‘The invention relates to a carbon brush, having a wear limit indicating function, having a current-carrying stranded wire being arranged in a brush body, and having a stranded indicating wire, which, at a stranded wire end section, is surrounded and fixed by a sleeve having an infeed opening, wherein the sleeve is arranged in a recess being formed in the brush body.
With hand tools that are driven electrically, such as drilling machines that are commercially operated, it is important, for using the working hours as efficiently as possible, to be able to schedule maintenance measures in conjunction with the hand tools accurately enough, in particular in the context of measures relating to replacing the carbon brushes. Hence, it is ensured that the required wear parts are available in good time for the anticipated maintenance date and that lost working hours due to unexpected maintenance work can be avoided to the greatest extent.
In order to inform about the condition of the carbon brushes in good time and to provide a warning that the wear limit of the carbon brushes will soon be reached, it is therefore standard practice to provide carbon brushes with a so-called stranded indicating wire, which is formed or arranged in the brush body of the carbon brush such that, for announcing that the wear limit will soon be reached, an electrically conductive contact between the stranded indicating wire and the slip ring or the commutator of the drive engine of the hand tool is established.
In order to avoid damage to the hand tool as a result of the operation of the hand tool being continued even after the wear limit has been reached, the indicating function that is fulfilled by the stranded indicating wire can additionally be complemented with a disconnection function, which brings about a compulsory interruption in the operating current supply via the stranded wire that carries the (operating) current. Said disconnection function can be configured as a mechanical disconnection mechanism. Thus, a disconnection mechanism is known, for instance from the document EP 0 512 234 BI, which mechanism is formed in the brush body as a component assembly that is composed of several components. The disconnection mechanism features a disconnection nipple which is formed so as to be electrically insulating, and which, being spring-preloaded, is received in a receiving bore. For generating the spring-preload, a pressure spring being coupled to the disconnection nipple is supported at a compressed filling compound which has been filled into the receiving bore, and which consists of a metal powder as a rule. By mechanically lifting the carbon brush off the commutator or off the slip ring of the electric engine, the interruption in the current supply is guaranteed.
Due to this complex design of the disconnection mechanism, producing the same also proves to be correspondingly laborious and time-consuming, having a plurality of production steps to be performed one after the other, starting with introducing the receiving bore, subsequently installing the combination of the disconnection nipple/pressure spring and finally partially filling the receiving bore with the metal powder for creating an abutment for the pressure spring.
One possibility of avoiding the laborious and time-consuming construction of a mechanical disconnection function consists in forming the stranded indicating wire in such a way that it also fulfills the disconnection function, in an electrical manner, besides the indicating function. Here, the stranded indicating wire is formed as a contact conductor for the disconnection function for activating an electrical disconnection device. Besides, both the recess for the stranded indicating wire and the recess for the stranded wire that carries the operating current are configured as receptions that are dimensioned as identically as possible.
Introducing the stranded wires into the carbon brush body turns out to be rather laborious and time-consuming in terms of manufacture, since the stranded wire ends that consist of a plurality of thin single wires, as a rule, have to be bent manually so as to be U-shaped or loop-shaped and have to be fed into the carbon brush body. In order to simplify this manufacturing process and to keep the required bore diameter of the recess as small as possible, so as not to weaken the brush body, the patent application publication DE 41 11 206 A1 proposes holding or guiding the stranded indicating wire by means of a sleeve, which is, in turn, fixed in the recess with respect to its position.
However, with this manner of fastening, too, feeding the stranded wire bundle into the sleeve proves to be a manufacturing step that is particularly time-consuming and that has to be carried out carefully, this manufacturing step therefore still being carried out manually and laboriously in most cases.
Thus, as a part of efficiently manufacturing carbon brushes, the task on which the invention is based consists in designing the coupling of a stranded wire, in particular of the stranded indicating wire, to the carbon brush in such a way that the stranded wire can securely be fixed in the carbon brush body with just a few simple production steps.
In conjunction with the preamble of claim 1, this task is solved in that the sleeve is formed as a centering sleeve, the inner diameter of which at the infeed opening corresponds to an outer diameter and features a tapering that is conical in the infeed direction.
Starting from a basic cylindrical shape of the sleeve and from a wall thickness of approximately half the inner diameter, in accordance with the invention, the inner diameter at the stranded wire infeed opening is extended to the size of the outer diameter, such that the front surface of the sleeve approaches zero and that there is no stop surface as an obstacle to the stranded wire bundle to be fed in when it is fed into the sleeve. In conjunction with the tapering of the inner diameter that is conical towards the recess bottom, a stranded wire being insulated in its stranded wire end section, but in particular also a stranded wire being stripped from its insulation in the stranded wire end section, slides into the interior of the centering sleeve without any resistance. In the case of a stranded wire being stripped from its insulation, it is precluded that single stranded wires be turned out and, hence, the risk of an unreliable coupling is precluded, in contrast to a sleeve having a planar front surface at the infeed opening. Hence, mounting the stranded wire is simplified both in the case where the stranded wire is initially coupled to the centering sleeve outside of the carbon brush and where the unit consisting of the stranded wire end section and the centering sleeve is subsequently introduced into the carbon brush body, and in the case where the stranded wire is fed into the centering sleeve already being premounted in the carbon brush body.
In a preferred design, the conical tapering of the inner diameter is confined to a section adjoining the infeed opening, wherein the centering sleeve, abutting thereon, features a section having a constant inner diameter. The conical tapering can basically extend over the entire length of the sleeve, which means that the sleeve constitutes an inner cone in its entirety, the inner diameter of which, when the outer diameter is constant, steadily decreases from the infeed edge having an arbitrarily small wall thickness up to the opposite end. Preferably, the conical course, in the longitudinal direction of the centering sleeve, is, however, confined to a section adjoining the infeed opening, an area having a constant inner diameter abutting on said section. This design is simple to realize in terms of manufacture and lends sufficient stability to the sleeve.
The conical section being limited to the area of the infeed opening in its length is, in an advantageous manner, formed such that the cone angle of the centering sleeve corresponds to a point angle of a centering drill. This design makes molding the sleeve interior in a manner being simple in terms of manufacture possible, by drilling with a centering drill. A preferred cone angle of 30° guarantees that the stranded wire bundle can be fed in an unobstructed way.
In a further advantageous design, the centering sleeve is configured as a sleeve being closed on one side. This centering sleeve being designed in a cup-shaped way surrounds the stranded wire end section as an electrically insulating socket within the carbon brush body—if required, in conjunction with an insulating adhesive layer having been applied to the outer wall of the stranded wire—and prevents, in normal operation, an electrical contact with the carbon brush. An electrically conductive coupling to the carbon brush body or to the commutator does not arise before abrasion of the (cup) bottom has also been effected as a result of the carbon brush wear.
In an alternative configuration, the centering sleeve can be configured as a sleeve being open on both sides. In this case, the stranded wire end section protrudes beyond the lower sleeve end and can be encircled by an insulating adhesive layer.
Preferably, the stranded indicating wire and the centering sleeve are pressed together by crimping or said stranded indicating wire is glued into place in the centering sleeve. In terms of production, these coupling techniques are simple to carry out before the arrangement is fed into the carbon brush body and guarantee a coupling having enough tensile strength.
In a further design, the centering sleeve is glued into place in the recess of the brush body. Here, the centering sleeve can be glued into place with the aid of an insulating adhesive material.
Advantageously, the centering sleeve is produced from a manufacturing material that does not conduct electricity. The manufacturing material can, for instance, be an insulating plastic material. In this way, it is ensured that the stranded indicating wire does not establish any electrical contact with the carbon brush body or with the slip ring as long as the wear limit has not been reached, yet.
Alternatively, the centering sleeve can consist of metal, wherein an adhesive material that does not conduct electricity is used as an insulating sheathing when gluing the centering sleeve into place in the recess of the brush body, and wherein the centering sleeve is configured as a sleeve being open on both sides. Due to its elasticity, a metal sleeve allows both easily squeezing the stranded indicating wire and easily fitting the sleeve into the recess of the carbon brush body. In addition, the metal can reliably be glued into place. In the case of a metal centering sleeve, the same is configured so as to be open from below, so as not to damage the commutator.
In a further configuration, the stranded indicating wire and the centering sleeve are fixed in the recess by tamping them down with a tamping powder. If the drilling depth of the recess is greater than the sleeve length, the sleeve can be fixed with the aid of a tamping powder, having the stranded indicating wire being fastened in the same, by tamping a coated section of the stranded indicating wire down, above the sleeve infeed opening. The tamping powder can be a metal tamping powder in this case.
Alternatively to fastening a coated stranded indicating wire, the stranded wire end section, within the recess, can feature exposed single wires, which are surrounded by an insulating tamping powder to fix the stranded indicating wire and the centering sleeve. In this case, due to the insulating tamping powder, a coating of the stranded indicating wire is Figures not required, such that the centering sleeve and the bore diameter of the recess can be construed so as to be smaller and, hence, more stable.
Preferably, the centering sleeve is utilized as a sleeve that is made of a conductive manufacturing material for coupling the current-carrying stranded wire to the brush body. Using a sleeve in a configuration as a centering sleeve is not confined to fastening a stranded indicating wire, but can rather also advantageously be utilized in the form of a metal sleeve for producing a mechanical and electrical coupling of the current-carrying stranded wire.
Further advantageous design features result from the following description and from the drawings, which explain a preferred embodiment of the invention by reference to examples. In the figures:
The centering sleeve 8 itself has been glued into the recess 6, preferably with the aid of insulating adhesive material, and produces a cup-shaped insulating socket for the stranded wire end section 12 of the stranded indicating wire 10, wherein, at the end of the stranded wire end section 12, the single wires 13, 14 that are uncovered by stripping them from their insulation protrude into the interior 20 (
An inner cone 30 narrowing towards the sleeve bottom 16 abuts on the infeed opening 22, which cone guides the single wires 14 and, in the further progress, fades into a section 32 having a constant inner diameter 26b. In contrast to known wire end sleeves, which feature a conical flange, the centering sleeve 8 in accordance with the invention can completely be inserted into a bore 6 of the carbon brush body 4 in an advantageous manner.
The hollow space 20, in a simple manner in terms of manufacture, is shaped by drilling with the aid of a centering drill, such that, for the cone angle α, a value results that can be selected so as to correspond to the point angle of the centering drill. A cone angle α of 30° has proved to be favorable in order to be able to feed in the stranded wire end section 12 without having to fear the risk that the single wires 13, 14 be turned out. By implication, other cone angles α are also possible—even cone angles α being independent from a drill geometry, as long as feeding in the stranded wire end section 12 works easily and the advantage of shaping the cone by the centering drill is renounced.
In a simplified manner, the centering sleeve 8 can also be configured as a sleeve being open on both sides, not having a bottom 16 (see
In an alternative design, the centering sleeve 8 can consist of a conductive manufacturing material, wherein an adhesive material that does not conduct electricity is used as an insulating sheathing when gluing the centering sleeve 8 into place in the recess 6 of the brush body 4. In this configuration, the insulating effect of a centering sleeve 8 having been produced from an insulating (plastic) material is replaced by the glue layer.
Furthermore, the centering sleeve 8 in accordance with the invention can also be utilized as a sleeve consisting of a conductive manufacturing material for coupling a current-carrying stranded wire to the brush body 4. In this arrangement for fixing the current-carrying stranded wire, too, the conical design 30 at the infeed opening 22 causes a simplified infeed of the current-carrying stranded wire. In this case, the centering sleeve 8 can also be configured as a sleeve being open on both sides, since a sheathing insulation within the brush body 4 is not required—in contrast, such an insulation even has to be avoided.
Number | Date | Country | Kind |
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10 2012 209 222 | May 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/061269 | 5/31/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/178790 | 12/5/2013 | WO | A |
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101533985 | Sep 2009 | CN |
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102010031415 | Jan 2012 | DE |
0585591 | Mar 1994 | EP |
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1412458 | Oct 1965 | FR |
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Entry |
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English Translation of Notification of First Office Action Chinese Patent Application No. 201380028886.4 ssue Date: Mar. 3, 2016. |
PCT/EP2013/061269 International Search Report Aug. 27, 2013. |
Number | Date | Country | |
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20150111397 A1 | Apr 2015 | US |