WO2010100073A1 - Abrasive point - Google Patents

Abstract

The invention relates to an abrasive point for machining work pieces made of metal, in particular of cast metal, having a base body with a grinding region effective on the outer surface for grinding the work piece and a shaft for clamping the tool in the collet chuck of a machine, wherein the base body is produced from metal and wherein the outer surface of the base body has abrasive particles that are held on said surface in a firmly bonded manner.

Description

 grinding

The invention relates to a grinding pin for the machining of workpieces made of metal, in particular cast metal, comprising a base body with an effective grinding on the outer surface grinding area for grinding the workpiece and having a shaft for clamping the tool in the collet of a machine. The invention also relates to a method of manufacturing the tool and specific uses of the tool.

Abrasive pins for abrasive machining, ie for more or less rough grinding of different materials, are known per se. Depending on the field of application, ceramic and synthetic resin-bonded grinding sticks are offered in different grain types, particle sizes and degrees of hardness. Grinding pins of different geometric shapes and with different shaft geometries are also used in mold making or in foundries, wherein the overall geometry of the grinding pin is adapted to the conditions on the workpiece to be machined. Usually, these tools are clamped by means of their shank in the collet of freehand machines or in stationary machines.

Disadvantage of the known ceramic-bonded or resin-bonded grinding pins is their low life. So the workspace in the application wears out snow. Because of the high wear, it is also necessary to adapt the geometry of the work area to the workpiece to be machined so that the removal is taken into account. Only in this way it can be ensured that the grinding pin can be used as long as possible despite wear. Overall, the wear thus not only leads to high Costs due to the heavy consumption of grinding pins, but also that a variety of geometries of grinding pins, namely ideally optimized to the respective application, must be kept.

The object of the present invention is now to propose grinding pins that offer great flexibility in terms of the shape of the workpiece to be machined with increased life. In addition, it is an object of the invention to provide a method for manufacturing the grinding pins and special applications.

These objects are achieved by the grinding pins having the features of claim 1, the method according to claim 7 and the uses according to claims 10 and 11. Advantageous embodiments are mentioned in the respective subclaims.

The basic idea of the invention is to provide a base body made of metal for the grinding pins and to cover its surface with abrasive grains, this surface covering being held on the surface by integral joining, in particular by soldering, gluing, coating and / or electroplating.

The method of the so-called "brazed single layer" (BSL) has proven to be a particularly advantageous method for integral joining, whereby the abrasive grains are held on the outer shell of the basic body by soldering, in particular by melt soldering BSL methods are particularly well-proven when abrasive filaments are used in industrial diamonds, but cubic boron nitride (CBN) abrasive grains can also be used.

It is quite a special feature of the invention that the abrasive grain is not completely integrated into the metal matrix as with sintered or laser-welded abrasives. The diamond abrasive grains are instead clearly recognizable and correspondingly effective. The Grinding pins according to the invention are therefore of particularly open-loop structure.

So far, the BSL process has only been known for the production of cutting discs whose edges are covered on both sides with diamond grinding bodies. Because of their excellent separating properties, these cutting discs are mainly used for processing stone materials. In addition, they are used as a "rescue disc" to rescue people from cars or houses in an emergency.

The grinding pins according to the invention, which are especially processed by means of BSL, are distinguished by their special properties: A particularly outstanding feature is an increased service life of the grinding pins, which can be achieved due to the low wear and high cutting power. Compared to the known grinding pins life is many times higher. Another major advantage of the low wear is that the grinding pins can be used flexibly. Finally, it is not so much to be feared that the surfaces are worn unevenly by a non-flat edition. The grinding pins according to the invention are characterized by a high edge stability. The individual pin shapes, such as approximated cylinders, cones, ellipsoids or combinations of these shapes, can thus be used more universally. Overall, these advantageous properties contribute to a high cost saving for the user. Depending on the grain size, the grinding pins can be used for roughing, finishing and fine grinding.

In addition to the significantly longer service life is another advantage of the invention grinding pins over known grinding pins in their lower temperature load, which contributes to the protection of the workpiece to be machined. In a particularly advantageous embodiment in terms of stability and heat dissipation, the base body and the shaft are integrally formed from metal. Because of their advantageous properties, the grinding pins according to the invention can be used for external grinding and internal grinding and for profile grinding, form grinding, surface grinding and cylindrical grinding. Depending on the type of bonding compound, in particular the slip used in the BSL, which is responsible for the bonding, the sanding pins can be produced in different degrees of hardness and used for various materials. The straightness of hardness to be produced particularly advantageously lies in the range of the soft degree of hardness "K" and the hard degree of hardness "R" according to EN 12413. The degree of hardness "K" is particularly well suited for universal use on surfaces of cast materials Gray and spheroidal graphite cast iron, as well as the grinding out of voids on gray and nodular cast iron parts.Rubrication pencils of hardness R are particularly suitable for robust use on edges of cast materials.They are characterized by high edge stability, long tool life and low tool wear adjust the peripheral speeds of the particular application and the respective hardness.

In this respect, a particular idea of the invention is to use the grinding pins for grinding workpieces made of cast metal, in particular cast steel, gray cast iron or ductile iron. The grinding pins can be clamped in a freehand machine or a stationary machine. Also in the case of these materials, the grinding pins are suitable for finishing grinding or fine grinding workpieces made of cast metal, in particular cast steel, gray cast iron or nodular cast iron. This particular suitability of the present invention with BSL grinding pads for these materials has surprisingly resulted from experiments.

The method according to the invention uses the following steps:

First, the rotationally symmetrical metallic base body is at least in the grinding area with an adhesive that serves as a primer or adhesive provided. Subsequently, on the provided with adhesive outer shell in the grinding dry abrasive grains, in particular diamond grinding or CBN grains applied, which are fixed on the surface by the adhesive.

The application can be carried out by sprinkling the abrasive grains on the outer shell. If the geometry of the grinding area allows it, it is particularly easy to apply the abrasive grains by immersing the body in a bed of abrasive grains. In order to achieve special grinding properties and / or a particularly appealing design, the abrasive grains can be applied in a predetermined orientation, for example by means of a template, on the base body.

In a further step, the grinding area provided with fixed abrasive grains is covered with a slurry containing the solder required for the BSL, a "slurry". "Slurry" denotes a substance in which the metallurgical bond matrix is mixed with in a suitable liquid mixed. Subsequently, especially after a first drying at room conditions, the base body prepared in this way is heated in an oven in order to initiate the "soldering." Advantageously, the base body is sintered in the furnace without pressure, Now the diamond abrasive grains are solid due to the metallurgical bond connected to the metallic body at the contact surface.

In the case of galvanization, at least the grinding area provided with fixed abrasive grains is subjected to a galvanic process by immersing it with the grinding pin as a cathode in a galvanic bath. Under applied stress, metallic precipitate originating from the anode is deposited, including the abrasive grains on the metallic grinding area.

In the figure, some advantageous geometries of the grinding pins according to the invention are shown: These geometries can be produced in different dimensions. These range from diameters and heights of a few millimeters to dimensions in the range of a few centimeters. When Geometries are presented in the forms shown in EN 12413. To call are a) the cylindrical pin, b) the roll round pin, c) the roller cone pin, d) the taper pin, e) the pointed bow pin, f) the ball pin and g) the top pin. In these cases, the complete surfaces of the base body 1 can be provided with abrasive grains (dotted area), while the shaft 2 remains naturally free. Base body 1 and shaft 2 are integrally formed.

Claims

claims 1. grinding pin for the machining of workpieces made of metal, in particular of cast metal, comprising a base body with an effective grinding on the outer surface grinding area for grinding the workpiece and having a shaft for clamping the tool in the collet of a machine, d ad u rc hsekenn ze ichnet in that the base body is made of metal, wherein the outer shell of the base body is provided with abrasive grains which are held on the outer shell in a material-locking manner. 2. Abrasive pin according to claim 1, characterized in that the abrasive grains are held by soldering, in particular by melt soldering, on the outer jacket. 3. Abrasive pin according to claim 1, characterized in that the abrasive grains are held by a galvanic bond on the outer sheath. 4. Abrasive pin according to one of the preceding claims, characterized in that the abrasive grains consist of diamond or CBN kömungen. 5. Abrasive pin according to one of the preceding claims, characterized in that the abrasive grains are applied in one layer by means of the BSL method (brazed single layer) on the outer jacket. 6. Abrasive pin according to one of the preceding claims, characterized in that the basic body has a spherical or conical or cylindrical shape or a combination of these forms. 7. Abrasive pin according to one of the preceding claims, characterized in that the basic body and the shaft are integrally formed. 8. A method for producing a grinding pin according to one of the preceding claims, deh rc hgekenn ze ichnet that the main body of metal in the grinding area is provided with an adhesive that applied to the outer jacket provided with adhesive abrasive grains, in particular diamond or CBN Schleifkömer and fixed and that provided with fixed abrasive grains grinding area a Process is established, which creates a bond between the abrasive grains and the outer shell. 9. The method of claim 8, wherein the grinding area provided with fixed abrasive grains is covered with a slurry containing the solder and that the body is heated in an oven. 10. The method according to claim 9, characterized in that the base body is sintered in the furnace. 11. The method of claim 8, wherein a grinding area provided with fixed abrasive grains is subjected to a galvanic process. 12. The method according to any one of claims 8 to 11, d a d u r c h e ce n c h e e s in that the abrasive grains are applied to the outer shell by a scattering process. 13. The process according to claim 8, wherein the abrasive grains are applied by immersing the main body in a bed. 14. Method according to one of claims 8 to 11, characterized in that the abrasive grains are applied to the base body in a predetermined orientation. 15. Use of a grinding pin according to one of the preceding claims for grinding workpieces made of cast metal, in particular cast steel, gray cast iron or ductile iron, wherein the tool is clamped in a freehand machine or a stationary machine. 16. Use of a grinding pin according to one of the preceding claims for rough grinding, finishing grinding or fine grinding of workpieces made of cast metal, in particular cast steel, gray cast iron or ductile iron.