DE102017220550A1 - Cooling system for a drive system and vehicle drive system - Google Patents

Abstract

The invention relates to a cooling system for a drive system and a vehicle drive system with such a cooling system. Here, an electric motor (1) and a functional unit (2, 3) arranged thereon are provided, as well as an electric machine cooling structure (1A) for passing a coolant for cooling the electric motor (1) and a functional unit cooling structure (FIG. 2A, 3A) for passing this coolant for cooling the functional unit (2, 3). The E-machine cooling structure (1A) and the functional unit cooling structure (2A, 3A) have a single common interface (1-2, 1-3) via which the coolant between these cooling structures (1A, 2A, 1A, 3A ) is interchangeable.

Description

The invention relates to a cooling system for a drive system, comprising an electric motor and having a functional unit arranged thereon, as well as a vehicle drive system with such a cooling system.

Electric motor vehicles usually have at least two coolant circuits. With the first coolant circuit, the electrical consumers and generators are cooled in series or in parallel. With the second circuit, the traction battery is usually cooled. The electric drive system, so at least the electric motor and the associated inverter, are usually cooled in series in the first cycle. The inverter is flowed through as the first component to ensure a minimum flow temperature. Thereafter, the electric drive machine and possibly a downstream of the electric motor transmission of the drive system is cooled.

In the automotive environment, the integration of the electric motor, the associated inverter and the gearbox has usually been dispensed with in practice. As a result, the inverter has its own metal housing, for example made of die-cast aluminum. The disadvantage of this is that this design of the inverter is structurally restrictive. In detail, this greatly limits the possibilities for positioning the individual components of the inverter. In addition, pipe or hose connections between the electric motor and the inverter and possibly also the transmission for the cooling of these components are thus required.

From the EP 2 846 442 A2 For example, a cooling system for a vehicle drive system is known. Here, a cooling structure of an electric machine with a cooling structure of an inverter via an external hose or pipe connection is coupled (see, for example 5 , Reference number 18 ). As a result, the risk of leaks is great.

The object of the present invention is to improve the state of the art.

This object is achieved by the features specified in the main claims. Preferred embodiments thereof are the dependent claims.

Accordingly, a cooling system for a drive system is proposed. The drive system comprises an electric motor, and it has a functional unit arranged on the electric motor. Such an electric machine is, for example, an electric motor. In particular, such an electric machine can be a synchronous or asynchronous or reluctance machine.

The cooling system has an e-machine cooling structure for passing a coolant to cool the e-machine. In addition, the cooling system has a functional unit cooling structure for passing this coolant for cooling also the functional unit. Thus, the coolant is used to cool both the E-machines, as well as the functional unit. Such a cooling structure is in particular formed as one or more cooling channels. In particular, these can be formed in a housing or another supporting structure of the electric motor or of the functional unit in order to form the respective cooling structure. The two cooling structures can be connected in series or in parallel.

The coolant is in particular a coolant, such as a water-glycol mixture.

It is now envisaged that the e-machine cooling structure and the functional unit cooling structure have a single common interface, via which the coolant is interchangeable between these cooling structures. Thus, the two cooling structures are coupled directly to each other exclusively via this one interface. An intermediate structure, such as an extra hose connection, which requires at least one further interface is therefore not available. It can therefore also be said that the interface is free of such a hose connection. The two cooling structures are thus coupled to each other in particular without tubing via the interface. This saves components and reduces costs. Thus, therefore, a direct, direct coolant-conductive connection between the two cooling structures is created.

Preferably, the functional unit is a transmission for translating a torque of the electric motor or an inverter for operating the electric motor. Accordingly, the functional unit cooling structure is a transmission cooling structure or an inverter cooling structure. Such an inverter converts in a conventional manner a direct electrical current in an alternating current for the electric motor (motor operation of the electric motor), and possibly also vice versa (regenerative operation of the electric motor). Such an inverter is therefore also referred to as AC / DC converter. Such a transmission has gear element with which the drive or braking torque of the electric motor is increased or reduced. The transmission may have a single fixed gear ratio or several selectable different gear ratios.

It may also be that on the electric motor both such an inverter, and such a transmission are arranged. In this case, one or both of the inverter and the transmission can each have the said functional unit cooling structure. Accordingly, the electric motor can then have only one such interface, namely for coupling the electric motor cooling structure with the transmission cooling structure or the inverter cooling structure. Or the e-machine then have exactly two such interface, namely the first to couple the e-machine cooling structure with the heat exchanger cooling structure and the second to couple the e-machine cooling structure with the transmission cooling structure. Thus, only a single interface is always provided between two of the cooling structures.

Accordingly, it may be provided that the transmission is arranged with its transmission-cooling structure at a first location of the electric motor and the inverter is arranged with its inverter cooling structure at another location of the electric motor. For example, the transmission can be arranged on one end side of the electric motor and the inverter on a radial stone surface of the electric motor. The e-machine cooling structure and the inverter cooling structure then have the single common (first) interface over which the coolant is interchangeable between these cooling structures. And the e-machine cooling structure and the transmission cooling structure then have the single common other (second) interface over which the coolant is interchangeable between these cooling structures.

The e-machine cooling structure may be part of a housing of the electric motor, in particular a cooling jacket. The functional unit cooling structure, that is to say in particular the inverter cooling structure or the transmission cooling structure, can then be part of a housing or a supporting structure of the associated functional unit. In the case of the inverter, such a supporting structure may in particular carry semiconductor power switches and / or an intermediate circuit capacitor of the inverter and at the same time be designed to cool it.

A first component of the interface is then formed by a part of the housing of the electric motor, and a second component of the interface is then formed by a part of the housing or the supporting structure of the functional unit. These two components of the interface are then formed in particular corresponding to one another, so that they fit into one another directly in a form-fitting manner or can be connected to one another directly in a form-fitting manner.

In particular, the interface may be configured to be completed by arranging the functional unit on the electric machine and thereby forming a (sealed) passage for the coolant between the E-machine cooling structure and the functional unit cooling structure.

The housing of the electric motor and / or the housing of the functional unit is in particular designed such that it terminates an interior of the housing from an exterior of the housing, in particular at least (splash) waterproof. Thus, the housing forms a certain protection against external environmental conditions. The housings can also be designed such that they are not yet completely self-sealing for themselves and only seal together by arranging them together.

In particular, the interface comprises precisely one (first) sealing surface on the E-machine cooling structure and exactly one other abutting (second) sealing surface on the functional unit cooling structure. Thus, the two cooling structures are directly adjacent to each other via these two sealing surfaces. By means of these sealing surfaces, an undesired escape of the coolant from the interface is prevented. The interface thus forms with the sealing surfaces a passage for the coolant between the two cooling structures. At the same time, the interface seals the passage to the outside by means of the sealing surfaces. One or both of the sealing surfaces may in this case comprise one or more sealing elements, for example an O-ring and / or a flat gasket and / or a thread seal.

The interface may allow the coolant to be forwarded and re-directed. By "forwarding" may be meant a forwarding of the coolant to the e-machine or a forwarding of the coolant to the functional unit, with "return" then the corresponding opposite direction is meant. In particular, the interface can thus form a first passage for conducting the coolant and a second passage for returning the coolant.

Alternatively, only one of Hinleiten and returning the cooling medium via the interface. Accordingly, the interface then forms just one passage for the coolant.

Preferably, the interface comprises, on the one hand, a coolant-conducting plug and, on the other hand, a coolant-conducting bushing corresponding thereto. The plug is then part of the a cooling structure, whereas the socket is then part of the other cooling structure. The interface is formed as by the connector, consisting of plug and socket.

Alternatively, the interface comprises a coolant-conducting first flange and a coolant-conducting second flange corresponding thereto. The first flange is then part of the one cooling structure, whereas the second flange is then part of the other cooling structure.

Also proposed is a vehicle drive system. This is in particular a motor vehicle drive system. The drive system has the electric motor and the inverter for operating the electric motor. In addition, the drive system has the proposed cooling system for cooling of the hopper and electric motor. In addition, the drive system can optionally also have the transmission. Here, the cooling system, as described, are also used for cooling the transmission.

The e-machine serves in particular as a traction drive. It then serves to generate a driving force of the vehicle. Such a drive system is used in particular in a motor vehicle which can be driven electrically at least for a time, such as, for example, a pure electric vehicle or a hybrid vehicle which has an additional combustion engine as a traction drive. Alternatively, the electric motor can also serve as an actuator, ie for actuating or adjusting a device of the vehicle, such as a vehicle steering or a vehicle chassis.

Due to the high degree of integration and the resulting compact installation space arrangement between the inverter and the electric motor and possibly the gearbox, there is a good thermal coupling between these components. As a result, the heat capacity of the coolant can be shared. Since in most cases the more critical design criterion of the inverter is the maximum output power and in the case of the e-machine is the continuous output, the performance of the drive system can be increased due to the space-close arrangement and the shared use of the heat capacity. There are no additional costs for this. Furthermore, certain temperature sensors can be saved in the cooling system due to thermal replacement modeling. For example, a temperature sensor on a stator of the e-machine can be omitted.

• 1 zeigt ein Antriebssystem, insbesondere ein Fahrzeugantriebssystem, insbesondere ein Kraftfahrzeugantriebssystem.

In the following the invention with reference to a figure ( 1 ), from which a further preferred embodiment and further preferred features of the invention can be removed.

• 1 shows a drive system, in particular a vehicle drive system, in particular a motor vehicle drive system.

The drive system has an electric motor 1 on and an inverter 2 for operating the electric machine 1 , In addition, the drive system has a transmission 3 for translating a torque of the electric machine 1 on. inverter 2 and gear 3 are designed for placement on the electric motor (see thick arrows). These are so at the electric motor 1 attached. The gear 3 is then, for example, on a front side of the electric motor 1 attached and the inverter is then, for example, on a radial side surface of the electric motor 1 attached, as in 1 indicated.

The electric machine 1 has an e-machine cooling structure 1A for passing a coolant for cooling the electric motor 1 on. The inverter 2 has an inverter cooling structure 2A for passing the coolant for cooling the inverter 2 on. Optionally, the transmission also has a transmission cooling structure 3A for passing the coolant for cooling the transmission 3 on.

The cooling structures 1A . 2A . 3A can in the respective component 1 . 2 . 3 have integrated cooling channels. The cooling structures 1A . 2A . 3A may thus be considered part of a housing or a supporting structure of the respective component 1 . 2 . 3 be educated. In the electric motor 1 and the transmission 3 can the cooling structures 1A . 3A form a cooling jacket.

The cooling structures 2A . 3A are each using exactly one interface 1 - 2 and 1 - 3 with the cooling structure 1A the electric machine 1 Coupled coolant-conducting.

The first interface 1 - 2 is on the one hand by a part of the housing of the electric motor 1 educated. For example, the housing forms at this point a flange or one of plug and socket, which are each coolant-conductive. The first interface 1 - 2 on the other hand, by a part of the housing or a supporting structure of the inverter 2 educated. For example, forms the housing or the supporting structure at this point to the flange of the electric motor 1 matching flange or one to the plug of the electric motor 1 suitable socket or one to the socket of the electric motor 1 matching plug, which are then also each coolant-conducting. This simply forms a passage for the coolant. The second interface 1 - 3 can be designed analogously to this.

the interface 1 - 2 is particularly designed so that the associated components complete and thus form the passage for the coolant, if inverter 2 and electric machine 1 be joined together. The second interface 1 - 3 can be designed analogously to this.

The cooling structures 1A . 2A . 3A are thus tubeless over the individual interfaces 1 - 2 and 1 - 3 directly coupled with each other.

In the present case, the interfaces form 1 - 2 and 1 - 3 in each case only a single passage for the coolant. Thus, either only a Hinleiten or only a return of the coolant is possible. This is what the components are 1 . 2 . 3 coupled from the perspective of the coolant in series, with a forward and backward to and from this series of components 1 . 2 . 3 done externally.

the interface 1 - 2 and / or the interface 1 - 3 Alternatively, it may also be designed such that it forms two passages in each case. One of the passages then serves for the passage of the coolant and the other of the passages then serves for the return of the coolant. This allows the units 1 . 2 . 3 from the point of view of the coolant also be coupled in series, but a forward and backward now but from and to this series, at least in part within the components 1 . 2 . 3 the series can be done.

LIST OF REFERENCE NUMBERS

1

E-machine

1-2

first interface

1-3

second interface

1A

E-machine cooling structure

2

inverter

2A

Inverter cooling structure

3

transmission

3A

Transmission cooling structure

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2846442 A2 [0004]

Claims (10)

Cooling system for a drive system, comprising an electric machine (1) and having a functional unit (2, 3) arranged thereon, having an electric machine cooling structure (1A) for passing a coolant for cooling the electric machine (1), and • with a functional unit cooling structure (2A, 3A) for passing this coolant for cooling the functional unit (2, 3), characterized in that the E-machine cooling structure (1A) and the functional unit cooling structure (2A, 3A) single common interface (1-2, 1-3) over which the coolant between these cooling structures (1A, 2A, 1A, 3A) is interchangeable. Cooling system after Claim 1 wherein the functional unit (2, 3) is a transmission (3) for translating a torque of the electric motor (1) or an inverter (2) for operating the electric motor (1). Cooling system after Claim 2 in which the transmission (3) is arranged at a first location of the electric motor (1) and the inverter (2) is arranged at another location of the electric motor (1), wherein the electric motor cooling structure (1A) and an inverter cooling structure (2A) having a single common interface (1-2) through which the coolant is interchangeable between these cooling structures (1A, 2A), and wherein the e-machine cooling structure (1A) and a transmission cooling structure (3A) have a single other common interface (1-3) over which the coolant is interchangeable between these cooling structures (1A, 3A). Cooling system according to one of the preceding claims, wherein the E-machine cooling structure (1A) is part of a housing of the electric motor (1), in particular a cooling jacket, and wherein the functional unit cooling structure (2A, 3A) is part of a housing or supporting structure of the functional unit (2, 3), and wherein a first component of the interface (1-2, 1-3) is a part of the housing of the electric motor (1) and a second component of the interface (1-2, 1-3) is a part of the housing or the supporting structure of the functional unit (2, 3). Cooling system according to one of the preceding claims, wherein the two cooling structures (1A, 2A, 1A, 3A) are tubelessly coupled together via the interface (1-2, 1-3) in a coolant-conducting manner. Cooling system according to one of the preceding claims, wherein the interface (1-2, 1-3) has exactly one sealing surface on the e-machine cooling structure (1A) and exactly one sealing surface on the functional unit cooling structure (2A, 3A). Cooling system according to one of the preceding claims, wherein the interface (1-2, 1-3) allows a forwarding and returning of the coolant. Cooling system according to one of the Claims 1 to 7 wherein the interface (1-2, 1-3) comprises a coolant-conducting plug and a coolant-conducting bushing corresponding thereto, the plug being part of the one cooling structure (1A, 2A, 3A), and wherein the bushing is a Part of the other cooling structure (1A, 2A, 3A). Cooling system according to one of the Claims 1 to 7 wherein the interface (1-2, 1-3) comprises a coolant-conducting first flange and a coolant-conducting second flange corresponding thereto, wherein the first flange is a component of the one cooling structure (1A, 2A, 3A), and wherein the second flange is a component of the other cooling structure (1A, 2A, 3A). Vehicle drive system with an electric motor (1), in particular as a traction drive or as an actuator, and with an inverter (2) for operating the electric motor (1), and with a cooling system for cooling the electric motor (1) and inverter ( 2) by means of a coolant, characterized in that the cooling system is designed according to one of the preceding claims.

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