EP1314946A1 - Heat exchanger, in particular evaporator - Google Patents

Abstract

The device has a flange element (17) directly mounted on a connection element (9) that axially bounds an inlet manifold (7) and an exhaust manifold (6) at one lateral end of the heat exchanger block (2) and is attached directly to the heat exchanger block and/or a component containing the manifolds mounted on the block. The inlet and exhaust ports (20,18) of the manifolds extend into the flange element. <??>AN Independent claim is also included for the following: a method of manufacturing an inventive device.

Description

The present invention relates to a product produced by complete soldering Heat exchanger, in particular an evaporator for a vehicle air conditioning system, with the features of the preamble of claim 1.

Such a heat exchanger is known for example from DE 198 14 051 A1 known and has a heat exchanger block of several, parallel mutually extending heat transfer channels. Furthermore, one Intake manifold and an outlet collection channel provided in parallel to each other and transverse to the heat transfer channels, with respect to the longitudinal extent of the heat transfer channels at one upper or lower end of the heat exchanger block are arranged and communicate with each other via the heat transfer channels. Of the known heat exchanger is as a disk heat exchanger formed in which the intake manifold, the outlet collection channel and the heat exchanger block with its heat transfer channels through in Longitudinal direction of the inlet collecting channel and the outlet collecting channel to each other layered discs are constructed. This disc heat exchanger has a cover, which in the layer direction the outermost Heat transfer channel limited. The cover has a with the Inlet manifold communicating inlet port and one with the Outlet collection channel communicating outlet opening. On the cover is outside in the layer direction an inlet / outlet channel plate attached, which contains an inlet channel and an outlet channel and at the a flange is attached, which has an inlet port and a Having outlet, wherein these nozzles parallel to the collecting channels run. The inlet and the outlet of the flange communicate via the inlet channel and the outlet channel of Inlet / outlet channel plate and over the inlet opening and the outlet opening the cover with the intake manifold or with the Outlet collection channel of the heat exchanger. The installation effort for a Such heat exchanger is relatively large.

From DE 197 19 251 A1 another heat exchanger is known, the is designed as a flat tube heat exchanger. Accordingly, the Inlet collection channel and the outlet collection channel in a collection box formed at the top or at the bottom of the heat exchanger block is attached, wherein the heat transfer channels of the heat exchanger block are formed in heat exchanger tubes. The collection box This Flachrohrwärmeübertragers is at one axial end through closed a lid on the outside, that is on one of the intake manifold or the outlet collecting channel side facing away, a with the Inlet manifold communicating port for an expansion valve and a connection communicating with the outlet collection channel for a Outlet tube are formed. The lid has a step, so that the said connections with respect to the longitudinal direction of the collecting channels arranged clearly in front of a lateral end of the heat exchanger block are. In this stage, for example, the expansion valve can be arranged become. Due to this construction, the collection box builds relatively high and must also be made relatively expensive inside to the at the terminals associated lateral end of the heat exchanger block to ensure a sufficient flow through the heat exchanger tubes.

From US 5 826 648, EP 0 947 796 A2, EP 0 660 053 B1, the EP 0 953 815 A2, EP 0 769 665 A2, DE 195 11 742 A1 and DE 199 50 128 A1 discloses other disc heat exchangers are known, each have relatively expensive constructed inlet / outlet channel plates to the Inlet manifold and outlet manifold with ports, in particular with a flange element containing the connections, too connect.

From US 5 529 117 and EP 0 762 072 A2 are further Flat tube heat exchanger known, each having an upper and a lower collection box. For both headers is a common lid provided, which has an inlet channel and an outlet channel contains and connections for an inlet pipe and an outlet pipe having. This structure is relatively expensive.

From EP 0 703 425 B1 it is known to use a heat exchanger Form flange in several parts by a in a support plate Einlaßstutzenteil and a Auslaßstutzenteil be used.

The known heat exchanger thus have a relatively expensive Construction, whereby their production is comparatively expensive. Furthermore, it is in the known heat exchangers usually the variant formation relatively expensive because, for example, for heat exchanger blocks of different heights, i.e. for different lengths of heat transfer channels, respectively different inlet / outlet channel plates must be provided.

The present invention deals with the problem, for a Heat exchanger of the type mentioned an embodiment specify, which has a particularly simple structure and correspondingly inexpensive to produce. Furthermore, an embodiment is intended be found in the variant formation for the heat exchanger is relatively inexpensive feasible.

This problem is inventively by a heat exchanger with the features of claim 1 solved. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea, the flange directly attached to a closure element, which in turn immediately at the inlet collecting channel and the outlet collecting channel containing component is attached. The arrangement of the flange element takes place in such a way that the neck formed in it Flange element each extend the associated collection channel axially, that is, the terminal is in close proximity to the Collection channels. The end element to which the flange element directly is attached, serves at a with respect to the longitudinal direction of the collecting channels lateral end of the heat exchanger block for axial limitation the collection channels. This is usually the terminating element in a disc heat exchanger around a cover, the in Layer direction limits the outermost heat transfer channel or at a flat tube heat exchanger around a lid, the the collecting ducts containing collecting tank axially limited. Accordingly it is the terminating element is a component which is connected to a usual heat exchanger is present anyway. By mounting the Flange element directly on this terminating element can additional flow components, such as e.g. a Inlet / outlet channel plate, omitted. Accordingly, simplifies the Assembly effort in the production of the heat exchanger. Furthermore This also makes the variant formation for the heat exchanger clear simplified, since different heights of the heat exchanger blocks not on the positioning or attachment of the flange element impact. In particular, no different need Inlet / outlet channel plates are provided and managed logistically. Furthermore, it is basically possible, the flange in the essentially identical in both disk heat exchangers and in Use flat tube heat exchangers. This standardization leads to further cost savings.

If the heat exchanger is designed as a flat tube heat exchanger, has the closure element forming the lid an inlet opening and an outlet in which the inlet port and the outlet of the Protrude flange. In a special training can the inlet opening and the outlet opening of the lid respectively as be formed cylindrical passage, so that the inlet opening and the Outlet each having an axially projecting annular collar, in the inlet port or the outlet is inserted. Through this Measure can be annular contact surfaces between the nozzle and to achieve the passages. The resulting capillary action brings advantages in the soldering. Furthermore, this material accumulation brings on this site strength advantages.

Appropriately, the flange may be configured so that in particularly simple manner, an expansion valve and / or an inlet pipe and / or an outlet pipe can be connected. The connections can preferably designed as plug-in connections, for the production a tight connection no soldering and no welding process need.

Furthermore, one or more threaded openings can be made on the flange element Be provided or threaded holes, with the help of a Expansion valve and / or a pipe assembly with an inlet pipe and / or an outlet tube on the flange can be screwed.

The problem underlying the invention is also by a method solved with the features of claim 11. By the expansion of the Neck in the passages of the openings of the lid is the flange element self-holding fixed on the lid, so no elaborate Clamping device is required for positioning the connection element, which considerably simplifies the complete soldering process.

Other important features and advantages of the invention will become apparent from the Subclaims, from the drawings and from the associated description of the figures based on the drawings.

It is understood that the foregoing and the ones below to be explained features not only in the specified Combination, but also in other combinations or in isolation are usable without the scope of the present invention leave.

Preferred embodiments of the invention are shown in the drawings and are explained in more detail in the following description, where like reference numerals refer to the same or functionally identical or refer to similar components.

Fig. 1

eine perspektivische Ansicht auf einen Wärmeübertrager bei einer ersten Ausführungsform,

Fig. 2

eine Schnittansicht im Bereich eines Flanschelements bei der Ausführungsform gemäß Fig. 1,

Fig. 3

eine Ansicht wie in Fig. 1, jedoch bei einer zweiten Ausführungsform, und

Fig. 4

eine Schnittansicht wie in Fig. 2, jedoch bei der Ausführungsform gemäß Fig. 3.

Show, in each case schematically,

Fig. 1

a perspective view of a heat exchanger in a first embodiment,

Fig. 2

1 is a sectional view in the region of a flange in the embodiment of FIG. 1,

Fig. 3

a view as in Fig. 1, but in a second embodiment, and

Fig. 4

a sectional view as in Fig. 2, but in the embodiment of FIG. 3rd

1, a heat exchanger 1, in particular a Evaporator of a Fahrzeugklimaanlge, a heat exchanger block 2, the internally several consecutively arranged or layered heat transfer channels 3, which are parallel to each other. Of the Heat exchanger block 2 is in the usual way with multiple layers arranged discs or disc pairs constructed, the Slices or pairs of discs containing the heat transfer channels 3. The individual pairs of discs are in the layer direction from one another spaced. Between adjacent disk pairs can be in common Way lamellar heat transfer medium or the like. be arranged. The heat exchanger block 2 is in a known manner by a gas flow permeable, whereby the individual pairs of discs are flowed around. The Operation of such a heat exchanger 1 is well known and therefore need not be explained in detail.

With respect to a symbolized by an arrow 4 longitudinal direction of the Heat transfer channels 3 are shown in FIG. 1 at an upper end of the fifth the heat exchanger block 2 internally an intake manifold 7 and a Outlet collection channel 6 arranged side by side, via the heat transfer channels 3 communicate with each other and parallel to each other as well run transversely to the heat transfer channels 3.

In the embodiment shown in Fig. 1 is a so-called disc heat exchanger, which consists of a variety of each other layered discs 8 and 9 or 10 is constructed. Two adjacent ones Discs 8, 9 and 10 form between them a U-shaped or two rectilinear heat transfer channels 3 and also include Channel sections, which in the assembled state, the inlet collection channel 7 and the outlet collecting channel 6 form. Accordingly, at the disc heat exchanger 1 shown in Fig. 1, the intake manifold 7, the outlet collection channel 6 and the heat exchanger block 2 with its Heat transfer channels 3 through the discs 8, 9, 10 constructed in the direction indicated by an arrow 13 longitudinal direction of the intake manifold 7 and the outlet collecting channel 6 are stacked on each other.

The embodiment of the disc heat exchanger 1 shown in FIG. 1 has at a lower end 11 of the heat exchanger block 2 more internal channels 12, which serve for flow deflection. The longitudinal direction 13 of the collecting channels 6 and 7 corresponds to the layer direction the discs 8, 9, 10. With respect to the layer direction 13 are between lateral ends 14 and 15 of the heat exchanger block 2 except the outermost heat transfer channels 3 all heat transfer channels 3 of identical or complementary pairs of identical Disks 8 built. Only the structure of the outermost heat transfer channels 3 takes place in conjunction with a cover 9 and 10 respectively.

Furthermore, the disk heat exchanger 1 shown here has the lateral ends 14 and 15 of the heat exchanger block 2 each one Side trim part 16.

In the embodiment of FIG. 1 forms the viewer facing cover 9, a closure element, the inlet manifold 7 and the outlet collecting channel 6 with respect to the longitudinal direction 13 at the viewer facing the lateral end 14 of the heat exchanger block 2 axially limited. This cover 9 is part of the Heat exchanger block 2 and thus attached to this.

The heat exchanger 1 also has a one-piece or one-piece Flange element 17, which in the region of the collecting channels 6 and 7 at the Cover 9 is attached. The flange member 17 includes two Threaded holes or threaded holes 24, with the help of components or assemblies on the flange 17 are screwed. For example can thereby a holder for an inlet pipe and / or an outlet pipe on Flange element 17 are screwed. Likewise, with the help of Tapped holes 24 an expansion valve on the flange 17th be screwed on.

Referring to Fig. 2, the flange member 17 at one of the intake manifold 7 facing side a cylindrical inlet port 20, which is inserted into an inlet opening 21, which in the region of the inlet collecting channel 7 is formed on the cover 9. In appropriate Way has the flange 17 at the outlet collection channel. 6 side facing also a cylindrical outlet port 18, the in an outlet opening 19 is inserted, which in the region of the Auslaßsammelkanals 6 is formed in the cover 9. Inlet pipe 20 and Outlet 18 extend parallel to the intake manifold 7 and zum Auslaßsammelkanal 6. Suitably, the flange 17 at the the collection channels 6 and 7 formed side, apart from the protruding therefrom neck 18 and 20, relatively flat.

The flange 17 has at its from the intake manifold 7th side facing away from a cylindrical terminal 23, on which a Expansion valve can be connectable, so that the connection 23 then forms an expansion valve port 23. Alternatively or additionally the port 23 may also be formed so that thereon an inlet pipe is connectable. Accordingly, this port 23 can then also as Inlet pipe connection 23 are designated. In addition, the Flange element 17 on its side facing away from the outlet collection channel 6 side a port 22 to which an outlet pipe is connectable. Accordingly, this port 22 can also be used as outlet pipe connection 22 be designated. The flange 17 faces the Terminal 22 on a paragraph, whereby the flange 17 with a exactly defined soldering surface comes to rest on the cover 9 and thereby simplifies the Dichtlötung.

The expansion valve port 23 and the inlet pipe port 23 is expedient coaxial with the inlet port 20 is formed. The connection 23 communicates with the inlet port 20 which penetrates the inlet port 21 and protrudes into and communicates with the intake manifold 7. In Similarly, the outlet pipe connection 22 is coaxial with Outlet port 18 is arranged, wherein the outlet pipe connection 22 with the Outlet 18 communicates, in turn, the outlet opening 19th penetrates and projects into the outlet collection channel 6 and with this communicated. From Fig. 2 it is clear that the nozzles 18 and 20 the respectively associated collecting channel 6 or 7 within the flange element Extend 17 axially.

According to Fig. 3, the heat exchanger 1 at another Embodiment be designed as a flat tube heat exchanger. On Such flat tube heat exchanger 1 has according to FIG. 3 at one end, here at the upper end 5 of the heat exchanger block 2 a collection box 25, in which the intake manifold 7 and the outlet collection channel. 6 are formed. The heat exchanger block 2 then consists of a Variety of parallel heat transfer tubes 26, with respect to the Longitudinal direction 13 of the collecting channels 6 and 7 in a relatively large number one behind the other and in particular in pairs next to each other are. The heat transfer tubes 26 then contain the heat transfer channels 3. In the embodiment shown here is at the bottom End 11 of the heat transfer block 2, another collection box 27th arranged, which contains one or more channels 12 and for the realization a flow deflection is used. The heat transfer tubes 26 are via appropriate passages with the channels 6, 7 and 12 of the Collecting boxes 25 and 27 connected. Also, the structure of such Flachrohrwärmeübertragers 1 is well known and therefore does not have be explained in more detail.

At the respect to the longitudinal direction 13 of the collecting channels 6, 7 axial Ends of the headers 25 and 27 are covers 28 and 29 at the respective Collecting box 25 and 27 attached, each of which contained therein Limiting channels 6, 7, 12 axially. Thus, the forms in Fig. 3 the Viewer facing, attached to the upper header box 25 lid 29 again a closure element, the inlet collecting channel 7 and the Outlet collection channel 6 with respect to the longitudinal direction 13 at the Viewer facing the lateral end 14 of the heat exchanger block. 2 axially limited. This lid 29 is thus directly on the collecting box 25, which contains the inlet collecting channel 7 and the outlet collecting channel 6, appropriate. At this special cover 29, the flange 17 appropriate.

According to Fig. 4, the lid 29 also includes an inlet opening 21 and an outlet opening 19. The inlet opening 21 and the outlet opening 19 are each formed as a cylindrical passage. Accordingly, the Inlet opening 21 with an axially projecting, in the intake manifold 7th protruding annular collar 31 while the outlet opening 19 an annular collar 30 which projects axially and into the Auslaßsammelkanal 6 protrudes. The inlet port 20 and the outlet port 18 of the Flange member 17 are dimensioned so that these in the passages of Inlet opening 21 and the outlet port 19 can be inserted, wherein an annular overlap in the region of the passage or the Ring collar 30, 31 results. Appropriately, the sizing is chosen so in that the flange element 17 faces the collecting tank 25 at its Side on the lid 29 comes to rest when the sockets 18 and 19 about flush with the ring collars 30 and 31.

From Fig. 4 it is apparent that in this embodiment, the nozzle 18 and 20 in the interior of the flange 17 an axial extension of the form respective collection channel 6 and 7 respectively.

Suitably, the production of the shown in Figs. 3 and 4 Flat tube heat exchanger 1 according to the following steps:

First, the flange member 17 is connected to the lid 29 by the inlet port 20 in the passage of the inlet port 21 and the outlet 18 are inserted into the passage of the outlet opening 19. Tolerance can be done with play. Subsequently, the Inlet port 20 and the outlet port 18 of the flange 17th expanded so that a strain with the passages or the annular collar 30 and 31 results. After this expansion, that is Flange element 17 self-holding positioned on the lid 29. Subsequently For example, the lid 29 can be attached to the device by means of corresponding tabs 32 (see FIG Collecting box 25 are attached. The completed heat exchanger 1 can then be completely soldered.

When heat exchanger 1 according to the invention is of special Meaning that by the selected arrangement of the flange 17th the dimensioning of the heat exchanger block 2 relatively arbitrary can be configured, with always the same flange 17th is usable. In addition, the assembly of the Heat exchanger 1 according to the invention, since the flange member 17th is attached directly to the cover 9 and the cover 29. Additional parts between the connection element 17 and the Cover 9 and the lid 29 are arranged, due to the selected arrangement of the flange 17 omitted.

LIST OF REFERENCE NUMBERS

1

Heat exchanger

2

heat exchanger block

3

Heat transfer channel

4

Longitudinal direction of 3

5

upper end of 2

6

exhaust collecting

7

Inlet collector channel

8th

disc

9

cover plate

10

cover plate

11

lower end of 2

12

channel

13

Longitudinal direction of 6, 7

14

lateral end of 2

15

lateral end of 2

16

Side trim panel

17

flange

18

outlet

19

outlet

20

inlet connection

21

inlet port

22

connection

23

connection

24

threaded opening

25

collection box

26

Heat pipe

27

collection box

28

cover

29

cover

30

gorget

31

gorget

32

flap

Claims (13)

Heat exchanger produced by complete soldering, in particular evaporator for a vehicle air conditioning system, comprising a heat exchanger block (2) comprising a plurality of mutually parallel heat transfer channels (3), an inlet collection channel (7) and an outlet collection channel (6), inlet collection channel (7) and outlet collection channel (7). 6) parallel to each other and transverse to the heat transfer channels (3), with respect to the longitudinal direction (13) of the heat transfer channels (3) at an upper or lower end (5) of the heat exchanger block (2) are arranged and communicate with each other via the heat transfer channels (3) wherein a flange member (17) is provided having an inlet port (20) communicating with the intake manifold (7) and an outlet port (18) communicating with exhaust manifold (6), the inlet port (20) and outlet port (18) being parallel to the intake manifold (7) and outlet collection channel (6), thereby g ekennzeichnet that the flange (17) directly to a connection element (9; 29) is mounted, which axially limits the inlet collecting channel (7) and the outlet collecting channel (6) with respect to their longitudinal direction (13) at a lateral end (14) of the heat exchanger block (2) and in turn directly to the heat exchanger block (2) and / or on a attached to the heat exchanger block (2), the inlet collecting channel (7) and the outlet collecting channel (6) containing component (25) is mounted, wherein the flange (17) is arranged so that the inlet port (20) the inlet collecting channel (7) and the outlet (18) axially extend the outlet collection channel (6) in the flange member (17). Heat exchanger according to claim 1, characterized in that the heat exchanger (1) is designed as a disk heat exchanger, wherein the inlet collecting channel (7), the outlet collecting channel (6) and the heat exchanger block (2) with its heat transfer channels (3) by in the longitudinal direction (13). of the inlet collecting channel (7) and outlet collecting channel (6) are stacked discs (8, 9, 10) are constructed, and that the closure element by a cover plate (9) is formed which limits the outermost heat transfer channel (3) in the layer direction (13) in the region of the inlet collecting channel (7) has an inlet opening (21) into which the inlet nozzle (20) protrudes, and in the region of the outlet collecting channel (6) has an outlet opening (19) into which the outlet nozzle (18) protrudes. Heat exchanger according to claim 1, characterized in that the heat exchanger (1) is designed as a flat tube heat exchanger, wherein the inlet collecting channel (7) and the outlet collecting channel (6) are formed in a collecting box (25) at the upper or lower end (5). the heat exchanger block (2) is mounted, whose heat transfer channels (3) in heat transfer tubes (26) are formed, and that the closure element is formed by a lid (29) which is attached to the axial end of the collecting tank (25), in the region of the inlet collecting channel (7) has an inlet opening (21) into which the inlet port (20) protrudes, and in the region of the outlet collecting channel (6) has an outlet opening (19) into which the outlet port (18) protrudes. Heat exchanger according to claim 3, characterized in that the inlet opening (21) and the outlet opening (19) are each formed as a cylindrical passage, so that the inlet opening (21) and the outlet opening (19) each have an axially projecting annular collar (30, 31) have, in which the inlet port (20) or the outlet port (18) is inserted. Heat exchanger according to one of claims 1 to 4, characterized in that the flange (17) on a side facing away from the inlet port (20) side has a connection (23) for an expansion valve which communicates with the inlet port (20). Heat exchanger according to claim 5, characterized in that the expansion valve connection (23) is formed coaxially with the inlet pipe (20). Heat exchanger according to one of claims 1 to 6, characterized in that the flange (17) on a side facing away from the inlet pipe (20) and outlet (18) side with the inlet port (20) communicating port (23) for an inlet pipe and / or a connection (22) communicating with the outlet port (18) for an outlet pipe. Heat exchanger according to claim 7, characterized in that the inlet pipe connection (23) is formed coaxially with the inlet connection (20) and / or that the outlet pipe connection (22) is formed coaxially with the outlet connection (18). Heat exchanger according to one of claims 1 to 8, characterized in that the flange element (17) has at least one threaded opening (24) which serves for screwing an expansion valve and / or a pipe arrangement with an inlet pipe and / or an outlet pipe. Heat exchanger according to claim 9, characterized in that the threaded opening (24) runs parallel to the inlet connection (20) and outlet connection (18). Heat exchanger according to one of claims 1 to 10, characterized in that the flange element (17) is formed in one piece or in one piece. Heat exchanger according to one of claims 1 to 11, characterized in that the flange element (17) is produced by milling, extrusion, investment casting or drop forging. Method for producing a heat exchanger (1), in particular an evaporator for a vehicle air conditioning system, at least according to claim 4, comprising the following steps: Attaching the flange (17) on the cover (29), wherein the inlet port (20) and the outlet port (18) in the corresponding passages of the inlet port (21) and the outlet port (19) are inserted Widening of the inlet nozzle (20) in the passage of the inlet opening (21) and the outlet nozzle (18) in the passage of the outlet opening (19), Attaching the lid (28) to the collecting box (25), Soldering of the completed heat exchanger (1).

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