SE1150720A1 - A grinding tool for machining brittle materials and a process for making a grinding tool - Google Patents

Abstract

19 SUMMARY The invention relates to a grinding tool 1 for machining spray material. The abrasive tool 1 has a core 2 and an abrasive edge 4. The abrasive edge 4 comprises abrasive particles 5 embedded in a matrix 6. The matrix 6 comprises a metallic binder and possibly also a polymeric binder. The metallic binder comprises silicon nitride in an amount of 0.02 - 5.0% by volume of the metallic binder. The invention also relates to a method for manufacturing the grinding tool. In the process, abrasive particles are mixed with metal powder and silicon nitride and the mixture is sintered. Polymer powder can also be added for sintering.

Description

FIELD OF THE INVENTION The invention relates to a grinding tool, in particular a grinding tool for grinding hard and / or sprayed materials such as tungsten carbide. The grinding tool can in particular be a grinding wheel. The invention also relates to a method for manufacturing such a grinding tool.

BACKGROUND OF THE INVENTION Grinding tools such as grinding wheels are used for machining spray material. One area where Adana grinding tools are used is the machining of such tools that are made of cemented carbide (tungsten carbide). For example, grinding tools can be used in machining operations in which drills or feed tools are formed by grinding. If the workpiece to be formed is made of a hard material such as tungsten carbide, the abrasive tool must have abrasive particles of a very hard material. In practice, this normally meant that the abrasive particles were diamond particles or grains of cubic boron nitride. Diamonds or grains of cubic boron nitride for this purpose are commercially available and can be considered as standard components. Diamonds for this purpose can typically have an average particle size of 50 .mu.m (the size of the particles varies, of course) and have a number of sharp edges which can cut into hard materials such as tungsten carbide. A known type of grinding tool for this purpose is a grinding wheel with a core which may be made of, for example, a metallic material such as steel or aluminum. The comb may also be made of a non-metallic material such as a polymeric material. The cam may be formed as a disc which may be mounted on a tool spindle for rotation about the axis of the disc-shaped metal core. An abrasive edge surrounds the karnan and is connected to the karnan. The abrasive edge may comprise abrasive particles embedded in a matrix with one or more adhesives. The material used in the abrasive edge is usually more expensive than the material in the karnan. Of that shell, the abrasive edge has a smaller extent in the radial direction than the cornea (i.e. the abrasive edge is normally a smaller part of the grinding wheel because it is more expensive).

During grinding, the abrasive edge gradually tears down until it is consumed and the grinding wheel can no longer be used.

Kneading adhesives for abrasive edges on grinding wheels include polymeric adhesives such as, for example, bakelite. Alternatively, the binder may be a ceramic binder. It is also advisable to use metallic binders, in particular bronze binders made by sintering. In such sintering operations, metal powders containing copper and tin are sintered together with abrasive particles such as diamond particles or grains of cubic bomitride. Sometimes silver can be added so that the bronze contains copper (Cu), tin (Sn) and silver (Ag). In the past, practical experience has shown that Cu / Sn / Ag alloys act as binders for abrasives and that such binders act as choices during grinding. Although the exact reason for this has not been fully understood, the inventors believe that improved heat conduction due to the addition of silver may explain why bronze alloys containing silver may act as binders for abrasives. However, since silver is expensive, other bronze alloys can be used to reduce the cost and the present invention is also applicable to bronze alloys without silver.

Other known bronze compositions for this purpose include copper / tin / cobalt (Cu / Sn / Co) and copper / tin / nickel (Cu / Sn / Ni). It has also been suggested that bronze compositions for this purpose may contain copper / tin / titanium (Cu / Sn / Ti).

A further edge system contains hybrids of polymeric and metallic binders in which metal powders are sintered together with polymeric material so that a matrix is formed in which the polymeric binder and the metallic binder (typically a bronze alloy described above) are closely intertwined at the microscopic level. In such hybrids, each of the metallic binder and the polymeric binder form a network and the respective networks of the binders merge into each other. Such a hybrid matrix comprising both a metallic binder and a polymeric binder is described in, for example, U.S. Pat. 6063148.

In addition to metallic and polymeric binders, such hybrids normally contain one or more fillers. Such a filler material may be graphite used for its lubricating properties.

The abrasive particles can have different properties. For example, the sharpness of diamonds may vary depending on the purpose for which the grinding tool is to be used. The properties of different diamonds can be matched to match the properties of different binders (or hybrids of binders).

In a good grinding tool, the abrasive particles must be bound in their matrix in such a way that the grinding tool functions as desired. It is unfortunate that the grinding tool has a good wear resistance so that it can be used over a longer period. However, a good notch resistance is not the only desirable property and the grinding tool having the greatest notch resistance is not necessarily the best choice. Other undesirable properties include low energy consumption (i.e. that the power required to operate the grinding tool is not anti & hog) and constant or at least predictable performance. If the abrasive effect of the abrasive edge varies too much over time, this problem arises. This is especially the case as the performance of the grinding tool varies on a salt that is unpredictable.

The extent of the abrasion on the grinding tool under given conditions depends to a very high degree on the properties of the matrix in which the abrasive particles are embedded. Darfcir, the composition of the matrix is important.

When a grinding tool is used to machine a workpiece, sharp edges and horns appear on the abrasive particles on the workpiece. In this way force is exerted on abrasive particles which are embedded in the matrix. During grinding, the abrasive particles are damaged. Small pieces are gradually broken away from the abrasive particles so that the abrasive particles gradually tear down. When the abrasive particles in an area of the abrasive edge have become completely worn, the workpiece will directly meet the matrix. The matrix that is skimmed is less hard than the workpiece and grooves down quickly. As a result, new abrasive particles come up to the surface of the abrasive edge and can begin to act on the workpiece.

However, if the matrix that heals the abrasive particles is too weak, abrasive particles can wear away from the matrix before they wear down. When this touches a part of the surface of the abrasive edge, the workpiece will come into direct contact with the relatively sparse matrix and wear down the matrix in the past. When this happens, the power consumption decreases temporarily until so much of the matrix has been worn down that new abrasive particles come to the surface. As a result, the abrasive edge of the grinding tool will be noted faster than would otherwise have been the case. If the operation of the grinding tool is programmed in advance, the consequence may be that the grinding procedure does not work correctly because the grinding tool has been set to operate on the basis of an assumption about tool diameter which is now incorrect. This problem becomes more serious if the abrasive edge is ripped out in a way that is black to predict, for example if abrasion occurs in sudden steps that occur at irregular intervals.

It is also desirable that the required power for the grinding operation can be kept low so that the energy consumption during grinding can be minimized.

Another undesirable property of grinding tools is a high G-number. The G-number expresses the ratio between the volume of material removed by the grinding tool from a workpiece and the volume lost by the grinding tool (the groove on the tool). A good grinding tool has a Mgt G number.

It is an object of the present invention to provide a grinding tool which has a high resistance to abrasion. A further object of the invention is to provide a tool which is grounded on a regular and predictable salt, which has a high power requirement and a high G-number. These moldings are achieved by the present invention which will be explained in the following.

SUMMARY OF THE INVENTION The invention relates to a grinding tool. The grinding tool is in particular intended as a grinding tool for processing hard and / or spraying materials such as tungsten carbide, but the grinding tool according to the invention could also be used for grinding other materials. The grinding tool comprises a core and an abrasive edge. The abrasive edge comprises abrasive particles embedded in a matrix and the matrix comprises a metallic binder which is a sintered bronze alloy. The metallic binder constitutes 50% - 100% of the matrix volume. According to the invention, the metallic binder contains silicon nitride in an amount amounting to 0.02 - 5.0% by volume of the metallic binder or optionally 0.1% by volume - 5.0% by volume of the metallic binder.

In embodiments of the invention, the matrix may further optionally comprise a polymeric binder which has been sintered together with the metallic binder so that the polymeric binder and the metallic binder form a joined network.

In embodiments of the invention, the silicon nitride constitutes 0.3 - 5.0% by volume of the metallic binder. It may, for example, constitute 0.5 - 5.0% by volume of the metallic binder, 1.0 - 5.0% by volume of the metallic binder or 0.5 - 3.0% by volume or 0.5 - 2.0% by volume.

The silicon nitride may be present in the form of grains with an average grain size which is preferably less than 10 μm but also preferably above 0.1 μm. Such particles can be 1250 Tyler Mesh particles. Thus, the particles may include particles up to 10 microns even if the average grain size is smaller.

When a polymeric binder is part of the matrix, the polymeric binder may comprise polyimide or be wholly or almost a belt of polyimide.

The matrix may optionally further comprise fillers such as graphite. Graphite had lubricating properties that can be unsightly during grinding.

The metallic binder is preferably a bronze alloy comprising copper, tin and silver.

The abrasive particles can be, for example, diamond particles or particles of cubic bomitride. For both diamonds and cubic bomitride, the abrasive particles can have an average particle size in the range zipm - 181 pm. In many realistic embodiments, the abrasive particles can have a size in the range of 46pm - 91pm. In embodiments of the invention, the abrasive particles may have a coating of copper or nickel.

The invention relates to a method of manufacturing the grinding tool according to the invention.

The process comprises sintering abrasive particles together with metal powder so that the sintering results in a matrix in which the abrasive particles are embedded. The matrix will thereby comprise a metallic binder. The metal powder comprises copper and tin so that the metallic binder will become a sintered bronze alloy. According to the invention, silicon nitride in the form of a powder is added to the metal powder for sintering and to such an extent that the silicon nitride will constitute 0.02 - 0.5% by volume of the metallic binder and preferably 0.1 - 5.0% by volume of the metallic binder.

In embodiments of the process of the invention, the metal powder may further comprise silver.

When reference has been made to the relative proportions of silicon nitride in the metallic binder, it is to be understood that this refers to the volume proportions of the powder used in the manufacturing process itself. In other words, the manufacturing process is such that, in the powder added for sintering, the silicon nitride constitutes 0.02 - 5.0% by volume of the metallic binder (the silicon nitride is shaved off as part of the metallic binder).

It is assumed that the silicon nitride particles will retain the same relative volume fraction Liven after sintering.

A polymer may optionally be added to the metal powder prior to sintering, preferably in the form of a polyimide powder so that a polymeric binder is also formed which forms part of the matrix.

The process can be carried out in such a way that the powder material for the matrix binder is mixed with the abrasive particles so that a mixture is formed. The mixture is then compacted in a cold press. The compacted mixture is then cured in an oven at a temperature in the range of 380 ° C - 520 ° C, preferably 400 ° C - 500 ° C for a period of 120-150 minutes. The compacted and hardened mixture is then placed in a press and subjected to a pressure of 1500 - 2000 kg / cm2. The pressure is then maintained until the mixture has a temperature below 300 ° C at night.

Filling material can optionally be added to the mixture of metal powder and abrasive particles before the sintering operation. The filler material may optionally include graphite.

The matrix of the grinding tool according to the invention can advantageously be a matrix which is a hybrid, i.e. a matrix having both a metallic binder and a polymeric binder. Solutions with hybrid bonds can combine the best properties of metallic binders with the best properties of polymeric binders. If sharpening of a sharpening tool needs to be done, a grinding tool with a hybrid matrix can be sharpened more easily than a pure metal matrix. At the same time, a grinding tool with a hybrid matrix has a better groove resistance than a matrix which only uses a polymeric binder.

BRIEF DESCRIPTION OF THE FIGURES Figure 1 is a schematic representation of a grinding tool.

Figure 2 is a schematic cross-sectional view of abrasive particles embedded in the abrasive edge of a grinding tool.

Figure 3 is a schematic cross-sectional view of a grinding tool acting on a workpiece.

Figure 4 is a diagram showing the power consumption for two different grinding tools. Figure 5 is a schematic cross-sectional view of a first embodiment of the grinding tool according to the invention.

Figure 6 is a schematic cross-sectional view of a second embodiment of the grinding tool according to the invention.

Figure 7 is a diagram showing the notching of a grinding tool as a function of the content of silicon nitride. Figure 8 is a diagram showing the G-number of a grinding tool as a function of the content of silicon nitride.

DETAILED DESCRIPTION OF THE INVENTION Referring to Figure 1, there is shown a grinding tool 1. The grinding tool may in particular be a grinding wheel which is intended for machining hard and / or brittle materials such as tungsten carbide. Such materials may be present in workpieces for such tools as, for example, drills or tooling tools and the grinding tool 1 according to the present invention may be a grinding wheel used to form such tools. The grinding tool 1 comprises a karna 2 and an abrasive edge 4. The cam 2 can be made of a less expensive material such as steel or some other metal !. Alternatively, the core could be made of, for example, a polymeric material. Kaman could also include more than one material. It can, for example, be made partly of metal such as steel or aluminum and partly of a polymeric material. The cam 2 can be provided with a through hole or cavity 3 so that the grinding tool 1 can be mounted on a spindle (not shown) for rotary movement. Referring to Figure 2, the abrasive edge 4 comprises abrasive particles 5 embedded in a matrix 6. The matrix 6 in turn contains a metallic binder which is a sintered bronze alloy. The metallic binder constitutes 50 - 100% by volume of the matrix 6 and embodiments are thus conceivable in which the entire matrix 6 consists of the metallic binder. Normally, however, the matrix 6 comprises at least flake other component. For example, it may include fillers such as graphite which have lubricating properties. In most embodiments, the matrix 6 would then comprise a polymeric binder which may be polyimide.

If the matrix 6 heals the abrasive particles 5 vd1, the abrasive particles 5 will emit small fragments and be graded down. As a consequence, the groove on the abrasive edge 4 will be comparatively slow so that the diameter of the grinding tool 1 can be kept substantially constant for a long time. Furthermore, grouting on the abrasive edge 4 will be held at a steady pace and the effect during operation will not vary so much.

If the matrix 6 is instead incapable of holding the abrasive particles firmly, abrasive particles may loosen long before they have fragmented. As a result, they will be lost before their full abrasive potential has been exploited. The grinding tool 1 will wear out faster and the diameter of the grinding tool (such as a grinding wheel) will decrease faster. A smaller diameter of the grinding tool 1 can result in a less accurate machining of the workpieces.

Reference is now made to Figure 3. A grinding tool 1 acts on a workpiece 7. The workpiece 7 may be, for example, a workpiece to be formed into a drill. The grinding tool 1 is rotated by means of a power source which acts through, for example, a spindle (not shown). As a result, the abrasive edge 4 of the workpiece 7 acts to cut a groove in the workpiece. In Figure 3, the workpiece has a core diameter CD which is constituted by the action of the grinding tool 1. If the grinding tool 1 is notched down so that its diameter decreases, then the core diameter CD will wax unless the grinding is not compensated (for example by repositioning the grinding tool 1 in relation to workpiece 7). It is therefore very unfortunate that the notation can be kept to a minimum and that the notation that takes place does not come in sudden unpredictable leaps.

It can be added that when the abrasive particles 5 are fragmented correctly bit by bit so this is good for the curing properties of the grinding tool 1, i.e. the grinding tool's ability to re-sharpen itself. When the abrasive particles 5 are fragmented bit by bit, the groove on the matrix 6 can run smoothly and the surface of the abrasive edge 4 is not salted as lightly again. If instead abrasive particles are suddenly worn away before they have been properly fragmented, then this tends to lead to a similar clogging of the surface, the surface of the abrasive edge 4 may be clogged to a greater extent by small particles 5 from the workpiece 7. This may be necessary. to temporarily take the grinding tool 1 out of operation so that the grinding tool 1 can be sharpened. If the abrasive particles are gradually fragmented, the risk of such clogging is less. When abrasive particles have become completely worn out, new abrasive particles 5 can come to the surface in a softer process which in itself contributes to the reshaping of the grinding tool (or rather the abrasive edge 4 of the grinding tool 1).

When abrasive particles are worn away from the abrasive edge before they have been completely fragmented, this tends to show up in the power consumption of the grinding tool; the effect drops suddenly and then starts to rise again after a while. If the abrasive particles are properly held by the matrix so that they are allowed to fragment as they should, then this can also be seen in the power consumption. In such a case, the power tends to remain constant over time (it should be noted, however, that there is always a certain gradual increase in the power requirement from the first workpieces, so that a lower power is required for the very first workpieces).

It has been suggested in an article by ED Kizikov and P. Kebko ("Microadditions to alloys of the system Cu-Sn-Ti", Institute of Superhard Materials, Academy of Science of 10 the Ukrainian SSR, Kiev, translated by Metallovedenie I Termicheskaya Obrabotka Metallov, No. 1, pages 50-53, January 1987) that an alloy of Cu / Sn / Ti used as a binder for diamond grinding tools is reinforced with 0.01% silicon nitride (Si3N4). According to the authors of that article, the addition resulted in a high stretch.

The inventors of the present invention have, to be sure, what steps can be taken to improve the ability of the matrix to retain the abrasive particles. Without wishing to be bound by any theory, the inventors believe that one reason metallic adhesives release abrasive particles embedded therein may be that dislocations within the metallic adhesive weaken the metallic adhesive. Assuming that this theory is correct, the inventors first thought that it would be possible to improve the matrix by reinforcing it with particles that block dislocations in the metallic binder. The inventors tested various additives to the metal powder used for sintering the metallic binder. One additive tested was alumina which was added in an amount corresponding to 1.0% by volume of the metallic binder. This led to a certain improvement but the Rirbdttringen was not as good as the inventors had hoped. The inventors also experimented with the addition of 0.01% by volume of silicon nitride. The improvement by that addition was even less than the improvement obtained by alumina. The inventors then investigated whether all amounts of silicon nitride would lead to better results. This was confirmed by experiments challenged by the inventors. When silicon nitride was added in amounts which were substantially more than 0.01% by volume of the metallic binder, it was discovered that a very noticeable improvement was obtained.

For example, the inventors tested a composition in which the metallic binder contained 0.1% by volume of silicon nitride (Si 3 N 4). An abrasive tool with this composition was then compared with a standard abrasive tool which used a hybrid matrix and which did not contain silicon nitride (Si 3 N 4). The grinding tools were both grinding tools in which the abrasive edge 4 was designed as a ring surrounding the cam 2. Under comparable conditions, the diameter of the standard tool was noted down 136 sqm while the diameter of the grinding tool with the experimental composition was only noted down by 581.1m. The G-number of the tool with 1.0% silicon nitride was 2335. For comparison, a tool with 0.01 volume% silicon nitride was noted down 94 in while a tool using 1.0 volume% alumina was noted down 84 pm.

A test was performed with a composition in which silicon nitride constituted 5% by volume of the metallic binder. The wear resistance was still good but not quite as good as for the tool with 1.0% by volume of silicon nitride. The tool with 5.0% silicon nitride also had higher power consumption. The G-number was good but not quite as good as for the tools with 1.0 and 0.1 volume%.

The inventors have also tested a grinding wheel which had a shape and composition similar to the other tools tested but in which the silicon nitride accounted for 0.1% by volume of the metallic binder. It turned out that, under the same test conditions as the other tools tested, the notch on the tool with 0.1 volume% silicon nitride was 62 μm and the G number was 2084. Although it was the basis in relation to the results obtained at 1% by volume so it was still a very patag improvement compared to the standard grinding tool.

The inventors have also tested a grinding wheel which had a silicon nitride content of 0.02% by volume of the metallic binder but which was otherwise like the other grinding wheels tested. Under equivalent test conditions, the grinding wheel with 0.02% by volume of silicon nitride had a groove (diameter reduction) of 58 μm and a G-number of 2283. The results were thus somewhat better than the results obtained at a ratio of 0.1% by volume.

The results led to the conclusion that a significant Miter result was obtained in the range 0.02 - 5.0% by volume of silicon nitride (Si3N4). In this range, it has been shown that both G-ratio and note resistance are significantly better at 0% or 0.01%.

Tests of note resistance and G-number have also been performed at 0% by volume, 0.01% by volume, 0.02% by volume, 1.0% by volume and 5.0% by volume of silicon nitride.

The tools tested were grinding wheels of essentially the same type as shown in Figure 5, i.e. grinding wheels with an abrasive edge surrounding a core 1 and where the grinding tool 11 rotates about an axis A during operation. The notch resistance as a function of the silicon nitride content can be seen in Figure 7. The notch resistance is expressed in Figure 7 as a reduction in diameter. As can be seen in Figure 7, the note resistance significantly decreased when the silicon nitride content increased from 0.01% to 0.02%. The wear resistance continued to be high up to a content of silicon nitride of 5% by volume of the metallic binder.

At 5.0% v / v silicon nitride, however, the notch resistance was slightly lower compared to the resistance observed at a content of 0.02% - 1.0%. The inventors have therefore concluded that the best note resistance is obtained in the range 0.02 - 5.0% by volume.

The G-number as a function of the content of silicon nitride can be seen in Figure 8. As can be seen in the figure, the best values are obtained at a content of silicon nitride in the range 0.02% - 5.0%. In Figure 8, it can also be seen that the G number decreases towards the right in the figure, even though the G number at 5.0% by volume is still good.

The inventors have therefore concluded that the metallic binder may contain silicon nitride in an amount of 0.02 to 5.0% by volume of the metallic binder. Since the power consumption was higher at 5.0% by volume, the inventors have concluded that the value below 5.0% will have good wear resistance but lower power consumption compared with tools that have a silicon nitride content of 5% by volume. A preferred range may therefore be 0.02% by volume to 3.0% by volume, 0.5 - 3.0% by volume, 0.5 - 2.0% by volume or 1.0 - 2.0% by volume of the metallic binder.

At 0.1% by volume, power consumption was generally lower at 0.02% by volume. At 5.0% by volume of silicon nitride, the power consumption was higher than at a content of. 0.02% but the power consumption at 5.0% by volume was smoother, the power consumption was more predictable than at 0.02% by volume.

The silicon nitride particles should preferably be up to 10 microns in size (1250 Tyler 30 Mesh). For salted particles, this will normally mean that the average grain size is less than 10 microns. The average grain size (D50) of the silicon nitride particles can then be around 2tm - 31.1m (depending on how the average particle size is measured). The specific surface area of the silicon nitride particles can advantageously be in the range 5 m2 / g - 6 m2 / g. If the particles used are too small, this can lead to clogging and problems during manufacture. In order to give the metallic binder optimum strength, the inventors further believe that particles up to 10 μm should preferably be included. Normally, the matrix 6 should further comprise a polymeric binder which has been sintered together with the metallic binder so that the polymeric binder and the metallic binder form a joined network (although such a polymeric binder is optional). The use of a polymeric binder makes it possible to fine-tune the properties of the matrix and adapt it to different types of abrasive particles. The polymeric binder may suitably be polyimide or comprise polyimide. The reason for this is that polyimide is heat resistant and can withstand the high temperatures during sintering. If a polymeric binder is used, the polymeric binder may be present in an amount of up to 50% by volume of the matrix (i.e., the amount of polymeric binder is in the range of 0-50% by volume of the matrix). For example, the polymeric binder may correspond to 10 to 40% by volume or 10 to 30% by volume of the matrix.

The polymeric binder could possibly be made of some other polymeric material. It could, for example, consist of polyamidimide which is also capable of withstanding high temperatures. However, polyimide is preferred because it has better abrasive properties than polyamidimide.

The metallic binder is preferably a bronze alloy comprising copper, tin and silver. Silver improves the adverse properties of the metallic binder.

The abrasive particles 5 can be either diamond particles or particles of cubic bomitride. Diamonds are harder and have better abrasive properties, but cubic boron nitride is more temperature resistant. In addition, diamonds can react chemically with certain materials.

The abrasive particles 5 may be are diamond particles or particles of cubic bomitride. The particles may be in the range 411m - 181 (AM although particles outside this range may be monitored depending on the requirements of each specific case. In many realistic embodiments the abrasive particles may have an average particle size in the range 461, tm - 91 μm). which is a range that is suitable for many grinding operations.

The abrasive particles may optionally have a coating of copper or nickel. A coating of copper or nickel can facilitate the bonding between the abrasive particles 5 and the matrix 6. However, the abrasive properties of the particles 5 will be somewhat reduced if the particles have such a coating.

The relative proportion of abrasive particles 5 in relation to the binders and fillers in the matrix 6 may vary depending on the requirements in each individual case. In many realistic embodiments, the amount of abrasive particles may correspond to one to 50% of the total volume of the abrasive edge (i.e., the total volume of the abrasive particles and matrix). If the relative proportion of abrasive particles exceeds 50%, there is a significant risk that the matrix will no longer be able to hold the abrasive particles. If the relative proportion of abrasive particles is less than 10%, the abrasive effect may be too small. The relative proportion of abrasive particles may preferably be in the range of 15% - 30% and an exemplary value may be 25%.

Preferably, the silicon nitride is present in the form of grains having an average grain size equal to or less than 10 microns but above 0.1 microns. For example, they may have an average size in the range of 1 tm - 10i.tm or 2ttm - 9 [m. The inventors believe that silicon nitride particles smaller than 0.1 .mu.m can lead to clumping of the silicon nitride particles, which reduces their reinforcing effect.

The silicon nitride particles can have three different crystallographic structures called α-, 0- and γ-phase (also known as trigonal phase, hexagonal phase and cubic phase). The most common are the aphase and the fl phase. It is only under high pressure and high temperature that the y-phase can be synthesized. Whichever of these phases can be used. Preferably the bevel is used. The silicon nitride particles added may awn be a mixture of particles of different phases.

Referring to Figure 4, a grinding tool according to the invention is compared with a standard grinding tool. The vertical axis represents power consumption while the horizontal axis represents a number of workpieces on which the respective grinding tools 30 have acted. In Figure 5, B5 represents a grinding tool according to the invention while EZ represents a standard grinding tool. As can be seen in Figure 4, the tool represented as B5 has a power consumption that first rises steeply and then remains essentially constant. The conventional tool represented by EZ has a power consumption that rises sharply and then suddenly falls before rising again. This indicates that the abrasive particles in the B-tool are slowly fragmented while EZ represents an abrasive tool where the abrasive particles are suddenly worn away. The use of the tool will be faster. It can be added that B5 represents a tool with both a metallic binder and a polymeric binder. The metallic binder is a bronze that has copper, tin and silver. It has been sintered using a metal powder containing by volume% copper, 45% by volume tin and 10% by volume silver. In the tool according to B5, the polymeric binder constitutes 1.0% by volume of the total amount of binder.

The grinding tool according to Figure 1 may have such a cross section as shown in Figure 5. In such an embodiment, the abrasive edge 4 may be located radially outside the core 2 so that the edge 4 completely surrounds the core 2. The tests explained with reference to Figure 4, Figure 7 and Figure 8 have been made on such a grinding tool. However, the invention is not limited to such an embodiment. Referring to Figure 6, it will be appreciated that the core 2 may extend at least as far in the radial direction as the abrasive edge 4. In Figure 6, the grinding tool has an abrasive edge 4 which does not extend beyond the core 2 in the radial direction. Instead, the abrasive edge 4 has an extension in the axial direction which differs from the core 2 (the axial direction is the axis of rotation A of the grinding tool 1 when it is driven by a spindle, see Figure 5 and Figure 6). It will also be appreciated that the grinding tool 1 is not necessarily designed for rotation. Instead, it could affect workpieces in a reciprocating motion. In the context of the claims, the term 'lama' is to be understood broadly as any raised body for the abrasive edge. a workpiece.

The invention further comprises a method for producing the tool according to the invention. The process comprises sintering abrasive particles together with metal powder comprising copper and tin so that the sintering results in a matrix in which the abrasive particles are embedded. The matrix comprises a metallic binder which is a sintered bronze alloy. According to the invention, silicon nitride in the form of powder is added to the metal powder for sintering in such a way that the silicon nitride will constitute 0.1 - 5.0% by volume of the metallic binder.

The metal powder used is preferably metal powder with particulate matter smaller than 44 μm, but they should preferably be larger than the silicon nitride particles. Preferably they should be at least twice as large. An average size in the interval 15 j_tm - 441.1m can be The metal powder can optionally also include silver.

The metal powder can come in the form of pre-alloyed particles or as particles of pure copper, pure tin, pure silver, etc.

A polymer can be added to the metal powder for sintering, preferably in the form of polyimide powder so that a polymeric binder is formed which is part of the matrix 6.

The sintering process can be carried out so that the powder material for the binder 6 binder is mixed with the abrasive particles 5. The mixture is compacted in a cold press. The compacted mixture is then cured in an oven at a temperature in the range of 380 ° C - 520 ° C, preferably 400 ° C - 500 ° C or 440 ° C - 460 ° C for a period of 120-150 minutes. The time required depends on the size. In a stone press form hays more time.

Then (preferably immediately afterwards) the compacted and hardened mixture is placed in a press and subjected to a pressure of 1500 - 2000 kg / cm 2. The pressure is then maintained until the mixture has a temperature below 300 ° C at night.

For example, the inventors have produced grinding tools according to this method in a process where the temperature in the oven was 450 ° C.

The abrasive edge 4 can also be produced by "kick plasma sintering" (SPS). By this technique, the abrasive edge 4 can be produced very quickly.

The edge with the matrix containing abrasive particles can be sintered separately and then attached (for example glued) to the core 2. Alternatively, the abrasive edge 5 can be sintered directly on the core 2 so that it binds to the core at the same time as it is formed. Before sintering, the cam 2 can be electrolytically welded with copper on at least one surface of the core which will measure the abrasive edge 4. The abrasive edge 4 can then be sintered on the copper coated surface so that a joint is formed.

Filling material can optionally be added to the mixture of metal powder and abrasive particles before the sintering operation. As% squares explained, the filler material may include graphite. Other possible filler materials may include, for example, alumina spheres.

Preferably, the bronze used in the metallic binder is selected from the group comprising copper - tin (Cu / Sn), copper - tin - cobalt (Cu / Sn / Co), copper - tin - nickel (Cu / Sn / Ni) or copper - tin - silver (Cu / Sn / Ag). Even more preferably 16, the bronze is a bronze of copper - tin - silver. Other bronze alloys can also be monitored.

The grinding tool according to the invention can be used for machining hard and / or sprayed materials. This does not exclude that the grinding tool can be used awn for other materials.

In embodiments of the invention, the matrix 6 may optionally also comprise at least one ceramic component in the form of ceramic particles. The ceramic component may be, for example, free and contain SiO 2. Ceramic particles for the matrix can consist of frit in the form of spherical particles having a particle size of 501, tm - 50011M depending on the size of the abrasive particles. For storm abrasive particles, larger ceramic particles will be used. The abrasive particles may be embedded in the ceramic particles while the ceramic particles are embedded in a hybrid matrix with a metallic binder and a polymeric binder. The ceramic particles can be hardened by the matrix than what the abrasive particles would hold. The healing properties of the abrasive edge are thereby improved. The ceramic component does not have as good a wear resistance as the metallic binder. By combining ceramic, metallic and polymeric binders, it is possible to combine the best properties of these binders.

Claims (14)

PATENT REQUIREMENTS An abrasive tool (1) for machining hard and / or spray material, which abrasive tool (1) comprises a core (2) and an abrasive edge (4), the abrasive edge (4) comprising abrasive particles (5) which are embedded in a matrix (6) and wherein the matrix (6) comprises a metallic binder which is a sintered bronze alloy and the metallic binder constitutes 50 - 100% by volume of the matrix, and contains silicon nitride in an amount of 0.02 - 5.0% by volume of the metallic binder, characterized in that the silicon nitride is present in the form of grains which have an average grain size of less than 10 μm and Over 0.1 μm An abrasive tool (1) according to claim 1, wherein the matrix (6) further comprises a polymeric binder which has been sintered together with the metallic binder so that the polymeric binder and the metallic binder form a joined network. An abrasive tool (1) according to claim 1 or claim 2, in which the silicon nitride is 0. 3 - 5.0% by volume of the metallic binder, typically 0.5-3% by volume and even more preferably 0.5-2% by volume. An abrasive tool according to claim 2, in which the polymeric binder comprises polyimide. An abrasive tool according to claim 1 or 2, in which the matrix further comprises filler material such as graphite. An abrasive tool according to any one of claims 1 to 5, in which the metallic binder is a bronze alloy comprising copper, tin and silver. An abrasive tool according to any one of claims 1 to 6, in which the abrasive particles (5) are diamond particles or particles of cubic boron nitride. An abrasive tool according to claim 7, in which the abrasive particles (5) have an average particle size in the range 4 μm - 181 μm and preferably in the range 46 μm - 91 μm. An abrasive tool according to claim 8, in which the abrasive particles (5) have a coating of copper or nickel. A method of making an abrasive tool (1) comprising sintering abrasive particles together with metal powder comprising copper and tin so that the sintering results in a matrix (6) in which the abrasive particles (6) are embedded and wherein the matrix comprises a metallic binder which is a sintered bronze alloy, characterized in that silicon nitride in the form of a powder is added to the metal powder for sintering and in such an amount that the silicon nitride will constitute 0.02 - 5.0% by volume of the metallic binder and wherein the silicon nitride added is in the form of grain which has an average grain size of less than 0.1 μm. A method according to claim 10, in which the metal powder further comprises silver. A method according to claim 10 or claim 11, in which a polymer is added to the metal powder for sintering, preferably in the form of polyimide powder, so that a polymeric binder is also formed which forms part of the matrix (6). A method according to any one of claims 10 to 12, wherein the method comprises; mixing the powder material before the binder of the matrix (6) with the abrasive particles (5); compacting the mixture in a cold press; curing the compacted mixture in an oven at a temperature in the range of 380 ° C - 520 ° C, preferably 400 ° C - 500 ° C for a period of 120 - 150 minutes; then placing the compacted and hardened mixture in a press where it has been subjected to a pressure of 1500 - 2000 kg / cm2; and maintaining the pressure until the mixture has a temperature below 300 ° C at night. A method according to any one of claims 10 to 13, wherein the filler material is added to the mixture of metal powder and abrasive particles before the sintering operation and wherein the filler material comprises graphite. 1 1 • 7