EP0033562A2 - Treating substances for tumbling methods - Google Patents

Abstract

For the surface treatment of workpieces by the tumbling method, the treatment bodies must be matched according to shape, size, specific weight and material hardness to the nature of the workpieces and the desired result of treatment. In addition, the treatment bodies are to have a high abrasive capacity with at the same time good stability so that the method can be designed to be as efficient as possible. Provided for this purpose according to the invention are treatment bodies consisting of a plastic compound, such as ceramic or plastic, which is cast or pressed to form geometric bodies with or without intermixed abrasive particles and is then solidified. The treatment bodies are characterised in that the surface of the geometric bodies has a plurality of groove-shaped or cup-shaped recesses. Whereas the previous development of the treatment bodies has shown that an increase in the abrasive capacity was always associated with a greater or lesser reduction in the service life, the treatment bodies according to the invention have a substantially higher abrasive capacity with a virtually unchanged service life. <IMAGE>

Description

The invention relates to machining bodies for the surface treatment of workpieces according to the surface grinding method, consisting of a plastic mass such as ceramic or plastic, which is cast or pressed with or without mixed-in grinding particles to form geometric bodies and is then solidified.

Such bodies are used, possibly together with liquid processing agents, for the surface treatment of workpieces (eg deburring, grinding, polishing, etc.). Vibratory grinding is a process in which a bed of processing means and workpieces is subjected to a vibration and circulation movement in a work container. The abrasive or even smoothing surface treatment is achieved by friction due to relative movement between the workpieces and the machining bodies. The surface grinding process can be matched to a large number of surface treatment types and any workpieces by selecting appropriate process parameters and size, shape and material properties of suitable machining bodies, unless the size of the latter makes them unsuitable for this process.

The surface grinding process is much more economical than the surface treatment of individual workpieces. It has therefore largely become established, particularly in the mass production of small parts. Nevertheless, efforts are being made to further improve the surface grinding process. Part of this effort is directed towards the machining bodies that wear out during operation and therefore have to be constantly supplemented or renewed. If one takes into account that the cost of the machining bodies often accounts for up to 40% of the total cost of a finishing grinding process, it is understandable that considerable efforts are made to develop machining bodies with a higher grinding performance and a longer service life. However, various ^- restrictive conditions must be observed. The service life cannot be increased arbitrarily, for example, by using machining bodies of substantially greater hardness. In addition to the size and shape of the workpieces, the hardness of their material must also be matched to the material of the workpieces and the type of surface treatment. Also the grinding performance, which essentially depends on the surface pressure between the machining body and the workpiece cannot be increased arbitrarily because the machining bodies have to be optimized for the respective machining process with regard to the size, shape and specific weight of their material.

Because of the abundance of influencing factors that have to be taken into account and contradicting one another, the development of the grinding wheels to date has progressed relatively slowly. Probably the oldest machining bodies for the surface grinding process are the polishing balls, in which the relatively long service life contrasts with a very low grinding performance. In contrast, experience has shown that cylinder sections with a circular or triangular cross-section have a higher grinding performance, but a shorter service life. In the case of machining bodies in the form of a pyramid, the ratio is shifted even further in favor of the grinding performance. This development shows that efforts have been made to create machining bodies whose length of cut edge is enlarged in relation to their surface or volume. However, this only applies to mint condition machining bodies, because their cutting edges are rounded in use due to wear, so that their effectiveness quickly deteriorates. In addition, this development had to suffer a considerable loss in tool life. This tends to apply regardless of the hardness for all materials that are considered for the production of machining bodies.

The invention has for its object to provide machining bodies with which the surface grinding process can be carried out more economically overall without the advantages gained here being lost again due to a complicated manufacture of the machining bodies. The sought-after machining bodies _' should have a high grinding performance with a good service life at the same time.

To solve this task. Machining bodies of the type described at the outset are proposed, which are characterized in that the surface of the geometric bodies has a plurality of groove-shaped or cup-shaped depressions. The processing bodies expediently consist of sections of an extruded strand of material which has groove-shaped depressions parallel to the pressing direction on the surface of the strand. They preferably consist of sections of an extruded strand of material, the cross-section of which essentially corresponds to a simple geometric surface (e.g. circle, triangle, square, etc.), which has indentations distributed inwards on the circumference.

In a further embodiment of the inventive concept, it is provided that the sections have cutting planes running perpendicular to the pressing direction of the material strand. Furthermore, the cutting planes can run at an angle of at least 30 ° to the pressing direction of the strand. Finally, it is possible to arrange the two cutting planes either so that they run parallel to one another or that the front and rear cutting surfaces have an angle of equal size with the pressing direction, to each other, however, are arranged rotated by 180 ° about the press axis. The groove-shaped depressions can be formed with different widths and depths. You expediently have a semicircular or U-shaped cross section. According to a further variant of the concept of the invention, the machining bodies can consist of individually cast or pressed geometric bodies which have groove-like or cup-shaped depressions on all surfaces.

It is readily apparent that the cutting edge length of a machining body of a given size and basic shape can be substantially increased when applying the inventive concept, which is synonymous with a corresponding increase in the grinding performance. Surprisingly, it has been found that the machining bodies according to the invention have approximately the same service life as those of the same basic geometric shape, but without groove-shaped or cup-shaped depressions. The considerable improvement in grinding performance with essentially the same service life is attributed to the fact that the machining bodies according to the invention show a completely different wear behavior. As a result of the longer cutting edge length, they act much more frequently on the workpieces with higher surface pressure, with the process conditions remaining the same, which results in the higher grinding performance. In addition, the groove-shaped or well-shaped depressions act as drainage channels for the material removed from the workpieces on the one hand and due to wear on the machining bodies on the other hand, thereby further improving the grinding performance and reducing the Wear of the machining body is achieved. In addition, there is another not inconsiderable advantage, which is that, overall, a lower abrasive body mass is required for a certain bulk volume. The material "saved" by the groove-shaped or cup-shaped depressions has practically no effect on the bulk volume of the processing bodies, but on the other hand represents a not inconsiderable saving in the production of the processing bodies. When using the processing bodies according to the invention, it has also been found that the reduction the weight of a particular processing body by saving material on the wells does not have any disadvantages. In many cases, it was assumed that the transition to specifically lighter materials for the manufacture of the machining bodies would inevitably lead to disadvantages, because in this way the specific surface pressure would be reduced. This effect is of course also to be taken into account in the machining bodies according to the invention, but it is more than compensated for by the substantially longer cutting edge length.

Finally, the higher grinding performance of the machining body according to the invention is also due to the fact that the total abrasion of workpieces and machining bodies affects the engagement of the grinding edges on the workpiece significantly less than in machining bodies without groove or cup-shaped depressions in which the abrasion temporarily accumulates and through which it can be removed from the respective grinding point.

• Figur 1 zeigt einen Bearbeitungskörper mit dreiecksförmigem Querschnitt.
• Figur 2 zeigt einen Bearbeitungskörper mit quadratischem Querschnitt.
• Figur 3 zeigt einen Bearbeitungskörper mit kreisförmigem Querschnitt.
• Figur 4 zeigt verschiedene Anordnungen der Schnittebenen.

Further details and advantages of the inventive concept are explained in more detail using the exemplary embodiments shown in the figures.

• Figure 1 shows a processing body with a triangular cross-section.
• Figure 2 shows a machining body with a square cross section.
• Figure 3 shows a machining body with a circular cross section.
• Figure 4 shows various arrangements of the cutting planes.

The machining body 1 shown in FIG. 1 consists of a section of an extruded strand of material with an essentially triangular cross-sectional area, groove-shaped depressions 2 being formed in the strand surface parallel to the pressing direction. The processing body 1 has been cut to length from the extruded material strand by cuts made perpendicular to the pressing direction.

FIGS. 2 and 3 show machining bodies 1 with a square or circular cross-sectional area. They also have groove-shaped depressions 2 parallel to the pressing direction and are cut to length from the material strand by cuts perpendicular to the pressing direction.

FIG. 3 shows a longer section of a strand of material 3 and the pressing direction is indicated by arrow 4. Are furthermore by dash-dotted lines Lines different possible cutting directions S1 to S5 for the department of the individual processing bodies indicated by the material strand. The cuts 1 to 3 form parallel cutting planes and the resulting machining bodies have a rhombic cross-sectional area in the side view. The cuts S3 to S5 form cutting planes which form the same angle with the pressing direction but which have a bearing rotated by 180 ° about the pressing axis. That way you can. Machining bodies are produced that have a trapezoidal or triangular cross-sectional area in the side view.

For the sake of a better overview, the illustration of the groove-shaped depressions has been omitted in FIG. It is readily apparent that a large number of geometric bodies of different shapes can be produced by appropriate selection of the cross-sectional shape of the strand and the arrangement of the cutting planes. In this way it is possible to optimally adapt the shape of the machining body to the surface treatment of workpieces in each individual case. Of course, machining bodies with arbitrarily large transverse and longitudinal dimensions can also be produced in this way.

If it is assumed that the side edges of the equilateral triangle have length 1 and the length of the machining body in the pressing direction also has length 1, for example in the case of a machining body according to FIG. 1, the total length of the cut edges in a machining body according to the prior art is the same 9. With a machining body according to

Figure 1, each with three groove-shaped depressions on the three strand surfaces, the total length of the cutting edges is 27. The grinding edge length, which is decisive for the grinding performance, is therefore 3 times as long as in the case of a processing body according to the prior art. As already mentioned, the grinding performance can be increased considerably in this way without reducing the service life of the machining bodies. It has also been found that the grinding effectiveness of machining bodies according to the invention is maintained longer than that of the prior art. This is very likely to be explained by the fact that even with heavy wear on the machining bodies, which are increasingly approaching the spherical shape, partial lengths of the grinding edges produced by the groove-shaped depressions themselves remain active even up to very high degrees of wear. The machining bodies according to the invention therefore not only have better grinding performance when new, they also retain the higher grinding performance until they have to be separated from the bed of machining bodies in the working container because they have become too small. Overall, the surface treatment of workpieces can therefore be carried out much more economically with the machining bodies according to the invention.

Claims (10)

1. Processing body for the surface treatment of workpieces according to the surface grinding method, consisting of a plastic mass, such as ceramic or plastic, which is cast or pressed with or without mixed-in grinding particles to form geometric bodies and then solidified, characterized in that the surface of the geometric body is a Has a plurality of groove or cup-shaped depressions. 2. Processing body according to claim 1, characterized in that they consist of sections of an extruded strand of material which has groove-shaped depressions parallel to the pressing direction on the strand surface. 3. Machining body according to claim 2, characterized in that it consists of sections of an extruded strand of material, the cross section of which essentially corresponds to a simple geometric surface (e.g. circle, triangle, square, etc.) which has inwardly distributed indentations on the circumference. 4. Machining body according to claim 2 or 3, characterized in that the sections have cutting planes extending perpendicular to the pressing direction of the strand of material. 5. Machining body according to claim 2 or 3, characterized in that their cutting planes extend at an angle of at least 30 ° to the pressing direction of the strand. 6. Machining body according to claim 5, characterized in that its two cutting planes run parallel to one another. 7. Machining body according to claim 5, characterized in that the front and rear cutting surface with the pressing direction have an equally large angle, but are arranged rotated to each other by 180 ° about the pressing axis. 8. Machining body according to one of claims 2 to 7, characterized in that groove-shaped depressions of different widths and depths are provided. 9. Machining body according to one of claims 1 to 8, characterized in that the depressions have a semicircular or U-shaped cross section. 10. Machining body according to claim 1, characterized in that they consist of individually cast or pressed geometric bodies which have groove-like or cup-shaped depressions on all surfaces.

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