Author: D. R. Brunstetter
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 20
Book Description
The Tensile Properties of Zirconium at Elevated Temperatures
Author: D. R. Brunstetter
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 20
Book Description
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 20
Book Description
Mechanical Properties of Zirconium at Elevated Temperatures
Author: Knud B. Pedersen
Publisher:
ISBN:
Category : Nuclear engineering
Languages : en
Pages : 124
Book Description
Publisher:
ISBN:
Category : Nuclear engineering
Languages : en
Pages : 124
Book Description
Mechanical Properties of Zirconium
Tensile Properties of Sheet Zirconium at Room and Elevated Temperatures
Author: A. D. Schwope
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 28
Book Description
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 28
Book Description
The Mechanical Properties of Consumable-arc Melted Kroll-process Zirconium
Author: R. G. Nelson
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 26
Book Description
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 26
Book Description
Elevated Temperature Mechanical Properties of Zirconium Diboride Based Ceramics
Author: Eric William Neuman
Publisher:
ISBN:
Category : Borides
Languages : en
Pages : 259
Book Description
"Research presented in this dissertation focused on the mechanical behavior of ZrB2 based ceramic at elevated temperatures. Flexure strength, fracture toughness, and elastic modulus were measured at temperatures up to 2300°C for three compositions: monolithic ZrB2 (Z); ZrB2 - 30 vol% SiC - 2 vol% B4C (ZS); and ZrB2 - 10 vol% ZrC (ZC). In argon, Z, ZS, and ZC had strengths of 210 (at 2300°C), 260 (at 2200°C), and 295 MPa (at 2300°C), the highest temperatures tested for each composition. Fractography was used extensively to characterize the strength limiting flaws as a function of temperature. Strength of ZS in argon was controlled by the SiC cluster size up to 1800°C, and the formation of B-O-C-N phases that bridged SiC clusters above 2000°C. For ZC, surface flaws introduced during specimen preparation were the source of critical flaws in the material up to 1400°C, sub-critical crack growth of surface flaws between 1600 and 2000°C, and microvoid coalescence above 2000°C. It was also shown that thermal annealing at either 1400, 1500, or 1600°C improves the strength and modulus of ZS at temperatures between 800°C and 1600°C. Heat treatment at 1400°C for 10 hours produced the largest improvement in strength, 430 MPa at 1600°C versus 380 MPa for the as processed material. As a whole, the research pointed to several key microstructural features currently limiting the mechanical properties at the highest temperatures. In particular, removal of unfavorable secondary phases, and improved control over microstructure, should be promising methods to improve the elevated temperature properties of ZrB2 ceramics."--Abstract, page iv.
Publisher:
ISBN:
Category : Borides
Languages : en
Pages : 259
Book Description
"Research presented in this dissertation focused on the mechanical behavior of ZrB2 based ceramic at elevated temperatures. Flexure strength, fracture toughness, and elastic modulus were measured at temperatures up to 2300°C for three compositions: monolithic ZrB2 (Z); ZrB2 - 30 vol% SiC - 2 vol% B4C (ZS); and ZrB2 - 10 vol% ZrC (ZC). In argon, Z, ZS, and ZC had strengths of 210 (at 2300°C), 260 (at 2200°C), and 295 MPa (at 2300°C), the highest temperatures tested for each composition. Fractography was used extensively to characterize the strength limiting flaws as a function of temperature. Strength of ZS in argon was controlled by the SiC cluster size up to 1800°C, and the formation of B-O-C-N phases that bridged SiC clusters above 2000°C. For ZC, surface flaws introduced during specimen preparation were the source of critical flaws in the material up to 1400°C, sub-critical crack growth of surface flaws between 1600 and 2000°C, and microvoid coalescence above 2000°C. It was also shown that thermal annealing at either 1400, 1500, or 1600°C improves the strength and modulus of ZS at temperatures between 800°C and 1600°C. Heat treatment at 1400°C for 10 hours produced the largest improvement in strength, 430 MPa at 1600°C versus 380 MPa for the as processed material. As a whole, the research pointed to several key microstructural features currently limiting the mechanical properties at the highest temperatures. In particular, removal of unfavorable secondary phases, and improved control over microstructure, should be promising methods to improve the elevated temperature properties of ZrB2 ceramics."--Abstract, page iv.
Science and Technology of Zirconia
Author: American Ceramic Society
Publisher:
ISBN:
Category : Science
Languages : en
Pages : 596
Book Description
Publisher:
ISBN:
Category : Science
Languages : en
Pages : 596
Book Description
Low and High Temperature Mechanical Properties of Annealed Zirconium
Author: Harry James Jackson
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 64
Book Description
Publisher:
ISBN:
Category : Zirconium
Languages : en
Pages : 64
Book Description
High-temperature Mechanical Properties of a Zirconium-modified, Precipitation-strengthened Nickel-30 Percent Copper Alloy
Author: John Daniel Whittenberger
Publisher:
ISBN:
Category : Copper-nickel alloys
Languages : en
Pages : 30
Book Description
Publisher:
ISBN:
Category : Copper-nickel alloys
Languages : en
Pages : 30
Book Description
Mechanical Properties of Irradiated Zirconium, Zircaloy, and Aluminum
Author: Richard E. Schreiber
Publisher:
ISBN:
Category : Aluminum alloys
Languages : en
Pages : 112
Book Description
Publisher:
ISBN:
Category : Aluminum alloys
Languages : en
Pages : 112
Book Description