KR20100043996A - Air conditioner - Google Patents

Abstract

PURPOSE: An air conditioner is provided to reduce manufacturing costs and power consumption by using a driving unit, in which the volume is relatively small, even if the size of a vein is increased. CONSTITUTION: An air conditioner comprises a chassis(11), a fan assembly, a heat exchanger, a discharge grill unit, a main vein, a motor, and a link member. The fan assembly is formed in the front of the chassis. The heat exchanger is formed in the front of the fan assembly. The discharge grill unit supports the heat exchanger, and has an air outlet. The main vein is rotatably formed in the discharge grill unit, and selectively shields the air outlet. The motor is installed in the discharge grill unit, and generates power for rotating the main vein. One end of the link member is connected to the rotary shaft of the motor, and the other end is connected to a separated part from the center of the main vein.

Description

Air Conditioner

The present invention relates to an indoor unit of an air conditioner.

In general, an air conditioner is a home appliance that maintains a room in a cooling or heating state through heat exchange between a refrigerant and air.

The air conditioner may be divided into a detachable type in which the indoor unit and the outdoor unit are provided as separate products, and an integral type provided in the unit. The indoor unit may be divided into an upper tooth type installed on the bottom surface of the installation space and a wall hanging type attached to the wall surface.

In addition, the wall-mounted indoor unit is equipped with a heat exchanger, a blowing fan for sucking indoor air, and a filter for filtering the sucked air. The blowing fan is a centrifugal fan or a cross flow fan.

An object of the present invention is to provide an air conditioner capable of applying a drive means having a relatively small capacity as compared with the extent to which the size of the vane means for shielding the discharge port is increased.

Air conditioner according to an embodiment of the present invention for achieving the above object, the chassis; A fan assembly provided at the front of the chassis; A heat exchanger provided in front of the fan assembly; A discharge grill unit supporting the heat exchanger and having an air outlet; A main vane rotatably provided to the discharge grill unit to selectively shield the air discharge port; A motor mounted to the discharge grill unit to generate power for rotation of the main vane; And a link member having one end connected to a rotation shaft of the motor and the other end connected to a point spaced apart from the rotation center of the main vane.

According to the air conditioner according to the embodiment of the present invention having the above configuration, even if the size of the vane is increased, the drive means having a relatively small capacity compared to the conventional drive means can be applied, thereby reducing the manufacturing cost and power consumption There is a reduction effect.

1 is an external perspective view of an indoor unit of an air conditioner according to an embodiment of the present invention.

Referring to FIG. 1, the air conditioner indoor unit 1 according to an embodiment of the present invention includes a chassis 11 forming a rear exterior and a front panel coupled to the front of the chassis 1 to form a front exterior. 12 and a center frame 13 interposed between the chassis 11 and the front panel 12 and having an inlet at an upper surface thereof. The indoor unit 1 includes a fan assembly (not shown) that sucks and discharges indoor air and a heat exchanger that exchanges heat between the indoor air sucked by the fan assembly and the refrigerant. In addition, a signal receiver 14 is provided on the front surface of the front panel 12 to receive an operation command signal output from the remote controller.

Figure 2 is an external perspective view showing a state in which the filter of the indoor unit is drawn out according to an embodiment of the present invention.

Referring to Figure 2, the indoor unit 1 according to an embodiment of the present invention is characterized in that the filter is automatically withdrawn, so that the user can conveniently separate the filter to clean and replace.

In detail, the filter ejector 15 according to the embodiment of the present invention includes a plurality of frames that are pulled out in multiple stages with a filter seated on a front surface thereof, and an ejector driving device and a frame providing driving force to draw out the plurality of frames in multiple stages. It is made of a blowout blocking unit 17 mounted at the bottom of the. In addition, the filter 16 is seated on the front surface of the filter ejector 15.

3 is a partial perspective view showing the flow of air discharged from the indoor unit according to an embodiment of the present invention.

Referring to FIG. 3, a discharge port is provided below the indoor unit 1, and a discharge grill unit 20 is mounted near the discharge port. In detail, the air discharged by the discharge grill unit 20 is discharged while spreading to the left and right.

The main vane 18 and the sub vane 19 are rotatably coupled to the discharge port. In addition, the gap between the front panel 12 and the discharge port is shielded by the ventilation blocking unit 17.

In detail, when the fan assembly mounted inside the indoor unit 1 is driven, most indoor air is sucked from the upper surface of the indoor unit 1, but a small amount of air is also sucked into the front of the indoor unit 1. The small amount of air is sucked through a gap formed between the front panel 12 and the discharge port, and a part of the air discharged from the discharge port may also be reintroduced into the gap. In order to prevent such a blowing phenomenon, the blowing blocking unit 17 is mounted at the lower end of the moving frame 153. In addition, the ventilation blocking part 17 shields a gap formed between the lower end of the front panel 12 and the discharge port. Therefore, a phenomenon in which a part of the air discharged to the discharge port is hit by the blow blocking unit 17 and flowed back into the indoor unit is prevented.

On the other hand, the main vane 18 is made of a width that is completely covered up to the ventilation block 17 and the length corresponding to the length of the discharge port. The rear end of the main vane 18 and the rear end of the sub vane 19 are rotatably coupled to one side of the discharge grill unit 20. When the main vanes 18 are closed, the ventilation blocking unit 17 and the sub vanes 19 are completely shielded. When the operation command of the indoor unit 1 is input, the sub vanes 19 and the main 18 rotate in opposite directions to open the discharge port. Here, the sub vanes 19 may start to rotate after the main vanes 18 are fully opened. Alternatively, the sub vanes 19 may begin to rotate immediately after the main vanes 18 rotate to an angle in a range that does not interfere with the sub vanes 19.

In addition, the sub vanes 19 may be set to have different rotation angles in the cooling mode and the heating mode. For example, in the heating mode, the rotation angle of the sub vanes 19 may be relatively smaller than in the cooling mode, so that the warm air discharged may be discharged toward the indoor floor. On the contrary, in the cooling mode, the rotation angle of the sub vanes 19 may be relatively large, so that the sub vanes 19 may be discharged to the upper space of the room. This is because the hot air is distributed in the upper side in the summer, and the cold air is distributed in the bottom side in the winter, so that the hot air is rapidly cooled and the warm air is quickly warmed.

The coupling relationship and the operating method of the main vanes 18 will be described in more detail below with reference to the drawings.

4 is an exploded perspective view of the discharge grill unit constituting the indoor unit according to the embodiment of the present invention.

4, the discharge grill unit 20 is mounted on the discharge port side of the indoor unit 1 according to the embodiment of the present invention, so that the discharged air can be widely discharged to the left and right.

In detail, a discharge port 202 is formed in the discharge grill unit 26, and a heat exchanger seat 201 is formed on an upper surface thereof. The heat exchanger seating portion 201 is a portion for supporting the lower end of the heat exchanger, and serves as a drain pan for collecting condensate generated on the surface of the heat exchanger. Therefore, the heat exchanger seating portion 201 may be referred to as a drain pan. In addition, a plurality of louver mounting holes 203 are formed in the bottom surface of the discharge port 202.

In addition, the discharge port 202 is selectively shielded by the sub vanes 19 and the main vanes 18. In detail, rotation shafts 181 and 191 protrude from both ends of the main vane 18 and the sub vane 19, respectively. In particular, the rotation shaft 181 of the main vane 18 protrudes at the lower end, and the rotation shaft 191 of the sub vane 19 protrudes at the upper end. Thus, the main vanes 18 and the sub vanes 19 form a structure that rotates in opposite directions. Here, the rotation in the opposite direction means that the two vanes rotate in the clockwise and counterclockwise directions when viewed from the side of the indoor unit 1.

Meanwhile, insertion holes for inserting the rotation shafts 181 and 191 may be formed at the side surfaces of the discharge grill unit 20. In addition, a main vane motor 30 and a sub vane motor 29 connected to the rotation vanes of the main vane 18 and the sub vane 19 are mounted on the side surfaces of the discharge grill unit 20, respectively.

In addition, the vane link connecting end 182 is further formed at both side ends of the main vane 18, the vane link connecting end 182 is formed at any point spaced apart from the rotating shaft 181. In addition, one end of the vane link 31 is connected to the rotation shaft of the main vane motor 30, and the other end of the vane link 31 is connected to the vane link connection end 182.

In addition, the discharge grill unit 20 further includes a louver assembly for guiding the left and right discharge of air.

In detail, the louver assembly includes a louver motor 28, a louver driving bar 27 connected to the rotation shaft of the louver motor 28, and a plurality of louvers arranged at regular intervals on the louver driving bar 27. 26). In addition, the plurality of louvers 26 are located at the discharge holes 202 of the discharge grill unit 20. Each of the plurality of louvers 26 is connected to both the louver drive bar 27 and the louver mounting hole 203.

5 is a partial perspective view showing the operation of the main vane and the sub vane of the indoor unit according to the embodiment of the present invention.

Referring to FIG. 5, the main vanes 18 and the sub vanes 19 of the indoor unit 1 according to the embodiment of the present invention selectively shield the discharge ports 202 of the discharge grill unit 20, respectively. In addition, the up and down flow of air discharged through the discharge port 202 is controlled.

As described above, rear ends of both side portions of the main vane 18 are rotatably coupled to the discharge grill unit 20 by the rotation shaft 181. One end of the vane link 31 is connected to the main vane 18, and the other end is connected to the rotation shaft of the main vane motor 30.

In detail, the vane link 31 may include a motor side link 311 having one end connected to a rotation shaft of the main vane motor 30 and a vane side link 312 having one end connected to the vane link connecting end 182. ) The other end of the motor side link 311 and the vane side link 312 are rotatably connected to each other.

As shown in the drawing, the main vane motor 30 is connected to a separate vane link 31 instead of directly connected to the rotation shaft 181 of the main vane 18 to rotate the main vane 18. This is to minimize the torque for doing so.

In detail, since the main vane 18 is larger in width and length than the sub vanes 19 or conventional vanes, its main load is relatively large. Therefore, when the drive motor is directly connected to the rotation shaft of the main vane 18, a drive motor having a large rotation torque is required. As a result, not only the size of the drive motor is increased, but also a problem arises that an indoor unit manufacturing cost increases.

However, as in the present embodiment, when the rotation torque acts at a point separated from the rotation center of the main vane 18 by using a separate vane link 31, a drive motor having a relatively small capacity is used. There is an advantage that the main vane 18 can be rotated.

In detail, the vane link 31 is formed by rotatably connecting end portions of the motor side link 311 and the vane side link 312. Therefore, when the main vane motor 30 operates, the motor side link 311 rotates to pull the vane side link 312. As the main vane 18 rotates, the angle formed by the motor side link 311 and the vane side link 312 becomes small. Thus, the vane link 18 is rotatable even when a relatively small amount of rotational torque is applied as compared to the case where a single straight link is used.

1 is an external perspective view of an indoor unit of an air conditioner according to an embodiment of the present invention.

Figure 2 is a perspective view showing a filter extraction structure of the indoor unit according to an embodiment of the present invention.

Figure 3 is a partial perspective view showing the flow of air discharged from the indoor unit according to an embodiment of the present invention.

Figure 4 is an exploded perspective view of the discharge grill unit constituting the indoor unit according to an embodiment of the present invention.

Figure 5 is a partial perspective view showing the operation of the main vane and the sub vanes of the indoor unit according to an embodiment of the present invention.

Claims (7)

Chassis; A fan assembly provided at the front of the chassis; A heat exchanger provided in front of the fan assembly; A discharge grill unit supporting the heat exchanger and having an air outlet; A main vane rotatably provided to the discharge grill unit to selectively shield the air discharge port; A motor mounted to the discharge grill unit to generate power for rotation of the main vane; And And a link member having one end connected to a rotation shaft of the motor and the other end connected to a point spaced apart from the rotation center of the main vane. The method of claim 1, The link is composed of a motor side link, one end of which is connected to the rotating shaft of the motor, and a vane side link, of which one end is connected to the main vane, And the other end of the motor side link and the other end of the vane side link are rotatably connected. The method of claim 2, And a rotation shaft of the motor is disposed at a point spaced apart from a hinge shaft which becomes a rotation center of the main vane. The method of claim 2, In the process of opening and closing the main vane, the air conditioner, characterized in that the angle between the motor-side link and the vane-side link is variable. The method of claim 2, In the process of opening the main vane, the angle formed by the motor side link and the vane side link is increased, And wherein the angle formed by the motor side link and the vane side link decreases while the main vane is closed. The method of claim 1, And a sub vane rotatably connected to the discharge grille at a point spaced apart from the center of rotation of the main vane. The method of claim 6, And an axis of rotation of the motor for driving the sub vanes is directly connected to a hinge axis which is a center of rotation of the sub vanes.

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