KR200198157Y1 - adjusting structure of delivery air of air conditioner - Google Patents

Abstract

In the discharge airflow control structure of the air conditioner according to the present invention, a frame is inserted into an upper portion of the front panel, and a stepped protrusion is formed so that the locking protrusion formed on the lower side of the discharge airflow control member is in contact with the frame to adjust the wind angle. In the discharge wind direction control structure of the formed air conditioner, the discharge wind direction control member is rotated about an axis to adjust the wind direction angle when the lower locking projection is in contact with the stepped projections of the frame. The present invention is characterized in that it comprises a notch portion formed to act the elastic force is the elastic force acts on the notch portion to adjust the wind direction angle according to the rotation of the discharge wind direction control member is made smoothly and smoothly, the contact excessive to the locking projection It is not applied by the force, and it is effective to prevent abrasion and damage occurring in the part. have.

Description

Adjusting structure of delivery air of air conditioner

The present invention relates to a structure for controlling the discharge direction of the air conditioner to heat the indoor air in the integrated air conditioner to smoothly control the direction of the air discharged back to the room.

In general, air conditioners are classified into various types according to their function or configuration of the unit. In the classification by function, they can be classified into cooling only, cooling and dehumidification only, and cooling and heating. Integrated air conditioners installed in windows and the like by integrating cooling and heat dissipation functions, and a separate type air conditioner which separates and installs a cooling device on an indoor side and a heat dissipation and compression device on an outdoor side, respectively.

As shown in Figs. 1 to 3, the integrated air conditioner as described above is provided with a front panel 10 having a suction port 11 for sucking air on the front surface of the interior side I. On the upper surface of the panel 10 is inserted a frame 20 having a space in which the discharge wind direction adjusting member 21 and the temperature control and master control switches 22 and 23 for controlling the temperature of the air and the speed of the fan are respectively inserted. It is.

The discharge wind direction adjusting member 21 has a plurality of blades 21a are erected at regular intervals, and shafts 21b are formed on both sides thereof to be installed and rotatable in the through holes 20a of the frame 20. Under the blade 21a, a locking protrusion 21c is formed to contact the stepped protrusion 20b of the frame 20 to adjust the wind direction angle when the discharge wind direction adjusting member 21 is rotated. have.

The indoor side (I) and the outdoor side (O) are divided with the partition member 30 therebetween, and the inlet 11 of the front panel 10 is located inside the front panel 10 of the indoor side I. The air introduced through the evaporator is purified while passing through the filter 40 to exchange heat with cold air, and transfers power of a motor (not shown) to suck the air in the room to the rear of the evaporator 50. A blower 60 that rotates to receive the product, a control box 70 for controlling a product on the side of the blower 60, and an inlet of the evaporator 50 to expand the refrigerant of room temperature and high pressure to a low temperature low pressure in a condenser described later. The capillary tube 80 is provided.

In the space of the outdoor side (O) formed on the rear of the partition member 30, a compressor (80) for compressing the refrigerant supplied from the evaporator (50) to a high temperature and high pressure on the bottom of one side of the base panel 31, and the Condenser 100 for condensing the refrigerant compressed from the compressor 80 at room temperature and high pressure on the rear side of the outdoor side O, and outdoor air is condenser 100 between the condenser 100 and the partition member 30. Propeller fan 110 is driven by the power of the motor (not shown) to be heat exchanged through the).

In the conventional integrated air conditioner configured as described above, when the power is applied by operating the control box 70 by a remote controller or a hand, the blower 60 and the propeller fan 110 are driven according to the driving of the motor (not shown). At the same time, the refrigerant introduced by the compressor 90 is compressed to high temperature and high pressure, and the compressed refrigerant is converted to room temperature and high pressure while passing through the condenser 100 through the refrigerant line, and the refrigerant is capillary tube 80. As it passes through the low temperature and expands to a low temperature and low pressure flows into the evaporator 50, it becomes a complete gas refrigerant of low temperature and low pressure to form a refrigerant cycle flowing into the compressor 90 again.

At this time, the hot air in the room is introduced through the inlet port 11 of the front panel 10 in accordance with the suction force of the blower 60 of the indoor side (I) to pass through the evaporator 50, cold air The heat exchanger is discharged back into the room through the discharge wind direction control member 21 on the upper side of the blower 60 to cool the room.

However, in the conventional integrated air conditioner as described above, when the air in the room is heat-exchanged with the cold air in the evaporator 50 and discharged again to the room, the discharge wind direction control member 21 moves the shaft 21b. The locking protrusion 21c which rotates about the center and is formed at the lower side of the discharge wind direction control member 21 is in contact with the stepped protrusion 20b of the frame 20 to adjust the wind direction angle. Due to frequent contact between 21c) and the stepped protrusion 20b, abrasion occurs between them, and because the stepped protrusion 20b has no elastic force, the locking protrusion 21c may be damaged when the wind direction is adjusted. There was this.

Therefore, the present invention is devised to solve the above problems, the object of the present invention is to convert the air of the room into cold air, the user is not worn when adjusting the direction of the air discharged back to the room up and down It is to provide a discharge wind direction control device for an air conditioner to adjust the desired angle.

In order to achieve the above object, the discharge wind direction adjusting structure of the air conditioner according to the present invention includes a frame inserted into an upper portion of the front panel, and a locking protrusion formed under the discharge wind direction adjusting member in contact with the frame. In the discharge wind direction control structure of the air conditioner is formed by forming a stepped projection to adjust the wind direction angle, the lower projection is a stepped projection of the frame when the discharge wind direction control member is rotated about an axis to adjust the wind direction angle It characterized in that it comprises a notch formed so that the elastic force acts on the stepped projection when contacted with.

1 is a perspective view showing a general air conditioner,

Figure 2 is an exploded perspective view showing a conventional air conditioner,

3 is an exploded perspective view showing a discharge wind direction control member of a conventional air conditioner;

4 is an assembled cross-sectional view taken along the line A-A of FIG.

5 is an exploded perspective view showing a discharge wind direction control member of an air conditioner according to the present invention;

6 is an assembled cross-sectional view taken along the line B-B of FIG.

Explanation of symbols on the main parts of the drawings

20: frame 20a: through hole

20b: stepped projection 20c: notch

21: discharge direction control member 21a: blade

21b: shaft 21c: locking projection

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

5 and 6, a frame 20 is inserted in an upper portion of the front panel 10, a discharge port is formed in the frame 20, and the discharge wind direction control member 21 is formed in the discharge port. Is rotated about the shaft 21b inserted into the through hole 20a.

The discharge wind direction adjusting member 21 has a plurality of blades 21a are erected at regular intervals, and shafts 21b are formed on both sides thereof to be installed and rotatable in the through holes 20a of the frame 20. Under the blade 21a, a locking protrusion 21c is formed to contact the stepped protrusion 20b of the frame 20 to adjust the wind direction angle when the discharge wind direction adjusting member 21 is rotated. have.

That is, the stepped protrusion 20b is formed in the frame 20 so that the engaging protrusion 21c formed under the discharge wind direction adjusting member 21 contacts and adjusts the wind direction angle. 20b) rotates the discharge wind direction adjusting member 21 about its axis 21b so that the lower locking projection 21c contacts the stepped protrusion 20b of the frame 20 when adjusting the wind angle. When the notch 20c is formed so that the elastic force acts on the stepped protrusion 20b.

The notch portion 20c is formed in a V-shape across the stepped protrusion 20b on the outside of the stepped protrusion 20b to which the catching protrusion 21c of the discharge wind direction control member 21 contacts.

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

First, when the power is applied by operating the control box 70 with a remote controller or a hand, the blower 60 and the propeller fan 110 are driven by the driving of the motor (not shown), and at the same time, the compressor 90 The refrigerant introduced by driving is compressed to high temperature and high pressure, and the compressed refrigerant is converted to room temperature and high pressure while passing through the condenser 100 through the refrigerant line, and the refrigerant expands to low temperature and low pressure while passing through the capillary tube 80. As it enters the evaporator 50, it becomes a low temperature low pressure full gaseous refrigerant and forms a refrigerant cycle flowing back into the compressor 90.

At this time, the hot air in the room is introduced through the inlet port 11 of the front panel 10 in accordance with the suction force of the blower 60 of the indoor side (I) to pass through the evaporator 50, cold air The heat exchanger is discharged back into the room through the discharge wind direction control member 21 on the upper side of the blower 60 to cool the room.

As described above, the direction of air discharged into the room is controlled by the discharge wind direction control member 21 rotating in the discharge port of the frame 20.

At this time, the locking projection 21c formed below the discharge wind direction control member 21 is in contact with the surface of the stepped projection 20b of the frame 20.

The stepped protrusion 20b has a V-shaped notch 20c formed at one side thereof, and an elastic force acts on the notched portion 20c when the locking protrusion 21c and the stepped protrusion 20b come into contact with each other. Adjustment of the wind direction angle according to the rotation of the wind direction control member 21 is made smoothly and smoothly, and the force due to excessive contact with the locking projection 21c is not applied.

As described above, according to the discharge wind direction control structure of the air conditioner according to the present invention, the engaging projection formed on the lower side of the discharge wind direction control member is in contact with the stepped projection of the frame bar, the step Since the V-shaped notch part is formed on the mold protrusion, elastic force acts on the notch part to smoothly and smoothly adjust the wind direction angle due to the rotation of the discharge wind direction control member. This is not applied, there is an effect to prevent the wear and damage generated in the portion.

Claims (2)

A frame is inserted into an upper portion of the front panel, and a stepped protrusion is formed to contact the locking protrusion formed on the lower side of the discharge wind direction control member to adjust the wind direction angle. The stepped projection has a discharge wind direction control structure of the air conditioner, characterized in that the notched portion is formed to deform the stepped projection when an excessive force is applied when the engaging projection. The method of claim 1, The notch part has a discharge wind direction control structure of an air conditioner, characterized in that it is formed in a V-shape across the stepped protrusions on the outside of the stepped protrusions in contact with the catching protrusions of the discharge wind direction adjusting member.