Effect of Properties of Titanium Aluminide Powders and Detonation Spraying Conditions on Phase and Structure Formation in Coatings
We have studied phase formation in detonation coatings sprayed from Ti - 50 at. % Al powders. The powders of the alloy were obtained by various methods: crushing an ingot and mechanical alloying of Ti and Al. Using polyphase nanostructural materials activated by mechanical alloying makes the process...
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| Published in: | Powder metallurgy and metal ceramics Vol. 44; no. 9-10; pp. 472 - 480 |
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01-09-2005
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| Abstract | We have studied phase formation in detonation coatings sprayed from Ti - 50 at. % Al powders. The powders of the alloy were obtained by various methods: crushing an ingot and mechanical alloying of Ti and Al. Using polyphase nanostructural materials activated by mechanical alloying makes the process of phase formation in the gas-thermal sprayed coatings based on them more general-purpose and controlled due to the more active and more subtle reaction of the material with the gaseous atmosphere. We have shown that from mechanically alloyed Ti - 50 at. % Al powder, using the detonation-gas spraying method we can consolidate a coating based on Al2TiO5 by oxidizing action of the working gas on the powder and also a coating based on titanium aluminides with TiN inclusions by nitriding action. The phase composition of the cast microstructural gamma-TiAl powder is inherited by the coating. |
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| AbstractList | We have studied phase formation in detonation coatings sprayed from Ti - 50 at. % Al powders. The powders of the alloy were obtained by various methods: crushing an ingot and mechanical alloying of Ti and Al. Using polyphase nanostructural materials activated by mechanical alloying makes the process of phase formation in the gas-thermal sprayed coatings based on them more general-purpose and controlled due to the more active and more subtle reaction of the material with the gaseous atmosphere. We have shown that from mechanically alloyed Ti - 50 at. % Al powder, using the detonation-gas spraying method we can consolidate a coating based on Al2TiO5 by oxidizing action of the working gas on the powder and also a coating based on titanium aluminides with TiN inclusions by nitriding action. The phase composition of the cast microstructural gamma-TiAl powder is inherited by the coating. We have studied phase formation in detonation coatings sprayed from Ti - 50 at.% Al powders. The powders of the alloy were obtained by various methods: crushing an ingot and mechanical alloying of Ti and Al. Using polyphase nanostructural materials activated by mechanical alloying makes the process of phase formation in the gas-thermal sprayed coatings based on them more general-purpose and controlled due to the more active and more subtle reaction of the material with the gaseous atmosphere. We have shown that from mechanically alloyed Ti - 50 at.% Al powder, using the detonation-gas spraying method we can consolidate a coating based on Al^sub 2^TiO^sub 5^ by oxidizing action of the working gas on the powder and also a coating based on titanium aluminides with TiN inclusions by nitriding action. The phase composition of the cast microstructural γ-TiAl powder is inherited by the coating.[PUBLICATION ABSTRACT] We have studied phase formation in detonation coatings sprayed from Ti - 50 at.% Al powders. The powders of the alloy were obtained by various methods: crushing an ingot and mechanical alloying of Ti and Al. Using polyphase nanostructural materials activated by mechanical alloying makes the process of phase formation in the gas-thermal sprayed coatings based on them more general-purpose and controlled due to the more active and more subtle reaction of the material with the gaseous atmosphere. We have shown that from mechanically alloyed Ti - 50 at.% Al powder, using the detonation-gas spraying method we can consolidate a coating based on Al sub(2)TiO sub(5) by oxidizing action of the working gas on the powder and also a coating based on titanium aluminides with TiN inclusions by nitriding action. The phase composition of the cast microstructural gamma -TiAl powder is inherited by the coating. |
| Author | Grechishkin, E F Gridasova, T Ya Sirovatka, V L Oliker, V E Timofeeva, I I |
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| CitedBy_id | crossref_primary_10_1007_s11106_006_0021_1 crossref_primary_10_1016_j_ceramint_2013_09_111 crossref_primary_10_1016_j_intermet_2012_01_020 crossref_primary_10_37434_as2023_02_04 crossref_primary_10_1134_S2075113319050095 crossref_primary_10_37434_tpwj2023_02_04 |
| Cites_doi | 10.1023/A:1018892422121 10.1002/maco.19970480103 10.1016/1359-6462(95)00552-8 10.1007/BF02676065 10.2320/matertrans1989.32.151 10.1007/BF03223244 |
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| References | 12_CR7 Y. F. Cheng (12_CR9) 1996; 34 S. Becker (12_CR8) 1992; 38 V. E. Oliker (12_CR3) 2003 C. Z. Carroll-Porczynski (12_CR20) 1966 F. H. Froes (12_CR15) 1995; A192 A. I. Zverev (12_CR22) 1979 12_CR19 F. Dettenwanger (12_CR11) 1998; 50 12_CR16 12_CR17 12_CR1 12_CR14 12_CR2 12_CR12 G. H. Meir (12_CR4) 1988 R. F. Voitovich (12_CR13) 1984 V. V. Skorokhod (12_CR18) 1998 M. Eckert (12_CR10) 1997; 48 D. E. Grady (12_CR21) 1986 S. Taniguchi (12_CR5) 1991; 32 K. L. Luthra (12_CR6) 1991; 36 |
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| Snippet | We have studied phase formation in detonation coatings sprayed from Ti - 50 at.% Al powders. The powders of the alloy were obtained by various methods:... We have studied phase formation in detonation coatings sprayed from Ti - 50 at. % Al powders. The powders of the alloy were obtained by various methods:... |
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| SubjectTerms | Alloy powders Alloys Aluminum base alloys Coatings Detonation Mechanical alloying Metallurgy Nanostructure Titanium base alloys Titanium compounds |
| Title | Effect of Properties of Titanium Aluminide Powders and Detonation Spraying Conditions on Phase and Structure Formation in Coatings |
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