KR102342119B1 - Air conditioner - Google Patents

Abstract

The present invention includes a rear body having a first air intake and a second air intake formed on an upper side of the first air intake; a heat exchanger disposed in front of the first air intake; a front body having an air discharge unit positioned in front of the heat exchanger and having an opening formed above the air discharge unit; a first blower disposed between the front body and the heat exchanger; a second blower located in the opening and sucking air through the second air inlet and discharging it to the outside; Including a second blower rotating mechanism for rotating the second blower in the upper direction, the lower direction, the left direction, and the right direction, the second blower can be rotated in four directions, up, down, left, and right, so that air can be supplied in more various discharge directions. It is possible to discharge, and there is an advantage in that the wind direction can be adjusted with high accuracy in four directions, up, down, left, and right than when the wind direction control member for adjusting the wind direction is rotatably installed.

Description

air conditioner {Air conditioner}

The present invention relates to an air conditioner, and more particularly, to an air conditioner in which a plurality of blowers are installed.

In general, an air conditioner can change the temperature, humidity, cleanliness, etc. by sucking air through an air inlet, and then discharging it into a room through an air outlet to change the indoor environment into a comfortable environment.

The air conditioner may have an air outlet through which air is discharged to the outside, and an air conditioning unit such as a heat exchanger or filter capable of changing the temperature, humidity or cleanliness of the air may be installed therein, and a blower for flowing air A device may be installed.

The air conditioner may include a discharge body in which an air discharge port is formed.

An example of the discharge body is disposed to be fixedly positioned on the upper part of the air conditioner, and it is possible to discharge the air conditioned into the room in a state where the position is fixed.

Another example of the discharge body may be rotatably disposed left and right on the upper part of the air conditioner, and a left and right three-dimensional airflow may be formed around the discharge body while rotating left and right at the top of the air conditioner.

KR Special 2001-0065315 A (published on July 11, 2001) KR 10-0273353 B1 (announced on April 02, 2001)

The air conditioner according to the prior art has a problem in that the auxiliary blower cannot control the vertical wind direction, and the air that has passed through the heat exchanger is always blown by the auxiliary blower, so the effect of improving the blowing ability by the auxiliary blower is low.

The present invention includes: a rear body having a first air inlet and a second air inlet formed on an upper side of the first air inlet; a heat exchanger disposed in front of the first air inlet; a front body having an air discharging unit positioned in front of the heat exchanger and having an opening formed above the air discharging unit; a first blower disposed between the front body and the heat exchanger; a second blower positioned in the opening and sucking air through the second air inlet and discharging it to the outside; and a second blower rotating mechanism for rotating the second blower in an upward direction, a downward direction, a left direction, and a right direction.

The opening may be located in front of the second air inlet, and may face the second air inlet in the front-rear direction.

The front body may include an upper guide in which the opening is formed and surrounding the outer periphery of the second blower.

The second blower may be smaller in size than the upper guide, and may be connected to the second blower rotating mechanism to be spaced apart from the inner circumferential surface of the upper guide.

The second blower includes a second blower body connected to the second blower rotating mechanism; a motor installed on the second blower body; It may include an axial fan connected to the motor and blowing air in a forward direction.

The second blower body includes a rear grill; A front grill coupled to the front of the rear grill may be included, and a motor mounting part to which the motor is mounted may be formed on one of the rear grill and the front grill.

The second blower rotating mechanism includes: a first motor connected to the second blower to rotate the second blower in any one of a vertical direction and a left and right direction; a rotor frame in which the first motor is installed; It may include a second motor for rotating the rotor frame in the other one of the vertical direction and the left and right directions.

The front body may have an upper guide in which the opening is formed and the second motor is mounted.

The air discharge unit may be formed to be elongated in the vertical direction on the front body, and the first blower may include a plurality of fan units spaced apart from each other in the vertical direction.

an air discharge unit cover disposed on the front body so as to be able to move up and down to open and close the air discharge unit; When the uppermost fan unit of the plurality of fan units is driven, the air outlet cover may further include an air outlet cover lifting mechanism for raising the air outlet cover to a height at which the entire air outlet is shielded by the air outlet cover. can

The air discharging unit cover lifting mechanism may lower the air discharging unit cover to a height at which the entire air discharging unit is opened when all of the plurality of fan units are driven.

According to the present invention, since the second blower can be rotated in four directions, up, down, left, and right, air can be discharged in more various discharge directions, and the accuracy is higher in four directions than when the wind direction control member for adjusting the wind direction is rotatably installed. It has the advantage of being able to control the wind direction.

In addition, the air sucked in through the second air inlet can be discharged into the room through the second blower without passing through the heat exchanger, so that the air can be quickly circulated through a larger space of the room and the entire room can be quickly air-conditioned. There is this.

In addition, since the air flowing by the first blower and the second blower is not discharged to the air discharge unit, but is concentrated to the second blower and discharged in the direction that the second blower faces, a strong discharge airflow is provided in the direction that the second blower faces There are advantages to being able to

1 is a longitudinal sectional view in a first mode of an embodiment of an air conditioner according to the present invention;
2 is a longitudinal cross-sectional view in a second mode of an embodiment of the air conditioner according to the present invention;
3 is a longitudinal cross-sectional view in a third mode of an embodiment of the air conditioner according to the present invention;
4 is a longitudinal cross-sectional view in a fourth mode of an embodiment of the air conditioner according to the present invention;
5 is a cross-sectional view of an air conditioner according to an embodiment of the present invention;
6 is a perspective view showing an operation example of an air conditioner according to an embodiment of the present invention;
7 is a perspective view showing an operation example of a second blower according to an embodiment of the air conditioner according to the present invention;
8 is a rear view of a second blower and a second blower rotating mechanism according to an embodiment of the air conditioner according to the present invention.
9 is a control block diagram of an air conditioner according to an embodiment of the present invention.

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

1 is a longitudinal sectional view of an air conditioner according to an embodiment of the present invention in the first mode, FIG. 2 is a longitudinal sectional view of an embodiment of the air conditioner according to the present invention in a second mode, and FIG. 3 is an air conditioner according to the present invention It is a longitudinal sectional view in the third mode of an embodiment of the air conditioner, FIG. 4 is a longitudinal sectional view in the fourth mode of an embodiment of the air conditioner according to the present invention, and FIG. 6 is a perspective view illustrating an operation example of an air conditioner according to an embodiment of the present invention. Fig. 6 (a) is a perspective view when the air conditioner is in the first mode, Fig. 6 (b) is a perspective view when the air conditioner is in the second mode, and Fig. 6 (c) is a perspective view of the air conditioner in the third mode It is a perspective view when it is in mode, and FIG. 6 (d) is a perspective view when the air conditioner is in the fourth mode.

The air conditioner may be provided with a plurality of air intakes 2 and 4 and an air discharge unit 6 . The air conditioner may include a heat exchanger 10 through which air and refrigerant exchange heat, and may include a plurality of blowers 12 and 16 for blowing air.

The air conditioner may include a rear body 22 through which external air is sucked into the air conditioner, and a front body 30 through which air inside the air conditioner is discharged to the outside. The air conditioner may include a case 37 that forms an exterior. The case 37 may be composed of an assembly in which a plurality of members are coupled. The case 37 may include a rear body 22 and a front body 30 . The rear body 22 may form a rear exterior of the air conditioner, and the front body 30 may form a front exterior of the air conditioner. Case 37 may include a base 38 . The base 38 may form a bottom surface of the air conditioner. The rear body 20 may be disposed above the rear portion of the base 38 . The front body 30 may be disposed above the front portion of the base 38 . The case 37 may further include a connection body 39 connecting the rear body 20 and the front body 30 . The connection body 39 may form a side surface and an upper surface exterior of the air conditioner.

A plurality of air intakes 2 and 4 may be formed in the rear body 22 . A first air inlet 2 may be formed in the rear body 22 , and a second air inlet 4 may be formed at a different position from the first air inlet 2 . The second air inlet (4) may be formed to have a higher height than the first air inlet (2). The second air inlet 4 may be formed to be spaced apart from the first air inlet 2 at an upper position of the first air inlet 2 . Air can be sucked into the air conditioner through the first air inlet 2 located at the lower side and flow toward the heat exchanger 10, and the second air inlet 4 located at the upper side It can be sucked into the air conditioner through the suction and flow toward the second blower 16 to be described later. The rear body 22 has a purification unit 24 that purifies the air sucked into the first air inlet 2 . This can be arranged. A purification unit guide 26 on which the purification unit 24 is installed may be disposed on the rear body 22 . The rear body 22 may be configured as a single member, and the rear body 22 may be configured as an assembly in which a plurality of members are coupled. When the rear body 22 is composed of a combination of a plurality of members, a lower rear body having a first air inlet 2 is formed, and an upper rear body having a second air inlet 4 formed and disposed above the lower rear body. it is possible to do

The heat exchanger 10 may be disposed in front of the first air inlet 2 . The air sucked in through the first air inlet 2 may flow to the heat exchanger 10 and pass through the heat exchanger 10 .

An air discharge unit 6 may be formed in the front body 30 . The front body 30 may have an opening 8 formed on the upper side of the air discharge unit 6 .

The air discharge unit 6 may be formed to be opened to the front body 30 in the front-rear direction. The air discharge unit 6 may be formed to be positioned in front of the heat exchanger 10 , and may be positioned in front of the blower 12 .

As shown in FIG. 6 , the air discharge unit 6 may be formed to be elongated in the vertical direction as a whole. The air discharge unit 6 includes a pair of straight discharge units 6A and 6B that are long in the vertical direction and spaced apart in the left and right directions, and a curved discharge unit connecting the lower portions of the pair of straight discharge units 6A and 6B ( 6C).

The front body 30 may be composed of an assembly in which a plurality of members are coupled. The front body 30 has a front outer body 34 that is opened in the front-rear direction and has a rectangular long portion in the vertical direction, and a front inner body that is smaller in size than the long portion and is located inside the long portion of the front outer body 34 . (36) may be included. In the front body 30 , the air discharge unit 6 may be positioned between the front outer body 34 and the front inner body 36 . The front inner body 36 may be connected to the front outer body 34 by the air discharge unit 6 , and may be supported by the front outer body 34 . The air discharge unit 6 may be configured as a discharge grill in the shape of a grill. The discharge grill may be connected to the front inner body 36 and may be connected to the front outer body 34 . The air discharge unit 6 may include a wind direction adjusting member rotatably installed between the front outer body 34 and the front inner body 36 and a motor for rotating the wind direction adjusting member.

The opening 8 may be formed to have a height higher than that of the air discharge unit 6 . The opening 8 may be formed to be positioned other than the front of the heat exchanger 10 . The opening 8 may be formed to be positioned in front of the second air inlet 4 . The opening 8 may be formed to be opened in the front-rear direction at the upper portion of the front body 30 . The opening 8 may be formed at a position facing the second air inlet 4 in the front-rear direction.

The front body 30 may include an upper guide 32 having an opening 8 formed therein. The upper guide 32 may surround the outer circumference of the second blower 16 to be described later and protect the outer circumference of the second blower 2 dlm. The second blower 16 may be rotated to be deflected in any one direction of up, down, left, and right at an inner position of the upper guide 32 .

The plurality of blowers 12 and 16 may include a first blower 12 disposed between the front body 30 and the heat exchanger 10 . The first blower 12 may be installed to be positioned in front of the heat exchanger 10 , and may be installed to face the front surface 11 of the heat exchanger 10 . The first blower 12 may be a main blower that sucks air through the first air inlet 2 , passes it through the heat exchanger 10 , and blows the air through the air outlet 6 . The first blower 12 may be located at the rear of the front inner body 34 and the air discharge unit 6 . The first blower 12 may suck in the rear air and blow it in the forward direction. When the first blower 12 is driven, it can suck air through the first air inlet 2 and pass it through the heat exchanger 10 , and the air that has passed through the heat exchanger 10 is fed to the air outlet 6 . can blow The first blower 12 may blow the air that has passed through the heat exchanger 10 upward. The first blower 12 may blow air upward when the air discharge unit 6 is blocked.

The first blower 12 may include a plurality of fan units 13, 14 and 15 spaced apart from each other in the vertical direction. The first blower 12 may be configured as an axial blower or a centrifugal blower.

When the first blower 12 is configured as an axial flow blower, each of the plurality of fan units 13, 14, and 15 may include a motor and an axial fan installed on the rotating shaft of the motor. In this case, a plurality of The fan units 13 , 14 , and 15 may be arranged so that each of the axial fans faces different parts of the air discharge unit 6 .

When the first blower 12 is configured as a centrifugal blower, each of the plurality of fan units 13, 14, and 15 includes a motor M and a centrifugal fan F installed on the rotating shaft of the motor M. can do. The centrifugal fan may be one of a turbofan and a sirocco fan. When the first blower 12 is configured as a centrifugal blower, the first blower 12 may include a fan housing 17 that guides air flowing by the centrifugal fan. The fan housing 17 may surround the plurality of fan units 13 , 14 , 15 . An opening 20A through which air can flow to the second blower 16 may be formed on the top surface of the fan housing 17 , and the uppermost fan unit 13 positioned at the uppermost side among the first blowers 12 . The air blown in the fan may flow to the second blower 16 through the opening 20A of the fan housing 17 .

The fan housing 17 may include an orifice 18 disposed in front of the heat exchanger 10 to guide air sucked toward the centrifugal fan. The orifice 18 may have a suction hole facing the heat exchanger 10 .

The fan housing 17 may include a front plate 19 for guiding air flowing by the centrifugal fan. The front plate 19 may function as an air guide whose rear surface guides air. The motor M of the first blower 12 may be installed on the front plate 19 . The front plate 19 may function as a motor mounter on which the motor M is mounted.

The fan housing 17 may include an inner guide 20 for guiding the air blown by the centrifugal fan in a forward direction where the air discharge unit 6 is located. The inner guide 20 may include a left plate part for guiding air flowing in the left direction from the centrifugal fan in a forward direction, and a right plate part for guiding air flowing in a right direction from the centrifugal fan in a forward direction. An opening 20A through which air passes in an upward direction may be formed at an upper portion of the inner guide 20 .

At least one of the orifice 18 , the front plate 19 , and the inner guide 20 has partition walls 18A and 18B that divide the flow paths of the plurality of fan units 13 , 14 and 15 to protrude. can be

When the first blower 12 includes three fan units 13 , 14 , 15 , the first blower 12 is located at the top of the plurality of fan units 13 , 14 , 16 . the uppermost fan unit 13, the central fan unit 14 located below the uppermost fan unit 13, and the plurality of fan units 13, 14, 15 located below the central fan unit 14. ) may include a lowermost fan unit 15 located at the lowermost side.

The first blower 12 may include two fan units 13 and 15. In this case, the first blower 12 includes an upper fan unit located at the upper side and a lower fan unit located at the lower side. It is possible to include

Hereinafter, it will be described that the first blower 12 includes three fan units: an uppermost fan unit 13 , a central fan unit 14 , and a lowermost fan unit 15 .

The uppermost fan unit 13 may blow air toward the upper part of the air outlet 6 , and the lowermost fan unit 15 may blow air toward the lower part of the air outlet 6 , The central fan unit 14 may blow air toward a middle part between the upper part and the lower part of the air discharge part 6 .

Here, the upper portion of the air discharge unit 6 may be a partial area X corresponding to the uppermost fan unit 13 in the front-rear direction among the entire area of the air discharge unit 6 , The middle portion Y may be another area Y corresponding to the central fan unit 14 in the front-rear direction among the entire area of the air discharge unit 6 , and the lower portion Z of the air discharge unit 6 is air It may be another area Z corresponding to the lowermost fan unit 15 in the front-rear direction among the entire area of the discharge unit 6 .

The plurality of fan units 13, 14 and 15 may be operated in the first blowing mode in which the uppermost fan unit 13, the central fan unit 14, and the lowermost fan unit 15 are all driven. In the first blowing mode, the first blower 12 may blow air toward the entire upper portion X, the middle portion Y, and the lower portion Z of the air discharge unit 6 .

The plurality of fan units 13, 14 and 15 may be operated in the second blowing mode in which the uppermost fan unit 13 and the central fan unit 14 are driven, and the lowermost fan unit 15 is stopped. have. In the second blowing mode, the first blower 12 may blow air toward the upper portion X and the middle portion Y of the air discharge unit 6 .

The plurality of fan units 13, 14 and 15 can be operated in the third blowing mode in which only the uppermost fan unit 13 is driven, and the central fan unit 14 and the lowermost fan unit 15 are stopped. have. In the third blowing mode, the first blower 12 may blow air toward the upper portion X of the air discharge unit 6 .

The plurality of fan units 13, 14 and 15 may have a stop mode in which the uppermost fan unit 13, the central fan unit 14, and the lowermost fan unit 15 are all stopped. In the stop mode, the first blower 12 does not blow air toward the air discharge unit 6 .

The plurality of blowers 12 and 16 may include a second blower 16 that sucks air through the second air inlet 4 and discharges it to the outside. The second blower 16 may be connected to a second blower rotating mechanism 40 to be described later to adjust the wind direction of the air discharged from the second blower 16 to the outside. The second blower 16 may have a smaller size than the upper guide 32 . The second blower 16 may be connected to the second blower rotating mechanism 40 to rotate. The second blower 16 may be connected to the second blower rotating mechanism 40 to be spaced apart from the inner circumferential surface 33 of the upper guide 32 . The second blower 16 may be installed to be suspended from the second blower rotating mechanism 40 .

The air conditioner may include a second blower rotating mechanism 40 for rotating the second blower 16 in the upper direction, the lower direction, the left direction, and the right direction.

The second blower 16 includes a second blower body 52 connected to the second blower rotating mechanism 40; a motor 54 installed on the second blower body 52; It may include an axial fan 56 connected to the motor 54 and blowing air in a forward direction.

The second blower body 52 includes a rear grill 58; A front grill 60 coupled to the front of the rear grill 58 may be included. A motor mounting part 62 to which the motor 54 is mounted may be formed in one of the rear grill 58 and the front grill 60 . When the motor mounting part 61 is formed on the rear grill 58 , the rotation shaft 55 of the motor 54 may protrude in a direction toward the front grill 60 . When the motor mounting part 61 is formed on the front grill 60 , the rotation shaft 55 of the motor 64 may protrude in a direction toward the rear grill 58 .

The motor 54 may rotate in the left and right directions together with the second blower body 52 when the second blower body 52 rotates in the left and right directions, and when the second blower body 52 rotates in the vertical direction, the second blower It may rotate with the body 52 in the vertical direction.

The axial fan 56 may be connected to the rotation shaft 55 of the motor 54 to suck air from the outside of the rear grill 58 and blow air in a direction toward the front grill 60 . The axial fan 56 may blow air in a direction in which the rotation shaft 55 of the motor 54 faces. For example, when the rotation shaft 55 of the motor 54 is directed in the forward direction, the axial fan 56 may blow air in the forward direction. When the rotating shaft 55 of the motor 54 faces the front upper side in an inclined direction, the axial fan 56 may blow air in the front upper side inclined direction. When the rotating shaft 55 of the motor 54 faces the front lower side inclined direction, the axial fan 56 may blow air in the front lower side inclined direction, and in this case, the air is discharged from the front of the air discharge unit 6 . It can be discharged inclined downward in the direction toward the.

The air conditioner may include an air discharge unit cover 70 disposed on the front body 30 to be able to move up and down to open and close the air discharge unit 6 . According to the height of the air discharge unit cover 70, the open area of the air discharge unit 6 may be different.

The air conditioner may further include an air discharge unit cover lifting mechanism 80 for lifting and lowering the air discharge unit cover 70 . The air discharge unit cover lifting mechanism 80 may include a driving source, a first gear 82 rotated by the driving source, and a second gear 84 meshed with the first gear 82 . The driving source may include an elevating motor 86 driven to elevate the air outlet cover, and the first gear 82 may be connected to a rotation shaft of the elevating motor 86 . The first gear 82 may be configured as a pinion installed on the rotation shaft of the elevating motor 86 , and the second gear 84 may be configured as a rack formed elongated in the air outlet cover 70 in the vertical direction. As shown in FIG. 5, the air outlet cover 70 may have a protrusion positioned to pass through the guide hole 35 formed in the case 37, and the rack is located inside the case 37 among the protrusions. It may be formed to be elongated in the vertical direction on the part.

The air outlet cover lifting mechanism 80 may adjust the elevation height of the air outlet cover 70 in multiple stages according to the number of the plurality of fan units 13, 14, and 15 turned on.

The air outlet cover lifting mechanism 80 can lower the air outlet cover 70 to a lower height as the number of the plurality of fan units 13, 14, and 15 is increased, and the plurality of fan units 13 (13) ( 14) As the number of turns on (15) decreases, the air outlet cover 70 can be raised to a higher height.

The air outlet cover lifting mechanism 80 may raise the air outlet cover 50 to the highest height when the number of on-on fan units among the plurality of fan units 13, 14, and 15 is the minimum. In addition, the air outlet cover lifting mechanism 80 may lower the air outlet cover 50 to the lowest height when the plurality of fan units 13, 14, and 15 are all turned on.

The air discharge unit cover lifting mechanism 80 may have a first opening/closing mode in which the air discharge unit cover 70 is lowered to a height H1 that opens the entire air discharge unit 6 .

The air discharging unit cover lifting mechanism 80 is the first in which the air discharging unit cover 70 is raised to a height H2 at which the air discharging unit cover 70 shields the lower portion of the air discharging unit 6 and opens the upper and middle portions of the air discharging unit 6 . It can have two opening/closing modes.

The air discharging unit cover lifting mechanism 80 is a first in which the air discharging unit cover 70 is raised to a height H3 at which the lower and middle portions of the air discharging unit 6 are shielded and the upper portion of the air discharging unit 6 is opened. It can have 3 opening/closing modes.

The air discharging unit cover lifting mechanism 80 may have a fourth opening/closing mode in which the air discharging unit cover 70 is raised to a height H4 that shields both the upper, middle and lower portions of the air discharging unit 6 .

The air outlet cover lifting mechanism 80 has a height H1 at which the entire air outlet 6 is opened when the plurality of fan units 13, 14, and 15 are all driven. can be lowered.

When the uppermost fan unit 13 among the plurality of fan units 13, 14, and 15 is driven, the air outlet cover lifting mechanism 80 has the entire air outlet cover 70 ), it is possible to raise the air outlet cover 70 to a height (H4) to be shielded.

The air outlet cover lifting mechanism 80 is driven by the uppermost fan unit 13 among the plurality of fan units 13, 14 and 15, and the central fan unit 14 and the lowermost fan unit 15 are When stopped, it may be operated in the fourth opening/closing mode, and in this case, the front of the uppermost fan unit 13 among the air discharge units 6 may be shielded by the air discharge unit cover 70 .

When the front of the uppermost fan unit 13 among the air outlets 6 is shielded by the air outlet cover 70 , the air blown in the front direction by the uppermost fan unit 13 is transferred to the air outlet 6 . ) cannot be discharged in the forward direction, and may flow to the second blower 16 by the rear surface of the air discharge unit cover 70 , and flow to the second blower 16 to blow the second blower 16 . direction can be discharged.

7 is a perspective view showing an operation example of a second blower of an embodiment of the air conditioner according to the present invention, and FIG. 8 is a rear view of the second blower and the second blower rotating mechanism of the embodiment of the air conditioner according to the present invention. .

Figure 7 (a) is a perspective view when the second blower 16 blows air toward the front direction (P), Figure 7 (b) is an inclined direction in which the second blower 16 is directed upward. It is a perspective view when blowing air in (Q), and (c) of FIG. 7 is a perspective view when the second blower 16 blows air in an oblique direction (R) toward the front lower side, d) is a perspective view when the second blower 16 blows air in the oblique direction S toward the front left, and (e) of FIG. 7 is the second blower 16 inclined direction toward the front right ( It is a perspective view when air is blown to T).

The second blower rotating mechanism 40 includes a first motor 62 connected to the second blower 16 to rotate the second blower 16 in any one of the vertical and horizontal directions, and the first motor 62 . ) and the rotor frame 64 is installed; It may include a second motor 66 for rotating the rotor frame 64 in the other one of the vertical direction and the left and right directions.

When the first motor 62 rotates the second blower 16 in the vertical direction, the second motor 66 may rotate the rotor frame 65 in the left and right directions, and conversely, the first motor 62 When rotating the second blower 16 in the left and right directions, the second motor 66 may rotate the rotor frame 65 in the vertical direction.

The first motor 62 may have a rotation shaft 63 connected to the second blower 16 . The rotating shaft 63 may be connected to the second blower body 52 to rotate the second blower body 52 . The first motor 62 may be connected to the second blower body 52 of the second blower 16 with the rotating shaft 63 positioned horizontally, and when the first motor 62 is driven, the second blower 16 ) may be rotated up and down about the rotation shaft 63 .

The rotor frame 64 may be formed in a circular or semi-circular shape, and may surround a portion of the outer circumference of the second blower 16 .

At least one of the rotor frame 64 and the second blower body 52 is positioned opposite to the rotation shaft 63 of the first motor 62 to rotate the second blower body 52 of the second blower 16 . A support shaft 65 for supporting may be disposed. The support shaft 65 is disposed to protrude from the second blower body 52 to be rotatably supported by a shaft support formed in the rotor frame 64 . Conversely, the support shaft 65 may protrude from the rotor frame 65 to be rotatably supported by a shaft support formed in the second blower body 52 .

The second motor 66 may be installed on the upper guide 32 . The second motor 66 may rotate the rotor frame 64 by having a rotating shaft 67 connected to the rotor frame 64 . When the first motor 62 is mounted to be positioned next to the rotor frame 64 , the second motor 66 may be connected to the rotor frame 64 from the upper side of the rotor frame 64 .

In the second motor 66 , the rotation shaft 67 is vertically positioned and may be connected to the rotor frame 64 , and when the second motor 66 is driven, the rotor frame 64 moves to the left about the rotation shaft 67 . , can be rotated right.

9 is a control block diagram of an air conditioner according to an embodiment of the present invention.

The present embodiment may include the input unit 90 for inputting the operation mode of the air conditioner. The air conditioner may include a control unit 100 for controlling the first blower 12 and the second blower 16 . When controlling the first blower 12 , the controller 100 may control each of the plurality of fan units 13 , 14 , and 15 , and may control a motor of the fan unit. The controller 100 may control the motor 54 when controlling the second blower 16 . The control unit 100 may control the second blower rotating mechanism 40 . The controller 100 may control the first motor 62 and the second motor 66 when the second blower rotating mechanism 40 is controlled. The control unit 100 may control the air discharge unit cover lifting mechanism 80 . The control unit 100 may control the lifting motor 86 when controlling the air discharge unit cover lifting mechanism 80 . The control unit 100 may control the air discharge unit cover lifting mechanism 80 in conjunction with the first blower 12 .

The air conditioner may have a first wide discharge mode in which air is discharged through the entire air discharge unit 6 and the second blower 16 . The input unit 90 may include a first wide discharge input unit capable of inputting the first wide discharge mode.

The air conditioner may have a second wide discharge mode in which air is discharged through the upper and middle portions of the air discharge unit 6 and the second blower 16 . The input unit 90 may include a second wide discharge input unit capable of inputting the second wide discharge mode. Here, the second wide discharge mode may have a smaller discharge area than the first wide discharge mode, and the number of fan units driven among the first blowers 12 may be one less.

The air conditioner may have an upper discharge mode in which air is discharged through an upper portion of the air discharge unit 6 and the second blower 16 . The input unit 90 may include an upper discharge input unit capable of inputting an upper discharge mode.

The air conditioner may have a concentrated discharge mode in which air is concentratedly discharged through the second blower 16 without discharging air to the air discharge unit 6 . The input unit 90 may include a concentrated discharge input unit capable of inputting the concentrated discharge mode.

The air conditioner may have an upward deflection discharge mode in which the second blower 16 blows air in an inclined direction of the front upper side. The input unit 90 may include an upwardly biased discharge input unit capable of inputting an upwardly biased discharge mode.

The air conditioner may have a downward deflection discharge mode in which the second blower 16 blows air in an oblique direction of the front lower side. The input unit 90 may include a downwardly biased discharge input unit capable of inputting a downwardly biased discharge mode.

The air conditioner may have a left-handed discharge mode in which the second blower 16 blows air in an inclined direction of the front left. The input unit 90 may include a left-handed discharge input unit capable of inputting a left-handed discharge mode.

The air conditioner may have a rightward discharge mode in which the second blower 16 blows air in an inclined direction to the front right. The input unit 90 may include a post-direction discharging input unit capable of inputting a post-direction discharging mode.

When the air conditioner is in any one of the first wide discharge mode, the second wide discharge mode, the upper discharge mode, and the concentrated discharge mode, the second blower 16 operates in the front discharge mode, the upper side discharge mode and the lower side discharge mode. It can be controlled in one of the biased discharge mode, the left-handed discharge mode, and the right-handed discharge mode. The air conditioner may include 20 discharge modes, and the air conditioner may form various discharge air streams.

Hereinafter, the operation of the present invention configured as described above will be described as follows.

First, when the first blower 12 is driven and the second blower 16 is driven, air may be discharged to the outside of the air conditioner through the air discharge unit 6 located at a relatively lower side, and It may be discharged to the outside of the air conditioner through the second blower 16 located on the upper side.

The control unit 100 may drive all the fan units 13 , 14 , 15 and the second blower 16 of the first blower 12 in the first wide discharge mode. The control unit 100 may control the air discharge unit cover lifting mechanism 80 so that the air discharge unit cover 70 is located at a height H1 at which the entire air discharge unit 6 is opened.

When the plurality of fan units 13, 14, and 15 of the first blower 12 are driven, the air behind the rear body 22 can pass through the first air inlet 2 through the heat exchanger 10. Thereafter, the air is blown in the forward direction by the plurality of fan units 13 , 14 , 15 and may be discharged to the air discharge unit 6 . And, when the second blower 16 is driven, the air behind the rear body 22 may be sucked into the air conditioner through the second air inlet 4 and may be sucked into the air conditioner without passing through the heat exchanger 10 . It may be sucked in by the second blower 16 , and may be discharged in a direction toward which the second blower 16 is directed.

In the first wide discharge mode, the air discharged from the air conditioner is blown by the front of the air discharge unit 6 and the second blower 16 as shown in FIGS. 1 and 6 (a). It may be dispersed and discharged most widely in the direction, and the air discharged from the air conditioner may be discharged while being spread most widely in the vertical direction in front of the air conditioner.

The control unit 100 drives the uppermost fan unit 13 and the central fan unit 14 among the plurality of fan units 13, 14, and 15 of the first blower 12 in the second wide discharge mode. In addition, the second blower 16 may be driven. Then, the control unit 100 raises the air discharge unit cover 70 to a height H2 that shields the front of the lowermost fan unit 15 among the air discharge units 6 so that the air discharge unit cover elevating mechanism 80 can control

When the uppermost fan unit 13 and the central fan unit 14 of the first blower 12 are driven, the air behind the rear body 22 passes through the first air inlet 2 and passes through the heat exchanger 10 Afterwards, the air is blown in the forward direction by the uppermost fan unit 13 and the central fan unit 14 to be discharged to the air discharge unit 6 . And, when the second blower 16 is driven, the air behind the rear body 22 may be sucked into the air conditioner through the second air inlet 4 and may be sucked into the air conditioner without passing through the heat exchanger 10 . It may be sucked in by the second blower 16 , and may be discharged in a direction toward which the second blower 16 is directed.

In the second wide discharge mode, the air discharged from the air conditioner is in front of the upper portion of the air discharge unit 6 and in front of the middle portion of the air discharge unit 6, as shown in FIGS. 2 and 6 (b). and the second blower 16 may be dispersedly discharged in a direction in which the air is blown, and the air discharged from the air conditioner may be discharged while spreading to a narrower width than in the first wide discharge mode.

In the upper discharge mode, the control unit 100 drives the uppermost fan unit 13 among the plurality of fan units 13, 14 and 15 of the first blower 12 and drives the second blower 16 as well. can do it Then, the control unit 100 raises the air discharge unit cover 70 to a height H3 that shields the front of the lowermost fan unit 15 and the front of the central fan unit 14 among the air discharge units 6 . It is possible to control the air discharge unit cover lifting mechanism (80).

When the uppermost fan unit 13 of the first blower 12 is driven, the air behind the rear body 22 may pass through the heat exchanger 10 through the first air inlet 2, and then the uppermost It may be blown forward by the fan unit 13 to be discharged to the air discharge unit 6 . And, when the second blower 16 is driven, the air behind the rear body 22 may be sucked into the air conditioner through the second air inlet 4 and may be sucked into the air conditioner without passing through the heat exchanger 10 . It may be sucked in by the second blower 16 , and may be discharged in a direction toward which the second blower 16 is directed.

In the upper discharge mode, the air discharged from the air conditioner is blown by the upper front of the air discharge unit 6 and the second blower 16 as shown in FIGS. 3 and 6 ( c ). may be discharged, and the air discharged from the air conditioner may be discharged while spreading to a narrower width than in the second wide discharge mode.

The control unit 100 drives the uppermost fan unit 13 among the plurality of fan units 13, 14 and 15 of the first blower 12 in the concentrated discharge mode and drives the second blower 16 as well. can do it In addition, the control unit 100 may control the air discharge unit cover lifting mechanism 80 so that the air discharge unit cover 70 rises to a height H4 that shields the entire air discharge unit 6 .

When the uppermost fan unit 13 of the first blower 12 is driven, the air behind the rear body 22 may pass through the heat exchanger 10 through the first air inlet 2, and then the uppermost It may be blown by the fan unit 13 . The air blown by the first blower 12 may flow to the second blower 16 without being discharged in the forward direction of the air discharge unit 6 because the air discharge unit 6 is blocked. And, when the second blower 16 is driven, the air behind the rear body 22 may be sucked into the air conditioner through the second air inlet 4 and may be sucked into the air conditioner without passing through the heat exchanger 10 . It may be sucked by the second blower 16 . Air flowing by the uppermost fan unit 13 of the first blower 12 and passing through the heat exchanger 10, and the air flowing by the second blower 16 and sucked into the second air inlet 4 may be merged in the inside of the second blower 16 or from the rear of the second blower 16 , and may be discharged in a direction toward which the second blower 16 is directed.

In the concentrated discharge mode, the air discharged from the air conditioner is not discharged through the air discharge unit 6 as shown in FIGS. 4 and 6 (d), but the second blower 16 blows the air. direction, and the air discharged from the air conditioner may be concentratedly discharged with a narrower width than in the upper discharge mode. In the concentrated discharge mode, the air conditioner discharges a narrower air discharge than in the upper discharge mode, and can discharge an airflow that is stronger than the upper discharge mode and can reach a long distance.

On the other hand, the present invention is not limited to the above embodiments, and various modifications are possible within the technical scope to which the present invention belongs.

2: first air inlet 4: second air inlet
6: air discharge part 8: opening
10: heat exchanger 12: first blower
13: uppermost fan unit 14: central fan unit
15: lowermost fan unit 22: rear body
30: front body 32: upper guide
40: second blower rotating mechanism 52: second blower body
54: motor 56: axial fan
58: rear grill 60: front grill
61: motor mounting part 62: first motor
64: rotor frame 66: second motor
70: air outlet cover 80: air outlet cover elevating mechanism

Claims (11)

a rear body having a first air inlet and a second air inlet formed above the first air inlet;
a heat exchanger disposed in front of the first air intake;
a front body in which an air discharge unit is positioned in front of the heat exchanger and an opening is formed above the air discharge unit;
a first blower disposed between the front body and the heat exchanger and including a plurality of fan units spaced apart from each other in a vertical direction;
a second blower located in the opening and sucking air through the second air inlet and discharging it to the outside;
a second blower rotating mechanism for rotating the second blower in an upward direction, a downward direction, a left direction, and a right direction;
an air discharge unit cover disposed on the front body so as to be able to move up and down to open and close the air discharge unit; and
and an air outlet cover lifting mechanism for adjusting the elevation height of the air outlet cover in multiple stages according to the number of fan units driven among the plurality of fan units.
The method of claim 1,
The opening is located in front of the second air inlet, and faces the second air inlet in a front-rear direction. The method of claim 1,
and the front body includes an upper guide having the opening formed therein and surrounding an outer periphery of the second blower. 4. The method of claim 3,
The second blower is smaller in size than the upper guide and is connected to the second blower rotating mechanism to be spaced apart from the inner circumferential surface of the upper guide. The method of claim 1,
The second blower
a second blower body connected to the second blower rotating mechanism;
a motor installed on the second blower body;
and an axial fan connected to the motor and blowing air in a forward direction. 6. The method of claim 5,
The second blower body
rear grille;
It includes a front grill coupled to the front of the rear grill,
An air conditioner in which a motor mounting portion to which the motor is mounted is formed on one of the rear grill and the front grill. The method of claim 1,
The second blower rotating mechanism is
a first motor connected to the second blower to rotate the second blower in any one of a vertical direction and a left and right direction;
a rotor frame in which the first motor is installed;
and a second motor for rotating the rotor frame in the other one of a vertical direction and a left and right direction. 8. The method of claim 7,
The front body is an air conditioner in which the opening is formed and an upper guide to which the second motor is mounted is formed. The method of claim 1,
The air discharging unit is formed to be elongated in the vertical direction on the front body. The method of claim 1,
The air discharge unit cover lifting mechanism,
An air conditioner for raising the air outlet cover to a height at which the entire air outlet is shielded by the air outlet cover when an uppermost fan unit among the plurality of fan units is driven. The method of claim 1,
The air discharging unit cover lifting mechanism lowers the air discharging unit cover to a height at which the entire air discharging unit is opened when all of the plurality of fan units are driven.

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