DE102021121032A1 - Jacket sleeve for a stator cooling jacket - Google Patents

Abstract

The invention relates to a jacket sleeve for a stator cooling jacket of an electric drive motor of a motor vehicle, having an outer sleeve jacket on which a stator-side boundary contour for the at least one cooling channel of an outer jacket of the stator core is formed, and an inner sleeve jacket with a core cooling area for contact with a stator core, wherein the sleeve inner shell has an axial overhang axially away from the core cooling area. The invention also relates to a stator cooling jacket with a jacket sleeve and an electric drive machine.

Description

The invention relates to a jacket sleeve for a stator cooling jacket for cooling a stator of an electrical machine in a housing using a coolant, a stator cooling jacket with such a jacket sleeve, and an electric drive machine for a motor vehicle.

Effective cooling of the rotor and stator in electric drive machines is the main requirement for high continuous torque and high continuous power, especially in current-excited synchronous machines (SSM). However, the invention can also be of interest for asynchronous machines, permanently excited synchronous machines and other electrical machines that also require a high cooling capacity.

A high continuous output is essential for dynamic driving behavior, for example when driving dynamically on country roads or when driving dynamically uphill.

In certain known electric drive machines for motor vehicles, the rotor of the electric drive machine is cooled with oil, in particular from the inside by hollow shaft cooling and on the end face by end face cooling, while the stator is cooled by water jacket cooling. Oil cooling for the stator core is also known per se.

However, the known cooling concepts do not show sufficient cooling capacity in the stator when stationary and at low speeds. This results in undesirably limited driving performance when driving uphill and disadvantages at the vehicle system level, since the heat output that can be generated is not sufficient to heat up the high-voltage battery during a cold start. For the latter reason, additional electric flow heaters are sometimes installed for cold starts, which lead to considerable additional costs, additional weight and space requirements.

For example, from the DE 10 2019 213 118 A1 an electric drive machine for a motor vehicle is known in which adequate cooling of the stator end windings appears difficult in the operating cases mentioned.

Against this background, it is an object of the invention to improve a stator cooling jacket.

Each of the independent and subordinate claims determines with its features an object that solves this problem. The dependent claims relate to advantageous developments of the invention.

In one aspect, a jacket sleeve for a stator cooling jacket, which may be in accordance with an embodiment of the invention or otherwise, is disclosed. The jacket sleeve has at least: (A) a sleeve outer jacket on which a stator-side boundary contour for the at least one cooling channel of the stator jacket is formed; and (B) a sleeve inner shell having a core cooling area for abutting a stator core.

The inner shell of the sleeve has, in particular on both sides, axially away from the core cooling area, an axial overhang in which, starting from the boundary contour, in particular on both sides, at least one, in particular several, outlet openings are formed as a continuous recess between the outer shell of the sleeve and the inner shell of the sleeve .

With the outlet openings, an effective cooling of the stator end windings can also be achieved on the outer radial side. In particular, effective cooling of the outer shell of the stator core can also be combined with effective cooling of the outside of the stator end windings. If an electrically non-conductive coolant, such as a suitable cooling oil, is used, both can be achieved with a coolant circuit. A winding overhang cooling area for cooling one or preferably both stator winding overhangs is thus formed in the axial overhang.

The use of a jacket sleeve as the radially inner delimitation of the coolant channels makes it possible to disassemble the stator or the electrical machine from the housing. In the case of known vehicle drive machines, in most concepts the stator is pressed into the housing, for example thermally shrunk. Then the stator cannot be dismantled with realistic effort. In the present solution, according to one embodiment, the stator can be pressed into the jacket sleeve, whereas the latter itself is only detachably attached to the housing, for example by means of a screw connection or a clamp connection. Then the stator - together with the jacket sleeve - can be removed from the housing and thus, for example, replaced in the event of a defect. This achieves a significantly better repairability of BEVs, in which the entire e-machine with housing no longer has to be replaced in the event of a stator defect - the economic total loss that is often associated with this can then be averted.

According to a further aspect, a stator cooling jacket is disclosed for cooling a stator of an electrical machine on an indirect The stator is accommodated in a housing by means of an in particular electrically non-conductive coolant, having at least one jacket sleeve according to one embodiment of the invention, in which the stator is accommodated radially on the inside and which supports the stator radially on the outside against the housing and with the housing forms the / the cooling channels of the stator cooling jacket. According to one embodiment, the coolant is a cooling oil.

According to a further aspect, an electric drive machine of a motor vehicle is disclosed, having a stator cooling jacket according to an embodiment of the invention and/or a jacket sleeve according to an embodiment of the invention.

The invention is based, among other things, on the consideration that forming the cross sections in the stator housing and/or in the stator laminated core and, in particular, deflecting and spraying out the coolant using additional sealing rings can be expensive and complex to manufacture. In addition, the direct pressing in of the outer casing of the stator core - in particular by means of a heat fit by means of shrinking - means that the stator cannot be dismantled economically and non-destructively in the event of failure, so that in the event of a stator defect, the entire drive machine including the housing must be replaced.

The invention is now based, inter alia, on the idea of forming the cross sections of the at least one stator cooling duct in a jacket sleeve which is provided radially between the stator arranged on the inside and the stator housing arranged on the outside. The flow guidance of the coolant, ie the geometry of the at least one cooling channel, can be configured very differently in different designs. In any case, the cross sections of the cooling channels are formed completely on the radial outside of the jacket sleeve, which can be designed in particular as a die-cast component.

The laminated core of the stator is pressed into this casing sleeve on the outer casing of the stator core and the casing sleeve is then pressed into the housing or is firmly connected in a detachable manner, for example screwed. One advantage of a detachable attachment is the maintainability of the stator, because the entire drive unit no longer has to be replaced if the stator becomes defective.

In contrast to a water-jacketed sleeve (when water or another electrically conductive liquid is used as the coolant) when using a non-electrically conductive coolant such as cooling oil, a so-called oil-jacketed sleeve does not have a perfect seal between the housing and the sleeve in direction of the working space of the electric drive machine is necessary because the non-conductive coolant cannot short-circuit the electric machine. So it is then not necessary to press the jacket sleeve into the housing; a detachable connection is sufficient.

According to one embodiment, the boundary contour of the jacket sleeve, in particular for delimiting the at least one cooling channel, is formed with one or more recesses that extend radially inwards from the sleeve outer jacket and are not continuous (through the entire radial wall thickness of the jacket sleeve), which have a cross section and completely or partially form a longitudinal extent of one or more cooling channels of the stator cooling jacket.

Various features of the stator cooling jacket are described here for different, advantageous developments of the invention. Where the shape and/or function of these features can result from the design of the jacket sleeve and in particular from its boundary contour, the features described are also to be understood as an advantageous further development of a jacket sleeve according to the invention.

According to one embodiment, the inner shell of the sleeve is designed to accommodate a stator of an electrical machine radially on the inside, and the outer shell of the sleeve is designed to be accommodated in a housing of the stator and/or the electrical machine.

According to one embodiment, the stator cooling jacket has at least: (a) at least one coolant inlet and at least one coolant outlet, which in each case can also be formed partially or completely on the jacket sleeve; and (b) one or more cooling channels extending between the coolant inlet and the coolant outlet for guiding coolant, which are arranged radially between the stator and the housing and in particular cover an entire outer jacket of the stator core for cooling, i.e. in particular essentially an entire axial extent and substantially an entire circumferential extent of the stator core outer shell. In the present case, the cooling channels in particular are partially or completely formed on the jacket sleeve.

According to one embodiment, the stator cooling jacket and/or the jacket sleeve extends axially beyond an axial extent of a stator core of the stator on one or both sides. There is a plurality in an axial overhang formed as a result on one side or on both sides of the stator core of outlet openings, in particular as the sole or additional coolant outlet.

In this way, effective cooling of the stator end windings can also be achieved on the outer radial side. In particular, effective cooling of the outer shell of the stator core can also be combined with effective cooling of the outside of the stator end windings. If an electrically non-conductive coolant, such as a suitable cooling oil, is used, both can be achieved with a coolant circuit.

According to one embodiment, the outlet openings are arranged in an axial extension area of a stator end winding. As a result, the stator end windings can be wetted with the coolant directly from radially outside, in particular without further heating up on an intermediate guide downstream of the stator jacket cooling.

According to one embodiment, the plurality of outlet openings are arranged in a circumferentially spaced distribution in an upper circumferential half of the jacket sleeve. This enables uniform cooling of the stator end windings over the entire circumference of the stator. Because of the influence of gravity and the coolant dripping down as a result, an arrangement of the outlet openings only in the upper half of the circumference is sufficient to cool the entire circumference, at least if coolant can escape at the entire upper half of the circumference. In particular, the outlet openings are spaced apart uniformly in the circumferential direction and/or distributed over essentially the entire upper half of the circumference.

According to one embodiment, the at least one cooling channel is formed in the overhang on the jacket sleeve in such a way that the outlet openings are supplied with coolant. According to one embodiment, the outlet openings form the coolant outlet into the housing interior. This means that no additional component is required for the coolant outlet. In a machine that runs wet anyway, an oil sump and/or a gravitational coolant collection is provided anyway, from which a coolant circuit with a heat exchanger for dissipating the absorbed heat can be operated, for example by means of a coolant pump.

According to one embodiment, the cooling channel is formed entirely or partially in the jacket sleeve, in particular cut out of the jacket sleeve; or one, several or all of the several cooling channels are formed in the jacket sleeve, in particular cut out of the jacket sleeve. In particular, a radially outer part or at least a radially outer cover of the cooling channel(s) is then formed on an inner casing of the housing.

According to one embodiment, the coolant inlet is arranged in a lower half of the circumference, in particular essentially at a lower circumferential position. In particular, with outlet openings arranged only in the upper half of the circumference, a short flow of coolant can thus be achieved while the entire circumference of the stator is covered at the same time.

Alternatively, according to one embodiment, the coolant inlet is arranged in an upper half of the circumference, in particular essentially in an upper circumferential position, for example if this appears to make more sense based on the intended operating case.

According to one embodiment, the coolant inlet is arranged axially in an edge region of the extent of the stator core. A simple coolant connection can thus be achieved.

According to one embodiment, the at least one cooling channel is designed in such a way that the coolant can be guided between the coolant inlet and the coolant outlet at least twice, in particular several times, in each case in an axial cooling channel section along a larger part or along the entire axial extent of the stator core or the stator. In particular, a deflection channel (section) is provided between each two axial cooling channel sections. According to one embodiment, axial cooling channel sections that are adjacent in the circumferential direction are connected to the coolant guide in such a way that flow can flow through them in opposite axial directions, in particular in opposite axial directions.

The flow through the stator cooling jacket is therefore not (exclusively) parallel in the same direction, but according to one embodiment in a meandering shape, i.e. in particular also in opposite directions, i.e. (with regard to the circumferential direction) alternately in one axial direction and in the other axial direction. In particular, a single cooling channel with several deflections can be flowed through in series and/or several partial channels can be flowed through in parallel along a section (in particular an entire axial section) of the cooling channel, which are combined again in particular downstream of the division.

According to different versions, the deflection channels for deflecting the coolant radially inwards can be formed in a sealing manner in the sealing elements or in the jacket sleeve; and sealing radially outwards, in particular in the housing.

Due to the counter-parallel, in particular meander-shaped, flow through the cooling ducts, in particular with several deflections of the coolant, the flow velocity in the individual cooling ducts is higher than in known stator cooling jackets, which are flowed through in the same direction in an axial direction only in an undirected manner or divided in parallel. A higher flow rate leads to a higher heat transfer coefficient between the coolant and the surface, resulting in a higher cooling capacity. Furthermore, an opposite axial flow leads to a good mixing of the coolant, ie the coolant does not laminarize in the cooling channels and there is therefore a good exchange of heat between the layer closest to the wall and the center of the channels.

According to one embodiment, the at least one cooling channel is designed in such a way that only one axial main flow direction of the coolant is provided in one or more cooling channels at each circumferential position.

In this way, effective cooling of the stator end windings can also be achieved on the outer radial side. In particular, effective cooling of the outer shell of the stator core can also be combined with effective cooling of the outside of the stator end windings. If an electrically non-conductive coolant, such as a suitable cooling oil, is used, both can be achieved with a coolant circuit.

A simple cooling channel arrangement can thus be implemented which does not require a splitting of the coolant flow; unlike in known stator cooling jackets, which have an undirected coolant flow between the coolant inlet and outlet, for example, or in which there is an axially central coolant inlet and coolant outlet on both sides, so that coolant flows in both axial directions at the same circumferential position or a coolant flow is provided in both axial directions. In both known cases, the flow velocity is reduced by the divided and/or unguided coolant flow, which reduces the heat dissipation. The present solution, with a single axial flow direction fixed at each circumferential position, ensures a higher flow rate and thus better heat dissipation.

The term an axial main flow direction means here in particular that, apart from any deflection areas provided, the coolant is only provided for a flow in one of the axial directions or with a directional component only in one of the axial directions. During operation, it may happen that coolant flows at a deflection point or, for example, with a low coolant flow with a directional component in the other axial direction, so that only the main flow direction of the coolant is in one axial direction, not necessarily the flow direction of 100% of the coolant provided at the circumferential position.

According to one embodiment, the main axial flow direction alternates in the circumferential direction, in particular with a deflection of the flow direction between two, in particular adjacent, circumferential positions. This enables uniform cooling of the outer shell of the stator core, in particular with regard to the axial extent and/or the circumference of the stator, even without a strong branching of the coolant flow.

According to one embodiment, a deflection channel is provided in a cooling channel from one axial direction to the other, which diverts downstream into at least two or three or more sub-channels, which are formed spaced apart from one another at adjacent circumferential positions. By providing a plurality of separate, in particular parallel, coolant flows, which then have a smaller cross section than a combined coolant flow, better heat dissipation from the stator core outer casing and/or into the coolant flow can be achieved.

According to one embodiment, the sub-channels are parallel to one another. According to one embodiment, no more than two or three or four sub-channels are arranged between two deflection channels.

According to one embodiment, the stator cooling jacket has two cooling ducts, each of which is set up to cool one of the lateral halves of the circumference. This way of dividing the coolant flow into two coolant streams can ensure that the peripheral region that has flowed last at the periphery of the outer casing of the stator core is not cooled to a significantly lesser extent because a lot of waste heat has already been absorbed. According to an alternative embodiment, the stator cooling jacket has only a single cooling duct in order to achieve a maximum throughflow rate of the cooling duct and thus high heat dissipation for a given absolute coolant flow.

According to one embodiment, the at least one cooling duct runs unbranched between the coolant inlet and the coolant outlet in order to achieve a maximum throughflow rate of the cooling duct and thus high heat dissipation for a given absolute coolant flow.

According to one embodiment, all axial cooling channel sections have the same coolant flow direction up. This allows a simple design of the stator cooling jacket to be achieved. In particular, any sealing elements that may be provided can then be of a simple design because they only seal against the escape of coolant, but do not have to deflect the coolant in a defined manner.

According to one embodiment, at least two sub-channels are arranged downstream of the coolant inlet, which cover different circumferential regions of the stator for cooling, in particular each with a plurality of deflections in deflection channels. This way of dividing the coolant flow into two coolant streams can ensure that the peripheral region that has flowed last at the periphery of the outer casing of the stator core is not cooled to a significantly lesser extent because a lot of waste heat has already been absorbed.

According to one embodiment, two or more circumferentially adjacent axial cooling duct sections have a coolant flow in the same axial direction, wherein in particular the axial cooling duct sections adjacent to the cooling duct group formed thereby provide a coolant flow in the other axial direction. By providing a plurality of separate, in particular parallel, coolant flows, which then have a smaller cross section than a combined coolant flow, better heat dissipation from the stator core outer casing and/or into the coolant flow can be achieved.

According to one embodiment, the cooling channel group has a common coolant inflow and a common coolant outflow in order to enable the stator cooling jacket to be easily connected to the coolant supply of the electric machine.

• 1 veranschaulicht eine Ausführung eines Statorkühlmantels, der nicht in einer Mantelhülse ausgebildet ist.
• 2 zeigt die Querschnitte der Kühlkanäle des Statorkühlmantels aus 1.
• 3 zeigt das Statorgehäuse aus 1, an dessen radialer Innenseite die radial äußeren Begrenzungen der Kühlkanäle des Statorkühlmantels ausgebildet sind.
• 4 veranschaulicht einen mäanderartig ausgebildeten Statorkühlmantel, der nicht in einer Mantelhülse ausgebildet ist.
• 5 zeigt die Querschnitte der Kühlkanäle des mäanderartig ausgebildeten Statorkühlmantels aus 4.
• 6 zeigt das Statorgehäuse aus 4, an dessen radialer Innenseite die radial äußeren Begrenzungen der Kühlkanäle des mäanderartig ausgebildeten Statorkühlmantels ausgebildet sind.
• 7 veranschaulicht einen mäanderartig im Statorblechpaket ausgebildeten Statorkühlmantel, der nicht in einer Mantelhülse ausgebildet ist.
• 8 zeigt die Querschnitte der Kühlkanäle des mäanderartig im Statorblechpaket ausgebildeten Statorkühlmantels aus 7.
• 9 zeigt den Stator aus 7, an dessen radialer Außenseite die radial inneren Begrenzungen der Kühlkanäle des mäanderartig im Statorblechpaket ausgebildeten Statorkühlmantels ausgebildet sind.
• 10 veranschaulicht einen mäanderartig in einer Mantelhülse ausgebildeten Statorkühlmantel gemäß einer beispielhaften Ausführung der Erfindung.
• 11 zeigt die Querschnitte der Kühlkanäle des mäanderartig in einer Mantelhülse ausgebildeten Statorkühlmantels aus 10.

Further advantages and possible applications of the invention result from the following description in connection with the figures:

• 1 12 illustrates an embodiment of a stator cooling jacket that is not formed in a jacket shell.
• 2 shows the cross sections of the cooling channels of the stator cooling jacket 1 .
• 3 shows the stator housing 1 , on the radial inside of which the radially outer boundaries of the cooling channels of the stator cooling jacket are formed.
• 4 illustrates a meandering stator cooling jacket that is not formed in a jacket sleeve.
• 5 shows the cross sections of the cooling channels of the meandering stator cooling jacket 4 .
• 6 shows the stator housing 4 , on the radial inside of which the radially outer limits of the cooling channels of the meandering stator cooling jacket are formed.
• 7 illustrates a stator cooling jacket which is designed in a meandering manner in the stator laminated core and is not designed in a jacket sleeve.
• 8th shows the cross sections of the cooling ducts of the stator cooling jacket, which is designed in a meandering manner in the stator laminated core 7 .
• 9 shows the stator 7 , on the radial outside of which the radially inner delimitations of the cooling channels of the stator cooling jacket, which is designed in a meandering manner in the stator laminated core, are formed.
• 10 FIG. 12 illustrates a stator cooling jacket formed in a meandering manner in a jacket sleeve according to an exemplary embodiment of the invention.
• 11 shows the cross sections of the cooling channels of the stator cooling jacket, which is designed in a meandering manner in a jacket sleeve 10 .

In the 10 and 11 an exemplary embodiment of the invention is shown. In the 1 until 9 three different, also unknown designs are shown, for which no protection per se is sought in the present case. Nevertheless, individual features of this embodiment can be combined with embodiments according to the invention.

All figures show - in individual cases different - sections of an electric drive machine 1 of a motor vehicle, having a rotor (not shown) and a stator 100.

Between the housing 300 radially on the outside and radially on the inside either the stator 100 or the jacket sleeve 200 is arranged for cooling the stator 100 stator cooling jacket 400.

The stator cooling jacket 400 has a coolant inlet 402 and a coolant outlet 404 . One or more cooling channels, which are arranged radially between the stator 100 and the housing 300 and cover an entire stator core outer jacket 102 of a stator core 104 of the stator 100 for cooling, extend between the coolant inlet 402 and the coolant outlet 404 . The cooling channels are designed differently in the various embodiments shown and are therefore each provided with different reference symbols in their description. In particular, each cooling channel geometry described in one of the embodiments shown can also be implemented in an exemplary embodiment of a jacket sleeve according to the invention, if necessary with manual adjustments to the individual application.

The stator cooling jacket 400 extends axially beyond an axial extension of the stator core 104 on both sides. A plurality of outlet openings 410 are arranged in each case in a projection 408.1 or 408.2 formed on both sides, so that the outlet openings 410 are arranged in an axial extension region of a respective stator end winding 106.1 or 106.2.

The outlet openings 410 are spaced apart in the circumferential direction u of the stator cooling jacket 400 in an upper half circumference 412 , the outlet openings 410 being distributed evenly over substantially the entire upper half circumference in the circumferential direction u.

In all of the embodiments shown, the totality of all outlet openings 412 forms the coolant outlet 404 into the interior of the housing, without further outlets being provided. In other embodiments that are not shown, at least one further outlet can also be provided, for example if a larger coolant flow is provided for cooling the stator core than is intended to flow out through the outlet openings 412 .

The discharged coolant pours into the interior of the housing and, following gravity, collects on the bottom of the housing, from where it is usually fed by a coolant pump to a heat exchanger for dissipating the stator heat and then fed back to the cooling circuit.

After the above description of features that are common to the different versions shown, the differences between the individual versions are explained below with reference to the figures.

1 FIG. 4 shows a stator cooling jacket 400 according to an embodiment not claimed per se, which is nevertheless shown here because it also shows features which can be advantageously combined with an embodiment according to the invention in certain applications.

In the execution of 1 the cross sections of cooling channels 414 of the stator cooling jacket 400 are formed in the housing 300, here as recesses already introduced during the housing casting from an aluminum alloy.

The housing 300 has a single wall and the cooling ducts 414 open on the inner casing of the housing are located on the inside. The flow geometry and thus the stator cooling jacket 400 are created by pressing in the stator 100 and two sealing elements 416 (one on each axial side of the stator core 104), designed here as a sealing ring made of aluminum or a suitable plastic.

In this embodiment, the cooling ducts 414 in the housing are integrated into the sand core for the stator seat as part of the gravity die casting process that is used anyway, and result in only minor additional expenditure. For example, a large number of cooling ducts 414 (particularly limited when the cooling ducts are formed in the housing by means of chill casting, here forty-four axially running cooling ducts 414 uniformly distributed in the circumferential direction u) are integrated into the housing 300, so that an axial flow through the housing 300 is made possible during operation.

Integrated on both axial sides of the stator core 104 as a circumferential cooling duct 418 is a collecting ring for supplying coolant to the outlet openings 410 and for draining into the housing 300 . The cross sections of the axial cooling channels 414 are closed in the region of the stator core 104 by pressing in the stator 100; the sealing of the collecting rings 418 is created by pressing in a sealing element 416 in each case.

In a variation of this exemplary embodiment that is not shown, the sealing element 416, which is pressed in before the stator is joined, can be integrated into the casting of the housing 300 instead. Irrespective of the variant used, the sealing elements 416 can have seals, e.g. made of plastic, on the contact surface with the stator 100 and/or with the housing 300. Alternatively, a liquid seal can be used as the seal.

In the case of a wet e-machine, in which there is cooling oil in the space of the e-machine, the seal of the sealing element can be omitted since a small leakage does not lead to any relevant disadvantages.

In the exemplary embodiment, the coolant feed into the stator cooling jacket takes place through the coolant inlet 402 in the circumferential direction u at the top and axially in the region of one of the overhangs 408.2 via the associated collecting ring 416.2. The cool In this case, medium flows through the axial cooling channels 414 to the other collecting ring 416.1. Alternatively, the coolant can be supplied through an additional circumferential channel in the axial center of the stator, with the direction of flow of the oil being axially outwards in the direction of both collecting rings. The features described in this section differed from the presently claimed invention.

In any case, the coolant return occurs by spraying the coolant onto both stator end windings 106 at the outlet openings 410 of the respective axial side. This spraying of the end windings from the outside and starting from the entire upper half of the circumference 412 leads to a very high cooling capacity, since all of the circumferential areas can be sprayed directly with relatively cool coolant.

2 FIG. 4 illustrates the stator cooling jacket 400 by showing all of the cross sections of the cooling channels 414 and 418 through which coolant flows. Outlet openings 410 of outlet 404 are present on both axial sides, even if these are only visible on the axial side of coolant inlet 402 in the illustration.

3 shows the stator housing 300 from 1 . On the radial inside of the stator housing 300 are the radially outer boundaries of the axially running cooling channels 414 of the stator cooling jacket from 1 and 2 educated. The two peripheral cooling channels 418.1 and 418.2 are shown here analogous to the representation in 1 recognizable.

4 illustrates a meandering stator cooling jacket 400 according to an embodiment that is not claimed per se, which is shown here because it also shows features that can be advantageously combined with an embodiment according to the invention in certain applications.

The cross sections of two meandering cooling channels 420.1 and 420.2 of the stator cooling jacket 400 are formed in the housing 300, here as recesses already introduced during the housing casting from an aluminum alloy. Each of the two meandering cooling channels 420.1 or 420.2 extends along a lateral half-circumference 422.1 (left/back in the illustration) or 422.2 (right/front in the illustration) to outlet openings 410, which serve as coolant outlet 404.

The housing 300 has a single wall and the cooling ducts 420 open on the inner casing of the housing are located on the inside. The flow geometry and thus the stator cooling jacket 400 are created by pressing in the stator 100 and two sealing elements 416 (one on each axial side of the stator core 104), designed here as a sealing ring made of aluminum or a suitable plastic.

Along its extension, each of the meandering cooling channels 420 initially has a distributor channel 424 downstream of a coolant inlet 402 arranged at the bottom of the housing 300 at the border of the two lateral circumferential halves 422 (in particular with regard to the coolant flow). The distributor channel distributes the coolant inflow to the two meandering cooling channels 420, with the coolant in each of the cooling channels 420 then being divided into two axial cooling channel sections 426, which are formed at a distance from one another at adjacent circumferential positions U1, U2 in the housing 300.

The axial cooling channel sections 426 run along the entire axial extension of the stator core and, after an axial passage of the stator core, open in a first axial direction A+ into a common deflection channel 428, which guides the coolant to adjacent circumferential positions U1, U2, at which several further (here again two ) axial cooling channel sections 426 are formed, which in operation return the coolant in the opposite axial direction A- to that axial side on which the coolant was admitted into the distribution channel. These axial cooling channel sections 426 in turn open into a common deflection channel 428, so that the coolant can again flow in the opposite (read again the first) axial direction A+ through further axial cooling channel sections 426 at further circumferential positions. This configuration is referred to herein as meandering or meandering.

The cross sections of the axial cooling channel sections 426 are sealed by the stator core outer shell 102, the cross sections of the common deflection channels 428 through the radial outside of the sealing rings 416, the same or different than those from the 1 until 3 can be trained. In any case, the outlet openings 410 are formed on the sealing rings and serve as a coolant outlet 404 starting from the deflection channels 426 .

The axial cooling channel sections 426 run in the area of the stator core 104, the common deflection channels 428 in the area of the axial overhang 408 and thus the stator end windings 106.

The associated part of the distributor channel 424, the associated deflection channels 428 and the associated axial cooling channel sections thus form the respective meandering cooling channel 420.

The stator cooling jacket 400 of 4 So will not - as in the present non-claimed embodiment according to the 1 until 3 - flows exclusively parallel in the same direction, but in a meandering form. In this case, all axial cooling channel sections 426 can be flown through in series or several of them can be divided in parallel, as here 4 described.

5 shows the cross sections of the meandering cooling channels 420.1 and 420.2, which together form the stator cooling jacket 400 of the embodiment 4 form. The coolant, here a cooling oil, enters one of the two cooling ducts in the middle on the underside, with the entire coolant flow dividing into two branches which meander on both sides of the stator and lead to the top of the stator. Each meander branch consists of two parallel cooling channels. This characteristic leads to a compromise between a high flow rate, and thus a high heat transfer coefficient, and a low pressure loss. The parallelization of several channels compared to a channel with a larger cross-section leads to an increase in surface area and thus in cooling capacity. More than two parallel channels can also be used here. The implementation described with a coolant inlet 402 at the bottom and a symmetrical oil flow to the top has the further advantage that the oil at the top analogous to the execution of the 1 until 3 spray onto the winding heads. Here, in contrast to the execution of the 1 until 3 the entire oil volume flow in the lower 70% of the channels can be used for cooling. In the possibly easier to manufacture and assemble version of 1 until 3 On the other hand, part of the oil on the side of the oil supply already squirts out onto the end winding.

6 shows the stator housing 4 , on the radial inside of which the radially outer limits of the meandering cooling ducts 420 of the meandering stator cooling jacket 400 are formed, with the sealing rings 416. The arrangement of the deflection ducts 428 in the axial overhang 408 and the arrangement of the axial cooling duct sections 426 in the region are particularly evident between the two axial projections 408, i.e. axially along the entire stator core 104 (which is not shown here).

7 illustrates a meandering stator cooling jacket 400 formed in the stator core 430, among other things, according to an embodiment not claimed per se, which is shown here because it also shows features that can be advantageously combined with an embodiment according to the invention in certain applications.

From the execution of 4 until 6 This embodiment differs in particular in that the cross sections of the cooling channels are not formed in the casting of the housing 300. Instead, the axial cooling channel sections 432 are removed from the stator laminated core 430 on the radial outside and are closed when assembled with the radial inside of the housing 300 . The supply or deflection of the coolant between the axial cooling channel sections 432 takes place through a distributor channel and deflection channels 434 (not shown due to the perspective), which are formed between the respective sealing element 436.1 or 436.2.

The sealing elements 436 are modified compared to the sealing elements 416 from the first two embodiments in that the cross sections of the distributor channel and the deflection channels 434 are introduced into the sealing elements 436 and are closed against the housing 300 when assembled.

The flow guidance is analogous to the stator cooling jacket in the embodiment in particular with regard to its meandering shape 4 until 6 .

The formation of the axial cooling channel sections 432 in the stator core 430 enables a significantly higher number (here eighty) of axial cooling channel sections 432 in the circumference of the stator core jacket (i.e. also a meandering branch), since the manufacturing tolerances of the stamped sheets of the stator core 430 are significantly higher than in chill casting . A higher number of channels can lead to a larger surface and thus to a higher effectiveness of the cooling concept. According to a modification of the embodiment, the cooling channel sections 432 in the laminated core 430 of the stator can be connected on the outer surface to form a closed surface in order to increase the robustness when joining the stator.

The sealing elements 436 can be made of aluminum or plastic. In the case of aluminium, the sealing elements can be produced as a cast or deep-drawn part. It is also conceivable that rubber or plastic is sprayed onto the aluminum to improve the sealing properties. In addition, a seal between the laminated core and the sealing element or between the housing and the sealing element via an O-ring is conceivable.

8th shows the cross sections of the meandering cooling channels 440.1 and 440.2, which together form the meandering stator cooling jacket 400 in the laminated stator core 430 of the embodiment 7 form. The cooling channels 440 share the manifold ca nal 438, and each have deflection channels 434 and axial cooling channel sections 432.

The coolant, here an electrically insulating cooling oil, enters both cooling channels 440 centrally on the underside via the coolant inlet 402 and the distribution channel 438; the entire coolant flow is divided into two branches, which meander on both sides of the stator—that is, alternately through an axial cooling channel section 432 and a deflection channel 434—lead to the upper side of the stator. Each meander branch consists of four parallel cooling channels. This characteristic leads to a compromise between a high flow rate, and thus a high heat transfer coefficient, and a low pressure loss. The parallelization of several channels compared to a channel with a larger cross-section leads to an increase in surface area and thus in cooling capacity. More than four parallel channels can also be used here. The implementation described with a coolant inlet 402 at the bottom and a symmetrical oil flow to the top has the further advantage that the oil at the top analogous to the versions of the 1 until 3 or the 4 until 6 spray onto the winding heads. Here, in contrast to the execution of the 1 until 3 the entire oil volume flow in the lower 70% of the channels can be used for cooling. In the possibly easier to manufacture and assemble version of 1 until 3 On the other hand, part of the oil on the side of the oil supply already squirts out onto the end winding.

9 10 shows the stator 100. FIG 7 and the associated sealing elements 436. On the stator core outer shell 102 of the stator core 104 of the stator 100, the radially inner boundaries of the axial cooling channel sections 432 are removed from the stator core 430, punched out here. Together with the distribution channel and the deflection channels 434, whose cross sections are formed in the sealing elements 436, and the inner surface of the in 9 In the stator housing 300 (not shown), the axial cooling channel sections 432 form the meandering cooling channels 440 .

The arrangement of the deflection channels 434 in the axial projection 408 and the arrangement of the axial cooling channel sections 432 in the area between the two axial projections 408, i.e. axially along the entire stator core 104, can be seen particularly clearly.

10 12 illustrates a stator cooling jacket 400 formed in a meandering fashion within a jacket sleeve 200 according to an exemplary embodiment of the invention.

The jacket sleeve 200 has an outer sleeve jacket 462 on which a stator-side delimiting contour 470 of the cooling channels of the stator cooling jacket 400 is introduced, so that recesses in the outer sleeve jacket 462 form the cross sections of the cooling channels. With regard to the coolant flow provided, the cooling channels are, for example, analogous to the exemplary embodiment according to FIGS 4 until 6 or according to the 7 until 9 formed, so here with two semi-circumferential, meandering cooling ducts 460.1 and 460.2, each of which has a plurality of axial cooling duct sections 452 and a plurality of deflection ducts 454, and is supplied with coolant from the coolant inlet 402, optionally by means of a common distribution duct 458.

11 FIG. 12 shows the cross sections of the cooling channels of the stator cooling jacket formed in the jacket sleeve 200. FIG 10 . The coolant, here an electrically insulating cooling oil, enters both cooling channels 460 centrally on the underside via the coolant inlet 402 and the distribution channel 458; the entire coolant flow is divided into two branches, which meander on both sides of the stator—that is, alternately through an axial cooling channel section 452 and a deflection channel 454—lead to the upper side of the stator. Each meander branch consists of four parallel cooling channels. This characteristic leads to a compromise between a high flow rate, and thus a high heat transfer coefficient, and a low pressure loss. The parallelization of several channels compared to a channel with a larger cross-section leads to an increase in surface area and thus in cooling capacity. More than four parallel channels can also be used here. The implementation described with a coolant inlet 402 at the bottom and a symmetrical oil flow to the top has the further advantage that the oil at the top analogous to the versions of the 1 until 3 or the 4 until 6 or the 7 until 9 spray onto the winding heads. Here, in contrast to the execution of the 1 until 3 the entire oil volume flow in the lower 70% of the channels can be used for cooling. In the possibly easier to manufacture and assemble version of 1 until 3 On the other hand, part of the oil on the side of the oil supply already squirts out onto the end winding.

The jacket sleeve 200 also has a sleeve inner jacket 464 with a core cooling area 466 for contact with the stator core 104 . The inner shell of the sleeve 464 has on both sides, axially away from the core cooling area 466, an axial projection 408, in which, starting from the deflection channels 454, which are arranged in the projection 408 and in the upper half of the circumference 412, the outlet opening 410 openings as a continuous recess (extending between the sleeve outer shell and the sleeve inner shell, ie through the wall thickness of the jacket sleeve 200 through) is formed.

With the outlet openings 410, effective cooling of the outer radial side of the stator end windings 106 can also be achieved in this configuration with a jacket sleeve 200. In addition, effective cooling of the stator core outer casing 102 can also be combined with effective cooling of the outside of the stator end windings 106.

If - as here - an electrically non-conductive cooling oil is used as the coolant, both can be achieved with a single coolant circuit. A winding overhang cooling area 468 for cooling the stator winding overhangs 106 is thus formed in the axial overhang 408 in particular.

The use of a jacket sleeve 200 as a radially inner delimitation of the coolant channels makes it possible to dismantle the stator 100 or the electric drive machine 1 from the housing 300 . In the case of known vehicle drive machines 1, in most concepts the stator is pressed into the housing, for example thermally shrunk. Then the stator cannot be dismantled with an economically and/or organizationally justifiable effort. In the present solution, however, the stator 100 is pressed into the jacket sleeve 200, whereas the jacket sleeve itself is only detachably fastened to the housing 300 by means of a screw connection. Therefore, the stator 100--together with the pressed jacket sleeve 200--can be removed from the housing 300 and thus replaced, for example, in the event of a defect. This achieves a significantly better repairability of BEVs, in which the entire electric machine with housing no longer has to be replaced in the event of a stator defect - the often associated, economic total loss of the vehicle can then be averted.

The jacket sleeve has a boundary contour 470 with a plurality of non-continuous recesses that extend radially inward from the sleeve outer jacket 462 and form the cross sections and the longitudinal extensions of the cooling channels 460 radially inward. The cross sections are closed by the assembly of the housing 300, the radial inner surface of which then rests against the cross sections. This connection does not necessarily have to be completely coolant-tight if a non-conductive coolant is used. A relatively small leakage coolant flow is acceptable.

The sleeve inner shell 464 is set up for radially inner accommodation of the stator 100, in particular the stator core 104 of the electric drive machine 1; the outer jacket of the sleeve 462 to be accommodated in the stator housing 300.

Of course, in other exemplary embodiments of the invention that are not shown separately, the jacket sleeve can have features that are found on a stator cooling jacket according to one of the versions 1 or 4 or 7 are realized. In particular, each cooling channel geometry shown there can also be implemented in a jacket sleeve according to the invention, if necessary with purely manual adjustments to the design of the cooling channel cross sections in the jacket sleeve instead of in the housing and/or the stator core and/or the sealing elements.

Reference List

1

electric drive machine

100

stator

102

stator core outer shell

104

stator core

106

stator end winding

200

jacket sleeve

300

Housing

400

stator cooling jacket

402

coolant inlet

404

coolant outlet

408

axial overhang

410

exhaust ports

412

upper half of the circumference of the stator cooling jacket

414

Housing recesses as axial cooling channels

416

Sealing element, here sealing ring

418

Circumferential cooling channel, here collection ring

420

meandering cooling channel

422

lateral half of the circumference of the stator cooling jacket

424

distribution channel

426

axial cooling channel sections formed in the stator housing

428

deflection channel

430

stator core

432

axial cooling channel sections, formed in the stator core

434

Deflection channels formed in the sealing element

436

Sealing element with recesses for the cross sections of the deflection channels

438

distribution channel

440

meandering cooling channel

452

axial cooling channel sections formed in the jacket sleeve

454

Deflection channels formed in the jacket sleeve

458

Distribution channel formed in the jacket sleeve

460

meandering cooling channel

462

sleeve outer jacket

464

sleeve inner jacket

466

core cooling area

468

winding head cooling area

470

Boundary contour of the jacket sleeve

a

axial direction

A+

first axial direction, in particular axial main flow direction of the coolant

A-

second axial direction, in particular opposite axial main flow direction

and

circumferential direction

u

perimeter position

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• DE 102019213118 A1 [0006]

Claims (15)

Jacket sleeve (200) for a stator cooling jacket (400) of an electric drive machine (1) of a motor vehicle, having - a sleeve outer jacket (462) on which a stator-side boundary contour (470) for the at least one cooling channel (460) of a stator core outer jacket (102) is formed, and - a sleeve inner jacket (464) with a core cooling area (466) for contact with a stator core (104), characterized in that the sleeve inner jacket has an axial overhang (408) axially away from the core cooling area, in which starting from the boundary contour, a plurality of outlet openings (410) are formed between the outer shell of the sleeve and the inner shell of the sleeve. Sheath sleeve according to claim 1 , characterized in that the boundary contour is formed with one or more recesses extending radially inwards from the outer shell of the sleeve, which completely or partially form a cross section and a longitudinal extension of one or more cooling channels of the stator cooling shell. Casing sleeve according to one of the preceding claims, characterized in that the outlet openings are arranged in an intended axial extension area of a stator end winding (106). Jacket sleeve according to one of the preceding claims, characterized in that the plurality of outlet openings are distributed in the circumferential direction (u) at a distance in an upper circumferential half (412). Sheath sleeve according to claim 4 , characterized in that the outlet openings are spaced apart in the circumferential direction (u) evenly and/or distributed over essentially the entire upper half of the circumference. Jacket sleeve according to one of the preceding claims, characterized in that the outlet openings (410) form the coolant outlet (404) into the housing interior. Jacket sleeve according to one of the preceding claims, characterized in that the at least one cooling channel (460) is designed such that only one axial main flow direction (A+, A-) of the coolant is provided at each circumferential position (U). Jacket sleeve according to one of the preceding claims, characterized in that the intended axial main flow direction (A+, A-) alternates in the circumferential direction. Jacket sleeve according to one of the preceding claims, characterized in that a deflection channel (454) from one (A+) to the other (A-) axial direction is provided in a cooling channel, which diverts downstream into at least two axial cooling channel sections (452), which are formed spaced from each other at adjacent circumferential positions (U). Sheath sleeve according to claim 9 , characterized in that the axial cooling channel sections are parallel to each other. Jacket sleeve according to one of the preceding claims, characterized by two cooling channels (460.1, 460.2), which are each set up for cooling one of the lateral peripheral halves (422.1, 422.2). Jacket sleeve according to one of the preceding claims, characterized in that two or more circumferentially adjacent axial cooling channel sections have a coolant flow in the same axial direction. Stator cooling jacket (400) for cooling a stator (100) of an electrical machine (1) at an indirect receptacle of the stator in a housing (300) by means of a coolant, having at least one jacket sleeve (200) according to one of the preceding claims, in which the stator is accommodated radially on the inside, and which supports the stator radially on the outside against the housing and which, together with the housing, forms the cooling duct(s) (460) of the stator cooling jacket. Stator cooling jacket according Claim 13 , characterized in that the stator cooling jacket extends axially beyond an axial extension of a stator core (104) of the stator and a plurality of outlet openings (410) are arranged in a projection (408) formed thereby. Electrical drive machine (1) of a motor vehicle, having a casing sleeve according to (200) one of Claims 1 until 12 and / or a stator cooling jacket (400) according to any one of Claims 13 or 14 .

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