EP3132893A1 - Method and apparatus for machining and roughening a surface - Google Patents

Abstract

The invention relates to a method and a system for processing and roughening a surface of a workpiece for a subsequent surface coating, wherein at least a portion of the surface is acted upon by at least one machining fluid at a processing pressure, wherein at least a portion of the surface is machined and provided with a microscopic roughening becomes. According to the invention, it is provided that after machining the surface is at least partially applied and cleaned with a cleaning fluid at a cleaning pressure, which is lower than the processing pressure.

Description

The invention relates to a method for processing and roughening a surface of a workpiece for a subsequent surface coating, wherein at least a portion of the surface is subjected to at least one machining fluid at a processing pressure, wherein at least a portion of the surface is machined and provided with a microscopic roughening, according to the preamble of claim 1.

The invention further relates to a system for processing and roughening a surface of a workpiece for a subsequent surface coating, wherein at least one first nozzle device is provided, with which a machining fluid for processing and roughening the surface in at least one area at a processing pressure can be applied, according to The preamble of claim 9.

On certain workpieces, it is desirable to provide surfaces with a metallic coating to protect them from mechanical or corrosive wear, for example. Especially in cylinder crankcases, also called engine block, reinforced the cylinder surfaces in the cylinder bores are provided with a metal coating. The metal coating can be applied by a thermal spraying process with a relatively thin layer thickness of a few 100 microns to a few millimeters.

In order to achieve a good bond between the surface and the applied metal coating, it is known to process the surface in advance. For this purpose, the surface can be roughened microscopically with a fluid jet. In this case, a fluid jet with a processing pressure of up to several 1000 bar directed to the surface to be coated. On such a microscopically roughened surface, a metallic coating adheres very well.

From the DE 10 2013 211 324 A1 It is known to first create a macroscopic groove structure on a surface to be coated and then superimpose this groove structure by a microscopic roughening by means of beam processing.

This method is basically very expensive, since a double processing of the surface takes place. In addition, a microscopic roughening is possible only with relatively stable groove structures, since the fluid jet at an operating pressure of up to several 100 bar damaged or destroyed finer grooves.

The invention has for its object to provide a method and a system for processing and roughening a surface of a workpiece, with which the surface can be particularly efficiently prepared for the subsequent coating.

The object is achieved, on the one hand, by a method having the features of claim 1 and, on the other hand, by a system having the features of claim 9. Preferred embodiments of the invention are specified in the respective dependent claims.

The inventive method is characterized in that after processing, the surface is at least partially applied and cleaned with a cleaning fluid at a cleaning pressure, which is less than the processing pressure.

In the preparation of a surface for a subsequent coating, the application of a machining fluid at an operating pressure of up to several 1000 bar represents the fundamentally last material-removing machining step. A high-pressure admission with the machining fluid basically ensures that the surface of contamination, in particular grease or oil deposits, is reliably cleaned due to previous machining operations. However, for this purpose, it must be ensured that a high-pressure processing of the entire surface to be coated takes place.

According to the invention, a cleaning device is provided, with which the surface to be coated is sprayed and cleaned at least in regions with a cleaning fluid at a cleaning pressure which is lower than the processing pressure during the application of the machining fluid. This eliminates the need to pressurize the entire surface to be coated with the machining fluid at a very high processing pressure of up to several 1000 bar. The targeted use of a cleaning fluid at a significantly reduced cleaning pressure, a cost savings due to a low demand for pressure energy and machining fluid is achieved. In addition, surface areas can be provided on the surface to be coated, which are provided with sensitive structures that could be damaged during a high-pressure application.

A preferred embodiment of the invention is that, in addition to being exposed to the microscopic roughening treatment fluid, macroscopic machining is carried out to form the profile surface for the purpose of forming defined profile elements. The macroscopic processing preferably takes place before the microscopic roughening, but can also be carried out simultaneously or subsequently. Preferably, the surface area is applied with the profile elements only with the cleaning fluid at the low cleaning pressure, but not with the processing fluid at a high pressure. After microscopic roughening, the entire surface can also be cleaned with the cleaning fluid. As a result, an arrangement of fine profile elements is made possible.

A particularly efficient process variant results according to the invention in that a wash liquid based on water is provided as the cleaning fluid. The washing liquid may in particular have fat-dissolving surfactants or other additives which are advantageous for the cleaning. A cleaning fluid based on water is environmentally friendly and inexpensive.

In principle, it is possible to use the same treatment fluid as the cleaning fluid, which is intended for microscopic roughening.

According to a preferred embodiment, the cleaning fluid is different from the machining fluid. In particular, the cleaning fluid is free from abrasive or abrasive particles, which are preferably present in the machining fluid. Corrosion protection additives can be provided in both fluids.

According to one embodiment of the method according to the invention, it is advantageously provided that the processing pressure between 500 bar and 4000 bar, in particular between 800 bar and 2500 bar is set. The amount of processing pressure depends largely on the hardness of the workpiece material to be machined. At the indicated pressures finest particles can be released from the workpiece material, so that a desired microscopic roughening is formed.

Another preferred variant of the method is that the cleaning pressure between 5 bar and 500 bar is set. The cleaning pressure is - depending on the material of the workpiece - significantly lower than the processing pressure of the machining fluid, so that damage to the fine profile elements is virtually avoided during cleaning.

Furthermore, it is advantageous according to an embodiment variant of the invention that a roughening is formed by means of the machining fluid in at least a second surface area of the surface to be coated and that the profile elements are created in at least a first surface area which is separate from the second surface area. In this way, a partial processing and roughening of the second surface area with the machining fluid can take place, while fine profile elements are created in the first surface area, which are not directly impacted by the machining fluid and thus damaged. A reliable and gentle cleaning of the fine profile elements is achieved by the cleaning fluid.

It is provided according to a development of the invention that in the at least first surface area only a macroscopic machining for forming the profile elements is performed. In this way, very fine profile elements can be formed, which have a height between 10 microns and 500 microns. The distance between the profile elements directly to each other can be a corresponding Include magnitude. The profile elements can be formed in particular by grooves, wherein webs remain as the actual profile elements between the grooves. In cross section, these may have a polygonal, semicircular or arcuate contour. It can also be made profile elements with undercut contour, such as a dovetail profile. The grooves are preferably produced by machining, for example by means of a turning tool or a milling tool. It is also possible to work by laser or a spark erosion process. The profile elements are preferably formed and arranged in a regular structure.

In contrast, in the microscopic beam processing, the surface is acted upon by a processing jet with a high pressure. In this case, individual particles are released from the surface to be coated, so that an irregular microscopic roughening takes place. This irregular roughening can be on average in the range between a few microns to 100 microns.

In this case, according to one embodiment of the invention, it is preferable for the second surface area to be provided in an edge section of the surface of the workpiece to be coated, in which only a roughening is formed by means of beam machining.

According to a finding of the invention, macroscopic profile elements in an edge section of the surface to be coated, in particular in cylinder bores, are particularly susceptible to damage due to a partial exposure. By providing the second surface area with an exclusive microscopic roughening in an edge portion, this susceptibility to damage is significantly reduced. The edge portion preferably has a width of 3 mm to 1 cm. In a cylinder bore preferably both opposite annular edge regions are free of profile elements and roughened only microscopically. In contrast, the profile elements are preferably located in a central region of the surface to be coated. The macroscopic profile elements represent a macroscopic roughening, which can be created relatively inexpensively compared to the high-pressure processing.

The inventive plant for processing and roughening a surface of a workpiece is characterized according to the invention in that at least one cleaning device is provided, which is designed for applying a cleaning fluid for cleaning the surface in at least one area at a cleaning pressure which is lower than the processing pressure ,

With the system according to the invention, in particular, the method described above can be carried out and the associated advantages can be achieved.

The cleaning device can in particular direct a jet of cleaning fluid onto the surface to be coated, by means of which the surface to be treated is cleaned, in particular freed of remaining chip particles or grease and oil residues.

To form the at least one cleaning jet, the cleaning device may comprise one or more nozzle elements. In principle, it is possible that the first nozzle device is used as the cleaning device, which is also provided for applying the machining fluid. In this case, only a sequential processing with machining fluid and cleaning fluid can be done.

A preferred embodiment of the system according to the invention is that the cleaning device has a second nozzle device for spraying the cleaning fluid. The second nozzle device may have one or more nozzle elements, which are preferably movable over the surface to be coated.

Furthermore, it is advantageous according to an embodiment of the invention that a first container for the processing fluid and a second container for the cleaning fluid are arranged. In this arrangement, in particular, various fluids can be used for processing and cleaning. The respective containers are connected via fluid lines to the nozzle devices. Via a pumping device, in particular an axial piston pump, the machining fluid or the cleaning fluid can be acted upon by the respective pressure for forming the fluid jet.

A further preferred embodiment of the invention consists in that at least one tool device is provided for the material-removing machining and forming of defined profile elements in the surface.

Preferably, it is provided according to the invention that the tool device has a turning tool, a milling head, a laser or a spark erosion device. In this way, in particular defined macroscopic profile elements can be incorporated in a predetermined structure in the surface chip removal. In comparison to a microscopic roughening by means of high-pressure processing, a material-removing processing and creation of macroscopic profile elements is less expensive.

In principle, the system can only be provided for processing and roughening a workpiece in preparation for a subsequent coating. According to one embodiment of the invention, it is preferred that a coating device is provided for applying a coating to the machined surface. Thus, both the pre-processing and the coating can be carried out with the system. Between the processing including cleaning and a coating, a drying device for drying the workpiece may be arranged.

The coating is preferably a metal coating, which is preferably produced by a thermal spraying or coating process, such as an LDS coating process or a plasma coating process. The coating is generally formed by a metallic alloy. In principle, the coating may also comprise a ceramic coating or a plastic coating.

The invention will be described in more detail below with reference to a preferred embodiment, which in a partial cross-sectional view in Fig. 1 is shown schematically.

Fig. 1 shows a part of a workpiece 10 with a cylinder bore 12 shown in half section with a bore axis 13. The cylinder bore 12 has a surface to be coated 14, which serves after coating as a cylinder surface in an engine block.

In the present exemplary embodiment, the surface 14 to be coated is substantially cylindrical, with chamfers 18 directed outwards being formed in the two lateral edge sections 16. The chamfers 18 have a helix angle to the bore axis 13, so that conical edge portions 16 are formed. In a central region 17 extending essentially coaxially to the bore axis 13, two first surface regions 20 are provided in the surface 14, in which macroscopic profile elements 22 are machined. The profile elements 22 are formed in the present embodiment as triangular webs by screwing parallel grooves or a helical groove in the surface 14. In each surface area 20 a plurality of adjacent profile elements 22 is provided.

An intermediate region 19 between the two first surface regions 20 is formed as a second surface region 30, in which only a microscopic roughening 32 is formed by means of a jet processing by a first nozzle device 41.

Also in the two outer edge portions 16 with the chamfers 18 second surface regions 30 are arranged, in which only a microscopic roughening 32 by means of the movable first nozzle device 41 without macroscopic profile elements 22 is formed.

The complicated surface to be produced second surface areas 30 with the microscopic roughening are arranged in the illustrated workpiece 10 in the areas in which the coating to be applied is particularly stressed. In the less stressed first surface regions 20, the macroscopic profile elements 22 are arranged, which ensure a sufficient connection with the applied coating in these less stressed sections. The subsequent coating is in particular a plasma coating with a metal alloy. The coating has a layer thickness which projects beyond the roughening 32 and the profile elements 22.

After microscopic roughening and before the surface coating, the surface to be coated is cleaned with a cleaning fluid from a second nozzle device 42. The second nozzle device 42 is movable so that targeted certain surface areas, such as only first surface areas 20 with profile elements 22 or all surface areas 20, 30 of the surface 14 to be coated with cleaning fluid can be applied.

Claims (14)

A method of processing and roughening a surface (14) of a workpiece (10) for a subsequent surface coating, wherein at least a portion of the surface (14) is exposed to at least one processing fluid at a processing pressure, wherein at least a portion of the surface (14) processes and provided with a microscopic roughening,
characterized,
that after processing the surface is at least partially applied and cleaned with a cleaning fluid at a cleaning pressure, which is less than the processing pressure. Method according to claim 1,
characterized,
in that, in addition to being exposed to the microscopic roughening treatment fluid, a macroscopic treatment is carried out to machine the surface (14) to form defined profile elements (22). Method according to claim 2 or 3,
characterized,
in that a washing liquid based on water is provided as cleaning fluid. Method according to one of claims 1 to 3,
characterized,
that the cleaning fluid is different from the machining fluid. Method according to one of claims 1 to 4,
characterized,
that the processing pressure between 500 bar and 4000 bar, in particular between 800 bar and 2500 bar is set. Method according to one of claims 1 to 5,
characterized,
that the cleaning pressure between 5 bar and 500 bar is set. Method according to one of claims 1 to 6,
characterized,
that a roughening by means of the machining fluid in at least a second surface region (30) of the surface to be coated (14) is formed, and
in that the profile elements (22) are produced in at least one first surface area (20) which is separate from the second surface area (30). Method according to one of claims 1 to 7,
characterized,
in that in the at least first surface area (20) only macroscopic processing is carried out for forming the profile elements (22). Apparatus for processing and roughening a surface (14) of a workpiece (10) for a subsequent surface coating, wherein at least one first nozzle device (41) is provided, with which a machining fluid for processing and roughening the surface (14) in at least one area a processing pressure can be applied, in particular for carrying out a method according to one of claims 1 to 8,
characterized,
in that at least one cleaning device is provided, which is designed to apply a cleaning fluid for cleaning the surface (14) in at least one region at a cleaning pressure which is lower than the processing pressure. Plant according to claim 9,
characterized,
in that a first container for the machining fluid and a second container for the cleaning fluid are arranged. Plant according to claim 9 or 10,
characterized,
in that at least one tool device is provided for the material-removing machining and forming of defined profile elements in the surface. Plant according to claim 11,
characterized,
in that the tool device has a turning tool, a milling head, a laser or a spark erosion device. Plant according to one of claims 9 to 12,
characterized,
in that a coating device is provided for applying a coating to the machined surface (14). Installation according to one of claims 9 to 13,
characterized,
in that the cleaning device has a second nozzle device (42) for spraying the cleaning fluid.

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