CH717967A2 - Cutting tool. - Google Patents

Abstract

The present invention relates to a cutting tool intended for the machining by machining of a piece and, in particular, of a ceramic watch component, said tool comprising a body (1) made of a material comprising by weight between 90 and 99.5% of W and between 0.5 and 10% of one or more elements chosen from Co, Ni, Mo, Cr and Fe.

Description

Field of the invention

The invention relates to a cutting tool intended for the machining by grinding of a part and, in particular, of a ceramic watch component.

Background of the invention

[0002] The choice of the design and the material of a cutting tool is decisive for the service life of the tool, the time of the machining cycle and the quality of the machined part.

[0003] Documents EP 0251264 and EP 0731751 disclose cutting tools made of tungsten carbides. These tools are efficient thanks to their high density which reduces vibration phenomena and thanks to their rigidity which prevents the bending of the tool during machining. However, they have the disadvantage of being extremely hard, which complicates the manufacture of the tool as such. Indeed, the cutting tools may include orifices intended for the circulation of the cooling liquid. In particular, they may comprise a circular orifice which extends along the axis of the tool and radial orifices opening out onto the active part of the cutting tool. It is important that the geometry of the tool is perfectly axisymmetric and therefore that the circular orifice is perfectly centered to avoid an unbalance phenomenon during the machining of the part. It can be difficult to guarantee this centering when the material of the cutting tool is too hard.

[0004] Tools made of high-strength steels are also known. These tools have lower hardnesses than tungsten carbides, which facilitates their manufacture. On the other hand, their density is less, which can generate the aforementioned vibratory phenomena.

Summary of the invention

The present invention aims to overcome the aforementioned drawbacks by proposing a cutting tool made of a material that meets all the following criteria: Very high rigidity with a Young's modulus greater than or equal to 300 GPa, Ease of machining with a hardness less than or equal to 450 HV, High density with a density greater than 15 g/cm<3>.

To this end, the present invention relates to a cutting tool comprising a body made of a sintered material comprising by weight between 90 and 99.5% of W in metallic form and not of carbides, and between 0.5 and 10% of a binder formed from one or more metallic elements chosen from Co, Ni, Mo, Cr and Fe.

[0007] The tool in this material has a hardness of between 300 and 450 HV, a rigidity of between 300 and 450 GPa and a density of between 16 and 20 g/cm<3>.

According to the invention, the active part of the body of the cutting tool is coated with an abrasive bonded with one or more elements chosen from Ni, Co and Mo. The binder of the tool material cut provides excellent grip with the binder of the abrasive layer, which limits the risk of peeling.

[0009] Other characteristics and advantages of the present invention will appear on reading the detailed description below with reference to the following figures.

Brief description of figures

Figures 1A and 1B respectively show a side view and a sectional view of the cutting tool according to the invention.

Description of the invention

The invention relates to a cutting tool intended to machine a part. By way of example, the part may be a horological exterior or movement component such as a middle part, a case back, a bezel, a crown, a pusher, a bracelet link, a bracelet, a pin buckle, a dial, a hand, a dial index, a toothed wheel, an axis, a pinion, a spring, a bridge, a plate, a screw and a balance wheel. Although not limited to this application, the cutting tool is particularly suitable for machining parts made of ceramic material.

The cutting tool shown in Figures 1A and 1B is provided with a body 1 which comprises an active part 2, also called head, intended to be in contact on its side surface with the workpiece. In the example illustrated, the cutting tool comprises a central orifice 4 coaxial with the longitudinal axis of the cutting body and a multitude of radial orifices 5 opening out at the level of the coating 3, also called layer, of the head 2 of the body 1. A row of orifices having an angle a of between 0 and 90° can be envisaged so as to allow the front face of the tool to be sprayed.

According to the invention, the body of the cutting tool is made of a material comprising tungsten and a binder chosen from one or more of the following elements which are Co, Ni, Mo, Cr and Fe. material comprises by weight between 90 and 99.5% of W and between 0.5 and 10% of one or more elements chosen from among Co, Ni, Mo, Cr and Fe. Preferably, it comprises by weight between 93 and 99% of W and between 1 and 7% of one or more elements chosen from Co, Ni, Mo, Cr and Fe. More preferentially, it comprises between 95 and 98% of W and between 2 and 5% of one or more elements selected from Co, Ni, Mo, Cr and Fe.

The body has a hardness between 300 and 450 HV, preferably between 300 and 400 HV. It has a Young's modulus of between 300 and 450 GPa, preferably between 300 and 400 GPa. It has a density between 16 and 20 g/cm<3>.

The head 2 of the body 1 is coated with a layer 3 comprising an abrasive and a metal binder. The abrasive can be a ceramic based on oxides, carbides or nitrides, such as for example cubic boron nitride, or an element such as diamond. The binder comprises one or more elements chosen from Ni, Co and Mo.

According to the invention, the cutting tool is made by sintering a mixture of tungsten powders and the metal binder. More specifically, the manufacturing process of the cutting tool includes a first step consisting in producing a mixture with the various powders, possibly in a humid environment. The starting powders preferably have a d50 of less than 45 μm. Optionally, a second mixture comprising the aforementioned mixture and an organic binder system (paraffin, polyethylene, etc.) can be produced. Then, the method comprises a step which consists in forming a blank by giving the mixture the shape of the body of the desired tool, by way of example, by injection such as injection molding (MIM: Metal Injection Molding), by pressing or 3D printing. Afterwards, the blank is sintered under partial gas pressure, under vacuum or under atmospheric pressure at a temperature of between 800 and 1500° C. for a time of between 10 minutes and 20 hours. This step can be preceded by a debinding step in a temperature range of between 60 and 500° C. if the mixture includes a binder system. Then, the method may include a step of finishing the shape of the body of the tool, and in particular of producing the orifices of the body, by conventional means such as drilling, milling, grinding, etc. The head of the body is then coated with the layer of Ni, Cr and/or Mo comprising the abrasive by electroplating.

[0017] Comparative tests were carried out between a high-strength steel cutting tool such as 1.3346, 1.3343 and 1.3255 and a cutting tool with the material according to the invention comprising tungsten and nickel and iron as binder .

[0018] The tests consisted in machining a ceramic middle part (ZrO2) of a watch case. The tests were carried out with a cutting tool having a body 6 mm in diameter and a head covered with the abrasive layer comprising diamond and nickel. The machining was carried out with a cutting speed of 660 m/min. Tool life was determined based on the number of parts machined without degradation of the abrasive layer. With the cutting tool according to the invention, 24 casebands were machined against 14 for the cutting tool made of high-strength steel.

Claims (9)

1. Cutting tool intended for machining a part, said tool comprising a body (1) made of a material comprising by weight between 90 and 99.5% of W and between 0.5 and 10% of one or more selected elements among Co, Ni, Mo, Cr and Fe. 2. Cutting tool according to claim 1, characterized in that the material comprises by weight between 93 and 99% of W and between 1 and 7% of one or more elements chosen from Co, Ni, Mo, Cr and F. 3. Cutting tool according to claim 1 or 2, characterized in that the material comprises by weight between 95 and 98% of W and between 2 and 5% of one or more elements chosen from Co, Ni, Mo, Cr and the Fe. 4. Cutting tool according to one of the preceding claims, characterized in that the material has a hardness of between 300 and 450 HV. 5. Cutting tool according to one of the preceding claims, characterized in that the material has a hardness of between 300 and 400 HV. 6. Cutting tool according to one of the preceding claims, characterized in that the material has a Young's modulus of between 300 and 450 GPa. 7. Cutting tool according to one of the preceding claims, characterized in that the material has a Young's modulus of between 300 and 400 GPa. 8. Cutting tool according to one of the preceding claims, characterized in that the body (1) comprises a head (2) intended to be in contact with the workpiece being machined, said head (2) comprising on its side outer surface a coating (3) comprising an abrasive and a binder. 9. Cutting tool according to the preceding claim, characterized in that the abrasive is chosen from ceramics and diamond and in that the binder comprises one or more elements chosen from Ni, Co and Mo.