FR3093355A1 - PLATE HEAT EXCHANGER - Google Patents

Abstract

Title of the invention: PLATE HEAT EXCHANGER The invention relates to a plate heat exchanger (1) for a vehicle comprising a heating body (2) and at least one collector (3), the heating body (2) comprising a plurality of plates (7, 8, 9), each plate having an outer perimeter (18) which delimits a heat exchange zone (17), characterized in that the collector (3) is arranged outside of the heat exchange zone (17) and in that the plates (7, 8, 9) are nested in each other. Application to motor vehicles.

Description

PLATE HEAT EXCHANGER

The field of the present invention is that of heat treatment systems for electric vehicles, in particular plate heat exchangers intended for the heat treatment of an element of the electric traction chain.

Electric motor vehicles are equipped with heat treatment systems used to cool different areas or components of the vehicle. It is in particular known to use heat transfer fluids and refrigerant fluids to cool the elements of an electric powertrain of the vehicle. The elements of the electric traction chain referred to are an electric motor capable of setting the vehicle in motion, an electrical storage device used to supply energy to the electric motor or even an electronic unit participating in the control of the elements of the electric traction chain .

Plate heat exchangers make it possible to heat treat, with the coolant fluid, the heat transfer liquid used for the heat treatment of the electrical storage device. These plate heat exchangers include a heating body consisting of a stack of plates forming tubes. A part of the tubes is dedicated to the circulation of the refrigerant fluid and another part of the tubes is dedicated to the circulation of the heat transfer liquid. It is within the heating body that heat exchanges take place.

When it is necessary to cool the electrical storage device, in particular during a charging phase, the plate heat exchanger functions as an evaporator. The plate heat exchanger works so that the coolant cools the heat transfer liquid, which is itself intended to cool the electrical storage device.

It is necessary to form inside the plate heat exchanger two separate circuits allowing a flow of the refrigerant on the one hand and the heat transfer liquid on the other. There are known plate exchangers configured so that the tubes dedicated to the refrigerant fluid communicate with each other in order to ensure the supply of refrigerant fluid in the heating body. The same is true for the tubes dedicated to the heat transfer liquid supplying the heat transfer liquid to the heating body. Such tubes are each formed by two metal sheets provided with at least one opening and stamped, the metal sheets being brazed one against the other in order to delimit said tubes so as to constitute the flow circuits of the heat transfer liquid or refrigerant fluid. In the known configurations, the tubes are welded over the entire periphery of the plates, the openings provided in the plates being welded on one or the other face of the tubes. Thus, the openings are located at the level of the zone where the heat exchanges of the coolant fluid/coolant fluid take place. This decreases the efficiency of heat transfer, as well as the distribution of the considered fluid around the opening.

The present invention aims to respond to these problems by proposing a particular arrangement of the plates with respect to at least one of the flow circuits traversing the plate heat exchanger.

The subject of the invention is therefore a plate heat exchanger for a vehicle comprising a heating body and at least one manifold, the heating body comprising a plurality of plates, each plate having an outer perimeter which delimits a heat exchange zone. heat, characterized in that the collector is arranged outside the heat exchange zone and in that the plates are nested one inside the other. The collector is external to the heat exchange zone. The collector and the heat zone occupy separate positions in the heat exchanger, which increases the amount of heat transferred at the heat exchange zone. The heating body is thus configured so that the distribution of the circulating fluid is homogeneous. The flow of said fluid is also homogenized within the heating body, thereby reducing pressure drops.

The collector is arranged outside the heat exchange zone in the sense that the collector is peripheral to the heat exchange zone. The heating body and the collector can thus be manufactured independently, before being assembled and then joined together during the brazing of the parts of the plate heat exchanger. Specific features can thus be made, for example, to the collector, without impacting the manufacture of the plate, and vice versa.

In the heating body, the plates are stacked so as to fit together. Their interlocking involves brazing the plates together.

According to one aspect of the invention, the heat exchange zone extends along a main plane, the outer perimeter of at least one plate comprising a first longitudinal edge and a second longitudinal edge opposite the first longitudinal edge, the first longitudinal edge and the second longitudinal edge being folded so as to each extend mainly in a plane secant to the main plane, the first longitudinal edge and the second longitudinal edge thus each defining an overlapping zone of at least one other plate. The plate includes the first longitudinal edge and the second longitudinal edge, folded. The plate is brazed on its outer perimeter at least at the level of the first longitudinal edge and the second longitudinal edge. The nesting zone is a region of contact between the plate having its first longitudinal edge and its second longitudinal edge bent, and another plate. The two plates are brazed at the level of the nesting zone. The nested plates are thus secured .

The main plane of the heat exchange zone corresponds to the plane in which the exchange zone extends its largest dimension. The first longitudinal edge and the second longitudinal edge extend in the greatest dimension of the plate. The first longitudinal edge and the second longitudinal edge extend in a direction mostly parallel to a longitudinal extension axis of the plate, included in the main plane and oriented in the largest dimension of the plate.

The first longitudinal edge and the second longitudinal edge are folded during the manufacture of the plates. Advantageously, a metal sheet is cut to the desired dimensions before being bent to form the first longitudinal edge and the second longitudinal edge. The plates thus folded are stacked so as to nest at the level of the nesting zone.

According to one aspect of the invention, the first longitudinal edge and the second longitudinal edge are both folded in the same direction. The plate is then profiled with a base corresponding to the heat exchange zone. The first longitudinal edge and the second longitudinal edge are advantageously bent so as to widen relative to the heat exchange zone, so as to promote the nesting of the nesting zone of the plate with the other plate .

According to one aspect of the invention, the plates of the plurality of plates all extend their first longitudinal edge and their second longitudinal edge in the same direction. The plates fit into each other. The interlocking areas overlap each other with the longitudinal edges of each plate interlocking one after the other.

Advantageously, the first longitudinal edge and the second longitudinal edge of each plate is bent according to the orientation of the heating body, according to a stacking direction of the plates. For example, for a heating body having plates stacked from a lower part towards an upper part, the first longitudinal edge and the second longitudinal edge are oriented towards the upper part of the heating body.

According to one aspect of the invention, the plurality of plates comprises a first plate and a second plate forming a pair, the pair of plates defining a tube comprising at least one opening opening onto the collector. The opening on the collector results from the assembly of the first plate and the second plate. When the first plate and the second plate are individualized, i.e. before mounting the heating body by stacking the plates, the opening does not exist. Such an opening of the tube on the manifold makes it possible to limit pressure drops during the tube/manifold transition.

According to one aspect of the invention, the first plate and the second plate are of identical conformation and arranged head to tail. The first plate and the second plate are, when individualized, indistinguishable. This makes it possible to standardize the manufacture of the plates. Advantageously, the first longitudinal edge and the second longitudinal edge are of identical size and inclination, to allow head-to-tail arrangement.

According to one aspect of the invention, the outer perimeter of the first plate comprises a first edge and a second edge opposite the first edge, the outer perimeter of the second plate comprises a first side and a second side opposite the first side, the the first edge and the second edge being folded and each connecting the first longitudinal edge and the second longitudinal edge of the first plate, the second side and the first side being folded and each connecting the first longitudinal edge and the second longitudinal edge of the second plate . The denominations “edge” and “flank” are intended to distinguish regions of the first plate from the same regions of the second plate. They are only used to facilitate the description and distinguish the plates they designate. The technical characteristics of the first border, the second border, the first sidewall and the second sidewall are considered to be similar, and the denominations could be interchanged without affecting the scope of the invention.

The first edge and the second edge extend transversely relative to the first longitudinal edge and the second longitudinal edge of the first plate. Advantageously, the first edge and the second edge extend perpendicularly relative to the first longitudinal edge and to the second longitudinal edge of the first plate.

The first flank and the second flank extend transversely relative to the first longitudinal edge and to the second longitudinal edge of the second plate. Advantageously, the first flank and the second flank extend perpendicularly relative to the first longitudinal edge and to the second longitudinal edge of the second plate.

According to one aspect of the invention, the first border extends in a first direction and the second border extends in a second direction opposite to the first direction, the first flank extends in the second direction and the second flank which s 'extends in the first direction, the second edge being in contact with the second sidewall. The second edge and the second flank are overlapping and joined together by brazing. The second border and the second flank contribute to the closure of the tube at the level of the external perimeter of the first plate and of the second plate. Conversely, the opening of the tube is at least delimited by the first border and the first sidewall.

According to one aspect of the invention, the pair of plates, called the first pair of plates, comprises the first plate and the second plate which delimit the tube, called the first tube, the heat exchanger comprising a third plate which delimits with the second plate a second tube. One and the same plate, the second plate, makes it possible to delimit the first tube and the second tube. The first tube and the second tube are immediately adjacent tubes. According to one aspect of the invention, the first pair of plates delimits the first tube, the first tube comprising the opening, called the first opening, the first opening leading to the collector, called the first collector, the second pair of plates delimits the second tube comprising a second opening leading to a second manifold separate from the first manifold. Two distinct circuits cross the heat exchanger: one crosses the first tube and the first collector, the other crosses the second tube and the second collector. During the implementation of the invention, it is at the level of the second plate that the heat exchange takes place between the two fluids traversing one and the other circuit. For the first pair of plates, the first opening is at least delimited by the first edge and the first sidewall. For the second pair of plates, the second opening is at least delimited by the second flank and the second rim.

According to one aspect of the invention, the heating body comprises a first longitudinal end and a second longitudinal end opposite the first longitudinal end, the first manifold being arranged at the first longitudinal end of the heating body and the second manifold being arranged at the second longitudinal end. The first longitudinal end includes the first edge, the first sidewall and the first flange. The second longitudinal end includes the second edge, the second sidewall and the second flange.

According to an alternative aspect of the invention, one of the collectors is arranged on at least one lateral end transverse to the first longitudinal end or transverse to the second longitudinal end. The lateral end comprises at least the first longitudinal edge or the second longitudinal edge.

According to one aspect of the invention, the third plate has a first flange which extends in the first direction and a second flange opposite the first flange and which extends in a second direction, the first side being in contact with the first flange . The first flank and the first rim are overlapping and joined together by brazing. The first flank and the first flange participate in the closing of the second tube at the level of the external perimeter of the second plate and of the third plate. On the other hand, the opening of the second tube is at least delimited by the second flank and the second rim.

The outer perimeter of the third plate includes the first flange and the second flange opposite the first flange, the first flange and the second flange being folded and each connecting the first longitudinal edge and the second longitudinal edge of the third plate.

The denominations “edge”, “flank” and “edge” are intended to distinguish regions of the first plate from the same regions of the second plate and of the third plate. They are only used to facilitate the description and distinguish the plates they designate. The technical characteristics of the first edging, the second edging, the first flank, the second flank, the first edging and the second edging are considered to be similar, and the denominations could be interchanged without affecting the scope of the invention.

According to one aspect of the invention, at least one of the longitudinal edges comprises a free edge, and at least the first edge and/or the second edge extending as far as the free edge. The first tube is closed by the second border, the second sidewall and the first longitudinal edge or the second longitudinal edge. The second tube is closed by the first sidewall, the first flange and the first longitudinal edge or the second longitudinal edge.

According to one aspect of the invention, the first longitudinal edge comprises a first free edge, the second longitudinal edge comprises a second free edge, and at least the first edge and/or the second edge extending as far as the first free edge and to the second free edge. The first tube is closed by the second border, the second sidewall, the first longitudinal edge and the second longitudinal edge. The second tube is closed by the first sidewall, the first flange, the first longitudinal edge and the second longitudinal edge.

According to one aspect of the invention, the first tube and the collector, called the first collector, participate in delimiting a first circulation volume of a refrigerant fluid, and the second tube and a second collector participate in delimiting a second circulation volume of 'a coolant, the first volume being separate from the second volume. Here, “a second collector” corresponds to the aforementioned second collector.

According to one aspect of the invention, the heating body comprises an alternation of first tubes and second tubes, the first tubes being supplied by the first collector and the second tubes being supplied by the second collector.

According to one aspect of the invention, each plate comprises a rib delimiting a U-shaped circulation profile, the opening of each tube being separated into an inlet portion and an outlet portion. The rib extends longitudinally over part of the heat exchange area of the plate, from the opening of the tube. The rib participates in separating the inlet portion and the outlet portion. The rib coincides with a separation of the first manifold or of the second manifold, each manifold being capable of supplying the first tube or the second tube with fluid, refrigerant fluid or heat transfer liquid, and of being supplied with fluid by the first tube or the second tube. For example, the first manifold comprises a first fluid inlet chamber open to the inlet portion of the first tube and a first fluid outlet chamber open to the outlet portion of the first tube. Similarly, the second manifold includes a second fluid inlet cell open to the inlet portion of the second tube and a second fluid outlet cell open to the outlet portion of the second tube.

In addition to the rib, the heat exchange zone comprises a plurality of disruptors configured to disrupt the flow of the refrigerant fluid in the first tube and/or a heat transfer liquid in the second tube.

According to one aspect of the invention, the inlet portion of the first tube is of similar size to the outlet portion of the first tube. The rib is centered transversely on the first plate and/or the second plate.

According to one aspect of the invention, the inlet portion of the second tube is of similar size to the outlet portion of the second tube. The rib is centered transversely on the second plate and/or the third plate.

According to an alternative aspect of the invention, the inlet portion of the first tube is larger in size than the outlet portion of the first tube. The rib is offset transversely on the first plate and/or the second plate. This configuration is advantageous when the fluid leaving the first tube, the refrigerant fluid, is expanded relative to the fluid entering the first tube. In particular, when the coolant enters the tube in the liquid phase and exits in the gaseous or two-phase liquid/gas phase.

According to an alternative aspect of the invention, the inlet portion of the second tube is larger in size than the outlet portion of the second tube. The rib is offset transversely on the second plate and/or the third plate. This configuration has its advantage when the fluid leaving the second tube, the heat transfer liquid, is expanded relative to the fluid entering the second tube.

According to one aspect of the invention, the first manifold comprises a first chamber and a second chamber, the first chamber of the first manifold has a smaller volume than the second chamber of the first manifold. When the heat exchanger operates as an evaporator, the first chamber is intended to distribute in the first tube the refrigerant at low pressure and at low temperature which is in the liquid phase. Once the heat exchange has been carried out in the heating body, the second chamber is intended to collect the low-pressure and low-temperature refrigerant fluid from the first tube, a refrigerant fluid which is then two-phase liquid/gas. The two-phase liquid/gas refrigerant fluid occupies a larger volume than the liquid phase refrigerant fluid.

According to one aspect of the invention, the first collector and/or the second collector has a decreasing passage section along a stacking direction of the plates of the heating body. The stacking direction is perpendicular to the main plane of the heat exchange zone. The decreasing passage section of the first manifold and/or of the second manifold respectively improves the distribution of the refrigerant fluid in the first tube and/or the distribution of the heat transfer liquid in the second tube.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description given below by way of indication in relation to the drawings in which:

- the is a general view, in perspective, of a plate heat exchanger according to the invention in a first embodiment,

- the is a perspective view of a plate of the plate heat exchanger shown in [Fig. 1],

- the is a cross-sectional view of the plate shown in [Fig. 2],

- the is a cross-sectional view of a stack of plates of the heating body of the plate heat exchanger according to the invention in the first embodiment,

- the is a longitudinal sectional view of the stack of plates illustrated in [Fig. 4],

- the , the [Fig. 9] and [Fig. 11] are general views, in perspective, of a plate heat exchanger according to the invention in other embodiments,

- the , the [Fig. 8], [Fig. 10], [Fig. 12] and [Fig. 13] are views in longitudinal section of the plate heat exchanger according to the various embodiments shown respectively in [Fig. 1], [Fig. 7], [Fig. 9], [Fig. 11] and [Fig. 11].

It should first be noted that the figures expose the invention in detail to implement the invention, said figures can of course be used to better define the invention if necessary.

In the rest of the description, the designations longitudinal or lateral, above, below, in front, behind refer to the orientation of the plates of the heating body of the plate heat exchanger according to the invention. The longitudinal direction corresponds to the longitudinal extension axis of the plate in which it extends, while the lateral orientations correspond to concurrent lines, that is to say which intersect the longitudinal direction, in particular perpendicular to the longitudinal extension axis of the plate. Finally, the directions referenced as upper or lower correspond to orientations according to the stacking direction of the plates which is perpendicular to the main plane of the heat exchange zone, the lower denomination containing the lower flange and the upper denomination containing the flange top of the plate heat exchanger.

Referring first to the , we see a plate heat exchanger 1 for a vehicle. The heat exchanger 1 comprises a heating body 2 and at least one collector 3. The plate heat exchanger 1 is configured to operate as an evaporator. It includes two collectors 3, 4 included in two separate circulation volumes. Each circulation volume is capable of circulating a fluid, such as a refrigerant fluid and a heat transfer fluid. Thus, the heat exchanger 1 is a two-fluid heat exchanger. During the implementation of the plate heat exchanger 1 as an evaporator, the fluids circulating in each of the circulation volumes carry out a heat exchange between them.

The heating body 2 comprises a first longitudinal end 5 and a second longitudinal end 6 opposite the first longitudinal end 5. The heating body 2 comprises a plurality of plates 7, 8, 9. In the plurality of plates 7, 8, 9, the plates 7, 8, 9 are stacked on top of each other in a stacking direction 10 perpendicular to a main extension axis A of the heat exchanger 1. In the heat exchanger 1 according to invention, the plates 7, 8, 9 are nested one inside the other as illustrated in the and [Fig. 5].

The heating body 2 is arranged between an upper cheek 11 and a lower cheek 12. The upper cheek 11 and the lower cheek 12 each make it possible to close one of the circulation volumes internal to the heat exchanger 1 with plates 7, 8, 9.

In this case, the heat exchanger 1 comprises two manifolds 3, 4. A first manifold 3 is a refrigerant fluid manifold having an inlet 13 and an outlet mouth 14 of the refrigerant. The inlet mouth 13 and the outlet mouth 14 are oriented in the same direction with respect to the stacking direction 10, on the side of the upper flange 11. The first manifold 3 is arranged at the first longitudinal end 5 of the body heating 2. A second manifold 4 is a heat transfer liquid manifold having an inlet 15 and an outlet 16 of heat transfer liquid. The inlet 15 and the outlet 16 are oriented in the same direction with respect to the stacking direction 10, on the side of the upper flange 11. The second collector 4 is arranged at the second longitudinal end 6 of the heating body 2. The first collector 3 and the second collector 4 are arranged outside the heating body 2. The first collector 3 and the second collector 4 are specifically arranged outside a heat exchange zone 17 seen on the , whose position is suggested by the dotted lines under the upper cheek 11.

The shows one of the plates 7, 8, 9 of the heating body 2 of the heat exchanger 1 according to the invention. This plate 7, 8, 9 is used to make the stack of plates 7, 8, 9 constituting the heating body 2. The plate 7, 8, 9 is secured with the other parts of the heat exchanger 1 by brazing once heat exchanger 1 is assembled.

The plate 7, 8, 9 extends along a longitudinal extension axis X. In the heating body 2, the longitudinal extension axis X of each plate 7, 8, 9 is parallel to the axis of main extension A of heat exchanger 1.

The plate 7, 8, 9 has an outer perimeter 18 which delimits the heat exchange zone 17. It is at the level of this heat exchange zone 17, which conducts heat, that the refrigerant fluid recovers the calories from the coolant liquid when the heat exchanger 1 according to the invention operates as an evaporator. The heat exchange zone 17 extends along a main plane P which includes the longitudinal extension axis X of the plate 7, 8, 9 and is perpendicular to the stacking direction 10.

The outer perimeter 18 of the plate comprising a first longitudinal edge 19 and a second longitudinal edge 20 opposite the first longitudinal edge 19. The outer perimeter 18 of the plate 7, 8, 9 comprises a first edge 21 and a second edge 22 opposite to the first edge 21. The first edge 21 and the second edge 22 each connect the first longitudinal edge 19 and the second longitudinal edge 20 of the first plate 7. The term “edge” is characteristic of one of the plates 7, 8, 9 called the first plate 7, but the outer perimeter 18 of all the plates 7, 8, 9 includes these same folded regions, indistinguishable on an isolated plate 7, 8, 9. The term "edge" can be modified by "sidewall" for a second plate 8, with a first sidewall 23 and a second sidewall 24 and by "edge" for a third plate 9, with a first edge 25 and a second edge 26.

The first longitudinal edge 19 and the second longitudinal edge 20 are both folded in the same direction indicated 27. The first longitudinal edge 19 and the second longitudinal edge 20 thus each extend mainly in a secant plane to the main plane P. In the first embodiment, the first longitudinal edge 19 and the second longitudinal edge 20 point towards the upper part of the heat exchanger 1.

The first border 21 and the second border 22 are folded. The makes it possible to visualize the second border 22, folded in the opposite direction 28 with respect to the first longitudinal edge 19 and to the second longitudinal edge 20.

A rib 29 is included in the heat exchange zone 17 and delimits a U-shaped circulation profile. The rib 29 extends from the second edge 22 towards the first edge 21 along the longitudinal extension axis X of the plate 7, 8, 9. In the extension of the rib 29, the second edge 22 comprises a tongue 30 oriented in the extension of the second edge 22, in the opposite direction 28. This tongue 30 provides the junction between the ribs 29 of successive plates 7, 8, 9, and mechanically reinforces the heating body 2.

The heat exchange zone 17 comprises a plurality of disturbers 31. The plurality of disturbers 31 is configured to disturb the flow of the refrigerant fluid within the heating body 2. In this embodiment, the disturbers 31 are distributed homogeneously over the entire heat exchange zone 17. All the disturbers 31 are otherwise identical in this embodiment.

A cut, stamped and bent metal sheet makes it possible to obtain the plate 7, 8, 9 as illustrated in . The rib 29 and the disruptors 31 result from stamping the metal sheet and the folded outer perimeter 18 makes it possible to obtain the first edge 21, the second edge 22, the first longitudinal edge 19 and the second longitudinal edge 20.

The illustrates plate 7, 8, 9 of [Fig. 2] according to section AA visible in [Fig. 2], section AA made perpendicular to the main plane P of the heat exchange zone 17. The first longitudinal edge 19 and the second longitudinal edge 20 are identical. Only the first longitudinal edge 19 is described here, but the description applies to the second longitudinal edge 20.

The plate 7, 8, 9 comprises a lower face 32, intended to be oriented towards the upper cheek 11 and an upper face 33 intended to be oriented towards the lower cheek 12.

The first longitudinal edge 19 defines a nesting zone 34, 35 of at least one other plate 7, 8, 9. In this case, the first longitudinal edge 19 defines an upper nesting zone 35 on the upper face side 33, here grayed out to make it easier to read the , and a lower nesting zone 34 on the lower face 32 side, the plate 7, 8, 9 being intended to nest with two other plates 7, 8, 9.

The first longitudinal edge 19 comprises a curved free edge 36 distinct from the nesting zones 34, 35. The free edge 36 is curved in the direction of the lower face 32.

The shows a fold line 37 of the outer perimeter 18 of the plate 7, 8, 9 is rounded and not angular.

The illustrates in section one of the disturbers 31 of the heat exchange zone 17. The disturbers 31 are all made so that the plate 7, 8, 9 is stamped in the direction of the upper face 33 of the plate 7, 8 , 9, thus hollowing out the lower face 32. The disruptors 31 are arranged alternately on the heat exchange zone 17, so that only one of them is visible on the section AA.

The has a stack of three plates 7, 8, 9 intended to be integrated into the heating body 2. The plates 7, 8, 9 of the plurality of plates 7, 8, 9 all extend their first longitudinal edge 19 and their second longitudinal edge 20 in the same direction. The first plate 7, the second plate 8 and the third plate 9 are visible here according to section AA illustrated in [Fig. 2].

The lower nesting zone 34 of the first plate 7 is in contact with the upper nesting zone 35 of the second plate 8. The lower nesting zone 34 of the second plate 8 is in contact with the nesting zone top 35 of the third plate 9.

The disturbers 31 are all made to hollow out the lower face 32. By stacking them, the disturbers 31 of the first plate 7 and those of the third plate 9 are aligned along the stacking direction 10. In the heat exchange zone 17, the lower face 32 of the first plate 7 is in contact with the upper face 33 of the second plate 8 at the level of the disturbers 31 of the second plate 8. In the heat exchange zone 17, the lower face 32 of the second plate 8 is in contact with the upper face 33 of the third plate 9 at the level of the disruptors 31 of the third plate 9.

The illustrates the first plate 7, the second plate 8 and the third plate 9 stacked, intended to be integrated into the heating body 2. The stacking of these three plates 7, 8, 9 is described according to a section perpendicular to the section AA. The refrigerant FR and the heat transfer liquid LC are each illustrated by separate arrows.

The first plate 7 and the second plate 8 form a pair of plates 7, 8, called the first pair 78 of plates, comprises the first plate 7 and the second plate 8. The second plate 8 and the third plate 9 form another pair of plates 8, 9, said second pair 89 of plates. The first plate 7 and the second plate 8 are of identical conformation and arranged head to tail. The third plate 9 and the second plate 8 are of identical conformation and arranged head to tail.

The outer perimeter 18 of the first plate 7 comprises the first edge 21 and the second edge 22 opposite the first edge 21. The first edge 21 and the second edge 22 each connect the first longitudinal edge 19 and the second longitudinal edge 20 of the first plate 7, here not visible due to the cut. The outer perimeter 18 of the second plate 8 comprises the first flank 23 and the second flank 24 opposite the first flank 23. The second flank 24 and the first flank 23 each connect the first longitudinal edge 19 and the second longitudinal edge 20 of the second plate 8. The outer perimeter 18 of the third plate 9 comprises the first flange 25 and the second flange 26 opposite the first flange 25. The first flank 23 and the second flank 24 each connect the first longitudinal edge 19 and the second longitudinal edge 20 of the third plate 9.

The first edge 21, the second edge 22, the first sidewall 23, the second sidewall 24, the first flange 25 and the second flange 26 are folded. Their folding direction is assessed with respect to a first direction 39 and a second direction 40 opposite to the first direction 39. The first direction 39, represented by a first arrow, is directed, in the heat exchanger 1, towards the cheek upper 11. The second direction 40, represented by a second arrow, is directed, in the heat exchanger 1, towards the lower flange 12.

The first edge 21 and the second edge 22 extend to the free edges 36 of the first plate 7. The first side 23 and the second side 24 extend to the free edges 36 of the second plate 8, not visible due to the viewing angle. The first rim 25 and the second rim 26 extend as far as the free edges 36 of the third plate 9, not visible due to the viewing angle.

The first edge 21, the second side 24 and the first rim 25 extend in the first direction 39. The second edge 22, the first side 23 and the second edge 22 extend in the second direction 40. The plates 7, 8, 9 overlapping head to tail, the second edge 22 is in contact with the second flank 24 and the first flank 23 is in contact with the first flange 25.

With the first longitudinal edges 19 and the second longitudinal edges 20 of the plates 7, 8, 9, each pair 78, 89 of plates delimits a tube 41, 42 provided with an opening 43, 44.

The first pair 78 of plates delimits a first tube 41 and the second pair 89 of plates delimits a second tube 42. The heating body 2 comprises alternating first tubes 41 and second tubes 42, the first tubes 41 being supplied by the first collector 3 and the second tubes 42 being supplied by the second collector 4.

The first tube 41 comprises a first opening 43, the first opening 43 intended to lead to the first manifold 3. The second tube 42 comprises a second opening 44 intended to lead to the second manifold 4.

The first tube 41 and the first manifold 3 participate in delimiting a first circulation volume of the refrigerant fluid FR. The second tube 42 and the second collector 4 participate in delimiting a second circulation volume of the heat transfer liquid LC. The circulation of the refrigerant FR in the first tube 41 is homogeneous around the first opening 43. The circulation of the heat transfer liquid LC in the second tube 42 is homogeneous around the second opening 44.

The shows a section of the heat exchanger 1, the section being made through the first tube 41 along a plane parallel to the main plane P of the exchange zone of the second plate 8. [Fig. 6] illustrates in section the volume of the first collector 3 and the volume of the second collector 4, as well as the first opening 43 of the first tube 41. The volume in section is characterized by a passage section of the collectors 3, 4. This section of passage corresponds to a surface of the collectors 3, 4. It is taken in the plane of the section, i.e. parallel to the main plane P. The passage section of the first collector 3 is delimited by the first opening 43 and a wall 60 of the first collector 3. The passage section of the second collector 4 is delimited by the second opening 44 and a wall 60 of the second collector 4.

The opening 43, 44 of each tube 41, 42 is separated into an inlet portion 45 and an outlet portion 46. In this embodiment, the inlet portion 45 of the first tube 41 is of similar size to the outlet portion 46 of the first tube 41. The volume of the first manifold 3 is similar to the volume of the second manifold 4.

The first collector 3 comprises a first chamber 47 and a second chamber 48, the first chamber 47 having a volume identical to that of the second chamber 48. The second collector 4 comprises a first cell 49 and a second cell 50, the first cell 49 having a volume identical to that of the second cell 50.

The first chamber 47 and the second chamber 48 are in one piece in this embodiment. The first chamber 47 is separated from the second chamber 48 by a first foot 51. The first foot 51 rests against the tabs 30, visible on the , the tabs 30 extending the ribs 29 of each second plate 8.

The first cell 49 and the second cell 50 are in one piece, in this embodiment. The first cell 49 is separated from the second cell 50 by a second foot 52. The second foot 52 bears against the tabs 30 extending the ribs 29 of the plates forming the second tubes 42, not visible due to the viewing angle.

The , the [Fig. 8], [Fig. 9], [Fig. 10], [Fig. 11], [Fig. 12] and [Fig. 13] present embodiments which differ from that presented in [FIG. 1], [Fig. 2], [Fig. 3], [Fig. 4], [Fig. 5] and [Fig. 6]. The [Fig. 7], [Fig.9] and [Fig. 11] differ from what was described in [Fig. 1]. The [Fig. 8], [Fig. 10], [Fig. 12] and [Fig. 13] differ from what was described in [Fig. 6]. In addition to the differences described below, the description respectively of [Fig. 1] and [Fig. 6], applies mutatis mutandis to [Fig. 7], [Fig. 9], [Fig. 11] on the one hand and in [Fig. 8], [Fig. 10], [Fig. 12], and [Fig. 13] on the other hand, and reference may be made to it for understanding and implementing the invention.

The , the [Fig. 8], [Fig. 9] and [Fig. 10] show heat exchangers 1 where the first chamber 47 of the first collector 3 has a smaller volume than the second chamber 48 of the first collector 3.

In the example of the , inlet 13, outlet 14, inlet 15 and outlet 16 are dimensionally equivalent.

In the example of the , the heat exchanger 1 is seen along a section BB, the section BB being made through the first tube 41 along a plane parallel to the main plane P of the exchange zone of the second plate 8. The inlet portion 45 of the first tube 41 is of smaller size than the outlet portion 46 of the first tube 41. The rib 29 is offset to allow this difference. The first foot 51 is also offset to coincide with the rib 29 and the tongue 30.

In the example of the , inlet mouth 13, inlet orifice 15 and outlet orifice 16 are dimensionally equivalent. The FR refrigerant outlet mouth 14 is for its part of larger size.

In the example of the , the heat exchanger 1 is seen along the section BB, the section BB being made through the first tube 41 along a plane parallel to the main plane P of the exchange zone of the second plate 8. The volume of the first collector 3 is greater than the volume of the second collector 4, as shown by a passage section of the first collector 3 coming from the cutting plane BB.

In , [Fig. 12] or [Fig. 13], the first manifold 3 and/or the second manifold 4 has a decreasing passage section along the stacking direction 10 of the plates 7, 8, 9 of the heating body 2.

In the example of the , inlet 13, outlet 14, inlet 15 and outlet 16 are dimensionally equivalent. The volume of the first collector 3 is equivalent to the volume of the second collector 4.

The and [Fig. 13] are sectional views of the heat exchanger 1 of [Fig. 11], the two cuts being parallel. A first cut being made through the first tube 41 along a plane parallel to the main plane P of the exchange zone of the second plate 8. The first cut, passing through the first tube 41, is lower than a second cut , passing through the second tube 42 parallel to the main plane P of the exchange zone of the second plate 8. In the example of [Fig. 12] and [Fig. 13], the inlet portion 45 of the first tube 41 is of equivalent size to the outlet portion 46 of the first tube 41.

In the example of the , the passage section of the first collector 3, coming from the first cut, is smaller than the passage section of the first collector 3, coming from the second cut, shown in [Fig. 13].

It is understood on reading the foregoing that the present invention proposes a plate heat exchanger configured to facilitate and optimize the exchanges of heat between the fluids traversing it. This heat exchanger, intended in particular to be integrated into a refrigerant circuit and a heat transfer liquid loop, has modular embodiments which facilitates the industrialization of the elements constituting it.

The invention cannot however be limited to the means and configurations described and illustrated here, and it also extends to any equivalent means or configuration and to any technical combination operating such means. In particular, the shape of the heat exchanger can be modified without harming the invention, insofar as the heat exchanger, in fine , fulfills the same functions as those described in this document.

Claims (10)

Plate heat exchanger (1) for a vehicle comprising a heater body (2) and at least one manifold (3), the heater body (2) comprising a plurality of plates (7, 8, 9), each plate having an external perimeter (18) which delimits a heat exchange zone (17), characterized in that the collector (3) is arranged outside the heat exchange zone (17) and in that the plates (7, 8, 9) are nested within each other. Heat exchanger (1) according to claim 1, wherein the heat exchange zone (17) extends along a main plane (P), the outer perimeter (18) of at least one plate (7, 8). , 9) comprising a first longitudinal edge (19) and a second longitudinal edge (20) opposite the first longitudinal edge (19), the first longitudinal edge (19) and the second longitudinal edge (20) being folded so as to s' extend each predominantly in a plane secant to the main plane (P), the first longitudinal edge (19) and the second longitudinal edge (20) thus each defining an interlocking zone (34, 35) of at least one other plate. Heat exchanger (1) according to the preceding claim, in which the first longitudinal edge (19) and the second longitudinal edge (20) are both folded in the same direction. A heat exchanger (1) according to any preceding claim, wherein the plurality of plates (7, 8, 9) comprises a first plate (7) and a second plate (8) forming a pair (78), the pair (78) of plates delimiting a tube (41) comprising at least one opening (43) opening onto the collector (3). Heat exchanger (1) according to the preceding claim, in which the first plate (7) and the second plate (8) are of identical conformation and arranged head-to-tail. A heat exchanger (1) according to any one of claims 4 to 5, wherein the outer perimeter (18) of the first plate (7) comprises a first rim (21) and a second rim (22) opposite the first. edge (21), the outer perimeter (18) of the second plate (8) comprises a first side (23) and a second side (24) opposite the first side (23), the first border (21) and the second border (22) being folded and each connecting the first longitudinal edge (19) and the second longitudinal edge (20) of the first plate (7), the second side (24) and the first side (23) being folded and each connecting the first longitudinal edge (19) and the second longitudinal edge (20) of the second plate (8). Heat exchanger (1) according to the preceding claim, wherein the first edge (21) extends in a first direction (39) and the second edge (22) extends in a second direction (40) opposite to the first direction (39), the first flank (23) extends in the second direction (40) and the second flank (24) which extends in the first direction (39), the second edge (22) being in contact with the second sidewall (24). A heat exchanger (1) according to any one of claims 4 to 7, wherein the pair (78) of plates, called the first pair (78) of plates, comprises the first plate (7) and the second plate (8) which delimit the tube (41), said first tube (41), the heat exchanger (1) comprising a third plate (9) which defines with the second plate (8) a second tube (42). Heat exchanger (1) according to the preceding claim, in which the first tube (41) and the manifold (3), called the first manifold (3), participate in delimiting a first circulation volume of a refrigerant fluid (38), and the second tube (42) and a second manifold (4) participate in delimiting a second circulation volume of a heat transfer liquid (LC), the first volume being separate from the second volume. Heat exchanger (1) according to any one of claims 8 to 9, in which each plate (7, 8, 9) comprises a rib (29) delimiting a U-shaped circulation profile, the opening (43, 44) each tube (41, 42) being separated into an inlet portion (45) and an outlet portion (46).