The present invention relates to a coating comprising at least one coating layer of TM-Al—O—N, exhibiting a solid solution with B1 cubic structure or spinodally decomposed phases with cubic structure, wherein the oxygen concentration in the TM-Al—O—N coating layer produces an increment of the thermal stability in comparison with a (TM1-xAlx)Nz coating layer whose element composition differs from the element composition of the (TM1-xAlx)OyNz coating layer only in that the (TM1-xAlx)Nz coating layer does not comprises oxygen, in such a manner that no precipitation of w-AlN phase is produced when the coating is exposed to temperatures higher than 1100° C. The present invention relates also to the use of such inventive coatings for applications in which the coating is exposed to temperatures above 1100° C.
In the context of the present invention the term “high temperatures” is used for referring to temperatures above 1100° C.
In the scientific article “Phase stability and elastic properties of titanium aluminum oxynitride studied by ab initio calculations” by Moritz to Baben, Leonard Raumann and Jochen M Schneider published in J. Phys. D: Appl. Phys. 46 (2013) 084002 (6pp), ab-initio calculation on TiAlON suggests a negative energy of mixing at 0K, i.e. likely solid solution formation between Fcc-Ti0.5Al0.5N and fcc-Ti0.5Al0.5O. But this study does not provide any insights on high temperature stability of cubic phase in TiAlN.
An objective of the present invention is to provide a coating comprising a metal nitride based PVD wear resistant coating for applications at high temperatures.
The metal nitride based coating should exhibit preferably following properties:
The objective of the present invention is attained by depositing transition metal aluminum nitride coatings (abbreviation: TM-Al—N coatings) comprising oxygen in a controlled manner. Hereafter called as “TM-Al—N coatings with controlled oxygen incorporation”.
TM can be one or more transition metals.
According to a preferred embodiment of a coating according to the present invention titanium is used as transition metal i.e. TM=Ti.
For better understanding of the present invention, one example of a coating according to the above-mentioned preferred embodiment will be explained in more detail.
TiAlN and TiAlON coating layers were deposited by using 3 TiAl targets having chemical composition 50:50 in atomic percentage. The target material was arc evaporated in a coating device of the type Ingenia P3e™ manufactured by Oerlikon Balzers. The sources were operated at 190 A arc current. The substrate temperature during deposition of the coating layers was maintained at 450° C. Vacuum was drawn till a pressure lower than 3.0●10−4 Pa. Nitrogen gas was used as reactive gas and the nitrogen partial pressure was maintained at 3.2 Pa. A negative bias voltage of −40 V was applied at the substrates to be coated. No oxygen gas flow was introduced in the coating chamber for deposition of the TiAlN coating layers. Oxygen gas flow was introduced in the coating chamber for the deposition of the TiAlON coating layers. Different TiAlON coating layers differing from each other in their oxygen content were deposited by adjusting a different oxygen gas flow. During deposition of each TiAlON layer the oxygen gas flow was maintained constant. Values of oxygen gas flows between 0 and 80 sccm were adjusted for the deposition of the different TiAlON coating layers. The element composition of the films, including the O-content in the deposited coating layers, was determined by using Elastic Recoil Detection Analysis (ERDA).
Both TiAlN and TiAlON were deposited exhibiting cubic phase.
The thermal stability of the cubic phase was analyzed.
The coated substrates were subjected to annealing at temperatures between 800° C. and 1300° C.
TiAlN and TiAlON coating layers were deposited by using 3 TiAl targets having chemical composition 40:60 in atomic percentage. The target material was arc evaporated in a coating device of the type Ingenia P3e™ manufactured by Oerlikon Balzers. The sources were operated at 120 A arc current and using confinement technology. The substrate temperature during deposition of the coating layers was maintained at 520° C. Vacuum was drawn till a pressure lower than 3.0●10−4 Pa. Nitrogen gas was used as reactive gas and the nitrogen partial pressure was maintained at 6.0 Pa. A negative bias voltage of −40 V was applied at the substrates to be coated. No oxygen gas flow was introduced in the coating chamber for deposition of the TiAlN coating layers. Oxygen gas flow was introduced in the coating chamber for the deposition of the TiAlON coating layers. Different TiAlON coating layers differing from each other in their oxygen content were deposited by adjusting a different oxygen gas flow. During deposition of each TiAlON layer the oxygen gas flow was maintained constant. Values of oxygen gas flows between 0 and 80 sccm were adjusted for the deposition of the different TiAlON coating layers. The element composition of the films, including the O-content in the deposited coating layers, was determined by using Elastic Recoil Detection Analysis (ERDA).
Both TiAlN and TiAlON were deposited exhibiting cubic phase.
The thermal stability of the cubic phase was analyzed.
The coated substrates were subjected to annealing at temperatures between 800° C. and 1300° C.
All measurements were performed on samples coated with the help of Ti50Al50 targets, however results are expected to be similar for other realistic target compositions (ranging from Ti20Al80 to Ti80Al20). It is preferred to have oxygen with more than 5 at % in the system. However, in general an oxygen atomic percentage above 25 at % is to be avoided, preferably a percentage above 20 at % is to be avoided and most preferred the oxygen percentage should be above 18 at % at most.
For the Ti0.5Al0.5N coating layer, wurtzite phase of aluminum nitride (abbreviation: W-AlN) precipitates already at 1000° C. In contrast, for oxygen containing coating layers of the type Ti0.5A10.5OyN1-y with y>0, w-AlN precipitates at a temperature higher than 1100° C., as it is shown in
The X-ray diffractograms of the Ti0.5Al0.5N coating layers as deposited and after annealing at 800° C., 900° C., 1000° C. and 1100° C. are shown in
The X-ray diffractograms of the Ti0.5Al0.5OyN1-y coating layers with y=0.26 as deposited and after annealing at 800° C., 900° C., 1200° C. and 1300° C. are shown in
The mechanical properties of the coating layers were investigated by nanoindentation. The Ti0.5Al0.5OyN1-y film with y=0.26 had after deposition a hardness of 28-32 GPa, and elastic modulus (also called Young's modulus) of 400-470 GPa.
A surprisingly high enhancement of the thermal stability was attained by incorporation of oxygen in the structure for forming TM1-xAlxOyNz.
With an oxygen concentration of 13 at. % in TM1-xAlxOyNz (y=0.26) the thermal stability in comparison with TM1-xAlxN was significantly increased in such a manner that spinodally decomposed phases with cubic structure could be maintained till a temperature of 1200° C.
In this manner, the spinodally decomposed phases with cubic structure, that gives superior mechanical properties was stable over a higher temperature window (till additional 200° C. more—from 900° C. to 1200° C.) with controlled incorporation of oxygen, as it is shown in
This let conclude that these kinds of inventive TM1-xAlxOyNz coating layers can be very useful for applications at high temperatures, in particular if the oxygen concentration in the coating layer after deposition is about 13%.
Samples coated with Ti40Al60-targets, according to Example 2, were as well investigated by X-ray after annealing during 30 mins in vacuum atmosphere at 800° C., 900° C., 1000° C., 1100° C. 1200° C. and 1300° C., respectively. The following observations were made with respect to the w-AlN formation:
A similar behavior can be expected for other TiAlN coating films having different Ti:Al ratios and also for other kinds of TM-Al—N coating films, for example CrAlN, VaAlN and NbAlN.
The coatings according to the present invention are particularly beneficial for coating surfaces of tools or components, which are to be used in applications involving exposition of surfaces of the tools or components to temperatures exceeding 1100° C.
The inventors suggest using these coatings for example for protecting and improving performance of components or tools used in:
(a) aero engine high pressure turbines or aero engine high pressure turbine sealing,
(b) machining of difficult-to-cut materials, e.g. nickel base super alloys such as Inconel 718,
(c) high temperature forming operations like rolling and forging operating at temperatures above 1100° C.
Additional insights into the structure evolution of TiAlN and TiAlON coatings is gained by analysis of as-deposited and annealed samples with scanning transmission electron microscopy (STEM) and atomic probe tomography (APT).
In as-deposited state, STEM-imaging of TiAlN (
Atomic probe tomography shows a random structure of Al-atoms in TiAlN as deposited (
TiAlON shows in as-deposited state layering as an effect of substrate rotation during deposition (
Compositional distribution analysis of atomic probe tomography data is a further method to follow decomposition. This technique and the application of Pearson coefficients (p) has been described by M. P. Moody et. al. in the scientific paper “Quantitative Binomial Distribution Analyses of Nanoscale Like-Solute Atom Clustering and Segregation in Atom Probe Tomography Data”, published in the journal Microscopy Research and Technique volume 71, pages 542-550. For TiAlN (
After annealing to 900° C., the TiAlN coatings show Pearson coefficients for Ti and Al close to 1, indicating segregation in the spinodally decomposed structure (
The decomposed structure is characterized by Pearson coefficients close to 1 for Ti and Al, as seen in TiAlN after annealing to 1000° C. (
Layers with the same chemical composition can have different crystalline phases, in particular a layer as claimed in claim 1 can exhibit a solid solution with B1 cubic structure or a layer as claimed in claim 2 can exhibit a spinodally decomposed phases with cubic structure. Layer growth and crystalline phase formation in PVD (Physical Vapor Deposition) is a complex process that can be influenced by several factors. Among the most important parameters besides composition: temperature, process pressure, bias, and degree of ionization. Furthermore, the thermal history has a decisive influence—if the layer is kept at a tempering temperature above the coating temperature, it can change the phase structure. This is the case for the difference between the substrate claimed in claim 1 and the substrate claimed in claim 2, as can also be seen in the text in
TiAlON coatings according to a preferred embodiment of the present invention were found to exhibit crystalline grains having a crystalline grain size, which is also known as domain size, that is in the range of 5 to 50 nm and preferably of 15 to 35 nm, which was determined by XRD (X-ray diffraction). This quantification was done according to a standard method (Sherrer's equation), based on the XRD patterns given in
TiAlON coatings preferably have atoms distributed in a close to random fashion
i. characterized by a Pearson coefficient for Ti (μTi)<0.20
ii. characterized by a Pearson coefficient for Al (μAl)<0.20
iii. characterized by a Pearson coefficient for N (μN)<0.20
TiAlON coatings preferably contain a periodic modulation of composition, in particular have a modulation of Al content. Furthermore, it is preferred that the compositional modulation has a periodicity of 5-30 nm, preferably ˜10 nm. This can be seen in particular in
Number | Date | Country | Kind |
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10 2019 105 886.4 | Mar 2019 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/056195 | 3/9/2020 | WO | 00 |
Number | Date | Country | |
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62850684 | May 2019 | US |