EP2467226A1

EP2467226A1 - Precision pressing and sintering of cutting inserts, particularly indexable cutting inserts

Info

Publication number: EP2467226A1
Application number: EP10736672A
Authority: EP
Inventors: Bernd Bitterlich; Michael Fripan; Kilian Friederich; Wolfgang KRÜMMEL; Ulrich Mowlai; Andreas Schlagenhof
Original assignee: Ceramtec GmbH
Current assignee: Ceramtec GmbH
Priority date: 2009-08-21
Filing date: 2010-07-20
Publication date: 2012-06-27
Also published as: CN102740999A; WO2011020667A1; KR20120066639A; JP2013502328A; DE102010031578A1; IL218204A0; US20120134758A1; BR112012003880A2; CA2771550A1

Abstract

The invention relates to a ready-for-use ceramic cutting insert for machining work pieces, produced by sintering a blank and comprising an upper and a lower face, both of which have a support surface for mounting in a clamp mounting of a cutting tool, lateral faces connecting the upper and lower faces, and cutting edges which have chamfers. In order to at least partly avoid re-machining after sintering, the support surfaces of the upper and lower faces and/or the chamfers have at least subareas which consist of the sinter skin produced as a result of the sintering and which have not been damaged by any material-removing treatment.

Description

Precision presses and sintering of inserts, in particular

Inserts

The invention relates to a ready-to-use produced by sintering a blank ceramic cutting plate having a top and bottom, each having a support surface for installation in a clamping holder of a cutting tool, with the top and bottom connecting side surfaces and cutting edges having chamfers to Machining of workpieces. Heretofore, the tight tolerances for a ceramic insert (e.g., G-tolerance in the in-circle diameter ± 25 μm at d = 12.7 mm and in the thickness s = ± 130 μm) could only be obtained by regrinding after sintering, i. in the state in which the material has already formed all its outstanding properties can be adjusted with diamond tools. In addition to the angles, radii and the cutting edge preparation of the indexable inserts, it also depends on a secure hold of the indexable insert in the insert seat. This makes appropriate demands on the flatness of the bearing surface of the indexable inserts. Previously, this requirement could only be achieved by surface grinding with diamond tools. This reworking is always associated with high grinding forces and pressures that cause damage to the material.

The invention has for its object to improve a ready insert according to the preamble of claim 1 so that a post-processing after sintering is at least partially avoided. In addition, a method for producing the insert according to the invention is to be specified. In addition, a preferred use will be presented.

The invention will be explained in more detail with reference to the claims. Due to the fact that the bearing surfaces of the upper and lower sides and / or the chamfers have at least partial surfaces which consist of the sintering skin produced during sintering and have not suffered any damage due to a material-removing treatment, post-processing after sintering is at least partially avoided.

In a preferred embodiment, the entire upper and lower sides consist of the sintering skin produced during sintering. Since the sintered skin often has a higher hardness than the base material, the wear resistance of the cutting material is thereby increased.

The more surface of the cutting plate made of the sintering skin formed during sintering, the higher the hardness. Therefore, all chamfers preferably consist of the sintering skin produced during sintering.

In an inventive embodiment therefore consist of individual side surfaces or preferably all side surfaces of the sintering skin formed during sintering.

An insert according to the invention thus preferably satisfies a dimensional accuracy according to M tolerance according to ISO 1382 and / or a dimensional accuracy according to G tolerance according to ISO 1382.

To improve the attachment to a carrier tool, the top and / or bottom of the cutting plate may have a trough or a through hole connecting the top and bottom.

Also, the top and / or bottom and / or the side surfaces and / or the chamfers may be provided with a single or multi-layer coating. The cutting plate preferably consists of one or more of the following ceramic cutting materials:

> α- / ß-SiAIONe with and without hard material reinforcement

> ß-Si3N4 with and without hard material reinforcement

> Mixed ceramics (AI2O3 - Ti (C ₁ N))

> ZTA (AI2O3 - ZrO2)

Preferably, the cutting plate is an indexable insert.

An inventive method for producing a prepared by sintering a blank ceramic cutting plate having a top and bottom, each having a support surface for installation in a clamping holder of a cutting tool, with the top and bottom connecting side surfaces and cutting edges having a chamfer , for machining of workpieces, is preferably characterized in that the blank of the insert brought by precision presses in the desired shape, then the blank is sintered and after sintering at least partial surfaces of the bearing surfaces of the top and / or bottom and / or bevel be subjected to any material-removing treatment.

It is preferable that the entire top and bottom and / or all chamfers and / or all side surfaces subjected to no material-removing treatment. In an inventive embodiment is pressed by the precision pressing of the blank a trough in the top and / or bottom or a connecting the top and bottom through hole. - A -

One or more of the following ceramic cutting materials are preferably used for the production of the blank:

> α- / ß-SiAIONe with and without hard material reinforcement

> ß-Si3N4 with and without hard material reinforcement

> Mixed ceramics (AI2O3 - Ti (C ₁ N))

> ZTA (AI2O3 - ZrO2)

A preferred method step is characterized in that the ceramic cutting materials are mixed to a compressible mass, which have a high flowability and thus in particular a constant mold filling, wherein the pourability angle characterizing the flowability of the mass is less than or equal to 35 °, preferably less than or equal to 30 ° , More preferably equal less than 25 ° is set. Advantageously, prior to sintering, the burrs of the blank are removed without damaging the edges of the blank.

Preferably, the different pressing and shrinkage behavior of different mass batches is taken into account, whereby the green density-shrinkage characteristic of each batch is determined by pressing and sintering tests and the necessary production green density is determined and this production green density is set when setting the presses as a target value for the green density of the blanks , Advantageously, during sintering, the gas exchange between the furnace atmosphere and the interior of the crucible in which the blanks are sintered is minimized and only crucible materials are used which are inert, ie, in no way interacting with the blanks during sintering. Preferably, the cutting insert according to the invention is used for cutting metals, plastics, wood or composite materials.

According to the invention, the dimensions are achieved in compliance with the M and G tolerance according to ISO 1832 when manufacturing indexable inserts made of materials of high performance ceramics by precision pressing and direct sintering.

The inventive step is therefore to bring the blank of the insert, before sintering, by precise pressing (also called precision presses) in such a form that allows that after sintering little or no regrinding of the top and bottom and / or the side surfaces of the finished sintered cutting plate is more necessary. The invention comprises a method for producing a cutting plate, in which the blank of the cutting plate is brought into the desired shape by precision pressing and then the blank is sintered, thereby forming the cutting plate. According to the invention after sintering no, in any case less loops longer required. In the blank at the same time preferably a trough is pressed, which makes it possible to clamp the cutting plate on a holder of a carrier tool. The invention further describes an insert with a sinter skin on the top and / or bottom and / or side surface and / or bevel of the insert. Preferably, these surfaces or cover these surfaces, the entire top and bottom of the insert. The invention also describes a ceramic cutting insert or indexable insert which satisfies a dimensional accuracy according to G tolerance according to ISO 1382 and whose surfaces consist of the sintered skin produced during sintering and therefore have not suffered any damage due to a material-removing treatment. The invention provides the following improvements in the application:

The damage to the ceramic by grinding is avoided, i. lower susceptibility of the products to operations in terms of scraping and crumbling.

Since the sintered skin often has a higher hardness than the base material, the wear resistance of the cutting material is further increased, which manifests itself in practice during machining by lower open space and notch wear.

• Due to the lower overall wear on the indexable insert, breakages on the component can be reduced due to the resulting lower cutting forces. The reduction in cutting forces also results in a significantly lower machine power consumption. This increases the distance to the limit value of the cutting force monitoring and the service life per cutting edge is increased.

Also advantageous is a reduction in the noise when using the indexable insert (WSP) according to the invention.

Various embodiments are conceivable:

Predominantly pressed: The outer contour of the insert is pressed and sintered with high precision; the height (also known as the part height) of the WSP continues to be ground, and the edge is chamfered.

Level pressed: the side surfaces are e.g. by grinding to the correct degree, whereby the dimensional accuracy of the G

Tolerance is achieved. The top and / or bottom remain unpolished, so that the sinter skin is preserved here. A chamfer can also be made by pressing alone or by grinding. Ready-pressed: External contour and part height are adjusted to the exact size by pressing and sintering only; Cutting edge is beveled. (Fig. 1) Highest embodiment: The chamfer is also precisely adjusted by pressing and sintering.

Today's standard for comparison: pressing and sintering of the blanks with a grinding allowance of one to several tenths of a millimeter; Face grinding, circumferential grinding and chamfering are found in 3 separate processes on 3 different machines with different requirements. There are many possibilities for damaging the material.

The invention relates to all high-performance ceramics cutting materials, in particular:

α- / ß-SiAIONe with and without hard material reinforcement, uncoated and coated. In particular, an α-gradient present in the material and the near-surface hardness gradient associated therewith are retained.

• ß-Si3N4 with and without hard material reinforcement, uncoated and coated.

Mixed ceramic (AI2O3 - Ti (C ₁ N)), uncoated and coated.

ZTA (AI2O3 - ZrO2), uncoated and coated.

The invention is based on the following inventive performances or the following features in the preparation are advantageous alone or in combination:

When pressing the blank is advantageous to set a very accurate and precisely centered gap between press dies and die. This can be realized in particular by a quick-release system.

The pressing process is preferably set extremely accurately and with high reproducibility.

Pressable mass with preferably very high flowability and thus constant mold filling capacity. The flowability is through the characterized so-called angle of repose. For the measurement, a defined amount of pressed granules is allowed to trickle evenly into a transparent container. Then, the bottom plate is opened a little way, so that part of the powder expires. Depending on the flowability of the granules remaining in the container powder forms a more or less steep edge whose

Angle is measured as angle of repose. The angle of repose should be less than or equal to 35 °, preferably less than or equal to 30 °, particularly preferably less than or equal to 25 °, for a good flowability.

A high consistency in the green density of all blanks is necessary. This is achieved by a mass with very good flowability and a very accurate regulating press. With an automatic mass and height measurement in connection to the press, the green density of each pressed part can be calculated. The scattering of the green density from blank to blank should be less than or equal to 0.5%, preferably less than or equal to 0.3% of the mean value (for example, see Figure 1: Production green density 1, 956 g / cm ³ , green densities are within

1, 951 - 1, 963 g / cm ³ , set at max. 0.3% deviation: 1, 951 - 1, 962 g / cm ³ ). Remove the burrs of the blank without damaging the edges of the blank. Due to the gap between the press dies and the die, a thin burr remains on the blank. This must be removed before sintering so that it does not sinter and then close

Outbreaks can lead to the edge.

Consideration of the different pressing and shrinkage behavior of different mass batches. In this case, the green density-shrinkage characteristic of each batch is determined by pressing and sintering tests and the required production green density is determined from this. This manufacturing green density applies when setting the presses as the setpoint for the green density of the blanks. Special furnace construction to avoid sintering distortion, density, shrinkage and color gradients. In particular, the gas exchange between furnace atmosphere and Tiegelinnerem must be minimized. additionally Only crucible materials that are inert, ie in no way interact with the blanks during sintering, may be used. These measures are necessary to achieve a homogeneous shrinkage of the blanks during sintering. If, on the other hand, interactions of the blanks with the furnace atmosphere or the crucible material take place, the shrinkage of the

Blanks influenced locally, so that a delay takes place during sintering and dimensional accuracy can no longer be guaranteed. When a sintering delay occurs, the corners and edges of the marginal parts are usually affected. For example, in the case of silicon nitride or SiAION materials, a high concentration of carbon in the gas atmosphere is caused by e.g. new graphite materials of the crucible or furnace insulation to reduce the sintering additives necessary for compaction on the surface. As a result, the shrinkage at the edge of the component is lower than in the center of the component, resulting in a distortion in the sintered component.

For better clamping of the cutting plate a recess is preferably introduced in the cutting plates, as described in WO 03/013770 A1. The trough has a spherical or circular elevation in the middle. The top of the survey is above the trough bottom and below the Schneidplatten- top. For clamping on a cutting tool engages a clamping claw with adapted molded nose form fit into the trough of the insert. This trough is used for positive clamping on a carrier body. Especially for drawing cuts, in which the cutting plate could be pulled out of its seat by the acting cutting forces, this cutting plate with the special trough offers itself. For further description of this trough see the cited document.

So that constant installation conditions are always given, in another embodiment of the invention, the trough is formed as shown in the EP 1 536 903 B1. In this case, a first clamping recess for clamping is introduced into the cutting tool and coaxially to the first clamping recess, a second clamping recess is arranged, wherein the first clamping recess are arranged lower than the second clamping recess and both lower than the cutting plate top. When clamping this insert in a tool, a clamping claw of the tool rests on the second clamping recess and, for example, engages with a nose in the first clamping recess. The distance from the bearing surface of the clamping claw to the trough is thus always constant. The cutting insert according to the invention can also be provided with a coating in one or more layers.

FIG. 1 shows the low scattering of the green densities from blank to blank. This should be less than or equal to 0.5%, preferably less than or equal to 0.3% of the mean. The production green density was 1, 956 g / cm ³ , the green densities were within 1, 951 - 1, 963 g / cm ³ , the target at max. 0.3% deviation: 1, 951 - 1, 962 g / cm ³ .

With the invention, the notch wear is reduced under the same conditions of use, namely

Operation: brake track roughing

Cutting speed: Vc = 1,000 m / min

Depth of cut f = 0.55 mm / rev

Feed ap = 3-4 mm

Material: GJL-alloyed

Stands: 100 parts

Service life criterion: Dimensional accuracy In an experiment, two indexable inserts (TDC) with a trough for clamping into a holder of a cutting tool for machining after reaching the service life criterion were investigated. A prior art coated PcBN insert was compared to an uncoated α- / β-SiAION WSP according to the present invention.

The inventively uncoated α- / ß-SiAION insert showed a significantly lower wear than the PcBN-WSP of the prior art after reaching the service life criterion.

Claims

claims

1. Ready-to-use prepared by sintering a blank ceramic cutting plate having a top and bottom, each having a support surface for installation in a clamping holder of a cutting tool, with the top and bottom connecting side surfaces and cutting edges having chamfering, for machining of workpieces, characterized in that the bearing surfaces of the top and bottom and / or the chamfers have at least partial surfaces which consist of the sintering skin produced during sintering and have not suffered any damage due to a material-removing treatment.

2. Cutting insert according to claim 1, characterized in that the entire top and bottom consist of the sintering skin formed during sintering.

3. Cutting insert according to claim 1 or 2, characterized in that all chamfers consist of the sintering skin formed during sintering.

4. Cutting insert according to one of claims 1 to 3, characterized in that individual side surfaces or preferably all side surfaces consist of the sintering skin formed during sintering.

5. Cutting insert according to one of claims 1 to 4, characterized in that the cutting plate of a dimensional accuracy to M tolerance according to ISO1382 and / or satisfies the insert a dimensional accuracy to G tolerance according to ISO1382.

6. Cutting insert according to one of claims 1 to 5, characterized in that the upper and / or underside of the cutting plate has a trough or a connecting the top and bottom through bore.

7. Cutting insert according to one of claims 1 to 6, characterized in that the top and / or bottom and / or the side surfaces and / or the chamfers are provided with a single or multi-layer coating.

8. Cutting insert according to one of claims 1 to 7, characterized in that the cutting plate of one or more of the following

Ceramic cutting materials consists of:

- α- / ß-SiAIONe with and without hard material reinforcement

- ß-Si3N4 with and without hard material reinforcement

Mixed ceramics (AI2O3 - Ti (C ₁ N))

- ZTA (AI2O3 - ZrO2)

9. A method for producing a ceramic insert produced by sintering a blank having a top and bottom, each having a support surface for installation in a clamping holder of a cutting tool, with the top and bottom connecting side surfaces and with

Cutting edges having a chamfer for machining workpieces, in particular for the production of a cutting plate according to one of claims 1 to 8, characterized in that the blank of the insert is brought by precision pressing in the desired shape, then the blank is sintered and after the At least sinter

Sub-surfaces of the bearing surfaces of the top and / or bottom and / or the bevel are not subjected to any material-removing treatment.

10.A method according to claim 9, characterized in that a recess in the top and / or bottom or a connecting the top and bottom through hole is pressed by the precision pressing of the blank.

11. The method according to any one of claims 9 or 10, characterized in that one or more of the following ceramic cutting materials is used to produce the blank:

- α- / ß-SiAIONe with and without hard material reinforcement

- ß-Si3N4 with and without hard material reinforcement

Mixed ceramics (AI2O3 - Ti (C ₁ N))

- ZTA (AI2O3 - ZrO2)

12. The method according to any one of claims 9 to 11, characterized in that the ceramic cutting materials are mixed to form a pressable mass, which has a high flowability and thus in particular a constant mold filling, wherein the pourability characterizing Schumtwinkel the mass is less than or equal to 35 ° , preferably less than or equal to 30 °, more preferably less than or equal to 25 ° is set.

13. The method according to any one of claims 9 to 12, characterized in that prior to sintering the burrs of the blank are removed without the edges of the blank are damaged.

14. The method according to any one of claims 9 to 13, characterized in that the different pressing and shrinkage behavior of different mass batches is taken into account, determined by pressing and sintering tests the green density-shrinkage characteristic of each batch and from the necessary manufacturing green density is determined and this Manufacturing green density when setting the presses is set as a target for the green density of the blanks.

15. The method according to any one of claims 9 to 14, characterized in that during sintering, the gas exchange between the furnace atmosphere and the

Crucible interior, in which the blanks are sintered, is minimized and only

Crucible materials are used which are inert, i. in no way interact with the blanks during sintering.