DE202011052186U1 - heat exchangers - Google Patents

Abstract

Heat exchanger, comprising - a plurality of superimposed first flow channels (4) of a cooling medium, - between the first flow channels (4) arranged at their ends with collecting boxes (7, 8) provided second flow channels (5) of a process medium, - wherein the first and second Flow channels (4, 5) in each case by separating plates (2) and this holding at a distance first and second block profiles (3, 6) and between respective block profiles (3, 6) arranged lamellae (9, 10) are formed, - wherein the first Flow channels (4) limiting first block profiles (3) are C-shaped, - extending from a base (31) of the first block profiles (3) has two resilient legs (32) in the direction of the slats (9) and between them in the direction of the slats (9) open recess (33) limit, characterized in that - the base (31) at least one recess (38, 39) for flexible formation of the base (31) of the first Block profiles (3).

Description

The present invention relates to a heat exchanger according to the preamble of claim 1.

A generic heat exchanger is for example from the DE 202 08 748 U1 known. The heat exchanger described therein is used in particular for high-temperature applications, for example in intercoolers or oil coolers of motor vehicles, which are subject to considerable thermal and mechanical loads due to high cyclic temperature differences and cyclically changing flow rates. These cyclic thermal loads and the cyclical pressure loads, in particular internal pressure loads, have an effect, in particular, on the components in the area of the supply of the hot medium, for example in the form of undesired material expansions or compressions of the components of the heat exchanger interconnected by soldering to form a rigid block.

In order to increase the life of such a heat exchanger, it is proposed in the above-mentioned protective document, the block profiles of the heat exchangers, which hold parallel separating plates at a distance, which together with arranged between the plates fins the flow channels of the cooling medium and the flow channels of the process medium to be cooled form, on a side facing away from the lamellae with a central recess with transverse to the flow directions of the hot and cold medium flexible, the solder surfaces having legs, thereby ensuring that one side of the block profile is made flexible and so forces or voltages vertically can absorb to the flow directions.

However, it has been shown that despite the partially flexible designed block profile, in particular by cyclically occurring loads, the life of the heat exchanger block reducing damage can not be sufficiently avoided.

Object of the present invention is to provide a heat exchanger with even increased life and even lower risk of cracks.

This object is achieved by a heat exchanger having the features of claim 1.

According to the invention, the first block profiles delimiting the first flow channels are both C-shaped, formed from a base of the block profiles extending in the direction of the slats, and provided with a flexibly formed base.

The flexible design of the base of the block profiles makes it possible to significantly reduce both the effects of pulsating or cyclic internal pressure loads on the heat exchanger and the effects of cyclic thermal loads.

Thus, in the case of cyclic internal pressure loads, the lamellae arranged between each two of the first block profiles, in particular the flanks of the tensions, preferably designed as turbulators, in the edge region of the front process passages are reduced by up to 40% by the flexible design of the first block profiles compared to the conventional design the block profiles. This increases the life of the heat exchanger block by a factor of 4 to 5.

The stresses caused by cyclic thermal stress on the arranged between each two of the first block profiles slats are reduced by the flexible design of the first block profiles by about 30% compared to the conventional design of the block profiles.

To the same extent, the stresses caused by cyclic thermal stress on the baffles at the edge of the first block profiles due to the thermal expansion in the block width direction by increasing the ratio of bending length for deflecting the baffle in a deformation of the baffle and by reducing the cyclic temperature difference between the flexible first block profile and preferably designed as turbulators lamellae. As a result, the service life of the lamellae, which are preferably designed as turbulators, in the process passages of the heat exchanger block increases by a factor of 3 to 4. The service life of the separator plates thereby increases by a factor of 1.5 to 3, depending on the thermal stresses caused by the thermal expansion in the block length direction ,

Advantageous embodiments of the invention are the subject of the dependent claims.

According to a preferred embodiment variant, the base of the block profiles has recesses running parallel to the running direction of the flow channels of the cooling medium, which recesses are in particular slot-shaped. This increases on the one hand the flexibility of the block profile, the second reduced by the introduction of the recesses and the mass of the block profile, thereby also the absorption capacity of the block profile is reduced. Finally, an enlargement of the heat-transferring surface on the block profile and thus a reduction of the thermal stresses is achieved by the introduction of the recesses.

The ends of the recesses in the interior of the base are widened according to a further embodiment variant, which leads to a further increase in the flexibility of the block profile and also to a further enlargement of the heat-transmitting surface of the block profile.

According to a further preferred embodiment, the recesses are arranged alternately on the side facing away from the lamellae and the side facing the lamellae.

In this case, the sum of the lengths of the alternately arranged recesses is particularly preferably greater than the length of the base of the first block profile, so that viewed in the longitudinal extent of the base, the ends of the recesses located in the interior of the base partially overlap.

Embodiments of the invention will be explained in more detail with reference to the accompanying drawings.

Show it:

1 a schematic perspective view of an embodiment of a heat exchanger with a heat exchanger block and laterally arranged collecting boxes,

2 a perspective view of the heat exchanger block with block profiles arranged therein,

3 an exploded view of a portion of the heat exchanger block 2 .

4 a variant of a turbulator used in the process passages in the block of the heat exchanger,

5 a cross-sectional view transverse to the flow direction of the cooling medium of the heat exchanger with block profiles arranged therein,

6 a sectional view of the heat exchanger 5 transverse to the flow direction of the medium to be cooled,

7 a sectional view of the heat exchanger in a plane parallel to the flow direction of the cooling medium and the process medium,

8th a sectional view of an embodiment variant of a block profile transverse to the flow direction of the cooling medium with one-sided resiliently formed base,

9 a sectional view of a further embodiment of a block profile transverse to the flow direction of the cooling medium with both sides resiliently formed base,

10 to 21 Sectional views of further embodiments of a block profile transverse to the flow direction of the cooling medium,

22 and 23 perspective views of further embodiments of block profiles with recesses transverse to the flow directions.

In the following description of the figures, terms such as above, below, left, right, front, back, etc. refer exclusively to the exemplary representation and position of the heat exchanger, the block profile, the collecting box and the like chosen in the respective figures. These terms are not intended to be limiting, that is to say, by different working positions or the mirror-symmetrical design or the like, these references may change.

In 1 is with the reference numeral 1 a heat exchanger block, the plurality of stacked dividers 2 has, with interposed superimposed first flow channels 4 a cooling medium and between the first flow channels 4 arranged and at their end with collection boxes 7 . 8th provided second flow channels 5 a process medium to be cooled as well as one parallel to the dividing plates 2 arranged upper and lower end plate 14 to surround the heat exchanger block 1 from above and below. The collection boxes 7 . 8th are hood-shaped or box-shaped in a conventional manner and at its end plate 14 facing side provided with a preferably semicircular recess formed by a correspondingly shaped end wall 13 is closable, with the end wall 13 through welds 12 with the end plate 14 and the housing of the temporary collecting tank 7 . 8th connected is. The side walls 73 (shown in the 1 and 6 ) of the collection boxes 7 . 8th are over welds 15 with the end faces of the heat exchanger block 1 through which the medium to be cooled enters and exits.

Due to the dimensions of the rectangular shaped dividers 2 becomes the length L and the depth T of the heat exchanger block 1 certainly.

As in the 1 to 3 can be seen, are the flow channels 4 of the coolant in a flow direction Y through between the dividing plates 2 arranged slats 9 formed, with the flow channels 4 parallel to the end faces of the heat exchanger block 1 run where the collecting boxes 7 . 8th are arranged.

Between the collection boxes 7 . 8th and the slats 9 are first block profiles 3 between the dividers 2 arranged at the front ends thereof to the heat exchanger block 1 in the inlet area of the hot, to be cooled process medium and the associated thermal and mechanical loads suitable equip.

The flow channels 5 of the medium to be cooled are also by between each two dividing plates 2 arranged slats 10 with at the side edges of the flow channels 5 final second block profiles 6 formed, wherein the second block profiles 6 , such as in 3 can be seen in the area of the contact surfaces with the dividing plates 2 and the outwardly facing surface are formed substantially rectangular, while the lamellae 10 facing side preferably as to the slats 10 towards tapered triangle is formed.

The flow channels 5 of the medium to be cooled forming lamellae 10 are, as in 4 is shown, preferably as turbulators with cams 101 and a cam pitch t (T) and flanks 102 formed with a material thickness s (T) to ensure sufficient under large thermal and mechanical cycling loads strength, the turbulators essentially serve the hot medium in the flow channels 5 to swirl. Accordingly, the second block profiles 6 also be referred to as Turbulatorprofile.

Both the components of the heat exchanger block 1 , as well as the dividers 2 , the slats 9 and 10 as well as the first and second block profiles 3 and 6 are preferably made of aluminum and are joined together by soldering to form a rigid block. Other heat exchanger agents such as copper, copper alloys, steel are also conceivable.

To reduce the effects of cyclic internal pressure loads on the heat exchanger as well as the effects of cyclic thermal loads are the first block profiles 3 resilient. For this is such a block profile 3 on the one hand, as known from the prior art, on one of the lamellae 9 facing end C-shaped, such as in 8th is shown to cyclically occurring loads by compression of the c-shaped leg forming legs 32 to be able to compensate.

According to the invention, one of the lamellae 9 facing away, the inflow region of the medium to be cooled side facing, which in the following as the basis 31 the first block profiles 3 is designated, also resilient.

As in the 5 . 7 and 8th shown, shows the entire block profile 3 in the direction of the longitudinal axis L of the block profile has a length a, which is divided into a length b of the base and a length c of the base 31 resilient leg 32 , which are in the direction of the lamella 9 extend and between them open in the direction of the slats recess 33 limit. Through the between the thigh 32 existing recess 33 with a passage 34 between the thighs 32 a width e can be a perpendicular to the dividing plates 2 acting force due to the entry of the hot medium from the first block profile 3 be balanced without affecting the connection between the the dividing plates 2 facing top or bottom of the block profiles 3 and the dividing plates 2 solves.

To those from the base 31 of the first block profile 3 on the second lamellae, preferably designed as turbulators 10 and the dividers 2 applied force due to the cyclic heating and cooling by entry of the medium to be cooled in the front header 7 and into the second flow channels 5 or to keep as low as possible due to the cyclic internal pressure, is also the basis 31 the block profiles on a the the flow channels 4 the cooling medium forming lamellae 9 opposite side formed resilient.

The resilient training is carried out in particular by parallel to the flow direction X of the flow channels 4 the cooling medium extending recesses 38 through which the base 31 of the first block profile on the lamellae 9 opposite side in outer webs 36 and at least one inner bridge 37 is divided. These recesses 38 are preferably formed as slots with a slot depth m, wherein the slot depth m in relation to the width b of the base 31 in a ratio of 0.4 ≤ m / b ≤ 0.9.

In addition, the slot depth m is preferably at least 1 mm smaller than the seam thickness of the weld designated as a dimension (height of the triangle which can be used in any desired seam shape) 15 over which the collecting boxes 7 . 8th at the inlet and outlet side of the process medium with the end faces of the heat exchanger block 1 are connected.

The width h1 of these slot-shaped recesses 38 stands preferably to the total width h of the first block profile 3 in a ratio of: 0.1 ≦ h1 / h ≦ 0.3.

The recesses 33 between the thighs 32 of the first block profile 3 is preferably formed circular with a diameter d. To the slats 9 towards the circular recess opens 33 to an opening gap 34 with a width e.

One opposite the in 8th shown embodiment of the first block profile 3 alternative variant with even more flexibility is in 9 shown (about 90% flexibility in the longitudinal extent of the block profile according to 8th compared to 100% flexibility in the longitudinal extension of the block profile according to 9 ). The block profile shown here 3 is characterized by the fact that in addition to the recesses 38 from the lamellae 9 opposite side also recesses 38 from the lamellae 9 facing side of the base 31 are provided her. The of the lamellae 9 facing side into the base 31 penetrating recess 38 preferably starts centrally in the recess 33 between the thighs 32 and is essentially the same as that of the lamellae 9 opposite side starting recesses 38 shaped.

At the in 9 the embodiment shown has the of the lamellae 9 facing side into the base 31 penetrating recess 38 a length n, which preferably corresponds to the equation n = m * (0.1-0.9) + (b-m). The width h2 of this recess 38 preferably corresponds to a ratio of 0.1 ≦ h2 / h ≦ 0.3.

In the following, further embodiments of the first block profile 3 based on 10 to 23 described, wherein the configuration of the legs 32 and the recesses provided between the legs 33 and the opening gap 34 is essentially maintained.

In the design variants of the first block profile according to the 10 . 11 . 13 . 18 to 20 and 22 are differently shaped recesses 38 from the lamellae 10 opposite side in the base 31 let in the block profile. Unlike the in 8th in the embodiment shown in the three in the direction of the depth B of the heat exchanger block 1 mutually arranged recesses 38 that of the slats 9 turned away side into the base 31 in the direction of the longitudinal extent L of the heat exchanger block 1 in the base 31 of the first block profile 3 protrude parallel and straight, are in the embodiment according to 10 the ends of the recesses 38 inside the base 31 expanded and in particular as circular expansions 381 educated. The diameter d1 of these circular extensions 381 is preferably 1.5 to 3 times the width h1 of the slot-shaped recesses 38 , The design of the in 11 shown block profiles 3 differs from that of the in 10 shown block profiles in that in the block profile 3 of the 11 only two instead of three recesses 38 are provided and that the center of the circular widenings 381 at the in 10 variant shown on an imaginary center line of the recess 38 is located while the circular widening 381 of the 11 positioned so that one of the by an outer bar 36 formed inside of the recesses 38 tangential in the circular expansion 381 passes.

At the in 13 shown embodiment with again three mutually positioned recesses 38 are circular extensions 381 with a diameter d1 are the recesses 38 to the collection box 7 . 8th conically widened, with the smallest width of the recesses 38 measured with h1. The width h3 at the outer edge of the base 31 The block profile is preferably dimensioned such that 1 ≦ h3 / h1 ≦ 3.

The length of all of the lamellae 9 away from the base 31 the block profiles 3 extending into recesses 38 preferably always corresponds to the above-mentioned length m.

At the in 18 shown embodiment of the first block profile 3 and the recesses 38 according to the in 8th formed embodiment shown. In addition, at the top and bottom, the dividers 2 facing sides of the block profile 3 wells 361 with a length t in the direction of the longitudinal extent L of the heat exchanger block 1 Mistake.

The length t of the depressions 361 in the direction of the longitudinal extent L of the heat exchanger block 1 preferably corresponds to the difference from the length b of the base 31 of the first block profile 3 and the length m of the recesses 38 multiplied by a factor of 1.1 to 3.

The depression 361 is preferably formed as a circle-shaped depression whose radius of curvature R preferably corresponds to the equation R = 0.5 + (0.15 - 1.15) · (b - m) ² .

At the in 19 shown embodiment variant are also in extension of the recesses 38 in the base 31 additional recesses 39 , here in the form of holes with a Diameter d3 provided even in the area of the base 31 of the first block profile 3 near the neck of the thighs 32 an impression of the block profile 3 in the direction of the width B of the heat exchanger block 1 to facilitate. The diameter d3 preferably corresponds to 1.5 to 5 times the inner height h1 of the substantially slot-shaped recesses 38 ,

At the in 20 shown embodiment of the first block profile 3 are two recesses from the side facing away from the lamellae 38 provided by two outer bars 36 and an inner walkway 37 are limited, with the recesses 38 yourself in the base 31 taper in, with a narrowest point h1 and a widest point h3 at the entrance of the recess 38 , In addition, between the two recesses 38 another recess 39 , which are considered to be through the entire depth T of the block profile 3 towards extending slot is formed. The length of the oblong hole k preferably corresponds to 0.4 to 0.6 times the length b of the base 31 of the first block profile 3 ,

At the in 22 shown embodiment of the first block profile 3 are additional recesses 38a in the base 31 of the block profile 3 introduced, which in turn are formed slit-shaped with a length s1, wherein the length s1 of these slot-shaped recesses 38 preferably about 0.6 to 0.8 times the length b of the base 31 of the block profile 3 equivalent. The width r1 of these recesses 38 preferably corresponds to a ratio of 0.01 ≦ r1 / T ≦ 0.03. These recesses 38a are in the direction of the depth T of the heat exchanger block 1 considered about every 20th to three tenths of the depth T of the heat exchanger block provided.

As 22 can be further seen, are several such slot-shaped recesses 38a provided, wherein the distance p1 between the individual recesses 38a in the direction of the depth T of the heat exchanger block 1 preferably 0.05 to 0.3 times the depth T of the heat exchanger block corresponds.

The 12 . 14 to 17 . 21 and 23 show further embodiments of the principle in 9 shown first block profile 3 , wherein these variants in common is that in addition to the recesses 38 from the lamellae 9 opposite side also recesses 38 from the lamellae 9 facing side of the base 31 are provided her.

In the embodiments according to 12 and 14 in which the of the slats 9 facing side into the base 31 recessed recess 38 with a circular widening 381 is provided, the diameter d2 corresponds to this circular expansion 381 preferably about 1.5 to 5 times the width h2 of the slot-shaped recesses 38 ,

At the in 15 shown embodiment of the first block profile 3 are the recesses 38 widening conically from outside to inside, wherein the end of the recesses 38 is formed semicircular. The narrowest part of the lamellae 9 away from the base 31 let recesses is preferably h1, at the opposite side of the base 31 recessed recess 38 the narrowest point is preferably h2. The diameter of the first-mentioned recesses is preferably d1, the recesses currently mentioned preferably d2.

In a further alternative embodiment of the first block profile 3 are the recesses 38 formed in the direction of its longitudinal extent m double conical, wherein the narrowest point has a width h1 and approximately centrally in the direction of the longitudinal extent m of the recesses 38 is provided. Accordingly, the recess 38 from the recess 33 between the thighs 32 formed starting, wherein the smallest width of this recess 38 in the direction of the longitudinal extension n is preferably h2 and the widest point at the entrance is h4, wherein the width h4 preferably corresponds to the equation 1 ≦ h4 / h2 ≦ 3 with a smallest width h2 which corresponds to the equation 0.1 ≦ h2 / h ≦ 0 , 3 corresponds.

Finally, in the embodiment according to 23 additionally slot-shaped recesses 38b in the block profile 3 from the lamellae 9 facing side introduced, which in the alignment of the recesses 38a according to 22 correspond. The slot-shaped recesses 38b extend here through the thighs 32 , The length s2 of these slot-shaped recesses 38b preferably corresponds to 1.2 to 1.8 times the length b of the base 31 of the first block profile 3 , The width r2 of these slot-shaped recesses 38b preferably corresponds to the equation 0.01 ≤ r2 / T ≤ 0.03.

As 23 can be further seen, are several such slot-shaped recesses 38b provided, wherein the distance p2 between the individual recesses 38b in the direction of the depth T of the heat exchanger block 1 preferably 0.05 to 0.3 times the depth T of the heat exchanger block corresponds.

To further relieve the dividing plates and the turbulators, it is also conceivable, the first and / or second block profiles 3 . 6 made of a springy material.

All of the abovementioned dimensions of the lengths, depths, widths or diameters of the recesses, depressions, etc. of the first block profiles are preferably selected according to the above-mentioned equations in order to increase the flexibility or enlargement of the heat-transferring surface by the possibilities described above by way of example first block profiles on the dividers and the second fins 10 to achieve a significant reduction in stress, in particular on the cyclically loaded components within the heat exchanger.

LIST OF REFERENCE NUMBERS

1

heat exchanger coil

2

plate

3

first block profile

31

Base

32

leg

33

recess

34

opening gap

35

palm

36

web

361

deepening

37

web

38

recess

38a

recess

38b

recess

381

expansion

39

recess

4

Flow channels cooling medium

5

Flow channels Process medium

6

second block profile

7

collection box

71

plenum

72

Headboard of the box profile

73

Side wall

8th

collection box

9

lamella

10

Lamella / turbulator

101

cam

102

flank

11

inlet connection

12

Weld

13

bulkhead

14

end plate

15

Weld

L

Length of the heat exchanger block

B

Width of the heat exchanger block

T

Depth of the heat exchanger block

X

Flow direction of the medium to be cooled

Y

Flow direction of the cooling medium

a

Length of the block profile

b

Length of the base of the block profile

c

Length of the legs of the block profile

d

Diameter of the recess

d1

Diameter of the extension

d2

Diameter of the extension

d3

Diameter of the recess

d4

Width of the recess

e

Width of the opening gap

h1

Width of the recess

h2

Width of the recess

h3

maximum width of the recess

h4

maximum width of the recess

k

Length of the recess

m

Length of the recess

n

Length of the recess

p1

Distance between two recesses

p2

Distance between two recesses

r1

Width of the recess

r2

Width of the recess

s1

Length of the recess

s2

Length of the recess

t

Length of the recess

s (T)

Material thickness of the turbulator

t (T)

Cam pitch of the turbulator

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

• DE 20208748 U1 [0002]

Claims (14)

Heat exchanger, comprising - a plurality of first flow channels arranged one above the other ( 4 ) of a cooling medium, - between the first flow channels ( 4 ), at their ends with collecting boxes ( 7 . 8th ) provided second flow channels ( 5 ) of a process medium, - wherein the first and second flow channels ( 4 . 5 ) in each case by separating plates ( 2 ) and these spaced first and second block profiles ( 3 . 6 ) and between respective block profiles ( 3 . 6 ) arranged lamellae ( 9 . 10 ) are formed, - wherein the first flow channels ( 4 ) limiting first block profiles ( 3 ) Are C-shaped, - being different from a base ( 31 ) of the first block profiles ( 3 ) two resilient legs ( 32 ) in the direction of the slats ( 9 ) and between them in the direction of the slats ( 9 ) open recess ( 33 ), characterized in that - the base ( 31 ) at least one recess ( 38 . 39 ) for the flexible training of the base ( 31 ) of the first block profiles ( 3 ) having. Heat exchanger ( 1 ) according to claim 1, characterized in that the base ( 31 ) of block profiles ( 3 ) on one of the slats ( 10 ) facing away from side is flexible. Heat exchanger ( 1 ) according to claim 1 or 2, characterized in that the base ( 31 ) of block profiles ( 3 ) on one of the slats ( 10 ) facing side is flexible. Heat exchanger ( 1 ) according to one of the preceding claims, characterized in that the base ( 31 ) of block profiles ( 3 ) parallel to the flow direction (X) of the flow channels ( 4 ) of the cooling medium extending recesses ( 38 ) having. Heat exchanger ( 1 ) according to claim 4, characterized in that the recesses ( 38 ) are slot-shaped. Heat exchanger ( 1 ) according to claim 5, characterized in that the ends of the recesses ( 38 ) inside the base ( 31 ) are widened. Heat exchanger ( 1 ) according to claim 6, characterized in that the ends of the recesses ( 38 ) are widened circular in cross-section. Heat exchanger ( 1 ) according to one of the preceding claims 5 to 7, characterized in that the slot-shaped region of the recesses ( 38 ) facing walls of Stegen ( 36 . 37 ) of the base parallel to each other. Heat exchanger ( 1 ) according to one of the preceding claims 5 to 7, characterized in that the slot-shaped region of the recesses ( 38 ) facing walls of Stegen ( 36 . 37 ) of the base taper conically. Heat exchanger ( 1 ) according to one of the preceding claims 5 to 9, characterized in that the recesses ( 38 ) alternately on the lamellae ( 10 ) and the side facing away from the lamella ( 10 ) facing side are arranged. Heat exchanger ( 1 ) according to claim 10, characterized in that the sum of the length (m, n) of the alternately arranged recesses ( 38 ) is greater than the length (b) of the base ( 31 ) of the first block profile ( 3 ). Heat exchanger ( 1 ) according to one of the preceding claims, characterized in that the first block profile ( 3 ) consists of a resilient material. Heat exchanger ( 1 ) according to one of the preceding claims, characterized in that the ratio of length (m) of the recesses ( 38 ) to the length (b) of the base ( 31 ) of the first block profile ( 3 ) is between 0.4 and 0.9. Heat exchanger ( 1 ) according to one of the preceding claims, characterized in that the ratio of the narrowest width (h1, h2) of the recesses ( 38 ) to the width (h) of the base ( 31 ) of the first block profile ( 3 ) is between 0.1 and 0.3.

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