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Search Results for low-carbon steel
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Book Chapter
Piercing of Low-Carbon Steel
Available to PurchaseSeries: ASM Handbook
Volume: 14B
Publisher: ASM International
Published: 01 January 2006
DOI: 10.31399/asm.hb.v14b.a0005109
EISBN: 978-1-62708-186-3
... in piercing. It illustrates the use of compound dies, progressive dies, and transfer dies; piercing of thick and thin stock and piercing holes at an angle to the surface; special piercing techniques; and shaving of low-carbon steels. compound dies low-carbon steel piercing progressive dies shear...
Abstract
This article illustrates the characteristics of pierced holes and summarizes the hole wall quality. Specific guidance in selecting die clearances is provided by considering the types of edges produced with different clearances. The article discusses the effect of tool dulling and the use of small and large clearance. It informs that the force needed to pierce a given material depends on the shear strength of the work metal, the peripheral size of the hole or holes to be pierced, stock thickness, and depth of shear on the punch. The article discusses the presses and tools used in piercing. It illustrates the use of compound dies, progressive dies, and transfer dies; piercing of thick and thin stock and piercing holes at an angle to the surface; special piercing techniques; and shaving of low-carbon steels.
Book Chapter
Blanking of Low-Carbon Steel
Available to PurchaseSeries: ASM Handbook
Volume: 14B
Publisher: ASM International
Published: 01 January 2006
DOI: 10.31399/asm.hb.v14b.a0005108
EISBN: 978-1-62708-186-3
... Abstract This article discusses the production of blanks from low-carbon steel sheet and strip in dies in a mechanical or hydraulic press. It describes the cutting operations that are done by dies in presses to produce blanks. The applications of blanking methods are described with examples...
Abstract
This article discusses the production of blanks from low-carbon steel sheet and strip in dies in a mechanical or hydraulic press. It describes the cutting operations that are done by dies in presses to produce blanks. The applications of blanking methods are described with examples. The article reviews the characteristics of blanked edges and explains how to calculate the forces and the work involved in blanking. Factors affecting the processing of blanks are discussed. The article provides information on the selection of work metal form, the effect of work metal thickness on the selection of material for dies and related components, as well as the selection of die type and design. The article illustrates the construction and use of short-run dies and conventional dies. It concludes with information on the shaving and deburring methods for blanking.
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Cap-to-pipe weldment. Low-carbon steel welded to medium-carbon steel; low-c...
Available to PurchasePublished: 01 January 1997
Fig. 12 Cap-to-pipe weldment. Low-carbon steel welded to medium-carbon steel; low-carbon steel filler metal (EL12). Source: Ref 15 Joint type Joggled lap Weld type, original design Square-groove, with backing ring Weld type, improved design Modified single-V-groove
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Comparison of nitrogen gradients in a low-carbon steel and in a low-alloy s...
Available to PurchasePublished: 01 August 2013
Fig. 7 Comparison of nitrogen gradients in a low-carbon steel and in a low-alloy steel containing chromium, both nitrided by the aerated bath process
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Image
Six low-carbon steel sheet specimens, separated by steel spacers, showing (...
Available to Purchase
in Metallography and Microstructures of Low-Carbon and Coated Steels
> Metallography and Microstructures
Published: 01 December 2004
Fig. 20 Six low-carbon steel sheet specimens, separated by steel spacers, showing (a) damage from mounting in a thermosetting phenolic resin and (b) lack of damage when mounted in a castable epoxy
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Image
Microstructure of a low-carbon steel sheet mounted in a steel clamp. The cl...
Available to Purchase
in Metallography and Microstructures of Low-Carbon and Coated Steels
> Metallography and Microstructures
Published: 01 December 2004
Fig. 24 Microstructure of a low-carbon steel sheet mounted in a steel clamp. The clamp is at the top. Note the excellent edge retention of the steel sample. Marshall's reagent. 500×
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Image
Electric-arc-sprayed low-carbon steel. Courtesy of Thermal Spray Technologi...
Available to PurchasePublished: 01 August 2013
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Effect of strip velocity on descaling time of hot-rolled low-carbon steel i...
Available to PurchasePublished: 01 January 1994
Fig. 5 Effect of strip velocity on descaling time of hot-rolled low-carbon steel in 4 g hydrochloric acid/100 mL, 22.7 g FeCl 2 /100 mL
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Image
Shear strength vs. joint clearance (brazing low-carbon steel with BAg-1). A...
Available to PurchasePublished: 09 June 2014
Fig. 6 Shear strength vs. joint clearance (brazing low-carbon steel with BAg-1). Adapted from Ref 3
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Image
Typical mechanical properties of low-carbon steel sheet shown by the range ...
Available to Purchase
in Carbon and Low-Alloy Steel Sheet and Strip
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 1 Typical mechanical properties of low-carbon steel sheet shown by the range of properties in steel furnished by three mills. Hot-rolled sheet thickness from 1.519 to 3.416 mm (0.0598 to 0.1345 in., or 16 to 10 gage); cold-rolled sheet thickness from 0.759 to 1.519 mm (0.0299 to 0.0598
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in Carbon and Low-Alloy Steel Sheet and Strip
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
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Effect of cold work on the tensile stress-strain curve for low-carbon steel...
Available to PurchasePublished: 01 January 1990
Image
Low-carbon steel, cold rolled 65%, showing the grain structure in the rolli...
Available to Purchase
in Sheet Formability of Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 8 Low-carbon steel, cold rolled 65%, showing the grain structure in the rolling plane ( R ), the longitudinal plane ( L ), and the transverse plane ( T ). RD, rolling direction
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Various regions of the HAZ of a single-pass low-carbon steel weld metal wit...
Available to PurchasePublished: 01 January 1990
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Schematic of the shrinkage of low-carbon steel. The contribution of each on...
Available to PurchasePublished: 01 December 2008
Fig. 1 Schematic of the shrinkage of low-carbon steel. The contribution of each one of the three distinct stages of volume contraction is shown: liquid shrinkage, solidification shrinkage, and solid contraction. Source: Ref 1
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Attempt to co-reduce cast cobalt alloy rods in low-carbon steel matrix. See...
Available to PurchasePublished: 30 September 2015
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Low-carbon steel drilled billet with seven cobalt alloy rods introduced (se...
Available to PurchasePublished: 30 September 2015
Fig. 14 Low-carbon steel drilled billet with seven cobalt alloy rods introduced (see Fig. 13 ). (a) Longitudinal section B-B′. (b) Cross section A-A′
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Powder metallurgy alloy FL-4405 (6.95 g/cm 3 ) joined to low-carbon steel r...
Available to PurchasePublished: 30 September 2015
Fig. 4 Powder metallurgy alloy FL-4405 (6.95 g/cm 3 ) joined to low-carbon steel rod without different filler wire diameter
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in Fabrication of Near-Net Shape Cost-Effective Titanium Components by Use of Prealloyed Powder and Hot Isostatic Pressing
> Powder Metallurgy
Published: 30 September 2015
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Work-hardening behavior of copper alloys versus that of low-carbon steel, a...
Available to PurchasePublished: 01 January 2006
Fig. 11 Work-hardening behavior of copper alloys versus that of low-carbon steel, austenitic stainless steel, and aluminum. (a) Effect of cold work by rolling reduction on ultimate tensile strength. (b) Effect of cold work on yield strength
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