KR20140092952A - Air conditioner - Google Patents

Abstract

An air conditioner of the present invention includes a main body which includes air inlets and a discharge guide having an internal space inside; an inner guide which is located on the inner side of a discharge guide and has the discharge guide and an air discharge path; and an inner guide moving device which moves the inner guide. The present invention can discharge the air in various directions in comparison with a case that the direction of wind is controlled by a vertical wind direction adjustment member or a horizontal wind direction adjustment member.

Description

Air conditioner

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly to an air conditioner having a discharge guide in which air is discharged and guided.

Generally, the air conditioner is a device that sucks indoor air, changes the temperature, humidity, and cleanliness, and then discharges it back into the room to air-condition the room.

The air conditioner can be classified into a cooler that cools the room, a radiator that heats the room, a dehumidifier that dehumidifies the room, a humidifier that humidifies the room, and a corrector that cleans the room.

The air conditioner has an air inlet and an air outlet formed in the main body, an air conditioning unit for changing the air in the main body, and an air blowing unit for sucking indoor air through the air inlet and discharging the air after passing through the air conditioning unit .

 The air conditioner can be provided with a plate-shaped wind direction adjusting member for adjusting the wind direction on the air outlet. The upper and lower wind direction adjusting members, which are horizontally disposed on the air outlet, can be rotated around the horizontal axis to adjust the vertical wind direction. The vertical wind direction adjusting member can be rotated around the vertical axis to adjust the left and right wind direction.

The air conditioner according to the related art is provided with a plurality of wind direction adjusting members each having a different arrangement direction and a different rotating direction for adjusting the wind direction in at least two directions by rotating the wind direction adjusting member in a plate- There is a problem.

According to an aspect of the present invention, there is provided an air supply apparatus comprising: a main body having an air inlet formed therein and having a discharge guide formed therein; An inner guide positioned inside the discharge guide and forming the discharge guide and the air discharge passage; And an inner guide moving mechanism for moving the inner guide.

 The inner guide moving mechanism can move the inner guide so that the shape of the air discharge passage is varied.

The inner guide moving mechanism can move the inner guide along the circumferential surface of the discharge guide.

The inner guide moving mechanism may move the inner guide so that the sectional shape of the air discharge passage changes from a closed loop shape to a crescent shape and then changes to a closed loop shape.

The inner guide moving mechanism is configured such that a part of the outer circumferential surface of the inner guide is brought close to the inner circumferential surface of the discharge guide and a part of the inner guide moving away from the inner circumferential surface of the discharge guide is distant from the inner circumferential surface of the discharge guide The inner guide can be moved.

 The inner guide moving mechanism can lift the inner guide and then move in a curved trajectory along the circumferential surface of the discharge guide.

The inner guide moving mechanism can move the inner guide in a curved trajectory and then lower it.

The inner guide moving mechanism may lower the inner guide to the center of the inner side of the discharge guide.

The inner guide moving mechanism may stop the inner guide at the inner center position of the discharge guide after moving the inner guide at the start of operation of the air conditioner.

The inner guide moving mechanism includes a fixed case fixed to the discharge guide; A motor installed in the fixed case; An inner guide connector connected to the inner guide; A power transmitting member for transmitting the driving force of the motor to the inner guide connector; And a moving guide installed in the fixed case and guiding the inner guide connector when the motor is driven.

The power transmitting member may include a pinion provided on a rotating shaft of the motor, and a rack fitted to the pinion and provided in the inner guide connector.

The inner guide connector may be formed with a connection portion connected to the inner guide.

The moving guide may be formed with a connecting through hole through which the connecting portion passes.

The inner guide connector may be formed with a protrusion guided by the moving guide.

The moving guide may be formed with a guide portion through which the protrusion is guided.

The guide portion may include a straight portion guided by the protrusion, and a curved portion connected to the straight portion and guided by the protrusion.

The curved portion may be connected to an upper portion of the straight portion.

The rectilinear portion may include a vertical portion for guiding the protruding portion up and down and the curved portion connected to the upper portion.

The straight portion may further include an inclined portion connecting the lower portion of the elevation portion and the curved portion.

The guide portion may have a guide groove formed in a surface facing the fixed case.

The present invention is capable of forming various discharge directions more than the case of adjusting the wind direction by rotating the horizontal wind direction adjusting member or the vertical wind direction adjusting member, and has a simple structure.

Further, there is an advantage that a horizontal wind direction adjusting member or a vertical wind direction adjusting member can form a concentrated wind direction in a forward oblique direction, which is difficult to adjust the wind direction, with a simple structure and control.

 In addition, there is an advantage that a more stereoscopic airflow can be formed because the air in the inner guide is uniformly discharged in front of the discharge guide and then concentratedly discharged in a specific direction.

Further, it is possible to determine the wind direction in a plurality of directions with one inner guide, and the number of components can be minimized.

 Further, it is possible to confirm that the air conditioner is in operation even at a remote place when moving the inner guide, and there is an advantage that the horizontal wind direction adjusting member or the vertical wind direction adjusting member can be kept cleaner than when rotated.

1 is a perspective view of an embodiment of an air conditioner according to the present invention,
2 is a front view of an embodiment of an air conditioner according to the present invention,
3 is a sectional view of one embodiment of an air conditioner according to the present invention,
4 is an enlarged cross-sectional view of part A shown in Fig. 3,
5 is an exploded perspective view of the inner guide and the inner guide moving mechanism according to the present invention,
Fig. 6 is a rear view showing the inside of the inner guide moving mechanism when the inner guide shown in Figs. 1 to 4 is moved,
FIG. 7 is a front view showing sequentially the process of moving the inner guide shown in FIG. 3 as time elapses.

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

FIG. 1 is a perspective view of an air conditioner according to an embodiment of the present invention, FIG. 2 is a front view of an air conditioner according to the present invention, and FIG. 3 is a sectional view of an air conditioner according to an embodiment of the present invention.

The air conditioner may be provided with an air inlet (4) in the main body (2) and a discharge guide (6). The air conditioner includes an inner guide (8) located inside the discharge guide (6) and forming the discharge guide (6) and the air discharge passage (P). The air conditioner includes an inner guide moving mechanism (10) for moving the inner guide (8). The inner guide moving mechanism 10 can move the inner guide 8 so that the shape of the air discharge passage P is variable.

The main body 2 may include a case 12 forming an outer appearance of the air conditioner. The case 12 may have an air inlet 4 formed on the back surface thereof. The main body 2 may include a heat exchanger 16 arranged inside the case 12 to heat-exchange the air sucked into the air inlet 4 with the refrigerant. The main body 2 may include at least one blowing unit 18 (20).

  The case 12 may be provided with an air outlet 24 through which air is discharged into the room. The air discharge port 24 may be formed at a position spaced apart from the discharge guide 6. The air exchanged in the heat exchanger 16 is discharged through the discharge guide 6 and / . At least one air outlet 24 may be formed in the case 12. The air outlet 24 may be formed on the side surface of the case 12. [ The air discharge port 24 can discharge air from the at least one side of the left and right sides of the case 12 to the side or the front side. The main body 2 may include a wind direction adjusting mechanism for adjusting the wind direction of the air discharged to the air outlet 24. The wind direction adjusting mechanism may be installed in the case 12. The wind direction adjusting mechanism may include a wind direction adjusting member 26 for guiding air and a wind direction adjusting motor (not shown) for generating a driving force for operating the wind direction adjusting member 26. The wind direction adjusting member 26 may be installed to close the air outlet 24 to the case 12. [ The wind direction adjusting motor may be installed in the case 12 to rotate the wind direction adjusting member 26.

The heat exchanger 16 can heat-exchange the air sucked into the air inlet 4 with the refrigerant. The heat exchanger 16 may be installed between the air inlet 4 and the blowers 18, 20 in the air flow direction.

The air blowing units 18 and 20 may be provided in the case 12 in a single or plural number. When a plurality of blowing units 18 and 20 are installed, two or three blowing units 18 and 20 may be installed. The air blowing units 18 and 20 suck indoor air through the air inlet 4 and pass through the heat exchanger 16 and then blow to the outlet unit 8 or blow out air to the outlet unit 8 and the air outlet 24 And an upper air blowing unit 18 for blowing air. The main body 2 may include an orifice 35 for guiding the air that has passed through the heat exchanger 16 to the upper air blowing unit 18 and the lower air blowing unit 20. The orifice (35) may be located in front of the heat exchanger (16). The orifice (35) may be provided with a first suction hole (35A) for guiding air sucked into the upper blower unit (18). The orifice (35) may be provided with a second suction hole (35B) for guiding air sucked into the lower air blowing unit (20). The upper blowing unit 18 may include an upper blowing fan 36 positioned in front of the upper portion of the heat exchanger 16 and an upper blowing motor 37 rotating the upper blowing fan 36. The air blowing units 18 and 20 may include a lower air blowing unit 20 that sucks indoor air into the air inlet 4 and passes through the heat exchanger 16 and then blows air to the air outlet 24. The lower air blowing unit 20 may include a lower air blowing fan 38 positioned at the lower front of the heat exchanger 16 and a lower air blowing motor 39 rotating the lower air blowing fan 38.

The case 12 may include a base 41, a suction panel 42, and a front panel 43. The suction panel 42 may be installed on the upper side of the base 41. The suction panel 42 may be provided with an air inlet 4. The suction panel 42 can be opened on the upper surface. The front panel 43 may be positioned in front of the suction panel 42. [ The front panel 43 may have an air outlet 24 formed in at least one of a left side plate and a right side plate. The upper surface of the front panel 43 can be opened.

The case 12 may include an ejection body 44 for guiding the air blown to the inside upper portion of the case 12. [ The discharge body 44 may be installed above the suction panel 42 and the front panel 42. The air blown to the upper side of at least one of the front panel 43 and the suction panel 42 can be introduced into the discharge body 44. The discharge body 44 may have an opening at the bottom so that air can be introduced. The discharge body 44 may be formed in a shape in which a left side, an upper side and a right side are clogged so as to surround a part of the outer circumferential surface of the discharge guide 6. [ The discharge body 44 may have a closed-back shape. The case 12 may include a front cover 45 and a side cover 46. The front cover 45 may cover the front surface of the front panel 43 and the front surface of the base 41 and a part of the discharge body 44 together. The front cover 45 may have an opening 47 larger than the front end of the discharge guide 6. The side cover 46 may be disposed so as to cover a part of the side surface of the base 41 and the side surface of the front panel 43 and the side surface of the discharge body 44. The side cover 46 may cover the side of the front panel 43 other than the air outlet 24.

 The discharge guide 6 is disposed inside the case 12 so that the air exchanged with the heat exchanger 16 can be guided to the outside of the case 12. [ The discharge guide 6 may be installed inside the discharge body 44. The discharge guide 6 can guide the air that has flowed to the discharge body 44 toward the front of the discharge guide 6. [ The discharge guide 6 may have a front opening. The discharge guide 6 may include a cylinder 52 in which air is guided, a space may be formed in the cylinder 52, and a space may be formed to extend toward the front. The discharge guide 6 may include a moving mechanism mounting portion 58 on which the inner guide moving mechanism 10 is mounted. At least one of the cylinder 52 and the moving mechanism mounting portion 58 may be mounted on the case 12 with a fastening member such as a screw. A fastening portion through which a fastening member such as a screw passes may be formed on the outer circumference of the tubular body 52 and a fastening portion to fasten the fastening portion of the tubular body 52 with a fastening member such as a screw may be formed on the discharge body 44 .

The inner guide 8 may be provided so that the outer circumferential surface 9 of the front surface, the back surface and the outer circumferential surface is spaced apart from the inner circumferential surface 7 of the discharge guide 6. The inner circumferential surface 9 of the inner guide 8 can form the inner circumferential surface 7 of the discharge guide 6 and the air discharge passage P. [ The outer circumferential surface 9 of the inner guide 8 can be the inner guide surface of the air discharge passage P and the inner circumferential surface 7 of the discharge guide 6 can be the inner guide surface of the air discharge passage P, It can be a face.

The inner guide moving mechanism 10 may be provided so that the outer circumferential surface 11 of the front surface, the back surface and the outer circumferential surface is spaced apart from the inner circumferential surface 7 of the discharge guide 6. [ The inner circumferential surface 11 of the inner guide moving mechanism 10 can form the inner circumferential surface 7 of the discharge guide 6 and the air discharge passage P. [ The outer peripheral surface 11 of the inner guide moving mechanism 10 can be the inner guide surface of the air discharge passage P. [

The air introduced into the discharge guide 8 is first guided to the outer peripheral surface 11 of the inner guide moving mechanism 10 and then guided to the outer peripheral surface 9 of the inner guide 8, The outer circumferential surface 11 of the moving mechanism 10 and the outer circumferential surface 9 of the inner guide 8 can constitute the inner guide surface of the air discharge passage P. [

5 is an exploded perspective view of the inner guide and the inner guide moving mechanism according to the present invention, and Fig. 6 is an exploded perspective view of the inner guide shown in Figs. 1 to 4 when the inner guide is moved Fig. 7 is a front view of the inner guide shown in Fig. 3, which is sequentially moved with the elapse of time. Fig.

The tubular body (52) may have a trumpet portion (51) having a larger size toward the front.

The cylindrical body 52 may have a front opening 53 formed in its front surface and a rear opening 54 formed in its rear surface. The end portion (55) of the tubular body (52) can be formed larger than the rear end (56). The tubular body 52 may be formed such that the front opening 53 is larger than the rear opening 54. [ The trunk section 51 may be formed between the distal end 55 and the rear end 56 of the tubular body 52.

The moving mechanism mounting portion 58 can be formed inside the cylindrical body 52 and can be positioned outside the cylindrical body 52. The moving mechanism mounting portion 58 may be formed on the rear portion of the cylindrical body 52. The moving mechanism mounting portion 58 may include a mounting portion 59 formed to be smaller in size than the space of the cylinder 52. The mounting portion 59 may be formed of a closed loop plate or a circular plate. The inner guide moving mechanism 10 can be mounted on the mounting portion 59. The moving mechanism mounting portion 58 may include at least one supporting leg 60 connecting the cylindrical body 52 and the mounting portion 59. The mounting portion 59 can be positioned behind the space of the cylinder 52 and at least one support leg 60 can connect the cylinder 52 and the mounting portion 59.

The inner guide 8 may have a trumpet portion 61 having a larger size toward the front. The trumpet portion 61 of the inner guide 8 may be smaller than the trumpet portion 51 of the discharge guide 6. [ The trumpet portion 61 of the inner guide 8 can be seen to face the trumpet portion 51 of the discharge guide 6. [ The size of the front surface of the inner guide 8 may be larger than the size of the back surface opening 54 of the cylindrical body 52.

The inner guide 8 may include a peripheral portion 64, a thick plate portion 65, and a front plate portion 66. The peripheral portion 64 of the inner guide 8 can be seen to face the cylinder 52 of the discharge guide 6. [ The peripheral portion 64 of the inner guide 8 is spaced apart from the cylindrical body 52 of the discharge guide 6 and between the peripheral portion 64 of the inner guide 8 and the cylindrical body 52 of the discharge guide 6 The air discharge passage P can be formed. The thick plate portion 65 of the inner guide 8 can face the inner guide moving mechanism 10. The front plate portion 66 of the inner guide 8 can be directed forward of the air conditioner. The inner guide 8 may include a display module 67 for displaying information. The display module 67 is installed between the front plate portion 66 and the thick plate portion 65 and can irradiate light for displaying information forward. The inner guide 8 may include an illumination module 68 that forms an illumination on the air discharge passage P. [ The lighting module 68 may be located inside the perimeter 64 to illuminate the perimeter 64 with light. The illumination module 68 can emit light in a radial fashion and the light emitted radially in the illumination module 68 can pass through the periphery 64 of the inner guide 8. The light having passed through the peripheral portion 64 of the inner guide 8 can illuminate the air discharge passage P while illuminating the inner peripheral surface 7 of the discharge guide 6. [ The inner guide 8 can be formed integrally with the thick plate portion 65 and the peripheral portion 64 and the front plate portion 66 can be formed as a front plate separately formed from the peripheral portion 64. The perimeter 64 may function as a diffusion plate for diffusing the light irradiated by the illumination module 68. The peripheral portion 64 may be formed to be transparent or translucent, and a light diffusing portion for diffusing the light emitted from the lighting module 68 may be formed on the inner circumferential surface or the outer circumferential surface thereof. The front plate portion 66 can function as a display window on which information of the display module 67 is displayed. The inner guide 8 may be provided with a display module mounting plate 69 on which the display module 68 is mounted and the display module mounting plate 69 is disposed between the front plate portion 66 and the rear plate portion 65 Can be installed. The display module mounting plate 69 may be formed with a light transmission hole 70 through which the light irradiated from the display module 67 is transmitted. The display module mounting plate 69 can function as a shielding plate for preventing the light irradiated from the lighting module 68 from being irradiated to the front plate portion 66 and can be installed in front of the lighting module 68 . The display module mounting plate 69 may be formed with a fastening portion 71 to be fastened by a fastening member such as a screw to the thick plate portion 65.

The inner guide moving mechanism 10 can move the inner guide 8 along the inner circumferential surface 7 of the discharge guide 6 in a curved trajectory. Here, the curved trajectory may be a circular trajectory or an arc trajectory close to a circle. The inner guide moving mechanism 10 can move the inner guide 8 so that the sectional shape of the air discharge passage P changes from the closed loop shape to the crescent shape and then changes to the closed loop shape.

The inner guide moving mechanism 10 is configured such that a portion 9 'of the outer circumferential surface 9 of the inner guide 8 comes close to the inner circumferential surface 7 of the discharge guide 6, The inner guide 8 can be moved away from the inner circumferential surface 7 of the discharge guide 6 while the opposite portion 9 "of the portion 9 ' 10 can lift the inner guide 8 and move it along a circumferential surface 7 in the discharge guide 6 to a curved trajectory O. The inner guide moving mechanism 10 includes an inner guide 8, The inner guide moving mechanism 10 can lower the inner guide 8 to the inner center of the discharge guide 6. The inner guide moving mechanism 10 Can stop the inner guide 8 at the start of operation of the air conditioner and then stop at the inner central position of the discharge guide 6. [

The inner guide moving mechanism (10) includes a fixed case (100) fixed to the discharge guide (6); A motor 110 installed in the stationary case 100; An inner guide connector (120) connected to the inner guide (8); A power transmitting member 130 (132) for transmitting the driving force of the motor 110 to the inner guide connector 120; And a moving guide 140 installed in the fixed case 100 and guiding the inner guide connector 120 when the motor 110 is driven.

 The stationary case 100 may include a thick plate portion 102 and a circumferential portion 104. The rear plate portion 102 of the fixed case 100 can form the back surface of the inner guide moving mechanism 10. [ The thick plate portion 102 of the stationary case 100 can face the moving mechanism mounting portion 58 and can be installed in the moving mechanism mounting portion 58 and in particular the mounting portion 59, (59). The peripheral portion 104 of the fixed case 100 can form the peripheral surface of the inner guide moving mechanism 10. [ The thick plate portion 102 of the stationary case 100 may be provided with a thick plate fastening boss 103 to which the moving guide 140 can be fastened by a fastening member such as a screw.

The circumferential portion 104 of the fixed case 100 can be opposed to the cylindrical body 52 of the discharge guide 6 and can be spaced apart from the cylindrical body 52 of the discharge guide 6, The cylinder 52 and the air discharge passage P can be formed. A motor accommodating space in which the motor 110 can be accommodated can be formed inside the peripheral portion 104 of the fixed case 100. The circumferential portion 104 of the stationary case 100 may be formed with a trumpet portion that gradually increases toward the front. The peripheral portion 104 of the stationary case 100 may be provided with a circumferential portion fastening boss 105 which can be fastened by a fastening member such as a screw.

The stationary case 100 may be provided with a motor fastening boss 106 protruding from the fastening case 100 to fasten the motor 110 with a fastening member such as a screw.

 The motor 110 may be installed in the stationary case 100 such that the rotary shaft 112 protrudes forward. The motor 110 can constitute one driving set together with the inner guide connector 120 and the power transmitting members 130 and 132 and the inner guide moving mechanism 10 can be constituted by the motor 110 and the inner guide connector 120 and the power transmitting member 130 (132).

 The inner guide connector 120 can move the inner guide 8 while being guided by the moving guide 140 when the motor 110 is driven.

The inner guide connector 120 may have a connection portion 121 connected to the inner guide 8. The connection portion 121 may be formed to protrude forward from the front surface of the inner guide connector 120. The connection portion 121 may be located at the front center of the inner guide connector 120. The connection portion 121 can pass through a support shaft 65a formed on the thick plate portion 65 of the inner guide 8. [ The support shaft 65a may be formed in a hollow cylinder shape. The connection part 121 can be fastened to the connection part holder 122 without any removal from the support shaft 65a. The connection part 121 may have a connection part holder fixing hole 121a to which the connection part holder 122 is fixed. The connection part holder 122 is screwed to the connection part 121 from the inner side of the inner guide 8 so that the connection part 121 is not removed and the connection part 121 supports the support shaft 65a, 8). The position of the connection part 121 can be changed when the motor 110 is driven and the position of the inner guide 8 can be changed according to the position of the connection part 121. [

The inner guide connector 120 may have a protrusion 123 guided by the moving guide 140. The protrusion 123 may protrude forward from the front surface of the inner guide connector 120. The protrusion 123 may be located apart from the connection portion 121 and the protrusion 123 may be located outside the front center of the inner guide connector 120.

6, the inner guide connector 120 may be formed with a power transmitting member receiving portion 124 in which the power transmitting member 130 (132) is located. The power transmitting member receiving portion 124 may be formed long in the longitudinal direction of the inner guide connector 120 and at least one of the power transmitting members 130 132 may be accommodated. The power transmitting member receiving portion 124 may be formed by a plate member that is open at the rear side and has four closed upper, lower, left, and right side surfaces. And all of the power transmitting member 130 (132) can be positioned inside the power transmitting member receiving portion 124. The power transmitting member receiving portion 124 has one of the upper, lower, left, The left and right sides of the power transmission member 130 (132) may be open and the three sides of the upper, lower, left, and right side surfaces may be clogged and any one of the power transmission members 130 (132) may be located inside the power transmission member accommodation portion 124, The other one of the members 130 (132) closes the open side of the power transmitting member receiving portion 124 This is possible.

The power transmitting members 130 and 132 may include a pinion 130 provided on the rotating shaft 112 of the motor 110 and a rack 132 coupled to the pinion 130 and provided in the inner guide connector 120 have.

 The pinion 130 can transmit the driving force of the motor 110 to the rack 132. [ The pinion 130 can be located in the space S formed by the power transmitting member receiving portion 124 and the rack 132. [

The rack 132 may be long in the longitudinal direction of the inner guide connector 120. The rack 132 can be integrally formed with the inner guide connector 120 and can be inserted into the inner guide connector 120 manufactured separately from the inner guide connector 120. The rack 132 can be raised and lowered when the pinion 130 is rotated. When the rack 132 reaches a position where the pinion 130 is not lifted further, the pinion 130 is rotated with the pinion 130 Can be rotated.

The moving guide 140 can form the front surface of the inner guide moving mechanism 10. [ The moving guide 140 may be provided so as to face the inner guide 8. The mating guide 140 may be installed to cover the front surface of the stationary case 100. The moving guide 140 can be fastened to the stationary case 100 with a fastening member such as a screw. The moving guide 140 may be formed with a connecting through hole 141 through which the connecting portion 121 passes. The connecting portion through hole 141 may be formed to be larger than the curved trajectory of the connecting portion 121.

 The moving guide 140 may be formed with a guide portion 142 through which the protrusion 123 formed in the inner guide connector 120 is guided. The guide portion 142 may be formed with a guide recess portion on the surface of the front surface and the rear surface facing the fixed case 100. [ The moving guide 140 may be formed in a plate shape as a whole, and the guide portion 142 may protrude forwardly.

 The guide portion 142 may include a straight portion 143 to which the protrusion 123 is guided and a curved portion 144 connected to the straight portion 143 and to which the protrusion 123 is guided. The protrusion 123 is linearly guided at the straight portion 143 and then enters the curved portion 144 and can be guided along the curved portion 144 and guided along the curved portion 144 and then guided to the straight portion 143 And can be guided to the rectilinear section 143.

The inner guide 8 can be linearly moved in a large width from the inside of the discharge guide 6 as the length of the straight portion 143 becomes longer.

 The curved portion 144 can be formed in a closed loop cross-sectional shape, and can be formed in a loop cross-sectional shape connected by a straight line portion 143. As the radius of the curved portion 144 is larger, the inner guide 8 can be moved in a larger curved trajectory.

The rectilinear section 143 may be elongated in the up-and-down direction or elongated in the left-right direction or elongated in the oblique direction between the up-down direction and the left-right direction.

The rectilinear section 143 may include a vertical section 145 for guiding the protrusion 123 up and down and a curved section 144 connected to the upper part. The linear portion 143 may further include an inclined portion 146 connecting the lower portion of the vertical portion 145 and the curved portion 144. The protrusion 123 may be guided along the vertical portion 145 and then enter the curved portion 144 and be guided in the curved portion 144 in a curved trajectory. The protruding portion 123 that has been accommodated in the curved trajectory enters the inclined portion 146 from the curved portion 144 and can be guided to the inclined portion 146. After being guided by the inclined portion 145, As shown in FIG.

  The guide portion 142 may include the straight portion 143 not including the inclined portion 146 and at least one of the vertical portion 145 and the horizontal portion (not shown) and the curved portion 144. The projecting portion 123 which is guided along the vertical portion 145 can be guided along the curved portion 144 in a circular path and then guided along the vertical portion 145 again. The projecting protrusion 123 which is guided along the horizontal portion can be guided in a circular path along the curved portion 144 and then horizontally moved in the opposite direction along the horizontal portion 145 again.

 Hereinafter, the operation of the present invention will be described.

First, when a user or the like inputs an operation command to an input unit (not shown) such as a remote control unit or a control panel installed in the air conditioner, the air conditioner can be controlled according to the inputted operation command.

The air conditioner may have an operation mode such as a cooling mode, a dehumidifying mode, a power saving mode, an air cleaning mode, and a rapid cooling mode. When the user inputs one of these, the air conditioner operates .

The air conditioner can have a general discharge mode in which air is uniformly discharged in the forward direction of the air conditioner, a concentrated discharge mode in which air is concentratedly discharged in a specific direction, and a mixed discharge mode in which a general discharge mode and a centralized discharge mode are mixed have.

The concentrated discharge mode may have a fixed fixed-direction air-discharge mode in which the air-direction is concentratedly discharged while the air-direction is fixed, and a variable air-concentration mode in which the air-direction is continuously changed.

When the air conditioner is in operation, the driving of the air blowing units 18 and 20 can be driven, and the air in the room can be sucked into the air inlet 2 and pass through the heat exchanger 18. The air having passed through the heat exchanger 18 can be blown to at least one of the discharge guide 6 and the air discharge opening 24 by the air blowing units 18 and 20. The air discharged to the air discharge port 24 can be discharged in the lateral direction in the case 12 or in the front lateral direction of the case 12. [ The air blown to the discharge guide 6 first passes between the discharge guide 6 and the inner guide moving mechanism 10 and the discharge guide 6 and then flows between the inner guide 8 and the discharge guide 6, Can be discharged in the forward direction of the air discharge passage (P) while being guided by the outer peripheral surface (9) of the inner guide (8) and the inner peripheral surface (7) of the discharge guide (6).

The air conditioner can be operated in a state in which the inner guide 8 is positioned at the center of the inner side of the discharge guide 10, as shown in Fig. 7 (A), in the general discharge mode. At this time, the outer periphery of the inner guide 8 may be spaced apart from the inner circumferential surface of the discharge guide 10 by the same distance L1, and the air discharge passage P may have a closed-loop shape as a whole. The air in the room can be uniformly discharged forward through the air discharge passage P whose cross section is in the form of a closed loop.

As shown in Figs. 7 (B) and 7 (C) and 7 (D) and 7 (E) in Fig. 7, the air conditioner has a portion 9 of the inner guide 8 Of the inner guide 8 is close to the ejection guide 10 and the portion 9 "of the portion 8 ' adjacent to the ejection guide 10 is away from the ejection guide 10. At this time, Can be spaced apart by a distance (L2) farther than in the normal discharge mode, and the air discharge passage (P) can have a generally crescent- Lt; / RTI > The air in the room can be concentratedly discharged through the air discharge passage P having a crescent-shaped cross section.

When the upper portion of the inner guide 8 is close to the discharge guide 6 and the lower portion of the inner guide 8 is distant from the discharge guide 6 as shown in Fig. 7 (B), the front left, front lower, and front right But can be concentratedly ejected in the downward direction.

When the left side portion of the inner guide 8 is close to the discharge guide 6 and the right side portion of the inner guide 8 is distant from the discharge guide 6 as shown in FIG. 7 (C), air flows in the front upper side, the front right side, And can be concentratedly ejected in the front right direction.

When the lower portion of the inner guide 8 is close to the discharge guide 6 and the upper portion of the inner guide 8 is distant from the discharge guide 6 as shown in FIG. 7 (D), the front left, front upper, It can be mainly ejected and concentratedly ejected toward the front upper direction.

When the right side portion of the inner guide 8 is close to the discharge guide 6 and the left side portion of the inner guide 8 is distant from the discharge guide 6 as shown in FIG. 7 (E), air flows in the front upper side, the front left side and the front lower side And can be concentratedly ejected toward the front left direction.

 When the air conditioner is in the fixed-air-concentration fixed-discharge mode, the inner guide 8 is moved to a specified position in the discharge guide 6 and fixed (fixed) .

The inner guide 8 can be continuously moved inside the discharge guide 6 without fixing the inner guide 8 to a specific position inside the discharge guide 6 when the air conditioner is in the variable air concentration variable discharge mode.

The inner guide 8 is moved to the inner left side, the inner lower side, the inner right side and the inner upper side while drawing a curved trajectory in the clockwise direction from the upper side of the discharge guide 6, The inner left side, the inner left side, and the inner upper side while drawing a curved trajectory in the counterclockwise direction from the upper side of FIG. In the variable-air-fuel ratio mode during the centralized discharge mode, the centralized discharge direction of the air can be continuously changed in the clockwise direction or counterclockwise direction.

In the mixed ejection mode, the air conditioner can sequentially perform the general ejection mode, the variable-direction variable concentration ejection mode, and the general ejection mode, while the air is ejected through the air discharge passage (P) The direction of concentrated air is continuously changed in the clockwise direction or the counterclockwise direction while the air-conditioned variable centralized discharge mode is continuously performed, and then the air is discharged through the air discharge passage P And can be evenly discharged forward.

 Hereinafter, the details will be described with reference to FIGS. 6 and 7. FIG.

6 (A), when the pinion 130 is engaged with the upper portion of the rack 132, the inner guide 8, as shown in Fig. 7 (A) It is possible to maintain a constant gap L1 with the inner circumferential surface of the discharge guide 6.

When the motor 110 is driven in a state where the outer circumferential surface of the inner guide 8 maintains a constant distance L1 from the inner circumferential surface of the discharge guide 6, the pinion 130 can be rotated, and the protrusions 123 Can be guided by the vertical portion 145 and the rack 132 can be lifted together with the inner guide connector 120. [ The inner guide 8 can be raised by the inner guide connector 120 when the inner guide connector 120 is lifted and the inner guide 8 can be lifted up by the upper guide And the lower part can be distant from the inner circumferential surface of the discharge guide 6. The shape of the air discharge passage P can be deformed into the shape of a crescent moon with the upper part opened, The air discharged to the air discharge passage (P) can be discharged through the crescent air discharge passage (P) opened at the top. On the other hand, if the air conditioner is in the sub-centralized discharge mode, the motor 110 can be stopped.

The protrusion 123 may enter the curved portion 144 at the vertical portion 145 and be guided by the curved portion 144 when the motor 110 continues to rotate the pinion 130 without stopping, 132 can be rotated together with the inner guide connector 120 at the center of rotation of the pinion 130. The inner guide guide 120 is rotated substantially horizontally around the pinion 130 as shown in Fig. 6C and the inner guide 8 is rotated about the pinion 130 as shown in Fig. The left side portion is close to the inner circumferential surface of the discharge guide 6 and the right side portion can be distant from the inner circumferential surface of the discharge guide 6. The shape of the air discharge passage P is deformed into a crescent- And the air can be concentratedly discharged to the front right side through the crescent air discharge passage P having the left side portion opened. On the other hand, if the air conditioner is in the right centralized discharge mode, the motor 110 can be stopped.

The protrusion 123 can continue to be guided along the curved portion 144 and the rack 132 can be guided by the pinion 130 as the center of rotation, Can be continuously rotated together with the connector 120. 6 (D), the inner guide 8 is rotatably supported by the pinion 130 as shown in FIG. 7 (D) The lower portion can be close to the inner circumferential surface of the discharge guide 6 and the upper portion can be distant from the inner circumferential surface of the discharge guide 6. The shape of the air discharge passage P can be changed into a crescent- And the air can be concentratedly ejected upward in the forward direction through the crescent air discharge passage P with the open top. On the other hand, if the air conditioner is in the upper concentrated discharge mode, the motor 110 can be stopped.

The protrusion 123 can continue to be guided along the curved portion 144 and the rack 132 can be guided by the pinion 130 as the center of rotation, And can be rotated together with the connector 120. The inner guide guide 120 is rotated approximately horizontally about the pinion 130 as shown in Figure 6E and the inner guide 8 is rotated about the pinion 130 as shown in Figure 7E, The left side can be distant from the inner circumferential surface of the discharge guide 6 and the shape of the air discharge passage P can be deformed into the shape of a crescent moon And the air can be concentratedly discharged to the front left side through the crescent air discharge passage P having the right side opened. On the other hand, if the air conditioner is in the left centralized ejection mode, the motor 110 can be stopped.

 The protrusion 123 can enter the inclined portion 146 from the curved portion 144 and the motor 110 can move the pinion 130 in a predetermined direction Time can be reversed. For example, if the rotation direction when the projection 123 is guided along the curved portion 144 is clockwise, the rotation direction when the projection 123 is guided along the slope portion 146 is a counterclockwise direction . The protrusion 123 can be guided obliquely along the inclined portion 146 so as to enter the lower portion of the vertical portion 145 when the pinion 130 rotates counterclockwise. 7, the inner guide 8 is moved toward the inner center of the discharge guide 6 while the protrusion 123 is guided obliquely along the inclined portion 146, The inner guide 8 can be positioned at the inner center of the discharge guide 6 as shown in Fig. 7 (A). The motor 110 can rotate the pinion 130 in the reverse direction of the reverse rotation after rotating the pinion 130 for a predetermined time. The rotation direction after the protrusion 123 reaches the lower portion of the vertical portion 145 when the rotation direction when the protrusion 123 is guided along the slope portion 146 is counterclockwise, Direction. When the pinion 130 is rotated as described above, the rack 132 can be rotated together with the inner guide connector 120 at the center of rotation of the pinion 130. The inner guide guide 120 is rotated substantially vertically with the pinion 130 as the center of rotation as shown in Figure 6 (A), and the inner guide 8, as shown in Figure 7 (A) It is possible to maintain a constant gap L1 with the inner circumferential surface of the discharge guide 6.

While the inner guide 8 is moving as described above, the concentrated discharge direction of air can be continuously changed.

  The air conditioner can be continuously operated in a state in which the inner guide 8 is once moved only once after the inner guide 8 has been moved and the inner guide 8 is fixed to the center of the inner side of the discharge guide 6, It is possible to continue the operation while repeating the movement of the moving body 8 a plurality of times.

However, the present invention is not limited to the above-described embodiment, and the curved portion 144 may be connected to the upper portion of one vertical portion 145 so that the inner guide 8 is lifted and moved at least twice in a circular path It is also possible to descend at the end. It is also possible that the curved portion 144 is connected to the lower portion of the straight portion 143 so that the inner guide 8 can be lowered and then lifted after moving in a circular locus, It goes without saying that various implementations of the inner guide 8 are possible.

2: Main body 4: Air inlet
6: Discharge guide 8: Inner guide
10: Inner guide moving mechanism 100: Fixing case
110: motor 120: inner guide connector
130: rack 132: pinion
140: moving guide P: air discharge passage

Claims (20)

A main body having an air inlet formed therein and formed with a discharge guide;
An inner guide positioned inside the discharge guide and forming the discharge guide and the air discharge passage;
And an inner guide moving mechanism for moving the inner guide. The method according to claim 1,
Wherein the inner guide moving mechanism moves the inner guide so that the shape of the air discharge passage is varied. The method according to claim 1,
Wherein the inner guide moving mechanism moves the inner guide along a circumferential surface of the discharge guide. The method according to claim 1,
Wherein the inner guide moving mechanism moves the inner guide so that the sectional shape of the air discharge passage changes from a closed loop shape to a crescent shape and then changes to a closed loop shape. The method according to claim 1,
The inner guide moving mechanism is configured such that a part of the outer circumferential surface of the inner guide is brought close to the inner circumferential surface of the discharge guide and a part of the inner guide moving away from the inner circumferential surface of the discharge guide is distant from the inner circumferential surface of the discharge guide And the inner guide is moved. The method according to claim 1,
Wherein the inner guide moving mechanism raises the inner guide and then moves in a curved trajectory along the circumferential surface of the discharge guide. The method according to claim 6,
Wherein the inner guide moving mechanism moves the inner guide in a curved trajectory and then descends. 8. The method of claim 7,
Wherein the inner guide moving mechanism descends the inner guide to the inner center of the discharge guide. The method according to claim 1,
Wherein the inner guide moving mechanism moves the inner guide at the start of operation of the air conditioner and stops the inner guide at an inner central position of the discharge guide. The method according to claim 1,
The inner guide moving mechanism
A fixed case fixed to the discharge guide;
A motor installed in the fixed case;
An inner guide connector connected to the inner guide;
A power transmitting member for transmitting the driving force of the motor to the inner guide connector;
And a moving guide installed in the fixed case and guiding the inner guide connector when the motor is driven. 11. The method of claim 10,
The power transmitting member
A pinion provided on a rotary shaft of the motor,
And a rack which is engaged with the pinion and is provided in the inner guide connector. 12. The method of claim 11,
Wherein the inner guide connector has a connecting portion connected to the inner guide protruded. 13. The method of claim 12,
Wherein the moving guide includes a connecting through hole through which the connecting portion passes. 13. The method according to claim 11 or 12,
Wherein the inner guide connector has protrusions guided by the moving guide. 15. The method of claim 14,
Wherein the moving guide includes a guide portion for guiding the protrusion. 16. The method of claim 15,
Wherein the guide portion includes a straight portion to which the protrusion is guided, and a curved portion connected to the straight portion and guided by the protrusion. 15. The method of claim 14,
And the curved portion is connected to an upper portion of the straight portion. 17. The method of claim 16,
Wherein the rectilinear portion includes a vertical portion for guiding the protruding portion up and down and the curved portion connected to the upper portion. 19. The method of claim 18,
Wherein the rectilinear portion further comprises an inclined portion connecting the lower portion of the elevation portion and the curved portion. 16. The method of claim 15,
And the guide portion has a guide groove portion formed on a surface facing the fixed case.

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