Pulsed electric current sintering of tungsten composites

Research output: ThesisMaster's thesis

Standard

Pulsed electric current sintering of tungsten composites. / Wang, Minwei; Massaut, Vincent (Peer reviewer).

Leuven, Belgium : KUL - Katholieke Universiteit Leuven, 2012. 100 p.

Research output: ThesisMaster's thesis

Harvard

Wang, M & Massaut, V 2012, 'Pulsed electric current sintering of tungsten composites', KUL - Katholieke Universiteit Leuven , Leuven, Belgium.

APA

Wang, M., & Massaut, V. (2012). Pulsed electric current sintering of tungsten composites. Leuven, Belgium: KUL - Katholieke Universiteit Leuven.

Vancouver

Wang M, Massaut V. Pulsed electric current sintering of tungsten composites. Leuven, Belgium: KUL - Katholieke Universiteit Leuven, 2012. 100 p.

Author

Wang, Minwei ; Massaut, Vincent. / Pulsed electric current sintering of tungsten composites. Leuven, Belgium : KUL - Katholieke Universiteit Leuven, 2012. 100 p.

Bibtex - Download

@phdthesis{4a4c8d50950d4c349aa62cc6a1c75c97,
title = "Pulsed electric current sintering of tungsten composites",
abstract = "This work investigates the processing of secondary phase strengthened tungsten composite materials for fusion reactor application. The goal is to explore the suitability of different secondary phases to strengthen tungsten and study their influence on the mechanical and physical properties of the processed tungsten-based composite materials. Yttrium oxide and titanium carbide are selected as candidate additives based on a thorough literature research. In order to disperse TiC or Y2O3 in the tungsten matrix, multidirectional mixing is used for both W/TiC and W/Y2O3 composites while the additive content is varied from 5 to 16 vol{\%}. High energy bead milling and chemical coating are also used on W/5vol{\%}Y2O3 composite materials in order to improve the dispersion of the oxide additive. All the composites are consolidated by pulsed electric current sintering (PECS) in the 1500-1700˚C temperature range, under a pressure of 106MPa. The processing of monolithic tungsten is also studied as a reference material. SEM, XRD, Vickers hardness test and 3 point bending test are conducted to characterize the microstructure, phase composite and mechanical properties of the processed materials.",
keywords = "tungsten, microstructure, mechanical properties",
author = "Minwei Wang and Vincent Massaut",
note = "Score = 2",
year = "2012",
month = "1",
language = "English",
publisher = "KUL - Katholieke Universiteit Leuven",
school = "KUL - Katholieke Universiteit Leuven",

}

RIS - Download

TY - THES

T1 - Pulsed electric current sintering of tungsten composites

AU - Wang, Minwei

A2 - Massaut, Vincent

N1 - Score = 2

PY - 2012/1

Y1 - 2012/1

N2 - This work investigates the processing of secondary phase strengthened tungsten composite materials for fusion reactor application. The goal is to explore the suitability of different secondary phases to strengthen tungsten and study their influence on the mechanical and physical properties of the processed tungsten-based composite materials. Yttrium oxide and titanium carbide are selected as candidate additives based on a thorough literature research. In order to disperse TiC or Y2O3 in the tungsten matrix, multidirectional mixing is used for both W/TiC and W/Y2O3 composites while the additive content is varied from 5 to 16 vol%. High energy bead milling and chemical coating are also used on W/5vol%Y2O3 composite materials in order to improve the dispersion of the oxide additive. All the composites are consolidated by pulsed electric current sintering (PECS) in the 1500-1700˚C temperature range, under a pressure of 106MPa. The processing of monolithic tungsten is also studied as a reference material. SEM, XRD, Vickers hardness test and 3 point bending test are conducted to characterize the microstructure, phase composite and mechanical properties of the processed materials.

AB - This work investigates the processing of secondary phase strengthened tungsten composite materials for fusion reactor application. The goal is to explore the suitability of different secondary phases to strengthen tungsten and study their influence on the mechanical and physical properties of the processed tungsten-based composite materials. Yttrium oxide and titanium carbide are selected as candidate additives based on a thorough literature research. In order to disperse TiC or Y2O3 in the tungsten matrix, multidirectional mixing is used for both W/TiC and W/Y2O3 composites while the additive content is varied from 5 to 16 vol%. High energy bead milling and chemical coating are also used on W/5vol%Y2O3 composite materials in order to improve the dispersion of the oxide additive. All the composites are consolidated by pulsed electric current sintering (PECS) in the 1500-1700˚C temperature range, under a pressure of 106MPa. The processing of monolithic tungsten is also studied as a reference material. SEM, XRD, Vickers hardness test and 3 point bending test are conducted to characterize the microstructure, phase composite and mechanical properties of the processed materials.

KW - tungsten

KW - microstructure

KW - mechanical properties

UR - http://ecm.sckcen.be/OTCS/llisapi.dll/open/ezp_120047

M3 - Master's thesis

PB - KUL - Katholieke Universiteit Leuven

CY - Leuven, Belgium

ER -

ID: 282403