DE102011053740A1 - Preparing a hard material tool component e.g. a full hard metal tool, comprises transforming and/or pressing or extruding a hard material, a sintering agent such as carbon monoxide, and/or binding agent to slug, and then sintering - Google Patents

Abstract

The method comprises transforming and/or pressing or extruding a hard material such as tungsten carbide, a sintering agent such as carbon monoxide, and/or a binding agent containing powder with a given particle size distribution to a slug, and then sintering. A hard material particle of the powder has two particle size distributions different from each other with multimodal distribution. Two hard material powder fractions or populations with particle size distributions different from each other are mixed with the sintering agent by wet beating. The method comprises transforming and/or pressing or extruding a hard material such as tungsten carbide, a sintering agent such as carbon monoxide, and/or a binding agent containing powder with a given particle size distribution to a slug, and then sintering. A hard material particle of the powder has two particle size distributions different from each other with multimodal distribution. Two hard material powder fractions or populations with particle size distributions different from each other are mixed with the sintering agent by wet beating. Two hard material powder fractions and/or populations are present as finished alloys. The particle size distributions are tuned on percentage shares of the powder fractions at the total powder in such a way that, according to mixing and pressing the powder, the hard material particles of the powder population with a large median diameter are held by the hard material particle of other powder population with a small median diameter. The hard material particles of the powder population with the large median diameter are embedded into a coherent composite of the hard material particles of the other powder population with the small median diameter. A space between the hard material particles of the powder population is filled with the large median diameter of the hard material particles of the other powder population with the small median diameter. The powder populations have a narrow particle size distribution, in which values for a measurement of D10 and D90 referred to the volume of up to 20% differ from the measured D50. The hard material particles are present in two particle size distributions, where an average particle size of the particle population is 0.3-0.5 mu m and an average particle size of the other particle population is 0.8-1.3 mu m. Independent claims are included for: (1) sinter-metallurgic powders for the preparation of a hard material tool component such as a full hard metal tool; (2) a hard material slug prepared by transformation and/or grouting or extrusion of a sinter-metallurgic powder; and (3) a sintered hard material body.

Description

The invention relates to a method for producing a hard material body, in particular a hard material tool component, such as. B. a solid carbide (VHM) tool in which a hard material such. B. WC, and sintering agents such. B. Co, and / or binder-containing powder having a predetermined particle size distribution is formed into a blank or pressed or extruded and then sintered. Furthermore, the invention relates to a sinter metallurgical powder suitable for this process. Finally, the invention relates to an optionally sintered hard material blank and a sintered hard material body, which can be produced by the method according to the invention and / or by means of the powder according to the invention.

Hard materials have recently been increasingly used as cutting materials in the machining of materials. In this case, the carbide is currently the most important cutting material. However, it should be emphasized that the invention should not be limited to carbide cutting materials. Rather, it extends to the entire field of hard materials, ie in addition to the metallic hard materials such as TiC, TiN, TiB ₂ , ZrC, ZrB ₂ , NbC, TaC, Cr ₃ C ₂ , CrB ₂ , MoSi ₂ or WC on non-metallic Hard materials, such as. As diamond, cubic boron nitride, Si ₃ N ₄ , SiC and corundum (Al ₂ O ₃ ), as well as on hard material systems such. As mixed carbides, carbonitrides, carbide-boride combinations, mixed ceramics and nitride ceramics, as described in detail in "HARDMETAL FOR THE PRACTITIONER"; Dr.-Ing. Wolfgang Schedler; VDI-Verlag GmbH, Dusseldorf, 1988 , are described.

Such hard materials, in particular hard metals are selected and assembled specifically for certain applications, wherein z. For example, a classification for hard metals ISO 513 in classes K10, K20, K10 / K20, K40, P25 and P40. Classes K10, K20, P25 and P40 are mixed grades in which, in addition to the tungsten carbide (WC) and the sintering agent Co, small amounts (between 2 and 17.5% by weight) of another hard material, namely TiC and Ta (Nb) C are added.

An essential distinguishing criterion is the particle size of the microstructure, which is less than 0.5 μm for class K40, less than 0.7 μm for classes K10 and K20, less than 1.5 μm for class K10 / K20 and less than 1.5 μm for classes P25 and P40 is less than 2.5 μm. For the carbide grades of classes K10 / K20 and K40, the following distinction is made: Normal grain size <2.5 μm fine grain <1.5 μm impalpable <0.7 μm ultra fine grain <0.5 μm Nano particle <0.1 μm

So far, one goes in the production of a hard material body so that the one certain hard material component, such. B. WC, containing sintered metallurgical powder is used or processed with a certain uniform particle size distribution, so that after sintering an equally uniform particle size distribution with the desired grain size spectrum can be achieved.

However, it has been shown that it can often lead to unwanted effects in the use of carburetor carbons thus composed, namely in the pure WC / Co types to Spanverschweissungen and Kolkverschleiß, or in the P-types with additional hard materials to reductions in toughness.

The invention is based on the object, an initially described method for producing a hard material body, in particular a hard material tool component, such as. As a solid carbide (VHM) tool to create, with which it is possible to expand the field of application of the hard material body without much additional effort. Another object is to provide a sinter metallurgical powder suitable for the process according to the invention. Finally, a further object is to provide a sintered hard material body which can be produced by the method according to the invention and / or by means of the powder according to the invention and which is characterized in that its properties are better controllable.

This object is achieved with respect to the method by the method steps of claim 1, with respect to the sinter metallurgical powder by the features of claim 9 and with respect to the hard material body by the features of claim 20.

According to the invention, the powder is composed in such a way that its hard-material particles of a particular type of hard material, ie, for. As the toilet particles are present in at least two mutually different particle size distributions with multimodal distribution. In this way arises - even taking into account any grain growth that may occur during sintering - a hard material structure that in previously unachieved form the advantages of an extremely hard material such. As the HM grade K10, with those of an extremely tough material such. B. the HM grade K40, connects, so that the field of application of the hard material body producible with the method according to the invention can be substantially extended. The additional expense during production is limited to the mixing of the powder fractions.

The method according to the invention is equally applicable if, as outlined in claim 2, the two hard material powder fractions or populations of the same variety with differing particle size distributions must be mixed with the sintering agent, preferably by wet grinding, or if according to claim 3 the powder is assembled in such a way that the at least two hard material powder fractions or populations of the same variety are each present as finished alloys, and that the particle size distributions of the at least two powder fractions or populations differ from one another.

Advantageous developments of the method are the subject of the dependent claims.

If, according to claim 4 or 14, the particle size distributions of the respective Hartstoffsorte on the percentage of the powder populations or powder fractions on the total powder are tuned such that after mixing and pressing the powder at least partially, d. H. over significant volume ranges, at least in regions all hard material particles of the powder population with the largest average diameter by means of the hard material particles of at least one other powder population with a smaller average diameter can be kept spaced from each other, results in a structure whose property is no longer determined solely by a particle population , so that the inventive effect of the control of the hard material properties, reproducible achievable. The same applies to the hard material blank according to claim 14.

The same applies to the development of claim 5, according to which the particle size distributions are matched to the percentage fractions of the powder fractions of the total powder such that after mixing and compression of the powder at least partially all hard material particles that powder population with the largest average diameter in a contiguous composite of hard material Particles of at least one further powder population with a smaller average diameter are embedded, preferably embedded from each other isolated. In this case, the hard particles with the smaller average diameter can have more influence on the properties of the hard material body. The same applies to the hard material blank or the hard material body relevant developments of claims 16 and 21st

With the development of claim 5, according to which the particle size distributions on the percentage fractions of the powder fractions are matched to the total powder such that after mixing and pressing the powder, at least in regions, the space between the hard material particles of that powder population with the largest mean diameter of the hard material Particles of at least one further powder population is filled with smaller average diameter, the proportion of the powder population can be minimized with smaller average diameter.

If the powder populations each have a narrow particle size distribution in which the values for the volume-related dimension d10 and d90 differ by up to 30%, preferably by up to 20%, from the dimension D50, the control of the microstructural properties can be refined.

Experiments with WC / Co-hard materials have shown that the manufacturing process without further ado, the benefits mentioned at the outset when hard material particles such. B. WC particles, are present in two particle size distributions, wherein the average particle size D50 of a particle population in the range between 0.3 and 0.5 .mu.m and the average particle size D50 of the other particle population in the range 0.7 to 1.3 microns , ie z. B. at 0.8 or 1.2 microns, the volume ratios of the individual particle populations in wide ranges, eg. B. between 30/70 and 70/30, could.

A sinter metallurgical powder, with which the method according to the invention is executable, is the subject of claim 9. According to an alternative may - according to claim 10 - that the powder as a mixture of at least two hard powder fractions or populations with mutually different particle size distributions, ie multimodal distribution ) and the sintering agent. Another alternative is the subject of claim 11, according to which the powder consists of at least two mutually mixed hard powder fractions or populations, which are present in each case as finished alloys, and that the particle size distributions of the at least two powder fractions or populations () in the sense of multimodal distribution differ from each other.

The hard material blank according to the invention, which can be produced by deformation or compression or extrusion of a sintered metallurgical powder according to one of claims 9 to 13, optionally with the addition of binder, is characterized in that the hard material particles in the unsintered or presintered hard material blank in at least two mutually differing particle size distributions with multimodal distribution. Advantageous developments are subject matter of claims 15 to 19.

The sintered hard material body according to the invention, which can be produced from a hard material blank according to one of claims 14 to 19, is the subject of claim 20 and it is characterized by the fact that its from a hard material component, such as. B. WC structure has at least two mutually differing particle size distributions with multimodal distribution.

With regard to the developments according to claims 21 to 24, the above to the claims 5, 6 to 8 applies.

Embodiments of the invention will be explained in more detail with reference to schematic drawings. Show it:

1 a diagram in which the particle size or grain size distribution in one or a hard material powder according to the invention or hard material blank hard material body is shown;

2 to 4 schematic representations of a bevel of embodiments of a hard material blank according to the invention or hard material body; and

5 and 6 schematic flow diagrams for explaining the method according to the invention.

In the inventive method for producing a hard material body, in particular a hard material tool component, such as. As a solid carbide (VHM) tool, a hard material such. B. WC, and sintering agents such. B. Co, and / or binder-containing powder having a predetermined particle size distribution to form a blank or pressed or extruded and then sintered. 1 shows how the powder is assembled.

A first hard material powder fraction or population, which is shown by a solid line, is present with a certain particle distribution, in which the volume-related dimension D50 _{1 is,} for example, about 0.4 μm. The dimension D50 ₁ means that at this value 50% by volume of the particles are smaller and 50% by volume of the particles are larger than 0.4 μm.

In the first particle distribution shown by a solid line is still the measure D10 _{1 located} , ie the particle size, which is below 10% by weight of the particles. Finally, the dimension D90 _{1 is} shown in the first particle distribution shown by a solid line, ie the particle size that falls below 90% by weight of the particles. Preferably, the particle size distribution is narrow, ie, the measure D10 ₁ and / or the measure D90 ₁ deviates only slightly from the measure D50 ₁ , for example by a maximum of 30%, preferably by a maximum of 20%.

The broken line shows the particle size distribution of another hard material powder fraction or population of the same hard material grade, ie WC. In this particle distribution, the volume-related dimension D50 _{2 is,} for example, about 0.8 μm. The dimension D50 ₂ again means that at this value 50% by volume of the particles are smaller and 50% by volume of the particles are larger than 0.4 μm.

In the second particle distribution represented by the dashed line, the dimension D10 ₂ is again drawn, that is to say the particle size which is less than 10% by weight of the particles. Finally, the dimension D90 _{2 is} shown in the second particle distribution shown by the dashed line, that is to say the particle size which is less than 90% by weight of the particles. Preferably, this particle size distribution is narrow, ie, the measure D10 ₂ and / or the measure D90 ₂ deviates only slightly from the measure D50 ₂ , for example by a maximum of 30%, preferably by a maximum of 20%.

A dotted line indicates the particle size distribution of a further powder component which differs from the hard material component with the different particle size distributions described above. This component can be, for example, a small amount of added TiC or Ta (Nb) C component.

If the powder according to 1 is compiled so are his hard material particles of the same variety, z. As the WC particles, in at least two mutually different particle size distributions PGV1 and PGV2 with multimodal distribution.

In this case, the powder can be assembled in such a way that the at least two hard material powder fractions or populations of the same variety, ie, for. B. WC with differing particle size distributions with a sintering agent such. B. Co, preferably by wet grinding, are mixed.

However, it is equally possible to put the powder together in such a way that the at least two hard material powder fractions or populations of the same variety each as Pre-alloys are present, and that the particle size distributions of the at least two powder fractions or populations differ from each other.

The presentation of the 1 not only applies to the composition of the hard material powder. It is equally valid for a polished section of a sintered blank or for the polished section of a finished sintered hard material body, in the latter case replacing the particle size distribution with a multimodal particle size distribution with respect to the same hard material. The particle size distribution differs from the particle size distribution in that an optionally occurring during sintering grain growth is taken into account.

The proportions of the individual powder fractions in the total powder can be varied within wide limits. Accordingly, the structure of the sintered blank or of the finished sintered hard material body also changes. This is based on the 2 to 4 explained in more detail, the schematic cross-sectional images of sintered blanks or finished sintered hard material bodies show, which are prepared according to the invention.

In the figures, those powder particles or hard material grains are hatched 10 represented, which belong to the particle or grain population with the largest mean diameter D50. In contrast, those powder particles or hard material grains are unshaded 12 shown belonging to the particle or grain population with the smaller mean diameter D50. The 2 shows a variant in which the particle size distributions are adjusted to the percentage of the powder fractions of the total powder such that after mixing and pressing the powder at least partially all hard material particles 10 the powder population with the largest mean diameter D50 ₂ in a coherent composite of the hard material particles 12 the at least one further powder population with a smaller average diameter D50 _{1 are} embedded, preferably embedded in isolation from one another.

The 3 shows a variant in which the particle size distributions are matched to the percentage of powder fractions of the total powder such that after mixing and pressing the powder at least partially all hard particles 10 the powder population with the largest average diameter D50 ₂ by means of the hard material particles 12 the at least one further powder population with a smaller average diameter D50 ₁ can be kept apart from each other.

The 4 Finally, shows a variant in which the particle size distributions are adjusted to the percentage of the powder fractions of the total powder such that after mixing and pressing the powder at least partially the space between the hard particles 10 the powder population with the largest mean diameter D50 ₂ of the hard material particles 12 the at least one further powder population with a smaller average diameter D50 _{1 is} filled.

As is clear from the 1 results, the particle size distributions PGV1 and PGV2 differ significantly, they could still overlap more or less strongly. In addition, they are preferably narrow, ie the powder populations with PGV1 or PGV2 are so spotted that the values for the volume-related dimension D10 and D90 differ by a maximum of up to 30%, preferably by a maximum of up to 20%, from the dimension D50 ,

Extensive tests were carried out with WC-Co hard metal, with hard metal powder having an average particle size D50 of 400 nm, 800 nm and 1200 nm being compressed or extruded in various mixing ratios of between 30:70% by weight and 70:30 , In the sintered hard material bodies, which were processed to cutting tools, not only the microstructures of the 2 to 4 be demonstrated, but also the above-mentioned improved material properties in the tool insert.

The 5 and 6 show exemplary embodiments of the method according to the invention for producing a hard material body.

According to 5 is a first powder fraction HS-P1 of raw cemented carbide having a first particle size distribution PGV1 in a certain mixing ratio (x%: y%) with a second powder fraction HS-P2 of raw carbide of the same grade with a second particle size distribution PGV2, for example, in a ball mill 16 in which the powder components are milled together with a suitable sintering agent SM. This is followed by spray-drying to form granules in which the hard-material particles-as indicated in the diagram-are present as finished alloys having a bimodal particle size distribution. The distribution in the granules are somewhat different from those of the raw carbide, since during grinding edge rounding and certain Aufbrechvorgänge take place.

Subsequently, the granules are mixed in a mixer 18 with a plasticizer such as wax or organic polymers, and then subjected to shaping, that is either subjected to a cold isostatic pressing process or an injection molding, extrusion or Matrizenpressvorgang. Nothing changes at the multimodal or bimodal particle size distribution.

In the sintering process, which is carried out after a temperature program adapted to the hard material and the sintering agent and under a suitable atmosphere, the structure is converted, wherein z. For example, in a WC-Co cemented carbide, a eutectic mixture of Co with some WC forms that wets and crawls along the WC crystallites. In the completely degassed oven is now the shrinking process, since acts on small pores in particular a strong pressure. When a coherent melt is formed, the cooling process can begin. Finally, there is a cemented carbide structure in which the particle size distribution is still multimodal, although the distribution variables, such as mean particle diameter D50 or values for D10 or D50 of the individual particle fractions, depend on the distribution in the sintered material. Can distinguish the blank. However, the quality of distribution remains.

An alternative embodiment of the manufacturing process is in 6 Here is a first powder fraction HS-P1 of raw carbide in a ball mill 16 With the addition of a suitable sintering agent SM, a first hard metal granulate having a first particle size distribution PGV1 (D50 is about 40 nm) is produced or sighted. From a second powder fraction HS-P2 of raw carbide of the same kind is in a ball mill 16 With the addition of a suitable sintering agent SM, a second cemented carbide granulate having a second particle size distribution PGV2 (D50 is about 800 nm) is produced or sighted. The granules are in a certain mixing ratio (x%: y%) optionally with the addition of z% of a further granules of the same or another type of cemented carbide particle with a further particle size distribution, indicated by a dotted line with a D50 value of about 1500 nm is in a mixer 18 in which the granules are mixed with a plasticizer, such as wax or organic polymers. From there, the raw material is subjected to shaping, ie either a cold isostatic pressing process or an injection molding, extrusion or die pressing process, so that a blank is produced in which the hard material particles are distributed in a multi- or bi- or trimodal manner.

Even after presintering, in which the binder has been expelled, nothing changes in the particle size distribution.

After the sintering process, which - as with reference to the 5 If the grain size distribution is still multimodal, the distribution variables, such as average particle diameter D50 or values for D10 or D50 of the individual particle fractions, depend on the distribution due to grain growth phenomena that may exist in the sintered blank can differ. However, the quality of distribution remains.

Of course, deviations from the described embodiments are possible without departing from the spirit of the invention. Thus, of course, more than two hard material particle fractions of the same hard material grade and different particle size distribution can be used. Also, the inventive method is in no way limited to certain hard materials.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• "HARDMETAL FOR THE PRACTITIONER"; Dr.-Ing. Wolfgang Schedler; VDI-Verlag GmbH, Dusseldorf, 1988 [0002]
• ISO 513 [0003]

Claims (24)

Method for producing a hard material body, in particular a hard material tool component, such as. B. a solid carbide (VHM) tool in which a hard material such. B. WC, and sintering agents such. B. Co, and / or binder-containing powder having a predetermined particle size distribution is formed into a blank or pressed or extruded and then sintered, characterized in that the powder is composed such that its hard material particles (HS-P1, HS-P2 ) are present in at least two mutually different particle size distributions (PGV1, PGV2) with multimodal distribution. A method according to claim 1, characterized in that the powder is assembled in such a way that at least two hard powder fractions or populations (HS-P1, HS-P2) of the same kind with mutually differing particle size distributions with the sintering agent (SM) preferably by Wet grinding, mixed, become. A method according to claim 1, characterized in that the powder is assembled in such a way that the at least two hard material powder fractions or populations (granules 1, granules 2) of the same sort are each present as finished alloys, and that the particle size distributions of at least two Powder fractions or populations (granules 1, granules 2) differ from each other. Method according to one of claims 1 to 3, characterized in that the particle size distributions are adjusted to the percentage of the powder fractions of the total powder such that after mixing and pressing of the powder at least partially all hard material particles ( 10 ) of the powder population with the largest mean diameter (D50 ₁ ) by means of the hard material particles ( 12 ) of at least one further powder population with a smaller average diameter (D50 ₂ ) can be kept spaced from each other. Method according to one of claims 1 to 3, characterized in that the particle size distributions on the percentage proportions () of the powder fractions are matched to the total powder such that after mixing and pressing the powder at least partially all hard material particles ( 10 ) that powder population with the largest mean diameter (D50 ₁ ) in a coherent composite of the hard material particles ( 12 ) of at least one further powder population with a smaller average diameter (D50 ₂ ) are embedded, preferably embedded in isolation from each other. Method according to one of claims 1 to 3, characterized in that the particle size distributions on the percentage proportions () of the powder fractions are matched to the total powder such that after mixing and pressing the powder at least partially the space between the hard particles ( 10 ) of the powder population with the largest mean diameter (D50 ₁ ) of the hard material particles ( 12 ) of at least one further powder population with a smaller average diameter (D50 ₂ ) is filled. Method according to one of claims 1 to 6, characterized in that the powder populations each have a narrow particle size distribution (PGV1, PGV2), wherein the values for the volume-related measure D10 and D90 by up to 30%, preferably by to differ by 20% from dimension D50. Method according to one of claims 1 to 7, characterized in that hard-material particles are present in two particle size distributions, wherein the mean particle size (D50 ₁ ) of a particle population in the range 0.3 to 0.5 microns and the average particle size (D50 ₂ ) of the other particle population is in the range between 0.8 and 1.3 microns. Sinter metallurgical powder for the production of a hard material body, in particular a hard material tool component, such as. B. a solid carbide (VHM) tool, in particular for use in the method according to one of claims 1 to 8, characterized in that it is composed in such a way that its hard particles ( 10 . 12 ) are present in at least two mutually different particle size distributions with multimodal distribution. Powder according to claim 9, characterized in that the powder is present as a mixture of at least two hard powder fractions or populations (HS-P1, HS-P2) of the same variety with differing particle size distributions and the sintering agent (SM). Powder according to claim 9, characterized in that it consists of at least two mixed hard powder fractions or populations of the same variety, each of which is present as finished alloys (granules 1, granules 2), and that the particle size distributions of at least two powder fractions or -populations (granules 1, granules 2) differ from each other. Powder according to one of claims 9 to 11, characterized in that the powder populations (HS-P1, HS-P2, granules 1, granules 2) each have a narrow particle size distribution, wherein the values for the volume-related measure D10 and D90 by up to 30%, preferably by up to 20% of the measure D50 differ. Powder according to one of claims 9 to 12, characterized in that hard-material particles are present in two particle size distributions, wherein the average particle size (D50 ₁ ) of a particle population (HS-P1, granules 1) in the range between 0.3 and 0.5 μm and the average particle size (D50 ₂ ) of the other particle population (HS-P2, granules 2) is in the range between 0.8 and 1.3 μm. Hard material blank produced by shaping or pressing or extrusion of a sintered metallurgical powder according to one of claims 9 to 13, optionally with the addition of binder, characterized in that the hard material particles ( 10 . 12 ) of the same kind in the unsintered or presintered hard material blank in at least two mutually different particle size distributions (PGV1, PGV2) with multimodal distribution. Hard material blank according to claim 14, that at least partially all hard material particles ( 10 ) of the hard material particle population with the largest mean diameter (D50 ₁ ) by means of the hard material particles ( 12 ) of the at least one further powder population with a smaller average diameter (D50 ₂ ) are kept spaced from each other. Hard material blank according to claim 14, characterized in that at least partially all hard material particles ( 10 ) of the largest average particle size (D50 ₁ ) of the hard material particle population into a coherent composite of the hard material particles ( 12 ) of at least one further hard material particle population with a smaller average diameter (D50 ₂ ) are embedded, preferably embedded in isolation from each other. Hard material blank according to claim 14, characterized in that at least in regions the space between the hard material particles ( 10 ) of the hard material particle population with the largest mean diameter (D50 ₁ ) of the hard material particles ( 12 ) the at least one further hard material particle population with smaller mean diameter (D50 ₂ ) is filled. Hard material blank according to one of claims 14 to 17, characterized in that the hard material particle populations (HS-P1, HS-P2, granules 1, granules 2) each have a narrow particle size distribution, in which the values for the the volume related dimension D10 and D90 by up to 30%, preferably differ by up to 20% of the dimension D50. Hard material blank according to one of claims 14 to 18, characterized in that hard-material particles are present in two particle size distributions, wherein the average particle size (D50 ₁ ) of a particle population (HS-P1, granules 1) in the range between 0.3 and 0 , 5 microns and the average particle size (D50 ₂ ) of the other particle population (HS-P2, granules 2) in the range between 0.8 and 1.3 microns. Sintered hard material body, producible from a hard material blank according to one of claims 14 to 19, characterized in that the structure has at least two mutually differing grain size distributions with multimodal distribution with respect to a hard material. Hard material body according to claim 20, that at least partially all hard material grains ( 10 ) of the hard material grain of the respective hard material type with the largest average diameter (D50 ₁ ) in a coherent composite of the hard material grains ( 12 ) which are embedded in at least one further smaller-mean-diameter (D50 ₂ ) grain / grain population, preferably embedded in isolation from one another. Hard material body according to claim 20, that at least partially the space between the hard-material grains ( 10 ) of the hard material grain of the respective hard material grain of the respective hard material type with the largest average diameter (D50 ₁ ) of the hard material grains ( 12 ) is filled at least one further smaller grain diameter (D50 ₂ ) grain selection of urea. Hard material body according to one of claims 20 to 22, characterized in that the urea-grain populations ( 10 . 12 ) of the respective type of hard material each have a narrow particle size distribution, in which the values for the area-related dimension D10 and D90 differ by up to 30%, preferably by up to 20%, from the dimension D50. Hard material body according to one of claims 20 to 23, characterized in that the microstructure has two grain size distributions with respect to a hard material, the mean grain size (D50 ₁ ) of the one grain of a cerium grain in the range between 0.3 and 0.5 microns and the average grain size (D50 ₂ ) of the other urea-grain population ranges between 0.8 and 1.3 μm.

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