Patent Application
20180250681
The invention relates to a tool for processing abrasive materials, in particular rocks, sand, oil sand or ores.
Tools for processing abrasive materials are used in known apparatuses for processing rocks, sand, oil sand or ores, such as for example crushers, such as roll crushers or sizers, or excavators. The tools, such as for example crusher teeth or excavator teeth, are exposed to high levels of wear and have therefore to be replaced regularly. Wear to the tools differs widely in particular in the case of tools mounted at different positions on the processing apparatus. For example, crushing tools arranged within the flow of material through the comminution apparatus wear significantly faster than crushing tools at the edge of the material flow. As a result of this irregular wear, it is known for example just to replace or repair individual crushing tools.
When repairing crushing tools, the original geometry of the crushing tool from before the onset of wear is re-established. It is known for example from EP 2891522 A1 to apply a build-up weld to the worn area, in order on the one hand to re-establish the geometry of the crushing tool and on the other hand to apply an additional antiwear layer to the crushing tool. However, due to the low carbide concentration of at most around 61% in the filler material used for the build-up welds, such build-up welds have low hardness.
On this basis, it is the object of the present invention to provide a tool with high wear resistance and a method for producing or treating such a tool.
This object is achieved by a tool having the features of the independent device of claim 1 and having the features of the independent method of claim 12. Advantageous further developments are revealed by the dependent claims.
According to a first aspect, a tool for processing abrasive materials, in particular rocks, sand or ores, comprises a main tool body and at least one hard metal plate arranged on the main tool body, wherein a build-up weld is applied to the surface of the hard metal plate and to the main tool body, by which weld the hard metal plate is bonded to the main tool body.
Abrasive materials should be understood to mean in particular minerals, such as for example rock, ores, coal, sand and oil sand.
The tool in particular comprises a crushing tool for comminuting rocks, oil sand, ores or other wear-inducing materials, such as for example a crusher tooth or a beating arm of a roll crusher, a crushing hammer of a hammer crusher or impact plates or prismatic elements of a crushing jaw of modular construction. The tool further comprises an excavator tooth, for example. The tool preferably comprises a locally delimitable wear region, which is arranged on the side faces of the crushing tool pointing substantially in the force direction, in particular in the crushing direction, and is worn during operation of the tool. The worn region of the crushing tool is for example an indentation on the surface of the tool.
The main tool body comprises at least the region of the tool which is exposed to wear during the processing of abrasive materials. The main tool body is for example made from a steel.
A hard metal plate should be understood substantially to mean a plate of a hard metal, such as for example sintered metal carbides, consisting in particular of 90-94% tungsten carbide and 6-10% cobalt. A hard metal plate arranged on the main tool body offers a high level of wear protection for the surface of the main tool body. In particular, the wear protection merely encompasses the region of the main tool body at which the greatest wear occurs during tool operation.
Build-up welding should be understood to mean a thermal coating method for surface treatment. A build-up weld provides a wear- and corrosion-resistant layer on a base material. By means of a heat source, for example a laser beam, the surface of the region to be provided with the build-up weld is heated and a filler material, in powder form or as a wire, is supplied and likewise heated by the heat source and applied to the surface of the main tool body. The filler material melts virtually completely. The filler material for example comprises a hard metal, such as for example materials with a high nickel content, tungsten carbide or titanium carbide. Build-up welding for example comprises laser build-up welding or plasma transferred arc welding (PTA). The build-up weld is applied to the surface of the hard metal plate and to the surface of the main tool body. This enables reliable attachment of the hard metal plate to the main tool body, wherein this attachment withstands a heavy mechanical load, in particular a crushing force, acting on the tool. Unlike other means of attachment, such as for example brazing or welding of the hard metal plate to the surface of the main tool body, a build-up weld offers the advantage of high strength and the fact that it causes only a slight temperature increase in the hard metal and the material of the main tool body. The main tool body of the tool is formed for example from a quenched and tempered steel, wherein welding or brazing, in particular at high temperatures of above around 600° C., destroys the grain structure of the material of the tool, so reducing the hardness and strength of the material of the tool. A build-up weld offers the advantage of being bonded to the hard metal and the material of the main tool body by way of a metallurgical bond, such that the build-up weld is firmly bonded to the surface of the main tool body and to the hard metal plate and withstands heavy mechanical loads. The build-up weld is in particular applied to the hard metal plate and the main tool body with only slight mixing of the hard metal of the former and the material of the latter. Laser build-up welding or plasma transferred arc welding (PTA) in particular allow only slight mixing of the material of the main tool body and the hard metal.
Mixing is understood in particular to mean the ratio between the total mass of a component and the mass which is melted and bonded by the build-up welding process. Conventionally, during melting and subsequent solidification the grain structure of the material is changed, for example destroyed. With only slight mixing a major part of the grain structure is retained, such that the hardness and the strength of the material are not influenced at all or only very slightly. The low amount of mixing of the material of the crushing tool and of the hard metal plate during build-up welding therefore reduces the amount by which the mechanical properties of the hard metal plate and of the main tool body deteriorate. In particular, the hard metal plate is at least partly enveloped by the build-up weld.
According to a first embodiment, a plurality of hard metal plates are mounted on the main tool body which are each bonded to the main tool body by way of a build-up weld. The hard metal plates have different geometries, for example.
According to one further embodiment, the hard metal plates are arranged parallel to one another. A mutually parallel arrangement of the hard metal plates allows optimum absorption of forces acting on the tool, such as for example forces which arise during processing of rocks, ores or sand, such as crushing forces of a crushing apparatus.
According to one further embodiment, each hard metal plate is bonded to a respective adjacent hard metal plate by way of a build-up weld. The hard metal plates are in particular arranged with uniform mutual spacing on the main tool body, wherein the distance between two adjacent hard metal plates is preferably such that the build-up weld may be applied between the hard metal plates by means of laser build-up welding. In particular, the spacing of two hard metal plates has a value of 5-15 mm.
According to one further embodiment, the at least one hard metal plate is arranged in such a way on the main tool body that it extends in the direction in which a force acting on the tool acts. In particular, the parallel hard metal plates extend parallel to the crushing force of a crusher. During operation of the tool for processing abrasive materials, the build-up weld applied to the hard metal plates wears faster than the hard metal plates, since the build-up weld has lower wear resistance than the hard metal plate. During operation of the tool, therefore, a recess forms between the hard metal plates as wear of the build-up weld progresses, such that the hard metal plates act as cutting edges and simplify the processing, for example comminution, of the material to be processed. In addition, during operation of the tool, material becomes deposited between adjacent hard metal plates on which the build-up weld has worn, whereby further wear of the build-up weld is reduced.
According to one further embodiment, at least one hard metal plate is arranged in a groove formed in the surface of the tool body. This simplifies positioning of the at least one hard metal plate in the indentation and in particular application of the build-up weld to the hard metal plate.
According to one further embodiment, the main tool body comprises a plurality of grooves, wherein each hard metal plate is arranged in a respective groove.
According to one further embodiment, the main tool body comprises an indentation, in particular a worn region, wherein the at least one hard metal plate is arranged in the indentation. The indentation is for example a region in the surface of the main tool body which has been worn during tool operation.
According to one further embodiment, the at least one hard metal plate is formed and arranged in the indentation in such a way that it fills the cross section of the indentation. In particular, the at least one hard metal plate is arranged in such a way that it re-establishes the original geometry of the tool. The original geometry of the tool is understood to mean the geometry prior to the occurrence of wear to the surface of the main tool body during the processing of abrasive materials. In particular, the geometry of the hard metal plate corresponds to the cross section of the indentation, such that the hard metal plate arranged in the indentation substantially re-establishes the original cross-sectional geometry of the tool. The hard metal plates have different geometries, for example, and are arranged in the indentation, with the build-up welds applied to said hard metal plates, in such a way that they fill the indentation. Preferably, a plurality of grooves each for accommodating one hard metal plate are applied in the indentation.
The build-up weld preferably comprises a filler material of in particular tungsten carbide or titanium carbide. In particular, the filler material has a carbide concentration of around 50-61%, so achieving a high level of build-up weld wear resistance.
According to one further embodiment, the thickness of the build-up welds is greater than the thickness of the at least one hard metal plate. This enables economies of material to be made in terms of the relatively cost-intensive hard metal plates.
The invention further comprises a processing apparatus for processing abrasive materials, comprising at least one tool as described above. A processing apparatus for example comprises a crushing apparatus such as a roll crusher or a hammer crusher, wherein a plurality of tools are preferably arranged around the circumference of a crushing roll of the roll crusher.
The invention further comprises a method for producing or treating a tool for processing abrasive materials, in particular rocks, sand or ores, wherein the tool comprises a main tool body, wherein the method comprises the steps of:
arranging at least one hard metal plate on the main tool body and applying a build-up weld to the hard metal plate and the main tool body, such that the at least one hard metal plate is attached to the main tool body.
The embodiments and advantages described with reference to the tool also apply mutatis mutandis with regard to the method for producing or treating a tool. A tool as previously described is produced by the method for producing or treating a tool. In particular, the build-up weld is applied by means of laser welding or plasma transferred arc welding (PTA).
According to one embodiment, a plurality of hard metal plates are arranged parallel to one another on the main tool body. According to one further embodiment, each hard metal plate is bonded at least to an adjacent hard metal plate and the main tool body by a build-up weld.
Prior to arranging the at least one hard metal plate on the main tool body, the main tool body is machined according to one further embodiment. This results in a uniform, simple main tool body geometry, whereby the configuration of the hard metal plates for arrangement on the main tool body is simplified. For example, the main tool body is milled out.
According to one further embodiment, the hard metal plates are arranged in such a way on the main tool body that they extend substantially in the direction in which a force acting on the tool acts. In particular, the plane of the at least one hard metal plate extends in the direction in which the force acts, in particular a crushing force of a crushing apparatus.
According to one further embodiment, prior to the step of arranging the at least one hard metal plate on the main tool body, at least one groove is introduced into the surface of the main tool body, wherein the at least one hard metal plate is arranged in a groove.
This simplifies positioning of the hard metal plate on the main tool body, wherein the step of applying the build-up weld to the at least one hard metal plate is also significantly simplified.
According to one further embodiment, prior to the step of arranging the at least one hard metal plate on the main tool body a plurality of parallel grooves are introduced into the surface of the main tool body, wherein in each case one hard metal plate is arranged in each groove.
According to one further embodiment, the main tool body comprises an indentation, in particular a worn region, wherein the at least one hard metal plate is arranged in the indentation. In particular, the grooves are formed in the indentation of the main tool body.
The invention is explained in greater detail below with the aid of a number of exemplary embodiments and with reference to the appended figures.
The tool 10 comprises a main tool body 18 with an indentation 14, which for example comprises a region on the surface of the tool main tool body 18 which has suffered wear during operation of the processing apparatus. The indentation 14 extends for example from the side face pointing in the processing direction to the upper face of the tool 10.
A hard metal plate 12 is arranged in the indentation 14. The hard metal plate 12 substantially exhibits the shape of the cross section of the indentation 14 and is arranged in such a way in the indentation 14 that it fills the cross section of the indentation. In the case of a worn tool 10, the hard metal plate 12 arranged in the indentation 14 re-establishes the original cross section of the tool from the prior formation of the wear-related indentation 14 in the surface. The hard metal plate 12 is bonded to the main body 18 of the tool 10 by way of a build-up weld 16.
The hard metal in particular comprises sintered metal carbides, with preferably 90-94% tungsten carbide embedded in 6-10% cobalt, in particular a cobalt matrix. The build-up welds for example comprise a filler material of hard metal, in particular tungsten carbides or titanium carbides. The build-up welds are preferably bonded to the hard metal of the hard metal plates by way of a metallurgical bond. For example, the build-up weld is applied to the hard metal plates and the main tool body 18 of the tool 10 by laser welding. In particular, the build-up weld is applied in such a way to the hard metal plate that only slight mixing is caused between the hard metal and the build-up weld.
The spacing of the hard metal plates 12 is configured in such a way that it is possible to apply a build-up weld 16 between two adjacent hard metal plates 12, for example by means of laser welding.
The grooves 20 extend substantially parallel to one another and exhibit a width which corresponds to the width of the hard metal plates. The grooves 20 form a holder for the hard metal plates 12 and extend in particular over the entire length of the indentation. One hard metal plate 12 is in each case arranged in each groove 20. In the exemplary embodiment shown in
The grooves 20 allow precise positioning of the hard metal plates 12 in the indentation 14 of the tool 10, wherein application of the build-up weld 16 to the hard metal plates 12 and the surface of the indentation 14 is further simplified.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2015 222 020.6 | Nov 2015 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2016/075418 | 10/21/2016 | WO | 00 |
