Title of Invention	A CUTTING TOOL
Abstract	The invention concerns a cutting tool having a base body and a single-layer or multi-layer coating applied thereto. To provide cutting tools which are improved over the state of the art it is proposed according to the invention that the coating includes at least one two-phase or multi-phase layer which contains at least two different phases of metal oxide, wherein the at least one two-phase or multi-phase layer is electrically conductive.

Title of Invention

A CUTTING TOOL

Abstract

The invention concerns a cutting tool having a base body and a single-layer or multi-layer coating applied thereto. To provide cutting tools which are improved over the state of the art it is proposed according to the invention that the coating includes at least one two-phase or multi-phase layer which contains at least two different phases of metal oxide, wherein the at least one two-phase or multi-phase layer is electrically conductive.

Full Text	Coated tool The invention concerns a cutting tool having a base body and a single-layer or multi-layer coating applied thereto. State of the art Cutting tools comprise a base body which is made for example from hard metal or carbide metal, cermet, steel or high-speed steel. Frequently a single-layer or multi-layer coating is applied to the base body to increase the service lives or also to improve the cutting properties. That single-layer or multi-layer coating includes for example metallic hard material layers, oxide layers and the like. CVD processes (chemical vapour deposition) and/or PVD processes (physical vapour deposition) are used for applying the layer. A plurality of layers within a coating can be applied exclusively by means of CVD processes, exclusively by means of PVD processes or by a combination of those processes. CVD processes provide substantially stable phases of the desired compounds whereas PVD processes also make it possible to apply metastable phases of compounds. In regard to the PVD processes, a distinction is made between various variants such as for example magnetron sputtering, arc vapour deposition (arc PVD), ion plating, electron beam evaporation and laser ablation. Magnetron sputtering and arc vapour deposition are among the PVD processes which are most frequently used for coating tools. There are in turn different modifications or variations of those PVD process variants such as for example pulsed or unpulsed magnetron sputtering or pulsed or unpulsed arc vapour deposition and so forth. DE 10 2004 044 240 A1 discloses a cutting tool with a layer structure having at least one single-phase, metastable, at least ternary oxide layer, wherein the oxide layer, besides oxygen, includes at least two further chemical elements selected from the elements in subgroups IV, V or VI of the period system, aluminium and silicon, of which one of the elements forms a primary component and at least a further one of the elements forms at least one secondary component. DE 199 37 284 A1 describes an electrically conducting multi-layer structure on a metallic substrate with a first layer comprising a metal material, in particular chromium, which is surface-passivating by naturally formed oxide, and a further layer applied by means of a PVD process comprising a gold or gold alloy material. That second layer is capable of at least partially neutralising the electrically insulating action of the naturally formed oxide film of the first layer. Arrangements which are coated in that way are used for example as carrier parts for screened mounting of electronic components. DE 196 51 592 A1 describes a coated cutting tool having a multi- layer coating which includes at least an aluminium oxide layer and metallic hard material layers. The metallic hard material layers are for example TiAIN layers applied by means of PVD processes. The aluminium oxide layer applied directly thereto is also deposited using a PVD process. DE 199 42 303 Al describes a cutting insert bit having a multi-phase aluminium oxide layer produced by a CVD process. The layer produced by the CVD process contains aluminium oxide, zirconium oxide and a third finely dispersed phase comprising an oxide, oxycarbide, oxynitride or oxycarbonitride of titanium. DE 197 37 470 Al describes a cutting body having a coating which has at least one multi-phase layer. The coating produced by a CVD process includes for example a zirconium carbonitride layer (cubic ZrCN) and ZrO2 in monoclinic and/or tetragonal form. The crystalline ZrCN matrix acts as a hard coating whereas the ZrO2 incorporated therein acts as a dry lubricant. DE 196 41 468 Al describes a composite body such as for example a cutting tool having a multi-layer coating with thin aluminium oxide layers and/or zirconium oxide layers. In coating cutting tools, in particular using a PVD process, only relatively thin coatings can be applied because of the normally insulating properties of the deposited layers. With an increasing layer thickness the procedure for deposition of the ions out of the plasma becomes unstable, which manifests itself for example particularly severely at the corners and edges of the coated body and detrimentally influences the hardness of the layers. To produce a cutting tool having a hard coating which has good properties even when greater layer thicknesses are involved stabilisation of the deposition procedure would therefore be desirable over a prolonged period of time, that is to say even when greater layer thicknesses are involved. Object The object of the present invention was that of providing cutting tools which are improved over the state of the art. The object according to the invention is attained by a cutting tool having a base body and a single-layer or multi-layer coating applied thereto, which is characterised in that the coating includes at least one two- phase or multi-phase layer which contains at least two different phases of metal oxide, wherein the at least one two-phase or multi-phase layer is electrically conductive. As already stated hereinbefore, the application of a single-layer or multi-layer coating to a cutting tool as a wear-resistant coating has long been known. What is novel in contrast is the production of such a coating with at least one two-phase or multi-phase layer which is electrically conductive and contains two different phases of metal oxide. That novel coating of the present invention opens up a wide range of possible options in terms of improving and/or adapting the resistance to wear, the service lives and/or the cutting properties of cutting tools. The resistance to wear, service life and cutting properties of a coating on a cutting tool depend on various factors such as for example the material of the base body of the cutting tool, the sequence, nature and composition of further layers present in the coating, the thickness of the various layers and not last the nature of the cutting operation performed with the cutting tool. For one and the same cutting tool, different resistances to wear can occur in dependence on the nature of the workpiece to be machined, the respective machining process and the further conditions during machining such as for example the generation of high temperatures or the use of corrosive cooling fluids. In addition a distinction is drawn between various kinds of wear which depending on the respective machining operation can influence the useful life of a tool, that is to say its service life, to a greater or lesser degree. Therefore further development of and improvement in cutting tools is always to be considered having regard to which tool properties are to be improved and is to be assessed under comparable conditions in relation to the state of the art. The at least one two-phase or multi-phase electrically conductive layer with at least two different phases of metal oxide, which is present in the coating according to the invention, can impart to the entire coating of the cutting tool properties which make the cutting tool superior to known cutting tools in comparable cutting operations and under comparable conditions. Those properties can involve resistance to wear, service lives, cutting properties or combinations thereof. In a preferred embodiment of the invention in the coating the at least two different phases of metal oxide in the at least one two-phase or multi-phase electrically conductive layer are at least two different phases of chromium oxide. The at least one two-phase or multi-phase layer can substantially completely consist of chromium oxide. Preferably it includes chromium oxide at least as a main component, that is to say in an amount which is predominant in relation to possible further components, with a proportion of chromium in relation to other metallic elements of at least 80 atomic %, preferably at least 90 atomic %, particularly preferably at least 95 atomic %. As a secondary component the at least two-phase or multi- phase layer can contain carbides, nitrides, oxides, carbonitrides, oxynitrides, oxycarbides, oxycarbonitrides, borides, boronitrides and oxoboronitrides of the elements of groups IVa to VIla of the periodic system and/or aluminium and/or silicon, hybrid metallic phases and phase mixtures of the aforementioned compounds, wherein chromium is excluded as an element of the secondary component. Main component in accordance with the present invention signifies that the metallic element is present in relation to other metallic elements of the same layer in an amount of at least 80 atomic %, preferably at least 90 atomic %, particularly preferably at least 95 atomic %. The compounds of the other metals in the same layer are referred in accordance with the present invention as a secondary component. In a further embodiment the at least one two-phase or multi-phase layer has at least three phases, wherein there is at least one phase of aluminium oxide. In this embodiment the other metal oxide which is not aluminium oxide and of which there are at least two different phases in the layer can be present as the main component and aluminium oxide as the secondary component. In a preferred variant of this embodiment the two- phase or multi-phase layer contains at least two phases of chromium oxide as the main component and a phase of aluminium oxide as the secondary component or hybrid phases of chromium oxide and aluminium oxide. In a further embodiment of the invention one of the metal oxide phases in the two-phase or multi-phase layer is a stable phase of metal oxide. In the embodiment according to the invention in which the at least one two-phase or multi-phase layer contains chromium oxide as the main component, the stable phase of metal oxide is preferably a phase of Cr2O3. In a further embodiment of the invention at least one of the metal oxide phases in the two-phase or multi-phase layer is a metastable phase. In the embodiment in which the at least one two-phase or multi-phase layer contains chromium oxide as the main component the metastable phase is preferably a metastable phase of chromium oxide of the stoichiometry CrOx, with 0.7 The term "stable phase" in accordance with this invention signifies a phase which under the given conditions is in a thermodynamically stable equilibrium state and does not change. The term "metastable phase" in accordance with this invention signifies a phase which is only apparently in a thermodynamic equilibrium state because under the given conditions such as for example pressure and/or temperature the equilibrium setting speed, that is to say the transition into the thermodynamically stable, lower-energy state, is too low. Metastable phases or states are such phases or states which only go into stable phases or states by elimination of an impediment. Elimination of the impediment can be effected by input of energy such as for example an increase in temperature or pressure. In a preferred embodiment of the invention in which the at least two different phases of metal oxide in the two-phase or multi-phase layer are chromium oxide phases, the elements chromium and oxygen taken together in the stable and metastable phases involve a ratio of Cr to O of about 1 to 0.8 - 1.2. If the ratio of Cr to O is greater than 1 to 0.8 (that is to say 1 to soft. If the ratio of Cr to O is less than 1 to 1.2 (that is to say 1 to >1.2) that has the disadvantage that the layer becomes too brittle. In a further preferred embodiment of the invention among the at least two different phases of metal oxide in the at least one two-phase or multi-phase layer at least one metal oxide phase is electrically conductive. If the main component of the two-phase or multi-phase layer comprises chromium oxide, then no phase of CrO2 which considered in itself would represent a conductive chromium oxide phase is included. The absence of a phase of CrO2 in the electrically conductive layer can be detected by means of XPS measurement. In such a layer containing chromium oxide as the main component, phases of Cr2O3, CrO3, CrOx with 0.7 detected by means of XPS measurement, but no phase of CrO2 (see Figure 1). The electrical conductivity of the two-phase or multi-phase layer is therefore not based on the presence of CrO2 which is electrically conductive in itself. The at least one two-phase or multi-phase layer of the coating is preferably of a layer thickness of 10 nm to 50 µm. If the layer thickness of the two-phase or multi-phase layer is less than 10 nm, its protective or wear resistance function is excessively low. If the layer thickness of the two-phase or multi-phase layer is greater than 50 µm excessively high stresses occur in the layer and the layer becomes too brittle, and that can lead to adhesion problems and spalling in operation of the tool. In a further embodiment the layer is of a layer thickness of 20 nm to 20 µm. In still a further embodiment the layer is of a layer thickness of 0.5 µm to 4 µm. Usually the at least one two-phase or multi-phase layer is of a Vickers hardness (Hv) of 500 to 4000. In a preferred embodiment the layer is of a Vickers hardness (Hv) of 700 to 3000. In still a further preferred embodiment the layer is of a Vickers hardness (Hv) of 800 to 2000. The electrical conductivity of the at least one two-phase or multi- phase layer in the coating of the present invention is markedly higher than that of non-conductors and semiconductors and is of the order of magnitude of metallic conductors. It is desirably more than 1 S/m. Preferably the electrical conductivity is more than 100 S/m. In a further embodiment the layer is of an electrical conductivity of more than 104 S/m. The electrical conductivity of the two-phase or multi-phase layer contained in the coating according to the invention is a surprising phenomenon as the layer as the main component contains metal oxides which are usually non-conducting. The conductivity of the layer is also not to be attributed to the presence of phases of pure metals as they are to be found in the layer not at all or only in negligibly small amounts which cannot explain electrical conductivity of the overall layer. The two-phase or multi-phase layer in the coating of the invention also does not contain any phases of metal oxides which considered in themselves are known to be electrically conductive such as for example CrO2, in proportions which could explain electrical conductivity of the overall layer. It is not possible at the present time to provide a definite explanation of the electrical conductivity of the two-phase or multi-phase layers according to the invention in the coating. It is assumed however that the two-phase or multi-phase layer according to the invention contains metastable, non-stoichiometric metal oxide phases which impart to the overall layer electrical conductivity of the order of magnitude of the conductivity of metals and which contribute to the excellent material properties of the coating according to the invention. In a further embodiment of the invention the at least one two-phase or multi-phase layer further has at least one secondary component. As a secondary component or components the at least one two-phase or multi- phase layer can contain carbides, nitrides, oxides, carbonitrides, oxynitrides, oxycarbides, oxycarbonitrides, borides, boronitrides and oxoboronitrides of the elements of groups IVa to Vlla of the periodic system and/or aluminium and/or silicon, hybrid-metallic phases and phase mixtures of the aforementioned compounds. Examples of such secondary compounds are (Al, Cr)2O3 with a ratio by weight of AI:Cr = 9:1, (Cr, AI, Si)2O3 with a ratio by weight of AI:Si = 9:1 and Cr:(AI, Si) = 1:2. If the coating of the cutting tool according to the invention is of a multi-layer structure it can include further hard material layers of the compositions specified hereinbefore for the secondary components. Examples of such hard material layers are layers comprising Al2O3, TiN, TiB2, cBN,hBN, TiBN, TiC, TiCN, TiN, TiAIN, CrAIN, TiAICN, TiAlYN, TiAICrN and CrN. Instead of or in addition to one or more hard material layers the coating can have one or more further two-phase or multi-phase layers which contain at least two different phases of metal oxide and are electrically conductive. The present invention thus includes coatings which only comprise one or more of the two-phase or multi-phase layers with at least two different phases of metal oxide of electrical conductivity, and also coatings which include any combination of such layers with further hard material layers in any number and sequence. Preferred coatings of the cutting tool according to the invention involve the following layers: (Al, Cr)2O3 - AlCrN - (AI, Cr)O, TiAIN - (Al, Cr)O, AlCrN - (Al, Cr)O, TiAIN - Al2O3 - (AI, Cr)O, CrAIN - [(Al, Cr)O - Al2O3]x - ZrN The two-phase or multi-phase layer contained in the coating of the cutting tool according to the invention, having at least two different phases of metal oxide and of electrical conductivity, is preferably produced by a PVD process, particularly preferably by magnetron sputtering, arc vapour deposition (arc PVD) or modifications of those processes. In the PVD coating installation a plasma atmosphere is produced at low pressure, which substantially comprises argon and oxygen. In the PVD magnetron process an argon plasma is fired in front of the target. High-power cathode sputtering occurs (magnetron sputtering). The metal vapour produced from the target in that way is deposited on the substrate with a reaction with the oxygen as a metal oxide layer. Further advantages, features and embodiments of the present invention are described by reference to the following examples and the Figure. Example 1 In a PVD coating installation (Flexicoat; Hauzer Techno Coating) hard metal substrates were provided with a two-layer PVD coating. Prior to deposition of the layers the installation was evacuated to 1x10-5 mbars and the hard metal surface was cleaned by ion etching at 170 V bias voltage. Substrate compositions: 1) HM-fine grain + 10.5 % by weight Co 2) HM-coarse grain + 10.5 % by weight Co +1 % by weight MC 3) HM-coarse grain + 11.0 % by weight Co +1 % by weight MC (Explanation: HM-fine grain = WC hard metal of mean grain size of ~ 1 µm HM-coarse grain = WC hard metal of mean grain size of 3 - 5 µm) MC = mixed carbides (TiC, TaC ...). Substrate geometry: SEHW120408 (in accordance with DIN-ISO 1832) Deposition of the layers: 1st layer: TiAIIM • arc deposition • target: Ti/AI (33/67 atomic %), round source (63 mm diameter), • 80 amperes, 495°C, 3 Pa N2 pressure, 40 volts substrate bias voltage, • 3 µm layer thickness; 2nd layer: (Al, Cr)2O3 • reactive magnetron sputtering, • target: Al/Cr (90/10 atomic %), round source (63 mm diameter), • 10 kW sputter power, 495°C, 0.5 Pa Ar pressure, about 100 sccm O2, 150 volts substrate bias voltage (unipolarly pulsed), • 1 µm layer thickness. The TiAIN layer serves for bonding between the substrate and the oxidic layer. XRD measurements, XPS measurements, microprobe measurements and resistance measurements were performed on the coating. The microprobe measurements for determining the overall composition were performed on a single (Al, Cr)2O3 layer as measurements on the layer composite TiAIN-(AI, Cr)2O3 with the microprobe leads to measurement errors. Resistance and conductivity measurements showed that the (Al, Cr)2O3 layer in the case of all substrates was overall electrically conductive, with conductivity levels of about 10 S/m. It was established by XRD and XPS measurement that the (Al, Cr)2O3 layer in the case of all substrates contained a stable y-AI2O3 phase, two stable Cr-oxide phases (CrO3, Cr2O3) and a rnetastable Cr-oxide phase (CrOx). Figure 1 shows the XPS spectrum of Cr (Mg Ka radiation). XPS measurement confirmed that the layer contained a total of 3 chromium oxide phases. The phase proportions estimated from XPS measurement were approximately as follows: Cr2O3 65 % by weight CrOx 20 % by weight CrO3 15 % by weight, wherein x was 0.9. In addition the results of the measurement operations showed that, within the (Al, Cr)2O3 layer, the rnetastable Cr-oxide phase was the only one of the metal oxide phases which was electrically conductive and imparted conductivity to the overall layer. A phase of conductive CrO2 could be excluded by virtue of the ascertained phase proportions and the proportion of oxygen determined by microprobe measurement. Comparative example For comparison purposes the same substrates as in Example 1 were provided in the same coating installation with a two-layer coating of the layer sequence 3 µm TiAIN - 1 µm Al2O3. The deposition conditions were the same as in Example 1 with the exception that a pure Al target was used in the step for the deposition of the Al2O3 layer. In a milling trial on a workpiece comprising 42CrMoV4 steel (strength: 850 MPa) the tools of Example 1 and the comparative example were compared. Milling was effected in the downcut mode without cooling lubricant at a cutting speed Vc = 236 m/min and a tooth feed fz = 0.2 mm. The amount of wear was measured on the tool flank surface in the form of the average wear mark width VB in mm (at the main cutting edge) after a milling travel of 4800 mm. The following wear mark widths VB were found: WE CLAIM 1. A cutting tool (1) having a base body (2) and a single-layer or multi-layer coating (3) applied thereto, characterised in that the coating includes at least one two-phase or multi-phase layer (4) which contains at least two different phases of metal oxide, wherein the at least one two- phase or multi-phase layer (4) is electrically conductive. 2. A cutting tool according to claim 1 characterised in that the at least two different phases of metal oxide in the at least one two-phase or multi-phase electrically conductive layer (4) are at least two different phases of chromium oxide. 3. A cutting tool according to claim 2 characterised in that the at least one two-phase or multi-phase layer (4) contains chromium oxide as the main component. 4. A cutting tool according to one of claims 1 to 3 characterised in that the at least one two-phase or multi-phase layer (4) has at least three phases, wherein there is at least one phase of aluminium oxide. 5. A cutting tool according to one of claims 1 to 4 characterised in that one of the metal oxide phases in the two-phase or multi-phase layer (4) is a stable phase of metal oxide, preferably a phase of Cr2O3. 6. A cutting tool according to one of claims 1 to 5 characterised in that at least one of the metal oxide phases in the two-phase or multi-phase layer (4) is a metastable phase, preferably a metastable phase of chromium oxide of the stoichiometry CrOx, with 0.7 7. A cutting tool according to one of claims 1 to 6 characterised in that the at least two different phases of metal oxide in the two-phase or multi-phase layer (4) are chromium oxide phases which taken together have a ratio of the elements Cr to O of about 1 to 0.8 - 1.2. 8. A cutting tool according to one of claims 1 to 7 characterised in that among the at least two different phases of metal oxide in the at least one two-phase or multi-phase layer (4) at least one metal oxide phase is electrically conductive. 9. A cutting tool according to one of claims 1 to 8 characterised in that the metal oxide phases in the two-phase or multi-phase layer (4) do not include a phase of CrO2. 10. A cutting tool according to one of claims 1 to 9 characterised in that the at least one two-phase or multi-phase layer (4) is of a layer thickness of 10 nm to 50 µm, preferably 20 nm to 20 µm, particularly preferably 0.5 µm to 4 µm. 11. A cutting tool according to one of claims 1 to 10 characterised in that the at least one two-phase or multi-phase layer (4) is of a Vickers hardness (Hv) of 500 to 4000, preferably 700 to 3000, particularly preferably 800 to 2000. 12. A cutting tool according to one of claims 1 to 11 characterised in that the at least one two-phase or multi-phase layer (4) is of an electrical conductivity of more than 1 S/m, preferably more than 100 S/m, particularly preferably more than 104 S/m. 13. A cutting tool according to one of claims 1 to 14 characterised in that the at least one two-phase or multi-phase layer (4) further has at least one secondary component formed by elements of subgroups IV, V or VI of the periodic system of the elements, aluminium and/or silicon and O, N, C and/or B. 14. A cutting tool according to one of claims 1 to 13 characterised in that the coating (3) includes further hard material layers formed by elements of subgroups IV, V or VI of the periodic system of the elements, aluminium and/or silicon and O, N, C and/or B. 15. A cutting tool according to one of claims 1 to 14 characterised in that the at least one two-phase or multi-phase layer (4) is produced by a PVD process, preferably by magnetron sputtering, arc vapour deposition (arc PVD) or modifications of said processes. 16. A cutting tool according to one of claims 1 to 15 characterised in that the base body is made from hard metal or carbide metal, cermet, steel or high-speed steel (HSS). 17. A cutting tool according to one of claims 1 to 16 characterised in that the coating includes at least two of the two-phase or multi-phase layers (4, 4') according to one of the preceding claims, wherein the at least two of the two-phase or multi-phase layers (4, 4') are arranged in directly superposed relationship or are separated from each other by one or more further hard material layers. 18. A cutting tool according to claim 17 characterised in that the at least two of the two-phase or multi-phase layers (4, 4') are of different compositions, different Vickers hardnesses (Hv) and/or different conductivities. The invention concerns a cutting tool having a base body and a single-layer or multi-layer coating applied thereto. To provide cutting tools which are improved over the state of the art it is proposed according to the invention that the coating includes at least one two-phase or multi-phase layer which contains at least two different phases of metal oxide, wherein the at least one two-phase or multi-phase layer is electrically conductive.

Full Text

Coated tool
The invention concerns a cutting tool having a base body and a
single-layer or multi-layer coating applied thereto.
State of the art
Cutting tools comprise a base body which is made for example from
hard metal or carbide metal, cermet, steel or high-speed steel. Frequently
a single-layer or multi-layer coating is applied to the base body to increase
the service lives or also to improve the cutting properties. That single-layer
or multi-layer coating includes for example metallic hard material layers,
oxide layers and the like. CVD processes (chemical vapour deposition)
and/or PVD processes (physical vapour deposition) are used for applying
the layer. A plurality of layers within a coating can be applied exclusively
by means of CVD processes, exclusively by means of PVD processes or by a
combination of those processes. CVD processes provide substantially
stable phases of the desired compounds whereas PVD processes also make
it possible to apply metastable phases of compounds.
In regard to the PVD processes, a distinction is made between
various variants such as for example magnetron sputtering, arc vapour
deposition (arc PVD), ion plating, electron beam evaporation and laser
ablation. Magnetron sputtering and arc vapour deposition are among the
PVD processes which are most frequently used for coating tools. There are
in turn different modifications or variations of those PVD process variants
such as for example pulsed or unpulsed magnetron sputtering or pulsed or
unpulsed arc vapour deposition and so forth.
DE 10 2004 044 240 A1 discloses a cutting tool with a layer structure
having at least one single-phase, metastable, at least ternary oxide layer,
wherein the oxide layer, besides oxygen, includes at least two further
chemical elements selected from the elements in subgroups IV, V or VI of
the period system, aluminium and silicon, of which one of the elements
forms a primary component and at least a further one of the elements
forms at least one secondary component.
DE 199 37 284 A1 describes an electrically conducting multi-layer
structure on a metallic substrate with a first layer comprising a metal
material, in particular chromium, which is surface-passivating by naturally
formed oxide, and a further layer applied by means of a PVD process
comprising a gold or gold alloy material. That second layer is capable of at
least partially neutralising the electrically insulating action of the naturally
formed oxide film of the first layer. Arrangements which are coated in that
way are used for example as carrier parts for screened mounting of
electronic components.
DE 196 51 592 A1 describes a coated cutting tool having a multi-
layer coating which includes at least an aluminium oxide layer and metallic
hard material layers. The metallic hard material layers are for example
TiAIN layers applied by means of PVD processes. The aluminium oxide
layer applied directly thereto is also deposited using a PVD process.
DE 199 42 303 Al describes a cutting insert bit having a multi-phase
aluminium oxide layer produced by a CVD process. The layer produced by
the CVD process contains aluminium oxide, zirconium oxide and a third
finely dispersed phase comprising an oxide, oxycarbide, oxynitride or
oxycarbonitride of titanium.
DE 197 37 470 Al describes a cutting body having a coating which
has at least one multi-phase layer. The coating produced by a CVD process
includes for example a zirconium carbonitride layer (cubic ZrCN) and ZrO2
in monoclinic and/or tetragonal form. The crystalline ZrCN matrix acts as a
hard coating whereas the ZrO2 incorporated therein acts as a dry lubricant.
DE 196 41 468 Al describes a composite body such as for example a
cutting tool having a multi-layer coating with thin aluminium oxide layers
and/or zirconium oxide layers.
In coating cutting tools, in particular using a PVD process, only
relatively thin coatings can be applied because of the normally insulating
properties of the deposited layers. With an increasing layer thickness the
procedure for deposition of the ions out of the plasma becomes unstable,
which manifests itself for example particularly severely at the corners and
edges of the coated body and detrimentally influences the hardness of the
layers. To produce a cutting tool having a hard coating which has good
properties even when greater layer thicknesses are involved stabilisation of
the deposition procedure would therefore be desirable over a prolonged
period of time, that is to say even when greater layer thicknesses are
involved.
Object
The object of the present invention was that of providing cutting
tools which are improved over the state of the art.
The object according to the invention is attained by a cutting tool
having a base body and a single-layer or multi-layer coating applied
thereto, which is characterised in that the coating includes at least one two-
phase or multi-phase layer which contains at least two different phases of
metal oxide, wherein the at least one two-phase or multi-phase layer is
electrically conductive.
As already stated hereinbefore, the application of a single-layer or
multi-layer coating to a cutting tool as a wear-resistant coating has long
been known. What is novel in contrast is the production of such a coating
with at least one two-phase or multi-phase layer which is electrically
conductive and contains two different phases of metal oxide. That novel
coating of the present invention opens up a wide range of possible options
in terms of improving and/or adapting the resistance to wear, the service
lives and/or the cutting properties of cutting tools.
The resistance to wear, service life and cutting properties of a
coating on a cutting tool depend on various factors such as for example the
material of the base body of the cutting tool, the sequence, nature and
composition of further layers present in the coating, the thickness of the
various layers and not last the nature of the cutting operation performed
with the cutting tool. For one and the same cutting tool, different
resistances to wear can occur in dependence on the nature of the
workpiece to be machined, the respective machining process and the
further conditions during machining such as for example the generation of
high temperatures or the use of corrosive cooling fluids. In addition a
distinction is drawn between various kinds of wear which depending on the
respective machining operation can influence the useful life of a tool, that is
to say its service life, to a greater or lesser degree. Therefore further
development of and improvement in cutting tools is always to be
considered having regard to which tool properties are to be improved and is
to be assessed under comparable conditions in relation to the state of the
art.
The at least one two-phase or multi-phase electrically conductive
layer with at least two different phases of metal oxide, which is present in
the coating according to the invention, can impart to the entire coating of
the cutting tool properties which make the cutting tool superior to known
cutting tools in comparable cutting operations and under comparable
conditions. Those properties can involve resistance to wear, service lives,
cutting properties or combinations thereof.
In a preferred embodiment of the invention in the coating the at
least two different phases of metal oxide in the at least one two-phase or
multi-phase electrically conductive layer are at least two different phases of
chromium oxide. The at least one two-phase or multi-phase layer can
substantially completely consist of chromium oxide. Preferably it includes
chromium oxide at least as a main component, that is to say in an amount
which is predominant in relation to possible further components, with a
proportion of chromium in relation to other metallic elements of at least 80
atomic %, preferably at least 90 atomic %, particularly preferably at least
95 atomic %. As a secondary component the at least two-phase or multi-
phase layer can contain carbides, nitrides, oxides, carbonitrides,
oxynitrides, oxycarbides, oxycarbonitrides, borides, boronitrides and
oxoboronitrides of the elements of groups IVa to VIla of the periodic
system and/or aluminium and/or silicon, hybrid metallic phases and phase
mixtures of the aforementioned compounds, wherein chromium is excluded
as an element of the secondary component.
Main component in accordance with the present invention signifies
that the metallic element is present in relation to other metallic elements of
the same layer in an amount of at least 80 atomic %, preferably at least 90
atomic %, particularly preferably at least 95 atomic %. The compounds of
the other metals in the same layer are referred in accordance with the
present invention as a secondary component.
In a further embodiment the at least one two-phase or multi-phase
layer has at least three phases, wherein there is at least one phase of
aluminium oxide. In this embodiment the other metal oxide which is not
aluminium oxide and of which there are at least two different phases in the
layer can be present as the main component and aluminium oxide as the
secondary component. In a preferred variant of this embodiment the two-
phase or multi-phase layer contains at least two phases of chromium oxide
as the main component and a phase of aluminium oxide as the secondary
component or hybrid phases of chromium oxide and aluminium oxide.
In a further embodiment of the invention one of the metal oxide
phases in the two-phase or multi-phase layer is a stable phase of metal
oxide. In the embodiment according to the invention in which the at least
one two-phase or multi-phase layer contains chromium oxide as the main
component, the stable phase of metal oxide is preferably a phase of Cr2O3.
In a further embodiment of the invention at least one of the metal
oxide phases in the two-phase or multi-phase layer is a metastable phase.
In the embodiment in which the at least one two-phase or multi-phase
layer contains chromium oxide as the main component the metastable
phase is preferably a metastable phase of chromium oxide of the
stoichiometry CrOx, with 0.7 The term "stable phase" in accordance with this invention signifies a
phase which under the given conditions is in a thermodynamically stable
equilibrium state and does not change.
The term "metastable phase" in accordance with this invention
signifies a phase which is only apparently in a thermodynamic equilibrium
state because under the given conditions such as for example pressure
and/or temperature the equilibrium setting speed, that is to say the
transition into the thermodynamically stable, lower-energy state, is too low.
Metastable phases or states are such phases or states which only go into
stable phases or states by elimination of an impediment. Elimination of the
impediment can be effected by input of energy such as for example an
increase in temperature or pressure.
In a preferred embodiment of the invention in which the at least two
different phases of metal oxide in the two-phase or multi-phase layer are
chromium oxide phases, the elements chromium and oxygen taken
together in the stable and metastable phases involve a ratio of Cr to O of
about 1 to 0.8 - 1.2. If the ratio of Cr to O is greater than 1 to 0.8 (that is
to say 1 to soft. If the ratio of Cr to O is less than 1 to 1.2 (that is to say 1 to >1.2)
that has the disadvantage that the layer becomes too brittle.
In a further preferred embodiment of the invention among the at
least two different phases of metal oxide in the at least one two-phase or
multi-phase layer at least one metal oxide phase is electrically conductive.
If the main component of the two-phase or multi-phase layer comprises
chromium oxide, then no phase of CrO2 which considered in itself would
represent a conductive chromium oxide phase is included. The absence of
a phase of CrO2 in the electrically conductive layer can be detected by
means of XPS measurement. In such a layer containing chromium oxide as
the main component, phases of Cr2O3, CrO3, CrOx with 0.7 detected by means of XPS measurement, but no phase of CrO2 (see Figure
1). The electrical conductivity of the two-phase or multi-phase layer is
therefore not based on the presence of CrO2 which is electrically conductive
in itself.
The at least one two-phase or multi-phase layer of the coating is
preferably of a layer thickness of 10 nm to 50 µm. If the layer thickness of
the two-phase or multi-phase layer is less than 10 nm, its protective or
wear resistance function is excessively low. If the layer thickness of the
two-phase or multi-phase layer is greater than 50 µm excessively high
stresses occur in the layer and the layer becomes too brittle, and that can
lead to adhesion problems and spalling in operation of the tool. In a
further embodiment the layer is of a layer thickness of 20 nm to 20 µm. In
still a further embodiment the layer is of a layer thickness of 0.5 µm to 4
µm.
Usually the at least one two-phase or multi-phase layer is of a
Vickers hardness (Hv) of 500 to 4000. In a preferred embodiment the
layer is of a Vickers hardness (Hv) of 700 to 3000. In still a further
preferred embodiment the layer is of a Vickers hardness (Hv) of 800 to
2000.
The electrical conductivity of the at least one two-phase or multi-
phase layer in the coating of the present invention is markedly higher than
that of non-conductors and semiconductors and is of the order of
magnitude of metallic conductors. It is desirably more than 1 S/m.
Preferably the electrical conductivity is more than 100 S/m. In a further
embodiment the layer is of an electrical conductivity of more than 104 S/m.
The electrical conductivity of the two-phase or multi-phase layer
contained in the coating according to the invention is a surprising
phenomenon as the layer as the main component contains metal oxides
which are usually non-conducting. The conductivity of the layer is also not
to be attributed to the presence of phases of pure metals as they are to be
found in the layer not at all or only in negligibly small amounts which
cannot explain electrical conductivity of the overall layer. The two-phase or
multi-phase layer in the coating of the invention also does not contain any
phases of metal oxides which considered in themselves are known to be
electrically conductive such as for example CrO2, in proportions which could
explain electrical conductivity of the overall layer.
It is not possible at the present time to provide a definite explanation
of the electrical conductivity of the two-phase or multi-phase layers
according to the invention in the coating. It is assumed however that the
two-phase or multi-phase layer according to the invention contains
metastable, non-stoichiometric metal oxide phases which impart to the
overall layer electrical conductivity of the order of magnitude of the
conductivity of metals and which contribute to the excellent material
properties of the coating according to the invention.
In a further embodiment of the invention the at least one two-phase
or multi-phase layer further has at least one secondary component. As a
secondary component or components the at least one two-phase or multi-
phase layer can contain carbides, nitrides, oxides, carbonitrides,
oxynitrides, oxycarbides, oxycarbonitrides, borides, boronitrides and
oxoboronitrides of the elements of groups IVa to Vlla of the periodic
system and/or aluminium and/or silicon, hybrid-metallic phases and phase
mixtures of the aforementioned compounds. Examples of such secondary
compounds are (Al, Cr)2O3 with a ratio by weight of AI:Cr = 9:1, (Cr, AI,
Si)2O3 with a ratio by weight of AI:Si = 9:1 and Cr:(AI, Si) = 1:2.
If the coating of the cutting tool according to the invention is of a
multi-layer structure it can include further hard material layers of the
compositions specified hereinbefore for the secondary components.
Examples of such hard material layers are layers comprising Al2O3, TiN,
TiB2, cBN,hBN, TiBN, TiC, TiCN, TiN, TiAIN, CrAIN, TiAICN, TiAlYN, TiAICrN
and CrN. Instead of or in addition to one or more hard material layers the
coating can have one or more further two-phase or multi-phase layers
which contain at least two different phases of metal oxide and are
electrically conductive. The present invention thus includes coatings which
only comprise one or more of the two-phase or multi-phase layers with at
least two different phases of metal oxide of electrical conductivity, and also
coatings which include any combination of such layers with further hard
material layers in any number and sequence.
Preferred coatings of the cutting tool according to the invention
involve the following layers:
(Al, Cr)2O3 - AlCrN - (AI, Cr)O,
TiAIN - (Al, Cr)O,
AlCrN - (Al, Cr)O,
TiAIN - Al2O3 - (AI, Cr)O,
CrAIN - [(Al, Cr)O - Al2O3]x - ZrN
The two-phase or multi-phase layer contained in the coating of the
cutting tool according to the invention, having at least two different phases
of metal oxide and of electrical conductivity, is preferably produced by a
PVD process, particularly preferably by magnetron sputtering, arc vapour
deposition (arc PVD) or modifications of those processes. In the PVD
coating installation a plasma atmosphere is produced at low pressure,
which substantially comprises argon and oxygen. In the PVD magnetron
process an argon plasma is fired in front of the target. High-power cathode
sputtering occurs (magnetron sputtering). The metal vapour produced
from the target in that way is deposited on the substrate with a reaction
with the oxygen as a metal oxide layer.
Further advantages, features and embodiments of the present
invention are described by reference to the following examples and the
Figure.
Example 1
In a PVD coating installation (Flexicoat; Hauzer Techno Coating) hard
metal substrates were provided with a two-layer PVD coating. Prior to
deposition of the layers the installation was evacuated to 1x10-5 mbars and
the hard metal surface was cleaned by ion etching at 170 V bias voltage.
Substrate compositions:
1) HM-fine grain + 10.5 % by weight Co
2) HM-coarse grain + 10.5 % by weight Co +1 % by weight MC
3) HM-coarse grain + 11.0 % by weight Co +1 % by weight MC
(Explanation:
HM-fine grain = WC hard metal of mean grain size of ~ 1 µm
HM-coarse grain = WC hard metal of mean grain size of 3 - 5 µm)
MC = mixed carbides (TiC, TaC ...).
Substrate geometry: SEHW120408 (in accordance with DIN-ISO 1832)
Deposition of the layers:
1st layer: TiAIIM
• arc deposition
• target: Ti/AI (33/67 atomic %), round source (63 mm diameter),
• 80 amperes, 495°C, 3 Pa N2 pressure, 40 volts substrate bias voltage,
• 3 µm layer thickness;
2nd layer: (Al, Cr)2O3
• reactive magnetron sputtering,
• target: Al/Cr (90/10 atomic %), round source (63 mm diameter),
• 10 kW sputter power, 495°C, 0.5 Pa Ar pressure, about 100 sccm O2,
150 volts substrate bias voltage (unipolarly pulsed),
• 1 µm layer thickness.
The TiAIN layer serves for bonding between the substrate and the
oxidic layer. XRD measurements, XPS measurements, microprobe
measurements and resistance measurements were performed on the
coating. The microprobe measurements for determining the overall
composition were performed on a single (Al, Cr)2O3 layer as measurements
on the layer composite TiAIN-(AI, Cr)2O3 with the microprobe leads to
measurement errors. Resistance and conductivity measurements showed
that the (Al, Cr)2O3 layer in the case of all substrates was overall electrically
conductive, with conductivity levels of about 10 S/m.
It was established by XRD and XPS measurement that the (Al, Cr)2O3
layer in the case of all substrates contained a stable y-AI2O3 phase, two
stable Cr-oxide phases (CrO3, Cr2O3) and a rnetastable Cr-oxide phase
(CrOx). Figure 1 shows the XPS spectrum of Cr (Mg Ka radiation). XPS
measurement confirmed that the layer contained a total of 3 chromium
oxide phases. The phase proportions estimated from XPS measurement
were approximately as follows:
Cr2O3 65 % by weight
CrOx 20 % by weight
CrO3 15 % by weight,
wherein x was 0.9. In addition the results of the measurement operations
showed that, within the (Al, Cr)2O3 layer, the rnetastable Cr-oxide phase
was the only one of the metal oxide phases which was electrically
conductive and imparted conductivity to the overall layer. A phase of
conductive CrO2 could be excluded by virtue of the ascertained phase
proportions and the proportion of oxygen determined by microprobe
measurement.
Comparative example
For comparison purposes the same substrates as in Example 1 were
provided in the same coating installation with a two-layer coating of the
layer sequence 3 µm TiAIN - 1 µm Al2O3. The deposition conditions were
the same as in Example 1 with the exception that a pure Al target was used
in the step for the deposition of the Al2O3 layer.

In a milling trial on a workpiece comprising 42CrMoV4 steel
(strength: 850 MPa) the tools of Example 1 and the comparative example
were compared. Milling was effected in the downcut mode without cooling
lubricant at a cutting speed Vc = 236 m/min and a tooth feed fz = 0.2 mm.
The amount of wear was measured on the tool flank surface in the
form of the average wear mark width VB in mm (at the main cutting edge)
after a milling travel of 4800 mm. The following wear mark widths VB were
found:

WE CLAIM
1. A cutting tool (1) having a base body (2) and a single-layer or
multi-layer coating (3) applied thereto, characterised in that the coating
includes at least one two-phase or multi-phase layer (4) which contains at
least two different phases of metal oxide, wherein the at least one two-
phase or multi-phase layer (4) is electrically conductive.
2. A cutting tool according to claim 1 characterised in that the at
least two different phases of metal oxide in the at least one two-phase or
multi-phase electrically conductive layer (4) are at least two different
phases of chromium oxide.
3. A cutting tool according to claim 2 characterised in that the at
least one two-phase or multi-phase layer (4) contains chromium oxide as
the main component.
4. A cutting tool according to one of claims 1 to 3 characterised in
that the at least one two-phase or multi-phase layer (4) has at least three
phases, wherein there is at least one phase of aluminium oxide.
5. A cutting tool according to one of claims 1 to 4 characterised in
that one of the metal oxide phases in the two-phase or multi-phase layer
(4) is a stable phase of metal oxide, preferably a phase of Cr2O3.
6. A cutting tool according to one of claims 1 to 5 characterised in
that at least one of the metal oxide phases in the two-phase or multi-phase
layer (4) is a metastable phase, preferably a metastable phase of
chromium oxide of the stoichiometry CrOx, with 0.7 7. A cutting tool according to one of claims 1 to 6 characterised in
that the at least two different phases of metal oxide in the two-phase or
multi-phase layer (4) are chromium oxide phases which taken together
have a ratio of the elements Cr to O of about 1 to 0.8 - 1.2.
8. A cutting tool according to one of claims 1 to 7 characterised in
that among the at least two different phases of metal oxide in the at least
one two-phase or multi-phase layer (4) at least one metal oxide phase is
electrically conductive.
9. A cutting tool according to one of claims 1 to 8 characterised in
that the metal oxide phases in the two-phase or multi-phase layer (4) do
not include a phase of CrO2.
10. A cutting tool according to one of claims 1 to 9 characterised in
that the at least one two-phase or multi-phase layer (4) is of a layer
thickness of 10 nm to 50 µm, preferably 20 nm to 20 µm, particularly
preferably 0.5 µm to 4 µm.
11. A cutting tool according to one of claims 1 to 10 characterised in
that the at least one two-phase or multi-phase layer (4) is of a Vickers
hardness (Hv) of 500 to 4000, preferably 700 to 3000, particularly
preferably 800 to 2000.
12. A cutting tool according to one of claims 1 to 11 characterised in
that the at least one two-phase or multi-phase layer (4) is of an electrical
conductivity of more than 1 S/m, preferably more than 100 S/m,
particularly preferably more than 104 S/m.
13. A cutting tool according to one of claims 1 to 14 characterised in
that the at least one two-phase or multi-phase layer (4) further has at least
one secondary component formed by elements of subgroups IV, V or VI of
the periodic system of the elements, aluminium and/or silicon and O, N, C
and/or B.
14. A cutting tool according to one of claims 1 to 13 characterised in
that the coating (3) includes further hard material layers formed by
elements of subgroups IV, V or VI of the periodic system of the elements,
aluminium and/or silicon and O, N, C and/or B.
15. A cutting tool according to one of claims 1 to 14 characterised in
that the at least one two-phase or multi-phase layer (4) is produced by a
PVD process, preferably by magnetron sputtering, arc vapour deposition
(arc PVD) or modifications of said processes.
16. A cutting tool according to one of claims 1 to 15 characterised in
that the base body is made from hard metal or carbide metal, cermet, steel
or high-speed steel (HSS).
17. A cutting tool according to one of claims 1 to 16 characterised in
that the coating includes at least two of the two-phase or multi-phase
layers (4, 4') according to one of the preceding claims, wherein the at least
two of the two-phase or multi-phase layers (4, 4') are arranged in directly
superposed relationship or are separated from each other by one or more
further hard material layers.
18. A cutting tool according to claim 17 characterised in that the at
least two of the two-phase or multi-phase layers (4, 4') are of different
compositions, different Vickers hardnesses (Hv) and/or different
conductivities.

The invention concerns a cutting tool having a base body and a
single-layer or multi-layer coating applied thereto. To provide cutting tools
which are improved over the state of the art it is proposed according to the
invention that the coating includes at least one two-phase or multi-phase
layer which contains at least two different phases of metal oxide, wherein
the at least one two-phase or multi-phase layer is electrically conductive.

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Patent Number

272134

Indian Patent Application Number

71/KOLNP/2010

PG Journal Number

13/2016

Publication Date

25-Mar-2016

Grant Date

18-Mar-2016

Date of Filing

06-Jan-2010

Name of Patentee

WALTER AG

Applicant Address

DERENDINGER STRASSE 53, 72072 TÜBINGEN, GERMANY

Inventors:

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

PCT International Classification Number

B22F7/00; C23C28/00; C23C30/00

PCT International Application Number

PCT/EP2008/056038

PCT International Filing date

2008-05-16

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	102007030734.0	2007-07-02	Germany