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General arrangement for upset welding of bars, rods, and <span class="search-highlight">pipes</span>. Source: Re...

General arrangement for upset welding of bars, rods, and pipes. Source: Re...

in Resistance Welding > Joining: Understanding the Basics
Published: 01 November 2011
Fig. 3.12 General arrangement for upset welding of bars, rods, and pipes. Source: Ref 3.5 , p 598 More
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<span class="search-highlight">Pipes</span>, joints, reducers, elbows, and T-shaped parts used in the oil and che...

Pipes, joints, reducers, elbows, and T-shaped parts used in the oil and che...

in Automated Filament Winding Systems > Composite Filament Winding
Published: 01 September 2011
Fig. 2.25 Pipes, joints, reducers, elbows, and T-shaped parts used in the oil and chemical industry More
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Use of short- and ultrashort-radius composite drill <span class="search-highlight">pipes</span> in drilling horiz...

Use of short- and ultrashort-radius composite drill pipes in drilling horiz...

in Filament Winding Technology Learned > Composite Filament Winding
Published: 01 September 2011
Fig. 7.25 Use of short- and ultrashort-radius composite drill pipes in drilling horizontally into an oil-and/or gas-bearing strata. A, horizontal well; B, vertical well. Source: Energy Information Administration, Office of Oil and Gas More
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The short- and ultrashort-radius composite drill <span class="search-highlight">pipes</span> exhibit little to no...

The short- and ultrashort-radius composite drill pipes exhibit little to no...

in Filament Winding Technology Learned > Composite Filament Winding
Published: 01 September 2011
Fig. 7.26 The short- and ultrashort-radius composite drill pipes exhibit little to no signs of wear after 160,000 cycles. More
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Coil efficiency for induction heating of <span class="search-highlight">pipes</span> as a function of wall thickn...

Coil efficiency for induction heating of pipes as a function of wall thickn...

in Process Design for Specific Applications > Elements of Induction Heating: Design, Control, and Applications
Published: 01 June 1988
Fig. 6.3(a) Coil efficiency for induction heating of pipes as a function of wall thickness and outer diameter using power-supply frequencies of (a) 60. From Brochure SA9906, Westinghouse Electric Corp., Baltimore More
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Coil efficiency for induction heating of <span class="search-highlight">pipes</span> as a function of wall thickn...

Coil efficiency for induction heating of pipes as a function of wall thickn...

in Process Design for Specific Applications > Elements of Induction Heating: Design, Control, and Applications
Published: 01 June 1988
Fig. 6.3(b) Coil efficiency for induction heating of pipes as a function of wall thickness and outer diameter using power-supply frequencies of (b) 180. From Brochure SA9906, Westinghouse Electric Corp., Baltimore More
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Coil efficiency for induction heating of <span class="search-highlight">pipes</span> as a function of wall thickn...

Coil efficiency for induction heating of pipes as a function of wall thickn...

in Process Design for Specific Applications > Elements of Induction Heating: Design, Control, and Applications
Published: 01 June 1988
Fig. 6.3(c) Coil efficiency for induction heating of pipes as a function of wall thickness and outer diameter using power-supply frequencies of (c) 960 Hz. From Brochure SA9906, Westinghouse Electric Corp., Baltimore More
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Localized corrosion of stainless steel <span class="search-highlight">pipes</span> from direct exposure to marine...

Localized corrosion of stainless steel pipes from direct exposure to marine...

in Materials Selection for Corrosion Control[1] > Corrosion in the Petrochemical Industry
Published: 01 December 2015
Fig. 1 Localized corrosion of stainless steel pipes from direct exposure to marine mists, compounded by plastic wraps More
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Time-to-failure of high-density polyethylene <span class="search-highlight">pipes</span> at different stresses an...

Time-to-failure of high-density polyethylene pipes at different stresses an...

in Fracture and Fractography > Characterization and Failure Analysis of Plastics
Published: 01 December 2003
Fig. 10 Time-to-failure of high-density polyethylene pipes at different stresses and temperatures. Source: Ref 11 More
Book Chapter

Structural Steels and Steels for Pressure Vessels, Piping, and Boilers

Series: ASM Technical Books
Publisher: ASM International
Published: 01 August 2018
DOI: 10.31399/asm.tb.msisep.t59220475
EISBN: 978-1-62708-259-4
... Abstract This chapter discusses the properties and compositions of steels used in pressure vessels, piping, boilers, rebar, and other structural applications. It covers fine-grained steels, quenched and tempered steels, and controlled rolled (thermomechanical treatment) steels. It also compares...
Abstract
This chapter discusses the properties and compositions of steels used in pressure vessels, piping, boilers, rebar, and other structural applications. It covers fine-grained steels, quenched and tempered steels, and controlled rolled (thermomechanical treatment) steels. It also compares and contrasts steels used for concrete reinforcement and in various types of pressure vessels, and presents a metallographic study of the effects of welding on the micro and macrostructure of steel.
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Macrographs showing examples of residual <span class="search-highlight">pipe</span> and&#x2F;or secondary <span class="search-highlight">pipe</span> in hot ...

Macrographs showing examples of residual pipe and/or secondary pipe in hot ...

in Solidification, Segregation, and Nonmetallic Inclusions > Metallography of Steels: Interpretation of Structure and the Effects of Processing
Published: 01 August 2018
Fig. 8.45 Macrographs showing examples of residual pipe and/or secondary pipe in hot formed bars produced from conventional ingots. No etching. More
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Overview of <span class="search-highlight">pipe</span> section. Cracking is visible on right end of the <span class="search-highlight">pipe</span> at t...

Overview of pipe section. Cracking is visible on right end of the pipe at t...

in Failure Analysis of Steel Welds > Failure Analysis of Heat Treated Steel Components
Published: 01 September 2008
Fig. 3 Overview of pipe section. Cracking is visible on right end of the pipe at the toe of the weld. Courtesy of MEICharlton, Inc. More
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Stainless steel <span class="search-highlight">piping</span> such as small-bore <span class="search-highlight">piping</span> is designed to leak before...

Stainless steel piping such as small-bore piping is designed to leak before...

in Introduction to Fatigue and Fracture > Fatigue and Fracture: Understanding the Basics
Published: 01 November 2012
Fig. 8 Stainless steel piping such as small-bore piping is designed to leak before break. A fatigue crack either initiates at the toe or the root of the weld. (a) Typical socket fitting with a fillet weld. (b) Micrograph of a cross section through a socket-welded joint showing fatigue crack More
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Comparison of last-pass heat sink welding <span class="search-highlight">pipe</span> tests with reference <span class="search-highlight">pipe</span> te...

Comparison of last-pass heat sink welding pipe tests with reference pipe te...

in Weld Corrosion in Specific Industries and Environments > Corrosion of Weldments
Published: 01 December 2006
Fig. 16 Comparison of last-pass heat sink welding pipe tests with reference pipe tests More
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Effect of a crack on the pattern of eddy-current flow in a <span class="search-highlight">pipe</span>

Effect of a crack on the pattern of eddy-current flow in a pipe

in Testing and Inspection of Metals—The Quest for Quality > Metallurgy for the Non-Metallurgist
Published: 01 October 2011
Fig. 7.28 Effect of a crack on the pattern of eddy-current flow in a pipe More
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Erosion pitting caused by turbulent river water flowing through copper <span class="search-highlight">pipe</span>...

Erosion pitting caused by turbulent river water flowing through copper pipe...

in The Durability of Metals and Alloys > Metallurgy for the Non-Metallurgist
Published: 01 October 2011
Fig. 16.4 Erosion pitting caused by turbulent river water flowing through copper pipe. The typical horseshoe-shaped pits point upstream. Original magnification: 0.5×. Source: Ref 16.2 More
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<span class="search-highlight">Pipe</span> or shrinkage cavity in the top of an ingot. Longitudinal section.

Pipe or shrinkage cavity in the top of an ingot. Longitudinal section.

in Solidification, Segregation, and Nonmetallic Inclusions > Metallography of Steels: Interpretation of Structure and the Effects of Processing
Published: 01 August 2018
Fig. 8.5 Pipe or shrinkage cavity in the top of an ingot. Longitudinal section. More
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<span class="search-highlight">Pipe</span> in a small ingot. Etched. A hot crack starting at the bottom of the pi...

Pipe in a small ingot. Etched. A hot crack starting at the bottom of the pi...

in Solidification, Segregation, and Nonmetallic Inclusions > Metallography of Steels: Interpretation of Structure and the Effects of Processing
Published: 01 August 2018
Fig. 8.6 Pipe in a small ingot. Etched. A hot crack starting at the bottom of the pipe and propagating between two grains can be seen. Copyright © Wiley-VCH Verlag GmbH &amp; Co. KGaA. Reprinted with permission. Source: Ref 1 More
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(a) Cross section of rolled structural profiles with “residual <span class="search-highlight">pipe</span>” (the b...

(a) Cross section of rolled structural profiles with “residual pipe” (the b...

in Hot Working > Metallography of Steels: Interpretation of Structure and the Effects of Processing
Published: 01 August 2018
Fig. 11.17 (a) Cross section of rolled structural profiles with “residual pipe” (the bottom of the pipe—solidification contraction—in the conventional ingot was not completely eliminated from the rolled product). No etching. (b) Cross section of a structural profile rolled from iron obtained More
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Dual-phase API X100 steel for <span class="search-highlight">piping</span> produced through controlled rolling. C...

Dual-phase API X100 steel for piping produced through controlled rolling. C...

in Structural Steels and Steels for Pressure Vessels, Piping, and Boilers > Metallography of Steels: Interpretation of Structure and the Effects of Processing
Published: 01 August 2018
Fig. 14.11 Dual-phase API X100 steel for piping produced through controlled rolling. C = 0.06%, Mn = 1.96%, Nb = 0.04%, Ti = 0.01%, + Ni, Cu, Mo. Granular ferrite and bainite (martensite and retained austenite are also present). Courtesy of Nippon Steel Corporation. Source: Ref 11 More