KR101718221B1 - Indoor unit for an air conditioner - Google Patents

Abstract

The present invention relates to an indoor unit of an air conditioner.
The indoor unit of the air conditioner according to the embodiment of the present invention includes a case; A suction unit formed at a rear portion of the case and sucking air; A heat exchanger for exchanging heat between the suctioned air and the suctioned air; A plurality of discharge devices rotatably provided at an outlet side of the heat exchanger; A blowing fan provided inside the plurality of discharging devices; A discharge device flow path for guiding the flow of air from an outlet side of the heat exchanger to an inlet portion of the plurality of discharge devices; And a plurality of ejecting apparatuses, wherein the plurality of ejecting apparatuses are respectively disposed at positions symmetrical with respect to the partitioning apparatus, .

Description

[0001] The present invention relates to an indoor unit for an air conditioner,

The present invention relates to an indoor unit of an air conditioner.

The air conditioner is a device for keeping the air in a predetermined space in a most suitable condition according to the purpose of use and purpose. Generally, the air conditioner includes a compressor, a condenser, an expansion device, and an evaporator, and a refrigeration cycle for compressing, condensing, expanding, and evaporating the refrigerant is driven to cool or heat the predetermined space .

The predetermined space may be variously proposed depending on the place where the air conditioner is used. For example, when the air conditioner is installed in a home or an office, the predetermined space may be a house or an indoor space of a building. On the other hand, when the air conditioner is disposed in a car, the predetermined space may be a boarding space on which a person boarded.

The air conditioner includes an outdoor unit installed outdoors and an indoor unit installed in the predetermined space. For example, the outdoor unit includes a compressor, an outdoor heat exchanger, and an outdoor ventilation fan, and the indoor unit includes an indoor heat exchanger and an indoor ventilation fan.

When the air conditioner performs cooling operation, the outdoor heat exchanger and the indoor heat exchanger may function as a condenser and an evaporator, respectively. On the other hand, when the air conditioner performs the heating operation, the outdoor heat exchanger and the indoor heat exchanger may function as an evaporator and a condenser, respectively.

The indoor unit further includes a discharge device for guiding the discharge of heat-exchanged air into the predetermined space. For example, the discharge device may be rotatably provided, so that the discharge direction of the air may be variously formed toward a plurality of points of the predetermined space.

The related art documents related thereto are as follows.

1. Public number (public date): 10-2009-0017289 (February 18, 2009)

2. Title of the invention: indoor unit of air conditioner

It is an object of the present invention to provide an indoor unit of an air conditioner capable of stabilizing air flow inside an indoor unit.

The indoor unit of the air conditioner according to the embodiment of the present invention includes a case; A suction unit formed at a rear portion of the case and sucking air; A heat exchanger for exchanging heat between the suctioned air and the suctioned air; A plurality of discharge devices rotatably provided at an outlet side of the heat exchanger; A blowing fan provided inside the plurality of discharging devices; A discharge device flow path for guiding the flow of air from an outlet side of the heat exchanger to an inlet portion of the plurality of discharge devices; And a plurality of ejecting apparatuses, wherein the plurality of ejecting apparatuses are respectively disposed at positions symmetrical with respect to the partitioning apparatus, .

Further, the first rotation center of the blowing fan is eccentric to the second rotation center of the plurality of ejection apparatuses.

The first rotation center of the blowing fan is formed at a position symmetrical with respect to the partitioning device in a state where the plurality of discharge devices are rotated at a predetermined first rotation angle.

Also, in the process of rotating the plurality of discharge devices, the first rotation center of the blowing fan rotates with a predetermined rotation radius, and in a state in which the plurality of discharge devices are rotated at a predetermined second rotation angle, And the distance from the first rotation center of the fan to the center of the partitioning device is variable.

The plurality of discharging apparatuses include a first discharging apparatus and a second discharging apparatus, and the first and second discharging apparatuses are arranged in the left-right direction with respect to the front of the plurality of discharging apparatuses do.

In addition, the discharge device flow path may include a first discharge device flow path for guiding the air that has passed through the heat exchanger to the inflow portion of the first discharge device; And a second discharge device flow path for guiding air passing through the heat exchanger to an inlet of the second discharge device.

Further, the partitioning device is characterized by partitioning the first discharge device flow path and the second discharge device flow path.

In addition, the partitioning device includes a wall for blocking the air of the first discharge device flow path from flowing into the flow path of the second discharge device.

Further, the wall is separated from the heat exchanger by a set distance (S1).

The partitioning device may further include: a first compartment defining at least a part of the front surface of the indoor unit; And a second compartment extending from the first compartment to the heat exchanger.

The second compartment includes a wall for partitioning the discharge device flow path.

Further, the partitioning device includes at least one surface on which a sealing device is installed.

Further, the sealing device is provided so as to close the gap between the discharge device and the partitioning device.

Further, the blowing fan may include a first blowing fan provided in the first discharging device and a second blowing fan provided in the second discharging device, and the first and second blowing fans are driven at different rotational speeds .

The indoor unit of the air conditioner according to another aspect includes: a case; A suction unit formed at a rear portion of the case and sucking air; A heat exchanger for exchanging heat between the suctioned air and the suctioned air; A first and a second discharge device rotatably installed at an outlet side of the heat exchanger; First and second blowing fans respectively provided in the first and second discharge devices and eccentrically rotated in a process of rotating the first and second discharge devices; And a partitioning device extending from an outlet side of the heat exchanger to an interspace of the first discharge device, wherein the partitioning device comprises: a display; And a wall extending from the display portion toward the heat exchanger and partitioning the outlet-side flow path of the heat exchanger into the first discharge device flow path and the second discharge device flow path.

According to the air conditioner of the present invention, a wall is provided between two rotating discharge devices, and an air flow path toward a blowing fan provided in each of the discharge devices can be partitioned, so that air flow can be stabilized It is effective.

Particularly, the blowing fans provided in the two discharge devices can be independently controlled and rotated at different rotational speeds. Since the air flow path can be partitioned by the wall, the air passing through the heat exchanger can be blown It is advantageous to prevent it from deflecting toward the fan side and flowing.

In addition, through the stabilization of the air flow, it is possible to prevent unstable air flow in a blowing fan having a low rotation speed, for example, surging phenomenon in which air pressure or wind speed fluctuates, And the noise can be reduced.

In addition, since the wall may be spaced apart from the center of rotation of the two discharge devices by the same distance, the size of the divided air channels may be the same so that the air is deflected toward one discharge device or one blower fan So that it can be prevented from flowing.

In addition, in the course of the rotation of the two discharge devices, the blowing fan provided in each discharge device rotates with a predetermined radius on the basis of the center of rotation of the discharge device, and the path of the two blowing fans, The air passing through the heat exchanger can be appropriately distributed corresponding to the number of revolutions of the two blowing fans.

That is, when one blowing fan of the two blowing fans is disposed closer to the wall or the heat exchanger, a phenomenon of flowing to the two blowing fans at a ratio different from the ratio of the number of rotations of the two independently controlled blowing fans Can be prevented.

In addition, although it may be ideal for the wall to be in contact with the front portion of the heat exchanger to completely divide the two air flow paths, considering that condensed water is generated on the surface of the heat exchanger during operation of the air conditioner, And may be spaced apart from the front surface of the heat exchanger by a predetermined distance. Therefore, it is possible to prevent the problem that the drainage of the condensed water is limited by the wall.

Further, a sealing device is provided in a gap existing between the discharge device and the case of the indoor unit, thereby preventing the generation of a wind that the air in the indoor space is likely to flow into the indoor unit. As a result, it is possible to prevent the occurrence of dew caused by the temperature difference between the indoor air and the indoor space of the indoor unit. In addition, it is possible to prevent generation of noise due to the friction between the indoor air and the discharge space and a decrease in the air volume of the discharge air.

1 is a front view showing the configuration of an indoor unit of an air conditioner according to an embodiment of the present invention.
2 is a cross-sectional view taken along line I-I 'of FIG.
3 is a cross-sectional view taken along line II-II 'of FIG.
4 is a cross-sectional view taken along line III-III 'of FIG.
5 is a view showing a relative positional relationship between the first and second discharging devices and the wall according to the embodiment of the present invention.
6 is an enlarged cross-sectional view of "A"
7 is an enlarged cross-sectional view of "B" in FIG.
FIG. 8 is a cross-sectional view illustrating the first and second ejection apparatuses according to the embodiment of the present invention as they are rotated.
FIG. 9A is a view showing a state in which air having passed through a heat exchanger is deflected to a discharge device when a wall is not present in an indoor unit according to an embodiment of the present invention.
FIG. 9B is a view showing a state in which, in the indoor unit according to the embodiment of the present invention, the air passing through the heat exchanger is distributed to two discharge devices corresponding to the number of rotations of the blowing fan.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. It is to be understood, however, that the spirit of the invention is not limited to the embodiments shown and that those skilled in the art, upon reading and understanding the spirit of the invention, may easily suggest other embodiments within the scope of the same concept.

1 is a cross-sectional view taken along the line I-I 'of FIG. 1, and FIG. 3 is a cross-sectional view taken along the line II-II' of FIG. 1 And FIG. 4 is a cross-sectional view taken along line III-III 'of FIG.

1 to 4, an indoor unit 10 of an air conditioner according to an embodiment of the present invention includes a case 20 forming an outer appearance. The case 20 includes a base 21 provided at a lower portion thereof and a front panel 23, a side panel 25 and a rear panel 27 provided on the base 21.

The front panel 23 is disposed at a front lower portion of the indoor unit 10. The side panels 25 form both side portions of the indoor unit 10 and the rear panel 27 forms a rear portion of the indoor unit 10.

The indoor unit (10) includes a discharge unit (110, 150) for discharging the heat-exchanged air in the indoor unit (10) to the indoor space. The ejecting apparatuses 110 and 150 may be installed at a front upper portion of the case 20, that is, at an upper side of the front panel 23.

The discharging apparatuses 110 and 150 may be provided movably. For example, the discharging apparatuses 110 and 150 may rotate in the lateral direction, that is, clockwise or counterclockwise, with respect to the front surface of the indoor unit 10. [

In detail, the discharging devices 110 and 150 include a first discharging device 110 and a second discharging device 150 which can be driven independently of each other. For example, both of the first and second discharging devices 110 and 150 may be rotated clockwise or counterclockwise. Alternatively, one of the first and second discharging devices 110 and 150 may be rotated clockwise One can rotate counterclockwise.

The amount of air discharged from the first discharging device 110 and the second discharging device 150 can be controlled differently. For example, the amount of air discharged from the first discharging device 110 may be greater than the amount of air discharged from the second discharging device 150. On the other hand, the amount of air discharged from the second discharging device (150) may be larger than the amount of air discharged from the first discharging device (110).

The amount of air discharged from the first discharging device 110 or the second discharging device 150 may be determined corresponding to the number of rotations of the blowing fan provided to the first and second discharging devices 110 and 150. For example, when the number of revolutions of the blowing fan increases, the amount of air to be blown out may increase.

The first and second discharging devices 110 and 150 may be disposed in parallel to the left and right front sides of the indoor unit.

The first discharging device 110 includes a first discharging main body 111 forming a first discharging flow path 115 and a first discharging portion 111 formed on the front surface of the first discharging main body 111 for discharging air 112). The first discharge portion 112 may extend in the longitudinal direction from the upper portion of the first discharge body 111 to the lower portion thereof. The first discharge portion 112 is provided with a first discharge vane 114.

The first ejection body 111 has a substantially cylindrical shape with an empty interior, and the upper and lower portions may be formed to be open. In the rear portion of the cylindrical shape, an inflow portion 119 through which the air that has passed through the heat exchanger 80 flows toward the blowing fan 130 is formed. In the cylindrical front portion, A portion 112 is formed.

In detail, the first discharge main body 111 includes a rear guide 118 disposed on a suction side of the first blowing fan 130. The rear guide 118 may be coupled to at least one of the lower plate 121 and the upper plate 125. The rear guide 118 guides the intake air to the first blowing fan 130 smoothly when the first blowing fan 130 rotates. The rear guide 118 can prevent the air flowing by the first blowing fan 130 from being separated from the first blowing fan 160.

The first discharge main body 111 further includes a stabilizer 117 disposed on the discharge side of the first blowing fan 130. The stabilizer 117 may be coupled to at least one of the lower plate 121 and the upper plate 125. The stabilizer 117 is installed to be spaced apart from the outer circumferential surface of the first blowing fan 130 to prevent the air discharged from the first blowing fan 130 from flowing back to the heat exchanger 80 side . The rear guide 118 and the stabilizer 117 extend in the longitudinal direction of the first blowing fan 130, that is, the longitudinal direction.

The first discharge passage 115 is a space formed inside the first discharge body 111 and can be understood as a passage through which the heat-exchanged air in the heat exchanger 80 flows.

The first ejection apparatus 110 includes a lower plate 121 for blocking the lower portion of the first ejection main body 111 and an upper plate 125 for covering the upper portion. For example, the lower plate 121 and the upper plate 125 may be integrally formed with the first discharge body 111, or may be configured to be coupled by a predetermined fastening member.

The indoor unit 10 includes a first supporter 250 for supporting a lower portion of the first ejection apparatus 110 and a second supporter 260 for supporting an upper portion of the first ejection apparatus 110. The first supporter 250 may be configured to support the lower side of the lower plate 121 and the second supporter 260 may be configured to support the upper side of the upper plate 125.

The upper plate 125 is provided with a protrusion 126 for providing the center of rotation of the first discharging device 110. The protrusion 126 protrudes upward from the upper plate 125 and can be rotatably supported by the second supporter 260. A groove may be formed in the second supporter 260 to receive the protrusion 126.

The indoor unit 10 includes driving devices 140 and 145 for rotating the first discharging device 110. The driving devices 140 and 145 include a driving motor 140 that generates a driving force and a driving gear 145 that is coupled to the driving motor 140 and rotates.

The driving gear 145 can rotate the discharge main body 111. In detail, a driven gear 123 interlocking with the driving gear 145 may be formed on the discharge main body 111 or the lower plate 121. In FIG. 2, for example, a driven gear 123 is illustrated as being formed on the lower plate 121.

Specifically, the lower plate 121 includes a motor receiving portion 122 for receiving the fan motor 135. The motor receiving portion 122 may be integrally formed with the lower plate 121 or may be configured as a separate member from the lower plate 121 and be coupled to the lower plate 121. For example, the driven gear 123 may be formed on the outer circumferential surface of the motor receiving portion 122.

The driving force of the driving motor 140 is transmitted to the lower plate 121 and the discharging main body 111 through the driving gear 145 and the driven gear 123. The discharging main body 111 is connected to the protruding portion 126, As shown in FIG.

The indoor unit 10 includes a first blowing fan 130 for generating an air flow and a fan motor 135 for driving the first blowing fan 130.

The first blowing fan 130 is rotatably installed in the first discharge body 111. In detail, the upper portion of the first blowing fan 130 includes a supporting portion 132 rotatably coupled to the upper plate 125. The upper plate 125 may include a groove or a hole to which the support portion 132 is coupled. The first blowing fan 130 can be rotated about the support portion 132. [ That is, the support part 132 constitutes the rotation center of the first blowing fan 130.

The fan motor 135 may be coupled to the lower side of the first blowing fan 130. In detail, the motor shaft 136 coupled to the fan motor 135 may extend upward from the fan motor 135 and may be coupled to the lower portion of the first blowing fan 130. The fan motor 135 may be installed in the motor receiving portion 122 and supported by the first supporter 250.

In summary, the first blowing fan 130 and the fan motor 135, that is, the fan motor assembly may extend in the longitudinal direction from the lower plate 121 of the first discharge device to the upper plate 125. The first blowing fan 130 may be installed at a height corresponding to the first discharging unit 112. That is, the air flow path discharged from the suction portion 31 to the first discharge portion 112 via the first blowing fan 130 forms a straight flow path from the rear upper portion to the front upper portion of the case 20 .

In the course of the rotation of the first discharge body 111, the first blowing fan 130 can rotate with a predetermined turning radius.

5) of the first blowing fan 130 and the second rotation center B1 of the first discharge body 111 (see FIG. 5) are spaced apart or eccentric. Accordingly, when the first discharge main body 111 rotates about the second rotation center B1, the first blowing fan 130 rotates about the first rotation center A1 and the second rotation center B1 Can be rotated with a turning radius.

At this time, the fan motor 135 may rotate together with the first blowing fan 130. The first rotation center A1 is formed at a position corresponding to the support portion 132 and the second rotation center B1 is formed at a position corresponding to the protrusion 126. [

Of course, it is needless to say that the first blowing fan 130 rotates by the fan motor 135 to generate an air flow. That is, the first blowing fan 130 can simultaneously perform the rotation and the revolving motion. For example, in a state in which the first discharge body 111 is rotated such that the first discharge portion 112 is opened, the first blowing fan 130 operates to discharge air.

The indoor unit 10 is provided with a suction unit 31 formed at a rear portion of the indoor unit 10 to suck air therein. For example, the suction portion 31 may be formed on the upper portion of the rear panel 27. The suction unit 31 may be provided with a suction grille 32.

The indoor unit 10 further includes a filter unit 70 disposed inside the suction unit 31 to clean the air sucked through the suction unit 31. The filter device (70) may include a plurality of filter members (71, 73).

The indoor unit 10 further includes a heat exchanger 80 disposed in front of the filter unit 70 to heat-exchange the air. A drain portion 86 for storing condensed water generated in the heat exchanger 80 may be installed below the heat exchanger 80. A partitioning device 200 for partitioning the first discharge device 110 and the second discharge device 150 is installed in front of the heat exchanger 80.

The filter unit 70 is installed between the suction unit 31 and the heat exchanger 80 and the heat exchanger 80 is disposed between the filter unit 70 and the partition unit 200 Can be understood as being installed.

The first blowing fan 130 may include, for example, a cross flow fan. Accordingly, the air can be sucked in the circumferential direction of the first blowing fan 130 and discharged in the direction of the outer circumference.

When the first blowing fan 130 is driven, the air sucked through the suction unit 31 passes through the first blowing fan 130 through the filter unit 70 and the heat exchanger 80, And can be discharged from the first discharge portion 112 to the indoor space via the first discharge passage 115. [

The configuration of the second ejection apparatus 150 is similar to that of the first ejection apparatus 110. For example, the fan motor assembly is installed inside the discharge main body, the rotation center of the blowing fan is eccentric from the rotation center of the discharge main body, and the inlet portion 159 is formed at the rear portion of the cylindrical discharge main body, A configuration in which the discharge portion 152 is formed is similar to that of the first discharge device 110. However, there is a difference from the first discharge device in that the fan motor 175 provided in the second discharge device 150 is arranged above the discharge main body 151.

In detail, the second ejection apparatus 150 includes a second ejection main body 151 forming a second ejection flow path 155 and a second ejection body 151 formed on the front surface of the second ejection main body 151, A portion 152 is included. The second discharging portion 152 may extend in the longitudinal direction from the upper portion of the second discharging body 151 to the lower portion thereof. A first discharge vane 154 is provided in the second discharge portion 152.

The second discharge main body 151 includes a stabilizer 157 and a rear guide 118. Explanations of these relate to the description of the stabilizer 117 and the rear guide 118 of the first discharging device 110.

The second ejection apparatus 150 includes a lower plate 161 coupled to an opened lower portion of the second ejection body 151 and an upper plate 165 coupled to an upper opened portion of the second ejection body 151 . For example, the lower plate 161 and the upper plate 165 may be integrally formed with the second discharge body 151, or may be configured to be coupled by a predetermined fastening member.

A second blowing fan 170 may be rotatably installed inside the second discharge main body 151. A fan motor 175 for providing a driving force to the second blowing fan 170 is installed above the second blowing fan 170. The upper plate 165 includes a motor receiving portion 165a for receiving the fan motor 175. [

The lower plate 161 is provided with a protrusion 166 for providing the center of rotation of the second discharging device 150. The protrusion 166 protrudes downward from the lower plate 161 and can be rotatably supported by the first supporter 250. The first supporter 250 may be formed with a groove for receiving the protrusion 166.

The indoor unit 10 includes driving devices 180 and 185 for rotating the second discharging device 150. The driving devices 180 and 185 include a driving motor 180 that generates a driving force and a driving gear 185 that is coupled to the driving motor 180 and rotates.

The driving gear 185 may rotate the second discharge main body 151. In detail, the second discharge main body 151 or the lower plate 161 may be provided with a driven gear 163 interlocked with the driving gear 185. For example, in FIG. 3, a driven gear 163 is shown as being formed in the lower plate 161.

The driving force of the driving motor 180 is transmitted to the second ejection body 151 and the lower plate 161 through the driving gear 185 and the driven gear 163, And can be rotated around the projection 166. [

The lower portion of the second blowing fan 170 includes a support 172 rotatably coupled to the lower plate 161. The lower plate 161 may include a groove or a hole to which the support portion 172 is coupled. The second blowing fan 170 can be rotated about the support portion 172. [ That is, the support portion 172 forms the center of rotation of the second blowing fan 170.

In summary, the second blowing fan 170 and the fan motor 175, that is, the fan motor assembly, may extend in the longitudinal direction from the upper plate 165 to the lower plate 161 of the second discharge device. The second blowing fan 170 may be installed at a height corresponding to the second discharging unit 152. That is, the air flow path discharged from the suction portion 31 to the second discharge portion 152 via the second blowing fan 170 forms a straight flow path from the rear upper portion of the case 20 toward the front upper portion can do.

In the course of the rotation of the second discharge main body 151, the second blowing fan 170 can rotate with a predetermined turning radius. 5) of the second blowing fan 170 and the second rotation center B2 (see Fig. 5) of the second discharge main body 151 are eccentric. Accordingly, when the second discharge main body 151 rotates about the second rotation center B2, the second blowing fan 170 rotates about the first rotation center A2 and the second rotation center b2 Can be rotated with a turning radius. The first rotation center R2 is formed at a position corresponding to the support portion 172 and the second rotation center C2 is formed at a position corresponding to the protrusion 166. [

The description of the suction unit 31, the filter unit 70, the heat exchanger 80, and the partition unit 200 is based on the description of the first discharge unit 110.

The indoor unit (10) further includes a partitioning unit (200) for partitioning the first and second discharge units (110, 150) to the left and right. That is, the partitioning device 200 can be understood as a device for partitioning the space from the heat exchanger 80 to the first and second ejection devices 110 and 150 to the left and right.

More specifically, the partitioning device 200 includes a first partition 210 provided at an upper portion of the front surface of the indoor unit 10 and a second partition 220 extending rearward from the first partition 210 .

For example, the first compartment 210 may include a display unit for displaying the operation information of the indoor unit 10.

The second compartment 220 is provided with a coupling part 221 which is coupled to the first compartment 210 and extends rearward and has both sides where the sealing device 300 or the second sealing member 320 is installed, .

The air passage of the air which extends rearward from the coupling portion 221 and has passed through the heat exchanger 80 is connected to the second partition 220 through a first discharge device flow path 251 and a second discharge device flow path 252 (Not shown). Here, the first discharge device flow path 251 is a flow path for guiding air to an inlet 119 of the first discharge main body 111, and the second discharge device flow path 252 is a flow path for guiding air And guided to the inflow portion 159 of the main body 151. [ The first and second discharging device flow paths 251 and 252 may be combined to form a "discharging device flow path".

The wall 225 may extend to a location adjacent the heat exchanger 80. The rear end of the wall 225 may extend from the front surface of the heat exchanger 80 by a predetermined distance S1. For example, the set distance S1 may be about 1 to 2 mm.

Ideally, it is theoretically possible for the wall 225 to be in contact with the heat exchanger 80, ideally for completely partitioning the air flow through the heat exchanger 80. However, since condensate may be generated in the heat exchanger 80 and the condensed water needs to be drained to the drain 86, the wall 225 may be connected to the heat exchanger 80 ) By a set distance S1.

5 is a view showing a relative positional relationship between the first and second discharging devices and the wall according to the embodiment of the present invention.

Referring to FIG. 5, the indoor unit 10 according to the embodiment of the present invention includes a first discharge device 110 and a second discharge device 150 that are rotatably provided. For example, the first and second discharging devices 110 and 150 may be arranged in the left-right direction when viewed from the front of the indoor unit.

The first discharging device 110 rotates about the second rotating center B1 of the first discharging main body 111. [ The second rotation center B1 may be defined by the protrusion 126. [ The first blowing fan 130 provided in the first discharging device 110 rotates about the first rotation center A1. The first rotation center A1 may be defined by the support portion 132. [

In the process of rotating the first discharging device 110, the first blowing fan 130 rotates by setting the distance between the first and second rotation centers A1 and B1 as a first rotation radius r1 . The path of the first rotation center A1 of the first blowing fan 130 forms the first rotation path t1.

The second discharging device 150 rotates about the second rotational center B2 of the second discharging main body 151. [ The second center of rotation B2 may be defined by the protrusions 166. The second blowing fan 170 provided inside the second discharging device 150 rotates about the first rotation center A2. The first rotation center A2 may be defined by the support portion 172. [

In the process of rotating the second discharging device 150, the second blowing fan 170 rotates by setting the distance between the first and second rotation centers A2 and B2 as a second rotation radius r2 . In the process of rotating the second discharging device 150, the path of the first rotation center A2 of the second blowing fan 170 forms the second rotation path t2.

The first rotation path t1 and the second rotation path t2 may be formed symmetrically with respect to the partitioning device 200.

The first and second discharging devices 110 and 150 may be disposed on the outlet side of the heat exchanger 80 with respect to the air flow path.

A partition device 200 is provided between the first discharge device 110 and the second discharge device 150. The partition device 200 forms at least a part of the front surface of the indoor unit 10 and extends rearward toward the heat exchanger 80. The rear end of the partitioning device 200 is spaced from the front surface of the heat exchanger 80 by a predetermined distance S1.

The partitioning device 200 divides the flow path of the air that has passed through the heat exchanger 80, that is, the outlet-side flow path of the heat exchanger 80 into the first discharge device flow path 251 and the second discharge device flow path 252 Can be divided. The size of the first discharge device flow path 251 and the size of the second discharge device flow path 252 may be the same.

In detail, the second rotation center B1 of the first ejection apparatus 110 and the second rotation center B2 of the second ejection apparatus 150 are formed at positions symmetrical with respect to the partition apparatus 200 do. That is, the distance d1 from the second rotation center B1 to the partitioning device 200 is formed to be equal to the distance d1 from the second rotation center B2 to the partitioning device 200 do.

In other words, a hypothetical line connecting the two second rotation centers B1 and B2 passes through the partitioning device 200, and on the virtual line, from the second rotation center B1 to the partitioning device 200 may be the same as the distance d1 from the second rotation center B2 to the center of the partitioning device 200. [

As described above, the partitioning device 200 is located at the intermediate point between the second rotation center B1 of the first discharge device 110 and the second rotation center B2 of the second discharge device 150 , It is possible to prevent the air flow from being deflected toward one of the discharge device side.

That is, in the process of rotating the first and second discharging apparatuses 110 and 150, any one of the discharging apparatuses is not located closer to the heat exchanger 80 side, The air passing through the heat exchanger 80 can be appropriately distributed to the first and second discharging devices 110 and 150 when the number of rotations of the two blowing fans 130 and 170 is the same, The flow of air sucked into the first and second flow passages 130 and 170 can be stabilized.

On the other hand, the first and second discharging apparatuses 110 and 150 can rotate in a direction in which the first and second discharging apparatuses 110 and 150 are spaced from each other with reference to the position of FIG. That is, when the positions of the first and second discharging apparatuses 110 and 150 are defined as 0 degrees, the first discharging apparatus 110 rotates counterclockwise to about 120 degrees, The device 150 may rotate clockwise about 120 degrees.

8 shows a state in which the first discharging device 110 rotates in the counterclockwise direction by 120 degrees and a state in which the second discharging device 150 rotates in the clockwise direction by 120 degrees.

In short, the first discharging device 110 can rotate in the clockwise or counterclockwise direction in the range shown in FIG. 4, that is, in the range between 0 degrees in the rotation direction and 120 degrees in the counterclockwise direction. The second discharging device 150 can rotate clockwise or counterclockwise at a position shown in FIG. 4, that is, in a range between 0 degrees in a clockwise direction and 120 degrees in a clockwise direction.

When the first and second discharging devices 110 and 150 are rotated at a rotation angle of 0 degree (first rotation angle), that is, at a position shown in FIG. 4, the first rotation center of the first blowing fan 130 A1 and the first rotation center A2 of the second blowing fan 170 are located at positions symmetrical with respect to the partitioning device 200. [ That is, the first rotation centers A1 and A2 are spaced apart by the same distance d3 from the center of the partitioning device 200, respectively.

The first and second discharging devices 110 and 150 independently rotate so that the first rotating center A1 of the first blowing fan 130 rotates along the first rotating path t1, 2 When the second rotation center A2 of the blowing fan 170 rotates along the second rotation path t2, the distance between the first rotation center A1 and the partitioning device 200 is smaller than the distance between the first rotation center A1 and the partitioning device 200, The distance between the rotation center A2 and the partitioning device 200 is different. The rotation angle of the first and second ejection apparatuses 110 and 150 at this time is called "second rotation angle ".

On the other hand, the rear end portion 226 of the wall 225 is disposed at a position substantially corresponding to an intermediate point with respect to the transverse direction of the heat exchanger 80, so that the outlet- .

The distance d2 between the second rotation center B1 and the rear end portion 226 of the first discharging device 110 is determined by the distance d2 between the second rotation center B2 of the second discharging device 150 and the second rotation center B2 of the second discharging device 150, And the distance d2 between the rear end portions 226.

According to the structure of the wall 225, the outlet-side flow path of the heat exchanger 80 is partitioned into the first and second discharge device flow paths 251 and 252 having the same size, so that air is discharged from the first and second discharge devices 110 and 150 So that they can be easily sucked into the first and second blowing fans 110 and 150.

When the first and second blowing fans 110 and 150 are formed to have different numbers of revolutions, the air that is divided into the blowing fan side having a smaller number of revolutions flows into the wall 225 to restrict the number of revolutions to flow toward the larger blower fan side.

6 is an enlarged sectional view of "A" in Fig. 4, and Fig. 7 is an enlarged sectional view of "B"

Referring to FIGS. 4, 6 and 7, air flows through a space or a gap between the first and second discharging devices 110 and 150 and the case 20 in the indoor unit 10 according to the embodiment of the present invention. The sealing device 300 is provided. The space or gap may be caused by the assembly tolerance required in the manufacturing process so that the first and second discharging devices 110 and 150 can be easily rotated without being interfered with the case 20. [

The sealing apparatus 300 includes a first sealing member 310 for blocking a space or a gap between the case 20 and the first discharging apparatus 110. In detail, the first sealing member 310 may be installed between one of the two side panels 25 and the outer surface of the first discharge body 111.

The first sealing member 310 is installed between the outer surface of the stabilizer 117 and the one side panel 25 to prevent indoor air from flowing into the indoor unit 10. For example, the first sealing member 310 may be coupled to the one side panel 25 and be capable of contacting the outer surface of the stabilizer 117.

The first sealing member 310 is configured to have a sufficient width so that the first discharging main body 111 can be maintained in a state of constant contact with the first discharging main body 111 during the rotation of the first discharging main body 111. The first sealing member 310 may extend longitudinally along the longitudinal direction of the first discharging body 111.

Specifically, the first sealing member 310 is mounted between the inner surface of the side panel 25 and the outer surface of the first discharge body 111, specifically, the stabilizer 117. The first sealing member 310 includes a sealing body 311 coupled to the side panel 25 and a contact portion coupled to the sealing body 311 and capable of contacting the first discharge body 111 313).

The sealing body 311 includes a tape adhered to the side panel 25. The contact portion 313 may include a brush made of fiber or a soft plastic material. The length of the contact portion 313 is,

The first sealing member 310 can be easily installed by the sealing body 311 and the contact portion 313 and even if the contact portion 313 is wet by moisture or the like, As shown in Fig.

The sealing device 300 includes a second sealing member 320 for blocking a space or a gap between the first discharging device 110 and the partitioning device 200. In detail, the second sealing member 320 may be installed between the outer surface of the partitioning device 200 and the rear guide 118. For example, the second sealing member 320 may be coupled to one side of the partition device 200 and may be disposed on the outer surface of the rear guide 118.

The second sealing member 320 is configured to have a sufficient width so that the first discharging body 111 can be maintained in a state of constant contact with the first discharging body 111 during the rotation of the first discharging body 111. The second sealing member 320 may extend longitudinally along the longitudinal direction of the first discharge body 111.

Specifically, the second sealing member 310 is mounted between one side of the partitioning device 200 and the outer surface of the first discharging main body 111, specifically, the rear guide 118. The second sealing member 320 is provided with a sealing body 321 coupled to the partitioning device 200 and a contact portion coupled to the sealing body 321 and capable of contacting the first discharging body 111 323).

The description of the configuration of the sealing main body 321 and the contact portion 323 explains the configuration of the sealing main body 311 and the contact portion 313.

The sealing device 300 includes a third sealing member 330 for blocking a space or a gap between the case 20 and the second discharging device 150. In detail, the third sealing member 330 may be installed between the other side panel of the two side panels 25 and the outer surface of the second discharge main body 151.

The third sealing member 330 is installed between the outer surface of the stabilizer 157 and the other side panel 25 to prevent indoor air from flowing into the indoor unit 10. For example, the third sealing member 330 may be coupled to the other side panel 25 and may be disposed on the outer surface of the stabilizer 157.

The third sealing member 330 is configured to have a sufficient width so that the third sealing member 330 can be kept in a state of constant contact with the second discharging main body 151 during the rotation of the second discharging main body 151. The third sealing member 330 may extend longitudinally along the longitudinal direction of the second discharge main body 151.

The sealing device 300 includes a fourth sealing member 340 for blocking a space or a gap between the second discharging device 150 and the partitioning device 200. In detail, the fourth sealing member 340 may be installed between the partitioning device 200 and the outer surface of the rear guide 158. For example, the fourth sealing member 340 may be coupled to the other surface of the partitioning device 200 and may be disposed on the outer surface of the rear guide 158.

The fourth sealing member 340 is configured to have a sufficient width so that the second discharging body 151 can be maintained in a state of constant contact with the second discharging body 151 during the rotation of the second discharging body 151. The fourth sealing member 340 may extend longitudinally along the longitudinal direction of the second discharge main body 151.

The first to fourth sealing members 310, 320, 330 and 340 may have the same configuration. In other words, the description of the third and fourth sealing members 330 and 340 provided in the second discharging device 150 explains the configuration of the sealing body 311 and the contact portion 313.

FIG. 9A is a view showing a state where air passing through a heat exchanger is deflected to a discharge device when a wall is not present in an indoor unit according to an embodiment of the present invention. FIG. 9B is a cross- In which the air passing through the heat exchanger is uniformly distributed to the two discharge units and flows inside the indoor unit.

9A is a schematic view illustrating a state in which at least a part of the partition device 200, for example, the wall 225 is not provided in the indoor unit according to the embodiment of the present invention, when the first and second blowing fans 130 and 170 are driven, (80). ≪ / RTI > At this time, the rotational speed W2 of the second blowing fan 170 is formed to be larger than the rotational speed W1 of the first blowing fan 130.

The blowing force of the second blowing fan (170) is larger than the blowing force of the first blowing fan (130). Therefore, the air that has passed through the heat exchanger (80) can be deflected toward the second discharge device flow path (252). In other words, the flow rate flowing to the first discharge device flow path 251 side becomes small.

Due to the bias of the air flow, a surging phenomenon occurs in which the air pressure or the air velocity fluctuates in the first and second blowing fans 130 and 170. Particularly, the surging phenomenon may occur in the first blowing fan 130 in which the flow rate is low. If the surging phenomenon occurs, the air flow becomes unstable and vibration and noise of the blowing fan are increased.

FIG. 9B is a graph showing the relationship between the air passing through the heat exchanger 80 when the first and second blowing fans 130 and 170 are driven when the partition device 200 is provided in the indoor unit according to the embodiment of the present invention. Show the flow. At this time, the rotational speed W2 of the second blowing fan 170 is formed to be larger than the rotational speed W1 of the first blowing fan 130.

The blowing force of the second blowing fan (170) is larger than the blowing force of the first blowing fan (130). Since the first and second discharging device flow paths 251 and 252 can be separated by the wall 225, the air flowing through any one of the first and second discharging device flow paths 251 and 252 can be separated from the other Flow in the flow path is prevented.

As a result, the air flow can be prevented from being deflected, and the air passing through the heat exchanger 80 can flow through the first and second blowing fans 130 and 170, corresponding to the rotational speeds of the first blowing fan 130 and the second blowing fan 170, 2 discharge device flow paths 251,

For example, since the rotational speed of the second blowing fan 170 is greater than the rotational speed of the first blowing fan 130, the amount of air flowing through the second discharging device flow path 252 becomes relatively large. Of course, when the number of revolutions of the first blowing fan 170 is relatively large, the amount of air flowing through the first discharge device flow path 251 will be relatively large.

As described above, the partitioning device 200 is provided between the first and second discharging devices 110 and 150 so that air having passed through the heat exchanger 80 can be guided to the first and second discharging device flow paths 251 and 252, There is an advantage that the deflection of the air flow can be prevented and the surging phenomenon in the first blowing fan 130 or the second blowing fan 170 can be prevented.

10: indoor unit 20: case
23: front panel 25: side panel
27: rear panel 31: suction portion 70: filter device 80: heat exchanger
110: first discharging device 111: first discharging main body
117, 157: Stabilizer 118, 158: Rear guide
130: first blowing fan 150: second discharging device
151: second discharge main body 170: second blowing fan
200: partition device 210: first partition
220: second compartment 225: wall
310, 320, 330, 340: first to fourth sealing members

Claims (15)

case;
A suction unit formed at a rear portion of the case and sucking air;
A heat exchanger for exchanging heat between the suctioned air and the suctioned air;
A plurality of discharge devices rotatably provided at an outlet side of the heat exchanger;
A blowing fan provided inside the plurality of discharging devices;
A discharge device flow path for guiding the flow of air from an outlet side of the heat exchanger to an inlet portion of the plurality of discharge devices; And
And a partitioning unit provided between the plurality of discharging units and partitioning the discharging unit flow paths,
Wherein each rotation center of the plurality of discharge devices is formed at a position symmetrical with respect to the partitioning device,
Wherein the first rotation center of the blowing fan
Wherein the first and second rotation centers are eccentric with respect to a second rotation center of the plurality of discharge devices.
delete The method according to claim 1,
In a state in which the plurality of discharge devices are rotated at a predetermined first rotation angle,
Wherein the first rotation center of the blowing fan is formed at a position symmetrical with respect to the partitioning device. The method according to claim 1,
During the rotation of the plurality of discharge devices,
Wherein the first rotation center of the blowing fan rotates with a predetermined rotation radius and the distance from the first rotation center of the blowing fan to the center of the partitioning device is variable. The method according to claim 1,
The plurality of discharging devices include a first discharging device and a second discharging device,
Wherein the first and second discharging devices are arranged in the left-right direction with respect to the front of the plurality of discharging devices. 6. The method of claim 5,
In the discharge device flow path,
A first discharge device flow path for guiding the air having passed through the heat exchanger to an inflow portion of the first discharge device; And
And a second discharge device flow path for guiding air passing through the heat exchanger to an inlet of the second discharge device. The method according to claim 6,
Wherein the partitioning device divides the first discharge device flow path and the second discharge device flow path. The method according to claim 6,
In the partitioning device,
And a wall for blocking the air in the first discharge device flow path from flowing into the flow path of the second discharge device. 9. The method of claim 8,
Wherein the wall is separated from the heat exchanger by a set distance (S1). The method according to claim 1,
In the partitioning device,
A first compartment forming at least a part of a front surface of the indoor unit; And
And a second compartment extending from the first compartment to the heat exchanger. 11. The method of claim 10,
In the second compartment,
And a wall separating the discharge device flow path. The method according to claim 1,
Wherein the partitioning device includes at least one surface on which a sealing device is installed. 13. The method of claim 12,
Wherein the sealing device is provided to close a gap between the discharge device and the partitioning device. 6. The method of claim 5,
Wherein the blowing fan includes a first blowing fan provided in the first discharging device and a second blowing fan provided in the second discharging device,
Wherein the first and second blowing fans are driven at different rotational speeds. case;
A suction unit formed at a rear portion of the case and sucking air;
A heat exchanger for exchanging heat between the suctioned air and the suctioned air;
A first and a second discharge device rotatably installed at an outlet side of the heat exchanger;
First and second blowing fans provided inside the first and second ejecting apparatuses and eccentrically rotated from the center of the first and second ejecting apparatuses in the process of rotating the first and second ejecting apparatuses; And
A partitioning device extending from an outlet side of the heat exchanger to an interspace of the first discharge device,
In the partitioning device,
A display unit; And
And a wall extending from the display unit toward the heat exchanger and partitioning the outlet-side flow path of the heat exchanger into the first discharge device flow path and the second discharge device flow path.

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