DE9219200U1 - Air conditioning condenser - Google Patents

Description

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PATENT ATTORNEYS - EUROPEAN PATENT AND TRADEMARK ATTORNEYS

D - 70174 Stuttgart Hospitalstraße 8 Tel.: (0711) 228110

Applicant:

Behr GmbH & Co. Stuttgart, 06.09.1999

Mauserstrasse 3 GA 13205

Da/mö
70469 Stuttgart

Condenser for a vehicle air conditioning system

The invention relates to a condenser for an air conditioning system of a vehicle, which contains a tube-fin block which is provided on both sides with collecting tubes which are divided by means of partition walls in such a way that the tube-fin block forms an upper condensing section for gaseous refrigerant and a lower subcooling section for liquid refrigerant, wherein next to one of the collecting tubes and parallel thereto a collector is arranged which is connected to this collecting tube.

In a known condenser of the type mentioned above (EP 0 480 330 A2), the collector, which serves as a kind of intermediate storage for liquid and gaseous refrigerant, is connected to a connecting line between the condensing section and the subcooling section.

The invention is based on the object of designing a condenser of the type mentioned at the outset in such a way that relatively great design freedom exists with regard to the design of the condensing section and in particular the subcooling section.

This object is achieved in that the collector forms a flow connection between the condensing section and the subcooling section and is connected to the condensing section via a first connecting opening and to the subcooling section via a second connecting opening arranged in the region of its bottom.

The arrangement of the collector, which is connected to the condensing section and the subcooling section via separate connecting openings, allows greater design freedom. In particular, it is possible to design the subcooling section within the condenser in such a way that the liquid coolant is fed to the subcooling section in the area of the lower end of the condenser, so that the liquid coolant flows through the condenser from bottom to top with several counter-directional movements on the way to an outlet connection.

In a further embodiment of the invention, it is provided that the collecting pipe and the parallel collector are designed as a double pipe, in the wall of which separating the two pipe chambers the connecting openings are arranged. This results in an extremely compact construction which does not contain any connecting or connection points that need to be sealed to the outside.

In a first embodiment, it is provided that the double pipe is assembled from at least two sheet metal profiles.

In another embodiment of the invention, the double pipe is composed of sheet metal profiles and an extruded connecting profile. In both embodiments, the individual elements are first preassembled and then soldered in an oven.

In a further embodiment of the invention it is provided that the double pipe is an extruded two-chamber pipe.

In a further embodiment of the invention, it is provided that the tube chamber serving as a collector is arranged offset relative to the plane of the tube-fin block. This offset arrangement can lead to considerable installation advantages, particularly when the condenser is arranged between a fan frame and a cooler for the engine fluid of a vehicle in the engine compartment, in which usually only little installation space is available.

Further features and advantages of the invention will become apparent from the following description of the embodiment shown in the drawing.

Fig. 1 shows a vertical section (along the line I-I

Fig. 2) by a capacitor according to the invention,

Fig. 2 is a plan view of the capacitor of Fig. 1,

Fig. 3 is a plan view of a modified embodiment of a capacitor according to the invention with its position installed in a motor vehicle with respect to other elements,

Fig. 4 and 5

modified embodiments for a double pipe made of sheet metal profiles, which serves as a collecting pipe and collector,

Fig. 6 and 7

Views of double pipes serving as header and collector, which are manufactured as extruded pipes,

Figs. 8 and 9

Top views of the double pipes serving as sairanel pipe and as collector, each consisting of a connecting profile and sheet metal profiles attached to it.

Fig. 10 a vertical partial section through the lower area
a modified embodiment of a capacitor with integrated collector, and

Fig. 11 a cross section through manifold and collector in
Area of a connection opening.

The condenser shown in Fig. 1 and 2 has a tube-fin block 10 with horizontally arranged flat tubes 11 and fins 12 arranged between them. The flat tubes 11 open into header pipes 13, 14, which run on both sides over the entire height of the tube-fin block 10. The header pipe 13 on the left in the drawing is provided with an inlet connection 15 for gaseous refrigerant coming from a compressor. The same header pipe 13 is also provided with a connection 16 for a line through which liquid refrigerant is transported to an expansion valve.

The two header pipes 13, 14 are divided vertically by partition walls 17, 18, which divide the tube-fin block 10 into an upper condensing section for the condensing gaseous refrigerant and a subcooling section for the already liquid refrigerant. The two partition walls 17, 18 are at the same height. The header pipes 13, 14 are divided in the condensing section above the partition walls 17, 18 by means of further intermediate partition walls 19, 20; 21, 22 in such a way that the gaseous refrigerant describes a curvilinear path in the condensing section, with the flow cross-section increasing with increasing cooling.

the decreasing volume of the gaseous refrigerant is also reduced.

A collector 23 is connected to one of the collecting pipes (in the drawing to the right-hand collecting pipe 14), which is connected to the lower outlet area of the condensing section via a connecting opening 24. Liquid coolant collects in the collector 23 up to a certain level. Gaseous coolant is located above this. The collector 23, through its function as a vapor separator and filling reservoir, ensures that the state of the coolant passing from the connecting opening 24 into the collector 23 is essentially saturated, i.e. the coolant is already completely condensed there.

The collector 23 is connected to the subcooling section in which liquid coolant is subcooled via a connecting opening 25, which is located particularly in the area of the base. The collecting pipes 13, 14 are each divided in the subcooling section by an intermediate partition wall 26, 27, so that a Z-shaped flow path for the liquid coolant is produced from the connecting opening 25 to the outlet connection 16.

The collecting pipes 13, 14 are closed at the top and bottom by end walls 28, 29, 30, 31. The end walls 30, 31 of the collecting pipe 14 also simultaneously form the upper and lower end walls for the tubular collector 23 attached to the collecting pipe 14.

As shown in Fig. 1, a dryer cartridge 32 is arranged within the collector 23. In the embodiment according to Fig. 1, the dryer cartridge 32 cannot be removed from the collector 23. In a modified embodiment, the closure wall 31, i.e. the bottom of the collector 23, is provided with a threaded connector into which a

A cover corresponding to the diameter of the dryer cartridge 32 is screwed in to seal it. In this embodiment, the dryer 32 can be removed from the collector and replaced.

In the embodiment according to Fig. 1 and 2, the manifold on the left in the drawing consists of two sheet metal profiles 33, 34 of approximately semi-oval cross-section, the edges of which overlap.

The collector pipe 14 on the right in the drawing is also composed of two sheet metal profiles 35, 36 which overlap one another. The sheet metal profile 35 is provided with extended edges 37 which form connecting surfaces for the collector 23, which consists of a substantially cylindrically bent sheet metal profile.

The entire capacitor is constructed in such a way that it can be pre-assembled in the form described so far, with the individual elements already held together by force or form. In this assembled or pre-assembled form, the capacitor is placed in a soldering furnace in which it is soldered, thus creating a firm and tight connection between the individual elements. For this purpose, the individual elements are provided with a solder plating in the known manner.

In motor vehicles, it is common practice for a condenser, as shown in Fig. 3, to be arranged in the direction of travel in front of a cooler 40 for the engine coolant. In front of the condenser there is then a fan with a fan frame 41. In the embodiment according to Fig. 3, the collector 23' is attached to the collector pipe 14' in such a way that it is offset from the plane of the tube-fin block 10. This makes it possible to attach the tubular collector 23' to the collector pipe 14' without having to change the previous installation dimensions. It is of course also possible to arrange the collector 23' rotated even further clockwise relative to the collector pipe 14' so that the tube-fin block 10 with the collector pipe 14 can be moved even closer to the cooler 40.

Furthermore, it is possible to provide the collector 23' with a contour which surrounds the indicated water tank 42 of the cooler at a distance.

In the embodiment according to Fig. 4, it is provided that the collecting pipe 14'' with the integrally formed collector 23'' is composed of three sheet metal profiles, similar to Fig. 1. In this embodiment, however, the sheet metal profile forming the collector 23' is provided with bent tabs which are placed on the collecting pipe 14'' from the outside and are soldered to it there to form a seal.

In the embodiment according to Fig. 5, it is provided that the collecting pipe 14' ' ' and the collector 23' ' ' are formed from only two sheet metal profiles 35 and 43. The sheet metal profile 35 corresponds in its shape to the sheet metal profile 35 used in Fig. 1 and 2. The sheet metal profile forming the collector 23' ' is a closed pipe 43 which has a flattening in the area facing the collecting pipe 14' ' '. It is of course also possible to use a completely cylindrical pipe or a rectangular or square or other shaped pipe.

In the embodiment according to Fig. 6, an extruded double tube 44 is provided, which forms a collecting tube with one tube chamber and the collector with another tube chamber.

As shown in Fig. 7, a double tube 45 may be provided having an asymmetrical profile if this is advantageous for installation reasons.

In the embodiment according to Fig. 8, an extruded intermediate profile 46 is provided which is provided with receiving slots 47, 48 running in the vertical direction, into which the edges of approximately semi-oval sheet metal profiles 49, 50 are inserted, which form a collecting pipe and a collector.

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The same principle as shown in Fig. 8 is also used in the embodiment shown in Fig. 9, i.e. two sheet metal profiles 52, 53 are joined together by means of an extruded connecting profile 51, which form a collecting pipe and a collector. The connecting profile 51 is provided with receiving slots 54, 55 running in a vertical direction, into which the edges of the sheet metal profiles 52, 53 are inserted.

As already mentioned, the connecting openings 24, 25 between the collecting pipe 14 and the collector 23, which are arranged at a distance from one another, ensure that the collector is flowed through by the coolant. In order to ensure that the subcooling section receives only liquid coolant from the connecting opening 25, the collector 23 must also fulfil the function of a liquid separator as ideally as possible. The effect of the collector 23 is then that, depending on the operating state, a different liquid level forms in the collector 23, which influences the condensation pressure and thus the associated condensation temperature in such a way that the state of the coolant flowing into the collector 23 through the connecting opening 24 is also largely saturated with liquid in all operating states. The slim design of the collector 23 can lead to gas bubbles being carried downwards from the connection opening 24 to the connection opening 25 due to the high flow speed of the refrigerant mass flow in the collector 23, which would impair the desired, best possible phase separation and thus the separation of the condenser module into condensation section and subcooling section. To prevent this, according to the embodiment according to Figs. 10 and 11, the connection opening 24 is designed in such a way that it creates a liquid vortex, whereby the heavier liquid components of the refrigerant mass flow move outwards and then flow downwards along the inner wall, while the lighter gas components remain in the center and migrate downwards. For this purpose, the connection opening 24 is designed as a punched

opening from which a tab 56 serving as a guide means is folded out. The tab 56 is directed towards the adjoining inner wall of the collector 23 so that the coolant flows into the collector with a vortex. In the embodiment shown, the collector 23 has a substantially cylindrical cross-section, with the tab 56 being directed approximately tangentially.

As shown in Fig. 10, it is possible to design the lower connection opening 25, through which coolant flows from the collector 23 to the subcooling section, in a corresponding manner. It is expedient here for the tab 57 to be folded out in the opposite direction, so that the liquid coolant flows out with a flow in the same direction.

As is also shown in Fig. 10, the collecting pipe 14 and the collector 23 connected to it are closed by means of a common cover 58 which is provided with slots corresponding to the contours of the collecting pipe 14 and the collector 23, so that this cover 58 is placed on the ends of the collecting pipe 14 and the collector 23 and is soldered to them. In the area of the collector 23, the cover 58 is provided with a threaded hole into which a sealing plug 59 is screwed. A sealing ring 60, in particular an O-ring, is inserted between the sealing plug 59 and the cover 58. The dryer 32 consists of drying granules filled into a ¹ ' bag. This dryer can be replaced after loosening the sealing plug 59. Advantageously, the dryer 32 is kept so short in the axial direction that it does not reach the area of the connecting opening 24, so that the dryer 32 does not prevent the formation of vortices in the collector 23.

Claims (9)

1. Condenser for an air conditioning system of a vehicle, which contains a tube-fin block which is provided on both sides with collecting tubes which are divided by means of partitions such that the tube-fin block forms an upper condensing section for coolant and a lower subcooling section for coolant, wherein next to one of the collecting tubes and parallel thereto a tubular collector is arranged which is connected to this collecting tube, characterized in that the collector ( 23 ) forms a flow connection between the condensing section and the subcooling section and is connected to the condensing section via a first connecting opening ( 24 ) and to the subcooling section via a second connecting opening ( 25 ). 2. Condenser according to claim 1, characterized in that the collecting tube ( 14 ) and the collector parallel thereto are designed as a double tube, in the wall of which separating the two tube chambers the connecting openings ( 24 , 25 ) are arranged. 3. Condenser according to claim 2, characterized in that the double tube is assembled from at least two sheet metal profiles ( 35 , 36 , 38 ; 35 , 43 ). 4. Condenser according to claim 2, characterized in that the double tube is composed of sheet metal profiles ( 49 , 50 ; 52 , 53 ) and an extruded connecting profile ( 46 ; 51 ). 5. Condenser according to claim 2, characterized in that the double tube is an extruded two-chamber tube ( 44 , 45 ). 6. Condenser according to one of claims 1 to 5, characterized in that a dryer ( 32 ) is arranged in the collector ( 23 ). 7. Condenser according to one of claims 1 to 6, characterized in that the tube chamber serving as a collector ( 23 ') is arranged offset from the plane of the tube-fin block ( 10 ). 8. Condenser according to one of claims 1 to 7, characterized in that at least the first connecting opening ( 24 ) leading from the condenser section to the collector ( 23 ) has an outlet with a shape generating a flow vortex in the collector. 9. Condenser according to claim 8, characterized in that the outlet of the connecting opening ( 24 ) is provided with a guide element ( 56 ) which is directed towards a wall of the collector adjoining the connecting opening.