DE102011113453A1 - Radiator i.e. coolant radiator, for use in air-conditioning system in engine space of vehicle, has modular tank connected with outer rib that is arranged at end part of core part along pipe stacking direction - Google Patents

Abstract

The radiator (1) has a modular tank (11) arranged in a lateral part of a collector tank (6) along longitudinal direction (X) of a pipe (3). Coolant at an inner section of the collector tank flows into the modular tank to collect the coolant in the modular tank. Another modular tank (12) is arranged in a lateral part from a core part (2) along pipe stacking direction (Z) for communicating with an inner section of the latter modular tank. The latter modular tank is connected with an outer rib (4) that is arranged at an end part of the core part along the stacking direction.

Description

The present invention relates to a cooler provided with a modulator tank having a liquid receiving function.

A modulator tank, which is for a conventional known radiator, is arranged to be connected to a side portion of a header tank connected to end portions of more than one pipe. Accordingly, the modulator tank is formed in an elongate shape at an end portion of the radiator on its lateral side along the header tank arranged with the vertical direction as its longitudinal direction (hereinafter referred to as a vertically elongated modulator tank).

In recent years, in the market for coolers, a flat-type cooler has been demanded, which requires a small space for its installation while maintaining the performance of a conventional radiator. To meet this demand, apart from reducing the thickness of a core member, it is also necessary to ensure the volume of the modulator tank to ensure the performance of the cooler. In the case of a conventional vertically long modulator tank, its tank diameter can not be made small due to the securing of the volume, and the thickness of the modulator tank in its front-to-rear direction becomes large in proportion to the thicknesses of the core part and the header tank. Accordingly, a dead space is generated around the core part, so that the entire radiator can not be made thinner.

A radiator in KR 10-0799551 B1 For a technology which can solve such a problem, the radiator is known KR 10-0799551 B1 is further provided with a horizontally elongated modulator tank, which is disposed at an upper end of a core member in a laterally positioned position along the core member in addition to a vertically elongated modulator tank disposed at an end portion of the radiator on its lateral side. The vertically elongated modulator tank and the horizontally elongated modulator tank are connected to each other through a connecting pipe, and the inner sides of both tanks communicate with each other. The horizontally elongated modulator tank is disposed on side plates provided at both ends of the core part at its upper and lower sides to reinforce the core part, and the horizontally elongated modulator tank is fixed to the side plate by a bracket.

However, because the horizontally elongated modulator tank in the radiator off KR 10-0799551 B1 is attached to the side plate at the upper end portion of the core part via the holder, there is a problem that the number of components and the man-hours are needed for the production.

The present invention addresses at least one of the above disadvantages. It is thus an object of the present invention to provide a cooler which can be thinned and can reduce the number of components while ensuring the filling characteristics of refrigerant.

In order to achieve the object of the present invention, there is provided a radiator having a core portion, a header tank, a first modulator tank, and a second modulator tank. The core part comprises a plurality of tubes and a plurality of outer ribs. Each of the plurality of tubes includes a refrigerant passage therein. A refrigerant flows through the refrigerant passage. The plurality of tubes and the plurality of outer ribs are alternately stacked such that an outer surface of each of the plurality of tubes is connected to corresponding adjacent two of the plurality of outer ribs. End portions of the plurality of tubes in a longitudinal direction of the tube are connected to the header tank such that the header tank communicates with the refrigerant passage of each of the plurality of tubes. The first modulator tank is disposed along a side part of the header tank in the longitudinal direction of the pipe to communicate with an inner portion of the header tank so that refrigerant in the inner portion flows from the header tank into the first modulator tank to flow in the first modulator tank first accumulator tank to be accumulated. The second modulator tank is disposed along a side part of the core part in a pipe stacking direction, and communicates with an inner portion of the first modulator tank. The second modulator tank is connected to one of the plurality of outer ribs disposed at an end part of the core part in the pipe stacking direction.

In order to achieve the object of the present invention, there is also provided a radiator having a core part, a pair of tanks, a first modulator tank, a second modulator tank, a desiccant and a filter. The core part comprises a plurality of tubes and a plurality of outer ribs. Each of the plurality of tubes includes a refrigerant passage therein. A refrigerant flows through the refrigerant passage. The plurality of tubes and the plurality of outer ribs are alternately stacked in a vertical direction from the core part. The core part is divided between a condensation part and a subcooling part. The pair of tanks holds the core part from both sides of the core part in a horizontal direction thereof. The first modulator tank is connected to one of the plurality of outer ribs disposed at an end portion of the core part in the vertical direction. The first modulator tank is connected to the pair of tanks such that an inner portion of the first modulator tank and respective modulating inner portions of the pair of tanks communicate with each other. The modulating inner portion of each of the pair of tanks disposed near the one of the plurality of outer ribs at the end portion of the core portion is partitioned from the other inner portion of each of the pair of tanks which is connected to the plurality of tanks Tubes is connected, whereby the modulating inner portion is not in communication with the core part. The second modulator tank is disposed on a lateral side of the core part in the horizontal direction along one of the pair of tanks in a longitudinal direction thereof, and is connected to the one of the pair of tanks. The second modulator tank communicates with the modulating inner portion of the one of the pair of tanks. An inner portion of the one of the pair of tanks other than the modulating inner portion communicates with the second modulator tank and is disposed near a downstream portion of the condensing portion in a flow direction of the refrigerant. The desiccant is disposed in the second modulator tank to absorb moisture in a refrigerant circuit. The filter is disposed in the second modulator tank to collect foreign substances in the refrigerant circuit.

The invention, together with its additional objects, features and advantages, will be best understood from the following description, the appended claims and the accompanying drawings, in which:

1 Fig. 12 is a perspective view illustrating a radiator in accordance with a first embodiment of the invention;

2 Fig. 10 is a fragmentary sectional view illustrating a second modulator tank and a part of a core part in the radiator in accordance with the first embodiment;

3 Fig. 12 is a schematic view illustrating a path for a refrigerant flow in the radiator of the first embodiment;

4 Fig. 12 is a fragmentary sectional view showing an embodiment of the radiator of the first embodiment concerning the refrigerant flow path from a first modulator tank to a second modulator tank;

5 Fig. 12 is a schematic view illustrating a difference in size of a modulator tank between the radiator of the first embodiment and a previously proposed radiator;

6 FIG. 12 is a graph illustrating a result of a test on the filling characteristics of refrigerant performed on the radiator of the first embodiment and the previously proposed radiator; FIG.

7 1 is a fragmentary sectional view illustrating an embodiment of a refrigerant flow path from a first modulator tank to a second modulator tank in a radiator in accordance with a second embodiment of the invention;

8th Fig. 4 is a fragmentary sectional view showing an embodiment of a radiator of a third embodiment of the invention concerning a refrigerant flow path from a first modulator tank to a second modulator tank;

9 Fig. 12 is a fragmentary sectional view showing an embodiment of a radiator of a fourth embodiment of the invention concerning a refrigerant flow path from a first modulator tank to a second modulator tank;

10 Fig. 12 is a fragmentary sectional view showing a second modulator tank and a part of a core part in a radiator in accordance with a fifth embodiment of the invention;

11 Fig. 12 is a fragmentary sectional view illustrating a second modulator tank and a part of a core part in a radiator in accordance with a sixth embodiment of the invention;

12 Fig. 12 is a fragmentary sectional view showing a second modulator tank and a part of a core part in a radiator in accordance with a seventh embodiment of the invention;

13 is a fragmentary sectional view showing a first modification of the second Represents modulator tanks in accordance with the seventh embodiment;

14 Fig. 12 is a fragmentary sectional view showing a second modification of the second modulator tank in accordance with the seventh embodiment;

15 Fig. 12 is a fragmentary sectional view showing embodiments of a first modulator tank and a second header tank in a radiator in accordance with an eighth embodiment of the invention;

16 Fig. 12 is a fragmentary sectional view showing embodiments of a first modulator tank and a second header tank in a radiator in accordance with a ninth embodiment of the invention;

17 Fig. 12 is a fragmentary sectional view showing an embodiment of the radiator of the ninth embodiment concerning a path for refrigerant flow from the first modulator tank to the second header tank;

18 Fig. 12 is a perspective view illustrating a radiator in accordance with a first additional modification;

19 a fragmentary sectional view taken along a line XIX-XIX in 18 which is an upper modulator tank and a part of a core part in the radiator of the first additional modification;

20 FIG. 4 is an enlarged view illustrating a part of the radiator of the first additional modification shown by an arrow. FIG XX in 18 is specified;

21 Fig. 12 is a schematic view illustrating a path for a refrigerant flow in the radiator of the first additional modification;

22 Fig. 11 is a front view illustrating a radiator in accordance with a second additional modification;

23 a fragmentary sectional view taken along a line XXIII-XXIII in 22 Fig. 11 is a lower modulator tank and a part of a core part in the radiator of the second additional modification; and

24 FIG. 12 is a schematic view illustrating a path for a refrigerant flow in the radiator of the second additional modification. FIG.

Embodiments of the invention will be described below with reference to the accompanying drawings. In each embodiment using the same reference numerals for the corresponding parts to those described in the previous embodiment (s), repeated descriptions may be omitted. In each embodiment, if only one part of the embodiment is described, the previously described other embodiment (s) may be applied to the other parts of the embodiment. In addition to the combination of components, the combination of which is specifically shown to be possible, in each embodiment, even if not clearly stated, a partial combination between embodiments may be possible, except where the combination is particularly inappropriate.

First embodiment

A cooler 1 in accordance with a first embodiment of the invention comprises a condensation part 2a and a subcooling part (overcooling part) 2 B at a core part 2 by a pile of pipes 3 is obtained, through which a refrigerant circulates. The cooler 1 has a function of receiving fluid from the refrigerant to hold the refrigerant in a refrigerant circuit. Such a cooler 1 is with reference to the 1 to 6 to be discribed.

As it is in the 1 is shown is the radiator 1 a refrigerant cooler with integrated modulator tank, which is applied to a refrigerant circuit used in an air conditioner for a vehicle. The cooler 1 includes a condensation part 2a cooling the refrigerant discharged from a compressor (not shown) in the refrigerant cycle to condense the refrigerant in the gaseous phase; a modulator tank 10 , which contains the refrigerant which flows from the condensation part 2a flows out, separates into refrigerant in the gaseous phase and refrigerant in the liquid phase to store the excess of refrigerant in the refrigerant cycle as a refrigerant of liquid phase, and which allows the refrigerant to flow out of liquid phase; and the subcooling part 2 B containing the refrigerant from liquid phase coming out of the modulator tank 10 flows out, cools to increase a degree of overcooling of the refrigerant. The cooler 1 is shaped to integrate these components. The modulator tank 10 The present embodiment has an L-shaped cylindrical body, and its inner spaces communicate with each other. The modulator tank 10 is from a first modulator tank 11 at one end of the radiator 1 in its lateral direction, and a second modulator tank 12 . at an upper end portion of the radiator 1 is arranged, assembled.

The cooler 1 includes a cylindrical first header tank 5 and a cylindrical second header tank 6 which are a pair of header tanks arranged at predetermined intervals. The core part 2 for the heat exchange is between the first header tank 5 and the second collector tank 6 arranged, and the core part 2 includes the condensation part 2a and the subcooling part 2 B , The cooler 1 is a cooler of the "multi-flow type", ie the refrigerant, which is in the first header tank 5 has flowed, flows towards the second header tank 6 along more than one refrigerant passage.

As it is in the 2 is shown, the core part comprises 2 many stacked pipes 3 having a flat shape in cross-section through which refrigerant flows in the horizontal direction, between the first header tank 5 and the second collector tank 6 , and the pipes 3 are connected together by soldering, with a corrugated outer rib 4 between these many pipes 3 is arranged. An end part of the pipe 3 is arranged in its longitudinal direction X, to communicate with the interior of the first header tank 5 to communicate, and the other end part of the pipe 3 is arranged to connect with the interior of the second header tank 6 to communicate. Each of the pipes 3 that the core part 2 form, is a porous tube, which small passages 31 having therein. Such a porous tube may be formed by extrusion molding. In addition, "D", which presses in 2 is a size of the thickness of the core part 2 out.

An inlet-side pipe connection 7 for refrigerant is at an upper end side of the first header tank 5 arranged, and an outlet-side pipe connection 8th for refrigerant is at a lower end side of the tank 5 arranged. The connections 7 . 8th are each with the first collector tank 5 connected.

As it is in the 3 are shown are two separators 51 . 52 which is an internal space of the tank 5 subdivide, inside the first collector tank 5 at an upper and lower part of the tank 5 arranged, and in a similar manner are two separators 61 . 62 inside of the second collector tank 6 arranged. These separators make the insides of the first header tank 5 and the second collector tank 6 each divided into three rooms in the vertical direction. Accordingly, the core part comprises 2 four groups of flow passages arranged in the vertical direction. Apart from these four groups is the condensation part 2a are made of three groups of flow passages arranged in the vertical direction and the subcooling part 2 B is made by the lowest passage group.

At the radiator 1 The present embodiment is a communicating passage 66 so formed between an inner space 64 which is at the second uppermost part of the second header tank 6 is arranged, and an inner space 111 from the first modulator tank 11 to communicate. A communication passage 67 is formed to be between an inner space 65 , which at the lowest part of the second header tank 6 is arranged, and the inner space 111 from the first modulator tank 11 to communicate.

Consequently, the refrigerant flowing through the inlet side pipe joint flows 7 has flowed in, through an internal space at the top of the first header tank 5 is arranged, the passage group, which at the uppermost part of the condensation part 2a is arranged, an inner space 63 at the top of the second collector tank 6 is arranged, the passage group, which at the second uppermost part of the condensation part 2a is arranged, an inner space, at the second uppermost part of the first header tank 5 is arranged, the passage group, which at the lowest part of the condensation part 2a is arranged, the inner space 64 , the second highest part of the second collector tank 6 is arranged, the inner space 111 from the first modulator tank 11 , the inner space 65 , which is at the bottom of the second collector tank 6 is arranged, the passage group, which the subcooling part 2 B forms, and an inner space, which at the lowest part of the first Sammlertank 5 is arranged, in that order. Then, the refrigerant flows to the outside of the radiator 1 out through the outlet pipe connection 8th , For this reason, the refrigerant forms a forward-backward flow and a forward flow (flow crosses the condensation part 2a three times) in the condensation section 2a ,

The cylindrical first modulator tank, which separates the refrigerant into gaseous and liquid refrigerants and stores the liquid refrigerant, is integrally formed on the outside of the second header tank 6 arranged. The first modulator tank 11 and the second collector tank 6 have such a relationship that their internal spaces through the communication passage 66 and the communication passage 67 communicate with each other. The condensation part 2a , the subcooling part 2 B and the first modulator tank 11 are each made of an aluminum material or a For example, aluminum alloy material is formed by press forming or extrusion casting, and joined together by integral brazing such as brazing in an oven.

The cooler 1 includes the second modulator tank 12 which is connected to the interior of the first modulator tank 11 is in communication and which is at the top of the core part 2 along a lateral part (upper end portion) of the core part 2 is arranged in a tube stacking direction Z. A desiccant that absorbs moisture in the refrigerant cycle and a filter that collects foreign substances in the refrigerant cycle are inside of the first modulator tank 11 and the second modulator tank 12 added. The second modulator tank 12 For example, a cylindrical body having a rectangular shape in cross section and the tank 12 is from a flat part 124 formed, of which at least the one with the outer rib 4 connected parts, which at the uppermost part of the core part 2 are arranged, have a flat shape.

The second modulator tank 12 has a length along the entire core part 2 in its lateral direction, and both ends of the tank 12 are with a relay tank 9 connected to an upper part of the second header tank 6 and an upper part of the first header tank 5 is arranged. The second modulator tank 12 is with the upper part of the first collector tank 5 connected, but there is an inner space 121 from the second modulator tank 12 and the inner space of the first collector tank 5 not in communication due to, for example, a partitioning element 21 , As a result of such a design of the tank 12 both ends of the second modulator tank 12 supported by the other elements. The second modulator tank 12 therefore maintains the desired resistance to vibration or the like, and the tank 12 can have a gain function on the core part 2 regardless of the lapse of its actual useful life. Like the inner space of the second modulator tank 12 indicates the inner space of the first collector tank 5 with which the second modulator tank 12 connected, a modulator function on.

The outer rib 4 , which at the uppermost part of the condensation part 2a is arranged, and the second modulator tank 12 are formed of an aluminum material or an aluminum alloy material by press molding, extrusion molding, etc., and are connected to each other by integral brazing such as brazing in an oven. As a result, the second modulator tank carries 12 the outer rib 4 , which at the uppermost part of the condensation part 2a is arranged from an upper part of the rib 4 , and the tank 12 protects the core part 2 before its deformation due to vibration and heat, to a reinforcing function of the core part 2 manufacture.

As it is in the 4 is shown, includes the radiator 1 the relay tank 9 which functions as an element through which the second modulator tank 12 and the first modulator tank 11 communicate. The relay tank 9 is integral with the upper part of the second header tank 6 formed, and an open end part 122 from the second modulator tank 12 , which is the cylindrical body, is inside the tank 9 arranged. Consequently, the inner space stand 121 from the second modulator tank 12 and the inner space of the tank 9 in communication with each other.

A communication board 20 is between the first modulator tank 11 and the relay tank 9 arranged. A through hole 201 is in the communication panel 20 educated. A refrigerant outlet connection 112 is in a wall part of the first modulator tank 11 formed, which the relay tank 9 opposite. The relay tank 9 includes a refrigerant inflow port 91 at its position, which the refrigerant outlet 112 from the first modulator tank 11 opposite. As a result of this placing between the relay tank 9 and the first modulator tank 11 meets the communication board 20 a function of connecting the refrigerant inflow port 91 , the through hole 201 and the refrigerant outflow port 112 , The plate 20 defines a clearance which is generally the same size as a thickness size of the communication board 20 , between the relay tank 9 and the first modulator tank 11 , The plate 20 thus forms an adiabatic layer of air between the two tanks 9 . 11 To function as a function of a braking delivery and a braking reception of heat between the two tanks 9 . 11 to serve.

The first modulator tank 11 , the second collector tank 6 , the relay tank 9 , the communication board 20 and the first modulator tank 11 are formed of an aluminum material or an aluminum alloy material, and they are connected to each other by an integral brazing such as brazing in an oven.

The refrigerant, which is discharged from the compressor in the refrigerant circuit, flows into the uppermost space in the first header tank 5 through the inlet-side pipe connection 7 , Then, the refrigerant flows through the uppermost passage group of the condensation part 2a to enter the inner space 63 at the top of the second header tank 6 to stream. The Refrigerant further flows through the passage group at the intermediate part of the condensation part 2a , the middle room in the first collector tank 5 and the lowest passage group of the condensation part 2a , in this order. The refrigerant flows into the inner space 64 because of the intermediate part of the second collector tank 6 , Thereafter, the refrigerant flows through the communication passage 66 from the inner space 64 at the intermediate part of the second header tank 6 to enter the inner space 111 from the first modulator tank 11 to stream. The refrigerant flows from the communication passage 67 outward from the radiator 1 through the inner space 65 at the lowest part of the second header tank 6 , the subcooling part 2 B , the lowest room in the first collector tank 5 and the outlet pipe connection 8th , Additionally, the refrigerant, which is in the inner space 111 from the first modulator tank 11 has flowed, even in the inner space 121 from the second modulator tank 12 stream. Accordingly, the volume of the modulator can be widened, and the filling characteristics of the refrigerant in the radiator can be improved.

As it is in the 5 In the case of a conventional radiator, because of the necessity of ensuring a predetermined amount of refrigerant in the refrigerant circuit, a size of the tank diameter of a modulator tank is illustrated 50 larger than the second collector tank 6 to ensure the required tank volume. As a result, when an end part of both tanks in a flow direction Y of an external fluid is made to coincide with each other, the conventional modulator tank protrudes 50 generally a size B in the 5 is specified on their other end pages. Further, in the case of the conventional radiator, a size of a length of the conventional tank is 50 in the tube longitudinal direction X generally by a size A larger, as shown in the 5 is specified.

In the case of the radiator 1 For example, the tank volume of the modulator may be through the second modulator tank 12 in addition to the first modulator tank 11 be ensured. Thus, the size of the tank diameter may be from the first modulator tank 11 be limited to being small. As a result, the size of the tank diameter can be stored from the first modulator tank 11 to the size of the thickness of the core part 2 or the size of the tank diameter from the second header tank 6 be approximated. As a result of the design of the radiator 1 In the present embodiment, the size of the radiator 1 be made lower, both in a thickness direction of the core part (flow direction Y of the outer fluid) and in a horizontal width direction of the core part (tube longitudinal direction X).

The inventors have tentatively tested the refrigerant cycle under predetermined conditions for each of the conventional radiator and the radiator 1 operated in the present embodiment. The results of an investigation of a change in the temperature of the supercooling part 2 B in relation to a change in the refrigerant charge in the circuit will be explained. The coolers used in the study have core parts which are the same size in both the conventional technology and the present embodiment. The size of the core part in its horizontal width direction (tube longitudinal direction X) is 600 mm; and the size of the core part in its longitudinal width direction (tube stacking direction Z) is 400 mm. In addition, it has been found that similar results are also obtained in a range of 600 to 700 mm of the size of the core portion in the horizontal width direction; and in a range of 300 to 500 mm of the size of the core part in the longitudinal width direction. The volume of a vertically elongate modulator tank in the conventional radiator and the total volume of the first and second modulator tanks in the radiator 1 The present embodiment is set the same.

As it is in the 6 is shown, when the refrigerant charge in the circuit is increased, a stable range in which the subcooling part 2 B is stable at about 9 ° C, in a range of 480 g to 640 g, the refrigerant charge in both of the coolers is reached. As shown above, the radiator 1 due to its structure, in which the modulator tank is separated into two parts, filling properties of the refrigerant, which cut off favorably in comparison with the conventional cooler, despite the reduction of the tank diameter. It is thus ensured that the radiator 1 can ensure equivalent performance.

The effects of the cooler 1 of the present embodiment will be described. The cooler 1 includes the first collector tank 5 in which the refrigerant with respect to the outside of the radiator 1 flows in and out, the core part 2 which is from the pipe 3 and the outer rib 4 formed alternately stacked, the first modulator tank 11 and the second modulator tank 12 with the interior of the first modulator tank 11 is in communication and along the lateral part of the core part 2 is arranged in the tube stacking direction Z. The first modulator tank 11 stands with the interior of the second collector tank 6 so in communication that the refrigerant from the inside of the second header tank 6 in the tank 11 can flow, and the tank 11 is along the lateral part of the second header tank 6 arranged in the tube longitudinal direction X. The second modulator tank 12 is with the outer rib 4 connected to the end portion of the core part 2 is arranged in the tube stacking direction Z.

As a result of this embodiment of the radiator 1 may be by providing the second modulator tank 12 , which at the lateral part of the core part 2 in the tube stacking direction 2 in addition to the first modulator tank 11 disposed on the side part of the second header tank 6 is provided to ensure a volume required for the modulator, despite the use of a structure for limiting a tank diameter of each of the modulator tanks. This is because the required volume can be shared by both of the tanks. Since the tank diameter can be limited in this way, the size of the radiator in its thickness direction as well as in its horizontal width direction is reduced to reduce a dead space around the radiator, and the installation capability of the radiator can thereby be improved. This is particularly useful in a radiator disposed in an engine compartment in a vehicle, for example.

Furthermore, it serves as a result of connecting the second modulator tank 12 with the outer rib 4 the second modulator tank 12 as a reinforcing element. Consequently, the tank can 12 are doubled in function as compared to a function of a conventional side plate or the like. Therefore, the rigidity of the radiator 1 maintained and improved, and the side plate can even be omitted. An increase in the number of components can be prevented. With the seized filling properties of refrigerant can thus the cooler 1 which can be made thinner and reduce the number of components can be provided.

As a result of arranging the open end part 122 of the second modulator tank 12 , which is a cylindrical body, inside the radiator 1 includes the radiator 1 the relay tank 9 which is connected to the interior of the second modulator tank 12 is in communication, integral with it at the top of the second header tank 6 ; and the communication board 20 which the through hole 201 which is between the relay tank 9 and the first modulator tank 11 is arranged. The first modulator tank 11 is with the refrigerant outflow port 112 in its wall part opposite to the relay tank 9 Mistake. The relay tank 9 includes the refrigerant inflow port 91 at the position which the Kältemittelausströmanschluss 112 opposite. The communication board 20 is between the relay tank 9 and the first modulator tank 11 arranged such that the refrigerant inflow port 91 , the through hole 201 and the refrigerant outflow port 112 communicate with each other.

As a result of this embodiment of the radiator 1 can by connecting the relay tank 9 and the first modulator tank 11 with each other, to each other through the communication board 20 between the tanks 9 . 11 to communicate without employing such a structure that the second collector tank 6 or the relay tank 9 and the first modulator tank 11 are directly connected, both tanks communicate with each other. As a result, the amount of heat transferred between the two tanks can be limited and the decrease in the performance of the cooler 1 can be dampened by this. Because a plate material from the communication plate 20 between both tanks 9 . 11 is further connected a path in the time in which the refrigerant through the communication plate 20 short, and the loss of heat in the time of passage of the refrigerant can thereby be reduced compared to the case of a line connection or the like. Accordingly, the performance of the radiator 1 by using the communication board 20 be ensured.

Second embodiment

In a second embodiment of the invention, with reference to the embodiment, which relates to a way by which the refrigerant from a first modulator tank 11A to a second modulator tank 12A flows, an embodiment other than the first embodiment will be described. In the 7 is a component denoted by the same reference numerals as in FIG 4 is the same component, and their operation and effect are also similar to those of the component in FIG 4 ,

A radiator of the second embodiment is the radiator 1 different in the first embodiment that the second modulator tank 12A to an inner space 111 of the first modulator tank 11A extends and its open end part 122 in the inner space 111 is arranged. Except for this difference, the radiator of the second embodiment and the radiator 1 of the first embodiment are the same, and they produce similar operation and effects.

As it is in the 7 is shown, goes a cylindrical body, which the second modulator tank 12A forms, through a second collector tank 6A through and extends such that its open end part 122 inside the first modulator tank 11A is arranged. As a result of this configuration of the radiator, the second header tank comprises 6A Through holes, which have such inner diameter that the second modulator tank 12A through the holes in its wall part on the side of the first header tank 5 and in its wall part on the side of the first modulator tank 11A can penetrate. A through hole having such an inner diameter that the second modulator tank 12A can penetrate through the hole is for the first modulator tank 11A provided in its wall part, which is in contact with the second header tank 6A or opposite is to the tank 6A with a distance away from the tank 6A ,

Consequently, the refrigerant flowing from the second header tank flows 6A in the first modulator tank 11A through a communication passage 66 has flowed into an inner space 121 through the open end part 122 of the second modulator tank 12A , As a result, the interior of the second modulator can be stored 12A be used as a modulator room.

In the radiator of the second embodiment, by extending the second modulator tank 12A , which is a cylindrical body, inside the first modulator tank 11A a communication path between the interior of the first modulator tank 11A and the interior of the second modulator tank 12A be realized by means of a small number of components and a simple configuration. In comparison with the first embodiment, for example, a dividing element 21 and a communication board 20 no longer necessary to reduce the number of components. By extending the second modulator tank 12A inside the first modulator tank 11A Further, the rigidity of the second modulator tank 12A elevated. As a consequence, a gain function that is based on a core part 2 through the second modulator tank 12A is exercised, even in the case be improved, in which the length of the tank 12A is made bigger.

Third embodiment

In a third embodiment of the invention, with reference to the embodiment relating to a path through which the refrigerant from a first modulator tank 11B to a second modulator tank 12B another embodiment than the second embodiment will be described. In the 8th is a component denoted by the same reference numerals as in FIG 7 is the same component, and their operation and effect are also similar to those of the component in FIG 7 ,

A radiator of the third embodiment is different from the radiator of the second embodiment in that an open end part 221 a communication element 22 that with the second modulator tank 12B is connected, in an inner space 111 from the second modulator tank 12B is arranged and thereby the second modulator tank 12B and the first modulator tank 11B communicate with each other. Besides this difference, the radiator of the third embodiment and the radiator of the second embodiment are the same, and they produce similar operation and effects.

As it is in the 8th is the second modulator tank 12B with an open end part 222 the cylindrical communication element 22 outside a second collector tank 6B connected. The communication element 22 extends through the second header tank 6B that its open end part 221 inside the first modulator tank 11B As a result of this configuration of the radiator, the second header tank includes 6B Through holes, which have such inner diameter, that the communication element 22 through the holes in its wall part on the side of the first header tank 5 and in its wall part on the side of the first modulator tank 11B can penetrate. A through hole having such an inner diameter that the communication element 22 can pass through the hole is for the first modulator tank 11B provided in its wall part, with the second collector tank 6B is in contact or opposite the tank 6B with a distance away from the tank 6B is.

As a consequence, the refrigerant flows out of the second header tank 6B in the first modulator tank 11B through a communication passage 66 has flowed along a passage in the communication element 22 through the open end part 221 from the communication element 22 in an inner space 121 of the second modulator tank 12B , The interior of the second modulator tank 12B can therefore be used as a modulator room.

In the radiator of the third embodiment, by extending the cylindrical communication member 22 that with the second modulator tank 12B connected to the interior of the first modulator tank 11B the use of a configuration of an extension of the second modulator tank 12B whose outer diameter size may be large, inside the first modulator tank 11B avoided. By means of a solder joint of the communication element 22 whose outer diameter size can be made smaller than the second modulator tank 12B Thus, a solder joint area can be reduced, and the Quality of the cooler can be ensured. In addition, a dividing element 21 unnecessary as compared with the first embodiment, and accordingly, a communication path between the inside of the first modulator tank 11 and the interior of the second modulator tank 12 be achieved by a small number of components and a simple design.

Fourth embodiment

In a fourth embodiment of the invention, with reference to the embodiment relating to a route through which refrigerant from a first modulator tank is stored 11 to a second modulator tank 12 flows, an embodiment other than the first embodiment will be described. In the 9 is a component denoted by the same reference numerals as in FIG 4 is the same component, and their operation and effect are also similar to those of the component in FIG 4 ,

A condensation part 2a in a cooler of the fourth embodiment represents a "total path" refrigerant flow. In the cooler of the fourth embodiment, more specifically, a separator which is an internal space of the tank 5 divided between an upper and lower part, inside a first header tank 5 arranged, and a separator is similar inside a second header tank 6C arranged. These separators make the insides of the first header tank 5 and the second collector tank 6C each divided into two rooms in the vertical direction. The refrigerant, which through an inlet-side pipe connection 7 has flowed in, accordingly flows through the first header tank 5 , the entire condensation part 2a and the second collector tank 6C , in this order. As a result, the refrigerant forms an "entire path" type flow in the condensing part 2a ,

As it is in the 9 is shown, the radiator of the fourth embodiment is different from the radiator 1 the first embodiment that the first modulator tank 11 and the second collector tank 6C are integrally connected, such that a refrigerant outflow port 112 of the first modulator tank 11 and a refrigerant inflow port 68 the second collector tank 6C coincide with each other. Apart from this difference, the radiator of the fourth embodiment and the radiator 1 of the first embodiment are the same, and they produce similar operation and effects. As a position of the open end part 122 of the second modulator tank 12 an inner space 63A from the second collector tank 6C is the refrigerant also flows into the second modulator tank 12 from the inside of the second header tank 6C ,

As a result, the refrigerant flowing from the second header tank flows 6C in the first modulator tank 11 through a communication passage 66 has flowed through the Kältemittelausströmanschluss 112 and the refrigerant inflow port 68 in the inner space 63A the second collector tank 6C , The refrigerant further flows into an inner space 121 from the second modulator tank 12 through the open end part 122 , Consequently, the interior of the second modulator tank can 12 be used as a modulator room. In addition, a part of the refrigerant, which is in the second header tank 6C through the condensation part 2a has flowed, move up to the inner space 121 from the second modulator tank 12 through the open end part 122 to pour into the inner space 63A is open.

As a result of the radiator according to the fourth embodiment, in the radiator in which the condensing part 2a forming the "total path" refrigerant stream, the open end part 122 of the second modulator tank 12 , which is a cylindrical body, inside of the second header tank 6C arranged, and the openings through which the interior of the first modulator tank 11 and the inside of the second collector tank 6C communicate with each other, are interconnected. As a result, a communication path between the inside of the first modulator can be stored 11 and the inside of the second modulator tank 12 be constructed by a small number of components and a simple design. In addition, a dividing element 21 unnecessary as compared with the first embodiment, and accordingly, a communication path between the inside of the first modulator tank 11 and the interior of the second modulator tank 12 be achieved by a small number of components and a simple design.

Fifth embodiment

In a fifth embodiment of the invention, an embodiment other than the first embodiment with respect to the second modulator tank will be described. In the 10 is a component denoted by the same reference numerals as in FIG 2 is the same component, and their operation and effect are also those of the component in the 2 similar.

A cooler of the fifth embodiment is in view of the configuration of a second modulator tank 12C from the radiator 1 different from the first embodiment. Except this difference are the radiator of the fifth embodiment and the radiator 1 of the first embodiment are the same, and they produce similar operation and effects.

As it is in the 10 has a shape of a cross section of the second modulator tank 12C , which is perpendicular to the tube longitudinal direction X, in the 10 illustrated form. The second modulator tank 12C includes a base part 124C Its area, by means of soldering with an outer rib 4 is connected, is flat, so that its contact area with the outer rib 4 can be easily ensured; and a cylindrical part through which the refrigerant from a first modulator tank 11 flows. The second modulator tank 12C having such a configuration is molded by extrusion molding. In addition, "D", printed in the 10 is indicated, a thickness of a core part 2 out.

In the radiator of the fifth embodiment, the second modulator tank includes 12C the base part 124C whose connecting area with the outer rib 4 is flat, and the cylindrical part through which the refrigerant from a first modulator tank 11 flows; and these components are molded by extrusion molding. As a result of this configuration, the contact area between the flat base part 124C and the outer rib 4 be made bigger. A gain function by the second modulator tank 12C for the core part 2 can therefore be increased. Due to the fact that the second modulator tank 12C having such a configuration may have the same components as in the first modulator tank 11 to be used. Thus, the reduction of the number of components and a reduction of the man-hours for the handling of parts can be realized, and the manufacturing cost of the cooler can thereby be reduced.

As a result of the present embodiment, due to the base part 124C whose connecting area with the outer rib 4 is flat, a contact area between the second modulator tank 12C and the outer rib 4 be made as large as possible, and a solder joint area can be ensured with it. In addition, against vibration, etc., which are applied to the radiator, the force from the side of the core part 2 is transmitted through the stable base part 124C be distributed. The gain function by the second modulator tank 12C for the core part 2 can therefore be improved.

Sixth embodiment

In a sixth embodiment of the invention, an embodiment other than the first embodiment with respect to the second modulator tank will be described. In the 11 is a component denoted by the same reference numerals as in FIG 2 is the same component, and their operation and effect are also similar to those of the component in FIG 2 ,

A cooler of the sixth embodiment is in the configuration of a second modulator tank 12D from the radiator 1 different from the first embodiment. Except for this difference, the radiator of the sixth embodiment and the radiator 1 of the first embodiment are the same, and they produce similar operation and effects.

As it is in the 11 has a shape of a cross section of the second modulator tank 12D , which is perpendicular to the tube longitudinal direction X, the shape that in the 11 is shown. The second modulator tank 12D is formed by an integral stacking of flattened tubes. The pipes 3 which is for the second modulator tank 12D used are the same tubes as the tubes 3 , which is a core part 2 form. A space between each two adjacent stacked tubes 3 comes with an adhesive 30 filled. Accordingly, the pipes 3 attached and integrated together close together to form a tank. In addition, "D", printed in the 11 is indicated, a thickness of a core part 2 out. A cladding material with a solder filler metal coating may replace the adhesive 30 to be used. This cladding material is between the pipes 3 arranged so that in each case two adjacent pipes 3 adhere to each other over the cladding material after a soldering operation. As a result, the stacked tubes 2 integrated to form a tank.

In the cooler of the sixth embodiment, the second modulator tank is 12D formed by integrally stacking the same tubes as the tubes 3 which is the core part 2 form. As a result of this configuration of the radiator, since the tube 3 which is for the core part 2 is used as an element containing the second modulator tank 12D forms, the components further divided. As a result, a reduction in the number of components and a man-hour reduction for parts handling can be realized, and the cost of manufacturing the cooler can be reduced. Due to the flattened shape of the tube 3 Furthermore, similar operations and effects are allowed the flat base part 124C realized in the fifth embodiment. The gain function by the second modulator tank 12C for the core part 2 can be increased.

Seventh embodiment

In a seventh embodiment of the invention, an embodiment other than the first embodiment with respect to the second modulator tank will be described. The 12 represents a structure from a second modulator tank 12E the seventh embodiment. The 13 is a fragmentary sectional view showing a second modulator tank 12F which shows a first modification of the second modulator tank 12E is. The 14 is a fragmentary sectional view showing a second modulator tank 12G which is a second modification. In the 12 to 14 is a component denoted by the same reference numerals as in FIG 2 is the same component, and their operation and effect are also similar to those of the component in FIG 2 , In addition, "D", which enters the 12 to 14 is indicated, a thickness of a core part 2 out.

A cooler of the seventh embodiment is in view of the configuration of a second modulator tank of the radiator 1 different from the first embodiment. Except for this difference, the radiator of the seventh embodiment and the radiator 1 of the first embodiment are the same, and they produce similar operation and effects.

First, as it is in the 12 is shown, the second modulator tank 12E by combining elements 12e1 . 12e2 formed, which are formed by a press processing. The second modulator tank 12E is from a first element 12e1 whose cross-sectional shape perpendicular to the tube longitudinal direction X is a U-shape, and a second element 12e2 , which is similarly U-shaped and whose outer shape is smaller than that of the first element 12e1 , composed. The second modulator tank 12E is formed by overlapping the elements 12e1 . 12e2 such that an outer surface of the second element 12e2 into an inner surface of the first element 12e1 is fitted to a space inside the tank 12E to define, and by a solder joint of these elements with each other.

Second, as it is in the 13 is shown, the second modulator tank 12F , which is the first modification of the second modulator tank 12E is as a result of the combination of elements 12f1 . 12f2 formed, which are produced by a press processing. The second modulator tank 12F is from a first element 12f1 , whose cross-sectional shape perpendicular to the tube longitudinal direction X is a flat plate shape, and a second element 12f2 , whose cross-sectional shape perpendicular to the tube longitudinal direction X is a U-shape formed. The second modulator tank 12E is formed by arranging the first element 12f1 on an open-side end surface of the U-shaped second element 12f2 that with an outer rib 4 is connected, and by joining by means of soldering these elements together.

Third, as it is in the 14 is shown, the second modulator tank 12G , which is the second modification of the second modulator tank 12E is as a result of the combination of elements 12g1 . 12g2 formed, which are formed by a press processing. The second modulator tank 12G becomes from a first element 12g1 whose cross-sectional shape is perpendicular to the tube longitudinal direction X is an L-shape, and a second element 12g2 , whose cross-sectional shape is perpendicular to the tube longitudinal direction X similar to an L-shape constructed. The second modulator tank 12G is by combining the first element 12g1 in a reverse L-shape with the L-shaped second element 12f2 formed with the outer rib 4 is connected, and by solder joining these elements together.

As a result of the cooler of the seventh embodiment, by a light forming method, a large contact area for a connection surface of the second modulator tank becomes 12E . 12F or 12G with the outer rib 4 and the manufacturing cost of the radiator can be reduced.

Eighth embodiment

In an eighth embodiment of the invention, an embodiment other than the fourth embodiment will be described with reference to the configuration of connection between a first modulator tank 11C and a second collector tank 6D be explained. A cross-sectional view, which in the 15 is shown, indicates a shape of a communication section that exists between the interior of the first modulator tank 11C and the interior of the second header tank 6D is in communication when the communication portion is cut along a cross-sectional surface perpendicular to the tube stacking direction Z. In the 15 is a component denoted by the same reference numerals as in FIG 9 is the same component, and their operation and effect are also similar to those of the component in FIG 9 ,

A radiator of the eighth embodiment is different from the fourth embodiment in that the first modulator tank 11C and the second collector tank 6D through a communication element 20A connected between the tanks 6D . 11C is arranged. Except for this difference, the radiator of the eighth embodiment and the radiator of the fourth embodiment are the same, and they produce similar operation and effects.

As it is in the 15 is shown, are the second header tank 6D and the first modulator tank 11C separate elements, which are formed by an extrusion casting. The first modulator tank 11C includes a cylindrical portion through which the refrigerant flows, and a flat side plate portion 113 which is integral with a lateral part of this cylindrical portion on the side of the second header tank 6D is shaped. A refrigerant outlet connection 112 goes through the plate part 113 through and is in the side plate part 113 educated. The second collector tank 6D includes a refrigerant inflow port 68 at its position, the refrigerant outflow port 112 opposite.

The communication element 12A which is a through hole 201 is between the second header tank 6D and the first modulator tank 11C appropriate. The communication element 20A includes claw-shaped hook parts 202 . 203 extending from both ends of the element 20A extend to be bent over it. The communication element 20A is arranged such that the refrigerant inflow port 68 , the through hole 201 and the refrigerant outflow port 112 are overlapping to be connected to each other in the tube longitudinal direction X when the element 20A between the second collector tank 6D and the first modulator tank 11C is attached to the tanks 6D . 11C connect to.

The hook part 202 is further bent over to an end portion of the side plate part 113 of the first modulator tank 11C to hold, and the hook part 203 is further bent over to the second collector tank 6D to keep. By means of a solder joint from the respective parts in this state become the second header tank 6D and the first modulator tank 11C attached to each other, wherein a communication state between their respective inner space 63A and inner space 111 is ensured.

As a consequence, the refrigerant flowing from the second header tank flows 6D in the first modulator tank 11C through a communication passage 66 has flowed into the inner space 63A the second collector tank 6D through the refrigerant inflow port 68 , the through hole 201 and the refrigerant outflow port 112 , The refrigerant further flows into an inner space 121 through an open end part 122 a second modulator tank 12 , As a consequence, the interior of the second modulator tank 12 be used as a modulator room.

In the cooler of the eighth embodiment, by the communication element 20A the second collector tank 6D and the first modulator tank 11C connected in such a way that the refrigerant between the tanks 6D and 11C can communicate. A structure of not integrating the two tanks 6D . 11C Therefore, to be directly attached to each other directly, can be used. An air layer for thermal insulation can thus be between the two tanks 6D . 11C be formed, and the delivery and reception of heat between the two tanks 6D . 11C can be limited thereby, which contributes to the improvement of the heat exchange performance. As a result of the use of hook parts 202 . 203 In addition, a solder joint after a process of a temporary fixation of the second header tank 6D and the first modulator tank 11C be executed. A communication path between the two tanks can thus be formed in a secure manner.

Ninth embodiment

In a ninth embodiment of the invention, an embodiment other than the first embodiment will be described with reference to the configuration of a connection between a first modulator tank 11D and a second collector tank 6E be explained. A cross-sectional view taken in the 16 is shown gives a shape of a section 40 at which a communication path is not between a first modulator tank 11D and a second collector tank 6E is formed when this portion is cut along a cross-sectional surface perpendicular to the tube stacking direction Z. A cross-sectional view, which in the 17 is shown, indicates a shape of a communication section which is between the interior of the first modulator tank 11D and the interior of the second header tank 6E is in communication when the communication portion is cut along a cross-sectional surface perpendicular to the tube stacking direction Z. In the 16 and 17 is a component denoted by the same reference numerals as in FIG 9 is the same component, and their operation and effect are also similar to those of the component in FIG 9 ,

A cooler of the ninth embodiment is the fourth embodiment different, that the first modulator tank 11D and the second collector tank 6E , which are integrally formed, via a communication plate 20B connected to each other, which is attached to slit-shaped hole sections, in the two tanks 11D . 6E are shaped. Besides this difference, the radiator of the ninth embodiment and the radiator of the fourth embodiment are the same, and they produce similar operation and effects.

As it is in the 16 is shown, the second collector tank 6E and the first modulator tank 11D as a common element which is integrally molded by extrusion molding. This common element is a single element molded by, for example, extrusion molding. The tanks (common element) 6E . 11D be at their common side part 40 connected where a cylindrical section of the first modulator tank 11D which defines a columnar inner space, and a cylindrical portion of the second header tank 6E , which defines a similar columnar inner space, overlap. The tanks 6E . 11D are integrally formed. The common side part 40 is formed on the whole or part of the area between the two tanks to extend in the tube stacking direction Z.

As it is in the 17 is shown, the common element comprises a slot-shaped hole portion 40a at an area of the common side part 40 extending in the tube stacking direction Z, through which the communication path between both tanks should be formed. The communication board 20B which is a through hole 201 has, is at this hole section 40a attached, and the common element and the communication board 20B are connected to each other by soldering. As a result, over the through hole 201 an inner space 111 of the first modulator tank 11D and an inner space 63A the second collector tank 6E in communication with each other.

Consequently, the refrigerant flowing from the second header tank flows 6E in the first modulator tank 11D through a communication passage 66 has flowed into the inner space 63A the second collector tank 6E through the through hole 201 , Furthermore, the refrigerant flows into an inner space 121 through an open end part 122 a second modulator tank 12 , As a result, the interior of the second modulator tank 12 be used as a modulator room.

In the radiator of the ninth embodiment, the second header tank 6E and the first modulator tank 11D the common elements integrally molded by extrusion molding. As a result of attaching the communication board 20B which the through hole 201 has, on the common element are in the cooler, the inner space 63A the second collector tank 6E and the inner space 111 of the first modulator tank 11D over the through hole 201 in communication.

As a result of this configuration of the radiator, the second header tank becomes 6E and the first modulator tank 11D as the common element formed by extrusion molding. Thus, a reduction in the number of components and a man-hour reduction for handling the parts can be realized, and a reduction in man-hours required for performing the solder joint can be expected to reduce the cost of manufacturing the cooler , As a result of fixing the communication board 20B with the through hole 201 at a predetermined position of the common element (at the hole portion 40a Furthermore, a communication path between the two tanks can be reliably formed without a soldering process of attaching the second header tank together 6E and the first modulator tank 11D is carried out. The manufacturing process of the cooler that reduces a solder joint area may be provided.

Modifications of the above embodiments will be described. The embodiments of the invention have been described above. However, the invention is by no means limited to the above embodiments and can be carried out by various modifications without departing from the scope of the invention.

In the above embodiments, the second modulator tank is tank 12 along the entire length of the core part 2 provided in its lateral direction. However, the invention is not limited thereto. For example, the second modulator tank may 12 with the outer rib 4 along a part of the core part 2 be connected so as to the function of amplifying the core part 2 to serve.

It has been described that the elements constituting the radiator of the above embodiments are formed of an aluminum material or an aluminum alloy material. Alternatively, they may be made of iron, copper, stainless steel or their alloys.

In the above embodiments, the tube is 3 a porous tube structure formed by extrusion molding. Alternatively, a structure of arranging an inner fin inside the pipe 3 be used. The inner rib is a corrugated member in which a comb portion and a trough portion are alternately and continuously formed, and is made by brazing on an inner wall surface of the pipe 3 connected. In addition, the invention is also applicable to a radiator having a tube without an inner rib.

As it is in the 18 to 21 is shown, the invention may additionally be applied to a radiator having the following features. The arrows, which are in the 21 are shown, indicate a flow of refrigerant in the radiator (an S-shaped reversal of the flow in this example). The radiator comprises a core part 303 as a result of vertical stacking of outer ribs 302 and pipes 301 is obtained. The pipe 301 includes a passage for refrigerant, and the outer fin 302 has a function of heat exchange with the atmosphere. The radiator includes a pair of tanks 204 which is the core part 303 from both the right and left ends of the core part 303 hold. An inlet-side connector 208 which is an inlet port of the radiator for refrigerant, and an outlet side connector 209 are with one of the tanks 204 connected. One lateral modulator tank 212 is with the other of the tanks 204 connected. The lateral modulator tank 212 is located on one side of the radiator, next to the other of the tanks 204 , along the other of the tanks 204 , The refrigerant in a refrigeration cycle flows from the inlet side connector 208 through the core part 303 in a meandering fashion and in the lateral modulator tank 212 , There is only one refrigerant inflow port in the lateral modulator tank 212 and this inflow port is generally disposed on the downstream side in a flow of the refrigerant in the radiator. A filter 207 for collecting foreign substances in the refrigeration cycle and a desiccant 206 for absorbing water in the refrigeration cycle are in the lateral modulator tank 212 added. An upper modulator tank 211 which is part of the lateral modulator tank 212 may be just above the outer rib 302 at an uppermost part of the core part 303 arranged and is together with this outer rib 302 connected. Both ends of the upper modulator tank 211 in a horizontal direction from the radiator are each with the pair of tanks 204 connected, and their inner sections communicate with each other. The lateral modulator tank 212 containing the inner volume with the upper modulator tank 211 divides and which is arranged at the conventional mounting position, has generally the same length as the other of the tanks 204 , The lateral modulator tank 212 has a communication hole 213 at an upper part thereof, and the lateral modulator tank 212 stands with the other of the tanks 204 through the communication hole 213 in communication. Accordingly, the lateral modulator tank communicate 212 and the upper modulator tank 211 with each other, thereby forming a substantially L-shaped configuration. The pair of tanks 204 each comprises spaces at their upper parts, and the spaces have a modulator function. The pair of tanks 204 also includes spaces at their lower parts and the spaces associated with the group of pipes 301 are connected. These rooms are separate and shared. The pipe 301 in the condensation part 303a may additionally have any shape. The path in the condensation part 303a may have any configuration. The core part 303 may be any width.

As it is in the 22 to 24 is shown, the invention may further be applied to a radiator, in which a sub-cooling part 303b on an upper side of a condensation part 303a is arranged in a vertical direction from the radiator. The arrows in the 24 are shown, indicate a flow of refrigerant in the radiator (an S-shaped reversal of the flow in this example). In the present modification, the upper modulator tank is 211 in the 18 to 21 (hereinafter referred to as a lower modulator tank 322 ) is arranged on the lower side of the radiator in the vertical direction. The lower modulator tank 322 is just below the lowest outer rib 302 arranged and is along with this lowest outer rib 302 connected. The lower modulator tank 322 is with a pair of tanks 204 connected, and their inner sections communicate with each other. A drying agent 206 and a filter 207 are in a lateral modulator tank 212 added. An outlet 223 for removing the desiccant 206 and the filter 207 is at an upper part of the lateral modulator tank 212 provided in the vertical direction. A method for connecting or communicating between the lateral modulator tank 212 and the lower modulator tank 322 can be similar to the cooler described above in the 18 to 21 be.

Additional advantages and modifications will be immediately apparent to those skilled in the art. The invention in its broader terms is therefore not limited to the specific details, representative apparatus, and illustrative examples shown and described.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• KR 10-0799551 B1 [0004, 0004, 0005]

Claims (13)

Radiator, comprising: a core part ( 2 ) comprising: a plurality of tubes ( 3 each of which includes a refrigerant passage therein, wherein refrigerant flows through the refrigerant passage; and a plurality of outer ribs ( 4 ), wherein the plurality of tubes ( 3 ) and the plurality of outer ribs ( 4 ) are alternately stacked such that an outer surface of each of the plurality of tubes ( 3 ) with corresponding adjacent two of the plurality of outer ribs ( 4 ) connected is; a collector tank ( 6 . 6A . 6B . 6C . 6D . 6E ), with which end portions of the plurality of tubes ( 3 ) are connected in a tube longitudinal direction (X) such that the collecting tank ( 6 . 6A . 6B . 6C . 6D . 6E ) with the refrigerant passage of each of the plurality of pipes ( 3 ) is in communication; a first modulator tank ( 11 . 11A . 11B . 11C . 11D ); which along a lateral part of the collecting tank ( 6 . 6A . 6B . 6C . 6D . 6E ) is arranged in the longitudinal direction (X) of the tube so as to communicate with an inner portion of the header tank (10). 6 . 6A . 6B . 6C . 6D . 6E ) such that the refrigerant in the inner portion of the header tank ( 6 . 6A . 6B . 6C . 6D . 6E ) into the first modulator tank ( 11 . 11A . 11B . 11C . 11D ) to flow in the first modulator tank ( 11 . 11A . 11B . 11C . 11D ) to be accumulated; and a second modulator tank ( 12 . 12A . 12B . 12C . 12D . 12E . 12F . 12G ), which along a lateral part of the core part ( 2 ) is arranged in a tube stacking direction (Z) and with an inner portion of the first modulator tank (Z) 11 . 11A . 11B . 11C . 11D ), the second modulator tank ( 12 . 12A . 12B . 12C . 12D . 12E . 12F . 12G ) with one of the plurality of outer ribs ( 4 ), which at an end part of the core part ( 2 ) is arranged in the tube stacking direction (Z). Radiator according to claim 1, further comprising: a relay tank ( 9 ) which is integral with an upper part of the header tank ( 6 ) is formed in a vertical direction thereof, with an open end portion (FIG. 122 ) of a cylindrical body containing the second modulator tank ( 12 ), inside the relay tank ( 9 ), the relay tank ( 9 ) thereby having an inner portion of the second modulator tank ( 12 ) is in communication; and a communication board ( 20 ), which between the relay tank ( 9 ) and the first modulator tank ( 11 ) is arranged and which a through hole ( 201 ), wherein: the first modulator tank ( 11 ) a refrigerant outflow port ( 112 ) on a wall part of the first modulator tank ( 11 ) associated with the relay tank ( 9 ) is opposite; the relay tank ( 9 ) a refrigerant inflow port ( 91 ) at a position of the relay tank ( 9 ) which communicates with the refrigerant outflow port ( 112 ) is opposite; and the communication board ( 20 ) between the relay tank ( 9 ) and the first modulator tank ( 11 ) to the refrigerant Einströmanschluss ( 91 ), the through hole ( 201 ) and the refrigerant outflow port ( 112 ) together. A cooler according to claim 1, wherein: a cylindrical body supporting the second modulator tank (10); 12A ), through the collecting tank ( 6A ) goes through; an open end part ( 122 ) from the cylindrical body inside the first modulator tank ( 11A ) is arranged; and the inner portion of the first modulator tank ( 11A ) and an inner portion of the second modulator tank ( 12A ) are in communication with each other such that refrigerant from the inner portion of the first modulator tank ( 11A ) in the inner portion of the second modulator tank ( 12A ) flows. A cooler according to claim 1, further comprising a cylindrical communication element ( 22 ), which is connected to the second modulator tank ( 12B ), wherein: the communication element ( 22 ) through the collector tank ( 6B ) passes through such that an open end part ( 221 ) of the communication element ( 22 ) inside the first modulator tank ( 11B ) is arranged; and the inner portion of the first modulator tank ( 11B ) and an inner portion of the second modulator tank ( 12B ) by the communication element ( 22 ) are in communication such that refrigerant from the inner portion of the first modulator tank ( 11B ) in the inner portion of the second modulator tank ( 12B ) flows. A cooler according to claim 1, wherein: an open end portion ( 122 ) of a cylindrical body containing the second modulator tank ( 12 ), inside the collector tank ( 6C ) is arranged such that an inner portion of the second modulator tank ( 12 ) and the inner section of the collecting tank ( 6C ) are in communication with each other; the first modulator tank ( 11 ) a refrigerant outflow port ( 112 ) on a wall part of the first modulator tank ( 11 ) to the collector tank ( 6C ) is opposite; the collector tank ( 6C ) a refrigerant inflow port ( 68 ) at a position from the header tank ( 6C ) connected to the refrigerant outflow port ( 112 ) is opposite; and the first modulator tank ( 11 ) and the collector tank ( 6C ) are integrally formed to the Refrigerant inlet connection ( 68 ) and the refrigerant outflow port ( 112 ) connect to. Radiator according to claim 1, wherein: the collecting tank ( 6D ) and the first modulator tank ( 11C ) are formed separately by extrusion; the first modulator tank ( 11C ) comprises: a cylindrical part through which refrigerant flows; and a side panel part ( 113 ), which has a flat shape and at a lateral part of the first modulator tank ( 11C ) in the longitudinal direction (X) of the tube on one side of the header tank ( 6D ) is formed by the cylindrical part, wherein the side plate part ( 113 ) a refrigerant outflow port ( 112 ), which by the side plate part ( 113 ) goes through; and the collector tank ( 6D ) a refrigerant inflow port ( 68 ) at a position of the collecting tank ( 6D ) connected to the refrigerant outflow port ( 112 ), wherein the radiator is a communication element ( 20A ), which has a through hole ( 201 ) and a claw-shaped hook part ( 202 . 203 ) and which between the collector tank ( 6D ) and the first modulator tank ( 11C ) to the refrigerant Einströmanschluss ( 68 ), the through hole ( 201 ) and the refrigerant outflow port ( 112 ), whereby the collecting tank ( 6D ) and the first modulator tank ( 11C ) by the hook part ( 202 . 203 ) are fixed together. Radiator according to claim 1, wherein the collecting tank ( 6E ) and the first modulator tank ( 11D ) are molded integrally in a common element by extrusion, the cooler further comprising a communication plate ( 20B ) having a through hole ( 201 ), wherein the communication plate ( 20B ) is attached to the common element such that the inner portion of the header tank ( 6E ) and the inner portion of the first modulator tank ( 11D ) through the through hole ( 201 ) are in communication. Radiator according to one of claims 1 to 7, wherein the second modulator tank ( 12C ) is formed by extrusion and comprises: a flat base part ( 124C ) which is connected to one of the plurality of outer ribs ( 4 ) connected to the end part of the core part ( 2 ) is arranged; and a cylindrical part through which refrigerant from the first modulator tank ( 11 ) flows. Radiator according to one of claims 1 to 7, wherein: the second modulator tank ( 12D ) comprises a plurality of tubes which is identical to the plurality of tubes ( 3 ), which the core part ( 2 ) form; and the plurality of tubes of the second modulator tank ( 12D ) are stacked integrally. Radiator according to one of claims 1 to 7, wherein the second modulator tank ( 12E . 12F . 12G ) is formed as a result of the combination of a plurality of elements formed by press molding. Radiator, comprising: a core part ( 303 ) comprising: a plurality of tubes ( 301 each of which includes a refrigerant passage therein, wherein refrigerant flows through the refrigerant passage; and a plurality of outer ribs ( 302 ), wherein: the plurality of tubes ( 301 ) and the plurality of outer ribs ( 302 ) alternately in a vertical direction from the core part ( 303 ) are stacked; and the core part ( 303 ) between a condensation part ( 303a ) and a subcooling part ( 303b ) is divided; a pair of tanks ( 204 ), which the core part ( 303 ) from both sides of the core part ( 303 ) in a horizontal direction thereof; a first modulator tank ( 211 . 322 ) which is connected to one of the plurality of outer ribs ( 302 ) connected at one end portion of the core part ( 303 ) is arranged in the vertical direction, and which with the pair of tanks ( 204 ) is connected such that an inner portion of the first modulator tank ( 211 . 322 ) and respective modulating inner portions of the pair of tanks ( 204 ) communicate with each other, the modulating inner portion of each of the pair of tanks ( 204 ) close to the one of the plurality of outer ribs ( 302 ) at the end portion of the core part ( 303 ) is arranged from the other inner portion of each of the pair of tanks (FIG. 204 ), which is connected to the plurality of tubes ( 301 ), whereby the modulating inner section does not interfere with the core part ( 303 ) is in communication; a second modulator tank ( 212 ), which on a lateral side of the core part ( 303 ) in the horizontal direction along one of the pair of tanks ( 204 ) is arranged in a longitudinal direction thereof and with the one of the pair of tanks (FIG. 204 ), wherein: the second modulator tank ( 212 ) with the modulating inner portion of the one of the pair of tanks ( 204 ) is in communication; and an inner portion of the one of the pair of tanks ( 204 ), which is different from the modulating inner portion, with the second modulator tank (FIG. 212 ) is in communication and near a downstream portion of the condensation part ( 303a ) is arranged in a flow direction of the refrigerant; a drying agent ( 206 ) stored in the second modulator tank ( 212 ) is arranged to absorb moisture in a refrigerant circuit; and a filter ( 207 ), which in the second modulator tank ( 212 ) is arranged to collect foreign substances in the refrigerant circuit. Radiator according to claim 11, wherein: the first modulator tank ( 211 ) having a highest of the plurality of outer ribs ( 302 ) is connected in the vertical direction; and the modulating inner portion of each of the pair of tanks ( 204 ) near the highest of the plurality of outer ribs ( 302 ) is arranged from the other inner portion of each of the pair of tanks (FIG. 204 ) is divided. Radiator according to claim 11, wherein: the first modulator tank ( 322 ) with a lowermost of the plurality of outer ribs ( 302 ) is connected in the vertical direction; the modulating inner portion of each of the pair of tanks ( 204 ) which is near the bottom of the plurality of outer ribs (FIG. 302 ) is arranged from the other inner portion of each of the pair of tanks (FIG. 204 ) is divided; the second modulator tank ( 212 ) a removal section ( 223 ) at an upper part of the second modulator tank ( 212 ) in the vertical direction; and the drying agent ( 206 ) and the filter ( 207 ) stored in the second modulator tank ( 212 ) are arranged through the removal section ( 223 ) are taken out.

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