KR20140019207A - Indoor unit of air conditioner and controlling method of the air conditioner - Google Patents

Abstract

Disclosed is an indoor unit of an air conditioner with improved inlet, outlet, and air path structures to increase operation efficiency, reduce noise, and perform the miniaturization of a size. The indoor unit of the air conditioner comprises a housing, one or more outlets, one or more inlets, one or more heat exchangers, and one or more mixed flow fans. The housing comprises a front panel on which one or more opening units are formed and a back panel connected to a back side of the front panel. One or more outlets are exposed to the front side of the front panel through the opening units. One or more inlets are formed in the back panel corresponding to the outlets. One or more heat exchangers are arranged in the front side of an inlet. The heat exchangers adsorb heat from air of the inlets or deliver the heat to the air which flows in through the inlets. One or more mixed flow fans are rotated between the heat exchanger and an outlet and outlet the air, which exchanges the heat in the heat exchanger, through the outlet.

Description

Indoor unit of air conditioner and control method of air conditioner {INDOOR UNIT OF AIR CONDITIONER AND CONTROLLING METHOD OF THE AIR CONDITIONER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an indoor unit of an air conditioner, and more particularly to an air conditioner having improved suction, discharge, and flow path structures.

Generally, an air conditioner is equipped with a compressor, a condenser, an evaporator, a blower fan, and the like, which removes dust and the like in the air while adjusting temperature, humidity, airflow, distribution and the like suitable for human activity by using a refrigeration cycle .

The air conditioner may be divided into a separate type air conditioner in which an indoor unit and an outdoor unit are separately installed, and an integrated type air conditioner in which an indoor unit and an outdoor unit are installed together in a single cabinet.

The indoor unit of the separate type air conditioner includes a heat exchanger for heat-exchanging the air sucked into the panel, and a blower fan that sucks the indoor air into the panel and blows the sucked air back into the room.

In general, a blower fan is disposed below the indoor unit of the separate air conditioner, and a heat exchanger and an air discharge port through which air is discharged are disposed above. The air sucked and blown by the blower fan moves to the upper part of the indoor unit, and the air moved to the upper part is discharged to the room via a heat exchanger and an air discharge port.

However, in the indoor unit having such a structure, since the blower fan and the heat exchanger are disposed up and down, respectively, there is a disadvantage in that the space utilization is not efficient.

In addition, since the air passing through the blowing fan must be discharged by moving to the upper part of the indoor unit, the flow path from the lower part of the indoor unit to the upper part is long, and the load on the blowing fan that blows the sucked air is large, which is inefficient in terms of energy utilization. However, there is a limit in increasing the air volume and the wind speed.

In addition, when the arrangement of the heat exchanger and the blower fan is narrowed in order to reduce the size of the indoor unit, the air-side resistance of the heat exchanger rises, resulting in a decrease in the performance of the blower fan and an increase in operating noise.

One aspect of the present invention provides an indoor unit of an air conditioner capable of increasing operation efficiency, reducing noise, and improving intake, discharge, and air flow path structures to realize miniaturization of size.

In addition, it provides an indoor unit of the improved air conditioner to conveniently adjust the wind direction and the amount of air discharged from the indoor unit.

The indoor unit of the air conditioner according to the spirit of the present invention; a housing including a front panel having at least one opening formed therein and a rear panel coupled to the rear of the front panel; and the front of the front panel through the at least one opening. At least one discharge port exposed to the at least one discharge port; and at least one suction port formed at the rear panel at a position corresponding to the at least one discharge port; and disposed in front of the suction port, and introduced through the at least one suction port. At least one heat exchanger for absorbing heat from air or transferring heat to the air introduced through the at least one inlet port; and air rotatably disposed between the heat exchanger and the discharge port to exchange heat in the heat exchanger. At least one of suctioning and discharging through the discharge hole It is characterized by including the above four-flow fan.

The discharge port, the vortex fan, the heat exchanger, and the suction port may be arranged in a line in the front and rear directions of the housing.

At least two or more of the plurality of discharge ports may be spaced apart in the up and down directions of the indoor unit.

An angle formed between the direction of the air sucked into the crossflow fan and the direction of the air discharged through the discharge port may be 15 ° or more and 60 ° or less.

A diffuser disposed in front of the vortex fan, wherein the diffuser includes a circular disk plate and a grill coupled to an outer circumferential surface of the disk plate to form the discharge port between the disk plate and the disk plate. Can be.

A drive motor coupled to a rear surface of the disc plate in a direction in which the rotation shaft thereof faces the suction port, and the vortex fan includes a hub coupled to a rotation shaft of the drive motor, and a plurality of wings coupled to an outer circumferential surface of the hub. It may include.

The crossflow fan may have a flow path such that the sucked air is discharged inclined with respect to the central axis of the hub.

The hub includes an inclined portion, and the angle from one point at which the inclination of the hub starts to an outer portion of the hub may be 10 kV to 40 kV.

The diameter of the hub may be reduced in the direction in which the rotation axis of the drive motor is directed.

The outer circumferential surface of the hub is formed to be inclined, and the angle formed by the tangential contact with the outer circumferential surface of the hub and the virtual straight line passing through the center of the rotation axis of the driving motor may be 10 ° or more and 40 ° or less.

The shortest distance between the wing end of the swirling fan and the front surface of the heat exchanger may be 20 mm or more and 50 mm or less.

It may be coupled to the rear of the grill, it may include a duct to form a flow path for moving the air sucked by the crossflow fan is discharged to the discharge port.

The plurality of swirling fans may be individually controllable.

In addition, the indoor unit of the air conditioner according to the spirit of the present invention; a housing including a front panel having a plurality of openings and a rear panel coupled to the rear of the front panel; and a plurality of suction ports formed in the rear panel; And a plurality of heat exchanger units disposed in front of the intake port, and a plurality of crossflow fan units disposed in front of the heat exchanger and having discharge ports exposed in front of the front panel through the openings. The four-flow fan unit, a diffuser forming the discharge port; and a drive motor coupled to the rear of the diffuser; and a four-flow fan rotatably coupled to the drive motor; and the four sides of the diffuser It characterized in that it comprises a; duct to form a flow path that moves in the process of the air sucked by the discharge port is discharged.

The opening, the crossflow fan unit, the heat exchanger, and the suction port may be arranged in a line in the front and rear directions of the housing.

The plurality of crossflow fan units may be spaced apart in the up and down directions of the indoor unit.

The side surface of the duct surrounding the drift fan is formed to be inclined, the angle formed by the tangential contact with the lateral side of the duct and the imaginary straight line passing through the center of rotation of the drift fan may be 5 ° or more and 15 ° or less.

The diffuser may include a circular disk plate and a grill coupled to an outer circumferential surface of the disk plate to form the discharge hole between the disk plate and the disk plate.

It may include a fixing frame for fixing the crossflow fan unit and the heat exchanger in the housing.

The vortex fan may include a hub coupled to the rotation shaft of the driving motor, the hub having an outer circumferential surface formed to be inclined, and a plurality of wings coupled to the outer circumferential surface of the hub.

The discharge port may be formed in a ring shape.

The indoor unit of the air conditioner may include a controller configured to generate a control command for independently controlling each of the plurality of vortex fan units in response to the selected operation mode.

The electronic device may further include a fan driver configured to control the motor in response to a control command of the controller.

Independent control of the plurality of crossflow fan units may be on / off control of each of the plurality of crossflow fan units independently.

Independent control of the plurality of crossflow fan units may be to independently control the rotation speeds of the plurality of crossflow fan units.

Independent control of the plurality of swirling fan units may be to turn off some of the plurality of swirling fan units and independently control the rotation speed of the remaining swirling fan units.

In addition, the control method of the air conditioner according to the spirit of the present invention, the control method of the air conditioner is provided with a plurality of crossflow fan unit in the indoor unit, receiving a selection of the operation mode; Generate a control command to perform the selected mode of operation; In response to the control command, characterized in that each of the plurality of four-flow fan unit is independently controlled.

Independent control of the plurality of crossflow fan units may be on / off control of each of the plurality of crossflow fan units independently.

Independent control of the plurality of crossflow fan units may be to independently control the rotation speeds of the plurality of crossflow fan units.

Independent control of the plurality of swirling fan units may be to turn off some of the plurality of swirling fan units and independently control the rotation speed of the remaining swirling fan units.

The discharge port may have a circular shape so that air may be discharged radially.

The discharge port may have a structure capable of opening and closing.

The suction port may be located on at least one of an upper side, a lower side, a left side, and a right side of the rear panel.

The radius of the disc plate may be in the range of -20% to + 20% of R when the distance between the point extending from the outer portion of the hub to the discharge port and the center point of the disc plate is defined as R.

The shortest distance between at least one of the heat exchangers and at least one of the suction ports may be 40 mm or more and 60 mm or less.

The shortest distance between one end of the wing of the crossflow fan and the heat exchanger may be 20 mm or more and 50 mm or less.

It may include a guide vane provided in the discharge port.

The guide vane may include a first vane formed in a ring shape along the circumferential direction of the discharge port, and a second vane provided radially at the discharge port.

The first vane may have a streamlined cross section.

The radially inner side surface of the first vane is formed at a rear end thereof with a predetermined angle of inclination with respect to the axial direction of the vortex fan, and the front end thereof is formed parallel to the axial direction of the vortex fan as the angle of inclination decreases toward the front. Can be.

The radially outer surface of the first vane may be formed to be convexly curved radially outward.

At least one wing plate extending from the disk plate to the grill in a first direction and guiding air blowing from the swirl fan, wherein the wing plate has a direction of rotation of the swirl fan along the first direction; It can be bent in the opposite direction.

The wing plate may be formed of a spiral rib.

The wing plate may include a front portion facing the front side and a rear portion facing the rear side, and the front portion and the rear portion may have different bending angles.

The rear portion may be more curved than the front portion.

In the indoor unit of the air conditioner of the present invention, since the inlet port, the heat exchanger, the circulating fan, and the discharge port are arranged in a line, the air flow path structure is simplified, so that the operation efficiency of the indoor unit can be increased, and the size of the indoor unit can be reduced.

In addition, the user can conveniently adjust the wind direction and the amount of air by individually controlling the plurality of four-flow fan, thereby improving user convenience.

1 is a view showing the indoor unit of the air conditioner according to an embodiment of the present invention.
Fig. 2 is a front view of the indoor unit shown in Fig. 1. Fig.
3 is a view showing a state in which the front panel of the indoor unit shown in FIG. 1 is separated.
4 is an exploded perspective view of a part of the indoor unit shown in FIG. 1.
5 is a cross-sectional view of the indoor unit shown in FIG. 1.
FIG. 6 is an enlarged view of a portion 'A' of FIG. 5.
7 is a view showing the air temperature distribution discharged from the discharge port according to the operation mode of the indoor unit of the air conditioner according to an embodiment of the present invention.
8 is a view showing a control system of the air conditioner according to the embodiment of the present invention.
9 is a view showing a control method of an air conditioner according to an embodiment of the present invention based on FIG.
10 is a view showing the indoor unit of the air conditioner according to another embodiment of the present invention.
FIG. 11 is a diagram illustrating a state in which the front panel of the indoor unit illustrated in FIG. 10 is separated.
12 is a view showing the indoor unit of the air conditioner according to another embodiment of the present invention.
FIG. 13 is a cross-sectional view of the indoor unit shown in FIG. 12.
14 is a view showing the indoor unit of the air conditioner according to another embodiment of the present invention.
15 is a view illustrating a diffuser shape (a) of an indoor unit of an air conditioner according to the prior art and a diffuser shape (b) of an indoor unit of an air conditioner according to another embodiment of the present invention.
FIG. 16 is an enlarged view of a portion 'B' of FIG. 15.
17 is a perspective view of FIG. 16.
18 to 20 show the flow of the discharged air by the diffuser of the indoor unit of the air conditioner according to the prior art and the diffuser of the indoor unit of the air conditioner according to another embodiment of the present invention.

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

FIG. 1 is a view showing an indoor unit of an air conditioner according to an embodiment of the present invention. FIG. 2 is a front view of the indoor unit shown in FIG. 1. FIG. And FIG. 4 is an exploded perspective view of a part of the indoor unit shown in FIG. 1, FIG. 5 is a cross-sectional view of the indoor unit shown in FIG. 1, and FIG. 6 is an enlarged view of a portion 'A' of FIG. 5.

As shown in FIGS. 1 to 6, the indoor unit 100 of the air conditioner includes a housing 110 forming an exterior of the indoor unit 100, and a plurality of crossflows disposed inside the housing 110. The fan unit 120, the at least one heat exchanger 130 disposed at the rear of the plurality of crossflow fan units 120 inside the housing 110, and the rear surface of the housing 110. It is configured to include a plurality of suction ports 140.

The housing 110 includes a front panel 112 having a plurality of openings 112a formed therein so that a discharge port 121a of the slave fan unit 120 can be exposed forward and a rear panel 112 coupled to the rear of the front panel 112, (114). The plurality of openings 112a may be provided in a circular shape and at least two or more openings may be spaced apart in the up and down directions of the front panel 112.

The four-flow fan unit 120 includes a diffuser 121 forming the discharge port 121a, a driving motor 122 coupled to the rear surface of the diffuser 121, and a four-flow fan rotatably coupled to the driving motor 122. 123 and a duct 124 coupled to the rear surface of the diffuser 121 to form a flow path 124a through which air sucked by the swirling fan 123 is discharged to the discharge port 121a. do.

The diffuser 121 includes a circular disc plate 121b, a circular grille 121c coupled to the outer circumferential surface of the disc plate 121b, and a ring (not shown) formed between the disc plate 121b and the grille 121c. Ring-type discharge port 121a. The diffuser 121 is disposed in front of the current fan 123 so that air passing through the current fan 123 can be discharged to the front of the front panel 112 through the discharge port 121a.

As shown in the figure, the disc plate 121b is disposed in the center of the circular grill 121c, but the position where the disc plate 121b is disposed is not limited to the center of the circular grill 121c. The diameter of the disk plate 121b is related to the noise generated when air is discharged from the indoor unit 100 of the air conditioner, and is preferably 225 mm to 265 mm. Also, although not shown, the disc plate 121b and the grille 121c may be provided so as to be movable forward or backward in the direction in which the air of the indoor unit 100 is discharged.

The grill 121c includes a wing plate 121d and can control the direction and amount of air discharged through the discharge port 121a by adjusting the number, shape or arrangement angle of the wing plate 121d.

It is also possible to adjust the airflow direction and air volume of the air discharged through the discharge port 121a by reducing or increasing the radial width of the discharge port 121a by adjusting the interval between the disk plate 121b and the grille 121c, The diameter of the plate 121b may be adjusted to adjust the direction and amount of air discharged through the discharge port 121a.

The driving motor 122 is coupled to the rear surface of the disc plate 121b so as to rotate the turntable fan 123 such that the rotational axis 122a thereof is disposed in a direction toward the rear panel 114. [

The circulating fan 123 is disposed between the diffuser 121 and the heat exchanger 130 to suck the air exchanged heat in the heat exchanger 130 to be discharged through the discharge port 121a, and the driving motor 122 Hub 123a coupled to the rotation shaft 122a of the (), and a plurality of wings 123b coupled to the outer circumferential surface of the hub 123a.

The diameter of the hub 123a is provided to gradually decrease in the direction toward which the rotation shaft 122a of the drive motor 122 faces, that is, toward the rear panel 114, and thus the outer circumferential surface of the hub 123a is inclined. Center of the rotation axis 122a of the driving motor 122 and the tangents L1 and L2 contacting the inclined outer circumferential surface of the hub 123a so that the intake air may be inclined toward the discharge port 121a by the swirling fan 123. The angle α formed by the virtual straight line Lc passing through may be 10 m or more and 40 m or less.

One point where the tangents L1 and L3 contacting the inclined outer circumferential surface of the hub 123a meet is called P1, and one point where the straight line extending from P1 meets the center of the disc plate 121b is referred to as P2. The point where the tangents L1 and L3 in contact with the inclined outer circumferential surface of N) meet on the extension line of the disc plate 121b or the disc plate 121b is called P3, and the length between P2 and P3 is defined as R, The radius of the plate 121b may be formed in the range of -20% to + 20% of R. The disk plate 121b causes air to flow along the surface of the disk plate 121b according to the Coanda effect. Therefore, it plays a role of suppressing generation of vortices due to the flow of air in the front of the discharge port 121a. When the radius of the disk plate 121b is formed in the range of -20% to + 20% of R, it can make the appearance aesthetically neat and suppress the generation of vortex in the front of the discharge port 121a to prevent the indoor unit ( 100) can improve the performance.

At least three of the wings 123b are equally spaced along the outer circumferential surface of the hub 123a. The blade 123b forms a pressure gradient in the forward and backward directions of the extruder fan 123 in the process of rotating together with the hub 123a to form a constant air flow.

Circular arcs connecting both edges of the blade 123b are connected by two circular arcs having different radii of curvature. The boundary 129 of the first arc 129a and the second arc 129b may be located on the rear surface of the wing 123b rather than the center of the wing 123b. Accordingly, the boundary 129 of the first arc 129a and the second arc 129b flows along the surface of the wing 123b as compared with the case where the boundary 129 of the first arc 129a and the second arc 129b is located at the center of the wing 123b or the front surface of the wing 123b. The peeling area | region where the flow of air peels can be made small. Therefore, it is possible to prevent the performance of the indoor unit 100 from falling off by peeling, thereby reducing the noise.

When the shortest distance between one end of the blade 123b and the heat exchanger 130 disposed behind the crossflow fan unit 120 is 'd1', the shortest distance d1 is preferably 20 mm or more and 50 mm or less. If the shortest distance (d1) is less than 20mm, the gap between the drift fan 123 and the heat exchanger (130) is narrowed, so that the suction resistance occurs, the operation noise is increased, and if the shortest distance (d1) exceeds 50mm, This is because the space between the fan 123 and the heat exchanger 130 is widened so that the air exchanged heat through the heat exchanger 130 may not be smoothly sucked into the swirling fan 123.

In addition, when the shortest distance between the heat exchanger 130 and the suction port 140 is 'd2', the shortest distance d2 is preferably 40 mm or more and 60 mm or less.

The duct 124 includes a flow path forming pipe 124a provided in a circular shape surrounding the current fan 123 and forming an air flow path so that the air sucked by the current fan 123 flows to the discharge port 121a, And a fixing plate 124b connected to the rear of the flow forming tube 124a to fix the duct 124 in the housing 110. [

The side of the flow forming tube 124a is inclined so that the intake air can be discharged obliquely toward the discharge opening 121a by the turbulence fan 123 together with the hub 123a, It is preferable that the angle formed by the tangent line L2 in contact with the straight line Lp parallel to the virtual straight line passing through the rotation center of the current fan 123 is 5 to 15..

A diffuser 121 is coupled and fixed to the inlet opening of the flow path forming pipe 124a and the duct 124 is fixedly coupled to the stationary frame 150 through a rectangular plate 124b.

The heat exchanger 130 is disposed between the main fan unit 120 and the inlet 140 to absorb heat from the air introduced through the inlet 140 or to transfer the heat to the air introduced through the inlet 140. The heat exchanger 130 includes a tube 132 and a header 134 coupled at the upper and lower sides of the tube 132.

The number of heat exchangers 130 disposed in the indoor unit 100 may be one or plural. That is, the same number of heat exchangers 130 as the number of the plurality of the slave fan units 120 may be disposed behind the slave fan unit 120 to correspond to the plurality of slave fan units 120, One heat exchanger 130 having a size corresponding to both of the extruded fan unit 120 may be disposed. Further, the heat exchanging capacity of the heat exchanger 130 need not be all the same. That is, one of the plurality of heat exchangers 130 having a relatively small heat exchange capacity may be disposed behind the corresponding one of the two or more fan fans 120, and the other one having a relatively large heat exchange capacity may include two or more fan fans 120 It is also possible to arrange it on the rear side of the unit 120.

The suction port 140 is provided on the rear panel 114 disposed at the rear of the heat exchanger 130 to guide the air outside the indoor unit 100 into the indoor unit 100. The suction port 140 may have the rear panel 114 disposed on at least one portion of an upper surface, a side surface, and a rear surface of the rear panel 114.

As with the heat exchanger 130, the number of the suction ports 140 provided on the rear panel 114 may be one or more. The number of intake ports 140 equal to the number of the plurality of the slave fan units 120 may be provided on the rear panel 114 so as to correspond to the plurality of the slave fan units 120, One inlet 140 may be provided on the rear panel 114, all of which have a size corresponding to both of them. The plurality of suction ports 140 need not be all the same size. That is, it is also possible that one of the plurality of suction ports 140 is disposed behind the corresponding one of the two slave fan units 120, and the other is disposed behind the corresponding two or more slave fan units 120 .

As shown in FIG. 6, air introduced into the housing 110 through the inlet 140 absorbs or loses heat while passing through the heat exchanger 130. The air exchanged in heat through the heat exchanger 130 is sucked by the sucker fan 123 and discharged to the outside of the housing 110 through the duct 124 and the discharge port 121a. At this time, the angle formed by the direction of the air sucked into the entrained fan 123 and the direction of the air discharged through the discharge port 121a is about 15 to 60..

The indoor unit 100 according to an embodiment of the present invention may include a plurality of hydrostatic fan units 120, a plurality of heat exchangers 130, and a plurality of inlets 140. For convenience of description, as illustrated in FIG. 5, the plurality of vortex fan units 120, the plurality of heat exchangers 130, and the plurality of suction ports 140 are disposed up, down, and in the longitudinal direction of the indoor unit 100. The arrangement arrange | positioned is demonstrated to an example.

The plurality of vortex fan units 120 include a first vortex fan unit 120a, a second vortex fan unit 120b, and a third vortex fan unit 120c that are spaced apart from each other in the longitudinal direction of the indoor unit 100. do. The plurality of heat exchangers 130 may include a first heat exchanger 130a and a second heat exchanger 130b spaced apart from each other in the longitudinal direction of the indoor unit 100 between the four-flow fan unit 120 and the suction port 140. And a third heat exchanger 130c. The plurality of suction ports 140 include a first suction hole 140a, a second suction hole 140b, and a third suction hole 140c that are spaced apart from each other in the longitudinal direction of the indoor unit 100 at the rear of the heat exchanger 130. do.

The first flow fan unit 120a, the first heat exchanger 130a, and the first suction opening 140a are arranged in parallel with each other, and the second flow fan unit 120b, the second heat exchanger 130b, and the first The two suction ports 140b are arranged in parallel with each other in a lower portion of the first suction fan unit 120a, the first heat exchanger 130a, and the first suction hole 140a, and the third suction fan unit 120c, The third heat exchanger 130c and the third suction port 140c are arranged in parallel with each other at a lower portion of the second flow fan unit 120b, the second heat exchanger 130b, and the second suction port 140b, respectively.

As described above, the plurality of vortex fan units 120a, 120b, and 120c, the plurality of heat exchangers 130a, 130b, and 130c disposed in the longitudinal direction of the indoor unit 100, and the plurality of suction ports 140a, respectively. Since 140b and 140c are arranged in a row in front and rear, the width of the indoor unit can be configured to be slim, and the flow path formed between the suction port 140 and the discharge port 121a is shortened, so that the operation efficiency of the indoor unit 100 is reduced. On the other hand, noise is reduced.

The first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c may be individually controlled to be turned on or off or rotated at different speeds, respectively. The first heat exchanger 130a, the second heat exchanger 130b, and the third heat exchanger 130c respectively corresponding to the 120a, the second drift fan unit 120b, and the third drift fan unit 120c, The refrigerant may be individually supplied according to the operation (on / off) states of the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c. For example, when the first drift fan unit 120a and the second drift fan unit 120b are operated (on) and the third drift fan unit 120c is stopped (off), the first drift fan unit ( Refrigerant is supplied to the first heat exchanger 130a and the second heat exchanger 130b corresponding to the 120a) and the second drift fan unit 120b, and the third heat exchange corresponding to the third drift fan unit 120c. The group 130c may be controlled to not supply a refrigerant. Although not shown, the first heat exchanger 130a and the second heat exchanger 130b to control the refrigerant supplied to the first heat exchanger 130a, the second heat exchanger 130b, and the third heat exchanger 130c. And each valve for blocking the flow path between the refrigerant pipes connected to the third heat exchanger 130c and the first heat exchanger 130a, the second heat exchanger 130b, and the third heat exchanger 130c, respectively. Alternatively, one-way valve having a plurality of ports connected to the first heat exchanger 130a, the second heat exchanger 130b, and the third heat exchanger 130c may be installed. As the type of valve, an electronic on / off valve using a solenoid, a pneumatic on / off valve, or the like may be used.

Hereinafter, the control method of the indoor unit 100 of the air conditioner having such a structure will be described in detail.

7 is a view showing the air temperature distribution discharged from the discharge port according to the operating mode of the indoor unit of the air conditioner according to an embodiment of the present invention, Figure 8 is a control system of the air conditioner according to an embodiment of the present invention 9 is a view showing a control method of an air conditioner according to an embodiment of the present invention based on FIG.

FIG. 7 is a diagram illustrating an air temperature distribution discharged from 121a according to an operation mode of an indoor unit 100 of an air conditioner according to an embodiment of the present invention. Indoor unit 100 according to an embodiment of the present invention is provided with a plurality of vortex fan unit (120a, 120b, 120c) in the vertical direction (or vertical direction of the indoor unit), a plurality of vortex fan unit (120a, 120b, 120c) By controlling the air volume or wind speed of the air discharged through the air conditioning of the desired form. Control of the air flow rate or wind speed of the air discharged through the plurality of swirl fan units 120a, 120b, and 120c is independent of the on / off control and the rotational speed (RPM) of each of the plurality of swirl fan units 120a, 120b, and 120c. Is achieved through control.

Denoted at 702 in FIG. 7 is the bottom surface of the air conditioning space. Also indicated by reference numeral 704 is the ceiling of the air conditioning space, which is about 250 cm high from the bottom surface 702. Reference numeral 706 denotes a breathing line, which indicates the height (for example, about 165 cm) at which the nose and mouth of an average adult (eg, about 180 cm) are placed.

FIG. 7A illustrates a first operation mode in which all of the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c are operated (on). This is a case where the rotation speeds of the fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c are controlled differently. That is, the rotation speed of the first drift fan unit 120a is 1000 RPM, the rotation speed of the second drift fan unit 120b is 1200 RPM, and the rotation speed of the third drift fan unit 120c is 1400 RPM. . In this case, the first heat exchanger unit 130a, the second heat exchanger unit 130b, and the second heat exchanger unit unit 120a, 120b, 120c, and the third heat exchanger unit 120c respectively. The three heat exchangers (130c) can all be controlled to supply the refrigerant.

Since both the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c are operated (on), the amount of air discharged is not only large but also wider because they are transmitted farther. Suitable for coordination of space.

FIG. 7B illustrates a second operation mode in which all of the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c are operated (on). In the case where the rotation speeds of the fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c are controlled differently, the first drift fan unit 120a as compared with FIG. ) And the rotation speed of the second drift fan unit 120b is lower than in the case of (A). That is, the rotation speed of the first drift fan unit 120a is 600 RPM, the rotation speed of the second drift fan unit 120b is 1000 RPM, and the rotation speed of the third drift fan unit 120c is 1400 RPM. . In this case, like the first operation mode, the first heat exchanger 130a and the second heat exchanger respectively corresponding to the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan fan unit 120c, respectively. 130b and the third heat exchanger 130c may be controlled to supply a refrigerant.

When comparing (B) of FIG. 7 with (A), in the case of (B), the air-conditioning effect is similar to (A), but it can be seen that the air-conditioning effect is mainly performed under the breathing line 802. In the case of (B), since the rotational speed of the first drift fan unit 120a and the second drift fan unit 120b is relatively lower than in the case of (A), the height of the air conditioning effect is relatively higher than (A). Even if it is lowered, the quiet operation and the energy consumption can be reduced.

FIG. 7C illustrates a third operation mode in which the first drift fan unit 120a is stopped (off) and only the second drift fan unit 120b and the third drift fan unit 120c are operated (on). In this case, the rotation speed of each of the second drift fan unit 120b and the third drift fan unit 120c is controlled differently. In other words, the first drift fan unit 120a is stopped, the rotation speed of the second drift fan unit 120b is 1000 RPM, and the rotation speed of the third drift fan unit 120c is 1400 RPM. In this case, the refrigerant is not supplied to the first heat exchanger 130a corresponding to the first fan fan unit 120a, and the second fan is connected to the second fan fan unit 120b and the third fan fan unit 120c, respectively. Both of the second heat exchanger 130b and the third heat exchanger 130c may be controlled to supply a refrigerant.

Comparing (C) of FIG. 7 with (A) and (B), in the case of (C), it can be seen that the distance and height of the air conditioning effect are further reduced than (A) and (B). In the case of (C), since the first friction fan unit 120a does not operate, the quiet operation is possible and the energy consumption is reduced even though the space of the air conditioning effect is relatively reduced than in (A) and (B). Can be.

FIG. 7D illustrates a fourth operation mode in which the first drift fan unit 120a and the second drift fan unit 120b are stopped (off) and only the third drift fan unit 120c is operated (on). If it is. At this time, the rotation speed of the third swirl fan unit 120c is set at 1400 RPM. In this case, the refrigerant is not supplied to the first heat exchanger 130a and the second heat exchanger 130b corresponding to the first drift fan unit 120a and the second drift fan unit 120b, and the third drift fan unit The third heat exchanger 130c corresponding to 120c may be controlled to supply a refrigerant.

When comparing (D) of FIG. 7 with (A), (B), (C), in (D), the distance and height of the air conditioning effect are relatively larger than (A), (B) and (C). It can be seen that the decrease. In the case of (D), since the first drift fan unit 120a and the second drift fan unit 120b do not operate, the space where the air-conditioning effect is applied is relatively larger than that of (A), (B), and (C). Even if it decreases, the quiet operation is possible and energy consumption can be reduced. In particular, (D) in this case, it is useful when you want to focus the air conditioning effect only in the short distance of the front of the indoor unit 100 in the air conditioning space.

The on / off control and the rotational speed control of each of the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c are not limited to those shown in FIG. Different combinations can achieve different air conditioning effects.

8 is a view showing a control system of the air conditioner according to the embodiment of the present invention. As shown in FIG. 8, an input unit 804, an outdoor temperature sensor 806, an indoor temperature sensor 808, an evaporator temperature sensor 810, and the like are provided on an input side of the controller 802 that controls the overall operation of the air conditioner. It is electrically connected so as to be communicable, and on the output side of the controller 802, the compressor 812, the electromagnetic expansion valve 814, the first fan driver 816a, the second fan driver 816b, and the third fan driver 816c. Is electrically connected to enable communication. The first fan driving unit 816a, the second fan driving unit 816b, and the third fan driving unit 816c respectively include the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c. ) Is operated according to a control command of the controller 802 to turn on / off each of the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c. Control the rotation speed. The controller 802 controls the on / off and rotational speeds of the first drift fan unit 120a, the second drift fan unit 120b, and the third drift fan unit 120c corresponding to the operation mode selected by the user. The control command is transmitted to each of the first fan driver 816a, the second fan driver 816b, and the third fan driver 816c.

9 is a view showing a control method of an air conditioner according to an embodiment of the present invention based on FIG. The control method of FIG. 9 is performed by the control system shown in FIG. As shown in FIG. 9, when the user powers on the air conditioner and selects a desired operation mode, the air conditioner controller 802 receives information on the operation mode selected by the user, and receives the received operation mode. By generating a corresponding control signal to be delivered to each part of the air conditioner according to an embodiment of the present invention to achieve the desired operation (902).

When the driving mode selected by the user is the first driving mode, the controller 802 performs the first driving mode on each of the first fan driver 816a, the second fan driver 816b, and the third fan driver 816c. By passing the control command for the first fan fan unit 120a to rotate at 1000 RPM, the second fan fan unit 120b to rotate at 1200 RPM, the third fan fan unit 120c is 1400 RPM Rotate to (904).

When the driving mode selected by the user is the second driving mode, the controller 802 performs the second driving mode on each of the first fan driver 816a, the second fan driver 816b, and the third fan driver 816c. By transmitting a control command for the first fan fan unit 120a to rotate at 600 RPM, the second fan fan unit 120b to rotate at 1000 RPM, the third fan fan unit 120c is 1400 RPM Rotate to (906).

When the driving mode selected by the user is the third driving mode, the controller 802 performs the third driving mode on each of the first fan driver 816a, the second fan driver 816b, and the third fan driver 816c. By transmitting a control command for the first drift fan unit 120a is turned off, the second drift fan unit 120b rotates at 1000 RPM, and the third drift fan unit 120c rotates at 1400 RPM. (908).

When the driving mode selected by the user is the fourth driving mode, the controller 802 performs the fourth driving mode on each of the first fan driver 816a, the second fan driver 816b, and the third fan driver 816c. By transmitting the control command for the first drift fan unit 120a and the second drift fan unit 120b are turned off, and the third drift fan unit 120c is rotated at 1400 RPM (910).

The operation of the selected operation mode is performed as described above, and when the operation of the operation mode is completed, the operation of the air conditioner is terminated (912).

10 is a view showing the indoor unit of the air conditioner according to another embodiment of the present invention, Figure 11 is a view showing a state in which the front panel of the indoor unit shown in FIG.

As shown in FIGS. 10 and 11, the indoor unit 200 is configured to include a single vortex fan unit 120a, and the lateral fan unit 120a is coupled to the front panel 112 at the front panel 112. One opening 112a is provided. Other configurations and operating principles are the same as the configuration and principle of the indoor unit 100 of the other air conditioner in the embodiment of the present invention described above, and thus detailed description thereof will be omitted.

12 is a view showing the indoor unit of the air conditioner according to another embodiment of the present invention, Figure 13 is a cross-sectional view of the indoor unit shown in FIG.

12 and 13, the diffuser 121 of the swirl fan unit 120 of the indoor unit 300 does not expose the swirl fan 123 through the discharge port 121a, and discharge port 121a. Guide vane 173 for guiding the flow of air discharged through the.

The guide vane 173 is provided between the disc plate 121b and the grill 121c and is spaced apart from the disc plate 121b in the circumferential direction to form a ring shape. The second vane 153b is formed to extend from the outer circumferential surface of the first vane 173a to the inner circumferential surface of the grill 121c.

The first vane 173a may include a radially inner surface opposite to the disc plate 121b and a radially outer surface opposite to the grill 121c.

The inner surface of the first vane 173a has a rear end portion which is located inside the discharge port 121a and is formed to be inclined with respect to the axial direction of the vortex fan 123 in the same manner as the flow path forming tube 124a. It may be configured to be parallel to the axial direction of (123).

The radially inner side surface of the first vane 173a is formed at a rear end thereof with a predetermined angle of inclination with respect to the axial direction of the vortex fan 123, but the front end portion of the first vane 173a is reduced as the angle of inclination decreases toward the front side. It can be formed parallel to the direction.

The cold air discharged inclined with respect to the axial direction of the vortex fan 123 by the vortex fan 123 and the flow path forming part 124a by the first vane 173a formed as described above is part of the first vane 173a. It is directed toward the axis of the drift fan 123 through the inner surface and the outer surface. In addition, the radially outer surface of the first vane 173a may be formed to be convexly curved outward in the radial direction as a whole, so that the cross section of the first vane 173a may be formed in a streamline shape as a whole. Therefore, the cool air discharged in parallel with the axial direction of the swirling fan 123 by the first vane 173a in the discharge port 121a may be led to the discharge port 121a in front of the discharge port 121a to reach a far distance from the discharge port 121a. The cold air discharged inclined with respect to the axial direction of the swirling fan 123 from the discharge port 121a may reach a region corresponding to a wide angle with respect to the discharge port 121a.

The second vanes 173b may be radially formed at the discharge holes 121a, and a plurality of second vanes 173b may be arranged at regular intervals over the entire discharge holes 121a. In addition, the second vane 173b is formed in a curved curve so as to rotate in one direction about the axis of the vortex fan 123 to induce a rotational air stream to be formed in the discharge air stream when the cold air is discharged from the discharge port 121a.

As such, the rotary airflow formed in the discharge airflow may serve to extend the discharge distance so that the cold air can reach a region far from the indoor unit 100.

The diffuser 121 in which the first vane 173a and the second vane 173b are provided is formed of an injection molded product, and the first vane 173a and the second vane 173b are formed in a circular disk plate 121b. It may be integrally formed with the grill 121c formed along the circumference of the discharge port 121a.

According to the illustrated embodiment, an example in which one first vane 173a is provided in the discharge port 121a is illustrated, but this is only one example, and a plurality of first vanes (radially in the discharge port 121a) are provided. 173a) may be provided.

Other configurations and operating principles are the same as the configuration and principle of the indoor unit 100 of the other air conditioner in the embodiment of the present invention described above, and thus detailed description thereof will be omitted.

14 is a view showing the indoor unit of the air conditioner according to another embodiment of the present invention, Figure 15 is a diffuser shape (a) of the indoor unit of the air conditioner according to the prior art and according to another embodiment of the present invention It is a figure which shows the diffuser shape (b) of the indoor unit of an air conditioner. FIG. 16 is an enlarged view of a portion 'B' of FIG. 15, and FIG. 17 is a perspective view of FIG. 16.

As shown in FIGS. 14 to 17, the diffuser 121 of the swirling fan unit 120 of the indoor unit 400 has a circular disk plate 121b and a circular shape coupled to an outer circumferential surface of the disk plate 121b. A grill 121c and a ring-shaped discharge port 121a formed between the disk plate 121b and the grill 121c are included. The diffuser 121 is disposed in front of the current fan 123 so that air passing through the current fan 123 can be discharged to the front of the front panel 112 through the discharge port 121a. The grill 121c may include a wing plate 421d and may adjust the wind direction and the air volume of the air discharged through the discharge port 121a by adjusting the number, shape, or placement angle of the wing plate 421d.

The wing plate 421d is formed in the shape of a spiral wing from the disc plate 121b to the grill 121c, thereby guiding the discharged air blown out from the swirling fan 123 to discharge it to the outside.

The vane plate 421d is configured to travel in a direction extending in the first direction from the disc plate 121b to the grill 121c. The first direction may be various directions including a spiral, a radial lamp, and the like from the disc plate 121b to the grill 121c. However, the first direction may be radial.

The vane plate 421d is curved in a direction opposite to the rotation direction of the swirling fan 123 along the first direction. When the swirling fan 123 rotates clockwise with respect to the view from the front of the diffuser 121, the wing plate 421d extends from the disk plate 121b to the grill 121c in a counterclockwise direction. When the swirling fan 123 rotates in the counterclockwise direction, the wing plate 421d is formed to extend in a clockwise direction from the disc plate 121b to the grill 121c.

As shown in FIG. 15, when the wing plate 35 is formed to extend in a clockwise direction from the disc plate 33 to the grill 34 in the related art, that is, in the same direction as the rotation direction of the swirling fan 123. When curved, the discharged air blown out from the swirling fan 123 is guided by the wing plate 35 to form a diffused air stream rather than a front air stream. On the other hand, in the case of having the same configuration as the present invention, the wing plate 421d blocks the progress of the discharge air spreading in all directions, and guides the deformation to the front airflow. That is, when the z-axis is directed toward the front surface of the diffuser 121, the y-axis is the radial direction toward the center of the diffuser 121, and the tangential direction of the circular shape of the diffuser 121 is the x-axis, the vortex fan 123 Among the discharged air blown out from the air in the x, y-axis direction is provided to be guided to the z-axis by the wing plate (421d).

The shape of the spiral blade of the wing plate 421d may be formed as a rib having a predetermined width. The wing plate 421d also serves to protect the internal configuration such as the vortex fan 123 in the interior of the indoor unit 100 from the outside, but mainly guides the discharge air blown out from the vortex fan 123 to form an air flow. Since the purpose is to form a rib having a predetermined width so that the discharged air can be sufficiently guided.

The wing plate 421d includes a front portion 422 facing the front and a rear portion 424 facing the rear, and the front portion 422 and the rear portion 424 may have different bending angles. The wing plate 421d may be divided into a front portion 422 facing the front side of the front panel and a rear portion 424 facing the rear side with respect to the side center portion. The wing plate 421d extends in the first direction from the disc plate 121b to the grill 121c and is curved in a direction opposite to the rotation direction of the swirling fan 123. The front part 422 and the rear part 424 becomes more effective in forming the front airflow when changing the bending angle.

In such a configuration, when the rear portion 424 is more curved than the front portion 422, it is more preferable in forming the front airflow. Since the rear portion 424 is more curved than the front portion 422, the side surface of the wing plate 421d is closer to the front of the diffuser 121, that is, the parallel to the z-axis toward the front portion 422 from the rear portion 424. It has a shape. Thus, the discharged air blown out from the swirling fan 123 is first guided by the rear portion 424, and is directed to the front of the diffuser 123 by the front portion 422 along the side of the wing plate 421d. Airflow forms.

The grill 121c is formed in an annular shape. As a result, the discharged air blown from the swirling fan 123 is prevented from spreading up, down, left, and right while discharging the front of the front panel 112 through the discharge port 121a, and guides the discharged air. .

It is also possible to adjust the airflow direction and air volume of the air discharged through the discharge port 121a by reducing or increasing the radial width of the discharge port 121a by adjusting the interval between the disk plate 121b and the grille 121c, The diameter of the plate 121b may be adjusted to adjust the direction and amount of air discharged through the discharge port 121a.

18 to 20 show the flow of the discharged air by the diffuser of the indoor unit of the air conditioner according to the prior art and the diffuser of the indoor unit of the air conditioner according to another embodiment of the present invention.

18 to 20, when the diffuser 32 according to the prior art, the rotation direction of the vortex fan 123 and the bending direction of the vane plate 35 is the same as the rotation of the vortex fan 123 Together, the air is discharged up, down, left, and right, and as a result, the airflow is diffused. In contrast, in the case of the diffuser 121 according to the present invention, the rotation direction of the swirling fan 123 and the curved direction of the wing plate 421d are opposite to each other, so that the discharged air blown out from the swirling fan 123 is wing plate 421d. It is not spread by the light, and is directed to the front while passing through the rear part 424 and the front part 42 of the wing plate 421d.

In addition, in the case of the diffuser 32 according to the prior art, since the wing plate 35 is disposed in the same direction as the rotation direction of the drift fan 123, the discharged air is further developed so that the discharge air flows in all directions from the front of the air conditioner. However, in the case of the diffuser 121 according to the present invention, the wing plate 421d is curved in a direction opposite to the rotational direction of the vortex fan 123, so that the discharged air is more developed than the diffused air. The front airflow is formed at the front of the conditioner to allow long-distance blowing.

Other configurations and operating principles are the same as the configuration and principle of the indoor unit 100 of the other air conditioner in the embodiment of the present invention described above, and thus detailed description thereof will be omitted.

100: indoor unit 110: housing
112: front panel 114: rear panel
120: Mixer fan unit 121: Diffuser
122: drive motor 123: swirl fan
124: duct 130: heat exchanger
140: inlet

Claims (47)

A housing including a front panel having at least one opening formed therein and a rear panel coupled to the rear of the front panel;
At least one discharge opening exposed to the front of the front panel through the at least one opening; and
At least one suction port formed in the rear panel at a position corresponding to the at least one discharge port; and
At least one heat exchanger disposed in front of the inlet to absorb heat from the air introduced through the at least one inlet or to transfer heat to the air introduced through the at least one inlet;
At least one crossflow fan rotatably disposed between the heat exchanger and the discharge port and configured to suck air discharged from the heat exchanger and discharge the air through the discharge port;
Wherein the air conditioner comprises an indoor unit. The method of claim 1,
And the discharge port, the swirl fan, the heat exchanger, and the suction port are arranged in a line in the front and rear directions of the housing. The method of claim 1,
At least two or more of the plurality of discharge ports are indoor units of the air conditioner, characterized in that spaced apart in the up, down direction of the indoor unit. The method of claim 1,
An indoor unit of an air conditioner, wherein an angle formed between a direction of air sucked into the crossflow fan and a direction of air discharged through the discharge port is 15 ° or more and 60 ° or less. 3. The method of claim 2,
A diffuser is disposed in front of the vortex fan, and the diffuser includes:
With a circular disk plate,
And a grill coupled to an outer circumferential surface of the disk plate to form the discharge port between the disk plate and the disk plate. 6. The method of claim 5,
A drive motor coupled to the rear surface of the disc plate in a direction in which the rotation shaft thereof faces the suction port,
The four-flow fan,
A hub to which the rotating shaft of the drive motor is coupled;
Indoor unit of the air conditioner, characterized in that it comprises a plurality of wings coupled to the outer peripheral surface of the hub. The method according to claim 6,
The four-flow fan is an indoor unit of the air conditioner, characterized in that the flow path is formed so that the sucked air is discharged inclined with respect to the central axis of the hub. The method of claim 7, wherein
The hub includes an inclined portion, the angle from the starting point of the inclination of the hub to the outer portion of the hub is an indoor unit of the air conditioner, characterized in that 10 to 40 °. 6. The method of claim 5,
The hub of the air conditioner, characterized in that the diameter of the hub is reduced in the direction that the rotation axis of the drive motor. The method according to claim 6,
The outer circumferential surface of the hub is formed to be inclined,
An indoor unit of an air conditioner, wherein an angle formed by a tangential line in contact with an outer circumferential surface of the hub and a virtual straight line passing through a center of a rotation axis of the driving motor is 10 to 40 kW. The method according to claim 6,
An indoor unit of an air conditioner, characterized in that the shortest distance between the wing end of the swirling fan and the front surface of the heat exchanger is 20 mm or more and 50 mm or less. The method according to claim 6,
The indoor unit of the air conditioner is coupled to the rear of the grill, characterized in that it comprises a duct to form a flow path that moves in the process of the air sucked by the crossflow fan is discharged to the discharge port. The method of claim 1,
Indoor air conditioner indoor unit, characterized in that each of the plurality of swirl fan is individually controllable. A housing including a front panel having at least one opening formed therein and a rear panel coupled to the rear of the front panel;
At least one suction port formed on the rear panel;
At least one heat exchanger disposed in front of the inlet;
At least one crossflow fan unit disposed in front of the heat exchanger and having a discharge port exposed through the opening to the front of the front panel;
The four-flow fan unit,
A diffuser forming the discharge port; and
A driving motor coupled to the rear of the diffuser;
And a vortex fan rotatably coupled to the drive motor;
A duct coupled to a rear surface of the diffuser to form a flow path that moves in the process of discharging air sucked by the crossflow fan to the discharge port;
Wherein the air conditioner comprises an indoor unit. 15. The method of claim 14,
And the opening, the swirl fan unit, the heat exchanger, and the suction port are arranged in a line in the front and rear directions of the housing. 15. The method of claim 14,
The plurality of four-flow fan unit indoor unit of the air conditioner, characterized in that spaced apart disposed in the up, down direction of the indoor unit. 15. The method of claim 14,
The side of the duct surrounding the crossflow fan is formed to be inclined,
An indoor unit of an air conditioner, wherein an angle formed by a tangential line in contact with a side surface of the duct and a virtual straight line passing through the center of rotation of the swirling fan meets is 5 mW or more and 15 mW or less. 15. The method of claim 14,
The diffuser,
With a circular disk plate,
And a grill coupled to an outer circumferential surface of the disk plate to form the discharge port between the disk plate and the disk plate. 15. The method of claim 14,
Indoor unit of the air conditioner, characterized in that it comprises a fixing frame for fixing the crossflow fan unit and the heat exchanger in the housing. 15. The method of claim 14,
The four-flow fan,
A hub coupled to the rotating shaft of the drive motor, the outer peripheral surface of which is inclined;
Indoor unit of the air conditioner, characterized in that it comprises a plurality of wings coupled to the outer peripheral surface of the hub. 21. The method of claim 20,
The four-flow fan is an indoor unit of the air conditioner, characterized in that the flow path is formed so that the sucked air is discharged inclined with respect to the central axis of the hub. 22. The method of claim 21,
The hub includes an inclined portion, the angle from the starting point of the inclination of the hub to the outer portion of the hub is an indoor unit of the air conditioner, characterized in that 10 to 40 °. 15. The method of claim 14,
The discharge unit is an indoor unit of the air conditioner, characterized in that formed in a ring (Ring) type. 15. The method of claim 14,
The indoor unit of the air conditioner includes a control unit for generating a control command for independently controlling each of the plurality of vortex fan units in response to the selected operation mode. 25. The method of claim 24,
An indoor unit of an air conditioner, further comprising a fan driver for controlling the motor in response to a control command of the controller. 25. The method of claim 24,
The independent control of the plurality of vortex fan units is an indoor unit of an air conditioner that independently controls on / off of each of the plural vortex fan units. 25. The method of claim 24,
The independent control of the plurality of swirl fan units is an indoor unit of the air conditioner that independently controls the rotation speed of each of the plurality of swirl fan units. 25. The method of claim 24,
The independent control of the plurality of vortex fan units is to turn off some of the plurality of vortex fan units and independently control the rotational speed of the remaining vortex fan units. In the control method of the air conditioner in which an indoor unit is provided with the some vortex fan unit,
Receive a selection of a driving mode;
Generate a control command to perform the selected mode of operation;
And a control method of the air conditioner independently controlling each of the plurality of vortex fan units in response to the control command. 30. The method of claim 29,
The independent control of the plurality of swirling fan units is a control method of the air conditioner to control each of the plurality of swirling fan units independently on / off. 30. The method of claim 29,
The independent control of the plurality of vortex fan units controls the rotation speed of each of the plurality of vortex fan units independently. 30. The method of claim 29,
The independent control of the plurality of vortex fan units, the control method of the air conditioner to turn off a part of the plurality of vortex fan units and to independently control the rotational speed of the remaining vortex fan unit. The method of claim 1,
The indoor unit of the air conditioner, characterized in that the discharge port is provided in a circular shape so that air can be discharged radially. The method of claim 1,
The air outlet is an indoor unit of the air conditioner, characterized in that the opening and closing structure. The method of claim 1,
The intake unit is an indoor unit of the air conditioner, characterized in that located on at least one of the upper side, lower side, left side, right side of the rear panel. The method according to claim 6,
The radius of the disk plate is in the range of -20% to + 20% of R when the distance between the one point extending the outer portion of the hub to the discharge port and the center point of the disk plate is defined as R Indoor unit of air conditioner. The method of claim 1,
The indoor unit of the air conditioner, characterized in that the shortest distance between at least one of the heat exchanger and at least one of the suction ports is 40 mm or more and 60 mm or less. The method of claim 1,
An indoor unit of an air conditioner, characterized in that the shortest distance between one end of the wing of the crossflow fan and the heat exchanger is 20 mm or more and 50 mm or less. The method of claim 1,
Indoor unit of the air conditioner, characterized in that it comprises a guide vane provided in the discharge port. 40. The method of claim 39,
The guide vane,
A first vane formed in a ring shape along the circumferential direction of the discharge port;
Indoor unit of the air conditioner, characterized in that it comprises a second vane provided radially to the discharge port. 41. The method of claim 40,
The indoor unit of the air conditioner, wherein the first vane is streamlined in cross section. 41. The method of claim 40,
The radially inner side surface of the first vane is formed at a rear end thereof with a predetermined angle of inclination with respect to the axial direction of the vortex fan, and the front end thereof is formed parallel to the axial direction of the vortex fan as the angle of inclination decreases toward the front. Unit of air conditioner becoming. 41. The method of claim 40,
An indoor unit of the air conditioner, wherein the radially outer surface of the first vane is formed to be convexly curved radially outwardly. 6. The method of claim 5,
At least one wing plate extending in a first direction from the disk plate to the grill and guiding air blowing from the swirling fan,
The vane of the indoor unit of the air conditioner, characterized in that curved in the direction opposite to the rotation direction of the swirl fan along the first direction. 45. The method of claim 44,
Indoor wing of the air conditioner, characterized in that the wing plate is formed of a spiral rib. 45. The method of claim 44,
The wing plate includes a front portion facing the front and a rear portion facing the rear,
The indoor unit of the air conditioner, wherein the front portion and the rear portion is different in the bending angle. 47. The method of claim 46,
The rear unit is an indoor unit of the air conditioner, characterized in that more curved than the front portion.

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