Standard

Open-cell superalloy foams via the combined electrolytic-suspension route. / Smorygo, O.; Mikutski, V.; Hancharou, V. и др.

2017. Работа представлена на International Powder Metallurgy Congress and Exhibition, Euro PM 2017, Milan, Италия.

Результаты исследований: Материалы конференцийматериалыРецензирование

Harvard

Smorygo, O, Mikutski, V, Hancharou, V, Tarusov, I, Ilyushchanka, A, Vinod Kumar, J & Sadykov, V 2017, 'Open-cell superalloy foams via the combined electrolytic-suspension route', Работа представлена на International Powder Metallurgy Congress and Exhibition, Euro PM 2017, Milan, Италия, 01.10.2017 - 04.10.2017.

APA

Smorygo, O., Mikutski, V., Hancharou, V., Tarusov, I., Ilyushchanka, A., Vinod Kumar, J., & Sadykov, V. (2017). Open-cell superalloy foams via the combined electrolytic-suspension route. Работа представлена на International Powder Metallurgy Congress and Exhibition, Euro PM 2017, Milan, Италия.

Vancouver

Smorygo O, Mikutski V, Hancharou V, Tarusov I, Ilyushchanka A, Vinod Kumar J и др. Open-cell superalloy foams via the combined electrolytic-suspension route. 2017. Работа представлена на International Powder Metallurgy Congress and Exhibition, Euro PM 2017, Milan, Италия.

Author

Smorygo, O. ; Mikutski, V. ; Hancharou, V. и др. / Open-cell superalloy foams via the combined electrolytic-suspension route. Работа представлена на International Powder Metallurgy Congress and Exhibition, Euro PM 2017, Milan, Италия.

BibTeX

@conference{254cdf47f450409c8bb56beccc2686c8,
title = "Open-cell superalloy foams via the combined electrolytic-suspension route",
abstract = "Low-density open-cell nickel foams were prepared by electrolytic replication of polyurethane foam. Then, the sintered products were impregnated with the 625 superalloy powder suspension. The final foam density could be controlled by number of impregnations. Then the foams were sintered in vacuum. The foam microstructure and distribution of alloying components (Cr, Nb and Mo) were dependent on the sintering temperature, which, in its turn, effected mechanical properties of the foams (the shape of the stress-strain curve and the yield stress). Complete densification of the powder layer was attained at temperatures close to the superalloy liquidus point, i.e. at 1320-1335oC. Addition of a mixture of Ni, Cr and Mo fine powders to the superalloy powder suspension favored the powder layer densification, ensured more uniform distribution of alloying elements and improved mechanical strength.",
author = "O. Smorygo and V. Mikutski and V. Hancharou and I. Tarusov and A. Ilyushchanka and {Vinod Kumar}, J. and V. Sadykov",
year = "2017",
language = "English",
note = "International Powder Metallurgy Congress and Exhibition, Euro PM 2017 ; Conference date: 01-10-2017 Through 04-10-2017",

}

RIS

TY - CONF

T1 - Open-cell superalloy foams via the combined electrolytic-suspension route

AU - Smorygo, O.

AU - Mikutski, V.

AU - Hancharou, V.

AU - Tarusov, I.

AU - Ilyushchanka, A.

AU - Vinod Kumar, J.

AU - Sadykov, V.

PY - 2017

Y1 - 2017

N2 - Low-density open-cell nickel foams were prepared by electrolytic replication of polyurethane foam. Then, the sintered products were impregnated with the 625 superalloy powder suspension. The final foam density could be controlled by number of impregnations. Then the foams were sintered in vacuum. The foam microstructure and distribution of alloying components (Cr, Nb and Mo) were dependent on the sintering temperature, which, in its turn, effected mechanical properties of the foams (the shape of the stress-strain curve and the yield stress). Complete densification of the powder layer was attained at temperatures close to the superalloy liquidus point, i.e. at 1320-1335oC. Addition of a mixture of Ni, Cr and Mo fine powders to the superalloy powder suspension favored the powder layer densification, ensured more uniform distribution of alloying elements and improved mechanical strength.

AB - Low-density open-cell nickel foams were prepared by electrolytic replication of polyurethane foam. Then, the sintered products were impregnated with the 625 superalloy powder suspension. The final foam density could be controlled by number of impregnations. Then the foams were sintered in vacuum. The foam microstructure and distribution of alloying components (Cr, Nb and Mo) were dependent on the sintering temperature, which, in its turn, effected mechanical properties of the foams (the shape of the stress-strain curve and the yield stress). Complete densification of the powder layer was attained at temperatures close to the superalloy liquidus point, i.e. at 1320-1335oC. Addition of a mixture of Ni, Cr and Mo fine powders to the superalloy powder suspension favored the powder layer densification, ensured more uniform distribution of alloying elements and improved mechanical strength.

UR - http://www.scopus.com/inward/record.url?scp=85056512013&partnerID=8YFLogxK

M3 - Paper

AN - SCOPUS:85056512013

T2 - International Powder Metallurgy Congress and Exhibition, Euro PM 2017

Y2 - 1 October 2017 through 4 October 2017

ER -

ID: 25389780