Skip Nav Destination
Close Modal
Search Results for
tensile strength
Update search
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
Filter
- Title
- Authors
- Author Affiliations
- Full Text
- Abstract
- Keywords
- DOI
- ISBN
- EISBN
- Issue
- ISSN
- EISSN
- Volume
- References
NARROW
Format
Topics
Book Series
Date
Availability
1-20 of 1243 Search Results for
tensile strength
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
1
Sort by
Image
Published: 01 October 2011
Fig. 13.1 Comparison of short-time tensile strength and tensile strength/density ratio for titanium alloys, three classes of steel, and 2024-T86 aluminum alloy. Data are not included for annealed alloys with less than 10% elongation or heat-treated alloys with less than 5% elongation.
More
Image
in Martensitic Steels
> Advanced-High Strength Steels<subtitle>Science, Technology, and Applications</subtitle>
Published: 01 August 2013
Fig. 8.6 Tensile strength and formability during hot forming. UTS, ultimate tensile strength. Source: Ref 8.6
More
Image
in Melting, Casting, and Powder Metallurgy[1]
> Titanium: Physical Metallurgy, Processing, and Applications
Published: 01 January 2015
Fig. 8.51 Ultimate tensile strength (UTS), yield strength (YS), and elongation of Ti-6Al-4V alloy produced using various additive manufacturing processes. DMD, direct-metal deposition; HIP, hot isostatic pressing; HT, heat treatment; LENS, laser-engineered net shaping ( Ref 8.16 ); DMLS
More
Image
Published: 01 November 2013
Fig. 1 Effect of carbon content on steel strength. UTS, ultimate tensile strength; YS, yield strength. Source: Ref 1
More
Image
Published: 01 October 2012
Fig. 2.36 Strength across fusion weld joint. Ultimate tensile strength values are estimated from hardness readings. Source: Ref 2.26
More
Image
Published: 01 June 2008
Fig. 11.1 Effect of carbon content on steel strength. UTS, ultimate tensile strength; YS, yield strength
More
Image
Published: 01 December 2015
Fig. 4 Notch tensile strength of high-strength steel plotted against testing temperature for three strain rates (crosshead speeds, ε ˙ ). Source: Ref 15
More
Image
in High-Carbon Steels—Fully Pearlitic Microstructures and Wire and Rail Applications
> Steels: Processing, Structure, and Performance
Published: 01 January 2015
Fig. 15.18 Changes in yield strength (a) and tensile strength (b) as a function of time at temperatures of 350 to 500 °C (660 to 930 °F). The as drawn strengths correspond to the 0 heating time, and the galvanized strengths are given by the horizontal dashed line. Source: Ref 15.50
More
Image
Published: 01 November 2012
Fig. 32 Relationships between the fatigue strength and tensile strength of some wrought aluminum alloys. Source: Ref 11
More
Image
Published: 01 July 2009
Fig. 14.3 Tensile strength (UTS), yield strength, and elongation as a function of temperature for extruded Lockalloy LX62. Source: London 1979
More
Image
Published: 01 July 1997
Fig. 6 Effect of material tensile strength or the fatigue strength of welded and unwelded specimens
More
Image
in Petroleum Reactor Pressure-Vessel Materials for Hydrogen Service
> Damage Mechanisms and Life Assessment of High-Temperature Components
Published: 01 December 1989
Fig. 7.1. Effect of room-temperature tensile strength on 100,000-h rupture strength of quenched-and-tempered and normalized-and-tempered 2¼Cr-1Mo steel ( Ref 12 ).
More
Image
Published: 01 December 1995
Fig. 20-4 Yield strength (0.2% offset) and tensile strength at room temperature as a function of ferrite content for CF-8 and CF-8M alloys. (Adapted from Beck et al.)
More
Image
Published: 01 December 1995
Fig. 20-7 Effect of nitrogen on the tensile strength, yield strength, and elastic modulus in constant ferrite content CF-8 steels
More
Image
Published: 01 December 1996
Fig. 8-47 (Part 1) Factors affecting (a) the tensile strength and (b) the yield strength of structural steels with a primary ferrite-pearlite microstructure. (From T. Gladman, D. Dulieu, and I.D. Mclvor, in MicroAlloying 75 , p 32, Union Carbide Corporation, New York (1977), Ref 24 )
More
Image
Published: 01 December 1996
Fig. 8-47 (Part 2) Factors affecting (a) the tensile strength and (b) the yield strength of structural steels with a primary ferrite-pearlite microstructure. (From T. Gladman, D. Dulieu, and I.D. Mclvor, in MicroAlloying 75 , p 32, Union Carbide Corporation, New York (1977), Ref 24 )
More
Image
in Modeling and Use of Correlations in Heat Treatment
> Principles of the Heat Treatment of Plain Carbon and Low Alloy Steels
Published: 01 December 1996
Fig. 9-26 Relation between yield strength and the tensile strength for steels. (From same source as Fig. 9-25 )
More
Image
in Modeling and Use of Correlations in Heat Treatment
> Principles of the Heat Treatment of Plain Carbon and Low Alloy Steels
Published: 01 December 1996
Fig. 9-27 Relation between the fatigue strength and the tensile strength for several steels. The straight lines have the slope shown. (Adapted from a compilation of T.J. Dola and C.S. Yen, Proc. ASTM , Vol 48, p 664 (1948), Ref 26 )
More
Image
Published: 01 March 2006
Fig. A.33 Representation of relative tensile strength and ductility of ausformed steels (highly deformed) compared with the same steels heat treated conventionally
More
Image
Published: 01 March 2002
Fig. 14.3 Room-temperature tensile strength vs. exposure times at 1038 °C (1900 °F) in air for Hastelloy X nickel-base solid-solution and carbide-strengthened superalloy
More
1