This application claims priority to pending European Application No. 17189622.8 filed on Sep. 6, 2017, the disclosure of which is incorporated by reference herein.
The invention relates to Slip-rings and brushes for Slip-Rings for transmission of electrical signals between rotating parts. Specifically, it relates to a stabilized gold wire brush which attenuates mechanical oscillations.
Electrical slip rings are used to transfer electrical power and/or signals between a rotating and a stationary part. Such devices are used in different applications, like wind energy plants or computer tomography scanners. There are also sever-al military and aerospace applications.
It is common to all of these applications, that a high lifetime and a low contact resistance as well as a low contact noise are required. Furthermore, in specific applications like a CT scanner, centrifuge with speeds exceeding 5 m/s relative speed of brush and module surface, applications with repetitive high accelerations like robots and pick & place machines require specific attention. The same applies for specific environmental requirements like in aerospace applications.
Slip rings are generally based on a first part having sliding tracks and a second part having brushes for sliding on the sliding tracks by a rotational movement. Due to external interference or by changes in friction, interfering movements of the brush other than the rotational movement or oscillations of the brush may occur. Specifically, if the excitation mechanism is based on friction effects, the term frictional induced vibration for these interfering movements is used. Such interfering movements may cause contact noise and/or contact interruptions, adversely affecting signal quality. In applications with an inductive load, electrical arcing may occur during such interruptions, which leads to significant corrosion and wear of the brush and the sliding track. As long as minimum arcing voltage and minimum arcing current e.g. 100 mA and 12 V for gold-gold contacts is exceeded also purely ohmic circuits will be subjected to arcing. At lower values still melting can occur with subsequent damage and wear.
EP 066 27 36 A1 discloses a multi-fiber brush where a strand of multiple thin fibers is used for contacting a sliding track. Due to the internal friction between the individual fibers, oscillations are suppressed. The drawback is the complex design having multiple thin wires held by a ferrule, which is expensive and difficult to manufacture. Furthermore, the fiber bundle has a comparatively large diameter and therefore requires a broad sliding track.
The embodiments provide mechanical stabilization of a sliding brush of a slip-ring, and preferably a wire brush for a slipring configured such that mechanical oscillations and/or interfering movements of the brush are reduced during the operation of the slipring. The proposed configuration may further lead to a reduction of contact noise, an increase in signal quality, lifetime and reliability of the brush during the operation. The same applies to a slipring comprising the so-configured brush and a sliding track. The solution should be simple and inexpensive and preferably does not require a change in the design of existing brush blocks. Furthermore, the design of proposed embodiment(s) facilitate an automated process of manufacture of such embodiment(s).
In an embodiment, a sliding brush is a wire brush comprising a metal wire. The wire brush includes a contact section configured to contact a sliding track. This contact section has a first end for holding the wire brush and a second end opposing to the first end. The first end may be held by or be attached to a brush block or a brush holder. As known from prior art, such a brush holder provides mechanical fixation of the brush together with an electrical contact to the brush. Preferably, under normal operating conditions, the contact section is in mechanical and electrical (galvanic) contact with a sliding track. A stabilizer arm extends preferably from the second end of the contact section. It preferably extends into a direction towards the first end of the contact section and/or roughly parallel to the contact section. The stabilizer arm holds a friction section which is in frictional contact with the contact section. Such a frictional contact may be established when the friction section is pressed to the contact section. Pressure may be applied sideward or from the top side. The pressing force may be generated by the stabilizer arm. The stabilizer arm may itself have spring characteristics. Preferably, the stabilizer arm is also a wire having a first end which extends from the second end of the contact section. Opposing to the first end of the stabilizer arm, there may be a second end which supports or bears the friction section. Furthermore, the friction section preferably includes a wire material. In an alternative embodiment, the friction section may also be a plate which may increase the frictional contact area between the friction section and the contact section.
In one embodiment, the contact section and the stabilizer arm are made of the same material. It is further preferred, if the contact section and the stabilizer arm are made of one piece. It is further preferred, if the friction section is also made (configured as) a one piece, integral unit with the stabilizer arm (to form a whole unit with the stabilizer arm) and preferably as one piece (integral whole unit) with the contact section. Preferably, the contact section, the stabilizer arm and the friction section are bent with a single, only one piece of wire.
It is preferred, if the stabilizer arm is separate from the contact section. It is further preferred, if there is no contact between the stabilizer arm and the contact section, except at the second end of the contact section which is connected to the stabilizer arm.
Preferably, the friction contact area, the area in which the friction section contacts the contact section, is located between the first end of the contact section and a first point corresponding to the middle of the contact section (and marking half a length of the contact section). Most preferably, it is located between the first end of the contact section and second point corresponding to 30% of the length of the contact section. The friction contact area is preferably between the first end of the contact section and the position where the contact section contacts the sliding track.
Preferably, the friction section includes a surface for generating a predetermined friction, preferably a higher friction. The surface may have a certain roughness or a structure to increase friction. Also, the contact section may have such a surface for generating higher friction, preferably in the contact area.
It is preferred, if the friction section presses or is pressed with a predetermined force against the contact section in the friction contact area.
It is further preferred, of the contact section includes a metal having spring-elastic properties. Such a metal may include at least one of spring steel, brass, bronze, silver, copper, nickel and alloys or combinations thereof. The contact section may also include a carbon material. It may include a piece or wire of carbon material connected to the metal wire or a metal wire coated or plated with a carbon material. The sliding brush may include metal sheet or wire and the contact section may be an attached (soldered, welded, for example) metal contact piece comprising a highly conductive material (brass, in one example), or the attached contact piece may include metal graphite (such as silver-graphite in one example).
It is further preferred, if the contact section has a surface includes a highly conductive material. Such a material may be nickel, silver, gold or any platinoid, a metal chemically resembling platinum, especially osmium, iridium, or palladium. Preferably, the contact section is plated or galvanized providing a thin gold or gold alloy layer.
In another embodiment, the stabilizer arm may be connected by a connecting means to the contact section. Such a connecting means may include at least one of a crimping sleeve, a solder connection, a glued connection, and a welding connection.
In another embodiment, the brush is made of sheet metal. The contact section may have a hole through which the friction section may penetrate (or pass through). The embodiments described herein for a wire brush may also be made with a sheet metal brush. The sheet metal brush may be made from sheet metal comprising at least one of the metals mentioned herein for brushes. The sheet may have a thickness between 0.05 and 3 mm preferably between 0.3 and 1.5 mm. The width may be between 1 and 20 mm, preferably between 3 and 10 mm. The brush may be manufactured by laser cutting, punching and/or bending.
The embodiments work best if there is a significant movement between the friction section at the stabilizer arm and the friction contact area of the contact section, as friction dissipates energy from the mechanical movement of the components. During normal operation, the contact section of the brush is firmly held at the brush block and supported by the sliding track. The second end of the contact section is free and unsupported during normal operation. If there is a certain movement between the sliding track and brush block or if there is a mechanical force to the contact section of the wire brush which may be caused by the stick-slip-phenomenon, the largest movement at the contact section will be at the unsupported second end. Therefore, this unsupported second end is used for transferring this movement via the stabilizer arm to the friction section generating friction with the contact section of the brush. Due to a lever-like design of the stabilizer arm, the amplitude of the movement may even increase at the location of the friction section.
A further embodiment relates to a slipring brush block which includes a brush carrier, holding at least one or preferably a plurality of slipring brushes as mentioned above. Preferably, the brush carrier includes an insulating material and/or electrically conductive material for electrical contact of the sliding brushes.
Another embodiment relates to a slipring assembly includes a sliding track and a slipring brush block as mentioned above. Preferably, at least one or multiple sliding tracks are held by a body of insulating material forming a slipring module.
The embodiments disclosed herein have the advantage, that vibrations and/or oscillations of the brush can be attenuated or reduced significantly. The stabilizer does not weaken the brush, nor does it change the spring properties which results in an unchanged contact force to a sliding track. There are no additional forces from external supports. The linear guidance by a V-groove in a sliding track is not affected, as there are no side forces to the brush. Also, the insulation properties remain unchanged. The new brush is fully compatible to previous brushes and can replace previous brushes without further modification of the slipring system.
In the following, the invention will be described by way of example, without limitation of the general inventive concept, on examples of embodiment and with reference to the drawings.
While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the drawings and detailed description thereto are not intended to limit the invention to the particular form disclosed, but on the contrary, the intention is to cover all modifications, equivalents and alternatives falling within the spirit and scope of the present invention as defined by the appended claims.
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The slip-ring brush block 120 includes a brush carrier 20, which may include a printed circuit board or any other insulating material. The brush carrier may also include a conducting material such as a metal, with insulated portions dimensioned to hold the brushes. The brush block 120 preferably holds a plurality of sliding brushes. In this embodiment, four wire brushes 21, 22, 23, and 24 are shown (which have respectively-corresponding brushes on the other side of the insulating body 10). It is appreciated that a different number of brushes and/or different type(s) of brushes could be used in a related embodiment. For example, multi-fiber brushes or carbon brushes can be used. The brushes are spaced with respect to one another such that they fit to corresponding sliding tracks of the slip-ring module 100. There must not necessarily be one brush per sliding track but, instead, there may additionally or in the alternatively be a plurality of brushes contacting a given sliding track to increase current capability and/or reduce noise and/or contact resistance.
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The slip-ring brush block 400 includes a brush carrier 420, which may include a printed circuit board or any other insulating material. It may also include a conducting material such as metal, portion of which are electrically insulated for holding the brushes. The brush block 400 preferably holds a plurality of sliding brushes. In this embodiment, two wire brushes 421, 422 are shown, but a different number of brushes and/or different types of brushes may be employed. The brushes are spaced such that they fit to corresponding sliding tracks 411, 412 of the slip-ring module. There must not necessarily be one brush per sliding track, but additionally or in the alternative there may be a plurality of brushes contacting a given sliding track to increase current capability and/or reduce noise and/or contact resistance.
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It will be appreciated to those skilled in the art having the benefit of this disclosure that this invention is believed to provide brushes for sliprings and sliprings. Further modifications and alternative embodiments of various aspects of the invention will be apparent to those skilled in the art. Accordingly, this description is to be construed as illustrative only and is for the purpose of teaching those skilled in the art the general manner of carrying out the invention. It is to be understood that the forms of the invention shown and described herein are to be taken as the presently preferred embodiments. Elements and materials may be substituted for those illustrated and described herein, parts and processes may be reversed, and certain features of the invention may be utilized independently, all as would be apparent to one skilled in the art after having the benefit of this description of the invention. Changes may be made in the elements described herein without departing from the spirit and scope of the invention as described in the following claims.
Number | Date | Country | Kind |
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17189622.8 | Sep 2017 | EP | regional |