The invention relates to an electric motor, in particular a starter motor for an internal combustion engine.
An electric starter motor for an internal combustion engine is described in DE 35 39 851 A1. In order to start the internal combustion engine, the armature of the electric starter motor is kinematically connected to a starter pinion, via which the crankshaft of the internal combustion engine is set in motion.
The power supply to the electric starter motor is generally provided via litz wires, which conventionally consist of copper and are electrically connected to the carbon brushes resting against the commutator. Since the carbon brushes are subject to wear, a tracking mechanism is generally provided for compensating for the wear, with it being necessary for the litz wires connected to the carbon brushes to also follow the tracking movement of the carbon brushes. Owing to vibrations and shocks as well as as a result of thermal influences, the litz wires are thus subjected to considerable loading, but this does not lead to failure or breakage of the litz wires over the life of the starter motor.
Usually, the litz wires which are connected to the carbon brushes and other litz wires which lead from a toe-in relay to a pole housing of the starter motor are in the form of braided litz wires with a round cross section, with it being necessary, owing to the installation situation, for the litz wires to be bent quite considerably, which results in an additional strain on the litz wires and in the risk of them coming into contact with other components. In addition, there is the risk of the braiding coming loose and, as a result, the litz wires fanning out.
The invention is based on the object of designing the electrical connection in an electric motor to be permanent and robust with at the same time good matching to structural conditions in the electric motor.
The electric motor according to the invention is preferably an electric starter motor for an internal combustion engine, which is in the form of a mechanically commutated DC motor, for example. The motor has one or more brush pairs, which are in contact with a commutator, via which the current is conducted into the armature winding of the armature. The brushes are each connected to an electrical conductor for supplying current. Furthermore, electrical conductors are provided which lead from a relay to a component of the electric motor and from there, via the further conductor, to the brushes. The conductor which leads from the relay to the component of the electric motor, in particular a pole housing, is coupled to a contact piece, from where the further conductor also leads to the carbon brushes.
The invention provides that at least one conductor has a rectangular cross section in a central section and is welded to the contact piece in the region of an end-side end section. This end-side end section preferably likewise has a rectangular cross section, but this has different dimensions than the central section.
Various advantages are achieved by virtue of this embodiment. In contrast to the prior art, in which conventionally round cross sections are used in the electrical conductor, the conductor with the rectangular cross section has increased flexibility, which results in better matching to the installation situation. Despite the flexibility of the conductor, there is no risk of fanning out in the case of an embodiment of the conductor as a litz wire. The conductor with the rectangular cross section can be bent or twisted about different axes without this resulting in any damage to the conductor.
The dimensions in that end section of the conductor via which the conductor is welded to the contact piece differ from the dimensions of the rectangular, central section of the conductor. Provision is made in particular of the central section to be flatter, i.e. to have a greater width and a smaller height than the end section which is welded to the contact piece. In this embodiment, the end section has a cross-sectional geometry which is advantageous for the welding operation.
Expediently, both opposing end-side end sections of the conductor are each provided with a rectangular cross section, which differs from the central section in terms of the cross-sectional geometry or dimensions, in particular is less flat than the central section. It may be expedient for at least one of the end sections, possibly both end sections, to be provided with a square cross section, which is advantageous for the welding operation since the required welding site, with the result that the conductor can be welded to the end-side contact element in a space-saving manner.
In accordance with a further expedient embodiment, provision is made for at least one end-side end section, but preferably both end-side end sections, to be produced by reshaping of the rectangular cross section with which the central section of the conductor is provided. By virtue of this reshaping process, starting from a conductor with a cross section which is constant over the axial length, compacting of the end sections with a less pronounced rectangular cross section is achieved, with only the cross-sectional form changing, but the cross-sectional area remaining the same or at least approximately the same in the end sections as the cross-sectional area in the central section of the conductor.
In order to avoid or at least reduce mechanical and thermally induced stresses in the conductor, the transition from the wider, central section of the conductor to at least one narrower end section is advantageously provided with an angle of a maximum of 75°, with respect to the longitudinal axis of the conductor. This angle is 60° or 45°, for example. In this way, a comparatively uniform transition between the wider, central section and the narrower, end-side end section is ensured. Damage during compacting, in particular in the form of stiffening of the litz wire, is avoided by virtue of the angle in the transition region being limited.
In order to ensure sufficiently high flexibility of the conductor, it is expedient to provide a ratio of width to height of at least 3:2 in the region of the central section, with the result that the width is at least 1.5 times the height. If appropriate, an even greater ratio of width to height is selected, for example a ratio of 4:2, 5:2, 6:2 or even greater.
Expediently, both end sections are welded to contact elements, for example one end section of the conductor is welded to a cable lug and the opposite end section to the contact piece, which is guided with insulation (for example insulating rubber) through the pole housing of the electric motor. In the case of a current-conducting conductor which leads to the commutator of the electric motor, the conductor is connected to the carbon brush on the commutator side and is welded to the contact piece on the side opposite the commutator, said contact piece being guided in insulating fashion through the pole housing.
Further advantages and expedient embodiments can be gleaned from the further claims, the description relating to the figures and the drawings, in which:
The same components have been provided with the same reference symbols in the figures.
The supply of current to the electric motor 1 takes place starting from a relay 7 via an electrical conductor in the form of a litz wire 8, which is connected, in particular welded, to a contact piece 9 on the side of the electric motor, said contact piece being arranged on the outer side of the pole housing. The litz wire 6 via which current is supplied to the carbon brush 5 is also connected to the contact piece 9. The litz wire 8 is welded to a cable lug 10 at the other end, said cable lug being pushed onto a bolt 11 in the relay 7 and being secured by a nut 12.
The litz wire 8 and expediently also the litz wire 6 each have a rectangular cross section in a central section and a likewise rectangular or square cross section in the two end sections thereof. The subsequent
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Number | Date | Country | Kind |
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10 2009 028 989.5 | Aug 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/062560 | 8/27/2010 | WO | 00 | 5/22/2012 |