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yield strength
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Series: ASM Technical Books
Publisher: ASM International
Published: 01 January 2017
DOI: 10.31399/asm.tb.sccmpe2.t55090067
EISBN: 978-1-62708-266-2
... steels and discusses the influence of composition, steelmaking practice, and application environment. chemical composition heat treatment high-strength steel stress-corrosion cracking STEELS with yield strengths greater than 1240 MPa (180 ksi), corresponding to hardnesses greater than 40...
Abstract
High-strength steels are susceptible to stress-corrosion cracking (SCC) even in moist air. This chapter identifies such steels and the applications where they are typically found. It provides information on crack growth kinetics and crack propagation models in which hydrogen embrittlement is the predominant mechanism. It explains how different application variables affect SCC, including loading mode, state of stress, type of steel, temperature, electrochemical potential, heat treatment, and deformation processes. It also compares SCC characteristics in different high-strength steels and discusses the influence of composition, steelmaking practice, and application environment.
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Published: 01 June 1983
Figure 11.37 Notch-yield ratio vs. tensile yield strength for aluminum alloys at 4 K ( Kaufman and Wanderer, 1971 ). ○ — 2xxx alloys; ● — 3xxx alloys; □ — 5xxx alloys; ◊ — 6xxx alloys; △ — 7xxx alloys; ▽ — casting alloys.
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in Properties and Performance of Aluminum Castings
> Aluminum Alloy Castings: Properties, Processes, and Applications
Published: 01 December 2004
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in Properties and Performance of Aluminum Castings
> Aluminum Alloy Castings: Properties, Processes, and Applications
Published: 01 December 2004
Fig. 8.13 Notch-yield ratio versus tensile yield strength for welds in aluminum alloy castings for combinations of casting alloys and filler alloys (middle number)
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in Properties and Performance of Aluminum Castings
> Aluminum Alloy Castings: Properties, Processes, and Applications
Published: 01 December 2004
Fig. 8.15 Notch-yield ratio versus tensile yield strength for aluminum casting alloys at –320 °F (–196 °C) and –423 °F (–253 °C)
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in Properties and Performance of Aluminum Castings
> Aluminum Alloy Castings: Properties, Processes, and Applications
Published: 01 December 2004
Fig. 8.17 Notch-yield ratio versus tensile yield strength for welded aluminum alloy castings at –320 °F (–196 °C) for combinations of casting alloys and filler alloys (middle number)
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Published: 01 December 2004
Fig. 12 Stress-strain diagram showing yield point or yield strength by extension-under-load method. o-m , specified extension under load. Line m-n is vertical, and the intersection point, r , determines yield strength value, R. Source: Ref 3
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Published: 01 June 2008
Fig. 26.5 Fracture toughness versus yield strength for high-strength aluminum alloys. Source: Ref 8
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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
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Published: 01 July 2000
Fig. 7.86 Relationship between yield strength and mean failure time for high-strength steels exposed as bent-beam tests in distilled water. Specimens were exposed at stress of 75% of the yield strength. Source: Ref 123
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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
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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
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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.)
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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
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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 )
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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 )
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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 )
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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. 9-28 The fatigue strength as a function of yield strength for steels. (From C.R. Brooks, The Heat Treatment of Ferrous Alloys , Hemisphere Publishing Corporation/McGraw-Hill Book Company, New York (1979), Ref 27 )
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Published: 01 January 1998
Fig. 14-38 Effect of austenitizing temperature on the yield strength and bend strength (a) and the plastic deflection and the total deflection (b) of T1 high-speed steel. Specimens were double tempered for 2.5 h periods at 555 °C (1030 °F). Source: ref 37
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Published: 01 January 1998
Fig. 14-39 (a) Effect of tempering temperature on the yield strength, bend strength, and hardness of T1 and M2 high-speed steels. Tempering time was 1 h. The T1 steel was austenitized at 1290 °C (2350 °F) and M2 steel was austenitized at 1220 °C (2225 °F). (b) Effect of tempering temperature
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