EP2235801A1

EP2235801A1 - Retaining element for a commutator sliding contact of an electric motor and electric motor

Info

Publication number: EP2235801A1
Application number: EP08864586A
Authority: EP
Inventors: Armin Stubner; Martin Heyder; Norbert Martin
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2007-12-20
Filing date: 2008-10-27
Publication date: 2010-10-06
Also published as: DE102007061745A1; KR101518797B1; WO2009080391A1; CN101904059B; KR20100106397A; JP5553768B2; JP2011507474A; CN101904059A

Abstract

The invention relates to a retaining element (1) for a commutator sliding contact (2) of an electric motor (4), comprising a spring section (5) that can be biased by means of bending. The invention provides that the spring section (5) is configured such that when the same is biased, the edge fiber tensions are at least approximately constant in the longitudinal direction in at least one partial section (6) of the spring section (5) extending in the longitudinal direction, preferably in the entire spring section (5).

Description

description

title

Holding element for a Kommutatorschleifkontakt an electric motor and electric motor

State of the art

The invention relates to a holding element for a commutator sliding contact of an electric motor according to the preamble of claim 1 and to an electric motor according to claim 12.

There are known as hammer brushes in which a Kommutatorschleifkontakt (carbon brush) is held on a spiral spring and is spring-loaded by this in the radial direction on a commutator. In this case, the bending spring is clamped with its remote from the sliding contact end in a carrier part (brush holder). In the bending spring arise in a deflection inhomogeneous fiber tension, which brings with it the risk of damage to the spiral spring in the region of the clamping by plastic deformation. In particular, after mounting the known hammer brushes, it is no longer possible to axially guide a ball bearing, which is fastened to the armature of the electric motor and has a larger diameter than the commutator, through a carrier part with the hammer brushes fixed thereto. As a result, a radial mounting direction of the support member with the hammer brushes is mandatory.

From WO 2004/051825 Al a hammer brush construction is known in which a defined contact force is to be generated by rolling a spring lever at a predetermined stop. Again, due to inhomogenous NEN fiber tensions the risk of damage to the spring lever in the region of the clamping, so that over-bending of the spring lever for mounting an axle-fixed ball bearing with a larger cross-section than the commutator is not possible.

DISCLOSURE OF THE INVENTION Technical Problem

The invention has for its object to propose a holding element for a Kommutatorschleifkontakt, in which the risk of damage is minimized by overbending. Furthermore, the object is to propose an electric motor with a correspondingly optimized holding element.

Technical solution

This object is achieved with regard to the retaining element with the features of claim 1 and with respect to the electric motor with the features of claim 11. Advantageous developments of the invention are specified in the subclaims. All combinations of at least two features disclosed in the description, the claims and / or the figures fall within the scope of the invention.

The invention is based on the idea of designing the spring section of the retaining element in such a way that the edge fiber stresses of the spring section are at least approximately constant in at least one section of the spring section. Preferred is a design of the spring Section, in which the edge fiber stresses are not only constant in a section of the spring portion in the longitudinal direction, but along the entire longitudinal extent of the spring portion. In other words, the spring section according to the invention is designed such that both the tensile stresses in the region of the largest bending radius and the compressive stresses in the region of the smallest bending radius in the longitudinal direction of at least one section, the flat, plate-shaped, spring section considered are constant. Of course, the fiber stresses are viewed transversely to the longitudinal extent and at least approximately zero in the region of a neutral fiber. An at least approximately constant edge-fiber stress iS of the invention is understood to mean a fiber tension which is essentially constant at every position in the longitudinal direction, ie deviates less than 10% from a fiber tension centered in the longitudinal direction. Preferably, the deviation is less than 5%, more preferably less than 1%. Particularly preferred is an embodiment of the spring portion of the holding element, wherein the spring portion, at least a portion of the spring portion, even then has constant Randfaserspannungen in the longitudinal direction, if the spring portion, for example, for mounting an axle-fixed ball bearing beyond the normal Vorspannungsmaß radially stretched on the outside, that is overstretched. A designed according to the concept of the invention retaining element with a spring portion formed as described has significant advantages over known holding elements. Thus, the risk of damage to the spring portion of the retaining element in a mounting region compared to known holding elements is substantially reduced, especially when the spring portion for Mounting an axle-fixed ball bearing with a larger diameter than the diameter of the commutator is over-springed. Plastic deformations are avoided due to longitudinally constant marginal fiber stresses and thus optimized strength. In addition, defined contact forces of the sliding contacts (carbon brushes) and angle of attack of the holding element for the operating case and over the life, ie at gradually verschleißendem Kommutatorschleifkontakt ensured. Furthermore, the angle of attack and the bearing force of the sliding contact are much less subject to tolerances than known holding elements, which consist of a plurality of components.

In a development of the invention, it is advantageously provided that, if the edge fiber stresses are not constant over the entire longitudinal extension of the spring section, a constant fiber tension of at least 90% of the total length of the spring section is achieved. In particular, the edge fiber tension is to be immediately adjacent to a fastening section with which the retaining element is fixed in a carrier part, at least approximately, preferably being exactly constant. An attachment of the holding element preferably takes place by clamping into a carrier part (brush carrier).

One possibility for the realization of edge fiber stresses which are at least approximately constant in the longitudinal direction is to form the spring section, but at least a partial section of the spring section, such that the width extension b (x) of the partial section or the entire spring section formed by solid material each position x along the length of the following formula obeys:

In this case, a width extension formed from solid material is understood to be the width extension completed by solid material, preferably a constant thickness extension, i. the width extension formed by solid material takes into account any recesses provided in the spring section, in particular breakthroughs. In the formula given above, Io is the length of the subsection with a constant edge fiber tension or the entire length of the spring section if the edge fiber tension is to be constant over the entire longitudinal extension of the spring section. The constant bo is the width extension of the partial section or of the entire spring section formed by solid material at an end facing away from the sliding contact, ie in a region immediately adjacent to a clamped region of the spring section or directly to a fastening section of the retaining element. The value bo is thus that of solid material, i. Width taken along the longitudinal direction furthest away from the grinding contact, without the consideration of recesses, of the region of the spring section. The variable x is a longitudinal extension coordinate and describes any position along the longitudinal extension of the subsection or the entire spring section.

If the spring section or the partial section of the spring section is formed exclusively of solid material, an above-mentioned subordinate section will taper or spring section in the longitudinal direction to the holding portion, ie its width extension decreases seen in the longitudinal direction, preferably linearly from. Particularly preferred is a symmetrical design of the spring section or of the partial section with respect to a longitudinal central axis (symmetry axis) of the partial section or of the spring section.

In particular, in the case of a partial section or spring section formed from solid material, a contour that tapers trapezoidally in the direction of the commutator sliding contact results.

If recesses, in particular in the form of apertures, are provided within the spring section or the partial section of the spring section, almost any circumferential contours of the partial section or of the spring section can be realized, as long as the width extension formed by solid material in the longitudinal direction of the partial section or the spring section considered decreases toward Kommutatorschleifkontakt.

Thus, in a further development of the invention, it can be realized, for example, that the actual width of the partial section and / or of the spring section is at least approximately constant in the longitudinal direction. This can be realized, for example, by broadening a preferably symmetrical inner recess in the longitudinal direction towards the commutator sliding contact. Particularly preferred is an embodiment in which the recess, in particular symmetrically widened in a triangular or trapezoidal manner towards the commutator grinding contact, in particular such that the solid material formed by The width extension adjacent to the recess obeys the previously described formula.

In order to ensure a defined relative position between the commutator loop contact and the rotating commutator against which the commutator contact contacts, an embodiment is preferred in which a holding section holding the commutator contact, in particular clamping, has a rigid, ie. non-resilient ground plane. Preferably, this ground plane or footprint is instantaneous, i. seamless over into the spring portion of the holding element.

Of particular advantage is an embodiment in which the spring section merges at its end facing away from the Kommutatorschleifkontakt end in a mounting portion with which the holding element is fixed in an electric motor, in particular in a support member (brush holder). Preferably, the attachment portion is equipped with a latching geometry and / or a lug geometry to allow a defined setting of the holding element in the, preferably made of thermoplastic material, carrier part. Additionally or alternatively, the retaining element can be clamped with its attachment portion in the support part and / or embossed by energy input in the form of heat or ultrasound at the attachment point. An undercut formed in this way prevents slipping out of the retaining element from its mounting position.

The invention also leads to an electric motor with a rotatably connected to an armature shaft commutator to which at least one Kommutatorschleifkontakt rests, in a holding element formed according to the concept of the invention is held. The electric motor preferably has an armature shaft-fixed ball bearing, in which the mounting is axially pushed axially through a carrier part having a plurality of holding elements each having a commutator grinding contact, during which the holding elements are overstretched. The assembly method described should be disclosed as an independent invention and claimed separately.

Brief description of the drawings

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawings. These show in:

1 is a side view of a prestressed holding element,

2 is a perspective view of the holding element ge ^¬ according to FIG. 1,

Fig. 3 federkraftbeaufschlagen a section of an electric motor, in which sev- eral holding elements are arranged in a plastic support part and each have a Kommuta ^¬ torschleifkontakt a commutator in a radial inward direction, and

Fig. 4 shows an alternative embodiment of a holding ^¬ element in which the spring portion seen in the longitudinal ^¬ extension has a constant overall width. Embodiments of the invention

In the figures, the same components and components with the same function with the same reference numerals.

1 and 2, a holding element 1 for a Kommutatorschleifkontakt 2 shown in Fig. 3 is shown. With the aid of the holding element 1, the commutator sliding contact 2 is spring-loaded in the radial direction inwardly on a rotatably arranged commutator 3 of an electric motor 4.

The holding element 1 shown in FIGS is formed as a one-piece stamped and bent part made of metal, here from a spring plate. The holding element 1 comprises a flat spring section 5, which is biased in the state shown in FIGS. 1 and 3 by bending transversely to its longitudinal extent. In this case, the angle of attack α marked in FIG. 3 determines the contact force F _A , with which the commutator sliding contact 2 rests on the outer circumference of the commutator 3.

The spring section 5 is designed such that the edge fiber stresses of a subsection 6 of the spring section 5 are at least approximately constant in the longitudinal direction of the subsection 6. In the section 6 with the length Io, the spring section 5 tapers in the direction of the holding section 7, ie its width formed from solid material (transversely to the longitudinal extension) decreases symmetrically with respect to a non-illustrated longitudinal central axis. In this case, the width b (x) formed by solid material obeys each position x along the longitudinal extension of the subsection 6 of the formula b (x) = ^ - (l _o -x).

This results in a trapezoidal contour of the partial section 6 formed completely from solid material in FIGS. 1 to 3.

As can be seen from FIG. 2, the length Io of the partial section 6 essentially corresponds to the total length of the spring section 5 - the length Io of the partial section 6 is shorter than the total length of the spring section 5 only by the minimum distance a Holding portion 7 adjacent region (length a) of the spring portion 5 takes the width not linearly as viewed in the section 6 in the direction of the holding section 7, but even by the provision of outwardly curved transition radii 8. The disadvantage of non-constant edge fiber stresses is accepted in the boundary region of the minimum length a to the holding section 7 in the embodiment shown in order to avoid loss of strength due to a notch effect that would occur if the spring section 5 sharp or with minimal transition radii in the holding section 7 would.

As is apparent from FIGS. 1 and 2, the spring portion 5 is adjacent to its in the drawing plane left end 9, at which its width is bo, to a mounting portion 10, which in the embodiment shown a tab for sliding on a Haltedom 11th (see Fig. 3). At the marked by the arrows 12, 13 points 12, 13, the support member 1 is supported in the carrier part 14 shown in FIG. 3 made of plastic. In this case, the point indicated by the arrow 13 coincides with the left in the drawing plane, ie, facing away from the holding section 7 end 9 of the spring portion 5 together. Alternative embodiments of the attachment portion 10, for example with a detent geometry, are also feasible. Additionally or alternatively, the attachment portion 10 can be embossed with the support member 14.

At the end 15 facing away from the end 9 of the spring section 5 goes over into a rigid, i. Non-resilient ground plane 16 of the holding portion 7. Along both longitudinal sides of the holding portion 7 protrude outward resilient curved side walls 17, which serve for lateral guidance of Kommutatorschleifkontaktes, which is received in a through hole 18, the rigid ground plane 16 penetrated. The passage opening 18 is bounded laterally by four spring tabs 19 which are each offset by 90 ° and which receive the commutator sliding contact 2 in a clamping manner between them. The spring tabs 19 extend in the direction of curvature of the holding element 1, whereas the side walls 17 are directed in an opposite direction.

In Fig. 3, the support member 14 (brush holder) with three holding elements 1 is shown. Wherein the three holding elements 1 each hold a Kommutatorschleifkontakt 2 by clamping and spring-loaded in the radial direction inwardly with a spring force on the non-rotatably connected to a not shown armature shaft commutator 3. In the illustrated electric motor 4 is a between two power levels switchable electric motor, wherein the holding elements 1 shown in the right half of the drawing are arranged such that a targeted Fehlkommutierung can be realized.

4, an alternative embodiment of a holding element 1 is shown. In this holding element 1, the total width of the spring section 5 is constant and corresponds at each position x along the longitudinal extension of the spring section 5 of the starting width bo. Nevertheless, the width extension of the spring section 5 formed by solid material is reduced in the longitudinal direction of the spring section 5 towards the holding section 7. The width extension formed by solid material obeys at least approximately the formula:

This is realized in the exemplary embodiment shown by the fact that a longitudinally extending recess 20 is arranged in the spring section 5, which is contoured in a triangular shape and the width of which increases linearly in the longitudinal direction of the spring section towards the holding section 7. The width extension b (x) formed by solid material is obtained at each position x by adding the partial widths bi (x) and b2 (x).

Claims

claims

A holding element for a commutator contact (2) of an electric motor (4), comprising a spring section (5) which can be prestressed by bending,

characterized,

in that the spring section (5) is designed such that, when this is pretensioned, the edge fiber stresses are at least approximately constant in the longitudinal direction in at least one longitudinally extending partial section (6) of the spring section (5), preferably in the entire spring section (5) are.

2. Retaining element according to claim 1, characterized in that the length (lo) of the subsection (6) corresponds to at least 90% of the total length of the spring section (5).

3. Retaining element according to claim 1, characterized in that b (x) of the partial section (6) or of the spring section (5) is formed at each position x along the longitudinal extension of the partial section (6) for the width extension b formed by solid material. or the spring section (5) applies:

where O is the length of the subsection (6) of the spring section (5) or the overall length of the spring section (5) and B o is the width formed by solid material. Extension of the section (6) at its end facing away from the Kommutatorschleifkontakt (2) (9, 15) or the solid material formed by the width extension of the spring portion (5) at its from the commutator loop contact (2) facing away from the end (9, 15) ,

4. Retaining element according to claim 3, characterized in that the solid width formed by solid material b (x) of the subsection (6) and / or the spring section (5) decreases in the longitudinal direction towards the commutator contact (2) decreases.

5. Retaining element according to one of the preceding claims, characterized in that the partial section (6) and / or the spring section (5) are contoured trapezoidal / is.

6. Retaining element according to one of the preceding claims, characterized in that in the partial section (6) and / or in the spring section (5) at least one recess (20) is provided.

7. Retaining element according to claim 6, characterized in that the actual width of the subsection (6) and / or the spring section (5) viewed in the longitudinal direction is constant / is.

8. Retaining element according to one of claims 6 or 7, characterized in that the recess (20) viewed in the longitudinal direction towards the Kommutatorschleifkontakt (2) transversely to its longitudinal extent, preferably triangular or trapezoidal, widening is formed.

9. Retaining element according to one of the preceding claims, characterized in that on the spring portion (5) adjacent, preferably a rigid base plane (16) exhibiting, holding portion (7) for, in particular clamping, holding the Kommutatorschleifkontaktes (2) is provided.

10. Retaining element according to claim 9, characterized in that the spring section (5) is viewed in the longitudinal direction between the holding section (7) and a preferably strap-shaped fastening section (10) for securing the holding element (1) in an electric motor (4). , in particular in a carrier part (14) is arranged.

11. Electric motor with a commutator (3) on which at least one commutator contact (2) is applied, which is held by a holding element (1) according to one of the preceding claims.