DE102022120411A1 - Cooling system for cooling power electronics and/or for coolant temperature control - Google Patents

Abstract

The invention relates to a cooling system (100), preferably for a motor vehicle, preferably an autonomous or semi-autonomous motor vehicle, in particular a truck or bus, with power electronics (21), preferably at least one control device and/or at least one computer, preferably for data processing for autonomous or semi-autonomous driving of the motor vehicle, and a circuit (20) for cooling the power electronics (21). The cooling system (100) is characterized in particular in that the circuit (20) comprises a valve (22) for coolant temperature control to avoid condensation formation on or in the power electronics (21). The invention also includes an associated method.

Description

The invention relates to a cooling system, preferably for a motor vehicle, in particular an autonomous or semi-autonomous motor vehicle (e.g. truck or bus). The cooling system is used in particular to cool power electronics, but also, for example. B. for coolant temperature control to avoid condensation formation on or in the power electronics. The invention also relates to an associated method.

It is known from practice that power electronics such as B. to ventilate and thus cool motor vehicle control devices. Power electronics in the form of e.g. B. high-performance computers for data processing for autonomous or semi-autonomous driving usually require more efficient cooling than conventional motor vehicle control units. However, excessive cooling of the power electronics and/or cold weather (e.g. in combination with low utilization of the power electronics and/or in a warm and/or humid environment of the power electronics) can lead to disadvantageous condensation forming on or in the power electronics .

One object of the invention is to provide an efficient and/or structurally simple, but at the same time particularly safe, option for cooling power electronics, in particular power electronics for data processing for autonomous or semi-autonomous driving.

This task can be solved with the features of the independent claims. Advantageous developments are disclosed in the subclaims or result from the following description of preferred exemplary embodiments of the invention.

The invention relates to a cooling system, preferably for a motor vehicle, in particular an autonomous or semi-autonomous motor vehicle, e.g. an autonomous or semi-autonomous truck or bus.

The cooling system includes power electronics, preferably at least one control device and/or at least one computer (e.g. at least one chip, processor and/or one or more other electronic components, etc.), preferably for data processing for autonomous or semi-autonomous driving of the motor vehicle. The computer can in particular be a high-performance computer.

The cooling system includes a circuit for cooling the power electronics. The circuit is preferably a cooling circuit, but can also e.g. B. be a refrigeration cycle.

The circuit serves in particular to carry a (e.g. gaseous or liquid) coolant.

The cooling system is characterized in particular in that the circuit includes a valve for coolant temperature control to avoid condensation formation on or in the power electronics, in order to advantageously maintain a temperature on or in the power electronics substantially above a dew point temperature.

The cooling system can expediently comprise at least one further circuit (e.g. cooling circuit and/or refrigeration circuit) in addition to the circuit. The further circuit serves in particular to carry a (e.g. gaseous or liquid) cooling medium or refrigerant.

The further cycle can z. B. a circuit of an air conditioning system, in particular for cooling an interior of the motor vehicle (e.g. a driver and / or passenger interior). The further cycle can therefore z. B. be an air conditioning circuit. The air conditioning circuit is preferably a refrigeration circuit.

The further circuit can alternatively be a battery cooling circuit, in particular for cooling a (e.g. rechargeable) battery device (e.g. battery device, etc.). The battery device can e.g. B. serve to supply energy to an electric motor for driving the motor vehicle. The battery cooling circuit is preferably a coolant circuit. The battery cooling circuit is preferably an accumulator cooling circuit.

In other words, the further cycle can e.g. B. be an air conditioning cooling circuit or a battery cooling circuit (e.g. accumulator cooling circuit).

However, it is also possible for the circuit and/or the further circuit to be an independent (e.g. active) circuit (e.g. refrigerant circuit), preferably independent and/or decoupled from one or more other circuits.

One advantage is e.g. B. that by means of an air conditioning refrigeration circuit and / or a battery cooling arrangement, at least one (expediently active and / or passive) circuit, which is often already present in motor vehicles, can be used to generate and / or provide refrigeration and / or cooling power to the power electronics to cool and/or temper. Alternatively or additionally, an advantage is that the cooling system e.g. B. can be set up not only for cooling the power electronics, but preferably also for coolant temperature control to prevent condensation from forming on or in the To avoid power electronics, so that advantageously a temperature on or in the power electronics can be kept essentially above a dew point temperature.

It is possible for the further circuit and the circuit to be connected to one another (e.g. coupled) via a (e.g. first) heat exchanger, preferably a plate heat exchanger, in particular thermally, preferably in such a way that the further circuit is used to generate and/or or provision of refrigeration and/or cooling power (appropriately refrigeration and/or cooling) can be used for the circuit.

The further cycle can z. B. be thermally connected to an additional circuit via a (e.g. further, in particular second) heat exchanger, preferably a chiller (e.g. evaporator), preferably so that the additional circuit is used to generate and / or provide cooling capacity for the Circuit and/or the further circuit can be used.

It is possible that the further circuit and/or the additional circuit comprises at least one of the following: an expansion element (e.g. an expansion valve), a compressor (e.g. compressor), a condenser, an evaporator and/or a Cooling device (e.g. a cooler with a fan).

In one embodiment, the circuit can z. B. include no expansion element, no compressor, no condenser and/or no evaporator.

It is also possible that the further cycle z. B. includes no expansion element, no compressor, no condenser and/or no evaporator.

The further cycle can z. B. be integrated between the circuit and the additional circuit.

The valve can e.g. B. be a directional control valve and / or be set up to bring together coolant at different temperatures as part of the circuit. Alternatively or additionally, the valve can have at least three connections and/or have at least two switching positions and/or be designed as a 3-way valve, in particular a 3/2-way valve.

The cycle can e.g. B. include a cooling device (in particular cooler with fan), e.g. B. in combination with the further circuit or instead of the further circuit.

In the context of the invention, z. B. the cooling device replaces the further circuit or the further circuit replaces the cooling device, but also z. B. a combination of the cooling device and the further circuit is possible.

The cooling device serves in particular to cool the coolant of the circuit.

The cooling device can e.g. B. a liquid-air heat exchanger, preferably with a fan, the performance of which can be advantageously increased by the fan.

It is possible for the circuit to comprise a first line section, which can preferably extend upstream of the power electronics between the heat exchanger and/or the cooling device and the power electronics. Alternatively or additionally, the circuit can e.g. B. include a second line section, which is z. B. can extend downstream of the power electronics between the power electronics and the cooling device and / or the heat exchanger.

The first line section can therefore z. B. be coupled to an input side of the power electronics and to an output side of the heat exchanger and / or the cooling device, alternatively or additionally the second line section z. B. can be coupled to an output side of the power electronics and to an input side of the heat exchanger and / or the cooling device.

It is possible for a third line section to connect the second line section to the valve and/or to form a bypass line in order to supply coolant (appropriately of the circuit) to the valve and/or into the first line section and preferably thus, bypassing the cooling device and/or the heat exchanger (especially indirectly) back to power electronics.

The third line section is expediently part of the circuit.

The valve can e.g. B. be integrated into the first and / or third line section.

It is possible for the third line section to branch off from the second line section at a branch point.

The branch point is preferably downstream of the power electronics and z. B. positioned upstream of the cooling device and/or the heat exchanger.

The circuit and/or the further circuit can e.g. B. include a pump.

The pump can e.g. B. be set up to, e.g. B. for coolant temperature control to avoid condensation formation on or in the power electronics, to change a coolant heat flow or coolant volume flow, preferably to optionally increase and / or reduce. The change can e.g. B. can be realized by changing the performance of the pump.

The pump is preferably integrated into the first line section and/or upstream of the power electronics and z. B. positioned downstream of the valve and/or downstream of the heat exchanger and/or the cooling device.

The valve preferably comprises a first inlet (which is preferably connected to an outlet of the heat exchanger and/or the cooling device by means of a first section of the first line section) and/or a second inlet (which is preferably connected to the second line section by means of the third line section) . Alternatively or additionally, the valve can expediently comprise an output in order to expediently direct coolant for coolant temperature control from the first inlet and/or from the second inlet to the power electronics and/or into a second section of the first line section, depending on the valve switching positions.

The first inlet can be used in particular to receive coolant cooled by means of the further circuit, the heat exchanger and/or the cooling device.

The second input can be used in particular to receive coolant warmed up by the power electronics.

The first input and/or the second input and/or the output may have at least one of the following: an open position in which it is fully open, a closed position in which it is fully closed, and/or at least one intermediate position in which it is partially open.

It is possible for the valve for coolant temperature control to have a switching position in which the first input is completely closed and the second input is completely or partially open, preferably such that coolant (in particular warmed up by the power electronics) flows between the output, the power electronics and can circulate to the second inlet, but an inflow of coolant via the first inlet and preferably thus from the cooling device and / or from the heat exchanger is prevented. This can z. B. a ("small") circuit mode can be made possible, which includes the power electronics, the valve (namely the preferably completely or partially opened second input) and preferably the pump, in particular with the first input closed and thus excluding the cooling device and / or the heat exchanger.

The valve can be used for coolant temperature control, e.g. B. have a switching position in which the first input is partially open and the second input is completely or partially open, preferably in such a way that coolant (in particular warmed up by the power electronics) can circulate between the output, the power electronics and the second input, but An inflow of coolant (in particular cooled by means of the further circuit and/or the cooling device) is also permitted via the first inlet and preferably thus from the cooling device and/or the heat exchanger. This can z. B. a circulation mode can be made possible, which includes the power electronics, the valve (namely preferably the first at least partially opened input and the second at least partially opened input) and the cooling device and / or the heat exchanger and z. B. includes the pump.

It is possible for the valve for coolant temperature control to have a switching position in which the first input is completely open, preferably such that coolant (in particular cooled by means of the further circuit and/or the cooling device) flows between the output, the power electronics and the first input circulates. The second input can z. B. be completely closed or only partially and / or intermittently opened. This allows a (“large”) circuit mode to be enabled, which includes the power electronics, the valve (namely preferably the fully opened first inlet) and the cooling device and/or the heat exchanger and e.g. B. includes the pump, preferably with the second input essentially closed.

The cooling device can e.g. B. be integrated into the second line section, positioned downstream of the power electronics and/or downstream of the branch point, and/or positioned upstream of the heat exchanger and/or the second input.

The coolant of the circuit can in particular absorb heat from the power electronics and use the heat for coolant temperature control to avoid condensation formation on or in the power electronics, preferably in combination tion with coolant cooled by means of the further circuit, the heat exchanger and/or the cooling device.

In the context of the invention, the circuit can therefore preferably provide at least three different circuit modes, namely preferably a first circuit mode to expediently increase the coolant temperature for the power electronics, a second circuit mode to expediently reduce the coolant temperature for the power electronics , and a third circuit mode that combines the first and second circuit modes.

The valve can e.g. B. be a mechanical valve.

It is possible that the valve is a thermostatic valve and/or a self-adjusting valve for coolant temperature control and thus preferably forms a non-electronically controlled and/or regulated valve. The valve can e.g. B. include an expansion material or expansion fluid that reacts to temperature fluctuations, preferably to influence a coolant flow, e.g. B. to block completely, to let through completely and/or to let through only partially. The valve can e.g. B. include a wax insert and slider.

The valve can e.g. B. be set up for temperature fixed value control, preferably to keep the coolant temperature for the power electronics in a predetermined temperature range. The predetermined (e.g. preset) temperature is preferably chosen so that falling below the dew point can be ruled out in all operating states.

It is possible that the valve is an electrical valve, in particular an electronically controlled and/or regulated valve.

The cooling system can e.g. B. include an electronic control and / or regulating device which is set up to control the valve and / or the pump, preferably for cooling the power electronics and / or for coolant temperature control to avoid condensation formation on or in the power electronics and / or to regulate.

The control and/or regulating device can in particular be set up to control and/or regulate the valve and/or the pump as a function of at least one of the following: a temperature and/or a humidity of the ambient air of the power electronics, a temperature or in the power electronics (e.g. a surface temperature of the power electronics), a coolant temperature of the circuit (e.g. upstream and/or downstream of the power electronics), a coolant temperature of the further circuit and/or a coolant temperature of the additional circuit. To record the temperature, the cooling system can e.g. B. include suitable sensors.

It is possible that the coolant temperature of the circuit, preferably on or (preferably shortly) before entering the power electronics, serves as a controlled variable for controlling the valve and/or the pump.

The control and/or regulating device can, for. B. be set up to carry out an adjustment with at least one dew point curve and / or to keep the coolant temperature in a predetermined temperature range.

It is possible that the control and/or regulating device forms part of the power electronics and is therefore preferably coolable by the circuit, or is made available in addition to the power electronics and, for. B. is decoupled from the circuit (appropriately thermally).

Depending on the exemplary embodiment, the first circuit, the further circuit and / or the additional circuit can be z. B. include a cooling device (in particular a cooler with a fan), an evaporator, a compressor and / or a condenser or can expediently be designed without a cooling device (in particular without a cooler with a fan), without an evaporator, without a compressor and / or without a condenser.

The further cycle can z. B. can be used to generate and/or provide cold and/or cooling power for the circuit, so that preferably cold and/or cool from the further circuit can be used by means of the circuit to cool the power electronics.

The battery cooling circuit can (in particular in addition to the battery device) e.g. B. include at least one electronic component (preferably control electronics, at least one chip, processor, at least one power converter (e.g. inverter) and / or one or more other electronic components, etc.).

The battery cooling circuit can in particular be set up to cool the at least one electronic component.

The at least one electronic component preferably comprises control electronics (e.g. at least one chip, processor, computer, etc.), preferably to control the battery device. Alternatively or additionally, the at least one electronic component can z. B. include a power converter (e.g. inverter), in particular for a motor vehicle air conditioning system.

It is possible that the further circuit is a low-temperature circuit, is a closed circuit and/or has a (in particular liquid or gaseous) cooling medium.

The further circuit and/or the additional circuit can expediently be designed as an active cooling circuit or passive cooling circuit.

It is possible that the circuit is a closed circuit, is a high-temperature circuit and/or has a coolant (in particular liquid or gaseous).

It should be mentioned that the power electronics can in particular include a high-performance computer, useful for data processing for autonomous or semi-autonomous driving of the motor vehicle.

It should also be mentioned that the coolant temperature control serves in particular to maintain a temperature on or in the power electronics essentially above a dew point temperature, in particular to avoid condensation formation on or in the power electronics.

It should also be mentioned that the coolant temperature control can preferably be achieved without reducing a coolant volume flow.

The cooling device of the circuit and/or the additional circuit in particular provides passive cooling.

It should also be mentioned that the battery cooling circuit is preferably a circuit for cooling a z. B. rechargeable battery device (e.g. battery device etc.).

It should also be mentioned that the cycle z. B. can be part of an air conditioning system, in particular for cooling an interior of a motor vehicle (e.g. a driver and / or passenger interior).

The cycle can also e.g. B. be part of a battery cooling arrangement, in particular with a battery device for supplying energy to an electric motor for driving a motor vehicle.

The invention also includes a motor vehicle, preferably an autonomous or semi-autonomous motor vehicle, with a cooling system as disclosed herein.

The motor vehicle is preferably a truck or bus that drives (in particular autonomously or semi-autonomously).

The invention also includes a method for a cooling system, preferably a cooling system as disclosed herein. The method may in particular be carried out with a cooling system as disclosed herein.

The cooling system includes power electronics, preferably at least one control device and/or at least one computer, preferably for data processing for autonomous or semi-autonomous driving of the motor vehicle, and a circuit for cooling the power electronics. The circuit includes a valve that regulates the temperature of the coolant to prevent condensation from forming on or in the power electronics.

The disclosure regarding the cooling system also applies to the method.

• 1 zeigt ein Kühlsystem gemäß Ausführungsbeispielen der Erfindung, und
• 2 zeigt eine Detailansicht des Kühlsystems, insbesondere eines Ventil zur Kühlmitteltemperierung.

The preferred exemplary embodiments and features of the invention described above can be expediently combined with one another. Other advantageous developments of the invention are disclosed in the subclaims or result from the following description of preferred exemplary embodiments of the invention in conjunction with the attached figures.

• 1 shows a cooling system according to embodiments of the invention, and
• 2 shows a detailed view of the cooling system, in particular a valve for coolant temperature control.

1 shows a cooling system 100 according to an embodiment of the invention, wherein 2 shows a detailed view of the cooling system 100, in particular a valve 22 for coolant temperature control.

The cooling system 100 is preferably part of a motor vehicle, e.g. B. an autonomous or semi-autonomous bus or truck.

The cooling system 100 includes power electronics 21, preferably at least one control device and/or at least one computer (e.g. at least one chip, processor, etc.), preferably for data processing for autonomous or semi-autonomous driving of the motor vehicle.

The cooling system 100 includes a circuit 20 for cooling the power electronics 21. The circuit 20 expediently serves to carry a (e.g. liquid or gaseous) coolant.

The cooling system 100 is characterized in particular by the fact that the circuit 20 includes a valve 22 for coolant temperature control to avoid condensation formation on or in the power electronics 21.

The cooling system 100 can also have at least one in 1 only include a further circuit 10 shown schematically, e.g. B. a refrigeration or cooling circuit, expediently with or without a cooling device (e.g. cooler with fan), compressor (e.g. compressor), condenser, evaporator and / or expansion element.

The further circuit 10 can z. B. be an expediently independent (in particular passive) cooling circuit (e.g. without a condenser and / or without a compressor (e.g. compressor), but in particular with a cooling device, in particular a cooler with a fan).

The further circuit 10 can also be an appropriately independent (in particular active) refrigeration circuit (e.g. with an expansion element, compressor (e.g. compressor), compressor and/or condenser).

The further circuit 10 can also z. B. be a circuit, in particular a refrigeration circuit of an air conditioning system for cooling an interior of the motor vehicle. The further circuit 10 thus forms z. B. an air conditioning refrigeration circuit. Alternatively or additionally, the further circuit 10 can be a battery cooling circuit, in particular for cooling a battery device (e.g. battery device) and/or its control electronics (e.g. at least one chip, processor and/or one or more other electronic components, etc.) . The battery device can e.g. B. serve to supply energy to an electric motor for driving the motor vehicle.

The further circuit 10 is optional and can z. B. be replaced by a cooling device 24 in the circuit 20 or vice versa. However, exemplary embodiments with the cooling device 20 and with the further circuit 10 are also possible.

The further circuit 10 can be e.g. B. be a conventional air conditioning refrigeration circuit or a conventional battery cooling arrangement, by means of which all components required to generate refrigeration and / or cooling power (in particular cooling device, compressor and / or condenser) of an active refrigeration circuit or passive cooling circuit can already be present and It is therefore advantageous not to have to be installed again or even to be operated electrically.

The further circuit 10 and the circuit 20 are expediently thermally connected to one another via a heat exchanger Cooling) can be used for circuit 20.

The circuit 20 can z. B. include an expansion tank 50 (e.g. expansion tank) for the coolant of the circuit 20. The further circuit 10 can also optionally include an expansion tank (e.g. expansion tank).

The valve 22 is preferably a 3-way valve. It can e.g. B. have at least three connections 22.1, 22.2, 22.3 and / or have at least two switching positions and z. B. be designed as a 3/2-way valve. In particular, the valve 22 can be set up to bring together coolant at different temperatures.

The circuit 20 can also have an optional cooling device 24 (e.g. cooler with fan), expediently in addition to the further circuit 10 or instead of the further circuit 10. It follows from this that the cooling device 24 is optional and the further circuit 10 is optional .

The circuit 20 comprises a first line section A and a second line section B.

The first line section A expediently extends upstream of the power electronics 21 between the heat exchanger X1 and/or cooling device 24 and the power electronics 21.

The second line section B expediently extends downstream of the power electronics 21 between the power electronics 21 and the heat exchanger X1 and/or the cooling device 24.

The power electronics 21 and the heat exchanger X1 and / or the cooling device 24 can therefore z. B. be positioned between the first line section A and the second line section B, so that the first line section A corresponds to a line section upstream of the power electronics 21 and downstream of the heat exchanger X1 and / or the cooling device 24 and / or the second line section B corresponds to a line section downstream of the power electronics 21 and upstream of the heat exchanger X1 and / or the cooling device 24 corresponds.

A third line section C of the circuit 20 is set up to form a bypass line and z. B. to connect the second line section B with the valve 22 in order to lead coolant to the valve 22 and/or into the first line section A, bypassing the cooling device 24 and/or the heat exchanger X1, and preferably back to the power electronics 21. The valve 22 is expediently integrated into the first line section A and the third line section C.

The third line section C branches off from the second line section B at a branch point 25. The branch point 25 is downstream of the power electronics 21 and z. B. positioned upstream of the cooling device 24 and / or the heat exchanger X1.

The cooling device 24 is preferably integrated into the second line section B and / or downstream of the branch point 25 and z. B. positioned upstream of the heat exchanger X1.

The circuit 20 also includes a pump 23, which can expediently be integrated into the first line section A. The pump 23 can z. B. be integrated into the circuit 20 upstream of the power electronics 21 and downstream of the valve 22 and/or downstream of the heat exchanger X1 and/or the cooling device 24.

The coolant of the circuit 20 can in particular absorb heat from the power electronics 21 and use the heat for coolant temperature control to avoid condensation formation on or in the power electronics 21, preferably in combination with coolant cooled by means of the heat exchanger X1 and/or the cooling device 24.

The valve 22 includes a first input 22.1, which is connected to an output of the heat exchanger X1 and/or the cooling device 24 by means of a first section A1 of the first line section A.

The valve 22 includes a second inlet 22.2, which is connected to the second line section B by means of the third line section C.

The valve 22 includes an output 22.3, depending on valve switching positions for coolant temperature control (expediently warmed up by means of the power electronics 21 and/or cooled by means of the further circuit 10 and/or the cooling device 24) via a second section A2 of the first line section A forward to the power electronics 21.

The first input 22.1 and/or the second input 22.2 and optionally the output 22.3 can z. B. have an open position in which it is completely open, have a closed position in which it is completely closed, and / or have at least an intermediate position in which it is partially opened.

The valve 22 can have different switching positions in order to selectively allow through and/or block coolant heated by the power electronics 21 and coolant cooled by the further circuit 10 and/or the cooling device 24 for coolant temperature control.

The valve 22 can z. B. have a switching position in which the first input 22.1 is completely closed and the second input 22.2 is completely or partially open, preferably so that coolant (in particular warmed up by the power electronics 21) between the output 22.3, the power electronics 21 and the second Input 22.2 can circulate, but an inflow of coolant via the first input 22.1 and preferably thus from the cooling device 24 and / or from the heat exchanger X1 can be prevented. This allows a (“small”) circuit mode to be made possible, which includes the power electronics 21, the valve 22 (namely the preferably completely or partially opened second input 22.2) and preferably the pump 23, in particular with the first input 22.1 closed and thus bypassing or .Exclusion of the cooling device 24 and/or the heat exchanger X1.

The valve 22 can z. B. have a switching position in which the first input 22.1 is partially open and the second input 22.2 is completely or partially open, preferably so that coolant (in particular warmed up by the power electronics 21) between the output 22.3, the power electronics 21 and the second Input 22.2 can circulate, but also an inflow of coolant (in particular cooled by means of the further circuit 10 and / or the cooling device 24) via the first input 22.1 and preferably thus from the cooling device 24 and / or the heat exchanger X1 is permitted. This can z. B. a circulation mode can be made possible, which includes the power electronics 21, the valve 22 (namely preferably the first at least partially open input 22.1 and the second at least partially open input 22.2) and the cooling device 24 and / or the heat exchanger X1 and z. B. the pump 23 includes.

The valve 22 can z. B. have a switching position in which the first input 22.1 is completely open, preferably in such a way that (in particular by means of the further circuit 10 and / or the cooling device 24 cooled) coolant circulates between the output 22.3, the power electronics 21 and the first input 22.1, and in which the second input 22.2 is completely closed or is only partially and / or intermittently opened. This allows a (“large”) circuit mode to be made possible, which includes the power electronics 21, the valve 22 (namely preferably the fully opened first input 22.1) and the cooling device 24 and/or the heat exchanger (expediently cold and/or cool)X1 and e.g. B. includes the pump 23, preferably with the second input 22.2 essentially closed.

The valve 22 can z. B. be a thermostat valve and / or a self-adjusting valve for coolant temperature control. The valve 22 can z. B. be a non-electronically controlled and / or regulated valve.

The valve 22 can in particular comprise an expansion material or expansion fluid that reacts to temperature fluctuations, preferably in order to influence a coolant flow.

The valve 22 can z. B. be set up for fixed temperature control in order to keep the coolant temperature for the power electronics 21 in a predetermined temperature range.

The pump 23 can z. B. be set up to, expediently for coolant temperature control to avoid condensation formation on or in the power electronics 21, change a coolant heat flow or coolant volume flow, preferably optionally increase and / or reduce.

In the context of the invention, it is in particular possible to generate refrigeration and/or cooling power for the circuit 20, in particular by including the cooling device 24, the at least one further circuit 10 and/or the additional circuit 30 discussed below, in particular a motor vehicle air conditioning system and/or or their refrigeration circuit components and/or a battery cooling arrangement and/or their refrigeration circuit components.

In the context of the invention, it is particularly possible for the circuit 20, the valve 22 and/or the pump 23 to be set up for coolant temperature control in order to avoid condensation formation on or in the power electronics 21, in particular because this results in a temperature on or in the power electronics 21 can expediently be kept essentially above a dew point temperature.

The valve 22 can in particular also be an electrical valve, in particular an electronically controlled and/or regulated valve.

The cooling system 100 may include an electronic control and/or regulating device (not shown in the figures).

The control and/or regulating device is expediently set up to control and/or regulate the valve 22 and/or the pump 23 depending on at least one of the following: a temperature and/or a humidity of the ambient air of the power electronics 21, one Temperature on or in the power electronics 21, a coolant temperature of the circuit 20 (e.g. upstream and/or downstream of the power electronics 21), a coolant temperature of the further circuit 10 and/or a coolant temperature of the additional circuit 30 ( see below). To record the respective temperature, e.g. B. suitable sensors can be used.

The control and/or regulating device can, for. B. be set up to carry out an adjustment with at least one dew point curve and / or to keep the coolant temperature for the power electronics 21 in a predetermined temperature range.

The control and/or regulating device can, for. B. form part of the power electronics 21 and can therefore preferably be cooled by the circuit 20. The control and/or regulating device can also be provided in addition to the power electronics 21 and can be decoupled from the circuit 20.

The cooling system 100 can also have an in 1 only schematically shown, optional additional circuit 30 (appropriately refrigeration circuit).

The further circuit 10 can expediently be thermally connected to the additional circuit 30 via a particularly further heat exchanger X2, preferably a chiller (e.g. evaporator), in particular such that the additional circuit 30 is used to generate and/or provide cooling power for the further circuit 10 and/or the circuit 20 can be used.

The additional circuit 30 can z. B. have a compressor and / or a capacitor. The additional circuit 30 can also expediently have an expansion element (e.g. expansion valve) upstream of the further heat exchanger X2.

The further circuit 10 is expediently integrated between the circuit 20 and the additional circuit 30.

In this exemplary embodiment, the further circuit 10 can preferably be a battery cooling circuit with a cooling device (e.g. cooler with fan), but preferably without an evaporator, without a condenser, without a compressor and/or without an expansion element. The additional circuit 20 can preferably be a refrigeration circuit with in particular a condenser, a compressor and an expansion element, in particular for generating cooling capacity for the further circuit 10, whereby the cooling capacity can also be expediently used indirectly for the circuit 20 by means of the heat exchanger X1.

The invention is not limited to the preferred embodiments described above. Rather, a large number of variants and modifications are possible, which also make use of the inventive idea and therefore fall within the scope of protection. In addition, the invention also claims protection for the subject matter and the features of the subclaims independently of the referenced features and claims.

Reference symbol list

10

at least one further circuit, preferably cooling circuit or refrigeration circuit

20

Circuit, preferably cooling circuit

21

Power electronics

22

Valve, preferably for coolant temperature control

22.1

first entrance

22.2

second entrance

22.3

Exit

23

pump

24

Cooling device, preferably a cooler with a fan

25

Branch point

X1

Heat exchanger, preferably plate heat exchanger, in particular first heat exchanger

A

first line section, preferably upstream of the power electronics and downstream of the heat exchanger and / or the cooling device

A1

first section

A2

second section

b

second line section, preferably downstream of the power electronics and upstream of the heat exchanger and / or the cooling device

C

third line section, preferably bypass line to bypass the cooling device and/or the heat exchanger

30

additional circuit, preferably refrigeration circuit

X2

Heat exchanger, preferably chiller, in particular another heat exchanger

50

Expansion tank

t

Coolant temperature

100

Cooling system

Claims (32)

Cooling system (100), preferably for a motor vehicle, preferably an autonomous or semi-autonomous motor vehicle, in particular a truck or bus, with: power electronics (21), preferably at least one control device and / or at least one computer, preferably for data processing for autonomous or semi-autonomous driving of the Motor vehicle, and a circuit (20) for cooling the power electronics (21), characterized in that the circuit (20) comprises a valve (22) for coolant temperature control to avoid condensation formation on or in the power electronics (21). cooling system (100). Claim 1 , characterized in that the cooling system (100) comprises at least one further circuit (10). cooling system (100). Claim 2 , characterized in that the further circuit (10) and the circuit (20) are thermally connected to one another via a heat exchanger (X1), preferably a plate heat exchanger, in particular so that the further circuit (10) is used to generate and/or provide refrigeration and/or cooling capacity can be used for the circuit (20). cooling system (100). Claim 2 or 3 , characterized in that the further circuit (10) is thermally connected to an additional circuit (30) via a particularly further heat exchanger (X2), preferably a chiller, preferably so that the additional circuit (30) is used to generate and/or provide Cooling capacity can be used for the circuit (20) and/or the further circuit (10). Cooling system (100) according to one of the Claims 2 until 4 , characterized in that the further circuit (10) and / or the additional circuit (30) comprises at least one of the following: - an expansion element, - a compressor, - a condenser, - an evaporator, and / or - a cooling device, preferably a cooler with a fan. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) - is a directional valve, in particular a 3-way valve and/or 3/2-way valve, - is set up to bring together coolant at different temperatures, and/ or - has at least three connections (22.1, 22.2, 22.3) and/or at least two switching positions. Cooling system (100) according to one of the preceding claims, characterized in that the circuit (20) comprises a cooling device (24), preferably a cooler with a fan. Cooling system (100) according to one of the preceding claims, characterized in that the circuit (20) comprises: - a first line section (A), preferably upstream of the power electronics (21) between the cooling device (24) and / or the heat exchanger ( X1) and the power electronics (21), and / or - a second line section (B), preferably downstream of the power electronics (21) between the power electronics (21) and the cooling device (24) and / or the heat exchanger (X1) extends. cooling system (100). Claim 8 , characterized in that a third line section (C) connects the second line section (B) to the valve (22) and / or forms a bypass line to deliver coolant to the valve, bypassing the cooling device (24) and / or the heat exchanger (X1). (22) and/or into the first line section (A) and preferably back to the power electronics (21). cooling system (100). Claim 9 , characterized in that the third line section (C) branches off from the second line section (B) at a branch point (25) and / or the valve (22) is integrated into the first line section (A) and the third line section (C). Cooling system (100) according to one of the preceding claims, characterized in that the circuit (20) comprises a pump (23). cooling system (100). Claim 11 , characterized in that the pump (23) is set up to change, preferably optionally increase and/or increase, a coolant heat flow or coolant volume flow, preferably for coolant temperature control in order to avoid condensation formation on or in the power electronics (21). to reduce. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) has: - a first inlet (22.1), preferably by means of a first section (A1) of the first line section (A) with an outlet of the cooling device ( 24) and/or the heat exchanger (X1), - a second input (22.2), preferably which is connected to the second line section (B) by means of the third line section (C), and - an output (22.3), in order to in Depending on valve switching positions, coolant is fed from the first input (22.1) and/or from the second input (22.2) to the power electronics (21) and/or into a second section (A2) of the first line section (A). cooling system (100). Claim 13 , characterized in that the first input (22.1) and/or the second input (22.2) - has an open position in which it is completely open, - has a closed position in which it is completely closed, and - has at least one intermediate position , in which it is partially open. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) for coolant temperature control has a switching position in which the first input (22.1) is completely closed and the second input (22.2) is completely or partially open, preferably so that coolant can circulate between the output (22.3), the power electronics (21) and the second input (22.2), but an inflow of coolant via the first input (22.1) is prevented. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) for coolant temperature control has a switching position in which the first input (22.1) is partially open and the second input (22.2) is completely or partially open, preferably so that coolant can circulate between the output (22.3), the power electronics (21) and the second input (22.2), but an inflow of coolant is also permitted via the first input (22.1). Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) for coolant temperature control has a switching position - in which the first inlet (22.1) is completely open, preferably so that coolant flows between the outlet (22.3), the power electronics (21) and the first input (22.1) can circulate, and preferably - in which the second input (22.2) is completely closed or is only partially and / or intermittently opened. Cooling system (100) according to one of the Claims 7 until 17 , characterized in that the cooling device (24) - is integrated into the second line section (B), - is positioned downstream of the power electronics (21) and/or downstream of the branch point (25), and/or - upstream of the heat exchanger (X1) is positioned. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) is a thermostatic valve and/or is a self-adjusting valve for coolant temperature control and thus preferably forms a non-electronically controlled and/or regulated valve. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) comprises an expansion material or expansion fluid that reacts to temperature fluctuations, preferably in order to influence a coolant flow. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) is set up for temperature fixed value control in order to keep the coolant temperature for the power electronics (21) in a predetermined temperature range. Cooling system (100) according to one of the preceding claims, characterized in that the valve (22) is an electrical valve, in particular an electronically controlled and/or regulated valve. Cooling system (100) according to one of the preceding claims, characterized in that the cooling system (100) comprises an electronic control and/or regulating device which is set up, preferably for cooling the power electronics (21) and/or for controlling the coolant temperature a condensation formation on or in the power electronics (21), the valve (22) and / or the pump (23) to control and / or regulate. cooling system (100). Claim 23 , characterized in that the control and / or regulating device is set up to control and / or regulate the valve (22) and / or the pump (23) depending on at least one of the following: - a temperature and / or a humidity of the ambient air of the power electronics (21), - a temperature on or in the power electronics (21), - a coolant temperature of the circuit (20), in particular upstream and / or downstream of the power electronics (21), - a coolant temperature the further circuit (10) and/or - a refrigerant temperature or coolant temperature of the additional circuit (30). cooling system (100). Claim 23 or 24 , characterized in that the coolant temperature of the circuit (20), preferably at or before entry into the power electronics (21), serves as a controlled variable for controlling the valve (22) and/or the pump (23). Cooling system (100) according to one of the Claims 23 until 25 , characterized in that the control and/or regulating device is set up to carry out an adjustment with at least one dew point curve and/or to keep the coolant temperature in a predetermined temperature range. Cooling system (100) according to one of the Claims 23 until 26 , characterized in that the control and/or regulating device - forms part of the power electronics (21) and can therefore preferably be cooled by the circuit (20), or - is provided in addition to the power electronics (21) and is provided by the circuit (20) is decoupled. Cooling system (100) according to one of the Claims 2 until 27 , characterized in that the further circuit (10) and/or the additional circuit (30) - is a refrigeration circuit, preferably an independent refrigeration circuit for generating cooling power for the circuit (20) and/or - is a refrigeration circuit, preferably an independent one Cooling circuit to generate cooling power for the circuit (20). Cooling system (100) according to one of the Claims 2 until 28 , characterized in that - the further circuit (10) is a refrigeration circuit Air conditioning for cooling an interior of the motor vehicle, or - the further circuit (10) is a battery cooling circuit for cooling a battery device, its control electronics and / or an inverter, in particular a battery device for an electric motor for driving the motor vehicle, and the additional circuit (30 ) a refrigeration circuit is used to generate and/or provide refrigeration capacity for the further circuit (10) and the circuit (20). Cooling system (100) according to one of the Claims 2 until 29 , characterized in that the further circuit (10) and / or the additional circuit (30) serves to generate and / or provide cooling and / or refrigeration power for the circuit (20) and preferably thus cool and / or cold from the further circuit (10) and/or the additional circuit (30) is used by means of the circuit (20) to cool the power electronics (21). Motor vehicle, preferably an autonomous or semi-autonomous motor vehicle, in particular a truck or bus, with a cooling system (100) according to one of the preceding claims. Method for a cooling system (100), preferably according to one of Claims 1 until 30 , with: power electronics (21), preferably at least one control device and / or at least one computer, preferably for data processing for autonomous or semi-autonomous driving of the motor vehicle, and a circuit (20) for cooling the power electronics (21), characterized in that the circuit (20) comprises a valve (22) which carries out coolant temperature control to avoid condensation formation on or in the power electronics (21).

Images