FR2944237A1 - COOLING DEVICE FOR MOTOR VEHICLE - Google Patents

Abstract

The subject of the invention is a cooling device (1) for a motor vehicle, comprising a cooling circuit capable of cooling an engine assembly (5) with the aid of a cooling liquid cooled by a radiator (6) coupled to a fan (13) with several speed levels, the fan (13) being controlled by a control system (9), characterized in that the control system (9) is able to control the speed level of the fan (13). ) depending on the temperature of the coolant, the control of the passage of a lower speed level to a higher speed level of the fan (13) being a function of a so-called rising target temperature, the control of the passage of said level a speed higher than said lower speed level being a function of a so-called descending target temperature lower than the rising target temperature.

Description

The invention relates to a cooling device for a motor vehicle, comprising a cooling circuit capable of cooling an engine assembly with a cooling liquid cooled by a radiator coupled to a cooling fan. several levels of speed. The invention is advantageously applicable to electric motor vehicles.

In an internal combustion engine, the repeated combustions overheat the parts in contact, such as pistons, cylinders, and valves, and diffuse on all mechanical parts of the engine. They must therefore be cooled under pain of destruction. For proper operation, the combustion engines thus need a regular and suitable temperature. In the case of a vehicle with electric propulsion, it is also necessary to cool the various elements of the power train. It is known to use a cooling system comprising one or more pumps for circulating a coolant through the engine, and a radiator, which is a heat exchanger for cooling the liquid. The radiator is usually coupled to a fan. The fan is a motor-driven blade apparatus used to force the passage of outside air into the radiator to absorb heat from the engine coolant. To adapt the cooling to the desired cooling, the fan is typically at several speeds, which are controlled by switches called control relays. In order not to use the control relays, it is desirable not to switch them too often.

The device according to the invention makes it possible to achieve this objective. The subject of the invention is a cooling device which makes it possible to extend the service life of the fan control relays.

The subject of the invention is thus a cooling device for a motor vehicle, comprising a cooling circuit capable of cooling an engine assembly by means of a coolant cooled by a radiator coupled to a fan with several levels of speed. the fan being controlled by a control system. According to the device according to the invention, the control system is able to control the fan speed level as a function of the coolant temperature, the control of the passage from a lower speed level to a higher speed level of the engine. fan being a function of a so-called rising target temperature, the control of the passage of said speed level higher than said lower speed level being a function of a so-called descending setpoint temperature lower than the rising target temperature.

Thus, the hysteresis control of the speed changes of the fan makes it possible not to carry out too frequent switching of the control relays. The fan may be further coupled to an air conditioning system and the control system is advantageously adapted to control the fan speed level according to a cooling need of the air conditioning system. The motor vehicle may be an electric vehicle and the engine assembly may include an electronic control system.

The electric vehicle may comprise a battery charger assembly and the cooling circuit is advantageously capable of cooling the charger assembly and the motor assembly. The control system is preferably adapted to control the fan speed level according to a cooling need of the charger assembly or the motor assembly. The device may comprise a first pump capable of selectively supplying cooling liquid to the motor assembly and a second pump capable of selectively supplying cooling liquid to the charger assembly.

For this purpose, the device may comprise a first valve adapted to prevent a passage of coolant in the charger assembly and a second valve adapted to prevent a passage of coolant in the motor assembly. The device may also include a hydraulic restriction to maintain a minimum flow of coolant in the engine assembly. The control system is advantageously capable of controlling the flow rate of each pump in a closed-loop control system as a function of the temperature of the coolant and a set temperature. Thus, the servocontrol of the flow rate of each pump in a closed loop makes it possible to limit its wear and its energy consumption. Other features and advantages of the present invention will emerge more clearly on reading the following description given by way of illustrative and nonlimiting example and with reference to the appended drawings in which: FIG. 1 illustrates in the form of a schematic diagram; blocks a cooling device according to the invention, integrated in an electric vehicle; - Figure 2 illustrates in block diagram form a control strategy of the device; - Figure 3 is a first diagram useful for understanding the strategy of Figure 4 illustrates in block diagram form a portion of the control strategy, and Figure 5 is a second diagram useful for understanding the control strategy. The cooling device 1, as illustrated in FIG. 1, comprises a first electric pump 2, a second electric pump 3, a battery charger 4, a motor assembly 5, a radiator 6 and a first solenoid valve 7. and a second solenoid valve 8. The first electric pump 2, the second electric pump 3, the first solenoid valve 7 and the second solenoid valve 8 are connected to a control device 9. The first electric pump 2 is intended to be used when driving the vehicle. vehicle, while the second electric pump 3 is intended to be used when recharging the battery. The flow rate of the first pump 2 and the flow rate of the second pump 3 can be adjusted by means of a control signal. The charger 4 allows, when the vehicle is stopped, to recharge the electric traction battery, not shown, from the home electrical network. The first solenoid valve 7 makes it possible to short-circuit the second pump 3 and the charger 4 while driving the vehicle, whereas the second solenoid valve 8 makes it possible to short-circuit the motor assembly 5 during charging of the battery, when it is believed that the cooling of the motor assembly 5 is not necessary. The second solenoid valve 8 can be connected to a hydraulic restriction 10 which makes it possible to achieve a pressure drop and thus to maintain a flow rate of coolant in the engine assembly 5, even when the second solenoid valve 8 is passing. 5 comprises a motor 11 and an electronic control system 12 intended in particular to transform the DC voltage of the battery into AC voltage. The radiator 6 is used to cool the coolant, similar to the cooling device of an internal combustion engine. It is equipped with a motor-fan 13 provided with rotating blades. The fan 13 may comprise three levels of speed of rotation of the blades: a zero speed, a low speed and a high speed.

It is necessary to cool the motor assembly 5 when driving the vehicle, and the charger 4 when the vehicle is stopped. The cooling strategy is managed by the control device 9. The control device 9 is a computer which is connected with sensors of the cooling circuit, in particular coolant temperature sensors. The computer 9 also controls the pumps 2,3, the solenoid valves 7,8, and the motor-fan unit of the radiator 6. The computer 9 is also advantageously connected to other computers of the vehicle, via a network of the type For example, the Controller Area Network (CAN) bus provides additional measures necessary for the cooling strategy. The control strategy of the cooling circuit can be carried out in the form of three modules A, B, C, as shown in Figure 2. Module A concerns the regulation of the temperature of the coolant. Module B concerns the choice of the electric pump 2,3. The module C relates to the control of the fan 13. The module A is responsible for developing a control of coolant flow rate according to the state of the vehicle (driving or recharging 30 the battery when stopped). The inputs of module A are: - the temperature T of the coolant: it can be obtained using one or more temperature sensors, - the temperature Text outside the vehicle, and - the speed V of the vehicle.

The inputs of module B are: - the flow control Dcom from module A, and - the state E of the vehicle: it is a signal coming from the central computer of the car which is worth 1 if one is in charging mode of the battery of the vehicle and which is worth 0 if one is in mode rolling.

The outputs of module B are: - the flow control Dcomi of the first pump, used in running mode. This is a signal between 0 and 100 and expressing the percentage of the maximum flow rate that can be achieved by the pump, and - the flow control Dcom2 of the second pump, used in charging mode. It is a signal between 0 and 100 and expressing the percentage of the maximum flow rate that can be achieved by the pump. In a simple manner, it is possible to choose to use only the second pump if the signal of the state of the vehicle is 1 and to use only the first pump if the signal of the state of the vehicle is 0.

The purpose of Module B is to automatically vary the flow control between a minimum flow value Dmin and a maximum flow value Dmax, depending on the temperature of the coolant. As long as the coolant temperature is lower than a set temperature, the flow control remains at the minimum value Dmin • As soon as the coolant temperature exceeds the set temperature, the flow control is obtained by regulating closed loop, the setpoint considered being the target temperature, and the reaction loop considered being the measured temperature of the coolant.

The inputs of the module C are: the cooling signal Sr. This is a logic signal produced, for example, in the central computer. This signal is the synthesis of the different signals coming from the various members of the traction system, which may be temperature sensors arranged near the engine, the charger and / or the electronic control system. If the signal is 0, there is no temperature alert from the organs. If it is 1, it means that at least one of the organs starts to be hot, and if it is 2, it indicates that at least one of the organs is in fault due to overheating. Thus, as soon as the signal is different from 0, the intensity of the cooling must be increased, the speed V of the vehicle, the temperature T of the coolant, and the control Cc. It is a logic signal, internal to the central computer, and is developed by a module responsible for carrying out the control commands of the air conditioning system of the vehicle. The signal Cc can take the value 0 (no fan control), the value 1 (fan control at low speed) or the value 2 (fan control at high speed). The output of the module C is the command C? Which is sent to the fan. The Cä control takes into account both the cooling needs of the air conditioning system and the need for cooling the power train circuit. The Cä command can be 0 (no fan control), 1 (low speed fan control) or 2 (high speed fan control). Figure 3 shows different setpoint temperatures as a function of vehicle speed.

The temperature TO represents the temperature setpoint for the flow control loop of the cooling circuit pumps. The temperature Ti corresponds to the temperature threshold above which the fan passes from zero speed to low speed.

The temperature Ti is greater than TO because it is sought to solicit the fan only if the flow control is insufficient. The temperature T2 corresponds to the temperature threshold above which the fan moves from low speed to high speed. The temperature T3 corresponds to the temperature threshold below which the fan moves from the high speed to the low speed, and the temperature T4 corresponds to the temperature threshold below which the fan passes from the low speed to the zero speed. The curves TO to T4 may constitute programmable maps in the calculator. The fan control strategy is illustrated in FIG. 4, which is a detailed view of the module C. The module C is composed of four blocks C1 to C4. Block C1 monitors the cooling signal Sr to see if any of the members of the power train require cooling. The block C1 then generates a signal, which, if there is a thermal alert on one of the components, drives the fan control at high speed. Block C2 checks whether the temperature T of the coolant is below or above the four temperature thresholds T1 to T4. The block C3 is an automaton that elaborates the command C, which is sent to the fan. Taking the example of the speed transition between the zero speed and the low speed of the fan, the transition from the zero speed to the low speed is controlled by the block C3 if the block Cl does not signal thermal alarm on one of the components and if at least one of the following two conditions is satisfied: the temperature T of the coolant is between T 1 and T 2, the control C c takes the value 1. Conversely, the passage of the small speed at zero speed is controlled by block C3 if the following three conditions are satisfied: - the block C1 does not signal a thermal alarm on any of the 10 components, - the temperature T of the coolant is less than T4 the control Cc takes the value 0. The block C4 is a delay block which makes it possible to further reduce the load on the fan control relays. With block C4, a minimum time interval is maintained between two changes in fan speed level. The block C4 can in particular be implemented if the differences between the different rising and falling setpoint temperatures are too small.

FIG. 5 shows the evolution of the temperature T of the coolant and the temperatures T1 to T4 as a function of time, as well as the evolution of the command C, sent to the fan as a function of time, for a vehicle speed. about 10 km / h. At the beginning, the temperature T is 30 ° C. and the control C is at 25 ° C. The temperature T then increases until the temperature T1 is reached. At this instant, the command C takes the value 1 and causes the passage Fan Po_1 from zero speed to low speed. When the temperature T reaches the value T2, the command C takes the value 2 and the device controls the passage P1-> 2 of the fan from the low speed to the high speed. The temperature T then reaches a maximum, then begins to decrease. When the temperature T reaches the value T3, the command C takes the value 1 and the device controls the passage PZ_1 of the fan from high speed to low speed. The temperature T then continues to fall and reaches the value T4. The command C, then takes the value 0 and the device controls the passage P1_o of the fan of the low speed at zero speed. Since the temperature T3 is lower than the temperature T2, and the temperature T4 is lower than the temperature T1, the switching of the control relays is delayed, which makes it possible to extend their service life. Although the device described above comprises two pumps, the invention may also relate to a device comprising one or more than two pumps. It can also be applied to a gasoline engine equipped with electric water pumps.

Claims (9)

REVENDICATIONS1. Cooling device (1) for a motor vehicle, comprising a cooling circuit capable of cooling an engine assembly (5) with a coolant cooled by a radiator (6) coupled to a fan (13) with several speed levels, the fan (13) being controlled by a control system (9), characterized in that the control system (9) is adapted to control the speed level of the fan (13) as a function of the temperature of the fan. coolant, the control of the passage of a lower speed level to a higher speed level of the fan (13) being a function of a so-called rising target temperature, the control of the passage of said speed level higher than said speed level lower depending on a so-called descending setpoint temperature lower than the rising target temperature. 2. Device (1) according to claim 1, characterized in that the fan (13) is further coupled to an air conditioning system and in that the control system (9) is adapted to control the speed level of the fan (13) according to a cooling need of the air conditioning system. 3. Device (1) according to claim 1 or 2, characterized in that the motor vehicle is an electric vehicle and in that the motor assembly (5) comprises an electronic control system (12). 4. Device (1) according to claim 3, characterized in that the electric vehicle comprises a battery charger assembly (4) and in that the cooling circuit is able to cool the charger assembly (4) and all motor (5). 5. Device (1) according to claim 4, characterized in that the control system (9) is adapted to control the speed level of the fan (13) according to a cooling need of the charger assembly (4). ) or the motor unit (5). 6. Device (1) according to claim 4 or 5, characterized in that it comprises a first pump (2) adapted to supply selectively coolant the motor assembly (5) and a second pump (3) adapted to selectively supplying coolant to the charger assembly (4). 7. Device (1) according to claim 6, characterized in that it comprises a first valve (7) adapted to prevent a passage of coolant in the charger assembly (4) and a second valve (8) adapted to prevent a passage of coolant in the motor assembly (5). 8. Device (1) according to claim 7, characterized in that it comprises a hydraulic restriction (10) for maintaining a minimum flow of coolant in the motor assembly (5). 9. Device (1) according to one of claims 6 to 8, characterized in that the control system (9) is adapted to control the flow rate of each pump (2, 3) in a closed loop control system. depending on the coolant temperature and a set temperature.