WO2000023718A1

WO2000023718A1 - Method for coating the bearing surface of a bearing component, and bearing component

Info

Publication number: WO2000023718A1
Application number: PCT/DE1999/003253
Authority: WO
Inventors: René Reinhard WEHNERT
Original assignee: Siemens Aktiengesellschaft
Priority date: 1998-10-21
Filing date: 1999-10-08
Publication date: 2000-04-27

Abstract

A bearing substance (15) is applied to the bearing surface (2) of a bearing component (1), especially a bearing in a turbomachine, by means of a laser beam (23). This improves the bearing substance's (15) ability to adhere to the bearing component (1) and therefore increases the service life of said bearing component (1).

Description

description

Process for coating the tread of a bearing component and bearing component

The invention relates to a method for coating the tread of a bearing component, in particular for a bearing of a turbomachine shaft. The invention also relates to a bearing component.

In the book "Machine Parts", Part 2, Köhler and Röbnitz, Verlag B.G. Teubner, Stuttgart, 1992, (8th ed., Page 92, chapter 2.3.3 Materials) the following is explained about materials for plain bearings:

"Properties for the suitability of a material as a plain bearing material are: good running-in, sliding and emergency running properties, high wear, pressure and fatigue strength, high flexibility and sufficient temperature resistance. If the lubrication fails and in the area of mixed friction, there is contact of bearing and bearing material must not be prevented. Therefore, even in bearings that otherwise run in the area of fluid friction, these materials must have good running properties. Essential here is the correct pairing of materials. Suitable materials offer a smooth, polished surface during the running-in period, unsuitable ones roughen up and tend to “eat.” Even with the right choice of material, for example due to lubrication failure, temperatures that reach the melting point of steel can occur locally at the points of contact used by turbine rotors For this reason, a bearing material with a low softening or melting point, for example white metal. This melts at temperatures that do not pose any danger to the cone. On page 96 of the same book it says: "The part of the bearing that contains the tread is called if it is undivided (or only slotted), liner. If it is divided, then the halves are called "bearing shells".

In the book "Gleitlager" by Lang and Stemhilper, from the series Konstruktionsbucher, Vol. 31, Springer Verlag 1978, on page 57:

"Because of the lack of strength, white metal is always used in a composite design, i.e. the white metal is poured into my support body and dovetail grooves are used to improve the positive fit. The load capacity increases, the lower the spout thickness

Under chap. 4.4 "Bearing damage" is described from page 65 onwards, which various causes of bearing damage can have. Soiling, wear, corrosion, washout / gravitation, fatigue, overheating, binding errors and installation errors are mentioned.

The object of the invention is to provide a method for coating the tread of a bearing component with a bearing material, which leads to a durable and reliable tread coating. Another object of the invention is to provide a bearing component that has a long service life due to a durable coating of its running surface with a bearing material.

According to the invention, the object directed to a method is achieved by a method for coating the tread of a bearing component with a bearing material, in which the bearing material is applied to the tread of the bearing component and melted by means of a laser beam.

The running surface of the bearing component is the surface on which the component to be supported, for example a shaft, is guided. As stated above, the bearing material was applied the tread of a bearing component so far by pouring or spinning. The invention is based on the knowledge that this application of the bearing material can lead to binding errors. These binding errors result e.g. B. from bubbles or cavities in the bearing material.

In contrast, in the invention, the bearing material is applied to the running surface of the bearing component by means of a laser beam. This leads to a considerably improved material connection between the bearing component and the bearing material. In addition, dovetail grooves can be dispensed with in the bearing component. This reduces both the manufacturing effort and the material requirement for bearing material. Furthermore, damage to the tread coating can be easily repaired by local application of the bearing material with the addition of heat. There is also a broader spectrum for the bearing materials that can be used. Finally, it is also possible to reduce the thickness of the bearing material coating and thus save additional bearing material.

The tread is preferably heated by the laser beam to such an extent that the bearing material forms a material connection with the tread. Such a cohesive connection corresponds to an alloying of the bearing material to the bearing component. A boundary layer is thus formed between the bearing component and the bearing material, which consists of an alloy of the bearing material with the base material of the tread. Such an alloying of the bearing material to the running surface results in a particularly good connection of the bearing material.

The laser beam preferably heats the running surface locally in a heating spot, the bearing material being applied to the heating spot. The laser beam is further preferably guided line by line over the running surface. This process can be automated well. Furthermore, certain construction elements, such as holes or bevels, can be processed in one step using laser technology.

After the tread has been coated with the bearing material, the laser beam is preferably guided over the running surface in such a way that the tread is smoothed by remelting of the bearing material. Applying the bearing material by means of the laser beam can result in humps forming along the guide of the laser beam, so that the tread - now formed by the bearing material - has a groove structure. Since the laser beam is preferably guided across the tread surface after line-by-line application, the re-melting, cell-shaped humps in the bearing material align with one another. The tread is smoothed.

A white metal is preferably applied as the bearing material. White metals are lead-tin-based alloys. A distinction is made between lead-rich and tin-rich alloys. The lead-rich alloys contain e.g. 10% by weight of tin, 15% by weight of antimony, 1% by weight of copper and the rest of lead. A tin-rich alloy contains e.g. 80% by weight of tin, 12% by weight of antimony, 6% by weight of copper and the rest of lead. These alloys meet the basic requirements for a bearing material particularly well.

The bearing component is preferably a liner.

The bearing component is preferably a bearing shell. A bearing shell of a bearing for a turbomachine shaft is further preferably coated with the bearing material. With turbo machine shafts weighing tons, there are particularly high demands on the bearing shells of your bearings. Even the smallest imbalance and vibrations lead to very large forces on the bearings. For the large and expensive bearing shells there is a particularly high need to prepare them quickly and if possible Place to repair. This is in a simple manner with the aid of the - possible connection of the bearing material ^¬ material by means of the laser beam - optionally localized. In particular, this means that expensive storage of bearing shells, for example, can be dispensed with.

According to the invention, the object directed to a bearing component is achieved by a bearing component with a base material and with a bearing material applied to the base material, the bearing material being applied in rows by means of a laser beam.

The bearing component thus has a line-like structure in the bearing material which can be uniquely assigned to the line-like local melting using a laser beam.

The bearing component is preferably part of a bearing of a turbomachine shaft. The bearing material is preferably a white metal.

Exemplary embodiments of the invention are explained in more detail by way of example with reference to the drawing. Some do not show to scale and schematically:

FIG. 1 shows the application of a bearing material to a bearing shell using a laser beam,

FIG. 2 shows the method from FIG. 1 in a top view,

FIG. 3 shows the method from FIG. 2 in an enlarged illustration in a longitudinal section,

FIG. 4 the smoothing of a bearing material applied line by line,

5 shows a section of a cross section through a bearing component, and Figure 6 shows a liner.

The same reference numerals have the same meaning in the different figures.

FIG. 1 shows a longitudinal section through a bearing component 1 designed as a bearing shell with a running surface 2. When the bearing shell 1 is used, a body (not shown) that is to be supported lies against the running surface 2, for example a shaft. The bearing shell 1 can be rotated by means of the roller 25. A laser beam 23 from a laser 21 strikes the running surface 2 of the bearing shell 1. At the point of incidence of the laser beam 23 on the running surface 2, the heating spot 31, a wire material 13 is melted from a wire 13. The bearing material 15 is thereby alloyed to the tread 2. The bearing shell 1 is rotated by means of a roller 25, so that the laser beam 23 is guided in a cell shape over the running surface 2. This is explained in more detail with reference to FIG. 4. This results in a very good connection of the bearing material 15 to the bearing shell 1. Binding errors which can occur when the bearing material 15 is applied conventionally do not occur here. Such binding errors can lead to detachment of the bearing material 15 from the bearing shell 1, which can lead to the functionality of the bearing shell 1 being disregarded or even to a complete failure. Due to the improved connection of the bearing material 15 by means of the laser beam, the error-free service life of the bearing shell 1 is significantly increased. In addition, the bearing shell 1 - or another bearing component 1 - can be easily and quickly repaired by applying bearing material 15 by means of the laser beam, which may only be local. For example, local detachments of the bearing material 15 can be easily repaired by welding using the laser beam m. FIG. 2 shows a top view of the arrangement in FIG. The laser beam 23 is guided along the feed direction 14. Bearing material 15 is melted from the wire 13 in the heating spot 31 of the laser beam 23.

FIG. 3 shows a further possibility of applying bearing material 15 to the running surface 2 of a bearing shell 1 by means of a laser beam 23. The laser beam 23 strikes the running surface 2 of the bearing shell 1 in a heating spot 31. The bearing material 15 is introduced into the heating spot 31 in powder form by means of a nozzle 33. The bearing material 15 melts in the heating spot 31. The bearing material 15 is therefore applied line by line to the bearing shell 1 with a leading melting lug 35.

FIG. 4 shows a longitudinal section through a bearing shell 1, onto which bearing material 15 is applied in a row-like manner. A laser beam 23 is guided over the bearing material 15 in a feed direction 24 directed transversely to the lines formed by bumps 26. As a result, the bearing material 15 is melted again and the bosses 26 of the row structure fuse to form a smooth surface 28.

FIG. 5 shows a section of a cross section through a bearing component 1. The bearing component 1 has a running surface 2. A bearing material 15 has been applied to the running surface 2 by means of a laser beam. The bearing material 15 is preferably a white metal. The bearing component 1 consists of a base material 51, for example a steel. An alloy layer 53 is formed between the bearing component 1 and the bearing material 15 by the application by means of a laser beam. This consists of an alloy of the base material 51 and the bearing material 15. Figure 6 shows a bearing component 1, which is designed as a liner 1. The liner 1 is a hollow cylinder. The inside of the hollow cylinder is the running surface 2. A bearing material 15 is applied to this running surface 2 by means of a laser beam, so that there is a very good connection of the bearing material 15 to the liner 1.

Claims

claims

1. A method for coating the tread (2) of a bearing component (1) with a bearing material (15), so that the bearing material (15) is applied to the bearing component (1) and melted by means of a laser beam (23).

2. The method according to claim 1, that the laser beam (23) heats the running surface (2) locally in a heating spot (31), the bearing material (15) being applied to the heating spot (31).

3. The method of claim 2, d a d u r c h g e k e n n z e i c h n e t that the laser beam (23) line by line over the tread (2) is guided.

4. The method according to any one of claims 1 to 3, characterized in that after the application of the bearing material (15), the laser beam (23) is guided over the tread (2) that smoothing of the tread (2) by remelting the Bearing material (15) results.

5. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that a white metal is applied as the bearing material (15).

6. The method according to any one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that a liner is used as the bearing component (1).

7. The method according to any one of claims 1 to 6, characterized in that a bearing shell is used as the bearing component (1).

8. The method according to claim 7, d a d u r c h g e k e n n z e i c h n e t that the bearing shell (1) of a bearing of a turbomachine shaft is coated with the bearing material (15).

9. Bearing component (1) with a base material and with a bearing material (15) applied to the base material, so that the bearing material (15) is applied like a line by means of a laser beam.

10. Bearing component (1) according to claim 9 for a bearing of a turbomachine shaft.

11. Bearing component (1) according to claim 9 or 10 with a bearing material made of white metal (15).

12. Bearing component (1) according to one of claims 9 to 11, which is designed as a bearing shell for a bearing of a turbomachine shaft.