rotor including a second region is shown.

When the air conditioner is operated in the dehumidification mode, moisture contained in the indoor air is adsorbed in the first area of the dehumidifying rotor, and the adsorbed moisture is transferred to the air passing through the second area in the second area by rotating the dehumidifying rotor. Is released.

In this case, since the air passing through the first area and the air passing through the second area are arranged to have the same flow direction, there is a problem that dehumidification efficiency is deteriorated.

This problem will be described in detail with reference to FIG. 1.

The indoor air flowing through the first air passage 1 passes through one side A of the first region 3a of the dehumidifying rotor 3 and sequentially passes through the other side C. Therefore, a large amount of moisture contained in the indoor air is adsorbed on one side (A) and a small amount on the other side (C).

In this way, one side (A) of the dehumidifying rotor (3) to which a large amount of moisture is adsorbed is rotated and located at point B of the second area (3b), and the other side (C) of the dehumidifying rotor (3) with a small amount of moisture adsorbed is It is located at point D of the second area 3b.

In this state, the outdoor air flowing through the second air channel 2 passes through one side (B) of the second area 3b where a large amount of moisture has been adsorbed, and the humidity increases and then the other area of the second area 3b is When passing through the side (D), moisture adsorbed on the other side (D) of the second area (3b) due to the increased humidity is discharged to the air passing through the other side (D) of the second area (3b). As the ratio of the product is reduced, the regeneration efficiency decreases. After that, if the dehumidifying rotor 3 is further rotated, moisture remaining without being released into the air from the other side (D) of the second area (3b) is located on the other side (C) of the first area (3a). , The efficiency of removing moisture from indoor air flowing through the first air passage 1 is reduced.

In addition, when the air conditioner operates in the ventilation mode, there is a problem in that the efficiency of total heat exchange is deteriorated. That is, when operating in the ventilation mode in winter, warm air from indoors is discharged to the outside through the first air passage (1), and cold air from outside through the second air passage (2) is introduced into the room. In this case, as the indoor air passes through the first region 3a, the temperature of one side A rises a lot, while the temperature of the other side C rises relatively less. In this state, when the dehumidifying rotor (3) rotates and one side where the temperature rises a lot becomes B position, and the other side, where the temperature rises less, becomes D position, the cold air outside flows through the second air channel (2). First, the temperature rises to some extent by contacting one side of the B position, but the heat transfer efficiency from the indoor air to the outdoor air decreases because the temperature has to pass through the other side (D), where the temperature is relatively lower, just before entering the room. do.

In addition, in the air conditioner of the prior art, a flow path switching unit for changing the flow path directions of the first air flow path and the second air flow path is shown.

When the flow path switching part is provided in the air conditioner, a connection part connected to the first air flow path and the second air flow path, and a damper for changing the direction of the air flow path should be provided. A plurality of such connection parts and dampers inside the air conditioner When is provided, the structure of the air conditioner becomes complicated, and there is a problem that the device becomes large.

The present invention has been devised to solve the above-described problems, and an object thereof is to provide an air conditioner capable of improving efficiency by allowing indoor air and outdoor air passing through a dehumidifying rotor to form a counter flow.

Another object of the present invention is to provide an air conditioner capable of miniaturizing the size of the air passing through the dehumidifying rotor while forming a counter flow.

Another object of the present invention is to provide an air conditioner capable of converting the flow path of indoor air and outdoor air introduced into the air conditioner using a simple structure.

Another object of the present invention is to provide an air conditioner capable of simplifying the structure by integrally providing an air introduction unit through which indoor air and outdoor air are introduced on one side of the main body.

Another object of the present invention is to provide an air conditioner capable of reducing a load of a driving unit for driving a damper for switching a flow path between indoor air and outdoor air, and reducing a flow path switching time.

The air conditioner of the present invention for achieving the above object comprises: a dehumidifying rotor that adsorbs moisture or discharges the adsorbed moisture while alternately passing through a first area and a second area by rotation; A first space part and a second space part respectively positioned on one side of the air passage passing through the second area, which is an indoor side and the other side of an outdoor side; And a third space part and a fourth space part respectively located on one side of the air passage through the first area, which is an indoor side and the other side, which is an outdoor side, and includes air passing through the first area and the second area. Air passing through it forms a counter flow.

The first space part may be stacked above the third space part, and the second space part may be stacked above the fourth space part.

A main body including the first to fourth spaces is provided; At one side of the main body, an air introduction part having two air passages formed so that indoor air introduced from the indoor and outdoor air introduced from the outdoor flow independently. It can be provided.

An indoor inlet provided on one side of the indoor side of the air introduction unit through which the indoor air is introduced; An outdoor inlet provided on the other side of the outdoor side of the air introduction unit through which the outdoor air is introduced; An indoor discharge port provided to communicate with the third space on one side of the interior of the main body to discharge air into the interior; In order to discharge air to the outdoors, an outdoor discharge port may be provided to communicate with the second space on the other side of the outside of the main body.

In the partition wall blocking between the main body part and the air introduction part, a first opening part which communicates the air flow path of the air introduction part and the first space part is formed in a part corresponding to the first space part, and corresponds to the fourth space part A second opening that communicates the air flow path of the air introduction part and the fourth space part may be formed in the part.

An indoor inlet provided on one side of the indoor side of the air introduction unit through which the indoor air is introduced; An outdoor inlet provided on the other side of the outdoor side of the air introduction unit through which the outdoor air is introduced; An indoor discharge port provided to communicate with the first space to discharge air into the room; And an outdoor outlet provided to communicate with the fourth space to discharge air to the outdoors.

In the partition wall blocking between the main body part and the air introduction part, a first opening part for communicating the air flow path of the air introduction part and the third space part is formed in a part corresponding to the third space part, and corresponding to the second space part A second opening that communicates the air flow path of the air introduction part and the second space part may be formed in the portion.

The air introducing unit may be provided with a damper for dividing the inner space of the air introducing unit into the two air passages, and switching the air passages between the indoor air and the outdoor air by rotation.

The damper allows indoor air introduced through the indoor inlet to flow to the first space through the first opening, and the outdoor air introduced through the outdoor inlet to flow to the fourth space through the second opening It is set to the first position to allow; A second for flowing indoor air introduced through the indoor inlet to the fourth space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the first space through the first opening Can be set by position.

The damper allows indoor air introduced through the indoor inlet to flow to the third space through the first opening, and the outdoor air introduced through the outdoor inlet to flow to the second space through the second opening. It is set to the first position to allow; A second for flowing indoor air introduced through the indoor inlet to the second space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the third space through the first opening Can be set by position.

The damper is formed in a plate shape that rotates about a rotation axis; A first damper member, a second damper member, a third damper member, and a fourth damper member are provided on the top, bottom, left, and right around the rotation axis of the damper; Both ends of the damper are in contact with the first damper member and the second damper member, respectively, to block the flow of air between the inner space of the air introduction part divided by the damper; The damper rotates so that both ends of the damper contact the third damper member and the fourth damper member, respectively, to block the flow of air between the inner space of the air introduction unit divided by the damper.

The third damper member includes a damper contact portion to which one end of the damper contacts, and an air blocking portion extending in a curved shape from an end of the damper contact portion to block air introduced through the indoor inlet; The fourth damper member may include a damper contact portion to which the other end of the damper is in contact, and an air blocking portion extending in a curved shape from an end of the damper contact portion to block air introduced through the outdoor inlet.

The air blocking part of the third damper member extends upward or downward from the end of the damper contact part of the third damper member, and the air blocking part of the fourth damper member is at the end of the damper contact part of the fourth damper member. It may extend in a direction opposite to the air blocking portion of the third damper member.

The damper may include an indoor damper for changing a flow direction of indoor air introduced through an indoor inlet, and an outdoor damper for changing a flow direction of outdoor air introduced through the outdoor inlet.

The indoor damper and the outdoor damper allow indoor air introduced through the indoor inlet to flow to the third space through the first opening, and allow outdoor air introduced through the outdoor inlet to flow through the second opening. It is set to a first position for flowing into the second space; A second for flowing indoor air introduced through the indoor inlet to the second space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the third space through the first opening Can be set by position.

The indoor damper and the outdoor damper allow the indoor air introduced through the indoor inlet to flow into the first space through the first opening, and the outdoor air introduced through the outdoor inlet through the second opening. It is set to a first position for flowing into the fourth space; A second for flowing indoor air introduced through the indoor inlet to the fourth space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the first space through the first opening Can be set by position.

The indoor damper and the outdoor damper are hinged to both ends of a central separation plate that vertically divides the inner space of the air introduction unit; When the indoor damper rotates the hinge of the indoor damper to one of the first position and the second position with respect to the rotational center, the indoor air flows to one of the upper space and the lower space of the central separation plate. ; When the outdoor damper rotates the hinge of the outdoor damper to be one of the first and second positions around the rotational center, the outdoor air flows to one of the upper space and the lower space of the central separation plate. It may be to let you do.

When the indoor damper and the outdoor damper rotate, a rotation limiting member for limiting a vertical rotation angle may be provided, respectively.

A first heat exchanger for heating or cooling the air flowing toward the first region and a second heat exchanger for heating or cooling the air flowing toward the second region may be provided.

A first blower for inhaling indoor air or outdoor air in any one of the first and third spaces; A second blower for inhaling indoor air or outdoor air in any one of the second and fourth spaces; The first blower and the second blower may be provided in spaces having different heights.

Air passing through the first region and air passing through the second region may have a step and flow in opposite directions.

According to the present invention, the efficiency of the air conditioner can be improved by allowing the indoor air and outdoor air passing through the dehumidifying rotor to form a counter flow.

In addition, while the air passing through the dehumidifying rotor forms a counter flow, the space before and after the dehumidifying rotor has a stacked structure, so that the size of the air conditioner can be reduced.

In addition, the structure of the air conditioner can be simplified by integrally providing an air introduction part through which indoor air and outdoor air flow into one side of the main body and a damper inside the air introduction part.

In addition, by allowing air to flow through an opening between the body portion and the air introduction portion, the path of the air passage is minimized, thereby minimizing static pressure loss when air flows, thereby reducing the load of the blower, thereby reducing power consumption.

In addition, by providing a damper on the indoor side and the outdoor side, respectively, the load of the driving unit for driving the damper for switching the flow path of indoor air and outdoor air can be reduced, and the flow path switching time can be reduced.

1 is a view showing air flow in a conventional dehumidifying rotor
2 is a view showing the configuration of an air conditioner according to the present invention
3 is a perspective view showing an air conditioner according to a first embodiment of the present invention
FIG. 4 is a perspective view showing an air introduction part in the air conditioner of FIG. 3
FIG. 5 is a cross-sectional view showing a state in which the damper of the air introduction part is rotated in the air conditioner of FIG. 3
6 is an AA cross-sectional view of FIG. 3
FIG. 7 is a cross-sectional view taken along BB of FIG. 3
8 is a perspective view showing an air conditioner according to a second embodiment of the present invention
9 is a perspective view showing an air introduction part in the air conditioner of FIG. 8
FIG. 10 is a cross-sectional view showing a state in which a damper of an air introduction part is rotated in the air conditioner of FIG. 8
11 is a cross-sectional view taken along the line CC of FIG. 8
12 is a DD cross-sectional view of FIG. 8
13 is a view showing an embodiment in which the body portion of the first embodiment and the air introduction portion of the second embodiment are combined
14 is a view showing the structure of an air introduction unit according to another embodiment

Hereinafter, an air conditioner of the present invention will be described in detail with reference to the accompanying drawings.

<First Example>

The configuration of an air conditioner according to a first embodiment of the present invention will be described with reference to FIGS. 2 to 7.

Referring to FIG. 2, the air conditioner 100 of the present invention includes a body part 110 having a dehumidifying rotor 121, a first heat exchanger 122 and a second heat exchanger 123 therein, It is provided on one side of the main body 110 and consists of an air introduction unit 150 through which indoor air and outdoor air are introduced.

An indoor inlet 101 through which indoor air is introduced is provided on one side of the air introduction unit 150, and an outdoor inlet 103 through which outdoor air is introduced is provided on the other side of the air introduction unit 150.

One side of the main body 110 is provided with an indoor outlet 102 for discharging air into the room, and the other side of the main body 110 is provided with an outdoor outlet 104 for discharging air to the outside. do.

A dehumidifying rotor 121 for adsorbing moisture or discharging the adsorbed moisture while alternately passing through the first area 121a and the second area 121b by rotation is provided inside the main body 110. The dehumidifying rotor 121 is provided with an adsorbent for adsorbing moisture therein.

In the dehumidification mode, the adsorbent located in the first region 121a adsorbs moisture contained in the indoor air passing through the first region 121a. When the adsorbent having absorbed moisture rotates and is positioned in the second area 121b, the indoor air is dehumidified by releasing moisture into the air passing through the second area 121b.

The dehumidifying rotor 121 is rotated by a driving unit (not shown) around an axis provided in the center.

In this case, the air passing through the first region 121a and the air passing through the second region 121b form a counter flow. Here, the counterflow means a state in which air flows in opposite directions. As such, when the air passing through the dehumidifying rotor 121 forms a counter flow, the dehumidification efficiency and the total heat exchange efficiency are improved, and the reason will be described later.

The main body 110 is provided with a heat pump for heating or cooling the air passing through the first region 121a and the second region 121b.

The heat pump may include a compressor 126 for compressing a refrigerant into a high-temperature and high-pressure gas refrigerant, a first heat exchanger 122 (for heating) or a first heat exchanger for condensing the refrigerant compressed by the compressor 126 into a medium-temperature and high-pressure liquid refrigerant. 2The heat exchanger 123 (dehumidification/cooling), an expansion valve 124 for reducing the refrigerant condensed in the first heat exchanger 122 or the second heat exchanger 123 to a low temperature low pressure refrigerant, the expansion valve ( A second heat exchanger 123 (for heating) or a first heat exchanger (122; for cooling) that evaporates the refrigerant depressurized in 124 to a low-temperature, low-pressure gas refrigerant, and is installed at the outlet side of the compressor 126 for cooling and cooling. It consists of a four-way valve 125 that changes the flow direction of the refrigerant during heating. The first heat exchanger 122 and the second heat exchanger 123 operate alternately as a condenser and an evaporator.

A first blower 141 and a second blower 142 are provided to inhale the indoor air or outdoor air.

A moisture supply unit 145 for supplying moisture to air flowing indoors may be provided between the first blower 141 and the first region 121a of the dehumidifying rotor 121. The moisture supply unit 145 may be configured to increase humidity by passing air through a humidifying filter to which moisture is adsorbed by being immersed in water filled in a water tank. The amount of humidification can be adjusted by the moisture supply unit 145.

A plurality of filters 126a, 126b, and 126c for filtering foreign substances contained in the air may be provided on the air passage through which the indoor air and outdoor air flow.

With reference to FIG. 3, the configuration of the main body 110 will be described.

The main body 110 has a two-layered hexahedral stacked structure in which the first to fourth spaces 111, 112, 113, and 114 have an inner space, and is surrounded by an outer cover 135.

The first space part 111 and the second space part 112 are indoors that are one side of the air passage passing through the second area 121b with the second area 121b of the dehumidifying rotor 121 interposed therebetween. It is located on the side and the outside side respectively. The third space part 113 and the fourth space part 114 interpose the first region 121a (FIG. 6) of the dehumidification rotor 121, and the air flow passage passing through the first region 121a. It is located on one side, the indoor side and the outdoor side, respectively.

The first space part 111 and the second space part 112 are located above the main body part 110, and the third space part 113 is arranged in a stacked structure under the first space part 111 In addition, a fourth space part 114 is disposed under the second space part 112 in a stacked structure.

The first space part 111 and the third space part 113 are divided by a first separation plate 131, and the second space part 112 and the fourth space part 114 are a second separation plate It is divided by 132, and the first space part 111 and the second space part 112 are divided by a third separation plate 133, and the third space part 113 and the fourth space part 114 is partitioned by a fourth separating plate 134 (FIG. 7).

The first area 121a is located under the body part 110, and the second area 121b is located above the body part 110, and the first area 121a and the second area 121b Are spatially separated from each other so that they do not communicate.

The first heat exchanger 122 (FIG. 6) is provided in the fourth space portion 114 to heat or cool the air flowing toward the first region 121a. The second heat exchanger 123 is provided in the first space 111 to heat or cool the air flowing toward the second region 121b.

The first blower 141 sucks indoor air from the indoor inlet 101 and flows it indoors through the indoor outlet 102, or sucks outdoor air from the outdoor inlet 103 to open the indoor outlet 102. It is provided in the third space 113 to flow through the interior. An inlet through which air is introduced from the first blower 141 communicates with the third space part 113, and an outlet through which air is discharged is connected to an indoor discharge port 102.

The second blower 142 sucks indoor air from the indoor inlet 101 and flows it to the outdoors through the outdoor outlet 104, or sucks outdoor air from the outdoor inlet 103 and passes through the outdoor outlet 104. It is provided in the second space part 112 to flow outdoors. An inlet through which air is introduced from the second blower 142 communicates with the second space 112 and an outlet through which air is discharged is connected to an outdoor outlet 104.

As described above, the first blower 141 and the second blower 142 may be provided in the third space 113 and the second space 112 of different heights having a step difference.

A cooler for cooling air discharged to the room may be further provided in the third space 113.

A partition wall 130 is provided to partition between the main body 110 and the air introduction unit 150. The air introduction part 150 is integrally provided on one side of the main body 110 with the partition wall 130 as a boundary.

The partition wall 130 has a first opening 130a and a second opening 130b (FIG. 6), so that the inner space and the first space 111 of the air introduction unit 150 are provided with the first opening 130a. ), and the inner space of the air introduction part 150 and the fourth space part 114 communicate with each other through the second opening part 130b. In addition, between the inner space of the air introducing unit 150 and the second space unit 112, and between the inner space of the air introducing unit 150 and the third space unit 113 are blocked by the partition wall 130, respectively. The first opening portion 130a and the second opening portion 130b are formed at positions in a diagonal direction so as to communicate with the first space portion 111 and the fourth space portion 114 in the partition wall 130, respectively.

An indoor inlet 101 is provided on the indoor side as one side of the air introduction part 150, and an outdoor inlet 103 is provided on the outdoor side as the other side of the air introduction part 150.

The indoor inlet 101 is provided at an indoor side adjacent to the first and third spaces 111 and 113 to allow indoor air to flow. The outdoor inlet 103 is provided on an outdoor side adjacent to the second space 112 and the fourth space 114 to allow outdoor air to flow in. A damper (not shown) may be provided at the indoor inlet 101 to allow or block indoor air from entering. In addition, a damper (not shown) may be provided in the outdoor inlet 103 to allow or block outdoor air from entering.

According to the configuration as described above, indoor air and outdoor air passing through the dehumidifying rotor 121 form a counter flow, thereby improving dehumidification efficiency and total heat exchange efficiency. In addition, the size of the air conditioner can be downsized by configuring the main body 110 in a hexahedron and having the first to fourth spaces 111, 112, 113, and 114 in a stacked structure. In addition, by allowing air to flow through the openings 130a and 130b between the body part and the air introduction part, the path of the air flow path can be minimized, thereby minimizing static pressure loss when air flows.

In addition, the first opening (130a) and the second opening (130b) is formed at a position having a step difference in the partition wall 130, the first blower 141 and the second blower 142 are space portions 113 and 112 having a step difference. ), and the first region 121a and the second region 121b of the dehumidification rotor 121 are also provided to have a step, so that counterflow can be formed while miniaturizing the size of the air conditioner. In addition, by minimizing the path of the air flow path between the indoor air and the outdoor air, static pressure loss during air flow is minimized, thereby reducing the load of the blower, thereby reducing power consumption.

The configuration of the air introduction unit 150 will be described with reference to FIG. 4.

In the inner space of the air introduction unit 150, an air flow passage through which indoor air introduced from the indoor inlet 101 flows and an air flow passage through which outdoor air introduced from the outdoor inlet 103 flows are provided by a damper 151 It is designed to form a space separated from each other by the boundary, so indoor air and outdoor air flow independently.

In the case of forming two air passages as described above, a damper 151 may be provided to switch the passage of indoor air and outdoor air.

The damper 151 has a plate shape and is provided so as to be rotatable about the rotation axis 151a, and in the ventilation mode, the damper 151 is set to a first position in the vertical direction as shown in Fig. 5(a), and the dehumidification mode As shown in Fig. 5(b), the damper 151 is set to a second position in the horizontal direction, thereby changing the direction of the air flow path.

When the damper 151 is at the first position, a first damper member 152 and a second damper member 153 contacting both ends of the damper 151 are provided on the upper and lower sides of the rotation shaft 151a, respectively. .

In addition, when the damper 151 is in the second position, the third damper member 154 and the fourth damper member 155 contacting both ends of the damper 151 are respectively located on the left and right sides of the rotation shaft 151a. It is equipped.

The first damper member 152 and the second damper member 153 are formed in a substantially U-shaped cross section, and the outer cover 156 and the partition wall 130 are vertically symmetrical with respect to the horizontal line passing through the rotation axis 151a. ).

The third damper member 154 is provided on the side where indoor air is introduced, and when the damper 151 is in a horizontal direction, a damper contact part 154a that contacts one end of the damper 151, and the damper contact part It is formed of an air blocking portion 154b that is bent at the end of 154a and extends in an upwardly inclined direction to block air flowing in through the indoor inlet 101. The damper contact part 154a has an end bent downward so that it may contact the damper 151.

The air blocking unit 154b is provided to block the upper portion of the indoor space of the air introduction unit 150, and the indoor air introduced from the indoor inlet 101 is blocked by the air blocking unit 154b. It flows into the first air introduction space 150a formed below (154b).

The fourth damper member 155 is provided on the side where outdoor air is introduced, and the damper contact part 155a that the other end of the damper 151 contacts when the damper 151 is in a horizontal direction, and the damper contact part It consists of an air blocking portion 155b extending downward in a bent shape at the outdoor end of 155a to block air introduced through the outdoor inlet 103. The damper contact portion 155a has an end bent upward so as to contact the damper 151.

The air blocking unit 155b is provided to block the lower portion of the outdoor interior space of the air introducing unit 150, and the outdoor air introduced from the outdoor inlet 103 is blocked by the air blocking unit 155b. It flows into the third air introduction space 150c formed on the upper part of (155b).

The air blocking portion 154b of the third damper member 154 and the air blocking portion 155b of the fourth damper member 155 extend in opposite directions from each of the damper contact portions 154a and 155a.

When the damper 151 is in the vertical direction as shown in FIG. 4, the space under the damper contact part 154a becomes the first air introduction space 150a, and the space above it becomes the second air introduction space ( 150b). In addition, the space above the damper contact part 155a becomes the third air introduction space 150c, and the space below it becomes the fourth air introduction space 150d.

Both ends of the damper 151 are made of an elastic material such as rubber, so that the first damper member 152 and the second damper member 153 and the third damper member 154 and the fourth damper member 155 When contacting the corresponding end of the air flow is blocked.

According to the above configuration, the structure of the air conditioner can be simplified by integrally providing an air introduction part through which indoor air and outdoor air are introduced on one side of the main body. In addition, by providing a damper capable of switching the flow path of indoor air and outdoor air inside the air introduction unit, various functions of the air conditioner including dehumidification and ventilation can be implemented by a simple structure.

The operation when the air conditioner 100 according to the first embodiment configured as described above is operated in the ventilation mode will be described with reference to FIGS. 5 to 7.

In the ventilation mode, the damper 151 is set to the first position as shown in FIG. 5(a). In this state, the first blower 141 and the second blower 142 are operated.

When the second blower 142 is operated, the indoor air introduced into the indoor inlet 101 is introduced into the first air introduction space 150a by the air blocking unit 154b as shown in FIG. 5(a). It is guided, and then flows upward to the second air introduction space 150b, and the flow direction is switched 90 degrees to flow along the (+) X-axis direction, and the first space 111 through the first opening 130a Flow to. As shown in FIG. 6, the indoor air flowing into the first space 111 flows in the direction of the (+) Y-axis from the indoor to the outdoor by changing the flow direction by 90 degrees to remove the dehumidifying rotor 121. After passing through the second region 121b, it flows to the second space 112. The indoor air of the second space part 112 is discharged to the outside through the second blower 142 and the outdoor discharge port 104 as shown in FIG. 7.

When the first blower 141 is operated, the outdoor air introduced through the outdoor inlet 103 is introduced into the third air introduction space 150c by the air blocking unit 155b as shown in FIG. 5(a). After being guided, after flowing downward to the fourth air introduction space 150d, the flow direction is switched 90 degrees to flow along the (+) X-axis direction, and the fourth space part 114 through the second opening part 130b Flow to. As shown in FIG. 6, the outdoor air flowing into the fourth space 114 is converted to the flow direction by 90 degrees and flows in the (-) Y-axis direction from the outdoor to the indoor, and thus the first of the dehumidifying rotor 121 After passing through the area 121a, it flows to the third space 113. The outdoor air of the third space 113 is introduced into the room through the first blower 141 and the indoor outlet 102 as shown in FIG. 7.

Through the above process, indoor air is discharged to the outside and a ventilation mode in which outdoor air is introduced into the room is performed. In this case, as shown in FIG. 6, since the air passing through the first area 121a and the air passing through the second area 121b become countercurrents in opposite directions, total heat exchange between indoor air and outdoor air during ventilation Can improve the efficiency of

That is, when operating in the ventilation mode in winter, the temperature of one side (A) of the first space portion 114 increases a lot by receiving heat from the indoor air as the indoor air passes through the second area 121b. The temperature of the other side (C) of the two-space part 112 is relatively less increased. In this state, the dehumidification rotor 121 rotates so that one side (A) of which the temperature rises a lot is located at point B of the third space part (113), and the other side (C) where the temperature rises less is the fourth space part. When it is located at point D of (114), the cold air from the outside first contacts the other side (D) of the first area (121a) located in the fourth space (114), the temperature rises slightly, and then flows into the room. As it passes through one side (B) located in the third space part 113 where the temperature has risen a lot just before it receives a large amount of heat contained in the indoor air, the efficiency of total heat exchange is improved.

In the dehumidification mode, the damper 151 is set to the second position as shown in FIG. 5(b). In this state, the first blower 141 and the second blower 142 are operated.

When the first blower 141 is operated, the indoor air introduced through the indoor inlet 101 is introduced into the first air introduction space 150a by the air blocking unit 154b as shown in FIG. 5(b). It is guided, and then guided along the horizontal direction in the (+) Y-axis direction by the damper 151 to flow to the fourth air introduction space 150d. The air in the fourth air introduction space 150d is converted in a flow direction by 90 degrees and flows along the (+) X-axis direction, and flows to the fourth space 114 through the second opening 130b. As shown in FIG. 6, the indoor air flowing into the fourth space 114 is converted by 90 degrees and flows along the (-) Y-axis direction from the outdoor to the indoor, thereby removing the dehumidification rotor 121. After passing through the first region 121a, it flows to the third space 113. The indoor air of the third space 113 is discharged into the room through the first blower 141 and the indoor discharge port 102 as shown in FIG. 7. Through this process, moisture contained in the indoor air is adsorbed while the indoor air passes through the first region 121a, thereby dehumidifying. In this case, the indoor air may be cooled by the first heat exchanger 122 provided at the front end of the first region 121a and then passed through the first region 121a.

When the second blower 142 is operated, the outdoor air introduced into the outdoor inlet 103 is introduced into the third air introduction space 150c by the air blocking unit 155b as shown in FIG. 5(b). It is guided, and then guided along the horizontal direction in the (-)Y-axis direction by the damper 151 to flow into the second air introduction space 150b. The air in the second air introduction space 150b is converted in a flow direction by 90 degrees and flows along the (+) X-axis direction, and flows into the first space 111 through the first opening 130a. As shown in FIG. 6, the indoor air flowing into the first space 111 flows in the (+)Y direction from the indoor to the outdoor after the flow direction is changed by 90 degrees, and the second of the dehumidification rotor 121 After passing through the region 121b, it flows to the second space 112. The outdoor air of the second space part 112 is discharged to the outdoors through the second blower 142 and the outdoor discharge port 104 as shown in FIG. 7. In this case, the outdoor air is heated by the second heat exchanger 123 provided at the front end of the second area 121b and then passes through the second area 121b, thereby reducing the moisture of the indoor air adsorbed on the dehumidifying rotor 121. The dehumidification rotor 121 is regenerated by discharging it to the outside.

The dehumidification mode is performed through the above process. In this case, as shown in FIG. 6, since the air passing through the first region 121a and the air passing through the second region 121b become countercurrents in opposite directions, dehumidification efficiency can be improved.

That is, the indoor air passes through one side (D) of the first region (121a) of the dehumidification rotor (121) and sequentially passes through the other side (B). Therefore, a large amount of moisture contained in the indoor air is adsorbed on one side (D) and a small amount on the other side (B). In this way, one side (D) of the dehumidifying rotor 121 to which a large amount of moisture has been adsorbed is rotated and located at point C of the second area (3b), and the other side (B) of the dehumidifying rotor 121 to which a small amount of moisture is adsorbed is It is located at point A of the second area 3b. In this state, even if outdoor air passes through the other side (A) of the second area (3b) where a small amount of moisture was adsorbed, the humidity only slightly increases, and then one side of the dehumidification rotor 121 where a large amount of moisture was adsorbed. A large amount of moisture can be removed while passing through (C). Therefore, the dehumidification efficiency increases.

<Second Example>

A configuration of an air conditioner according to a second embodiment of the present invention will be described with reference to FIGS. 8 to 12.

Referring to FIG. 8, in the air conditioner 200 according to the second embodiment of the present invention, the main body 210 and the air introduction part 250 are integrally coupled with the partition wall 230 interposed therebetween. The body part 210 is the same as the first embodiment in that the inner space is surrounded by the outer cover 235 as a hexahedron of the first to fourth space parts 211, 212, 213, and 214 of a stacked structure.

Hereinafter, a description will be given focusing on a configuration that is different from that of the first embodiment, and detailed descriptions of the remaining identical configurations will be omitted.

The indoor outlet 202 for discharging indoor air or outdoor air introduced into the air conditioner 200 into the room is provided to communicate with the first space 211, and flows into the air conditioner 200. An outdoor outlet 204 for discharging indoor air or outdoor air to the outside is provided to communicate with the fourth space 214.

In the partition wall 230 that blocks between the main body 210 and the air introduction part 250, an air flow path and a third space part (in a portion corresponding to the third space part 213) are located inside the air introduction part 250. A first opening 230a communicating with 213) is formed, and at a portion corresponding to the second space 212, a first opening for communicating the air passage inside the air introduction part 250 and the second space 212 Two openings 230b are formed. That is, the first opening portion 230a and the second opening portion 230b are formed at positions in the diagonal direction so that the partition wall 230 communicates with the third space portion 213 and the second space portion 212, respectively.

The second space part 212 is provided with a first heat exchanger 222 to heat or cool the air flowing toward the second region 221b of the dehumidification rotor 221. The third space 213 is provided with a second heat exchanger 223 (FIG. 11) to heat or cool the air flowing toward the first region 221a (FIG. 11) of the dehumidifying rotor 221.

A first blower 241 for inhaling the indoor air or outdoor air is provided in the first space 211, and the inlet through which air is introduced communicates with the first space 211, and an outlet through which air is discharged. Is connected to the indoor discharge port 202, and discharges the air from the first space part 211 into the room through the indoor discharge port 202.

The second blower 242 for inhaling the indoor air or outdoor air is provided in the fourth space 214, and an inlet through which air is introduced communicates with the fourth space 214, and an outlet through which air is discharged. Is connected to the outdoor outlet 204 to discharge the air from the fourth space 214 to the outside through the outdoor outlet 204.

The air introduction unit 250 includes an indoor damper 251a for converting a flow path of indoor air introduced from the indoor inlet 201, and an outdoor side for converting a flow path of outdoor air introduced from the outdoor inlet 203. A damper 251b is provided.

Even in the case of the second embodiment, the first opening portion 230a and the second opening portion 230b are formed at a position having a step difference in the partition wall 230, and the first blower 241 and the second blower 242 have a step difference. Each of the spaces 211 and 214 is provided, and the first region 221a and the second region 221b of the dehumidification rotor 221 are also provided to have a step, so that counter flow can be formed while miniaturizing the size of the air conditioner. have. In addition, by minimizing the path of the air flow path between the indoor air and the outdoor air, static pressure loss during air flow is minimized, thereby reducing the load of the blower, thereby reducing power consumption.

The configuration of the air introduction unit 250 will be described in more detail with reference to FIG. 9.

The indoor damper 251a and the outdoor damper 251b have rotation shafts 251-1a and 251-1b at both ends of the central separation plate 252 that vertically divide the inner space of the air introduction unit 250 It is hinged by means of.

The indoor damper 251a is provided to be rotatable about the rotation shaft 251-1a, and in the ventilation mode, the indoor damper 251a is rotated upward as shown in FIG. 10(a). It is set to the position and is set to a second position in which the indoor damper 251a is rotated downward as shown in FIG. 10(b) in the dehumidification mode, thereby changing the direction of the air flow path.

The outdoor damper 251b is provided to be rotatable about the rotation shaft 251-1b, and in the ventilation mode, the outdoor damper 251b is rotated downward as shown in FIG. 10(a). It is set to the position and is set to the second position in which the outdoor damper 251b is rotated upward as shown in FIG. 10(b) in the dehumidification mode, thereby changing the direction of the air flow path.

When the indoor damper 251a is at the first position or the second position, a first rotation limiting member to which the indoor damper 251a comes into contact to limit the upward or downward rotation angle of the indoor damper 251a (254a) and the second rotation limiting member 254b (FIG. 10) are provided to be inclined upward or downward with respect to the rotation shaft 251-1a.

In addition, when the outdoor damper 251b is at the first position or the second position, the outdoor damper 251b is in contact with the first rotation to limit the upward rotation angle or the downward rotation angle of the outdoor damper 251b. The limiting member 255a and the second rotation limiting member 255b are provided to be inclined upward or downward based on the rotation shaft 251-1b.

Therefore, when the indoor damper 251a rotates about the rotation shaft 251-1a to be at one of the first position and the second position, the indoor air flows above the central separation plate 252 The second air introduction space 250b, which is a space, and the fourth air introduction space 250d, which is a lower space of the central separation plate 252, flows into one of the outer dampers 251b and the rotation shaft 251-1b. ), the outdoor air flows to one of the second air introduction space 250b and the fourth air introduction space 250d when rotated to become one of the first position and the second position.

The operation when the air conditioner 200 according to the second embodiment configured as described above is operated in the ventilation mode will be described with reference to FIGS. 10 to 12.

In the ventilation mode, the indoor damper 251a and the outdoor damper 251b are set to the first position as shown in FIG. 10(a). In this state, the first blower 241 and the second blower 242 are operated.

When the second blower 242 is operated, the indoor air flowing into the first air introduction space 250a through the indoor inlet 201 is guided downward by the indoor damper 251a, as shown in FIG. 10(a). Is introduced into the fourth air introduction space (250d). The air in the fourth air introduction space 250d is converted in a flow direction of 90 degrees in the (+) X-axis direction and flows to the third space 213 through the first opening 230a. As shown in FIG. 11, the indoor air flowing into the third space 213 is converted in a direction of 90 degrees and flows along the (+) Y-axis direction from indoor to outdoor, thereby removing the dehumidification rotor 221. After passing through the first region 221a, it flows to the fourth space 214. The indoor air of the fourth space part 214 is discharged to the outdoors through the second blower 242 and the outdoor discharge port 204 as shown in FIG. 12.

When the first blower 241 is operated, the outdoor air flowing into the outdoor inlet 203 is guided upward by the outdoor damper 251b as shown in FIG. 10(a), and the second air introducing space 250b Flows into. The air in the second air introduction space 250b is converted in a direction of the (+) X axis by 90 degrees and flows into the second space 212 through the second opening 230b. As shown in FIG. 11, the indoor air flowing into the second space 212 is converted by 90 degrees and flows in the (-)Y-axis direction from the outdoor to the indoor, and thus the second of the dehumidifying rotor 221 After passing through the region 221b, it flows to the first space 211. The indoor air of the first space part 211 is introduced into the room through the first blower 241 and the indoor outlet 202 as shown in FIG. 12.

Through the above process, indoor air is discharged to the outside and a ventilation mode in which outdoor air is introduced into the room is performed. In this case, as shown in FIG. 11, since the air passing through the first area 221a and the air passing through the second area 221b become countercurrents in opposite directions, total heat exchange between indoor air and outdoor air during ventilation Can improve the efficiency of

In the dehumidification mode, the indoor damper 251a and the outdoor damper 251b are set to the second position as shown in FIG. 10(b). In this state, the first blower 241 and the second blower 242 are operated.

When the first blower 241 is operated, the indoor air flowing into the first air introduction space 250a through the indoor inlet 201 is upwards by the indoor damper 251a as shown in FIG. 10(b). After being guided and introduced into the second air introduction space 250b, it flows in a horizontal direction along the (+) Y-axis direction to the outdoor end of the second air introduction space 250b. The air in the second air introduction space 250b is converted in a flow direction by 90 degrees and flows to the second space 212 through the second opening 230b along the (+)X-axis direction. As shown in FIG. 11, the indoor air flowing into the second space 212 is converted by 90 degrees and flows in the (-)Y-axis direction from the outdoor to the indoor, and thus the second of the dehumidifying rotor 221 After passing through the region 221b, it flows to the first space 211. The indoor air of the first space part 211 is discharged into the room through the first blower 241 and the indoor discharge port 201 as shown in FIG. 12. Through this process, moisture contained in the indoor air is adsorbed while the indoor air passes through the second region 221b, thereby dehumidifying. In this case, the indoor air may be cooled by the first heat exchanger 222 provided in the front end of the second region 221b and then passed through the second region 221b.

When the second blower 242 is operated, the outdoor air flowing into the third air introduction space 250c through the outdoor inlet 203 is lowered by the outdoor damper 251b as shown in FIG. 10(b). After being guided and introduced into the fourth air introduction space 250d, it flows in a horizontal direction along the (-) Y-axis direction to the indoor end of the fourth air introduction space 250d. The air in the fourth air introduction space 250d is converted in a flow direction by 90 degrees and flows to the third space 213 through the first opening 230a along the (+)X-axis direction. As shown in FIG. 11, the indoor air flowing into the third space 213 is converted by 90 degrees and flows in the (+) Y-axis direction from indoor to outdoor, and the first of the dehumidifying rotor 221 After passing through the region 221a, it flows to the fourth space 214. The indoor air of the fourth space part 214 is discharged to the outdoors through the second blower 242 and the outdoor discharge port 204 as shown in FIG. 12. In this case, the outdoor air is heated by the second heat exchanger 223 provided in the front end of the first region 221a and then passes through the first region 221a to prevent moisture of the indoor air adsorbed on the dehumidifying rotor 221. The dehumidification rotor 221 is regenerated by discharging it to the outside.

The dehumidification mode is performed through the above process. In this case, as shown in FIG. 11, since the air passing through the first region 221a and the air passing through the second region 221b become countercurrents in opposite directions, dehumidification efficiency can be improved.

In addition, by separating the damper for switching the flow path of indoor air and outdoor air into an indoor damper 251a and an outdoor damper 251b, the load of the driving unit for driving the damper can be reduced and the flow path switching time can be reduced.

<Modified Example 1>

13 is a view showing an embodiment in which the body portion 110 of the first embodiment and the air introducing portion 250 of the second embodiment are combined, and FIG. 13(a) shows the flow paths of indoor air and outdoor air in a ventilation mode. Fig. 13(b) shows the flow path of indoor air and outdoor air in the dehumidifying mode.

That is, the air introduction part 250 is provided with an indoor damper 251a and an outdoor damper 251b, and the first opening 130a has the second air introduction space 250b and the first space 111 It is formed in the partition wall 130 to communicate with each other, and the second opening part 130b is formed in the partition wall 130 so that the fourth air introduction space 250b and the fourth space part 114 communicate with each other. In addition, the first blower 141 and the second blower 142 are provided in the third space part 113 and the second space part 112, respectively, as shown in FIG. 3.

In this way, if two dampers 251a and 251b are provided in the air introduction unit 250, they can be coupled to each other to be compatible with the body portion 110 of the first embodiment and the body portion 210 of the second embodiment. Operation in dehumidification mode is possible.

<Modified Example 2>

The embodiment shown in FIG. 14 is similar to the structure in which the air introduction part 150 of the first embodiment and the body part 210 of the second embodiment are combined, but the third damper member 354 and the fourth of the air introduction part 350 are combined. There is a difference in that the damper member 355 has a structure different from that of the third damper member 154 and the fourth damper member 155 of the first embodiment, and the remaining configurations are the same.

14(a) shows the flow paths of indoor air and outdoor air in the ventilation mode, and FIG. 14(b) shows the flow paths of indoor air and outdoor air in the dehumidification mode.

The third damper member 354 is provided on the side where indoor air is introduced, and when the damper 351 is in a horizontal direction, a damper contact portion 354a that contacts one end of the damper 351, and the damper contact portion ( It is formed of an air blocking portion 354b that is bent at the end of 354a and extends in a downwardly inclined direction to block air introduced through the indoor inlet 301. The damper contact part 354a has an end bent upward so that it may contact the damper 351.

The air blocking unit 354b is provided to block the lower portion of the indoor space of the air introducing unit 350, and the indoor air introduced from the indoor inlet 301 is blocked by the air blocking unit 354b. It flows into the second air introduction space 350b formed on the upper part of 354b. The air in the second air introduction space 350b flows downward to the first air introduction space 350a and then flows to the third space 213 through the first opening 230a.

The fourth damper member 355 is provided on the side where outdoor air is introduced, and the damper contact part 355a to which the other end of the damper 351 contacts when the damper 351 is in a horizontal direction, and the damper contact part It includes an air blocking portion 355b extending upward in a bent shape at the outdoor end of 355a to block the air introduced through the outdoor inlet 303. The damper contact part 355a has an end bent downward so that it can contact the damper 351.

The air blocking unit 355b is provided to block the upper portion of the outdoor interior space of the air introducing unit 350, and the outdoor air introduced from the outdoor inlet 303 is blocked by the air blocking unit 355b to prevent the air blocking unit. It flows into the fourth air introduction space 350d formed under the (355b). The air in the fourth air introduction space 350d flows upward to the third air introduction space 350c and then flows to the second space 212 through the second opening 230b.

The air blocking portion 354b of the third damper member 354 and the air blocking portion 355b of the fourth damper member 355 extend in a vertical direction from each of the damper contact portions 354a and 355a.

As described above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above-described embodiments, and various modifications within the scope of the claims and the detailed description of the invention and the accompanying drawings. It is possible to do so, and this also belongs to the present invention.

100, 200: air conditioner 101, 201, 301: indoor inlet
102, 202: indoor outlet 103, 203, 303: outdoor inlet
104, 204: outdoor outlet 110, 210: main body
111, 211: first space part 112, 212: second space part
113, 213: third space part 114, 214: fourth space part
121, 221: dehumidifying rotor 121a, 221a: first area
121b, 221b: second area 122, 222: first heat exchanger
123, 223: second heat exchanger 130, 230: bulkhead
141, 241: first blower 142, 242: second blower
150, 250, 350: air introduction part 150a, 250a, 350a: first air introduction space
150b, 250b, 350b: 2nd air introduction space
150c, 250c, 350c: 3rd air introduction space
150d, 250d, 350d: 4th air entry space
151, 251, 351: damper 152, 352: first damper member
153, 353: second damper member 154, 354: third damper member
154a, 155a, 354a, 355a: damper contact part
154b, 155b, 354b, 355b: air block
254a, 255a: first rotation limiting member 254b, 255b: second rotation limiting member

Claims (21)

A dehumidifying rotor for adsorbing moisture or discharging the adsorbed moisture while alternately passing through the first and second areas by rotation; A first space part and a second space part respectively positioned on one side of the air passage passing through the second area, which is an indoor side and the other side of an outdoor side; Including; a third space portion and a fourth space portion respectively positioned on one side of the air passage passing through the first area, the indoor side and the other side, the outdoor side,
Air passing through the first region and air passing through the second region form a counter flow,
A main body including the first to fourth spaces is provided;
At one side of the main body, an air introduction part having two air passages is provided so that the indoor air introduced from the indoor and the outdoor air introduced from the outdoor flow independently;
An air conditioner provided with a damper for dividing the inner space of the air introducing unit into the two air passages and switching the air passages between the indoor air and outdoor air by rotation The method of claim 1,
The first space portion is stacked above the third space portion, and the second space portion is stacked above the fourth space portion. delete The method of claim 1,
An indoor inlet provided on one side of the indoor side of the air introduction unit through which the indoor air is introduced;
An outdoor inlet provided on the other side of the outdoor side of the air introduction unit through which the outdoor air is introduced;
An indoor discharge port provided to communicate with the third space on one side of the interior of the main body to discharge air into the interior;
An outdoor discharge port provided to communicate with the second space on the other side of the outside of the main body to discharge air to the outside;
Air conditioner comprising a The method of claim 4,
In the partition wall blocking between the main body part and the air introduction part, a first opening part which communicates the air flow path of the air introduction part and the first space part is formed in a part corresponding to the first space part, and corresponds to the fourth space part An air conditioner, characterized in that a second opening for communicating the air flow path of the air introduction part and the fourth space part is formed at the part. The method of claim 1,
An indoor inlet provided on one side of the indoor side of the air introduction unit through which the indoor air is introduced;
An outdoor inlet provided on the other side of the outdoor side of the air introduction unit through which the outdoor air is introduced;
An indoor discharge port provided to communicate with the first space to discharge air into the room;
An outdoor discharge port provided to communicate with the fourth space to discharge air to the outside;
Air conditioner comprising a The method of claim 6,
In the partition wall blocking between the main body part and the air introduction part, a first opening part for communicating the air flow path of the air introduction part and the third space part is formed in a part corresponding to the third space part, and corresponding to the second space part An air conditioner, characterized in that a second opening for communicating the air flow path of the air introduction part and the second space part is formed at the portion to be formed. delete The method according to claim 5 or 7,
The damper,
A first for flowing indoor air introduced through the indoor inlet to the first space through the first opening, and for flowing outdoor air introduced through the outdoor inlet to the fourth space through the second opening Set to a location;
A second for flowing indoor air introduced through the indoor inlet to the fourth space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the first space through the first opening Air conditioner, characterized in that the position is set The method according to claim 5 or 7,
The damper,
A first for flowing indoor air introduced through the indoor inlet to the third space through the first opening, and flowing outdoor air introduced through the outdoor inlet to the second space through the second opening Set to a location;
A second for flowing indoor air introduced through the indoor inlet to the second space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the third space through the first opening Air conditioner, characterized in that the position is set The method according to claim 5 or 7,
The damper is formed in a plate shape that rotates about a rotation axis;
A first damper member, a second damper member, a third damper member, and a fourth damper member are provided on the top, bottom, left, and right around the rotation axis of the damper;
Both ends of the damper are in contact with the first damper member and the second damper member, respectively, to block the flow of air between the inner space of the air introduction part divided by the damper;
Air conditioning, characterized in that the damper rotates so that both ends of the damper contact the third damper member and the fourth damper member, respectively, to block the flow of air between the inner space of the air introduction unit divided by the damper group The method of claim 11,
The third damper member includes a damper contact portion to which one end of the damper contacts, and an air blocking portion extending in a curved shape from an end of the damper contact portion to block air introduced through the indoor inlet;
The fourth damper member comprises a damper contact portion to which the other end of the damper is in contact, and an air blocking portion extending in a curved shape from an end of the damper contact portion to block air introduced through the outdoor inlet. Air conditioner The method of claim 12,
The air blocking part of the third damper member extends upward or downward from the end of the damper contact part of the third damper member, and the air blocking part of the fourth damper member is at the end of the damper contact part of the fourth damper member. An air conditioner, characterized in that it extends in a direction opposite to the air blocking portion of the third damper member. The method according to claim 5 or 7,
The damper comprises an indoor damper for changing the flow direction of indoor air introduced through the indoor inlet and an outdoor damper for changing the flow direction of outdoor air introduced through the outdoor inlet. group The method of claim 14,
The indoor damper and the outdoor damper,
A first for flowing indoor air introduced through the indoor inlet to the third space through the first opening, and flowing outdoor air introduced through the outdoor inlet to the second space through the second opening Set to a location;
A second for flowing indoor air introduced through the indoor inlet to the second space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the third space through the first opening Air conditioner, characterized in that the position is set The method of claim 14,
The indoor damper and the outdoor damper,
A first for flowing indoor air introduced through the indoor inlet to the first space through the first opening, and for flowing outdoor air introduced through the outdoor inlet to the fourth space through the second opening Set to a location;
A second for flowing indoor air introduced through the indoor inlet to the fourth space through the second opening, and flowing outdoor air introduced through the outdoor inlet to the first space through the first opening Air conditioner, characterized in that the position is set The method of claim 14,
The indoor damper and the outdoor damper are hinged to both ends of a central separation plate that vertically divides the inner space of the air introduction unit;
When the indoor damper rotates the hinge of the indoor damper to one of the first position and the second position with respect to the rotational center, the indoor air flows to one of the upper space and the lower space of the central separation plate. ;
When the outdoor damper rotates the hinge of the outdoor damper to be one of the first and second positions around the rotational center, the outdoor air flows to one of the upper space and the lower space of the central separation plate. Air conditioner, characterized in that The method of claim 14,
Air conditioner, characterized in that, when the indoor damper and the outdoor damper rotate, a rotation limiting member for limiting the vertical rotation angle is provided, respectively. The method of claim 1,
An air conditioner comprising: a first heat exchanger for heating or cooling the air flowing toward the first region and a second heat exchanger for heating or cooling the air flowing toward the second region The method of claim 1,
A first blower for inhaling indoor air or outdoor air in any one of the first and third spaces;
A second blower for inhaling indoor air or outdoor air in any one of the second and fourth spaces;
An air conditioner, characterized in that the first blower and the second blower are provided in spaces having different heights. The method of claim 1,
Air conditioner, characterized in that the air passing through the first area and the air passing through the second area have a step and flow in opposite directions.

Images