EP4378018A1

EP4378018A1 - Thermal regulation device for cooling electrical energy storage means

Info

Publication number: EP4378018A1
Application number: EP22754870.8A
Authority: EP
Inventors: Aurelie Bellenfant; Marc HERRY; Fethy DJALLAL; Julien VERON; Juan Carlos BATISTA
Original assignee: Valeo Systemes Thermiques SAS
Current assignee: Valeo Systemes Thermiques SAS
Priority date: 2021-07-26
Filing date: 2022-07-25
Publication date: 2024-06-05
Also published as: US20240347812A1; WO2023006695A1; CN118120097A; FR3125636B1; FR3125636A1

Abstract

The invention relates to a thermal regulation device (4) for cooling electrical energy storage means (2), the thermal regulation device (4) comprising a tube (6) configured to be in contact with the electrical energy storage means and comprising at least one circulation channel (8) for circulating a heat transfer fluid, a manifold (10) disposed at one end of the tube (6) and having collection chambers (26) in fluidic communication with the at least one circulation channel (8) of the tube (6), and at least two connecting sleeves (18, 18a, 18b) arranged on either side of the manifold (10) and configured to communicate with the same collection chamber (26), the connecting sleeves (18, 18a, 18b) each being a different shape.

Description

DESCRIPTION

Title: Thermal regulation device for cooling electrical energy storage devices.

The field of the present invention is that of thermal regulation devices. The present invention relates more particularly to the means used to cool the electrical energy storage devices fitted to such vehicles.

It is known nowadays to equip electric, thermal or hybrid vehicles with electrical energy storage devices allowing an electrical supply to the various elements of the vehicle. These electrical energy storage devices are generally composed of electrical energy storage cells positioned in a battery pack.

Car manufacturers are now seeking to provide more powerful electric or hybrid vehicles, with increased electric range. For this, more and more battery packs, and/or ever larger battery packs, are installed on these electric or hybrid vehicles. It is known to install all or at least some of these battery packs at the floor of the vehicle, substantially over the entire width of the vehicle.

It is understood that, during operation of the vehicle, the battery packs can give off a significant quantity of heat and therefore be subjected to temperature rises which can cause them to be damaged, or even destroyed, in certain cases. Consequently, their cooling is essential in order to keep them in good condition and thus ensure the reliability, autonomy and performance of the vehicle. In addition, the operation of the battery packs may be less efficient in the event of low temperatures, the electrical or electronic components fitted to these battery packs then needing a time to rise to temperature before operating at full efficiency.

To do this, one or more thermal regulation devices intended to regulate the temperature of the battery packs are implemented to ensure the heating and/or cooling functions of the electrical or electronic components at inside these battery packs and thus optimize the operation of the various components.

These thermal regulation devices are generally traversed by a heat transfer fluid which can, as required, either absorb the heat emitted by each battery pack in order to cool it or provide heat if the temperature of the battery pack is insufficient for its correct operation.

It is known in particular, in battery packs where electrical energy storage cells are arranged vertically next to each other so as to form a plurality of successive rows of cells, to have thermal regulation devices having a tube arranged between two rows of cells and within which heat transfer fluid is able to circulate. The contact between the tube and the cells allows an evacuation, or a supply, of calories via the heat transfer fluid. To manage the arrival and evacuation of the heat transfer fluid, a fluid collection box is placed at one end of the tube and the heat transfer fluid inlet and outlet pipes are connected to this collection box. The heat transfer fluid arriving via this inlet duct pours at least in part into the tube via a first collection chamber provided in the collection box, while the fluid leaving the tube, after having recovered calories, for example to lower the temperature of the battery pack, flows into the exhaust duct via a second collection chamber also provided in the collection box.

In order to allow the circulation of the heat transfer fluid within the tube, the latter is pierced with a multitude of circulation channels along which the heat transfer fluid circulates from one longitudinal end of the tube to the other. These channels are grouped into two sets of circulation in order to allow a circulation of heat transfer fluid in a first direction, away from the collection box, distinct from a circulation of heat transfer fluid in a second opposite direction. It is then necessary to communicate fluidically the first collection chamber within the collection box with the first assembly of circulation within the tube and to communicate fluidically the second collection chamber within the collection box with the second assembly. of circulation within the tube, ensuring that there is no direct communication from one collection chamber to the other, to prevent, for example, heat transfer fluid heated during its passage through the tube from passing from the second circulation assembly to the first collection chamber and being reinjected hot into the tube.

In this context aiming to improve sealing solutions at the junction between a tube and a collection box of a thermal regulation device, the present invention proposes an alternative to existing devices having as its object a tube of a thermal regulation for cooling electrical energy storage devices, the tube extending along a main longitudinal direction of elongation and comprising a plurality of longitudinal channels for the circulation of heat transfer fluid formed side by side in the material inside the tube and which open onto each longitudinal end face of the tube, the longitudinal channels being divided into a first assembly for the circulation of heat transfer fluid and a second assembly for the circulation of heat transfer fluid, characterized in that at least a longitudinal end face of the tube has a sealing zone which is arranged between the channels participating in forming the first 1st circulation set and the channels participating in forming the second circulation set.

According to the invention, the sealing zone is a solid zone which is formed in a longitudinal end face of the tube and which has no orifice, or, where appropriate, an orifice blocked by a local supply of material contributing to ensure a solid surface.

According to one characteristic of the invention, each circulation assembly comprises a transverse alignment of several longitudinal channels arranged in parallel with respect to each other, and in which the sealing zone is arranged on the transverse alignment of each of the sets of traffic.

According to one characteristic of the invention, the sealing zone extends between the two circulation assemblies over a transverse dimension at least equal to the corresponding transverse dimension of a longitudinal channel of one of the two circulation assemblies.

According to one characteristic of the invention, the sealing zone extends over the entire longitudinal dimension of the tube, from one end face to the other. In other terms, a longitudinal strip of material, extending from one end face to the other, is not pierced by a circulation channel.

According to one characteristic of the invention, the sealing zone extends only over the longitudinal end face(s) of the tube. In particular, the tube may comprise a plurality of channels which extend parallel to each other at regular intervals over the entire transverse dimension of the tube, and a closure element is provided to cover at least one of the channels at the level of the face. longitudinal end of the tube considered. This sealing element may in particular consist of a plug sized to seal a single channel or else of a plate sized to seal several neighboring channels.

According to one characteristic of the invention, the tube has a corrugated shape, adapted to be in contact with at least one row of electrical energy storage devices. The corrugated shape makes it possible in particular to increase the contact surface between the tube and each of the electrical energy storage devices and consequently improve the heat exchange performance.

According to a characteristic of the invention, the sealing zone is arranged in the center of the tube along the transverse dimension.

The invention also relates to a thermal regulation device for cooling electrical energy storage devices, comprising a tube as previously described and configured to be in contact with the electrical energy storage devices, and further comprising a collection box arranged at one end of the tube and comprising within it collection chambers fluidly communicating respectively with the channels of the first circulation assembly and the channels of the second circulation assembly, and at least two connection sleeves arranged on either side another of the collection box and configured to communicate with the same collection chamber.

According to one characteristic of the invention, the collection chambers are delimited by a common central wall formed in the collection box, said central wall resting against the sealing zone when the collection box and the tube are integral one another. According to one characteristic of the invention, the collection box is formed by two shells fixed one on the other, each shell having two hollows formed by deformation of the shell participating in forming respectively a collection chamber and a rib arranged between the two hollow, the rib of each shell being intended to be in contact with the rib of the other shell to form said central wall.

The invention also relates to an electrical energy storage device for an electric or hybrid vehicle, comprising several sets of electrical energy storage members and several thermal regulation devices as previously described, each thermal regulation device being arranged between two sets of electrical energy storage devices.

According to one characteristic of the invention, two neighboring thermal regulation devices are configured to be connected in a sealed manner by direct cooperation of a connection sleeve of a first thermal regulation device, equipped with a seal, with a connection sleeve of a second thermal regulation device.

The invention also relates to a method for assembling a thermal regulation device according to the invention, during which:

- the collection box is formed by assembling two shells against each other,

- inserting a longitudinal end face of the tube provided with a sealing zone inside the collecting box until the central wall formed in the collecting box is in contact with the sealing zone sealing,

- the assembly formed by the collection box and the tube is brazed.

Other characteristics, details and advantages of the invention will emerge more clearly on reading the description which follows on the one hand, and several examples of embodiment given by way of indication and not limitation with reference to the appended schematic drawings on the other. part, on which:

[Fig. î] is a representation in perspective of a battery pack as a whole equipped with several electrical energy storage devices and a plurality of thermal regulation devices according to the invention; [Fig. 2] is a detail view of several electrical energy storage members and of one end of several thermal regulation devices, seen in FIG. 1;

[Fig. 3] is a representation in perspective of a thermal regulation device according to a first embodiment in which the circulation of the heat transfer fluid intended to circulate in this device has been represented by arrows in solid lines;

[Fig. 4] is a representation in perspective of a thermal regulation device according to a second embodiment in which the circulation of the heat transfer fluid intended to circulate in this device has been represented by arrows in solid lines;

[Fig. 5] is a perspective representation of one end of a thermal regulation device, showing a distribution box and connection sleeves projecting from either side of this box;

[Fig. 6] is a cross-sectional view of two neighboring thermal regulation devices, showing in particular the cooperation between connecting sleeves made in one piece with the distribution box formed at the end of the corresponding thermal regulation device;

[Fig. 7] is a schematic perspective representation, similar to that of Figure 3, in which the distribution box has been partially shown to make its internal structure visible and to make visible the internal structure of the tube at one end of which is fixed the distribution box;

[Fig. 8] is a perspective view of the tube of Figure 5;

[Fig. 9] is a representation in perspective, according to a perspective angle similar to that of FIG. 3, illustrating an alternative embodiment of the invention; [Fig. 10] is a sectional view of two neighboring thermal regulation devices, in a section plane similar to that of FIG. 4, illustrating the variant embodiment of FIG. 7; [Fig. it] is a sectional view of a tube according to a first alternative embodiment of the invention;

[Fig. 12] is a sectional view of a tube according to a second alternative embodiment of the invention. The features, variants and different embodiments of the invention may be associated with each other, in various combinations, insofar as they are not incompatible or exclusive with respect to each other. In particular, variants of the invention may be imagined comprising only a selection of characteristics described below in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage and/or to differentiate the invention. compared to the prior art.

In the following description, the terms "longitudinal",

"transverse" and "vertical" refer to the orientation of a thermal regulation device according to the invention. A longitudinal direction corresponds to a main extension direction of a thermal regulation device and a transverse direction corresponds to a direction substantially perpendicular to a main extension plane of a thermal regulation device and to a main extension direction of a hydraulic connection sleeve of the thermal regulation device, this transverse direction being perpendicular to the longitudinal axis L. Finally, a vertical direction is perpendicular to the longitudinal direction and to the transverse direction.

An electrical energy storage device 1 according to one aspect of the invention, in particular intended to equip an electric or hybrid vehicle, comprises several sets of electrical energy storage devices 2, also called energy storage cells hereinafter. electrical energy, and several thermal regulation devices 4 arranged close to these cells to allow heat exchange between them.

The electrical energy storage members have in particular the shape of cylindrical cells, here of circular section, arranged vertically, that is to say perpendicular to the longitudinal and transverse plane in which the electrical energy storage device is mainly inscribed.

The electrical energy storage devices 2 are in particular arranged in successive rows 3, parallel to each other, and each row, or set of electrical energy storage devices, extends mainly longitudinally.

Thermal regulation devices 4 are arranged between two rows 3 of adjacent electrical energy storage devices, with in particular a tube 6 which is configured to be in contact with the electrical energy storage devices 2 of these two adjacent rows 3 .

In the example illustrated, the rows 3 are staggered relative to each other, that is to say with a longitudinal offset of the storage members of one row relative to the storage members of the neighboring row, which makes it possible to optimize the size of the electrical energy storage device 1, and the thermal regulation devices 4 each comprise a tube 6 of corrugated shape in order to be able to be in contact with each of the electrical energy storage members 2 of the two rows 3 between which they extend respectively.

Heat transfer fluid is intended to circulate inside this tube 6 of corrugated shape in order to be able to exchange calories with the electrical energy storage devices 2, via the heat-conducting wall of the tube. In particular, when the electrical energy storage devices 2 must be cooled following a rise in temperature during their operation, the heat transfer fluid is intended to recover the calories and to evacuate them from the electrical energy storage device 1.

Each thermal regulation device 4 comprises, to allow this exchange of calories, the tube 6 mentioned above, here of corrugated shape, within which is formed at least one circulation channel 8 of heat transfer fluid, and at least one collection box 10 which is arranged at a longitudinal end 12 of the tube 6 and whose purpose is to collect the fluid from an inlet duct 14 of heat transfer fluid and to distribute it in the circulation channel(s) 8 within the tube 6 and / or intended to collect the heat transfer fluid at the outlet of the tube 6 and to direct it into an evacuation pipe 16 of heat transfer fluid.

In other words, the heat transfer fluid is intended to circulate in the inlet conduit, and at each collection box encountered by the inlet conduit, a portion of heat transfer fluid is directed towards this collection box and the device for associated thermal regulation and another portion of heat transfer fluid is directed through the continuation of the inlet duct to feed the next collection box.

According to the invention, the heat transfer fluid inlet duct 14 and the heat transfer fluid discharge duct 16 are formed by the direct cooperation of connection sleeves 18 secured to two neighboring collection boxes 10, without there being any intermediate devices arranged between these connection sleeves 18, it being understood, where appropriate, that a seal may be carried by one of the connection sleeves and rest on the other connection sleeve at the level of the zone direct connection between the sleeves.

The characteristics relating to the connection sleeves 18 allowing in particular the direct cooperation as mentioned will be described in more detail below.

However, it can be seen at this stage of the description, based on the illustrations in Figures 1 and 2, that two connection sleeves 18 extend on either side of a collection box 10 to form a pair 19, and that the two connection sleeves 18 of this pair have a different shape from each other, so as to allow the sleeve of a first type 18a associated with a first collection box 10 to be connected directly to a sleeve of the second type 18b associated with a second collection box 10, without it being necessary to provide additional connection means.

Furthermore, it can be noted that each assembly formed by a collection box 10 and its connection sleeves 18 is identical from one thermal regulation device 4 to another.

FIG. 3 illustrates a first embodiment of the thermal regulation device according to the invention, in the circulation of the fluid is said to be in LF, that is to say with the same portion of heat transfer fluid which circulates in both directions within of tube 6 after passing through a return box 20 at one of the longitudinal ends of the tube.

More particularly, the thermal regulation device 4 comprises in this first embodiment a tube 6 and at each of its longitudinal ends a collection box 10 and a return box 20.

The tube 6 comprises several channels 8 formed within it, divided into two sets of circulation which are distinguished in that the same portion of heat transfer fluid circulates in the first direction of circulation Si within the channels of a first set of circulation 21 and in a second direction of circulation S2, opposite to the first direction of circulation Si, within the channels of a second set of circulation 22.

The collection box 10 disposed at a first longitudinal end 12 of the tube is equipped with connection sleeves 18 to allow the arrival and evacuation of the heat transfer fluid. The collection box 10 is configured to guide the fluid circulating in the connection sleeves 18 participating in forming the heat transfer fluid inlet duct 14 towards a part of the channels, here the channels of the first circulation assembly 21, within the tube and to guide the fluid leaving the tube through the other part of the channels, here the channels of the second circulation assembly 22, in the connection sleeves 18 participating in forming the heat transfer fluid evacuation conduit 16.

The deflection box 20 arranged at a second longitudinal end of the tube 6 does not include any connection sleeves and is only fluidly connected to the tube 6. The deflection box 20 is configured to guide the fluid flowing in one direction in part of the channels of traffic to the other part of the traffic channels so that it flows in the other direction.

The result of this configuration, as illustrated by the arrows visible in FIG. 3, is an inlet of heat transfer fluid via a first connecting sleeve 18 of a pair 19, a passage of a portion of this heat transfer fluid into the tube 6 in a first direction of circulation Si while the other part of this heat transfer fluid continues its route in the inlet duct 14 in the direction of a neighboring thermal regulation device 4, a circulation of heat transfer fluid within the channels of the first circulation assembly 21 in a first direction of circulation Si during which the heat transfer fluid recovers or transfers calories with the surface of the cells in contact with the tube 6, at the level of its channels of the first circulation assembly 21, a change of direction in the return box and a passage in the tube in a second direction of circulation S2, with a circulation of heat transfer fluid this time within the channels of the second circulation assembly 22 in the second direction of circulation S2 during which the heat transfer fluid again recovers or yields calories with the surface of the cells in contact with the tube, at the level of its channels of the second circulation assembly 22, and a fluid outlet via the second connection sleeve 18 of said pair 19, which joins fluid from the neighboring thermal control device.

FIG. 4 illustrates a second embodiment of the thermal regulation device 4 according to the invention, in the circulation of the heat transfer fluid is said to be in I, that is to say with the same portion of heat transfer fluid which circulates only in a direction within the tube 6.

More particularly, the thermal regulation device 4 comprises in this second embodiment a tube 6 and at each of its longitudinal ends a collection box 10.

Here again, the tube 6 comprises several channels 8 formed within it, divided into two sets of circulation which are distinguished this time in that two different portions of fluid can circulate distinctly within the tube, in their respective set of channels. A first portion of heat transfer fluid can thus circulate in the first direction of circulation Si within the channels of the first circulation assembly 21 and a second portion of heat transfer fluid can circulate in a second direction of circulation S2, opposite to the first direction of circulation, within the channels of the second set of circulation 22.

Each collection box 10 is here equipped with connection sleeves 18 within the meaning of the invention, that is to say configured to be able to cooperate directly with connection sleeves of an adjacent collection box to form a conduit of inlet 14 and an exhaust duct 16 of heat transfer fluid. Here again, each collection box 10 is configured to guide the heat transfer fluid circulating in the connection sleeves 18 participating in forming the fluid inlet conduit 14 to a part of the channels within the tube 6 and to guide the fluid leaving the tube through the other part of the channels in the connecting sleeves 18 participating in forming the fluid discharge conduit 16.

It results from this configuration, as illustrated by the arrows visible in Figure 4, two separate circuits. A first circuit Cl comprises a fluid inlet via a first sleeve of a first collection box, a passage of part of this fluid in the tube in a first direction of circulation while the other part of this fluid continues its road in the supply duct in the direction of a neighboring thermal regulation device, and an outlet of the fluid via a first sleeve of the second collection box after having passed through the tube, to join the fluid coming from the neighboring thermal regulation device . And a second circuit C2 comprises a fluid inlet via a second sleeve of the second collection box, a passage of part of this fluid in the tube in a second direction of circulation while the other part of this fluid continues its road in the supply duct in the direction of a neighboring thermal regulation device, and an outlet of the fluid via a second sleeve of the first collection box after having passed through the tube, to join the fluid coming from the neighboring thermal regulation device .

In an alternative not shown here, a circulation of the heat transfer fluid in I can be implemented with the heat transfer fluid which circulates only in one direction within the tube 6, and with collection boxes at each end of the tube which do not include only two connecting sleeves each. The heat transfer fluid circulates in the same direction in each of the channels within the tube, between a header box forming a supply header box at one end of the tube and another header box forming an evacuation header box at the other end of the tube.

We will now describe in more detail a thermal regulation device and a manifold equipped with connection sleeves in accordance with the invention, in particular with reference to Figures 5 to 7. It should be noted that the detailed description of the manifold which will follow can in particular be applied to the two embodiments of the thermal regulation device mentioned above. As mentioned, the thermal regulation device 4 comprises a tube 6 comprising at least one heat transfer fluid circulation channel 8, here a plurality of channels 8 as seen in Figure 7, on which a shell participating in forming the box collection 10 has been removed to make the interior of the latter visible and the presence of the channels in the tube.

The tube 6 has the shape of a plate extending along a main direction of longitudinal elongation, so as to follow the direction of longitudinal elongation of the row 3 of cells with which the tube must be in contact to perform the function of heat exchange.

More particularly, the tube 6 here has a corrugated shape with a succession of ridges 26 along the longitudinal direction of elongation of the tube, in order to be able to be in contact with each of the cells of the rows 3 surrounding the tube 6, these rows being arranged in a staggered arrangement. It is understood that the channels 8 within the tube 6 follow the corrugated shape.

Furthermore, a collection box 10, arranged at a longitudinal end 12 of the tube 6, is more clearly visible in Figure 5.

This collection box 10 is formed by two shells 11 placed one against the other so as to define fluid collection chambers 26 communicating with the channels as will be described below.

To bring or evacuate the heat transfer fluid from these collection chambers 26, connection sleeves 18 are arranged on either side of the collection box 10, taking the form of hollow tubular portions making it possible to guide the circulation of fluid.

According to one characteristic of the invention, the collection box 10 and the two connection sleeves 18 form a one-piece assembly, that is to say an assembly which cannot be disassembled without causing the destruction of one and/or or the other of the parts forming this whole. This one-piece assembly can in particular be obtained, prior to the assembly of the thermal regulation devices 4 in contact with the electrical energy storage members 2, by a brazing operation, it being noted that the brazing operation making the box one-piece collection 10 and the connection sleeves 18 can be made simultaneously with a brazing operation making the tube integral with the collection box.

By way of non-limiting example of the invention, the collection box IO and the connection sleeves 18 are made of the same material, and more particularly of aluminum.

As previously mentioned, the connection sleeves 19 are arranged on either side of the collection box 10 in pairs 19, a pair 19 of connection sleeves being formed by two connection sleeves whose elongation axes, c that is to say the axis of revolution of the tubular portion, are substantially coincident. The heat transfer fluid can flow from one connection sleeve to the other connection sleeve of the same pair, each pair 19 thus forming part of a heat transfer fluid inlet 14 or outlet 16 conduit.

As mentioned, according to the invention, connecting sleeves 18 of two neighboring thermal regulation devices 4 cooperate directly to simplify the assembly process. FIG. 6 illustrates in particular the fitting of a connection sleeve of a thermal regulation device directly into a connection sleeve of a neighboring thermal regulation device. In order to allow this direct cooperation, a connecting sleeve 18 of a pair 19 is configured as a male element and forms a sleeve of a first type 18a and the other connecting sleeve 18 of this pair 19 is configured as a male element. female and forms a sleeve of a second type 18b. The assembly of two neighboring thermal regulation devices with each other is achieved by causing a connection sleeve of the first type 18a, or male sleeve, associated with one of the thermal regulation devices, and a connection sleeve of the second type 18b to cooperate. , or female sleeve, associated with the other of the thermal regulation devices. In other words, the connection sleeves of the same pair have distinct shapes with respect to each other to allow direct cooperation without intermediary between two connection sleeves belonging to two neighboring thermal regulation devices, in a context where the thermal regulation devices have identical shapes from one device to another. More particularly, a connection sleeve of the first type 18a comprises an external diameter, and in particular at the level of a free end 180a opposite to the collection box IO, the value Di of which is slightly less than the value Ü2 of the internal diameter of a connection sleeve of the second type 18b, and in particular at a free end 180b opposite the collection box.

It should be understood that the external diameter of a first type coupling sleeve, i.e. a male element intended to be inserted inside a female element, is considered to be slightly less than the internal diameter. of a second type connection sleeve since it allows insertion by fitting of the male element into the female element.

As shown in particular in Figure 5, considering a pair 19 of connection sleeves, the connection sleeve of the first type 18a has a free end, opposite the collection box 10, which may have dimensions external dimensions smaller than the corresponding external dimensions of this connection sleeve in the vicinity of the collection box, so as to present a male shape tending to shrink as the distance from the collection box increases, while the connection sleeve of the second type 18b comprises a free end, opposite the collection box 10, which may have internal dimensions greater than the corresponding internal dimensions of this connection sleeve in the vicinity of the collection box, so as to have a shape female tending to widen as the distance from the collection box increases.

In a variant not shown, the connection sleeves 18a, 18b form a tubular portion of substantially constant dimensions from the collection box to their free end 180a, 180b, with one of the connection sleeves, forming the male sleeve, which has an outer face 28 whose diameter is slightly smaller than the diameter of the inner face 30 of the other connection sleeve, forming the female sleeve.

Whatever the embodiment variant, a first male connection sleeve associated with the collection box comprises means of cooperation with a female connection sleeve of a first thermal regulation device neighbor which are arranged on its outer face 28 and a second female connection sleeve, arranged opposite the first male connection sleeve with respect to said collection box, comprises means of cooperation with a male connection sleeve of a second neighboring thermal regulation device which are arranged on its internal face 30.

The shape of each of these sleeves participates in forming means 32 of cooperation of the connection sleeves between them, with a zone of the internal face 30 of a female connection sleeve 18b which is sized and shaped to be in contact with a area of the outer face 28 of a male connection sleeve 18a.

Furthermore, at the level of the internal 30 and external 28 faces of the connection sleeves intended to be in contact with a corresponding surface of another sleeve and forming these means of cooperation 32, a zone 34 for receiving a seal ring 36 is provided. This annular seal 36 protrudes from the corresponding face of the connection sleeve of the first or second type 18a, 18b. In the example illustrated, the annular seal 36 forms a projection from the external face 28 of the male connection sleeve, but it will be understood that it could be associated with a female connection sleeve and form a projection from the internal face 30 of the last. As can be seen in particular in FIG. 6, the reception zone 34 of the annular seal 36 may comprise a groove 38 formed in the thickness of the corresponding face of the connection sleeve and sized to accommodate the at least one ring seal 36.

As mentioned, two connection sleeves form a pair 19 by being aligned and arranged on either side of the collection box 10. In the illustrated embodiment, the thermal regulation device 4 is such that two pairs 19 connecting sleeves are integral with the collection box 10, again forming a one-piece assembly, with for each pair a connecting sleeve disposed on either side of the collection box. In this way, each pair 19 of connection sleeves can communicate with one of the collection chambers 10. In this context of collection chamber with two pairs of connection sleeves, and as illustrated in FIG. 5 in particular, a connection sleeve of a first pair of connection sleeves arranged on a first side of the collection box 10 has a shape and dimensions identical to those of a connection sleeve of the second pair of connection sleeves arranged on the second side of the collection box 10.

In this way and as can be seen in Figure 6, the direct cooperation of the connection sleeves in the example illustrated with two pairs of connection sleeves contributes to creating two parallel ducts, namely the heat transfer fluid inlet duct 14 and the heat transfer fluid discharge duct 16.

FIG. 7 makes particularly visible the fact that the collection box 10 of the thermal regulation device 4 comprises within it collection chambers 26 fluidly communicating respectively with at least one of the circulation channels 8 formed within the tube, and more particularly one of the circulation assemblies 21, 22 formed by several channels.

The collection box 10 is here formed by two shells 11 attached and fixed against each other, with fixing means on the periphery of the shells. At least one shell has hooking lugs 40 which allow the shells to be held together before a soldering operation freezing the position of the shells and the holding of the collection box.

Each shell 11 has two hollows 42 formed by deformation of the shell and a rib 44 placed between the two hollows. It is understood that when the shells are fixed to each other, the hollows 42 of each shell 11 are arranged opposite to form the collection chambers 26 mentioned above and the ribs 44 of each shell 11 are in contact with one another. on the other to form a central wall 46 which delimits and separates the collection chambers 26 from each other.

This central wall 46 is intended to be in contact with a solid surface of the tube forming a sealing zone 48, devoid of circulation channels, in order to ensure sealed contact and to prevent that within the collection box , the fluid present in a first collection chamber does not flow into the other collection chamber, or into channels which should not be connected to this first collection chamber. Each hollow 42 is defined by a bottom wall 41 which is pierced with an orifice 43 substantially at its center. This orifice allows a passage of fluid between the collection chamber 26 formed by the hollow and a connection sleeve 18 of the pair of connection sleeves opening into this collection chamber 26.

Each shell 11 is equipped with two connection sleeves 18a, 18b which respectively open into one of the two hollows 42 formed in this shell 11.

In other words, the connection sleeves are configured to communicate each with a collection chamber, and it is understood that the sleeves arranged on either side of the collection box are configured to communicate with the same collection chamber.

The thermal regulation device 4 as it has just been described can be produced by a particular assembly of the invention, during which the collection box 10 is formed by assembling two shells 11 one against the other. and in which the tube 6 and the collection box 10 disposed at one longitudinal end of the tube are assembled together.

In particular, provision is made in a first step to bring the tube 6, via a longitudinal end face 12, into contact with a shell 11 of the collection box 10, and more particularly by bringing the zone of sealing 48 present in the tube 6 against the rib 44 of this shell 11.

In a next step, the second shell participating in forming the collection box

10 is attached against the first shell, so as to enclose the longitudinal end 12 of the tube 6 between the two shells 11. The shells can be held against each other by cooperation of the hooking lugs 40 present on a shell with the edge of the other shell.

11 should be noted that the second shell is fitted against the first shell so that the rib 44 of this second shell is pressed both against the rib 44 of the first shell and against the sealing zone 48 of the tube. In this way, the sealing zone 48 is found against the central wall 46 of the collection box formed by the grouping of the ribs 44 of the two shells.

Once the tube 6 has been correctly inserted into the collection box 10, the assembly thus formed is brazed. We will now describe a method for assembling an electrical energy storage device i as it has been described previously.

The thermal regulation devices are prepared beforehand by brazing a header box, connection sleeves and a tube, so as to form a one-piece assembly, as just described. A seal is then attached, after this brazing operation, to one of the connection sleeves of a pair of connection sleeves integral with a header box.

The method is particular according to the invention in that it comprises at least a first step during which electrical energy storage members 2 are deposited against a tube 6 of a first thermal regulation device 4. During this step, it can in particular be carried out a step of depositing glue against the face of the tube intended to be in contact with the electrical energy storage members.

Secondly, a tube 6 of a second thermal regulation device is placed against the electrical energy storage devices 2 previously deposited. The pressure exerted against the electrical energy storage members participates in pressing them against the first tube and ensures the bonding between this first tube and the electrical energy storage members.

At the same time, the connection sleeves 18 associated with this tube 6 of the second thermal regulation device 4 and arranged on one side of the collection box 10 of this second device are inserted directly into the connection sleeves 18 associated with the tube of the first device and arranged on one side of the collection box of the first device facing the second device.

Figure 8 makes particularly visible a tube 6 of a thermal regulation device 4 for cooling electrical energy storage devices, the tube extending along a main longitudinal direction of elongation according to the orientation mentioned above.

The tube 6 is configured in such a way as to comprise a plurality of longitudinal channels 8 for the circulation of heat transfer fluid formed side by side in the material inside the tube. In the example illustrated in Figure 8, these channels have a rectangular passage section, without this being limiting of the invention. The channels pass through, so that they open out on each longitudinal end face 12 of the tube 6. As mentioned above, the longitudinal circulation channels 8 are divided into a first heat transfer fluid circulation assembly 21 and a second heat transfer fluid circulation assembly 22, which allow in particular the circulation of heat transfer fluid in two opposite directions within the tube 6.

As previously mentioned, on at least one longitudinal end face 12 of tube 6, a sealing zone 48 is arranged between the channels participating in forming the first circulation assembly 21 and the channels participating in forming the second circulation set 22.

The sealing zone 48 is a solid zone formed in a longitudinal end face 12 of the tube 6. The sealing zone can in particular be placed in the center of the longitudinal end face 12 of the tube according to the transverse dimension.

This solid zone can either be formed by the material of the tube, no orifice being dug in the material of this zone, or be obtained by means of a closure device, that is to say a contribution material room, overlapping an orifice opening onto this longitudinal end face.

In the first case, the sealing zone 48 extends over the entire longitudinal dimension of the tube 6, from one longitudinal end face 12 to the other, and for this purpose, a strip of longitudinal material, extending from one end face to the other, is not pierced by a circulation channel.

In the second case, the sealing zone 48 extends only over the longitudinal end face(s) 12 of the tube. Channels 8 extend at regular intervals over the entire transverse dimension of the tube, and a plug covers a channel on one end face, or a plate covers the end of several neighboring channels.

In more detail, each circulation assembly 21, 22 comprises a transverse alignment of several longitudinal circulation channels 8 arranged in parallel with respect to each other. The transverse alignment of the canals of the first set of circulation can in particular be confused with the transverse alignment of the channels of the second set of circulation. The sealing zone 48 is arranged on the transverse alignment of each of the circulation assemblies.

A distinction should be made between the sealing zone 48 and the walls 50 delimiting neighboring channels 8 of the same circulation assembly. The sealing zone must in particular be large enough to serve as a support surface for the central wall 46 of the corresponding collection box 10.

More particularly, the sealing zone 48 extends between the two circulation assemblies 21, 22 over a transverse dimension at least equal to the corresponding transverse dimension of a longitudinal channel of one of the two circulation assemblies.

A variant embodiment of the invention is illustrated in FIG. 9, which differs from what has been previously described in that there are additionally provided fastening means 52 to make it possible to ensure the position of the connecting sleeves brought into direct cooperation with each other.

In this variant, one of the connection sleeves 18 of a pair of connection sleeves of the thermal regulation device comprises a slot 54 passing through the thickness of this sleeve from the internal face 30 to the external face 28, and the fixing means comprise, in addition to this light, a fixing clip 56 capable of being inserted into the light once this sleeve is in direct cooperation with the connection sleeve of a neighboring thermal regulation device.

The fixing clip 56 is sized so that a branch 58 passing through the slot 54 faces an abutment surface formed in the connecting sleeve of the neighboring thermal regulation device. In order to ensure the retaining function of the fastening means, the branch 58 of the clip can be housed in a groove formed in the external face of the connection sleeve of the neighboring thermal regulation device.

In the example illustrated, two diametrically opposed slots are formed on a sleeve and the fixing clip has two branches sized to be housed respectively in each of these slots. Another difference consists in that the thermal regulation device comprises two distinct tubes which are connected by the same header box, instead of a single tube as previously described. Such an embodiment can in particular make it possible to ensure that the heat transfer fluid circulates distinctly in each circulation channel, by simplifying the problem of sealing between the collection chambers within the collection box and the circulation channels.

In accordance with the invention, this alternative embodiment allows direct cooperation of the connection sleeves, as illustrated in FIG. 10, without any intermediate part between the connection sleeves other than the seal.

Figure io makes visible for this alternative embodiment the positioning of the fixing clip 56 passed through the slot 54 to be housed in a notch.

Figures 11 and 12 illustrate alternative embodiments of the tube, as previously described with reference to Figure 8.

In a first alternative, illustrated in Figure 11, the tube 6 differs from what was previously described in that the transverse dimension of the sealing zone 48 is larger. More particularly, the transverse dimension of the sealing zone can be equal to at least twice the vertical dimension of a channel 8 for the circulation of heat transfer fluid. The vertical dimension is a compromise between a surface large enough to ensure sealing and a surface that does not strongly impact the quantity of heat transfer fluid that can circulate in a circulation assembly within the tube.

In a second alternative, illustrated in FIG. 12, the tube 6 differs from what has been previously described in that the thickness of the sealing zone 48, that is to say a transverse dimension perpendicular to the vertical dimensions and longitudinal of the tube, is reduced compared to the transverse dimension of the tube of the tube. This allows a lightening of the tube by removal of material, in an area where it is not advantageous in terms of heat exchange to have contact with the electrical energy storage devices since no heat transfer fluid circulates in this sealing area. The invention as it has just been described makes it possible to meet the objectives it had set itself, namely to propose a thermal regulation device, in particular for an electrical energy storage device, in which the compartmentation heat transfer fluid circulation zones is improved. This is possible thanks to the production of a special sealing zone in a tube pierced with heat transfer fluid circulation channels, said sealing zone forming on a longitudinal end face of the tube a solid contact surface against which abut a rib of a collection chamber secured to the tube. 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. By way of non-limiting example, and as may have been mentioned previously, the number and shapes of the channels arranged in the tube may vary when the channels are grouped into at least two distinct circulation sets separated by a zone sealing according to the invention, that is to say large enough to be distinct from the walls delimiting two neighboring channels of the same circulation assembly.

Claims

1. Tube (6) of a thermal regulation device (4) for cooling electrical energy storage devices (2), the tube (6) extending along a main longitudinal direction of elongation and comprising a plurality of longitudinal channels (8) for the circulation of heat transfer fluid formed side by side in the material inside the tube and which open onto each longitudinal end face (12) of the tube, the longitudinal channels being distributed into a first heat transfer fluid circulation assembly (21) and a second heat transfer fluid circulation assembly (22), characterized in that at least one longitudinal end face (12) of the tube (6) has a zone of sealing (48) which is arranged between the channels participating in forming the first circulation assembly (21) and the channels participating in forming the second circulation assembly (22).

2. Tube (6) according to claim 1, in which each circulation assembly (21, 22) comprises a transverse alignment of several longitudinal channels (8) arranged in parallel with respect to each other, and in which the zone of sealing (48) is arranged on the transverse alignment of each of the circulation assemblies.

3. Tube (6) according to claim 1 or 2, wherein the sealing zone (48) extends between the two circulation assemblies (21, 22) over a transverse dimension at least equal to the corresponding transverse dimension d a channel (8) longitudinal to one of the two sets of circulation.

4. Tube (6) according to one of the preceding claims, wherein the sealing zone (48) extends over the entire longitudinal dimension of the tube (6), from one end face (12) to the 'other.

5. Tube (6) according to one of claims 1 to 3, wherein the sealing zone (48) extends only over the longitudinal end face(s) (12) of the tube (6).

6. Tube (6) according to one of the preceding claims, in which the sealing zone (48) is arranged at the center of the tube along the transverse dimension.

7. Thermal regulation device (4) for cooling electrical energy storage members (2), comprising a tube (6) according to one of the preceding claims and configured to be in contact with the storage of electrical energy (2), and further comprising a collection box (10) arranged at one end of the tube and comprising within it collection chambers (26) fluidly communicating respectively with the channels of the first circulation assembly ( 21) and the channels of the second circulation assembly (22), and at least two connection sleeves (18) arranged on either side of the collection box and configured to communicate with the same collection chamber (26).

8. Thermal regulation device (4) according to the preceding claim, in which the collection chambers (26) are delimited by a common central wall (46) formed in the collection box (10), said central wall (46) being bearing against the sealing zone (48) when the collection box (10) and the tube (6) are integral with one another.

9. Thermal regulation device (4) according to the preceding claim, in which the collection box (10) is formed by two shells (11) fixed one on the other, each shell having two recesses (42) formed by deformation of the shell participating in forming respectively a collection chamber (26) and a rib (44) disposed between the two hollows, the rib of each shell being intended to be in contact with the rib of the other shell to form said wall central (46).

10. Electrical energy storage device (1) for an electric or hybrid vehicle, comprising several sets of electrical energy storage members (2) and several thermal regulation devices (4) according to one of claims 7 to 9, each thermal regulation device (4) being arranged between two sets of electrical energy storage members (2).

11. Storage device according to the preceding claim, in which two neighboring thermal regulation devices (4) are configured to be connected in a sealed manner by direct cooperation of a connection sleeve (18) of a first thermal regulation device, equipped with a seal (36), with a connection sleeve (18) of a second thermal regulation device.

12. A method of assembling a thermal regulation device (4) according to one of claims 7 to 9, in which:

- the collection box (10) is formed by assembling two shells (11) one against the other, - a longitudinal end face (12) of the tube (6) provided with a sealing zone (48) is inserted inside the collection box (10) until the central wall (46 ) formed in the collection box (10) or in contact with the sealing zone, - the assembly formed by the collection box (10) and the tube (6) is brazed.