Method for producing a multilayer sliding bearing element

专利摘要:
The invention relates to a method for producing a multilayer sliding bearing element having a first layer of a metal having an inner side, after which this inner side is cleaned by sweeping the entire inner surface with a laser and then at least one further layer is applied to the inner side of the first layer , The cleaning is carried out with an ultrashort pulse laser. Preferably, the first layer is a copper-based alloy, in particular a bronze. In particular, with the cleaning of the inside, these are simultaneously roughened to form a microgeometry, preferably with an arithmetic mean roughness Ra of between 30 nm and 1 μm, preferably with an average roughness depth Rz of between 200 nm and 5 μm. The cleaning is preferably carried out by line-sweeping the inside of the first layer with the laser in processing paths which overlap one another. The cleaning of the inside of the first layer is preferably carried out at a distance from the laser, which corresponds to the focal length of the laser. As a further layer, a bonded coating layer can be applied.
公开号:AT15618U2
申请号:TGM50155/2017U
申请日:2017-08-18
公开日:2018-03-15
发明作者:Ing Dr Georg Leonardelli Dipl
申请人:Miba Gleitlager Austria Gmbh；
IPC主号:

专利说明:

Description: The invention relates to a method for producing a multilayer sliding bearing element having a first layer of a metal having an inner side, after which this inner side is cleaned by sweeping the entire inner surface with a laser and then at least one on the inner side of the first layer another layer is applied.
Mehrschichtgleitlager and their preparation are widely described in the prior art. In the simplest case, these are two-layer bearings in which a running layer is arranged on a supporting layer. However, embodiments are also known which have more than two layers.
In the production of these multilayer plain bearings are often forming processes and, associated with it, also mechanical machining of surfaces, such as fine boring or impact spaces, required to comply with predetermined geometries of multilayer bearings. This also applies to the supporting layer, the so-called back metal layer. Often this consists of a steel, but it can also be used other materials, such as bronzes.
To save the tools as possible, to improve the clamping accuracy, to avoid damage to parts or to improve the bond strength of the interconnected layers, surfaces of impurities from previous operations must be exempted, including oils and fats. For this purpose, solvents can be used, which are often applied manually by means of appropriate cloths. However, these cleaning methods are problematic due to the very low process quality due to very quickly soiling cloths and the associated reduced cleaning effect. Last but not least, solvents are problematic for health.
A safe cleaning of a surface to be coated is possible with erosive methods. But as well as the chemical cleaning also this mechanical cleaning leads to contamination and carryover of material and dirt. This in turn can not only lead to a reduction of the adhesive strength of the coating to be deposited on this surface, but also to the formation of corrosive nuclei, especially when these contaminants are embedded in the cleaned layer. The latter can arise, for example, in that the surface to be coated is partially melted.
The object of the present invention is to provide an improved cleaning method for the production of multi-layer plain bearings.
The object of the invention is achieved in the aforementioned method in that the cleaning is carried out with an ultrashort pulse laser.
The advantage here is that the cleaning of the inside of the first layer can be performed with consistent quality and high security of non-reflow, since relatively little energy is introduced into the respective surface areas subjected to the cleaning by the use of a ultrashort pulse laser. It does not create individual holes with remelted edges. By vaporizing the fats and oils, no solvents are required, so that no residues of solvent remain on or in the first layer. In particular, structural changes due to the heat input into the first layer can be better avoided by using an ultrashort pulse laser. The cleaning can thus be carried out more easily by machine without changing the microstructure of the first layer.
According to one embodiment of the method can be provided that a copper-based alloy, in particular a bronze, is used as the first layer. Copper-base alloys, such as bronzes in particular, exhibit pronounced reflectivity, whereby the use of a laser to clean the surface of a layer of a multi-layer slip oil element bislana has been problematic, if not at least partially imperfect.
By using an ultrashort pulse laser, the problems associated with the laser cleaning of surfaces of copper-base alloys are not or not very pronounced, namely that they are exposed to the laser radiation for a relatively long time, whereby the risk of melting surface areas increases significantly.
Preferably, according to another embodiment of the method with the cleaning of the inside of these roughened simultaneously to form a micro-geometry. The roughening, ie the material removal, can further increase the quality of the surface cleaning. At the same time, however, a surface can also be created with which improved adhesion of the layer to be deposited thereon can be achieved.
In order to further improve these effects, in particular to increase the adhesive strength of the further layer on the first layer, it can be provided according to embodiments that the microgeometry with an arithmetic mean roughness Ra according to DIN EN ISO 4287: 2010 between 30 nm and 1 pm and / or that the microgeometry with an average roughness Rz according to DIN EN ISO 4287: 2010 between 200 nm and 5 pm at a maximum single roughness Rmax according to DIN EN ISO 4287: 2010 between 200 nm and 5 pm is produced.
According to another embodiment of the method can be provided that the cleaning is performed by cell-like sweeping the inside of the first layer with the laser in processing paths, wherein the processing paths overlap each other. The overlap of the laser points can further increase process reliability.
It can also be provided according to a further embodiment of the method that the cleaning of the inside of the first layer takes place at a distance from the laser, which corresponds to the focal length of the laser. Not only can the energy efficiency of the surface cleaning be improved, but also the previously mentioned microgeometry can be better prepared, since the laser can create traces on the inside of the first layer, for example in the form of a pattern due to the cell-shaped sweeping.
Particularly preferred as a further layer, a bonded coating layer is applied to the first layer. In particular, in such layers, the advantages of the method come into play, since thus the continuous loadability of the polymer layers which are more susceptible to wear in comparison with metallic layers can be improved.
For a better understanding of the invention, this will be explained in more detail with reference to the following description.
By way of introduction, it should be noted that the location information chosen in the description, such as. top, bottom, side, etc. are related to the directly described embodiment of the multi-layer sliding bearing element and are to be transferred mutatis mutandis to the new situation in a change in position.
The multi-layer sliding bearing element may be formed in the form of a half-shell, and forms in this case, together with at least one further sliding bearing element from a sliding bearing, as is well known. It is also possible that the multi-layer sliding bearing element is designed as a sliding bearing bushing (in this case, the multi-layer sliding bearing element is at the same time the plain bearing) or as a thrust ring. Further, there is the possibility of another division, for example, a third division, so that the multi-layer sliding bearing element is combined with two other sliding bearing elements to form a sliding bearing, wherein at least one of the two other sliding bearing elements may also be formed by the multi-layer sliding bearing element. In this case, the multi-layer sliding bearing element does not cover an angular range of 180 ° but an angular range of 120 °. But there is also the possibility that at least one of the at least one further sliding bearing elements is formed by the multi-layer sliding bearing element.
In particular, the multi-layer sliding bearing element is intended for use in the engine industry or in engines.
A multi-layer sliding bearing element, which is cleaned during its production by the method according to the invention, has at least a first layer and at least one further layer.
It should be mentioned at this point that the term "cleaning" both the removal of at least one fat per se, as well as the removal of at least one oil and other impurities, such as solvent, is understood and oils are those commonly used in the manufacture of multi-layered sliding bearing elements.
In addition to this, if necessary, any existing dirt can be removed. This dirt can also be present in the form of typical deposits of processing fluids from previous processing steps. The processing fluids also include, but are not limited to, coolants, machining oils, drilling emulsions, etc. The deposits may also be of a salt or other solid nature.
The first layer is in particular the supporting layer of a multi-layer guide bearing element. This is usually the radially outermost layer of a radial sliding bearing.
The further layer is in particular the running layer in the case of a two-layer or multi-layer sliding bearing element. The running layer is that layer which, during operation, is in contact with the component to be supported, ie in particular a shaft, unless an additional so-called flash is applied which, for example, serves for the inlet of the multi-layer sliding bearing.
It should be noted, however, that the first layer can also be formed by another layer of a multi-layer sliding bearing element, for example a so-called bearing metal layer.
In any case, the further layer is deposited directly on the first layer of the multi-layer sliding bearing element.
The support layer forms the so-called back side metal, which faces a bearing receptacle in which the multi-layer sliding bearing element is received during operation. Normally, in the case of cup-shaped multi-layer sliding bearing elements, this back-side metal layer forms the radially outer layer, provided that no antifretting layer which is intended to prevent damage to a sliding bearing due to micromovements between the bearing receptacle and the multilayer plain bearing element is applied.
The support layer may consist of a steel. However, it is also possible to use other, known metallic materials. Preferably, the support layer or generally the first layer is formed by a copper-based alloy, in particular a bronze.
However, the first layer can also be formed by an aluminum alloy.
According to a further preferred embodiment of the method, the further layer is made of a bonded coating. Coating lacquer is understood to mean a lacquer which contains a solvent (mixture), at least one precursor for a polymer and at least one solid lubricant and optionally reinforcing agent. For this, after application to the first layer by drying and polymerization, in particular at elevated temperature, a solid layer is produced with sliding properties.
As a polymer, a polyimide, in particular a polyamideimide, is preferably prepared. As solid lubricants, preferably graphite and MoS2 are used. The reinforcing agents may be particulate, for example oxides or mixed oxides, in particular bismuthvana-date, chromium-antimony-rutile or mixtures thereof.
However, other known bonded coatings may also be used.
The multi-layer sliding bearing element may also have more than two layers. Thus, for example, between the support layer and the running layer, said bearing metal layer and / or at least one bonding layer and / or at least one diffusion barrier layer may be arranged.
The metallic materials that can be used in multi-layer sliding bearing elements for the running layer, the bearing metal layer, the bonding layer and the diffusion barrier layer are known from the prior art, so reference is made in this respect.
The method for producing a multi-layer sliding bearing element per se are known from the prior art. In essence, two methods can be distinguished here. According to a first embodiment, a planar substrate is produced from the material for the support layer and, if appropriate with interposition of at least one intermediate layer (in particular at least one of the above), the running layer is arranged thereon, from which the composite material is produced. These include e.g. the classical methods such as roll cladding, cast cladding, sintering. From this blank is then formed by forming the multi-layer sliding bearing element.
In addition, there are also processes in which the deformation of the blank is carried out before the deposition of the material for the overlay. These include, for example, electrodeposition and PVD methods, such as e.g. Sputtering.
In addition, there is the possibility that the support layer is formed by the component itself, so for example a connecting rod, in particular in the region of the connecting rod eye. In this case, the running layer is then applied by direct coating of the connecting rod.
In all methods, a mechanical processing in the course of the production of the multi-layer sliding bearing element may be required in order to provide the desired or required geometry with the lowest possible tolerances can. Usually these are mostly machining operations, such as fine boring or bumping. These mechanical operations use coolants in the form of oils or oily liquids to protect the tools from overheating and thus extend tool life.
Further, the materials for the individual layers or composites thereof may come into contact with fats in the processing machines during the manufacturing process of the multi-layer sliding bearing element.
The fats and oils and generally dirt must be removed again. This applies in particular to the inside of the support layer (or generally the first layer), before a further layer is deposited thereon.
As the inner side, the radially inner surface or the surface of a layer of a multilayer sliding bearing element closer to a component to be supported is generally referred to.
For cleaning the inside of the first layer, an ultrashort pulse laser is used. It is a laser beam source that emits pulsed laser light with pulse durations in the range of picoseconds to femtoseconds or in the range of picoseconds to attoseconds or in the range of femtoseconds to attoseconds. The pulse duration is therefore less than 1 ns.
The cleaning of the inside can after a machining and before a further mechanical processing, in particular for the removal of chips (incurred, for example, when fine boring), are performed. The removal of the chips is preferably carried out by brushing. In particular, the brushing is performed only after degreasing, as less chips stick to the brushes.
In order to clean the corresponding surface of the multilayer sliding bearing element (it is also understood as a precursor of the finished multilayer element in the sense of the invention), the entire inside of the first layer (or the supporting layer) is traversed with the laser, so that the Laser in the course of cleaning every spot of this surface at least once passes.
The sweeping of the surface with the laser can be done linearly in the form of a dot matrix. It is advantageous if the focus of the laser is on the surface to be cleaned, for which the distance between the surface to be cleaned and the laser corresponds to the focal length. As a result, the surface is punctured by the laser.
But it can also be provided that the surface to be cleaned is located outside the focal point of the laser, for which the distance between the surface and the laser is smaller or larger than its focal length. As a result, the surface of the laser radiation in the form of a circle or an ellipse, depending on which position the laser occupies to the surface, hit.
In this case, the distance between the surface and the laser (ie, the exit of the light beam from the laser) by a value smaller or larger than the focal length, which is selected from a range of 0.5 mm to 20 mm, in particular from a range of 2mm to 5mm.
The distances of the points or circles of said grid are chosen in particular so that adjoin the areas covered by the laser per pulse adjacent to each other or preferably overlap each other.
Furthermore, the distance between the laser and the surface to be degreased can be selected such that the focal point lies below the first layer, ie outside.
The laser-cleaning can be done without removal of the metal from which the first layer consists. Further, the laser cleaning can be performed so that no change in the structure of the support layer takes place. In addition, the cleaning can also be carried out such that no compounds with a constituent of the material of the first layer, such as oxides, are removed with the laser.
According to a preferred embodiment of the method can be roughened simultaneously with the formation of a microgeometry with the cleaning of the inside of the first layer, for which a corresponding removal of material from the surface of the first layer takes place.
The microgeometry is preferably with an arithmetic mean roughness Ra according to DIN EN ISO 4287: 2010 between 30 nm and 1 pm, preferably between 30 nm and 70 nm, and / or with an average roughness Rz according to DIN EN ISO 4287: 2010 between 200 nm and 5 pm, preferably between 200 nm and 350 nm, produced at a maximum individual roughness Rmax according to DIN EN ISO 4287: 2010 between 200 nm and 5 pm. Of course, Rmax can not be smaller than Rz.
For carrying out the cleaning laser pulses are used, preferably the number of pulses is high and the pulse duration is short, whereby a thermal load on the surface to be cleaned can be avoided. The pulse rate can vary between 10 kHz and 1 MHz. The area power depends on the pulse frequency and the distance between the individual laser spots on the surface to be degreased (the size of the laser spots can be between 50 pm and 300 pm). For example, at 35 W output power of the laser, the max. Pulse energy approx. 175 pJ and the area power approx. 3 J / cm (pulse frequency 200 kHz, pulse duration 1 ps).
It is further preferred if the pulse strength and the pulse duration of the laser are kept constant during the entire cleaning of the surface.
According to one embodiment, it can be provided that the cleaning is performed by cell-like sweeping the inside of the first layer with the laser in processing paths, wherein the processing paths overlap each other. The overlap duna range can be selected from 1% to 50%% of the width of a processing line. All processing tracks preferably have the same width.
The embodiments describe possible embodiments of the method, wherein combinations of the individual variants are possible with each other.

权利要求:
Claims (8)
[1]
claims
1. A method for producing a multi-layer sliding bearing element having a first layer of a metal having an inner surface, after which this inside is cleaned by sweeping the entire inner surface with a laser and then on the inside of the first layer at least one further layer is applied, characterized characterized in that the cleaning is carried out with an ultrashort pulse laser.
[2]
2. The method according to claim 1, characterized in that a copper-based alloy, in particular a bronze, is used as the first layer.
[3]
3. The method according to claim 1 or 2, characterized in that with the cleaning of the inside this is roughened simultaneously to form a micro-geometry.
[4]
4. The method according to claim 3, characterized in that the microgeometry is produced with an arithmetic mean roughness Ra according to DIN EN ISO 4287: 2010 between 30 nm and 1 pm.
[5]
5. The method according to any one of claims 3 or 4, characterized in that the microgeometry with an average roughness Rz according to DIN EN ISO 4287: 2010 between 200 nm and 5 pm at a maximum single roughness Rmax according to DIN EN ISO 4287: 2010 between 200 nm and 5 pm is produced.
[6]
6. The method according to any one of claims 1 to 5, characterized in that the cleaning is performed by cell-like sweeping the inside of the first layer with the laser in processing paths, wherein the processing paths overlap each other.
[7]
7. The method according to any one of claims 1 to 6, characterized in that the cleaning of the inside of the first layer is performed at a distance from the laser, which corresponds to the focal length of the laser.
[8]
8. The method according to any one of claims 1 to 7, characterized in that as a further layer, a lubricating varnish layer is applied.

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATGM50155/2017U|AT15618U3|2017-08-18|2017-08-18|Method for producing a multilayer sliding bearing element|ATGM50155/2017U| AT15618U3|2017-08-18|2017-08-18|Method for producing a multilayer sliding bearing element|

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US16/025,202| US20190055987A1|2017-08-18|2018-07-02|Method for producing a multi-layer plain bearing|

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CN201810786962.2A| CN109404417A|2017-08-18|2018-07-18|Method for manufacturing multilayer plain bearing element|

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EP18187299.5A| EP3444490A1|2017-08-18|2018-08-03|Method for the production of a multilayer sliding bearing element|

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BR102018017008-2A| BR102018017008A2|2017-08-18|2018-08-20|METHOD FOR THE PRODUCTION OF A MULTIPLE LAYER ROLLING ELEMENT|