KR100420338B1 - A compressor shaking preventing structure for air conditioner - Google Patents

Abstract

The present invention relates to a compressor flow preventing structure of an air conditioner. In the present invention, the flow of the compressor is prevented, and damage to peripheral components caused by the flow of the compressor is prevented. To this end, reinforcing spacers 36 and 66 are formed in the lower air guide 30 and the shroud 60 which are installed adjacent to the compressor 56 so as to maintain a constant distance from the compressor 56. The reinforcement spacers 36 and 36 ′ reinforce the lower guide 30 and the shroud 60 while minimizing the space in which the compressor 56 can flow. And even if the reinforcement spacers 36 and 36 'are damaged by the impact applied by the compressor 56, there is no problem in the functions of the air guide 30 and the shroud 60.

Description

A compressor shaking preventing structure for air conditioner

The present invention relates to an air conditioner, and more particularly, to a compressor flow preventing structure for preventing the flow of a compressor in an integrated air conditioner.

1 is an exploded perspective view showing a main configuration of an integrated air conditioner according to the prior art. Looking at the internal structure of the integrated air conditioner with reference to this, the base fan (1) forms the bottom of the air conditioner. The front grill 3 is installed on the indoor front surface of the base fan 1.

In the front grill 3, a suction part 3i, which is a passage through which air in the room is introduced, is formed at a lower side thereof, and an upper part of the front grill 3 has a discharge grill 3e for discharging the heat exchanged inside the air conditioner to the room Is formed. Although not shown in the drawings, a suction grill (not shown) is installed in the suction unit 3i, and a filter (not shown) is installed between the suction grill and the suction unit 3i.

An indoor heat exchanger 5 is installed inside the front grill 3. The indoor heat exchanger (5) is for heat exchange between the air sucked through the suction unit (3i) and the working fluid of the air conditioning cycle, more precisely installed in the air guide (7) to be described below.

An air guide 7 is installed on the base fan 1 at the rear of the indoor heat exchanger 5. The air guide 7 serves to partition the air conditioner into the indoor side and the outdoor side as a whole. Therefore, the indoor side and the outdoor side are blocked by the air guide 7 to block the flow of air therebetween. At the top of the air guide 7 is formed a brace 8 for connection with the shroud 18 which will be described below.

A scroll 9 is installed inside the air guide 7. The scroll 9 has a flow guide surface 9g formed therein with a predetermined curvature from one side to the other side.

An orifice 11 is installed to correspond to the front surface of the scroll 9, that is, the indoor heat exchanger 5. The orifice 11 is perforated with an orifice hole 12 which guides the air flowing through the indoor heat exchanger 5 to the sirocco fan 13 which will be described below. A discharge guide 11e for guiding the air heat-exchanged with the discharge grill 3e is integrally formed at the upper end of the orifice 11.

Meanwhile, a sirocco fan 13 is installed inside the scroll 9 to allow indoor air to flow through the suction unit 3i, the indoor heat exchanger 5, and the orifice hole 12. The sirocco fan 13 sucks air through the orifice hole 12 and blows it in the centrifugal direction. The blown air is guided along the flow guide surface 9g to the discharge guide 11e. Flows.

The part described so far is the indoor side of the integrated air conditioner, and now describes the configuration of the outdoor side partitioned from the indoor side by the air guide 7.

On the outdoor side of the air guide 7 is mounted a sirocco fan 13 and a motor 15 for rotating the blowing fan 17 to be described below. The motor 15 protrudes in a direction in which the rotation shafts face each other. One of the rotating shafts penetrates the air guide 7 and extends to the center of the scroll 9 to rotate the sirocco fan 13.

And the blower fan 17 is installed on the outdoor rotating shaft of the motor (15). The blower fan 17 serves to exchange heat by sucking outside air to the outdoor side of the air conditioner and passing the outdoor heat exchanger 19 to be described below. The blower fan 17 is provided with a ring 17r for connecting the wing tip thereof.

Next, a shroud 18 for guiding the air flow formed by the blowing fan 17 is installed on the base fan 1. The shroud 18 is formed with a through hole 18 ′ so that air flow is formed in accordance with the rotation of the blowing fan 17 communicating with the outdoor heat exchanger 19 side so that the blowing fan 17 is located. The shroud 18 guides the air sucked from the outside by the blower fan 17 and serves to flow to the entire outdoor heat exchanger 19 to be described below. The shroud 18 is fastened to the channels 19 'provided at both ends of the outdoor heat exchanger 19, and is also connected through the air guide 7 and the brace 8 to support the upper end thereof.

The outdoor heat exchanger 19 is installed on the outdoor side of the base fan 1 so as to face the shroud 18. The outdoor heat exchanger 19 allows the air sucked from the outside and the working fluid of the air conditioning cycle to exchange heat. And a compressor 20 which is a component of an air conditioning cycle is installed on the base fan 1 corresponding to the air guide 7 and the shroud 18.

Finally, the outer case 21 shields the various parts forming the air conditioner as described above from the outside. The outcase 21 as described above constitutes the appearance of the air conditioner.

The integrated air conditioner having such a configuration is used in such a way that the part corresponding to the indoor side is installed in the space for air conditioning and the part corresponding to the outdoor side is outdoors.

However, the integrated air conditioner according to the prior art as described above has the following problems.

The compressor 20 installed in the space corresponding to the shroud 18 and the air guide 7 is particularly easy to shake during transportation of the air conditioner, and the shroud which is an adjacent component due to such shaking. 18) and the air guide (7) to impact. In severe cases by such an impact, the shroud 18 and the air guide 7 may be damaged and leakage may occur.

In order to solve this problem, the shroud 18 and the air guide 7 are relatively widened, and the shroud 18 and the upper end of the air guide 7 are fastened using a brace 8. The relative position between the shroud 18 and the air guide 7 is maintained. However, when the distance between the shroud 18 and the air guide 7 becomes relatively wider, the length of the brace 8 also becomes longer, so that the strength of the brace 8 is weakened, and as a whole, There is a problem that the size increases.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to minimize the flow of the compressor.

Another object of the invention is to reinforce the strength of the parts around the compressor.

Another object of the present invention is to downsize the air conditioner.

1 is an exploded perspective view showing a main configuration of an air conditioner according to the prior art.

Figure 2 is an exploded perspective view showing the main configuration of the air conditioner to which the preferred embodiment of the compressor flow prevention structure according to the present invention is applied.

Figure 3 is a rear perspective view showing the configuration of the air guide constituting the embodiment of the present invention.

Figure 4 is a perspective view showing the configuration of the upper guide constituting the embodiment of the present invention.

Figure 5 is a perspective view showing the configuration of the shroud constituting an embodiment of the present invention.

Figure 6 is a perspective view showing the configuration of the secondary bridge constituting the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

30: Air guide 32: Rear wall

34: through hole 36: reinforcement spacer

37: upright 37 ': cavity

38: control box seat 40: upper air guide

42: discharge port 44: insertion portion

46: fastener 50: motor

52: blower 54: blowing fan

56: compressor 60: shroud

62: through-hole 64: fastening piece

66: fastener 66: reinforcement spacer

67: upright 67 ': cavity

70: auxiliary bridge

According to a feature of the present invention for achieving the object as described above, the present invention is installed at a predetermined interval with the inside during the indoor side air oil to guide the flow of indoor air, and the inside during the air oil at an outdoor side A compressor provided between the inside of the outdoor air oil for guiding the flow of air and between the inside of the indoor air oil and the inside of the outdoor air oil and forming a heat exchange cycle, and the inside of the indoor air oil adjacent to the compressor. And a reinforcing spacer which is integrally formed inside each other during the portion and the outdoor side air oil to reinforce the internal strength during the air oil.

The reinforcing spacer is formed such that the plate-shaped wall projecting on the inner surface during the air oil has a cavity open therein in the direction of the compressor.

The height of the protrusion is determined so that the upper end of the plate-shaped wall of the reinforcement spacer has a constant distance from the compressor.

An auxiliary bridge is further provided for selectively connecting the upper end portion of the inner side during the indoor air oil and the inner side during the outdoor air oil.

According to the present invention having such a configuration, there is an advantage in that the flow of the compressor is prevented and damage of peripheral parts due to the flow of the compressor is prevented, and the air conditioner can be miniaturized as a whole.

Hereinafter, the configuration of a preferred embodiment of the compressor flow preventing structure of the integrated air conditioner according to the present invention having the configuration as described above.

According to FIG. 2 to FIG. 6, in the embodiment of the present invention, the air guide 30 and the air guide 40 which are separately manufactured and assembled in the flow of air in the indoor side are in charge. The lower air guide 30 and the upper air guide 40 also serve to partition the indoor side and the outdoor side.

Through holes 34 are formed in the rear wall 32 of the air guide 30 as described above, and the motor 50 to be described below is seated. In addition, a reinforcement spacer 36 is installed at the outdoor side of the rear wall 32 of the lower air guide 30 as shown in FIG. 3. The reinforcement spacer 36 is formed by protruding upright to the rear wall 32 so that the four upright plates 37 are perpendicular to each other. A cavity 37 'is formed in the upright plate 37 so as to open toward the compressor 56, which will be described below.

The upright plate 37 is preferably formed such that the shape of the upper end, that is, the height of the protruding thereof has a predetermined distance from the shape of the outer peripheral surface of the adjacent compressor (56). Meanwhile, in the illustrated embodiment, the upright plate 37 is formed to have one cavity 37 ', but this is not necessarily the case. ') May be formed. Reference numeral 38 denotes a control box seat.

The upper air guide 40 is installed at the upper end of the lower air guide 30 and is configured to discharge air that has passed through the lower air guide 30 into a space for air conditioning. The upper air guide 40 has a discharge port 42 formed in communication with the lower air guide 30.

And, as shown in Figure 4, the upper side of the upper guide 40 is formed with an insertion portion 44 for connection with the shroud 60 to be described below. The fastening hole 46 is drilled in the insertion portion 44 from the top surface to the bottom. Here, the position where the insertion portion 44 is formed is the opposite portion where the reinforcement spacer 36 is formed.

Meanwhile, a motor 50 is mounted in the through hole 34 of the lower air guide 30, and the blower is installed in the lower air guide 30 to form an air flow in the indoor side of the air conditioner. 52) is installed on one rotation shaft. And the other rotation shaft of the motor 50 is installed in the shroud 60 to be described below, the blowing fan 54 is formed to form an air flow in the outdoor side.

In addition, a compressor 56 is installed between the air guide 30 and the shroud 60. The compressor is mounted on the base fan, and is installed adjacent to the reinforcement spacer 36 of the lower air guide 30.

Next, the configuration of the shroud 60 to guide the flow of air from the outdoor side will be described. The shroud 60 guides the air sucked from the outside by the blower fan 54 from the outside, and a through hole 62 in which the blower fan 54 is installed is formed at the center thereof. 5, the fastening piece 64 is formed at a position corresponding to the insertion portion 44 of the upper guide 40. The fastening hole 65 is formed in the fastening piece 64.

Meanwhile, a reinforcement spacer 66 is formed at one side of the shroud 60 corresponding to the compressor 56. The reinforcement spacer 66 has four upright plates 67 protruding to stand upright on the surface of the shroud 60. These reinforcing spacers 66 are formed to be perpendicular to each other so that the cavity 67 is opened toward the compressor 56 therein. ') Is formed.

And the upper surface of the upright plate 67 is formed to have a predetermined distance from the surface of the compressor 56. Such a reinforcement spacer 66 forms the same function as the reinforcement spacer 36 formed in the lower air guide 30, and only its height is relatively low.

Finally, the auxiliary bridge 70 may be used to connect the upper end of the upper guide 40 and the shroud 60 when necessary. The auxiliary bridge 70 is not necessarily used.

When describing the shape of the auxiliary bridge 70, the insertion piece 72 inserted into the insertion portion 44 of the air guide 40 is bent at one end. In addition, fastening holes 72 and 74 are drilled on both ends of the upper surface of the auxiliary bridge 70 so as to correspond to the fastening hole 46 of the upper air guide 40 and the fastening hole 65 of the shroud 60, respectively. It is.

Hereinafter, the operation of the compressor flow preventing structure of the integrated air conditioner according to the present invention having the configuration as described above will be described.

In this embodiment, the compressor 56 is located between the air guide 30 for guiding the flow of air on the indoor side and the shroud 60 for guiding the flow of air on the outdoor side. More specifically, it is installed between the reinforcement spacer 36 of the lower air guide 30 and the reinforcement spacer 66 of the shroud 60. At this time, the outer surface of the compressor 56 and the reinforcement spacers 36 and 66 are provided at regular intervals.

As such, the reinforcement spacers 36 and 66 are positioned to be adjacent to the surface of the compressor 56 to have a predetermined gap. Such reinforcement spacers 36 and 66 first serve to prevent the compressor 56 from flowing. That is, the reinforcement spacers 36 and 66 and the surfaces of the compressor 56 are adjacent to each other to prevent the compressor 56 from flowing relatively much.

The reinforcement spacers 36 and 66 serve to reinforce the lower air guide 30 and the shroud 60, respectively. That is, the upright plates 37 and 67 are formed on the surfaces of the lower air guide 30 and the shroud 60 so as to meet at right angles to each other to serve as reinforcement.

In addition, the reinforcement spacers 36 and 66 may be damaged by the compressor 56 when a large impact is applied from the outside to the air conditioner and the compressor 56 is greatly flown. Even if damaged, the air guide 30 and the shroud 60 will not interfere with guiding the flow of air.

On the other hand, the upper air guide 40 is assembled to the upper end of the lower air guide 30, the air is sucked in the space for air conditioning by the blower 52 and the air passed through the lower air guide 30 again You will be guided to the space for air conditioning.

The upper guide 40 and the shroud 60 may be connected using the auxiliary bridge 70. However, the connection using the auxiliary bridge 70 is selectively made only when necessary.

Particularly, in the present invention, the spacing between the air guide 30 and the shroud 60 can be relatively reduced by using the reinforcement spacers 36 and 66. In this case, the air conditioner can be miniaturized as a whole. Will be.

As described above, the air conditioner according to the present invention forms a reinforcement spacer on the air guide and the shroud to prevent the compressor from flowing and to withstand the shock applied by the compressor.

Therefore, since the reinforcement spacer is resistant to impact while minimizing the flow of the compressor, the gap between the air guide and the shroud can be narrowed, thereby miniaturizing the air conditioner.

In addition, the strength of the lower air guide and shroud is reinforced by the reinforcing spacer, and even if the reinforcing spacer is primarily damaged due to the impact of the flow of the compressor, there is no effect on the function of the lower guide and shroud. Therefore, the operation reliability of the compressor can be improved.

Claims (4)

The inside of the indoor air oil for guiding the flow of indoor air, An inside of the outdoor air oil installed at a predetermined distance from the inside of the air oil to guide the flow of outdoor air; A compressor installed between the inside of the indoor air oil and the inside of the outdoor air oil to form a heat exchange cycle; Compressor flow of an integrated air conditioner comprising a reinforcing spacer which is formed integrally with the inside of the indoor air during the indoor air and adjacent to the compressor to reinforce the internal strength of the air during the air. Resistant structure. The compressor flow preventing structure according to claim 1, wherein the reinforcing spacer is formed such that a plate-shaped wall protruding from the inner surface of the air oil has a cavity open in the compressor direction. 3. The compressor flow preventing structure of the integrated air conditioner according to claim 1 or 2, wherein the protruding height is determined so that the upper end of the plate-shaped wall of the reinforcing spacer has a predetermined distance between the compressor and the compressor. 4. The compressor flow preventing structure of the integrated air conditioner according to claim 3, further comprising an auxiliary bridge for selectively connecting the inner end of the indoor air oil and the upper end of the inner air oil.