WO2022105953A2

WO2022105953A2 - Disc cutter body for machining of solid materials

Info

Publication number: WO2022105953A2
Application number: PCT/CZ2021/050139
Authority: WO
Inventors: Pavel Kožmín; Jiří Syrovátka; Robin Poul
Original assignee: Hofmeister S.R.O.
Priority date: 2020-11-23
Filing date: 2021-11-22
Publication date: 2022-05-27
Also published as: JP2023549997A; CZ2020628A3; WO2022105953A3; CZ308950B6

Abstract

A disc cutter body includes a hub (1), a transient portion (2) containing a composite material (CFRP) comprising wound and laid carbon fibres with density of the composite material ranging from 1.5 to 1.9 g/cm3, and a rim (3) provided with multiple connection sockets for connection of cutting inserts (5). The hub (1) and the rim (3) are linked up by a self-supporting composite material only to limit transfer of undesired high-frequency oscillations from the hub (1) to the rim (3), and vice versa. A glued joint is used on the connection surfaces (10) between the hub (1) and the transient portion (2), and between the transient portion (2) and the rim (3). The transient portion (2) includes at least one plate body (8) made of the composite material. The boundary contour (7) of a connection surface (10) between the hub (1) and the transient portion (2) and/or between the transient portion (2) and the rim (3) has regular undulated shape with a defined distance of wave peaks on the circle for torque transfer from the hub (1) to the transient portion (2) and/or from the transient portion (2) to the rim (3).

Description

Disc cutter body for machining of solid materials

Field of the invention

The present invention relates to the field of a structure of a hybrid machining body characterized in a topology consisting of joining of individual steel components to each of components manufactured from composite materials (CFRP) in order to achieve improved final dynamic properties of the whole miling tools for machining in machine tools.

Background of the invention

A precise material selection and structural embodiment of milling tools to provide a perfect machining quality and long life of the milling tools is necessary owing to growing demands for highly precise machining of solid materials (in particular aluminium alloys in automotive). A milling tool of long life and for quality machining is disclosed in CZ 2,019,137. The milling tool includes a gripping portion being connected through a transient portion to the cutting portion adapted for attaching of at least one cutting insert. At least partially, the transient portion includes a composite material (CFRP) comprising wound carbon fibres. The gripping portion and cutting portion are connected through self-supporting composite material only to avoid transfer of undesirable high-frequency oscillations from the gripping portion to the cutting portion, and vice versa.

Geometry and structure of the body in a rotary version describes a cutting head for machining in three axes. A connection surface between the gripping portion and the transient portion and between the transient portion and the cutting portion has a cylindrical, or conical, rotary shape.

CZ 201429677 U discloses a rotary holder for a cutting tool. The holder includes a steel base body provided with a composite winding of continuous carbon fibres and polymer binder. The composite winding serves to attenuate the oscillations of the cutting tool gripped in the holder. US 6,273,924 Bl discloses a milling tool in the form of a disc cutter. The milling tool includes the disc carrier of carbon composite provided with a central fastening hole. Separate cutting inserts are placed across the circumference of the disc carrier surface. A common disadvantage of the solutions in the art is in particular insufficient attenuation of vibrations by a milling tool embodied as a disc cutter. It is therefore the purpose of the present intention to provide a structure of a disc cutter body of low inertial masses and excellent properties of vibrations attenuation that occur in the course of the machining to provide highly accurate machining.

Summary of the invention

Disclosed herein is a structure of a disc cutter body for machining of solid materials. The solid materials the disc cutter is intended for may, in particular, include alloys, thermoplastics, reactoplastics, or composite materials. The body includes a hub to fasten the cutter in a machine tool known from the art. The hub has attached a transient portion thereon containing the composite material (CFRP) comprising wound and laid carbon fibres. Density of the composite material ranges from 1.5 to 1.9 g/cm³ The transient portion has attached a rim thereon provided with a set of connection sockets for connection of cutting inserts. A disc cutter emerges after the cutting inserts are attached onto the body.

The hub and the rim are linked up through the self-supporting composite material only. The purpose of said arrangement is to limit the transfer of undesired high-frequency oscillations during machining from the hub to the rim, and vice versa. A glued joint is used on the connection surfaces between the hub and the transient portion, and between the transient portion and the rim.

The transient portion contains at least first plate body of the composite material. A boundary contour of the connection surface between the hub and the transient portion, and/or between the transient portion and the rim has a regular undulated shape with a defined distance between the wave peaks on the circle. The boundary contour is a projection of the connection surface on the body side surface. In other words, the regular undulated shape has a defined wave peak pitch on imaginary pitch circle. The purpose of shaping of the connection surface is to improve stiffness of the body, which improves attenuation of vibrations, and torque limit the connection is capable of transferring from the hub to the transient portion, and/or from the transient portion to the rim.

To achieve high level of torque transfer and high stiffness of the body, it is favourable when the boundary contour of the connection surface comprises a set of smooth linked curves consisting of straight line and circle segments. Further, the boundary contour of the connection surface may be mathematically defined by a polynomial function of higher order of at least 3. The smallest radius R of any curvature of the boundary contour of the connection surface is at least 0.5 mm.

To improve stiffness of the body and the torque transfer limit, the boundary contour of the connection surface may be different in its shape or size on the first (e.g., right) side of the body, and/or phase-rotated according to the body rotation axis against the boundary contour of the connection surface on the other (e.g., left) side of the body.

In favourable embodiment, the transient portion may further include at least second plate body connected to the first plate body. The plate bodies are located so that they have a common rotation axis. In particular, the glued joint may be used for their mutual link. This is in particular for reasons of production (available material thickness from which the transient portion may easily be produced), however, in some cases the transient portion consisting of the joint plate bodies may have a positive impact on the body stiffness and attenuation of vibration. In addition to the first plate body and the second plate body, the transient portion may also include other plate bodies located and connected likewise to the first plate body and the second plate body.

In the described case of use of at least two plate bodies, the boundary contour of the connection surface of the first plate body may be different in its shape or size and/or phase- rotated according to the body rotation axis against the boundary contour of the connection surface of at least second plate body. Thereby, stress and vibrations occurring during the machining are distributed to multiple wave peaks (wave peaks of the first plate body and unequally located wave peaks of at least second plate body). This results in improved attenuation properties and higher body stiffness.

When using at least two plate bodies it is favourable if the first plate body is provided with multiple holes in which bolts are placed perpendicularly to the first plate body surface. Body of each bolt is then arranged outside the area of at least second plate body, and fastened in either hub or rim. This may be favourably achieved by said phase rotation of the plate bodies where the wave peaks of the first plate body get in the valley between two adjacent wave peaks of at least second plate body. A hub or rim projection provided with a thread to which each bolt from the first plate body is fastened penetrates to said valley of at least second plate body. To achieve maximum strength of the glued joint, it is favourable if the hub surface and/or rim surface and/or transient portion surface is made coarse on at least part of the connection surface for receiving the adhesive. Such coarse part may have in particular a form of a set of grooves.

Description of drawings

The exemplary embodiment of the proposed technique is described with reference to the drawings, where:

Fig 1 - is general oblique right-hand sided view on the cutter with the body having its transient portion from the first plate body and the second plate body, wherein the boundary contour of the connection surface between the hub and the transient portion as well as between the transient surface and the rim is a set of smooth linked curves consisting of the straight line and circle segments;

Fig. 2 - is general oblique left-hand sided view on the cutter from Fig. 1;

Fig. 3 - is cross-section of the cutter from Fig. 1 and Fig. 2;

Fig. 4 - is semi-finished rim (still without the connection sockets for attaching of the cutting inserts) with two connection surfaces for fitting of the first plate body and the second plate body of the body from Fig. 1 to Fig. 3.

Exemplary embodiment of the invention

The exemplary embodiment of a disc cutter body for machining of solid material includes a hub 1 for fastening of the cutter to a machine tool. The hub 1 has attached a transient portion 2 thereon containing a composite material (CFRP) comprising wound and laid carbon fibres. In this case, the density of the composite material is 1.7 g/cm³.

The transient portion 2 has attached a rim 3 thereon provided with a set of connection sockets for connection of cutting inserts 5. The hub 1 and the rim 3 are linked up through the self- supporting composite material only. The transition of undesirable high-frequency oscillations during machining from the hub 1 to the rim 3, and vice versa, is limited thereby. A glued joint is used on the connection surfaces 10 between the hub 1 and the transient portion 2, and between the transient portion 2 and the rim 3.

The transient portion 2 includes a first plate body 8 and a second plate body 8’ made of said composite material. The second plate body 8’ is connected to the first plate body 8 using the glued joint and located so that they have a common rotation axis.

Boundary contours 7 of connection surfaces 10 of the first plate body 8 and the second plate body 8’ between the hub 1 and the transient portion 2 have regular undulated shape with a defined distance between the wave peaks on a circle to improve the body stiffness and torque transfer limit from the hub 1 to the transient portion 2. The boundary contour 7 of the connection surface 10 is a set of smooth linked curves consisting of straight line and circle segments of the radius R of at least 1 mm. The same shape is used also for the boundary contours 7 of the connection surfaces 10 between the transient portion 2 and the rim 3 for torque transfer from the transient portion 2 to the rim 3.

The boundary contour 7 of the connection surface 10 on the first body side (hence on the first plate body 8) is phase-rotated according to body rotation axis against the boundary contour 7 of the connection surface 10 on the other body side (hence on the second plate body 8 ).

The first plate body 8 is provided with multiple holes in which bolts 9 are placed perpendicularly to the surface of the first plate body 8, The body of each bolt 9 runs through the first plate body 8, is arranged outside the area of the second plate body 8’ and fastened in the hub 1 or in the rim 3.

The second plate body 8’ is likewise provided with multiple holes in which bolts 9 are placed perpendicularly to the surface of the second plate body 8\ Body of each bolt 9 runs through the second plate body 8’, is arranged outside the area of the first plate body 8 and fastened in the hub 1 or in the rim 3. A coarse surface is made on a part of the connection surfaces 10 of the hub 1 and of the rim 3 for application of glue.

Said body is provided with multiple cutting inserts 5 attached to the connection sockets, and the disc cutter is formed thereby.

The exemplary embodiment is shown in Fig. 1 to Fig. 4. List of reference numerals

1 - hub

2 - transient portion

3 - rim

5 - cutting insert

7 - boundary contour

8 - first plate body

8’ - second plate body

9 - bolt

10 - connection surface

Claims

1. A disc cutter body for machining of solid material including a hub (1) for fastening of the cutter to a machine tool, a transition portion (2) attached to the hub (1) containing composite material (CFRP) comprising wound and laid carbon fibres, where density of the composite material is from 1.5 to 1.9 g/cm³, and the transient portion (2) has attached a rim (3) thereon provided with a set of connection sockets for connection of cutting inserts (5), wherein the hub (1) and the rim (3) are linked up by self-supporting composite material only to limit transfer of undesired high-frequency oscillations from the hub (1) to the rim (3), and vice versa, wherein there is a glued joint on the connection surfaces (10) between the hub (1) and the transient portion (2), and between the transient portion (2) and the rim (3), characterized in that the transient portion (2) contains at least a first plate body (8) made of the composite material, and a boundary contour (7) of a connection surface (10) between the hub (1) and the transient portion (2) and/or between the transient portion (2) and the rim (3) has regular undulated shape with a defined distance between the wave peaks on a circle for torque transfer from the hub (1) to the transient portion (2) and/or from the transient portion (2) to the rim (3).

2. The disc cutter body according to claim 1 characterized in that the boundary contour (7) of the connection surface (10) comprises a set of smooth linked curves consisting of straight line and circle segments, and/or is mathematically defined by a polynomial function of higher order of at least 3, wherein the curvature radius R of the boundary contour (7) of the connection surface (10) is at least 0.5 mm.

3. The disc cutter body according to claim 1 or 2 characterized in that the boundary contour (7) of the connection surface (10) on the first side of the body is different in its shape or size and/or phase-rotated according to the body rotation axis against the boundary contour (7) of the connection surface (10) on the other body side.

4. The disc cutter body according to any of one preceding claims 1 to 3 characterized in that the transient portion (2) further includes at least the second plate body (8’) connected to the first plate body (8) so that they have a common axis.

5. The disc cutter body according to claim 4 characterized in that the boundary contour (7) of the connection surface (10) of the first plate body (8) is different in shape and/or phase-rotated according to the body rotation axis against the boundary contour (7) of the connection surface (10) of at least second plate body (8’).

6. The disc cutter body according to claim 5 characterized in that the first plate body (8) is provided with multiple holes in which bolts (9) are placed perpendicularly to the first plate body (8) surface, wherein the body of each bolt (9) is arranged outside the area of at least second plate body (8’) and fastened in either hub (1) or rim (3).

7. The disc cutter body according to any of one preceding claims 1 to 6 characterized in that the surface of the hub (1) and/or of the rim (3) and/or of the transient portion (2) is at least partially provided on the connection surface (10) with a coarse surface for application of the glue.