초록 ▼

Milling cutter (1), which can rotate about a cutter longitudinal axis (A), comprises a sleeve-shaped shaft (2) provided with an inner lying chip evacuation channel (11), which is arranged, in essence, symmetric to the cutter longitudinal axis (A), and with a suction opening (12). The milling cutter

Milling cutter (1), which can rotate about a cutter longitudinal axis (A), comprises a sleeve-shaped shaft (2) provided with an inner lying chip evacuation channel (11), which is arranged, in essence, symmetric to the cutter longitudinal axis (A), and with a suction opening (12). The milling cutter also comprises a milling head (3, 3a, 3b, 3c), which is held coaxial to the cutter longitudinal axis (A) and to the shaft (2) while being held on said shaft and which comprises, as cutting edges (7, 9), a face cutting edge (7) and a peripheral cutting edge (9). At least one cutting edge (7, 9) forms a positive rake angle (′Ya,′Yr) on the periphery of the milling head (3, 3a, 3b, 3c). The milling cutter (1) is particularly suited for machining light metals, especially for circular milling.

대표청구항 ▼

What is claimed is: 1. A method of milling a magnesium workpiece with an end milling cutter comprising a central longitudinal axis about which said end milling cutter is to be rotated, said end milling cutter comprising: a rotatable shaft comprising an internal channel disposed in said shaft; said

What is claimed is: 1. A method of milling a magnesium workpiece with an end milling cutter comprising a central longitudinal axis about which said end milling cutter is to be rotated, said end milling cutter comprising: a rotatable shaft comprising an internal channel disposed in said shaft; said internal channel being configured to receive and guide chips produced during a cutting process; said internal channel being configured to be operatively connected to a suction device configured to create a suction force in said internal channel to suck chips produced during a cutting process through said internal channel; a milling head being disposed at an end of said shaft and being connected to said shaft to be driven and rotated by said shaft in a cutting operation, wherein said rotatable shaft comprises an inner diameter, said milling head comprises an outer diameter, and the inner diameter of said rotatable shaft is smaller than the outer diameter of said milling head, at least in an area that borders said milling head; and said milling head comprising: an end face being disposed at an end of said end milling cutter and facing away from said shaft; said end face being substantially orthogonal to the longitudinal axis; said end face comprising a substantially flat solid portion being disposed substantially in a plane; a peripheral side surface disposed about the perimeter of said milling head; a cutting structure being configured to cut an object in a cutting process; and said cutting structure comprising: a face cutting edge being disposed to lie in said end face and substantially in the plane of said end face of said milling head; a peripheral cutting edge being disposed to lie in said peripheral side surface of said milling head; at least one of said cutting edges being configured to form a positive rake angle; upon said face cutting edge forming a positive rake angle, said face cutting edge being configured as follows: (a) said face cutting edge and said peripheral side surface forming an angle, across a solid portion of said end face between said face cutting edge and said peripheral side surface, at the intersection of said face cutting edge and said peripheral side surface; said face cutting edge angle comprising an acute angle configured to form a positive rake angle; upon said peripheral cutting edge forming a positive rake angle said peripheral cutting edge being configured as follows: (b) said peripheral cutting edge and said end face forming an angle, across a solid portion of said peripheral side surface between said peripheral cutting edge and said end face, at the intersection of said peripheral cutting edge and said end face; and said peripheral cutting edge angle comprising an acute angle configured to form a positive rake angle; said method comprising the steps of: rotating said rotatable shaft and driving and rotating said milling head; creating a suction force in said internal channel using a suction device operatively connected to said internal channel; bringing said milling head into contact with the magnesium workpiece; cutting the magnesium workpiece with said cutting edges of said end milling cutter and producing magnesium chips; and sucking the magnesium chips into and through said internal channel in said shaft and conducting the magnesium chips away from the magnesium workpiece to essentially prevent combustion of the magnesium chips; and essentially preventing combustion of the magnesium chips. 2. The method according to claim 1, wherein: both the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge are configured to form positive rake angles; and at least one of the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge is at least 10°. 3. The method according to claim 2, wherein: said milling head is formed in one piece from a cutting material; said milling head has an aperture surface for the removal of chips into said internal channel configured to receive and guide chips, which amounts to at least 35% of the cross section surface of said shaft; and said step of sucking magnesium chips into and through said internal channel in said shaft comprises sucking magnesium chips through said aperture surface and into said internal channel. 4. The method according to claim 3, wherein: the height of said milling head is a maximum of 50% of the diameter of said milling head; said milling head is realized with at least three lobes; and said face cutting edge extends from one edge of said milling head to beyond the longitudinal axis of said end milling cutter. 5. The method according to claim 4, wherein said milling cutter comprises at least one of (a) through (f), as follows: (a) said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a fluid feed opening located laterally on said outer shaft; (b) said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a helical fluid channel between said inner shaft and said outer shaft; (c) said internal channel configured to receive and guide chips comprises a diameter; the diameter of said internal channel configured to receive and guide chips is at least 75% of said shaft diameter; (d) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said outer shaft is a maximum of 10% of said shaft diameter; (e) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of the inner shaft is a maximum of 10% of the shaft diameter; and (f) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said inner shaft is less than the wall thickness of said outer shaft. 6. The method according to claim 5, wherein: said peripheral cutting edge is adjacent to a corner cutting edge on said face cutting edge; said corner cutting edge, with reference to the direction of the longitudinal axis of said end milling cutter, is the part of said milling head that is axially the farthest from said shaft; said peripheral cutting edge encloses an angle of twist of at least 10° with the longitudinal axis of said end milling cutter; said milling head has a peripheral step, adjacent to which in the direction toward said shaft is a tapered area of said milling head; said peripheral cutting edge is adjacent to said peripheral step; said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a fluid feed opening located laterally on said outer shaft; said milling cutter comprises a helical fluid channel between said inner shaft and said outer shaft; said internal channel configured to receive and guide chips comprises a diameter; the diameter of said internal channel configured to receive and guide chips is at least 75% of said shaft diameter; the wall thickness of said outer shaft is a maximum of 10% of said shaft diameter; the wall thickness of said inner shaft is a maximum of 10% of said shaft diameter; and the wall thickness of said inner shaft is less than the wall thickness of said outer shaft. 7. A method of milling a light metal workpiece with an end milling cutter comprising a central longitudinal axis about which said end milling cutter is to be rotated, said end milling cutter comprising: a rotatable shaft comprising an internal channel disposed in said shaft; said internal channel being configured to receive and guide chips produced during a cutting process; said internal channel being configured to be operatively connected to a suction device configured to create a suction force in said internal channel to suck chips produced during a cutting process through said internal channel; a milling head being disposed at an end of said shaft and being connected to said shaft to be driven and rotated by said shaft in a cutting operation, wherein said rotatable shaft comprises an inner diameter, said milling head comprises an outer diameter, and the inner diameter of said rotatable shaft is smaller than the outer diameter of said milling head, at least in an area that borders said milling head; and said milling head comprising: an end face being disposed at an end of said end milling cutter and facing away from said shaft; said end face being substantially orthogonal to the longitudinal axis; said end face comprising a solid portion being substantially flat; a peripheral side surface disposed about the perimeter of said milling head; a cutting structure being configured to cut an object in a cutting process; said cutting structure configured to cut in a rotational cutting direction; and said cutting structure comprising: a face cutting edge being disposed to lie in said end face of said milling head; a peripheral cutting edge being disposed to lie in said peripheral side surface of said milling head; at least one of said cutting edges being configured to form a positive rake angle; upon said face cutting edge forming a positive rake angle, said face cutting edge being configured as follows: (a) said face cutting edge having a first portion and a second portion; said first portion of said face cutting edge disposed adjacent said peripheral side surface; said second portion of said face cutting edge disposed away from said peripheral side surface; said first portion of said face cutting edge being configured to be rotationally ahead of, in the rotational cutting direction, to precede rotationally, said second portion of said face cutting edge during use; upon said peripheral cutting edge forming a positive rake angle, said peripheral cutting edge being configured as follows: (b) said peripheral cutting edge having a first portion and a second portion; said first portion of said peripheral cutting edge disposed adjacent said end face; said second portion of said peripheral cutting edge disposed away from said end face; and said first portion of said peripheral cutting edge being configured to be rotationally ahead of, to precede rotationally, said second portion of said peripheral cutting edge during use; said method comprising the steps of: rotating said rotatable shaft and driving and rotating said milling head; creating a suction force in said internal channel using a suction device operatively connected to said internal channel; bringing said milling head into contact with the light metal workpiece; cutting the light metal workpiece with said cutting edges of said end milling cutter and producing light metal chips; and sucking the light metal chips into and through said internal channel in said shaft and conducting the light metal chips away from the light metal workpiece. 8. The method according to claim 7, wherein at least one of the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge is at least 10°. 9. The method according to claim 8, wherein both the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge are configured to form positive rake angles. 10. The method according to claim 9, wherein said milling cutter comprises at least one of (a) and (b) (a) said milling head is formed in one piece from a cutting material; said milling head has an aperture surface for the removal of chips into said internal channel configured to receive and guide chips, which comprises at least 35% of the cross section surface of the outer diameter of said shaft; and said step of sucking light metal chips into and through said internal channel in said shaft comprises sucking light metal chips through said aperture surface and into said internal channel; (b) the height of said milling head is a maximum of 50% of the diameter of said milling head; said milling head is realized with at least three lobes; and said face cutting edge extends from one edge of said milling head to beyond the longitudinal axis of said end milling cutter. 11. The method according to claim 10, wherein said milling cutter comprises at least one of (a) through (h), as follows: (a) said peripheral cutting edge is adjacent to a corner cutting edge on said face cutting edge; said corner cutting edge, with reference to the direction of the longitudinal axis of said end milling cutter, is the part of said milling head that is axially the farthest from said shaft; and said peripheral cutting edge encloses an angle of twist of at least 10° with the longitudinal axis of said end milling cutter; (b) said milling head has a peripheral step, adjacent to which in the direction toward said shaft is a tapered area of said milling head; said peripheral cutting edge is adjacent to said peripheral step; and said shaft is realized with a double wall, with an inner shaft and an outer shaft; (c) said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a fluid feed opening located laterally on said outer shaft; (d) said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a helical fluid channel between said inner shaft and said outer shaft; (e) said internal channel configured to receive and guide chips comprises a the diameter; the diameter of said internal channel configured to receive and guide chips is at least 75% of said shaft diameter; (f) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said outer shaft is a maximum of 10% of said shaft diameter; (g) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said inner shaft is a maximum of 10% of said shaft diameter; and (h) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said inner shaft is less than the wall thickness of said outer shaft. 12. The method according to claim 11, wherein: said peripheral cutting edge is adjacent to a corner cutting edge on said face cutting edge; said corner cutting edge, with reference to the direction of the longitudinal axis of said end milling cutter, is the part of said milling head that is axially the farthest from said shaft; said peripheral cutting edge encloses an angle of twist of at least 10° with the longitudinal axis of said end milling cutter; said milling head has a peripheral step, adjacent to which in the direction toward said shaft is a tapered area of said milling head; said peripheral cutting edge is adjacent to said peripheral step; said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a fluid feed opening located laterally on said outer shaft; said milling cutter comprises a helical fluid channel between said inner shaft and said outer shaft; said internal channel configured to receive and guide chips comprises a diameter; the diameter of said internal channel configured to receive and guide chips is at least 75% of said shaft diameter; the wall thickness of said outer shaft is a maximum of 10% of said shaft diameter; the wall thickness of said inner shaft is a maximum of 10% of said shaft diameter; and the wall thickness of said inner shaft is less than the wall thickness of said outer shaft. 13. A method of milling a workpiece with a milling cutter comprising a central longitudinal axis about which said milling cutter is to be rotated, said milling cutter comprising: a rotatable shaft comprising an internal channel disposed in said shaft; said internal channel being configured to receive and guide chips produced during a cutting process; said internal channel being configured to be operatively connected to a suction device being configured to create a suction force in said internal channel to suck chips produced during a cutting process through said internal channel; a milling head being disposed at an end of said shaft and being connected to said shaft to be driven and rotated by said shaft in a cutting operation, wherein said rotatable shaft comprises an inner diameter, said milling head comprises an outer diameter, and the inner diameter of said rotatable shaft is smaller than the outer diameter of said milling head, at least in an area that borders said milling head; and said milling head comprising: an end surface being disposed at an end of said milling cutter and disposed away from said shaft; said end surface being substantially transverse to the longitudinal axis; said end surface comprising a solid portion; a peripheral side surface being disposed about the perimeter of said milling head; a cutting structure being configured to cut an object in a cutting process; and said cutting structure comprising: an end cutting edge being disposed to lie in said end surface; and a peripheral cutting edge being disposed to lie in said peripheral side surface of said milling head; said method comprising the steps of: rotating said rotatable shaft and driving and rotating said milling head; creating a suction force in said internal channel using a suction device operatively connected to said internal channel; bringing said milling head into contact with the workpiece; cutting the workpiece with said cutting edges of said end milling cutter and producing chips; and sucking the chips into and through said internal channel in said shaft and conducting the chips away from the workpiece. 14. The method according to claim 13, wherein: at least one of said cutting edges is configured to form a positive rake angle; upon said end cutting edge forming a positive rake angle, said end cutting edge being configured as follows: (a) said end cutting edge and said peripheral side surface forming an angle, across a solid portion of said end surface between said end cutting edge and said peripheral side surface; said end cutting edge angle comprising an acute angle; said end cutting edge acute angle being configured to dispose said end cutting edge at a positive rake angle; and upon said peripheral cutting edge forming a positive rake angle said peripheral cutting edge being configured as follows: (b) said peripheral cutting edge and said end surface forming an angle, across a solid portion of said peripheral side surface between said peripheral cutting edge and said end surface; said peripheral cutting edge angle comprising an acute angle to form a positive rake angle; and said peripheral cutting edge acute angle being configured to dispose said peripheral cutting edge at a positive rake angle. 15. The method according to claim 14, wherein: said end surface comprises an end face disposed to face away from said shaft; said solid portion of said end face is disposed to lie substantially in a plane; said end cutting edge comprises a face cutting edge disposed to lie substantially in the plane of said end face; at least one of the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge is at least 10°. 16. The method according to claim 15, wherein: said milling head is formed in one piece from a cutting material; said milling head has an aperture surface for the removal of chips into said internal channel configured to receive and guide chips, which amounts to at least 35% of the cross section surface of said shaft; and said step of sucking chips into and through said internal channel in said shaft comprises sucking chips through said aperture surface and into said internal channel. 17. The method according to claim 16, wherein: the height of said milling head is a maximum of 50% of the diameter of said milling head; said milling head is realized with at least three lobes; and said face cutting edge extends from one edge of said milling head to beyond the longitudinal axis of said milling cutter. 18. The method according to claim 17, wherein both the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge are configured to form positive rake angles. 19. The method according to claim 18, wherein said milling cutter comprises at least one of (a) through (h), as follows: (a) said peripheral cutting edge is adjacent to a corner cutting edge on said face cutting edge; said corner cutting edge, with reference to the direction of the longitudinal axis of said milling cutter, is the part of said milling head that is axially the farthest from said shaft; and said peripheral cutting edge encloses an angle of twist of at least 10° with the longitudinal axis of said milling cutter; (b) said milling head has a peripheral step, adjacent to which in the direction toward said shaft is a tapered area of said milling head; said peripheral cutting edge is adjacent to said peripheral step; said shaft is realized with a double wall, with an inner shaft and an outer shaft; (c) said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a fluid feed opening located laterally on said outer shaft; (d) said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a helical fluid channel between said inner shaft and said outer shaft; (e) said internal channel configured to receive and guide chips comprises a diameter; the diameter of said internal channel configured to receive and guide chips is at least 75% of said shaft diameter; (f) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said outer shaft is a maximum of 10% of said shaft diameter; (g) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said inner shaft is a maximum of 10% of said shaft diameter; (h) said shaft is realized with a double wall, with an inner shaft and an outer shaft; the wall thickness of said inner shaft is less than the wall thickness of said outer shaft; and (i) both the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge are greater than 10°. 20. The method according to claim 19, wherein: said peripheral cutting edge is adjacent to a corner cutting edge on said face cutting edge; said corner cutting edge, with reference to the direction of the longitudinal axis of said milling cutter, is the part of said milling head that is axially the farthest from said shaft; said peripheral cutting edge encloses an angle of twist of at least 10° with the longitudinal axis of said milling cutter; said milling head has a peripheral step, adjacent to which in the direction toward said shaft is a tapered area of said milling head; said peripheral cutting edge is adjacent to said peripheral step; said shaft is realized with a double wall, with an inner shaft and an outer shaft; said milling cutter comprises a fluid feed opening located laterally on said outer shaft; said milling cutter comprises a helical fluid channel between said inner shaft and said outer shaft; said internal channel configured to receive and guide chips comprises a diameter; the diameter of said internal channel configured to receive and guide chips is at least 75% of said shaft diameter; the wall thickness of said outer shaft is a maximum of 10% of said shaft diameter; the wall thickness of said inner shaft is a maximum of 10% of said shaft diameter; the wall thickness of said inner shaft is less than the wall thickness of said outer shaft; and both the rake angle of said face cutting edge and the rake angle of said peripheral cutting edge are over 10°.