DE102012210471B4 - Spring claw for radial and axial fixation of rotationally symmetrical elements - Google Patents

Abstract

Spring claw (10) for fixing an electric motor (41) having a connecting section (25) and several spring elements (35) with a clamping section (50), - the clamping section (50) at an end of the spring elements (35) facing away from the connecting section (25) ) is arranged, - an actuating section (55) is provided on each individual spring element (35) between the connecting section (25) and the clamping section (50), - wherein a contour of the individual spring elements (35) is designed such that the spring elements (35) expand in their contour when force is exerted on the actuating section (55), the spring elements (35) being arranged radially on the outside on the connecting section (25) and having spring sections (30) which are opened up by an axial force acting on the actuating section (55 ), where the force is created by contact with an actuating surface (45), expand in their contour, so that the spring claw (10) on the clamping abs Section (50) has an enlarged diameter or radius compared to a first state, characterized in that a fastening section (20) is arranged radially on the inside of the connecting section (25), and that each individual spring element (35) has an arcuate contour.

Description

The invention relates to a spring claw and a device with such a spring claw according to the preamble of the independent claims 1 and 7.

State of the art

From the DE 44 47 880 B4 a spring claw for an electric motor is known, which has a newly formed connecting portion and a spring element with a clamping portion, wherein the clamping portion is disposed radially outwardly on the spring element. The clamping portion is attached to a side facing the connecting element of the spring element. To mount the spring claws, a mounting tool is necessary, so that the spring element is compressed or expanded to use the spring claw for attachment of magnets of an electric motor.

The WO 2012/022731 A2 shows a spring claw with spring elements extending axially from a connecting portion.

The DE 694 24 282 T2 and the DE 100 21 404 C2 disclose a circlip having a circular connection portion. The connecting portion has radially inwardly and outwardly extending tabs. The radially inwardly directed tabs intersect into a shaft.

The US 3,484,016 A . US 3,934,745 A and the US 4,180,178 A show bottle caps, which have a closed connection area. Further, the lid is not intended to connect a housing to a shaft.

Disclosure of the invention

It is an object of the invention to provide a spring claw, which makes it possible without assembly tool even in hard to reach positions in a housing, an electric motor easy to assemble and can compensate in addition component tolerances of components.

This object is achieved by means of the features of claim 1. Advantageous embodiments are given in the dependent claims.

An inventive spring claw for the radial and axial fixation of a first and a second elements comprises a connecting portion and at least one arcuate spring element with a clamping portion. The spring element is arranged radially on the outside at the connecting portion, wherein the clamping portion is arranged on the end remote from the connecting portion of the spring element and facing the connecting portion. Between the connecting portion and the clamping portion, an actuating portion is provided on the spring portion, which faces away from the clamping portion. In this case, a contour of the spring portion is formed such that expands in an axial force on the operating portion of the spring portion in its arc shape or contour and deformed back reversibly in a starting position at a decrease in the axial force. Thus, the spring claw jammed on the first element and the first and the second element are clamped together. As a result, the spring claw on the clamping section has an enlarged diameter or radius relative to the first state and at least partially surrounds the first element. In the assembled state, the spring claw has a residual stress with which the spring claw braces itself between the two elements.

This has the advantage that the spring claw can be easily fixed on the component to be mounted and placed in an installation space of a housing. Upon contact with an actuating surface, such as a bottom of the installation space with the actuating portion and a corresponding axial force, the spring portion is widened and can encompass another component such as a stator of an electric motor or the housing of the electric motor and fixed thereto. Due to the contact with the actuating surface, the assembly of the spring claw can be done without tools. Furthermore, component tolerances between further elements of a device, in particular an electric motor, can thus be compensated for in particular between housing and stator in the axial direction.

It is particularly advantageous if the clamping section is arranged on a side surface of the spring element facing the connection section and the actuation section is arranged on a side surface of the spring element facing away from the clamping section.

In a further embodiment, a fastening portion is provided on the connecting portion radially inwardly, which is aligned substantially perpendicular to the connecting portion. In this way, the orientation of the spring claw on a cylinder portion of a housing part or a shaft can be easily determined, and tilting of the spring claw can be avoided during assembly.

In a further embodiment, the spring portion has a parabolic contour. This is particularly well suited to the spring portion upon contact of the actuating portion with a expand another component with particularly axial low force.

In a further embodiment, the spring element has a radially inner first rectilinear region and a subsequently radially outwardly arranged arcuate region on which an actuating section is arranged, wherein the arcuate region is followed by a rectilinearly formed second region. This embodiment of the spring claw can be widened particularly easily in order to grasp a further element with little axial effort and to fix the spring claw so reliably to this further element.

In another embodiment, the spring claw is formed in one piece and of the same material, so that the spring claw is easy to produce in a punching and bending process.

The object is also achieved by the features of a device according to claim 7. Advantageous embodiments are given for this purpose in the dependent claims.

A device according to the invention comprises the above-described spring claw, a first element and a second element. The spring claw is disposed on the first member, the actuating portion facing a corresponding actuating surface of the second member. This is designed to actuate the actuating portion of the spring element in an axial force, so that the spring portion widens and engages around the first element. When the axial force decreases, the spring claw clamps firmly to the first element and advantageously ensures a tolerance compensation and a preload between the first and the second element.

It is particularly advantageous if the first element is a stator of an electric motor and the second element is a housing of the electric motor.

Alternatively, it is particularly advantageous if the first element is a control motor of a throttle valve of an internal combustion engine and the second element is a housing for receiving the control motor to an intake passage of an internal combustion engine.

The invention will be explained in more detail with reference to figures. Showing:

1 a perspective view of a spring claw;

2 a sectional view through an electric motor with the in 1 shown feather claw;

3 a section of the in 1 shown electric motor;

4 in the 1 shown feather claw in an assembled state; and

5 in the 2 shown feather claw in the installed state.

1 shows a perspective view of a spring claw 10 in unassembled condition. 2 shows a sectional view through an electric motor with the in 1 shown feather claw 10 and 3 a section (shown in dotted lines) of the 2 marked section, with the feather claw 10 in a first state corresponding to a mounting state (shown in phantom), and in a perspective view in FIG 4 is shown and shown in a second state, which corresponds to an installation state (shown by a solid line) and in a perspective view in 5 is shown. Due to the design of the spring claw 10 or the device with the spring claw 10 will the 1 to 5 explained below together. Also, the same reference numerals are used for the same components.

The feather claw 10 has a longitudinal axis 15 and radially inside a mounting portion 20 on. The orientation of the attachment section 20 is substantially parallel to the longitudinal axis 15 , The attachment section 20 is in 1 by partially annular segments 21 designed. However, it is also conceivable, the attachment section 20 completely form as a closed ring. To the attachment section 20 borders a connecting section 25 radially outward lying. The longitudinal axis 15 the spring claw forms a normal of the flat in a plane formed connecting portion 25 , Close to this radially outward lying several spring elements 35 at. The feather claw 10 is formed in one piece and of uniform material. The spring elements 35 are radially outward from the connecting portion 25 from. Every single spring element 35 has an arcuate contour, wherein a survey of the arcuate contour of the spring portion 30 from the plane of the connection section 25 in the direction of the longitudinal axis 15 he follows.

In an unstressed mounting condition ( 2 . 3 dashed lines) has the spring claw 10 a smaller radial, but larger axial extent, ie in the direction of the longitudinal axis 15 , as in the tensioned installation state (in 2 . 3 shown by a solid line).

In 2 and 3 is a device with a housing 40 an electric motor 41 represented as a first element. The housing 40 is on the inside rotationally symmetrical and has an actuating surface 45 in the embodiment perpendicular to the longitudinal axis 15 the feather claw 10 is aligned. In the case 40 it may be, for example, a housing of an electric motor or a housing for a throttle valve of an internal combustion engine.

The spring element 35 the feather claw 10 includes a spring section 30 and a clamping portion 50 , the one at the longitudinal axis 15 and thus to the connection section 25 towards the first side surface 51 of the spring element 35 is arranged. On an opposite to the first side surface 51 arranged second side surface 52 of the spring element 35 , the actuating surface 45 of the housing 40 facing and the clamping portion 50 is remote, is an operating section 55 on the spring section 30 or spring element 35 intended.

The clamping section 50 is also a stator 60 of the electric motor 41 However, as a second element of the device facing and can not fully encompass it radially in its first untensioned state, so that in this mounting state of the clamping portion 50 only in a border area 61 of the stator 60 with an edge 65 of the spring element 35 on the stator 60 rests on (cf. 3 and 4 ). In the assembly becomes the stator 60 with the feather claw 10 in the case 40 introduced and absorbed by this until the actuating surface 45 of the housing 40 the corresponding operating section 55 of the spring element 35 touched. Will the stator 60 with the feather claw 10 after contact with the feather claw 10 continue with an axial insertion force for further insertion into the housing 45 acted upon, this causes the actuating surface 45 against the operating section 55 of the spring element 35 pushes and the spring section 30 widened by the axial force in its contour, so that the Federkralle 10 at the clamping portion 50 has a relation to the first state increased diameter or radius. This expansion takes place until the clamping section 50 completely the stator 60 on an outer peripheral surface 70 of the stator 60 embraces. Due to the contour of the spring element 35 in the spring section 30 Furthermore, an overlapping of the clamping portion 50 at the stator 60 radially avoided on the outside.

Is the axial insertion force after reaching the installation state of the stator 60 taken back, so relaxes the spring section 30 such in the direction of its mounting state (first state) that the clamping portion 50 by the spring element 35 to the peripheral side 70 of the stator 60 is pressed. The contact takes place with respect to the attachment section 20 in the assembled state on a housing part of the stator 60 seated. At the same time is the operating section 55 in contact with the actuating surface 45 of the housing 40 , allowing component tolerances between the stator 60 and the housing 40 be compensated. The component tolerance compensation takes place in that the spring claw 10 in the assembled state has a residual stress, with which the Federkralle 10 between the two elements mentioned above 40 . 60 that is, between the stator 60 and housing 40 , tense. As a result, the feather claw 10 the stator 60 also axially and radially in the housing 40 fixed. Also, the electric motor points 41 by the tension by means of the spring claw 10 an improved vibration behavior, since even at high induced in the axial direction vibrations of the stator 60 reliable by the spring claw 10 in the case 40 is fixed. By fixing the stator 60 by means of the spring claw 10 and the thus improved vibration behavior is also the noise of the electric motor 41 reduced. The design of the spring claw 10 offers the further advantage that even with high radial forces a reliable radial fixation takes place.

As materials are depending on the production and field of application of the spring claw 10 and the components to be fixed both high-strength materials such as spring steel, but also plastics suitable as a material.

The contact force of the spring claw 10 can depending on the purpose of the components to be fastened, here the stator 60 on the housing 40 , by the number of spring elements 35 and / or by the shape / contour of the spring elements 35 or the spring section 30 , in particular depending on the material thickness, the width in the circumferential direction of the spring claw 10 and the material can be flexibly adapted to the elements to be fixed.

Preferably, the contour of the spring portion 30 parabolic shaped. This embodiment offers the advantage that a high radial clamping force can be provided by means of a small axial insertion force.

Alternatively, it is also possible that the spring section 30 , as in 2 and 3 shown a first rectilinear area 80 which is connected to the connecting portion 25 adjoins, taking on the first area 80 radially outside an arcuate trained area 81 connects, in which also the operating section 55 is arranged, being attached to the arcuate portion 81 radially outside a second rectilinearly formed second area 85 connects, at the radially outer lying of the clamping portion 50 is arranged. This embodiment also offers the advantage of a low axial insertion force for widening the spring section 30 while providing a high contact pressure in the clamping section 50 ,

In the 2 and 3 is an example of the stator 60 in a housing 40 of the electric motor 41 both radially and axially by means of the spring claw 10 in the case 40 attached. Alternatively, other elements are suitable for using the spring claw 10 to be attached. So it is quite conceivable, an electric motor or a servomotor for controlling a throttle valve in an intake passage or housing for arrangement on an intake passage of an internal combustion engine by means of the spring claw 10 to fix.

The basis of the 1 to 5 explained feather claw 30 or the device explained represent preferred or exemplary embodiments of the invention. In addition, further embodiments are conceivable, which may comprise further modifications or combinations of features. In particular, it should be noted that the above features can be combined.

It is essential, however, that the spring claw particularly suitable for fixing rotationally symmetrical elements both in the radial and in the axial direction in rotationally symmetrical shots, such as the housing shown 40 , suitable is.

Claims (10)

Feather claw ( 10 ) for fixing an electric motor ( 41 ) comprising a connecting section ( 25 ) and several spring elements ( 35 ) with a clamping section ( 50 ), - wherein the clamping section ( 50 ) at a connecting portion ( 25 ) facing away from the end of the spring elements ( 35 ), - between the connecting section ( 25 ) and the clamping section ( 50 ) an actuation section ( 55 ) on each individual spring element ( 35 ) is provided, - wherein a contour of the individual spring elements ( 35 ) is designed such that the spring elements ( 35 ) upon application of force to the actuating section ( 55 ) in their contour, wherein the spring elements ( 35 ) radially outward on the connecting portion ( 25 ) are arranged and spring sections ( 30 ) characterized by an axial force acting on the actuating portion ( 55 ), wherein the force by a contact with an actuating surface ( 45 ) arises, widen in its contour, so that the Federkralle ( 10 ) at the clamping portion ( 50 ) has a relation to a first state enlarged diameter or radius, characterized in that at the connecting portion ( 25 ) radially inside a mounting portion ( 20 ) is arranged, and that each individual spring element ( 35 ) has an arcuate contour. Feather claw ( 10 ) according to claim 1, characterized in that the clamping portion ( 50 ) at one of the connecting sections ( 25 ) facing side surface ( 51 ) of the spring element ( 35 ) and the operating section ( 55 ) at one of the clamping portion ( 50 ) facing away from the side surface ( 52 ) of the spring element ( 35 ) is arranged. Feather claw ( 10 ) according to claim 1 or 2, characterized in that the attachment portion ( 20 ) substantially perpendicular to the connecting portion ( 25 ) is aligned. Feather claw ( 10 ) according to one of claims 1 to 3, characterized in that the contour of the spring element ( 35 ) is parabolic. Feather claw ( 10 ) according to one of claims 1 to 4, characterized in that the spring section ( 30 ) has a radially inner first rectilinear region (FIG. 80 ) and an adjoining radially outwardly arranged arcuate area ( 81 ), on which the actuating portion ( 55 ) is arranged and to which a rectilinear trained second area ( 85 ). Feather claw ( 10 ) according to one of the preceding claims characterized by a one-piece and uniform material training. Device comprising a spring claw ( 10 ) for fixing an electric motor ( 41 ) according to one of the preceding claims, a first element ( 60 ) and a second element ( 40 ), with the feather claw ( 10 ) on the first element ( 60 ) is arranged, wherein an actuating portion ( 55 ) of the feather claw ( 10 ) a corresponding actuating surface ( 45 ) of the second element ( 40 ), wherein the actuating surface ( 45 ) of the second element ( 40 ) is formed, the actuating portion ( 55 ) of a spring section ( 30 ) of the feather claw ( 10 ) in such a way that the spring section ( 30 ) of the feather claw ( 10 ) and at the first element ( 60 ) and the first and second elements ( 40 . 60 ), wherein the spring section ( 30 ) by the axial force acting on the actuating surface ( 45 ) of the operating section ( 55 ) widens in its contour, so that the Federkralle ( 10 ) at the clamping portion ( 50 ) has an enlarged diameter or radius relative to the first state, and the first element ( 60 ) at least partially engages, characterized in that the spring claw ( 10 ) in the mounted state has a residual stress, with which the spring claw ( 10 ) between the two elements ( 40 . 60 ) braced. Device according to claim 7, characterized in that the first element ( 60 ) is rotationally symmetrical, wherein the second element ( 40 ) for at least partially receiving the first element ( 60 ) is designed. Device according to claim 7 or 8, characterized in that the first element ( 60 ) as a stator of the electric motor ( 41 ), wherein the second element ( 40 ) a housing of the electric motor ( 41 ). Device according to claim 7 or 8, characterized in that the first element ( 60 ) an electric motor ( 41 ) for controlling a throttle valve, and the second element ( 40 ) is an intake passage of an internal combustion engine.

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