KR101989096B1 - Heat exchanger - Google Patents

Abstract

The heat exchanger of the air conditioner of the present invention comprises: a lower header having a lower flow path; An upper header formed with an upper flow path; A plurality of flat tubes each having a plurality of flow passages communicating with the lower flow path and the upper flow path; And a heat exchanging unit having a fin disposed between the plurality of flat tubes, wherein the lower flow path includes a first lower flow path in which a part of the plurality of flat tubes communicate with each other, Wherein a width of the heat exchange zone in which the plurality of flat tubes and the fin are heat-exchanged with air is longer than a width in the longitudinal direction, and an inner cross sectional area of the upper header and an inner cross sectional area of the lower header form a plurality The refrigerant can be uniformly distributed to the plurality of flat tubes with a simple structure and the generation of the superheated tube can be minimized because the heat exchanger capacity can be maximized.

Description

Heat exchanger of air conditioner {Heat exchanger}

The present invention relates to a heat exchanger of an air conditioner, and more particularly to a heat exchanger of an air conditioner in which a lower header and an upper header are communicated with a plurality of flat tubes.

Generally, a heat exchanger can be used as a condenser or an evaporator in a refrigeration cycle apparatus comprising a compressor, a condenser, an expansion mechanism, and an evaporator. The heat exchanger may be installed in a vehicle, a refrigerator, or an air conditioner, and may exchange heat of the refrigerant with air.

The heat exchanger may be divided into a fin tube type heat exchanger and a microchannel type heat exchanger. The heat exchanger may include a tube through which the refrigerant passes, a heat transfer member connected to the tube, and a header connected to the tube to distribute the refrigerant to the tube.

A refrigerant inlet pipe for guiding the refrigerant to the header may be connected to the heat exchanger, and a refrigerant outlet pipe for discharging the refrigerant from the header may be connected.

KR 10-2009-0048352 A (2009.05.13)

The heat exchanger according to the prior art is an invention that improves the heat exchange performance by positioning and sizing of the communication holes and the refrigerant distribution according to the ratio of the sectional area of the header to the sectional area of the refrigerant channel of the tube There is a problem that it is not sufficiently reflected.

The heat exchanger of the air conditioner according to the present invention includes: a lower header having a lower flow path; An upper header formed with an upper flow path; A plurality of flat tubes each having a plurality of flow passages communicating with the lower flow path and the upper flow path; And a heat exchanging unit having a fin disposed between the plurality of flat tubes, wherein the lower flow path includes a first lower flow path in which a part of the plurality of flat tubes communicate with each other, And a heat exchange zone in which the plurality of flat tubes and the fin are heat-exchanged with air among the upper header and the lower header is longer than the transverse width in the longitudinal direction, and the inner cross sectional area of the upper header and the lower header The internal cross-sectional area may be 0.7 times or more of the total cross-sectional area of the plurality of flat tubes constituting one pass.

The upper header can be discharged to the rest of the plurality of flat tubes after the refrigerant flowing into the upper flow path through a part of the plurality of flat tubes hits an upper inner wall surface of the upper header.

And an inlet pipe for introducing and guiding the refrigerant in a direction orthogonal to the plurality of flat tubes. The inlet pipe may communicate with one of the first lower flow path and the second lower flow path. The inlet tube may include a plurality of branch tubes.

The total cross-sectional area of the flow path can be determined by Equation (1).

[Equation 1] Acell = Tn X Cn X A

Here, the Acell is the sum of the cross-

Tn is the number of flat tubes constituting one pass,

Cn is the number of flow paths formed in each of the plurality of flat tubes,

A is the cross-sectional area of the flow path.

The inner cross-sectional area of the upper header and the inner cross-sectional area of the lower header may be 0.8 times or less of the total cross-sectional area of the flow path.

The width in the longitudinal direction may be 1.5 times or more of the width in the transverse direction.

The longitudinal width may be 2.5 times or less of the lateral width.

A plurality of the heat exchange units may be arranged before and after the air flow direction and an inlet pipe for introducing refrigerant into the first lower flow path formed in one of the plurality of heat exchange units may be connected, And an outlet pipe through which the refrigerant flows out may be connected to the first lower flow path formed in the lower header of the other of the heat exchange units. A plurality of communication holes may be communicated with a separation portion between a second lower flow path formed in a lower header of any one of the plurality of heat exchange units and a second lower flow path formed in another lower header of the plurality of heat exchange units. The total cross-sectional area of the plurality of communication holes may be 4 to 8% of the area of the separation area.

 The plurality of heat exchanging units may be disposed in the air flow direction, and the upper header may be divided into a first upper flow path and a second upper flow path. An inlet pipe for guiding refrigerant into the flow path may be connected to the flow path, and an outlet pipe for guiding refrigerant outflow may be connected to the second upper flow path. A first lower flow path formed in a lower header of any one of the plurality of heat exchange units and a first lower flow path formed in a lower header of the other one of the plurality of heat exchange units can communicate with a plurality of first communication holes, The second lower flow path formed in the lower header of any one of the heat exchange units and the second lower flow path formed in the lower header of the other one of the plurality of heat exchange units may be communicated with the plurality of second communication holes. Wherein the total sum of the cross sectional areas of the plurality of first communication holes is a sum of a cross sectional area of a first lower flow path formed in one of the plurality of heat exchange units and a first lower flow path formed in the other lower header of the plurality of heat exchange units And may be 4 - 8% of the area. Wherein the total sum of the cross-sectional areas of the plurality of second communication holes is a sum of a cross-sectional area of the second lower flow path formed in one of the plurality of heat exchange units and a second lower flow path formed in the other lower header of the plurality of heat exchange units And may be 4 - 8% of the area.

The present invention maximizes the capacity of the heat exchanger by selecting the longitudinal direction width and the transverse direction width of the heat exchange area, and by the optimum ratio of the total cross sectional area of the flow tubes of the plurality of flat tubes constituting one path, The refrigerant can be evenly distributed to the plurality of flat tubes and the occurrence of the superheated tube can be minimized.

Further, there is an advantage that the cooling efficiency can be increased by the optimum ratio of the total cross sectional area of the plurality of communication holes and the area of the separation portion formed with the plurality of communication holes.

Also, there is an advantage that the generation of the superheated tube can be minimized while enhancing the heat exchanger capability at a minimum cost without providing a separate distributor or capillary tube outside the heat exchanger of the air conditioner.

FIG. 1 is a configuration diagram illustrating an air conditioner to which an embodiment of a heat exchanger of an air conditioner according to the present invention is applied.
FIG. 2 is a side view showing the inside of an indoor unit when an embodiment of a heat exchanger of an air conditioner according to the present invention is installed inside an indoor unit;
FIG. 3 is a side view illustrating an embodiment of a heat exchanger of an air conditioner according to the present invention.
FIG. 4 is an exploded perspective view showing an embodiment of a heat exchanger of an air conditioner according to the present invention, FIG.
FIG. 5 is a front view showing an embodiment of a heat exchanger of an air conditioner according to the present invention. FIG.
6 is a sectional view taken along the line AA in Fig. 3,
7 is a sectional view taken along line BB of Fig. 3,
8 is a sectional view taken along line CC of Fig. 5,
9 is a cross-sectional view taken along line DD of Fig. 5,
10 is a graph showing the heat exchanger capacity according to the width ratio of the width of the heat exchange zone in the widthwise direction of the heat exchange zone and the widthwise width of the heat exchange zone in the heat exchanger of the air conditioner according to the present invention,
11 is a sectional view showing the inside of a header of an embodiment of a heat exchanger of an air conditioner according to the present invention,
12 is a graph showing the rate of occurrence of superheated tubes according to the ratio of the inner cross sectional area of the header of the heat exchanger of the air conditioner according to the present invention to the sum of the flow cross sectional areas of a plurality of flat tubes constituting one path,
Fig. 13 is a front view showing a plurality of communication holes and a separating portion of an embodiment of a heat exchanger of an air conditioner according to the present invention,
14 is a graph showing the cooling efficiency according to the ratio of the total sectional area of a plurality of communication holes of the heat exchanger of the air conditioner to the area of the separation portion of the present invention,
15 is a perspective view showing another embodiment of the heat exchanger of the air conditioner according to the present invention,
16 is an exploded perspective view showing another embodiment of the heat exchanger of the air conditioner according to the present invention,
17 is a plan view showing a top header of another embodiment of the heat exchanger of the air conditioner according to the present invention,
18 is a plan sectional view showing a lower header of another embodiment of the heat exchanger of the air conditioner according to the present invention.

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

1 is a block diagram showing the configuration of an air conditioner to which an embodiment of a heat exchanger of an air conditioner according to the present invention is applied.

 As shown in Fig. 1, the air conditioner includes a compressor 2 for compressing refrigerant, an outdoor heat exchanger 4 for exchanging heat with the outdoor air, an expansion mechanism 6 for expanding the refrigerant, And an indoor heat exchanger 8 that is heat-exchanged with air. The air conditioner can heat the refrigerant compressed in the compressor (2) through the outdoor heat exchanger (4) while exchanging heat with the outdoor air and be condensed. The outdoor heat exchanger 4 can function as a condenser. The refrigerant condensed in the outdoor heat exchanger (4) flows to the expansion mechanism (6) and can expand. The refrigerant expanded by the expansion mechanism (6) can be evaporated by heat exchange with indoor air while passing through the indoor heat exchanger (8). The indoor heat exchanger 8 can function as an evaporator for evaporating the refrigerant. The refrigerant evaporated in the indoor heat exchanger can be recovered to the compressor (2). The refrigerant can circulate the compressor (2), the outdoor heat exchanger (4), the expansion mechanism (6), and the indoor heat exchanger (8) to cool the room.

The compressor (2) can be connected to a compressor suction passage for guiding the refrigerant passed through the indoor heat exchanger (8) to the compressor (2), and an accumulator (9) capable of accumulating liquid refrigerant can be installed in the compressor suction passage .

The indoor heat exchanger (8) may be formed with a refrigerant passage through which the refrigerant passes. The liquid heat exchanger (8) can be connected to a liquid pipe (10) guiding the refrigerant passing through the expansion mechanism (6) to one end of the refrigerant flow path. The indoor heat exchanger (8) is connected to an engine (11) which is evaporated in the indoor heat exchanger (8) and guided by the refrigerant flowing to the other end of the refrigerant passage.

The compressor 2 and the outdoor heat exchanger 4 can be installed inside the outdoor unit I and the expansion mechanism 6 can be installed in the outdoor unit I when the indoor unit I and the outdoor unit O are separated from each other, The indoor heat exchanger 8 can be installed in the indoor unit I or the outdoor unit O and the indoor heat exchanger 8 can be installed in the indoor unit I,

The outdoor unit O may be provided with an outdoor fan 12 for blowing outdoor air to the outdoor heat exchanger 8 and outdoor air blown to the outdoor heat exchanger 4 by the outdoor fan 12 may be supplied to the outdoor heat exchanger It is possible to condense the refrigerant passing through the refrigerant circuit 4.

The indoor unit I may be provided with an indoor fan 13 for blowing indoor air to the indoor heat exchanger 8 and the indoor air blown to the indoor heat exchanger 8 by the indoor fan 13 may be supplied to the indoor heat exchanger 8, It is possible to condense refrigerant passing through the evaporator 8.

2 is a side view of the interior of the indoor unit when the heat exchanger of the air conditioner according to the present invention is installed inside the indoor unit.

The indoor unit I may include a casing 16 which forms the appearance of the indoor unit, as shown in Fig. The casing 16 may be provided with an air inlet 14 and an air outlet 15. The casing 16 may be composed of an assembly of a plurality of members. The casing 16 may include a suction panel 17 having an air inlet 14 and a discharge panel 18 having an air outlet 15 formed therein. The casing (6) may include a base (19) for supporting the load of the indoor unit (I). The casing 16 may include a front panel that forms the front exterior of the air conditioner.

The indoor heat exchanger (8) and the indoor fan (13) can be installed inside the casing (16).

The indoor air can be sucked into the casing 16 through the air inlet 14 and can be discharged to the air outlet 15 after passing through the inside of the casing 16. [

The indoor heat exchanger (8) can exchange indoor air sucked through the air inlet (14) with the refrigerant when the indoor fan (13) is driven. The indoor heat exchanger (8) may be disposed vertically in the casing (16). The indoor heat exchanger (8) may be installed vertically inside the casing (16). The indoor heat exchanger (8) can be installed inclined inside the casing (16).

The indoor heat exchanger 8 has a lower header 30 and an upper header 40 spaced apart from each other in the vertical direction and a lower header 30 and an upper header 40 are disposed in a plurality of flat tubes 50 and 70 And a heat exchanger connected thereto.

The heat exchanger of the air conditioner according to the present invention can constitute at least one of the outdoor heat exchanger (4) and the indoor heat exchanger (8), and particularly to the indoor heat exchanger (8) It is more preferable that the outdoor heat exchanger 4 and the indoor heat exchanger 8 are each constituted by the heat exchanger of the air conditioner according to the present invention. The indoor heat exchanger 8 functions as an evaporator during the cooling operation and the outdoor heat exchanger 4 functions as an evaporator during the heating operation and in this case the indoor heat exchanger 8 functions as an evaporator, And the outdoor heat exchanger 4 may be constructed as a heat exchanger of the air conditioner according to the present invention.

3 is a side view illustrating an embodiment of a heat exchanger of an air conditioner according to the present invention.

The heat exchanger of the air conditioner according to the present invention may include a heat exchange unit (HU1) (HU2) that exchanges heat with air while passing the refrigerant. The heat exchanger of the air conditioner may include an inlet pipe 100 to which the liquid pipe 10 shown in Fig. 1 is connected and an outlet pipe 110 to which the organs 11 shown in Fig. 1 are connected.

The heat exchanger of the air conditioner can include one heat exchange unit HU1 and both the inlet pipe 100 and the outlet pipe 110 can be connected to one heat exchange unit HU1. In this case, the refrigerant in the liquid pipe 10 is allowed to flow to the engine 11 after flowing in the order of the inlet pipe 100, the single heat exchanging unit HU1, and the outlet pipe 110. [

The heat exchanger of the air conditioner can include a plurality of heat exchange units HU1 and HU2 through which the refrigerant R sequentially passes, and the plurality of heat exchange units HU1 and HU2 are arranged in the air flow direction, . The inlet pipe 100 may be connected to one of the plurality of heat exchange units HU1 and HU2 and the outlet pipe 110 may be connected to the other one of the plurality of heat exchange units HU1 and HU2 . In this case, the refrigerant R of the liquid pipe 10 is connected to the inlet pipe 100, one of the plurality of heat exchange units HU1 and HU2, and the other of the plurality of heat exchange units HU1 and HU2 (HU2), and the outlet pipe (110), and then flows into the engine (11). It is preferable that the heat exchanger of the air conditioner includes a plurality of heat exchange units HU1 and HU2 for compactness. The plurality of heat exchange units HU1 and HU2 may include an electrothermal heat exchanging unit HU1 through which the refrigerant R passes first and a rear heat exchanging unit HU2 through which the refrigerant R later passes, 100 may be connected to the electrothermal heat exchange unit HU1 and the outlet pipe 110 may be connected to the rear heat exchanging unit HU2. The heat exchanger can be installed such that air passes first through the rear heat exchanging unit HU2 and then through the heat transfer heat exchanging unit HU1 and air passes through the heat transfer heat exchanging unit HU1 first, It can be installed to pass through the heat exchange unit HU2.

The heat transfer heat exchanging unit HU1 and the rear heat exchanging unit HU2 will be referred to as an electrothermal heat exchanging unit HU1 and a rear heat exchanging unit HU2, And the rear heat exchanger unit HU2 will be referred to as a heat exchange unit HU1 (HU2).

FIG. 4 is an exploded perspective view showing an embodiment of a heat exchanger of an air conditioner according to the present invention, FIG. 5 is a front view showing an embodiment of a heat exchanger of an air conditioner according to the present invention, 7 is a sectional view taken along the line BB of Fig. 3, Fig. 8 is a sectional view taken along the line CC of Fig. 5, and Fig. 9 is a sectional view taken along line DD of Fig.

The heat exchange units HU1 and HU2 include a lower header 30; An upper header 40 spaced apart from the lower header 30; A plurality of flat tubes 50 and 70 communicating the inside of the lower header 30 with the inside of the upper header 40 and the pins 90 disposed between the plurality of flat tubes.

 The lower header 30 is formed with a lower flow path PL1 or PL2 through which the refrigerant passes and an upper header PU through which the refrigerant passes is formed in the upper header 40. A plurality of flat tubes 50, And a flow path communicating with the lower flow path and the upper flow path are respectively formed. The flow path formed in the plurality of flat tubes (50) and (70) may be a heat exchange path for heat exchange with air while passing the refrigerant.

The lower header 30 may be elongated in a direction X perpendicular to the flow direction Z of the air. The lower header 30 may have a longer length in the longitudinal direction of the lower flow paths PL1 and PL2. The lower header 30 may be formed with a lower slit 32 through which the lower portion of the flat tubes 50 and 70 pass. The lower slit 32 may be formed on the lower header 30. A plurality of lower slits 32 may be formed as many as the number of the flat tubes 50 and 70 and a plurality of lower slits 32 may be spaced apart in the longitudinal direction of the lower header 30.

The lower flow paths PL1 and PL2 include a first lower flow path PL1 in which a part 50 of the plurality of flat tubes 50 and 70 are in communication and a second lower flow path PL2 in which the remaining one of the plurality of flat tubes 50 and 70 And a second lower flow path PL2 communicating with the second lower flow path PL2. The lower header 30 may be provided with a partition 33 for partitioning the inside of the lower header 30 to the left and right. The lower header 30 may have a partition wall insertion hole 34 into which the partition wall 33 is inserted and the partition wall 33 may be inserted into the partition wall insertion hole 34. The partition wall 33 can divide the inside of the lower header 30 into a first lower flow path PL1 and a second lower flow path PL2.

The upper header 40 may be elongated in a direction parallel to the lower header 30. The upper header 40 may be vertically spaced from the lower header 30 at an upper position of the lower header 30. The upper header (40) may have an upper flow path (PU) therein in which the refrigerant can flow in its longitudinal direction (X). The upper header 40 may be formed with an upper slit 42 through which the upper portions of the flat tubes 50 and 70 pass. The upper slit 42 may be formed at the lower portion of the upper header 40. A plurality of upper slits 42 may be formed as many as the number of the flat tubes 50 and 70 and a plurality of upper slits 42 may be spaced apart in the longitudinal direction of the upper header 40.

The upper header 40 may be formed such that one upper flow path PU is long in the horizontal direction. The refrigerant flowing into the upper flow path PU through the part 50 of the plurality of flat tubes 50 and 70 hits the upper inner wall surface 44 of the upper header 40, 70 to the remainder (70).

A plurality of flow paths C1, C2, and C3 may be formed in each of the plurality of flat tubes 50, 70. The plurality of flat tubes 50 and 70 includes a first group flat tube 50 composed of flat tubes 60 to 69 for communicating the first lower flow path PL1 with the upper flow path PU, And a second group of flat tubes 70 composed of flat tubes 80 to 89 for communicating the flow path PL2 with the upper flow path PL.

When the refrigerant flows into the first lower flow path PL1, the refrigerant introduced into the first lower flow path PL1 flows into the flat tubes of the first group flat tube 50 60-69 and can pass through the flat tubes 60-69 constituting the first group of flat tubes 50. [ The refrigerant may flow upward into the upper flow path PU after passing through the flat tubes 60 to 69 constituting the first group of flat tubes 50. The refrigerant that has flowed from the flat tubes 60 to 69 constituting the first group flat tube 50 to the upper flow path PU is merged in the upper flow path PU and flows into the upper header PU in the upper flow path PU, In the horizontal direction, which is the longitudinal direction of the valve body. The refrigerant in the upper flow path PU can be lowered while being distributed to the flat tubes 80 to 89 constituting the second group flat tubes 70 and the refrigerant in the upper tubes PU constituting the second group of flat tubes 70 80 to 89). The refrigerant can flow down to the second lower flow path PL2 after passing through the flat tubes 80 to 89 constituting the second group of flat tubes 70, The refrigerant flowing in the flat tubes 80 to 89 may be combined in the second lower flow path PL2.

When the refrigerant flows into the second lower flow path PL2, the heat exchange units HU1 and HU2 cool the refrigerant introduced into the second lower flow path PL2 into the flat tubes 80 to 89 and can pass through the flat tubes 80 to 89 constituting the second group of flat tubes 70. [ The refrigerant may flow upward into the upper flow path PU after passing through the flat tubes 80 to 89 constituting the second group of flat tubes 70, The refrigerant flowing into the upper flow path PU from the upper flow path PU can flow in the horizontal direction in the longitudinal direction of the upper header 40 in the upper flow path PU while being combined in the upper flow path PU. The refrigerant of the upper flow path PU can be lowered while being distributed to the flat tubes 60 to 69 constituting the first group of flat tubes 50 and the refrigerant of the flat tubes 60 to 69). The refrigerant can flow down to the first lower flow path PL1 after passing through the flat tubes 60 to 69 constituting the first group of flat tubes 50, The refrigerant flowing in the flat tubes 60 to 69 can be combined in the first lower flow path PL1.

The heat exchange units HU1 and HU2 may include, for example, a total of twenty (20) of the plurality of flat tubes, and the first group of flat tubes 50 may be composed of ten flat tubes 60 to 69 , And the second group flat tubes 70 may be composed of ten flat tubes 80 to 89. The heat exchange units HU1 and HU2 are provided with a first lower flow path PL1, a first group flat tube 50, an upper flow path PU, a second group flat tube 70, PL2) can be constituted. The heat exchange units HU1 and HU2 are connected to the second lower flow path PL2, the second group flat tube 70, the upper flow path PU, the first group flat tube 50, PL1) can be constituted. In this case, the number of the flat tubes constituting one path of the heat exchange units HU1 and HU2 may be ten.

As another example, the heat exchange units HU1 and HU2 may include a total of 30 flat tubes, the first group flat tubes 50 may be composed of 15 flat tubes, and the second group flat tubes 70 ) May be composed of 15 flat tubes. At this time, the heat exchange units HU1 and HU2 are provided with the first lower flow path PL1, the first group flat tube 50 and the upper flow path PU, A second group of flat tubes 70 and a second lower flow path PL2 or a second lower flow path PL2, a second group of flat tubes 70, an upper flow path PU, , The first group flat tube 50, and the first lower flow path PL1. In this case, the number of flat tubes constituting one path of the heat exchange units HU1 and HU2 can be 15.

The heat exchanger of the air conditioner is not limited to the number of flat tubes but may be various numbers such as 10, 24, 36, 40, and the like. In FIGS. 4 and 5, ten flat tubes 60 to 69 constitute a first group flat tube 50 for convenience, and another ten flat tubes 80 to 89 constitute a second group flat tube 70 ).

The inlet tube 100 may direct the refrigerant to one of the lower header 30 and the upper header 40 and the outlet tube 110 may be positioned between the lower header 30 and the upper header 40, Can guide.

When the heat exchanger of the air conditioner includes a single number of heat exchange units HU1, the inlet pipe 100 for introducing the refrigerant into the heat exchanger guides the refrigerant to either the first lower flow path PL1 or the second lower flow path PL2 And the outlet pipe 110 for guiding the refrigerant to flow out can discharge the refrigerant guided to the other of the first lower flow path PL1 and the second lower flow path PL2.

When the heat exchanger of the air conditioner includes a plurality of heat exchange units HU1 and HU2, the first lower flow path formed in the lower header 30 of any one of the plurality of heat exchange units HU1 and HU2 The refrigerant is introduced into the first lower flow path PL2 formed in the lower header 30 of the other one of the plurality of heat exchange units HU1 and HU2, A second lower flow path PL2 formed in the lower header 30 of any one of the plurality of heat exchange units HU1 and HU2 and a plurality of heat exchange units The second lower flow path PL2 formed in the lower header 30 of the other one of the first and second flow paths HU1 and HU2 may be communicated with the plurality of communication holes 35, 36, 37, and 38.

The inlet pipe 100 can guide the refrigerant in a direction perpendicular to the plurality of flat tubes 50 and 70. The inlet tube 100 may be arranged long in a direction orthogonal to the longitudinal direction Y of the plurality of flat tubes 50 and 70 and in a direction Z orthogonal to the longitudinal direction X of the lower header 30 have. In this case, the refrigerant may flow into the lower header 30 in a direction parallel to the flow direction of the air, and may be horizontally dispersed left and right inside the lower header 30. When the refrigerant flowing into the lower header 30 flows horizontally while being horizontally dispersed, the inlet pipe 100 can more evenly distribute the refrigerant and can distribute the refrigerant more efficiently in the longitudinal direction of the plurality of flat tubes 50, (Z) orthogonal to the longitudinal direction (X) of the lower header (30) while being orthogonal to the longitudinal direction (Y) of the lower header (30). In the inlet pipe 100, it is possible for one inlet pipe to guide the refrigerant to a substantially central position of the first lower flow path P1. The inlet pipe 100 includes a common pipe and a plurality of branch pipes branched from the common pipe. A common pipe is connected to the liquid pipe 10, and a plurality of branch pipes are connected to a plurality of positions of the first lower flow path P1 It is possible to guide the refrigerant.

The inlet pipe 100 may be arranged to be long in the longitudinal direction X of the lower header 30 while being perpendicular to the longitudinal direction Y of the plurality of flat tubes 50 and 70. In this case, the refrigerant may flow in the longitudinal direction of the lower header 30 from the side of the lower header 30 and may flow into the lower header 30, and may flow in the horizontal direction inside the lower header 30. The length of each of the first lower flow path PL1 and the second lower flow path PL2 is shorter than the length of the lower header 30 because the lower header 30 is divided into the first lower flow path PL1 and the second lower flow path PL2, Is less than that in the case where the inside of the inlet pipe 100 is not partitioned left and right, the phenomenon of the liquid refrigerant being pushed against the inlet pipe 100 can be minimized. That is, even when the inlet pipe 100 is arranged long in the longitudinal direction X of the lower header 30, since the lengths of the first lower flow path PL1 and the second lower flow path PL2 are short, It can be uniformly dispersed in a plurality of flat tubes.

The outlet pipe 110 can guide the refrigerant out in a direction orthogonal to the plurality of flat tubes 50 and 70. The outlet pipe 110 is arranged long in a direction orthogonal to the longitudinal direction Y of the plurality of flat tubes 50 and 70 and in a direction Z perpendicular to the longitudinal direction X of the lower header 30 And can be arranged long in the longitudinal direction X of the lower header 30 while being perpendicular to the longitudinal direction Y of the plurality of flat tubes 50 and 70.

 Meanwhile, as shown in FIG. 5, the heat exchanger capacity of the air conditioner can be determined according to the size and shape of the heat exchange area (Aheat). The heat exchange area (Aheat) may be a region where a plurality of flat tubes (50) and (70) and a fin (90) heat exchange with air. The heat exchange area Aheat can completely serve as a heat exchange area between the lower header 30 and the upper header 40. The heat exchange area Aheat can be a heat exchange area between the lower header 30 and the upper header 40, The region where the plurality of flat tubes 50, 70 and the fins 90 are located may be the heat exchange region.

The height of the portion of the plurality of flat tubes 50 and 70 located between the lower header 30 and the upper header 40 may be the longitudinal width L of the heat exchange area Aheat.

The heat exchange area Aheat includes a plurality of flat tubes 50 and 70. The heat exchange area Aheat includes a left end of the flat tube 89 positioned at the left end in the horizontal direction and a left end of the flat tube 89 positioned at the right end of the plurality of flat tubes 50, And the distance between the right end of the first housing 60 and the second housing 60 may be the width W of the lateral direction.

The longitudinal width L of the heat exchange area Aheat may be longer than the width W of the transverse direction. The lateral width (W) in the longitudinal direction width L will be described in more detail with reference to FIG.

 The heat exchanger of the air conditioner may have an inner sectional area Aheader of the upper header 40 and an inner sectional area Aheader of the lower header 40 equal to or greater than 0.7 times the total sectional area of a plurality of flat tubes constituting one pass .

 The total cross-sectional area of the plurality of flat tubes constituting one path can be determined by Equation (1).

[Equation 1] Acell = Tn X Cn X A

Where Acell is the total cross-sectional area of the flow path. Tn is the number of flat tubes constituting one pass. Cn is the number of the flow paths C1, C2, and C3 formed in each of the plurality of flat tubes, and A is the cross-sectional area of the flow path.

The heat exchanger of the air conditioner may have the same cross sectional area A of the flow paths C1, C2, and C3 formed in each of the plurality of flat tubes. In this case, A may be the cross sectional area of the flow path 1. The heat exchanger of the air conditioner may have different cross sectional areas A of the flow paths C1, C2, and C3 formed in each of the plurality of flat tubes. In this case, the flow paths C1, C2 ) ≪ / RTI > (C3). That is, Cn X A in Equation 1 can be the sectional area sum of the plurality of flow paths C1, C2, and C3 formed in one flat tube.

For example, a total of seven flow paths C1, C2, and C3 are formed in each of the plurality of flat tubes 50 and 70, and a total of 10 flats A total of ten flat tubes are communicated with the second lower flow path PL2 and the cross sectional area of the flow path is A (the average cross sectional area when the cross sectional areas of the flow paths are different), the number of the flat tubes constituting one path The total cross-sectional area Acell of the flow path cross-sectional area Acell can be 10 X 7 XA and the internal cross-sectional area Aheader of the upper header 40 is 10, and the number of the flow paths C1, C2, And the inner cross-sectional area Aheader of the lower header 30 may be 0.7 times or more of 10 X 7 XA, which is the sum of the flow cross sectional areas.

The inner sectional area Aheader of the upper header 40 and the inner sectional area Aheader of the lower header 30 will be described in detail with reference to FIG.

  The heat exchanger of the air conditioner is connected to the second lower flow path PL2 formed in the lower header 30 of any one of the plurality of heat exchange units HU1 and HU2 and the other of the plurality of heat exchange units HU1 and HU2 And the second lower flow path PL2 formed in the lower header 30 of the one HU2. The separating section 39 includes a second lower flow path PL2 formed in the lower header 30 of any one of the plurality of heat exchange units HU1 and HU2 and a second lower flow path PL2 formed between the plurality of heat exchange units HU1 and HU2 And the second lower flow path PL2 formed in the lower header 30 of the other HU2. A plurality of communication holes 35, 36, 37, and 38 may be formed in the separation portion 39. [ The total cross sectional area of the plurality of communication holes 35, 36, 37 and 38 may be 4 to 8% of the area of the separating portion 39.

A plurality of communication holes 35, 36, 37, and 38 may be formed in the lower header 30 of each of the plurality of heat exchange units HU1 and HU2. The plurality of communication holes 35, 36, 37, and 38 may be spaced apart in the longitudinal direction of the lower header 30. The total cross sectional area of the plurality of communication holes 35, 36, 37, and 38 will be described in detail with reference to FIG.

The heat exchanger of the air conditioner has a heat exchanger unit HU1 to which the inlet pipe 100 is connected and a rear heat exchanger unit HU2 to which the outlet pipe 110 is connected.

Hereinafter, the lower header 30 of the electrothermal heat exchanging unit HU1 will be referred to as a heat transfer lower header, and the plurality of flat tubes 50, 70 of the electrothermal heat exchanging unit HU1 will be referred to as a plurality of electrothermal flat tubes, And the upper header of the header HU1 will be referred to as an upper header.

The plurality of flat tubes 50 and 70 of the rear heat exchanging unit HU2 are referred to as a plurality of rear heating tubes and the rear heating heat exchanging unit HU2 is composed of the rear heat exchanging unit HU2, The upper header of the header HU2 will be referred to as a header of the succeeding header.

The heat exchanger of the air conditioner may be constructed such that the heat transfer lower header and the heat transfer lower header are joined to each other, the heat transfer upper header and the heat transfer upper header may be joined together, and the heat transfer plural flat tubes and the heat transfer plural flat tubes may be spaced in the air flow direction .

The heat exchanger of the air conditioner may be a separating portion 39 in which a part of the plate portions to which the heat transfer lower header and the rear heat lower header are joined is formed with the communication holes 35, 36, 37, When the thick plate portion of the electrothermal heat exchange unit HU1 and the entire plate portion of the rear heat exchanging unit HU2 are joined to the front plate portion of the rear heat exchanger unit HU2 and the rear plate portion of the rear heat exchanger unit HU2, 36, 37, and 38 may be formed.

The heat exchanger of the air conditioner may be such that the refrigerant is introduced into the first lower flow path PL1 of the lower header of the heat transfer from the inlet pipe 100 and dispersed in the first lower flow path PL1 of the lower header of the heat transfer, It can flow upward while passing through the group flat tube 50. The refrigerant can then flow to the upper flow path PU of the heat transfer upper header and horizontally to the upper side of the heat transfer second group flat tube 70. Thereafter, the refrigerant may flow downward while passing through the heat transfer second group flat tube 70, and may flow to the second lower flow path PL2 of the heat transfer lower header. The flow direction of the refrigerant in the second lower flow path PL2 of the electrothermal lower header can be reversed in the refrigerant flowing into the second lower flow path PL2 of the electrothermal lower header and then the plurality of communication holes 35, (37) and (38). The refrigerant can be flowed into the rear heat exchanging unit HU2 while being partially dispersed in the plurality of communication holes 35, 36, 37, and 38 in a state where the refrigerant is partially evaporated in the heat transfer heat exchange unit HU1. The refrigerant that is dispersed while passing through the plurality of communication holes 35, 36, 37, and 38 may be introduced into the second lower flow path PL2 of the downstream header.

The refrigerant flowing into the second lower flow path PL2 of the header lower header may then flow upward while passing through the rear second group flat tube 70. [ The refrigerant may then flow to the upper flow path PU of the header upper header and horizontally to the upper side of the rear row first flat tube 50. Thereafter, the refrigerant may flow downward through the first row group flat tube (50) and flow to the first lower flow channel (PL1) of the rear row lower header. The refrigerant that has flowed into the first lower flow path PL1 of the rear lower header can then flow into the outlet pipe 110 and pass through the outlet pipe 110. The refrigerant passes through the heat transfer heat exchanging unit HU1 and the rear heat exchanging unit HU2 ), In a state of being heat-exchanged with air in sequence.

FIG. 10 is a graph showing the heat exchanger capacity according to the length ratio between the width of the heat exchange zone in the widthwise direction of the heat exchange zone and the widthwise width of the heat exchange zone in the heat exchanger of the air conditioner according to the present invention.

The heat exchanger performance of the air conditioner can be improved if the longitudinal width L of the heat exchange area Aheat is longer than the lateral width W. [ The heat exchange area Aheat may have a longitudinal width L of at least 1.5 times the width W of the transverse direction. The heat exchange area Aheat may have a longitudinal width L of 2.5 times or less of the width W of the transverse direction. Hereinafter, the ratio of the longitudinal width L to the lateral width W will be referred to as length ratio.

The heat exchanger of the air conditioner can improve the heat exchange performance as the lengths of the plurality of flat tubes 50 and 70 become longer while the widths of the lower header 30 and the upper header 40 are constant, have. The heat transfer area of the heat exchanger of the air conditioner can be increased as the length of the plurality of flat tubes (50) and (70) becomes longer.

In the heat exchanger of the air conditioner, the longitudinal width (L) of the heat exchange area (Aheat) having the best heat exchanger capability can be confirmed experimentally while the lateral width (W) of the heat exchange area (Aheat) is constant. The heat exchanger capacity of the air conditioner can be confirmed experimentally by the length ratio (L / W) based on the longitudinal width (L) with the best heat exchanger capability. The performance of the heat exchanger can be confirmed while changing the length ratio while keeping all other factors that may affect the performance of the heat exchanger constant such as the air flow rate blown into the heat exchanger of the air conditioner and the mass flow rate of the refrigerant , And the experimental result can be shown as FIG.

As shown in FIG. 10, when the length ratio (L / W) is 2.4, the maximum heat exchanger capacity of the air conditioner can be exerted, and the maximum heat exchanger capacity The length ratio (L / W) capable of exhibiting 95% can be confirmed. The heat exchanger of the air conditioner can be identified by its length ratio (L / W), while maintaining the heat exchanger capacity of approximately 98% of the maximum heat exchanger capacity when the length ratio (L / W) And can maintain a heat exchange performance of about 95% of the maximum heat exchanger capacity when the length ratio is 1.0. It is preferable that the heat exchanger of the air conditioner is designed such that the length ratio (L / W) is larger than 1 and smaller than 2.5.

FIG. 11 is a sectional view showing the inside of the header of the heat exchanger of the air conditioner according to the present invention, FIG. 12 is a sectional view of the header of the heat exchanger of the air conditioner according to the present invention, And the ratio of the total cross-sectional area of the plurality of flat tubes constituting the flow path.

The number of superheated tubes can be minimized when the inner cross sectional area of the upper header 40 and the inner cross sectional area of the lower header 30 are 0.7 times or more of the total cross sectional flow area of the plurality of flat tubes constituting one path. Here, the superheated tube is a flat tube in which overheating occurs when the refrigerant can not be evenly distributed to a plurality of flat tubes.

The inner cross-sectional area of the upper header 40 is an inner cross-sectional area in a direction orthogonal to the longitudinal direction of the upper header 40, and may be a cross-sectional area of the upper flow path PU.

The internal cross-sectional area of the lower header 30 is an internal cross-sectional area in a direction orthogonal to the longitudinal direction of the lower header 30, and may be a cross-sectional area of the first lower flow path PL1 or a cross-sectional area of the second lower flow path PL2.

The inner sectional area Aheader of the upper header 40 and the inner sectional area Aheader of the lower header 30 may be 0.8 times or less of the flow cross sectional area total Acell.

Hereinafter, for the sake of convenience, the inner cross-sectional area of the upper header 40 and the inner cross-sectional area of the lower header 30 will be referred to as the inner cross-sectional area Aheader of the header. The ratio (Aheader / Acell) of the inner cross-sectional area (Aheader) of the header to the flow cross sectional area sum (Acell) of a plurality of flat tubes constituting one path is referred to as a cross sectional area ratio.

The number of the superheating tubes may be different according to the sectional area ratio of the heat exchanger of the air conditioner.

The heat exchanger of the air conditioner has a sectional area of the upper flow path PU and a sectional area of the first lower flow path PL1 and a sectional area of the second lower flow path PL1 PL2 may increase as the cross-sectional area Aheader of the superheated tube increases. Sectional area of the first lower flow path PL1 and the sectional area Aheader of the second lower flow path PL2 are constant, Acell) increases, the rate of occurrence of superheated tubes (%) can be increased.

The heat exchanger of the air conditioner can be confirmed by the experiment that the sectional area ratio in which the superheating tube is minimized or the superheated tube is not generated according to the sectional area ratio. The number of the superheated tubes according to the cross sectional area ratio is changed by changing only the sectional area ratio while keeping all other factors which may affect the generation of the superheated tube such as the air flow rate blown to the heat exchanger of the air conditioner and the mass flow rate of the refrigerant, The number of superheated tubes can be tested, and the experimental result can be shown as in FIG.

The range of the cross sectional area ratio at which the superheated tube is generated at an appropriate level can be determined based on the cross sectional area ratio at which the superheated tube is minimized in the heat exchanger of the air conditioner. When the cross-sectional area ratio of the heat exchanger of the air conditioner is approximately 0.78, the superheat tube may not be generated or minimized. It can be confirmed experimentally that a heat exchanger of the air conditioner generates approximately 10% of the superheated tubes among a plurality of flat tubes when the cross sectional area ratio is approximately 0.67. If the sectional area ratio of the heat exchanger of the air conditioner is 0.7 or more, the superheated tube may be less than 10%, and therefore, it is preferable that the sectional area ratio is 0.7 or more. On the other hand, the heat exchanger of the air conditioner preferably has a sectional area ratio of 0.8 or less.

FIG. 13 is a front view showing a plurality of communication holes and separating portions of an embodiment of a heat exchanger of an air conditioner according to the present invention, FIG. 14 is a perspective view showing a total sum of a plurality of communication hole sectional areas of an embodiment of a heat exchanger of an air conditioner, The cooling efficiency according to the area ratio is shown in the graph.

The area As can be determined by the height H of the second lower flow path PL2 and the width K in the longitudinal direction of the lower header of the second lower flow path PL2. The plurality of communication holes 35, 36, 37, and 38 may have the same or different cross sectional areas. The total sum (Au) cross-sectional area of the plurality of communication holes 35, 36, 37, 38, a plurality of communication holes 35, 36, 37, 38, when the same cross-sectional area of the (π D ² / 4 XN). Here, D is the diameter of the communication hole, and N is the number of the communication holes 35, 36, 37, and 38 formed in the separation portion 39. Area ratio (Au / As) of the plurality of communication holes 35, 36, 37, 38, the cross-sectional area total sum (Au) and the separating portion 39 of the ^{(π D 2/4 XN)} / (HXK) . When the refrigerant passes through the plurality of communication holes 35, 36, 37, and 38 shown in FIG. 13, a mist flow may be generated due to the orifice effect.

If the cross-sectional area of the communication holes 35, 36, 37 and 38 of the air conditioner is too small, the compressor load can be increased and the efficiency can be reduced due to an increase in the pressure loss.

If the sectional area of the communication holes 35, 36, 37 and 38 is too large, the refrigerant is not uniformly distributed to the plurality of communication holes 35, 36, 37 and 38, The efficiency may be lowered.

The plurality of communication holes 35, 36, 37, and 38 can be verified through experiments to maximize the cooling performance of the heat exchanger of the air conditioner. The cooling performance of the heat exchanger of the air conditioner can be confirmed while changing the total cross sectional area of the plurality of communication holes 35, 36, 37, and 38 with respect to the area of the separation portion 39. 13 shows experimental results in which the cooling performance is measured while the other factors that may affect the cooling performance are all the same while the total sum of the sectional areas of the plurality of communication holes 35, 36, 37, and 38 is varied .

Hereinafter, the ratio (Au / As) of the total area of the plurality of communication hole sectional areas Au to the area of the separation area As is referred to as a communication hole area ratio Au / As.

As shown in FIG. 13, the heat exchanger of the air conditioner can exhibit higher cooling performance than the other sections (P, R) in the section (Q) where the communicating hole area ratio (Au / As) is 0.04 to 0.08 have.

In the heat exchanger of the air conditioner, the total sum (Ah) of the plurality of communication hole sectional areas (Ah) with respect to the area of the separation part (As) is too small when the communication hole area ratio (Au / As) is less than 0.04, Lt; / RTI >

The efficiency of the heat exchanger of the air conditioner may be lowered in accordance with the refrigerant imbalance when the area R of the communication hole area ratio (Au / As) exceeds 0.08.

 It is preferable that the total cross sectional area Au of the plurality of communication holes 35, 36, 37 and 38 is 4 to 8% of the area As of the separation portion 39. More preferably, the total cross-sectional area Au of the plurality of communication holes 35, 36, 37, 38 is 5 to 7% of the area As of the separation portion 39.

FIG. 16 is an exploded perspective view showing another embodiment of the heat exchanger of the air conditioner according to the present invention, and FIG. 17 is an exploded perspective view of the air conditioner according to the present invention. FIG. 15 is a perspective view showing another embodiment of the heat exchanger of the air conditioner according to the present invention, FIG. 18 is a top cross-sectional view showing a lower header of another embodiment of the heat exchanger of the air conditioner according to the present invention.

  In the heat exchanger of the air conditioner of this embodiment, a plurality of heat exchange units HU1 '(HU2') may be arranged before and after the air flow direction.

The upper header 40 of any one of the plurality of heat exchange units HU1 'and HU2' may be partitioned into a first upper flow path PU1 and a second upper flow path PU2. The inside of the upper header 40 of any one of the plurality of heat exchange units HU1 'and HU2' is partitioned into a first upper flow path PU1 and a second upper flow path PU2 by a partition wall 43. [ .

An inlet pipe 100 for introducing refrigerant into the first upper flow path PL1 of any one of the plurality of heat exchange units HU1 'and HU2' may be connected. An outlet pipe 110 for guiding refrigerant outflow may be connected to the second upper flow path PL2 of one of the plurality of heat exchange units HU1 'and HU2'.

The upper header 40 of the other one of the plurality of heat exchange units HU1 'and HU2' may be formed such that one upper flow path PU is elongated in the longitudinal direction of the upper header 40 . The inlet pipe 100 and the outlet pipe 110 may not be connected to the other one of the plurality of heat exchange units HU1 'and HU2'.

A first lower flow path PL1 formed in the lower header 30 'of any one of the plurality of heat exchange units HU1' and HU2 'and a second lower flow path PL2 formed in the plurality of heat exchange units HU1' and HU2 ' The first lower flow path PL1 formed in the lower header 30 'of the other HU2' may communicate with the plurality of first communication holes 35 ', 36', 37 ', 38' .

The first lower flow path PL1 formed in the lower header 30 'of any one of the plurality of heat exchange units HU1' and HU2 'and the other of the plurality of heat exchange units HU1' and HU2 ' A first separating portion 35 'having a plurality of first communication holes 35', 36 ', 37', and 38 'is formed between the first lower flow path PL1 formed in the lower header 30' of one HU2 ' Lt; RTI ID = 0.0 > 39 '. ≪ / RTI >

The total cross sectional area of the plurality of first communication holes 35 ', 36', 37 ', 38' may be 4 to 8% of the area of the first separator 39 '. The effect of the total cross sectional area of the first communication holes 35 ', 36', 37 ', and 38' and the area of the first separator 39 'is the same as or similar to that of the first embodiment of the present invention A detailed description thereof will be omitted.

A second lower flow path PL2 formed in the lower header 30 'of one of the plurality of heat exchange units HU1' and HU2 'and a second lower flow path PL2 formed in the lower header 30' of the plurality of heat exchange units HU1 'and HU2' The second lower flow path PL2 formed in the lower header 30 'of the other HU2' may communicate with the plurality of second communication holes 35, 36, 37,

The second lower flow path PL2 formed in the lower header 30 'of any one of the plurality of heat exchange units HU1' and HU2 'and the other of the plurality of heat exchange units HU1' and HU2 ' A second separation portion 39 formed with a plurality of second communication holes 35, 36, 37 and 38 is formed between the second lower flow path PL2 formed in the lower header 30 'of one HU2' Lt; / RTI >

The total cross sectional area of the plurality of second communication holes 35, 36, 37, 38 may be 4 to 8% of the area of the second separation portion 39. The effect of the sectional area sum of the plurality of second communication holes 35, 36, 37 and 38 and the area of the second separator 39 is the same as or similar to that of the embodiment of the present invention, It is omitted.

The plurality of heat exchange units HU1 'and HU2' include an electrothermal heat exchanging unit HU1 'through which the refrigerant first passes and a rear heat exchanging unit HU2' through which the refrigerant passing through the electrothermal heat exchanging unit HU1 ' And the refrigerant in the liquid pipe 10 flows into the channel of the electrothermal heat exchanging unit HU1 'through the inlet pipe 100 and passes through a part of the flow path of the electrothermal heat exchanging unit HU1' As shown in FIG. The refrigerant flowing into the flow path of the rear heat exchanging unit HU2 'can pass through the entire flow path of the rear heat exchanging unit HU2' and then can flow into the rest of the flow path of the heat heat exchanging unit HU2 '. The refrigerant passing through the rest of the flow path of the heat transfer heat exchanging unit HU2 'may flow to the engine 11 through the outlet pipe 110. [

The partition wall 43 is formed in the upper header 40 of the electrothermal heat exchanging unit HU1 'so that the first heat exchanger HU1' The inlet pipe 100 is connected to the first upper flow path PU1 instead of the first lower flow path PL1 and the outlet pipe 110 is connected to the first upper flow path PU2, The first lower flow path PL1 of the heat transfer heat exchange unit HU1 'and the first lower flow path PL1 of the rear heat exchange unit HU2' are connected to the second upper flow path PU2 other than the second lower flow path PL2, A plurality of communication holes 35 ', 36', 37 ', and 38' that communicate with each other are formed, and other configurations are the same as those of the embodiment of the present invention, Is omitted.

The heat transfer heat exchanging unit HU1 'is connected to the first header passage PU1 formed in the upper header 40' of the heat transfer heat exchange unit HU1 'and the first header channel PU2 formed in the lower header 30' of the heat transfer heat exchange unit HU1 ' And a first group of flat tubes 50 for communicating the lower flow path PL1. The electrothermal heat exchange unit HU1 'is connected to the second lower flow path PL2 formed in the lower header 30' of the electrothermal heat exchange unit HU1 'and the second lower flow path PL2 formed in the upper header 40' of the electrothermal heat exchange unit HU1 ' And a second group of flat tubes 70 for communicating the upper flow path PU2.

The rear heat exchanger unit HU2 'is constituted by a first lower flow path PL1 formed in the lower header 30' of the rear heat exchange unit HU2 'and a second lower flow path PL2 formed in the upper header 40' of the rear heat exchange unit HU2 ' And a rear row first group flat tube 50 communicating the flow paths PU. The rear heat exchanging unit HU2 'is connected to the upper flow path PU formed in the upper header 40' of the rear heat exchanging unit HU2 'and the second flow path PU formed in the lower header 30' of the rear heat exchanging unit HU2 ' And a rear row second group flat tube 70 communicating the flow path PL2.

The heat exchanger of the air conditioner is composed of an electrothermal heat exchanger unit HU1 'to which the inlet pipe 100 and the outlet pipe 110 are connected and a rear heat exchanger unit HU2' to which the inlet pipe 100 and the outlet pipe 110 are not connected ') Is described in detail.

Hereinafter, the lower header 30 'of the electrothermal heat exchanging unit HU1' will be referred to as a heat transfer lower header. The plurality of flat tubes 50, 70 of the heat transfer heat exchanging unit HU1 ' The upper header 40 'of the electrothermal heat exchange unit HU1' will be referred to as a heat-transferring upper header.

The plurality of flat tubes 50 and 70 of the rear heat exchanger unit HU2 'are referred to as a plurality of rear heating tubes. The lower header 30' of the rear heat exchanger unit HU2 ' The upper header 40 'of the rear heat exchanger unit HU2' will be referred to as a rear header.

The heat exchanger of the air conditioner may be constructed such that the heat transfer lower header and the heat transfer lower header are joined to each other, the heat transfer upper header and the heat transfer upper header may be joined together, and the heat transfer plural flat tubes and the heat transfer plural flat tubes may be spaced in the air flow direction .

The heat exchanger of the air conditioner includes a first separating portion 39 'in which a plate portion to which an electrothermal lower header and a rear end lower header are joined is formed with a plurality of first communication holes 35', 36 ', 37', and 38 ' And a second separation portion 39 having a plurality of second communication holes 35, 36, 37, and 38 formed therein. When the heat transfer lower header plate portion of the electrothermal heat exchange unit HU1 'and the header header front plate portion of the rear heat exchanger unit HU2' are joined, the heat transfer lower header plate portion of the electrothermal heat exchanging unit HU1 'and the rear heat exchanging unit HU2 Each of the rear header lower front plate portions of the rear header lower plate portion of each of the plurality of first communication holes 35 ', 36', 37 ', and 38' and the plurality of second communication holes 35, 36, 37, The plurality of first communication holes 35 ', 36', 37 ', and 38' and the plurality of second communication holes 35, 36, 37, and 38 may be separated from each other (39 ') and (39), respectively.

The first separator 39 'may be formed between the first lower flow path PL1 of the sub-header and the first lower flow path PL1 of the header of the subsequent header, PL1 are distributed to a plurality of first communication holes 35 ', 36', 37 ', and 38' formed in the first separator 39 ', and the first lower flow path PL1 ). ≪ / RTI >

The second separation portion 39 may be formed between the second lower flow path PL2 of the header lower header and the second lower flow path PL1 of the heat transfer lower header and the second lower flow path PL2 May be distributed to a plurality of second communication holes 35, 36, 37, and 38 formed in the second separator 39 and flow to the second lower flow path PL2 of the heat transfer lower header . The second separator 39 has the same structure as the separator 39 of the embodiment of the present invention and the plurality of second communication holes 35, 36, 37, and 38 are formed in the communication hole 35, 36, 37, and 38, and only the direction in which the refrigerant passes may be different from the embodiment of the present invention.

The heat exchanger of the air conditioner can flow refrigerant from the inlet pipe 100 to the first upper flow path PU1 of the heat transfer upper header and be dispersed in the first upper flow path PU1 of the heat transfer upper header, And can flow downward while passing through the flat tube 50.

The refrigerant can then flow into the first lower flow path PL1 of the sub-header, the flow direction of the refrigerant in the first lower flow path PL1 of the sub-header can be reversed, and the plurality of first communication holes 35 ') 36', 37 ', 38', and through the first separator 39 '.

The refrigerant that is dispersed while passing through the plurality of first communication holes 35 ', 36', 37 ', and 38' may be introduced into the first lower flow path PL1 of the downstream header.

The refrigerant introduced into the first lower flow path PL1 of the rear sub-header may flow upward while passing through the rear group first flat tube 50.

The refrigerant can then flow to the upper flow path PU of the header upper header and horizontally to the upper side of the rear row second group flat tube 70.

Thereafter, the refrigerant may flow downward while passing through the rear row second group flat tubes 70, and may flow to the second lower flow channel PL2 of the rear row lower header.

The refrigerant flowing into the second lower flow path PL2 of the rear lower header can be bent in the flow direction of the refrigerant and then dispersed in the plurality of second communication holes 35, 36, 37, (39). ≪ / RTI >

The refrigerant that has been dispersed while passing through the plurality of second communication holes 35, 36, 37 and 38 can be introduced into the second lower flow path PL2 of the heat transfer lower header.

The refrigerant flowing into the second lower flow path PL2 of the electrothermal lower header may flow upward while passing through the second group flat tube 70.

The refrigerant that has flowed to the upper side of the heat transfer second group flat tube (70) can flow to the second upper flow path (PU2) of the heat transfer upper header.

The refrigerant that has flowed into the second upper flow path PU2 of the upper header of the heat is then introduced into the outlet pipe 110 and can pass through the outlet pipe 110. The refrigerant passes through a part of the heat transfer heat exchanging unit HU1 ' Can be flowed to the engine 11 in a state of sequentially exchanging heat with the heat from the heat exchange unit HU2 and the remainder of the heat transfer heat exchange unit HU1 '.

  Hereinafter, the first upper flow path PU1 of the heat transfer upper header is referred to as a heat transfer upper first flow path, the first lower flow path PL1 of the heat transfer lower header is referred to as a heat transfer lower first flow path, The second lower flow path PL2 of the header of the lower header is referred to as a second lower flow path and the second lower flow PL2 of the lower header of heat transfer is referred to as a second lower flow path And the second upper flow path PL2 of the upper header is referred to as a second upper flow path, and the flow of the refrigerant will be described below.

The refrigerant in the liquid pipe 10 sequentially passes through the heat transfer upper first flow path, the heat transfer first group flat flow path, and the heat transfer lower first flow path in the inlet pipe 100, and passes through a part of the flow path of the heat transfer heat exchange unit HU1 ' .

The refrigerant in the first lower flow path is flowed into the rear heat exchanging unit HU2 'by being introduced into the first lower flow path through the first communication holes 35', 36 ', 37', and 38 ' . The refrigerant in the first sub-flow passage of the rear row can pass through the rear heat exchanging unit (HU2 ') sequentially through the first row group flat tube, the upper flow passage, the rear row second group tube and the rear row lower second flow passage.

The refrigerant in the second lower flow path can flow into the heat transfer heat exchange unit HU1 'by being introduced into the second heat transfer sub-flow path through the second communication holes 35, 36, 37, The refrigerant in the second sub-passage may sequentially pass through the second sub-group tube and the second sub-passage and pass through the remaining channels of the heat transfer heat exchanging unit HU1 '. The refrigerant in the electrothermal upper second flow path may flow to the engine 11 through the outlet pipe 110.

2: compressor 4: outdoor heat exchanger
6: Expansion mechanism 8: Indoor heat exchanger
30: Lower header 33:
40: upper header 43: partition wall
50, 70: a plurality of flat tubes 90: pins
100: inlet pipe 110: outlet pipe
HU1: Heat transfer heat exchanger unit HU2: Post heat exchanger unit
PL1: first lower flow path PL2: second lower flow path
PU: upper flow path PU1: first upper flow path
PU2: second upper flow path

Claims (20)

A lower header formed with a lower flow path;
An upper header formed with an upper flow path;
A plurality of flat tubes each having a plurality of flow passages communicating with the lower flow path and the upper flow path;
And a heat exchange unit having a fin disposed between the plurality of flat tubes,
Wherein the lower flow path is divided into a first lower flow path in which a part of the plurality of flat tubes are in communication and a second lower flow path in which the remaining of the plurality of flat tubes are in communication,
Wherein a plurality of the heat exchange units are arranged before and after the air flow direction,
An inlet pipe for introducing refrigerant into the first lower flow path formed in the lower header of any one of the plurality of heat exchange units is connected,
And an outlet pipe through which the refrigerant flows out is connected to the first lower flow path formed in the lower header of the other of the plurality of heat exchange units,
A plurality of communication holes are communicated with a separation section between a second lower flow path formed in a lower header of any one of the plurality of heat exchange units and a second lower flow path formed in another lower header of the plurality of heat exchange units,
Wherein the heat exchange area in which the plurality of flat tubes and the fin are heat-exchanged with air has a width in the longitudinal direction longer than a width in the transverse direction,
The inner cross sectional area of the upper header and the inner cross sectional area of the lower header are 0.7 times or more of the total cross sectional flow area of the plurality of flat tubes constituting one path,
Wherein the sectional area sum of the plurality of communication holes is 4 to 8% of the area of the separating area. The method according to claim 1,
Wherein the upper header is configured such that the refrigerant flowing into the upper flow path through a part of the plurality of flat tubes hits an upper inner wall surface of the upper header and then flows out to the rest of the plurality of flat tubes. The method according to claim 1,
Wherein the inlet tube guides the refrigerant in a direction orthogonal to the plurality of flat tubes. The method according to claim 1,
And the inlet pipe communicates with one of the first lower flow path and the second lower flow path. The method according to claim 1,
Wherein the inlet pipe includes a plurality of branch pipes. The method according to claim 1,
Wherein the total cross-sectional area of the flow path is determined by the equation (1).
[Equation 1] Acell = Tn X Cn XA
Here, the Acell is the sum of the cross-
Tn is the number of flat tubes constituting one pass,
Cn is the number of flow paths formed in each of the plurality of flat tubes,
A is the cross-sectional area of the flow path. The method according to claim 1,
Wherein an inner cross-sectional area of the upper header and an inner cross-sectional area of the lower header are 0.8 times or less of the total cross-sectional area of the flow channel. The method according to claim 1,
Wherein the width in the longitudinal direction is at least 1.5 times the width in the transverse direction. The method according to claim 1 or 8,
Wherein the width in the longitudinal direction is not more than 2.5 times the width in the transverse direction. delete delete delete delete delete delete delete delete A lower header formed with a lower flow path;
An upper header formed with an upper flow path;
A plurality of flat tubes each having a plurality of flow passages communicating with the lower flow path and the upper flow path;
And a heat exchange unit having a fin disposed between the plurality of flat tubes,
Wherein the lower flow path is divided into a first lower flow path in which a part of the plurality of flat tubes are in communication and a second lower flow path in which the remaining of the plurality of flat tubes are in communication,
Wherein a plurality of the heat exchange units are arranged before and after the air flow direction,
An inlet pipe for introducing refrigerant into the first lower flow path formed in the lower header of any one of the plurality of heat exchange units is connected,
And an outlet pipe through which the refrigerant flows out is connected to the first lower flow path formed in the lower header of the other of the plurality of heat exchange units,
A plurality of communication holes are communicated with a separation section between a second lower flow path formed in a lower header of any one of the plurality of heat exchange units and a second lower flow path formed in another lower header of the plurality of heat exchange units,
Wherein each of the inner cross sectional area of the upper header and the inner cross sectional area of the lower header is 0.7 times or more of the total cross sectional flow area of the plurality of flat tubes constituting one path,
Wherein the sectional area sum of the plurality of communication holes is 4 to 8% of the area of the separating area. 19. The method of claim 18,
Wherein the total cross-sectional area of the flow path is determined by the equation (1).
[Equation 1] Acell = Tn X Cn XA
Here, the Acell is the sum of the cross-
Tn is the number of flat tubes constituting one path,
Cn is the number of the flow paths formed in each of the plurality of flat tubes,
A is the cross-sectional area of the flow path. 19. The method of claim 18,
Wherein an inner cross-sectional area of the upper header and an inner cross-sectional area of the lower header are 0.8 times or less of the total cross-sectional area of the flow channel.

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