Surface treatment for mitigation of hydrogen absorption into alloys /

Polarization experiments show that deposited zinc effectively

Bibliographic Details
Main Author: Zheng, Guanghong, 1960-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1994.
Subjects:
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Description
Summary:Polarization experiments show that deposited zinc effectively
inhibits the discharge of hydrogen up to 46% on AISI 4340
steel, 58% on HY 130 steel, 68% on Inconel 718 alloy, and 60%
on Monel K500 alloy compared with the currents obtained on
each corresponding bare alloy. In the presence of a
monolayer coverage of zinc on the substrates, the hydrogen
permeation rate through AISI 4340 steel, HY 130, and Inconel
718 alloy membranes are reduced by 51, 90, 40%, respectively.
In the presence of lead, the hydrogen discharge reactions are
reduced by 44 and 67% on AISI 4340 steel and Inconel 718
alloy, respectively, and hydrogen permeation through AISI
4340 steel and Inconel 718 membrane are inhibited by 71 and
70%, respectively. The direct hydrogen entry mechanism was
shown experimentally and theoretically to be correct for HY
130 steel and Pd for small values of cathodic current density
i,. This mechanism also explains why steady state hydrogen
atom permeation current density is independent of the
membrane thickness and diffusivity and directly proportional
to the cathodic current density. It was found that the
direct entry mechanism is applicable only when the rate of
hydrogen diffusion through a metal membrane is comparable to
the hydrogen absorption rate. This could occur when the
hydrogen atom diffusion rate is fast compared to the
absorption rate. As a consequence, the absorbed hydrogen
immediately diffuses from the anodic side of the metal that
has high diffusivity or low thickness and explains why the
permeation current density for palladium, iron and iron
alloys, is independent of thickness. In order to interpret
the permeation experimental data, the lyer-Pickering-
Zamanzadeh hydrogen permeation model and the direct entry
mechanism were modified by including a mass transfer term in
the hydrogen discharge equation.
Item Description:Vita.
"Major Subject: Chemical Engineering".
Physical Description:xviii, 158 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references.