WO2012041922A1 - Current-transmitting arrangement for electromechanical machines and systems - Google Patents

Abstract

The invention relates to a current-transmitting arrangement for electromechanical machines and systems, comprising a slip ring arranged on a shaft. The slip ring has a slip ring body made of a hard electrically conductive non-oxidic ceramic material. The invention further relates to a slip ring body and to a method for producing the slip ring body.

Description

 Power transmission arrangement for electromechanical machines and installations

The present invention relates to a power transmission assembly for electromechanical machines and equipment with a arranged on a shaft slip ring and a contact surface in sliding contact against a S chleifringoberfläche adjacent, having carbon contact element. Moreover, the present invention relates to a ceramic material for use as Schleifring- body for a S chleifring such Stromübertragungsanordnung, a method for producing a slip ring body for such a power transmission device and a S chleifringkörper for a S chleifring such Stromübertragungsanordnung.

Current transfer arrangements of the type mentioned are used in principle wherever a current transfer contact between a rotating part, rotor, and a stationary part, stator takes place to form electromechanical machines. As a contact element for the power transmission, a slip ring is formed on the rotor, which usually has a metal S chleifringkörper and is for power transmission in physical contact with a fixed contact element of the stator, which as a rule So-called carbon brush is executed with a mainly consisting of graphite or a mixture of graphite and copper brush body, which is subject to constant wear due to the contact between a contact surface formed on the brush body and the slip ring surface.

As a rule, the replacement of a brush body of a carbon brush is much easier than the replacement of a slip ring, great care is taken to ensure that as low as possible wear on the slip rings. This is all the more true if the usually time-consuming expiry of replacement of slip rings in exposed locations with cumbersome accessibility, as is the case for example on wind turbines, or under particularly harsh environmental conditions must be done. Thus, for example, abrasive components or additives added to the brush body to provide some abrasive effect in contact with the slip ring surface to remove, for example, a surface coating formed on the metallic abrasive surface or the formation of a transfer film formed by graphite deposition on the slip ring surface to limit, added only to a relatively small extent, to prevent excessive wear by surface abrasion of the slip ring surface. The consequence of this is that in a particularly conducive to the formation of a surface covering environment, as is the case for example at elevated operating temperatures in oil or lubricant-containing air or in a corrosive environment, it can lead to a surface coating despite the abrasive additives of the brush body , which jeopardizes a proper function of the power transmission arrangement.

In addition, it may be precisely at elevated operating temperatures due to the different thermal expansion coefficients between metallic S chleifringkörpern and insulating, formed for example of ceramic insulation intermediate bodies of the rotor mechanical problems in the operation of corresponding electromechanical machines come.

The present invention is therefore based on the object to propose a power transmission arrangement, which allows for a trouble-free operation even under particularly harsh environmental conditions, and on the other hand requires low maintenance.

This object is achieved by a current transfer arrangement with the features of claim 1 dissolved.

In the power transmission arrangement according to the invention, on the one hand, the contact element in addition to the carbon as electrically conductive

Component on an abrasive component, and on the other hand, the slip ring to form a hard, resistant to abrasion resistant S chleifringoberfläche a S chleifringkörper of a hard electrically conductive non-oxidic ceramic material. The inventive combination of a abrasive component having a contact element with an electrically conductive slip ring body of a non-oxide ceramic material allows the contact element to add the abrasive component in such an amount and / or quality to achieve such abrasion effect that a safe removal of Ensures formed on the slip ring surface surface coverings or a generation of an undesirable surface covering or excessive transfer film can be prevented without it comes as a result of the abrasive component of the contact element to such wear on the slip ring surface, an undesirable accumulation of maintenance operations or replacement would make the slip ring body required. As abrasive components or additives are basically material particles in question, which have a greater hardness compared to graphite as the main component of the brush body.

The slip ring body achieves the corresponding abrasion resistance by forming it from a hard non-oxidic ceramic material. In contrast to carbon-graphite ceramic materials, which are soft and form a greasy transfer film in contact with a mating partner, non-oxide ceramic materials are hard with a corresponding surface resistance.

The necessary for the function of a power transmission arrangement electrical conductivity of the non-oxide ceramic body can be achieved, for example, that a semiconductor is used. Although the electrical conductivity of a polycrystalline

Non-metal, so a semiconductor, reduced by a multiple compared to the electrical conductivity of metals, so far the possibility of an electrically conductive ceramic as a material for a slip ring body due to a corresponding technical prejudice was not considered at all. However, it is basically possible to take into account or at least partially compensate for a correspondingly reduced electrical conductivity by taking into account the geometry of the slip ring body, that is to say, for example, in the shape and size of the slip ring surface. In particular, the resulting due to the limited electrical conductivity high electrical resistances with appropriate heating of the slip ring body a proper Funkti on the slip ring body are not opposed, especially since the volume change effects in a ceramic slip ring body due to the relatively low temperature expansion coefficient are relatively low. In addition, there is basically the possibility to increase the electrical conductivity of the ceramic material by electrically conductive additives or treatments.

In particular, in this context, it is particularly advantageous if, according to one embodiment of the current transfer arrangement for the slip ring body, a non-oxidic silicon carbide-based ceramic material is selected. Particularly good results with regard to a sufficient electrical conductivity are possible if the material is a composite material, in addition to silicon carbide

Graphite for forming a corresponding silicon carbide graphite matrix. In a further phase in addition to silicon carbide, a metal, for example copper or aluminum, may be present.

According to the invention, a non-oxidic ceramic material has been disclosed for use as a material for a slip ring body of a slip ring of a power transmission device comprising silicon carbide and graphite as components and having in a preferred composition at least 50 volume percent silicon carbide and at least 40 volume percent graphite.

In the method according to the invention for producing a slip ring body for a power transmission arrangement for electromechanical machines, in a first phase of the process, a carbon molded body is carbonized and graphitized, and in a subsequent second phase of the process impregnation of the molded body with liquid silicon followed by training a silicon carbide graphite composite matrix.

The slip ring body according to the invention is characterized by the production steps of the method according to the invention and accordingly has a microstructure with a silicon carbide-graphite composite matrix. Alternatively, the grahite part can also be removed by oxidation and the voids formed in the slip ring body by the resulting porosity can be filled by impregnating the slip ring body with a metal, such as, for example, copper of the aluminum.

For the slip ring body according to the invention, there are a variety of possible applications, especially in machines or systems with very high service life requirements or those where as long as possible maintenance intervals are sought, in particular because of difficult accessibility of the power transmission arrangement. Examples include: electrical or electromechanical drives of motor vehicles or generators of wind turbines.

Claims

claims

1. power transmission arrangement for electromechanical machines and systems with a arranged on a shaft slip ring and with a contact surface in sliding contact against a slip ring surface adjacent, having carbon contact element,

 characterized,

 the contact element has an abrasive component in addition to the carbon as the electrically conductive component, and the slip ring has a slip ring body made of a hard electrically conductive non-oxidic ceramic material to form a hard, abrasion-resistant slip ring surface.

2. Power transmission arrangement according to claim 1,

 characterized,

the material selected for the slip ring body is a silicon carbide based ceramic material.

3. A power transmission arrangement according to claim 2,

 characterized,

 that the ceramic material is a composite material which has graphite in addition to silicon carbide.

4. Ceramic material for use as a slip ring body for a slip ring of a power transmission arrangement for electromechanical machines and plants,

 characterized,

 that the material is formed as a composite material with the components silicon carbide and graphite.

5. Ceramic material according to claim 4,

 characterized,

 that the material has a composition with

at least 50% silicon carbide by volume,

- at least 40% by volume of graphite.

6. A method for producing a slip ring body for a slip ring of a power transmission assembly for electromechanical machines and plants,

 characterized,

that in a first phase of the process a carbon mold is carbonized and graphitized, and in a subsequent phase of the process the carbon mold is impregnated with liquid silicon to form a composite matrix of silicon carbide and graphite.

7. Slip ring bodies for a power transmission arrangement for electromechanical machines and installations,

 marked by,

 an embodiment of a ceramic material having the features of claims 4 or 5.

8. slip ring body according to the preceding claim,

 characterized,

 the slip ring body has a microstructure with a composite matrix of silicon carbide and graphite.

9. slip ring body according to claim 8,

 characterized,

 that the slip ring body has a microstructure with a composite matrix of silicon carbide and a metallic portion.

10. slip ring body according to claim 9,

 characterized,

 the metallic component consists of copper and / or aluminum or an alloy containing copper or aluminum.