The present invention relates to a rotary cutting tool such as a face milling cutter or a corner milling cutter having means for adjusting the axial position of the individual throwaway inserts relative to the tool body and to each other.
In finish milling, it is important to arrange the cutting edges of throwaway inserts with high positional accuracy. Any axial displacement of the cutting edges of the inserts may result in a rough finished surface of the workpiece, chatter, burrs and/or a shortened life of the tool.
There are various proposals for adjusting or eliminating such axial displacement of the cutting edges of inserts, including those disclosed in the following patent documents 1 to 4.
Patent document 1: JP patent publication 2001-252813A
Patent document 2: JP utility model publication 7-27719
Patent document 3: JP utility model publication 3064324
Patent document 4: JP patent publication 2002-516762A
Patent document 1 discloses a face milling cutter including a plurality of throwaway inserts. Each insert has its back and one of its side faces that faces toward the axis of the tool seated on insert-mounting seats formed on the tool body. Also, each insert has its other side face that faces toward the proximal end of the tool supported by a pushpin that can be moved by an adjusting screw. In this arrangement, since the pushpins for the respective inserts are moved axially of the tool, no reference positions are set for the respective inserts in the axial direction of the tool. Thus, when the inserts are replaced with new ones, or their positions are changed, it is necessary to adjust the axial positions of all of the inserts. A long time is needed for such adjustment. Instead of such pushpins, some other prior art proposes to use wedges for axially advancing the inserts by moving its tapered surface. This arrangement has the same problem as mentioned above.
Patent document 2 proposes a cutter including an adjusting element fixed to the tool body by means of a wedge and having a resiliently deformable portion. Using the resiliently deformable portion as the reference position of the insert, this portion is resiliently deformed by advancing a bolt threaded into the adjusting element to adjust the axial position of the insert. In this arrangement, since the insert is retracted utilizing the elastic restoring force of the resiliently deformable portion, the axial position of the insert tends to vary, so that adjustment is difficult. When the resiliently deformable portion is deformed, the yield point may be exceeded. Over a long period of use, the resiliently deformable portion tends to be fatigued. Accumulated fatigue could cause the resiliently deformable portion to lose its restoring force or to be damaged.
Patent documents 3 and 4 disclose groove milling cutters having means for adjusting the axial positions of the cutting edges of inserts. Each insert is received in a pocket of which the wall is partially resiliently deformable. A ball is pressed against the resiliently deformable portion of the wall by means of an adjusting screw to move the insert received in the pocket and thus its cutting edge. This arrangement has the same problems as the arrangement of Patent document 2. That is, since the pocket wall does not always return to the original position when the ball is retracted, it may be necessary to apply greater pressure to the wall with the ball next time to advance the cutter to the same position as before. Thus, when the pocket wall is repeatedly deformed, the yield point may be eventually exceeded. If the yield point is exceeded, the pocket wall will never return to its original position. In the worst case, it may be damaged.
Further, in order to uniformly deform the resilient portions of the plurality of pocket walls by applying equal pressures thereto, their thicknesses have to be strictly uniform. In order to form pocket walls having strictly uniform thicknesses, extremely sophisticated and difficult techniques, as well as long time, are needed.
Conventional cutters having mechanisms for adjusting the axial positions of the individual inserts are designed to bear loads applied to the inserts during rough cutting on the adjusting mechanisms themselves. Thus, the inserts cannot be supported reliably. Also, since the axial reference surfaces (displaceable surfaces) tend to fluctuate, it is often necessary to adjust the positions of the reference surfaces even before rough cutting. Such cutters are therefore not suitable for use in rough cutting.
An object of the present invention is to provide a rotary cutting tool which can be used both for rough cutting and finish cutting in a stable manner, and which has means for individually adjusting the axial positions of the cutting edges of a plurality of throwaway inserts which is simple in structure.
According to the present invention, there is provided a rotary cutting tool comprising a tool body formed with a plurality of insert-mounting grooves in an outer periphery thereof at a front end thereof, throwaway inserts each having a cutting edge, a back face and four side faces, and received in one of the insert-mounting grooves, clamp means each for detachably securing one of the inserts to the tool body, adjusting screws each for adjusting axial position of one of the inserts, the insert-mounting grooves each having three seating faces for positioning one of the inserts in rotational, radial and axial directions of the tool by coming into contact with the back face and two adjacent ones of the four side faces, respectively, each of the adjusting screws being threadedly engaged in the tool body so as to extend substantially in the axial direction of the tool near one of the insert-mounting grooves such that one end thereof is movable axially in either direction from one of the three seating faces for positioning the corresponding insert in the axial direction of the tool, whereby each of the inserts can be positioned in the axial direction of the tool by the one of the three seating faces and by the one end of one of the adjusting screws.
Preferably, each of the adjusting screw is formed with a head at the one end, the head being formed with an engaging portion for engaging a tool for driving each of the adjusting screws, each of the adjusting screws being threaded into the cutter body from the front end of the cutter body such that the engaging portion is exposed outside, the head having an end face adapted to abut one of the side faces of each of the inserts that faces toward the rear end of the tool body.
Each insert is positioned axially either by the seating face for axially positioning the insert or by the adjusting screw. During rough cutting, the adjusting screw should be retracted so as to axially position the insert by seating the insert on the seating face for axially positioning the insert. During finish cutting, only an insert or inserts that are axially offset from the other inserts are axially moved and positioned by the corresponding adjusting screws.
During rough cutting, the inserts are positioned by the seating faces of the insert-mounting grooves only without the need for position adjustment using the position adjusting mechanisms (adjustment for canceling any displacement from the reference surfaces). Since three sides of each insert are restrained during rough cutting, rough cutting can be carried out in a stable manner.
Before finish cutting, the inserts are temporarily positioned in the respective insert-mounting grooves to find any insert or inserts that are axially retracted from the most advanced insert or inserts by more than a predetermined distance. Then, only such axially retracted insert or inserts are pushed forward by turning the corresponding adjusting screws. It is not necessary to move all of the inserts. Since the adjusting screws are rigid members having least resilience, they are never resiliently deformed to move and support the inserts. Thus, they can support the inserts much more reliably than conventional resilient adjusting means. Adjustment is made much more quickly, too. Since the adjustment mechanism for each insert is practically a single adjusting screw, it is extremely simple in structure.
A single rotary cutter according to the present invention can be used both for rough cutting and finish cutting. There is no need to prepare two different kinds of cutters for rough cutting and finish cutting. A single cutter would be substantially less expensive than two cutters and its maintenance would be much easier.
[
[
[
[
[
[
1. Cutter body
2. Throwaway insert
2
a. Back
2
b,
2
c. Side face
3. Clamp means
3
a. Clamp screw
3
b. Threaded hole
3
c. Clamp piece
4. Adjusting screw
4
a. Top
4
b,
4
c. Engaging portions
5. Insert-mounting groove
5
a,
5
b,
5
c. Seating face
Hereinbelow, the rotary cutting tools embodying the invention are described with reference to
Insert-mounting grooves 5 are formed in the outer periphery of the cutter body 1 at its distal end. As shown in
The clamp means 3 each comprise a clamp screw 3a inserted in a countersunk hole formed through the center of each insert 2 and threaded into a threaded hole 3b formed in the seating face 5a of each groove 5 (
Each adjusting screw 4 has turning portions (spanner engaging portions) 4b and 4c on the top 4a and side of its head. Each adjusting screw 4 is driven into the tool body 1 near each groove 5 with its head facing toward the distal end of the tool body 1. In this state, the screw 4 has to be turnable in either direction so as to protrude or retract from the seating face 5c. The adjusting screw 4 may be driven into the tool body 1 obliquely relative the axis of the tool so that the top 4a of its head will make surface contact with the side face 2c.
When mounted to the tool body 1, the inserts 2 should be arranged such that their cutting edges are axially offset from one another by a distance not exceeding 10 micrometers, preferably not exceeding 5 micrometers.
The adjusting screws 4 are positioned so that their tops 4a are slightly retracted from the respective seating faces 5c. In this state, the inserts 2 are set in the respective grooves 5 with their backs 2a and adjacent side faces 2b and 2c seated on the seating faces 5a to 5c of the respective grooves 5, and then the clamp screws 3a are passed through the countersunk holes of the respective inserts 2 and threaded into the threaded holes 3b to securely fix the inserts 2 to the tool body 1. In this state, if each insert can be axially positioned suitably, its side face 2c may be in contact with the top 4a of the head of the adjusting screw 4.
In this state, workpieces are cut roughly. Then, the workpieces are finished. In finishing the workpieces, if it is necessary to narrow the axial displacement of the cutting edges of the inserts, with the backs 2a and side faces 2b and 2c of the respective inserts 2 pressed against the seating faces 5a to 5c, the clamp screws 3a are loosened, and then, any insert or inserts of which the cutting edges retract from the cutting edge of the most advanced one of the inserts are advanced axially by turning the corresponding adjusting screws 4 until their cutting edges substantially align with the cutting edge of the most advanced insert in a direction perpendicular to the axis of the tool.
The clamp means 6 of the embodiment of
In the embodiment, the adjusting screws 4 are turned by inserting a screwdriver from the distal end (front end) of the tool. But instead, the turning tool 4 may be structured such that the adjusting screws 4 are turned by inserting a screwdriver from the proximal end (rear end) of the tool.
The inserts 2 of the invention are not particularly limited. For example, they may have their cutting edges formed of sintered diamond members 2d brazed to their substrates as shown in
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP05/06067 | 3/30/2005 | WO | 00 | 1/27/2009 |