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STP962 Hydrogen Embrittlement: Prevention and Control Raymond Louis Pages: 421 Published: 1988 PDF (7.4M): $59 Print: $59 Print + PDF: $88.50 Save 25%!

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Table of Contents

Introduction
Raymond L.

Opening Remarks
Sonnino C.

Overview: Sections 1 and 2
Anctil A.

Opening Remarks
Fricioni R.

Summary: Section 3
Fricioni R.

Overview: Section 4
McIntyre D.

Overview: Section 5
Blackburn J.

Overview: Section 6
Field W.

Hydrogen Embrittlement Test Methods: Current Status and Projections
Raymond L.

Electrochemical Aspects of Hydrogen in Metals
DeLuccia J.

Hydrogen Embrittlement Coverage by U.S. Government Standardization Documents
Clegg E.

Other ASTM Committees and ISO Committees Involved in Hydrogen Embrittlement Test Methods
Grobin A.

Specifications for Hydrogen Control Testing of Materials
Coates D.

Accelerated Acceptance Testing for Hydrogen Embrittlement Control
Dreher R.

Assessment of the Degree of Hydrogen Embrittlement Produced in High-Strength 4340 Steel by Plating-and-Baking Processes Using Slow Strain Rate Testing
Pollock W.

Electrochemical Sensor for the Determination of Hydrogen in Metals by Potential Measurements
Mackor A., Schoonman J., Wim de Kreuk C.

The Barnacle Electrode Method to Determine Diffusible Hydrogen in Steels
Agarwala V., Berman D.

The Development of an In-Situ Sensor for Measuring the Hydrogen Content of Liquid Iron
Kawase H., Ohtsubo T., Yamazaki S.

A Study of the Effect of Voids on Hydrogen Diffusion Through Electroslag Refined Steel
Shewmon P., Wang M.

Sensitivity of Steels to Degradation in Gaseous Hydrogen
Cialone H., Holbrook J.

The Present Status of the Disk Pressure Test for Hydrogen Embrittlement
Fidelle J.

Screening Tests for Hydrogen Stress Cracking Susceptibility
Crumly W.

Ranking Materials for Extreme Sour Gas Service Using the Slow Strain Rate Method
Mclntyre D.

A Bent Beam Test Method for Hydrogen Sulfide Stress Corrosion Cracking Resistance
Cox D.

Selection of Petroleum Industry Materials Through Use of Environmental Cracking Tests
Ciaraldi S.

In Situ Measurement of Hydrogen in Weld Heat Affected Zones Thru Mass Spectrometry and Computer Analysis
Dubois D., Faure F., Leblond J., Lemoine V., Pressouyre G., Saillard P.

Testing of Welding Electrodes for Diffusible Hydrogen and Coating Moisture
Siewert T.

Diffusible Hydrogen Testing by Gas Chromatography
Dannecker J., Quintana M.

The Effect of Weld Metal Diffusible Hydrogen on the Cracking Susceptibility of HY-80 Steel
Wong R.

In-Process Prediction of the Diffusible Hydrogen Content of Gas Metal Arc Welds
Chionis W., White D.

Prevention of Hydrogen Embrittlement by Surface Films
Murray G.

Hydrogen Embrittlement and Relief Treatment Study of Zinc Phosphate-Coated Submunitions
Voorhis G.

Examination of Cadmium-Plated Aircraft Fasteners for Hydrogen Embrittlement
Bruggeman G., Levy M.

Proof Test Logic for Hydrogen Embrittlement Control
Krams W.

Quantitative Analysis of Critical Concentrations for Hydrogen-Induced Cracking
Faure F., Pressouyre G.

Assessment of the Degree of Hydrogen Embrittlement Produced in Plated High-Strength 4340 Steel by Paint Strippers Using Slow Strain Rate Testing
Grey C., Pollock W.

The Hydrogen Embrittlement Susceptibility of Ferrous Alloys: The Influence of Strain on Hydrogen Entry and Transport
Moran P., Scully J.

Hydrogen Transport, Microstructure, and Hydrogen-Induced Cracking in Austenitic Stainless Steels
Altstetter C., Perng T.

Temperature Dependence of Fatigue Crack Propagation in Niobium-Hydrogen Alloys
Polvanich N., Salama K.

Author Index


Subject Index


Committee: F07
Paper ID: STP962-EB
DOI: 10.1520/STP962-EB
ISBN-EB: 978-0-8031-6239-6

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STP962-EB