EP3465883A1

EP3465883A1 - Cooling of an electric machine

Info

Publication number: EP3465883A1
Application number: EP17721661.1A
Authority: EP
Inventors: Jin-kang LI; Holger Fröhlich; Wolfgang Halbmeyer; Matthias UECKER; Yakup GUENSAYAN
Original assignee: Continental Automotive GmbH
Current assignee: Vitesco Technologies GmbH
Priority date: 2016-06-03
Filing date: 2017-05-04
Publication date: 2019-04-10
Also published as: WO2017207210A1; DE102016209752A1; US20190222090A1; CN109314430A

Abstract

The invention relates to an installation part (28) for a housing (8) of an electric machine (1), wherein the installation part (28) is designed to form a section (29) of a cooling channel (11) together with the housing (8) when the installation part is installed in the housing (8). The invention further relates to the housing (8), to the electric machine (1), and to a method for producing an electric machine (1).

Description

description

Cooling of an electric machine The invention relates to cooling technologies

electric machine, in particular an electric motor or generator.

Drive devices, in particular hybrid drive devices, are used to drive motor vehicles, wherein hybrid drive devices typically include an internal combustion engine and an electric machine. The case acting as a motor and generator electric machine has a shaft with a rotor arranged on the shaft and a stator. The stator and the rotor are disposed within a housing of the electric machine.

In the electric machine, in particular in its stator and / or rotor, waste heat is generated, so that cooling of the electric machine is required. Typically, in the housing, a cooling channel for passing a cooling fluid, for example, liquid coolant or air, is incorporated for cooling the electric machine. After introducing the cooling fluid into the cooling channel, the cooling fluid absorbs heat.

It is known that a housing of an electric machine, in which a cooling channel is integrated to produce a single piece or in molds ^¬ molding process to produce two parts with an inner casing and an outer casing. In the latter method, the inner housing is inserted into the outer housing and thereby the housing with the cooling channel produced. In the manufacture of the electrical machine, it is generally desirable that the electrical machine requires little space. For this purpose, it is beneficial that an outer diameter or a circumference of the housing - in a one-piece design and a two-part design - is as small as possible. This space can be saved and beyond material for the production of the housing or the electric machine can be reduced. It is therefore an object of the present invention to provide technologies for cooling an electrical machine, by means of which a space-optimized and cost ^¬ favorable cooling of an electrical machine, in particular those winding heads, is made possible.

The object is solved by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims, the description and the drawings. According to a first aspect of the invention, an internals for a housing of an electric machine is provided. The built-in is designed such that it forms a portion of a cooling channel in the installed state in the housing together with the housing.

Through the cooling channel, it is possible to dissipate heat from the active parts of the electric machine partially and selectively.

In particular, so-called hot spots of the electrical Ma ^¬ machines can be partially and targeted cooled.

Preferably, the portion of the cooling channel is in the region of a winding head of the electric machine. Thus, it is particularly advantageous possible loss heat, in the field of Winding head is generated as a special hotspot, effectively dissipate.

The internals may preferably be a deep-drawn sheet metal component. Thus, the internals or the cooling channel cover with a small thickness of a metal sheet, in particular of steel or aluminum, by

Deep drawing can be made. The thickness of the built-in part may in particular be between 1 mm and 3 mm.

According to a second aspect of the invention, a housing for an electrical machine is provided, in particular an outer housing ^¬ with an inner contour, wherein the housing together with an internals according to the first aspect of the invention forms at least a portion of a cooling channel. The Kühlkanalab ^¬ cut is particularly preferably formed between the inner contour of the housing and the internals. By mounting the mounting part in the housing, in particular in the outer housing, at least one cooling channel can be formed media-tight with respect to the environment. A along the inner contour of the outer housing resulting cooling channel allows a particularly small space for the housing of the electric machine, whereby the electric machine or its housing can be very inexpensively compared to the prior art (in particular cast or two-piece housing). The housing may be made especially in a Alumini ^¬ to-die-casting process.

In particular, the electric machine may comprise an inlet opening, in particular designed as an inlet connection, for introducing a cooling fluid into the at least one cooling channel section. Likewise, the electric machine can form an outlet opening, in particular as an outlet nozzle, for discharging of the cooling fluid from the at least one cooling passage section.

The Kühlka- formed by the baffles and the housing nalabschnitt may further particular form a radial Kühlka ^¬ nalabschnitt a cooling system within the electrical machine. The radial cooling channel section enables circulating cooling, in particular in the region of the end winding of the stator of the electric machine. Gap fillers can be used for better heat conduction.

Furthermore, indirect cooling, e.g. be used by turbulent air circulation, which can be generated by rotation of a rotor of the electric machine. The radial cooling passage portion may be further connected to an axial bore within the housing for distributing coolant.

The Kühlka ^¬ nalabschnitt formed by the mounting parts and the housing is based on a particularly simple construction of housing and internals and guarantees optimal cooling, especially in the winding head region of the electric machine, whereby a greater power output can be achieved.

Preferably, the housing has a depression, a bore or an inner contour in the region of the cooling channel section. The recess or inner contour can in particular be a channel-like recess running around the circumference of the housing or on the inside of the housing, which is designed to form the at least one cooling channel section.

According to a further embodiment, the thickness of the housing in the region of the cooling channel section is greater than the thickness of the built-in part. In particular, the maximum thickness of the housing (preferably including the webs for the formation of the cooling Channel section) be greater, in particular by a multiple greater than the thickness of the insert or the cooling channel cover. According to a further embodiment, it is advantageously provided that the axial extent of the built-in component is less than 30%, 20%, 10% or 5% of the maximum axial extent of the housing. Advantageously, the housing and the internals or the cooling channel cover can be cohesively connected mitei ^¬ each other. A cohesive connection which is necessary for this purpose can be ensured, for example, by means of an adhesive connection. To support a corresponding bonding process (hardening process) can continue to a

Clip connection between the housing and the internals or the cooling channel cover may be provided.

If the internals are adhesively bonded to the housing by means of an adhesive, it is further provided that pockets or grooves for adhesive of the adhesive bond are formed between the internals and the housing.

Alternatively, it can also be provided that the internals are fixed in a fluid-tight manner in an axial end region of the housing to the housing by means of a sealing ring. In particular, the internals can be positively connected by means of an O-ring with the housing. In this context, according to a further embodiment, the housing may have at least one annular groove in which a corresponding sealing ring is arranged.

According to a third aspect of the invention, there is provided an electric machine comprising a housing according to the invention as described above. According to a fourth aspect of the invention, a method for manufacturing an electric machine or a drive device is provided. The method includes loading ^¬ riding provide an installation part according to one of claims 1 to 3, and a housing having an inner contour. Furthermore, a fastening of the mounting part takes place on or in the housing, so that the inner contour of the housing and the internals form a portion of a cooling channel of the electric machine. The internals and the housing can be manufactured and provided separately. The internals may in particular be a deep-drawn sheet metal component. The housing can be produced in particular in a die-casting process. The inner contour of the housing may in particular a channel-like recess for forming the nigstens ^¬ we include a cooling channel section. Furthermore, by mechanical processing, eg drilling, within the housing at least one axial bore for the transport and distribution of coolant can be generated.

At the beginning or before the actual assembly of the housing and internals may also preferably a sticky tape in designated pockets or grooves are introduced, which may be located between the internals and the housing. By installing or inserting the built-in part into the housing, at least one cooling channel is formed between the housing and the internals, which can in particular be configured media-tight. The connection between internals and housing is preferably cohesive. To support the process of gluing the fixture in the housing, a clip connection between the housing and the internals may be provided. Because the at least one cooling channel section is not produced in one operation, such as, for example, in the mold casting method known from the prior art, relatively inexpensive production methods are possible, in particular with regard to series production. Thus, in particular, the housing in a die-casting process and the internals in one

Deep drawing process or produced in an extrusion molding process. The fact that the at least one Kühlkanalab ^¬ cut can be generated during assembly of the insert into the housing, a particularly simple construction with low production costs of the electric machine is possible. The electrical machine may further comprise from ^¬ particular a stator having a laminated stator core, a rotor with a laminated rotor core and a rotor shaft in known manner, being inserted in the stack of stator coil windings with protruding in the axial direction of the electrical machine stator windings.

Embodiments of the invention are explained in more detail below with reference to the schematic drawing. Hereby shows:

Fig. 1 is a diagram of a half-section of an electrical

Machine with a housing and two mounting parts in

Form of cooling channel covers in the area of stator Wiekelköpfen,

Fig. 2 is a diagram of a half section of another

electric machine with a housing and a formed as elongated cooling duct cover component,

Fig. 3 is a sectional view of another electrical

Machine with a housing and a refrigeration system nalabdeckung trained internals for winding head cooling,

Fig. 4 is an enlarged detail view of the insert after

3,

Fig. 5 is a first perspective view of a fitting for the electric machine of FIG. 3 and

6 is a second perspective view of the fitting of FIG .. 5

FIG. 1 shows the diagram of a half section of an electric machine 1 with a rotor, which comprises a rotor laminated core 2 and is mounted non-rotatably on a rotor shaft 3. The rotor shaft 3 is rotatably received within two arranged at axial ends of the electric machine 1 bearings 4. Coaxially around the rotor or its rotor laminated core 2, a stator with a stator laminated core 5 is arranged. Inside the stator laminated core 5 there are coil windings, which at axially opposite ends of the stator laminated core

5 form two stator winding heads 6 (shown on the right in FIG. 1) and 7 (shown on the left in FIG. 1). The stator winding heads

6 and 7 protrude beyond the rotor core 2 in the axial direction.

Further, the electrical machine 1 comprises a diecast housing ^¬ 8, which is an outer housing and the stator laminated core coaxially encloses 5. The housing 8 has an inflow port 9 and a drain port 10 for cooling fluid. The inflow port 9 and the outflow port 10 are connected to each other by means of a cooling channel 11. In this way, coolant can enter via the inflow port 9, through the cooling channel 11 are passed and discharged via the drain port 10.

The cooling channel 11 comprises a bore 12 extending in the axial direction L through the housing 8, a first radial one

Cooling passage section 13 and a second radial cooling channel ^¬ section 14. The first radial cooling passage section 13 is formed by an inner contour 15 of the housing 8 and a first internals 16. For this purpose, the housing 8 in the region of the first radial cooling channel section 13 a channel-like recess or bore 17, which is covered by the first internals 16, so that the first radial cooling passage portion 13 is formed, which is impermeable to the cooling liquid and positively by an adhesive bond between the baffles 16 and the housing 8 is made. The first internals 16 has in

Cross-section of a U-profile and is disposed on the housing 8 in the region of the stator winding head 6 shown in Figure 1 on the right. In this way, cooling liquid flowing through the first radial cooling passage section 13 can cool the right stator winding head 6.

Similarly, the second radial cooling passage section 14 is formed by means of the housing 8 and a second fitting in the form of a cooling channel cover 18. The second internals 18 is attached to the housing 8 in the region of the stator winding head 7, which is shown on the left in Figure 1, by means of an adhesive bond cohesively. The axial bore 12 which extends through the housing 8, is connected in the region of the left stator winding head 7 with a radial bore portion 19, which in turn merges into the second cooling passage portion 14 which is fluid-tightly bounded by the second internals 18 and fluidly connected to the drain port 10. 1 also includes the electric machine an inverter 20 to an inverter-cooling duct 21. In the embodiment shown, the inflow port 9 is arranged for the Kühlflüs ^¬ sigkeit in the range of inverter 20, with the plane passing through the housing 8 axial bore 12 in one

End shield 22 of the electric machine 1 continues and is connected to the inflow port 9.

Fig. 2 shows a diagram of a half section of another electric machine 1, which is different from the electrical

Machine 1 according to Figure 1 differs in particular by a different design of the cooling channel 11.

The cooling channel 11 comprises a bore 12 which extends in the axial direction L of the electric machine 1 within the housing 8 and which continues in the direction of an inlet connection 9 for coolant in a bearing plate 22 of the electric machine 1, the inflow connection 9 being in one Inverter 20 of the electric machine 1 is arranged. In the direction of the left in Fig. 2 shown axial end of the electrical

Machine 1 merges the axial bore 12 into a radial bore 23 within the housing 8. The radial bore 23 opens in the direction of the stator laminated core 5 of the electric machine 1 in an intermediate space 24 between an inner contour 15 of the housing 8 and an outer contour 25 of the stator laminated core 5.

Between the stator laminated core 5 and the housing 8, a cooling channel cover 26 is arranged, which forms an insert member, and runs parallel over the entire length of the stator 5 with its arranged at opposite axial ends stator winding heads 6 and 7.

The insert component 26 and the housing 8 is such material ^¬ connected to each other, that a fluid-tight waste Section 27 of the cooling channel 11 is formed, which the entire outer region of the stator 5, in particular its winding heads

6 and 7, and is fluidly connected to the drain port 10.

Figures 3 and 4 show another electric machine 1 with a rotor which comprises a rotor core 2 and is rotatably mounted on a rotor shaft 3. 5 and 6 show a suitable for the electric machine 1 of FIG. 3 internals 28. The rotor shaft 3 is rotatably received within two arranged at axial ends of the electric machine 1 bearings 4. Coaxially around the rotor laminated core 2, a stator with a stator laminated core 5 is arranged. Within the stator sheet ^¬ packet 5 are coil windings which form at two axially opposite ends of the stator laminated core 5, two Sta ^¬ tor winding heads 6 and 7. The stator winding heads 6 and

7 protrude in the axial direction beyond the rotor laminated core 2 addition.

Furthermore, the electric machine 1 comprises a die-cast housing 8, which is an outer housing, and which coaxially surrounds the rotor with its rotor core 2 and the stator with its stator core 5 and its winding heads 6 and 7. The housing 8 has an inflow port 9 and a drain port 10 for cooling fluid. The inflow connection 9 and the outflow connection 10 are connected to one another by means of a cooling channel 11. In this way, cooling liquid can enter via the inflow port 9, be passed through the cooling channel 11 and be discharged via the outflow port 10.

The cooling channel 11 includes an axis extending in the axial direction through the housing 8 hole 12 and a radial Kühlka ^¬ nalabschnitt 29 defined by an inner contour 15 (Fig. 4) of the Housing 8 and an insert in the form of a cooling channel cover 28 is formed. For this purpose, the housing 8 in the region of the radial cooling channel portion 29 has a radial bore 30, which is closed radially outward by a closure cap 31 and is covered radially inwardly by the internals 28, so that the radial cooling channel portion 29 is formed, which for ^¬ impermeable the cooling liquid is and is produced in a form-fitting manner by an adhesive connection between the internals 28 and the housing 8. The deep-drawn internals 28, for example made of aluminum, has a substantially U-shaped cross-section ^¬ profile with a central opening 32, one leg 33 is stepped, to rest against the inner contour 15 of the housing 8 in regions and partially from the inner contour 15th to be spaced to form the cooling channel portion 29. The housing 8 forms two pockets or grooves 34, which can be filled with adhesive to then bring the internals 28 into abutment with the housing 8 and to bond with this. Coolant can enter via the inlet port 9 along the axial bore 12, the radial bore 30 and the

Cooling duct section 29 are passed and exit via the outlet port 10. In this way, Kühlflüs ^¬ sigkeit which flows through the cooling passage section 29, and in particular to in Fig. Shown on the left stator winding 7 3 cool.

Furthermore, the electric machine 1 comprises an inverter 20 with an inverter housing 35 and an inverter cooling channel 21. In the embodiment shown, the inflow connection 9 for the cooling liquid is arranged in the region of the inverter 20, wherein the axial bore extending through the housing 8 12 continues in a bearing plate 22 of the electric machine 1 and is connected to the inflow port 9.

Claims

Patent claims

1. Internals (16, 18, 26, 28) for a housing (8) of an electrical machine (1), the internals (16, 18, 26, 28) being designed in such a way that it is installed in the housing (8). to form a section (13, 14, 27, 29) of a cooling channel (11) together with the housing (8).

2. Internals (16, 18, 26, 28) according to claim 1, characterized in that the section (13, 14, 27, 29) of the

Cooling channel (11) is located in the area of a winding head (6, 7) of the electrical machine (1).

3. Internals (16, 18, 26, 28) according to claim 1 or 2, characterized in that the internals (16, 18, 26, 28) is a deep-drawn sheet metal component.

4. Housing (8) for an electrical machine (1), the housing (8) together with an internal (16, 18, 26, 28) according to one of the preceding claims having a section (13, 14, 27, 29). Cooling channel (11) forms.

5. Housing (8) according to claim 4, characterized in that the housing (8) has a recess or bore (17, 19, 23, 30) in the area of the section (13, 14, 27, 29) of the cooling channel (11). having .

6. Housing (8) according to claim 4 or 5, characterized in that the thickness of the housing (8) in the area of the section (13, 14, 27, 29) of the cooling channel (11) is greater than the thickness of the built-in part (16 , 18, 26, 28) .

7. Housing (8) according to one of claims 4 to 6, ^{characterized} in that the axial extent of the built-in part (16, 18, 26, 28) is less than 30% of the maximum axial extent of the housing (8).

8. Housing (8) according to one of claims 4 to 7, characterized in that the internals (16, 18, 26, 28) are cohesively connected to the housing (8).

9. Housing (8) according to one of claims 4 to 8, ^{characterized} in that the internals (16, 18, 26, 28) are cohesively connected to the housing (8) by means of an adhesive connection and that between the internals ( 16, 18, 26, 28) and the housing (8) pockets or grooves (34) are formed for the adhesive of the adhesive connection.

10. Electric machine (1) comprising a housing (8) according to one of the preceding claims.

11. Method for producing an electrical machine (1).

- Providing an installation part (16, 18, 26, 28) according to one of claims 1 to 3 and a housing (8) with an inner contour (15),

- Attaching the built-in part (16, 18, 26, 28) to the housing (8) so that the inner contour (15) of the housing (8) and the built-in part (16, 18, 26, 28) form a section (13, 14 , 27, 29) of a cooling channel (11) of the electrical machine (1).