WO2012156119A1 - Bearing device - Google Patents

Abstract

The invention relates to a bearing device (100) comprising a bearing body (20) for receiving a bearing (38) that is used to support a shaft (12), said bearing being arranged in a receiving body (15), in particular a housing, in a formfitting manner. The bearing body (20) radially fixes the bearing (38) on the bearing outer circumference (42) which has a round shape, and a flange-like circumferential bearing body region which forms a through-opening (28) for the shaft (12) forms a first axial stop (27) for the bearing (38). According to the invention, the bearing body (20) has a polygonal inner contour in the region of the bearing (38) in order to radially fix the bearing (38), said inner contour being arranged so as to be in contact with the outer circumference (42) of the bearing (38) at least at three at least punctiform but preferably linear contact sites (43) and fixing said bearing in a clamp-locking manner.

Description

 description

Storage facility

State of the art

The invention relates to a bearing device according to the preamble of claim 1. Such a bearing device is known from DE 10 2009 028 133 A1 of the applicant. The known bearing device has a bearing body for receiving a bearing, which in turn serves to support a shaft section of an electric motor. By means of such a bearing body, the electric motor or the shaft can be connected in an upstream mounting process with the bearing body, and insert the unit so formed in the housing, for example, an actuator form-fitting manner. This allows a particularly efficient and cost-effective production, in which the bearing is positioned or fixed in the housing over the bearing body in the desired manner. The bearing is received within the bearing body both radially, and possibly axially fixed. The radial bearing or fixing of the bearing in the bearing body is usually carried out by form or clamping, in which the bearing body has a corresponding to the outer diameter of the bearing corresponding inner contour. In order to enable the corresponding clamping fit, the inner contour of the bearing body is formed slightly smaller than the outer diameter of the bearing. A disadvantage is that the required dimensions of the bearing body must be maintained relatively accurate, and in particular, for example, are temperature dependent. Not only the accuracy of the bearing body in the region of the press fit is relatively expensive, but due to the fully applied to the outer contour of the bearing inner contour of the bearing Body is also the camp during assembly and operation relatively heavily stressed.

Disclosure of the invention

Based on the illustrated prior art, the invention has the object, a storage device according to the preamble of claim 1 such that both the most rational and cost-effective production of the bearing body is made possible, as well as improved the power flow between the bearing and the bearing body , in particular decoupled. This object is achieved with a bearing device with the features of claim 1 according to the invention that the bearing body for radial fixation of the bearing in the region of the bearing has a polygonal inner contour that at least punctiform, but preferably linear in at least three places in abutting contact with the Outside circumference of the bearing is arranged and this fixed by adhesion. In other words, this means that the bearing, in contrast to the prior art, no longer over its entire outer circumference form- or kraftchlüssig is applied to the bearing body, but at least three places, the accurate positioning of the

Allow bearing in the bearing body, wherein the remaining locations of the bearing are not acted upon by a force through the bearing body. As a result, in particular the mechanical stress of the bearing is reduced, which leads to improved operating characteristics of the bearing and enables the use of cheaper bearings.

Advantageous developments of the storage device according to the invention are listed in the subclaims. All combinations of at least two of the features disclosed in the claims, the description and / or the figures fall within the scope of the invention.

Particularly preferred for the exact radial positioning of the bearing within the bearing body, it is when the points at which the bearing is guided within the bearing body are arranged at regular Wnkelabständen to each other. In a particularly preferred structural embodiment, it is provided that six points are provided, which bear linearly on the bearing body. As a result, the mechanical load on the bearing body is kept relatively low at the individual points, and by providing at least six bearing points a very accurate positioning of the bearing in the bearing body allows or afflicted with relatively large tolerances manufacturing of bearings allows, as by the Relatively large number of places the camp nevertheless can be recorded relatively accurate position.

Particularly inexpensive and easy to manufacture the bearing body, this consists of metal and is designed as a deep-drawn / stamped part.

It is furthermore preferred that the bearing body has a second axial stop for the bearing, which acts on the bearing in the direction of the first axial stop. As a result, the bearing acts as a fixed bearing, wherein over the bearing body possibly occurring axial forces can be absorbed over a large area and transmitted to the housing, for example.

The second axial stop can be formed relatively easily and inexpensively by at least one deformation of sections of the bearing body, whereby an at least indirect contact of the bearing with the bearing body is achieved by the deformation.

Such a deformation can be particularly easily formed by at least one, in particular by a punched portion formed from the bearing body.

In order to enable a large-area and targeted introduction of the axial force required to form the second axial stop on the bearing, it is also proposed that the second axial stop be separated by a separate axial stop

Part is formed, which is inserted in the bearing body.

A particularly advantageous mounting of the bearing in the bearing device can be achieved if the separate component is designed as a radially elastically deformable ring which has a passage in the radially non-energized state, which is greater than the outer diameter of the bearing, and in the radial kraftbeaufschlagtem state rests with its front side on the end face of the bearing. As a result, the bearing can be guided through the passage opening of the separate component for mounting in the bearing body and, after radial application of force to the separate component, movement against the mounting direction is prevented by abutment of the bearing on the end face of the separate component.

In addition, a particularly simple and inexpensive mounting of the bearing is achieved in the bearing body, when the ring for mounting the bearing in a fixing region of the bearing body is clamped, wherein the passage of the ring is greater than the outer diameter of the bearing, and if the ring for forming the second axial stop is acted upon radially and axially in the direction of the first axial stop, so that the ring rests axially on the end face of the bearing.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawing.

The shows in:

1 is a drive shaft of an actuator, which is mounted in a bearing device according to the invention, in a partially cutaway perspective view,

2 shows a cross section through the bearing device for illustrating the flow of force between the bearing and the bearing device and

Fig. 3

and

4 each simplified representations for explaining the assembly process of a bearing in a storage device according to the invention during different assembly stages, each in a simplified longitudinal and cross-section. The same components or components with the same function are provided in the figures with the same reference numerals.

1 parts of an actuator, in particular a transmission drive unit are shown, as for example as Sitzverstellungsantrieb,

Window lifter drive or windscreen wiper drive is used in a motor vehicle. Here, the drive unit 10 has an electric motor whose armature 1 1 is connected to a drive shaft 12. The drive shaft 12 has, axially spaced from the armature 1 1, a toothed area in the form of a drive worm 13, which meshes with a (gear) toothed wheel, not shown, which in turn is at least indirectly connected to the drive, e.g. a seat, a window or a windshield wiper is used.

The components of the drive unit 10 are taken for example in a housing 15, which is formed for example as a metal casting, or as an injection molded part (made of plastic). In the housing 15, a recess 16 is formed, which serves to receive a bearing device 100 according to the invention. The bearing device 100 can be fabricated in advance together with components of the electric motor, in particular with the armature 11 and its drive shaft 12, as a structural unit, and fixed by insertion into the recess 16 within the drive unit 10. In this case, the housing 15 in this case, for example, consists of two half-shells, of which only the lower half-shell 17 is shown in FIG.

The bearing device 100 serves to position the drive shaft 12 with its armature 1 1 radially and axially within the drive unit 10, wherein the electric motor has a further, not shown in the figures bearing, preferably on the bearing means 100 opposite side of the armature shaft 12th or the armature 11 is attached to a stub axle, and is arranged for example within the pole housing, also not shown, of the electric motor.

The bearing device 100 has a bearing body 20 according to the invention, which consists in particular of sheet metal and is formed as a stamped / deep-drawn part. Alternatively, it is also possible that the bearing body 20 is made of plastic. The bearing body 20 has a perpendicular to the longitudinal axis 21 of the drive shaft 12 extending bearing flange 22, in the wall, for example, one or more openings 23, for example, for performing an electrical cable, is / are formed. The bearing body 20 is on the armature 11 opposite side of the bearing flange 22 in a hollow cylindrical portion 24 via. The hollow cylindrical region 24 in turn consists of a Lagerfixierabschnitt 25 and a bearing receiving portion 26. The bearing receiving portion 26 has a radially inwardly drawn axial stop 27, which is formed by forming the material of the bearing body 20. The bearing flange 22 opposite side of the bearing body 20 is provided in the region of Axialan- impact 27 with a through hole 28 in order to pass the drive shaft 12 through the bearing body 20 can.

In the wall of the Lagerfixierabschnitts 25, which is cylindrical in Fig. 1, but in the context of the invention, for example, four, each arranged at 90 ° to each other wall sections can be several, preferably at uniform angular intervals over the circumference of Lagerfixierabschnitts 25 arranged apertures 30 formed, in particular by a punching operation. The openings 30 have in the illustrated embodiment, an H-shape, so that in each case a radially inwardly deformable retaining tab 31, 32 is formed on opposite sides of the respective opening 30.

The bearing receiving portion 26 is formed in the embodiment in the form of a hexagon 33, so that distributed over the circumference in a Wnkel distance of 60 ° each to each other flat side surfaces 34 are formed with arranged thereon fixing edges 35.

The bearing receiving portion 26 serves to receive a bearing 38 of the drive shaft 12 serving bearing 38, which is designed in particular as a rolling or ball bearing.

As can be seen in particular with reference to FIGS. 3 and 4, the bearing 38 has an inner ring 39, rolling elements 40 and an outer ring 41. According to the invention, the outer ring 41 is received in the bearing receiving section 26 by form or clamping in such a way that the outer circumference 42 of the outer ring

41, as can be seen with reference to FIG. 2, punctiform or linear (in alignment to the longitudinal axis 21 of the drive shaft 12) approximately at the center in the area of the side surfaces 34 at contact points 43 formed as contact points. Radial forces generated by the drive shaft 12 are thus transmitted from the outer ring 41 to the bearing receiving section 26 in accordance with the force arrows 44 in the region of the contact lines 43. The bearing receiving portion 26 is in turn in the region of the side edges 33 in the recess 16 of the housing 15 positively or non-positively, so that the likewise linear contact surfaces 45 between the bearing body 20 and the recess 16 corresponding to the force arrows 46 of the transmission of radial forces between the bearing receiving portion 26 and the bearing body 20 to the housing 15 and vice versa.

The radial fixation of the bearing 38 within the bearing receiving portion 26, as already explained, by clamping or positive engagement. For this purpose, the bearing receiving portion 26 between the side surfaces 34 at a distance corresponding to the diameter of the (standardized) diameter of the outer ring 41 of the

Bearing 38 corresponds.

The axial positioning or fixing of the bearing 38 in the bearing body 20 takes place, for example, by means of a C-shaped clamping ring 48 which can be seen in FIGS. 3 and 4. The clamping ring 48, which is rectangular in cross-section only in the exemplary embodiment, but in principle has an arbitrary cross-section has a longitudinal slot 49, so that the clamping ring 48 is elastically deformable by radial compression in its diameter. The clamping ring 48 is disposed within the Lagerfixierabschnitts 25 on the Lageraufnahmeab- section 26 side facing, as can be seen in particular with reference to FIGS. 3 and 4. Preferably, the outer diameter of the clamping ring 48 is formed such that it is received for mounting by clamping within the Lagerfixierabschnitts 25, as shown in FIG. 3 can be seen. Furthermore, the inner diameter of the clamping ring 48 in the state in which it is received by clamping within the Lagerfixierabschnitts 25, preferably such that it is slightly larger than the outer diameter of the bearing 38, so that the bearing 38 according to the direction of Arrow 51 can be inserted or positioned from the side of the bearing flange 22 through the clamping ring 48 into the bearing receiving section 26, the bearing 38 abutting against the axial stop 27 on the one hand, and the end face 52 facing the clamping ring 48 on the other hand. least almost aligned with the facing end face 53 of the clamping ring 48 is arranged.

The axial positioning or fixation of the bearing 38 by the clamping ring 48, which acts as a second axial stop 54 is effected by reducing the diameter of the clamping ring 48 such that corresponding to FIG. 4, the end face 52 of the bearing 38 in abutting contact with the end face 53 of the clamping ring 48 device. For this purpose, in addition to the reduction in diameter of the clamping ring 48 an additional, acting in the direction of arrow 51 axial force is required. Both the radial force, as well as the axial force on the clamping ring 48 is either, as in the embodiment of FIG. 1, achieved by radial impressions or pressing the retaining tabs 31, 32, or, as shown with reference to FIGS. 3 and 4 by pressing in, for example, three fixing lugs 55 arranged at approximately 120 ° apart from each other.

The storage device 100 described so far can be modified or modified in many ways, without deviating from the inventive idea. This is the bearing 38 with its outer ring 41 no longer, as in the prior art, over the entire circumference in the bearing body 20 to receive, but only at least three points of contact or contact lines 43rd

Claims

claims

1. bearing device (100), with a bearing body (20) for receiving a bearing of a shaft (12) serving bearing (38) which is positively and non-positively in a receiving body (15), in particular a housing is arranged, wherein the bearing body (20) the bearing (38) radially fixed on its outer circumference (42) having a round shape and with a flange-like circumferential area forming a passage opening (28) for the shaft (12) a first axial stop (27) for the bearing (38 ) forms, characterized in that the bearing body (20) for radial fixation of the bearing (38) in the region of the bearing (38) has a polygonal inner contour which at least punctiform, but preferably linearly at least three contact points (43) in abutting contact with the Outer circumference (42) of the bearing (38) is arranged and fixed by positive locking.

2. Storage device according to claim 1,

 characterized,

 in that the contact points (43) are arranged at regular intervals relative to one another.

3. Storage device according to claim 2,

 characterized,

 that six contact points (43) are provided, which rest linearly on the bearing (38).

Bearing device according to one of claims 1 to 3,

characterized,

that the bearing body (20) consists of metal and is formed as a deep-drawn / stamped part.

Bearing device according to one of claims 1 to 4,

characterized,

in that the bearing body (20) has a second axial stop (54) for the bearing (38) which urges the bearing (38) in the direction of the first axial stop (27).

Bearing device according to claim 5,

characterized,

in that the second axial stop (54) is formed by at least one deformation of sections (31, 32; 55) of the bearing body (20) which are arranged in at least indirect contact with the bearing (38).

Bearing device according to claim 6,

characterized,

in that the sections (31, 32, 55) are each formed by a stamped hole in the bearing body (20).

Bearing device according to claim 5,

characterized,

in that the second axial stop (54) is formed by means of a separate component (48) which is inserted in the bearing body (20).

Bearing device according to claim 8,

characterized,

that the separate component is designed as a radially elastically deformable ring (48) which has a passage in the radially non-force-loaded state, which is greater than the outer diameter of the bearing (38), and in its radially kraftbeaufschlagtem state with its end face (53) the end face (53) of the bearing (38) rests.

10. Bearing device according to claim 9,

 characterized,

 in that the ring (48) is clampingly received in a fixing region (25) of the bearing body (20) for mounting the bearing (38), wherein the passage of the ring (48) is greater than the outer diameter of the bearing (38), and in that Ring (48) for forming the second axial stop (54) radially and axially in the direction of the first axial stop (27) is subjected to force, so that the ring (48) axially against the end face (52) of the bearing (38).

1 1. Drive unit (10), in particular gear drive unit such as seat adjustment drive, window lift or wiper drive in a motor vehicle with a bearing device (100) according to one of claims 1 to 10.