1-20 of 1021

Search Results for weld metals

Save search
Follow your search
Access your saved searches in your account
Would you like to receive an alert when new items match your search?
Close Modal
Sort by
Image

Examples of notch locations for toughness testing of weld metals (a and b) ...

Available to Purchase
in Fatigue and Fracture Control of Welds[1] > Weld Integrity and Performance
Published: 01 July 1997
Fig. 24 Examples of notch locations for toughness testing of weld metals (a and b) and HAZ (c through g) More
Image

Examples of notch locations for toughness testing of weld metals (a and b) ...

Available to Purchase
in Metallic Joints: Mechanically Fastened and Welded > Fatigue and Fracture: Understanding the Basics
Published: 01 November 2012
Fig. 31 Examples of notch locations for toughness testing of weld metals (a and b) and heat-affected zone (HAZ) (c through g). Source: Ref 16 More
Image

Fracture toughness of AWS 316 and 316L weld metals at 76 and 4 K as a funct...

Available to Purchase
in Structural Alloys > Materials at Low Temperatures
Published: 01 June 1983
Figure 11.22 Fracture toughness of AWS 316 and 316L weld metals at 76 and 4 K as a function of ferrite content ( Read et al., 1980 ). More
Image

Fracture toughness of fully austenitic weld metals at 4 K as a function of ...

Available to Purchase
in Structural Alloys > Materials at Low Temperatures
Published: 01 June 1983
Figure 11.23 Fracture toughness of fully austenitic weld metals at 4 K as a function of grain width. ● — Read et al., 1980 ; △ — LCP; ○ — MFTF. LCP and MFTF refer to weld procedure qualification welds prepared for the Large Coil Project, Oak Ridge National Laboratory and the Magnetic Fusion More
Image

(c) Weld metal: grain-boundary region. 1% nital. 100×. (d) Weld metal: c...

Available to Purchase
in Welding > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 11.22 (Part 2) (c) Weld metal: grain-boundary region. 1% nital. 100×. (d) Weld metal: center of a grain. 1% nital. 100×. More
Image

(e) Weld metal, grain-refined pass. 1% nital. 100×. (f) Weld metal, grai...

Available to Purchase
in Welding > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 11.26 (Part 2) (e) Weld metal, grain-refined pass. 1% nital. 100×. (f) Weld metal, grain-refined pass. Picral. 1000×. (a) and (h) Weld metal: 0.11C-0.14Si-1.01 Mn (wt%). Butt weld made in seven passes in 14 mm plate. (g) Weld metal, as-deposited pass. 1% nital. 100×. (h) Weld More
Image

Weld metal forming a corrosion cell on steel. Weld metal may be anodic to s...

Available to Purchase
in Principles of Corrosion > Surface Engineering for Corrosion and Wear Resistance
Published: 01 March 2001
Fig. 5 Weld metal forming a corrosion cell on steel. Weld metal may be anodic to steel, creating a corrosion cell when immersed. More
Book Chapter

Metallic Joints: Mechanically Fastened and Welded

Available to Purchase

Series: ASM Technical Books
Publisher: ASM International
Published: 01 November 2012
DOI: 10.31399/asm.tb.ffub.t53610263
EISBN: 978-1-62708-303-4
... where fatigue failures are likely to occur in cold-driven rivet and friction joints, and why the fatigue strength of welded joints can be much lower than that of the parent metal, depending on weld shape, joint geometry, discontinuities, and residual stresses. The chapter also explains how to improve...
Abstract
This chapter discusses the fatigue behavior of bolted, riveted, and welded joints. It describes the relative strength of machined and rolled threads and the effect of thread design, preload, and clamping force on the fatigue strength of bolts made from different steels. It explains where fatigue failures are likely to occur in cold-driven rivet and friction joints, and why the fatigue strength of welded joints can be much lower than that of the parent metal, depending on weld shape, joint geometry, discontinuities, and residual stresses. The chapter also explains how to improve the fatigue life of welded joints and discusses the factors that can reduce the fracture toughness of weld metals.
View PDF for content titled, <span class="search-highlight">Metallic</span> Joints: Mechanically Fastened and <span class="search-highlight">Welded</span>
Image

Pitting corrosion resistance of base metal relative to weld metal placed in...

Available to Purchase
in Properties of Stainless Steel Welds[1] > Weld Integrity and Performance
Published: 01 July 1997
Fig. 22 Pitting corrosion resistance of base metal relative to weld metal placed in 6 wt% FeCI 3 solution for 24 h per ASTM G 48 (method A). Source: Ref 35 More
Image

Pitting of underalloyed (relative to base metal) type 308L weld metal. The ...

Available to Purchase
in Corrosion of Austenitic Stainless Steel Weldments > Corrosion of Weldments
Published: 01 December 2006
Fig. 12 Pitting of underalloyed (relative to base metal) type 308L weld metal. The type 316L stainless steel base metal is unaffected. About 2.5× More
Image

Chloride SCC of type 304 stainless steel base metal and type 308 weld metal...

Available to Purchase
in Corrosion of Austenitic Stainless Steel Weldments > Corrosion of Weldments
Published: 01 December 2006
Fig. 20 Chloride SCC of type 304 stainless steel base metal and type 308 weld metal in an aqueous chloride environment at 95 °C (200 °F). Cracks are branching and transgranular. More
Image

Pitting corrosion resistance of base metal relative to weld metal placed in...

Available to Purchase
in Corrosion of Duplex Stainless Steel Weldments > Corrosion of Weldments
Published: 01 December 2006
Fig. 9 Pitting corrosion resistance of base metal relative to weld metal placed in 6 wt % FeCl 3 solution for 24 h duration per ASTM 648 (method A). Source: Ref 14 More
Image

Pitting of underalloyed (relative to the base metal) type 308L weld metal. ...

Available to Purchase
in Corrosion of Stainless Steel Weldments[1] > Corrosion in the Petrochemical Industry
Published: 01 December 2015
Fig. 9 Pitting of underalloyed (relative to the base metal) type 308L weld metal. The type 316L stainless steel base metal is unaffected. About 2.5× More
Image

Electroslag weld low oxygen content. Weld metal: 0.20C-0.22Si-1.08Mn. Singl...

Available to Purchase
in Welding > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 11.21 Electroslag weld low oxygen content. Weld metal: 0.20C-0.22Si-1.08Mn. Single-pass weld in 25 mm plate. (a) Weld region; longitudinal section. 3% nital. 1×. (b) Weld metal. 215 HV. Arrow indicates large area of bainite. (c) Weld metal. 215 HV. Arrow indicates large area More
Image

Electroslag butt weld in 0.2% C 50 mm thick plate. Weld metal: 0.16C-0.37Si...

Available to Purchase
in Welding > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 11.22 (Part 1) Electroslag butt weld in 0.2% C 50 mm thick plate. Weld metal: 0.16C-0.37Si-0.90Mn (wt%). (a) # Transverse section. 3% nital. 1.25×. (b) Weld metal. 170 HV. 1% nital. 1 O×. (c) Weld metal: grain-boundary region. 1% nital. 100×. (d) Weld metal: center of a grain. 1 More
Image

Electroslag butt weld in 0.15% C 50 mm thick plate. Weld metal: 0.16C-0.37S...

Available to Purchase
in Welding > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 11.23 Electroslag butt weld in 0.15% C 50 mm thick plate. Weld metal: 0.16C-0.37Si-0.90Mn (wt%). (a) and (b) Weld metal, as deposited. 170 HV. Picral. 1000×. (c) and (d) Weld metal, after weldment has been austenitized at 925 °C and cooled at 500 °C/h. 125 HV. (c) 1% nital. 100 More
Image

Shape of the weld pool formed in an electron-beam weld. Metal flows down th...

Available to Purchase
in Welding > Light Microscopy of Carbon Steels
Published: 01 August 1999
Fig. 11.28 (Part 3) (g) Shape of the weld pool formed in an electron-beam weld. Metal flows down the front of the weld pool and then in the direction of the arrows after the weld pool has passed. After Ref 20 . More
Image

Welding Research Council (WRC-1988) diagram used to predict weld metal ferr...

Available to Purchase
in Corrosion of Weldments[1] > Weld Integrity and Performance
Published: 01 July 1997
Fig. 8 Welding Research Council (WRC-1988) diagram used to predict weld metal ferrite content. Source: Ref 18 More
Image

Effect of welding process on weld metal toughness for low-alloy steels. Sou...

Available to Purchase
in Properties of Carbon Alloy Steel Welds[1] > Weld Integrity and Performance
Published: 01 July 1997
Fig. 4 Effect of welding process on weld metal toughness for low-alloy steels. Source: Ref 5 More
Image

(a) Crack in electron-beam-welded aluminum alloy Al-6061 (right: weld metal...

Available to Purchase
in Cold Spray Applications in Repair and Refurbishment for the Aerospace, Oil and Gas, and Power-Generation Industries > High Pressure Cold Spray: Principles and Applications
Published: 01 June 2016
Fig. 11.10 (a) Crack in electron-beam-welded aluminum alloy Al-6061 (right: weld metal; left: parent metal). (b) Crack-free electron beam weld in Al-6082 alloy made with cold-sprayed buttering layer using Al-4041 alloy. Source: Ref 11.15 . Courtesy of TWI Ltd. More