WO2022175350A1 - Method for managing the heat of an electric battery - Google Patents

Abstract

The invention relates to a thermal management device (4) for a rechargeable electric battery (2) of an electric and/or hybrid vehicle (1); said heat management device (4) comprises at least one regulating means (6) for regulating the temperature of the electric battery (2), a control module (8) configured so as to provide at least one control command (A) of the temperature to the regulating means (6); the thermal management device (4) further comprises a communication member (10) configured so as to communicate with a navigation system (12) and to acquire events (E) from the navigation system (12) with regard to a predetermined itinerary; the thermal management device being characterised in that the communication member (10) is configured so as to acquire at least one event (E) relating to a relief present on the predetermined itinerary and to transmit it to the control module (8), the control module (8) being configured so as to generate at least one control command (A) destined for the regulating means (6) so as to regulate the temperature of the electric battery (2) according to said event (E) relating to a relief.

Description

THERMAL MANAGEMENT DEVICE OF AN ELECTRIC BATTERY

The present invention relates to the field of electric vehicle batteries, in particular automobiles. More particularly, the invention relates to a device for thermal management of a vehicle electric battery, as well as an associated method for thermal management of such an electric battery.

The propulsion of an electric vehicle, or of a hybrid vehicle, is carried out entirely, or partially, by means of an electric motor which is supplied with electricity by at least one electric battery giving the vehicle an autonomy which can be of the order of several hundred kilometres.

The electric batteries fitted to such vehicles generate heat during their use. It is known that these vehicles include thermal management means for such electric batteries, these management means being configured to be able to heat or cool the electric batteries. Indeed, the operation of these batteries is optimal when their temperature is within a defined temperature range, generally between 20°C and 40°C.

More particularly, an electric battery having a temperature greater than 40°C would not operate optimally, the overheating generated by such a temperature possibly in particular involving the degradation of all or part of the components of the battery, and an electric battery having a temperature less than 20° C. would not operate optimally either, its performance in terms of energy supply could for example be lower, which would imply degraded performance and, where appropriate, autonomy of the vehicle. For example, the range of an electric or hybrid vehicle can be 200 kilometers for example when the temperature of its electric battery is 25°C and 180 kilometers when the temperature of its electric battery is lower. at 10°C.

In this context of thermal regulation of the battery, it should be noted that the temperature of the electric battery varies in particular according to the relief, more particularly a hill or a descent, on which the vehicle is traveling. More specifically, in order for the vehicle to be able to cross a hill, the electric battery must provide more electrical energy than when the vehicle is rolling on the flat or downhill, so that the electric motor of the vehicle is capable of supplying the necessary motive power. This results in a rise in the temperature of the electric battery and an increased risk of the appearance of overheating, which implies a need for greater thermal regulation.

The present invention falls within this context and has as its main object a thermal management device for a rechargeable electric battery of an electric and/or hybrid vehicle, the thermal management device comprising at least one means for regulating the temperature of the electric battery, a control module configured to give at least one temperature control instruction to the regulation means, the thermal management device comprising a communication device configured to communicate with a navigation system and to collect events from of the navigation system concerning a determined route, characterized in that the communication unit is configured to collect at least one event relating to a relief present on the determined route and to transmit it to the control module, the control module being configured to generate at least one control instruction intended for the regulation means for re regulate the temperature of the electric heater according to this event relating to a relief.

According to the invention, the thermal management device makes it possible to consider the characteristics of an event relating to a relief present on the route in order to generate a command instruction for a means of regulating the temperature of the battery so as to anticipate the crossing of the terrain by the vehicle and the variation in temperature of the battery which will result therefrom.

The route taken by the vehicle may be a route determined by the driver himself and/or the navigation system, the latter being able to determine the route with respect to a destination chosen by the driver. The route can also be determined by the navigation system from among a plurality of routes that the vehicle can take. Indeed, when the driver does not indicate the destination of the trip, the navigation system can calculate a plurality of routes that the vehicle can take within a determined radius, for example 5 kilometers.

According to an optional characteristic of the invention, the communication device is configured to transmit at least one event relating to a coast present on the determined route to the control module, the control module being configured to generate the control instruction intended for the regulation means to prevent the temperature rise of the electric battery.

When crossing a hill, the vehicle's electric battery is used more heavily, and the temperature of the electric battery increases. The control module generates, before crossing the hill, a control instruction intended for the regulation means so as to limit the temperature of the electric battery when the vehicle crosses the hill. By way of example, the control instruction intended for the regulation means is such that the latter can be implemented to cool the electric battery preventively, or else be blocked so as not to preheat the electric battery while winter temperatures, for example, should require such preheating. More particularly, the control instruction is calculated so that the regulating means performs cooling of the electric battery such that the temperature of this battery is included when crossing the coast in a range of optimum operating temperatures of the electric battery. .

According to another optional characteristic of the invention, the control module is configured to receive parameters relating to the elevation of the coast, and/or to the length of the coast and/or even to the regulatory speed limit on this coast. , and to take these parameters into account for the calculation of the control instruction.

According to another optional characteristic of the invention, the communication unit is configured to transmit at least one event relating to a descent present on the determined route to the control module, the control module being configured to generate the instruction to command to the regulation means to stop the thermal regulation of the electric heater. Since the electric battery is under little demand when the vehicle is traveling downhill, the control means orders the stopping of the regulation of the temperature of the electric battery, in particular to save energy for example.

According to another optional characteristic of the invention, the electric battery comprises an optimum operating temperature, this temperature being included in a temperature range, the control module being configured to generate the control instruction if the temperature of the electric battery is higher and/or lower than the terminals of this temperature range.

According to another optional characteristic of the invention, the control module is configured to generate a control instruction allowing the temperature regulation to be stopped by the regulation means when the temperature of the electric battery is within the range of temperatures. Alternatively, the control instruction generated by the control module could aim to maintain regulation on a fixed target temperature within the temperature range.

According to another optional characteristic of the invention, the communication device is configured to transmit to the control module parameters associated with each of the events relating to a relief, such as for example the inclination of the slope, the distance over which extends this relief or the speed of movement authorized on this relief, the control module being configured to generate a control instruction ordering the regulation means to cool or heat the electric battery according to this event and the parameters associated with this event.

According to another optional characteristic of the invention, the control module is configured to determine a threshold distance, between the start of the relief associated with the event and the point at which the vehicle must be located when the control instruction must be sent to the regulation means, or at the level of which the control instruction must be implemented by the regulation means, the control module being configured to compare the actual distance measured between the actual position of the vehicle and the relative event to the relief at the threshold distance, and to transmit the control instruction to the regulation means as soon as the actual distance is equal to or less than the threshold distance.

According to another optional characteristic of the invention, the control module is configured to determine the threshold distance as a function of the current temperature of the electric battery, and/or of the variation in the temperature of the electric battery with respect to the energy to be provided when crossing the relief considered, and/or the thermal management power that the means can provide of regulation.

According to another optional characteristic of the invention, the communication unit is configured to transmit to the control module a first event relating to a first relief present on the determined route and at least one second event relating to a second relief present on the determined route, the control module being configured to calculate a threshold distance for each event transmitted to it and to prioritize the control instruction to be generated according to the threshold distance that the vehicle is intended to cross first.

The invention also relates to a method for thermal management of an electric battery of a vehicle comprising a first step during which the communication member of a thermal management device according to any one of the preceding characteristics communicates with a navigation system for collecting at least one event relating to the route determined by the driver, the method comprising a second step during which the communication device transmits at least the event to the control module, the method comprising a third step during which the control module generates a control instruction to the regulation means intended for the temperature regulation means so that the latter regulates the temperature of the electric battery according to the event received from the communication organ.

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:

Figure 1 is a schematic representation of a vehicle equipped with a thermal management device according to the invention;

FIG. 2 is a flowchart representing a thermal management method according to 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, we can imagine variants of the invention 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 with respect to the state of the prior technique. In FIG. i is illustrated an electric or hybrid vehicle i comprising a rechargeable electric battery 2 and a thermal management device 4 of the electric battery 2. The electric or hybrid vehicle 1 can for example be an electric or hybrid motor vehicle, a vehicle electric or hybrid electric road motorized two- or three-wheeler, electric velocipede, or electric scooter.

The electric battery 2 equipping the electric or hybrid vehicle 1 can be an electric battery 2 with liquid electrolytes or with solid electrolytes. According to an exemplary embodiment of the invention, the electric battery 2 can be recharged via a wired electrical connection connected to a charging terminal of said electric battery 2, and/or can be recharged by induction.

The electric heater 2 has an optimum operating temperature. It is understood from this that the characteristics of the electric battery 2 are at their optimum level when the electric battery 2 has a temperature substantially equal to the optimum temperature. For example, a characteristic of the electric battery 2 can be the distance traveled by the electric or hybrid vehicle 1 when the electric battery 2 is fully recharged. This distance traveled may for example be 200 kilometers when the electric battery 2 is at the optimum temperature, and 130 kilometers when the electric battery 2 is at a temperature approximately 12° C. lower than the optimum temperature.

The optimum temperature of the electric battery 2 varies from one electric battery 2 to another and it depends in particular on the materials and the processes used to manufacture the electric battery 2. From the optimum operating temperature, it is possible to determine a temperature range in which the operating performance of the electric battery 2 remains optimal. The lower value and the upper value of this temperature range, which can be called optimum temperature range, are respectively for example of the order of 0.7 and 1.3 times the optimum temperature of functioning. These values are generally provided by the manufacturer of the electric heater 2. Outside this range of optimum temperatures, it is considered that the electric heater 2 can deteriorate. By way of example, the optimum operating temperature may be of the order of 28° C., and the lower value of the operating temperature range is then of the order of 20° C. while the upper value of the operating temperature range is then of the order of 35°C. As will be described in more detail below, it is desired that the temperature of electric battery 2 at the instant of starting of the electric or hybrid vehicle i be substantially equivalent to the lower value of the range of optimum temperatures, to be directly operational in an efficient way while allowing a rise in temperature which does not immediately generate overheating, that is to say a temperature above the range of optimal values.

For this, the thermal management device 4 of the electric heater 2 comprises means 6 for regulating the temperature of the electric heater 2 and a control module 8 configured to give at least one temperature control instruction A by means of regulation 6.

The regulation means 6 of the electric heater 2 makes it possible to heat and/or cool the electric heater 2 according to the temperature of the electric heater 2 and according to the command instruction A sent by the control module 8. The means regulator 6 can for example be a pipe network extending over at least one face of the electric battery 2, the pipe network being traversed by a heat transfer fluid intended to exchange calories with the electric battery 2 to control the temperature of this one. However, another type of means 6 for regulating the temperature of the electric battery 2 can be implemented here without departing from the scope of the invention.

According to the invention, the electric battery 2 is configured to have an optimum operating temperature, this optimum temperature being included in a range of temperatures called the range of optimum temperatures and which correspond to temperatures that the battery can have and which do not prevent not operating or charging the battery under good conditions. The control module 8 is configured to generate a control instruction A if the temperature of the electric battery 2 is higher and/or lower than this range of optimum temperatures. When the temperature of the electric heater 2 is higher than the maximum value of the range of optimum temperatures or lower than the minimum value of the range of optimum temperatures, the control module 8 issues a control instruction A intended for the regulation means 6 so that the latter heats and/or cools the electric battery 2, the temperature of the electric battery 2 then being closer to the optimum operating temperature. In other words, the control module 8 generates a control instruction A intended for the regulation means 6 of the electric battery which is a function of the temperature of the electric battery 2.

In a complementary way, the control module 8 can be configured to generate a command instruction A ordering the stopping of the temperature regulation by the regulation means 6. More particularly, when the temperature of the electric battery 2 is included in the range of optimum temperatures, the electric heater 2 then no longer needing to be thermally regulated, the control module 8 can order the stopping of the thermal regulation of the electric heater 2.

According to the invention, the thermal management device 4 comprises a communication unit 10 configured to communicate with a navigation system 12 and to collect events E from the navigation system 12 concerning a determined route. The communication unit 10 is configured to collect at least one event E relating to a relief present on the determined route and to transmit it to the control module 8, the control module 8 being configured to generate at least one command instruction A of the temperature of the electric battery 2 as a function of this or these events E relating to a relief.

It is understood here that the main function of the communication unit 10 is the transmission of events E relating to at least one relief present on the determined route of the navigation system 12 to the control module 8.

To recover the events E relating to a relief present on the determined route, the communication device 10 can for example collect all the events of the determined route, then sort the events E relating to the reliefs and only transmit to the control module 8 these events E sorted and relating to the reliefs. Alternatively, the communication device 10 can be configured to collect only events E relating to a relief present on the determined route of the navigation system 12, the communication device 10 then transmitting all the events E that it has been retrieved from the control module 8. Additionally, and without departing from the context of the invention, the control module according to the invention could, in order to generate the command instruction for the thermal regulation means of the battery, taking account of other events retrieved from a navigation system, provided that at least one of the events E relates to a relief.

The determined route is a route defined at the start of the journey and/or during the journey which will be implemented and followed by the vehicle 1, whether it is a route to reach a defined destination or one of the routes starting from the point where the vehicle is at the present time when no defined destination is known.

By way of example, the determined route may correspond to a route determined by the driver, and more precisely to a route calculated by the navigation system 12 to reach a destination defined by the driver. In this configuration, the communication unit 10 collects the events E relating to a relief present on the determined route, then transmits them to the control module 8.

Alternatively, the determined route may correspond to a route identified by the control module on the basis of a recurrence of this route recorded by the control module and stored in an associated database. By way of example, the control module is able to identify that the route taken each Wednesday morning is the same and that the route determined corresponds to this route. Here again, in this configuration, the communication unit 10 collects the events E relating to a relief present on the determined route, then transmits them to the control module 8.

In the case where the destination is not known, and no recurrence has enabled the control module to identify the determined route by itself, the navigation system 12 can calculate a plurality of determined routes to anticipate all of the events E that the vehicle 1 may encounter and which are present within a defined radius around the vehicle 1, this radius possibly being for example 5 kilometers (km). The communication unit 10 then records all the events E present on the plurality of routes and which relate to a relief, then transmits them to the control module 8.

In the examples described above, the navigation system 12 continuously updates the route determined as a function of the route that the vehicle 1 actually follows, and the communication device 10 also continuously retrieves all of the events E relating to a relief present on this determined route, to transmit them to the control module 8. It is understood here that the route taken by the vehicle 1 can vary and that the determined route is then modified, and that in this case, the communication device 10 transmits to the control module 8 the new events E relating to a relief present on the modified determined route, the control module adapting the command instruction A according to the new events E received from the communication device 10.

“Event E relating to a relief” means any event E present on the determined route and which presents a variation in elevation, i.e. a climb or a descent for example. The communication device 10 is configured to transmit parameters associated with each of the events E relating to a side and/or a descent, such as for example the inclination of the slope, the distance over which this relief extends or again the traffic speed authorized on this relief, this list not being exhaustive.

As mentioned previously, the communication unit 10 is configured to transmit at least one event E relating to a relief present on the determined route to the control module 8, the control module 8 being configured to generate an instruction command A ordering the regulation means 6 to cool the electric battery 2, or to stop a battery preheating function, for example if ambient temperature conditions have required such a preheating operation, depending on this event E and parameters associated with this event.

When the vehicle 1 is traveling on a hill, the energy to be supplied by the electric battery 2 is greater compared to the energy to be supplied by the electric battery 2 when vehicle 1 is traveling on a substantially flat road. Consequently, the increase in the quantity of energy to be supplied leads to an increase in the temperature of the electric battery 2, this temperature then possibly becoming higher than the temperature corresponding to the maximum value of the optimum operating temperature range of the electric battery 2. According to the invention, to limit the temperature of the electric battery 2 and prevent it from exceeding said maximum value, the control module implements the regulation means 6 prior to the arrival of the vehicle on the coast so as to anticipate the cooling of the electric battery 2. More particularly, the regulation means 6 is implemented to cool the electric battery so that the temperature of the latter is in a lower slice of the range of optimal temperatures, that is to say so that the temperature of the electric battery 2 is close to the minimum value of said temperature range while being included in s this temperature range.

Advantageously, the control module 8 generates a cooling control instruction A according to the event E relating to the coast transmitted by the communication device 10. It is understood that the control module 8 takes into account, for example, the difference in level of the coast or the length of the coast. By way of example, the longer and steeper the coast to come on the determined route, the closer the temperature of the battery targeted after the temperature regulation implemented by the regulation means to the minimum value of said range. of temperature. On the other hand, if the coast to come on the determined route is short and not very steep, the temperature regulation implemented by the regulation means may be minimal, so that the energy cost associated with this action of cooling the battery electric is not detrimental to the vehicle's range.

In addition, the control module 8 determines a threshold distance between the start of the relief associated with the event E and the point at which the vehicle 1 must be located when the command instruction A must be sent to the regulation means , or when the control instruction A must be implemented by the regulating means. The control module 8 is then configured to compare the real distance measured between the real position of the vehicle 1 and the event E relating to the relief and the threshold distance, and to transmit the control instruction A to the regulation means 6 as soon as the actual distance is equal to or less than the threshold distance.

To determine this threshold distance, the control module 8 takes into consideration the current temperature of the electric battery 2, the variation in the temperature of the electric battery 2 with respect to the energy to be supplied when crossing the relief considered, and/ or even the thermal management power that the regulation means 6 can provide.

The control module 8 is thus also configured to retrieve temperature information from the electric battery 2, and to consider this information in the calculation of a control instruction A. More particularly, the temperature of the electric battery at the time of the calculation of the control instruction can have an effect on the intensity of the cooling action of the regulation means 6 and/or on the threshold distance at which the control instruction must be transmitted to the regulation means 6. As for example, if when approaching a relief, the temperature of the electric battery 2 is included in the range of optimum temperatures while being close to the minimum value, the control module 8 may not issue an instruction to control A, so as not to generate unnecessary energy expenditure and not to impact the range of the vehicle.

It is understood from the above that the control instructions issued by the control module 8, when a relief is detected, are mainly for preventive purposes. Indeed, the command instructions generated by the control module 8 make it possible to prevent future increases and/or drops in temperature of the electric battery 2. By anticipating these thermal variations, the control module 8 ensures that the temperature of the battery electric 2 is included, when the vehicle is traveling in the relief, in the optimum temperature range to optimize the operation of the battery and therefore the operation of the vehicle in this relief.

It should be understood that conventionally, when overheating of the electric battery 2 occurs while the vehicle i is traveling on a hill, it is conventional thermal regulation means which intervene to cool the electric battery 2, this cooling being accompanied by a drop in the energy power that can be supplied to the motor by the battery to combat against this overheating. However, the control module 8 can issue a control instruction A also when the vehicle i is rolling uphill, in particular when the temperature of the electric battery 2 increases and approaches the maximum value of the temperature range. Here again, it should be noted that the control module is configured to consider the existence of a relief on the road of the vehicle and to preventively adapt the temperature of the battery, in particular so as to avoid overheating and an action high-intensity point cooling which is energetically expensive and which is accompanied by a mode of reduction in the performance of the vehicle.

Advantageously, the cooling of the electric battery 2 by the regulation means 6 and ordered by a command instruction A of the control module 8 is carried out so that the temperature is not lower than the minimum value of the range of optimal temperatures, so that the battery can continue to operate in temperatures favorable to it.

In what preceded, the relief considered by the control module 8 is a hill, which implies a rise in temperature of the electric battery, and the action controlled by the regulation means 6 is thus a preventive cooling of the electric battery.

The relief considered can also be a descent. Thus, according to the invention, the communication device io is also configured to transmit at least one event E relating to a descent present on the determined route to the control module 8, the control module 8 being configured to generate an instruction command A ordering the regulation means 6 to stop the heating and/or to cool the electric battery 2. Indeed, when the vehicle î is rolling downhill, the energy to be supplied by the electric battery 2 is reduced or even, in some cases, zero, so that the temperature of the electric battery 2 naturally tends to decrease, or at the very least to stagnate. In this configuration, the control means generates a control instruction A to stop the regulation of the temperature by the regulation means 6.

The control module 8 can also order the control instructions according to a sequence of events E relating to several reliefs present on the determined route. For this, the communication device io is configured to transmit to the control module 8 a first event E relating to a first relief present on the determined route and at least one second event E relating to a second relief present on the determined route. These two events E can for example be positioned one after the other, the first event E being able for example to relate to a first coast having a slight drop, and the second event E being able for example to relate to a second hill with a greater drop. In this configuration, the vehicle 1 is intended to encounter the first event E then the second event E according to the determined route.

According to the invention, the control module 8 is configured to generate a first command instruction A according to the first event, and a second command instruction A according to the second event, the second command instruction A being configured to refine and /or delete the first command instruction A. It is understood here that if the second event E requires greater thermal regulation of the electric heater 2 than the first event, the control module 8 refines the first command instruction A thanks to the second control instruction A so as to refine the first control instruction A to the crossing of the first and second events E.

According to the example cited above, the first rib has a lower elevation than the second rib. The electric battery 2 will thus provide more energy to cross the second hill compared to crossing the first hill. The control module 8 generates a first command instruction A intended for the regulation means so that the latter cools the electric battery 2 to a first temperature making it possible to maintain a temperature in the range of optimal temperatures when the first event is crossed, and a second control instruction A intended for the regulation means so that the latter cools the electric battery 2 to a first temperature making it possible to maintain a temperature in the range of optimum temperatures when the second event is crossed. Since the cooling desired via the second control instruction A is greater than the cooling desired via the first control instruction A, the point corresponding to the threshold distance at which the second control instruction A is sent to the regulation means can be reached by the vehicle before the point corresponding to the threshold distance at which the first control instruction A is sent to the regulation means. In this way, the second control instruction is prioritized relative to the first control instruction. It is understood from the above that the control module 8 is configured to prioritize the control instructions according to the most important thermal management needs for the electric battery 2.

We will now describe a thermal management method of the electric battery 2 of the vehicle 1, in particular with reference to Figure 2.

The method for thermal management of the electric battery 2 of the vehicle 1 comprises a first step Si during which the communication unit 10 of the thermal management device 4 communicates with a navigation system 12 to collect one or more events E relating to the route determined by the driver.

According to a first exemplary embodiment, the communication unit 10 retrieves all of the events E relating to the determined route then sorts so as to then only transmit the events E relating to a relief present on the determined route.

According to a second exemplary embodiment, the communication unit 10 retrieves only all of the events E relating to a relief present on the determined route. In this configuration, the communication unit 10 then transmits all the events E retrieved to the control module 8.

The thermal management method comprises a second step S2 during which the communication device 10 transmits at least the event E to the control module 8. In other words, after having recovered and/or sorted events E relating to a relief present on the route, the communication unit 10 transmits them to the control module 8.

The method comprises a third step S3 during which the control module 8 generates a control instruction A by means of regulation 6 of the temperature of the electric battery 2 according to the event E received from the communication device 10 It is understood here that, during the third step S3, the control module 8 takes into account the various events E to generate at least one command instruction A to anticipate the thermal regulation of the electric battery 2. Depending on the nature of the event, depending on whether it is a hill or a descent for example, the control module 8 generates the instruction control A to regulate the thermal management of the electric heater 2, or even to refine a previous control instruction A for the approach of the event.

The method also comprises a fourth step S4 during which the control module 8 transmits the control instruction A to the regulating means 6 of the electric heater 2, then the regulating means 6 of the electric heater 2 heats, cools and/or stops regulation of electric heater 2.

The present invention cannot however be limited to the means and configurations described and illustrated here and it also extends to any equivalent means and configuration as well as to any technically effective combination of such means. In particular, the arrangement of the various elements in particular in FIG. 1 is arbitrary and can be modified without departing from the scope of the invention.

Claims

1. Thermal management device (4) of a rechargeable electric battery (2) of an electric and/or hybrid vehicle (1), the thermal management device (4) comprising at least one regulation means (6) of the temperature of the electric battery (2), a control module (8) configured to give at least one temperature control instruction (A) to the regulation means (6), the thermal management device (4) comprising a communication device (10) configured to communicate with a navigation system (12) and to collect events (E) from the navigation system (12) concerning a determined route, characterized in that the communication device (10) is configured to collect at least one event (E) relating to a relief present on the determined route and to transmit it to the control module (8), the control module (8) being configured to generate at least one command instruction (A) to the regulation means ( 6) to regulate the temperature of the electric battery (2) according to this event (E) relating to a relief.

2. Thermal management device (E) according to claim 1, wherein the communication device (10) is configured to transmit at least one event (E) relating to a coast present on the determined route to the control module ( 8), the control module (8) being configured to generate the control instruction (A) intended for the regulation means (6) to prevent the temperature rise of the electric battery (2).

3. Thermal management device (4) according to any one of the preceding claims, in which the communication device (10) is configured to transmit at least one event (E) relating to a descent present on the determined route to the control module (8), the control module (8) being configured to generate the control instruction (A) to the regulation means (6) to stop the thermal regulation of the electric battery (2).

4. Thermal management device (4) according to any one of the preceding claims, in which the electric battery (2) comprises an optimum operating temperature, this optimum temperature being included in a temperature range, the control module (8 ) being configured to generate the control instruction (A) if the temperature of the electric heater (2) is higher and/or lower than the terminals of this range of temperature.

5. Thermal management device (4) according to claim 4, in which the control module (8) is configured to generate a control instruction (A) allowing the temperature regulation to be stopped by the regulation means ( 6) when the temperature of the electric heater (2) is within the temperature range.

6. Thermal management device (4) according to any one of the preceding claims, in which the communication device (10) is configured to transmit to the control module (8) parameters associated with each of the events (E) relating to a relief, the control module (8) being configured to generate a command instruction A ordering the regulation means (6) to cool or heat the electric battery (2) according to this event (E) and the associated parameters to this event.

7. Thermal management device (4) according to any one of the preceding claims, in which the control module (8) is configured to determine a threshold distance between the start of the relief associated with the event (E) and the point at which the vehicle (1) must be located when the control instruction (A) must be sent to the control means, or at which the control instruction (A) must be implemented by means of regulation, the control module (8) being configured to compare the actual distance measured between the actual position of the vehicle (1) and the event (E) relating to the relief with the threshold distance, and to transmit the control instruction ( A) to the regulation means (6) as soon as the actual distance is equal to or less than the threshold distance.

8. Thermal management device (4) according to the preceding claim, in which the control module (8) is configured to determine the threshold distance according to the current temperature of the electric battery (2), and/or the variation the temperature of the electric battery (2) in relation to the energy to be supplied when crossing the relief in question, and/or the thermal management power which the regulation means (6) can supply.

9. Thermal management device (4) according to any one of claims 7 or 8, wherein the communication device (10) is configured to transmit to the control module (8) a first event (E) relating to a first relief present on the determined route and at least one second event (E) relating to a second relief present on the determined route, the control module (8) being configured to calculate a threshold distance for each event (E) transmitted to it and to prioritize the control instruction (A) to be generated according to the threshold distance that the vehicle is intended to cross in first.

10. A method of thermal management of an electric battery (2) of a vehicle (1) comprising a first step (Si) during which the communication member (10) of a thermal management device (4) according to any one of the preceding claims communicates with a navigation system (12) to collect at least one event (E) relating to the route determined by the driver, the method comprising a second step (S2) during which the communication device (10) transmits at least the event (E) to the control module (8), the method comprising a third step (S3) during which the control module (8) generates a command instruction ( A) to the regulation means (6) so that the latter regulates the temperature of the electric battery (2) according to the event (E) received from the communication device (10).