DE9418971U1 - Low-friction supported compression spring - Google Patents

Description

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INA Rolling Bearings Schaeffler KG, 91072 Herzogenaurach

ANR 17 17 332

2688-11-EN

Low-friction compression spring

The invention relates to a torsion spring supported with low friction in a locking element, in particular according to the features forming the preamble of claim 1.

A locking element of this type is known from DE-A 42 36 685, in which at least one end of the compression spring rests on the base of a bushing or in the guide part via a bearing, designed as a roller or plain bearing, to reduce friction. Such a compression spring support represents an effective measure for reducing friction and thus improves the function of the locking element. Free rotation of the guide element is particularly necessary when it interacts with a locking bracket that engages it radially. However, the use of a bearing leads to an increase in costs, which is often not accepted for locking elements produced in large quantities.

The object of the invention is therefore to realize a cost-effective torsion spring support that:

a) is designed to optimize installation space and reduces the number of components;

b) which, held captive on a conventional torsion spring or in the locking element, enables easy installation.
35

According to the invention, this object is achieved by the characterizing parts of claims 1 and 6.

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According to the invention according to claim 1, at least one spring end is formed centrally to the compression spring in such a way that a point support is established on the base or on the front side in the guide part. This results in a cost-effective compression spring support that reduces friction, through which the spring length and thus the required installation space can be reduced in an advantageous manner, or the compression spring can be extended with the same installation space. In addition, a reduction in components results, which can prevent incorrect assembly due to components not being used.

The embodiment of the invention according to claims 2 and 3 provides a compression spring with a spring end that, pointing in the axial direction, is semicircularly shaped or is directed straight towards the center of the torsion spring, whereby the formation ensures a point contact arranged centrally to the torsion spring.

According to claim 4, both ends of the compression spring are shaped in such a way that a point-like contact is created, whereby the design of the spring ends depending on the existing circumstances or installation conditions can be the same or can differ from one another.

According to claim 5, at least one spring end is supported on a curvature that is provided on the front side in the guide part or on the base of the bushing. The curvatures formed by mechanical processing or in the deep-drawing process can also be produced inexpensively and do not require any additional parts.

It is expedient, according to claim 6, to arrange a shaped disk between the spring end and the curvature, which provides low-friction spring support and also prevents disadvantageous tilting of the compression spring.

The invention according to claim 7 provides that the compression spring is assigned a separate component for point support, which rests against the compression spring or its contact surface. According to the invention, the separate component can follow the rotational movement of the compression spring or be positioned in a rotationally rigid manner. This design enables the use of a

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conventional torsion spring without specially arranged spring ends. Furthermore, this invention facilitates assembly by captively attaching the separate component to the compression spring or its contact surface.

The embodiment of the invention according to claim 8 provides a guide disk or a support housing which is fastened to at least one spring end in a force-fitting and/or form-fitting manner and the guide disk or the support housing is curved to match the contact side of the compression spring, e.g. rounded like a dome.

According to claim 9, a shaped disk is provided which is inserted into the bore of the guide part or is centered on the base of the bushing and is curved towards the compression spring to form a point-like contact for the compression spring. To prevent loss during assembly, the shaped disk can also be pressed into the bore or permanently attached to the base.

Claim 10 provides for a molding of the end turn of the compression spring, which follows a circular or spiral course offset radially inwards and has a short, straight end piece that extends beyond the middle of the compression spring. In order to manufacture the support housing or the shaped disk cost-effectively, claim 10 provides for these to be manufactured from sheet steel using a deep-drawing process.

The invention is explained in more detail below in the description of the figures using exemplary embodiments with reference to the drawings.

Figures 1 to 4 show locking elements with identical designs with different supports for the compression spring. They show:

Figure 1 shows a compression spring which is supported on the one hand by an arcuate end and on the other hand by an insert with a rounded support;

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2688-11-EN

Figure 2: Support elements of the same design, rounded towards the outside, formed on the sheet metal, which are attached to the end of the compression spring;

Figure 3 on the bottom and in the inner bore of the guide part

adjacent support elements, on whose curved contact surface the compression spring is supported;

Figure 4 a compression spring with spring ends pointing inwards towards the spring centre, which are attached to a curved base

or, rest against a curvature of the front side in the guide part;

Figure 5 shows a locking element in which a spring end is centered in a funnel of the guide part and the white

The other end of the spring rests against the curvature via a shaped disk.

Figure 1 shows a locking element 1 in section, which is screwed into a gearbox housing with an outer part 2 via an external thread 3, e.g. The external thread is limited on one side by an external hexagon that projects radially outwards via the external thread 3. The outer part 2 is provided with a continuous inner bore 4, into which a position-fixed bushing is inserted, the inside of which serves as a raceway for a roller bearing 6 of the locking bolt 7. The locking bolt 7 is composed of a guide part 8, the outer surface of which serves as a counter-raceway for the roller bearing 6 and which has a bore 9 designed as a blind hole for receiving a compression spring 10, which on the other hand is supported on a base 11 of the bushing 5. The guide part 8 has, at its end opposite the bore 9, a roller-bearing locking element 13 which is inserted into a recess 12 and is fixed in position by a retaining plate 14. To achieve a travel limit of the locking bolt 7, a projection 15 is used which comes into contact with an end stop 16. To advantageously improve the rotational mobility, i.e. low-friction support, of the locking bolt 7, the torsion spring 10 has, at the end facing the base 11, an almost semicircular locking element in the middle of the

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Compression spring 11 has a spring end 17 arranged thereon. At the opposite end, the compression spring 10 rests against a shaped disk 18, which supports each other with a curved outer surface on a front side 19 of the bore 9.
5

In further embodiments (Figure 2 to Figure 5) of a locking element 1 according to the invention, the components that correspond to the first embodiment are provided with the same reference numbers, so that with regard to their description, reference can be made to the description of the first embodiment.

In Figure 2, the compression spring 30 rests with the spring end 37 on the front face 19 of the guide part 8 via a support housing 28 inserted at the end of the bore 9 designed as a blind hole. The support housing 28, designed as a hollow body and produced by a deep-drawing process, has a cylindrical section which the end turn of the compression spring 30 encloses in a force-fitting and/or form-fitting manner. On the cylindrical section pointing in the direction of the front face 19, the support housing 28 has a section which radially covers the outer contour of the compression spring 30 to form a contact surface for the compression spring 30, to which an outwardly curved base is connected to achieve a low-friction point contact on the front face 19. To center the support housing 28 in the bore 9, the guide part 8 is narrowed radially inwards in the end region. A further support housing 28 is inserted at the opposite end of the compression spring 30, which rests on the base 11.

The compression spring 40 shown in Figure 3 has spring ends 47 that are angled inwards almost at right angles to the longitudinal axis of the spring and point towards the center of the compression spring 40. The spring ends 47 are each supported on a curved base of a shaped disk 38 that is directed in the direction of the compression spring 40. The shaped disk 38 is centered in the bore 9 or on a step 39 of the base 11 via a cylindrical section.

The locking element 1 in Figure 4 has a compression spring 40 according to Figure 3. The spring ends 47 are supported directly in the guide part 8

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on a curvature 46 which is provided on the front side 19 and on the curvature 49 of the base 11. This installation space also enables a point-based, low-friction support of the torsion spring 40 without intermediate separate components.
5

Figure 5 shows the compression spring 60 with a spring end 57 that is shaped radially inwards and with a section that axially coincides with the longitudinal axis of the compression spring 60 is supported in a funnel 59 arranged centrally in the front side 19. A shaped disk 58 is arranged on the opposite spring end 57 and is supported on the curvature 49 of the base 11.

2688-11-EN

Reference symbols 1 locking element 30 compression spring 2 Exterior part 37 Spring end 3 external thread 38 Form disc 4 Internal bore 40 compression spring 5 socket 46 Curvature 6 Rolling bearings 47 Spring end 7 Locking base 49 Curvature 8 Guide part 50 compression spring 9 Bore 57 Spring end 10 compression spring 58 Form disc 11 Floor 59 funnel 12 Recess 60 compression spring 13 Locking element 14 Retaining plate 15 Approach 16 End stop 17 Spring end 18 Form disc 19 Front side 28 Support housing

Claims (11)

INA Wälzlager Schaeffler KG, 91072 Herzogenaurach ANR 17 17 332 2688-11-DE Claims 1. Low-friction supported compression spring in a locking element, which is used in particular for fixing the position of axially displaceable and/or pivotable adjusting elements, such as. B. selector shafts of transmissions, wherein the locking element has an outer part with a bore for receiving a guide part, which, at the end pointing in the direction of the adjusting element, is provided with a preferably spherical locking element which engages in a recess in the selector rod and the compression spring is supported on a front side of the guide part facing away from the locking element on a base of the outer part, wherein at least one compression spring system is designed to reduce friction, characterized in that the compression spring (10, 30, 40, 50, 60) is supported at certain points on the base (11) or on the front side (19) in the guide part (8) via at least one spring end (17, 37, 47, 57) formed centrally to the compression spring (10, 30, 40, 50, 60). 2. Low-friction supported compression spring according to claim 1, characterized in that the compression spring (10) is supported by a semicircular spring end (17) aligned axially in the direction of a longitudinal axis of the compression spring (10) (Figure 1). 3. Low-friction supported compression spring according to claim _{1 1} , characterized in that a spring end (57) is shaped to point towards the center of the compression spring (60) and is centered in a funnel (59) of the guide part (8) with an end section aligned in a straight line in accordance with the longitudinal axis of the compression spring (40, 50) (Figure 5). 4. Friction-reduced compression spring according to claim I ₁ , characterized in that both spring ends (47) of the compression spring (50) are almost point- 2688-11-EN 2 form on the base (11) or on the front side (19) of the guide part (8). 5. Low-friction supported compression spring according to claim 1, characterized in that one spring end (47) is supported on a curvature (46) of the front side (19) and the other spring end (47) is supported on a curvature (49) integrally connected to the base (11) (Figure 4). 6. Low-friction supported compression spring according to claim 1, characterized in that the compression spring (60) rests against the curvature (49) via a shaped disk (58) centered on the spring end (57) (Figure 5). 7. Low-friction supported compression spring according to the preamble of claim 1, characterized in that the compression spring (10, 30, 40, 60) is assigned a separate component for point-like support, which rests on the compression spring (10, 30, 40, 60) or its contact surface, wherein the separate component follows the rotational movement of the compression spring (10, 30, 40, 60) or is positioned in a rotationally rigid manner. 8. Low-friction supported compression spring according to claim 7, characterized in that a shaped disc (18) or a support housing (28) is held in a force-fitting or form-fitting manner at one spring end (17, 37), which is rounded towards the contact side (Figure 1, 2). 9. Low-friction supported compression spring according to claim 7, characterized in that the compression spring (40) is provided with a shaped disk (38) pressed into the bore (9) of the guide part (8) and/or centered on the base (11) (Figure 3). 10. Low-friction supported compression spring according to claim 1 or 7, characterized in that a spring end (37, 47) of the compression spring (40, 50) forms an inwardly offset circular or spiral support which is aligned at right angles to a longitudinal axis of the compression spring (40, 50) (Figures 3, 4). 11. Low-friction supported compression spring according to one of claims 7 to 9, characterized in that the shaped disk (18), the support housing (28) and the shaped disk (38) are made from a steel sheet by a deep-drawing process 1.1 bar .s in.d.