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high strength low alloy steel
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Image
Published: 01 September 2005
Fig. 13 P/M transfer gear made of high-strength low-alloy steel. (a) Original P/M processing technique, which required machining of flange section. (b) Modified P/M technique, which required no additional machining
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Book Chapter
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.
Image
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
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Image
Published: 01 December 2015
Fig. 3 Oxidation of carbon steel and high-strength low-alloy (HSLA) steel in air. Source: Ref 2
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Published: 01 June 2008
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in Attributes of Advanced High-Strength Steels
> Advanced High-Strength Steels: Science, Technology, and Applications, Second Edition
Published: 31 October 2024
Fig. 4.9 Energy-absorbing capabilities of a high-strength, low-alloy (HSLA) steel and an advanced high-strength steel. DP, dual phase. Source: Ref 4.1
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in Introduction to Advanced High-Strength Steels
> Advanced High-Strength Steels: Science, Technology, and Applications, Second Edition
Published: 31 October 2024
Fig. 1.14 Grades and types of high-strength steels. HSLA, high strength, low alloy; BH, bake hardenable; IF, interstitial free; TRIP, transformation-induced plasticity; DP, dual phase; CP, complex phase; MS, martensitic. Source: Ref 1.15
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 June 2008
DOI: 10.31399/asm.tb.emea.t52240371
EISBN: 978-1-62708-251-8
... structural steels, SAE/AISI alloy steels, high-fracture-toughness steels, maraging steels, austenitic manganese steels, high-strength low-alloy steels, dual-phase steels, and transformation-induced plasticity steels. alloying elements mechanical properties low-alloy structural steels SAE/AISI alloy...
Abstract
Alloy steels are alloys of iron with the addition of carbon and one or more of the following elements: manganese, chromium, nickel, molybdenum, niobium, titanium, tungsten, cobalt, copper, vanadium, silicon, aluminum, and boron. Alloy steels exhibit superior mechanical properties compared to plain carbonsteels as a result of alloying additions. This chapter describes the beneficial effects of these alloying elements in steels. It discusses the mechanical properties, nominal compositions, advantages, and engineering applications of various classes of alloy steels. They are low-alloy structural steels, SAE/AISI alloy steels, high-fracture-toughness steels, maraging steels, austenitic manganese steels, high-strength low-alloy steels, dual-phase steels, and transformation-induced plasticity steels.
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in Advanced Steels for Forming Operations
> Metallography of Steels<subtitle>Interpretation of Structure and the Effects of Processing</subtitle>
Published: 01 August 2018
; CMn: C-Mn structural steels; HSLA: high-strength low alloy steels; DP: dual phase; CP: complex phase; TRIP: transformation-induced plasticity. Source: Ref 2
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Published: 01 January 2015
Fig. 12.1 Ranges of elongation and tensile strength combinations for various types of low-carbon steels. BH, bake-hardening; CMn, carbon manganese; CP, complex phase; DP, dual-phase; HSLA, high-strength, low-alloy steel; IF, interstitial-free; IF-HS, interstitial-free high-strengh; ISO
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 August 1999
DOI: 10.31399/asm.tb.lmcs.t66560081
EISBN: 978-1-62708-291-4
... and niobium- and vanadium-containing steels, and high-strength low-alloy steels. Chapter 5 discusses the composition, microstructure, and properties of these workhorse materials and explains how to identify the cause of production-related issues such as lamellar tearing and ferrite-pearlite banding. It also...
Abstract
This chapter covers a broad range of low-carbon steels optimized for structural applications. Low-carbon structural steels are generally considered the highest-strength steels that can be welded without undue difficulty, even in the field. They include mild steels, carbon-manganese and niobium- and vanadium-containing steels, and high-strength low-alloy steels. Chapter 5 discusses the composition, microstructure, and properties of these workhorse materials and explains how to identify the cause of production-related issues such as lamellar tearing and ferrite-pearlite banding. It also describes some of the alloying variations that have been developed to improve machinability and the mechanisms by which they work.
Series: ASM Technical Books
Publisher: ASM International
Published: 01 January 2017
DOI: 10.31399/asm.tb.sccmpe2.t55090419
EISBN: 978-1-62708-266-2
... Abstract This chapter describes nondestructive evaluation (NDE) test methods and their relative effectiveness for diagnosing the cause of stress-corrosion cracking (SCC) service failures. It discusses procedures for analyzing various types of damage in carbon and low-alloy steels, high-strength...
Abstract
This chapter describes nondestructive evaluation (NDE) test methods and their relative effectiveness for diagnosing the cause of stress-corrosion cracking (SCC) service failures. It discusses procedures for analyzing various types of damage in carbon and low-alloy steels, high-strength low-alloy steels, hardenable stainless steels, austenitic stainless steels, copper-base alloys, titanium and titanium alloys, aluminum and aluminum alloys, and nickel and nickel alloys. It identifies material-environment combinations where SCC is known to occur, provides guidelines on how to characterize cracking and fracture damage, and explains what to look for during macroscopic and microscopic examinations as well as chemical and metallographic analyses. It also includes nearly a dozen case studies investigating SCC failures in various materials.
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Published: 01 January 2015
Fig. 7.10 Widmanstätten ferrite saw teeth with low dislocation density in a copper-containing high-strength, low-alloy steel cooled at 0.1 °C/s (0.2 °F/s). Transmission electron microscopy micrograph. Source: Ref 7.11
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in The Expanded Metallographic Laboratory
> Metallographer’s Guide<subtitle>Practices and Procedures for Irons and Steels</subtitle>
Published: 01 March 2002
Fig. 6.16 An extraction replica showing titanium-molybdenum carbides in a high-strength, low-alloy steel. 130,000×
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in Steel Fundamentals
> Advanced High-Strength Steels: Science, Technology, and Applications, Second Edition
Published: 31 October 2024
Fig. 2.15 Continuous cooling transformation diagram for high-strength, low-alloy steel (AISI/SAE 5450). Source: Ref 2.1
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Image
Published: 01 July 1997
Fig. 19 Percent ductile fracture vs. test temperature for the submerged arc bead-in-groove welds deposited in high-strength low-alloy steel. The numbers 1 through 4 accompanying the alloy designation represent the heat input levels in kJ/mm. Source: Ref 16
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Image
in Steel Fundamentals
> Advanced-High Strength Steels<subtitle>Science, Technology, and Applications</subtitle>
Published: 01 August 2013
Fig. 2.15 Continuous cooling transformation (CCT) diagram for high-strength, low-alloy steel AISI/SAE 4340. Source: Ref 2.1
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Book Chapter
Series: ASM Technical Books
Publisher: ASM International
Published: 01 December 1995
DOI: 10.31399/asm.tb.sch6.t68200327
EISBN: 978-1-62708-354-6
... Abstract This chapter describes the processes involved in heat treatment of carbon and low alloy steel, high strength low alloy steels, austenitic manganese steels, martensitic stainless steels, and austenitic stainless steels. In addition, precipitation hardening and quench hardening of carbon...
Abstract
This chapter describes the processes involved in heat treatment of carbon and low alloy steel, high strength low alloy steels, austenitic manganese steels, martensitic stainless steels, and austenitic stainless steels. In addition, precipitation hardening and quench hardening of carbon steel is also covered.
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Published: 01 January 2015
Fig. 12.11 Maximum machine upset pressure required as a function of weld area in flash welding. The upset pressure capacity required for titanium is much less than for stainless and high-strength, low-alloy steels.
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Image
Published: 01 January 2015
Fig. 7.6 Continuous-cooling-transformation diagram for a high-strength, low-alloy steel containing 0.06% C, 1.45% Mn, 1.25% Cu, 0.97% Ni, 0.72% Cr, and 0.42% Mo. PF, polygonal ferrite; WF, Widmanstätten ferrite; AF, acicular ferrite; GF, granular ferrite. Source: Ref 7.11
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