EP1348070A1 - Cooling system for a motor vehicle - Google Patents

Abstract

The invention relates to a cooling system for a motor vehicle, comprising at least one coolant pump (30), which is provided for circulating a coolant in the cooling system, and a main cooler (10), which has at least one main cooler inlet (11) and at least one main cooler outlet (12). The main cooler inlet (11) is connected at least temporarily to a coolant outlet (24) of a combustion engine to be cooled (20), while the main cooler outlet (12) is connected to a coolant inlet (23) of said combustion engine (20). According to the invention, at least one first aggregate (60, 80) to be cooled is connected parallel to the combustion engine and/or the main cooler (10).

Description

Cooling system for a motor vehicle

The present invention relates to a cooling system for a motor vehicle with at least one coolant pump which is intended to circulate a coolant in the cooling system, and with a main cooler which has at least one main cooler inlet and at least one main cooler outlet, the main cooler inlet at least temporarily with a Coolant outlet of an internal combustion engine to be cooled is connected, while the main cooler outlet is connected to a coolant inlet of the internal combustion engine.

State of the art

In the case of internal combustion engines, the need for cooling generally arises from the fact that the surfaces in contact with hot gases and their lubrication inside the cylinder can only withstand the occurring temperatures within certain limits without damage. Temperatures of over 2000 ° C occur with the ignitions, but there are cooling phases in the cylinder interior between two ignitions, for example due to purge air, expansion processes or heat removal during Evaporation of the fuels are caused, so that overall there is a much lower average temperature. Parts such as spark plugs, injection nozzles, antechambers, exhaust valves, piston crowns and so on must withstand particularly high average temperatures, which is why such parts are made of materials with high heat resistance and are equipped with good heat dissipation and special cooling measures. Therefore, cooling systems are sets einge- to this heat dissipation, in ^'which, in order to subsequently deliver a coolant which flows through the cooling water spaces surrounding at least the cylinder and cylinder head, the heat via a condenser at least partially to the environment.

Figure 1 shows a schematic representation of a generic cooling system according to the prior art. A cooler 10 has a cooler inlet 11 and a cooler outlet 12. An internal combustion engine 20 to be cooled has a coolant inlet 23 and a coolant outlet 24, the coolant outlet being connected to the cooler inlet 11 via lines 101, 102 and a mixing valve 50. To circulate the coolant, a coolant pump 30 is provided, the pressure side 34 of which is connected via a line 105 to the coolant inlet 23 of the internal combustion engine 20. The suction side 33 of the coolant pump 30 is connected to the cooler outlet 12 of the cooler 10 via lines 103, 104. The coolant outlet 24 can be connected to the suction side 33 of the coolant pump 30 via the mixing valve 50, which can be formed, for example, by a thermostatic valve and a short-circuit line 106. Depending on the position of the mixing valve 50, this becomes from the coolant outlet 24 Leaving coolant is only or partially supplied to the cooler inlet 11, or it is via the short-circuit line. 106 supplied exclusively or partially to the suction side 33 of the coolant pump 30. With the help of the mixing valve 50, the temperature of the coolant flowing through the internal combustion engine 20 can thus be regulated. FIG. 1 also shows an expansion tank 40 which is not of interest here and which is connected via a line 108 to the cooler inlet 11 and via a line 107 to the cooler outlet 12. Furthermore, a cooler fan 45 is provided, which serves to direct an air flow onto the cooler 10 so that the heat can be released into the ambient air in the desired manner via the cooler 10. The radiator fan 45 can be regulated or controlled, for example, as a function of the coolant temperature and / or as a function of the vehicle speed and thus of the airstream.

In modern vehicles, various engine auxiliary units, which are also referred to briefly below as units or additional units, are used, which can include, for example, electrical machines, oil coolers, compressors and the like. In many cases it is necessary to cool such units in a manner similar to the internal combustion engine itself. In connection with oil coolers or oil-water heat exchangers, in particular for automatic transmission oil, it has therefore already been proposed to supply coolant removed from a special cooler section to the oil-water heat exchanger before it is passed on to the internal combustion engine. Beyond that it is customary, for example, to also connect the vehicle heater to the coolant circuit, it being possible for additional coolant pumps to be provided in the area of the heating system.

Advantages of the invention

Because the cooling system according to the invention provides that at least one first unit to be cooled is connected in parallel to the internal combustion engine and / or to the main cooler, this unit can be cooled without additional coolant pumps being required and without either the unit being driven by the Heated coolant is supplied to the internal combustion engine or that heated coolant is supplied to the internal combustion engine by the unit.

According to a particularly preferred embodiment of the cooling system according to the invention, at least one second unit to be cooled is also provided, which is connected to the cooling system via an additional cooler. By using an additional cooler, the second unit to be cooled can be operated at a temperature that is different from the engine temperature level, for example a significantly lower temperature.

In the cooling system according to the invention it can be provided that the first unit is an electrical machine, for example a generator, a starter, an (additional) drive motor or a starter generator. For example, if the second unit is an electrical circuit, in many cases it may be necessary for this circuit to be operated in a significantly lower temperature range than the internal combustion engine. A particularly preferred embodiment of the cooling system according to the invention provides that the first unit is an electrical machine and in particular a starter generator, and that the second unit is a power electronics circuit assigned to the starter generator. Starter generators combine the function of conventional starters and conventional alternators or generators. Starter generators are relatively strong heat sources and therefore have to be cooled in many cases. Since they can often be operated at similar temperatures as the coolant used to cool the internal combustion engine, the parallel connection to the internal combustion engine and / or to the main cooler is particularly advantageous. The power electronics circuit uss, which are usually necessarily assigned to a starter generator, are also cooled in many cases in order to avoid damage to the components forming the circuit. However, the coolant temperatures normally used for the cooling of internal combustion ^engines' performance for such consumer electronics circuit are usually too high. It is therefore particularly advantageous if the power electronics circuit assigned to the starter generator is connected to the cooling system via an additional cooler, so that the power electronics circuit can operate in a temperature range which is significantly below that of the coolant used for cooling the internal combustion engine. One embodiment of the cooling system according to the invention provides that a mixing valve is provided between the main cooler inlet and the coolant outlet, which is connected in a manner known per se via a short-circuit line to the suction side of the coolant pump, and that the first unit is located between the mixing valve and the coolant outlet of the internal combustion engine is connected. In this embodiment, the waste heat from the first unit can be used during the warm-up phase of the internal combustion engine to heat it up more quickly. For this purpose, the mixing valve completely or partially shuts off the coolant supply to the main cooler, so that both the coolant flowing back from the internal combustion engine and the coolant directed through the first unit are supplied via the short-circuit line to the suction side of the coolant pump.

Another embodiment of the cooling system according to the invention also provides that a mixing valve is provided between the main cooler inlet and the coolant outlet, which is connected to the suction side of the coolant pump via a short-circuit line. In this embodiment, however, it is also provided that the first unit is connected between the mixing valve and the main cooler inlet. This embodiment makes it possible that the first ^'unit can be operated at lower temperatures than the internal combustion engine. However, in this embodiment, the waste heat from the first unit can only be used to a limited extent to shorten the warm-up phase of the internal combustion engine. This is due to the fact that the first gat. flowing coolant can only flow back through the main cooler into the cooling branch of the internal combustion engine.

It is preferably provided that the first unit is connected on the pressure side of the coolant pump. This measure ensures that the coolant pump, which is present anyway, generates the required coolant volume flow, so that in many cases an additional coolant pump can be dispensed with.

In embodiments in which at least one second unit to be cooled is provided which is connected to the cooling system via an additional cooler, it is preferably provided that the additional cooler has at least one additional cooler inlet which is connected to the pressure side of the coolant pump. This measure can ensure that the coolant flows through the auxiliary cooler at a sufficient pressure.

If at least one second unit to be cooled is provided, which is connected to the cooling system via the additional cooler, a particularly preferred embodiment of the cooling system according to the invention provides that the additional cooler has at least one. Has additional cooler outlet, which is connected to the second unit via a valve. The coolant volume flow flowing through the second unit can be influenced by this valve. This measure makes it possible, for example, for the second unit to be operated at significantly lower temperatures than the internal combustion engine, specifically within a defined second temperature. range. The provision of such a second defined ^' temperature range can bring advantages, for example, if the first unit is formed by a starter generator and the second ^' unit is formed by a power electronics circuit assigned to the starter generator. In this case, it is possible, for example, to operate the starter generator itself in a temperature range similar to that of the internal combustion engine, while the associated power electronics circuit can be operated in a significantly lower temperature range in order to ensure that the components of the power electronics circuit are not thermally destroyed or be adversely affected.

In particular in this context, that is, if the second unit is a power electronics circuit, a preferred embodiment of the cooling system according to the invention provides that a temperature sensor is assigned to the second unit. If the second unit is formed by a power electronics circuit, it can be provided, for example, that the temperature sensor is integrated into the electronics at the thermally most important point.

If a temperature sensor is provided, it is possible, for example, to actuate a valve upstream of the second unit as a function of the temperature detected by the temperature sensor. Suitable control and / or regulating devices can be provided for this purpose. For example, if the second aggregate is formed by a power electronics circuit or any other circuit possible to integrate the control and / or regulating devices in this circuit. Of course, embodiments are also possible in which corresponding control and / or regulating devices are provided separately from the second unit.

In the cooling system according to the invention it can be provided that the delivery rate of the coolant pump depends on the temperature detected by the temperature sensor. Such a dependency of the delivery capacity of the coolant pump can be provided for the entire temperature range in question or only for certain temperature ranges. If, for example, the temperature sensor detects that the temperature of the second unit is too high, even though a valve assigned to it is completely open, the coolant pump can be controlled by this measure in such a way that its delivery rate is increased.

In the cooling system according to the invention, it can additionally or alternatively be provided that the delivery rate of the coolant pump can be controlled or regulated independently of the speed of the internal combustion engine.

In this context in particular, embodiments are possible in which the coolant pump is an electrical coolant pump.

The main cooler and / or the additional cooler is preferably assigned at least one cooler fan known per se. Depending on the spatial arrangement of the main cooler and possibly the additional cooler, a common one Cooling fan can be provided or a separate cooling fan can be assigned to each of the coolers. In this context, the cooling system according to the invention preferably provides that the temperature detected by the temperature sensor is taken into account in the control or regulation of the cooler fan. Of course, other temperature sensors or other sensors can also be provided, the measurement signals of which are used to control or regulate the cooling fan or other components of the cooling system.

However, the preferred embodiment of the invention provides that the valve is actuated in the manner of a control.

It can further be provided that the second unit is connected to the suction side of the coolant pump. If the coolant outlet of the second unit is connected to the suction side of the coolant pump, the coolant flowing out of the second unit can be supplied to the coolant flowing out of the main cooler. This. This measure is particularly useful when the temperature of the coolant flowing out of the second unit is still sufficiently low to enable the internal combustion engine to be cooled.

In all embodiments of the cooling system according to the invention it can be provided that the first unit to be cooled, which is connected in parallel to the internal combustion engine and / or the main cooler, is an oil cooler, which of course does not rule out the possibility that further re first units, for example a starter generator, are also connected in parallel.

Regardless of what the first unit is specifically formed, it can be provided in the cooling system according to the invention that a valve is assigned to the first unit. This applies in particular to the cases already mentioned in which the first unit is formed by a starter generator and / or an oil cooler.

drawings

The invention is explained in more detail below with reference to the accompanying drawings.

Show it:

Figure 1 shows a cooling system according to the prior art _r

FIG. 2 shows a first embodiment of the cooling system according to the invention, in which two first units in the form of a starter generator and an oil cooler are provided,

FIG. 3 shows a second embodiment of the cooling system according to the invention, in which a first unit in the form of an oil cooler and a second unit in the form of a power electronics circuit are provided, FIG. 4 shows a third embodiment of the cooling system according to the invention, in which two first units in the form of an oil cooler and a starter generator and a second unit in the form of a power electronics circuit are provided, the power electronics circuit being assigned to the starter generator, and

5 shows a fourth embodiment of the cooling system according to the invention, in which a first unit in

Form of a starter generator and a second unit in the form of a power electronics circuit are provided, the power electronics being assigned to the starter generator.

Description of the design examples

A description of the system components follows, which are at least substantially the same for the embodiments according to FIGS. 2 to 5.

In the embodiments of the cooling system of the invention according to Figures 2 to 5, the ^'cooling system comprises a main radiator 10 including a main hollow pure passage 11 and a main outlet Kuhle 12th Adjacent to the main cooler 10 is a cooler fan, designated 45 overall. The radiator fan 45 has a fan 46 and a radiator fan motor 47, which can set the fan 46 in rotation. An expansion tank 40 which is not of interest here is connected via a line section 108 to the main cooler inlet 11 and connected to the main cooler outlet 12 via a line section 107. The cooling system primarily serves to cool an internal combustion engine 20. The internal combustion engine 20 has a cylinder head 21 and an engine block 22. A coolant inlet 23 of the internal combustion engine 20 is indicated schematically, as is a coolant outlet 24. The coolant outlet 24 of the internal combustion engine 20 is connected to the main cooler inlet 11 via a line section 101, a mixing valve 50 and a line section 102. The mixing valve 50 can be formed, for example, by a thermostatic valve known per se. The coolant inlet 23 of the internal combustion engine 20 is connected to the pressure side 34 of a coolant pump 30 via a line section 105. The suction side 33 of the coolant pump 30 is connected to the main cooler outlet 12 via a line section 103 and a line section 104. A short-circuit line 106 is assigned to the mixing valve 50, the coolant outlet 24 of the internal combustion engine via a line section 101, the mixing valve 50, the short-circuit line 106, a line section 104 (except for the embodiment according to FIG. 5), the coolant pump 30 and a line section 105 the coolant inlet 23 can be connected. The operating temperature of the internal combustion engine 20 can thus be set or regulated via the mixing valve 50, for example in the form of a thermostatic valve. For example, during the warm-up phase of the internal combustion engine 20, the coolant supply to the main cooler 10 can be completely or partially shut off by the mixing valve 50, so that the operating temperature of the internal combustion engine 20 can be reached more quickly. as if the coolant was passed through the main cooler 10. The 'cylinder head 21 of the internal combustion engine 20 also has a heating connection 25. Coolant which has been heated by the internal combustion engine 20 can be removed from the heating connection 25. The heating connection 25 is connected to a heating heat exchanger 35 via a line section 109. By means of suitable measures, an air flow is conducted through the heating heat exchanger 35, which air flow is provided, for example, to heat the passenger compartment. In order to be able to set the temperature differently for the driver and front passenger compartments, two outputs are assigned to the heating heat ^exchanger 35, the first of which has a first heating valve 36, while the second of a second heating valve 37. The amount of coolant flowing through different sections of the heating heat exchanger 35 can be influenced via the first heating valve 36 and the second heating valve 37, and the temperature for the left and right side of the vehicle can be influenced. The first heating valve 36 and the second heating valve 37 are connected to the suction side of a heating medium pump 32 via line sections 113 and 112, respectively. The pressure side of the heating medium pump 32 is connected to the suction side 33 of the coolant pump 30 via a line section 114. In the case shown • the heating medium and the cooling medium are formed by one and the same medium. The heating connection 25 of the internal combustion engine 20 is also connected to the heating medium inlet of a washer fluid heat exchanger 39 via a line section 110. The washer fluid heat exchanger 39 is provided to heat liquid in a washer fluid reservoir 38, thereby to prevent icing of the washer fluid system, not shown. The outlet of the washer fluid heat exchanger 39 is also connected to the suction side of the heating medium pump 32 via a line section 111.

According to the embodiment in FIG. 2, a first unit 60 in the form of a starter generator is connected in parallel to the internal combustion engine 20 and the main cooler 10. The coolant inflow of the starter generator 60 is connected via a line section 115 to the pressure side 34 of the coolant pump 30. The coolant outlet of the starter generator 60 is connected via a line section 116 between the mixing valve 50 and the coolant outlet 24 of the internal combustion engine 20. Similarly, a further first unit 80 is connected in parallel to the internal combustion engine 20 and to the main cooler 10, the coolant inlet of the unit 80 being connected to the pressure side 34 of the coolant pump 30 via a line section 117, while the coolant outlet of the unit 80 is connected via a line section 118 is connected between the mixing valve 50 and the coolant outlet 24 of the internal combustion engine 20. A valve 81 is provided in the line section 118, with _. which the coolant supply to the unit 80 can be adjusted. The fact that two units are provided in this embodiment is optional, which is why the line sections 117, 118 are shown with dashed lines. Because the starter generator 60 and the oil cooler 80 are connected on the pressure side 34 of the coolant pump 30, these units 60, 80 can be cooled without the need for an additional coolant pump. The embodiment of the The cooling system according to the invention according to FIG. 2 has the advantage that, for example, the waste heat from the starter generator 60 during the warm-up phase of the internal combustion engine 20 can be used for faster heating of the internal combustion engine 20 by completely or partially shutting off the coolant supply to the main cooler 10 through the mixing valve 50. The valve 81 assigned to the oil cooler 80 makes it possible, for example, for the oil cooler 80 to be operated at higher temperatures than the internal combustion engine 20, specifically by restricting the coolant supply to the oil cooler 80 via the valve 81, if necessary.

There follows a description of the cooling system according to FIG. 3, with reference being made to the corresponding statements regarding the system components common to the embodiments of FIGS. 2 to 5, and only the relevant differences will be discussed below in order to avoid repetitions. In the second embodiment of the cooling system according to the invention according to FIG. 3, a first unit 80 to be cooled in the form of an oil cooler is connected in parallel to the internal combustion engine 20 and to the main cooler 10. A valve 81 is assigned to the oil cooler 80, so that the oil cooler 80 can optionally be operated at a higher temperature than the internal combustion engine 20. The valve 81 is arranged in a line section 118 which is between the mixing valve 50 and the coolant outlet 24 of the internal combustion engine 20 is connected. As in the embodiment according to FIG. 2, the coolant inlet of the oil cooler 80 is connected to the pressure side of the coolant pump 30 via a line section 117. In addition to In the embodiment according to FIG. 3, the first unit 80 connected in parallel is provided with a second unit 10 to be cooled, which is connected to the cooling system via an additional cooler 15. The additional cooler 5 15 is arranged locally in the embodiment shown such that the cooler fan 45 can also act on the additional cooler 15. The additional cooler 15 has an additional cooler inlet 16 which communicates with the pressure side 34 via line sections 119 or 117

10 of the coolant pump 30 is connected. Furthermore, the additional cooler 15 has an additional cooler outlet 17, which is connected to the coolant inlet of the second unit 70 via a line section 120. A valve 72 is located in the line section 120

15. provided through which the amount of coolant supplied to the second unit 70 can be influenced. Furthermore, the second unit 70 is assigned a temperature sensor 71, which detects the temperature of the second unit 70 or the temperature of the temperature-sensitive

20 th components of the unit 70 detected. The operating temperature of the second unit 70 can be set using the temperature sensor 71 and the valve 72 in the manner of a control. Due to the fact that the coolant emerging from the main cooler 10

25 flows next through the additional cooler 15 before it is fed to the second unit 7 ^' 0, the second unit 70 can be operated at a significantly lower temperature than the internal combustion engine 20. The coolant emerging from the second unit 70 has in the

30 Rule a temperature that is still low enough to cool the engine 20. For this reason, the coolant outlet of the second unit 70 is over a line section 123 is connected to the short-circuit line 106 and thus the suction side 33 of the coolant pump 30. In the embodiment according to FIG. 3, the second unit 70 can be formed, for example, by a circuit, in particular a power electronics circuit, which has to be operated at significantly lower temperatures than the internal combustion engine 20.

There follows a description of the cooling system according to FIG. 4, with reference being made to the corresponding explanations above with regard to the system components common to the embodiments of FIGS. 2 to 5, and only the relevant differences are discussed below in order to avoid repetitions. Figure 4 shows a third embodiment of the cooling system according to the invention. In this embodiment, a first unit 80 to be cooled in the form of an oil cooler is connected in parallel to the internal combustion engine 20. For this purpose, the coolant outlet of the oil cooler 80 is connected via a line section 118 between the coolant outlet 24 of the internal combustion engine 20 and the mixing valve 50. The line section 118 is again assigned a valve 81 with which the operating temperature of the oil cooler 80 can be set. The coolant inlet of the oil cooler 80 is connected to the pressure side 34 of the coolant pump 30 via a line section 117. Since the oil cooler 80 is optionally provided, the line sections 117 and 118 are again shown in dashed lines. In addition to the oil cooler 80, a further first unit 60 in the form of a starter generator is provided. The starter generator 60 is also connected in parallel to the internal combustion engine 20. The coolant inlet of the starter rators 60 is connected via a line section 115 to the pressure side 34 of the coolant pump 30. The coolant outlet of the starter generator 60 is connected via a line section 116 between the mixing valve 50 and the coolant outlet 24 of the internal combustion engine 20. In the illustrated case, the starter generator 60 is operated in approximately the same temperature range as the internal combustion engine 20, because in the line section 116 or in the line section 115 there is no valve specifically assigned to the starter generator 60. In particular if the starter generator 60 is to be operated at higher temperatures than the internal combustion engine, at least one such valve can be provided in the line section 116 and / or in the line section 115. The starter generator 60 has a power electronics circuit 70 which must be operated at significantly lower temperatures than the starter generator 60 itself. An additional cooler 15 is therefore provided in the embodiment according to FIG. 4, which is arranged spatially adjacent to the main cooler 10, so that the cooler fan 45 can also act on the additional cooler 15. The additional cooler 15 has an additional cooler inlet 16 which is connected to the pressure side 34 of the coolant pump 30 via a line section 119 and a line section 115. Furthermore, the additional cooler 15 has an additional cooler outlet 17, which is connected via a line section 120 to the coolant inlet of the power electronics circuit 70, which in this embodiment forms a second unit to be cooled, which is connected to the cooling system via the additional cooler 15. A valve 72 is provided in the line section 120 in order to set the amount of coolant used to cool the power electronics circuit 70 and use it to determine the operating temperature of the power electronics circuit 70. The power electronics circuit 70 is also assigned a temperature sensor 71, which is preferably arranged in the most heat-sensitive area of the power electronics circuit 70. The power electronics circuit 70 may include circuit components that _. are provided to evaluate the temperature detected by the temperature sensor 71 or a corresponding signal. A particularly effective arrangement is obtained if the valve 72 is actuated via appropriate circuit components in the manner of a regulation as a function of the temperature detected by the .vo temperature sensor 71. The coolant outlet of the power electronics circuit 70 is connected to the short-circuit line 106 via a line section 123 and thus to the suction side 33 of the coolant pump 30 via a further line section 104. Enables the embodiment according to FIG 4 ^• it that the starter generator 60 is operated even with a higher Temperaturniveäu than its associated power electronics circuit 70. A further coolant pump is not required for this purpose.

There follows a description of the cooling system according to FIG. 5, with regard to the system components common to the embodiments of FIGS. 2 to 5, reference being made to the corresponding explanations above and only the relevant differences being discussed below in order to avoid repetitions. Figure 5 shows a fourth embodiment of the cooling system according to the invention. at In this embodiment, a starter generator 60 forms a first unit to be cooled. In the embodiment shown in FIG. 5, the coolant outlet of the starter generator 60 is connected via a line section 122 between the main cooler inlet 11 and the mixing valve 50. The coolant inlet of the starter generator 60 is connected to the pressure side 34 of the coolant pump 30 via a line section 115. With this connection variant of the first unit or the starter generator 60, the ^' starter generator 60 can be operated at lower temperatures than the internal combustion engine 20'. For this purpose, the coolant flow can be throttled 30 by the engine 20 even at a high flow rate of the coolant pump, beispiels-, by the valve 50 to the operating temperature of the engine 20 to increase ^'. However, the waste heat from the starter generator 6 can only be used to a limited extent in this connection variant to shorten the warm-up phase of the internal combustion engine 20 ^′ , because the coolant emerging from the starter generator 60 can only flow back to the cooling branch of the internal combustion engine 20 via the main cooler 10. The starter generator 60 is again assigned a power electronics circuit 70 which forms a second unit which is connected to the cooling system via an additional cooler 15. The additional cooler 15 is again spatially adjacent to the main condenser 10, so that a single ^'radiator fan 45 can act on both the main cooler 10 and the additional cooler 15 °. The additional cooler 15 has an additional cooler inlet 16, which is connected to the pressure side 34 of the coolant pump 30 via line sections 119, 115. Furthermore, the additional cooler 15 has an additional cooler outlet 17 on the 120 via a line section. communicates with a coolant inlet of the power electronics circuit 70. A valve 72 is provided in the line section 120, via which the operating temperature of the power electronics circuit 70 can be set. Suitable control and / or regulating devices can be provided for this purpose. The coolant outlet of the power electronics circuit 70 is connected to the suction side 33 of the coolant pump 30 via a line section 121 and a line section 104. As a result, the coolant heated by the power electronics circuit 70 is supplied to the cooling branch for the internal combustion engine 20.

The preceding description of the exemplary embodiments according to the present invention is only for illustrative purposes and not for the purpose of restricting the invention. Various changes and modifications are possible within the scope of the invention without leaving the scope of the invention and its equivalents.

Claims

Expectations

1. Cooling system for a motor vehicle, with at least one coolant pump (30) which is intended to circulate a coolant in the cooling system, and with a main cooler (10) having at least one main cooler inlet (11) and at least one main cooler outlet (12) , wherein the main cooler inlet (11) is at least temporarily connected to a coolant outlet (24) of an internal combustion engine (20) to be cooled, while the main cooler outlet (12) is connected to a coolant inlet (23) of the internal combustion engine (20), characterized in that that at least one first unit (60, 80) to be cooled is connected in parallel to the internal combustion engine and / or to the main cooler (10).

2. Cooling system according to claim 1, characterized in that at least one second unit (70) to be cooled is provided, which is connected to the cooling system via an additional cooler (15).

3. Cooling system according to one of the preceding claims, characterized in that the first unit (60) is an electrical machine.

4. Cooling system according to one of the preceding claims, characterized in that the second unit (70) circuit (70).

5.- Cooling system according to one of the preceding claims, characterized in that the first unit (60) is a starter generator, and that the second unit (70) is a power electronics circuit assigned to the starter generator.

6. Cooling system according to one of the preceding claims, characterized in that between the main cooler inlet (11) and the coolant outlet (24), a mixing valve

(50) is provided, which is connected via a short-circuit line (106) to the suction side (33) of the coolant pump (30)

Connection is established, and that the first unit (60, 80) between the mixing valve (50) and the coolant outlet

(24) is connected.

7. Cooling system according to one of the preceding claims, characterized in that a mixing valve (50) is provided between the main cooler inlet (11) and the coolant outlet (24), which is connected to the suction side (33) of the coolant pump (30) via a short-circuit line (106) ) is connected, and that the first unit (60, 80) is connected between the mixing valve (50) and the main cooler inlet (11).

8. Cooling system according to one of the preceding claims, characterized in that the first unit on the pressure side (34) of the coolant pump (30) is connected.

9. Cooling system according to one of the preceding claims, characterized in that the additional cooler (15) has at least one additional cooler inlet (16) which is connected to the pressure side (34) of the coolant pump (30).

10. Cooling system according to one of the preceding claims, characterized in that the additional cooler (15) has at least one additional cooler outlet (17) which is connected to the second unit (70).

11. Cooling system according to one of the preceding claims, characterized in that the additional cooler outlet (17) is connected to the second unit (70) via a valve (72).

12. Cooling system according to one of the preceding claims, characterized in that the second unit (70) is assigned a temperature sensor (71).

13. Cooling system according to one of the preceding claims, characterized in that the valve (72) is actuated as a function of the temperature detected by the temperature sensor (71).

14. Cooling system according to one of the preceding claims, characterized in that the delivery capacity of the coolant pump (30) depends on the temperature detected by the temperature sensor (71).

15. Cooling system according to one of the preceding claims, characterized in that the delivery rate of the coolant pump (30) can be controlled or regulated independently of the speed of the internal combustion engine.

16. Cooling system according to one of the preceding claims, characterized in that the coolant pump (30) is an electrical coolant pump.

17. Cooling system according to one of the preceding claims, characterized in that the main cooler (10) and / or the additional cooler (15) is assigned at least one cooler fan (45), and that the temperature detected by the temperature sensor (71) in the control or Control of the radiator fan (45) is taken into account.

18. Cooling system according to one of the ^' preceding claims, characterized in that the valve (72) is actuated in the manner of a regulation.

19. Cooling system according to one of the preceding claims, characterized in that the second unit (70) is connected to the suction side (33) of the coolant pump (30).

20. Cooling system according to one of the preceding claims, characterized in that the first unit (80) to be cooled which is connected in parallel with the internal combustion engine and / or the main cooler (10) is an oil cooler.

21. Cooling system according to one of the preceding claims, characterized in that the first unit (60, 80) is assigned a valve (81).