Sawing beads and method for making the same

The invention claimed is: 1. A method for producing a sawing bead, said sawing bead comprising an abrasive layer on a metal sleeve, said abrasive layer comprising diamond particles embedded in a metal matrix material, said method comprising the steps of: providing said metal sleeve that is made to rotate axially; providing a supply of metal matrix material in powder form carried in a gas flow; providing a supply of diamond particles; igniting an energy source in the form of a laser beam; wherein said laser beam melts said metal matrix material on said metal sleeve, thereby forming a molten metal pool wherein said diamond particles are thrown, and wherein the temperature of said molten metal pool is held at or above 1150° C. for less than 200 ms to limit internal graphitization of said diamond particles. 2. The method of claim 1 , wherein said diamond particles have a mean size above 100 μm. 3. The method according to claim 1 , wherein said laser beam irradiates a first elongated area of the surface of said metal sleeve, said first elongated area spanning substantially the axial length of said metal sleeve, and wherein said supply of metal matrix material arrives at the surface of said metal sleeve in a second elongated area spanning substantially the axial length of said metal sleeve, said second elongated area being smaller in area than said first elongated area, said first elongated area substantially covering said second elongated area. 4. The method according to claim 3 , wherein the axial centre line of said second elongated area is offset with respect to the axial centre line of said first elongated area, said offset being in the direction of rotation of said metal sleeve. 5. The method according to claim 1 , wherein the power of said laser beam is adjusted during the deposition of said abrasive layer by keeping the area of said molten metal pool substantially constant during deposition. 6. The method of claim 5 , wherein said molten metal pool area is continuously monitored during the deposition of said abrasive layer and used as a feedback signal to steer the power of said laser beam. 7. The method according to claim 1 , wherein the molten metal pool is cooled to below the solidus temperature of said metal matrix material within one turn of said sleeve to prevent external thermal degradation of said diamond particle. 8. A sawing bead, comprising: a metal sleeve, and an abrasive layer attached to said metal sleeve, said abrasive layer comprising diamond particles, wherein some but not more than 60% of said diamond particles show internal graphitization. 9. The sawing bead according to claim 8 , wherein said abrasive layer is deposited by laser cladding. 10. A sawing bead comprising a metal sleeve, an abrasive layer attached to said metal sleeve, said abrasive layer comprising diamond particles embedded in a metal matrix material, wherein some of the diamond particles show internal graphitization, and wherein said abrasive layer is deposited by a method of laser cladding, comprising the steps of: providing said metal sleeve that is made to rotate axially; providing a supply of metal matrix material in powder form carried in a gas flow; providing a supply of diamond particles; and igniting an energy source in the form of a laser beam; wherein said laser beam melts said metal matrix material on said metal sleeve, thereby forming a molten metal pool wherein said diamond particles are thrown; and wherein the temperature of said molten metal pool is held at or above 1150° C. for less than 200 ms to limit internal graphitization of said diamond particles. 11. The sawing bead according to claim 8 , wherein some but not more than 40% of the diamond particles show internal graphitization. 12. The sawing bead according to claim 11 , wherein less than 10% of the diamonds show external thermal degradation. 13. A sawing cord comprising a steel cord and sawing beads threaded thereon wherein the sawing beads are separated by a polymer sleeve, said sawing beads comprising an abrasive layer on a metal sleeve, said abrasive layer comprising diamond particles embedded in a metal matrix material, wherein said sawing beads are made according to a method comprising the steps of: providing said metal sleeve that is made to rotate axially; providing a supply of metal matrix material in powder form carried in a gas flow; providing a supply of diamond particles; and igniting an energy source in the form of a laser beam; wherein said laser beam melts said metal matrix material on said metal sleeve, thereby forming a molten metal pool wherein said diamond particles are thrown, and wherein the temperature of said molten metal pool is held at or above 1150° C. for less than 200 ms to limit internal graphitization of said diamond particles. 14. A sawing cord, comprising: a steel cord and sawing beads threaded thereon, wherein the sawing beads are separated by a polymer sleeve, and wherein said sawing beads comprise a plurality of sawing beads according to claim 8 .