EP1992451A1 - High grain concentration grinding tool - Google Patents

Abstract

Grinding tool with a working part and a holder, wherein the working part is formed from a distributed in the volume of the working abrasive grain in a metal bound form, characterized in that the percentage of the abrasive grain over 50% of the volume of the working part and the remaining volume with a binder is filled, that the abrasive grain is composed of natural and artificial diamond, or corundum, or silicon carbide or boron carbide, that the abrasive grain size is 1 to 2000 microns, that metal or alloys of different metals based on copper, nickel, as a binder Manganese, phosphorus, zinc and germanium is used, that the abrasive grain is coated with metal at least 1 micron thick, wherein the coating is bonded to the binder by means of a diffusion layer and the melting temperature of the coating metal is not lower than the melting temperature of the binder alls or the alloy of various binding metals.

Description

The device relates to a grinding tool according to the preamble of claim 1.

The tool made in this way can be used for cutting, drilling and grinding various materials and surfaces.

The grinding tool consists of a working part and a holder or an opening for inserting the holder, which is mounted in the central region. The working part is made of the distributed on its circumference abrasive grain in metallically bonded form (usually diamond abrasive grain). The grinding tools according to this device are all drills, cutters, grinding wheels and all other tools in which the working part has abrasive particles of the abrasive assigned. The abrasives used to make the tool are solid particles (grain particles) various compositions: diamonds (natural and artificial), electrocorundum, corundum, silicon carbide, boron carbide and other substances known in the grinding industry with a particle size of 1 to 2000 μM. Abrasive metal tools are known (copyright of the USSR No. 1703718 , Class C 25 D 5/02, 1989 and copyright of the USSR No. 1705052 , Class B 24 D 3/34, 1988.), which are produced by the electrochemical process or by sintering, including hot pressing of the powder starting materials in various protective media. The technologies used for this purpose reduce the stability of the main parameters in mass production because of many switching factors. This leads, in a number of cases, to a reduction in the quality of the tools produced. The abrasive grain of these tools is not precoated with metal. This metal would penetrate all superficial defects and pores of the abrasive grain and form a transition layer for the bonding metal. It also lacks the diffusion layer between the binder and the coating metal. All this reduces the retention of the grain in the working part and thus also the Abschleiffestigkeit.

Known is a grinding tool (copyright of the USSR No. 2042499 , Class B 24 D 17/00, 1995), which contains a holder. The holder is firmly connected to the working part. The working part is made of a mixture of diamond grain and filler particles with a metallic binder. The disadvantage of this tool is the loss of grinding properties when crumbling the diamond grain from the surface of the working part. In addition, the Abschleiffestigkeit and the performance of the tool decreases when cavities and caverns are formed in the tool body by the crumbling. The disadvantages of this method are also that the abrasive grain is premixed and compacted with the metallic binder. This excludes a maximum dense filling of the mold with the grain, since during pressing the metallic binder takes up a part of the space from the outset. Thus, this tool has lower abrasion resistance and performance than the tool of the invention. The abrasive grain is not precoated with metal. This metal would penetrate all superficial defects and pores of the abrasive grain and form a transition layer for the bonding metal. It also lacks the diffusion layer between the binder and the coating metal. All this reduces the retention of the abrasive grain in the working part and thus also the wear resistance. Lowering the concentration by incorporating powder compounding and compacting reduces the performance of the tool.

Known is the patent Russian Federation no. 240914 for a grinding tool containing interconnected rough and finish grinding wheels. The grinding wheels consist of the abrasive grain and the binder. New is the fact that in addition to the binder hollow spherical particles are added in an amount of 40-50% of the volume occupied by the particles of the tool. The abrasive grain in the compact state forms a dense packing and occupies 50-65% and the organic binder 35-50% of the tool volume. The size of the abrasive grain in the roughing wheel is 1000-1600 μm and the size of the hollow spherical particles 50-80 μm, in the finish grinding wheel 400-500 μm and 20-25 μm, respectively. The disadvantage of this tool is the fact that the organic binder does not have high strength, abrasion resistance and heat resistance. This reduces the abrasion resistance of the tool. The abrasive grain has no diffusion bonding with the binder. It is mechanically fixed in the binder. In addition, the spherical particles introduced into the organic binder are microdefects. These microdefects additionally weaken the bond strength of the binder. The invention greatly limits the scope of use. It requires the use of abrasive particles with a limited size range of 1000 to 1600 microns. It is obvious that for fine boring, or for example for finish grinding, such granularity is not applicable. It is impossible to make thin-walled grinding drills and a tool with sharp and fine edges from such a mixture. Also known is a grinding tool (a drill) according to the patent of the Russian Federation no. 2092302 , This tool contains a working part of a mixture of the diamond grain firmly bonded by means of metallic binder and of the particles of the filling compound which are comparable to the grain and distributed by volume. It contains a holder, which is mounted in the middle area of the working part. The holder has therein recesses for the accommodation of the diamond grain and / or the particles of the filling material. The bonding of the diamond grain to the metallic binder is carried out as a metallic film on the grain surface. The outer surface of the working part is uneven.

This tool is made from the abrasive particles and the metallic binder which occupies part of the tool volume. This reduces the abrasion resistance and performance of the tool. The abrasive grain is not precoated with metal. The metal would penetrate all superficial defects and pores of the abrasive grain and form a transition layer for the metal of the binder. It also lacks the diffusion layer between the binder and the metal coating. All this reduces the gripping of the grain in the tool and consequently also the abrasion resistance. The disadvantage of this tool and all known tools is also that the volume of the abrasive grain in metallically bound form at most 50% of the working part volume (see Fig. 1 ). In Fig. 1 1 denotes the abrasive grain of larger fraction, 2 the binding material in metallically bound form and 3 the abrasive grain of smaller fraction. Therefore, all of the abovementioned and known abrasive tools with the metallic binder have reduced performance and abrasion resistance. A greater density of the abrasive in the working part ensures greater abrasion resistance of the tool. The increase in concentration by 20% leads z. B. to increase the Abschleiffestigkeit to 20%.

The closest to the invention grinding tool is the patent of the Russian Federation no. 2113531 refer to. In this patent, the sintered diamond material contains 50-99.0% by volume of diamonds and the remainder is the binder phase. The diamond material has excellent resistance to breakage, corrosion resistance, heat resistance as well as Abschleiffestigkeit and can be sintered under relatively low pressure and low temperature. The binder phase is formed by a single or a mixed phase of the compound or of the mixture of at least one elemental substance of the Periodic Table with the phosphorus compound or from the above-described compound or the mixture with the oxide of the elemental material. The elemental material is selected from Group IIIB, IVA and VIB rare earth elements, iron group metals, Mn, V, alkali metals and alkaline earth metals. Disadvantage of this type and the type of binding of the abrasive is the fact that the binder according to the Russian Federation no. 2113531 fracture and cracking (as in Fig. 2 shown) is exposed because the abrasive grain is not completely and not uniformly coated with the binder. This results in abrasion / wear of the abrasive coating in the individual parts of the tool and in reducing the abrasion resistance of the tool as compared to the abrasive tool of the invention. The disadvantages of the type of binding of the abrasive according to the Russian Federation Patent No. 2113531 belongs insufficiently sure holding of a grain. The main requirement for increasing the abrasion resistance of each tool is a secure gripping of the grain. In the conventional tool (hot pressing), the grain is preferably mechanically held in the binder. According to different estimates, it provides 5 to 10% of its durability.

It is an object of the invention to increase the performance and the abrasion resistance of the grinding tool in metallically bonded form and to expand the design possibilities.

This object is solved by the features of claim 1.

• höhere Haltbarkeit jedes einzelnen Kornteilchens, was die Erhöhung der gesamten Werkzeughaltbarkeit zur Folge hat;
• höhere Kantenhaltbarkeit, was ermöglicht, dass das Werkzeug mit sehr scharfen Arbeitskanten bis hin zur Dicke eines Schleifkornteilchens verwendet werden kann;
• längere Aufrechterhaltung der vorgegebenen Ausgangsform des Werkzeugs.

The layer thickness of the coating should be more than 1 μm, otherwise fractures may occur on the surface. This would be to partially detect the grain and to worsen the grain attachment in the tool (as in Fig. 2 shown) to lead. The coating is applied to the abrasive grain (1) at high temperature (s. Fig. 4 ) that the metal (5) maximally penetrates all the pores (3) and cracks (4) on the surface of the abrasive grain and forms a "root system" that holds the metallic bond on the surface. The metal coating should be so penetrating that a layer adhesion of at least 5 MPa is ensured. The high adhesion ensures improved retention of the abrasive grain within the tool. Thereafter, the thus coated grain is poured into a mold. The mold is made of a material whose melting temperature (fracture temperature) should be higher than the melting temperature of the binder metal (2). The binder metal (2) is poured in a molten state into the mold. Here, the melting temperature of the metal (2) should be lower than the melting temperature of the coating metal (5) of the grain, in order to avoid the melting of the metal (2) and the detection of the abrasive grain surface. The binder may be metal or an alloy of any metals having a melting temperature above 700 ° C. Depending on the type of metal used, the melting temperature of the bond and thus its hardness, abrasion resistance and heat resistance depend. In order to produce a tool with the required destruction resistance, different alloys with different physical-mechanical properties can be used. A different destruction resistance allows an optimal self-sharpening of the tool during its operation. The methods differ by the melting temperature. The binder is a metal or the alloy of any metals having a melting temperature above 700 ° C. As the binder, for example, an alloy based on copper, nickel, phosphorus having a melting temperature of 700 to 800 ° C can be used. As an example, the alloy (No. 1) can be cited. It consists of 80% copper, 17% nickel and 3% phosphorus. This alloy has a melting temperature of 780 ° C. The diamond grinding tool made on this basis has been used to grind cobalt-chromium alloy dentures. Due to a low melting temperature and a relatively low strength of the alloy, the grinding spindle carriers have optimum performance. They had a high one Metal picking speed, and self-sharpening was done at low loads in manual mode. The binder may be a copper, nickel and zinc based metal alloy having a melting temperature of 800 to 900 ° C. As an example, the alloy (No.2) can be cited. It consists of 55% copper, 25% nickel and 20% zinc. The melting temperature is 865 ° C. This alloy is used to make diamond grinding spindle carriers to machine ceramic tooth crowns. In manual operation of the diamond grinding tool, the component composition ensures maximum effectiveness and speed of finish grinding the surface of the ceramic tooth crowns. This alloy ensures a high bonding hardness of the tool and at the same time a quick self-sharpening. This makes it possible to increase the grinding speed by 1.5 times compared to the previous example. The binder may be a copper, nickel and germanium based metal alloy or a copper, nickel, manganese and tin based alloy having a melting temperature of 900 to 1000 ° C. As an example, the alloy (No. 3) can be cited. It consists of 80% copper, 5% germanium, 1% nickel, 13.5% manganese and 0.5% tin. The melting temperature of the alloy is 1030 ° C. This alloy was used to make a roller tool for glass edging. Thanks to a hard composition and higher temperature, this alloy ensures a tight bond of the diamond grain in the tool, which processes the glass edges. The use of the foregoing alloys in this case has low strength and rapid wear. Thus, the tool based on these alloys is not effective for this operation. The tool of the first alloy worked only 60 meters of the edge with a glass thickness of 5 mm. The second alloy tool worked 125 meters. The third alloy tool worked 600 meters. The binder may be a copper, nickel and manganese based metal alloy having a melting temperature of 1000 to 1100 ° C. As an example, the alloy (# 4) based on 58% copper, 25% nickel and 17% manganese can be cited. The melting temperature is 1095 ° C. This alloy has a high durability and heat resistance. The result manufactured thin-walled tubular drill for deep drilling of granite, marble and concrete are extremely efficient and durable. The diamond drill bit with a diameter of 50 mm and a diameter of 6 mm drills 300 - 500 meters of granite until complete drill wear. The drill bits of alloys Nos. 1 - 3 could drill only 10-30 meters under similar conditions. After that, the self-destruction took place. It is explained by the fact that the working conditions of the drills in a blind hole are very hard. In such holes, the load on the binding metal exceeds its thermal and fatigue strength limit due to poor coolant supply and sludge removal. This leads to the complete destruction of the tool. The melting temperature of the metal coating is always higher than the melting temperature of the binder metal (or the alloy). In particular, the metal or metal alloy used in the coating has a melting temperature in excess of 1400 ° C. The type of metal or alloy used for the coating will depend on the melting temperature and, accordingly, other performance characteristics of the coating. In particular, nickel or nickel with a small amount of admixture can be used as the coating. In this case, the melting temperature of the coating is 1400 to 1600 ° C. As the coating, pure chromium or chromium having a small amount of blending can be used. In this case, the melting temperature of the coating is 1600 to 1650 ° C. As the coating, pure molybdenum or molybdenum having a small amount of blending can be used. In this case, the melting temperature of the coating is 1600 to 2400 ° C. As the coating, pure tungsten or tungsten having a small amount of blending can be used. In this case, the melting temperature of the coating is 2400 to 3500 ° C. The selection of a specific metal for the coating depends on the tool requirements. The higher the melting temperature of the coating, the higher the melting temperature for the binding metal (alloy) can be specified. From the given type of abrasive heat resistance and bond hardness of the tool depend. The higher the melting temperature of the binder metal, the higher the bond hardness and Heat resistance of the tool can be obtained. A higher bond strength of the working part ensures a higher abrasion resistance of the tool. Not all cases result in a higher bond hardness as a positive result. The use of the grinding tool, for example as a drilling tool, requires a larger space between the individual granules for removing the sludge (the worn finely dispersed material). But with the high hardness of the bonding material, this can not be achieved since the wear of the bond between the individual particles of grain requires a great pressure which is not always permissible when drilling brittle material. In this case, the wear on the wear is slow and the space for sludge removal is insufficient. The mud accumulates in the cutting area. This area provides an annular sac cavity and thus prevents contact of the abrasive grain with the surface to be processed. This allows the drilling to be stopped and converted into a slip in the mud layer. If a proper hardness is chosen for the bond, which ensures the optimum wear of the metal in the space between the grain particles, the mud is fed to the cavities formed and does not prevent drilling. The pouring of the binder metal in the melt state ensures better adhesion with the surface of the abrasive grain particles. First, in the molten state, the metal better penetrates into the surface structure of the abrasive grain, and second, it forms a stronger diffusion layer with the coating metal of the grain (5). The packaging of the grain into the mold is therefore carried out (s. Fig. 3 ) such that each grain particle has direct contact with a maximum number of other grain particles. In any case, the contact number of each grain particle should have more than 2. This is achieved by a higher packing density of the grain (higher concentration). In this case, the thickness of the contact zone between the grain particles is equal to the thickness of two layers of the coating metal (5). Preferred is a variant in which within the grinding tool each grain particle has contact with at least four other grain particles and the thickness of the contact zone does not exceed the thickness of two layers of the coating metal. Also preferred is a variant in which the grain particles of the abrasive average more than eight Have contacts with adjacent grain particles. For certain types of work of the tool, a preferred variant is the packaging of mainly symmetrical abrasive grain particles having a spherical shape. In this case, the contact number becomes 12 (3 grain particles have contact with each grain particle from below, with 3 grain particles from the top and 6 grain particles from both sides). Such a packaging of the abrasive grain ensures a maximum contact number of the grain particles with each other and gives the structure of the tool uniformity and strength. The density of packaging is achieved by a special procedure, for example by vibration of the mold with the freely poured grain particles. In this case, a packing possibility for the abrasive grain in elongated form. In another case, the grain particles have a needle shape, which ensures a higher grinding ability. This shape makes it possible to not only create the densest packing of the grain in the mold, but also to spatially align the grain optimally for each specific type of tool. The abrasive grain, which has an elongated shape, is oriented within the working part of the tool in a certain way. The grain within the working part of the tool can be densified to the maximum, and the average distance (with a spread of at most 25%) between the grain particles exactly matches the average diameter of the grain fraction of the main fraction. A higher concentration of the abrasive grain ensures a higher performance of the tool compared to the tool with a lower concentration under otherwise identical circumstances. In addition, the durability of the tool increases due to the larger number of abrasive grains. Moreover, the grain particles are better retained by a firm adhesion of the coating metal to the abrasive grain and by the diffusion layer between this coating metal 5 and the bonding metal 2 within the tool body. This ensures the following positive properties:

• higher durability of each individual particle, resulting in an increase in overall tool holdability;
• higher edge durability, which allows the tool to be used with very sharp working edges down to the thickness of an abrasive particle;
• longer maintenance of the given initial shape of the tool.

The surface of the tool may have regular (for example, spiral) and irregular elevations of any height and configuration. These surveys ensure better removal of worn material, more efficient machining and better cooling conditions. In this case, the width of the elevations in the direction of the working surface to the size of an abrasive particle, which is used for the production of the tool, decrease. This makes it possible to create cutting tools from an abrasive grain. The firm diffuse adhesion of the grain in the tips of the elevations of the working part ensures a long-term work of the grain and prevents its rapid crumbling. One of the embodiments of the tool provides that the tips of all abrasive grain particles are arranged on the surface at the same distance from the axis of rotation. This arrangement ensures minimal vibration during the work of the tool, uniform participation of all grain particles in the work and a regular decrease in the surface to be machined (without individual scratches and eruptions). The rotating grinding tool can be performed with openings in the working part. The openings may be both perpendicular and at different angles with respect to the axis of rotation. A cylindrical cutter can, for. B. by means of openings in the direction of rotation and be designed by other openings in the opposite direction. This makes it possible to simultaneously discharge the mud through the first openings and to supply the coolant through the other openings. The rotating grinding tool may have a multi-layered (in height) construction. The construction consists of several abrasive layers different in composition. Each fulfills its own processing. In between, there is no margin or interlayer because they are made in one mold at a time. For example, a drill has the grain size of 200 μm and a Countersink one of 125 microns. The manufacturing method consists in first pouring into the mold a precisely measured amount of the 200 μm grain and then casting a special composition. This composition forms a thin interlayer which prevents the layers from mixing during skimming and vibratory compaction of the second layer. The cast intermediate layer forms a fine film which prevents mixing of the lower grain layer with the upper layer. In the course of heating the mold before sintering, this intermediate layer evaporates. The grinding tool can have any required height of the fine intermediate layer or the wall, since the grain is first heaped up freely without pressing. The pressing is always accompanied by a bow effect. This circumstance limits the ability to manufacture thin walls of high height. The thickness of the layer or wall (h) may have a diameter of 3 grain particles (and more) and the height for the required design size. This ability to make the volumetrically filled, fine walled abrasive tool (less than three diameters of grain, h = 3d, d is the main grain's abrasive grain diameter), ensures abrasive tool savings for a precision sized peripheral cutter. For a long drill with relatively fine walls energy is saved during drilling (thinner cut). Fine and brittle boards can be drilled without being crushed. The height L (or / and the length) of the working part of the tool is determined exactly according to the formula L = k · h, in which the coefficient k can be varied from 5 to 500. If a tool with elevations on the work surface (discs, thin-walled drills) is needed, the thickness should be chosen according to the formula h = 3d with d = diameter of the abrasive grain (with the coating) of the main fraction of the tool's work piece to clog the working surface avoid. Peripheral discs can be used to cut minimal thickness and great depth without breakouts and with a clean surface. The lack of breakouts and the clean surface are ensured by regular packing of the grain and equal spacing of its tips from the disc lifting level. This edge shape (about 3 diameter of the abrasive grain particle) prevents clogging of the surface, since the lateral Grain particles are torn off and the edge wins a pointed (to the thickness of a Kornteilchens) form. If a metallic and non-metallic support (eg, composite or ceramic) is attached to the working part, the support surface has regular and non-regular protrusions and depressions of any dimensions and configurations and may be used as a closure fixture (eg dovetail (e.g. Fig. 5 ) to be appropriate.

The protrusions and depressions provide a larger contact surface and the closure attachment a higher mechanical and diffuse adhesion between the working part and the holder. In this case, the surface of the holder can be performed with the predetermined unevenness. The size of the unevenness is comparable to the size of the grain particles (slightly larger). This firstly ensures the enlargement of the contact surface and secondly additionally prevents the detachment of the working part from the holder in the course of the rotation, since the grain particles, which engage in the recesses, create a mechanical breakdown resistance. In this case, a diffusion layer between the bonding metal and the support material is formed in the course of tool production. The layer formation is ensured by the selection of suitable substances and the procedure of production. The abrasive grain with the above type of coating is provided by the applicant. The grain appearance with different coating types is in Fig. 6 in which the coated abrasive grain 8 and the uncoated abrasive grain 1 (diamond in this case) are designated.

Another embodiment of the abrasive grain coating is used in the case where the abrasive grain surface has no cracks, pores, and defects. In this case, a special technology for metal coating is used. In this technology, a diffusion layer is formed in the contact area of the metal with the abrasive grain surface, which ensures a firm adhesion through physicochemical bonds.

A further variant of the grinding tool provides that the binding metal fills all defects of the grain coated with the metal in such a way that a mechanical adherence of the covering layer to the abrasive grain is ensured. The working surface of the tool may have various recesses and bumps which serve to better supply the coolant (including air) to the machining area and remove the worn material therefrom. In this case, the elevations on the tool surface can have a shape which narrows after each circumferential line in the direction of the working surface and ends with a sharp edge. The edge thickness does not exceed 3 times the diameter of the abrasive grain of the main fraction forming the working part of the tool. All of the designs and implementations of the above-described tools, which have the specified density of the abrasive in the working part volume of the tool and a diffusion layer in the abrasive grain coating, are characterized by higher abrasion resistance and high bonding hardness which outperforms the performance of all known metal bond abrasive tools , characterized.

Claims (21)

Grinding tool with a working part and a holder, wherein the working part is formed from a distributed in the volume of the working part abrasive grain in a metal-bound form,
characterized,
that the percentage of abrasive grain (1) about 50% of the volume of the working part (6) is and the remaining volume with a binder (2) is filled,
that the abrasive grain (1) is composed of natural and artificial diamond or electrocorundum, or corundum, or silicon carbide or boron carbide,
that the abrasive grain size is 1 to 2000 μm,
in that metal or alloys of different metals based on copper, nickel, manganese, phosphorus, tin and germanium are used as binder (2),
that the abrasive grain (1) is at least 1 micron is coated thick with metal, the coating (8) with the binder (2) is connected by means of a diffusion layer and the melting temperature of the coating metal (5) is not lower than the melting temperature of the binder metal (2 ) or the alloy of various binder metals. Grinding tool according to claim 1,
characterized,
that the melting temperature of the binder metal (2) is in the range of 700 to 2400 ° C. Grinding tool according to claim 1,
characterized, that the metal coating (5) has a melting temperature of 1400-3500 ° C. Grinding tool according to claim 1,
characterized,
that each grit particles of the abrasive grain (1) within the grinding tool contact with at least four other grain particles and has
that the thickness of the contact zone does not exceed two layers of the coating metal (5). Grinding tool according to claim 1 to 4,
characterized,
that the abrasive grain (1) in the working part (6) of the tool is maximally compressed and the average distance between the individual grain particles of the main fraction is equal to the average diameter of the grain of the main fraction. Grinding tool according to claim 1 to 4,
characterized,
that the tips of all the abrasive grain particles (1) are arranged on the surface at the same distance from the rotational axis. Grinding tool according to claim 1,
characterized,
that the abrasive grain particles (1) have an average of eight adjacent grain particles contact. Grinding tool according to claim 1,
characterized,
that mainly symmetrical abrasive grain (1) is used and the abrasive grain (1) has a spherical shape and the number of contacts between the adjacent contact particles is 12 on average. Grinding tool according to claim 1 to 4,
characterized,
that the abrasive grain (1) has an elongated shape and
in that the abrasive grains (1) in the working part (6) of the tool are aligned in one direction. Grinding tool according to claim 1 to 4,
characterized,
in that the abrasive grain (1) is arranged in layers in the working part (6), each layer having its own grain size and type of abrasive. Grinding tool according to claim 1 to 4,
characterized,
that the metal coating (5) in all the pores (3), cracks (4) and defects of the surface of the abrasive grain (1) and adhering the coating (8) on the abrasive grain mechanically. Grinding tool according to claim 1 to 4,
characterized,
that the adhesion of the coating on the abrasive grain (1) is at least 5 MPa. Grinding tool according to claim 1 to 4,
characterized,
in that the working part (6) is connected to the holder (7) by the diffusion layer. Grinding tool according to claim 1 to 4,
characterized,
in that the holder (7) and the diffusion layer have recesses and elevations which increase the connection area and ensure the connection to the working part (6). Grinding tool according to claim 1 to 4,
characterized,
in that the depressions and the elevations of the holder (7) and of the diffusion layer form the shape of a closure. Grinding tool according to claim 1 to 4,
characterized,
in that the surface of the holder (7) has an unevenness which is comparable to the grain size of the abrasive grain (1). Grinding tool according to claim 1 to 4,
characterized,
that the surface of the working part (6) has depressions and projections, the supply of coolant, including air, ensure the work area and discharge of the worn material therefrom. Grinding tool according to claim 1 to 4,
characterized,
that the elevations on the surface of the working part (6) have a narrowing shape, wherein the elevation on the surface narrows after each circumferential line in the direction of the working surface and ends with a sharp edge, and
that the thickness of the edge exceeds the diameter of the abrasive grain (1) of the main fraction, the main fraction forms the working part (6) of the tool. Grinding tool according to claim 1 to 4,
characterized,
in that the working part (6) of the tool has openings through which coolant is supplied to the processing area and the worn out material is removed therefrom. Grinding tool according to claim 1 to 4,
characterized,
that the working part (6) of the tool has grooves or openings, wherein a part of the grooves or openings is inclined to the rotation axis and ensures the removal of the worn material, while the other part of the grooves or openings in the opposite direction is inclined and the Supply of coolant ensured. Grinding tool according to claim 1 to 4,
characterized,
that the working part (6) of the tool has a thickness h, where h = 3 and d represents the diameter of the abrasive grain (1) (with the coating) of the main fraction of the working part (6) of the tool and
that the height (and / or length) L of the working part (6) L = k * h is determined according to the formula and k = 5: 500th

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