DE102014208176A1 - sliding contact - Google Patents

Abstract

A sliding contact arrangement has a first contact piece (1) and a second contact piece (2). The contact pieces (1, 2) are equipped with form-complementary contact areas, wherein the contact pieces (1, 2) are movable relative to each other in a sliding direction. The contact region of the first contact piece (1) has, in a projection substantially perpendicular to the sliding direction (3), a trajectory (8, 8a) which is equipped with a rise.

Description

The invention relates to a sliding contact arrangement comprising a first contact piece and a second contact piece, which have complementary shaped contact areas, which are movable relative to each other in a sliding direction.

Such Gleitkontaktanordnung is for example from the US patent US 3,319,214 known. There, a first contact piece and a second contact piece are complementary in shape, wherein the two contact pieces are movable relative to each other in a sliding direction. The two known contact pieces are inserted into one another, wherein for contacting one of the contact areas is designed as a narrow strip by an elastically deformable contact spring. In a frequent relative movement of the contact pieces of the sliding contact arrangement, for example by thermal changes in length, vibrations, etc., due to the contact spring used a punctual abrasion at the adjacent contact area occur. In particular, in the case of high-quality sliding contact arrangements which, for example, have galvanic coatings in order to keep the contact contact resistances low, such an abrasion can lead to a failure of the sliding contact arrangement. Thus, the known sliding contact arrangement is indeed inexpensive to produce with good contact. However, the stability of the sliding contact arrangement is limited with repeated relative movements of the two contact pieces.

It is therefore an object of the invention to provide a sliding contact arrangement, which has an improved stability.

According to the invention this object is achieved in a sliding contact arrangement of the type mentioned above in that the contact region of the first contact piece in a projection substantially perpendicular to the sliding direction follows a course of a path having an increase.

A sliding contact arrangement can be used, for example, to connect current path sections of an electric power transmission device with each other. Electric power transmission devices are used for the transmission of electrical energy, wherein within a phase conductor, an electric current is driven by a potential difference. The sliding contact arrangement may be part of such a phase conductor. For example, the phase conductor can be arranged within an encapsulating housing, which encloses the phase conductor. The phase conductor may be kept electrically isolated relative to the encapsulating housing. A fluid located in the interior of the encapsulating housing can cause an electrical insulation of the phase conductor. Accordingly, a contact arrangement can also be embodied fluid-insulated. In order to be able to economically produce a phase conductor extending over relatively long distances, the phase conductor can be composed of individual segments, whereby individual segments can be contacted with one another via a sliding contact arrangement. By using a sliding contact arrangement, relative movements of the individual segments of the phase conductor can be compensated. Thus, the occurrence of tension in the phase conductor is prevented. A sliding contact arrangement has for this purpose a first contact piece and a second contact piece. The two contact pieces are movable relative to each other. Thus, for example, in the context of an assembly by moving the contact pieces into one another, it is possible to make contact with the contact pieces. Contact areas of the contact pieces should be designed to complement each other. For example, a contact region of the first contact piece can be socket-shaped or bolt-shaped and, correspondingly, a contact region of the second contact piece can be bolt-shaped or bush-shaped. A relative movement should be possible substantially along an axially extending sliding direction. In this case, however, deviations from an ideal axial extension of an axial sliding direction are possible, so that, for example, a compensation of a tilting of the contact areas / the contact pieces can be made to each other. In a bolt-shaped / bush-shaped configuration, inner and outer circumferential surfaces of the bushing or of the bolt can serve as contact regions. In order to allow a sufficient Kontaktanpresskraft and defined current transfer points, the contact area of the first contact piece should follow a defined path. The web may extend at least in sections substantially azimuthally to the sliding direction. For example, a web may be designed substantially strip-shaped. A web may extend in the form of a line-like track on one of the contact pieces. An opposing contact area should extend in a planar manner, for example in the form of a lateral surface. The web can be defined, for example, by a succession of a plurality of contacting points of a contact region, which serve to galvanically contact the contact pieces. It can be provided that the web is determined for example by a contact-switching device, such as contact fingers, contact springs, contact blades, etc., which produce a plurality of contact points between the first and / or the second contact piece in the course of the web. The contact region of the first contact piece may be integrally formed with the contact piece, but it may also be provided that for forming a contact region, a discrete contact exchange device is arranged on the first contact piece. The contact switching device may be mounted on one of the contact pieces and be part of a contact area. For example, the web can be defined by a groove-shaped recess running in the first or in the second contact piece, into which, for example, a contact-switching device can be inserted. The contact switching device bridges the web following a joint gap between the first contact piece and the second contact piece. Thus, the Kontaktanpresskräfte between the two contact pieces can be transmitted along a defined path. Contact forces can be transferred specifically in the area of the web.

In a projection substantially perpendicular to the sliding direction of the contact pieces, the web should preferably have a rise. That is, the web is at least partially aligned substantially different from a parallel or perpendicular to the projection axis. The sliding direction can be defined by an axis of the sliding direction, along which a relative movement between the contact pieces of the sliding contact arrangement is possible. This sliding direction can be, for example, a main direction of a relative movement between the first and second contact piece in order to bring the contact areas of the two contact pieces into engagement with one another or separate from one another. An increase in the course of the path can increase the number of potential points of contact compared to the orthogonal position of tracks with respect to the direction of sliding while maintaining similar dimensions of the contacts. Thus, an enlarged area is available to distribute Kontaktanpresskräfte. This can counteract premature punctual wear. As the number of contact points increases, the contact area between the first and second contact piece increases, so that forces are distributed over a larger area. This counteracts a point overloading of the contact areas between the contact pieces, whereby abrasion is reduced. Thus, the stability of the sliding contact arrangement can be increased. Preferably, contact pieces can be used with circular cylindrical lateral surfaces. This allows easy contact with the contacts. Further, the contact pieces can also rotate relative to each other.

A further advantageous embodiment may provide that the web rotates about the sliding direction.

A circulation of the web around the sliding direction can for example take place such that, for example, a wave-shaped, toothed, etc. course is provided. It can be provided an open circulation. In a projection in the sliding direction, an open path can be defined, for example, by a helical course of the path, which results in a closed circulation, for example, by a multiple circulation around the sliding direction when projecting in the direction of the same.

Advantageously, it can be provided that the web has a helical course.

A helical course makes it possible, depending on the spiral pitch in the direction of the sliding direction, to arrange an increased number of contact points along the path between the first and second contact pieces, even on short axial areas. The slope of the helix may vary.

A further advantageous embodiment may provide that the web rotates closed in itself.

By a self-contained circulation of the web dielectrically favorable contact areas can be formed, as an endless circulation of the closed path is given. In this case, it can be provided to increase the number of contact points between the contact pieces, that a plurality of self-contained paths, which are arranged, for example, extending substantially parallel.

A further advantageous embodiment may provide that the web has a monotonous increase in its course.

A monotonous increase of the web should preferably be carried out consistently over the entire course of the web. As a result, even with a relative movement of the contact pieces in the sliding direction to each other all track sections claimed substantially similar. Turning points or saddle points in the course of the course should be avoided, since these points of discontinuity represent an increase, which in turn could possibly lead to occasional increased wear. A monotonic course can be achieved for example by a helical path.

A further advantageous embodiment may provide that the web is an elliptical path.

An elliptical path has the advantage over a circular-cylindrical outer surface that its length is extended in relation to a circular path, wherein the path can be self-contained. The web can lie in one plane. An elliptical path may preferably extend in a plane which is pierced by the axis which extends in the sliding direction and thereby between the Sliding direction and the plane is preferably included an angle different from 90 °. Preferably, an obtuse-angled cutting of the plane of the elliptical path and the axis of the sliding direction should be provided.

A further advantageous embodiment can provide that the elliptical path is arranged on a lateral surface of a hollow cylinder / cylinder with a circular / annular cross-section.

The use of circular or annular cross-sections makes it possible to use circular-jacket-shaped surfaces on the inner or outer jacket side of the contact pieces in order to form a contact region. An elliptical course of the web should preferably lie in a plane which lies transversely to the sliding direction of the relatively movable contact pieces. As a result, a simplified assembly is possible because with contacting the two contact pieces together first a low-force connection of the contacts is made possible and with increasing overlap of the contact pieces with each other a continuous increase in the contact forces is recorded. This allows a simplified mounting of the sliding contact arrangement. In addition, circular contours have dielectrically favorable properties, so that such sliding contact arrangements also in the high and medium voltage range, d. H. can be used with voltages over 1000 volts, especially over 30,000 volts and 70,000 volts.

Furthermore, it can be advantageously provided that the contact region has an elastically deformable contact bridge following the web.

By using a contact bridge, it is possible to form the train following a defined number of contact points between the first and second contact piece. An elastically deformable contact bridge penetrates a joint gap between the first and second contact piece and forms a contact-switching device between the two contact pieces. If necessary, various types of contact bridges can be used. For example, elastically deformable contact fingers, elastically deformable contact blades or elastically deformable coil springs can be used. When the two contact pieces are in contact with one another, the contact bridges can produce an elastic bond between the first and the second contact piece with reversible elastic deformation. By such a galvanic contacting an electrically conductive transition in the contact region between the first and the second contact piece is made possible. A contact bridge may be part of a contact region, in particular of the first contact piece.

A further advantageous embodiment may provide that the contact pieces are angularly movable relative to each other.

An angular movement of the contact pieces may be provided as an alternative or in addition to a sliding movement of the contact pieces relative to each other. An angular movement, d. H. a pivotable alignment of the contact pieces to each other, for example, take place about an axis which is transverse, in particular substantially perpendicular to the sliding direction. Due to a flexible deformability of a contact region, for example by an elastically deformable contact bridge, a compensation of an enlargement or reduction of a joint gap between the first contact piece and the second contact piece can take place. Thus, in addition to an axial compensation of relative movements of portions of a phase conductor, a tilting of the phase conductors via a sliding contact arrangement according to the invention is made possible. Depending on the dimensional accuracy of the shape complementarity of the contact pieces to each other, d. H. Depending on the width of the joint gap between the contact pieces, a deflection of the contact pieces to each other by a few degrees or more 10 degrees may be allowed. In addition, the deflection can be limited by the depth of overlap of the contact pieces in the sliding direction.

A further advantageous embodiment may provide that at least one of the contact pieces is rotatable substantially about the axis of the sliding direction.

In addition to an axial and / or angular movement of the contact pieces of the sliding contact arrangement relative to one another, it is also possible for a rotation of at least one of the contact pieces to be provided about an axis of the sliding direction. This can cause an additional reduction of a punctual abrasion of a contact area. A relative rotation of the contact pieces to one another may additionally be superimposed by a relative angular movement. It is thus possible, for example, for a narrow-band track of a contact area on one of the contact pieces to face a larger, for example hollow-cylindrical bush-shaped, contact area of the other contact piece.

In the following, an embodiment of the invention is shown schematically in a drawing and described in more detail below. It shows the

1 a section through a sliding contact arrangement, the

2 an enlarged view of one of the 1 known first contact piece and the

3 a perspective view of one of 1 known second contact piece.

The 1 shows a section through a sliding contact arrangement. The sliding contact arrangement has a first contact piece 1 and a second contact piece 2 on. Contact areas of the first and the second contact piece 1 . 2 are formed complementary in shape, wherein the second contact piece 2 is formed hollow cylindrical. The contact pieces 1 . 2 can have circular cross-sections. The first contact piece 1 has a cylindrical contour, so that the first contact piece 1 in a hollow recess of the second contact piece 2 can protrude. The first contact piece 1 may for example also be designed as a hollow cylinder. The two contact pieces 1 . 2 are essentially coaxial with an axis 3 aligned and overlap in facing frontal areas each other. The second contact piece 2 has an inner side of a contact area. The contact area of the second contact piece 2 is through a portion of an inner wall of the second contact piece 2 formed and in this case has a planar extension, which substantially corresponds to the inner circumferential surface of a straight hollow cylinder with an annular cross-section.

The first contact piece 1 and the second contact piece 2 are part of a phase conductor, which is a transmission of an electric current along the axis 3 serves. The phase conductor is divided into different segments, wherein for compensating for changes in length, which are thermally conditioned, for example, the first and the second contact piece 1 . 2 essentially along the axis 3 (Sliding direction) are movable relative to each other. Both the first and the second contact piece 1 . 2 are inside an encapsulating housing 4 arranged. The encapsulating housing 4 has a first tubular encapsulation section 5 and a second tubular encapsulation section 6 on. The two tubular encapsulation sections 5 . 6 also have a hollow cylindrical structure, wherein the two encapsulation sections 5 . 6 pick up the phase conductor inside. Since the first and the second contact piece 1 . 2 Part of the phase conductor are, are also the two contact pieces 1 . 2 from the encapsulating housing 4 surround. The encapsulation sections 5 . 6 are coaxial with the axis 3 arranged. In addition to arranging a single phase conductor within an encapsulating housing 4 can also be an arrangement of multiple phase conductors within a common encapsulating 4 be provided. The phase conductors should be opposite to the encapsulating housing 4 as well as be electrically isolated from each other. For electrical insulation is the inside of the encapsulating 4 filled with an electrically insulating fluid. The electrically insulating fluid flows around and flushes through the two contact pieces 1 . 2 so that between the contact pieces 1 . 2 as well as the encapsulating housing 4 an electrically insulating track is formed. The contact pieces 1 . 2 therefore, they do not require any solid insulation that would surround them. This is a simplified design of the contact areas and a simplified overlap of the two contact pieces 1 . 2 allows. As electrically insulating fluids, for example, gases and / or liquids can be used. Preferably, electronegative fluids such as sulfur hexafluoride, carbon dioxide, nitrogen or other mixtures can be used. The encapsulating housing 4 should be designed to be fluid-tight to one inside the encapsulating 4 to prevent entrapped fluid from volatilizing. The encapsulating housing 4 can be designed as a pressure vessel, so that a fluid located inside can be pressurized. Between the first and the second tubular encapsulation section 5 . 6 has the encapsulating housing 4 a variable-length encapsulating housing section 7 on. The variable-length encapsulating housing section 7 is present bellows-shaped and on the one hand fluid-tight with the first tubular encapsulating housing portion 5 and on the other hand with the second tubular encapsulation section 6 connected. The variable-length encapsulating housing section 7 is essentially coaxial with the axis 3 aligned. In the present case are the variable-length encapsulating housing section 7 as well as the first and the second contact piece 1 . 2 arranged in an axial course such that the two contact pieces 1 . 2 from the variable-length encapsulating housing section 7 are encompassed. This makes it possible that relatively changes in length in the phase conductor and optionally in the encapsulating 4 occurring length changes close together can be compensated. Furthermore, by an adjacent location of the contact pieces 1 . 2 the sliding contact arrangement and the variable-length encapsulating housing section 7 given the possibility of a limited tilting of the contact pieces 1 . 2 and optionally a preferably corresponding tilting of the first and second tubular encapsulation housing sections 5 . 6 to allow and compensate. As a result, a flexible electric power transmission device is given. To the contact pieces 1 . 2 relative to the encapsulating housing 4 To position, electrically insulating support elements may be provided, which are different from the respective contact piece 1 . 2 to the encapsulating housing 4 extend and cross the electrically insulating fluid thereby. For example, columnar support insulators or disc-shaped support insulators may be used.

While the second contact piece 2 inside jacket side having a contact area, which an inner circumferential surface of a straight hollow cylinder with annular cross section corresponds, has the first contact piece 1 in comparison to a smaller area contact area. The contact area of the first contact piece 1 follows a train 8th , which in a vertical projection to the axis 3 (in the present case to the plane of the 1 ) has an increase, so that in the projection the web 8th transverse to the axis 3 however, it is not cut perpendicularly from this one. Such a projection is perpendicular to the axis 3 is in the 1 shown by way of example. The train 8th the contact area of the first contact piece 1 is present by a in an outer circumferential surface of the first contact piece 1 introduced self-contained circumferential groove defined. The contact area of the first contact piece 1 has a strip-shaped path 8th on. The train 8th runs closed around the cylinder axis of the first contact piece 1 , The train 8th has the shape of an elliptical ring. The train 8th lies in a plane. The self-contained circumferential groove opens in the radial direction, the web 8th has an elliptical course. The contact area of the first contact piece 1 has a contact bridge 9 on. The contact bridge 9 is in the present case designed in the form of a spiral spring, the course of the path with its helical turn 8th follows and forms an elliptical ring. Here is the extension of the contact bridge 9 chosen in the radial direction such that spirals of the contact bridge 9 the lateral surface of the first contact piece 1 overtop. Grooved edges of the web 8th defining groove prevent axial movement out of the contact bridge 9 out of the groove. The contact bridge 9 protrudes beyond the lateral surface of the first contact piece 1 in the way that upon insertion of the first contact piece 1 in a bush-shaped opening or the contact region of the second contact piece 2 an elastic deformation of the contact bridge 9 takes place, so that both the first and the second contact piece 1 . 2 Contact points are formed which a low-impedance transition between the first and the second contact piece 1 . 2 via the contact areas. In addition to a use of a helical spring and other elements for forming a contact area in the form of a contact bridge 9 possible. For example, elastically deformable contact fingers, contact blades or other suitable elastically deformable contact areas can also be used.

With a broken full line is in the 1 a second train 8a symbolizes. For example, several tracks 8th . 8a on one or both contact pieces 1 . 2 be positioned so that the number of contact points can be additionally increased. In addition to a parallel formation of, for example, two elliptical orbits 8th . 8a For example, a helical outer shell side around the first contact piece 1 be provided circumferential path.

In addition to in the 1 shown elliptical path 8th or more parallel tracks 8th . 8a can also be provided further courses. For example, a train 8th . 8a be provided with varying climbs. That's how a train can do 8th for example, wavy, cracked or jagged and so on.

The 2 shows an enlargement of the contact region of the first contact piece 1 by train 8th and the contact bridge 9 , The contact bridge 9 protrudes beyond the lateral surface of the first contact piece 1 by an amount A addition. This amount A is necessary to elastic deformation of the contact bridge 9 upon insertion thereof into the contact area of the second contact piece 2 make. Furthermore, this transfer A is through the contact bridge 9 necessary to also have an optional between the two contact pieces 1 . 2 transverse to the axis 3 intended to compensate for tilting and a permanent contact between the first and second contact piece 1 . 2 independent of a relative position in the direction of the axis 3 as well as at a substantially perpendicular to the axis 3 done tilting the contact pieces 1 . 2 compensate. In addition, there is the possibility of a rotation of the first and second contact piece relative to each other, so that in addition an improved use of the second contact piece 2 available contact area is given. In the 2 is with interrupted full line of self-contained circulation of the web 8th symbolized in one plane. The level of the railway 8th gets off the axis 3 punctured. The axis 3 and the level of the train 8th are aligned differently from 90 ° to each other.

Next is the course of another track with interrupted solid line 8a symbolized with elliptical course.

The 3 shows a perspective view into the contact region of the second contact piece 2 into it. Between the broken solid lines extends the used contact area of the second contact piece 2 which is used, for example, when a tilting of the first and second contact piece 1 . 2 relative to each other. This results in a sickle-shaped curved area, wherein in the region of the sickle ends of an axis of an angular tilting of the first and second contact piece 1 . 2 lies. In the hatched crescent-shaped area, contacting points of contact between the contact areas of the first and second contact piece takes place 1 . 2 , In addition to such an angular deflection of the first and second contact piece 1 . 2 can also have an axial Relative movement of the first and second Kontakstück 1 . 2 respectively. Furthermore, in addition, a rotation of the first and second contact piece relative to each other, whereby an improved use of the second contact piece 2 available contact area is made possible.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• US 3,319,214 [0002]

Claims (10)

Sliding contact arrangement comprising a first contact piece ( 1 ) and a second contact piece ( 1 ), which have shape-complementary formed contact areas, in a sliding direction ( 3 ) are movable relative to each other, characterized in that the contact region of the first contact piece ( 1 ) in a projection substantially perpendicular to the sliding direction ( 3 ) a course of a train ( 8th . 8a ), which has an increase. Sliding contact arrangement according to claim 1, characterized in that the track ( 8th . 8a ) around the sliding direction ( 3 ) rotates. Sliding contact arrangement according to claim 1 or 2, characterized in that the web ( 8th . 8a ) has a helical course. Sliding contact arrangement according to one of claims 1 to 3, characterized in that the web ( 8th . 8a ) runs closed in itself. Sliding contact arrangement according to one of claims 1 to 4, characterized in that the web has a monotonous increase in its course. Sliding contact arrangement according to one of claims 1 to 5, characterized in that the web ( 8th . 8a ) is an elliptical path. Sliding contact arrangement according to claim 6, characterized in that the elliptical path ( 8th . 8a ) is arranged on a lateral surface of a hollow cylinder / cylinder with a circular / circular cross-section. Sliding contact arrangement according to one of Claims 1 to 7, characterized in that the contact area is one of the tracks ( 8th . 8a ) the following elastically deformable contact bridge ( 9 ) having. Sliding contact arrangement according to one of claims 1 to 8, characterized in that the contact pieces ( 1 . 2 ) are angularly movable relative to each other. Sliding contact arrangement according to one of claims 1 to 9, characterized in that at least one of the contact pieces ( 1 . 2 ) is rotatable substantially about the axis of the sliding direction.

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