KR20180044684A - Centrifugal blower and Air conditioner having the same - Google Patents

Abstract

The present invention relates to a centrifugal blower and an air conditioner including the same. According to one embodiment of the present invention, the centrifugal blower comprises: a first impeller; a second impeller spaced apart from the first impeller; a scroll housing having a first suction hole formed on one side plate to suck and supply air to the first impeller, and having a second suction hole formed on the other side plate to suck and supply air to the second impeller; and a motor to simultaneously rotate the first and second impellers. The scroll housing includes: a partition formed between the one side plate and the other side plate to be spaced apart from the one side plate and the other side plate, and partitioning a first flow path to receive the first impeller and a second flow path to receive the second impeller; and a discharge unit to discharge the air of the first and second flow paths. The partition includes a pair of partition units spaced apart from each other in left and right directions. Accordingly, provided is an advantage capable of minimizing dew formed on the partition due to a temperature difference between the air sucked through the first suction hole and the air sucked through the second suction hole.

Description

[0001] Centrifugal blower and air conditioner having the same [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a centrifugal blower and an air conditioner having the centrifugal blower. More particularly, the present invention relates to a centrifugal blower for sucking air to blow air in a centrifugal direction and an air conditioner having the same.

The centrifugal blower is an centrifugal blower having an impeller located in the scroll housing, the inlet flow of the impeller is in the direction of the rotational axis and the flow of the outlet of the impeller is in the direction perpendicular to the rotational axis.

When the impeller is rotated, the impeller can flow air, and the air that is flowed by the impeller is guided along the scroll housing and then discharged through the discharge portion.

The centrifugal blower may be classified into a multi-bladed blower, a turbo blower, a plate blower, and the like depending on the structure of the impeller.

The centrifugal blower can be installed in various devices for moving air such as an air conditioner to flow air.

The centrifugal blower may have a suction port formed in each of the both side plates, and a discharge portion may be formed in addition to both side plates. In this case, the centrifugal blower may be configured as a double suction centrifugal blower for sucking air in two directions to blow air.

KR 10-1241730 B1 (Announcement on Mar 08, 2013) KR 1998-048748 A (published on September 15, 1998) KR 10-2016-0006274 A (published Jan. 19, 2016)

An object of the present invention is to provide a centrifugal blower capable of sucking air in both directions to blow air and minimizing dew formation due to temperature differences of air having different temperatures, and an air conditioner having the centrifugal blower.

A centrifugal blower according to an embodiment of the present invention includes a first impeller; A second impeller spaced apart from the first impeller; A scroll housing having a first suction hole formed in one side plate to receive air as a first impeller and a second suction hole in which air is sucked into the second impeller; And a motor for rotating the first impeller and the second impeller together.

The air conditioner having the centrifugal blower includes a centrifugal blower having a first suction hole and a second suction hole spaced from each other; A heat exchanger through which the air sucked into the first suction hole passes; And a filter through which the air sucked into the second suction hole passes, the centrifugal blower including a first impeller; A second impeller spaced apart from the first impeller; A scroll housing having a first suction hole formed in one side plate and a second suction hole formed in the other side plate; And a motor for rotating the first impeller and the second impeller together.

The scroll housing includes a partition wall and a discharge portion.

The partition may be spaced apart from one side plate and the other side plate between one side plate and the other side plate of the scroll housing. The partition defines a first flow path for receiving the first impeller and a second flow path for receiving the second impeller. The barrier rib includes a pair of barrier ribs spaced apart from each other in the left-right direction; And a heat insulating member disposed between the pair of partition walls.

The discharging portion discharges the air of the first flow path and the air of the second flow path.

The heat insulating member may be thicker than each of the pair of partition walls.

The pair of partition walls includes a first partition wall portion having one side facing the first impeller and one side plate facing each other and a second partition wall portion having one side facing the second impeller and the other side plate, .

The first impeller may include a first hub facing the first partition and the second impeller may include a second hub facing the second partition.

The first hub and the second hub may be spaced apart from each other with the first partition wall, the heat insulating member, and the second partition wall. The first hub and the second hub may be connected to each other through a connection portion. And each of the heat insulating member and the second partition wall portion may be formed with a through hole through which the connection portion passes.

The scroll housing may include a scroll portion connecting the one side plate and the other side plate and partially surrounding the outer circumference of the heat insulating member.

According to the embodiment of the present invention, even when the temperature of the air sucked in the first flow path and the temperature of the air sucked in the second flow path are different, it is possible to minimize the formation of dew on the pair of partition walls due to heat insulation by the heat insulating member, The blower has an advantage that the utilization can be increased.

At least a part of the partition is disposed between the first hub of the first impeller and the second hub of the second impeller so that the air flowing by the first impeller and the air flowing by the second impeller are minimized There is an advantage to be able to.

Further, the heat insulating member is protected by the scroll portion, which has a high reliability.

1 is a front view showing a centrifugal blower and an air conditioner having the centrifugal blower according to an embodiment of the present invention;
FIG. 2 is an exploded perspective view of the air conditioner shown in FIG. 1,
3 is a cross-sectional view of the air conditioner shown in Fig.

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

1 is a front view showing a centrifugal blower and an air conditioner having the centrifugal blower according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of the air conditioner shown in FIG. 1, Fig.

The centrifugal blower 16 is attached to the air conditioner to suck air into the inside of the air conditioner and to blow the air inside the air conditioner to the outside of the air conditioner.

The air conditioner may include an air conditioning module (1) for sucking and air-conditioning air and discharging the air to the room. The air conditioner may further include a base 2 placed on the floor of the room.

The air conditioning module 1 can be mounted on the base 2 and the air conditioning module 1 can air inhale the air at a predetermined height in the room. The air conditioning module (1) can constitute a stand type air conditioner together with the base (2).

The centrifugal blower 16 may be a part of the air conditioning module 1 and can suck air into the air conditioning module 1. After the air passes through the inside of the air conditioning module 1, And can be discharged to the outside.

The centrifugal blower 16 may include a scroll housing 50, a first impeller 61, a second impeller 62, and a motor 70.

The scroll housing 50 can form the appearance of the centrifugal blower 16.

The scroll housing 50 may have a space therein in which the first impeller 61 and the second impeller 62 are rotatably received.

The scroll housing 50 may include a spaced-apart side plate 16A and a side plate 16B. The scroll housing 50 may have a first suction hole 17 through which the air is sucked by the first impeller 61 into the one side plate 16A and a second suction hole 17 through the second impeller 62, The second suction hole 18 may be formed.

The scroll housing 50 may further include a partition 52 positioned between the one side plate 16A and the other side plate 16B. The partition 52 may be formed in a space inside the scroll housing 50.

The partition 52 may be spaced apart from the one side plate 16A and the other side plate 16B. The partition 52 may be formed in parallel with the one side plate 16A and the other side plate 16B of the scroll housing 50, respectively. The partition 52 may define a first flow path P1 in which the first impeller 61 is received and a second flow path P2 in which the second impeller 62 is received.

The partition 52 has a pair of partition portions 53 and 54 spaced from each other in the left-right direction; And a heat insulating member 55 disposed between the pair of partition walls 53 and 54.

The pair of barrier ribs 53 and 54 may include a first barrier rib portion 53 and a second barrier rib portion 54.

One side of the first partition wall 53 faces the first impeller 61 and one side plate 16A, and the other side faces the heat insulating member 55. One side of the second partition wall 54 faces the second impeller 62 and the other side plate 16B, and the other side faces the heat insulating member 55.

The first partition wall 53 and the second partition wall 54 may be spaced apart from each other in the thickness direction of the heat insulating member 55. A space for accommodating the heat insulating member 55 may be formed between the first partition 53 and the second partition 54. The heat insulating member 55 may insulate the first partition wall portion 53 and the second partition wall portion 54 between the first partition wall portion 53 and the second partition wall portion 54. [

The heat insulating member 55 may be thicker than each of the pair of partition portions 53 and 54. [ One side of the heat insulating member 55 may be in contact with the first partition wall 53 and the other side may be in contact with the second partition wall 54.

The scroll housing 50 may include a scroll portion 57 connecting one side plate 16A and the other side plate 16B. The scroll portion 57 may be formed in a scroll shape along the outer periphery of the integral impeller 60, which will be described later.

The pair of partition walls 53 and 54 may be integrally protruded from the scroll portion 57 or formed separately from the scroll portion 57 and welded to the inner surface of the scroll portion 57, And is then coupled to the scroll portion 57 by a fastening member such as a screw.

A part of the scroll portion 57 may surround the outer periphery of the heat insulating member 55. [ The heat insulating member 55 is clogged by the scroll portion 57 and can be kept highly reliable without any removal.

The scroll housing 50 may include a discharge portion 59 through which air in the first flow path P1 and air in the second flow path P2 are discharged. The discharge portion 59 may be formed to protrude from the scroll portion 57. The discharge portion 59 may be formed with a discharge path in which the air of the first flow path P1 and the air of the second flow path P2 are discharged and guided in the forward direction. The discharge flow passage may be formed so that the cross-sectional area gradually increases toward the front direction. The discharging portion 59 may be formed to gradually expand toward the front direction.

The centrifugal blower 16 can blow the air sucked through the left suction hole 17 in the forward direction and blow the air sucked in through the right suction hole 18 in the forward direction.

The discharge portion 59 may be formed by separating a first discharge passage through which the air flowing in the first passage P1 passes and a second discharge passage through which air flowing in the second passage P2 passes.

Part of the partition wall 52 is located inside the discharge portion 59 and the inside of the discharge portion 59 can be partitioned into the first discharge passage and the second discharge passage.

The partition wall 52 may include an inner partition wall positioned between the left plate 16A and the right plate 16B and an outer partition wall positioned inside the discharge portion 59. [ The outer barrier ribs may be formed to extend from the inner barrier ribs.

The scroll housing 50 may further include a left orifice 56 positioned in the left suction hole 17 and a right orifice 58 located in the right suction hole 18. [

The left air guide surface 56 may be coupled to the left air plate 16A and the left air guide surface may be formed in which the flow path becomes gradually smaller as the hub 63 of the first impeller 61 gets closer to the inner periphery .

The right op- tical piece 58 can be coupled to the right side plate 16B and the right air guide surface can be formed in which the flow path becomes smaller as the hub 65 of the second impeller 62 gets closer to the inner periphery .

The scroll housing 50 can constitute a housing portion surrounding the left impeller 60 with the left side plate 16A, the right side plate 16B and the scroll portion 57, and the discharge portion is provided in front of this housing portion in the forward direction As shown in Fig.

The first impeller 61 may be rotated together with the second impeller 62.

The first impeller 61 may include a first hub 63 facing the first partition 53. The first impeller 61 may include a first blade 64 disposed in the first hub 63.

The first blade 64 may be formed on the opposite surface of the first hub 63 facing the first partition wall 53 on both surfaces. The first impeller 61 may be a turbo fan or a sirocco fan. The first blade 64 may be a turbofan bladder or a sirocco fan.

The second impeller (62) may be spaced apart from the first impeller (61). The second impeller (62) may include a second hub (65) facing the second partition (54). The second impeller 62 may include a second blade 66 disposed on the second hub 65.

The second blade 66 may be formed on the opposite surface of the opposite surface of the second hub 65 facing the second partition wall 54. The second impeller 62 may be a turbo fan or a sirocco fan, and the second blade 66 may be a turbofan bladder or a sirocco fan.

The second hub 65 of the second impeller 62 may be spaced apart from the first hub 63 of the first impeller 61. The second hub 65 of the second impeller 62 may be spaced apart from the first hub 63 of the first impeller 61 with the partition 52 therebetween. The second hub 65 of the second impeller 62 is connected to the first hub 51 of the first impeller 61 via the first partition 53, the heat insulating member 55 and the second partition wall 54 63, respectively.

A gap G may be formed between the second hub 65 and the first hub 63 to locate a part of the partition 52. The gap G between the second hub 65 and the first hub 63 may be larger than the thickness T of the partition wall 52. [

A part of the partition wall 52 can be disposed between the first hub 63 and the second hub 65 and the air in the first flow path P1 and the air in the second flow path P2 are mixed with each other Can be minimized.

The centrifugal blower 16 can integrate the first impeller 61 and the second impeller 62 into one body. In this case, the first impeller 61 and the second impeller 62 are connected to each other through the connecting portion 67, Lt; / RTI >

One end of the connecting portion 67 may be connected to the first hub 63 and the other end of the connecting portion 67 may be connected to the second hub 63. The connecting portion 67 may connect the first hub 63 and the second hub 65, May be connected to the hub (65).

The connecting portion 67 may be formed into a cylindrical shape or a hollow cylindrical shape.

The diameter D of the connecting portion 67 may be smaller than the diameter of the first hub 63 and the diameter of the second hub 64. [

The centrifugal blower may include an integral impeller 60 in which a first impeller 61 and a second impeller 62 are connected to each other by a connecting portion 67. The integral impeller 60 includes two hubs 63 and 65, May be connected to the connecting portion 67 to constitute a dual hub double suction impeller.

A through hole 51 through which the connection portion 67 can be rotatably formed may be formed in the partition 52. That is, the through holes 51 may be formed in the first partition 53, the heat insulating member 55, and the second partition 54 to allow the connection portion 67 to rotate therethrough.

The motor 70 may rotate the first impeller 61 and the second impeller 62 together. The rotation axis of the motor 70 can be arranged horizontally. The rotation axis of the motor 70 may be connected to at least one of the first hub 63 and the second hub 65.

Since the centrifugal blower includes the integral impeller 60 in which the first impeller 61 and the second impeller 62 are integrated and the rotary shaft of the motor 70 is connected to the integral impeller 60, There is an advantage in that the assembling process is simpler than when the rotating shaft of the motor 70 is connected.

The motor bracket 72 can be engaged with one of the scroll portion 57 and the left orifice 56 and the right orifice 58 of the scroll housing 50 and the motor 70 is seated on the motor bracket 72 The motor mount 74 can be coupled.

The rotation axis of the motor 70 can be arranged horizontally, and the integral impeller 60 can be rotated about the horizontal rotation axis.

Centrifugal blower 16 may include at least one dual suction centrifugal fans 41, 42, The centrifugal blower 16 may be configured such that a plurality of both suction centrifugal fans 41, 42, and 43 are connected.

If the centrifugal blower 16 includes two dual suction centrifugal fans, the two dual suction centrifugal fans may include an upper dual suction centrifugal fan and a lower dual suction centrifugal fan disposed below the upper dual suction centrifugal fan have.

When the centrifugal blower 16 includes three or more both-suction centrifugal fans, the three or more both-suction centrifugal fans include an upper-side two-suction centrifugal fan located at the uppermost position, a lower-side both-suction centrifugal fan located at the lowest position, And at least one central double-suction centrifugal fan 42 disposed between the upper dual-suction centrifugal fan 41 and the lower dual-suction centrifugal fan 43.

Each of the plurality of double suction centrifugal fans 41, 42 and 43 includes a scroll housing 50, an integral impeller 60 housed in the scroll housing 50, and a motor 70 connected to the integral impeller 60 .

The centrifugal blower 16 may be long in the vertical direction and short in the lateral direction. The centrifugal blower 16 may further include a thick plate 16D, an upper plate 16E and a lower plate 16F.

The centrifugal blower 16 may further include a horizontal plate 44 disposed between two vertically adjacent two-suction centrifugal fans.

The upper plate 16E of the centrifugal blower 16 is located at the upper part of the both suction centrifugal fans located at the uppermost one of the plurality of both suction centrifugal fans and can form an upper surface appearance of the centrifugal blower.

The lower plate 16F of the centrifugal blower 16 is positioned below the both suction centrifugal fans located at the lowermost one of the plurality of both suction centrifugal fans and can form the bottom surface of the centrifugal blower.

The horizontal plate 44 may be disposed at least one between the upper plate 16E and the lower plate 16F of the centrifugal blower 16. [

The horizontal plate 44 can be spaced apart from the upper plate 16E and the lower plate 16F of the centrifugal blower 16 and between the upper plate 16E and the lower plate 16F of the centrifugal blower 16, And can be partitioned into fan receiving portions.

The suction fan 50 can be connected to the horizontal plate 44 and the lower suction plate 50 can be connected to the horizontal plate 44. [ .

The horizontal plate 44 can be connected to the lower portion of the scroll housing 50 of the both suction centrifugal fans located on the relatively upper side among the adjacent both suction centrifugal fans and can be connected to the scroll housing 50 of the lower suction centrifugal fan 50).

The centrifugal blower 16 can rotate the first impeller 61 and the second impeller 62 together when the motor 70 is driven.

The air on the left side of the left side plate 16A flows into the first impeller 61 and flows along the first flow path P1 when the first impeller 61 and the second impeller 62 rotate, The air on the right side of the first impeller 16B may flow into the second impeller 62 and flow along the second flow path P2.

The temperature of the air flowing along the first flow path P1 and the air flowing along the second flow path P2 may be different by a heat exchanger or the like located around the centrifugal blower 16. [

For example, the air flowing along the first flow path P1 may be heat-exchanged air heated or cooled by the heat exchanger through which the refrigerant passes, and the air flowing along the second flow path P2 is heat- In this case, air passing through the first flow path P1 and air passing through the second flow path P2 may have a temperature difference.

For example, the air flowing along the first flow path P1 may be the low temperature air cooled by the evaporator through which the refrigerant passes, and the air flowing along the second flow path P2 flows through the condenser In this case, the air passing through the first flow path P1 and the air passing through the second flow path P2 may have a temperature difference.

For example, the air flowing along the first flow path P1 may be indoor air flowing in the room, and the air flowing along the second flow path P2 may flow outside the room, In this case, the air passing through the first flow path P1 and the air passing through the second flow path P2 may have a temperature difference.

The partition 52 of the present embodiment is provided with the heat insulating member 55 between the first partition wall portion 53 forming the first flow path P1 and the second partition wall portion 54 forming the second flow path P2 And the heat insulating member 55 can minimize the heat transfer between the first partition wall portion 53 and the second partition wall portion 54. The heat insulating member 55 is disposed between the first partition wall portion 53 and the second partition wall portion 54, It is possible to minimize the formation of dew on the surface of at least one of the plurality of nozzles 54.

Hereinafter, an example in which the centrifugal blower 16 is installed in the air conditioner will be described.

The air conditioner may have a left air inlet 11 and a right air inlet 12 so that the air in the room can be quickly sucked. The air conditioner may include a left suction body 13 formed with a left air intake port 11 and a right suction body 14 formed with a right air intake port 12. [

The front air outlet 15 may be formed on the front surface of the air conditioner so that the air conditioner concentrically discharges air, which is air-conditioned inside, in the front direction of the air conditioner.

That is, the front surface of the air conditioner may be provided with a front air outlet 15 through which air circulated in the front of the air conditioner can be discharged in the front direction of the air conditioner.

The front air outlet 15 may be long in the vertical direction on the front surface of the air conditioner and may be short in the lateral direction. The air discharged from the air conditioner to the outside can be a long front discharge air stream in the vertical direction while being concentrated toward the front of the center of the air conditioner.

The left suction body 13 and the right suction body 14 may be spaced apart from each other with a centrifugal blower 16, which will be described later, interposed therebetween. Each of the left suction body 13 and the right suction body 14 may be rounded or bent in a direction in which the front portion and the rear portion are brought close to each other.

The left suction body 13 and the right suction body 14 may be arranged so as not to block the front air outlet 15. [ The lateral distance L1 between the front end of the left suction body 13 and the front end of the right suction body 14 may be longer than the lateral width L2 of the front air outlet 15.

The left suction body 13 may be positioned on the left side of the left frame 31 and the front end of the left suction body 13 may cover a part or the whole of the left frame 31. The rear end of the left suction body 13 may be disposed on the left frame 31, Or a part of or the whole of the back surface of the substrate.

On the other hand, the right suction body 14 can be positioned on the right side of the right frame 32, which will be described later, and the front end thereof can be disposed so as to cover part or all of the front face of the right frame 32, (Not shown).

The air conditioner may further include a heat exchanger 20 through which the air sucked into the first suction hole 17 passes and a filter F through which the air sucked into the second suction hole 18 passes.

The heat exchanger 20 may be a side heat exchanger disposed on the side of the centrifugal blower 16. The heat exchanger 20 and the filter F may be spaced laterally with the centrifugal blower 16 therebetween.

The heat exchanger (20) may be arranged so that at least a part of the heat exchanger (20) faces the first suction hole (17). The heat exchanger 20 may be formed larger than the first suction hole 17.

The air flowing toward the first suction hole 17 when the first impeller 62 rotates is heated or cooled while passing through the heat exchanger 20 and then flows through the first suction hole 17 to the first flow path P1 Lt; / RTI >

The heat exchanger 20 may be a refrigerant-air heat exchanger such as a fin-tube type heat exchanger or a micro-channel tube heat exchanger for exchanging heat between air and refrigerant.

During the cooling operation of the air conditioner, the low-temperature low-pressure refrigerant can flow into the heat exchanger 20 and the air passing through the heat exchanger 20 can be cooled by heat exchange with the low-temperature and low-pressure refrigerant.

The filter F may be disposed at least partially facing the second suction hole 18 so that the air flowing toward the second suction hole 18 during rotation of the second impeller 62 passes through the filter F It is possible to suck foreign matter such as dust or smell particles into the second flow path P2 through the second suction hole 17 while passing through the filter.

The filter F may comprise at least one air purifying filter. The air purifying filter may be a dust filter such as a HEPA filter or an electrostatic dust filter that filters fine dust smaller than the pre-filter 21, or an activated carbon filter or a carbon filter for removing odors.

The air purifying filter can be disposed in the order of the deodorizing filter and the dust collecting filter in the air flow direction.

The air conditioner may include at least one frame 31 (32) that supports the centrifugal blower (16). The frames 31 and 32 may be formed with openings 31A and 31B through which air can pass in the lateral direction.

The air conditioner may further include a left frame (31) and a right frame (32).

The left frame 31 and the right frame 32 can be spaced laterally with the centrifugal blower 16 interposed therebetween.

The left frame 31 can be disposed on the left side of the centrifugal blower 16 and the heat exchanger 20 can be received in the opening 31A formed in the left frame 31. [

The right frame 32 may be disposed on the right side of the centrifugal blower 16. The filter F may be accommodated in the opening 31B formed in the right frame 32 or disposed beside the right frame 32. [

The air conditioner may be provided with a front air discharge port 15 between the left frame 31 and the right frame 32 in which air having passed through the discharge portion 59 is discharged to the outside.

The air conditioner may include a left prefilter 21 disposed between the left air intake port 11 and the heat exchanger 20. [ The air conditioner may further include a right pre-filter (22) disposed between the right air inlet (12) and the filter (F).

On the other hand, the centrifugal blower 16 may include a left fastening plate 59A fixed to the left frame 31 and a right fastening plate 59B fixed to the right frame 32. [

The left fastening plate 59A and the right fastening plate 59B may be formed so as to protrude from the scroll housing 50.

The left fastening plate 59A may be formed to protrude leftward from the rear portion of the scroll housing 50. The left fastening plate 59A may be arranged to cover at least a part of the rear surface of the left frame 31 and may be fastened to the left frame 31 by fastening members such as screws or hooks such as hooks.

The right fastening plate 59B may be formed to protrude rightward from the rear portion of the scroll housing 50. The right fastening plate 59B may be disposed to cover at least a part of the rear surface of the right frame 32 and may be fastened to the right frame 32 by a fastening member such as a screw or a hook such as a hook.

The left fastening plate 59A can serve as a left shielding portion for covering the left side plate 16A of the scroll housing 50 and the left frame 31 and the right fastening plate 59B can function as a left side shielding portion for covering the right side plate 16A of the scroll housing 50 16B and the rear end of the right frame 32. [0064] FIG.

The air conditioner air conditioner may include at least one air conditioning member (80) (82) for adjusting the airflow direction of air discharged to the air outlet (15).

The wind direction adjusting members 80 and 82 can be rotated to open and close the air outlet 15. The wind direction adjusting members 80 and 82 may be arranged to be rotated in opposite directions to each other.

The wind direction adjusting members 80 and 82 can be arranged to be rotated around the vertical center axis and can open the front air outlet 15 when it is rotated to protrude in the opposite direction of the centrifugal blower 16, The air blown from the blower 16 can be guided to be discharged in the forward direction of the air conditioner.

The wind direction adjusting members 80 and 82 are provided on the left frame 31 or the centrifugal blower 16 and the left wind direction adjusting member 80 provided on the right frame 32 or the centrifugal blower 16, 82).

The left wind direction adjusting member 80 and the right wind direction adjusting member 82 can shield the front air outlet 15 when they are rotated close to each other and protect the centrifugal blower 16 at this time.

Hereinafter, the operation of the present embodiment will be described.

First, when the motor 70 is driven, the air around the left air intake port 11 can pass through the left air intake port 11 and be sucked into the air conditioner. This air can be heat exchanged with the heat exchanger 20 while passing through the heat exchanger 20 and can be colder or hotter than air at room temperature by the refrigerant passing through the heat exchanger 20. [ The heat exchanged air with the heat exchanger 20 can flow along the first flow path P1 through the left side plate 16A of the centrifugal air blower 16. [

On the other hand, the air around the right air intake port 12 can pass through the right air intake port 12 and be sucked into the air conditioner. Such air can pass through the filter (F), and the foreign matter can be filtered by the filter (F). The air having passed through the filter F is clean air at room temperature that has passed through the filter F without heat exchange with the filter F. The clean air at room temperature passes through the right side plate 16B of the centrifugal air blower 16, Can flow along the two flow paths (P2).

When the air guided along the first flow path P1 is heat exchanged air having a temperature higher than or lower than room temperature and air guided along the second flow path P2 is air at room temperature, the temperature of the first partition wall 53 The temperature of the second partition wall portion 54 may be different.

The heat exchange between the first partition wall portion 53 and the second partition wall portion 54 can be minimized by the heat insulating member 55 between the first partition wall portion 53 and the second partition wall portion 54 , And dew formation on the outer surface of the partition 52 can be minimized.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

16: Centrifugal blower 16A: Left side plate
16B: right side plate 17: first suction hole
18: second suction hole 20: heat exchanger
50: scroll housing 51: through hole
52: partition wall 53: first partition wall section
54: second partition wall portion 55:
57: scroll part 59: discharge part
60: integral impeller 61: first impeller
62: second impeller 63: first hub
65: second hub 67:
70: Motor F: Filter

Claims (12)

A first impeller;
A second impeller spaced apart from the first impeller;
A scroll housing having a first suction hole formed in the first side plate for sucking air through the first impeller and a second suction hole formed in the other side plate for sucking air into the second impeller;
And a motor for rotating the first impeller and the second impeller together,
The scroll housing
A partition wall spaced apart from the one side plate and the other side plate between the one side plate and the other side plate and defining a first flow path for receiving the first impeller and a second flow path for receiving the second impeller;
And a discharge portion through which the air of the first flow path and the air of the second flow path are discharged,
The partition wall
A pair of partition walls spaced in the left and right direction;
And a heat insulating member disposed between the pair of partition walls. The method according to claim 1,
Wherein the heat insulating member is thicker than each of the pair of partition walls. The method according to claim 1,
The pair of partition walls
A first partition wall facing the first impeller and the one side plate, the first partition wall facing the heat insulating member,
And a second partition wall having one surface facing the second impeller and the other side surface facing the heat insulating member. The method of claim 3,
Wherein the first impeller includes a first hub facing the first partition,
And the second impeller includes a second hub facing the second partition. 5. The method of claim 4,
Wherein the first hub and the second hub are spaced apart from each other by the first partition wall, the heat insulating member, and the second partition wall,
The first hub and the second hub are connected to each other through a connection portion,
Wherein the first partition wall, the heat insulating member, and the second partition wall are each provided with a through hole through which the connection portion passes. The method according to claim 1,
Wherein the scroll housing includes a scroll portion that connects the one side plate and the other side plate and partially surrounds the outer periphery of the heat insulating member. A centrifugal blower spaced apart from the first suction hole and the second suction hole;
A heat exchanger through which the air sucked into the first suction hole passes;
And a filter through which the air sucked into the second suction hole passes,
The centrifugal blower
A first impeller;
A second impeller spaced apart from the first impeller;
A scroll housing having the first suction hole formed in one side plate and the second suction hole formed in the other side plate;
And a motor for rotating the first impeller and the second impeller together,
The scroll housing
A partition wall spaced apart from the one side plate and the other side plate between the one side plate and the other side plate and defining a first flow path for receiving the first impeller and a second flow path for receiving the second impeller;
And a discharge portion through which the air of the first flow path and the air of the second flow path are discharged,
The partition wall
A pair of partition walls spaced in the left and right direction;
And a heat insulating member disposed between the pair of partition walls. 8. The method of claim 7,
Wherein the heat insulating member has a centrifugal blower thicker than each of the pair of partition portions. 8. The method of claim 7,
The pair of partition walls
A first partition wall facing the first impeller and the one side plate, the first partition wall facing the heat insulating member,
And a second partition wall facing one end of the second impeller and the other side face of the second impeller facing the other side face of the second impeller. 10. The method of claim 9,
Wherein the first impeller includes a first hub facing the first partition,
And the second impeller includes a second hub facing the second partition wall. 11. The method of claim 10,
The first hub and the second hub are spaced apart from each other by the first partition wall, the heat insulating member, and the second partition wall,
The first hub and the second hub are connected to each other through a connection portion,
Wherein the first partition wall, the heat insulating member, and the second partition wall are each provided with a through hole through which the connection portion rotatably passes. 8. The method of claim 7,
Wherein the scroll housing includes a scroll portion connecting the one side plate and the other side plate and partially surrounding the outer periphery of the heat insulating member.

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