KR102061157B1 - Heat exchange and air conditioner having the same - Google Patents

Abstract

The air conditioner is in communication with the housing, the refrigerant inlet pipe into which the refrigerant flows in, the refrigerant outlet pipe, the refrigerant inlet pipe, and the refrigerant outlet pipe, and includes a heat exchanger provided inside the housing to exchange heat with external air. And a first circular tube heat exchanger and a first circular tube heat exchanger for exchanging heat through a circular tube in which a refrigerant flows, and a tubular heat exchanger and a tube type heat exchanger for exchanging heat through a plate-shaped tube in which a refrigerant flows. It characterized in that it comprises a second circular tube heat exchanger for discharging the refrigerant to the refrigerant outlet pipe by heat exchange through the circular pipe flows. Through this configuration, there is no overheating or subcooling section of the heat exchanger, thereby maximizing heat transfer performance.

Description

Heat exchanger and air conditioner having same {HEAT EXCHANGE AND AIR CONDITIONER HAVING THE SAME}

The present invention relates to a heat exchanger and an air conditioner having the same, and more particularly, to a heat exchanger having a structure for improving the heat transfer performance of the heat exchanger and an air conditioner having the same.

In general, an air conditioner is a device that removes dust in the air while controlling temperature, humidity, air flow, and distribution suitable for human activity using a refrigeration cycle. The main components of the refrigeration cycle include a compressor, a condenser, an evaporator and a blower fan.

The condenser and the evaporator exchange heat with the outside through a heat exchanger including a flow path through which the refrigerant flows.

The heat exchanger includes a round tube heat exchanger in which a circular tube is inserted into the fin and a flat tube heat exchanger in which a flat tube is inserted into the fin. The round tube heat exchanger has the disadvantage of easy control but low heat transfer efficiency, and the flat tube heat exchanger has high heat transfer efficiency but difficult control.

In addition, the flat tube heat exchanger is difficult to evenly distribute the amount of refrigerant flowing in each flat tube because the refrigerant flows through the header to several flat tubes at once. For this reason, in the flat tube heat exchanger, part of the heat dissipation state is partially superheated, and part of the wet steam state is discharged in the state of overheating while being mixed at the outlet. The part becomes larger and there is a problem that the heat transfer performance falls.

One aspect of the present invention provides a heat exchanger and an air conditioner having the same, which can increase heat transfer efficiency and reduce overheating and subcooling sections.

Air conditioner according to the spirit of the present invention is a housing; A refrigerant inlet pipe and a refrigerant outlet pipe through which the refrigerant flows in and out; And a heat exchanger communicating with the coolant inlet pipe and the coolant outlet pipe and provided inside the housing to exchange heat with external air. The heat exchanger is in communication with the coolant inlet pipe and through a round tube through which the coolant flows. A first round tube heat exchanger for heat exchange; A tubular heat exchanger in communication with the first round tube heat exchanger and configured to exchange heat through a plate-shaped tube through which a refrigerant flows; And a second circular tube heat exchanger communicating with the tubular heat exchanger and heat-exchanging through a circular tube through which the refrigerant flows to discharge the refrigerant to the refrigerant outlet tube.

Refrigerant guide unit for guiding the movement of the refrigerant between the heat exchanger; The refrigerant guide unit, The refrigerant guide pipe for distributing the refrigerant from the refrigerant inlet pipe to the first circular tube heat exchanger; A second refrigerant guide tube distributing a refrigerant from the first circular tube heat exchanger to the tubular heat exchanger; A third refrigerant guide tube distributing a refrigerant from the tubular heat exchanger to the second round tube heat exchanger; And a fourth refrigerant guide tube configured to guide the refrigerant from the second circular tube heat exchanger to the refrigerant discharge pipe.

Inlet and outlet for the refrigerant flows in and out to the heat exchanger may be provided together on one side of the heat exchanger, the refrigerant guide may be disposed on one side of the heat exchanger.

The first circular tube heat exchanger, the second circular tube heat exchanger, and the tubular heat exchanger may be provided in parallel.

An inlet provided at one side of the housing to suck air from the outside; A discharge port provided at another side of the housing to allow air inside the housing to flow out; And a flow passage through which air passes through the suction port and the discharge port, wherein the heat exchanger may be disposed on the flow path.

The first circular tube heat exchanger and the second circular tube heat exchanger may be provided to contact one surface of the tubular heat exchanger.

Heat exchanger according to the spirit of the present invention is a tubular heat exchanger having a plate-like tube through which the refrigerant flows; A first circular tube heat exchanger and a second circular tube heat exchanger having a circular tube in which a refrigerant flows; A refrigerant inlet tube communicating with the first round tube heat exchanger to introduce a refrigerant; And a refrigerant outlet pipe communicating with the second circular tube heat exchanger to allow the refrigerant to flow out, wherein the refrigerant flowing into the first circular tube heat exchanger through the refrigerant inlet pipe passes through the tubular heat exchanger to the second circular tube heat exchanger. It is introduced, characterized in that discharged through the refrigerant outlet pipe.

Refrigerant guide unit for guiding the movement of the refrigerant between the heat exchanger; The refrigerant guide unit, The refrigerant guide pipe for distributing the refrigerant from the refrigerant inlet pipe to the first circular tube heat exchanger; A second refrigerant guide tube distributing a refrigerant from the first circular tube heat exchanger to the tubular heat exchanger; A third refrigerant guide tube distributing a refrigerant from the tubular heat exchanger to the second round tube heat exchanger; And a fourth refrigerant guide tube configured to guide the refrigerant from the second circular tube heat exchanger to the refrigerant discharge pipe.

The heat exchanger of the present invention and the air conditioner with the same reduce the supercooling and overheating sections, thereby maximizing the heat transfer performance, and do not require a separate distribution mechanism to prevent overcooling and overheating, thereby improving manufacturing efficiency and economy. Can be.

1 is a view showing an outdoor unit of an air conditioner according to an embodiment of the present invention.
2 is a front perspective view of a heat exchanger according to an embodiment of the present invention.
3 is a rear perspective view of a heat exchanger according to an embodiment of the present invention.
4 is an exploded perspective view of a heat exchanger according to an embodiment of the present invention.
5, 6, 7 is a view of the refrigerant circulation of the heat exchanger according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings an embodiment according to the present invention will be described in detail.

1 is a top cross-sectional view of an outdoor unit of an air conditioner according to an embodiment of the present invention.

As shown in FIG. 1, the outdoor unit 10 of the air conditioner according to the present invention includes a housing including an upper panel (not shown), a rear panel 12, and a side panel 13, and an inner space of the housing. The partition wall 28 which divides into the compression chamber 20 and the heat exchange chamber 24 is provided. An upper panel (not shown) is provided above the heat exchange chamber 24 and the compression chamber 20.

The heat exchange chamber 24 has a heat exchanger 100 provided in a shape bent along the rear panel 12 and the side panel 13 of the housing, and introduces external air into the housing to allow the heat exchanger 100 to pass therethrough. Thereafter, an axial flow fan 30 for flowing air out of the housing and a bell mouse 90 for guiding the flow of air generated by the axial flow fan 30 are provided. In the inner space of the bell mouse (90), a guide part (80) provided to protect the axial fan (30) is provided.

The motor 32 for driving the axial fan 30 is provided inside the housing.

The rear panel 12 and the side panel 13 are formed with an inlet 14 for allowing air to flow into the heat exchanger 100, and the front panel 11 allows the air passing through the heat exchanger 100 to flow out. The discharge port 11a is formed.

The heat exchanger 100, the motor 32, the axial fan 30, and the bell mouse 90 are arranged side by side from the upstream side of the air flow generated by the axial fan 30.

In the compression chamber 20, a compressor 22 for compressing a refrigerant is provided. The refrigerant compressed by the compressor 22 moves to the heat exchanger 100 side.

2 is a front perspective view of a heat exchanger according to an embodiment of the present invention, FIG. 3 is a rear perspective view of a heat exchanger according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view of a heat exchanger according to an embodiment of the present invention. to be.

The heat exchanger 100 includes a round tube heat exchanger 110 and a tubular heat exchanger 120. The heat exchanger 100 may be disposed on the flow path 15 provided between the suction port 14 and the discharge port 11a.

The circular tube heat exchanger 110 may include a circular tube heat exchanger heat exchange fin 116 provided to cross the circular tube 112 and the circular tube 112 through which the refrigerant flows.

Circular tube 112 may be provided in a variety of shapes, in the embodiment of the present invention is a plurality of tubes having a circular cross section is provided to be bent in a U-shape, the flow path may be formed to allow the refrigerant to flow therein have. Specifically, the circular tube 112 is bent to form a curved portion of the circular tube curved portion 112a and the circular tube curved portion 112a formed at the end of the pair of circular tube straight portion 112b formed of a straight section. It may include. In addition, the circular pipes 112 may be extruded from an aluminum material in consideration of heat exchange efficiency.

A pair of circular tube heat exchanger inlet pipe 114b serving as an inlet for refrigerant and a circular tube heat exchanger outlet tube 114b serving as an outlet are provided at ends of the pair of circular tube straight lines 112b.

The circular tube heat exchanger heat exchange fin 116 is provided in the circular tube to increase the heat transfer area with the outside air to improve the heat exchange efficiency of the refrigerant flowing through the circular tube, and to contact the outer wall of the circular tube straight part 112b. Is disposed, a plurality of spaced apart at regular intervals in a direction perpendicular to the direction in which the circular tube 112 extends.

The tubular heat exchanger 120 may include a tubular heat exchanger heat exchange fin 124 provided between the tube 122 and the tube 122 to widen the heat transfer area.

Tube 122 may be provided in a variety of shapes, in the embodiment of the present invention is made of a plate-like, the flow path is formed so that the refrigerant flows therein. In addition, the plurality of tubes 122 may be formed in parallel.

The tubular heat exchanger heat exchange fins 124 may be provided to contact the plurality of tubes 122 between the plurality of tubes 122. The tubular heat exchanger heat exchange fins 124 may be provided in various shapes, and in the embodiment of the present invention, may be bent and provided in a zigzag shape.

The tubular heat exchanger 120 is provided with a pair of header units 126, and the plurality of tubes 122 are coupled with a pair of header units 126 at both ends. The header unit 126 includes a header unit 126 provided at one end of the tube 122, a first header unit 126a, and a header unit 126 provided at the other end, and a second header unit 126b.

The first header unit 126a and the second header unit 126b are disposed to be spaced apart from each other by a predetermined interval, and the plurality of tubes 122 are provided between the first header unit 126a and the second header unit 126b. Can be. The refrigerant flowing into the tubular heat exchanger 120 through the first header unit 126a is distributed to the plurality of tubes 122, and the refrigerant flowing through the tube 122 through the second header unit 126b may be circulated. Can be.

The first header unit 126a may be provided with a tubular heat exchanger 120, a tubular heat exchanger inlet tube 128a serving as a refrigerant inlet, and a tubular heat exchanger outlet tube 128b serving as an outlet.

The heat exchanger 100 may be provided with a refrigerant inlet tube 102 and a refrigerant outlet tube 104 through which refrigerant flows in and out. In detail, the refrigerant inlet tube 102 and the refrigerant outlet tube 104 may communicate with the first circular tube heat exchanger 110a and the second circular tube heat exchanger 110b, respectively.

The circular tube heat exchanger 110 may include a first circular tube heat exchanger 110a and a second circular tube heat exchanger 110b. The first circular tube heat exchanger (110a) and the second circular tube heat exchanger (110b) may be partitioned and arranged in one circular tube heat exchanger (110), or may be composed of a separate circular tube heat exchanger (110). .

The refrigerant guide unit 140 is a configuration for guiding the refrigerant between the heat exchangers 100, and is provided between the refrigerant inlet pipe 102 and the first circular tube heat exchanger 110a to distribute the refrigerant (the first refrigerant guide tube ( 141, a second refrigerant guide tube 142 provided between the first circular tube heat exchanger 110a and the tubular heat exchanger 120 to guide the refrigerant from the first circular tube heat exchanger 110a to the tubular heat exchanger 120. A third refrigerant guide tube 143 provided between the tubular heat exchanger 120 and the second circular tube heat exchanger 110b to guide the refrigerant from the tubular heat exchanger 120 to the second circular tube heat exchanger 110b. ), And may include a fourth refrigerant guide tube 144 provided between the second circular tube heat exchanger 110b and the refrigerant outlet pipe 104 to join and guide the refrigerant.

One end of the first refrigerant guide tube 141 communicates with the refrigerant inlet tube 102, and the other end communicates with the plurality of circular tube heat exchanger inlet tubes 114a of the first circular tube heat exchanger 110a. The refrigerant may be distributed and introduced into the first circular tube heat exchanger (110a).

One end of the second refrigerant guide tube 142 communicates with the plurality of circular tube heat exchanger outlet tubes 114b of the first circular tube heat exchanger 110a to introduce refrigerant, and the other end of the second refrigerant guide tube 142 is tubular of the tube type heat exchanger 120. The refrigerant may be connected to the heat exchanger inlet pipe 128a to be joined to and introduced into the tubular heat exchanger 120.

One end of the third refrigerant guide tube 143 is connected to the tube-type heat exchanger outlet tube 128b of the tube-type heat exchanger 120 to introduce refrigerant, and the other end of the third refrigerant tube 143 is provided with a plurality of circular tubes of the second circular tube heat exchanger 110b. In communication with the heat exchanger inlet pipe 114a, the refrigerant may be distributed and introduced into the second round tube heat exchanger 110b.

One end of the fourth refrigerant guide tube 144 communicates with the plurality of circular tube heat exchanger outlet pipes 114b of the second circular tube heat exchanger 110b so that the refrigerant is introduced therein, and the other end thereof communicates with the refrigerant outlet tube 104. Thus, the refrigerant may join and flow out into the refrigerant outlet pipe 104.

The refrigerant guide unit 140 may be provided at one side of the heat exchanger 100. In detail, the circular tube heat exchanger inlet tube 114a and the circular tube heat exchanger provided at the end of the circular tube straight line 112b of the first circular tube heat exchanger 110a and the second circular tube heat exchanger 110b for the refrigerant to flow in and out. The air outlet pipe 114b and the tubular heat exchanger inlet pipe 128a and the tubular heat exchanger outlet pipe 128b provided in the first header unit 126a of the tubular heat exchanger 120 are provided on the same side. The coolant guide 140 may be disposed on one side.

The following describes the operation of the heat exchanger and the air conditioner having the same according to the above configuration.

5, 6, and 7 is a view of the refrigerant circulation of the heat exchanger according to an embodiment of the present invention.

As shown in FIG. 5, the refrigerant is introduced through the refrigerant inlet tube 102 and is introduced into the first circular tube heat exchanger 110a through the first refrigerant guide tube 141.

Thereafter, the refrigerant circulates through the first circular tube heat exchanger 110a and enters the tubular heat exchanger 120 as shown in FIG. 6 through the second refrigerant guide tube 142.

Subsequently, the tubular heat exchanger 120 is circulated and introduced into the second circular tube heat exchanger 110b through the third refrigerant guide tube 143, and the second circular tube heat exchanger 110b is circulated as shown in FIG. 7. The latter flows out from the heat exchanger 100 through the refrigerant outlet pipe 104.

In this process, while the heat exchange through the first circular tube heat exchanger (110a) so that the outlet dryness of the refrigerant is in the range of 0.1 ~ 0.4, while the heat exchange through the tubular heat exchanger 120, the outlet dryness of the refrigerant is 0.8 ~ It is in the range of 0.95, and finally can be controlled to be a heat exchange in the second round tube heat exchanger (110b) to be a dryness 1 and the desired superheat at the outlet.

On the contrary, in the case of cooling, the air flows in the opposite direction to the heating time, and is made into a wet steam state in the superheated steam state through the first circular tube heat exchanger (110a), and then the dryness is maintained in the tubular heat exchanger (120) while maintaining the wet steam state. Lower, so that the final second round tube heat exchanger (110b) has a dryness of zero and a desired degree of subcooling.

In the above, specific embodiments have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and those skilled in the art may make various changes without departing from the spirit of the technical idea of the invention as set forth in the claims below. .

10: outdoor unit 11: front panel
11a: discharge port 12: rear panel
13 side panel 14 inlet port
15: Euro 20: compression chamber
24: heat exchange chamber 28: partition wall
30: axial fan 32: motor
90: Bell Mouse 80: Guide
100: heat exchanger 102: refrigerant inlet pipe
104: refrigerant outlet pipe 110: round tube heat exchanger
110a: first round tube heat exchanger 110b: second round tube heat exchanger
112: round tube 112a: round tube curved portion
112b: straight portion of the round tube 114a: round tube heat exchanger inlet tube
114b: round tube heat exchanger outlet tube 116: round tube heat exchanger heat exchange fin
120: tube type heat exchanger 122: tube
124: tube type heat exchanger heat exchanger fin 126: header unit
126a: first header unit 126b: second header unit
128a: Tubular heat exchanger inlet tube 128b: Tubular heat exchanger outlet tube
140: refrigerant guide unit 141: first refrigerant guide tube
142: second refrigerant guide tube 143: third refrigerant guide tube
144: 4th refrigerant guide tube

Claims (8)

housing;
A refrigerant inlet pipe and a refrigerant outlet pipe through which the refrigerant flows in and out;
And a heat exchanger communicating with the refrigerant inlet tube and the refrigerant outlet tube, the heat exchanger being provided inside the housing to exchange heat with external air.
The heat exchanger,
A first circular tube heat exchanger communicating with the refrigerant inlet tube and heat exchanged through a circular tube through which the refrigerant flows, the circular tube straight line portion having a circular tube heat exchanger inlet tube and a circular tube heat exchanger outlet tube at each end;
A heat exchanger communicating with the first circular tube heat exchanger and heat-exchanging through a plate-shaped tube in which a refrigerant flows, the tube heat exchanger including a first header unit provided with a tube heat exchanger inlet tube and a tube heat exchanger outlet tube;
The tube is in communication with the heat exchanger, and the heat exchange through the circular tube in which the refrigerant flows to discharge the refrigerant to the refrigerant outlet pipe, the circular tube straight portion provided with a circular tube heat exchanger inlet tube and a circular tube heat exchanger outlet tube at each end A second round tube heat exchanger comprising; And
And a refrigerant guide unit for guiding a movement of the refrigerant between the heat exchangers.
The refrigerant guide unit,
A first refrigerant guide tube connected to the refrigerant inlet tube and the circular tube heat exchanger inlet tube of the first circular tube heat exchanger to distribute refrigerant from the refrigerant inlet tube to the first circular tube heat exchanger;
A second refrigerant connected to the circular tube heat exchanger outlet tube of the first circular tube heat exchanger and the tube heat exchanger inlet tube of the tubular heat exchanger to distribute refrigerant from the first circular tube heat exchanger to the tubular heat exchanger Guide officer;
A third refrigerant connected to the tubular heat exchanger outlet tube of the tubular heat exchanger and the circular tube heat exchanger inlet tube of the second circular tube heat exchanger to distribute refrigerant from the tubular heat exchanger to the second circular tube heat exchanger Guide officer; And
And a fourth refrigerant guide tube connected to the circular tube heat exchanger outlet tube and the refrigerant outlet tube of the second circular tube heat exchanger to guide the refrigerant from the second circular tube heat exchanger to the refrigerant outlet tube. Air conditioner characterized in that. delete The method of claim 1,
Inlet and outlet for the refrigerant flows in and out to the heat exchanger is provided on one side of the heat exchanger, the refrigerant guide unit is characterized in that arranged on one side of the heat exchanger. The method of claim 1,
And the first circular tube heat exchanger, the second circular tube heat exchanger, and the tubular heat exchanger are arranged to be parallel to each other. The method of claim 1,
An inlet provided at one side of the housing to suck air from the outside;
A discharge port provided at another side of the housing to allow air inside the housing to flow out;
And a passage through which air flows in communication with the suction port and the discharge port.
And the heat exchanger is disposed on the flow path. The method of claim 1,
And the first circular tube heat exchanger and the second circular tube heat exchanger are in contact with one surface of the tubular heat exchanger. A tubular heat exchanger having a plate-shaped tube through which a refrigerant flows, the tubular heat exchanger including a first header unit provided with a tubular heat exchanger inlet tube and a tubular heat exchanger outlet tube;
A first circular tube heat exchanger and a second circular tube heat exchanger, each having a circular tube in which a refrigerant flows, the circular tube straight line portion having a circular tube heat exchanger inlet tube and a circular tube heat exchanger outlet tube at each end;
A refrigerant inlet tube communicating with the first round tube heat exchanger to introduce a refrigerant;
A refrigerant outlet tube communicating with the second circular tube heat exchanger to allow refrigerant to flow out; And
And a refrigerant guide unit for guiding a movement of the refrigerant between the heat exchangers.
The refrigerant guide unit,
A first refrigerant guide tube connected to the refrigerant inlet tube and the circular tube heat exchanger inlet tube of the first circular tube heat exchanger to distribute refrigerant from the refrigerant inlet tube to the first circular tube heat exchanger;
A second refrigerant connected to the circular tube heat exchanger outlet tube of the first circular tube heat exchanger and the tube heat exchanger inlet tube of the tubular heat exchanger to distribute refrigerant from the first circular tube heat exchanger to the tubular heat exchanger Guide officer;
A third refrigerant connected to the tubular heat exchanger outlet tube of the tubular heat exchanger and the circular tube heat exchanger inlet tube of the second circular tube heat exchanger to distribute refrigerant from the tubular heat exchanger to the second circular tube heat exchanger Guide officer; And
And a fourth refrigerant guide tube connected to the circular tube heat exchanger outlet tube and the refrigerant outlet tube of the second circular tube heat exchanger to guide the refrigerant from the second circular tube heat exchanger to the refrigerant outlet tube. and,
And a refrigerant flowing into the first circular tube heat exchanger through the refrigerant inlet pipe is introduced into the second circular tube heat exchanger via the tubular heat exchanger and discharged through the refrigerant outlet tube. delete

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