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gouging

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Relation between <span class="search-highlight">gouging</span> wear and carbon content for various types of steel...

Relation between gouging wear and carbon content for various types of steel...

in Carbon and Alloy Steels > Alloying: Understanding the Basics
Published: 01 December 2001
Fig. 33 Relation between gouging wear and carbon content for various types of steel and cast iron More
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Deep caustic <span class="search-highlight">gouging</span> below the insulating deposits on ID side of an economi...

Deep caustic gouging below the insulating deposits on ID side of an economi...

in Water-Side Corrosion Failures > Failure Investigation of Boiler Tubes: A Comprehensive Approach
Published: 01 December 2018
Fig. 6.61 Deep caustic gouging below the insulating deposits on ID side of an economizer tube More
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<span class="search-highlight">Gouging</span> abrasion

Gouging abrasion

in Types of Wear and Erosion and Their Mechanisms > Tribomaterials: Properties and Selection for Friction, Wear, and Erosion Applications
Published: 30 April 2021
Fig. 4.20 Gouging abrasion More
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Effect of carbon content, microstructure, and hardness on <span class="search-highlight">gouging</span> wear rati...

Effect of carbon content, microstructure, and hardness on gouging wear rati...

in Wear-Resistant Steels > Steel Castings Handbook
Published: 01 December 1995
Fig. 19-10 Effect of carbon content, microstructure, and hardness on gouging wear ratio ( 15 ) More
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Typical flaws in seamless tubing, (a) blister, (b) <span class="search-highlight">gouge</span>, (c) lamination, (...

Typical flaws in seamless tubing, (a) blister, (b) gouge, (c) lamination, (...

in Inspection of Tubular Products > Inspection of Metals: Understanding the Basics
Published: 01 April 2013
Fig. 4 Typical flaws in seamless tubing, (a) blister, (b) gouge, (c) lamination, (d) lap (arrow), (e) pit, (f) plug scores, (g) rolled-in slugs, (h) scab, (i) seam (arrow). Source: Ref 1 More
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Sprial bevel gear tooth, 3×, showing surface <span class="search-highlight">gouge</span> due to the breaking of a...

Sprial bevel gear tooth, 3×, showing surface gouge due to the breaking of a...

in Causes of Gear Failure > Systematic Analysis of Gear Failures
Published: 01 June 1985
Fig. 5-34. Sprial bevel gear tooth, 3×, showing surface gouge due to the breaking of a cutter blade. More
Book Chapter

Wear Failures

Series: ASM Technical Books
Publisher: ASM International
Published: 01 November 2012
DOI: 10.31399/asm.tb.ffub.t53610461
EISBN: 978-1-62708-303-4
... Abstract This chapter discusses the causes and effects of wear along with prevention methods. It covers abrasive, erosive, erosion-corrosion, grinding, gouging, adhesive, and fretting wear. It also discusses various forms of contact-stress fatigue, including subsurface-origin fatigue, surface...
Abstract
This chapter discusses the causes and effects of wear along with prevention methods. It covers abrasive, erosive, erosion-corrosion, grinding, gouging, adhesive, and fretting wear. It also discusses various forms of contact-stress fatigue, including subsurface-origin fatigue, surface-origin fatigue, subcase-origin fatigue (spalling fatigue), and cavitation fatigue.
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Book Chapter

Wear Failures—Abrasive and Adhesive

Series: ASM Technical Books
Publisher: ASM International
Published: 30 November 2013
DOI: 10.31399/asm.tb.uhcf3.t53630169
EISBN: 978-1-62708-270-9
... Abstract This chapter is a detailed account of the general characteristics and effects of and the methods for preventing or reducing different categories of wear failures, namely abrasive (erosive, grinding, and gouging), adhesive, and fretting wear. abrasive wear adhesive wear fretting...
Abstract
This chapter is a detailed account of the general characteristics and effects of and the methods for preventing or reducing different categories of wear failures, namely abrasive (erosive, grinding, and gouging), adhesive, and fretting wear.
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(a) Transverse cut section view of the failed tube near leakage area indica...

(a) Transverse cut section view of the failed tube near leakage area indica...

in Water-Side Corrosion Failures > Failure Investigation of Boiler Tubes: A Comprehensive Approach
Published: 01 December 2018
Fig. 6.63 (a) Transverse cut section view of the failed tube near leakage area indicating localized metal wastage. (b) Inner surface low-magnification view near leakage showing metal wastage in the form of gouging, 12× More
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Failure of this axle shaft resulted from torsional fatigue in the tensile p...

Failure of this axle shaft resulted from torsional fatigue in the tensile p...

in The Final Analysis > Systematic Analysis of Gear Failures
Published: 01 June 1985
Fig. 6-1. Failure of this axle shaft resulted from torsional fatigue in the tensile plane, originating from one of several gouge marks observed around the shaft at the splined radius. The fatigue crack progressed for a large number of cycles before final fracture. More
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Submerged arc welding. (a) Process schematic. (b) Submerged arc welding of ...

Submerged arc welding. (a) Process schematic. (b) Submerged arc welding of ...

in Fabrication and Finishing of Metal Products > Metallurgy for the Non-Metallurgist
Published: 01 October 2011
Fig. 6.29 Submerged arc welding. (a) Process schematic. (b) Submerged arc welding of flame-gouged seam joining the head to the shell inside a tower. Four passes were made with a current of 400 amperes and a speed of 356 mm/min (14 in. / min). Courtesy of Lincoln Electric More
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Localized corrosion of asbestos-gasketed flanged joints in a type 304 stain...

Localized corrosion of asbestos-gasketed flanged joints in a type 304 stain...

in Microbiologically Influenced Corrosion[1] > Corrosion in the Petrochemical Industry
Published: 01 December 2015
Fig. 19 Localized corrosion of asbestos-gasketed flanged joints in a type 304 stainless steel piping system. (a) Single remaining biodeposit adjacent to resulting corrosion on the flange. Numerous other similar deposits were dislodged in opening the joint. (b) Closeup of gouging-type corrosion More
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Effect of welding on the life of a carbon steel structure. (a) and (b) 46 c...

Effect of welding on the life of a carbon steel structure. (a) and (b) 46 c...

in Introduction to Fatigue and Fracture > Fatigue and Fracture: Understanding the Basics
Published: 01 November 2012
Fig. 10 Effect of welding on the life of a carbon steel structure. (a) and (b) 46 cm (18 in.) long crack found in a carbon steel as-forged nozzle that was arc gouged. Failure occurred after five years in service during cold startup procedure. (c) Micrograph showing a hardened layer More
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Idealized representations of the two types of force applications on abrasiv...

Idealized representations of the two types of force applications on abrasiv...

in Wear Failures > Fatigue and Fracture: Understanding the Basics
Published: 01 November 2012
. This is characteristic of grinding and gouging abrasion, in which the hard particles are forced to scratch or cut the metal surface. (b) Represents the cutting or plowing action of a loose particle flowing across the metal surface after impinging upon the surface. This is characteristic of erosive wear, in which free More
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Idealized representations of the two types of force applications on abrasiv...

Idealized representations of the two types of force applications on abrasiv...

in Wear Failures—Abrasive and Adhesive[1] > Understanding How Components Fail
Published: 30 November 2013
of grinding and gouging abrasion, in which the hard particles are forced to scratch or cut the metal surface. (b) Cutting or plowing action of a loose particle flowing across the metal surface after impinging upon the surface. This is characteristic of erosive wear, in which free particles strike the surface More
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Schematics illustrating the four types of abrasive wear. (a) Low-stress abr...

Schematics illustrating the four types of abrasive wear. (a) Low-stress abr...

in Principles of Friction and Wear > Surface Engineering for Corrosion and Wear Resistance
Published: 01 March 2001
, and pitting from impressed particles. Damage is almost always more severe than low-stress abrasion. (c) Gouging abrasion where material removal is caused by the action of repetitive compressive loading of hard materials such as rocks against a softer surface, usually a metal. (d) Polishing wear where material More
Book Chapter

Wear-Resistant Steels

Series: ASM Technical Books
Publisher: ASM International
Published: 01 December 1995
DOI: 10.31399/asm.tb.sch6.t68200253
EISBN: 978-1-62708-354-6
... severity of abrasion is so bad that large pieces of surface are removed as evidenced by visual grooving, then Gouging Abrasion is said to occur. This type of Abrasive Wear occurs in the crushing of rock and/or various ores where particle sizes range from several inches down to the order of 1/4 inch (0.6...
Abstract
This chapter provides the definitions of fundamental wear mechanisms. The chapter describes the properties and applications of materials used for wear resistance. It discusses the processes involved in screening tests for wear resistance. In addition, the practical application of wear-resistant principles is covered.
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Subcase-origin fatigue. (a) As the name implies, subcase fatigue cracks ori...

Subcase-origin fatigue. (a) As the name implies, subcase fatigue cracks ori...

in Wear Failures > Fatigue and Fracture: Understanding the Basics
Published: 01 November 2012
of the surface, leaving a longitudinally ridged and gouged appearance. The ridges are the locations where two adjacent fatigue cracks joined and sent a crack through the case to the surface. This and the gear in (b) were made of low-carbon alloy steel, case carburized to a surface hardness near 60 HRC. (d) Cross More
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Subcase-origin fatigue. (a) As the name implies, subcase fatigue cracks ori...

Subcase-origin fatigue. (a) As the name implies, subcase fatigue cracks ori...

in Wear Failures—Fatigue[1] > Understanding How Components Fail
Published: 30 November 2013
of the surface, leaving a longitudinally ridged and gouged appearance. The ridges are the locations where two adjacent fatigue cracks joined and sent a crack through the case to the surface. This and the gear in (b) were made of low-carbon alloy steel, case carburized to a surface hardness near 60 HRC. (d) Cross More
Book Chapter

Water-Side Corrosion Failures

Series: ASM Technical Books
Publisher: ASM International
Published: 01 December 2018
DOI: 10.31399/asm.tb.fibtca.t52430204
EISBN: 978-1-62708-253-2
... corrosion, caustic gouging, and pitting External corrosion or fire-side corrosion: For example, waterwall fireside corrosion, superheater/reheater fireside corrosion, and acid dew point corrosion The process of oxidation of iron is known as rusting or corrosion . The interaction of steam...
Abstract
This chapter discusses the effects of corrosion on boiler tube surfaces exposed to water and steam. It describes the process of corrosion, the formation of scale, and the oxides of iron from which it forms. It addresses the primary types of corrosion found in boiler environments, including general corrosion, under-deposit corrosion, microbially induced corrosion, flow-accelerated corrosion, stress-assisted corrosion, erosion-corrosion, cavitation, oxygen pitting, stress-corrosion cracking, and caustic embrittlement. The discussion is supported by several illustrations and relevant case studies.
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