FR3140414A1 - Device and method for filling a pressurized gas tank - Google Patents

Abstract

Device (1) for filling pressurized gas tanks comprising a distributor (2) intended to supply a tank (3) with pressurized gas from a fluid source (4), the device (1) comprising a system (1A) of refrigeration for cooling a flow of gas from the distributor (2), the refrigeration system (1A) comprising a circuit (5) of coolant, such as brine, comprising the following elements arranged in series in this order : a reserve (6) of coolant, comprising an upper part (61) configured to house a hot mass of the coolant and a lower part (62) configured to house a cold mass of the coolant, at least one first exchanger (7) ) of heat having an inlet connected to an outlet of the lower part (62) of the reserve (6) by a first pipe (51), the at least one first heat exchanger (7) being configured to ensure a thermal exchange between the coolant and a source (8) of cold, and a second heat exchanger (9) having an inlet connected to the first heat exchanger (7) by a second pipe (52) of the coolant circuit (5), and an outlet connected to an inlet of the upper part (61) of the reserve (6) by a third pipe (53) of the coolant circuit (5), the second heat exchanger (9) being configured to ensure an exchange of heat between the coolant and the gas flow of the filling device (1), characterized in that the circuit (5) comprises a first branch portion (10) connecting the second pipe (52) to the lower part (62) of the reserve (6) to allow a transfer of coolant fluid selectively from the at least one first heat exchanger (7) towards the lower part (62) of the reserve (6), or from the lower part (62) of the reserve (6) towards the second heat exchanger (9) without passing through the at least one first heat exchanger (7). Abstract figure: Fig. 1

Description

Device and method for filling a pressurized gas tank

The invention relates to a device and a method for filling a pressurized gas tank.

The invention relates more particularly to a device for filling a pressurized gas tank comprising a distributor intended to supply the tank with pressurized gas from a fluid source, the device comprising a refrigeration system for cooling a gas flow of the distributor, the refrigeration system comprising a coolant circuit, such as brine, the coolant circuit comprising the following elements arranged in series in this order:
- a reserve of coolant, comprising an upper part configured to house a hot mass of the coolant and a lower part configured to house a cold mass of the coolant,
- at least one first heat exchanger having an inlet connected to an outlet of the lower part of the reserve by a first pipe, the at least one first heat exchanger being configured to ensure a heat exchange between the coolant and a source of heat cold, and
- a second heat exchanger having an inlet connected to the at least one first heat exchanger by a second pipe of the coolant circuit, and an outlet connected to an inlet of the upper part of the reserve by a third pipe of the coolant circuit coolant, the second heat exchanger being configured to ensure heat exchange between the coolant and the gas flow from the distributor.

In a filling device as described above, the intermediate position of at least one first heat exchanger between the reserve and the second heat exchanger ensures, for a given temperature of the coolant leaving the reserve, a higher temperature. low at the entrance to the second exchanger. In addition, this intermediate position of the first heat exchanger makes it possible to increase the coefficient of performance of the refrigeration unit associated with the filling device.

However, with the device described above, the temperature of the coolant in the reserve and at the outlet of the reserve remains difficult to control. Therefore, the temperature of the coolant at the inlet and outlet of at least one first heat exchanger also remains difficult to control.

An aim of the present invention is to overcome all or part of the disadvantages of the prior art noted above.

To this end, the device according to a first aspect of the invention, moreover conforming to the generic definition given in the preamble above, is essentially characterized in that the refrigerant fluid circuit comprises a first branch portion connecting the second pipe to the lower part of the reserve to allow a transfer of coolant fluid selectively from the at least one first heat exchanger towards the lower part of the reserve, or from the lower part of the reserve towards the second heat exchanger without pass through at least one first heat exchanger.

By providing a first branch portion connecting the second pipe to the lower part of the reserve, the device according to this first aspect of the invention makes it possible to return at least part of a flow of coolant to the lower part of the reserve. having passed through the at least one first heat exchanger. The return of the refrigerant fluid to the lower part of the reserve makes it possible to accumulate refrigerations there and to (re)constitute at least in part the cold mass of the refrigerant fluid, independently of the refrigeration needs at the distributor. Thus, the device according to this first aspect of the invention promotes and/or makes it possible to maintain in the reserve a separation between the cold mass of the coolant located in the lower part, and the hot mass of the coolant located in the upper part.

In addition, a partial return of the coolant from the at least one first heat exchanger towards the lower part of the reserve has the effect of limiting the flow of coolant transferred to the second heat exchanger from said at least one first heat exchanger. heat. Thus, the device according to this first aspect of the invention makes it possible to control (reduce) the cold power supplied to the second heat exchanger from the at least one first heat exchanger.

Furthermore, by providing a first branch portion connecting the second pipe to the lower part of the reserve, the device according to this first aspect of the invention makes it possible to supply the second heat exchanger with a flow of cold mass coming directly from the lower part of the reserve. This flow of cold mass coming directly from the lower part of the reserve towards the second heat exchanger can be in addition to or in substitution for a flow of cooled coolant after passing through the at least one first heat exchanger towards the second exchanger heat. Thus, in the event of shutdown of at least one first heat exchanger, the flow of cold mass coming directly from the lower part of the reserve towards the second heat exchanger ensures continuity of operation for the filling device.

It should be noted that with two cold mass flows available at the inlet of the second heat exchanger, namely a first flow coming directly from the lower part of the reserve, and a second flow passing through the at least one first exchanger heat, the device according to this first aspect of the invention introduces more latitude in controlling the temperature of the coolant at this inlet.

The device according to a second aspect of the invention, moreover conforming to the generic definition given in the preamble above, is essentially characterized in that the coolant circuit comprises a fourth pipe connecting an outlet of the upper part from the reserve to the inlet of at least one first heat exchanger.

By providing a fourth pipe in addition to the first pipe to connect the at least one first heat exchanger to the reserve, the device according to this second aspect of the invention offers more latitude for controlling/regulating the quantity of hot mass and the quantity of cold mass contained in the reserve. Likewise, the device according to this second aspect of the invention offers more latitude for controlling/regulating the temperature of the coolant at the inlet and/or outlet of at least one first heat exchanger, thanks to different possible mixtures between a flow of hot mass leaving the upper part of the reserve and a flow of cold mass leaving the lower part of the reserve.

Furthermore, embodiments of the device according to the first and/or second aspect of the invention may include one or more of the following characteristics:
- the first pipe, the second pipe and the third pipe of the coolant circuit define a first refrigeration loop of the device;
- the fourth pipe, the second pipe and the third pipe of the coolant circuit define a second refrigeration loop of the device;
- the first refrigeration loop and the second refrigeration loop are configured to be put into service simultaneously or sequentially;
- the first branch portion connects the first pipe to the second pipe;
- the reserve comprises at least one perforated transverse plate configured to separate the upper and lower parts of the reserve so as to limit transfers of coolant between the hot mass located at the level of the upper part and the cold mass located at the level of the lower part;
- the coolant circuit comprises a second branch portion connecting the second pipe to the third pipe to allow all or part of the coolant leaving the at least one first heat exchanger to return to the reserve without passing through the second exchanger heat;
- the coolant circuit comprises a third branch portion connecting the third pipe to the second pipe to allow all or part of the coolant leaving the second heat exchanger to return to said second exchanger without passing through the reserve or through the at least a first heat exchanger;
- the coolant circuit comprises at least one member for circulating the coolant in the coolant circuit and/or at least one member for controlling the temperature of the coolant;
- the coolant circuit comprises at least one set of valve(s) configured to control the flows in the circuit, for example one or more three-way valves arranged at a junction between two or more of the pipes and/or the portions of derivation;
- the first diversion portion and the second diversion portion are connected to the second pipe by the same set of valves, for example a three-way valve.

The invention also relates to a method of filling a pressurized gas tank by means of a device according to the first aspect above and any one of the characteristics above or below, in which a flow of coolant is transferred through the first bypass portion selectively from the at least one first heat exchanger to the lower part of the reserve, or from the lower part of the reserve to the second heat exchanger without passing through the at least one first exchanger heat.

According to possible particularities, the flow of coolant transferred from the lower part of the reserve towards the second heat exchanger without passing through the at least one first heat exchanger is in addition to or in substitution for a flow of coolant transferred from the at least one first heat exchanger towards the second heat exchanger.

According to possible particularities, the method comprises a step of circulating a hot mass flow and a cold mass flow of the coolant from the reserve towards the at least one first heat exchanger through respectively the first pipe and the fourth pipe for regulating the temperature of the coolant at the inlet and/or outlet of the at least one first heat exchanger.

Finally, the invention relates to a method of filling a pressurized gas tank by means of a device according to the second aspect above and any one of the characteristics above or below, comprising a step of setting circulation of a hot mass flow and a cold mass flow of the coolant from the reserve towards the at least one first heat exchanger through respectively the first pipe and the fourth pipe to regulate the temperature of the coolant at the inlet and/or or at the outlet of at least one first heat exchanger.

The invention may also relate to any alternative device or method comprising any combination of the characteristics above or below within the scope of the claims.

Other features and advantages will appear on reading the description below, made with reference to the following figures in which:

represents a schematic and partial view illustrating a possible example of structure and operation of a device of the invention according to a first embodiment;

represents a schematic and partial view illustrating a possible example of structure and operation of a device of the invention according to a second embodiment.

The device 1 for filling pressurized gas tanks illustrated is for example a filling station for pressurized hydrogen tanks. This device 1 comprises a distributor 2 (flexible fitted with a nozzle for example) intended to supply a tank 3 with gas under pressure from a source 4 of fluid (storage(s) and/or compressor(s) and/ Or other). The device 1 also includes a refrigeration system 1A for cooling the gas flow from the distributor 2.

In particular, the refrigeration system 1A comprises a circuit 5 of coolant, such as brine for example. This circuit 5 comprises a reserve 6 of coolant, at least a first heat exchanger 7 ensuring a heat exchange between the coolant and a source 8 of cold, and at least a second heat exchanger 9 ensuring a heat exchange between the flow of coolant and a flow of gas from the distributor 2. The reserve 6, the at least one first heat exchanger 7 and the at least one second heat exchanger 9 are arranged in series in a closed loop and define in this order the direction of circulation of the coolant inside the loop.

The reserve 6 comprises an upper part 61 configured to house a relatively hotter mass of the coolant and a lower part 62 configured to house a relatively colder mass of the coolant. The hot mass has a higher average temperature than the cold mass.

The upper part 61 and the lower part 62 of the reserve 6 each have at least one opening allowing a flow of the coolant through the reserve 6. In the example illustrated, the upper part 61 has a separate inlet and an outlet for the flow of the hot mass of the coolant through the reserve 6. The lower part 62 has an inlet and an outlet which are formed by the same opening for the flow of the cold mass of the coolant through the reserve 6.

In addition, the reserve 6 may comprise in its volume at least one perforated transverse plate configured to separate the upper part 61 and the lower part 62 of the reserve 6 so as to limit the transfers of coolant between the hot mass located at the level of the upper part 61 and the cold mass located at the lower part 62. Such a plate promotes temperature stratification of the coolant in the reserve 6.

In the example illustrated, the reserve 6 comprises two perforated plates which define between them an intermediate part 63 located between the upper part 61 and the lower part 62. The coolant located at the level of the intermediate part 63 has an average temperature between that of the cold mass and that of the hot mass.

The at least one first heat exchanger 7 comprises an inlet which is connected to the outlet of the lower part 62 of the reserve 6 by a first pipe 51 of the coolant circuit 5. Advantageously, the at least one first heat exchanger 7 is an evaporator.

In a non-limiting manner, the cold source 8 associated with the at least one first heat exchanger 7 may comprise a circuit (not illustrated) of a refrigerant, which comprises in a loop: a pump, an evaporator, a reserve of refrigerant then a passage in the at least one first heat exchanger 7. This passage is configured to cool the refrigerant fluid (here the brine) circulating in the refrigerant fluid circuit 5.

The second heat exchanger 9 has an inlet connected to an outlet of the first heat exchanger 7 via a second pipe 52 of the coolant circuit 5. In addition, the second heat exchanger 9 has an outlet connected to the inlet of the upper part 61 of the reserve 6 by a third pipe 53 of the coolant circuit 5.

It should be noted that the second heat exchanger 9 may include a conductive mass which can be pre-cooled by the coolant to increase the thermal inertia of the cooling (and if necessary cool even without the simultaneous passage of coolant).

The first pipe 51, the second pipe 52 and the third pipe 53 form a first refrigeration loop of the coolant circuit 5.

According to a first aspect of the invention, the coolant circuit 5 comprises a first branch portion 10 connecting the second pipe 52 to the lower part 62 of the reserve 6. Thus, the first branch portion 10 allows a transfer of fluid refrigerant selectively from the first heat exchanger 7 towards the lower part 62 of the reserve 6, or from the lower part 62 of the reserve 6 towards the second heat exchanger 9 without passing through the first heat exchanger 7.

By providing a first branch portion 10 connecting the second pipe 52 to the lower part 62 of the reserve 6, the device 1 according to this first aspect of the invention makes it possible to return towards the lower part 62 of the reserve 6 at least a part of a flow of coolant having passed through the first heat exchanger 7.

The return of the refrigerant fluid to the lower part 62 of the reserve 6 makes it possible to accumulate frigories there and to (re)constitute at least in part the cold mass of the refrigerant fluid, independently of the refrigeration requirements at the distributor 2 The upper part 61 of the reserve 6 remains little affected by this return of coolant.

Thus, the device 1 according to this first aspect of the invention promotes and/or makes it possible to maintain in the reserve 6 a separation between the cold mass of the coolant located in the lower part 62, and the hot mass of the coolant located in the upper part 61.

In addition, the return of the coolant in the lower part 62 of the reserve 6 has the effect of limiting the flow of coolant transferred to the second heat exchanger 9 from the first heat exchanger 7. Thus, the device 1 according to this first aspect of the invention makes it possible to control (reduce) the cold power supplied to the second heat exchanger 9 from the first heat exchanger 7 without losing frigories.

Furthermore, by providing a first branch portion 10 connecting the second pipe 52 to the lower part 62 of the reserve 6, the device 1 according to this first aspect of the invention makes it possible to supply the second heat exchanger 9 with a flow of cold mass coming directly from the lower part 62 of the reserve 6. This flow of cold mass coming directly from the lower part 62 of the reserve 6 towards the second heat exchanger 9 can be in addition to or in substitution for a flow of refrigerant fluid cooled after passing through the first heat exchanger 7 to the second heat exchanger 9. Thus, in the event of shutdown of the first heat exchanger 7, the flow of cold mass coming directly from the lower part 62 of the reserve 6 towards the second heat exchanger 9 ensures continuity of operation for the filling device 1.

It should be noted that with two cold mass flows available at the inlet of the second heat exchanger 9, namely a first flow coming directly from the lower part 62 of the reserve 6, and a second flow passing through the first exchanger 7 of heat, the device 1 according to this first aspect of the invention introduces more latitude in controlling the temperature of the coolant at this inlet. Indeed, the two cold mass flows can be at different temperatures, and their mixing in judiciously chosen proportions makes it possible to obtain an intermediate temperature at the inlet of the second heat exchanger 9.

Advantageously, the first branch portion 10 connects the first pipe 51 to the second pipe 52. This arrangement makes it possible to distribute a flow of cold mass leaving the lower part 62 of the reserve 6 between these two pipes 51, 52.

According to a second aspect of the invention in combination or not with the first aspect above, the refrigeration circuit 5 comprises a fourth pipe 54 which connects the outlet of the upper part 61 of the reserve 6 to the inlet of the first exchanger 7 heat. Thus, according to this second aspect of the invention, the coolant circuit 5 comprises two pipes 51, 54 which connect the inlet of the first heat exchanger 7 respectively to the outlet of the lower part 62 of the reserve 6 and to the exit from the upper part 61 of the reserve 6.

By providing a fourth pipe 54 in addition to the first pipe 51 to connect the first heat exchanger 7 to the reserve 6, the device 1 according to this second aspect of the invention offers more latitude for controlling/regulating the quantity of hot mass and the quantity of cold mass contained in the reserve 6. Likewise, the device 1 according to this second aspect of the invention offers more latitude for controlling/regulating the temperature of the coolant at the inlet and/or outlet of the first exchanger 7 of heat, thanks to different possible mixtures between a flow of hot mass leaving the upper part 61 of the reserve 6 and a flow of cold mass leaving the lower part 62 of the reserve 6.

Advantageously, the fourth pipe 54 is connected to the first pipe 51. The two pipes 51, 54 have a common segment 55 connected to the inlet of the first heat exchanger 7. The mixing between the cold mass flow passing through the first pipe 51 and the hot mass flow passing through the fourth pipe 54 is carried out at the level of the common segment 55.

The fourth pipe 54 forms with the second pipe 52 and the third pipe 53 a second refrigeration loop. Thus, the refrigerant fluid circuit 5 according to this second aspect of the invention comprises two refrigeration loops which cooperate with one another.

It should be noted that the above refrigeration loops can be activated selectively. Each of these loops can then be associated with the first branch pipe 10 to form a filling device conforming to the spirit of the first aspect of the invention.

Advantageously, the coolant circuit 5 can comprise a second branch portion 11 connecting the second pipe 52 to the third pipe 53. This second branch portion 11 is configured to allow all or part of the coolant to exit the first heat exchanger 7, particularly in the event of its stopping, to return to the reserve 6 without passing through the second heat exchanger 9. More specifically, the coolant returns to the upper part 61 of the reserve 6 to form the hot mass. This return does not reach the lower part 62 of the reserve 6, thus making it possible to maintain a separation therein between the hot mass and the cold mass.

Advantageously, the coolant circuit 5 can comprise a third branch portion 12 connecting the third pipe 53 to the second pipe 52. The third branch portion 12 is configured to allow all or part of the coolant to exit the second heat exchanger 9 to return to said second exchanger 9 without passing through the reserve 6 nor through the first heat exchanger 7.

Advantageously, the coolant circuit 5 preferably comprises at least one member 13, 14 for circulating the coolant in the coolant circuit 5 and/or at least one member 15, 16 for controlling the temperature of the coolant. refrigerant fluid. The at least one member 13, 14 for circulating the coolant in circuit 5 can be, for example, a pump. In the example illustrated, a first circulation member 13 and a first temperature control member 15 are positioned at the level of the segment 55 common to the pipes 51, 54.

Advantageously, the coolant circuit 5 preferably comprises at least one set of valve(s) 17, 18, 19 configured to control the flows in the circuit 5. The at least one set of valve(s) 17, 18 , 19 consists, for example, of one or more three-way valves arranged at a junction between two or more of the pipes 51, 52, 53, 54 and/or the diversion portions 10, 11, 12.

In the example illustrated, a first set of valves 17, for example a three-way valve, connects the first pipe 51, the fourth pipe 54, and their common segment 55. A second set of valves 18, for example a three-way valve , connects the first branch portion 10 and the second branch portion 11 to the second pipe 52.

In an embodiment illustrated in , the device 1 can include several distributors (here two distributors 2a, 2b) intended to supply separate tanks 3a, 3b, simultaneously or not. To do this, the device 1 comprises several second heat exchangers (here two heat exchangers 9a, 9b) each associated with a distributor 2a, 2b. The second heat exchangers are arranged in parallel on circuit 5. In the example illustrated, device 1 can also include several first heat exchangers 7a, 7b arranged in parallel on circuit 5.

In order to integrate the different first heat exchangers 7a, 7b into circuit 5, the common segment 55 presents a first set of parallel branches passing respectively through the different first heat exchangers 7a, 7b.

Furthermore, in order to integrate the different second heat exchangers 9a, 9b into circuit 5, the second pipe 52 has a second set of parallel branches (here two branches) each connecting an inlet of a second heat exchanger 9a, 9b at an outlet of the assembly formed by the first heat exchangers 7a, 7b. Likewise, the third pipe 53 has a third set of parallel branches (here two branches) each connecting an outlet of a second heat exchanger 9a, 9b to the inlet of the reserve 6.

In other words, in this second embodiment, the second pipe 52 and the third pipe 53 together form a series of pairs of parallel branches passing respectively through the second heat exchangers 9a, 9b. Each pair of this series includes a branch belonging to the second pipe 52 and a branch belonging to the third pipe 53.

Between a branch of the second pipe 52 and a branch of the third pipe 53 which pass through a second given exchanger 9a, 9b, the device 1 can comprise a branch portion 12a, 12b. This diversion portion 12a, 12b is configured to allow all or part of the coolant at the outlet of the second exchanger 9 considered to return to it without passing through the reserve 6 or through the assembly formed by the first exchangers 7a, 7b heat. Alternatively, this diversion portion 12a, 12b can be configured to allow all or part of the coolant leaving the assembly formed by the first exchangers 7a, 7b to return to the reserve 6 without passing through the second exchanger 9 considered.

As in the first embodiment, here also the circuit 5 comprises a set of members 14a, 14b for circulating fluid and a set of valve(s) 19a, 19b configured to control the flows in the circuit 5. in particular, distribution valve(s) (not shown) can be provided to control the flow of coolant towards the different second heat exchangers 9a, 9b.

Claims (15)

Device (1) for filling pressurized gas tanks comprising a distributor (2) intended to supply a tank (3) with pressurized gas from a fluid source (4), the device (1) comprising a system (1A) of refrigeration for cooling a flow of gas from the distributor (2), the refrigeration system (1A) comprising a circuit (5) of coolant, such as brine, the circuit (5) comprising the following elements arranged in series in this order:

• a reserve (6) of coolant, comprising an upper part (61) configured to house a hot mass of the coolant and a lower part (62) configured to house a cold mass of the coolant,
• at least one first heat exchanger (7) having an inlet connected to an outlet of the lower part (62) of the reserve (6) by a first pipe (51), the at least one first heat exchanger (7) being configured to ensure a heat exchange between the coolant and a cold source (8), and
• a second heat exchanger (9) having an inlet connected to the first heat exchanger (7) by a second pipe (52) of the coolant circuit (5), and an outlet connected to an inlet of the upper part (61) of the reserve (6) by a third pipe (53) of the coolant circuit (5), the second heat exchanger (9) being configured to ensure a heat exchange between the coolant and the gas flow from the distributor ( 2),

characterized in that the circuit (5) comprises a first branch portion (10) connecting the second pipe (52) to the lower part (62) of the reserve (6) to allow transfer of coolant fluid selectively from at least a first heat exchanger (7) towards the lower part (62) of the reserve (6), or from the lower part (62) of the reserve (6) towards the second heat exchanger (9) without passing through the at minus a first heat exchanger (7). Device according to the preceding claim, characterized in that the inlet of at least one first heat exchanger (7) is also connected to an outlet of the upper part (61) of the reserve (6) by a fourth pipe (54) of the coolant circuit (5). Device according to one of claims 1 or 2, characterized in that the first pipe (51), the second pipe (52) and the third pipe (53) of the coolant circuit (5) define a first refrigeration loop of the device. Device according to one of claims 2 or 3, characterized in that the fourth pipe (54), the second pipe (52) and the third pipe (53) of the coolant circuit (5) define a second refrigeration loop of the device. Device according to the preceding claim, characterized in that the first refrigeration loop and the second refrigeration loop are configured to be put into service simultaneously or sequentially. Device according to any one of the preceding claims, characterized in that the first branch portion (10) connects the first pipe (51) to the second pipe (52). Device according to any one of the preceding claims, characterized in that the reserve (6) comprises at least one perforated transverse plate configured to separate the upper (61) and lower (62) parts of the reserve (6) so as to limit the transfers of coolant between the hot mass located at the upper part (61) and the cold mass located at the lower part (62). Device according to any one of the preceding claims, characterized in that the coolant circuit (5) comprises a second branch portion (11) connecting the second pipe (52) to the third pipe (53) to allow all or part of the coolant leaving the at least one first heat exchanger (7) to return to the reserve (6) without passing through the second heat exchanger (9). Device according to any one of the preceding claims, characterized in that the coolant circuit (5) comprises a third branch portion (12) connecting the third pipe (53) to the second pipe (52) to allow all or part of the coolant at the outlet of the second heat exchanger (9) to return to said second exchanger (9) without passing through the reserve (6) or through the at least one first heat exchanger (7). Device according to any one of the preceding claims, characterized in that the coolant circuit (5) comprises at least one member (13, 14) for circulating the coolant in the coolant circuit (5) and/ or at least one member (15, 16) for controlling the temperature of the coolant. Device according to the preceding claim, characterized in that the coolant circuit (5) comprises at least one set of valve(s) (17, 18, 19) configured to control the flows in the circuit (5), for example a or three-way valves arranged at a junction between two or more of the pipes (51, 52, 53, 54) and/or the diversion portions (10, 11, 12). Device according to the preceding claim, characterized in that the first diversion portion (10) and the second diversion portion (11) are connected to the second pipe (52) by the same set of valves (18), for example a valve three lanes. Method of filling a pressurized gas tank by means of a device (1) according to any one of the preceding claims, in which a flow of coolant is transferred through the first diversion portion (10) selectively from the at least a first heat exchanger (7) towards the lower part (62) of the reserve (6), or from the lower part (62) of the reserve (6) towards the second heat exchanger (9) without passing through the at least a first heat exchanger (7). Method according to the preceding claim, in which the flow of coolant transferred from the lower part (62) of the reserve (6) to the second heat exchanger (9) without passing through the at least one first heat exchanger (7). is in addition to or in substitution for a flow of coolant transferred from the at least one first heat exchanger (7) to the second heat exchanger (9). Method according to the preceding claim, comprising a step of circulating a hot mass flow and a cold mass flow of the coolant from the reserve (6) towards the at least one first heat exchanger (7) through respectively the first pipe (51) and the fourth pipe (54) to regulate the temperature of the coolant at the inlet and/or outlet of the at least one first heat exchanger (7).