KR20140092953A - Air conditioner - Google Patents

Abstract

An air conditioner of the present invention comprises: a main body having an air intake port and a discharge guide; and a light-emitting unit forming an air discharge path together with the discharge guide and having a plurality of light-emitting sources for emitting light toward the air discharge path, wherein the light-emitting sources selectively emit lights of various colors and the light-emitting unit varies the number of the light-emitting sources emitting light of a first color of the various colors and the number of the light-emitting sources emitting light of a second color of the various colors, according to the level of cleanliness, thereby easily checking the cleanliness of air by the color and by the shape of light expressed through the air discharge path.

Description

Air conditioner

The present invention relates to an air conditioner, and more particularly, to an air conditioner capable of displaying air cleanliness.

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-conditioning unit may be constituted by a heat exchanger in the case of a cooler or a radiator, and an electrostatic dust precipitator or a filter in the case of a cleaner.

The air conditioner may include a degree of cleanliness sensing unit for detecting the degree of cleanliness of a room such as a dust sensor, and the degree of cleanliness sensed by the degree of cleanliness sensing unit may be displayed by a display unit such as an LCD display. The display unit can display the cleanliness in numerical values.

There is a problem in that the air conditioner according to the related art has a problem that it is difficult to easily identify the cleanliness at a long distance distant from the display unit and the display unit has to be installed at a position where it can be easily recognized from the outside.

An object of the present invention is to provide an air conditioner capable of visually expressing an air cleanliness degree in an air discharge passage.

According to an aspect of the present invention, there is provided an air conditioner comprising: a main body having an air inlet formed therein and having a discharge guide; And a light emitting mechanism including a plurality of light emitting sources that emit light toward the air discharge path and form the discharge guide and the air discharge passage, wherein the light emitting source selectively emits light of a plurality of colors, The number of light-emitting sources that emit light of the first color and the number of light-emitting sources that emit light of the second color among the plurality of colors are varied according to the degree of cleanliness.

The light emitting mechanism may form a closed loop light band in the air discharge passage.

Wherein the light emitting mechanism has an inner guide whose periphery is spaced apart from an inner peripheral surface of the discharge guide to form an inner peripheral surface of the discharge guide and the air discharge passage, and an inner guide provided inside the inner guide, Optical module.

Wherein the optical module comprises: a main PCB mounted on the inner guide; A plurality of subfolder ratios installed in the main PCB, and the light emitting sources may be installed in the subframe.

At least two light sources may be installed in the sub-picture ratio.

The sub-pixel ratio may be set to be orthogonal to the main PCB, and the light-emitting source may be provided on a surface of the sub-pixel of the sub-pixel facing the air discharge path.

At least two of the plurality of light-emitting sources constitute a light-emitting group, and the light-emitting sources constituting the same light-emitting group can be controlled together.

The plurality of light emitting sources may be sequentially spaced apart from the circular virtual line, and the plurality of light emitting sources may form adjacent light emitting groups together.

The plurality of light-emitting sources may be classified into a plurality of light-emitting groups as well as adjacent light-emitting groups, and when at least two light-emitting groups among the plurality of light-emitting groups emit light of the same color, adjacent light- Light of the same color can be emitted together.

When the degree of cleanliness of the light emitting device is variable, the hue of at least a part of the plurality of light emitting sources may be changed.

The light source of the plurality of light sources may be changed in color after gradually decreasing the illuminance.

The light source of the plurality of light sources may be gradually changed in color after the color is changed,

If the cleanliness is the most comfortable range, the plurality of light sources may emit light of the first color, and if the cleanliness is the most contaminated range, the plurality of light sources may emit light of the second color If the cleanliness degree is in the middle range between the most comfortable range and the most contaminated range, a plurality of light emitting sources may emit a first color and a plurality of light emitting sources may emit a second color.

When the degree of cleanliness is in the middle range, the number of light emitting sources that emit light of the first color increases as the level of cleanliness increases, and as the level of cleanliness decreases, the number of light emitting sources that emit light of the second color increases .

The plurality of light emitting sources may be sequentially disposed in a circular virtual line, and the light emitting mechanism sequentially emits the plurality of light emitting sources along the circular virtual line in the stabilization mode, So that the illumination strip can be formed.

The light emitting device may vary the position of the illumination strip along the air discharge path in the stabilization mode.

The light emitting mechanism can gradually light the light at the back of the light-emitting band in the stabilization mode.

The light emission mechanism can gradually turn off the illuminance of the light emission source to be turned off and then turn off.

The direction in which the plurality of light emitting sources are sequentially turned off may be the same as the direction in which the plurality of light emitting sources are sequentially turned on.

An air conditioner according to the present invention includes: a main body having an air inlet formed therein and having a discharge guide; An inner guide spaced apart from an inner peripheral surface of the discharge guide to form an air discharge passage with an inner peripheral surface of the discharge guide; And an optical module provided in the discharge guide or the inner guide and having a plurality of light sources for emitting light toward the air discharge passage, wherein the light source selectively emits light of a plurality of colors, and the optical module has a cleanliness The number of light emitting sources that emit light of the first color and the number of light emitting sources that emit the light of the second color among the plurality of colors are varied.

The light emitting mechanism may form an illumination band that is positionally variable along the air discharge path in the stabilization mode.

According to the present invention, the cleanliness of the air can be more easily confirmed by the color of the light and the shape of the light expressed in the air discharge passage, and the cleanliness of the air can be easily recognized even at a long distance.

Further, since the air discharge passage can be utilized as a cleanliness display space, there is an advantage in that the structure is simple and the aesthetics is improved as compared with the case of displaying cleanliness through a separate display.

1 is a perspective view of an embodiment of an air conditioner according to the present invention,
2 is a sectional view of one embodiment of an air conditioner according to the present invention,
FIG. 3 is a control block diagram of an embodiment of an air conditioner according to the present invention.
FIG. 4 is a front view showing the inside of the light emitting device of the embodiment of the air conditioner according to the present invention,
FIG. 5 is a front view of the air conditioner according to an embodiment of the present invention,
FIG. 6 is a front view illustrating a light emission mode when air purifying stabilization of an air conditioner according to an embodiment of the present invention is expressed. FIG.

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

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

 Referring to Figs. 1 and 2, the air conditioner includes a main body 8 having an air inlet 2 and having a discharge guide 6.

The main body 8 may include a case 12 forming an outer appearance of the air conditioner. The case 12 may have an air inlet 2 formed on its back side. The main body 8 may include a heat exchanger 16 arranged inside the case 12 to heat-exchange the air sucked into the air inlet 2 with the refrigerant. The main body 8 may include at least one ventilation 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 8 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 27 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 27 is 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 2 with the refrigerant. The heat exchanger 16 may be installed between the air inlet 2 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 2 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 8 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 2 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 2. 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 end portion (53) of the tubular body (52) can be formed larger than the rear end (54). The tubular body 52 may include a flow guide portion formed in a shape of a trunk portion. The ejection guide 6 may include a bracket portion 56 on which a light emitting mechanism 60 and a light emitting mechanism moving mechanism 80 to be described later are installed. The bracket portion 56 can be formed to be positioned inside the cylindrical body 52 and can be formed to be positioned at the rear end 54 of the cylindrical body 52. The bracket portion 56 may be formed to be positioned behind the space of the cylinder 52. The bracket portion 56 may include a mounting portion 57 formed to be smaller in size than the space of the cylinder 52. The mounting portion 57 may be formed in an annular or disc shape. A light emitting mechanism 60 and a light emitting mechanism moving mechanism 80, which will be described later, may be mounted on the mounting portion 57. [ The bracket portion 56 may include at least one support leg 58 connecting the cylinder 62 and the mounting portion 57. The mounting portion 57 can be positioned behind the space of the cylinder 52 and at least one support leg 58 can connect the cylinder 52 and the mounting portion 57. [ At least one of the cylinder 52 and the bracket 56 may be mounted on the case 12 by 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 air conditioner includes a light emitting mechanism (60) that forms a discharge guide (6) and an air discharge passage (59) and emits light toward the air discharge passage (59).

 The light emitting mechanism 60 may be spaced apart from the inner circumferential surface 7 of the discharge guide 6. The light emitting mechanism 60 can form the inner peripheral surface 7 of the discharge guide 6 and the air discharge passage 59. [ The light emitting mechanism 60 may be provided with a light emitting source that emits light toward the air discharge path 59. The light emitting source may be composed of an LED. The light emitting source can selectively emit light of a plurality of colors. The light emitting mechanism 60 may include a plurality of light emitting sources. The light emitting mechanism 60 can form a closed loop light band by the air discharge passage 59. [ The light emitted from the light emitting mechanism 60 can be directed radially through the air discharge passage 59 to the discharge guide 6 to the inner peripheral surface 7 have. When the light emitting mechanism 60 irradiates light to the entire area of the outer circumferential surface, a closed loop light band can be formed in the air discharge passage 59. The light emitting mechanism 60 can form a streamlined light band in the air discharge passage 59 when light is irradiated to a part of the outer peripheral surface. The light emitting mechanism 60 may form a closed loop type illumination band or a wired illumination band by the number of the light emission sources among the plurality of light emission sources. The light-emitting structure of the light-emitting device 60 will be described later in detail, while the light-emitting structure of the light-emitting structure 60 is similar to the light-emitting structure of the closed-loop shape.

 The air conditioner includes an inner guide 64 which is spaced apart from the inner peripheral surface 7 of the discharge guide 6 and forms an inner peripheral surface 7 of the discharge guide 6 and an air discharge passage 59, 64 of the optical module. The inner guide 64 and the optical module 66 can constitute a light emitting mechanism 60. [ The optical module 66 may include a plurality of light sources for emitting light toward the air discharge passage 59.

The inner guide 64 can form an outer appearance of the light emitting mechanism 60. [ The inner guide 64 may have a space for accommodating the optical module in which the optical module 66 is accommodated. The inner guide 64 may include a front plate portion, a thick plate portion, and a peripheral portion. The peripheral portion of the inner guide 64 is spaced apart from the inner peripheral surface 7 of the discharge guide 6 to form the inner peripheral surface 7 of the discharge guide 6 and the air discharge passage 59. The inner guide 64 includes a light emitting cover 67 for receiving the optical module 66 and forming the inner circumferential surface 7 of the discharge guide 6 and the air discharge passage 59, And a front plate 68 disposed on the light emitting cover 67 and blocking the front surface of the light emitting cover 67. The luminescent cover 67 may be a shape in which the back surface is clogged and the front surface is opened. The luminescent cover 67 can constitute a thick plate portion and a peripheral portion of the inner guide 64. The luminescent cover 67 may be formed of a transparent material or a translucent material through which light is transmitted. The luminescent cover 67 may be formed with a light diffusion portion capable of diffusing light on the inner circumferential surface or the outer circumferential surface. When light is emitted from the light emitting source to the light emitting cover 67, the light can be diffused as it passes through the light emitting cover 67.

  The optical module 66 can be installed inside the inner guide 64 and can irradiate the light toward the periphery of the inner guide 64. [

  The light emitting mechanism 60 can be fixedly mounted on the main body 2. The light emitting mechanism 60 can be mounted on the main body 2 so as to be rotated or moved. When the light emitting mechanism 60 is installed to be fixed to the main body 2, the inner guide 64 may be fixed to the discharge guide 6. The inner guide 64 can be mounted to the bracket portion 56, particularly to the mounting portion 57 with a fastening member such as a screw. The light emitting mechanism 60 may be connected to the light emitting mechanism driving unit 80 and the light emitting mechanism driving unit 80 may be disposed on the ejection guide 6 And can be fixedly installed. The light emitting device driving part 80 can rotate or move the light emitting device 60 from behind the light emitting device 60. [ The light emitting device driving unit 80 may be formed to be smaller in size than the light emitting device 60. The light emitting device driving unit 80 may be mounted to the bracket portion 56, particularly, the mounting portion 57 with a fastening member such as a screw. The light emitting mechanism driving unit 80 includes a rear guide 81 positioned at the back of the light emitting mechanism 60, a motor 82 provided inside the rear guide 81, a light emitting mechanism 60 interlocked with the motor 82, And at least one power transmitting member (not shown) for rotating or moving the motor. The rear guide 81 can form an appearance of the light emitting device driving unit 80. [ The rear guide 81 may have a motor receiving space in which the motor 82 is housed. The rear guide 81 may include a front plate portion, a rear plate portion and a peripheral portion. The peripheral portion of the rear guide 81 is spaced apart from the inner peripheral surface 7 of the discharge guide 6 to form the inner peripheral surface 7 of the discharge guide 6 and the air discharge passage 59.

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

Referring to FIG. 3, the air conditioner may include a cleanliness sensing unit 90 for sensing the cleanliness of the air. The light emitting mechanism 60 can be controlled according to the detection result of the cleanliness detection unit 90. The degree of cleanliness sensing unit 90 is a sensor for sensing the degree of pollution of air, and a dust sensor, a gas sensor, or the like can be used. The air conditioner may include an input unit 92 through which a user inputs various commands. The air conditioner may include a control unit (94) for controlling the light emitting mechanism (60). The control unit 94 can control not only the light emitting mechanism 60 but also various electric components 27, 37 and 39 such as the wind direction adjusting motor 27 installed in the main body 8. [ The control unit 94 can control the light emitting mechanism 60 according to the detection result of the correction degree detecting unit 90. The control unit 94 can control the light emitting mechanism 60 so that the light emitting mechanism 60 displays the cleanliness degree when the user inputs the cleanliness degree display command through the input unit 92. [ The air conditioner can purify the indoor air by the clean unit 96 for purifying the air, and it is possible to display only the indoor cleanliness without the clean unit 96. The cleaning unit 96 can constitute an electrostatic precipitator for ionizing and collecting foreign substances in the air. The cleaning unit 96 can include a photocatalytic filter coated with a photocatalyst such as TiO2 and an ultraviolet irradiator for irradiating ultraviolet rays with a photocatalytic filter. The cleaning unit 96 may be of various types depending on the manner of cleaning the air. The clean unit 96 may be installed in front of or behind the air inlet 2 in the air flow direction. The control unit 94 can control the light emitting mechanism 60 to display the degree of cleanliness when the user inputs a clear command through the input unit 92 and can turn on the clean unit 96, The air conditioner can be operated in a clean mode. The control unit 94 can control the light emitting mechanism 60 so that the light emitting mechanism 60 displays the degree of cleanliness when the user turns on the air conditioner.

The control unit 94 can display the degree of cleanliness by using the light emission colors of the plurality of light emission sources. The plurality of light sources may selectively emit light of a first color among a plurality of colors and light of a second color of a plurality of colors when a clean command is input to the input unit 92 or a cleanliness display command is input. The light emitting source may be composed of LEDs, and the degree of cleanliness can be expressed by selectively emitting light of the first color and light of the second color.

On the other hand, the light emitting mechanism 60 can be controlled in a control pattern in which the light emission mode (that is, the stabilization mode) for expressing air purification stabilization and the light emission mode (cleanliness display mode) for expressing cleanliness are different. The stabilization mode may be a mode for preparing the execution of the cleanliness display mode to be performed thereafter. The stabilization mode may be a mode in which the cleanliness detection unit 90 waits until it becomes a condition for accurately detecting the indoor cleanliness. The stabilization mode may be a mode for collecting cleanliness data for a predetermined period of time in order to detect the cleanliness of the room while sensing a more accurate cleanliness.

FIG. 4 is a front view showing the interior of the light emitting device of the embodiment of the air conditioner according to the present invention, and FIG. 5 is a front view showing an example of cleanliness in an embodiment of the air conditioner according to the present invention.

 The light emitting mechanism 60 includes a main PCB 100 mounted on the inner guide 64 shown in FIG. 2; And a plurality of subfolders 101 to 108 provided in the main PCB 100. [ The light emission source may be installed in the sub-picture ratio 101-108. The plurality of light emission sources 111-126 may be dispersed in a plurality of sub-pixel areas 101-108. The main PCB 100, the plurality of sub-PCBs 101-108, and the plurality of light sources 111-126 can constitute the optical module 66 shown in FIG.

The main PCB 100 may be a donut-shaped disk. The main PCB 100 may be installed vertically in the inner guide 64.

The sub-picture ratio may be set orthogonally to the main PCB 100. At least two light sources may be provided in the sub-picture ratio. The plurality of subfeedbacks 101 to 108 may be provided on one surface of the main PCB 100 in a protruding manner. The plurality of sub-pixel areas 101-108 may be oriented in different directions.

The light emitting source may be provided on the surface of the sub-package side facing the air discharge path 59 shown in Fig. 2 on both surfaces. The plurality of light emitting sources 111-126 may be sequentially and spaced apart from the circular virtual line O. At least two of the plurality of light emitting sources 111-126 constitute a light emitting group, and the light emitting sources constituting the same light emitting group can be controlled together. For example, the four light emitting sources can constitute one light emitting group, and the four light emitting sources forming one light emitting group can be turned on and off together, and can be controlled together in the same color. Two light sources may be provided in one sub-picture ratio, two adjacent sub-picture ratios may constitute one light-emitting group, and a total of four light sources may be controlled together. The number of light emitting sources constituting one light emitting group is not limited to four, but may be two, three, five, or the like.

The degree of cleanliness sensed by the degree of cleanliness sensing unit 90 may be divided into at least three levels, and the number of the light-emitting sources emitting light of the first color and the number of light- The number of the light-emitting sources may be different. Here, the first color may be lighter than the second color.

The plurality of light emitting sources 111-126 can emit light of the first color when the degree of cleanliness sensed by the degree of cleanliness sensing unit 90 is the most comfortable range.

 The plurality of light emitting sources 111-126 may emit light of the second color if the degree of cleanliness detected by the degree of cleanliness sensing unit 90 is the most contaminated.

 The plurality of light emitting sources 111-126 may be arranged in a manner such that a part of the plurality of light emitting sources 111-126 is divided into a first range And the rest of the plurality of light emitting sources 111-126 may emit a second color. Here, the intermediate range may be divided into a plurality of levels, and the light emitting device 60 may be divided into a plurality of levels for each level in the intermediate range, and the number of light emitting sources for emitting light of the first color, The number of light emitting sources to emit light may be different. The middle range may be more than two levels, and the middle range is divided into three levels.

When the degree of cleanliness sensed by the degree of cleanliness sensing unit 90 is in the middle range, the number of light-emitting sources that emit light of the first color can be increased as the level of cleanliness increases, and as the level of cleanliness decreases, The number of light emitting sources for emitting light can be increased.

5A shows a first light emitting mode when all of the plurality of light emitting sources 111-126 emit light of the first color. 5B shows a case where the number of light emitting sources emitting light of the first color is smaller than that of FIG. 5A and the number of light emitting sources emitting light of the second color is smaller than that of the light of the first color The second light emission mode is smaller than the number of light emission sources that emit light. 5 (C) shows a case where the number of light emitting sources emitting light of the first color is smaller than that of the case of (B) of FIG. 5, The second light emitting mode is a second light emitting mode. FIG. 5 (d) shows the case where the number of light emitting sources that emit light of the first color is smaller than that of FIG. 5 (a), and the number of light emitting sources that emit light of the second color The fourth light emission mode is shown. FIG. 5E shows a fifth light emitting mode when all of the plurality of light emitting sources 111-126 emit light of the second color.

 The first mode of the first to fifth light emitting modes can visually express the highest degree of cleanliness and the fifth mode of the first to fifth light emitting modes can visually express the lowest degree of cleanliness. And the second mode of the first to fifth emission modes may express less cleanliness than the first mode. And the third mode of the first to fifth emission modes can express less cleanliness than the second mode. The fourth mode among the first to fifth light emitting modes can express cleanliness lower than the third mode and higher cleanliness than the fifth mode.

The plurality of light emitting sources 111-126 may be divided into a plurality of light emitting groups A, B, C, and D. The plurality of light emitting sources 111-126 can constitute one light emitting group by adjacent light emitting sources. For example, when a total of 16 light emitting sources 111-126 are sequentially arranged in a circular virtual line, the first light emitting source 111 and the second light emitting element 111 closest to the first light emitting source 111 in the clockwise direction A third light emitting source 113 closest to the second light emitting source 112 in the clockwise direction and a fourth light emitting source 114 closest to the third light emitting source 113 in the clockwise direction 1 light emitting group (A). The fifth light emitting source 115 and the sixth light emitting source 116 and the seventh light emitting source 116 and the eighth light emitting source 118 are arranged in a clockwise direction on the basis of the first light emitting source 51, (B). ≪ / RTI > The ninth light emitting source 119, the tenth light emitting source 120 and the eleventh light emitting source 121 and the twelfth light emitting source 122 can constitute the third light emitting group C in the above- have. The thirteenth light emitting source 123, the fourteenth light emitting source 124 and the fifteenth light emitting source 125 and the sixteenth light emitting source 126 can constitute the fourth light emitting group D.

When at least two light emitting groups among the plurality of light emitting groups A, B, C, and D emit light of the same color, adjacent light emitting groups can emit light of the same color together. The plurality of light emitting groups A, B, C and D are arranged in a clockwise direction in the order of the first light emitting group A, the second light emitting group B, the third light emitting group C, (D). ≪ / RTI > For example, when two light emitting groups are emitted in a first color, the adjacent first light emitting group (A) and the second light emitting group (B) may emit light in a first color. When the three light emitting groups emit light of the first color, the adjacent first light emitting group (A), the second light emitting group (B), and the third light emitting group (C) may emit light in a first color. As another example, for example, when three light emitting groups are emitted with a second color, the second light emitting group B, the third light emitting group C, and the fourth light emitting group D together form a second color As shown in FIG.

The degree of cleanliness is determined by setting the range in which the degree of cleanliness sensed by the degree of cleanliness sensing unit 90 is the most comfortable level as the first level and the comfortable range as the second level, . Here, the fifth level may be the level with the lowest degree of correction.

The light emitting mechanism 60 is configured such that the light emitting sources 111-114 of the first light emitting group A, the light emitting sources 115-118 of the second light emitting group B, Both the light emitting sources 119-122 of the third light emitting group C and the light emitting sources 123-126 of the fourth light emitting group D can be emitted in the first color.

The light emitting mechanism 60 includes the light emitting sources 111-114 of the first light emitting group A and the light emitting sources 115-118 of the second light emitting group B when the degree of cleanliness is the second level, The light emitting sources 119-122 of the third light emitting group C may emit light in a first color and the light emitting sources 123-126 of the fourth light emitting group D may emit light in a second color .

The light emitting mechanism 60 is configured such that the light emitting sources 111-114 of the first light emitting group A and the light emitting sources 115-118 of the second light emitting group B are arranged in the first And the light emitting sources 119-122 of the third light emitting group C and the light emitting sources 123-126 of the fourth light emitting group D may emit light of a second color .

The light emitting device 60 can emit light of a first color when the cleanliness level is the fourth level and the light emitting sources 111-114 of the first light emitting group A can emit light of a first color, Both the light emitting sources 119-122 of the third light emitting group C and the light emitting sources 123-126 of the fourth light emitting group D can be emitted in the second color have.

The light emitting mechanism 60 is configured such that the light emitting sources 111-114 of the first light emitting group A, the light emitting sources 115-118 of the second light emitting group B, Both the light emitting sources 119-122 of the third light emitting group C and the light emitting sources 123-126 of the fourth light emitting group D can be emitted in the second color.

 The light emitting mechanism 60 may change the color of at least a part of the plurality of light emitting sources 111-126 when the degree of cleanliness sensed by the degree of cleanliness sensing unit 90 is variable. The light source of the plurality of light emitting sources 111-126 whose color is changed may be changed in color after the illuminance gradually decreases. The light source of the plurality of light emitting sources 111-126 whose color is changed may be gradually increased after the color is changed.

For example, when the degree of cleanliness changes from the third level to the second level due to the clean operation of the air conditioner or the change of the indoor environment, the light emitting sources 119-122 of the third light emitting group C emit light of the second color The light emission sources 119-122 of the third light emitting group C gradually lower the illuminance of the second color light emission, and after the light emission of the first color is switched to the light emission of the first color, The lightness of the second color light emission can be gradually increased. That is, at the time of changing the level of cleanliness, the first color and the second color can be changed gradually without changing suddenly, and the fatigue of the eyes that the user can feel can be minimized.

FIG. 6 is a diagram sequentially illustrating a light emission mode when air purifying stabilization of an air conditioner according to an embodiment of the present invention is expressed with time.

 The light emitting mechanism 60 can form an illumination band L whose position is variable along the air discharge passage 59, as shown in Fig. 6, in the stabilization mode. The light emitting mechanism 60 can change the position of the illumination strip L as time elapses in the stabilization mode.

The light emitting mechanism 60 can sequentially emit the plurality of light emitting sources 111-126 along the circular virtual line O shown in FIG. 4, and sequentially emit the light emitting sources that emit light along the circular virtual line O So that the light-emitting zone L can be formed. The light strip L can be activated while drawing a circle in the air discharge passage 59. [ In the stabilization mode, the plurality of light emitting sources 111-126 may be in an on state while the remaining light emitting sources 111-126 may be in the off state. In the light emitting mechanism 60, The light-emitting band L can be formed in a wired form. The plurality of light-emitting sources 111-126 can be continuously switched from the on-state light-emitting source to the on-state light-emitting source along with the elapse of time, and in particular, Direction. ≪ / RTI >

The light emitting device 60 may first turn on the first light emitting source 111 among the plurality of light emitting sources 111-126 shown in FIG. 4, then turn on the second light emitting source 112 with a time difference thereafter have. The second light emitting source 112 of the second light emitting source 112 can emit light together with the first light emitting source 111 and can turn on the third light emitting source 113 with a time difference thereafter. The third light emitting source 113 of the third light emitting source 113 emits light together with the first light emitting source 111 and the second light emitting source 112 and the light emitting band L emits light through the air discharge path 59 It gradually gets longer. The light emitting mechanism 60 sequentially turns on the remainder of the plurality of light emitting sources in this manner. The illumination band L formed by the light emitting mechanism 60 forms a semicircular illumination band in a gradually rounded shape in the air discharge passage 59 as time elapses and then is activated in a wire shape close to a circle .

The light emitting mechanism 60 is configured such that the time difference from the first light emitting source 111 that is the first light emitting element that was emitted first is set to a value before the light emitting source 126 positioned last in the clockwise direction with respect to the first light emitting source 111 is turned on And can be turned off sequentially. The direction in which the plurality of light emitting sources 111-126 are sequentially turned off may be the same as the direction in which the plurality of light emitting sources 111-126 are sequentially turned on.

6A and 6B show the positions of the illumination strips according to the elapse of time. The light emission mechanism 60 has the same structure as that of FIGS. 6A and 6B, The position of the illumination strip L can be continuously changed along the air discharge passage 59. [

The light emitting mechanism 60 can change the illumination band L during the set time period as shown in FIG. 6B, FIG. 6G, FIG. 6A, and FIG. You can repeat this several times.

In the stabilization mode, the air conditioner can emit light from the plurality of light emitting sources 111-126 only in one of the first color and the second color. Hereinafter, it is assumed that the on-emission source emits light of the first color. It is explained that the position of the illumination band is changed clockwise between the clockwise direction and the counterclockwise direction.

The light emitting mechanism 60 can gradually darken the light of the backlight T of the illumination band in the stabilization mode. The light emitting mechanism 60 can gradually turn off the illuminance of the light emitting source that is the off target to gradually darken the light of the backlight T of the illumination band.

6A and 6B show the case where the light emitting sources 111-114 of the first light emitting group A and the light emitting sources 123-126 of the fourth light emitting group D shown in FIG. When the light emitting sources 119-122 of the first light emitting group C are on and the light emitting band L when the light emitting sources 115-118 of the second light emitting group B is off is set to the air discharge passage 59 It is the degree to which it is expressed. At this time, among the light emitting sources 123-126 of the third light emitting group C, the light emitting source 119 located at the rearmost position in the clockwise direction can be gradually turned off after lowering the illuminance.

6 shows the illumination band L after time elapses in FIG. 6 (B) and FIG. 6 shows the light-emitting sources 115- The light emitting sources 111-114 of the first light emitting group A and the light emitting sources 123-126 of the fourth light emitting group D are on, And the light-emitting band L when the light-emitting diodes 119-122 are off is represented in the air discharge passage 59. [ At this time, among the light emitting sources 123-126 of the fourth light emitting group D, the light emitting source 123 located at the rearmost position in the clockwise direction can be gradually turned off after lowering the illuminance.

6A is a view showing the illumination band L after time elapses in FIG. 6 (G), and FIG. 6A is a view showing the light emitting sources 119-122 of the third light emitting group C, The light emitting sources 115-118 of the light emitting group B and the light emitting sources 111-114 of the first light emitting group A are on and the light emitting sources 123-126 Is off in the air discharge passage 59. In this case, as shown in Fig. At this time, among the light emitting sources 111-114 of the first light emitting group D, the light emitting source 111 located at the rear in the clockwise direction can be gradually turned off after lowering the illuminance.

FIG. 6 is a view showing the illumination band L after time elapses in FIG. 6 (G), and the light emitting sources 123-D of the fourth light emitting group D shown in FIG. The light emitting sources 119-122 of the third light emitting group C and the light emitting sources 115-118 of the second light emitting group B are on, And the light-emitting band (L) when the light-emitting element (111-114) is in the air discharge passage (59). At this time, among the light emitting sources 115-118 of the second light emitting group B, the light emitting source 115 located at the rear in the clockwise direction can be gradually turned off after lowering the illuminance.

  After the illumination strip L is formed as shown in Fig. 6 (a), the illumination strip L continues to be varied as shown in Fig. 6 (B), Fig. 6 (G) and Fig. 6 So that the user can easily identify the stabilization mode even at a long distance.

The air conditioner may be configured such that a user inputs an operation command of the air conditioner through the input unit 92 or a user inputs a clean command through the input unit 92 or a user inputs a cleanliness display command through the input unit 92 In this case, as shown in Fig. 6, the stabilization mode can be performed first, and then, according to the cleanliness degree, the cleanliness display mode can be performed as shown in Fig.

The present invention is not limited to the above-described embodiment, and it is also possible that the optical module 66 is installed in the discharge guide 6 to irradiate light toward the air discharge passage 59, It will be understood that various changes and modifications may be made without departing from the scope of the invention.

2: inlet 6: discharge guide
8: main body 59: air discharge passage
60: Light emitting mechanism 64: Inner guide
66: optical module 100: main PCB
101, 102, 103, 104, 105, 106, 107 108:
111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125,
A, B, C, D: Luminescent group L; Light strip
O: Circular imaginary line T: Tail of light strip

Claims (21)

A main body having an air inlet formed therein and having a discharge guide;
And a light emitting mechanism including a plurality of light emitting sources for emitting light toward the air discharge passage, the light emitting mechanism forming the discharge guide and the air discharge passage,
The light-emitting source selectively emits light of a plurality of colors,
Wherein the light emitting device has a number of light emitting sources that emit light of a first color among a plurality of colors and a number of light emitting sources that emit light of a second color among a plurality of colors. The method according to claim 1,
Wherein the light emitting mechanism forms a closed loop light band in the air discharge passage. The method according to claim 1,
Wherein the light emitting mechanism has an inner guide whose periphery is spaced apart from an inner peripheral surface of the discharge guide to form an inner peripheral surface of the discharge guide and the air discharge passage, and an inner guide provided inside the inner guide, An air conditioner comprising an optical module. The method of claim 3,
Wherein the optical module comprises: a main PCB mounted on the inner guide;
And a plurality of sub-file resources installed in the main PCB,
Wherein the light emitting source is disposed at the sub-picture ratio. The method of claim 3,
Wherein at least two light sources are provided in the sub-picture ratio. The method of claim 3,
Wherein the sub-picture ratio is set orthogonally to the main file ratio,
Wherein the light emitting source is provided on a surface of the two sides of the sub-package facing the air discharge passage. The method according to claim 1,
Wherein at least two of the plurality of light-emitting sources constitute a light-emitting group, and the light-emitting sources constituting the same light-emitting group are controlled together. 8. The method of claim 7,
Wherein the plurality of light emitting sources are sequentially spaced apart from a circular virtual line,
Wherein the plurality of light-emitting sources include adjacent light-emitting sources together constituting a light-emitting group. 8. The method of claim 7,
The plurality of light-emitting sources include adjacent light-emitting sources as a light-emitting group and a plurality of light-emitting groups,
Wherein at least two light emitting groups of the plurality of light emitting groups emit light of the same color when adjacent light emitting groups emit light of the same color. The method according to claim 1,
Wherein the light emitting mechanism changes the color of at least a part of the plurality of light emission sources when the degree of cleanliness is variable. 11. The method of claim 10,
Wherein the light source of the plurality of light sources is changed in color after the illuminance gradually decreases. The method according to claim 10 or 11,
Wherein the light source of the plurality of light sources is changed in color after the color is changed. The method according to claim 1,
If the degree of cleanliness is the most comfortable range, the plurality of light-emitting sources emit light of the first color,
If the degree of cleanliness is the most contaminated, the plurality of light-emitting sources emit light of a second color,
Wherein a plurality of light emission sources emit a first color and a plurality of light emission sources emit a second color when the cleanliness degree is in the middle range between the most comfortable range and the most contaminated range. The method of claim 3,
When the degree of cleanliness is in the middle range, the number of light emitting sources that emit light of the first color increases as the level of cleanliness increases, and as the level of cleanliness decreases, the number of light emitting sources that emit light of the second color increases Air conditioner. The method according to claim 1,
Wherein the plurality of light emitting sources are sequentially spaced apart from a circular virtual line,
Wherein the light emitting mechanism sequentially emits the plurality of light emitting sources along the circular hypothetical line in the stabilization mode and sequentially turns off the light emitting sources that are emitting light along the circular hypothetical line to form an illumination band. The method according to claim 1,
Wherein the light emitting mechanism varies the position of the illumination band along the air discharge path in the stabilization mode. 17. The method of claim 16,
Wherein the light emitting mechanism gradually blurs the light at the tail of the light strip in the stabilization mode. 16. The method of claim 15,
Wherein the light emission mechanism gradually decreases the illuminance of the light emission source to be turned off and then turns off. 16. The method of claim 15,
Wherein the direction in which the plurality of light emitting sources are sequentially turned off is a direction in which the plurality of light emitting sources are sequentially turned on. A main body having an air inlet formed therein and having a discharge guide;
An inner guide spaced apart from an inner peripheral surface of the discharge guide to form an air discharge passage with an inner peripheral surface of the discharge guide;
And an optical module provided in the discharge guide or the inner guide and having a plurality of light sources for emitting light toward the air discharge passage,
The light-emitting source selectively emits light of a plurality of colors,
Wherein the optical module varies the number of light emitting sources that emit light of the first color among the plurality of colors and the number of the light emitting sources that emit the light of the second color among the plurality of colors. 21. The method of claim 20,
Wherein the light emitting mechanism forms an illumination band that is positionally variable along the air discharge path in the stabilization mode.

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