DE102010025677A1 - dressing tool - Google Patents

Abstract

A dressing tool (100, 200, 300, 400, 500) for conditioning abrasive articles, in particular ceramic bonded abrasive articles, the dressing tool (100, 200, 300, 400, 500) comprising a body having a self-supporting and a working area of the dressing tool defining functional coating (120, 220, 320, 420, 520), wherein the functional coating (120, 220, 320, 420, 520) has a porous bonding matrix (121, 121, 522) interspersed uniformly with hard-material grains (122, 222, 322, 422). 221, 321, 421, 521) is characterized in that in the porous bonding matrix (121, 221, 321, 421, 521) additionally embedded reinforcing elements (130, 230, 330, 430, 530) made of a hard material for stabilization the function pad (120, 220, 320, 420, 520) are present.

Description

Technical area

The Invention relates to a dressing tool for conditioning abrasive articles, in particular of ceramic bonded abrasive articles, wherein the Dressing comprises a body, which a self-supporting and defining a working area of the dressing tool Functional wear, with the functional coating evenly with porous grains interspersed porous bonding matrix includes. Furthermore, the invention relates to the use a dressing tool.

State of the art

Grinding Tools or abrasives use in operation depending on the grinding process and material pairing with time and therefore must be in Profiled and sharpened at certain intervals with a dressing tool become. By profiling is meant in particular the molding of a Abrasive article, d. H. the creation of a defined tool profile. In this case, for example, the Schleifbelaggeometrie in a prescribed Form brought, and plan and concentricity error corrected. When sharpening becomes generates a defined microtopography, i. H. the grinding wheels Be particularly contaminants and blunt abrasive grains freed, leaving sharp abrasive grains exposed and thus sufficient grain supernatants are generated. ever according to the material of the abrasive body profiling takes place simultaneously with sharpening (for example with ceramic bonded Abrasive bodies), or it will after profiling additional sharpening process (eg with grinding wheels with metal or synthetic resin bond) performed.

To the Dressing of abrasive bodies, for example ceramic bonded abrasive bodies with cubic boron nitride (CBN), are usually galvanic or metal bonded Diamond dressing tools used. For galvanically bonded diamond dressing tools becomes a body in a workspace with a Layer of diamond grains occupied, which then by a galvanic coating, for example of nickel metal, be attached to the surface of the body. Although such diamond dressing tools have a relatively high Wear resistance on, but may be due the single-layer occupancy with wear of the diamond monolayer not be reworked and therefore must be regularly Completed in a costly and time consuming process and new be occupied.

at Metal bonded diamond dressers are the diamond grains multilayer in a metal matrix arranged on the base body dispersed. Dressing tools of this type also have one Relatively high wear resistance and can be reprofiled and sharpened. In particular, metal-bound Diamond dressing tools can be used on the grinding wheel however, produce surface topographies which in the later Use in the grinding process often an undesirable running-in behavior Regarding the surface roughness on machined Cause workpiece. The profile retention is also limited and such dressing tools must therefore be relatively frequent reprofiled and sharpened even more frequently which in turn is costly and time consuming.

Diamond pliers with ceramic bonding have also been proposed as possible alternatives to electrodeposited or metal bonded diamond dressers. From the magazine IDR ( Industry Diamonds Rundschau; Issue 39 (2005); Pages 38-42 For example, ceramic-bonded dressing tools for cubic boron nitride (CBN) abrasive tools are known which have a functional coating with diamond grains in a porous bonding matrix. However, the ceramic-bonded dressing tools available today are generally unable to satisfy completely, in particular with regard to service life and profile retention, in order to be used economically in series production.

It There is therefore still a need for an improved dressing tool, which in particular for the conditioning or dressing of ceramic bonded abrasive articles, for example ceramic-bonded abrasive bodies with cubic boron nitride (CBN), is optimized.

Presentation of the invention

task The invention is a, the above-mentioned technical field to create associated dressing tool, which can be repeatedly conditioned is and with improved profile retention additionally the Generation of optimized surface topographies on machining grinding body allows.

The Solution to the problem is due to the features of the claim 1 defined. According to the invention are in the porous Bonding matrix additionally embedded reinforcing elements made of a hard material to stabilize the functional coating in front.

The functional coating of the dressing tool according to the invention is in particular self-supporting. In other words, this means that the functional coating is mechanically stable, in particular independently of the main body. Grundsätz Lich, it would therefore be conceivable to dispense with the dressing tool according to the invention on a functional surface bearing body. However, this makes little sense for practical and economic reasons. The self-supporting function coating differs from a coating, as it is present for example in galvanically coated dressing wheels, with the same contact surface between the body and coating respectively functional coating in particular by a voluminous and interspersed construction.

Under a hard material or hard material are used in the present context in particular substances having a Mohs hardness of at least 8.5, in particular at least 9.5 understood. Preferred examples are diamond, diamond-based composite materials and / or cubic crystalline boron nitride (CBN). It is basically but Other substances as hard materials conceivable, such. Silicon carbide, Alumina, boron carbide, tungsten carbide, vanadium carbide, titanium carbide, Titanium nitride and / or zirconium dioxide.

Under Reinforcing elements are in the present case in particular shaped elements from a Harststoffmaterial to understand. The reinforcing elements point towards the hard material grains in the binding matrix especially different geometric shapes and sizes on.

As has been shown results from the combination of a hard grains permeated porous binding matrix and disposed therein Reinforcing elements made of a hard material a particularly advantageous Functional coating for dressing tools. Such a functional coating shows in particular very good free-cutting properties. Grinder, which is processed by the dressing tools according to the invention are, hardly have any appreciable run-in behavior. The latter is in particular for optimum surface roughness the processed with the inventive dressing tools Due to abrasive particles.

moreover it is in a suitable embodiment of the inventive Functional surfaces possible, a self-sharpening effect to achieve so that wear and dressing properties in Keep a grinding wheel constant. from that in particular results in an improved profile retention or a dressing tool contour remains for a relatively long time constant. In other words, the inventive show Dressing tools a greatly reduced rounding susceptibility. This is the interval for re-profiling the dressing tool even compared to conventional dressing tools significantly extended.

in principle allows the design of the inventive Dressing tool a repeated rework to restore the profile loyalty. This is without an economically unfavorable New allocation, as with conventional dressing tools, on the part by the manufacturer or with appropriate equipment even by the customer himself possible.

The combination of the invention with hard material grains interspersed porous bonding matrix and reinforcing elements made of hard material also results in an efficient heat dissipation the heat generated when dressing an abrasive article. This protects both the dressing tool and the grinding wheel.

As has been shown, it is with the inventive dressing tool also possible, abrasive with relatively large To measure diameters and this even with high-precision CNC-controlled Dressing with point contact between dressing tool and Abrasives. Thus, the inventive Dressing tools for various applications more flexible deploy.

All in all allows the dressing tool according to the invention with improved profile retention, the generation of optimized Surface topographies on the grinding wheel to be processed and at the same time the dressing tool according to the invention is several times be conditioned. Due to the inventive design the dressing tool can be particularly time and cost Save dressing of grinding wheels.

With Advantage, the porous binding matrix has a pore volume from 10-80%, preferably 30-50%, more preferably 35-45%, up. In combination with the inventive Reinforcing elements can be characterized the free-cutting properties and the surface topographies of abrasive bodies, which is processed by the dressing tools according to the invention be, optimize.

It but is also possible in principle, a pore volume less than 10% or more than 80%. In these Cases, however, may have the free-cutting properties or the surface topographies of the inventive Dressing tools machined grinding reduced become.

In particular, the porous bonding matrix comprises an oxidic inorganic material, wherein the oxidic inorganic material preferably comprises Al ₂ O ₃ , ZrO ₂ , SiO ₂ , Fe ₂ O ₃ and / or ZnO. It may also be advantageous to form the porous bonding matrix in the form of a mixture of different oxidic inorganic materials. In an advantageous variant exists the porous bonding matrix exclusively of one or more oxidic inorganic materials. Oxidic inorganic materials, and in particular the abovementioned representatives, have proved to be particularly expedient, since they have a relatively high stability and are chemically relatively inert to a large number of materials even at elevated temperatures. At the same time can be realized with such materials in an economical manner with hard material grains, especially diamond grains, interspersed porous bonding matrices. On the one hand the pore volume can be controlled well and on the other hand an effective embedding of the reinforcing elements is made possible.

However, the porous bonding matrix is not necessarily made of an oxidic inorganic material. Depending on the intended use, it may also be advantageous if the porous bonding matrix comprises a non-oxidic inorganic material, which is in particular a carbide and / or a nitride, and particularly preferably the non-oxidic inorganic material SiC, B ₄ C, Si ₃ N ₄ , TiC, Fe ₃ C, TiN and / or WC. In particular, the porous bonding matrix can also consist exclusively of the non-oxidic inorganic material. Thus, the spectrum of materials for the bonding matrix can be extended and adapted to special requirements. Carbides and nitrides as a non-oxidic inorganic material have been found to be particularly suitable because it can be produced as in the oxidic inorganic materials in an economic manner with hard material grains, in particular diamond grains, interspersed porous bonding matrices. Also in this case, the pore volume can be well controlled and realize an effective embedding of the reinforcing elements.

It however, it may also be advantageous to use the porous binding matrix from a combination of an oxidic inorganic material and a non-oxide inorganic material. In the case of oxidic inorganic material and non-oxidic Inorganic material, I am dealing with advantage to one or several of the above representatives. This allows the mechanical Properties of the binding matrix even more specific to specific requirements to adjust. As it has been shown, it is also a combination an oxidic inorganic material and a non-oxidic one inorganic material possible, with hard material grains to realize offset porous matrices and the reinforcing elements to embed effectively.

It but is also possible in principle, other materials provide for the binding matrix. It can however, under certain circumstances the advantages described above omitted.

In contains a particularly advantageous embodiment the porous binding matrix is a metallic phase and / or an intermetallic phase, wherein preferably the metallic phase and / or the intermetallic phase Cu, Sn, Zn, Fe, Co, Ni, Ag, Cr, V, Zr, Mn and / or Al as metals includes. Under an intermetallic In this context, in particular, a phase will essentially become one understood homogeneous compound of two or more metals, wherein a lattice structure of the intermetallic phase in particular of differs from the lattice structures of the constituent metals.

by virtue of the metallic phase and / or the intermetallic phase can in particular the wetting and adhesion between bonding matrix and Reinforcing elements are improved. At the same time the grain holding forces between the hard grains and the binding matrix are increased. Overall leaves Thus, the function coating by a binding matrix with a metallic phase and / or the intermetallic phase in mechanical Optimize respect without sacrificing wear resistance the functional coating over conventional dressing tools would be reduced. This is especially true in combination with one or more of the abovementioned oxidic inorganic Materials and / or non-oxide inorganic materials.

A porous bonding matrix with a metallic phase and / or However, the intermetallic phase is not mandatory, necessary. It is also possible in the porous binding matrix instead of the metallic phase and / or the intermetallic phase to provide other additives or entirely metallic Phase and / or to abandon the intermetallic phase.

Especially indicates the metallic phase and / or the intermetallic phase in the porous binding matrix a volume fraction of 5-60% on. Such volume fractions have in terms of mechanical Optimization of the porous binding matrix as particularly advantageous proved.

in principle However, they are also smaller in volume than 5% or larger Volume shares as 60% possible. The with the metallic Phase and / or the intermetallic phase associated positive However, effects may be reduced.

Advantageously, the porous binding matrix has an open pore structure. Under an open pore structure is in particular a structure the porous bonding matrix in which adjacent pores in the bonding matrix at least partially communicate with each other. Thus, in particular the free-cutting properties of the functional coating can be improved.

It But is also possible in principle, a closed Pore structure or a mixture of a closed and a provide open pore structure.

Especially Advantageously, the functional coating is produced by a sintering process. In functional coatings produced in this way can be in particular a good cohesion of the bonding matrix, high grain holding forces between the hard material grains and the bonding matrix and realize an effective embedding of the reinforcing elements.

moreover allows the sintering process a particularly economical production the function covering, while at the same time a sufficient accuracy in controlling the pore volume in the binding matrix becomes.

in principle But the functional coating can also by other the Produce specialist known manufacturing process.

A Grain size of the hard grains is in particular 20-600 microns, preferably 80-100 microns. Grains of hard material with these grain sizes can be stable in the binding matrix embed and give in particular in conjunction with those described above Materials and the reinforcing elements a robust functional coating, which also has good free-cutting properties. As optimal have grain sizes of 80-100 microns exposed.

It is in principle also possible, smaller grain sizes than 20 microns or larger grain sizes than Provide 600 microns. However, this may be omitted the advantages mentioned above.

With Advantage are the hard grains in the form of diamond grains before, wherein preferably a volume fraction of the diamond grains 30-40%. Diamond grains are suitable due to their outstanding hardness, mechanical Robustness and relatively high chemical inertness.

in principle But it is also conceivable, in addition to or instead of Hard material grains of diamond other hard material grains to provide from other hard material.

One Volume share of 30-40% has become particular. in combination with the materials mentioned above for the binding matrix and a pore volume of 10-80%, preferably 30-50%, further preferably 35-45%, proved suitable.

Of the Volume fraction of the diamond grains can also be smaller than 30%, which may be the dressing performance reduced. Larger volume shares than 40% hardly bring an added benefit and are particularly economical.

With Advantage is the functional coating multi-layered or multi-layered. This means in particular that the function coating several Layers or layers of superposed hard material grains having. In other words, the hard grains are with Advantage multi-layer dispersed in the functional coating. The individual layers or layers of the functional coating are in particular with respect to a direction perpendicular to the contact surface of the functional coating with the main body on top of each other. In a rotationally symmetrical body The individual layers or layers are therefore particularly in radial direction one above the other. A functional coating with multilayer construction allows in particular a multiple Regrinding of the dressing tool according to the invention. In particular in combination with the reinforcing elements assets multi-layered functional coverings also with regard to Wear resistance and cutting properties to convince.

in principle it is also possible to provide a single-layer function coating. But in particular the possibilities are reduced with regard to the repeated regrinding of the dressing tool. However, this would be one of the inventive Advantages of an application advantageous porous Structure partially eliminated.

As has been found, a minimum thickness of the functional coating preferably corresponds to at least five times, more preferably at least ten times, an average grain diameter of the hard material grains. In a particularly preferred embodiment, the minimum thickness of the functional coating corresponds to at least thirty times the mean grain diameter of the hard material grains. In this case, the mean grain diameter of the hard material grains is to be understood as meaning in particular the mean value over all grain diameters of the hard material grains contained in the functional coating. The thickness of the functional coating is measured in particular in a direction perpendicular to the contact surface of the functional coating with the base body. In the case of a rotationally symmetrical base body, the thickness is measured in particular in the radial direction. On the one hand, said minimum thickness allows multiple regrinding of the dressing tool according to the invention. On the other hand, it has been shown that the function coating, in particular in combination with the Ar mierungselementen, a particularly high wear resistance with good cutting properties has.

It but in principle also lower thicknesses be provided, although the possibilities Reduce the regrinding and possibly the wear resistance decreases.

The Reinforcing elements are preferably as elongated and / or cuboidal rods before, preferably a Ratio of a length of the cuboid Chopsticks to a thickness and / or a width of the cuboid Chopstick has a value of 2-7. The chopsticks can be rounded in particular in an end-side area and / or one on an edge profile and / or a shape of a side surface have adapted form of the functional coating. This can be done For example, the sticks directly to an edge area and / or arrange a side surface of the function pad adjacent what best enables these particularly exposed areas of the functional coating strengthened.

A maximum length of the reinforcing elements is in a preferred Embodiment at least equal to half the thickness of Function covering. The thickness of the functional coating is, as already mentioned above, in particular in a direction perpendicular to a contact surface between the main body and the functional coating measured. The reinforcing elements are preferred perpendicular to a contact surface between the base body and the function pad arranged.

Especially Advantageously, the reinforcing elements have a maximum length which is at least twice as large, preferably five Times as big, is how a mean grain diameter in the Binding matrix present hard grains.

With such trained reinforcing elements can stability and profile retention of the functional coating, in particular in interaction with the pore volume and materials described above, in particular be significantly improved economically.

ever Under certain circumstances, it can also be advantageous after application be, other embodiments or arrangements of the reinforcing elements provided. Conceivable are in principle z. B. reinforcing elements in Shape of thin platelets with three, four or three even more corners, with single or all corners too may be rounded. Also rounded particles, z. B. hemispherical and / or spherical particles, can basically be used as reinforcing elements become. The reinforcing elements can also be oblique or parallel to the contact surface between the base body and functional coating be arranged.

In a particularly advantageous embodiment the reinforcing elements except for unavoidable impurities exclusively Diamond. This will be a particularly high gain and Profile retention of the functional coating achieved. But they are too other materials than diamond conceivable.

So can the reinforcing elements in particular also from a Composite material, in particular the composite material Contains diamond and a metallic phase. Preferably the diamond in the composite material accounts for 80-90% by weight and the metallic phase accounts for 10-20% by weight on.

Such Reinforcing elements can z. Depending on the composition and construction of the binding matrix upon embedding in the binding matrix Benefits and / or the stability of the functional coating improve.

The Composite material can also be composed differently and basically there are also reinforcement elements without diamond, z. B. of cubic boron nitride, possible.

It may also be advantageous, different reinforcing elements to be made of different materials. So z. B. reinforcing elements, which except for unavoidable impurities Made exclusively of diamond, with reinforcing elements a composite material, e.g. B. of diamond and a metallic Phase, be combined.

Especially Preferably, the reinforcing elements are on an edge and / or on a side surface of the function pad adjacent. This will be the most exposed during dressing Strengthening of the function pad or the dressing tool optimally. The reinforcing elements are in particular at an edge profile and / or a shape of the side surface formed.

In a preferred embodiment is the main body formed rotationally symmetrical with respect to a rotation axis and is in particular as a disk, ring and / or in pot form. This makes the inventive dressing tool for use the rotary machining of grinding wheels, which represents a particularly effective variant of dressing. The main body is advantageously made of a metal, such as z. As stainless steel. The use of basic bodies stainless steel gives high strength and chemical inertness a variety of cooling lubricants.

at a disc as a body is the function coating in particular mounted on an outer shell of the disc. It is also possible the functional coating in addition to or instead of attachment to arrange on the outer shell in frontal areas of the disc.

at a basic body in the form of a ring, the functional coating basically on an outer sheath and / or an inner sheath of the ring. It is also possible the function coating in addition to or instead of mounting on the outer jacket to arrange on frontal areas of the ring.

at pot-shaped basic bodies, the functional coating for example, on an outer surface and / or an inner surface the cup-shaped body present.

The Reinforcing elements are preferred with their longitudinal central axes arranged in the radial direction of the base body. By the orientation of the reinforcing elements is minimized Number of reinforcing elements optimum profile retention and Wear resistance of the functional coating achieved what the manufacturing cost reduced. This especially when used with reinforcing elements in the form of elongated and / or cuboidal Rod.

in principle However, the reinforcing elements can also be inclined and / or perpendicular to the radial direction of the body to be ordered. It is also possible different reinforcing elements in the function covering with their longitudinal central axes in different To align directions.

In Another preferred variant is the reinforcing elements anchored with advantage additionally in the main body. This allows the connection between the functional coating and the base body be additionally improved, what the profile stability and Wear resistance of the inventive Dressing tool benefits. The reinforcing elements can in this case, for example, in holes, grooves and / or recesses present in the body and thus have a particular high-precision position relative to the main body.

It However, it is also possible the reinforcing elements only to be provided in the functional coating. This can be, for example reduce the length of the reinforcing elements, what the manufacturing cost reduced.

Out the following detailed description and the totality of the claims arise further advantageous embodiments and feature combinations the invention.

Brief description of the drawings

The used to explain the embodiment Drawings show:

1 A plan view of the front side of a first dressing tool according to the invention with a rotationally symmetrical base body and a reinforced by reinforcing elements function covering;

2 A cross section through the dressing tool 1 along the line AA;

3 A detail view of 2 (Area of the dashed circle in 2 ), which the edge region of the main body of the dressing tool 1 without functional lining shows;

4 A detail view of 2 (Area of the dashed circle in 2 ), which forms the edge region of the dressing tool 1 with functional coating shows;

5 A plan view of the front side of a second dressing tool according to the invention with a rotationally symmetrical basic body and a reinforced by reinforcing elements function covering;

6 A cross section through the dressing tool 5 along the line BB;

7 A detail view of 6 (Area of the dashed circle in 6 ), which forms the edge region of the dressing tool 5 shows;

8th A cross section through the dressing tool 5 along the line CC;

9 A plan view of the front side of a third dressing tool according to the invention with a rotationally symmetrical base body and a reinforced by reinforcing elements function covering;

10 A cross section through the dressing tool 9 along the line DD;

11 A detail view of 10 (Area of the dashed circle in 10 ), which forms the edge region of the dressing tool 9 shows;

12 A detailed view of the edge region of a fourth inventive dressing tool in cross section;

13 A detail view of the border area a fifth inventive dressing tool in cross section.

in principle In the figures, like parts are given the same reference numerals.

Ways to execute the invention

A first dressing tool according to the invention 100 is in the 1 - 4 shown. This has a basic body 110 made of stainless steel, which is a frusto-conical disc with a large circular front 111 and a plane-parallel arranged small circular front side 112 (in 1 from the bigger front 111 concealed) is formed. A diameter of the main body 100 measures for example about 100 mm. The two circular faces 111 . 112 are over a substantially conical lateral surface 113 (please refer 2 ) connected. The main body 110 or the frusto-conical disc are rotationally symmetrical with respect to a perpendicular to the two end faces 111 . 112 standing axis of rotation 116 or longitudinal central axis of the main body 110 educated.

Along the axis of rotation 116 extends a central cylindrical bore 115 continuously from the big front 111 to the small front 112 , The central hole 115 serves in particular for receiving a drive axle of a machine tool. Around the central hole 115 are several cylindrical mounting holes 117 at regular intervals on one to the central hole 115 or to the axis of rotation 116 arranged concentric circle. The mounting holes 117 serve to fix the body, for example, with mounting screws in a machine tool. A diameter of the mounting holes 117 is in one of the big frontage 111 facing portion widened stepwise, so that screw heads of the mounting screws below a plane of the large end face 111 in the main body 110 can be placed.

In 3 is the design of the body 110 in the edge region or in the region of the lateral surface 113 shown enlarged (area of the dashed circle in 2 ), to illustrate the design of the body 110 the other existing and described below elements of the first dressing tool 100 are not shown. One of the 3 corresponding representation with the other elements is in 4 given.

In one on the larger front 111 adjacent area of the lateral surface 113 is a groove completely surrounding the main body 118 introduced into the body. The circumferential groove 118 has a rectangular profile and is in the radial direction of the body 110 as well as to the big front side 11 open. In the circumferential groove 118 are at regular intervals several cuboid depressions 119 in the radial direction in the body 110 brought in. The cuboid depressions 119 have in the radial direction z. B. a depth of 0.5-2 mm.

In the circumferential groove 118 is an annular functional coating 120 arranged with rectangular cross-section. The functional coating 120 protrudes in the radial direction from the groove 118 out and is with the big frontage 111 of the basic body 110 roughly flush.

The functional coating 120 consists of a porous matrix 121 with a plurality of hard grains dispersed therein 122 , The porous matrix 121 has z. B. a pore volume of 40% and consists for example of Al ₂ O ₃ with a metallic phase of z. B. Cu, which based on the porous matrix 121 has a volume fraction of, for example, 30%. The hard grains 122 lie z. B. in the form of diamond grains and have at a mean particle size of, for example, about 91 microns, a volume fraction of z. B. about 36%. A thickness 124 of the functional coating 120 or the porous matrix 121 in the radial direction or perpendicular to the contact surface with the main body 110 measures z. B. about 3.5 mm, which is about 38 times the mean grain diameter of the hard grains 122 equivalent.

The functional coating 120 is z. B. in a known sintering process on the body 110 applied.

In each of the several cuboid depressions 119 each is a reinforcing element 130 in the form of an elongated cuboid diamond rod in the base body 110 anchored. The with their end sections in the cuboid depressions 119 present reinforcing elements 130 or the cuboid diamond rods protrude with their longitudinal central axes in the radial direction from the main body 110 away and are approximately in the middle of the functional coating 130 embedded. The from the main body 110 opposite ends 131 the reinforcing elements 130 borders directly on the outer lateral surface 123 of the functional coating 120 and are on the course of the outer lateral surface 123 formed. In other words, they are from the main body 110 opposite ends 131 the reinforcing elements 130 approximately flush with the outer lateral surface 123 of the functional coating 120 ,

The reinforcing elements 130 For example, have a width and a thickness of about 0.4 mm. A length of reinforcing elements 130 in radial direction measures z. B. about 4 mm. The length of the reinforcing elements 130 is thus greater than the entire thickness 124 of the functional coating 120 or the porous binding matrix 121 , The reinforcing elements 130 exist except for unavoidable impurities z. B. made of diamond.

In the 5 - 8th is a second dressing wheel according to the invention 200 displayed. This has a body 210 on, which is formed substantially the same except for the edge region, as the first body 110 of the first dressing tool 100 and accordingly over a large front page 211 , a small frontage 212 , a conical surface 213 , a central hole 215 , a rotation axis 216 and several mounting holes 217 which are all executed as the corresponding elements in the first body.

In contrast to the main body 110 of the first dressing tool 100 the basic body has 210 of the second dressing tool 200 but not on a circumferential groove in one on the large front 211 adjacent area of the lateral surface 213 , Instead, the body is 210 of the second dressing tool 200 a circumferential projecting flange 218 with rectangular cross section available. At regular intervals are in the flange 218 continuous rectangular grooves 219 introduced, which in a direction parallel to the axis of rotation 216 completely through the flange 218 pass through. The grooves 219 are thus in one direction to the large front 211 towards as well as in one direction to small end face 210 towards and in the radial direction open.

In each of the rectangular grooves 219 is in each case a reinforcing element 230 in the form of an elongated cuboid diamond rod in the base body 210 anchored. The with their end sections in the rectangular grooves 219 present reinforcing elements 230 or the cuboid diamond rods protrude with their longitudinal central axes in the radial direction from the main body 210 path.

The reinforcing elements 230 of the second dressing tool 200 For example, have the same dimensions as the reinforcing elements 130 of the first dressing tool 100 and exist for. B. also made of diamond.

The areas between the reinforcing elements 230 are at the second dressing tool 200 with a functional coating 220 filled in, bringing the reinforcing elements 230 each with two opposite sides in the functional coating 220 are embedded. The individual sections of the function cover 220 lie in the form of ring segments with a rectangular profile. The reinforcing elements 230 and the sections of the functional cover 220 together form one the main body 210 surrounding and continuous ring with rectangular profile. One in the direction of the axis of rotation 216 measured thickness of the functional body 220 essentially corresponds to the thickness of the reinforcing elements measured in the same direction 230 ,

The functional coating 220 of the second dressing tool 200 also has a porous matrix 221 with dispersed therein hard material grains 222 , The porous matrix 221 as well as the hard material grains 222 of the functional coating 220 of the second dressing tool 200 For example, they are substantially the same as the porous matrix 121 and the hard grains 122 of the functional coating 120 of the first dressing tool 100 ,

In the 9 - 11 is a third dressing tool according to the invention 300 shown. This has a body 310 which is in the form of a substantially cylindrical and about an axis of rotation 316 rotationally symmetrical disk is present. A thickness of the main body 310 or the disc, measured in a direction parallel to the axis of rotation 316 , tapers with respect to a perpendicular to the axis of rotation 316 lying cross-sectional plane E from the central region of the body 310 first in the radial direction and conically in a further outward region.

Along the axis of rotation 316 extends a central cylindrical bore 315 through the main body 310 , The central hole 315 serves in particular for receiving a drive axle of a machine tool.

In 11 is the embodiment of the third dressing tool 300 Enlarged displayed in the edge area (area of the dashed circle in 10 ).

In a perpendicular to the cross-sectional plane E lateral surface 313 of the basic body 310 are at regular intervals several cuboid depressions 319 in the radial direction in the body 310 brought in. The cuboid depressions 319 have in the radial direction z. B. a depth of 0.5-2 mm.

On the lateral surface 313 is an annular functional coating 320 arranged. The functional coating 320 points in the area of the lateral surface 313 a rectangular cross section, which merges in the radial direction in a wedge-shaped tapered portion. In a radially outermost region is the functional coating 320 as a rounded edge 323 educated.

The functional coating 320 consists of one porous matrix 321 with a plurality of hard grains dispersed therein 322 , The porous matrix 321 has z. B. a pore volume of 40% and consists for example of Al ₂ O ₃ with a metallic phase of z. B. Cu, which based on the porous matrix 321 has a volume fraction of, for example, 30%. The hard grains 322 lie z. B. in the form of diamond grains and have at a mean particle size of, for example, about 91 microns, a volume fraction of z. B. about 36%. A thickness 324 of the functional coating 320 or the porous matrix 321 in the radial direction or perpendicular to the lateral surface 313 or contact surface with the main body 310 measures z. B. about 3.5 mm, which is about 38 times the mean grain diameter of the hard grains 322 equivalent.

In each of the several cuboid depressions 319 each is a reinforcing element 330 in the form of an elongated cuboid diamond rod in the base body 310 anchored. The with their end sections in the cuboid depressions 319 present reinforcing elements 330 or the cuboid diamond rods protrude with their longitudinal central axes in the radial direction from the main body 310 away and are approximately in the middle of the functional coating 330 embedded. The from the main body 310 opposite ends 331 the reinforcing elements 330 borders directly to the rounded edge 323 of the functional coating 320 and are attached to the shape of the rounded edge 323 formed. In other words, they are from the main body 310 opposite ends 331 the reinforcing elements 330 roughly flush with the rounded edge 323 of the functional coating 320 ,

The reinforcing elements 330 have, for example, a width and a thickness of approximately 0.4 mm, as in the first dressing tool. A length of reinforcing elements 330 in the radial direction measures z. B. about 4 mm, which is greater than the thickness 324 of the functional coating 320 or the porous binding matrix. The reinforcing elements 330 exist except for unavoidable impurities z. B. made of diamond.

12 shows a detailed view of a fourth inventive dressing tool 400 , The main body 410 of the fourth dressing tool 400 is essentially the same design as the main body 110 of the first dressing tool 100 out 1 , In contrast, the fourth dressing tool 400 However, no cuboid depressions in the circumferential groove 418 appropriate.

In the circumferential groove 418 is however like the first dressing tool 100 also with the fourth dressing tool 400 an annular functional coating 420 arranged with rectangular cross-section. The functional coating 420 protrudes in the radial direction from the groove 418 out and is with the big frontage 411 of the basic body 410 roughly flush.

The functional coating 420 of the fourth dressing tool 400 also has a porous matrix 421 with dispersed therein hard material grains 422 , The porous matrix 421 as well as the hard material grains 422 of the functional coating 420 of the fourth dressing tool 400 For example, they are substantially the same as the porous matrix 121 and the hard grains 122 of the functional coating 120 of the first dressing tool 100 ,

In the functional coating 420 of the fourth dressing tool 400 are several reinforcing elements 430 embedded in the form of elongated cuboid diamond rods. The reinforcing elements 430 are aligned with their longitudinal central axes in the radial direction. In contrast to the first dressing tool 100 are the reinforcing elements 430 of the fourth dressing tool 400 but not in the main body 410 anchored, but spaced from this. The reinforcing elements 430 are laterally in the functional coating 420 arranged and bordered with their the body 410 opposite ends 431 directly in a corner area of the function cover 420 to the outer lateral surface 423 of the functional coating 420 and are on the course of the outer lateral surface 423 formed. One perpendicular to the opposite ends 431 present side surface of the reinforcing elements is in the plane of the large end face 411 to the boundary surface of the functional coating 420 arranged adjacent.

This is the reinforcing elements 430 at the fourth dressing tool 400 each on four sides of the porous matrix 421 or the functional coating 420 surround and reinforce in particular one of the main body 410 facing away edges of the function covering 420 ,

The reinforcing elements 430 of the fourth dressing tool 400 are shorter than the reinforcing elements 130 of the first dressing tool 100 However, for example, have the same thicknesses and widths as the reinforcing elements 130 of the first dressing tool 100 and exist for. B. also made of diamond.

13 shows a detailed view of a fifth inventive dressing tool 500 , The main body 500 of the fifth dressing tool is substantially identical to the fourth dressing tool 400 out 12 , In the circumferential groove 518 of the fifth dressing tool 500 is the same as the fourth dressing tool 400 a functional coating 520 with a porous matrix 521 and dispersed therein hard material particles 522 arranged. The porous matrix 521 as well as the hard material grains 522 of the functional coating 520 of the fifth dressing tool 500 For example, they are substantially the same as the porous matrix 121 and the hard grains 122 of the functional coating 120 of the first dressing tool 100 ,

In the functional coating 520 of the fifth dressing tool 500 are several reinforcing elements 530 embedded in the form of elongated cuboid diamond rods approximately in the middle. The reinforcing elements 530 are aligned with their longitudinal central axes in the radial direction. Unlike the fourth dressing tool 400 are the reinforcing elements 530 at the fifth dressing tool 500 However, on all sides of the boundary surfaces of the functional coating 520 spaced. This is the reinforcing elements 530 completely in the functional coating 520 or in the porous matrix 521 embedded. In other words, the reinforcing elements 530 all sides of the functional coating 520 or the porous matrix 521 surround.

In a first practical test was the fourth inventive dressing tool 400 out 12 for profiling a ceramically bonded CBN grinding wheel in particle size 46 μm with a nominal internal profile radius of 0.15 + 0.05 mm. Even after 60 profiled tools no significant wear on the inventive dressing tool has occurred. All of the fourth with the fourth dressing tool according to the invention 400 dressed CBN grinding wheels had a comparably high quality and in particular showed no undesirable running-in behavior in subsequent grinding processes. In other words, the CBN grinding wheels were fully usable immediately after dressing.

For comparison purposes, a first not according to the invention dressing tool was produced, which is constructed substantially the same as the fourth inventive dressing tool 400 , but no reinforcing elements 430 or elongated cuboid diamond rods has. The non-inventive dressing tool was then subjected to the same practical test as the fourth inventive dressing tool 400 , It has been found that in the non-inventive dressing tool after 30 profiled grinding wheels wear of the dressing tool contour is outside the allowable tolerance of 0.05 mm at the profile radius.

In a second practical test, the second inventive dressing tool 200 from the 5 - 8th used for profiling a ceramic bonded sintered corundum disk of grain size F100 and the dimension 84 × 40 × 24 mm. When radially grooving a groove, an edge radius of 0.12 mm is obtained. The with the second inventive dressing tool 200 machined ceramic bonded sintered corundum also showed no undesirable run-in behavior in a subsequent grinding process.

For comparison purposes, a second non-inventive dressing tool was produced, which is constructed substantially the same as the second inventive dressing tool 200 , but no reinforcing elements 230 or elongated cuboid diamond rods has. After an analog profiling application as in the second practical test, the edge radius of the second non-inventive dressing tool is 0.48 mm. The wear resistance of the second dressing tool according to the invention 200 is thus increased by a factor of 4 compared with the second non-inventive dressing tool.

As it turned out, the dressing tools used in the practical tests could be used 200 . 400 be sanded easily and repeatedly.

The Embodiments described above are merely as illustrative examples, which are within the scope of the invention can be modified as desired.

Thus, the dressing tools designed for the rotating dressing of grinding bodies can 100 . 200 . 300 . 400 . 500 basically be executed in a variant for standing dressing. In this case, z. B. be dispensed rotationally symmetrical body and instead plate-shaped body can be used.

It is also possible with the dressing tools 100 . 200 . 300 . 400 . 500 differently shaped body 110 . 210 . 310 . 410 . 510 provide, which are particularly adapted to the particular application of the dressing tool. Conceivable z. B. cup-shaped base body with a cylindrical drive shaft, wherein the functional coatings z. B. at an edge and / or lateral surface of the pot-like base body or at any angle between 0 and 90 °.

Likewise, the function pads 120 . 220 . 320 . 420 . 520 also have different outer diameters in different areas, the different area z. B. connected via one or more steps, edges and / or rounded transition areas. In this case, in particular in the area of all steps, edges and / or rounded transition areas, correspondingly adapted reinforcing elements can be present which reinforce these particularly exposed areas.

But it is also possible with the dressing tools 100 . 200 . 300 . 400 . 500 in addition to the existing functional coverings 120 . 220 . 320 . 420 . 520 further functional coatings on the basic bodies 110 . 210 . 310 . 410 . 510 provide, which in particular can also be reinforced with reinforcing elements.

The functional coverings 120 . 220 . 320 . 420 . 520 may instead or in addition to the diamond grains 122 . 222 . 322 . 422 . 522 Also contain other hard grains, especially with different grain diameters included.

For all dressing tools 100 . 200 . 300 . 400 . 500 can in addition to the existing reinforcing elements 130 . 230 . 330 , 430 . 530 further reinforcing elements in the functional coverings 120 . 220 . 320 . 420 . 520 available. The further reinforcing elements can be z. B. beside and / or between the existing reinforcing elements 130 . 230 . 330 , 430 . 530 be arranged.

In particular, it is in all dressing tools 100 . 200 . 300 . 400 . 500 also possible to provide differently shaped reinforcing elements and / or reinforcing elements made of different materials. It is also conceivable, a part or all reinforcing elements 130 . 230 . 330 . 430 . 530 in non-radial direction, z. B. with their longitudinal central axes parallel to the axes of rotation 116 . 216 . 316 to arrange. This is of course also possible with other reinforcing elements.

As has been shown, the porous binding matrix 121 . 221 . 321 . 421 . 521 the dressing tools 100 . 200 . 300 . 400 . 500 additionally or instead of the oxidic inorganic material also contain a non-oxide inorganic material. As a result, the porous bonding matrix can be adapted, for example, to specific requirements or to special material combinations of the dressing tool and the abrasive body. Likewise, the metallic phase in the porous binding matrices 121 . 221 . 321 . 421 . 521 also be omitted or there are other or additional metals provided in the metallic phase.

In summary it should be noted that novel dressing tools have been created, which are nachprofilierbar and compared to conventional Dressing tools in particular by improved profile retention distinguished. Due to the complex interaction between the with Hard material grains interspersed porous binding matrix and the reinforcing elements arranged therein can be simultaneously optimized surface topographies on the processed Produce abrasive particles, so this is essentially no have adverse entry behavior more.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited non-patent literature

• - Industry Diamonds Rundschau; Issue 39 (2005); Pages 38-42 [0005]

Claims (22)

Dressing tool ( 100 . 200 . 300 . 400 . 500 ) for conditioning abrasive bodies, in particular ceramic bonded abrasive bodies, wherein the dressing tool ( 100 . 200 . 300 . 400 . 500 ) comprises a basic body, which has a self-supporting functional covering () defining a working area of the dressing tool ( 120 . 220 . 320 . 420 . 520 ), the functional coating ( 120 . 220 . 320 . 420 . 520 ) evenly with hard material grains ( 122 . 222 . 322 . 422 . 522 ) interspersed porous binding matrix ( 121 . 221 . 321 . 421 . 521 ), characterized in that in the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) additionally embedded reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) of a hard material for stabilizing the functional coating ( 120 . 220 . 320 . 420 . 520 ) are present. Dressing tool according to claim 1, characterized in that the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) has a pore volume of 10-80%, preferably 30-50%, more preferably 35-45%. Dressing tool according to one of claims 1-2, characterized in that the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) comprises an oxidic inorganic material, wherein preferably the oxidic inorganic material Al ₂ 0 ₃ , ZrO ₂ , SiO ₂ , Fe ₂ O ₃ and / or ZnO includes. Dressing tool according to one of claims 1-3, characterized in that the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) comprises a non-oxidic inorganic material, which is in particular a carbide and / or a nitride and particularly preferably the non-oxide inorganic material SiC, B ₄ C, Si ₃ N ₄ , TiC, Fe ₃ C, TiN and / or WC includes. Dressing tool according to claim 4, characterized in that the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) consists of a combination of the oxidic inorganic material and the non-oxide inorganic material. Dressing tool according to one of claims 1-5, characterized in that the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) contains a metallic phase and / or an intermetallic phase, wherein the metallic phase and / or the intermetallic phase preferably includes Cu, Sn, Zn, Fe, Co, Ni, Ag, Cr, V, Zr, Mn and / or Al. Dressing tool according to claim 6, characterized in that the metallic phase and / or the intermetallic phase in the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) has a volume fraction of 5-60%. Dressing tool according to one of claims 1-7, characterized in that the porous binding matrix ( 121 . 221 . 321 . 421 . 521 ) has an open pore structure. Dressing tool according to one of claims 1-8, characterized in that the functional coating ( 120 . 220 . 320 . 420 . 520 ) is produced by a sintering process. Dressing tool according to one of claims 1-9, characterized in that a grain size of the hard grains ( 122 . 222 . 322 . 422 . 522 ) 20-600 microns, preferably 80-100 microns, is. Dressing tool according to one of claims 1-10, characterized in that the hard material grains ( 122 . 222 . 322 . 422 . 522 ) in the form of diamond grains, wherein preferably a volume fraction of the diamond grains is 30-40%. Dressing tool according to one of claims 1-11, characterized in that the functional coating ( 120 . 220 . 320 . 420 . 520 ) is constructed in several layers. Dressing tool according to one of claims 1-12, characterized in that a minimum thickness of the functional coating ( 120 . 220 . 320 . 420 . 520 ) at least five times, in particular at least ten times, a mean grain diameter of the hard grains ( 122 . 222 . 322 . 422 . 522 ) corresponds. Dressing tool according to one of claims 1-13, characterized in that the reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) are present as elongated and / or parallelepiped-shaped rods, wherein preferably a ratio of a length of the cuboidal rod to a thickness and / or a width of the cuboidal rod has a value of 2-7. Dressing tool according to one of claims 1-14, characterized in that the reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) except for unavoidable impurities consist exclusively of diamond. Dressing tool according to one of claims 1-15, characterized in that the reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) consist of a composite material, wherein in particular the composite material contains diamond and a metallic phase. Dressing tool according to claim 16, characterized in that that the diamond in the composite material accounts for 80-90% by weight and the metallic phase has a weight fraction of 10-20%. Dressing tool according to one of claims 1-17, characterized in that the reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) to an edge ( 323 ) and / or to a side surface ( 123 . 423 ) of the functional coating ( 120 . 220 . 320 . 420 . 520 ) are arranged adjacent. Dressing tool according to one of claims 1-18, characterized in that the basic body ( 110 . 210 . 310 . 410 . 510 ) with respect to a rotation axis ( 116 . 216 . 316 ) is rotationally symmetrical and is present in particular as a disc and / or ring and wherein particularly preferably the basic body ( 110 . 210 . 310 . 410 . 510 ) consists of metal. Dressing tool according to claim 19, characterized in that the reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) with their longitudinal central axes in the radial direction of the basic body ( 110 . 210 . 310 . 410 . 510 ) are arranged. Dressing tool according to one of claims 1-20, characterized in that the reinforcing elements ( 130 . 230 . 330 . 430 . 530 ) additionally in the basic body ( 110 . 210 . 310 . 410 . 510 ) are anchored. Use of a dressing tool according to one of Claims 1-21 for conditioning abrasive bodies, preferably ceramic bonded abrasive and especially preferably of abrasive bodies of cubic boron nitride.

Images