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HSLA steel

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Oxidation of carbon <span class="search-highlight">steel</span> and high-strength low-alloy (<span class="search-highlight">HSLA</span>) <span class="search-highlight">steel</span> in air. ...

Oxidation of carbon steel and high-strength low-alloy (HSLA) steel in air. ...

in Oxidation > High-Temperature Corrosion and Materials Applications
Published: 01 November 2007
Fig. 3.7 Oxidation of carbon steel and high-strength low-alloy (HSLA) steel in air. Source: Ref 13 , reproduced from Ref 14 More
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Oxidation of carbon <span class="search-highlight">steel</span> and high-strength low-alloy (<span class="search-highlight">HSLA</span>) <span class="search-highlight">steel</span> in air. ...

Oxidation of carbon steel and high-strength low-alloy (HSLA) steel in air. ...

in High-Temperature Gaseous Corrosion[1] > Corrosion in the Petrochemical Industry
Published: 01 December 2015
Fig. 3 Oxidation of carbon steel and high-strength low-alloy (HSLA) steel in air. Source: Ref 2 More
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Oxidation of carbon <span class="search-highlight">steel</span> and <span class="search-highlight">HSLA</span> <span class="search-highlight">steel</span> in air. Source: Ref 11 , 12

Oxidation of carbon steel and HSLA steel in air. Source: Ref 11 , 12

in Carbon and Alloy Steels > Alloying: Understanding the Basics
Published: 01 December 2001
Fig. 31 Oxidation of carbon steel and HSLA steel in air. Source: Ref 11 , 12 More
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Energy-absorbing capabilities of an <span class="search-highlight">HSLA</span> <span class="search-highlight">steel</span> and an AHSS. Source: Ref 4....

Energy-absorbing capabilities of an HSLA steel and an AHSS. Source: Ref 4....

in Attributes of Advanced High-Strength Steels > Advanced-High Strength Steels<subtitle>Science, Technology, and Applications</subtitle>
Published: 01 August 2013
Fig. 4.9 Energy-absorbing capabilities of an HSLA steel and an AHSS. Source: Ref 4.1 More
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Fine grain size in high-strength low-alloy (<span class="search-highlight">HSLA</span>) <span class="search-highlight">steel</span>. Source: Ref 14

Fine grain size in high-strength low-alloy (HSLA) steel. Source: Ref 14

in Alloy Steels > Elements of Metallurgy and Engineering Alloys
Published: 01 June 2008
Fig. 20.13 Fine grain size in high-strength low-alloy (HSLA) steel. Source: Ref 14 More
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Variation of fatigue limit and yield stress for TRIP, DP, and <span class="search-highlight">HSLA</span> <span class="search-highlight">steels</span>. ...

Variation of fatigue limit and yield stress for TRIP, DP, and HSLA steels. ...

in Attributes of Advanced High-Strength Steels > Advanced-High Strength Steels<subtitle>Science, Technology, and Applications</subtitle>
Published: 01 August 2013
Fig. 4.7 Variation of fatigue limit and yield stress for TRIP, DP, and HSLA steels. Source: Ref 4.1 More
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Fatigue crack growth rate results for two A588 grade A <span class="search-highlight">HSLA</span> <span class="search-highlight">steels</span> showing ...

Fatigue crack growth rate results for two A588 grade A HSLA steels showing ...

in Carbon and Alloy Steels > Alloying: Understanding the Basics
Published: 01 December 2001
Fig. 21 Fatigue crack growth rate results for two A588 grade A HSLA steels showing comparison of LS and SL testing orientations. CON, conventional; CaT, calcium treatment. Improved isotropy of the calcium-treated steel is noted. More
Book Chapter

High-Strength Low-Alloy Steels

Series: ASM Technical Books
Publisher: ASM International
Published: 01 December 2001
DOI: 10.31399/asm.tb.aub.t61170193
EISBN: 978-1-62708-297-6
... Abstract This article discusses the effect of alloying on high-strength low-alloy (HSLA) steels. It explains where HSLA steels fit in the continuum of commercial steels and describes the six general categories into which they are divided. It provides composition data for standard types...
Abstract
This article discusses the effect of alloying on high-strength low-alloy (HSLA) steels. It explains where HSLA steels fit in the continuum of commercial steels and describes the six general categories into which they are divided. It provides composition data for standard types or grades of HSLA steel along with information on available mill forms, key characteristics, and intended uses. The article explains how small amounts of alloying elements, particularly vanadium, niobium, and titanium, control not only the properties of HSLA steels, but also their manufacturability.
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Book Chapter

Low-Carbon Steels

Series: ASM Technical Books
Publisher: ASM International
Published: 01 January 2015
DOI: 10.31399/asm.tb.spsp2.t54410233
EISBN: 978-1-62708-265-5
... This chapter discusses various alloying and processing approaches to increase the strength of low-carbon steels. It describes hot-rolled low-carbon steels, cold-rolled and annealed low-carbon steels, interstitial-free or ultra-low carbon steels, high-strength, low-alloy (HSLA) steels, dual-phase...
Abstract
This chapter discusses various alloying and processing approaches to increase the strength of low-carbon steels. It describes hot-rolled low-carbon steels, cold-rolled and annealed low-carbon steels, interstitial-free or ultra-low carbon steels, high-strength, low-alloy (HSLA) steels, dual-phase (DP) steels, transformation-induced plasticity (TRIP) steels, and martensitic low-carbon steels. It also discusses twinning-induced plasticity (TWIP) steels along with quenched and partitioned (Q&amp;P) steels.
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Polygonal ferrite (light structure) formed in <span class="search-highlight">HSLA</span>-80 <span class="search-highlight">steel</span> isothermally tr...

Polygonal ferrite (light structure) formed in HSLA-80 steel isothermally tr...

in Ferritic Microstructures > Steels<subtitle>Processing, Structure, and Performance</subtitle>
Published: 01 January 2015
Fig. 7.7 Polygonal ferrite (light structure) formed in HSLA-80 steel isothermally transformed at 675 °C (1250 °F) for 500 s. Martensite (dark structure) has formed during cooling in austenite untransformed after the isothermal hold. Light micrograph, nital etch. Courtesy of M. Kumar. Source More
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Continuous-cooling-transformation diagram for <span class="search-highlight">HSLA</span>-80 <span class="search-highlight">steel</span>. Source: Ref 7...

Continuous-cooling-transformation diagram for HSLA-80 steel. Source: Ref 7...

in Ferritic Microstructures > Steels<subtitle>Processing, Structure, and Performance</subtitle>
Published: 01 January 2015
Fig. 7.12 Continuous-cooling-transformation diagram for HSLA-80 steel. Source: Ref 7.24 More
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Lower strength grade of <span class="search-highlight">HSLA</span> hot-rolled <span class="search-highlight">steel</span> strip. High carbon, low manga...

Lower strength grade of HSLA hot-rolled steel strip. High carbon, low manga...

in Low-Carbon Structural Steels > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 5.10 Lower strength grade of HSLA hot-rolled steel strip. High carbon, low manganese, microalloys: niobium and vanadium. 0.085C-0.20Si-1.06Mn-0.003M0-0.022Nb-0.004Ti-0.017V-0.001S-0.014P (wt%). 185 HV. (a) Quarter-thickness region. Nital. 100×. (b) Quarter-thickness region. Nital More
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Higher-strength grade of <span class="search-highlight">HSLA</span> hot-rolled <span class="search-highlight">steel</span> strip. 0.055C-0.21Si-1.46Mn-...

Higher-strength grade of HSLA hot-rolled steel strip. 0.055C-0.21Si-1.46Mn-...

in Low-Carbon Structural Steels > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 5.11 Higher-strength grade of HSLA hot-rolled steel strip. 0.055C-0.21Si-1.46Mn-0.004Mo-0.045Nb-0.038Ti-O.003V-0.003S-0.013P (wt%). 250 HV. (a) Central region. Nital. 100×. (b) Central region. Nital. 1000×. (c) Scanning electron micrograph of central region. Nital. 5000×. More
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Higher-strength grade of <span class="search-highlight">HSLA</span> hot-rolled <span class="search-highlight">steel</span> strip. High carbon, high man...

Higher-strength grade of HSLA hot-rolled steel strip. High carbon, high man...

in Low-Carbon Structural Steels > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 5.12 (Part 1) Higher-strength grade of HSLA hot-rolled steel strip. High carbon, high manganese, microalloys: niobium and vanadium. 0.085C-0.19Si-1.42Mn-0.003M0-0.045Nb-0.003Ti-0.038V-0.001S-0.015P (wt%). 220 HV. (a) Quarter-thickness region. Nital. 100×. (b) Quarter-thickness region More
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Higher-strength grade of <span class="search-highlight">HSLA</span> hot-rolled <span class="search-highlight">steel</span> strip. (a) to (g) Low ca...

Higher-strength grade of HSLA hot-rolled steel strip. (a) to (g) Low ca...

in Low-Carbon Structural Steels > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 5.13 (Part 1) Higher-strength grade of HSLA hot-rolled steel strip. (a) to (g) Low carbon, high manganese, microalloys: molybdenum, niobium, and titanium. 0.065C-0.35Si-1.38Mn-0.24Mo-0.065Nb-0.017Ti-0.003V-0.002S-0.013P (wt%). 240 HV. (a) Quarter-thickness region. Nital. 100×. (b More
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General comparison of Charpy V-notch toughness for a mild-carbon <span class="search-highlight">steel</span> (AST...

General comparison of Charpy V-notch toughness for a mild-carbon steel (AST...

in Steel Products and Properties > Metallurgy for the Non-Metallurgist
Published: 01 October 2011
Fig. 8.5 General comparison of Charpy V-notch toughness for a mild-carbon steel (ASTM A 7, now ASTM A 283, grade D), an HSLA steel, and a heat-treated constructional alloy steel More
Book Chapter

Applications of Advanced High-Strength Steels

Series: ASM Technical Books
Publisher: ASM International
Published: 01 August 2013
DOI: 10.31399/asm.tb.ahsssta.t53700159
EISBN: 978-1-62708-279-2
... Material breakdown by mass of the BIW structure, shown in Fig. 11.8 , indicates that AHSS account for 34.4% while high-strength, low-alloy (HSLA) steel accounts for 22.6%. Fig. 11.8 Color-coded material breakdown by mass for BIW structure of the 2013 Cadillac ATS. Source: Ref 11.6 2013 Ford...
Abstract
This chapter reviews the nomenclature of different vehicle components helpful in identifying the target applications and discusses the implementation of advanced high-strength steels (AHSS) in automotive and nonautomotive industries. In addition, the chapter provides information on the utilization and trends of AHSS in vehicle bodies and closures.
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A STEM micrograph of titanium-molybdenum carbides in an extraction replica ...

A STEM micrograph of titanium-molybdenum carbides in an extraction replica ...

in The Expanded Metallographic Laboratory > Metallographer’s Guide<subtitle>Practices and Procedures for Irons and Steels</subtitle>
Published: 01 March 2002
Fig. 6.28 A STEM micrograph of titanium-molybdenum carbides in an extraction replica of a HSLA steel. Micrograph taken in dark field, thus the precipitates appear white in a dark matrix. 230,000×. Courtesy of K.A. Taylor, Bethlehem Steel Corporation More
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Variation in transverse Charpy V-notch impact energy with temperature for H...

Variation in transverse Charpy V-notch impact energy with temperature for H...

in Carbon and Alloy Steels > Alloying: Understanding the Basics
Published: 01 December 2001
Fig. 11 Variation in transverse Charpy V-notch impact energy with temperature for HSLA steels containing varying amounts of sulfur. The steels were silicon-aluminum killed with a minimum yield strength of 450 MPa (65 ksi). More
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Variation in transverse Charpy V-notch impact energy with temperature for H...

Variation in transverse Charpy V-notch impact energy with temperature for H...

in Low-Temperature and Cryogenic Steels > Steel Castings Handbook
Published: 01 December 1995
Fig. 23-14 Variation in transverse Charpy V-notch impact energy with temperature for HSLA steels containing varying amounts of sulfur. The steels were silicon-aluminum killed with a minimum yield strength of 450 MPa (65 ksi). More