DE102004047304A1 - Subcooling condenser - Google Patents

Abstract

In a subcooling condenser (1) in which a plurality of heat transfer tubes (4) connect a pair of header tubes (2, 3), the heat exchanger core (6) is divided into a refrigerant condensation core (7) and a subcooling core (8) That is, the heat transfer tubes of the refrigerant condensation core (7) are formed as tubes in which inner fins are accommodated, and the heat transfer tubes of the subcooling core (8) are formed as tubes whose inner spaces are divided by dividing walls into a plurality of flow paths, different from each other , While maintaining a desired heat radiation performance, the flow resistance of the entirety of the condenser (1) can be reduced.

Description

The The present invention relates to a supercooling condenser and to more specific a hypothermic Capacitor for use in an air conditioning system for vehicles, etc., and the total flow resistance of the assembly of the capacitor while retaining the advantages due to the subcooling Type can reduce.

It is a hypothermic Condenser known in which a plurality of heat transfer tubes, which are extend parallel to each other, a pair of manifolds with each other connect, in which a heat exchanger core of the condenser into a refrigerant condensation core for condensing refrigerant and a subcooling Core for subcooling of refrigerant, that of the refrigerant condensation core condensed, is divided, and which has an excellent refrigerant condensing ability can provide while at the same time making the whole of a cooling system small and inexpensive, by forming it as a capacitor integral with a liquid pressure vessel formed is (for example, JP-A-2002-31436). In such a supercooling condenser can by forming the refrigerant condensation core in a structure of a one-way of the refrigerant, the structure of the Capacitor be simplified and the capacitor can be made small (for example JP-A-2002-31436).

However, even if the refrigerant condensation core is formed in a one-lane structure of the refrigerant, it is considered necessary to maintain a target refrigerant condensation function of the refrigerant condensation core and a target refrigerant supercooling function of the undercooling core, a ratio in resistance between the headers and the heat pipes within a specified range (for example, JP-A-2000-111274). In order to satisfy such a relationship in resistance, in JP-A-2002-31436 or JP-A-2000-111274, the same structure as that of the heat transfer tubes of the refrigerant condensation core is used as the structure of the heat transfer tubes of the subcooling core, and in Figs Specifically, a heat transfer tube into which an inner fin for accommodating a complicated three-dimensional flow is accommodated in the tube is used. For example, in a subcooling condenser 101 who in 11 shown is a pair of manifolds 102 . 103 by a plurality of heat transfer tubes 104 , which extend parallel to each other, connected, wave-like ribs 105 are between adjacent pipes 104 arranged a heat exchanger core 106 is in a refrigerant condensation core 107 , the refrigerant flowing from a refrigerant inlet 109 into the manifold 102 is introduced, condensed, and a supercooling core 108 split the refrigerant flowing from the refrigerant condensation core 107 was condensed and from the lower section of the manifold 103 is introduced, further supercooled, the supercooled refrigerant is from an outlet 110 left out, leaving the refrigerant condensation core 107 is formed in a structure of a one-way of the refrigerant in an air flow direction A, and in such a sub-cooling condenser 101 becomes the same structure, which is an inner rib 111 , which forms a three-dimensional flow of the refrigerant in the tube, contains, for heat transfer tubes 104 of the refrigerant condensation core 107 and heat transfer tubes 104 the hypothermic core 108 used.

If such a heat transfer tube, the a three-dimensional flow is used in a pipe, but is used, in particular the undercooling Core in a fluid area for passing the condensed liquid refrigerant, the flow resistance of the same large, and the flow resistance the entirety of the undercooling Capacitor increases. When the flow resistance of the whole increases the load on the whole of the cooling system, that contains the capacitor, too, and in particular takes the power consumption of a compressor to. For example, it may be in a cooling system in an air conditioning system for vehicles, for this The power consumption of a compressor is demanded that this as far as possible is reduced, be necessary, the flow resistance described above keep down the totality of the capacitor as small as possible.

For the purpose common to a reduction of the flow resistance of the subcooling core, JP-A-10-9714 describes a structure in which an air-cooling cross-finned condenser using an HFC refrigerant mixture of R404A, R507, R407C and the like ( an air-cooling cross-finned condenser using a U-shaped tube as a heat transfer tube for passing a heat exchange medium), the diameter of the heat transfer tube of the supercooling section is set larger than the diameter of the heat transfer tube of the condensation section. However, this capacitor is a capacitor of a completely different type, and not a single type of refrigerant is used, and therefore, this structure is not for the object of of the present invention as it is to be solved applied.

Accordingly, it is an object of the present invention, an improved structure a hypothermic one To provide capacitor in a subcooling A condenser in which a plurality of heat transfer tubes extending extend parallel to each other, connect a pair of headers, a heat exchanger core of the condenser into a refrigerant condensation core for condensing refrigerant and a subcooling Core for subcooling of refrigerant, that of the refrigerant condensation core was condensed, is divided, and where the refrigerant condensation core is formed in a structure of a one-way of refrigerant, the flow resistance can greatly reduce the totality of the capacitor without doing so the advantages due to the one-way structure of the refrigerant condensation core to impair. This would achieve an object of the present invention, namely that the power consumption of a compressor in a case that this in an air conditioning system for Vehicles is applied, can be reduced, and efficiency the totality of the system increases can be while the advantages due to the one-way structure, such as a design freedom of the refrigerant inlet pipe side, when it is attached to a vehicle to be maintained.

The Task is solved through a subcooling Capacitor according to claim 1.

Around to solve the above problem is a hypothermic Capacitor according to the present invention Invention provided, which includes a pair of manifolds and a plurality of heat transfer tubes, which connect the pair of manifolds together and in parallel extend to each other, wherein a heat exchanger core of the capacitor into a refrigerant condensation core for Condensing refrigerant and a subcooling Core for subcooling of refrigerant, that from the refrigerant condensation core has been condensed, wherein the refrigerant condensation core is formed in a structure of a one-way of the refrigerant, characterized in that heat transfer tubes of the refrigerant condensation core and heat transfer tubes of the undercooling Kernes as heat transfer tubes are formed, which differ from each other, so that a Heat transfer tube for the refrigerant condensation core as a heat transfer tube is formed, in the same an inner rib, the three - dimensional flow of the refrigerant forms in the tube, and receives a heat pipe for the subcooling Core formed as a heat transfer tube is, whose interior in a plurality of flow paths in an air flow direction through partitions, which are integrally formed with the tube is divided (a first aspect of the present invention).

The Task is also solved through a subcooling A capacitor according to claim 3.

Further is a hypothermic Capacitor according to the present invention Invention provided, which includes a pair of manifolds and a plurality of heat transfer tubes, which connect the pair of manifolds together and in parallel extend to each other, wherein a heat exchanger core of the capacitor in a refrigerant condensation core for condensing refrigerant and a subcooling Core for subcooling of refrigerants, condensed by the refrigerant condensation core was subdivided, wherein the refrigerant condensation core in a structure a one-way of refrigerant is formed, characterized in that heat transfer tubes of the refrigerant condensation core and heat transfer tubes of the undercooling Kernes as heat transfer tubes are formed, which differ from each other, so that a Heat pipe for the Refrigerant condensation core as a heat transfer tube is formed, in the same an inner rib, which is a three-dimensional flow of refrigerant forms in the tube, receives, and a heat transfer tube for the subcooling Core as a heat pipe is formed, the interior of which in a plurality of flow paths in an air flow direction divided by an inner rib received in the tube is (a second aspect of the present invention).

The Task is also solved through a subcooling A capacitor according to claim 5.

Further, a supercooling condenser according to the present invention is provided, comprising a pair of header pipes and a plurality of heat transfer tubes connecting the pair of header pipes and extending in parallel to each other, wherein a heat exchange core of the condenser into a refrigerant condensation core for condensing refrigerant and a subcooling core for subcooling refrigerant condensed by the refrigerant condensation core is divided, wherein the refrigerant condensation core is formed in a structure of a one-way of the refrigerant, characterized in that heat transfer tubes of the Refrigerant condensation core and heat transfer tubes of the subcooling core are both formed in a configuration in which the interior of each of the tube is divided into a plurality of flow paths in an air flow direction, and the heat transfer tubes of the refrigerant condensation core and the heat transfer tubes of the subcooling core formed as heat transfer tubes are different from each other, so that a pressure loss per heat transfer tube in a heat transfer tube for the subcooling core is set lower than that in a heat transfer tube for the refrigerant condensation core, at a same fluid passage condition (a third aspect of the present invention).

at This third aspect of the present invention can provide a Structure used in which either at least one of the heat transfer tube for the Refrigerant condensation core and the heat transfer tube for the supercooling Core as a heat pipe is formed, the interior of which in a plurality of flow paths through partitions that are integrally formed with the tube, in an air flow direction is divided, or at least one of the heat transfer tube for the Refrigerant condensation core and the heat transfer tube for the supercooling Core as a heat pipe is formed, the interior of which in a plurality of flow paths in an air flow direction divided by an inner rib received in the tube is.

The Task is also solved through a subcooling A capacitor according to claim 9.

Furthermore is a hypothermic Capacitor according to the present invention Invention provided, which includes a pair of manifolds and a plurality of Heat transfer tubes, which connect the pair of manifolds, and in parallel extend to each other, wherein a heat exchanger core of the capacitor Kon in a refrigerant condensation core for condensing refrigerant and a subcooling Core for subcooling of refrigerant, that of the refrigerant condensation core has been condensed, wherein the refrigerant condensation core is formed in a structure of a one-way of the refrigerant, characterized in that a flow resistance of the subcooling Kernes to 1/2 or less of a total flow resistance of the ensemble of the capacitor is fixed (a fourth aspect of the present Invention). This fourth aspect may be used together with those described above First, second and third aspects of the present invention be used.

further developments The invention are each characterized in the subclaims.

at such undercooling Capacitors according to the present invention Invention are the structures of the heat transfer tubes of the refrigerant condensation core and the heat transfer tubes of the undercooling Kernes, in the conventional Technology were used in a same structure as heat transfer tube structures formed, which differ from each other, and the pressure loss per heat transfer tube in a heat transfer tube for the undercooling Core is set lower than that in a heat transfer tube for the Refrigerant condensing core. In this case, the flow resistance of the undercooling Kernes set so that it is much lower than that of a hypothermic Kernes in a conventional supercooling Capacitor is, while the flow resistance of the whole of the capacitor is greatly reduced. The goal of the reduction of flow resistance is it, the conventional flow resistance, 2/3 or more of the flow resistance the totality of the capacitor down to 1/2 or reduce less of it. In such a cool Capacitor, the flow resistance the entirety of the capacitor, in particular by reducing the flow resistance the hypothermic core, reduced while the advantages of the integral structure with the undercooling Core can be maintained, it becomes possible to power consumption a compressor in a case where the condenser in a cooling system is installed, reduce.

Therefore can be at the subcooling Capacitor according to the present invention Invention while the advantages due to the one-way structure of the refrigerant condensation core retained, such as benefits that allow the Condenser simple and small form, and which the design freedom the refrigerant inlet pipe side, if the condenser is attached to a vehicle, increase one Power consumption of a compressor when the condenser in one Air conditioning system for Vehicles used, reduced, and efficiency of Totality of the system can be increased become.

Further Features and Practices of Invention will become apparent from the description of embodiments with reference to the attached drawings. From the figures show:

1 FIG. 15 is a perspective view of a subcooling capacitor according to a first embodiment of the present invention. FIG.

2 FIG. 15 is an enlarged partial perspective view of a heat transfer tube of a refrigerant condensation core in the subcooling condenser, which is shown in FIG 1 is shown.

3 is an enlarged perspective partial view of a heat transfer tube of a subcooling core in the subcooling condenser, which in 1 is shown.

4 FIG. 16 is a graph showing a relationship between the refrigerant inclusion amount and the flow resistance of a conventional supercooling condenser shown in FIG 11 is shown, shows.

5 FIG. 16 is a graph showing a relationship between the refrigerant inclusion amount and the flow resistance of the subcooling condenser, which is shown in FIG 1 shown shows.

6 Fig. 12 is a graph showing a relationship between the wind speed of the wind and the heat radiation performance of a product according to the present invention and a product according to a conventional technology.

7 Fig. 12 is a graph showing a relationship between the refrigerant circulation amount and the flow resistance in a product according to the present invention and a product according to a conventional technology.

8th FIG. 14 is a partial perspective view of a heat transfer tube of a subcooling core in a subcooling condenser according to a second embodiment of the present invention. FIG.

9 FIG. 15 is a partial perspective view of a heat transfer tube of a refrigerant condensation core in a subcooling condenser according to a third embodiment of the present invention. FIG.

10 FIG. 14 is a partial perspective view of a heat transfer tube of a subcooling core in the subcooling condenser according to the third embodiment of the present invention. FIG.

11 FIG. 12 is a perspective view of a conventional supercooling condenser. FIG.

The 1 to 3 show a supercooling condenser according to a first embodiment of the present invention and correspond to the aforementioned first aspect of the present invention. In 1 has a subcooling capacitor 1 a pair of headers 2 . 3 , a plurality of heat transfer tubes 4 holding the pair of headers 2 . 3 connect together and extend parallel to each other, and wave-like ribs 5 on, between each adjacent heat transfer tubes 4 are arranged. A heat exchanger core 6 is in a refrigerant condensation core 7 for condensing refrigerant coming from a refrigerant inlet pipe 9 into the manifold 2 is introduced, and a hypothermic core 8th to further sub-cool the refrigerant coming from the refrigerant condensation core 7 was condensed and from the lower section of the manifold 3 is sub-divided, and the supercooled refrigerant is from a refrigerant outlet pipe 10 omitted. The refrigerant condensation core 7 namely, is formed in a structure of a one-way of refrigerant, the manifold 2 is through a separation 11 divided into an upper and a lower portion and the upper and lower portions of the interior of the manifold 3 communicate with each other so that a liquid refrigerant can be stored therein. In the manifold 3 is a holding plate 12 , which has a central connecting part, provided, and it may be a component, which in the collecting pipe 3 is used, such as holding a structure member for holding desiccant or a filter (not shown) while maintaining the vertical connection structure.

In such a supercooling condenser 1 According to this embodiment, as it is in 2 shown is the heat transfer tube 4 for the refrigerant condensation core 7 as a heat transfer tube 4a formed, which has essentially the same structure as that in 11 having a structure, in which an inner rib 14 in a tubular body 13 for forming a three-dimensional flow of refrigerant in the tubular body 13 is used. As in 3 is shown is the heat transfer tube 4 for the undercooling core 8th as a heat transfer tube 4b formed, wherein the interior of the tube in a plurality of small flow paths 16 in an air flow direction A through partitions 15 , which are formed integrally with the tubular body, is divided. Consequently, the heat transfer tubes 4a of the refrigerant condensation core 7 and the heat transfer tubes 4b the hypothermic core 8th formed as heat transfer tubes, which differ from each other in the inner structure.

Undercool with the above the capacitor 1 is, although the interior of the heat pipe 4b into a plurality of small flow paths 16 is divided because the corresponding flow paths 16 are formed as flow paths extending straight in the same direction Rohrerstreckungs, the flow resistance (pressure drop) per tube very small compared to the heat transfer tube 4a of the refrigerant condensation core 7 into which the inner rib 14 , which forms a three-dimensional flow, is used. As a result, the flow resistance of the entirety of the subcooling core 8th greatly reduced and the flow resistance of the whole of the supercooling condenser 1 is also greatly reduced.

The 4 and 5 show, by way of example, comparisons of the flow resistance (pressure difference between inlet and outlet of a condenser) between a conventional product and the condenser according to the first embodiment of the present invention described above. For example, in the conventional, in 11 shown capacitor is as in 4 That is, when the refrigerant inclusion amount decreases although the ratio slightly varies, the flow resistance of the subcooling core is 2/3 or more of the flow resistance of the entirety of the condenser, and the flow resistance of the entirety of the condenser is relatively high. On the other hand, with the subcooling condenser 1 according to the first embodiment of the present invention as described above 5 is shown, even if the refrigerant entrapment amount varies, the flow resistance of the subcooling core is suppressed to be only 1/2 or less of the flow resistance of the entirety of the condenser, and the flow resistance of the entirety of the condenser is compared to that in FIG 4 reduced shown.

Further shows 6 the heat radiation power relative to the velocity of the air passing through the subcooling condenser, that is, relative to the forward wind speed of the subcooling condenser. As in 6 is shown, there is almost no difference in the heat dissipation between the in 1 pictured product according to the present invention and the conventional product used in 11 is pictured on.

In addition, shows 7 the flow resistance of the entirety of the condenser relative to the refrigerant circulation amount. As in 7 is shown, the flow resistance of the in 1 imaged product according to the present invention, compared to the flow resistance of the conventional product, which in 11 is shown.

And that is possible with the supercooling condenser 1 according to the present invention, in 1 while maintaining a desired heat exchange performance, that is, a desired heat radiation performance, and the advantages due to the one-way structure of the refrigerant condensation core 7 such as advantages that make it possible to make the condenser simple and small and to increase the freedom of design of the refrigerant inlet pipe side when the condenser is mounted on a vehicle, by greatly reducing the flow resistance of the entirety of the condenser. When the subcooling capacitor 1 is installed in a cooling system of an air conditioning system for vehicles, a power consumption of a compressor can be greatly reduced, and the efficiency of the entirety of the system can be increased.

8th shows a heat transfer tube of a subcooling core in a subcooling condenser according to a second embodiment of the present invention. The structures of the other sections, in particular the structure of a heat transfer tube 4a of the refrigerant condensation core 7 , are essentially the same as those in the 1 and 2 are shown. This embodiment corresponds to the aforementioned second aspect of the present invention, in which embodiment the heat transfer tube 21 for the undercooling core 8th is formed as a heat transfer tube, the interior thereof into a plurality of flow paths in an air direction A through an inner rib 22 that in the pipe 21 is included, divided, and corresponding small flow paths 23 passing through the inner rib 22 be divided, parallel to each other straight in the pipe extension direction.

Also, in such a subcooling condenser, the heat transfer tubes 4a of the refrigerant condensation core 7 and the heat transfer tubes 21 the hypothermic core 8th formed as heat transfer tubes, which differ from each other, and in the heat transfer tube 21 for the undercooling core 8th whose interior is in a plurality of small flow paths 23 is divided, the flow resistance per pipe (pressure loss) is very small, compared to the heat transfer tube 4a for the refrigerant condensation core 7 in which an inner rib 14 is used to form a three-dimensional flow. As a result, the flow resistance of the entirety of the subcooling core 8th greatly reduced, and the flow resistance of the whole of the supercooling condenser 1 is also greatly reduced. Therefore, services similar to those used in the 5 to 7 shown are provided.

The 9 and 10 show heat transfer tubes of a subcooling capacitor according to a third embodiment of the present invention, wherein 9 a heat transfer tube 31 a refrigerant condensation core 7 shows or 10 a heat transfer tube 32 a hypothermic core 8th shows. The structures of the other sections are essentially the same as those in 1 are shown. This embodiment corresponds to the aforementioned third aspect of the present invention, wherein the heat transfer tube 31 of the refrigerant condensation core 7 and the heat transfer tube 32 the hypothermic core 8th both are formed in a configuration in which the interior of the tube is divided into a plurality of flow paths in an air flow direction A and the respective heat transfer tubes 31 and 32 are formed as heat transfer tubes that differ from each other, so that the pressure loss per tube from the heat transfer tubes 32 the hypothermic core 8th becomes lower than that of the heat transfer tubes 31 of the refrigerant condensation core 7 , Further, at least one of the heat transfer tubes 31 and 32 , in this embodiment, both of the heat transfer tubes 31 and 32 formed as a heat transfer tube, wherein the interiors of the respective tubes in a plurality of small flow paths 35 . 36 is divided in an air flow direction A and the corresponding small flow paths 35 . 36 extend parallel to each other straight in the corresponding pipe extension directions. In this embodiment, although the number of small flow paths 35 . 36 per tube is the same, the small flow path 36 formed in the cross-sectional area larger than the small flow path 35 such that the flow resistance per tube from the heat transfer tube 32 the hypothermic core 8th is set to be smaller than that of the heat transfer tube 31 of the refrigerant condensation core 7 is.

Also, in such a subcooling condenser, the heat transfer tubes 31 of the refrigerant condensation core 7 and the heat transfer tubes 32 the hypothermic core 8th are formed as heat transfer tubes that are different from each other and the flow resistance (pressure loss) per tube from the heat transfer tube 32 the hypothermic core 8th , whose flow area is set larger, becomes very small compared to the heat transfer tube 31 for the refrigerant condensation core 7 , whose flow area is set smaller. As a result, the flow resistance of the entirety of the subcooling core 8th greatly reduced and the flow resistance of the whole of the supercooling condenser 1 is also greatly reduced. Therefore, services similar to those used in the 5 to 7 shown are presented.

In the embodiment described above, although a structure is used, the interiors of the two heat transfer tubes may be used 31 . 32 into a plurality of small flow paths 35 . 36 through partitions 33 . 34 , which are formed integrally with the tubular bodies, are divided, at least one heat transfer tube in a structure such as a in 8th is shown, wherein the interior of the tube is divided into a plurality of flow paths in the air flow direction by an inner rib which is received in the tube.

Further, in the respective embodiments described above, the flow resistance of the subcooling core is preferable 8th to set 1/2 or less of the flow resistance of the entirety of the capacitor. It is desirable to satisfy such a relationship of the flow resistance irrespective of the structures of the heat transfer tubes of the refrigerant condensation core 7 and the heat transfer tubes of the subcooling core 8th , and thereby it becomes possible the flow resistance of the entirety of the supercooling condenser 1 to reduce greatly. Namely, though not shown, by satisfying such a relationship of the flow resistance, the aforementioned fourth aspect of the present invention can be achieved.

The The present invention can be applied to any supercooling condenser in which a plurality of heat transfer tubes, which extend parallel to each other, a pair of manifolds with each other connect, the heat exchanger core in a refrigerant condensation core and a subcooling Core is divided and where the refrigerant condensation core as a one-way structure of refrigerant is trained, applied, and in particular he is considered a capacitor suitable in a cooling system of an air conditioning system for vehicles is installed.

Claims (9)

Subcooling condenser, which has a pair of headers ( 2 . 3 ) and a plurality of heat transfer tubes ( 4 ; 4a . 4b ; 21 ; 31 . 32 ), which connect the pair of manifolds with each other and extend parallel to each other, wherein a Heat exchanger core ( 6 ) of the condenser into a refrigerant condensation core ( 7 ) for condensing refrigerant and a subcooling core ( 8th ) for subcooling refrigerant condensed by the refrigerant condensing core, wherein the refrigerant condensing core is formed in a one-lane structure of refrigerant, characterized in that heat transfer tubes ( 4a ) of the refrigerant condensation core ( 7 ) and heat transfer tubes ( 4b ) of the supercooling core ( 8th ) are formed as heat transfer tubes, which differ from one another, so that a heat transfer tube ( 4a ) is formed for the refrigerant condensation core as a heat transfer tube having in the same an inner rib ( 14 ), which forms a three-dimensional flow of refrigerant in the pipe, receives, and a heat transfer tube ( 4b ) is formed for the subcooling core as a heat transfer tube, the interior of which in a plurality of flow paths ( 16 ) in an air flow direction (A) by partitions ( 15 ), which are formed integrally with the tube is divided. A subcooling condenser according to claim 1, wherein a flow resistance of the subcooling core ( 8th ) to 1/2 or less of a total flow resistance of the entirety of the capacitor ( 1 ). Subcooling condenser, which has a pair of headers ( 2 . 3 ) and a plurality of heat transfer tubes ( 4 ; 4a . 4b ; 21 ; 31 . 32 ), which connect the pair of manifolds to each other and extend parallel to each other, wherein a heat exchanger core ( 6 ) of the condenser into a refrigerant condensation core ( 7 ) for condensing refrigerant and a subcooling core ( 8th ) for subcooling refrigerant condensed by the refrigerant condensing core, wherein the refrigerant condensing core is formed in a one-lane structure of refrigerant, characterized in that heat transfer tubes ( 4a ) of the refrigerant condensation core ( 7 ) and heat transfer tubes ( 21 ) of the supercooling core ( 8th ) are formed as heat transfer tubes, which differ from one another, so that a heat transfer tube ( 4a ) is formed for the refrigerant condensation core as a heat transfer tube having in the same an inner rib ( 14 ), which forms a three-dimensional flow of refrigerant in the pipe, receives, and a heat transfer tube ( 21 ) is formed for the subcooling core as a heat transfer tube, the interior of which in a plurality of flow paths ( 23 ) in an air flow direction (A) by an inner rib ( 22 ), which is received in the tube is divided. A subcooling condenser according to claim 3, wherein a flow resistance of the subcooling core ( 8th ) to 1/2 or less of a total flow resistance of the entirety of the capacitor ( 1 ). Subcooling condenser, which has a pair of headers ( 2 . 3 ) and a plurality of heat transfer tubes ( 4 ; 4a . 4b ; 21 ; 31 . 32 ), which connect the pair of manifolds to each other and extend parallel to each other, wherein a heat exchanger core ( 6 ) of the condenser into a refrigerant condensation core ( 7 ) for condensing refrigerant and a subcooling core ( 8th ) for subcooling refrigerant condensed by the refrigerant condensing core, wherein the refrigerant condensing core is formed in a one-lane structure of refrigerant, characterized in that heat transfer tubes ( 31 ) of the refrigerant condensation core ( 7 ) and heat transfer tubes ( 32 ) of the supercooling core ( 8th ) are both formed in a configuration in which the interior space of each tube is divided into a plurality of flow paths ( 35 . 36 ) is divided in an air flow direction (A) and the heat transfer tubes of the refrigerant condensation core and the heat transfer tubes of the subcooling core are formed as heat transfer tubes which are different from each other, so that a pressure loss per heat transfer tube in a heat transfer tube ( 32 ) for the subcooling core ( 8th ) is set lower than that in a heat transfer tube ( 31 ) for the refrigerant condensation core ( 7 ) at a same fluid flow condition. The supercooling condenser according to claim 5, wherein at least one of said heat transfer tube (16) 31 ) for the refrigerant condensation core ( 7 ) and the heat transfer tube ( 32 ) for the subcooling core ( 8th ) is formed as a heat transfer tube whose interior is in a plurality of flow paths ( 35 . 36 ) in an air flow direction (A) by partitions ( 33 . 34 ), which are formed integrally with the tube is divided. A subcooling condenser according to claim 5 or 6, wherein at least one of the heat transfer tube for the refrigerant condensation core ( 7 ) and the heat transfer tube ( 21 ) for the subcooling core ( 8th ) is formed as a heat transfer tube whose interior is in a plurality of flow paths ( 23 ) in an air flow direction (A) by an inner rib ( 22 ), which is received in the tube is divided. A subcooling condenser according to any one of claims 5 to 7, wherein a flow resistance of the subcooling core ( 8th ) to 1/2 or less of a total flow resistance of the entirety of the capacitor ( 1 ). Subcooling condenser, which has a pair of headers ( 2 . 3 ) and a plurality of heat transfer tubes ( 4 ; 4a . 4b ; 21 ; 31 . 32 ), which connect the pair of manifolds to each other and extend parallel to each other, wherein a heat exchanger core ( 6 ) of the condenser into a refrigerant condensation core ( 7 ) for condensing refrigerant and a subcooling core ( 8th ) for subcooling refrigerant condensed by the refrigerant condensation core, wherein the refrigerant condensation core is formed in a one-lane refrigerant structure, characterized in that a flow resistance of the subcooling core is 1/2 or less of a total flow resistance the entirety of the capacitor ( 1 ).