Effectiveness of a Pullout Test Method Developed to Characterize Fundamental Fiber-Matrix Interfacial Mechanisms in Viscoelastic Asphalt Concrete

Effectiveness of a Pullout Test Method Developed to Characterize Fundamental Fiber-Matrix Interfacial Mechanisms in Viscoelastic Asphalt Concrete

AbstractCurrent production of fiber-reinforced asphalt concrete (FRAC) is associated with challenges related to performance inconsistencies, workability, and economic feasibility. Understanding fundamentals of fiber-matrix interaction in FRAC is key to identifying root causes of the observed inconsi...

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Bibliographic Details
Published in:Journal of materials in civil engineering Vol. 36; no. 7
Main Authors: Rahman, Md Nafiur, Serin, Sercan, Ozer, Hasan
Format: Journal Article
Language:English
Published: New York American Society of Civil Engineers 01-07-2024
Subjects:
Asphalt
Constitutive relationships
Embedment
Fiber pullout
Fiber reinforced concretes
Fiber reinforcement
Fiber-matrix interfaces
Interfacial properties
Loading rate
Mixtures
Pull out tests
Technical Papers
Temperature effects
Test methods
Test procedures
Viscoelasticity
Workability
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Summary:AbstractCurrent production of fiber-reinforced asphalt concrete (FRAC) is associated with challenges related to performance inconsistencies, workability, and economic feasibility. Understanding fundamentals of fiber-matrix interaction in FRAC is key to identifying root causes of the observed inconsistencies and enhancing the performance of FRAC mixtures. There is no model or experimental method to predict fiber behaviors in viscoelastic AC. A novel fiber pullout test procedure was designed and developed to characterize interfacial properties of fibers in a viscoelastic AC medium. The test method was used to develop a fundamental understanding of fiber pullout behavior where fiber diameter, embedment length, and mixture characteristics are considered as key test parameters. The test method allowed characterization of the effects of temperature and loading rate as well considering fiber reinforcement in viscoelastic AC application. The pullout tests were successfully completed for the key variables. The experiments were extended to mixture scale to apply some of these key fundamental principles learned from the pullout tests. Embedment length and fiber diameter emerged as the key variables of pullout behavior of fibers in the AC. The fiber-matrix interface was not found to be sensitive to temperature and loading rate as much as bulk viscoelastic AC is. The proposed testing method designed and developed in this paper will help in building fundamental constitutive relationships of fiber-matrix behavior in viscoelastic AC and design FRAC mixes using a mechanistic approach.
ISSN:0899-1561
1943-5533
DOI:10.1061/JMCEE7.MTENG-17681