WO2018154249A1 - Thermal conditioning system for a motor vehicle, using a battery pack thermal management device - Google Patents

Abstract

A thermal conditioning system for a motor vehicle comprising: - a first air conditioning circuit in which a coolant flows, - a second circuit for the thermal regulation of at least one electrical energy storage element (150), comprising a thermal management device (100) in thermal contact with the at least one electrical energy storage element (150), which thermal management device (100) comprises at least one flow channel for a heat transfer fluid suitable for exchanging heat with the at least one electrical energy storage element (150), the ends of which channel lead, respectively, into a heat transfer fluid intake manifold (120) and a heat transfer fluid discharge manifold (140); the second thermal regulation circuit communicates with the first air conditioning circuit such that heat exchange can take place between the heat transfer fluid and the coolant in order to cool, for instance, the at least one electrical energy storage element (150). According to the invention, the heat transfer fluid intake manifold (120) of the thermal management device (100) comprises a first conduit (130) through which the coolant of the first air conditioning circuit flows.

Description

 Thermal conditioning system of a motor vehicle implementing a device for thermal management of a battery pack

1. Field of the invention

 The present invention relates to the thermal regulation of a set of at least one battery.

 The invention more particularly relates to a heat transfer fluid thermal regulation device for a set of at least one battery in the field of motor vehicles with electric drive and / or hybrid.

 The invention also relates to a thermal conditioning system of a motor vehicle implementing such a thermal regulation device.

 2. Prior Art

 The electrical energy of electrically and / or hybrid powered vehicles is provided by one or more batteries.

 In this type of vehicle, the battery is generally formed of a plurality of electric cells arranged in a protective housing to form what is called a battery pack.

 A problem is that during operation, the batteries are heated and may be damaged.

 In addition, if the temperature is too low, the battery life can decrease sharply.

 The thermal regulation of the battery is, therefore, an important point.

 In fact, the temperature of the battery must remain between 20 ° C and

40 ° C to ensure reliability, battery life and vehicle performance while maximizing battery life.

This regulation of the temperature of the battery, and in particular its cooling is ensured by means of a coolant which circulates in a thermal management device placed inside the battery pack housing and consisting of a heat exchange plate, in contact with the electric cells, so as to regulate their temperature by thermal conduction.

 A heat exchange plate is generally made of a thermally conductive material and is composed of two plates placed one against the other in order to form one or more heat transfer fluid circulation channels, the ends of which are connected respectively to a collector. .

 Such a circuit (or loop) for thermal regulation 6 of the batteries, illustrated schematically in FIG. 1, furthermore comprises a pump P for forcing the circulation of the heat transfer fluid inside the heat exchange plate of the cooling device. thermal management 2.

 The heat transfer fluid can thus absorb heat emitted by the electric cells in order to cool them and evacuate this heat at a heat exchanger 4, located outside the battery pack housing.

 The heat transfer fluid can also, if necessary, bring heat to heat the electric cells.

 To do this, the thermal control loop 6 comprises an additional heating device H, using, for example, electrical resistors or resistors with a positive temperature coefficient.

 Such an additional heating device is essential for regulating the temperature of the electric cells, especially at low temperatures in winter, where it is necessary to increase the temperature of the electric cells before starting to charge them.

 Moreover, the vehicles are frequently equipped with a heating, ventilation and / or air conditioning system for thermally regulating the interior space of the passenger compartment of the vehicle by delivering an interior air flow at the desired temperature.

The heating, ventilation and / or air conditioning installation generally comprises an air conditioning loop 13 inside which circulates a refrigerant fluid, and more specifically a main loop 14 comprising a compressor 16 forcing the flow of refrigerant in this main loop 14 so that it passes through a condenser 17 before passing through an expansion device, or expander, TXVl then an evaporator 18 ( for cooling air to flow to the passenger compartment of the vehicle, before reaching the compressor again 16.

 In this main loop 14, the refrigerating fluid thus carries out a thermodynamic cycle in which it discharges its heat at the condenser 17, and in which it captures the heat at the level of the evaporator 18.

 In some cases, the thermal regulation loop 6 of the electric cells is in relation with the air conditioning loop 13, so as to allow a heat exchange between the coolant and the heat transfer fluid, in particular for cooling the electric cells.

 The heat transfer fluid of the thermal control circuit 6 of the electric cells can thus be cooled by circulation in the heat exchanger 4 of coolant / coolant type, which is connected to the air conditioning loop 13.

 More specifically, the main loop 14 is connected to the heat exchanger 4 via another bypass loop 21, which is connected to the output of the condenser 17 and the input of the compressor 16.

 This bypass loop 21 comprises a TXV 2 expander that the refrigerant crosses before circulating in the heat exchanger 4 and then return to the main loop by being fed back to the input of the compressor 16.

 However, such a solution using the air conditioning loop for cooling but requiring an additional heating device for heating the battery and a pump, is cumbersome and does not meet the current requirements of the automotive field.

Indeed, because of the perpetual increase of the level electrification of hybrid and electric vehicles, it is necessary to increase the amount of storage cells of electrical energy.

 However, the space allocated to the integration of such electric cells is limited, so that it is necessary to optimize the size of the thermal regulation circuit of the electric cells.

3. Summary of the invention

 The invention proposes for this purpose a thermal conditioning system of a motor vehicle comprising:

 a first air conditioning circuit in which a refrigerant circulates,

 a second thermal regulation circuit of at least one electrical energy storage element, comprising a thermal management device disposed in thermal contact with said at least one electrical energy storage element, said thermal management device comprising at least one less a heat transfer fluid circulation channel able to heat exchange with said at least one electrical energy storage element and the ends of which penetrate into a heat transfer fluid intake manifold and a heat transfer fluid outlet manifold respectively ,

 the second thermal regulation circuit being in relation with the first air conditioning circuit so as to allow a heat exchange between the coolant and the coolant, for example for cooling said at least one electrical energy storage element,

According to the invention, the heat transfer fluid intake manifold of the thermal management device comprises a first refrigerant passage of the first air conditioning circuit.

The present invention thus proposes a new type of electrical cell thermal management device which is implemented in a thermal regulation loop in connection with the air conditioning loop of a vehicle, so as to allow a heat exchange between the coolant and the heat transfer fluid, in particular for cooling the electric cells.

 More precisely, the thermal regulation device simultaneously performs the functions of thermal management of the electric cells and heat exchange between the heat transfer fluid of the thermal regulation loop and the cooling fluid of the air conditioning loop.

 To do this, a duct of the air conditioning loop carrying the refrigerant fluid passes through the intake manifold of the thermal control device of the electric cells.

 The heat transfer fluid can thus absorb heat emitted by the electric cells in order to cool them and evacuate this heat, not at the level of an additional heat exchanger as described in the prior art, but at the level of the collector. admission of heat transfer fluid of the thermal management device in which the coolant is in thermal contact with the refrigerant.

 In other words, the thermal regulation loop thermally exchanges with the air conditioning loop inside the thermal management device.

 The approach of the invention therefore makes it possible to reduce, in a general manner, the bulk and the weight of the thermal regulation circuit of the electric cells forming the battery, by the elimination of a cumbersome and expensive heat exchanger and by the decrease in fluidic connections.

More generally, this reduces the size of the thermal conditioning system in the motor vehicle, facilitate installation and minimize the risk of non-sealing by reducing the number of fluid connections. According to a particular aspect of the invention, the intake manifold and the heat transfer fluid outlet manifold of the thermal management device respectively comprise an inlet port and a heat transfer fluid outlet port.

 According to a particular aspect of the invention, the intake manifold comprises an internal partition delimiting:

 a first cooling fluid coolant chamber, in which the heat transfer fluid inlet port opens and the first refrigerant fluid duct extends at least in part, and

a second so-called homogenization chamber for the coolant fluidly communicating with the first chamber and in which an end of said at least one circulation channel of a heat transfer fluid opens.

 According to a particular embodiment of the invention, the first coolant passageway has a coolant inlet located at one end of said intake manifold and a coolant outlet located at the opposite end of said coolant manifold. admission.

 Advantageously, said first conduit for the passage of a refrigerant fluid is of rectilinear shape.

 According to a particular embodiment of the invention, the first refrigerant passageway has a coolant inlet and a coolant outlet located at the same end of said intake manifold.

 Advantageously, said first refrigerant passage conduit has a substantially U-shaped, a first portion of said first conduit extending into the first chamber and a second portion extending into the second chamber.

According to a particular embodiment of the invention, the heat transfer fluid outlet manifold of the thermal management device comprises a second refrigerant passage of the first air conditioning circuit fluidly communicating with the first conduit.

 Advantageously, the first refrigerant passageway has a refrigerant inlet located at one end of said intake manifold and the second refrigerant passageway has a refrigerant outlet located at an end of said exhaust manifold. said coolant inlet and outlet being located on the same side of said thermal management device.

 Advantageously, the first duct and the second duct are connected by a connecting duct situated on one side of said thermal management device opposite to the refrigerant inlet and outlet.

 According to a particular embodiment of the invention, said first refrigerant passage conduit has a substantially U-shaped shape, a first portion of said first conduit extending into the first chamber and a second portion of said first conduit extending into the second chamber, the coolant discharge manifold of the thermal management device comprising a second refrigerant passage of the first air conditioning circuit fluidly communicating with the first conduit and having a substantially U-shape.

 According to a particular aspect of the invention, the ends of the first and second refrigerant passage ducts are connected in pairs by a first and second connection ducts extending on the same side of the thermal management device.

 According to a particular aspect of the invention, the first connecting duct has a refrigerant inlet and said second connecting duct has a refrigerant outlet.

According to a particular aspect of the invention, the refrigerant inlet and the coolant outlet are connected to a pressure regulator mounted on the thermal management device. According to a particular aspect of the invention, the thermal conditioning system comprises a pump for forcing the circulation of the coolant in the second thermal regulation circuit, said pump being mounted on the thermal management device.

 The invention also relates to a thermal management device intended to be implemented in a thermal regulation circuit of at least one electrical energy storage element of a thermal conditioning system of a motor vehicle, said system of thermal conditioning further comprising an air conditioning circuit in which a cooling fluid circulates, said thermal management device being intended to come into thermal contact with said at least one electrical energy storage element, said thermal management device comprising at least one a heat transfer fluid circulation channel adapted to heat exchange with said at least one electrical energy storage element and whose ends penetrate into a heat transfer fluid intake manifold and a heat transfer fluid outlet manifold respectively, the thermal regulation circuit being intended to be put in relation with the air conditioning circuit so as to allow a heat exchange between the coolant and the coolant, for example for cooling said at least one electrical energy storage element.

 According to the invention, the heat transfer fluid intake manifold of the thermal management device comprises a first refrigerant flow passage intended to be connected to the first air conditioning circuit.

 The invention therefore proposes a thermal regulation device making it possible to improve the compactness and the tightness of the thermal regulation circuits, in particular of a storage cell for electrical energy of a motor vehicle.

To do this, the thermal regulation device comprises in a same collector box at least, a portion of the refrigerant circuit and a portion of the cooling circuit, the manifold being in fluid communication with a plurality of cooling channels, themselves in contact with one or more cells for storing electrical energy.

4. List of figures

 Other features and advantages of the invention will appear on reading the following description of particular embodiments, given as simple illustrative and non-limiting examples, and the appended figures, namely:

 Figure 1 is a schematic representation of a thermal conditioning system of a motor vehicle according to the prior art;

 FIG. 2 is a schematic representation of a first embodiment of a thermal management device according to the invention; FIG. 3 schematically represents a second embodiment of a thermal management device according to the invention;

 FIG. 4 schematically represents a third embodiment of a thermal management device according to the invention, and

 FIG. 5 schematically represents a fourth embodiment of a thermal management device according to the invention.

5. Detailed description of the invention

The thermal conditioning system of an electric vehicle according to the invention comprises a first circuit, or loop, of air conditioning and a second circuit of thermal regulation of a battery of the vehicle. This second circuit comprises a thermal management device for regulating the temperature of several electrical energy storage elements, called electrical cells, constituting the battery, either by heating the cells or by cooling them.

 This thermal management device is arranged with the electric cells in a sealed and sealed housing thus forming a battery pack.

 Unlike the prior art approach according to which the heat transfer liquid of the thermal regulation circuit is cooled by circulation in a heat exchanger / coolant type heat exchanger, which is connected to the air conditioning loop and which is distinct from the cooling device. thermal management, the invention provides that the coolant liquid is cooled by the coolant in the thermal management device of the electric cells.

 More specifically, the coolant is cooled by the coolant at the heat transfer fluid intake manifold of the thermal management device, the intake manifold communicating with a heat exchange plate in contact with the battery.

 Figures 2 to 5 illustrate different embodiments of the thermal management device of the invention, the references to the identical elements being incremented by one hundred with each change of embodiment.

 FIG. 2 illustrates a first embodiment of the thermal management device 100 of the battery of a vehicle.

As illustrated in FIG. 2, the heat exchanges between the electrical cells 150 _" and the thermal management device 100 are implemented at a heat exchange plate 110 on which the electrical cells 150 rest.

This heat exchange plate 110 comprises at least one internal channel, and preferably a plurality of internal channels (not shown), in which circulates a coolant which is here water. The thermal management device 100 comprises two collectors 120, 140 in fluid communication with the internal channels of the heat exchange plate 110, and disposed on either side of the heat exchange plate 110 and the electric cells 150.

 The intake manifold 120 comprises at one of its ends a heat transfer fluid inlet port 121 for the distribution of the coolant in the thermal management device 100.

 The exhaust manifold 140 comprises at one of its ends an outlet port 141 of heat transfer fluid to evacuate the thermal control device 100 the heat transfer fluid.

 Thus, the input port 121 and the heat transfer fluid outlet port 141 are situated substantially on the same side of the thermal management device 100.

 In this configuration, the heat transfer fluid is admitted by one of the two manifolds, said intake manifold 120, and is evacuated by the other of the two collectors, said exhaust manifold 140.

 The connection between the two collectors 120, 140 is effected by the plurality of internal channels, which extend along the electric cells 150 and ensure a unidirectional circulation of the coolant. This is called "I" circulation.

 Furthermore, the heat transfer fluid is set in motion in the internal channel circuit via a pump.

 In this first embodiment, the intake manifold 120 comprises a rectilinear duct 130 for the passage of refrigerant circulating in the first air conditioning circuit.

 Thus, the second circuit of thermal regulation of the electric cells

150 is in relation with the first air conditioning circuit so as to allow a heat exchange between the coolant and the coolant, for example for cooling the electric cells 150. The conduit 130 for circulating the coolant enters at one end of the intake manifold 120, on the side of the heat-transfer fluid inlet port 121, and exits through the opposite end of the intake manifold 120.

 The inlet and outlet of the refrigerant in the intake manifold 120 are referenced 131 and 132 respectively.

 Consequently, the conduit 130 for the passage of the refrigerant fluid passes through the thermal management device at the level of the intake manifold 120.

 It is thus understood that the coolant which has, for example, absorbed the heat energy of the electric cells 150 through the heat exchange plate 110 is collected by the exhaust manifold 140, then directed to the intake manifold 120 through conduits not shown.

 In the intake manifold 120, the heat transfer fluid can release its heat energy because the intake manifold 120 also has a conduit 130 through which the cooling fluid of the air conditioning circuit passes.

 In the opposite case where it is desired to heat the electric cells 150, the second thermal regulation circuit is connected to a heating device, using for example electrical resistors or resistors with a positive temperature coefficient. The coolant then makes it possible to bring the heat energy to the electric cells 150 via the heat exchange plate 110.

 Note that the intake manifold 120 comprises an internal partition 122 which extends along the longitudinal axis of the intake manifold 120 and has a length slightly less than the length of the interior space of the intake manifold 120.

One of the longitudinal ends of the internal wall 122 is fixed against an end wall of the intake manifold 120, on the side of the heat transfer fluid inlet port 121. Thus, the internal partition 122 makes it possible to define a substantially U-shaped heat transfer fluid conduit inside the intake manifold 120.

 This internal partition 122 thus separates the interior space of the intake manifold 120 into two chambers or zones, namely:

 a first cooling chamber 123 for the coolant in which the rectilinear duct 130 for the circulation of the refrigerant fluid extends and into which the heat transfer fluid inlet port 121 opens, and

 a second chamber, called the heat transfer fluid temperature homogenization chamber 124, which comprises the connections to the internal channels of the heat exchange plate 110 and which communicates with the cooling chamber 123 via a passage located at the end of the intake manifold 120 opposite the inlet port 121 of heat transfer fluid.

 A first heat exchange is thus implemented between the coolant and the coolant in the intake manifold 120 of the thermal management device 100, and more precisely in the cooling chamber 123.

 A second heat exchange is implemented between the electric cells 150 and the coolant circulating in the internal channels of the heat exchange plate 110 of the thermal management device 100.

 In the "cooling" mode of operation of the electric cells 150, the refrigerant entering the intake manifold 120, flowing in the duct 130, absorbs the heat of the coolant while evaporating, which has the effect of to cool the coolant and thus the electrical cells 150 constituting the battery of the vehicle.

Thus, the heat transfer fluid is cooled in the thermal management device 100 by the refrigerant of the air conditioning system which also circulates in this device. In the so-called "heating" operating mode, the refrigerant entering the intake manifold 120, circulating in the duct 130, transfers heat from the coolant condensing, which has the effect of heating the fluid coolant and therefore the electrical cells 150.

 FIG. 3 illustrates a second embodiment of the thermal management device 200 of the battery of a vehicle.

 In this second embodiment, the intake manifold 220 comprises a conduit 130 for circulating the coolant, which has a substantially U-shaped shape, so that the inlet 231 and the refrigerant outlet 232 are located on the same end of the intake manifold 220, the side of the heat transfer fluid inlet port 221.

 A first portion of the duct 230 extends longitudinally in the cooling chamber 223 along one face of the internal partition 222, bypasses the end of the internal partition 222 and the second portion extends longitudinally in the chamber of the internal partition 222. homogenization 224 along the other side of the internal partition 222.

 This particular arrangement of the inlet 230 and the outlet 231 of refrigerant fluid facilitates their connection to an expansion member, or expander, 206 of the refrigerant fluid mounted on the thermal management device 200, and more precisely on the collector 220 admission.

 In addition, the particular shape of the conduit 230 makes it possible to optimize the heat exchange between the coolant and the coolant.

 FIG. 4 illustrates a third embodiment of the thermal management device 300 of the battery of a vehicle.

In this third embodiment, the intake manifold 320 comprises in the cooling chamber 323 a conduit 330 for circulating a refrigerant fluid opening at each longitudinal end of the intake manifold 320. The coolant inlet 331 is located near the heat transfer fluid inlet port 321.

 Similarly, the exhaust manifold 340 comprises a straight conduit 330 'for the circulation of the refrigerant fluid opening at each longitudinal end of the exhaust manifold 340.

 The outlet 332 of coolant 332 is located near the heat transfer fluid outlet port 341.

 The ends of the coolant circulation ducts 330, 330 'opposite respectively to the inlet 331 and to the refrigerant outlet 332 are interconnected by a connecting duct 333.

 Thus, the conduits 330, 330 ', 333 define a substantially U-shape refrigerant circulation circuit, the refrigerant circulating in the intake manifold 320, then in the exhaust manifold 340 via the connecting duct 340 In these manifolds 320, 340, the coolant is in thermal contact with the heat transfer fluid.

 In this embodiment, the conduits 330, 330 ', 300 are preferably rectilinear conduits.

 FIG. 5 illustrates a fourth embodiment of the thermal management device 400 of the battery of a vehicle.

 In this fourth embodiment, the intake manifold 420 comprises a substantially U-shaped refrigerant circulation duct 430, bypassing the internal partition 422.

 The exhaust manifold 440 also comprises a duct 430 'circulating the refrigerant fluid, substantially U-shaped.

The free ends of the ducts 430, 430 'are connected in pairs by a first connecting duct 433 and a second connecting duct 433' respectively. These connecting ducts 433, 433 'are disposed on the same side of the thermal management device 400, namely on the side of the input port 421 and the output port 441 of the heat transfer fluid.

 The first connecting duct 433 comprises a refrigerant inlet 431 and the second connecting duct 433 'comprises a refrigerant outlet 432.

 The coolant entering the thermal management device 400 through the inlet 431 is distributed in the conduits 430, 430 'U disposed in the collectors 420, 440 respectively. Once the coolant has circulated in the manifolds 420, 440, it is directed to the outlet 432.

 This particular arrangement of the inlet 431 and the outlet 432 of refrigerant fluid facilitates their connection to an expansion member, or expander 406, of the refrigerant fluid mounted on the thermal management device 400.

 In these collectors 420, 440, the coolant is in thermal contact with the coolant.

 It is thus noted that in all these embodiments, the coolant pump, or water pump, can be assembled on the intake manifold of the thermal management device.

 Of course, the invention is not limited to the embodiments described above and provided solely by way of example. It encompasses various modifications, alternative forms and other variants that may be considered by those skilled in the art in the context of the present invention and in particular any combination of the different modes of operation described above, which can be taken separately or in combination.

Claims

A thermal conditioning system of a motor vehicle comprising:

 a first air conditioning circuit in which a refrigerant circulates,

 a second thermal regulation circuit of at least one electrical energy storage element (150), comprising a thermal management device (100) disposed in thermal contact with said at least one electrical energy storage element (150); ), said thermal management device (100) comprising at least one circulation channel of a heat transfer fluid able to heat exchange with said at least one electrical energy storage element (150) and the ends of which penetrate into a collector d an inlet (120) for the coolant and an outlet manifold (140) for the coolant respectively,

 the second thermal regulation circuit being in relation with the first air conditioning circuit so as to allow a heat exchange between the coolant and the coolant, for example for cooling said at least one electrical energy storage element (150) ,

characterized in that the intake manifold (120) of heat transfer fluid of the thermal management device (100) comprises a first conduit (130) for passage of the refrigerant fluid of the first air conditioning circuit. Thermal conditioning system according to claim 1, characterized in that the intake manifold (120) and the heat transfer fluid discharge manifold (140) of the thermal management device (100) respectively comprise an inlet port. (121) and an outlet port (141) of heat transfer fluid.

3. Thermal conditioning system according to claim 2, characterized in that the intake manifold (120) comprises an internal partition (122) delimiting:

a first chamber (123) for cooling the coolant, in which the heat transfer fluid inlet port (121) opens and the first refrigerant fluid duct (130) extends at least in part, and

- A second chamber (124) said homogenization of the heat transfer fluid fluidly communicating with the first chamber (123) and wherein an end of said at least one heat transfer fluid circulation channel opens.

4. Thermal conditioning system according to one of claims 1 to 3, characterized in that the first conduit (130) for passage of the refrigerant fluid has a coolant inlet (131) located at one end of said intake manifold ( 120) and a coolant outlet (132) at the opposite end of said intake manifold (120).

5. Thermal conditioning system according to claim 4, characterized in that said first conduit (130) for the passage of a refrigerant fluid is of rectilinear shape.

6. Thermal conditioning system according to one of claims 1 to 3, characterized in that the first conduit (230) for passage of the refrigerant fluid has a coolant inlet (231) and a refrigerant outlet (232) located at the same end of said intake manifold

7. Thermal conditioning system according to claim 6 when dependent on claim 3, characterized in that said first conduit (230) for passage of the refrigerant fluid has a substantially U-shaped, a first portion of said first conduit (230). extending into the first chamber (223) and a second portion extending into the second chamber (224).

8. Thermal conditioning system according to one of claims 1 to 3, characterized in that the exhaust manifold (340) of the heat transfer fluid of the thermal management device (300) comprises a second conduit (330 ') of passage of the refrigerant fluid of the first air conditioning circuit fluidly communicating with the first conduit (330).

9. Thermal conditioning system according to claim 8, characterized in that the first conduit (330) for the passage of the refrigerant fluid has a coolant inlet (331) located at one end of said intake manifold (320) and the second conduit (330 ') for passage of refrigerant fluid has an outlet (332) for refrigerant fluid at an end of said exhaust manifold (340), said refrigerant inlet and outlet (331, 332) being located on the same side said thermal management device (300).

Thermal conditioning system according to claim 9, characterized in that the first duct (330) and the second duct (330 ') are connected by a connecting duct (333) located on one side of said thermal management device (300). ) opposite the inlet and outlet (331, 332) of refrigerant.

11. Thermal conditioning system according to claim 3, characterized in that said first conduit (430) for the passage of the cooling fluid. has a substantially U-shaped shape, a first portion of said first conduit

(430) extending into the first chamber (423) and a second portion of said first conduit (430) extending into the second chamber (424),

the exhaust collector (440) of the heat transfer fluid of the thermal management device (400) comprising a second conduit (430 ') for passage of the refrigerant fluid of the first air conditioning circuit fluidly communicating with the first duct (430) and having a shape substantially in U.

12. Thermal conditioning system according to claim 11, characterized in that the ends of the first and second conduits (430, 430 ') for passage of the refrigerant fluid are connected in pairs by a first and second connecting ducts (433, 433). ') extending from the same side of the thermal management device (400). 13. Thermal conditioning system according to claim 12, characterized in that the first connecting pipe (433) has an inlet

(431) and said second connecting pipe (433 ') has a coolant outlet (432). 14. Thermal conditioning system according to one of claims 6, 7 and 13, characterized in that the inlet (231, 431) of refrigerant and the outlet (232, 432) of refrigerant are connected to a pressure reducer ( 206, 406) mounted on the thermal management device (200, 400). 15. Thermal conditioning system according to one of claims 1 to 14, characterized in that it comprises a pump (P) for forcing the circulation of heat transfer fluid in the second thermal control circuit, said pump (P) being mounted on the thermal management device (100).