Title of Invention	TOOL WITH MULTI-LAYERED METAL OXIDE COATING
Abstract	The present invention relates to a cutting tool having a base body and a multilayered coating applied thereto, wherein at least two layers of the multilayered coating arranged one on top of the other contain, or consist of, metal oxide of the same metal or of different metals. In order to create cutting tools which are better than those of the prior art, it is proposed according to the invention that the at least two metal oxide layers arranged one on top of the other be produced successively by different PVD-processes, selected from i) reactive magnetron sputtering (RMS), ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, wherein modifications of the respective processes i) to v) do not constitute different PVD-processes.

Title of Invention

TOOL WITH MULTI-LAYERED METAL OXIDE COATING

Abstract

The present invention relates to a cutting tool having a base body and a multilayered coating applied thereto, wherein at least two layers of the multilayered coating arranged one on top of the other contain, or consist of, metal oxide of the same metal or of different metals. In order to create cutting tools which are better than those of the prior art, it is proposed according to the invention that the at least two metal oxide layers arranged one on top of the other be produced successively by different PVD-processes, selected from i) reactive magnetron sputtering (RMS), ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, wherein modifications of the respective processes i) to v) do not constitute different PVD-processes.

Full Text	Tool with Multi-Layered Metal Oxide Coating The invention relates to a cutting tool having a base body and a multilayered coating applied thereto, wherein at least two layers of the multilayered coating which are arranged one on top of the other contain, or consist of, metal oxide of the same metal or of different metals. Prior Art Cutting tools consist of a base body which is made, for example, of hard metal, cermet, steel or high-speed steel. In order to increase durability, or, also, to improve the cutting properties, a single-layered or multilayered coating is often applied to the base body. This single-layered or multilayered coating may, for example, comprise hard metal material layers, oxide layers, and the like. Application of the coating is done by CVD-processes (chemical vapour deposition) and/or by PVD-processes (physical vapour deposition). A plurality of layers within a coating can be applied by means of CVD-processes alone, by means of PVD-processes alone, or by a combination of both processes. There are various variants of PVD-processes, e.g. i) magnetron sputtering, ii) arc vapour deposition (Arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition. Magnetron sputtering and arc vapour deposition are the most frequently used PVD-processes for coating tools. Within each individual PVD- process variant there are, in turn, various modifications, e.g. pulsed or unpulsed magnetron sputtering, or pulsed or unpulsed arc vapour deposition etc. The target in the PVD-process may be a pure metal, or a combination of two or more metals. If the target comprises several metals, then all those metals are incorporated at the same time into the layer of a coating constructed during the PVD-process. The ratio of the proportions of metals to one another in the constructed layer depends upon the ratio of the proportions of metals in the target, but it also depends on conditions in the PVD-process, since individual metals are released from the target in greater amounts under certain conditions, and/or are deposited on the substrate in greater amounts than other metals. In order to produce certain metal compounds reactive gases are fed to the reaction chamber during the PVD-process, e.g. nitrogen to produce nitrides, oxygen to produce oxides, carbon-containing compounds to produce carbides, carbonitrides, oxicarbides etc., or mixtures of these gases to produce corresponding mixed compounds. EP-A-0668369 discloses a PVD-coating process, wherein hard material layers consisting of nitrides or carbonitrides of the metals Ti, Zr, Hf or alloys of TiAl, ZrAI, HfAl, TiZr, TiZrAI, are produced with an imbalanced magnetron, wherein during a specific time interval of the coating process additional coating material is deposited from a cathodic arc discharge vapour deposition process onto the substrates to be coated. DE-A-102004044240 discloses the application to one or more metal oxide layers onto a cutting tool in a PVD-process, in particular by the use of magnetron sputtering. DE-A-19937284 describes an electrically conductive multi-layered build-up on a metal substrate, having a first layer consisting of a metal material, in particular chrome, the surface of which is passivated by naturally formed oxide, and having a further layer of gold or gold alloy material which is applied by means of a PVD-process. That second layer is capable of at least partially cancelling the electrically insulating effect of the naturally formed oxide film of the first layer. Coated arrangements of this kind are used, for example, as supporting structures for the screened housing of electronic components. DE-A19651592 describes a coated cutting tool having a multilayered coating comprising at least one aluminium oxide layer and hard metal material layers. The hard metal material layers are, for example, TiAIN-layers applied by means of PVD-processes. The aluminium oxide layer which is applied directly thereon is also deposited by way of a PVD-process. Problem The problem forming the basis of the present task was to provide cutting tools which are better that the prior art. This problem according to the invention is solved by way of a cutting tool of the kind mentioned in the introduction, which is characterised in that the at least two metal oxide layers, arranged one on top of the other, are produced successively by different PVD processes selected from i) reactive magnetron sputtering, ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, wherein modifications of the respective processes i) to v) do not constitute different PVD-processes. In the sense of the present invention, i) magnetron sputtering, ii) arc vapour deposition (Arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition are "different PVD-processes". Within each of these PVD-processes i)tov) there are modifications, and, in the sense of the present invention, the modifications of a PVD-process are not regarded as "different PVD-processes", Modifications of the "magnetron sputtering" PVD-process are, for example, "dual magnetron sputtering", "RF-magnetron sputtering", "bipolar magnetron sputtering", "unipolar magnetron sputtering", "DC-diode-magnetron sputtering", "DC-triode-magnetron sputtering", "pulsed magnetron sputtering", "unpulsed magnetron sputtering" and mixes of the afore-mentioned processes. Similarly, various modifications and mixed forms of modifications exist for the "arc vapour deposition" (Arc-PVD), "ion plating", "electron beam vapour deposition" and "laser deposition" PVD-processes. The modifications to PVD-processes i) to v) are very well known to the person skilled in this domain, and therefore do not need to be dealt with in greater detail here. The application of a multilayered coating, and also of a coating comprising a plurality of metal oxide layers, onto a cutting tool in the form of a wear protection coating has been known for a long time. However, the application of the metal oxide layers to the same base body using different PVD-processes is new and results in completely new coatings with new properties. This new kind of coating according to the present invention opens up a wide range of possibilities for improving and/or adapting the resistance to wear, the durability and/or the cutting properties of cutting tools. The resistance to wear, the durability and the cutting properties of a coating on a cutting tool are dependent upon various factors, e.g. on the material of the base body of the cutting tool, on the sequence, type and composition of the layers present in the coating, on the thickness of the various layers, and, last but not least, on the type of cutting operation which is performed by the cutting tool. Different resistances to wear can result for one and the same cutting tool, depending upon the type of work piece to be machined, the respective machining process, and other conditions during machining, e.g. the development of high temperatures, or the use of corrosive cooling agents. Furthermore, a distinction is made between different kinds of wear which can have varying degrees of influence upon the useful life, i.e. the durability, of a tool, depending upon the machining operation which it performs. Therefore, the development and improvement of cutting tools must always be considered in terms of which tool properties are to be improved, and it should be assessed under comparable conditions to the prior art. Surprisingly, it has been seen that by combining various PVD-processes for the purpose of applying at least two metal oxide layers arranged one on top of the other to the base body the properties of the entire coating can be purposefully influenced, and cutting tools with an improved resistance to wear, an improved cutting ability and better durability can be produced. By applying the metal oxide layers using different PVD-processes, metal oxide layers with different internal stress behaviours (internal compressive stress and internal tensile stress), for example, are produced in relatively large layer thicknesses (e.g. above 5 to 10 µ or more). By slightly adjusting various lattice parameters (e.g. in Al2O3 and (AICr)2O3), whilst the lattice structure is the same, a significant tensioning of the lattice, and thus an increase in hardness, can be produced, for example. Further properties, such as red hardness, thermodynamic stability, low crack propagation and the heat expansion coefficient can be purposefully influenced in a coating according to the invention. In one embodiment of the invention, in the coating of the cutting tool the two metal oxide layers arranged one on top of the other are arranged directly on one another without an intermediate layer/layers. In dependence on the deposited layers, particularly good adhesion between the layers can advantageously result in this instance. In an alternative embodiment of the invention, in the coating of the cutting tool there is arranged, between the two metal oxide layers arranged one on top of the other, at least one non-oxide intermediate layer, preferably at least one metal nitride layer. By way of example, a ZrN-layer can be provided between two ZrO2-Iayers. By depositing a metal nitride layer as an intermediate layer, the deposition process of the metal oxide layers is stabilised, and "decontamination" of the target(s) can be achieved. Depending upon the material, an improvement in respect of the bonding of the oxide layers has been observed. Furthermore, depending on the material, an increase in hardness has also been found. According to a further embodiment of the invention, in the coating of the cutting tool one of the at least two metal oxide layers arranged one on top of the other is produced by magnetron sputtering, and another of the at least two metal oxide layers arranged one on top of the other, which is arranged thereabove or therebelow, is produced by arc vapour deposition (arc-PVD). In another embodiment of the invention, in the coating of the cutting tool the at least two metal oxide layers arranged one on top of the other are produced successively by different PVD-processes in the same PVD-apparatus, without the cutting tool body being removed from the PVD-apparatus between application of the at least two metal oxide layers arranged one on top of the other, and/or without the vacuum which prevails in the PVD-apparatus during the PVD process being reduced between application of the at least two metal oxide layers arranged one on top of the other. In another embodiment of the invention, in the coating of the cutting tool the at least two metal oxide layers arranged one on top of the other comprise oxides of the elements from Groups IVa to VIla of the periodic system and/or aluminium and/or silicon. In another embodiment of the invention, in the coating of the cutting tool at least one of the at least two metal oxide layers arranged one on top of the other has metal oxide of just one metal. In another embodiment of the invention, in the coating of the cutting tool at least one of the at least two metal oxide layers arranged one on top of the other further has at least one secondary component from carbides, nitrides, oxides, carbonitrides, oxinitrides, oxicarbides, oxicarbonitrides, borides, boronitrides, borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides, borooxocarbonitrides, oxoboronitrides of the elements of Groups IVa to VIla of the periodic system and/or of aluminium and/or silicon, mixed metal phases and phase mixes of the afore- mentioned compounds. In another embodiment of the invention, in the coating of the cutting tool the coating comprises further hard material layers consisting of carbides, nitrides, oxides, carbonitrides, oxinitrides, oxicarbides, oxicarbonitrides, borides, boronitrides, borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides, borooxocarbonitrides, oxoboronitrides of the elements from groups IVa to VIla of the periodic system and/or aluminium and/or silicon, mixed metal phases and phase mixes of the afore-mentioned compounds. In another embodiment of the invention, in the coating of the cutting tool the layers of the coating have layer thicknesses of 10 nm to 50 µm, preferably of 20 nm to 20 µm, particularly preferably of 0.2 µm to 4 µm. In another embodiment of the invention, in the coating of the cutting tool the coating has a Vickers hardness (Hv) of between 500 and 4000, preferably of between 700 and 3500, particularly preferably of between 1500 and 3000. In another embodiment of the invention, in the coating of the cutting tool the base body is produced from hard metal, cermet, steel or high-speed steel (HSS). In another embodiment of the invention, in the coating of the cutting tool the metal oxides of the at least two metal oxide layers arranged one on top of the other have the same crystal structure. This means that depending on the material deposited improved adhesion of the layers to one another can be achieved. Examples of metal oxides with the same crystal structure are a-AI2O3 / Cr2O3. In an alternative embodiment of the invention, in the coating of the cutting tool, the metal oxides of the at least two metal oxide layers arranged one on top of the other have a different crystal structure. Depending upon the material deposited, this can be particularly advantageous for inhibiting column growth of the crystals and for avoiding columns of crystallites, which would lead to increased brittleness. In another embodiment of the invention, in the coating of the cutting tool the phases within the XRD, XPS and/or TEM spectrum which have the highest intensity (the main phases) of the at least two metal oxide layers arranged one on top of the other have the same crystal structure. In the context of the present invention, the main phases are those phases in a layer of the coating which are clearly in excess over other phases of the same layer. In another embodiment of the invention, in the coating of the cutting tool the phases in the XRD, XPS and/or TEM-spectrum which have the highest intensity (the main phases) of the at least two metal oxide layers arranged directly one on top of the other have a different crystal structure. The invention also comprises a process for the production of a cutting tool with a base body and a multilayered coating applied thereto, wherein metal oxide of the same metal or of different metals is applied successively by different PVD processes in at least two layers of the multilayered coating arranged one on top of the other, wherein the PVD-processes are selected from i) reactive magnetron sputtering, ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, and wherein modifications of the respective processes i) to v) do not constitute different PVD-processes. In another embodiment of the process according to the invention, one of the at least two metal oxide layers arranged one on top of the other is applied by reactive magnetron sputtering, and a further one of the at least two metal oxide layers arranged one on top of the other, arranged thereon or thereunder, is applied by arc vapour deposition (arc-PVD). In another embodiment of the process according to the invention, the at least two metal oxide layers arranged one on top of the other are applied successively by different PVD-processes in the same PVD-apparatus, without the cutting tool body being removed from the PVD-apparatus between the application of the at least two metal oxide layers arranged one on top of the other, and/or without the vacuum which prevails in the PVD-apparatus during the PVD-process being reduced between application of the at least two metal oxide layers arranged one on top of the other. It will be clear that all individual features, such as described herein for specific embodiments of the invention, can be combined with all the other features of the inventive embodiments described, so far as this is technically reasonable and possible, and that such combinations are considered to be disclosed within the scope of this description. Simply for the sake of better readability, we will not name each and every possible combination here. Further advantages, features and embodiments of the present invention will be described with the aid of the following examples. EXAMPLES In a PVD-coating apparatus (Flexicoat; Hauzer Techno Coating), hard metal substrates composed of HM-coarse grain + 10.5% wt Co (HM-coarse grain = WC- hard metal with an average grain size of 3 - 5 µm) were provided with a multi-layered PVD-coating. The substrate geometry was SEHW120408 or ADMT160608-F56 (according to DIN-ISO 1832). Before the layers were deposited, the apparatus was evacuated to 1x10-5 mbar, and the hard metal surface was cleaned by ion etching with a bias voltage of 170 V. Depositing of the Layers: TiAIN (Arc Vapour Deposition; AVD) ¦Target: Ti/AI (33/67 At.-%) Round source (63 mm diameter), ¦ 80 amps, 495°C, 3 Pa N2-pressure, 40 volt substrate bias voltage, Y-AI2O3 (Arc Vapour Deposition: AVD) ¦ Target: Al-Round source (63 mm diameter), ¦ 80 amps, 495°C, 0.7 Pa O2-pressure, 70 volt substrate bias voltage, ?-AI2O3 (reactive magnetron sputtering; RMS) ¦ Target: Al ¦ 10 kW sputtering output, 495°C, 0.5 Pa Ar-pressure, 150 volt substrate bias voltage (unipolar, pulsed) ZrO2 (Arc Vapour Deposition: AVD) ¦ Target: Zr-Round source (63 mm diameter), ¦ 80 amps, 495°C, 0.7 Pa O2-pressure, 70 volt substrate bias voltage ZrO2 (reactive magnetron sputtering: RMS) ¦ Target: Zr ¦ 10 kW sputtering output, 495°C, 0.5 Pa Ar-pressure, 150 volt substrate bias voltage (unipolar, pulsed), The following coatings were applied onto the base body using different PVD-processes: The tools from Example 1 and from Comparative Examples 1a and 1b were compared in a milling experiment on a workpiece composed of 42CrMoV4-steel (strength: 850 MPa). Milling took place at a constant velocity, without cooling lubricant, at a cutting rate of vc = 236 m/min and with a forward feed rate per tooth of fz = 0.2 mm. Wear was measured on the tool flank as an average wear of the cutting edge WCE in mm (of the main cutting edge) after a milling path of 4800 mm. The following values for wear to the cutting edge WCE were found: Comparative Examples 1a and 1b showed an approximately linear increase in wear. The results show a significantly better wear behaviour for the tool according to the invention in Example 1 than for the tools according to Comparative Examples 1a and 1b. The tools of Example 2 and of Comparative Example 2 were compared in the same milling experiment as that described for the tools of Example 1 and of Comparative Examples 1a and 1b. The following values for wear to the cutting edge WCE were found: The results show a significantly better wear behaviour for the tool of Example 2 according to the invention than for the tool according to Comparative Example 2. CLAIMS WE CLAIM 1. A cutting tool having a base body and a multilayered coating applied thereto, wherein at least two layers, arranged one on top of the other, of the multilayered coating contain, or consist of, metal oxide of the same metal or of different metals, characterised in that the at least two metal oxide layers arranged one on top of the other are produced successively by different PVD processes selected from i) RMS, ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, wherein modifications of the respective processes i) to v) do not constitute different PVD-processes. 2. A cutting tool according to Claim 1, characterised in that the two metal oxide layers arranged one on top of the other are arranged directly on one another without intermediate layer(s). 3. A cutting tool according to Claim 1, characterised in that arranged between the two metal oxide layers arranged one on top of the other is at least one non-oxide intermediate layer, preferably at least one metal nitride layer. 4. A cutting tool according to one of the preceding claims, characterised in that one of the at least two metal oxide layers arranged one on top of the other is produced by RMS, and another of the at least two metal oxide layers arranged one on top of the other, which is arranged thereabove or therebelow, is produced by arc vapour deposition (arc-PVD). 5. A cutting tool according to one of the preceding claims, characterised in that the at least two metal oxide layers arranged one on top of the other are produced successively by different PVD-processes in the same PVD-apparatus, without the cutting tool body being removed from the PVD-apparatus between application of the at least two metal oxide layers arranged one on top of the other, and/or without the vacuum which prevails in the PVD-apparatus during the PVD process being reduced between application of the at least two metal oxide layers arranged one on top of the other. 6. A cutting tool according to one of the preceding claims, characterised in that the at least two metal oxide layers arranged one on top of the other comprise oxides of the elements from Groups IVa to VIla of the periodic system and/or of aluminium and/or silicon. 7. A cutting tool according to one of the preceding claims, characterised in that at least one of the at least two metal oxide layers arranged one on top of the other has metal oxide of just one metal. 8. A cutting tool according to one of the preceding claims, characterised in that at least one of the at least two metal oxide layers arranged one on top of the other further has at least one secondary component from carbides, nitrides, oxides, carbonitrides, oxinitrides; oxicarbides, oxicarbonitrides, borides, boronitrides, borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides, borooxocarbonitrides, oxoboronitrides of the elements of Groups IVa to VIla of the periodic system and/or aluminium and/or silicon, mixed metal phases and phase mixes of the afore-mentioned compounds. 9. A cutting tool according to one of the preceding claims, characterised in that the coating comprises further hard material layers consisting of carbides, nitrides, oxides, carbonitrides, oxinitrides, oxicarbides, oxicarbonitrides, borides, boronitrides, borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides, borooxocarbonitrides, oxoboronitrides of the elements from groups IVa to VIla of the periodic system and/or aluminium and/or silicon, mixed metal phases and phase mixes of the afore-mentioned compounds. 10. A cutting tool according to one of the preceding claims, characterised in that the layers of the coating have layer thicknesses of 10 nm to 50 µm, preferably of 20 nm to 20 µm, particularly preferably of 0.2 µm to 4 µm. 11. A cutting tool according to one of the preceding claims, characterised in that the coating has a Vickers hardness (Hv) of between 500 and 4000, preferably of between 700 and 3500, particularly preferably of between 1500 and 3000. 12. A cutting tool according to one of the preceding claims, characterised in that the base body is produced from hard metal, cermet, steel or high-speed steel (HSS). 13. A cutting tool according to one of the preceding claims, characterised in that the metal oxides of the at least two metal oxide layers arranged one on top of the other have the same crystal structure. 14. A cutting tool according to one of Claims 1 to 12, characterised in that the metal oxides of the at least two metal oxide layers arranged one on top of the other have a different crystal structure. 15. A cutting tool according to one of Claims 1 to 12, characterised in that within the XRD, XPS and/or TEM spectrum the phases which have the highest intensity (the main phases) of the at least two metal oxide layers arranged one on top of the other have the same crystal structure. 16. A cutting tool according to one of Claims 1 to 12, characterised in that within the XRD, XPS and/or TEM-spectrum the phases which have highest intensity (the main phases) of the at least two metal oxide layers arranged directly one on top of the other have a different crystal structure. 17. A process for the production of a cutting tool with a base body and a multilayered coating applied thereto, wherein metal oxide of the same metal or of different metals is applied successively by different PVD processes in at least two layers of the multilayered coating arranged one on top of the other, wherein the PVD- processes are selected from i) RMS, ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, and wherein modifications of the respective processes i) to v) do not constitute different PVD-processes. 18. A process according to Claim 17, characterised in that one of the at least two metal oxide layers arranged one on top of the other is applied by RMS, and a further one of the at least two metal oxide layers arranged one on top of the other, arranged thereon or thereunder, is applied by arc vapour deposition (arc-PVD). 19. A process according to one of Claims 17 or 18, characterised in that the at least two metal oxide layers arranged one on top of the other are applied successively by different PVD-processes in the same PVD-apparatus, without the cutting tool body being removed from the PVD-apparatus between the application of the at least two metal oxide layers arranged one on top of the other, and/or without the vacuum which prevails in the PVD-apparatus during the PVD-process being reduced between application of the at least two metal oxide layers arranged one on top of the other. The present invention relates to a cutting tool having a base body and a multilayered coating applied thereto, wherein at least two layers of the multilayered coating arranged one on top of the other contain, or consist of, metal oxide of the same metal or of different metals. In order to create cutting tools which are better than those of the prior art, it is proposed according to the invention that the at least two metal oxide layers arranged one on top of the other be produced successively by different PVD-processes, selected from i) reactive magnetron sputtering (RMS), ii) arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser deposition, wherein modifications of the respective processes i) to v) do not constitute different PVD-processes.

Full Text

Tool with Multi-Layered Metal Oxide Coating
The invention relates to a cutting tool having a base body and a multilayered coating
applied thereto, wherein at least two layers of the multilayered coating which are
arranged one on top of the other contain, or consist of, metal oxide of the same metal
or of different metals.
Prior Art
Cutting tools consist of a base body which is made, for example, of hard metal,
cermet, steel or high-speed steel. In order to increase durability, or, also, to improve
the cutting properties, a single-layered or multilayered coating is often applied to the
base body. This single-layered or multilayered coating may, for example, comprise
hard metal material layers, oxide layers, and the like. Application of the coating is
done by CVD-processes (chemical vapour deposition) and/or by PVD-processes
(physical vapour deposition). A plurality of layers within a coating can be applied by
means of CVD-processes alone, by means of PVD-processes alone, or by a
combination of both processes.
There are various variants of PVD-processes, e.g. i) magnetron sputtering, ii) arc
vapour deposition (Arc-PVD), iii) ion plating, iv) electron beam vapour deposition and
v) laser deposition. Magnetron sputtering and arc vapour deposition are the most
frequently used PVD-processes for coating tools. Within each individual PVD-
process variant there are, in turn, various modifications, e.g. pulsed or unpulsed
magnetron sputtering, or pulsed or unpulsed arc vapour deposition etc.
The target in the PVD-process may be a pure metal, or a combination of two or more
metals. If the target comprises several metals, then all those metals are incorporated
at the same time into the layer of a coating constructed during the PVD-process. The
ratio of the proportions of metals to one another in the constructed layer depends
upon the ratio of the proportions of metals in the target, but it also depends on
conditions in the PVD-process, since individual metals are released from the target in
greater amounts under certain conditions, and/or are deposited on the substrate in
greater amounts than other metals.
In order to produce certain metal compounds reactive gases are fed to the reaction
chamber during the PVD-process, e.g. nitrogen to produce nitrides, oxygen to
produce oxides, carbon-containing compounds to produce carbides, carbonitrides,
oxicarbides etc., or mixtures of these gases to produce corresponding mixed
compounds.
EP-A-0668369 discloses a PVD-coating process, wherein hard material layers
consisting of nitrides or carbonitrides of the metals Ti, Zr, Hf or alloys of TiAl, ZrAI,
HfAl, TiZr, TiZrAI, are produced with an imbalanced magnetron, wherein during a
specific time interval of the coating process additional coating material is deposited
from a cathodic arc discharge vapour deposition process onto the substrates to be
coated.
DE-A-102004044240 discloses the application to one or more metal oxide layers
onto a cutting tool in a PVD-process, in particular by the use of magnetron sputtering.
DE-A-19937284 describes an electrically conductive multi-layered build-up on a
metal substrate, having a first layer consisting of a metal material, in particular
chrome, the surface of which is passivated by naturally formed oxide, and having a
further layer of gold or gold alloy material which is applied by means of a
PVD-process. That second layer is capable of at least partially cancelling the
electrically insulating effect of the naturally formed oxide film of the first layer.
Coated arrangements of this kind are used, for example, as supporting structures for
the screened housing of electronic components.
DE-A19651592 describes a coated cutting tool having a multilayered coating
comprising at least one aluminium oxide layer and hard metal material layers. The
hard metal material layers are, for example, TiAIN-layers applied by means of
PVD-processes. The aluminium oxide layer which is applied directly thereon is also
deposited by way of a PVD-process.
Problem
The problem forming the basis of the present task was to provide cutting tools which
are better that the prior art.
This problem according to the invention is solved by way of a cutting tool of the kind
mentioned in the introduction, which is characterised in that the at least two metal
oxide layers, arranged one on top of the other, are produced successively by
different PVD processes selected from i) reactive magnetron sputtering, ii) arc vapour
deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser
deposition, wherein modifications of the respective processes i) to v) do not
constitute different PVD-processes.
In the sense of the present invention, i) magnetron sputtering, ii) arc vapour
deposition (Arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser
deposition are "different PVD-processes". Within each of these PVD-processes
i)tov) there are modifications, and, in the sense of the present invention, the
modifications of a PVD-process are not regarded as "different PVD-processes",
Modifications of the "magnetron sputtering" PVD-process are, for example, "dual
magnetron sputtering", "RF-magnetron sputtering", "bipolar magnetron sputtering",
"unipolar magnetron sputtering", "DC-diode-magnetron sputtering",
"DC-triode-magnetron sputtering", "pulsed magnetron sputtering", "unpulsed
magnetron sputtering" and mixes of the afore-mentioned processes.
Similarly, various modifications and mixed forms of modifications exist for the "arc
vapour deposition" (Arc-PVD), "ion plating", "electron beam vapour deposition" and
"laser deposition" PVD-processes. The modifications to PVD-processes i) to v) are
very well known to the person skilled in this domain, and therefore do not need to be
dealt with in greater detail here.
The application of a multilayered coating, and also of a coating comprising a plurality
of metal oxide layers, onto a cutting tool in the form of a wear protection coating has
been known for a long time. However, the application of the metal oxide layers to the
same base body using different PVD-processes is new and results in completely new
coatings with new properties. This new kind of coating according to the present
invention opens up a wide range of possibilities for improving and/or adapting the
resistance to wear, the durability and/or the cutting properties of cutting tools.
The resistance to wear, the durability and the cutting properties of a coating on a
cutting tool are dependent upon various factors, e.g. on the material of the base body
of the cutting tool, on the sequence, type and composition of the layers present in the
coating, on the thickness of the various layers, and, last but not least, on the type of
cutting operation which is performed by the cutting tool. Different resistances to wear
can result for one and the same cutting tool, depending upon the type of work piece
to be machined, the respective machining process, and other conditions during
machining, e.g. the development of high temperatures, or the use of corrosive
cooling agents. Furthermore, a distinction is made between different kinds of wear
which can have varying degrees of influence upon the useful life, i.e. the durability, of
a tool, depending upon the machining operation which it performs. Therefore, the
development and improvement of cutting tools must always be considered in terms of
which tool properties are to be improved, and it should be assessed under
comparable conditions to the prior art.
Surprisingly, it has been seen that by combining various PVD-processes for the
purpose of applying at least two metal oxide layers arranged one on top of the other
to the base body the properties of the entire coating can be purposefully influenced,
and cutting tools with an improved resistance to wear, an improved cutting ability and
better durability can be produced.
By applying the metal oxide layers using different PVD-processes, metal oxide layers
with different internal stress behaviours (internal compressive stress and internal
tensile stress), for example, are produced in relatively large layer thicknesses
(e.g. above 5 to 10 µ or more). By slightly adjusting various lattice parameters
(e.g. in Al2O3 and (AICr)2O3), whilst the lattice structure is the same, a significant
tensioning of the lattice, and thus an increase in hardness, can be produced, for
example. Further properties, such as red hardness, thermodynamic stability, low
crack propagation and the heat expansion coefficient can be purposefully influenced
in a coating according to the invention.
In one embodiment of the invention, in the coating of the cutting tool the two metal
oxide layers arranged one on top of the other are arranged directly on one another
without an intermediate layer/layers. In dependence on the deposited layers,
particularly good adhesion between the layers can advantageously result in this
instance.
In an alternative embodiment of the invention, in the coating of the cutting tool there
is arranged, between the two metal oxide layers arranged one on top of the other, at
least one non-oxide intermediate layer, preferably at least one metal nitride layer.
By way of example, a ZrN-layer can be provided between two ZrO2-Iayers. By
depositing a metal nitride layer as an intermediate layer, the deposition process of
the metal oxide layers is stabilised, and "decontamination" of the target(s) can be
achieved. Depending upon the material, an improvement in respect of the bonding of
the oxide layers has been observed. Furthermore, depending on the material, an
increase in hardness has also been found.
According to a further embodiment of the invention, in the coating of the cutting tool
one of the at least two metal oxide layers arranged one on top of the other is
produced by magnetron sputtering, and another of the at least two metal oxide layers
arranged one on top of the other, which is arranged thereabove or therebelow, is
produced by arc vapour deposition (arc-PVD).
In another embodiment of the invention, in the coating of the cutting tool the at least
two metal oxide layers arranged one on top of the other are produced successively
by different PVD-processes in the same PVD-apparatus, without the cutting tool body
being removed from the PVD-apparatus between application of the at least two metal
oxide layers arranged one on top of the other, and/or without the vacuum which
prevails in the PVD-apparatus during the PVD process being reduced between
application of the at least two metal oxide layers arranged one on top of the other.
In another embodiment of the invention, in the coating of the cutting tool the at least
two metal oxide layers arranged one on top of the other comprise oxides of the
elements from Groups IVa to VIla of the periodic system and/or aluminium and/or
silicon.
In another embodiment of the invention, in the coating of the cutting tool at least one
of the at least two metal oxide layers arranged one on top of the other has metal
oxide of just one metal.
In another embodiment of the invention, in the coating of the cutting tool at least one
of the at least two metal oxide layers arranged one on top of the other further has at
least one secondary component from carbides, nitrides, oxides, carbonitrides,
oxinitrides, oxicarbides, oxicarbonitrides, borides, boronitrides, borocarbides,
borocarbonitrides, borooxinitrides, borooxocarbides, borooxocarbonitrides,
oxoboronitrides of the elements of Groups IVa to VIla of the periodic system and/or
of aluminium and/or silicon, mixed metal phases and phase mixes of the afore-
mentioned compounds.
In another embodiment of the invention, in the coating of the cutting tool the coating
comprises further hard material layers consisting of carbides, nitrides, oxides,
carbonitrides, oxinitrides, oxicarbides, oxicarbonitrides, borides, boronitrides,
borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides,
borooxocarbonitrides, oxoboronitrides of the elements from groups IVa to VIla of the
periodic system and/or aluminium and/or silicon, mixed metal phases and phase
mixes of the afore-mentioned compounds.
In another embodiment of the invention, in the coating of the cutting tool the layers of
the coating have layer thicknesses of 10 nm to 50 µm, preferably of 20 nm to 20 µm,
particularly preferably of 0.2 µm to 4 µm.
In another embodiment of the invention, in the coating of the cutting tool the coating
has a Vickers hardness (Hv) of between 500 and 4000, preferably of between 700
and 3500, particularly preferably of between 1500 and 3000.
In another embodiment of the invention, in the coating of the cutting tool the base
body is produced from hard metal, cermet, steel or high-speed steel (HSS).
In another embodiment of the invention, in the coating of the cutting tool the metal
oxides of the at least two metal oxide layers arranged one on top of the other have
the same crystal structure. This means that depending on the material deposited
improved adhesion of the layers to one another can be achieved. Examples of metal
oxides with the same crystal structure are a-AI2O3 / Cr2O3.
In an alternative embodiment of the invention, in the coating of the cutting tool, the
metal oxides of the at least two metal oxide layers arranged one on top of the other
have a different crystal structure. Depending upon the material deposited, this can
be particularly advantageous for inhibiting column growth of the crystals and for
avoiding columns of crystallites, which would lead to increased brittleness.
In another embodiment of the invention, in the coating of the cutting tool the phases
within the XRD, XPS and/or TEM spectrum which have the highest intensity (the
main phases) of the at least two metal oxide layers arranged one on top of the other
have the same crystal structure.
In the context of the present invention, the main phases are those phases in a layer
of the coating which are clearly in excess over other phases of the same layer.
In another embodiment of the invention, in the coating of the cutting tool the phases
in the XRD, XPS and/or TEM-spectrum which have the highest intensity (the main
phases) of the at least two metal oxide layers arranged directly one on top of the
other have a different crystal structure.
The invention also comprises a process for the production of a cutting tool with a
base body and a multilayered coating applied thereto, wherein metal oxide of the
same metal or of different metals is applied successively by different PVD processes
in at least two layers of the multilayered coating arranged one on top of the other,
wherein the PVD-processes are selected from i) reactive magnetron sputtering, ii) arc
vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and
v) laser deposition, and wherein modifications of the respective processes i) to v) do
not constitute different PVD-processes.
In another embodiment of the process according to the invention, one of the at least
two metal oxide layers arranged one on top of the other is applied by reactive
magnetron sputtering, and a further one of the at least two metal oxide layers
arranged one on top of the other, arranged thereon or thereunder, is applied by arc
vapour deposition (arc-PVD).
In another embodiment of the process according to the invention, the at least two
metal oxide layers arranged one on top of the other are applied successively by
different PVD-processes in the same PVD-apparatus, without the cutting tool body
being removed from the PVD-apparatus between the application of the at least two
metal oxide layers arranged one on top of the other, and/or without the vacuum
which prevails in the PVD-apparatus during the PVD-process being reduced between
application of the at least two metal oxide layers arranged one on top of the other.
It will be clear that all individual features, such as described herein for specific
embodiments of the invention, can be combined with all the other features of the
inventive embodiments described, so far as this is technically reasonable and
possible, and that such combinations are considered to be disclosed within the scope
of this description. Simply for the sake of better readability, we will not name each
and every possible combination here.
Further advantages, features and embodiments of the present invention will be
described with the aid of the following examples.
EXAMPLES
In a PVD-coating apparatus (Flexicoat; Hauzer Techno Coating), hard metal
substrates composed of HM-coarse grain + 10.5% wt Co (HM-coarse grain = WC-
hard metal with an average grain size of 3 - 5 µm) were provided with a multi-layered
PVD-coating. The substrate geometry was SEHW120408 or ADMT160608-F56
(according to DIN-ISO 1832). Before the layers were deposited, the apparatus was
evacuated to 1x10-5 mbar, and the hard metal surface was cleaned by ion etching
with a bias voltage of 170 V.
Depositing of the Layers:
TiAIN (Arc Vapour Deposition; AVD)
¦Target: Ti/AI (33/67 At.-%) Round source (63 mm diameter),
¦ 80 amps, 495°C, 3 Pa N2-pressure, 40 volt substrate bias voltage,
Y-AI2O3 (Arc Vapour Deposition: AVD)
¦ Target: Al-Round source (63 mm diameter),
¦ 80 amps, 495°C, 0.7 Pa O2-pressure, 70 volt substrate bias voltage,
?-AI2O3 (reactive magnetron sputtering; RMS)
¦ Target: Al
¦ 10 kW sputtering output, 495°C, 0.5 Pa Ar-pressure, 150 volt substrate bias
voltage (unipolar, pulsed)
ZrO2 (Arc Vapour Deposition: AVD)
¦ Target: Zr-Round source (63 mm diameter),
¦ 80 amps, 495°C, 0.7 Pa O2-pressure, 70 volt substrate bias voltage
ZrO2 (reactive magnetron sputtering: RMS)
¦ Target: Zr
¦ 10 kW sputtering output, 495°C, 0.5 Pa Ar-pressure, 150 volt substrate bias
voltage (unipolar, pulsed),
The following coatings were applied onto the base body using different
PVD-processes:
The tools from Example 1 and from Comparative Examples 1a and 1b were
compared in a milling experiment on a workpiece composed of 42CrMoV4-steel
(strength: 850 MPa). Milling took place at a constant velocity, without cooling
lubricant, at a cutting rate of vc = 236 m/min and with a forward feed rate per tooth of
fz = 0.2 mm.
Wear was measured on the tool flank as an average wear of the cutting edge WCE in
mm (of the main cutting edge) after a milling path of 4800 mm. The following values
for wear to the cutting edge WCE were found:
Comparative Examples 1a and 1b showed an approximately linear increase in wear.
The results show a significantly better wear behaviour for the tool according to the
invention in Example 1 than for the tools according to Comparative Examples 1a
and 1b.

The tools of Example 2 and of Comparative Example 2 were compared in the same
milling experiment as that described for the tools of Example 1 and of Comparative
Examples 1a and 1b. The following values for wear to the cutting edge WCE were
found:

The results show a significantly better wear behaviour for the tool of Example 2
according to the invention than for the tool according to Comparative Example 2.
CLAIMS
WE CLAIM
1. A cutting tool having a base body and a multilayered coating applied thereto,
wherein at least two layers, arranged one on top of the other, of the multilayered
coating contain, or consist of, metal oxide of the same metal or of different metals,
characterised in that the at least two metal oxide layers arranged one on top of the
other are produced successively by different PVD processes selected from i) RMS, ii)
arc vapour deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition
and v) laser deposition, wherein modifications of the respective processes i) to v) do
not constitute different PVD-processes.
2. A cutting tool according to Claim 1, characterised in that the two metal oxide
layers arranged one on top of the other are arranged directly on one another without
intermediate layer(s).
3. A cutting tool according to Claim 1, characterised in that arranged between
the two metal oxide layers arranged one on top of the other is at least one non-oxide
intermediate layer, preferably at least one metal nitride layer.
4. A cutting tool according to one of the preceding claims, characterised in that
one of the at least two metal oxide layers arranged one on top of the other is
produced by RMS, and another of the at least two metal oxide layers arranged one
on top of the other, which is arranged thereabove or therebelow, is produced by arc
vapour deposition (arc-PVD).
5. A cutting tool according to one of the preceding claims, characterised in that
the at least two metal oxide layers arranged one on top of the other are produced
successively by different PVD-processes in the same PVD-apparatus, without the
cutting tool body being removed from the PVD-apparatus between application of the
at least two metal oxide layers arranged one on top of the other, and/or without the
vacuum which prevails in the PVD-apparatus during the PVD process being reduced
between application of the at least two metal oxide layers arranged one on top of the
other.
6. A cutting tool according to one of the preceding claims, characterised in that
the at least two metal oxide layers arranged one on top of the other comprise oxides
of the elements from Groups IVa to VIla of the periodic system and/or of aluminium
and/or silicon.
7. A cutting tool according to one of the preceding claims, characterised in that
at least one of the at least two metal oxide layers arranged one on top of the other
has metal oxide of just one metal.
8. A cutting tool according to one of the preceding claims, characterised in that
at least one of the at least two metal oxide layers arranged one on top of the other
further has at least one secondary component from carbides, nitrides, oxides,
carbonitrides, oxinitrides; oxicarbides, oxicarbonitrides, borides, boronitrides,
borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides,
borooxocarbonitrides, oxoboronitrides of the elements of Groups IVa to VIla of the
periodic system and/or aluminium and/or silicon, mixed metal phases and phase
mixes of the afore-mentioned compounds.
9. A cutting tool according to one of the preceding claims, characterised in that
the coating comprises further hard material layers consisting of carbides, nitrides,
oxides, carbonitrides, oxinitrides, oxicarbides, oxicarbonitrides, borides, boronitrides,
borocarbides, borocarbonitrides, borooxinitrides, borooxocarbides,
borooxocarbonitrides, oxoboronitrides of the elements from groups IVa to VIla of the
periodic system and/or aluminium and/or silicon, mixed metal phases and phase
mixes of the afore-mentioned compounds.
10. A cutting tool according to one of the preceding claims, characterised in that
the layers of the coating have layer thicknesses of 10 nm to 50 µm, preferably of
20 nm to 20 µm, particularly preferably of 0.2 µm to 4 µm.
11. A cutting tool according to one of the preceding claims, characterised in that
the coating has a Vickers hardness (Hv) of between 500 and 4000, preferably of
between 700 and 3500, particularly preferably of between 1500 and 3000.
12. A cutting tool according to one of the preceding claims, characterised in that
the base body is produced from hard metal, cermet, steel or high-speed steel (HSS).
13. A cutting tool according to one of the preceding claims, characterised in that
the metal oxides of the at least two metal oxide layers arranged one on top of the
other have the same crystal structure.
14. A cutting tool according to one of Claims 1 to 12, characterised in that the
metal oxides of the at least two metal oxide layers arranged one on top of the other
have a different crystal structure.
15. A cutting tool according to one of Claims 1 to 12, characterised in that within
the XRD, XPS and/or TEM spectrum the phases which have the highest intensity
(the main phases) of the at least two metal oxide layers arranged one on top of the
other have the same crystal structure.
16. A cutting tool according to one of Claims 1 to 12, characterised in that within
the XRD, XPS and/or TEM-spectrum the phases which have highest intensity (the
main phases) of the at least two metal oxide layers arranged directly one on top of
the other have a different crystal structure.
17. A process for the production of a cutting tool with a base body and a
multilayered coating applied thereto, wherein metal oxide of the same metal or of
different metals is applied successively by different PVD processes in at least two
layers of the multilayered coating arranged one on top of the other, wherein the PVD-
processes are selected from i) RMS, ii) arc vapour deposition (arc-PVD), iii) ion
plating, iv) electron beam vapour deposition and v) laser deposition, and wherein
modifications of the respective processes i) to v) do not constitute different
PVD-processes.
18. A process according to Claim 17, characterised in that one of the at least two
metal oxide layers arranged one on top of the other is applied by RMS, and a further
one of the at least two metal oxide layers arranged one on top of the other, arranged
thereon or thereunder, is applied by arc vapour deposition (arc-PVD).
19. A process according to one of Claims 17 or 18, characterised in that the at
least two metal oxide layers arranged one on top of the other are applied
successively by different PVD-processes in the same PVD-apparatus, without the
cutting tool body being removed from the PVD-apparatus between the application of
the at least two metal oxide layers arranged one on top of the other, and/or without
the vacuum which prevails in the PVD-apparatus during the PVD-process being
reduced between application of the at least two metal oxide layers arranged one on
top of the other.

The present invention relates to a cutting tool having a base body and a multilayered
coating applied thereto, wherein at least two layers of the multilayered coating
arranged one on top of the other contain, or consist of, metal oxide of the same metal
or of different metals. In order to create cutting tools which are better than those of
the prior art, it is proposed according to the invention that the at least two metal oxide
layers arranged one on top of the other be produced successively by different
PVD-processes, selected from i) reactive magnetron sputtering (RMS), ii) arc vapour
deposition (arc-PVD), iii) ion plating, iv) electron beam vapour deposition and v) laser
deposition, wherein modifications of the respective processes i) to v) do not
constitute different PVD-processes.

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Patent Number

278589

Indian Patent Application Number

70/KOLNP/2010

PG Journal Number

54/2016

Publication Date

30-Dec-2016

Grant Date

26-Dec-2016

Date of Filing

06-Jan-2010

Name of Patentee

WALTER AG

Applicant Address

DERENDINGER STRASSE 53, 72072 TUBINGEN, GERMANY

Inventors:

#	Inventor's Name	Inventor's Address
1	SCHIER, VEIT	OBERE GÄRTEN 21/1, 70771 LEINFELDEN-ECHTERDINGEN GERMANY

PCT International Classification Number

C23C14/00; C23C14/08; C23C30/00

PCT International Application Number

PCT/EP2008/056037

PCT International Filing date

2008-05-16

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	102007030735.9	2007-07-02	Germany