The new method, called electromechanical pull-out testing, can be used throughout the construction industry and in any composite application where neither of the interface materials is completely electrically insulating.
"This technique takes the guesswork out of determining small, but
important, differences in bond strength," said Deborah D.L. Chung, Niagara
Mohawk Professor of Materials Science at UB, professor of mechanical and
aerospace engineering and principal investigator.
Chung described the method recently at the Third International Conference on Composites Engineering. Xuli Fu, a doctoral candidate in the UB Department of Mechanical and Aerospace Engineering, is co-investigator on the project.
When two materials are bonded together, the new composite will prove only as strong as the connection, or interface, that holds them together. When steel and concrete are connected, for example, the interface is the potential weak link in the system. "If the interface is bad, then the steel's strength cannot be utilized," Chung explained.
The new technique makes use of a direct correlation Chung discovered between the strength of the bond between materials and the electrical resistance associated with the interface.
The traditional method of measuring bond strength involves embedding a single fiber of a material, such as steel or carbon, in the matrix, such as cement, and measuring the amount of force it takes to pull it out. The bond is the connection between the fiber and the matrix.
With the new technique, after the fiber is embedded in the matrix, electrical contacts are applied to the fiber and to the matrix near the fiber. An electric current is passed through a contact on the fiber and a contact on the matrix. The electrical resistivity is calculated based on these voltmeter readings.
"We can then plot the contact resistivity versus bond strength," explained Chung. "The curve of the plotted points represents that correlation. A different formulation or surface treatment would cause the whole curve to shift. From that shift, one can tell clearly what the change in bond strength is."
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