PSI - Issue 16
Available online at www.sciencedirect.com ScienceDirect StructuralIntegrity Procedia 00 (2019) 000 – 000 Available online at www.sciencedirect.com Scienc Direct StructuralIntegrity Procedia 00 (2019) 000 – 000
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Procedia Structural Integrity 16 (2019) 134–140
© 2019 The Authors. Published by Elsevier B.V. Peer-review under responsibility of the 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” organizers. © 2019 The Author(s). Published by Elsevier B.V. Peer- review under responsibility of the 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” organizers It has been investigated the Ni-Co alloys (obtained from powder 0.1...0.3 mm under hot gaseous (in argon) isostatic pressure (up to 300 MPa) (Ni60Co15Cr8W8Al2Mo3) (Firth Rixon Metal Ltd, Sheffield) and deformed (obtained by vacuum induced remealting) materials (Ni62Cr14Co10Mo5Nb3Al3Ti3) for gaseous turbine discs. Investigation has performed i the range of temperature 25 … 800 ° С and hydrogen pressure up to 70 MPa. By the 3D visualization of crack morphology it has bee discovered the structure of fatigue crack surface and established the refer points on crack path, including the boundary between the atrix and intermetallic particles (400×200 μm), crack opening, structural elements distributions on the surface for selection of next local areas for more precisi fracture surface and TEM exami ations. Hydrogen influence on cyclic crack resistance parameters appears in the decreasing of loading cycles number (with amplitudes 15 MPa) in hydrogenated specimens of both alloys and increase with hydrogen concentration. At the highest hydrogen saturation regimes of Ni60Co15Cr8W8Al2Mo3 alloy (800 °С , 35 MPa Н 2 , 36 hours, С Н = 32.7 ppm) number of cycles, which necessary for crack initiation is 3 times less in comparison with specimen in initial state. At crack initiation step in hydrogenated Ni56Cr14Co15Mo5Al3Ti3 alloy it has been established that before intermetallic inclusion (400×200 μm ) local stresses increased, after its passing – has decreased. By fracture surface investigation it has been found the micro cracks up to 40 μm. Thin structure of heat resistant superalloys h as characterises by disperse phase agglomeration with dimensions from 5 to 30 nm and crack propagation has a jumping character wi th no less then 50…70 nm st ps. © 2019 The Author(s). Published by Elsevier B.V. Peer- review under responsibility of the 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” organizers 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” Hydrogen assisted crack initiation and propagation in nickel-cobalt heat resistant superalloys Alexander Balitskii* Karpenko Physico-Mechanical Institute of the National Academy of Sciences of Ukraine, 5 Naukova St., Lviv, 79060, Ukraine It has been investigated the Ni-Co alloys (obtained from powder 0.1...0.3 mm under hot gaseous (in argon) isostatic pressure (up to 300 MPa) (Ni60Co15Cr8W8Al2Mo3) (Firth Rixon Metal Ltd, Sheffield) and deformed (obtained by vacuum induced remealting) materials (Ni62Cr14Co10Mo5Nb3Al3Ti3) for gaseous turbine discs. Investigation has performed in the range of temperature 25 … 800 ° С and hydrogen pressure up to 70 MPa. By the 3D visualization of crack morphology it has been discovered the structure of fatigue crack surface and established the refer points on crack path, including the boundary between the matrix and intermetallic particles (400×200 μm), crack opening, structural elements distributions on the surface for selection of next local areas for more precision fracture surface and TEM examinations. Hydrogen influence on cyclic crack resistance parameters appears in the decreasing of loading cycles number (with amplitudes 15 MPa) in hydrogenated specimens of both alloys and increase with hydrogen concentration. At the highest hydrogen saturation regimes of Ni60Co15Cr8W8Al2Mo3 alloy (800 °С , 35 MPa Н 2 , 36 hours, С Н = 32.7 ppm) number of cycles, which necessary for crack initiation is 3 times less in comparison with specimen in initial state. At crack initiation step in hydrogenated Ni56Cr14Co15Mo5Al3Ti3 alloy it has been established that before intermetallic inclusion (400×200 μm ) local stresses increased, after its passing – has decreased. By fracture surface investigation it has been found the micro cracks up to 40 μm. Thin structure of heat resistant superalloys h as characterises by disperse phase agglomeration with dimensions from 5 to 30 nm and crack propagation has a jumping character wi th no less then 50…70 nm steps. 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” Hydrogen assisted crack init a ion and propagation in nickel-cobalt heat resistant superalloys Alexander Balitskii* Karpenko Physico-Mechanical Institute of the National Academy of Sciences of Ukraine, 5 Naukova St., Lviv, 79060, Ukraine Abstract Abstract Keywords: Nickel-cobalt superalloys; hydrogen, crack initiation; intermetallic inclusion .
Keywords: Nickel-cobalt superalloys; hydrogen, crack initiation; intermetallic inclusion .
* Corresponding author. Tel.: +38-032-229-6254; fax: +38-032-263-4227. E-mail address: balitski@ipm.lviv.ua
2452-3216 © 2019 The Author(s). Published by Elsevier B.V. Peer- review under responsibility of the 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” organizers 2452-3216 © 2019 The Author(s). Published by Elsevier B.V. Peer- review under responsibility of the 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” organizers * Corresponding author. Tel.: +38-032-229-6254; fax: +38-032-263-4227. E-mail address: balitski@ipm.lviv.ua
2452-3216 2019 The Authors. Published by Elsevier B.V. Peer-review under responsibility of the 6th International Conference “Fracture Mechanics of Materials and Structural Integrity” organizers. 10.1016/j.prostr.2019.07.032
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