EP2831961A1

EP2831961A1 - Brush block for a slip ring arrangement

Info

Publication number: EP2831961A1
Application number: EP13711857.6A
Authority: EP
Inventors: Peter Pollner
Original assignee: Schleifring und Apparatebau GmbH
Current assignee: Schleifring und Apparatebau GmbH
Priority date: 2012-03-26
Filing date: 2013-03-12
Publication date: 2015-02-04
Anticipated expiration: 2033-03-12
Also published as: WO2013143842A1; US20150024610A1; EP2831961B1; DE102012204830A1; CN104380542A; CN104380542B; US9281648B2

Abstract

A brush block for a slip ring arrangement consists of a spring clamp, which is mechanically held by two bores of a circuit board and which transitions into two contact springs. The spring clamp also has a solder joint for electrical contact with a conductor trace. Said solder joint is mechanically decoupled from the contact springs by two angle bends of the spring clamp.

Description

Brush block for a slip ring assembly

Technical area

The invention relates to a brush block and a slip ring assembly for transmitting electrical signals by means of sliding contacts between mutually rotatable parts. On a sliding track made of electrically conductive material, at least one sliding contact, also called a brush, grinds from a likewise electrically conductive material. Due to the galvanic contact between the grinding path and brush electrical current can be transmitted.

State of the art

A brush block in which spring wires are soldered in a circuit board, for example, from DE 201 15 215 Ul or from US 4,583,797 known. The production is relatively simple, with a precise positioning of the individual brush wires is hardly possible. Furthermore, the durability under continuous load is not satisfactory because the solder joints break up over time.

In EP 1 453 155 A2 a slip ring brush is disclosed, which is soldered to the top of a circuit board. By introducing solder from the underside of the circuit board is trying to obtain a large-scale solder joint, which should then achieve a sufficient mechanical strength. A disadvantage of this brush block is that in addition to the complex manufacturing process, due to the large support length of the brush wire on the circuit board and to avoid transverse forces on the solder joint only a U-shaped brush assembly can be realized. As a result, two brushes are at opposite locations the slideway, which requires a lot of installation space and allows only two brushes per slideway. DE 101 58 381 B4 discloses a slip ring transmitter in which a contact spring is fastened to a printed circuit board by a clamping mechanism. In JP 2010-232139A a generic arrangement is disclosed, wherein the brush wires are soldered in vias.

Presentation of the invention

The invention has for its object to design a brush block and a slip ring assembly such that it allows long-term stable fixation of the brushes and secure contact. At the same time this brush block and this slip ring assembly should be easy and inexpensive to produce, and have a long life and reliability. Furthermore, a flexible brush assembly and in particular a space-saving V-shaped brush arrangement should be possible, in which a plurality of brush blocks can be attached to a slip ring.

This object is achieved by a device according to claim 1. Advantageous embodiments of the invention are specified in the subclaims.

An inventive brush block for a sliding track comprises at least one carrier, which is preferably a printed circuit board. Furthermore, the brush block comprises at least one spring clip, which is electrically contacted on the carrier and mechanically fixed. The spring clip is preferably made of a metal wire or of a metallic sheet. Long-term investigations on brush blocks have shown that solder joints which are used both for contacting and mechanically fixing brushes often fail prematurely. Therefore, the brush block according to the invention is based on a separation of electrical contacting and mechanical fixing. For this purpose, the carrier comprises two preferably substantially parallel bores which hold a bent spring clip. In this case, the cranked part of the spring clip is located on the first side of the carrier, while the spring clip on the second side of the carrier, which is directed towards the grinding path or the slip ring module, forms at least one contact spring, preferably two contact springs. The spring clip is electrically contacted on the first side. For this purpose, it is soldered to the carrier with an electrical conductor, for example a conductor track. There is no solder connection to the spring clip on the second side of the carrier. As a result of this arrangement, an electrical contacting is now preferably carried out on the first side of the carrier by means of a contacting point, which is preferably a soldering point. Alternatively, the contacting can also include a press-in. Forces generated by a slip path on the contact springs are introduced into the carrier via the bores starting from the second side of the carrier. Between the contact spring and the contacting point is located on the first side of the carrier further a crank for mechanical relief of the bonding solder joint. The bend is here a resilient element. Thus, the pressure forces of the contact spring do not burden the solder joint, resulting in a substantial extension of the life and a much higher reliability. The fact that the spring clip is held in two holes, there is also an anti-rotation, which allows the recording of torques parallel to the surface of the carrier without loading the solder joint. The contacting and in particular Kontaktierungslötstelle could also be a through hole in a hole, unless through this hole a segment of the spring clip with a contact spring leads. Furthermore, it is preferred if the bore has a diameter corresponding to the diameter of the spring clip. In order to allow a good lateral guidance of the spring clip, the diameter of the bore should not be greater than twice the diameter, preferably 1.5 times and more preferably 1.2, or 1.1, 1.05 or 1.01 times the diameter , In order to achieve an even better guidance or fixation, the spring clip could also be pressed into the bore. For this purpose, the bore preferably has a smaller diameter than the diameter of the spring clip. Preferably, in this case, the diameter of the bore is not more than 0.95 or 0.9 times and more preferably 0.8 times the diameter of the spring clip. To increase the stability of the bore, it could be provided with a via. In this case, the via preferably has mechanically supporting properties and reinforces the bore. Although it serves to improve the electrical contact with the carrier, primarily the electrical contact is made by the mechanically non-loaded solder joint. In the case of a spring clip made of a flat material, a recess with a cross section corresponding to the cross section of the flat material could be provided instead of a bore.

In a first variant of the invention, the spring clip has a center piece with two ends, in which a crank with subsequent contact spring is provided at each end.

In a further variant of the invention, a crank with subsequent contact spring is provided only at one end of the middle piece.

Alternatively, two or more cranks can be provided in succession instead of a cranking. Basically, a bend can have different shapes. It could be semicircular or rectangular, or have a polygonal wire guide.

Particularly preferred here is an arrangement of the contact spring in V-shape, since this is particularly compact and has good transmission properties. However, according to each other in particular also a U-shape can be produced, in which the contact springs protrude approximately perpendicularly from the holes of the carrier. Preferably, the spring clip is not soldered within the holes. Therefore, the holes are particularly preferably not metallized in the interior. It can also be achieved with spring clips that are soldered in the holes, good results. Thus, the solder joint in the bore is not primarily necessary for the electrical contact, since the electrical contact is made via a mechanically decoupled by a bend contacting position. Thus, such a brush block would work well even if this solder joint in the hole.

The brushes are preferably metal wires and comprise at least one electrically conductive material. Preferably, you have a core of a mechanically stable and resilient material, such as steel, copper beryllium or brass and an outer coating or shell of a highly electrically conductive and preferably corrosion-resistant material, such as silver, gold or a gold alloy. Likewise, the brushes may also comprise wires of silver / or gold or alloys thereof.

A slip ring arrangement according to the invention has a slideway and at least one of the brush blocks disclosed herein. For guiding the brushes, the grinding path preferably has at least one V-groove. In principle, however, also sliding tracks with other geometries can be used. These may be, for example, flat sliding tracks or sliding tracks with U-shaped grooves (semicircular, elliptical).

A method according to the invention for producing a brush block described herein comprises the following steps:

1. providing a carrier with at least two holes,

2. Inserting a spring clip with at least one offset,

3. Make a bonding solder joint. Optionally, a lateral bending of the contact spring for adjusting the correct angle or the correct shape, such as a V-shape can be done.

Description of the drawings

The invention will now be described by way of example without limitation of the general inventive idea by means of embodiments with reference to the drawings.

FIG. 1 shows a brush block according to the invention

FIG. 2 shows the section of a brush block

FIG. 3 shows a further section of a brush block

FIG. 4 shows a detail of a spring clip

Figure 5 shows another embodiment of the invention

FIG. 6 shows a further embodiment of the invention

FIG. 7 shows a complete slip ring transmission

FIG. 8 shows the forces on contact springs

FIG. 1 shows a brush block 20 according to the invention. The brush block has a carrier 21, preferably a printed circuit board. The carrier 21 serves here for receiving contact springs 31, 32 as well as conductor tracks 60 for connecting the contact springs. The contact springs are here in a V-shape from the carrier. This design can be at least two, but usually also arrange four brush blocks around a slip ring module, allowing for a higher contact count. The conductor tracks have here connection bores 61, in or through which a connection wire can be inserted and soldered. By way of example, in each case two pairs of contact springs are electrically connected to one another by means of a strip conductor. Through these parallel circuits, the contact resistance can be reduced, the reliability increased and the contact noise can be reduced. The attachment of the brush block can be done via the fasteners 68 with holes 69

In Figure 2, a brush block is shown in section. The first contact spring 31 and the second contact spring 32 are integrally formed from a spring clip. The spring clip has a center piece 35, which is soldered to the carrier 21 in a contacting point. It is preferably soldered to a conductor 60 here. The middle piece 35 goes on one side into a first crank 33 and from there into the first contact spring 31 via, and from the second side into a second crank 34 and from there into the second contact spring 32 via. The middle piece 35 and the cranks 33, 34 lie on the first side 26 of the carrier. The contact springs 31, 32 are performed by means of bores 24, 25 through the carrier 21 to the second side 27 out. The bores of the carrier 21 can optionally be metallized inside or not metallized. Preferred for the invention is that the contact springs in the bore are not soldered to the circuit board. Therefore, it is further preferred if the holes are not metallized.

In Figure 3, the brush block is shown again in section. Here, the spring clip 30 with the middle piece 35, with its ends 37, 38, the cranks 34, 33 and the contact springs 31, 32 to see.

FIG. 4 shows a detail of a spring clip. The middle piece 35 of the spring clip 30 is by means of the contacting point 40 with the first side 26 of the Carrier 21 connected. Another solder joint 41 may be mounted between the second crank 34 and the second contact spring 32 on the first side 26 of the carrier 21 for the mechanical relief of the contacting point 40 via the crank 34. Preferably, however, there is no solder material at this location. Furthermore, there is preferably no solder connection between the second contact spring 32 and the second bore 25 in the carrier 21. However, for example, a press fit or a positive connection between them could exist.

FIG. 5 shows another embodiment of the invention. Here, the first contact spring 51 and the second contact spring 52 are separate mechanical components. These are not connected by a central piece. Instead, a first end piece 55 is guided at one end of the crank 53 through a second bore 25 and a first contact spring 51 through a first bore 24. The second contact spring is preferably designed symmetrically thereto. A second end 56 at the other end of the crank 54 to the second contact spring 52 is fixed here by a bore in the carrier 21. The contact springs shown here can be used individually or optionally arranged symmetrically. The contacting point 40 is located on the first side of the carrier 21 at the end of the second bore 25 or in a Durchkontaktie- tion of this bore.

FIG. 6 shows a further embodiment of the invention. This is similar to the embodiment of Figure 3. However, only one contact spring 32 is provided here.

7 shows a complete slip ring with a brush block 20, the first contact spring 22 and the second contact spring 23 on a grinding path 11 on a Schleifbahnträger 12 of a rotatable slip ring module 10th grind and thus be in electrical contact with this. There are still the directions of the forces 71, 72 located on the contact spring 22, 23.

In FIG. 8, the forces on the contact spring are again shown in detail. The forces 71, 72 are perpendicular to the contact points of the contact springs on the grinding path. In this illustration, only the force 72 will be discussed, since the force 71 is symmetrical to the opposite contact spring to this. The force 72 can be divided into a first component 73 parallel to the carrier and a second component 74 perpendicular to the carrier. The component 73 parallel to the carrier is balanced by a second opposite component from the other contact spring. The component 74 perpendicular to the carrier is already partially received at the bending point 36 of the contact spring directly at the beginning of the bore 25 in the carrier. The crank 34 acts like a spring and prevents a still small proportion of the second vertical component 74 from overburdening the solder joint on the center piece. Furthermore, results from these forces at the entry point of the contact springs in the carrier 21, a bending moment 75, which can also be largely absorbed by the bore 25 in the carrier.

LIST OF REFERENCE NUMBERS

10 slip ring module

11 slideway

12 slideway carriers

20 brush block

21 carriers

22 first contact spring

23 second contact spring

24 first bore

25 second hole

26 first side of the carrier

27 second side of the carrier

30 spring clip

31 first contact spring

32 second contact spring

33 first bend

34 second bend

35 middle piece

36 bending point

37, 38 ends of the middle piece

40 contact point

41 soldering contact spring

51 first contact spring

52 second contact spring

53 first bend

54 second crank first tail

second tail

, 62 trace

, 63 connection hole

Mounting element mounting hole, 72 forces on the contact springs, 74 force components

Claims

claims

A brush block for a sanding track (11) comprising at least one support (21) with a first side facing away from the sanding path, a second side facing the sanding path, and at least one spring clip (30) attached thereto with at least one contact spring (31, 32, 51 ), wherein the spring clip with at least one contact point (40) is electrically conductively connected to an electrical conductor on the carrier, the carrier (21) has two bores (24, 25) for supporting the spring clip (30), and the spring clip starting from the first side to the second side of the carrier passes through both holes and on the second side in at least one contact spring (31, 32, 51) passes,

characterized in that

the spring clip (30) has at least one offset (33, 34) on the first side of the carrier between the at least one contacting point (40) and the at least one contact spring (31, 32).

2. Brush block according to claim 1,

characterized in that

the contacting point (40) is a solder joint.

3. Brush block according to claim 1,

characterized in that

the contacting point (40) comprises a press-in contact.

4. Brush block according to claim 1 or 2,

characterized in that

the spring clip (30) has a central piece (35) with two ends (37, 38) which at each end into a crank (33, 34) with subsequent Kon- (31, 32) merges, and wherein the center piece via the contacting point (40) is connected to the carrier (21).

5. Brush block according to claim 1 or 2,

characterized in that

the spring clip (30) has a central piece (35) with two ends (37, 38) which is provided at each end in a crank (33, 34) with only a bend in a subsequent contact spring (33) passes and the second crank protrudes into a bore with one end, and wherein the middle piece is connected to the carrier (21) via the contacting point (40).

6. Brush block according to claim 1,

characterized in that

the spring clip (30) has an offset (53) with a contact spring (51) passing through the first bore (24) on one side, and the second side of the offset projects into the second bore (25) and simultaneously via a contacting point (25). 40) is connected to the carrier (21).

7. Brush block according to claim 6,

characterized in that

the second bore (25) is internally metallized and filled with solder.

8. Brush block according to one of the preceding claims,

characterized in that

the carrier (21) is designed as an electrical circuit board.

9. Brush block according to one of the preceding claims,

characterized in that at least one contact spring (31, 32) a core of a mechanically stable and resilient material, such as steel, copper beryllium or brass and an outer coating or shell of a good electrical conductivity and preferably corrosion resistant material, such as silver, gold or a Silver or gold alloy has.

10. Brush block according to one of the preceding claims,

characterized in that

at least one contact spring (31, 32) silver, gold or a silver or gold alloy has.

11. Brush block according to one of the preceding claims,

characterized in that

the at least one contacting point (40) is located on the first side of the carrier.

12. Brush block according to one of the preceding claims,

characterized in that

at least one bore through which a contact spring of the spring clip is guided, having a metallization on the inside, which is not soldered to the spring clip.

13. slip ring assembly comprising a sanding track (1) and at least one brush block according to one of the preceding claims.

14. A method for producing a brush block according to one of the preceding claims characterized by the following steps:

Providing a carrier with at least two holes, Inserting a spring clip with at least one offset,

- Making a contacting solder joint.