METHOD FOR OPERATING A COOLING SYSTEM OF A MOTOR VEHICLE WITH COOLING CAPACITY CONTROL

Abstract

A method for operating a cooling system of a motor vehicle for cooling at least one component, a cooling system of a motor vehicle for cooling at least one component, and a motor vehicle having such a cooling system. The cooling system has a coolant circuit and a refrigerant circuit. The coolant circuit serves for cooling the at least one component and the refrigerant circuit and the coolant circuit are coupled thermally to one another via a heat exchanger. The coolant circuit has a conveying device for conveying a coolant in the coolant circuit. A cooling power of the refrigerant circuit can be regulated. The regulation of the cooling power of the refrigerant circuit is realized in a manner dependent on a return temperature of the coolant and/or on a temporal development of the return temperature of the coolant.

Claims

1. A method for operating a cooling system of a motor vehicle for cooling at least one component, wherein the cooling system has a coolant circuit and a refrigerant circuit, wherein the coolant circuit serves for cooling the at least one component and the coolant circuit has a conveying device for conveying a coolant in the coolant circuit, and the refrigerant circuit and the coolant circuit are coupled thermally to one another via a heat exchanger, said method comprising: regulating a cooling power of the refrigerant circuit in a manner that is dependent on a return temperature of the coolant and/or on a temporal development of the return temperature of the coolant.

2. The method as claimed in claim 1, wherein the regulation of the cooling power is carried out such that multiple temperature windows for the return temperature are defined and the cooling power to be provided by the refrigerant circuit is associated with the respective temperature window.

3. The method as claimed in claim 1, further comprising (i) increasing the cooling power if the return temperature exceeds a specific value and/or the temporal development of the return temperature exceeds a specific value, and/or (ii) reducing the cooling power if the return temperature falls below a specific value and/or the temporal development of the return temperature falls below a specific value.

4. The method as claimed in claim 1, further comprising regulating the cooling power in a manner dependent on a feed temperature of the coolant and/or on a temporal development of the feed temperature of the coolant.

5. A cooling system of a motor vehicle for cooling at least one component, said cooling system comprising: a coolant circuit for cooling the at least one component, wherein the coolant circuit comprises (i) a conveying device for conveying a coolant in the coolant circuit, and (ii) a temperature sensor for measuring a return temperature of the coolant in the region of the return; a refrigerant circuit coupled thermally to the coolant circuit via a heat exchanger; and wherein the cooling system further comprises (iii) a regulating device for regulating a cooling power of the refrigerant circuit, wherein the regulating device is configured to regulate the cooling power of the refrigerant circuit in a manner dependent on the return temperature of the coolant and/or on a temporal development of the return temperature of the coolant.

6. The cooling system as claimed in claim 5, wherein the refrigerant circuit has a compressor, a condenser and an expansion valve.

7. The cooling system as claimed in claim 5, wherein the cooling system has a chiller that forms the heat exchanger or the heat exchanger is a constituent part of the chiller.

8. The cooling system as claimed in claim 5, wherein the cooling system comprises a further temperature sensor for measuring a feed temperature of the coolant in the region of the feed.

9. An electric or partially-electric motor vehicle comprising the cooling system as claimed in claim 5.

10. The motor vehicle as claimed in claim 9, wherein the component to be cooled is a battery, power electronics, a semiconductor component, an insulated gate bipolar transistor, or a control unit.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] In the following figures, the invention will be discussed in more detail on the basis of an exemplary embodiment, without being limited to these. In the figures:

[0026] FIG. 1 shows an embodiment of a cooling system according to aspects of the invention in a schematic illustration,

[0027] FIG. 2 shows two diagrams relating to regulation of a refrigerant circuit according to the prior art,

[0028] FIG. 3 shows two diagrams relating to regulation of the cooling power of a refrigerant circuit according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0029] FIG. 1 shows a cooling system 1 according to aspects of the invention, wherein said cooling system 1 has a coolant circuit 3 and a refrigerant circuit 4, wherein the coolant circuit 3 serves for cooling the three components 2. In the present case, the components 2 are electrified components, for example are power electronics or components of power electronics or are a high-voltage battery. The refrigerant circuit 4 and the coolant circuit 3 are coupled thermally to one another via a heat exchanger 5. The refrigerant circuit 4 has a compressor 9, a condenser 10 and an expansion valve 11. The refrigerant of the refrigerant circuit 3 circulates clockwise in the refrigerant circuit 4, as is indicated by the arrow 12. The coolant circuit 3 has a conveying device 6 for conveying a coolant in the coolant circuit 3, wherein the coolant circulates counterclockwise in the coolant circuit 3, as is indicated by the arrow 13. The cooling system 1 has a temperature sensor 7 for measuring a return temperature of the coolant in the region of the return, and thus before the entry of the coolant into the heat exchanger 5. The cooling system 1 furthermore has a further temperature sensor 8 for measuring a feed temperature of the coolant in the region of the feed. This temperature sensor 8 is accordingly arranged in the region after the exit of the coolant from the heat exchanger 5. During the operation of the cooling system 1, the feed temperature is lower than the return temperature.

[0030] The cooling system 1 has a regulating device (not illustrated in any more detail) for regulating the cooling power of the refrigerant circuit 4, wherein the regulating device is configured to regulate the cooling power of the refrigerant circuit 4 in a manner dependent on the return temperature of the coolant and/or on a temporal development of the return temperature of the coolant.

[0031] Regulation in a manner dependent on a temporal development of the return temperature of the coolant has the advantage that, in this way, an increase in the cooling power of the refrigerant circuit can be realized if rapid heating of the coolant in the coolant circuit is registered. Consequently, thermal escalations can be avoided or damped.

[0032] The regulation of the cooling power of the refrigerant circuit may be realized for example through an increase in the rotational speed of the compressor 9 and/or through a change of the settings of the expansion valve 11.

[0033] The advantages of the solution according to aspects of the invention become clear from a comparison of FIGS. 2 and 3. FIG. 2 shows a curve 16 in the upper diagram, wherein said curve 16 shows the temporal development of the temperature of a component to be cooled. The curve 18 shows a cooling power of the refrigerant circuit 4 where the regulation of the cooling power is realized in a manner dependent on the temperature of the component 2. The curve 17 in the lower diagram in FIG. 2 shows a rotational speed of the compressor 9 for attaining the corresponding cooling power. The dash-dotted line 20 shows a time-averaged cooling power of the refrigerant circuit 4.

[0034] As can be seen in the diagrams in FIG. 2, the temperature development of the component 2 is highly dynamic, that is to say relatively intense changes in temperature take place over relatively short time scales. Accordingly, the cooling power or the compressor rotational speed is correspondingly dynamically readjusted if the temperature of the component 2 is used for the regulation of the cooling power of the refrigerant circuit 4. On average, the result is a relatively high cooling power, which is associated with a correspondingly high energy consumption.

[0035] FIG. 3, by contrast, shows regulation as provided by the solution according to aspects of the invention. The curve 19 in the upper diagram in FIG. 3 then shows not the temperature of the component 2 to be cooled but the return temperature of the coolant in the coolant circuit 3. As shown by a comparison of the two upper diagrams in FIGS. 2 and 3 or of the curves 16 and 19, the temporal profile of the return temperature is smoother or more damped than the temporal development of the temperature of the component 2. The reason for this is that the coolant has a very much larger thermal mass compared to the component 2 and accordingly has a higher thermal inertia than the component 2. Although an increase in the temperature of the component 2 also leads to an increase in the temperature of the coolant at the return of the refrigerant circuit 3, the temporal development of the temperature is correspondingly damped owing to the relatively large thermal mass. According to aspects of the invention, it is then provided that the temperature of the coolant at the return is used for the regulation of the cooling power of the refrigerant circuit 4. Accordingly, it is also the case that the temporal development of the cooling power of the refrigerant circuit 4 or the compressor rotational speed is very much slower or more damped than in the case in FIG. 2 or in the methods known from the prior art. Likewise, the average cooling power is lower than in the case in the method according to the prior art.

[0036] In the upper diagram in FIG. 3, two temperature windows 14 and 15 are additionally drawn, wherein the first temperature window 14 covers relatively low temperatures and the temperature window 15 covers relatively high temperatures, wherein the two temperature windows 14, 15 are adjacent to one another. A cooling power to be provided by the refrigerant circuit 4 is associated with the respective temperature window 14, 15, wherein the cooling power is higher in the temperature window 15 than in the temperature window 14.

[0037] In the present case, the regulation of the cooling power is realized not solely on the basis of the absolute return temperature, and thus not solely on the basis of which temperature window 14, 15 the return temperature is in, but additionally in a manner dependent on the temporal development of the return temperature of the coolant. In the present case, an increase in the cooling power will already occur if the temporal development of the return temperature, and thus the change in temperature per unit time, exceeds a specific value. Furthermore, a reduction in the cooling power will already occur if the temporal development of the return temperature falls below a specific value. The regulation on the basis of the temporal development of the return temperature has the advantage that, in the case of the occurrence of a trend in the temperature development, for example a rapid rise in the temperature, an increase in the cooling power will, as a preventive measure, already occur before the return temperature exceeds a specific value, in order, in this way, to prevent an excessively large increase in the temperature.

LIST OF REFERENCE SIGNS

[0038] 1 Cooling system [0039] 2 Component [0040] 3 Coolant circuit [0041] 4 Refrigerant circuit [0042] 5 Heat exchanger [0043] 6 Conveying device [0044] 7 Temperature sensor [0045] 8 Temperature sensor [0046] 9 Compressor [0047] 10 Condenser [0048] 11 Expansion valve [0049] 12 Arrow [0050] 13 Arrow [0051] 14 First temperature window [0052] 15 Second temperature window [0053] 16 Curve [0054] 17 Curve [0055] 18 Curve [0056] 19 Curve [0057] 20 Curve