Collector plate for a motor vehicle heat exchanger

Abstract

A collector plate for a motor vehicle heat exchanger may include a first receiving zone for tubes of a first tube bundle of a heat exchanger. The collector plate may include a second receiving zone for tubes of a second tube bundle of a heat exchanger and a groove extending between the first and second receiving zones. The collector plate may be thinner in a region of the groove. Further, the collector plate may have a channel reducing the thickness of the collector plate from a first face of the collector plate and opposing a second face of the collector plate including the groove.

Claims

1. A collector plate for a motor vehicle heat exchanger, comprising: a first receiving zone for tubes of a first tube bundle of the heat exchanger; a second receiving zone for tubes of a second tube bundle of the heat exchanger; and a groove extending between the first and second receiving zones, the collector plate being thinner in a region of the groove, wherein the collector plate comprises a channel reducing a thickness of the collector plate from a first face of the collector plate, opposing a second face of the collector plate comprising the groove, and wherein the channel is a circular indentation on the first face of the collector plate.

2. The collector plate as claimed in claim 1, wherein the thinning in the region of the groove corresponds to a minimum thickness of the collector plate in the region of the groove, which is greater than 50% and/or less than 75% of a maximum thickness of the collector plate in the region of the groove.

3. The collector plate as claimed in claim 1, wherein the groove is defined by a fold of the collector plate.

4. The collector plate as claimed in claim 3, wherein the fold has a U-shaped cross section.

5. The collector plate as claimed in claim 4, wherein the thinning of the collector plate is located in a region of one or more angles of the U-shaped cross section of the fold.

6. The collector plate as claimed in claim 1, wherein on the second face of the collector plate the groove is configured to be oriented toward a cover forming with the collector plate at least one water chamber.

7. The collector plate as claimed in claim 1, of substantially rectangular shape, with rounded corners, wherein the collector plate comprises a rectangular shape with rounded corners, and wherein the groove extends in a longitudinal direction of the collector plate.

8. The collector plate as claimed in claim 1, wherein the first and/or the second receiving zones for tubes comprise a plurality of slots which are preferably parallel to one another, each slot out of the plurality of slots is configured to be traversed by the end of one respective tube.

9. The collector plate as claimed in claim 8, wherein said each slot out of the plurality of slots is at a top of a respective projection of the collector plate, wherein the respective projection is of an oblong shape, a length of the oblong shape being further preferably substantially perpendicular to the groove, and wherein the respective projections protrude from the second face of the collector plate with the groove.

10. The collector plate as claimed in claim 1, forming a recess about the first and second receiving zones, the groove leading into the recess on either side.

11. A heat exchange device for a motor vehicle comprising a radiator for cooling the engine of the motor vehicle, with two methodical passes, comprising: a first and a second tube bundle; a first collector plate and a second collector plate; at least one first single cover fixed to the first collector plate and forming a water inlet and a water outlet; and a second cover fixed to the second collector plate and forming a guide for the water between the first tube bundle and the second tube bundle, the first collector plate comprising: a first receiving zone for tubes of a first tube bundle of a heat exchanger, a second receiving zone for tubes of a second tube bundle of the heat exchanger, and a groove extending between the first and second receiving zones, wherein the first collector plate being thinner in a region of the groove, wherein the collector plate comprises a channel reducing a thickness of the collector plate from a first face of the collector plate, opposing a second face of the collector plate comprising the groove, and wherein the channel is a circular indentation on the first face of the collector plate.

12. The heat exchange device as claimed in claim 11, further comprising a first seal ring which is received in the groove of the first collector plate arranged between the first collector plate and a wall of the first cover, to separate a distribution space, which places the water inlet and the first tube bundle in fluidic communication, from a collection space, which places the water outlet and the second tube bundle in fluidic communication, the seal ring being of U-shaped cross section.

13. The heat exchange device as claimed in claim 11, wherein the first collection plate forms a recess about the first and second receiving zones, the groove leading into the recess on either side, the recess receiving a single second seal ring clamped between the first collector plate and a wall of the first cover, the seal ring being of U-shaped cross section.

14. The heat exchange device as claimed in claim 13, wherein the second seal ring has a shape of a figure of an eight with a central arm, the central arm forming the first seal ring which is received in the groove of the first collector plate.

15. A collector plate for a motor vehicle heat exchanger, comprising: a first receiving zone for tubes of a first tube bundle of the heat exchanger; a second receiving zone for tubes of a second tube bundle of the heat exchanger; and a groove extending between the first and second receiving zones, wherein the collector plate thinning in a region of the groove, thereby forming a deformation notch in the region of the groove, enabling adaptation of the collector plate to different expansions of the tubes of the first and second bundles, wherein the thinning facilitates relative pivoting of the first and second receiving zones about the thinning, wherein the collector plate comprises a channel reducing a thickness of the collector plate from a first face of the collector plate, opposing a second face of the collector plate comprising the groove, and wherein the channel is a circular indentation on the first face of the collector plate.

Description

(1) The invention will be understood more clearly by reading the following non-limiting description which is provided by way of illustration with reference to the accompanying drawings, in which:

(2) FIGS. 1 and 2 show a heat exchanger for a motor vehicle respectively in perspective and in front view;

(3) FIGS. 3 and 4 illustrate a collector plate of the heat exchanger of FIG. 1 respectively in perspective and in section along the line IV-IV;

(4) FIG. 5 illustrates a detail of FIG. 4;

(5) FIG. 6 illustrates a variant of the detail of FIG. 5; and

(6) FIGS. 7 and 8 show respectively in a cut-away perspective and an exploded view a detail of the assembly of the heat exchanger of FIG. 1.

(7) In the remainder of the description, elements which are identical or of identical function bear the same reference numeral. For the purpose of a concise description, only the differences between the embodiments shown are described.

(8) FIGS. 1 and 2 illustrate an embodiment of a heat exchanger 10 (or thermal exchanger). In this particular case, it is a heat exchanger with two methodical passes for cooling the gearbox and the engine of a motor vehicle. Such an exchanger may, for example, cool the water which traverses therethrough, by means of an airflow F created by the speed of displacement of the motor vehicle.

(9) The heat exchanger 10 essentially comprises two bundles of tubes 12 (only one thereof being visible in FIGS. 1 and 2) extending in two parallel planes which are offset relative to one another in a direction perpendicular to the planes. The bundles of tubes are assembled between two collector plates 14, 16 receiving the ends of the tubes 12 and two lateral cheeks 18, 20. The collector plates 14, 16 are of generally rectangular shape, in this particular case with rounded corners. The collector plates 14, 16 may be made of metal, in particular aluminum.

(10) A first cover 22 is fixed to the collector plate 14 located at a first longitudinal end of the heat exchanger 10, the assembly thus formed sometimes being called a water chamber. The first cover 22 forms a water inlet 24 and a water outlet 26 of the heat exchanger 10. The first cover 22 also forms with the collector plate 14 two spaces: a first so-called distribution space places the water inlet 24 in fluidic communication with a first tube bundle, in this particular case the tube bundle which is not visible in the figure, designed to be placed downstream relative to the direction of the propagation of the cooling airflow F; a second so-called collection space places the water outlet 26 in fluidic communication with the second tube bundle.

(11) A second cover 28 is fixed to the collector plate 16 located at the second end of the heat exchanger 10 opposing the first end. This second cover 28 defines with the collector plate 16 a hollow space which places the first and second bundles of tubes 12 in fluidic communication.

(12) The operation of this heat exchanger 10 may be summarized as follows: the hot water enters the heat exchange device 10 via the water inlet 24; the hot water traverses the distribution space formed by the first cover 22 and the collector plate 14 toward the first tube bundle 12 located downstream relative to the second tube bundle 12 in the direction of the flow of air F, this first tube bundle 12 thus being in contact with the air previously heated by the contact with the second tube bundle 12; at the end of the heat exchanger 10 opposing the water inlet 24, the water makes a half turn guided by the cover 28 which conducts the water toward the second tube bundle 12; the water then traverses this second tube bundle 12 until it reaches the collection space formed by the first cover 22 and the collector plate 14, which conducts the cooled water to the water outlet 26.

(13) Thus the first tube bundle 12 is traversed by fluid which is generally hotter than the fluid traversing the second tube bundle 12. As a result, the tubes of the first tube bundle expand to a greater extent than the tubes of the second tube bundle. Since these two bundles of tubes 12 are fixed to the two collector plates 14, 16, in particular by brazing, the different expansions of the tubes produce forces on the collector plates in a direction substantially parallel to the direction of extension of the tubes, and thus substantially perpendicular to the planes of the collector plates 14, 16.

(14) However, as described below, the collector plate 14 is designed in this case to limit the effects of these expansions, in particular in order to avoid the risks of the appearance of cracks or other more significant damage which could impair the seal of the collector plates 14, 16, making the heat exchange device 10 ineffective or, at the very least, less efficient.

(15) Thus as illustrated in FIG. 3, which shows a face 14a of the collector plate—hereinafter the internal face 14a—designed to be oriented toward the first cover 22 and opposite the face 14b referenced in FIG. 4 ˜hereinafter the external face, the collector plate 14 comprises two zones 30, 32 for receiving tubes of the first and second bundles 12 of tubes. In this case, these zones are symmetrical relative to a longitudinal median plane of the plate 14. Each receiving zone 30, 32 is formed from substantially half of the collector plate 14. Each receiving zone for the tubes 30, 32 comprises, for example, the same number of slots 34 for receiving tubes of the tube bundle 12, the slots 34 being traversed by the end of the tubes so that these lead respectively into the distribution space or into the collection space defined with the first cover 22. In order to ensure the seal of this assembly, the tubes may be brazed to the collector plate 14, in particular in the region of these slots 34. Moreover, the slots 34 are produced in this case at the top of reliefs or projections 36 relative to the internal face 14a of the collector plate 14. The projections may be of oblong shape as illustrated in FIG. 3 in order to make them more rigid and/or to adapt them to the shape of the tubes, the ends thereof being received by said projections. Preferably, in order to optimize the number of slots 34 the principal direction of the oblong shape of the projections 36 thus corresponds substantially to the width of the collector plate 14.

(16) The two receiving zones 30, 32 are separated by a groove 38 in the internal face 14a. The groove 38 is designed to receive a seal ring, providing the seal between the distribution space and the collection space.

(17) The groove 38 extends in this case in a straight line corresponding to a longitudinal direction of the collector plate 14. This shape of the groove 38 is particularly suitable for receiving a seal providing the seal between the collector plate 14 and the first cover 22, the geometry of said seal preferably being simple in order to ensure its efficiency.

(18) In this case, the groove 38 is formed by a fold 40 of the collector plate 14. This embodiment is particularly advantageous since the fold 40 may be produced during the same stamping step as that for forming the slots 34 and/or the projections 36.

(19) The fold 40 in this case has a U-shaped cross section. This shape of the fold 40 provides a greater flexibility thereto. More specifically and as visible in FIG. 5, in particular, the fold 40 comprises two cheeks 42, 44 about a web 46 defining the base of the groove 38. The cheeks 42, 44 form with the web an angle of between, for example, 70° and 130°. The angle between the cheeks and the web may, in particular, be defined as being the maximum angle between the tangents to the face 14a of the collector plate 14 in the region of the cheeks 42, 44 and a plane parallel to the plane of extension of the collector plate 14.

(20) As is more particularly visible in FIG. 5, the collector plate 14 has a thinning in the region of the groove 38. More specifically, in this case the thickness of the collector plate 14 is at a minimum e.sub.min at least locally in the region of the groove 38. This thinning may be produced substantially in the region of one or more angles of U-shaped cross section of the fold 40, i.e. in the region of the corners 48 at the junction between the cheeks 42, 44 and the web 46 of the fold 40. The thickness e.sub.min, of the plate 14 may be between 50% and 75% of the maximum thickness e.sub.max of the plate 14 in the region of the fold 40. In particular, the thickness e.sub.min of the plate 14 may be greater than 0.8 mm and/or less than 1.2 mm. The maximum thickness e.sub.max of the plate 14 in the region of the fold 40 may be greater than 1 mm and/or less than 2 mm, in particular substantially equal to 1.5 mm. In this case, this maximum thickness e.sub.max is that of the plate 14 at the ends of the cheeks 42, 44 of the fold 40 which are not joined to the web 46. The thickness e.sub.max may be equal to the thickness of the plate 14 in the region of the receiving zones 30, 32, in particular in the vicinity of the groove 38.

(21) FIG. 6 illustrates a variant in which the collector plate 14 has on its external face 14b a deformation or channel 50 forming a more significant thinning. The channel 50 is produced in the region of the groove 38. The channel 50 extends, in particular, parallel to the groove 38. The channel 50 may in turn permit a thinning of the collector plate 14 to be created in the region of the fold 40. Alternatively, however, this channel 50 is produced in addition to a thinning as described relative to FIG. 5. Particularly advantageously, the channel 50 and/or any thinning of the plate 14 in the region of the groove 38 is produced closer to the receiving zone which receives the tubes of the first tube bundle, i.e. the tubes traversed by the hotter fluid, than the receiving zone which receives the tubes of the second tube bundle, i.e. the tubes traversed by the colder fluid. In particular, when the groove is produced in the form of a fold 40 the thinning and/or groove 50 are not produced at the top of the fold 40 but are offset relative to this top, in the direction of the receiving zone of the tubes traversed by the hotter fluid. This makes it possible to facilitate the deformation of the collector plate 14 in the region of the groove 38 by rotation about the thinning.

(22) FIGS. 7 and 8 illustrate in more detail the assembly of the first cover 22 on the first collector plate 14. A seal ring 52 is received in the groove 38. The seal ring 52 has a U-shaped cross section in order to be received in the groove 38 and to receive a wall 54 of the first cover 22. The wall 54 makes it possible to separate the distribution space which is in fluidic communication with the water inlet 24, on the one hand, and the first tube bundle, on the other hand, and the collection space which is in fluidic communication with the water outlet 26, on the one hand, and the second tube bundle on the other hand.

(23) As is more particularly visible in FIG. 8, the seal 54 is advantageously the central arm of a seal 56 in the shape of a figure of eight. The seal 56 may be of U-shaped cross section in order to receive the walls of the first cover 22 and thus provide the seal of these covers. The part of the seal 56 not received in the groove 38 is received in a recess 58 produced in the internal face 14a of the collector plate 14 and surrounding the first and second receiving zones 30, 32.

(24) The invention is not simply limited to the embodiments described but has the possibility of numerous variants which are accessible to the person skilled in the art.

(25) In particular, in the embodiment described, a single first cover forms the water inlet and water outlet of the heat exchange device. As a variant, however, the water inlet and water outlet are formed by separate covers.