Field of the Invention

The present invention relates to an end mill comprising an end mill head having a pull rod secured thereto and a shank having a hole into which the pull rod is fitted, said end mill head having a cutting edge and said end mill having a center axis. The invention further relates to an end mill head and methods for securing an end mill head to a shank.

Prior Art

A previously known end mill with a detachable head is disclosed in JP patent document No. 57-189713. The known tool includes a neck portion which is integral with the end mill head, which neck portion constitute a potential breakage area for the tool. Another problem with such prior art is that it have been found unstable in some high speed applications, due to the lack of support at radially outwards surfaces. In addition unnecessarily expensive tool material is used in the neck portion.

Objects of the Invention

An object of the present invention is to provide a ball nose end mill in which performance and useful life are improved.

Another object of the present invention is to provide a ball nose end mill which has an extremely good stability such that a machined surface can be obtained which is substantially free from chatter marks.

Still another object of the present invention is to provide an easily mountable ball nose end mill .

Still another object of the present invention is to provide a ball nose end mill which due to its configuration saves expensive cutting tool material.

Description of the Drawings

The present invention will be explained in more detail by referring to the accompanying drawings, wherein: Fig. 1A is an exploded and sectioned side view showing an embodiment of a ball end mill according to the present invention,

Fig. IB is a magnified side view showing the ball end mill of Fig. 1A as assembled, Fig. 2 is a top view of an end mill head according to the present invention,

Figs. 3A and 3B are side views of the end mill head,

Fig. 4 is a bottom view of a lower side of the end mill head, Fig. 5 is a cross-sectional view of the end mill head along line V-V in Fig. 3A,

Fig. 6 is a perspective view of the end mill head.

CONFIRMATION COPY

Fig. 7A is an exploded and sectioned side view an alternative embodiment of a ball end mill according to the present invention.

Fig. 7B is a magnified side view showing the ball end mill of Fig. 7A as assembled,

Fig. 8 is a top view of an alternative end mill head according to the present invention,

Figs. 9A and 9B are side views of the alternative end mill head, Fig. 10 is a bottom view of a lower side of the alternative end mill head,

Fig. 11 is a cross-sectional view of the alternative end mill head.

Fig. 12 is a cross-sectional view of the alternative end mill head along line XII-XII in Fig 11A,

Fig. 13 is a perspective view of the alternative end mill head.

Detailed Description of the Invention Figs. 1A and IB show an embodiment of a detachable ball nose end mill 10 according to the present invention. The end mill 10 comprises a mill head 11, a pull rod or screw 12 and a shank 13. The pull rod 12 is threaded into the mill head 11 and the pull rod is further connected to the shank 13. The shank is preferably held in a rotatable spindle in a milling or drilling machine, not shown The shank 13 has a hole 14 into which the pull rod 12 is fitted. The end mill head 11 has cutting edge means 15, such as two identical cutting edges 16 extending at least from the outermost point of the head towards the center axis 17 of the tool. The cutting edge means 15 may alternatively include three or four identical cutting edges. The cutting edges 16 preferably meet in the vicinity of the center axis 17. The end mill head and the shank comprise cooperating abutment surfaces 19 and 20 The abutment surfaces are preferably planar and extend generally perpendicularly to the center axis 17 of the end mill. Preferably the cutting edge means 15 follow a path, which is larger than 180° so as to allow outcopying during upwardly directed feed. The path is preferably circular and its largest diameter is larger than the diameter of the abutment surface 19 and the diameter of the shank. The largest diameter of the abutment surface 19 of the mill head and the outer diameter of the abutment surface 20 of the shank are substantially identical. Each cutting edge 16 lies in a plane P which forms an acute angle β with the center axis 17, when seen in a view as shown m Fig. 3B The angle β is 5 to 15°, preferably about 10°. The pull rod 12 is separable from the end mill head by means of threads 18 or bayonet means, the latter not shown. The end mill head does not extend axially rearwards of the plane of the surfaces 19 and 20 The pull rod and the end mill head comprise conical cooperating centering surfaces 21 and 22 The centering surfaces 21 and 22 taper at an acute angle α relative to the

center axis 17 towards an axially forward free end 34 of the pull rod, Fig. IB. The angle α is between 1 to 20°, preferably 5 to 10° . The end mill head is made from material harder than the material of the pull rod. The end mill head is manufactured by mixing powder of sintered hard alloy or cermet with an organic binder such as plastics and forming the mixture to pellets or granulates, moulding the pellets or granulates according to an injection moulding process and sintering the obtained product at a temperature of 1300 to 1500°C. The pull rod is preferably made from steel, which is relatively inexpensive. The free ends of the pull rod comprise fastening means, such as threads 23 and 25 and/or bayonet means, for engagement with corresponding fastening means 18 and 24, respectively, in the end mill head and in the shank. The end mill head has holes 26 for promoting pressurized medium, such as air or liquid, to remove chips and the medium is supplied from the tool holder, not shown. The end mill head comprises external key grip means 27 for mounting and dismounting. The end mill head 11 for cutting material during its revolution about the center axis 17 further comprises clearance means 28, a first recess 29, having centering means 22 therein, and a second recess 30, having fastening means 18 therein. At least two substantially parallel flushing channels 26 are provided in the end mill head, extending from the second recess 30 and terminating in chip flutes or rake faces 31 of the end mill head. The recesses 29, 30 make a penetrated blind hole, i.e. a hole with a certain depth at which the flushing channels 26 connect. Said hole has a substantially decreasing cross-sectional area in direction towards the cutting edge means 15.

The elongated pull rod to be used in the rotatable ballnose end mill further comprises key grip means 32 and 33, such as hexagon wrench holes for Allen keys, at the first free end 34 and a second free end 35, respectively. The centering surface 21 is provided closer to the first free end 34 than to the second free end 35 of the pull rod. The diameter of the first free end 34 is smaller than the diameter of the second free end 35. A longitudinally extending hole 36 is provided in the pull rod, said hole extending from one free end to another for the promotion of pressurized medium, such as liquid or air. Medium to remove chips is supplied through the hole 36 and the flush channels. Now, a mounting and dismounting method for the detachable ball nose end mill will be described below primarily in connection with Figs. 1A and IB. The pull rod 12 is mounted by inserting the rod into the hole 14 of the shank 13 and by rotating the rod with a key, not shown, in the grip 32 or 33 to a predetermined depth. The threads 25 of the rod will then engage the threads 24 of the shank. The portions 37 and 38 are manufactured with small tolerances so as to provide a slip fit and to minimize relative radial movement. Preferably at least one of the threads 24 and 25 is provided

with a locking medium, such as plastics, so as to increase the resistance against unscrewing.

The end mill head 11 is then placed over the free end 34 of the rod and is rotated such that the engagement of threads 18 and 23 draw the head axially towards the shank until the centering surfaces 21 and 22 engage and center the mill head. Further rotation of the head, by means of a wrench acting externally on the key grip means 27, will result m rotation also of the rod 12 until the abutment surfaces 19 and 20 will come into contact and stop further axial movement of rod and head.

In an alternative mounting procedure the end mill head and the pull rod are joined together such that the centering surfaces 21, 22 engage and then the rod and the head are threaded as a unit into the shank hole 14, until the abutment surfaces 19, 20 engage and stop further axial movement of rod and head

The above-described threads are provided such that the forces acting on the cutting edge means 15 will tend to further tighten them if not already tightened This will also be the case if an alternative fastening means, for example a bayonet coupling, is used.

When the cutting edge means 15 has become worn and the head 11 shall be replaced, then the above procedure concerning the head, is reversed. Since the threads 24 and 25 are more tightly interconnected due to the locking medium, these threads will not unscrew during unscrewing the head. Therefore a new head may be mounted without loosening the rod 12. An alternative, preferable, method for mounting and dismounting the detachable ball nose end mill is hereinafter described. First, the head and the pull rod are joined together via the threads 18 and 23 until the centering surfaces 21, 22 come in contact. Then the rod and the head are threaded as a unit into the shank hole 14, until the abutment surfaces 19, 20 engage and stop further axial movement of rod and head.

Referring now to Figs. 7A through 13, an alternative embodiment of a tool according to the present invention will be described. It is understood that like numerals depict like details as described in connection with the previous embodiment . Figs 9A and 9B show an embodiment of a detachable ball nose end mill 10 comprising a mill head 11' , a pull rod or screw 12' and a shank 13' . The pull rod 12' is screwn into the mill head 11' and the pull rod is further connected to the shank 13' . The shank 13' has a hole 14' into which the pull rod 12' is fitted. The end m ll head 11' has cutting edge means 15' such as two identical cutting edges 16' extending at least from the outermost point of the head towards the center axis 17' of the tool The cutting edge means 15' may alternatively include three or four identical cutting edges. The cutting edges 16' preferably meet in the vicinity of the center axis 17' . The end mill head and the

shank comprise cooperating abutment surfaces 19' and 20' The abutment surfaces are preferably planar and extend generally perpendicularly to the center axis 17' of the end mill. Preferably the cutting edge means 15' follow a path, which is larger than 180° so as to allow outcopying during upwardly directed feed. The path is preferably circular and its largest diameter is larger than the diameter of the abutment surface 19' and the diameter of the shank. The largest diameter of the abutment surface 19' of the mill head and the outer diameter of the abutment surface 20' of the shank are substantially equal Each cutting edge 16' lies m a plane P' which forms an acute angle β' with the center axis 17' , when seen m a view as shown in Fig. 9B The angle β' is 5 to 15°, preferably about 10° The pull rod 12' is separable from the end mill head by means of threads 18' or bayonet means, the latter not shown. The end mill head extend partially axially rearwards of the plane of the surfaces 19' and 20' The shank and the end mill head comprise substantially cylindrical cooperating centering surfaces 21' and 22' , respectively The centering surface 21' of the shank is located in a recess 40' m the forward free end of the shank. The centering surface 22' of the mill head is located externally on a projection 41' extending rearwardly of the abutment surface 19' , a distance L. The centering surfaces 21' and 22' extend substantially parallel to the center axis 17' . The end mill head is made from material harder than the material of the pull rod. The threads 25' of the rod will then engage the threads 24' of the shank. The end mill head is manufactured by mixing powder of sintered hard alloy or cermet with an organic binder such as plastics and forming the mixture to pellets or granulates, molding the pellets or granulates according to an injection molding process and sintering the obtained product at a temperature of 1300 to 1500°C. The pul] rod is preferably made from steel, which is relatively inexpensive The free ends of the pull rod comprise fastening means, such as threads 23' and 25' and/or bayonet means, for engagement with corresponding fastening means 18' and 24' , respectively, in the end mill head and in the shank. The end mill head has holes 26' for promoting pressurized medium, such as air or liquid, to remove chips and the medium is supplied from the tool holder, not shown. The end mill head comprises external key grip means 27' for mounting and dismounting.

The end mill head 11' for cutting material during its revolution about the center axis 17' further comprises clearance means 28' , a first recess 29' , having centering means 22' therein, and a second recess 30, having fastening means 18' therein. At least two flushing channels 26' are provided in the end mill head, extending from the second recess 30' and terminating m chip flutes or rake faces 31' of the end mill head.

The elongated pull rod to be used n the rotatable ballnose end mill further comprises key grip means, such as

hexagon wrench holes for Allen keys, at the first free end 34' and a second free end 35' , respectively. The diameter of the first free end 34' is smaller than the diameter of the second free end 35' . A longitudinally extending hole 36' is provided in the pull rod, said hole extending from one free end to another for the promotion of pressurized medium, such as liquid or air. Medium to remove chips is supplied through the hole 36' and the flush holes 26' .

Now, a mounting and dismounting method for the detachable ball nose end mill will be described below primarily m connection with Figs. 7A and 7B The pull rod 12' is mounted by inserting it into the hole 14' of the shank 11' and by rotating the rod w th a key, not shown, from the front or from the rear into the grip means 32' or 33' , respectively, to a predetermined depth. The threads 25' of the rod will then engage the threads 24' of the shank.

The end mill head 11' is then placed over the free end 34 ' of the rod and is rotated such that the engagement oi threads 18' and 23' draw the head axially towards the shank until the centering surfaces 21' and 22' engage and centei the mill head The surfaces 21' and 22' are manufactured with small tolerances so as to provide a slip fit and to minimize relative radial movement. Preferably at least one of the threads 24' and 25' is provided with a locking medium, such as plastics, so as to increase the resistance against unscrewing. Further rotation of the head, by means of a wrench acting externally on the key grip means 27' , will result in rotation also of the rod 12' until the abutment surfaces 19' and 20' will come m contact and stop further axial movement of rod and head.

The above-described threads are provided such that the forces acting on the cutting edge means 15' will tend to further tighten them if not already tightened. This will also be the case if an alternative fastening means, for example a bayonet coupling, is used.

When the cutting edge means 15' has become worn and the head 11' shall be replaced, then the above procedure concerning the head, is reversed. Since the threads 24' and 25' are more tightly interconnected due to the locking medium, these threads will not unscrew during unscrewing the head. Therefore a new head may be mounted without loosening the rod 12' .

An alternative, preferable, method for mounting and dismounting the detachable ball nose end mill is hereinafter described. First, the head and the pull rod are joined together via the threads 18' and 23' preferably until the rod reaches the bottom of the thread 18' Then the rod and the head are threaded as a unit into the shank hole 14' , until the abutment surfaces 19' , 20' engage and stop further axial movement of rod and head

There are several common features m the two embodiments of a tool according to the present invention, described above. The end mill heads are preferably made in

injection moulded tungsten carbide and have integrated threads placed axially forwards of the planar abutment surfaces. The mill head describes the largest diameter of the entire tool. There is provided only a frictional connection - between the mill head and the shank in the rotational direction of the tool . The pull rods are externally threaded at all free ends and they include a central channel for distribution of a flush medium to be transferred to a widened space and successively through the flush channels to the 0 cutting edge area. The pull rod is positioned m the vicinity of the forward end of each shank. There are key grips for rotation of each end mill head during assembling.

The centering principals however, of each embodiment of the tool according to the present invention differ m that 5 in the first case the centering surfaces are positioned internally in the mill head and externally on the pull rod while tapering forwardly. In the other case, the centering surfaces are positioned externally on the mill head and internally on the shank while being parallel with the ^(" rotational axis of the tool.

Although the present invention has been described m connection with preferred embodiments thereof, it will be appreciated by those skilled in the art that additions, deletions, modifications, and substitutions not specifically 5 described may be made without departing from the spirit and scope of the invention as defined in the appended claims.