DRILLING MILLING TOOL AND METHODS FOR PRODUCING A THROUGH-HOLE

Abstract

A drilling and milling tool (100) for a metallic workpiece, with a drilling and milling shank (120) having a plurality of circumferentially-cutting cutter tips (151, 152, 153, 154) and a plurality of front-end-cutting cutter tips (131, 132). At least one of the front-end-cutting cutter tips (132) is, at the same time, a circumferentially-cutting cutter tip whose radially outermost cutting point or cutting edge section projects, in the radial direction (R), beyond the circumferentially-cutting cutter tips (151 152, 153, 154). The circumferentially-cutting cutter tips (151, 152, 153, 154) are made with straight cutting edges and together these cutting edges produce a cylindrical cut contour. Two methods that can be carried out with the drilling and milling tool (100) for producing a through-going bore in a metallic workpiece.

Claims

1-11. (canceled)

12. A drilling and milling tool (100) for a metallic workpiece (200), the drilling and milling tool comprising: a drilling and milling shank (120) having a plurality of circumferentially-cutting cutter tips (151, 152, 153, 154) and a plurality of front-end cutter tips (131, 132) at a leading end of the shank such that at least one of the front-end cutter tips at the end (132) is, at a same time, a circumferentially-cutting cutter tip having a radially outermost cutting point or cutting edge section projecting, in a radial direction (R), beyond the circumferentially-cutting cutter tips (151, 152, 153, 154), the circumferentially-cutting cutter tips (151, 152, 153, 154) being made with straight cutting edges, and together the straight cutting edges producing a cylindrical cut contour.

13. The drilling and milling tool (100) according to claim 12, wherein the circumferentially-cutting cutter tips (151, 152, 153, 154) are arranged stepwise and overlapping in an axial direction (L) along helical chip flutes (141, 142) extending away from the front-end cutter tips (131, 132).

14. The drilling and milling tool (100) according to claim 13, wherein the drilling and milling shank (120) has two front-end cutter tips (131, 132), from which two helical chip flutes (141, 142) extend away, along which the circumferentially-cutting cutter tips (151, 152, 153, 154) are arranged.

15. The drilling and milling tool (100) according to claim 12, wherein the cutting edges of the circumferentially-cutting cutter tips (151, 152, 153, 154) are designed for either rough-milling or finish-milling.

16. The drilling and milling tool (100) according to claim 15, wherein the cutting edges of the circumferentially-cutting cutter tips (151, 152, 153, 154) have a defined roughness by virtue of either a roughened profile or a ground profile.

17. The drilling and milling tool (100) according to claim 12, wherein the drilling and milling tool comprises at least one face-milling cutter (170).

18. The drilling and milling too! (100) according to claim 12, wherein the drilling and milling tool has internal coolant ducts.

19. A method for producing a through-going bore (210) in a metallic workpiece (200) using a drilling and milling too! (100) having a drilling and milling shank (120) which has a plurality of circumferentially-cutting cutter tips (151, 152, 153, 154) and a plurality of front-end cutter tips (131, 132), at a leading end of the shank, such that at least one of the front-end cutter tips at the end (132) is, at a same time, a circumferentially-cutting cutter tip having a radially outermost cutting point or cutting edge section that projects beyond the circumferentially-cutting cutter tips (151, 152, 153, 154) in a radial direction, the circumferentially-cutting cutter tips (151, 152, 153, 154) are made with straight cutting edges, and together the straight cutting edges produce a cylindrical cut contour, the method comprising the following which are carried out in one working operation: drilling through the workpiece (200) by a forward-feed movement (A) of the drilling and milling tool (100); stopping the forward-feed movement (A) of the drilling and milling tool (100) as soon as the circumferentially-cutting cutter tips (151, 152, 153, 154), on the drilling and milling tool (100), are located inside the bore (210) just produced; and orbital milling (Z) of an inside surface (220) of the bore.

20. A method of producing a through-going bore (210) in a metallic workpiece (200) using a drilling and milling tool (100) having a drilling and milling shank (120) which has a plurality of circumferentially-cutting cutter tips (151, 152, 153, 154) and a plurality of front-end cutter tips (131, 132), at a leading end of the shank, such that at least one of the front-end cutter tips at the end (132) is, at a same time, a circumferentially-cutting cutter tip having a radially outermost cutting point or cutting edge section that projects beyond the circumferentially-cutting cutter tips (151, 152, 153, 154) in a radial direction, the circumferentially-cutting cutter tips (151, 152, 153, 154) are made with straight cutting edges, and together the straight cutting edges produce a cylindrical cut contour, the method comprising the following carried out during one working operation: drilling through the workpiece (200) by forward-feed movement (A) of he drilling and milling tool (100); either face-miffing or fiat countersinking an edge of the bore at an end of the forward-feed movement (A); withdrawing the drilling and milling tool (100) and stopping the withdrawing movement (B) as soon as the circumferentially-cutting cutter tips (151 152, 153, 154) are located inside the bore (210) just produced; and orbital milling (Z) of the inside surface (220) of the bore.

21. The method according to claim 19, wherein the orbital milling is carried out with a non-circular trajectory.

22. The method according to claim 19, wherein the drilling through is full drilling or counterboring.

23. The method according to claim 20, wherein the orbital milling is carried out with a non-circular trajectory.

24. The method according to claim 20, wherein the drilling through is full drilling or counterboring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] Below, the invention will be explained in greater detail, as a non-limiting example, with reference to an example embodiment related to the drawing. Features illustrated in the drawing and/or explained in what follows can also be general features of the invention and further developments of the invention, even independently of illustrated and/or described combinations of features. The drawing shows:

[0030] FIG. 1: A drilling and milling tool, viewed from the side; and

[0031] FIGS. 2A-2C: Show a sequence according to the invention for producing a through-going bore with the drilling and milling tool illustrated in FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0032] The drilling and milling tool 100 shown in FIG. 1 comprises a drilling and milling shank (main body) 120 and a tool holder interface 110. At the front end of the shank 120 are two replaceable cutting tips 131 and 132 whose cuts overlap in the radial direction R. In the shank 120, leading away from the cutters 131 and 132 at the front end there are two helical or spiral chip flutes (chip chambers) 141 and 142. Along these chip flutes 141 and 142 are in each case arranged a plurality (for example four) circumferentially-cutting cutter tips 151, 152, 153 and 154 that overlap in the axial direction L and have straight cutting edges, which are fixed by screwing, brazing or bonding to the webs alongside the flutes 141 and 142 to form cascading or stepped pockets. These circumferentially-cutting cutter tips are for example PCD (polycrystalline diamond) cutters.

[0033] In the view shown, only the four cutter tips 151, 152, 153 and 154 that'are arranged along the visible chip flute 141 can be seen. In the other, out-of-sight chip flute 142 there are also arranged four cutter tips, which in particular have the same orbits or trajectories so that in each case two cutters opposite one another form a cutter pair. Each cutter tip can be cooled by a coolant emerging by way of internal coolant ducts through a coolant outlet 160, such that the coolant outlets 160 for the circumferentially-cutting cutter tips 151 to 154 are located directly in the stepped pockets.

[0034] The drilling and milling tool 100 also comprises a flat cutter tip 170 with a transition chamfer 171 on the inside, which serves for face-milling. Preferably, all the cutter tips 131, 132, 151, 152, 153, 154, and 170 are replaceable. The cutter tips 131, 132, 151, 152, 153, 154, and 170 can also be made from different materials.

[0035] The radially outermost cutter tip 132 on the end of the shank 120 at the same time also cuts circumferentially, since its radially outermost cutting point (see arrow) projects in the radial direction R beyond the cutter tips 151 to 154 arranged around the circumference of the shank, so that the orbit or trajectory of the cutting point has a larger diameter than the orbits or trajectories of the cutting edges of the cutter tips 151 to 154 which only cut circumferentially. Furthermore it is provided that the cutting edges of the only circumferentially-cutting cutter tips 151 to 154, combined together, produce a cylindrical cut or milled contour so that their orbit or trajectory with its smaller diameter forms or describes a uniform, i.e. coherent cylindrical shell surface.

[0036] The drilling and milling tool 100 enables a through-going bore to be produced in a workpiece, for example with a diameter of around 50 mm, and in the same working step enables the inside surface of the bore just produced to be machined. This is explained in more detail below with reference to FIGS. 2A-2C, wherein the procedure described serves, for example, for the production of a bearing seat to hold an outer bearing race of a roller bearing.

[0037] The metallic workpiece 200 is drilled through by rotating and forward-feeding D/A the drilling and milling tool 100 (and/or the workpiece 200 to be drilled through), during which the two front-end cutter tips 131 and 132 are in cutting engagement, whereas the cutter tips 151 to 154 at the circumference of the shank 120, rotating with an orbit or trajectory of smaller diameter, do not come into cutting engagement with the inside surface 220 of the bore. At the end of the actual forward-feed movement A, the edge of the bore is face-milled or even flat-countersunk by means of the flat cutter tip 170, so that by virtue of the chamfer 171 on the flat cutter tip 170 a corresponding chamfer (inlet chamfer, front bevel) is produced at the edge or inlet of the bore. Thus, during the face milling or flat countersinking, chamfering takes place. That sequence is illustrated in FIGS. 2A and 2B, with the optional flat countersinking indicated only by a broken line in FIG. 2B.

[0038] The return movement B of the drilling and milling tool 100 is stopped as soon as the circumferentially-cutting cutter tips 151 to 154 are inside the bore 210 just produced. By orbital machining (orbital milling) Z the inside surface of the bore, or bore wall 220, is now machined, this stage being a milling, rough-milling or finish-machining operation. The cutting edges of the cutter tips 151 to 154 are designed appropriately. In that way the entire inside surface 220 of the bore is machined at the same time. The orbital machining is carried out without any axial relative movement between the drilling and milling tool 100 and the workpiece 200, although in principle there may be an axial relative movement.

[0039] During the orbital machining Z, without loss of time and with the help of at least one additional and correspondingly designed cutter tip on the shank 120 a back-end chamfer at the outlet of the bore can be produced. This simultaneous conjoint production of a back-end chamfer can be called reverse orbiting. Thus, if appropriately designed the drilling and miffing tool according to the invention also enables reverse orbiting for the production of a back-end chamfer at the outlet of the bore 210 previously produced in the workpiece 200. Analogously, during the orbital machining an inlet chamfer can be produced at the bore inlet if this has not already been produced by the face-miffing or flat countersinking.

[0040] After the end of the orbital machining Z, the drilling and milling tool 100 or its shank 120 is positioned concentrically in the bore 120 produced, and withdrawn without contact.

[0041] Another procedure without face milling and/or flat countersinking at the inlet side of the bore is explained above.

[0042] With a suitable design of the drilling and milling tool 100, in principle bore contours which are slightly concave or slightly convex in the axial direction L can also be produced. This is achieved in particular by appropriate design and arrangement of the cutter tips 151 to 154 that only cut circumferentially, to produce a correspondingly convex-cylindrical (barrel-shaped) or concave-cylindrical cut or milled contour. The production of non-circular bore contours is described above.

[0043] The chip flutes 141 and 142 are formed along substantially the full axial length of the drilling and milling shank 120. Thanks to these, both during drilling and during the subsequent milling effective clearing of the chips from the front-end and circumferentially-cutting cutter tips 131, 132, 151, 152, 153 and 154 can be ensured. Owing to the staggered arrangement of the circumferentially-cutting cutter tips 151 to 154 along the chip flutes 141 and 142, the flutes are not, or only slightly clogged or damaged by the chips produced (no direct impact) and also are not subject to any premature wear, so that the tool has a long life.

INDEXES

[0044] 100 Drilling and miffing tool [0045] 110 Tool holder interface [0046] 120 Drilling and milling shank [0047] 131 Cutter tip [0048] 132 Cutter tip [0049] 141 Chip flute [0050] 142 Chip flute [0051] 151 Cutter tip [0052] 152 Cutter tip [0053] 153 Cutter tip [0054] 154 Cutter tip [0055] 160 Coolant outlet opening [0056] 170 Flat cutter tip [0057] 171 Chamfer [0058] 200 Workpiece [0059] 210 Bore [0060] A Forward-feed movement [0061] B Return movement [0062] D Rotation movement [0063] L Axial direction [0064] R Radial direction [0065] Z Orbital machining