Organic bonded abrasive tools, having controlled microstructures, comprise a relatively low volume percentage of abrasive grain and a relatively low hardness grade, but are characterized by the excellent mechanical strength and efficient grinding performance of much harder grade, lower porosity tool
Organic bonded abrasive tools, having controlled microstructures, comprise a relatively low volume percentage of abrasive grain and a relatively low hardness grade, but are characterized by the excellent mechanical strength and efficient grinding performance of much harder grade, lower porosity tools, especially in versatile grinding processes, such as centerless grinding. A method for centerless grinding with these tools is provided. Methods for making the abrasive tools utilizing agglomerated abrasive grain are described.
대표청구항▼
We claim: 1. A bonded abrasive tool, comprising a three-dimensional composite of (a) a first phase comprising 20-48 vol % abrasive grains bonded with 20 to 48 vol % organic bond material and less than 10 vol % porosity, wherein 50 to 100 vol % of the abrasive grains are in the form of a plurality o
We claim: 1. A bonded abrasive tool, comprising a three-dimensional composite of (a) a first phase comprising 20-48 vol % abrasive grains bonded with 20 to 48 vol % organic bond material and less than 10 vol % porosity, wherein 50 to 100 vol % of the abrasive grains are in the form of a plurality of grains agglomerated together by sintering the grain with an inorganic binder material, and wherein the first phase is the continuous phase of the composite; and (b) a second phase consisting of 16 to 34 vol % porosity; wherein the bonded abrasive tool is characterized by a hardness grade between J and S on the Norton Company grade scale and a minimum burst speed of 6000 sfpm (30.48 m/s). 2. The bonded abrasive tool of claim 1, wherein the first phase of the composite comprises 24-44 vol % abrasive grains bonded with 28-38 vol % organic bond material and less than 10 vol % porosity, and the second phase consists of 18-28 vol % porosity. 3. The bonded abrasive tool of claim 1, wherein the first phase of the composite comprises 26-38 vol % abrasive grains bonded with 26-38 vol % organic bond material, and the second phase consists of 18-24 vol % porosity. 4. The bonded abrasive tool of claim 1, wherein the first phase of the composite comprises a minimum of 1 vol % inorganic binder material. 5. The bonded abrasive tool of claim 4, wherein the hardness grade of the bonded abrasive tool is at least two grade softer than that of an otherwise identical conventional tool made with abrasive grains that have not been agglomerated together by sintering with an inorganic binder material. 6. The bonded abrasive tool of claim 4, wherein the first phase of the composite comprises 2 to 12 vol % inorganic binder material. 7. The bonded abrasive tool of claim 1, wherein the inorganic bond material is selected from the group consisting of glass, vitrified bond materials, ceramic bond materials, glass-ceramic bond materials, inorganic salt materials and metallic bond materials, and combinations thereof. 8. The bonded abrasive tool of claim 1, wherein the first phase of the composite further comprises a plurality of grains agglomerated together by curing with an organic binder material. 9. The bonded abrasive tool of claim 1, wherein the first phase of the composite is a reticulated network of abrasive grain anchored within the organic bond material. 10. The bonded abrasive tool of claim 1, wherein the organic bond material is selected from the group consisting of phenolic resin materials, epoxy resin materials, polyimide resin materials, rubber materials, phenol formaldehyde resin materials, urea formaldehyde resin materials, melamine formaldehyde resin materials, acrylic resin materials and combinations thereof. 11. The bonded abrasive tool of claim 1, wherein the abrasive tool has a density of less than 2.4 g/cc. 12. The bonded abrasive tool of claim 1, wherein the abrasive tool has a density of less than 2.0 g/cc. 13. The bonded abrasive tool of claim 1, wherein the abrasive tool has an elastic modulus of less than 20 GPa. 14. The bonded abrasive tool of claim 1, wherein the first phase of the composite further comprises secondary, non-agglomerated abrasive grain. 15. A method for centerless grinding, comprising the steps of: (a) providing a bonded abrasive wheel, comprising a three-dimensional composite of (i) a first phase comprising 20-48 vol % abrasive grains bonded with 20 to 48 vol % organic bond material and less than 10 vol % porosity, wherein 50 to 100 vol % of the abrasive grains are in the form of a plurality of grains agglomerated together by sintering the grain with an inorganic binder material, and wherein the first phase is the continuous phase of the composite; and (ii) a second phase consisting of 16 to 34 vol % porosity; wherein the bonded abrasive tool is characterized by a hardness grade between J and S on the Norton Company grade scale and a minimum burst speed of 6000 sfpm (30.48 m/s); (b) mounting the bonded abrasive wheel on a centerless grinding machine; (c) rotating the wheel; and (d) bringing a grinding surface of the rotating wheel into contact with a workpiece being rotated by a regulating wheel and supported by a workrest fixture for a sufficient period of time to grind the workpiece; whereby the wheel removes workpiece material at an effective material removal rate, the grinding surface of the wheel remains substantially free of grinding debris and, after grinding has been completed, the workpiece is substantially free of thermal damage. 16. The method for centerless grinding of claim 15, wherein the bonded abrasive wheel has a minimum burst speed of 7500 sfpm (38.10 m/s). 17. The method for centerless grinding of claim 15, wherein the bonded abrasive wheel is rotated at a speed of 5500 to 9600 sfpm (27. 94 to 48.96 m/s). 18. The method for centerless grinding of claim 15, wherein the bonded abrasive wheel is a cylinder, having two circular faces, a mounting hole, and a radial perimeter and the grinding surface of the wheel is the radial perimeter of the cylinder.
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