EP0336066B1 - Grinding wheel for plunge-cut grinding - Google Patents

Abstract

The grinding wheel (2), which is intended in particular for plunge-cut grinding, has a first abrasive-layer part (5) which contains fine-grained diamonds as well as a further abrasive-layer part (9) which contains larger diamond grains. This grinding wheel can be a straight wheel as well as a cup wheel. Known embodiments of such grinding wheels either cannot obtain the required surface roughness or exhibit high wear, since they do not have a continuous high proportion of diamonds in the outer marginal area of the end face as protection against rounding-off of the outer edge. In order to remedy this, provision is made for the abrasive-layer part (9) to be provided with diamond grains of larger grading which are arranged in a single layer parallel to the axis of rotation of the straight wheel, the diamonds being arranged at right angles to the axis of rotation in several layers and being held in mutual contact in an electro-deposited bond (10). <IMAGE>

Description

The invention relates to a grinding wheel, in particular for deep grinding, with a two-part abrasive coating which contains fine-grained diamonds in one part and a second abrasive coating part which is formed on one side and contains coarser-grained diamonds.

When deep-grinding a workpiece with a peripheral grinding wheel or a cup grinding wheel with diamond or cubic-crystalline boron nitride, a so-called roof profile forms on the effective grinding wheel surface over the course of the grinding wheel life. The shape of the roof profile depends on the width of the grinding surface and the height of the infeed of the grinding wheel. The main cutting work has to be done by the part of the grinding wheel grinding surface that initially intervenes in the feed direction, while the subsequent part largely determines the surface quality. Since the different surface sections of the grinding wheel therefore have different tasks it is known to design the parts of the grinding surface differently taking into account the different loads, specifically with regard to the diamond grain sizes used in these sections and the concentration of diamonds.

A known circumferential grinding wheel carries fine-grained diamonds on its circumferential surface and a cup grinding wheel on its end surface, which are held in a bond which consists, for example, of a phenolic resin and copper. In that area of the grinding wheel which is subjected to greater loads, diamond grains of larger classification are arranged, while in the area which determines the surface quality, diamonds of smaller classification are embedded. The areas have the same type of bond and the diamond grains are distributed stochastically according to their respective volumetric proportion in the bond.

Usually, the different abrasive coating zones are selected so that the grinding wheel with the covering part with a fine grain classification achieves the required surface quality, the covering part with a larger diamond classification does not break down under the resulting load at a given machining volume per unit of time and does not generate any impermissible forces and temperatures. Has proven itself. B. with a covering width of 5 mm, the division into a 3 mm wide covering zone for the fine-grained part and a 2nd mm wide covering zone for the coarse-grained part.

In deep grinding according to the so-called quick-point method, in which the axes between the grinding wheel and the workpiece are aligned at an angle to one another, only an almost punctiform contact between the grinding wheel and the workpiece is desired. The effective grinding wheel width should be as small as possible. This is the only way to achieve the goal of the process of working with very high stock removal rates. This results in a large load on a narrow zone in the outer edge area of the grinding surface. To avoid excessive wear of the covering due to the high load, the coarsest possible abrasive grains should be selected in combination with a wear-resistant bond. This is the only way to maintain the required dimensional accuracy on the workpiece, because otherwise the grinding wheel wear would cause shape deviations, in particular cylinder shape deviations on the workpiece.

On the other hand, the choice of such a grinding surface creates an excessive roughness of the workpiece surface, which is usually not permitted during grinding.

The previously known types of grinding wheels for this grinding method either did not achieve the required surface roughness or they showed excessive wear or else had to are dressed too often during their lifetime.

The object of the invention is to provide a grinding wheel with a small engagement width for deep grinding, which continuously has a very high diamond content in the outer edge region of the end face as protection against wear or rounding of this outer edge and at the same time brings about a high surface quality. According to the invention, it is provided that the abrasive coating of a grinding wheel on the front face lying in the feed direction consists of a coating of diamond grains with a grain size of 150 to 400 micrometers, which is single-layer in the circumferential disc in the direction of the axis of rotation of the grinding wheel and multi-layer perpendicular to that Axis of rotation of the grinding wheel is formed, the diamond grains touching each other in z. B. a galvanically deposited nickel bond are held, while in a cup grinding wheel the single-layer design of the diamond coating is aligned parallel to the axis of rotation.

The invention is defined by claims 1 and 2, respectively.

The invention thus provides for the single-layer abrasive coating zone with coarse diamond and a wear-resistant bond to be assigned a zone with a fine-grained abrasive that is around 2-3 mm wide. This part of the abrasive coating has the task of reducing the roughness of the workpiece surface. The grinding wheel designed in this way allows a high stock removal rate, whereby the abrasive coating zone with coarse diamond, which is decisive for the high stock removal rate, only intervenes with a small effective width and therefore implements the process principle, while a downstream part of the abrasive coating zone only reduces the roughness generated on the workpiece surface, without the process principle of low To significantly influence the engagement width to achieve high performance.

The grinding wheel according to the invention has the advantage that, from the start of its use until it is completely used up, the load on an extremely high diamond area of the end face is continuously absorbed by the load, so that no roof formations or bevels or roundings on this edge Need to be bought. It shows that even with the greatest loads, such as deep grinding using the quick-point method, the wear on the outside of the grinding wheel is no greater than that of the exposed to a lower load, but also less resistant peripheral surface, so that the original profile is retained even after prolonged use and wear of the grinding wheel. Due to the fact that the relatively large diamond grains lie directly next to one another in the outer edge area, not only is the tool attaining a long service life, but also because of the short life effective grinding wheel width also ensures a high stock removal rate with optimal grinding properties.

Various options are available for applying and holding the abrasive coating according to the invention with diamonds of small grain size on the peripheral surface on the abrasive body, which are held in a bond. In general, however, it is useful if the diamonds of the end face with their z. B. to be deposited electroplated nickel bond on an intermediate layer, which is connected to the bond of the fine diamond grains of the peripheral surface. If the fine diamond grains are bonded, for example made of bronze, the adhesion of the nickel to be electroplated to this bond is improved if an intermediate layer is arranged, which consists, for example, of sintered iron. In general, however, it is advantageous if the intermediate layer consists of a metal which is part of the binding of the fine abrasive grains of the abrasive coating on the peripheral surface. If this bond consists, for example, of a phenolic resin with a copper powder, the intermediate layer should preferably consist of a powder-metallurgical copper layer. It is sufficient if the intermediate layer has a thickness of only 0.1 to 0.3 mm, as can be achieved in a sintering process in a mold in which this intermediate layer and the binder with the fine-grained layers are used at the same time distributed small diamond is sintered.

• Figur 1: zwei Darstellungen der Lage einer Schleifscheibe zum Werkstück beim Tiefschleifen nach dem Quick-Point-Verfahren;
• Figur 2: die Seitenansicht eines Werkstückes mit Schleifscheibe im Einsatz;
• Figur 3: den Randbereich einer vorbekannten Schleifscheibe;
• Figur 4: eine Topfschleifscheibe nach der Erfindung im Schnitt und
• Figur 5: den Randbereich einer erfindungsgemäßen Umfangsschleifscheibe mit Zwischenschicht.

Two embodiments of the invention are explained below with reference to a drawing. The drawing shows:

• Figure 1: two representations of the position of a grinding wheel to the workpiece during deep grinding according to the quick-point method;
• Figure 2: the side view of a workpiece with grinding wheel in use;
• Figure 3: the edge area of a known grinding wheel;
• Figure 4: a cup grinding wheel according to the invention in section and
• Figure 5: the edge area of a peripheral grinding wheel according to the invention with an intermediate layer.

The arrangement shown in FIG. 1 shows a grinding wheel 2 in its position relative to the workpiece 1 when grinding according to the quick-point method, in which there is an almost punctiform contact between these parts and thus a very high load on the grinding wheel 2.

It can be seen from the side view shown on the left that the axis of the grinding wheel 2 is inclined by an angle β to the axis of the workpiece 1 and in the top view according to the right part of FIG. 1 by an angle α, so that not only an inclined position exists within the drawing level, but also in spatial terms.

The feed of the grinding wheel 2 takes place according to the arrow 3, the arrow 3 'indicating the direction of advance. When working in this way, in particular the outer end face area of the grinding wheel is loaded. This end face region is designated by 6 in FIG. 2, the grinding wheel 2 again being advanced in accordance with the arrow 3. In the case of such deep grinding, the surface quality of the workpiece 1 is generated by the peripheral surface 4, while the end surface 6 causes the material to be removed.

In order to take these different loads into account, in a known grinding wheel 2 according to FIG. 3, the grinding covering consists of two different parts. Part 6 of the abrasive coating has larger diamond grains than that of part 5. In this known arrangement, however, the diamonds are held on the front side in a loose distribution and at a distance from one another in a bond which consists of the same material as the bond of the abrasive coating 5 of the circumferential surface 4. This has the consequence that at a heavier load a "roof profile" 7 or a bevel on the outer edge of the grinding wheel must be accepted, which leads to a reduction in the removal rate and increase the grinding forces of the tool.

These disadvantages are eliminated in the embodiments according to FIGS. 4 and 5, which have a grinding surface 9 on the end face or peripheral side of the grinding wheel, which consists of a single covering made of large diamond grains 9 ', which is formed in one layer in the direction parallel to the axis of rotation of the grinding wheel and in multiple layers in the direction perpendicular to the axis of rotation of the peripheral grinding wheel according to FIG. 5 and vice versa in the cup grinding wheel according to FIG. 4.

When grinding with a peripheral grinding wheel according to FIG. 5, the axis of rotation of the wheel runs parallel to the ground workpiece edge. The large diamonds, arranged in a single layer, then form the end face of the grinding wheel. The circumferential surface of the grinding wheel is marked "4" in FIG. However, if you use a cup grinding wheel, the axis of rotation of the grinding wheel runs perpendicular to the ground workpiece edge. In this case, the coarse-grained part of the covering is the peripheral surface of the grinding wheel and the grinding surface marked "4" is the end surface of the grinding wheel. In both In some cases, the feed direction runs parallel to the ground workpiece edge and is directed from left to right in FIG. 4.

The individual abrasive grains 9 ', which have a size of 150 to 400 microns, are held in a galvanically deposited nickel bond 10, which allows an arrangement of the diamond grains 9' to each other, in which they touch directly.

As a material for binding the fine-grained diamonds in the peripheral surface 4, a phenolic resin with nickel powder is provided, so that there is sufficient adhesion to the electroplated nickel for holding the diamond 9 '. In contrast, however, an intermediate layer 8 is provided in the embodiment according to FIG. 5 for better adhesion. This intermediate layer 8 applied by powder metallurgy in the sintering process preferably consists of a metal which is also part of the bond of the abrasive coating 5. If, for example, this bond consists of a resin and a copper powder or steel powder, the intermediate layer 8 can also consist of copper or steel.

Claims (7)

1. Grinding wheel (2) for plunge-cut grinding with an abrasive coating part (5) which contains fine grain diamonds, as well as an abrasive coating part (9) which contains bigger diamond grains (9'), characterized in that the abrasive coating part (9) which bears the bigger diamond grains (9') bears parallel to the axis of rotation of the circumferential grinding wheel (2) diamond grains (9') placed in a single layer with a grading of 150 to 400 micrometers which are placed in several layers perpendicularly to the axis of rotation and which are hold in an electro-deposited linkage (10) by being in contact reciprocally.
2. Grinding wheel according to the preamble of claim 1, characterized in that it is configured as a cup grinding wheel and that the abrasive coating part (9) which bears the bigger diamond grains (9') bears perpendicularly to the axis of rotation of the cut grinding wheel (2) diamond grains (9') which are placed in a single layer with a grading of 150 to 400 micrometers which are placed in several layers parallel to the axis of rotation and which are hold in an electro-deposited linkage (10) by being in contact reciprocally.
3. Grinding wheel according to claim 1 and 2, characterized in that the abrasive coating part (9) which bears the bigger diamond grains (9') is placed on an intermediate layer (8) applied by powder metallurgy.
4. Grinding wheel according to claim 3, characterized in that the intermediate layer (8) is constituted by sintered iron.
5. Grinding wheel according to claim 3, characterized in that the intermediate layer (8) is constituted by a metal which is a constituent of the linkage of the abrasive grains of the abrasive coating (5) at the circumferential surface (4).
6. Grinding wheel according to claim 3, characterized in that the intermediate layer (8) is constituted by nickel.
7. Grinding wheel according to claim 3, characterized in that the intermediate layer (8) has a thickness of 0,1 to 0,3 mm.

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