EP1405386A1 - Device for fixing an electromotor - Google Patents

Abstract

The invention relates to a device (10) for fixing an electromotor (18), in particular a fan motor. Said device comprises an essentially pot-shaped receiving housing (12), acting as a motor housing (32) with a receiving opening (14), into which the electromotor (18) at least partially projects and a retaining flange (34) mounted on the receiving housing (12) for fixing the motor housing (32) to a support element (36), for example a motor vehicle heating and/or air conditioning system, in addition to elements for radially and axially fixing the electromotor (18) in the motor housing (32). According to the invention, the receiving housing (12) has at least one elastic retaining element (50, 52, 90) for axial fixation. Said element is at least partially coated with an elastic material (66) on the side that faces the motor (18), is connected to the receiving housing (12) by its first axial end (54) and lies directly against the motor (18) in the vicinity of its second axial end (58).

Description

Device for fastening an electric motor

The invention relates to a device for fastening an electric motor, in particular a blower motor according to the preamble of the independent claim.

Blower motors for heating and air conditioning systems, which are used, for example, in motor vehicles, are generally decoupled from the vehicle in terms of vibration technology in order to reduce the transmission of structure-borne noise from the motor or the blower unit to the body and thus to the interior of the vehicle.

The main source of the undesirable vibrations of DC motors, for example, are motor unbalance and commutation within the motor. Commutation occurs when the copper windings of the armature carry current while the motor is operating. During each rotation of the armature shaft, current is conducted once in each direction through the existing windings of the motor. The current flow in the windings generates a reaction under the influence of a permanent magnetic field, which is passed on as a torque pulse.

Common fastening methods for such motors in the fan housings consist in first fastening the motor in an adapter part, for example by inserting it, which in turn is then fastened in a motor holder. There is typically a flange on the motor mount itself for the secure connection of the

Engine with the air conditioning system, for example, via a support part formed on the body.

To attach the actual motor in the adapter part or a motor housing, the use of snap hooks the screwing of the components and also clamping the motor between two housing halves known. It is also known to press electric motors directly into a motor holder with their pole ring.

Elastic damping elements can be inserted between the adapter part receiving the motor and the actual motor mount, which are intended to ensure decoupling of the motor mount from the motor vibrations.

Normally, rubber in the form of appropriately shaped rubber elements is inserted between the engine and the motor housing, in the flange or between the flange and a support element of the air conditioning system

To dampen vibrations of the air conditioning system or the body and to suppress disturbing noises for the driver or his passengers in the interior of the vehicle.

In practice, there are a number of ways to use the rubber or decoupling elements made of rubber between the housing flange and the air conditioning system or between the motor and motor housing in order to dampen the vibration impulses.

For example, DE 43 34 124 AI discloses a device for receiving an electric motor, which achieves a particularly low-vibration and thus noise-damping effect by virtue of the fact that between the inner walls of this receiving device and the ones facing it

At least one elastic damping element is arranged on the outer walls of the motor housing and is supported on the mutually facing walls of the receiving device and the motor housing. These elastic damping elements, which in a preferred embodiment of the device of DE 43 34 124 AI are correspondingly shaped rubber elements, mean increased assembly and material expenditure, which unnecessarily increases the cost of such a device.

DE 36 18 177 AI describes a holder for an electric motor, in which the motor is inserted into a motor holder and is secured against axial slipping by inwardly projecting resilient lugs.

DE 196 52 328 C2 discloses a noise-insulated holding device for an electric motor, in which the electric motor is inserted into a first plug-in receptacle, which serves as an adapter part, and is axially secured by latching hooks. This plug-in receptacle has radially pivotable tongues in the manner of spiral springs distributed over its outer circumference. On these tongues radially outwardly projecting webs are molded onto the correspondingly shaped, sound-absorbing intermediate parts, such as rubber caps, for example, which can be plugged into the clamping connection.

The adapter part is inserted into a larger motor mounting part when mounting the bracket of DE 196 52 328 C2. If the electric motor with its housing is now inserted into the adapter part, the tongue-like spiral springs are pressed outwards, so that they engage in corresponding fixing openings of the motor mounting part, mediated via the noise-insulating intermediate parts.

The method of the motor mount, which is disclosed by the teaching of DE 196 52 328 C2, is quite complex and very component-intensive, which leads to increased assembly and thus also cost and time expenditure. Advantages of the invention

The device according to the invention for fastening an electric motor with the features of the independent claim has the advantage that a simple assembly of the motor is achieved by means of fastening hooks without an adapter with simultaneous decoupling by rubber damping elements.

This leads to a motor - motor housing combination that ensures a secure and additionally vibration-damped mounting of the electric motor with the least amount of parts and assembly work.

Advantageously, a plurality of spring-elastic holding elements of a receiving housing, which serves as a motor housing, act directly on the electric motor, so that there is no need to use adapter housings or intermediate housings. The resilient

Holding elements of the device according to the invention are advantageously provided at least in places on the side facing the engine with an elastic material, so that there is additional vibration and noise damping due to the elastic properties of this material.

Advantageous embodiments of the device according to the invention result from the features listed in the subclaims.

In an advantageous embodiment of the device according to the invention, the elastic material with which the spring-elastic holding elements are provided on their side facing the motor is a thermoplastic Elastomer. This can be applied in a simple and therefore advantageous manner directly to the resilient holding element, for example by a two-component spraying process.

A device according to the invention which is particularly light in terms of installation weight and easy to produce is obtained if both the motor housing, that is to say the receiving housing for the motor, and the spring-elastic holding elements are made from a plastic, for example from a polypropylene plastic.

This embodiment enables a significant weight reduction of the device according to the invention for holding the electric motor. In particular, the housing parts can be produced in an injection molding process, so that it is also possible in a simple manner to form additional components and carrier elements for engine components on the housing.

The resilient holding elements for the motor can be formed in one piece, preferably in one piece, in a tongue-like manner directly on the pot-shaped receiving housing. In this case, the holding element can pass directly into the wall of the receiving housing at its lower end and remains movable with its second axial end relative to the housing wall, so that a corresponding bending stress results on this tongue-like spring element, via which the motor is fixed in the receiving device can.

A secure fastening of the motor in the motor housing results especially when the spring-elastic holding elements have a hook-shaped fastening element at their free ends, for example in the form of locking lugs, which in Appropriate recesses and contact edges of the electric motor or attack. In this way, the electric motor can be secured in a simple but reliable manner in the axial direction against slipping.

In one embodiment of the device according to the invention, the holding elements engage with their hook-shaped free ends on an end face of the electric motor. With this type of fastening, it is conceivable that the electric motor can be inserted into the motor housing in both possible orientations, which would expand the range of applications of the motor mount. For example, the hook-shaped ends of the resilient holding elements can grip around the end of the pole ring, thereby axially securing the motor.

The motor is thus attached directly to the motor housing with the least amount of parts and assembly work using fastening hooks using elastic damping elements.

The same advantages also apply to a particularly advantageous embodiment of the device according to the invention for fastening a motor, in which the hook ends of the spring-elastic holding elements engage directly in the motor. A significant reduction in the overall depth of the assembled motor-motor housing combination can be achieved if the latching hooks engage away from the end of the motor, for example directly in openings on the circumference of the pole ring. This enables an advantageous arrangement of the fan impeller, for example close to the motor, since the hook and holding element geometry cannot collide with the impeller of the fan. If the locking elements are provided with a tangential coating in the area of the engagement in the motor, almost any noise and vibration coupling into the hook ends and thus into the motor housing is avoided. This measure additionally secures the motor itself against rotation in the receiving housing.

Alternatively, the electric motor can also be secured against radial rotation by means of stop webs which are mounted in the bottom region of the pot-shaped receiving housing and point into the housing and engage in corresponding openings in the electric motor. A particularly advantageous embodiment results if these stop webs are also covered with an elastic material, such as a thermoplastic elastomer. The last method simplifies the manufacture of the fastening hooks.

To increase the dynamic stability of the motor in the motor housing, additional elastic supports for radially fixing the motor can be attached to the inside of the motor housing. For example, an elastic ring or a plurality of molded-on beads made of an elastomer can occupy the inner circumference of the receptacle in a circle and support the electric motor against the housing wall.

A good radial fixation of the motor in the motor housing results if a plurality, typically three or four, of axially attached to the inner wall of the receiving housing, elastic decoupling elements are provided, which minimize sound and vibration transmission of the motor to the housing. These radial decoupling elements can also advantageously be molded directly onto the rigid wall of the motor housing. A particularly advantageous embodiment of the device according to the invention results if the radial decoupling elements running axially in the receiving housing are formed directly on the resilient holding elements. This functional combination of axial and radial decoupling is very useful in terms of production technology and enables reliable decoupling of the motor housing from the motor with relatively simple means when fastening the motor in the receiving housing and a reduced manufacturing effort. To realize these axially and radially acting decoupling elements, the resilient holding elements and the axially aligned areas of the inner wall of the receiving housing are covered with elastic material that decouples the motor and the motor housing from one another, but reliably secures the motor in the housing.

However, if the center of gravity of the motor is outside the base point of the spring-elastic holding elements, separate attachment of the radial decoupling elements in the rigid area of the receptacle housing is preferred, so that the catches are not loaded and deformed by the motor weight or circumferential forces due to bending, which means that the motor is in a fixed position in the housing and thus in the body of the vehicle would no longer be guaranteed.

The device according to the invention experiences a further advantageous embodiment when a counter bearing is present in the motor housing, which leads to an additional axial and radial fixation of the motor in the receiving housing. This is achieved in particular in that the counter bearing likewise has an elastic damping element or is designed directly as such. A particularly advantageous embodiment that is easy to implement is obtained if the counter-bearing is injected directly into the receiving housing. For this purpose, the counter bearing can also be produced from a thermoplastic elastomer, which is injection molded onto the housing in a two-component injection molding process. A counter bearing is particularly advantageous which has a plurality of webs which run in a star shape and which have a roller-shaped or roller-shaped surface on their side facing the motor and thus any surface

Pendulum movements of the motor in the motor housing can absorb.

Alternatively, the counter bearing can also be preassembled on the engine itself, also with appropriate elastic elements.

drawing

Further advantages of the device according to the invention can be found in the description and the drawing.

In the drawing, embodiments of the device according to the invention are shown in a simplified, schematic manner. The description, drawings and claims contain numerous features in combination. A person skilled in the art will also consider these features individually and combine them into useful further combinations.

Show it:

FIG. 1 shows a section through a first exemplary embodiment of a device according to the invention with an electric motor inserted, FIG. 2 shows a detail of the first exemplary embodiment of the device according to the invention,

FIG. 3 shows the detail of the device according to the invention from FIG. 2 in another representation,

FIG. 4 shows a second exemplary embodiment of the device according to the invention in section,

FIG. 5 shows a detail of the second exemplary embodiment of the device according to the invention,

FIG. 6 shows the detail of the device according to the invention from FIG. 5 in another representation,

Figure 7 shows another embodiment of the device according to the invention in section, and

Figure 8 shows a detail of the embodiment of the device according to the invention according to Figure 7 in supervision.

FIG. 1 shows a first exemplary embodiment of the device 10 according to the invention. In this exemplary embodiment, the device 10 comprises a receiving housing 12 with a receiving opening 14 through which a motor 16, in particular an electric motor 18, can be inserted into the housing 12. In the illustration in FIG. 1, the electric motor 18 has already been completely inserted into the receiving housing. In a schematic manner, shown in simplified form, the electric motor 18 is provided with a

Pole ring 20, which simultaneously forms a pole housing 19, a motor shaft 22, a first bearing 24 and a second bearing 26 for holding the shaft 22, and a brush holder 28 with an associated commutator 30. On the outside of the receiving housing 12 serving as the motor housing 32, a motor flange 34, in the exemplary embodiment of FIG. 1 in one piece with the receiving housing 12, is formed. Via this motor flange 34, the electric motor 18 can be fastened to a corresponding support element 36 of a ventilation or air conditioning system or directly to the body of a motor vehicle. The motor flange 34 has openings 38 for fastening the motor housing 32 to the carrier element 36. Furthermore, on

Motor flange 34 or on the outside of the receiving housing 12 there are devices for the electrical connection of the motor 18 to a current and voltage source (not shown in FIG. 1) for operating the electric motor 18. Holding devices can optionally be formed on the motor housing 32 or on the motor flange 34 for fastening further components both of the electric motor 18 and of the blower.

In the exemplary embodiment in FIG. 1, the receiving housing 12 is made of plastic and has a pot-shaped construction with a cylindrical housing part 42 which essentially encompasses the electric motor 18 introduced and one in the exemplary embodiment opposite the receiving opening 14 except for an area for receiving a counter bearing 44 closed bottom part 46.

In the area of the receiving opening 14 of the motor housing 32, on the inner wall 48 of the housing 12 there are a plurality of spring-elastic holding elements 50 which run axially to the motor shaft 22 for fixing the electric motor 18 in place

Mounted device 12 attached. The holding elements 50 are in the illustrated embodiment, as can be seen in the detailed views of this embodiment in Figures 2 and 3, as a radially pivotable, resilient Tongues 52 formed from the cylindrical part 42 of the receiving housing 12. For this purpose, a first end 54 of these spring elements 50 is fixedly connected to the motor housing 12 by being formed, for example, in one piece on the circumference of the receiving housing 12. On their axial

Longitudinal sides 55 have the spring tongue 52 spaced apart from the wall 57 of the receiving housing 12 by slots 56. With their second, free ends 58, the spring tongues 52 can be pressed in the radial direction into associated pocket-like recesses 60 in the wall 57 of the motor housing 32 in order to open the receiving opening 14 of the receiving housing 12 so that the electric motor 18 is inserted into the receiving housing 12 can be.

Figure 2 shows a tear from the wall 57 of the

Receiving housing 12 of the device 10 according to the invention. Two lateral incisions or slots 56 separate the holding element 50 from the wall 57 of the housing 12 and thus form the tongues 52, which enable the holding element 50 to be resiliently movable.

FIG. 3 shows the position of the spring tongues 52 relative to the recesses 60 in the wall 57 of the receiving housing 12 of the device 10 according to the invention when the electric motor 18 has not yet been used.

If the electric motor 18 is inserted into the receiving housing 12, the resilient tongues 52 are pressed radially outward into the pocket-like recesses 60, so that the electric motor 18 can be inserted into the housing 32 past the holding elements 50. The spring-elastic holding elements 50 then act with a corresponding counterforce on the electric motor 18 and thereby fix it in the motor housing 32. At their second end 58 opposite the base part 46 of the receiving housing 12, the spring-elastic holding elements 50 have, as can be seen particularly clearly in the illustration in FIG. 1, additional, radially projecting, hook-shaped fastening elements 62. In the exemplary embodiment shown in FIG. 1, these fastening hooks 62 in the form of latching lugs 98 encompass an end face 64 of the inserted electric motor 18 and thus fix it in the axial direction in the receiving housing 12.

For vibration decoupling and a corresponding noise damping of the motor 18, both the spring-elastic holding elements 50 and the hook-shaped fastening elements 62 are provided on the side facing the motor 18 with an elastic material 66 in the form of a

Elastomer 68 coated. 1 is a thermoplastic elastomer 70 which is introduced directly into the plastic housing in a two-component injection molding process.

The elastomer coating of the spring tongues 52 extends in the axial direction over the actual spring length and thus beyond the first end 54 of the spring tongues 52, down on the inner housing wall 48 into the bottom region 46 of the receiving housing 12.

In the bottom part 46 of the pot-shaped receiving device 12 there is a recess 74 in the form of a central opening 76 for a second bearing 26 of the shaft 22 of the electric motor 18. In the exemplary embodiment in FIG. 1, this bearing 26 of the motor shaft 22 is via a bracket 78 on the pole housing 19 and thus attached to the electric motor 18 itself. In the central bottom opening 76 of the device 10 according to the invention, an elastic damping element 80 for the shaft bearing 26 is formed, which acts as a counter bearing 44 for the axial fastening of the electric motor 18 by the locking hook 62 is used. This damping counter bearing 44, which consists of an elastomer 68, is likewise injected directly into the housing 12 and additionally ensures radial damping and fixing of the electric motor 18 in the motor housing 32.

Also formed in the bottom area of the receiving housing 12 according to the invention are a plurality of stop webs 82 pointing in the direction of the receiving opening 14. These

Stop webs 82, which can also be covered with an elastic damping material 66, engage in openings of the electric motor 18 or clamp a bearing bracket 78 of the motor shaft 22 on each side. In this way, the motor 18 can be secured against rotation in the motor housing 32.

For additional radial decoupling and fixing of the electric motor 18 in the motor housing 32, in the area of the first end 54 of the spring-elastic holding elements 50 there are elastic decoupling elements 86 which are formed radially inwards and run in the axial direction and exert a corresponding pressure on the pole ring 20 of the electric motor 18 and keep it safe but vibration-dampened in the motor housing. This measure significantly improves the dynamic stability of the motor 18 in the motor housing 32.

Figure 4 shows a second embodiment of the device according to the invention in a partial view.

Components of the same type in this exemplary embodiment are provided with the same reference numerals as in FIG. 1 of the first exemplary embodiment. The device 10 according to the invention in turn consists of a pot-shaped receiving housing 12, on which a motor flange 34 for fastening a motor 16 to a carrier element 36 of a heating or cooling system of a vehicle is integrally formed. In the illustration in FIG. 4, an electric motor 18 is inserted into the motor housing 32. The individual, schematically illustrated components of the electric motor 18 correspond to those from the exemplary embodiment in FIG. 1. A fan or blower impeller 88 is additionally mounted on a shaft 22 of the electric motor 18.

The exemplary embodiment of the device 10 according to the invention shown in FIG. 4 in turn has a plurality of spring-elastic holding elements 50 distributed over the circumference of the receiving housing, only two of which are shown in FIG. 4. The spring-elastic holding elements 50 are in this embodiment in the form of spiral springs 90 with their one, first end 54 integrally formed on the, preferably made of plastic motor housing 32 and elastic at their second, free end 58, in particular in the radial direction with the application of a certain force flexible. Axial slots 56 in the wall 57 of the receptacle housing 12, which laterally delimit the spring-elastic holding elements 50 from the receptacle housing, enable radial flexibility. The design of the spring elements 90 from the receiving housing 12 can be clearly seen in the detailed representations of FIGS. 5 and 6.

FIG. 5 shows a section from the wall 57 of the receiving housing 12 with a correspondingly formed spiral spring 90. FIG. 6 shows the same section again for clarification in a top view. The spring-elastic holding elements 50 are coated on their side facing the motor 18 with an elastic damping means 66, which in the special exemplary embodiment in FIG. 4 is a directly injection-molded thermoplastic elastomer 70.

At their free, upper end 58, the elastic spiral springs 90 have fastening elements 62, which point radially into the receiving housing 12, in the form of latching lugs 98, which are likewise covered on their side facing the motor with an elastic damping material 66. These fastening elements 62 engage in the electric motor and thereby fix it.

In the exemplary embodiment shown in FIG. 4, the spring-elastic holding elements 50 engage with their radial fastening elements 62 attached to their free end 58 directly in correspondingly aligned openings 94 in the pole housing 19 or the pole ring 20 of the electric motor 18.

The position of the engagement of the fastening hooks 62 away from an end face 64 of the motor 18 enables an advantageous arrangement of the fan impeller 88 close to the motor. This measure advantageously makes the overall depth of the entire fan arrangement, for example, compared to the exemplary embodiment shown in FIG reduced because the hook geometry of the locking lugs 98 does not collide with the geometry of the blower impeller 88.

Through a tangential, possibly also elastic covering 87 of the fastening hooks 62 and 98 in the area of the engagement in the motor 18, any coupling of noise and vibrations into the hooks 62, 98 or the spring-elastic holding elements 50 and thus avoided in the motor housing 32 and the motor 18 additionally secured against rotation.

For radial fixation and vibration damping of the electric motor 18 in the device 10 according to the invention according to FIG. 4, a plurality of elastic decoupling elements 86, which run in the axial direction and are formed on the inner wall 48 of the receiving housing 12 in the region of the first end 54 of the spring-elastic holding elements 50, are in turn attached , These are in

Embodiment molded directly onto the holding elements 50 and the housing inner surface 48 aligned therewith, but in principle can also be connected to the housing 12 in another way.

In the bottom area 46 of the device 10 according to the invention according to the exemplary embodiment in FIG. 4 there is a further, elastic damping element 80, which is also molded as a thermoplastic elastomer 70 in a two-component injection molding process onto the bottom 46 of the receiving housing 12. This further damping element 80 serves as a counterbearing 44 for both the axial and the radial fixation of the electric motor 18 in the receiving device 12.

FIG. 7 shows a further exemplary embodiment of the device 10 according to the invention with a cup-shaped motor housing 32 which receives an electric motor 18 and to which a motor flange 34 is attached for fastening the device 10 to a body of a motor vehicle. The motor housing 32 has a receiving opening 14, a cylindrical housing part 42 which receives the motor 18 in the installed state and a housing base 46 in which a central opening 76 for the shaft 22 of a Electric motor 18 or for a, a bearing of the shaft 22 supporting damping element 80 is present.

Corresponding openings 38 are provided on the motor flange 34 for screwing the device 10 according to the invention to a carrier part 36 of the body or to the air conditioning system of a motor vehicle. A connection opening 72 for an electrical plug contact for operating the electric motor 18 is likewise formed on the motor flange.

The essentially pot-shaped receptacle housing 12 has a plurality of spring-elastic holding elements 50 distributed over its circumference, which are formed in a tongue-like manner 52 from the receptacle housing 12. For this purpose, there are axial incisions 56 in the receiving housing 12 on the side of the spring tongues 50, 52, which allow the spring tongues 50, 52 to be pivoted or bent radially.

The free end 58 of the spring tongues 50, 52 is provided with fastening elements 62, 98, which point radially inward and point to the motor shaft 22 and protrude at right angles from the spring tongues 50, 52, and which secure an electric motor 18 inserted into the receiving housing 12 against displacements in the axial direction , The spring tongues 50, 52 and the fastening elements 62, 98 can be covered on the inside with an elastic damping material 66.

For radial decoupling and fixing one in the

Receiving housing 12 introduced electric motor 18 are on the inner wall 48 of the receiving housing 12 a plurality of, in this embodiment axially extending decoupling elements 86, which project to a certain degree radially into the receiving housing 12. This Elastic decoupling elements 86 for the radial movements of the motor 18 can have a roll or roller shape, or can also have a conical or pointed shape.

In the exemplary embodiment in FIG. 7, the radial decoupling elements 86 are spaced apart from the spring-elastic holding elements 50, which ensure axial fastening and decoupling of the electric motor 18, in the rigid region 100 of the receiving housing 12, so that the axial and the radial damping components lie on the circumference of the Motor housing 12 according to the invention are arranged separately from each other. Such a separate attachment of the radial decoupling elements 86 is particularly preferred when the center of gravity of the electric motor is outside the

Base of the spring-elastic holding elements is located. Otherwise, the holding elements 50 could be excessively stressed and deformed by the motor weight or rotating forces due to bending, as a result of which a fixed position of the motor would no longer be guaranteed.

As a counter bearing 44 is located in the bottom region 46 of the pot-shaped receptacle 12, an elastic damping element 80, which can be injected into the receptacle 12, or else on the other

Types known in the art can be mounted in the housing. This counter bearing 44 counteracts the radial or axial decoupling elements of the device 10 according to the invention and thus fixes the electric motor 18 both axially and radially

Direction.

FIG. 8 shows the pot-shaped receiving housing 12 of the device 10 according to the invention in a top view looking into the housing 12. About the scope Distributed in this exemplary embodiment are three resilient holding elements 50 which can be pressed radially outward into pocket-like recesses 60 provided on the circumference of the housing using a corresponding force. For this purpose, the holding elements 50 are connected at their first end 54 to the receiving housing 12, but laterally separated from the latter by slots 56. The holding elements 50 have, at their second axial end 58, which corresponds to the visible upper end in FIG. 8, radially inward-pointing latching hooks 98.

Spaced from the resilient holding elements 50 are radial decoupling elements 86 made of an elastic material 66, also distributed over the circumference of the housing 12. The radial decoupling elements 86 run in the axial direction on the inner wall 48 of the receiving housing 12 and have a convex interior of the receiving housing 12 directed surface, which can also be tapered or tapered and come to rest with the motor installed, for example against the pole housing 19 or the pole ring 20 of the electric motor 18 and thereby fix it radially in the motor housing 32. To increase the elasticity of the radial decoupling component 86, axial incisions 102 can be made in the wall 57 of the cup-shaped receiving housing 12, on the back of the radial decoupling elements 86, into which the elastic material 66 of the radial decoupling elements 86 by the inserted motor can be pressed in, so that the elastic behavior of these damping components is additionally increased.

In the bottom element 46 of the pot-shaped receptacle housing 12 of the device 10 according to the invention there is a counter bearing 44 made of elastic material 66, preferably a molded one thermoplastic elastomer 70 formed. In the exemplary embodiment shown, the elastic counter bearing 44 has a central opening 104 for the shaft 22 of the electric motor 18. The counter bearing 44 also has, on its side facing the receiving opening 14 of the motor housing 12, a plurality of star-shaped, radially outwardly extending webs 106 in the form of roller bodies 108 on which the electric motor 18 or the bearing bracket 78 carrying the associated bearing of the motor shaft 22 when wobbling Can roll movements to a certain extent damping.

The counter bearing 44 designed in this way enables motor vibrations that occur both radially and axially to be decoupled.

Also arranged in the bottom region of the pot-shaped receiving housing 12 in this exemplary embodiment of the device according to the invention are two stop webs 110 pointing in the direction of the receiving opening 14, between which a bearing bracket 78 of the electric motor 18 can be clamped. In the exemplary embodiment shown, these stops 110 are likewise provided with an elastic damping material 66 at their contact points with the motor. With the aid of these stops 110, the motor 18 can be secured against rotation within the motor housing 32. The stop webs 110 can be easily formed in one piece on the motor housing 32 or directly on the counter bearing 44.

The device according to the invention is not limited to the exemplary embodiments presented in the description.

Thus, the device according to the invention is not limited to use for blower motors. Everyone else too Motors which are to be decoupled from vibration and are to be installed in a correspondingly damped manner can advantageously be fastened by the fastening device according to the invention.

In particular, the radial decoupling elements do not have to run axially on the housing wall of the motor mount. Rather, for example, two or more circular decoupling elements in the form of corresponding elastic beads running inside the entire circumference of the housing wall are also conceivable.

The elastic decoupling materials do not necessarily have to be molded on, but can also be applied directly to the corresponding components of the motor housing by other methods known to the person skilled in the art, such as for example by gluing.

Claims

Expectations

1. Device (10) for fastening an electric motor (18), in particular a blower motor, with a motor housing

(32) serving, essentially pot-shaped receptacle (12) with a receptacle opening (14) into which the electric motor (18) at least partially protrudes, with a holding flange (34) attached to the receptacle housing (12) for fastening the motor housing (32) a carrier element

(36), for example a motor vehicle heating and / or air conditioning system, and with means for radially and axially fixing the electric motor (18) in the motor housing (32), characterized in that the receiving housing (12) has at least one spring-elastic holding element (50, 52,90) for axial fixation, which is at least partially covered with an elastic material (66) on its side facing the motor (18) and is connected with its first axial end (54) to the receiving housing (12) and in Area of its second axial end (58) directly on the engine

(18) is present.

2. Device according to claim 1, characterized in that the elastic material (66) covering the resilient holding element (50, 52, 90) is an elastomer (68), in particular a thermoplastic elastomer (70).

3. Device according to claim 1 or 2, characterized in that the elastic material (66,68,70) is injection molded onto the at least one spring-elastic holding element (50,52,90).

4. Device according to one of claims 1 to 3, characterized in that the at least one resilient holding element (50, 52, 90) on the pot-shaped receiving housing (12) is resilient, preferably in one piece.

5. Device according to one of the preceding claims, characterized in that the at least one resilient holding element (50, 52, 90) has a hook-shaped, pointing in the radial direction at its end (58) facing the receiving opening (14) of the motor housing (32) Fastening element (62.98).

6. The device according to claim 5, characterized in that a plurality, preferably three, of the resilient

Hold elements (50, 52, 90) with their hook-shaped ends (62, 98) on an end face (64) of the motor (18) penetrated by the motor shaft (22) of the electric motor (18).

7. Device according to one of claims 1 to 5, characterized in that a plurality, preferably three, of the resilient holding elements (50, 52, 90) with their hook-shaped ends (62, 98) at one point away from the end face (64) of the electric motor engage in the motor, in particular in the pole ring (20) of the motor (18).

8. The device according to claim 7, characterized in that an electric motor (18) inserted into the receiving housing (12) by means of a tangential, in particular elastic covering (89) of the hook-shaped ends (62, 98) of the resilient

Holding elements (50, 52, 90) in the area of engagement in the motor (18) is secured against radial rotation.

9. Device according to one of claims 1 to 7, characterized in that in the receiving housing (12) used electric motor (18) by a plurality of on the opposite side of the receiving opening (14) end of the receiving housing (12) attached in the direction to the receiving opening (14), stops (82) are secured against rotation.

10. Device according to one of the preceding claims, characterized in that the motor housing (32) and the spring-elastic holding elements (50, 52, 90) consist of plastic, in particular of a polypropylene plastic.

11. Device according to one of the preceding claims, characterized in that an electric motor (18) used in the receiving housing (12) in the radial direction by at least one on the inner wall (48) of the receiving housing

(12) extending, elastic decoupling element (86) is secured.

12. The apparatus according to claim 11, characterized in that an electric motor used in the receiving housing (12)

(18) is secured in the radial direction by a plurality of elastic decoupling elements (86) running axially on the inner wall (48) of the receiving housing (12).

13. The apparatus according to claim 12, characterized in that the at least one radial decoupling element (86) consists of an elastomer (68), in particular of a thermoplastic elastomer (70) and are molded onto the inner wall (48) of the receiving housing (12).

14. The apparatus according to claim 12 or 13, characterized in that the axially extending, radial decoupling elements (86) are formed on the side of the spring-elastic holding elements (50, 52, 90) facing the electric motor (18).

15. Device according to one of the preceding claims, characterized in that a counter bearing (44) for axial and / or radial fixation of an electric motor (18) in the motor housing (32) is present.

16. The apparatus according to claim 15, characterized in that the counter bearing (44) is an elastically shaped

Damping element (80).

17. The apparatus according to claim 16, characterized in that the counter bearing (44) consists of an elastomer (68), in particular of a thermoplastic elastomer (70), which is injection molded directly onto the receiving device (12).

18. Device according to one of claims 1 to 14, characterized in that an elastic counter bearing (44) is preassembled on an electric motor (18) inserted into the receiving housing (12).

19. The device according to claim 17 or 18, characterized in that the counter bearing (44) has a plurality of radially extending webs (106) which, in the direction of the receiving opening (14), a convex, in particular roller or roller-shaped surface contour (108 ) demonstrate.