DE102016201970A1 - Electric machine - Google Patents

Abstract

An electric machine comprises a first and a second element, which are mounted rotatably about a common axis of rotation against each other. On a radial side of the first element, a magnetic element is mounted and in a region between the first element and the magnetic element is a viscous mass. In the first element, a channel for supplying the viscous mass is provided, wherein a first end of the channel is in the region of the magnetic element.

Description

State of the art

The invention relates to an electrical machine. In particular, the invention relates to an electric generator or an electric motor for converting a rotational movement into electrical energy or vice versa.

An exemplary electric DC motor with electronic commutation (BLDC: brushless direct current) comprises a radially outer stator and a radially inner rotor, which are rotatably mounted about a common axis of rotation against each other. One or more windings are mounted on the stator and one or more permanent magnets on the rotor, wherein currents through the windings can be switched on and off in such a way that magnetic fields are produced on the windings, which attract or repel the permanent magnets, so that between the stator and the rotor a torque acts and electrical energy can be converted into a rotational movement. To attach the permanent magnets on the rotor, they can be glued flat on a radial outer side of the rotor. Applying an adhesive in this area can be problematic during manufacture of the DC motor. For example, if the viscosity of the adhesive is low, the adhesive may flow out of the area between the stator and the permanent magnet before it sets. However, if the viscosity is high, the adhesive may be applied between the two elements to be bonded only before they are joined together. However, the adhesive can then be pushed away by joining so that it can not develop its full adhesion. Deferred adhesive can lead to adverse effects in other areas of the electric motor.

The invention has for its object to provide an improved electrical machine that supports the use of a viscous mass during assembly of the machine. The invention achieves this object by means of the subject matter of the independent claim. Subclaims give preferred embodiments again.

An electric machine comprises a first and a second element, which are mounted rotatably about a common axis of rotation against each other. On a radial side of the first element, a magnetic element is mounted. In a region between the magnetic element and the first element is a viscous mass. In this case, a channel for supplying the viscous mass is provided in the first element, wherein a first end of the channel is in the region of the magnetic element.

This makes it possible to spend the viscous mass during assembly of the electrical machine through the channel to its destination. The mass can be compressed at a time in the channel to which the magnetic element is already arranged or aligned on the first element. A gap between the magnetic element and the first element, in which the mass is to be pressed, can therefore be adjusted in a simplified manner. The production of the electric machine can be simplified.

By attaching the mass in the region between the magnetic element and the first element after their relative arrangement or orientation can be avoided that the mass wegrinnt or pushed away during assembly of the magnetic element on the first element. The amount of mass applied between the magnetic element and the first element can thereby be optimized. A disturbance of the electrical machine by weggeronnene or pushed away mass can be avoided. For example, it can be avoided that displaced or coagulated mass affects a static or dynamic center of gravity of the first or second element. A noise or a lifetime of the electrical machine can be positively influenced. A manufacturing quality and a constant production of the electrical machine, especially in mass production, can be improved. A loss of mass, which can not be supplied to its intended function, can be reduced, which can result in cost advantages. The mass can be precisely dosed and applied better. Through the channel, a saving of material in the first element may be due, whereby manufacturing costs of the first element may be lowered. Preferably, the channel is in an electromagnetically or strength-critical uncritical region of the first element, so ideally no further adjustments are required. By saving material, a weight advantage can be achieved on the first element. An additional effort to attach the channel in the first element can be done easily and inexpensively.

The electrical machine can be produced in a modular system, wherein individual elements of the electrical machine can be adopted depending on requirements from a ready-made selection. Through the channel, the attachment of the viscous mass can be used as an additional degree of freedom, so that in different embodiments of the electric machine from the kit different amounts and / or types of masses are used. The flexibility of the modular system can be increased.

Preferably, the channel comprises a plurality of first ends, each located in the region of the magnetic element. Thereby, a larger surface area between the first element and the magnetic element can be surely supplied with the ground.

A second end of the channel is preferably located at an axial portion of the first member. The supply of the mass can be effected from the axial direction. The fixing of the magnetic element to the first element during the feeding can thereby be simplified.

It is further preferred that the channel is widened funnel-shaped in the region of the second end. In this case, the channel tapers along its extension from the second to the first at least on a first section. In other words, the cross-section of the channel is increased in an orifice area at the second end, so that a viscous-mass dispenser can more easily dock to the channel.

In a further embodiment, a reverse widening of the channel is possible, so that the cross section in the region of the second end is smaller than in a region between the first and the second end. Increasing the cross-section of the channel may be generally useful to replace a larger portion of material of the first element with the mass. As a result, for example, a weight advantage can be achieved on the first element.

In a further embodiment, a cross-sectional profile of the channel is adapted to the viscosity of the mass. In particular, the cross-section can be made large at high viscosity and small at low viscosity. In yet another embodiment, the cross-section of the channel varies in size along the length of the channel.

In a particularly preferred embodiment, the composition comprises a viscous coatable and curable adhesive, in particular for attaching the magnetic element to the first element. The adhesive may be liquid or pasty by being pressed into or through the channel and then curing. The curing may be initiated or accelerated by the addition of a hardener, by the influence of oxygen or light, by the influence of heat or in another known manner.

In another embodiment, the mass comprises a thermal paste. In yet another embodiment, the mass comprises a damping material, which is preferably adapted to damp a mechanical vibration. Structure-borne sound or airborne noise emissions of the electrical machine can be reduced as a result.

In one embodiment, the first element comprises a number of axially stacked sheets each including a recess, the recess forming a portion of the channel. Each sheet can be provided in a simple manner, for example by means of punching with a matching recess. The recesses can be chosen so that virtually any desired shape of the channel can be achieved. It is particularly preferred that the channel in the region of the second end comprises an axial portion and in the region of the first end of a radial portion, wherein the sections merge into one another. The sheets may be axially secured together in any manner, such as by gluing or welding. In one embodiment, the sheets are produced by means of stamping in a progressive die and directly connected to each other during punching by means of punching packet points or adhesive. Subsequent welding of the sheets or providing the sheets with a baked enamel, which is thermally cured after joining the sheets, is also possible.

In one variant, the magnetic element comprises a permanent magnet. In another variant, it comprises a magnetic guide element such as a return ring or other magnetic guide element. In this case, the housing is preferably made of a non-magnetic material, for example plastic or aluminum, but it can also be a magnetic material such as steel are used. In a further embodiment, the housing may also be designed as a magnetic guide element. In all cases, the magnetic element may be mounted radially inward or radially outward of the first element.

One of the elements may comprise a stator and the other a rotor. The magnetic element may be facing or facing away from the second element in the radial direction. The electric machine may concern an electric motor or an electric generator. The electrical machine can be commutated mechanically or electronically and operated by means of direct current or alternating current. Preferably, the electric machine is adapted to be used on board a motor vehicle, for example, for driving a pump, in particular a liquid pump for conveying a fluid for cooling an internal combustion engine. The magnetic element can be arranged on any radial surface of the first element, wherein the first element does not necessarily have to be designed radially symmetrical. In a plan view along the axis of rotation, the first element, for example, have a radial single tooth, star-shaped or otherwise constructed. The magnetic element can also be sunk in the radial direction on the first element. This arrangement is also referred to as "burying".

Brief description of the figures

The invention will now be described in more detail with reference to the attached figures, in which:

1 an electric machine;

2 a detail of the machine from 1 ;

3 Longitudinal sections through a stator and a rotor of the machine of 1 in one embodiment;

4 Stator sheets of the machine from 1 in one embodiment;

5 Rotor laminations of the machine of 1 in one embodiment; and

6 a further embodiment of the rotor of the machine of 1 represents.

1 shows an exemplary electric machine 100 , not all elements of the electric machine 100 are shown. Around a rotation axis 105 are a stator 110 and a rotor 115 rotatably mounted. In the illustrated embodiment, the electric machine 100 designed as an inner rotor, the stator 110 on a radial outside of the rotor 115 However, a reverse arrangement is also possible. More generally, the electric machine includes 100 a first and a second element around the axis of rotation 105 are rotatably supported against each other, wherein one of the elements of the stator 110 and the other the rotor 115 includes. By way of example, the electric machine is 100 from 1 As an electric motor with electronic commutation, but it is also possible a different commutation and regardless of the electric machine 100 be designed or used as a generator.

In the illustrated embodiment, on a radial outside of the rotor 115 one or more permanent magnets 120 mounted, preferably on a circumference about the axis of rotation 105 distributed as evenly as possible. Further, in the illustrated embodiment, on a radial outside of the stator 110 a motor housing 125 attached, which can also serve as a guide for a magnetic flux. In another embodiment, alternatively or additionally, a magnetic return ring may be provided for this purpose. The return ring can in the radial direction of an annular gap between the rotor 115 and the stator 110 turned away and the permanent magnet 120 radially facing the annular gap. In other embodiments, other arrangements may be chosen. In particular, the housing may be formed without function as a magnetic guide element. In this case, the housing may alternatively be made of a magnetizable material such as steel or of a material without magnetic properties such as plastic or aluminum.

In an area between the motor housing 125 and the stator 110 is a crowd 130 brought in. The crowd 130 is preferably applied viscous, so liquid or pasty during mounting in the illustrated area. After attaching the mass 130 a change in their viscosity can wait or be brought about. In particular, the mass 130 harden or become completely frozen. The crowd 130 may include, for example, an adhesive, a thermal grease or a damping mass.

It is proposed a channel 135 in the stator 110 to provide a first end in the area between the motor housing 125 and a radial surface of the stator 110 and a second end preferably on an axial surface of the stator 110 having. Through the channel 135 can the crowd 130 be led to their destination. In this sense, the channel serves 135 in the broadest sense as a lost form for the attachment of the mass 130 ,

Similarly, in the in 1 illustrated embodiment, a channel 135 in the rotor 115 provided for a spending of mass 130 in an area between a radial surface of the rotor 115 and the permanent magnet 120 to enable. The channels 135 in the stator 110 and in the rotor 115 can be provided independently of each other. Preferably, several channels 135 on a circumference around the axis of rotation 105 in the stator 110 or the rotor 115 arranged distributed.

2 shows a detail of the machine 100 from 1 , For better understanding, the permanent magnet 120 and the motor housing 125 shown transparently. In one embodiment, the cross section of a channel 135 enlarged in the area of its first end, so that the channel 135 in a laterally enlarged area between the permanent magnet 120 and the rotor 115 or the motor housing 125 and the stator 110 empties. In another embodiment, the cross section of the channel changes 135 not in the area of its first end.

Dimensions 130 passing through the canal 135 can be pressed, in a gap between the permanent magnet 120 and the rotor 115 or the motor housing 125 and the stator 110 spread and in particular after setting, crosslinking or curing hold the respective elements together by means of adhesion.

3 shows longitudinal sections through the stator 110 and the rotor 115 the electric machine 100 from 1 , The stator 110 is in 3A represented and the rotor 115 in 3B , Good to see is the course of the channel 135 for the mass 130 , In an exemplary way are the channels 135 in the stator 110 and in the rotor 115 formed in the same way, with different versions can be selected. The channel 135 each has a plurality of first ends in the region of the radial surface of the stator 110 or the rotor 115 on. Preferably, on each channel 135 however, only a second end is provided, preferably at an axial surface of the stator 110 or the rotor 115 lies. The channel 135 may include an axial portion associated with the second end and a radial portion for each of the first ends. In another embodiment, the channel 135 but also be shaped differently, for example, rounded, oblique or curvy.

In 3 It can also be seen that the stator 110 preferably a number of stator laminations 305 includes, along the axis of rotation 105 stacked together and preferably interconnected to form a lamination stack for the stator. In a corresponding manner, the rotor 115 a number of rotor laminations 310 include, which are also stacked in the axial direction and preferably attached to each other to form a disk set for the rotor. The connection is preferably made to Paketierpunkten provided for this purpose 315 , which preferably a positive engagement of axially adjacent sheets 305 . 310 allow or where a cohesive connection can be made.

4 shows stator laminations 305 the machine 100 from 1 in a preferred embodiment. 4A shows a stator plate 305 that in the stator 110 in the presentation of 3A is used above 4B a stator plate 305 that in the embodiment of 3A below, in the area of the first end of the canal 135 is used, and 4C a stator plate 305 that in the embodiment of 3A is used below. The upper stator plate 305 from 4A has a recess 405 on, in a plane of rotation about the axis of rotation 105 is closed on all sides. This results in an axial section of the channel 135 whose length is the thickness of the stator lamination 305 equivalent. Become several upper stator laminations 305 superimposed, the length of the axial portion of the channel increases 135 , The middle stator plate 305 from 4B has a recess 405 which is open in a radially outer direction. This will create a radial section of the channel 135 realized. The lower stator plate 305 from 4C finally has no recess 405 on, making it to complete the channel 135 can be used in the axial direction. A practically arbitrary form of the channel 135 can be achieved by the stator laminations 305 of the stator 110 each with matching recesses 405 be provided and then stacked axially.

5 shows rotor laminations 310 of the rotor 115 according to the embodiment of 3B , 5A shows an upper rotor plate 310 . 5B a middle rotor sheet 310 and 5C a lower rotor plate 310 , each referring to the representation of 3B , In the same way as above with respect to 4 has been described, the channel can 135 in the rotor 115 be formed in virtually any way by matching recesses 405 in the stator laminations 305 introduced and the stator laminations 305 then axially stacked and connected together.

6 shows a further embodiment of the rotor 115 the machine 100 from 1 , Instead of the multiple permanent magnets 120 the in 1 illustrated embodiment is here a single ring magnet 605 on the radial outside of the rotor 115 appropriate. 6A shows an oblique view and 6B a corresponding view with transparent ring magnet shown 605 , The channels 135 for the mass 130 are exemplary as in the example in 2 However, other arrangements are also possible.

Generally, the number of channels is 135 in the stator 110 or in the rotor 115 as well as the shape of the canal 135 along its extension between its first, radial and its second, preferably axial end, preferably to a specific embodiment of the electrical machine 100 customizable.

Claims (10)

Electric machine ( 100 ), full: A first and a second element ( 110 . 115 ) around a common axis of rotation ( 105 ) are rotatably mounted against each other; One on a radial side of the first element ( 110 . 115 ) attached magnetic element ( 120 . 125 ); A viscous mass ( 130 ) in an area between the first element ( 110 . 115 ) and the magnetic element ( 120 . 125 ), characterized in that - in the first element ( 110 . 115 ) a channel ( 135 ) for supplying the viscous mass ( 130 ), wherein a first end of the channel ( 135 ) in the region of the magnetic element ( 120 . 125 ) lies. Machine ( 100 ) according to claim 1, wherein the channel ( 135 ) comprises a plurality of first ends, each in the region of the magnetic element ( 120 . 125 ) lie. Machine ( 100 ) according to claim 1 or 2, wherein a second end of the channel ( 135 ) at an axial portion of the first element ( 110 . 115 ) lies. Machine ( 100 ) according to claim 3, wherein the channel ( 135 ) is widened funnel-shaped in the region of the second end. Machine ( 100 ) according to one of the preceding claims, wherein a cross-sectional profile of the channel ( 135 ) to the viscosity of the mass ( 130 ) is adjusted. Machine ( 100 ) according to any one of the preceding claims, wherein the mass ( 130 ) a viscous coatable and curable adhesive for mounting the magnetic element ( 120 . 125 ) on the first element ( 110 . 115 ). Machine ( 100 ) according to any one of the preceding claims, wherein the mass ( 130 ) comprises a thermal grease or a damping material. Machine ( 100 ) according to one of the preceding claims, wherein the first element ( 110 . 115 ) a number of sheets stacked in the axial direction ( 305 . 310 ), each having a recess ( 405 ) comprising a portion of the channel ( 135 ). Machine ( 100 ) according to one of the preceding claims, wherein the magnetic element is a permanent magnet ( 120 ) or a magnetic guide element ( 125 ). Machine ( 100 ) according to one of the preceding claims, wherein one of the elements comprises a stator ( 110 ) and the other a rotor ( 115 ).

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