DE20307299U1 - Shaft with a hub - Google Patents

Description

•♦ ·

08.05.2003 Saile
5

ROBERT BOSCH GMBH; D-70442 Stuttgart

Shaft with a hub

State of the art

The invention is based on a shaft with a hub according to the preamble of claim 1. 15

From DE 198 04 502.6 Al a shaft-hub connection is known, with a shaft and a hub, which is connected to the shaft in a rotationally fixed but axially displaceable manner. The hub is axially fixed between two stops by two shoulders extending transversely to the shaft axis. A spring washer forms a first stop, which is connected to an outer section on the

0 rests against a shoulder. A radially inward-facing section is supported by a

Inner edge on the shaft, whereby the inner edge rests against the shaft in a spring-loaded manner at an axial distance from the shoulder. Grooves are provided which increase the axial force that the spring washer can absorb. However, this only allows the axial force to be changed in steps that depend on the width of the grooves. 25

Advantages of the invention

According to the invention, a spring washer forms a first stop, which rests with an outer portion against a shoulder of the hub, while a radially inwardly directed

0 section with an inner edge on the shaft by the inner edge in an axial

The spring washer is pushed from the shaft end over the shaft until its outer section rests against the shoulder of the hub. The inner edge gives way while it moves in the opposite direction.

The direction of the load is supported and clamped by friction on the circumference of the shaft. Because the shaft has a smooth surface into which the inner edge of the spring washer grips, the axial force of the spring can be continuously adjusted.

The spring washer can be pressed against the shoulder until the hub is axially fixed between the two stops without play. To ensure that there is no play even after long periods of operation, the spring washer is pre-tensioned when assembled. To release the axial fixation, the spring washer is cut open with a tool and replaced with a new one when reassembling.

In a preferred embodiment of the invention, the inner edge of the spring washer is embossed into the surface of the shaft. It is advantageous if at least the inner edge of the spring washer is harder, at least on the surface, than the surface of the shaft at the mounting point of the spring washer. Preferably, the material of the spring washer is harder than that of the shaft.

To facilitate assembly with sufficient axial force, the inner diameter of the spring washer before assembly is 3% to 8% smaller than the outer diameter of the shaft at the mounting point of the spring washer. The holding force is improved by making the inner diameter of the spring washer before assembly 4% to 7% smaller than the

outside diameter of the shaft at the mounting point of the spring washer. The best results are achieved when the inside diameter of the spring washer before mounting is 5% smaller than the outside diameter of the shaft at the mounting point of the spring washer.

5 The surface of the shaft 20 preferably has an average roughness depth of 1 μm to 250 μm,

ideally from 4μηι to 63μηι. This represents the best compromise between ease of assembly and axial holding force.

According to one embodiment, the inwardly directed portion of the spring washer is

0 spring tongues are formed. These can give way slightly radially during assembly, while

relatively stiff to absorb the support moment.

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It is also advantageous that the outer section of the spring washer has an axially bent collar that points away from the shoulder. The collar stiffens the outer area and makes assembly and disassembly easier because it is easier to attach tools to.
5

Since the shaft is fixed to the hub in a short installation space without play, it is particularly suitable for use in an electric motor gear unit, especially for adjusting equipment parts such as window lifters and sunroofs in motor vehicles where installation conditions are cramped.
10

drawing

Further advantages emerge from the following description of the drawing. The drawing shows an embodiment of the invention. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will also expediently consider the features individually and combine them into useful further combinations. They show: Fig. 1 a partial longitudinal section through an electric motor gear unit and Fig. 2 a partial view according to arrow II in Fig. 1.

0 Description of the embodiment

An electric motor (not shown) drives a gear 50 via a gear stage, which is connected in a rotationally fixed manner to a shaft 20. The gear 50 has a hub part 52, which is rotatably mounted on the outer circumference in a housing 38, wherein the gear 50 is provided with a

5 front side is axially fixed to the housing 38 and supports the shaft 20 axially on one side.

At the free end of the shaft 20, which protrudes from the housing 38, there is a pinion 46 with a toothing 48 on its circumference and with a hub 10, which is connected to the shaft 20 in a rotationally fixed manner, but at least during assembly can be moved axially. The torque is transmitted by a

0 Serration 30 between the shaft 20 and a bore 16 of the hub 10 by

Frictional engagement and/or positive engagement. The serration 30 can be incorporated into the circumferential surface of the shaft 20 or into the circumferential surface of the bore 16.

The hub 10 has shoulders 12 and 14 on its opposite end faces, which are axially fixed between two stops. One stop is formed by a spring washer 22, which rests with an outer section 26 on the shoulder 12 of the hub and is supported on the shaft 20 via an inwardly directed section 32, in that its inner edge 24 rests on the circumference of the shaft 20 at an axial distance 40 from the shoulder 12. The outer section 26 and the inner edge 24 are expediently aligned concentrically with a shaft axis 18.

The inner edge 24 of the inwardly directed section 32 is expediently designed with sharp edges. The inner edge 24 encloses an angle α of less than or equal to 90°.

To facilitate assembly while ensuring sufficient axial force, the inner diameter of the spring washer 22 is 3% to 8% smaller than the outer diameter of the shaft 20 at the mounting location of the spring washer 22 before assembly. The holding force is improved by making the inner diameter of the spring washer 22 4% to 7% smaller than the outer diameter of the shaft 20 at the mounting location of the spring washer 22 before assembly. The best results are achieved when the inner diameter of the spring washer 22 is approximately 5% smaller than the outer diameter of the shaft 20 at the mounting location of the spring washer 22 before assembly. The percentages are of course subject to manufacturing tolerances.

0, since the diameter of the shaft 20, for example, has a tolerance of ±0.05mm

and the inner diameter of the spring washer 22 before assembly of ±0.1mm. For example, the shaft 20 at the said assembly point has a diameter of 7±0.05mm and the spring washer has an inner diameter of 6.65±0.1mm. From this, the deviation of the diameters can be easily calculated and is in the sense of this application in

5 contain the percentage information.

The spring washer 22 is pushed from the shaft end onto the shaft 20, whereby the inner edge 24 and the inwardly directed section 32 yield radially in a resilient manner. For this purpose, it is expedient for spring tongues 42 to form the inwardly directed section 32. These provide

0 radially in the mounting direction, while it bends slightly under opposite load from

outer section 26 is very rigid. When the spring washer 22 is mounted, the inner edge 24 grips the smooth surface of the shaft 20. This enables the spring force to be continuously varied, while the spring washer 22 can still absorb high supporting forces.

The surface of the shaft 20 ideally has an average roughness depth of λ to 250 μm, preferably from 4 μm to 63 μm. The gripping takes place via a positive connection, which is created due to the sharp edge of the inner edge 24 of the spring washer 22, in that the inner edge 24 is pressed into the smooth shaft 20. For this purpose, at least the inner edge 24 of the spring washer 22 is harder, at least on the surface, than the surface of the shaft 20 at the mounting point of the spring washer 22. Preferably, the material of the spring washer 22 is harder than the material of the shaft 20.

A surface 34 on the housing 38 forms the second stop against which the spring washer 22 presses the hub 10 under a slight preload. In order to improve the starting properties between the hub 10 and the surface 34, a thrust washer 36 is arranged between the shoulder 14 and the surface 34. This extends radially into the area of the teeth 48 of the pinion 46. The surface 34 can thus be arranged on a diameter that is larger than the largest diameter of the hub 10. Since the surface 34 on the housing 38 simultaneously serves to axially fix the pinion 46 on the shaft 20 and the shaft 20 in the housing 38, it requires only a small overall length in addition to a few components.

The outer section 26 of the spring washer 22 has an axially bent collar 44 which points away from the shoulder 12. This stiffens the outer area 26. Furthermore, it offers a

easy way to attach tools.

Claims (14)

1. Shaft ( 20 ) with a hub ( 10 ) which is connected to the shaft ( 20 ) in a rotationally fixed but axially displaceable manner and is axially fixed between two stops by two shoulders ( 12 , 14 ) extending transversely to the shaft axis ( 18 ), wherein a spring washer ( 22 ) forms a first stop, which rests with an outer section ( 26 ) on one shoulder ( 12 ), while a radially inwardly directed section ( 32 ) is supported with an inner edge ( 24 ) on the shaft ( 20 ), in that the inner edge ( 24 ) rests resiliently on the shaft (20) in an axially fixed manner at an axial distance ( 40 ) from the shoulder ( 12 ), characterized in that the shaft ( 20 ) has a smooth surface in which the inner edge ( 24 ) of the spring washer ( 22 ) clawed. 2. Shaft ( 20 ) according to claim 1, characterized in that the inner edge ( 24 ) of the spring washer ( 22 ) is embossed into the surface of the shaft ( 20 ). 3. Shaft ( 20 ) according to claim 1 or 2, characterized in that at least the inner edge ( 24 ) of the spring washer ( 22 ) is harder, at least on the surface, than the surface of the shaft ( 20 ) at the mounting point of the spring washer ( 22 ). 4. Shaft ( 20 ) according to claim 1 or 2, characterized in that the material of the spring washer ( 22 ) is harder than that of the shaft ( 20 ). 5. Shaft ( 20 ) according to one of the preceding claims, characterized in that the inner edge ( 24 ) of the inwardly directed portion ( 32 ) is sharp-edged. 6. Shaft ( 20 ) according to one of the preceding claims, characterized in that the inner edge ( 24 ) of the inwardly directed portion ( 32 ) encloses an angle (α) of less than or equal to 90°. 7. Shaft ( 20 ) according to one of the preceding claims, characterized in that the inwardly directed portion ( 32 ) of the spring washer ( 22 ) is formed by spring tongues ( 42 ). 8. Shaft ( 20 ) according to one of the preceding claims, characterized in that the inner diameter of the spring washer ( 22 ) before assembly is 3% to 8% smaller than the outer diameter of the shaft ( 20 ) at the mounting location of the spring washer ( 22 ). 9. Shaft ( 20 ) according to one of the preceding claims, characterized in that the inner diameter of the spring washer ( 22 ) before assembly is 4% to 7% smaller than the outer diameter of the shaft ( 20 ) at the mounting location of the spring washer ( 22 ). 10. Shaft ( 20 ) according to one of the preceding claims, characterized in that the inner diameter of the spring washer ( 22 ) before assembly is 5% smaller than the outer diameter of the shaft ( 20 ) at the mounting location of the spring washer ( 22 ). 11. Shaft ( 20 ) according to one of the preceding claims, characterized in that the surface of the shaft ( 20 ) has an average roughness depth of 1 µm to 250 µm. 12. Shaft ( 20 ) according to one of the preceding claims, characterized in that the surface of the shaft ( 20 ) has an average roughness depth of 4 µm to 63 µm. 13. Shaft ( 20 ) according to one of the preceding claims, characterized in that the outer portion ( 26 ) has an axially bent collar ( 44 ) which points away from the shoulder ( 12 ). 14. Shaft ( 20 ) according to one of the preceding claims, characterized by the use in an electric motor transmission unit, in particular for adjusting equipment parts such as window lifters and sliding roofs in motor vehicles.