The strong correlation between the density and the physical and mechanical properties of graphite suggests that the method of nondestructive density evaluation could be developed into a characterization technique of great value for the overall improvement of the safety of graphite moderator reactors. In this study, the oxidation-induced density changes in nuclear graphite for very high temperature reactor were determined by a conventional destructive bulk density measurement method (BM) and by a new nondestructive method based on acoustic microscopy and image processing (AM). The results were compared in order to validate the applicability of the latter method. For a direct comparison of the results from both measurements, two specimens were prepared from a cylindrical graphite sample (1 in. diameter and 1 in. height, oxidized to 10% weight loss at 973 K in air for 5 h). The specimens were used for characterization by BM and AM methods, respectively. The results show that, even with a large standard deviation of the AM, the density changing trend from both methods appeared the same. The present observation may be attributed to the fact that AM images reflect characteristic density changes of the graphite sample through the acoustic impedance changes. This study demonstrates the possibility of using AM as a nondestructive technique for the evaluation of density changes in graphite when a database is prepared through a systematic series of experiments.

2.
Contescu
,
C. I.
,
Baker
,
F. S.
, and
Burchell
,
T. D.
, 2006, “
Development of an ASTM Graphite Oxidation Test Method
,”
Extended Abstracts of CARBON ’06 International Carbon Conference
, Aberdeen, Scotland, p.
193
.
3.
Shibata
,
T.
,
Hanawa
,
S.
,
Sumita
,
J.
,
Tada
,
T.
,
Sawa
,
K.
, and
Iyoku
,
T.
, 2005, “
Non-Destructive Evaluation on Mechanical Properties of Nuclear Graphite With Porous Structure
,”
Proceedings of GLOBAL 2005
, Tsukuba, Japan, Oct. 9–13, Paper No. 360.
4.
Babout
,
L.
,
Mummery
,
P. M.
,
Marrow
,
T. J.
,
Tzelpi
,
A.
, and
Withers
,
P. J.
, 2005, “
The Effect of Thermal Oxidation on Polycrystalline Graphite Studied by X-Ray Tomography
,”
Carbon
,
43
, pp.
765
774
. 0008-6223
5.
El Guerjouma
,
R.
,
Mouchtachi
,
A.
,
Jayet
,
Y.
, and
Baboux
,
J. C.
, 1992, “
Non Destructive Evaluation of Graphite by Ultrasonic Velocity Measurement Using Cross-Correlation and Hilbert Transform Methods
,”
IEEE Proceedings of the 1992 Ultrasonics Symposium
, pp.
829
832
.
6.
Briggs
,
A.
, 1985,
An Introduction to Scanning Acoustic Microscopy
,
Oxford University Press
,
Oxford, UK
.
7.
ASTM
, 2000, “
Standard Test Method for Bulk Density by Physical Measurements of Manufactured Carbon and Graphite Articles
,”
Annual Book of ASTM Standards
, DO2.FO, Paper No. ASTM C 559-90.
8.
Qu
,
J.
, and
Blau
,
P. J.
, 2006, “
Scanning Acoustic Microscopy for Characterization of Coatings and Near-Surface Features of Ceramics
,”
The 30th International Conference & Exposition on Advanced Ceramics & Composites
, Cocoa Beach, FL.
9.
IMAGE-PRO PLUS, 2006, Version 5.0 for Windows, Media Cybernetics, Inc.
10.
Prasad
,
M.
, 2001, “
Mapping Impedance Microstructure in Rocks With Acoustic Microscopy
,”
The Leading Edge
,
20
, pp.
172
179
. 1070-485X
11.
Contescu
,
C. I.
,
Azad
,
S.
,
Miller
,
D.
,
Lance
,
M. J.
,
Baker
,
F. S.
, and
Burchell
,
T. D.
, 2008, unpublished.
12.
Contescu
,
C. I.
, 2008, private communication.
You do not currently have access to this content.