FR3101917A1 - Single radiator cooling system - Google Patents

Abstract

The present invention relates to a cooling system which comprises three closed circuits for circulating thermal fluid and a heat exchanger (2) common to the first circuit (c1), operating at high temperature and to the second circuit (c2), operating at low temperature. and a third circuit (c3), operating according to the Rankine cycle (ORC), connecting an evaporator (E) of the first circuit (c1) and a condenser (C) of the second circuit (c2). Figure 4 to publish.

Description

Single radiator cooling system

The subject of the invention is a cooling system for a vehicle comprising an internal combustion engine, to which is added a heat recovery circuit, in particular with electric hybridization.

Conventional heat engine cooling circuits pass through equipment such as radiators to release the heat acquired by the heat transfer fluid, crossing the engine. Such systems are generally formed of a closed circuit, in which circulates a cooling fluid, in particular a mixture of water and ethylene glycol. Such a closed circuit can include a pump, heat exchangers with the internal combustion engine and/or its equipment, a thermostat, a radiator, and a heater. The heat dissipated in the radiators is however lost, and this is why more complete devices, including a heat recovery circuit added to the cooling circuit, have also been developed. The applicant was particularly interested in organic Rankine cycle or ORC thermal energy recovery circuits embedded in transport systems preferably with electric hybridization such as cars, trucks, trains, stationary engines, etc.

As it is widely known, the Rankine cycle is a thermodynamic cycle by which heat from an external heat source is transmitted to a closed circuit which contains a fluid, called working fluid or heat transfer fluid. This type of cycle generally breaks down into a step during which the working fluid used in liquid form is compressed isentropically, followed by a step where this compressed liquid fluid is heated and vaporized in contact with a heat source. This vapor is then expanded, during another stage, in an isentropic manner in an expansion machine, then, in a final stage, this expanded vapor is cooled and condensed in contact with a cold source. To carry out these different steps, the circuit generally comprises a compressor pump to circulate and compress the fluid in liquid form, an evaporator which is swept by a hot fluid to achieve at least partial vaporization of the compressed fluid, an expansion machine to expand superheated steam, such as a turbine, which transforms the energy of this steam into another energy, such as mechanical or electrical energy, and a condenser through which the heat contained in the steam is transferred to a cold source, generally the outside air which sweeps this condenser or a liquid loop at low temperature, to transform this vapor into a fluid in liquid form.

For the field of internal combustion engines, conventional Rankine cycles consist of the insertion of a coolant loop for the recovery of heat losses from the engine. In general, this recovery is carried out on the exhaust gases and/or the EGR gases (exhaust gas recirculation), or on the cooling circuit or on both simultaneously.

When this recovery is carried out on the cooling system, the Rankine cycle evaporator allows a heat exchange between the cooling fluid and the heat transfer fluid of the Rankine cycle. The evaporator can generally be located on the recirculation branch of the cooling circuit upstream of the thermostat to benefit from all the flow coming from the engine or downstream of the thermostat on the radiator branch so as not to disturb the regulation in engine temperature.

Under these conditions, recuperation must be controlled, in particular in cold internal combustion engine conditions, so as not to penalize the rise in engine temperature, which could harm its performance by degrading fuel consumption and pollutant emissions during this period. phase. Once the internal combustion engine has reached the ideal operating temperature, the thermostat located downstream of the Rankine circuit heat exchanger sends the excess calories from the cooling circuit not removed by the Rankine cycle back to the radiator.

On light or heavy vehicles, the increase in cooling needs and the different levels of regulation temperature, namely at high temperature (HT) from 80 to 100°C for the internal combustion engine and at low temperature (BT) from 30 at 60°C for the electric motor, the batteries, electrical components and the supercharging air, require the use of several dedicated and separate cooling circuits as well as the implementation of several radiators to evacuate the calories from each circuit in front of the vehicle. With the increasing complexity of vehicles and the addition of functions requiring cooling, the space available to house the radiators on the front panel is very limited, and requires the optimization of the available space. Very often an HV radiator and a LV radiator are thus placed in cascade one in front of the other or one next to the other with masking effects, which affects their efficiency and leaves little possibility of increase in useful cooling power necessary in the event of the addition of a low temperature ORC which requires cooling on its condenser.

Document US2018/0064002A1 relates to a single radiator cooling device for a hybrid vehicle. The solution offers "split cooling" with part of the flow to the electrical system and a second part to the heat engine. The part dedicated to cooling the electrical part is subject to a phase change.

Document US2017/0007575A1 relates to a shared HT and LT radiator device. The HT radiator is normally dedicated to cooling the internal combustion engine and the BT radiator to cooling the ORC circuit present on the vehicle. The vehicle's HV and LV circuits are connected by a 2-way valve allowing circuits to be mixed and the flow rates to be adjusted in each of them. This adjustment valve is opened or closed depending on the load conditions of the combustion engine. When the engine is lightly loaded, the valve is open, the ORC circuit can thus benefit from the LV radiator as well as the HT radiator for its cooling. The exchange surface is thus increased by pooling the surfaces. The device disclosed in this document includes an engine radiator which can thus be used for cooling the engine or that of the ORC thanks to a "split cooling" device associated with a 2-way valve.

In general, the cooling capacity of the high temperature (HT) engine radiator is oversized for the typical use of a user who uses the engine at partial load. This maximum exchange power is only useful in critical cases of cooling needs, such as high power dissipation, coupled with low air speed on the heatsink and high outside temperatures.

Under normal conditions of use, the internal combustion engine is under little stress and the available cooling surface is underused. This exchange surface of the HT radiator is taken to the detriment of the vehicle's LT cooling or ORC condenser, which are often dimensioned as accurately as possible even in the vehicle's nominal operating conditions.

The cooling devices according to the prior art have the disadvantage of implementing a complex and oversized cooling system. The invention consists in proposing an optimized cooling architecture with a single radiator for a heat engine preferably associated with electric hybridization and equipped with an ORC system. The HT cooling circuit necessary for the operation of the heat engine and the ORC thus consists of a single radiator shared between the heat engine, the ORC circuit and the other components present on the vehicle and requiring BT cooling such as a battery , electric machine, power electronics, charge air cooler, etc. In addition to the advantages in terms of optimizing the vehicle's cooling performance, pooling vehicle cooling within a single low-temperature loop simplifies the vehicle's cooling circuit in the presence of an ORC and a possible solution. electrical hybridization, and therefore potentially a reduction in cost and size and increase the reliability of the whole. In this configuration, the vehicle thus has a single large-capacity radiator on the front face.

The present invention relates to a cooling system for a vehicle comprising a spark-ignition or compression-ignition heat engine, to which is added a heat recovery circuit, in particular with electrical hybridization.

According to the invention, the cooling system comprises three closed thermal fluid circulation circuits: the first circuit comprising at least one heat engine, an evaporator, a first circuit pump, a thermostat and a heat exchanger, the second circuit comprising at least one at least one condenser, one pump of the second circuit and one heat exchanger connected in series, and the third circuit, according to the Rankine cycle, comprising at least one evaporator, one condenser, one turbine and one pump of the third circuit connected in series, in which :
- a single and unique cooling fluid circulates in the first and second circuits, and a heat transfer working fluid circulates in the third circuit,
- the heat exchanger of the first circuit and the heat exchanger of the second circuit is a single and unique heat exchanger,
-within said evaporator, the cooling fluid of the first circuit exchanges heat with the working fluid of the third circuit,
within said condenser, the cooling fluid of the second circuit exchanges heat with the working fluid of the third circuit.

According to one embodiment, the cooling system also comprises an air heater and a bypass of the air heater in the first circuit. According to one embodiment, the cooling system includes an evaporator bypass in the first circuit and includes a condenser bypass in the second circuit.

According to one embodiment of the cooling system, the air heater and the evaporator are connected in series or in parallel in the first circuit.

According to one embodiment, the cooling system also comprises at least one element to be cooled, in particular a RAS (charge air cooler), BATT (battery) and MEL (electric machine) in the second circuit.

According to one embodiment of the cooling system, the various elements to be cooled are mounted in series, parallel or a combination of both.

According to one embodiment of the cooling system, the first, second and third circuits comprise progressive valves.

The invention also consists of a method of using the cooling system, in which in the engine warm-up mode, the thermostat of the first circuit is closed, the pumps of the first circuit and the second circuit are activated and the pump of the third circuit is disabled. It should be noted that disabling the pump of the third circuit has a result equivalent to the installation of bypass devices at the level of the evaporator and the condenser since in both cases there is no exchange of heat between the first circuit and the second circuit through the third circuit.

The invention also consists in a method of operating the cooling system, in which in mixed mode the thermostat of the first circuit is closed and the pumps of all three circuits are activated.

The invention also consists in a method of operating the cooling system, in which in high load mode, the thermostat of the first circuit is open, the pumps of the first and second circuits are activated, and the pump of the third circuit is deactivated. It should be noted that disabling the pump of the third circuit has a result equivalent to the installation of bypass devices at the level of the evaporator and the condenser since in both cases there is no exchange of heat between the first circuit and the second circuit through the third circuit.

The invention also consists of a method of using the cooling system, in which transitional phases within the three operating modes and between the three operating modes are carried out by varying the rotational speeds of the pumps of the three circuits and by gradually opening the thermostat of the first circuit according to the temperature of the cooling system and the level of engine load observed.

The invention also consists of a vehicle, in particular a motor vehicle, comprising a cooling system, in which said heat exchanger is arranged close to an air inlet.

Other characteristics and advantages of the method according to the invention will appear on reading the following description of non-limiting examples of embodiments, with reference to the appended figures and described below.

List of Figures

Fig. 1 illustrates a standard prior art diagram with two stacked radiators.

Fig. 2 illustrates a standard prior art diagram with two stacked radiators.

Fig. 3 illustrates a standard prior art layout with three stacked radiators.

Fig. 4 illustrates, schematically and in a non-limiting manner, the detail of an implementation of the invention according to one embodiment.

Fig. 5 illustrates, schematically and in a non-limiting manner, the detail of an implementation of the invention according to the temperature rise operating mode.

Fig. 6 illustrates, schematically and in a non-limiting way, the detail of an implementation of the invention according to the mixed mode of operation.

Fig. 7 illustrates, schematically and in a non-limiting way, the detail of an implementation of the invention according to the high load operating mode.

Detailed description of figures

The system according to the invention comprises several types of heat exchangers. The heater, the supercharging air (RAS) and the heat exchanger (the radiator), can be exchangers of the liquid/air type. The exchangers in the heat engine, in the electric motor and the batteries can be conduction exchangers between a hot body and a liquid circuit. The evaporator and the condenser can be exchangers of the liquid/liquid type.

The single radiator cooling system according to the invention proposes to rationalize and optimize the cooling needs of the vehicle by using a single radiator with an optimized surface, that is to say an equivalent surface representing at most the sum of the surfaces of the low temperature radiator. , the high temperature radiator, and the ORC condenser of a circuit according to the prior art. The radiator can be positioned on the front of the vehicle and can operate preferentially at low temperatures in the 30-60°C range. It simultaneously cools the internal combustion engine when the thermostat opens, the ORC system (organic Rankine cycle) when it is in operation, and any other cooled components on the vehicle, such as the heat exchanger. charge air, a battery, power electronics, an electrical machine, etc. Indeed, the various members to be cooled are generally not cooled concomitantly. More specifically, in the case of a hybrid system in which there is an alternation between the use of the combustion engine and the electric machine, the cooling needs switch between the two engines.

The invention proposes a simplification of all the exchangers cooling the vehicle by pooling the cooling loop for the components cooled around a single radiator.

Fig. 1 illustrates a standard diagram of the prior art with a heat engine (1) with a first high temperature HT cooling loop (c1), comprising a pump of the first circuit (P1) operating over a temperature interval of between 80-100 °C, a thermostat (T1) and a second low temperature cooling loop (c2) BT, operating over a temperature range of between 30-60°C. The two loops are separate and implement two radiators (2a, 2b) stacked one behind the other. The second circuit (c2) cools low temperature elements BT and comprises a pump of the second circuit (P2), a hydraulic flow restrictor (R) and a thermostat (T2) connected in series. The hydraulic flow restrictor (R) and the thermostats (T1, T2) can of course be replaced by any other flow regulating device, such as for example valves. These valves can preferably be progressive and managed by a control unit based on temperature sensors and following operating logics aimed at optimizing the cooling system. The devices to be cooled in the second circuit (c2) can be a battery (not shown), an electric machine (MEL) and its electronic power module (not shown) and the charge air (RAS).

Fig. 2 illustrates a standard prior art diagram of FIG. 1 with the flow distribution typical for use on the motorway. The arrows represent the direction of circulation of the coolant and the thickness of the arrows represents the amplitude of the flow in each portion of the circuit.

Fig. 3 illustrates a standard prior art diagram of FIG. 1 with a third ORC heat recovery loop (c3) operating over a temperature range of between 30-60°C. The third loop (c3) connects an evaporator (E), a third pump (P3), a condenser (C) and a turbine (T). The three loops are separated from each other and implement three radiators and condenser (2a, 2b, C) stacked one behind the other or next to each other depending on the space available .

The proposed solution is a cooling system for a vehicle comprising three closed circuits (c1, c2, c3), cf. Fig. 4.

Fig. 4 illustrates the diagram of an implementation of the invention with a first high temperature HT cooling loop (c1), able to operate over a temperature range of between 80-100°C, a second cooling loop (c2) low temperature BT, able to operate over a temperature range between 30-60°C and a third (c3) ORC heat recovery loop (organic Rankine cycle) able to operate over a temperature range between 30-60°C . These three circuits comprise at least one heat source, a cooling exchanger and a pump for circulating the heat transfer liquid between the constituent elements of the circuit. In this architecture, two cooling loops (hereafter also called circuits) can be distinguished, mounted in parallel with each other, separated by an HT thermostat and connected to a single radiator. On each loop a pump ensures the circulation of the coolant in the circuit. At the junction point of the two circuits (c1) and (c2) the heat transfer liquid which arrives, in an operating mode, at a different temperature (HT and BT) in each of the first and second circuits (c1) and (c2) is mixed and its mixing temperature is defined according to the respective flow rates in each loop.

In detail, the first circuit (c1) comprises at least one heat engine (1), an evaporator (E), a first circuit pump (P1), a thermostat (T1) and a heat exchanger (2), named by the suite also radiator. The primary role of this first circuit (c1) is to cool at least the heat engine (1). The evaporator (E) evacuates part of the heat from the first circuit (c1) to the circuit (c3). In addition, the first circuit may include a heater (A) for heating the passenger compartment of the vehicle. For this embodiment, as the heat engine (1) rises in temperature, the heater (A) can be the first exchanger to evacuate the heat from the circuit. When the engine (1) approaches and reaches its optimum operating temperature, the evaporator (E) is also caused to evacuate the heat from the circuit (c1) to the circuit (c3). This is achieved by gradually putting the pump of the third circuit (P3) into operation. Finally, the gradual opening of the thermostat (T1) allows the evacuation of heat through the heat exchanger (2). We can therefore note a progressive response of the circuit according to the rise in temperature of the thermal engine and according to the thermal power to be evacuated.

The second circuit (c2) cools low temperature elements BT and comprises at least one condenser (C), a second circuit pump (P2) and a heat exchanger (2) connected in series. The elements can be mounted in series or parallelized on each cooling loop. A preferential order can be defined between the elements between them according to the chosen configuration. According to one embodiment of the invention, the second circuit (c2) can comprise at least one device to be cooled. The devices to be cooled in the second circuit (c2) can be a battery (not shown), an electric machine (MEL) and its electronic power module (not shown), the charge air (RAS). The preferred order of systems to be cooled on the series LV loop may be: condenser (C), battery, electrical machine(s) (MEL) and charge air cooling (RAS) in order to benefit lowest temperatures to ensure the proper functioning of the ORC. However, any other series/parallel order and arrangement combining series and parallel assembly is possible, in order to best meet the cooling requirements and the specific constraints of the vehicle. The second circuit (c2) may also optionally comprise a hydraulic flow rate restrictor (R) which may contribute to regulating the temperature within this circuit by modifying the flow rates in each branch.

The third circuit (c3), operating according to the Rankine cycle, comprises at least one evaporator (E), a condenser (C), a turbine (T) and a third circuit pump (P3) connected in series. The third circuit (c3) makes it possible to recover energy, by means of the turbine (T) of the Rankine cycle circuit. The turbine (T) can be connected to an electric generator (not shown) or any other energy recovery device.

The system according to the invention comprises the following particularities:
- a single and unique cooling fluid circulates in the first (c1) and second (c2) circuits, in other words, the circuits (c1) and (c2) are connected to each other at the level of the heat exchanger (2);
-a working fluid circulates in the third circuit (c3);
- within said evaporator (E), the cooling fluid of the first circuit (c1) exchanges heat with the working fluid of the third circuit (c3),
-within said condenser (C), the cooling fluid of the second circuit (c2) exchanges heat with the working fluid of the third circuit (c3).

According to one embodiment of the invention, the cooling system may also comprise within the first circuit (c1) an air heater (A) for the passenger compartment heating and possibly a bypass (not shown) of the air heater, which allows a faster rise in temperature of the heat engine. Optionally, the first circuit (c1) can also include other HV elements, such as an exchanger on the exhaust gases (not shown) to accelerate the rise in temperature of the engine, etc.

According to another embodiment of the invention, the cooling system may include a bypass (not shown) of the evaporator (E) in the first circuit (c1) and said second circuit (c2) may include a bypass (not shown ) of the condenser (C). This makes it possible not to circulate the liquid in the evaporator (E) and the condenser (C) during transition phases, such as the temperature rise of the heat engine (1) or when the thermal conditions in the system are not not met to operate the third circuit (c3). It should be noted that disabling the pump of the third circuit (P3) has a result equivalent to the installation of bypass devices at the level of the evaporator (E) and the condenser (C) because in both cases there is no heat exchange between the first circuit (c1) and the second circuit (c2) through the third circuit (c3).

According to another embodiment of the invention, the heater (A) and the evaporator (E) can be connected in series or in parallel within the first circuit (c1).

According to another embodiment of the invention, the second circuit (c2) may also comprise at least one element to be cooled, in particular a charge air exchanger (RAS), electrical components such as the battery or the storage of the electrical energy (not shown), one or more electrical machines (MEL) and corresponding power electronic module (not shown), in addition to the condenser (C), the heat exchanger (2) and the pump (P2). The different elements to be cooled can be connected in series, parallel or a combination of both.

According to another embodiment of the invention, the first, second and third circuits (c1, c2, c3) can comprise progressive valves (not shown). The progressive valves make it possible to change between the different operating modes of the system in a progressive way to continuously optimize the performance of the system taking into account parameters such as the load of the motors, the temperatures in the three circuits and in the environment in which it takes place. finds the system, the operating strategies depending on whether performance is sought, battery charging in the case of a hybrid system, reduction of pollutants, etc.

Several operating modes of the cooling loops can be implemented depending on the life of the vehicle. These different implementations are independent.

The invention also consists of a method of using the cooling system in which in temperature rise mode (cf. Fig 5), the thermostat (T1) of the first circuit (c1) is closed, the evaporator (E) and the condenser (C) are bypassed and the pumps of the first circuit (P1) and of the second circuit (P2) are activated. The thermostat (T2) of the second circuit (c2) is closed or slightly open. The thermostat (T2) of the second circuit (c2) and the hydraulic flow restrictor (R) are optional. It should be noted that disabling the pump of the third circuit (P3) has a result equivalent to the installation of bypass devices at the level of the evaporator (E) and the condenser (C), since in both cases figure, there is no heat exchange between the first circuit (c1) and the second circuit (c2) through the third circuit (c3). In this engine temperature rise mode (also called engine heater), the heat engine (1) is still at a temperature below its nominal regulation temperature. Under these conditions, two preferential circulations are to be considered and marked in black line on the diagram Fig. 5. The circuits in gray are not operational. Under these conditions, the radiator (2) is only used to cool the LV components of the second circuit (c2) when necessary and the ORC of the third circuit (c3) is not operational.

The invention also consists of a method of using the cooling system in which in mixed mode (cf. Fig. 6), the thermostat (T1) of the first circuit (c1) is closed or slightly open and the pumps of the three circuits (P1, P2, P3) are activated. In this mixed mode, the combustion engine (1) is at the ideal operating temperature. The ORC system (circuit c3) is started and recovers via the evaporator (E) the available thermal power supplied by the thermal engine (1). Under these conditions, all or almost all of the HT thermal power of the first circuit (c1) is transferred to the LV loop via the ORC system, and only a small flow possibly transits to the radiator (2) via the thermostat (T1) slightly open when the ORC system is unable to recover all of the heat flow from the heat engine (1). The second circuit (c2) takes priority in the use of the radiator (2) and fixes the temperature of the water mixture in the radiator, preferably between 30 and 60°C. The heat engine (1) is mainly cooled by the ORC system of the third circuit (c3) by heat exchange by the evaporator (E) and, depending on the capacity of the evaporator (E) to evacuate the heat load, also by the radiator (2) in low temperature condition. The wide opening of the thermostat (T2) and the restriction imposed by the hydraulic flow restrictor (R) have the purpose of passing the entire flow of the second circuit (c2) into the radiator (2), which operates in BT mode. The thermostat (T2) of the second circuit (c2) and the hydraulic flow restrictor (R) are optional.

The invention also consists of a method of using the cooling system in which in high load mode (cf. Fig. 7), the thermostat (T1) of the first circuit (c1) is opened more significantly (to arrive at full opening depending on the temperature) that in the temperature rise mode, the evaporator (E) and the condenser (C) are bypassed and the pumps of the first and second circuits (P1, P2) are activated. It should be noted that disabling the pump of the third circuit (P3) has a result equivalent to the installation of bypass devices at the level of the evaporator and the condenser since in both cases there is no heat exchange between the first circuit (c1) and the second circuit (c2) through the third circuit (c3). The shaded branches in Fig. 7 represent the deactivation of the third circuit (c3), the thin black lines represent the passage of a low flow and the branches represented in thick black represent the parts of the circuit with a very high or maximum flow.

By way of example, the realization of this mode of operation under heavy load can advantageously comprise the use of a temperature sensor (not shown) on the first circuit (c1) downstream of the thermostat. This sensor is used to monitor the temperature of the coolant. When the load on the heat engine is such that the temperature exceeds a high threshold, a control unit (not shown) can consider that the system is in high load mode. The first circuit (c1) then takes priority for the evacuation of the thermal load, the pump of the first circuit (P1) is activated at its maximum operating speed, and the heat exchanger (2) switches to HT mode. Therefore, the pump of the third circuit (P3) is deactivated because the recovery of energy by means of the ORC is then stopped. Finally, the pump of the second circuit (P2) is activated at low or intermediate speed because the coolant leaving the heat exchanger (2) reaches a very high temperature to allow optimal cooling of the components located on the second circuit (c2).

In this high load operating mode, the heat engine (1) is under high load conditions with limited vehicle cooling capacities, such as a rise in the neck and therefore the cooling capacities of the radiator (2) operating at BT are no longer sufficient to clear the thermal load. The third circuit (c3) is no longer able to transfer the thermal power emitted by the heat engine (2) to the LV loop. Under these conditions, the thermostat (T1) will open significantly to allow the heat engine to cool. The coolant to the radiator then rises in temperature, preferably around 80-100°C, given the increase in flow rates from the heat engine (1). The single cooling circuit then behaves like a conventional high-temperature circuit. The LV loop, i.e. the second circuit (c2), is no longer cooled at low temperature. The third circuit pump (P3) is deactivated, so the evaporator (E) and the condenser (C) are also deactivated because the ORC no longer works. Under these heavy load conditions, the electrical part of the vehicle and its power electronics are, as a general rule, not operational. The cooling of the supercharging air (RAS), carried out at a relatively high temperature is degraded, which can lead to a reduction in the performance of the supercharging and a drop in the performance of the vehicle. Despite these degraded conditions, the combustion engine (1) is cooled satisfactorily with a large heat exchange surface dedicated to it to guarantee its reliability.

According to one embodiment of the invention, the method of using the system can comprise the three implementations described above (temperature rise mode, mixed mode and high load mode) depending on the desired mode.

According to an embodiment of the invention, the method of using the cooling system includes transient phases within the three modes of operation and between the three modes of operation. These transient phases are achieved by varying the speeds of rotation of the pumps of the three circuits (P1, P2, P3) in a differentiated manner and by gradually opening the thermostats (T1, T2) and the bypasses if necessary. These actuators are managed by a control unit (not shown) which takes account of at least one sensor (not shown) measuring the temperature of the first circuit (c1).

The invention also consists of a vehicle, in particular a motor vehicle, comprising a cooling system as defined above, in which said heat exchanger (2) is arranged close to an air inlet. In order to control this cooling system more finely, information from other temperature sensors on the branches of the circuits (c1, c2 and c3) and of the surrounding air can possibly be integrated into the control unit. Obviously, the control unit is able to control other actuators such as a fan to force the air flow in front of the radiator, the opening of the ventilation openings modifying the coefficient of penetration into the air of the vehicle and the irrigation of the radiator, etc.

It goes without saying that the invention is not limited solely to the embodiments of the recesses, described above by way of example, on the contrary it embraces all variant embodiments.

Claims (12)

Cooling system for a vehicle comprising three closed thermal fluid circulation circuits (c1, c2, c3), the first circuit (c1) comprising at least one heat engine (1), an evaporator, a pump of the first circuit (P1) , a thermostat (T1) and a heat exchanger (2), the second circuit (c2) comprising at least one condenser, a second circuit pump (P2) and a heat exchanger (21) connected in series, and the third circuit ( c3), according to the Rankine cycle, comprising at least one evaporator (E), a condenser (C), a turbine (T) and a third circuit pump (P3) connected in series, characterized in that:
-a single and unique cooling fluid circulates in the first (c1) and second (c2) circuits, and a working fluid circulates in the third circuit (c3),
- the heat exchanger (2) of the first circuit (c1) and the heat exchanger (2) of the second circuit (c2) is a single and unique heat exchanger (2),
- within said evaporator (E), the cooling fluid of the first circuit (c1) exchanges heat with the working fluid of the third circuit (c3),
-within said condenser (C), the cooling fluid of the second circuit (c2) exchanges heat with the working fluid of the third circuit (c3). Cooling system according to Claim 1, in which the first circuit (c1) also comprises an air heater (A) and preferably an air heater bypass. A cooling system according to claim 1 or 2, wherein said first circuit (c1) comprises an evaporator bypass and said second circuit (c2) comprises a condenser bypass. Cooling system according to Claim 2, in which, within the first circuit (c1), the air heater (A) and the evaporator (E) are connected in series or in parallel. Cooling system according to one of the preceding claims, in which the second circuit (c2) also comprises at least one element to be cooled, in particular a charge air cooler (RAS) and an electric machine (MEL). Cooling system according to Claim 5, in which the various elements to be cooled are connected in series, parallel or a combination of the two. Cooling system according to one of the preceding claims, in which the first, second and third circuits (c1, c2, c3) comprise progressive valves. Method of using the cooling system according to one of Claims 1 to 7, in which, in temperature rise mode, the thermostat (T1) of the first circuit (c1) is closed and the pumps of the first circuit (P1) and of the second circuit ( P2) activated. Method of using the cooling system according to one of Claims 1 to 7, in which in mixed mode the thermostat (T1) of the first circuit (c1) is closed and the pumps of the three circuits (P1, P2, P3) are activated. Method of using the cooling system according to one of Claims 1 to 7, in which, in full load mode, the thermostat (T1) of the first circuit (c1) is open and the pumps of the first and second circuits (P1, P2) are activated . Method of using the cooling system according to Claims 8 to 10, in which transitional phases within the three operating modes and between the three operating modes are carried out by varying the speeds of rotation of the pumps of the three circuits in a differentiated manner. (P1, P2, P3) and gradually opening the thermostat (T1) of the first circuit (c1). Vehicle, in particular motor vehicle, comprising a cooling system according to one of Claims 1 to 7, in which the said heat exchanger (2) is arranged close to an air inlet.