KR101518797B1 - Retaining element for a commutator sliding contact of an electric motor and electric motor - Google Patents

Abstract

The present invention relates to a support member (1) for a commutator sliding contact (2) of an electric motor (4) comprising a spring section (5) which can be biased by bending. According to the present invention, when the spring section 5 is biased, the edge deformation force of at least the longitudinally extending spring section 6, preferably in the longitudinal direction of the entire spring section 5, is formed at least nearly constant.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a retention element for a commutator sliding contact of an electric motor,

The present invention relates to a support member 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.

A hammer brush is known in which a commutator sliding contact is supported on a helical spring and a spring force is applied to the commutator in a radial direction by the helical spring. The end of the helical spring, away from the sliding contact, is secured within the support (brush holder). Uneven fiber stresses occur during deflection in helical springs, which causes a risk of damage due to plastic deformation in the fixed position area of the spiral spring. In particular, it is impossible for the ball bearing fixed to the armature of the electric motor, which has a larger diameter than the commutator after mounting the known hammer brush, to axially penetrate the holder portion to which the hammer brush is fixed. Therefore, the radial mounting direction of the holder portion including the hammer brush must be set in advance.

WO 2004/051825 A1 discloses a hammer brush structure in which a predetermined bearing force is to be formed by rolling a spring lever in a stopper provided in advance. In this case, too, the spring lever can not be bent to assemble the shaft fixed ball bearing, which has a larger cross section than the commutator, because of the risk of damage to the fixed area of the spring lever due to non-uniform fiber stress.

It is an object of the present invention to provide a support member for a commutator sliding contact with a minimized risk of damage due to bending. It is also an object of the invention to provide an electric motor with a correspondingly optimized support member.

This object is achieved by the features of claim 1 for the support member and by the features of claim 11 for the electric motor. Advantageous refinements of the invention are set forth in the dependent claims. The scope of the present invention includes all combinations of two or more features set forth in the detailed description, the claims and / or the drawings.

The idea of the present invention is to form a spring section of the support member such that the extreme fiber stress of the spring section is at least nearly constant in at least one section section of the spring section when viewed longitudinally. It is desirable that the design of the spring section be constant along the entire longitudinal length of the spring section, not only in the partial section of the spring section as viewed in the longitudinal direction. In other words, the spring section according to the invention has tensile stress in the maximum bending radius range and compressive stress in the minimum bending radius range when viewed in the longitudinal direction of at least one partial section of the preferably flat, plate-shaped spring section . Of course, the fiber stress is different when viewed transversely with respect to the longitudinal direction, and at least nearly zero in the neutral fiber region. In the present invention, the at least almost constant edge strain is a fiber stress which is substantially constant at any position in the longitudinal direction, that is, a fiber stress measured in the longitudinal direction and a deviation of less than 10%. Preferably, the deviation is less than 5%, particularly preferably less than 1%. When the spring section is inflated radially outward beyond the magnitude of the common reserve tension, for example for the mounting of a shaft fixed ball bearing, i.e. when it is over-expanded, at least one section section of the spring section, An embodiment of the spring section of the support member, which still has a constant edge strain in the direction of the axis of rotation, is particularly preferred. According to the concept of the present invention, a support member having a spring section formed as described above has significant advantages over known support members. If the spring section is excessively resilient for mounting a shaft fixed ball bearing with a diameter greater than the diameter of the commutator, the risk of damage to the spring section of the support member in the stationary area is significantly reduced compared to known support members. Plastic deformation is prevented due to the constant edge strain in the longitudinal direction and the associated optimized strength. Also, the prescribed bearing capacity of the sliding contact (carbon brush) and the approach angle of the support member are ensured during operation and over the life time, i.e. when the commutator sliding contact is gradually worn. In addition, the supporting force and the approach angle of the sliding contact have much less tolerance than in known support members made up of a plurality of parts.

In the improvement of the present invention, preferably, a constant fiber stress is obtained over at least 90% of the entire length of the spring section when the edge strain is not constant over the entire longitudinal length of the spring section. In particular, the edge straining force should be at least nearly, preferably exactly exactly, adjacent to the fastening section that secures the support member to the holder portion. The fixing of the supporting member is preferably carried out by fixing in a holder portion (brush holder).

The possibility of realizing an edge strain at least nearly constant in the longitudinal direction is due to the fact that the width length b (x) of the solid section material of the partial section or of the entire spring section at each position x along the length direction, A spring section, at least one partial section of the spring section,

A width length formed of a solid material means a width length filled with a solid material, preferably a constant thickness length. That is, the width length formed by the solid material does not take into account the grooves, especially the openings, placed in the spring section. Where l ₀ is the length of the section section with constant edge strain or the length of the spring section when the edge strain is to be constant over the entire longitudinal length of the spring section. The constant b ₀ is the width of the entire spring section or section of the solid material at the end remote from the sliding contact, i. E., In the fixed region of the spring section directly or directly adjacent to the fixed section of the support member. That is, the value b ₀ is the width of the region of the spring section furthest away from the sliding contact when viewed in the longitudinal direction, without considering the groove, and formed of a solid material. The variable x is the longitudinal coordinate and represents an arbitrary position along the longitudinal direction of the entire spring section or partial section.

If the spring section or the partial section of the spring section is formed solely of solid material, the partial section or spring section following the formula is tapered in the longitudinal direction towards the support section. That is, the width length of the spring section or the partial section of the spring section decreases preferably linearly when viewed in the longitudinal direction. It is particularly preferred that the spring section or the section is formed symmetrically with respect to the longitudinal center axis (symmetry axis) of the spring section or section.

In particular, a contour is formed which is tapered in a trapezoidal shape in the direction of the commutator sliding contact in a partial section or spring section formed of a solid material.

If a recess, especially in the form of an opening, is provided in the spring section or the partial section of the spring section, the width length formed by the solid material is reduced towards the commutator sliding contact when viewed in the longitudinal direction of the partial section or spring section, Almost any circumferential contour of the section can be implemented.

In an improvement of the present invention, for example, the actual width of the spring section and / or the section may be at least approximately constant when viewed in the longitudinal direction. This can be realized, for example, by preferably extending the symmetrical internal recess towards the commutator sliding contact in the longitudinal direction. Particularly preferred is an embodiment in which the recesses extend in a triangular or trapezoidal shape towards the commutator sliding contact, in particular symmetrically, such that the width dimension formed by the solid material follows the above equation close to the recess.

In order to ensure a defined relative position between the commutator sliding contact and the rotating commutator with which the commutator sliding contact comes into contact, an embodiment in which the supporting section, which specifically supports and fixes the commutator sliding contact, has a rigid, i.e., non-elastic, Do. Preferably, said base plane or base surface is directly, i.e. without seam, to a spring section of the support member.

Particularly preferred is an embodiment in which the ends of the spring section, remote from the commutator sliding contact, lead to a fixed section that secures the support member in the electric motor, in particular the holder section (brush holder). A locking structure and / or a bracket structure is preferably provided in the securing section, so that a defined support of the support member is possible, preferably in a holder part made of a thermoplastic material. Additionally or alternatively, the securing section of the support member is fixed to the holder portion and / or is stamped at a fixed position by energy introduction in the form of heat or ultrasonic waves. The resulting undercut prevents the support member from slipping off from the mounting position.

The present invention also relates to an electric motor having a commutator connected to an armature shaft that is non-rotatably connected to at least one commutator sliding contact supported on a support member formed in accordance with the sphere of the present invention. Preferably, the electric motor has an armature shaft fixed ball bearing, wherein the bearing member is excessively expanded while being axially moved by the holder portion including a plurality of support members having respective commutator sliding contacts upon mounting . The above-described mounting method is disclosed as an independent invention and may be separately claimed.

Other advantages, features and details of the present invention will be described with reference to the drawings in the following description of the preferred embodiments.

In accordance with the present invention, there is provided an electric motor having a support member for a commutator sliding contact and a correspondingly optimized support member, wherein the risk of damage by bending is minimized.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a side view of a supported member (undergoing a preliminary tension).
Figure 2 is a perspective view of the support member according to Figure 1;
Figure 3 is a partial view of an electric motor in which a plurality of support members are disposed in a plastic holder portion and the support members apply spring resilience radially inwardly toward the commutator in each commutator slide contact.
Figure 4 shows an alternative embodiment of a support member having a constant overall width when viewed in the longitudinal direction.

In the drawings, identical parts and parts having the same function have the same reference numerals.

1 and 2 show a support member 1 for the commutator sliding contact 2 shown in Fig. The commutator sliding contact 2 is spring-resiliently radially inwardly directed toward the rotatably disposed commutator 3 of the electric motor 4 by the support member 1.

The support member 1 shown in the figure is an integral metal stamping-bending part, here formed as a spring thin plate. The support member 1 comprises a flat spring section 5 which is biased by being curved transversely with respect to its longitudinal direction in the state shown in Figures 1 and 3. [ The approach angle alpha shown in Fig. 3 defines the bearing force F _A for supporting the commutator sliding contact 2 on the periphery of the commutator 3.

을 따른다. The spring section (5) is formed such that the edge deformation force of the partial section (6) of the spring section (5) is at least substantially constant in the longitudinal direction of the section section (6). The spring section in the longitudinal section part (6) having a (l ₀₎ (5) is tapered in the direction of the supporting section (7). That is, the width formed by the solid material (the transverse direction with respect to the longitudinal direction) decreases symmetrically with respect to the longitudinal central axis not shown. The width b (x) formed of the solid material is defined as the width (x) at each position x along the longitudinal direction of the partial section 6,

.

From the above equation, a trapezoidal outline of the partial section 6 formed entirely of solid material in Figs. 1 to 3 is given.

The length (l ₀₎ of the part section (6) the length (l ₀₎ is substantially equivalent to the overall length of the spring section 5, part section (6), as shown in Figure 2 is the spring section (5 (A). ≪ / RTI > The width in the region (length a) of the spring section 5 adjacent to the support section 7 is not linearly reduced as in the partial section 6 when viewed in the direction of the support section 7, (8). In order to prevent the weakening of the strength due to the notch effect which may occur when the spring section 5 leads to the support section 7 with a sharp or minimum transition radius, the minimum length for the support section 7 of the illustrated embodiment In the limit range of a), the disadvantage of non-constant edge strain is exerted.

As shown in Figs. 1 and 2, the end 9 of the spring section 5 having a width b _{0 on the} left side of the drawing is adjacent to the fixed section 10, In the example, it has a bracket for sliding into a support dome 11 (see Fig. 3).

At positions 12 and 13 indicated by arrows 12 and 13, a support member 1 is supported on the plastic holder portion 14 shown in Fig. The position indicated by the arrow 13 coincides with the end 9 of the spring section 5, which is on the left side of the drawing plane, i.e. away from the support section 17. As an alternative embodiment of the stationary section 10, for example, a locking structure may be implemented. Additionally or alternatively, the securing section 10 may be compression stamped with the holder portion 14. [

The end 15 of the spring section 5, remote from the end 9, leads to the rigid, i.e., non-elastic, base plane 16 of the support section 7. Along the two longitudinal sides of the support section (7), a sidewall (17) that vibrates outward by elasticity protrudes, which sidewall is used for side guides of the commutator sliding contact, the commutator sliding contact (18) passing through the opening (16). The sides of the through openings 18 are restricted by four spring brackets 19 each offset by 90 degrees from one another and the commutator sliding contacts 2 are received between the spring brackets. The spring brackets 19 extend in the bending direction of the support member 1, while the side walls 17 are aligned in the opposite direction.

Figure 3 shows a holder portion 14 (brush holder) having three support members 1. The three support members 1 each fix and support one commutator sliding contact 2 and guide the commutator sliding contact radially inwardly toward the commutator 3 connected to the armature shaft, Apply spring elasticity. The illustrated electric motor 4 is an electric motor which is switchable between two output stages, and the support member 1 shown in the right half of the figure is arranged so that intentional mis-rectification can be realized.

In Fig. 4 an alternative embodiment of the support member 1 is shown. The overall width of the spring section 5 in this support member 1 is constant and corresponds to the starting width b ₀ at each position x along the longitudinal direction of the spring section 5. However, the width length of the spring section 5 formed of a solid material is reduced toward the support section 7 in the longitudinal direction of the spring section 5. The width length formed from the solid material follows at least approximately the following formula:

.

.

In the illustrated embodiment, a longitudinally extending recess 20 is arranged in the spring section 5, said recess having a triangular contour and the width of said recess in the longitudinal direction of the spring section 7). ≪ / RTI > The width length b (x) formed of the solid material is obtained by adding the partial widths b ₁ (x) and b ₂ (x) at each position x.

2 commutator sliding contact
4 Electric motors
5 Spring Section

Claims (11)

A support member for a commutator sliding contact (2) of an electric motor (4), comprising a spring section (5) that can be biased by bending,
The spring section 5 is formed so that the edge deformation force in the longitudinal direction when biased is substantially constant in at least a partial section 6 of the spring section 5 extending in the longitudinal direction, Characterized in that the width dimension (b (x)) of the spring section (6) and / or of the spring section (5) formed of solid material decreases in the longitudinal direction towards the commutator sliding contact (2) Support members for commutator sliding contacts of motors. The method of claim 1, wherein the length of the partial section (6) (l ₀₎ is the spring section (5), characterized in that corresponding to at least 90% of its length, the commutator sliding contact support member of the electric motor of. Method according to claim 1 or 2, characterized in that at the respective positions (x) along the longitudinal direction of said spring section (5) or said partial section (6) (6), the following equation is applied to the width length b (x)

, Wherein l ₀ is the length of the partial section (6) of the spring section (5) or the entire length of the spring section (5) and b ₀ is the length of the partial section 6 of the end portion 9 of the spring section 5 of the spring section 5 remote from the commutator sliding contact 2 or of the width of the end 9 of the spring section 5 Wherein the support member for the commutator sliding contact of the electric motor is made of a metal. delete 3. A support member for a commutator sliding contact of an electric motor according to claim 1 or 2, characterized in that said partial section (6) and / or said spring section (5) have a trapezoidal contour. A support member for a commutator sliding contact (2) of an electric motor (4), comprising a spring section (5) that can be biased by bending,
The spring section 5 is formed so that the edge deformation force in the longitudinal direction when biased is substantially constant in at least a partial section 6 of the spring section 5 extending in the longitudinal direction, Characterized in that at least one recess (20) is arranged in the spring section (6) and / or in the spring section (5). 7. A support member for a commutator sliding contact of an electric motor according to claim 6, characterized in that the actual width of said partial section (6) and / or said spring section (5) is constant in the longitudinal direction. 8. A device according to claim 6 or 7, characterized in that the recess (20) is formed to extend transversely with respect to the commutator sliding contact (2) when viewed in the longitudinal direction towards the commutator sliding contact (2) And a support member for a commutator sliding contact of the electric motor. A spring section (5) according to any one of claims 1, 2, 6 and 7, characterized in that a support section (7) having a rigid base plane (16) Characterized in that it is provided for supporting the contact (2). 10. A device according to claim 9, characterized in that the spring section (5) is arranged for securing the support member (1) to the electric motor (4) between the support section (7) and the stationary section Wherein the support member is formed of a metal. An electric motor comprising a commutator to which at least one commutator sliding contact (2) supported by a support member (1) according to any one of claims 1, 2, 6 and 7 is in contact.

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