Title:
Tensile and Bond Properties of GFRP Reinforcing Bars
Author(s):
L. Javier Malvar
Publication:
Materials Journal
Volume:
92
Issue:
3
Appears on pages(s):
276-285
Keywords:
bond (concrete to reinforcement); concretes; fibers; plastics, polymers, and resins; Materials Research
DOI:
10.14359/1120
Date:
5/1/1995
Abstract:
The bond characteristics of four different types of glass fiber reinforced plastic (GFRP) reinforcing bars with different surface deformations were analyzed experimentally. Local bond stress-slip data, as well as bond stress-radial deformation data, needed for constitutive modeling of the interface mechanics, were obtained for varying levels of confining pressure. In addition to bond stress and slip, radial stress and radial deformation were considered fundamental variables needed to provide for configuration- independent relationships. Each test specimen consisted of a No. 6 GFRP reinforcing bar embedded in a 3-in.- (76-mm)-diameter, 4-in.- (102-mm)-long cracked concrete cylinder subjected to a controlled, constant amount of confining axisymmetric radial pressure. Only 2.625 in. (67 mm, i.e., the equivalent of five steel bar lugs) of contact were allowed between the bar and the concrete. For each reinforcing bar-type bond stress-slip and bond stress- radial deformation, relationships were obtained for five levels of confining axisymmetric radial pressure. It was found that small surface indentations were sufficient to yield bond strengths comparable to that of steel bars. Effects of the deformations on tensile properties were addressed. It was also shown that radial pressure is an important parameter that can increase the bond strength threefold.