KR20010104466A - Air conditioner - Google Patents

Abstract

The present invention relates to an air conditioner. The present invention relates to an orifice (45) configured to maximize the efficiency of the turbo fan (60) in an integrated air conditioner. The orifice 45 partitions between the turbo fan 60 and the indoor heat exchanger 40 so that air passing through the indoor heat exchanger 40 flows to the turbo fan 60 without leakage. To this end, an insertion protrusion 47 ′ is formed at an edge of the orifice hole 47 of the orifice 45 to be inserted into the turbo fan 60. And do not form another structure on the upper end of the orifice 45, in the installation of the orifice 45 between the turbo fan 60 and the indoor heat exchanger 40, it is possible to adopt a variety of methods and orders have.

Description

Integrated Air Conditioner {Air conditioner}

The present invention relates to an air conditioner, and more particularly, to an integrated air conditioner that is configured to guide the flow of air that is sucked indoors in an integrated air conditioner and passes through the indoor heat exchanger and discharged back to the room.

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 air heat-exchanged inside the air conditioner back into 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.

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. The orifice 11 has a discharge guide 11e formed at an upper end thereof, so that a top-down inserted between the indoor heat exchanger 5 and the sirocco fan 13 from the top to the lower part during the actual assembly. Assembled in the down method.

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 ′ communicating with the outdoor heat exchanger 19 side such that the blowing fan 17 is located.

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. Although not shown in the drawings, the outdoor side is provided with a compressor, an expansion valve, and the like that are components of an air conditioning cycle.

Finally, the outer case 20 shields the various parts forming the air conditioner as described above from the outside. The outcase 20 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.

On the other hand, looks at the air conditioner is operated for cooling. That is, when the air conditioner is driven, the air conditioning cycle is operated and the motor 15 rotates the sirocco fan 13 and the blowing fan 17.

Therefore, in the indoor side, air in the space for air conditioning is delivered to the indoor heat exchanger 5 via the suction part 3i. The air exchanges heat with the working fluid while passing through the indoor heat exchanger 5 to a relatively low temperature.

And the heat exchanged air by the rotation of the sirocco fan 13 is transmitted to the sirocco fan 13 through the orifice hole (12). The air sucked into the sirocco fan 13 through the center portion is guided and discharged in the centrifugal direction of the sirocco fan 13 and is guided along the flow guide surface 9g of the scroll 9 to discharge the guide 11e. Is delivered to.

The low temperature air delivered to the discharge guide 11e is discharged into the space for air conditioning through the discharge grill 3e.

On the other hand, the outdoor side is the operation of discharging the heat received by the working fluid from the indoor heat exchanger (5) to the outside. That is, the blower fan 17 is sucked into the outdoor side of the air conditioner of the outside air and passes through the outdoor heat exchanger 19 to exchange heat with the working fluid to release heat to the outside.

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

First, the orifice 11 is formed at the upper end of the air guide 7 and the discharge guide (11e) placed on the upper end of the scroll 9 integrally formed so that the air guide 7 and the scroll (9) It must be assembled after installation. Therefore, there is a problem that the order is much limited in establishing the assembly process in the field.

In addition, since the discharge guide 11e is formed integrally with the orifice 11, there is a problem in that the molding is subject to many restrictions.

In addition, since the orifice 11 is assembled in the top-down manner as described above, there is a problem that a lot of restrictions are placed on the shape of the sirocco fan 13 corresponding to the orifice 11. That is, the orifice 11 installed on the front side of the sirocco fan 13 must deliver the air passing through the indoor heat exchanger 5 to the sirocco fan 13 without leakage, and when assembled in the top-down manner. In the sirocco fan 13 and the orifice 11 facing each other is formed in a plane is bound to be in contact with each other. Even in this case, there is a problem in that a gap occurs due to various tolerances between the sirocco fan 13 and the orifice 11 and leakage occurs.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide an air conditioner orifice having a simpler and more various assembly method.

Another object of the present invention is to provide an orifice having a configuration in which an orifice and a fan can be fastened to each other.

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 internal configuration of an integrated air conditioner having an orifice of a preferred embodiment of the present invention.

Figure 3 is a perspective view showing a turbofan constituting a preferred embodiment of the present invention.

4 is a cross-sectional view taken along the line AA ′ of FIG. 2.

Explanation of symbols on the main parts of the drawings

30: base fan 35: front grill

36: suction part 37: discharge grill

40: indoor heat exchanger 45: orifice

46: partition 47: orifice ball

47 ': Insertion protrusion 48,48': 1st side wall part

49,49 ': second side wall portion 50: air guide

55: motor 60: turbo fan

62: hub 64: blade

66: shroud 70: blowing fan

72: ring 75: shroud

80: outdoor heat exchanger 85: discharge guide

87: discharge portion 89: guide portion

90: outer case

According to a feature of the present invention for achieving the above object, the present invention is a heat exchanger having an indoor heat exchanger for heat exchange with the air of the space for air conditioning and an outdoor heat exchanger for heat exchange with the outside air of the space A cycle, a partition member for partitioning the indoor heat exchanger side and the outdoor heat exchanger side, a turbo fan for forming a flow of air at the indoor heat exchanger side, and a blower fan for forming a flow of air at the outdoor heat exchanger side And an orifice installed between the turbofan and the indoor heat exchanger to guide the air passing through the indoor heat exchanger to the turbofan.

The orifice has a through hole communicating with an indoor heat exchanger side and the turbo fan side at the center thereof, and an insertion rib is formed around the through hole so as to protrude toward the turbo fan side and positioned inside the turbo fan. In addition to forming a flow path for the flow of air on both sides of the through hole at the same time is further provided with a fastening portion for fastening with the peripheral components.

It further comprises a discharge guide provided on the top of the turbo fan and the partition member to guide the air discharged from the turbo fan to the space for air conditioning.

According to the present invention having such a configuration, it is possible to maximize the efficiency of the turbo fan by preventing the occurrence of gaps between the turbo fan and the orifice forming the flow of air in the room side, by forming only the orifice separately from the turbo fan and There is an advantage to be able to diversify the fastening method.

On the other hand, conventional injection molding parts such as the orifice 45, the air guide 50, the shroud 75, the discharge guide 85 is formed using an ultra-foaming method of the polymer material. The ultra-foaming method is to supply the fluid in the supercritical state to the polymer material to be injected or extruded so that relatively small bubbles are uniformly distributed therein.

Products formed by such a method has the advantage that the relatively small bubbles are uniformly distributed therein to increase the strength while lightening the product, and the soundproofing and heat insulating properties are improved.

Hereinafter, a preferred embodiment of the air conditioner according to the present invention as described above will be described in detail with reference to the accompanying drawings.

As shown in FIG. 2, in the present embodiment, the base fan 30 forms the bottom of the air conditioner. The base fan 30 is provided with various components forming an air conditioner.

The front grill 35 is installed at the indoor side of the base fan 30. The front grill 35 is formed with a suction part 36 through which air in a space for air conditioning is sucked into the air conditioner. The suction part 36 is formed to occupy approximately the lower half of the front grill 35. In addition, an upper part of the front grill 35 is provided with a discharge grill 37 for discharging the heat-exchanged air into the space for air conditioning.

And the indoor heat exchanger 40 is installed to correspond to the front grill 35, more precisely the suction unit 36. The indoor heat exchanger (40) constitutes a heat exchange cycle in which a working fluid flows therein to exchange heat with air passing through the indoor heat exchanger (40).

An orifice 45 for guiding air passing through the indoor heat exchanger 40 is installed at the rear of the indoor heat exchanger 40. The orifice 45 is formed with a square plate partition wall 46 for partitioning between the indoor heat exchanger 40 and the turbo fan 60 to be described below, the center of the partition wall 46 is heat exchanged indoors The orifice hole 47 which guides the air which passed through the machine 40 to the turbofan 60 is drilled. At the edge of the orifice hole 47, an insertion rib 47 'protruding to be inserted into the turbo fan 60 is formed.

The first and second side wall portions 48 and 48 'and 49 and 49' are formed at both ends of the partition wall 46, respectively. The first side wall portions 48 and 48 'are connected to both ends of the indoor heat exchanger 40, respectively, to prevent air from leaking around the orifice 45 and at the same time with the indoor heat exchanger 40. It serves to support and fix the peripheral parts. The second side wall portions 49 and 49 'are formed on opposite sides of the first side wall portions 48 and 48', and are coupled to the air guide 50 to be described below. 49 ') serves to form a flow path of the air guide side 50.

On the other hand, the orifice 45 is installed between the indoor heat exchanger 40 and the air guide 50, the lower end of the indoor heat exchanger 40 is located on the lower surface of the air guide 50. The air guide 50 is installed on the base fan 30 to serve to partition the indoor side and the outdoor side in the air conditioner.

On the outdoor side of the air guide 50, a motor 55 for driving the turbo fan 60 and the blowing fan 70 to be described below is mounted. Of course, the motor 55 may be mounted through a separate bracket according to the design condition of the air conditioner. The motor 55 is provided such that the rotating shaft protrudes at both ends thereof to rotate the turbo fan 60 and the blowing fan 70 at the same time.

Here, the turbo fan 60 for producing the air flow on the indoor side will be described. The turbo fan 60 sucks air through the suction part 36 in the room side, that is, the space for air conditioning, heat-exchanges through the indoor heat exchanger 40, and discharges the air to the space for air conditioning again. To provide the driving force.

An example of such a turbofan 60 is shown well in FIG. 3. As shown in the drawing, a hub 62 is provided at one center of the motor 55 to be connected to the rotating shaft of the motor 55. At the end where the hub 62 extends in the circumferential direction, a plurality of blades 64 are installed along the edge thereof. The blade 64 is formed orthogonal to the portion extending from the hub 62.

The blade 64 has a blade exit angle smaller than 90 ° and has a backward curved blade having an inner and outer ratio smaller than 0.8. In addition, the blade 64 is formed to have a rotating streamlined structure, and the inlet width at which air is guided to the blade 64 is formed larger than the outlet width.

The shroud 66 is integrally formed on the blade 64 on one side of the blade 64, that is, on the opposite side to which the hub 62 is provided. The shroud 66 is formed to connect all of the plurality of blades 64, in particular connected to the blades 64 along the narrowing side of the blade 64. The shroud 66 serves to guide the flow of air flowing along the blade 64 so that the air passing between the blades 64 adjacent to each other is discharged with a predetermined wind pressure.

Next, the blower fan 70 is installed at the outdoor side to be driven by the motor 55. The blower fan 70 is installed and driven on the rotating shaft of the motor 55, and sucks air from the outside (outside) of the air conditioner and passes the outdoor heat exchanger 80 to be described below. Allow heat exchange. A ring 72 is installed to connect the tip of the blower fan 70. The ring 72 serves to splash the condensed water on the bottom surface of the base fan 30 to the outdoor heat exchanger 80 when the blowing fan 70 rotates.

On the other hand, a shroud 75 for guiding the air flow formed by the blowing fan 70 is installed on the base fan 30. A through hole 76 is formed through the center of the shroud 75 in which the blowing fan 70 is located.

The outdoor heat exchanger 80 is installed on the base fan 30 so as to face the shroud 75. The outdoor heat exchanger 80 exchanges heat with the working fluid while the air sucked from the outside of the air conditioner by the blower fan 70 passes.

Next, a discharge guide 85 that guides the air discharged from the turbo fan 60 to the discharge grill 37 is installed at an upper end of the air guide 50. The discharge guide 85 is formed with a discharge portion 87 in communication with the interior of the air guide 50, the turbo fan 60 is installed, and discharge the air passing through the discharge portion 87 to the discharge grill (37) The guide part 89 which guides to) is formed. The discharge guide 85 is also provided with a brace 86 for fastening with the shroud 75.

The various components described above are shielded from the outside by the outer case 90. The outer case 90 is provided with an air through part 92 for the air flowing in and out of the air conditioner by the blowing fan 70.

Hereinafter, the operation of the air conditioner according to the present invention having the configuration as described above in detail.

In the present invention, the turbo fan (60) to create a flow of air is sucked into the interior of the air conditioner in the room for air conditioning, the heat exchanged while passing through the indoor heat exchanger 40 and discharged back to the room space In order to provide maximum efficiency, the turbo fan 60 is provided with an orifice 45 that is coupled to the turbo fan 60.

That is, an insertion protrusion 47 'is formed at an edge of the orifice hole 46 of the orifice 45 to be inserted into the shroud 66 of the turbo fan 60 so as to be inserted into the orifice 45 and the turbo fan. The leakage between the (60) is prevented from occurring.

In this case, in order to more reliably couple the orifice 45 and the turbo fan 60, no other structure is formed at the upper end of the orifice 45. In this way, when assembling the orifice 45 to the turbo fan 60, not only can it be inserted from the front of the turbo fan 60, but also it can be assembled using a top-down method or a slide method.

Here, the slide type means that the insertion protrusion 47 ′ is spaced apart so as not to interfere with the turbo fan 60 in assembling the orifice 45 from the top between the turbo fan 60 and the indoor heat exchanger 40. After being inserted into the state, when the insertion protrusion 47 'comes to a position in front of the turbo fan 60, it is to be inserted into the turbo fan 60 from the front.

On the other hand, since no other structure is formed at the upper end of the orifice 45, the assembling of the orifice 45 can be performed in more various ways. Therefore, the work can be performed in a variety of ways and order with respect to the assembly of the orifice 45 in the workplace, it is possible to facilitate the design work of the orifice 45 and related parts.

As described above, the air conditioner according to the present invention does not integrally form another structure at the upper end of the orifice which is located between the indoor heat exchanger and the turbofan and guides the air passing through the indoor heat exchanger to the turbofan. The effect of being able to employ various assembly methods and assembly order can be obtained.

And since the orifice and the turbo fan is configured to be coupled in such a way that one side is inserted into the other side there is an advantage that can not maximize the efficiency of the turbo fan because the leakage of air does not occur between them.

Claims (3)

A heat exchange cycle including an indoor heat exchanger for heat exchange with air in a space for air conditioning and an outdoor heat exchanger for heat exchange with outside air in the space; A partition member partitioning the indoor heat exchanger side and the outdoor heat exchanger side; A turbo fan for forming a flow of air at the indoor heat exchanger side; A blowing fan forming a flow of air at the outdoor heat exchanger; And an orifice installed between the turbo fan and the indoor heat exchanger to guide the air passing through the indoor heat exchanger to the turbo fan. According to claim 1, wherein the orifice is provided in the center of the through-hole for communicating the indoor heat exchanger side and the turbofan side, The periphery of the through-hole is formed to protrude toward the turbo fan side is inserted ribs located inside the turbo fan, An integrated air conditioner is formed at both ends thereof, further comprising a fastening part for fastening the peripheral parts while forming a flow path for air flow at both sides of the through hole. The integrated air conditioner according to claim 1 or 2, further comprising a discharge guide provided at an upper end of the turbo fan and the partition member to guide the air discharged from the turbo fan to a space for air conditioning. group.