Mechanistic Modeling of Fracture in Asphalt Mixtures under Compressive Loading
Publication: Journal of Materials in Civil Engineering
Volume 25, Issue 9
Abstract
When an asphalt mixture is subjected to a destructive compressive load, it experiences a sequence of three deformation stages, as follows: the (1) primary, (2) secondary, and (3) tertiary stages. Most literature research focuses on plastic deformation in the primary and secondary stages, such as prediction of the flow number, which is in fact the initiation of the tertiary stage. However, little research effort has been reported on the mechanistic modeling of the damage that occurs in the tertiary stage. The main objective of this paper is to provide a mechanistic characterizing method for the damage modeling of asphalt mixtures in the tertiary stage. The preliminary study conducted by the writers illustrates that deformation during the tertiary flow of the asphalt mixtures is principally caused by the formation and propagation of cracks, which was signaled by the increase of the phase angle in the tertiary phase. The strain caused by the growth of cracks is the viscofracture strain, which can be obtained by conducting the strain decomposition of the measured total strain in the destructive compressive test. The viscofracture strain is employed in the research reported in this paper to mechanistically characterize the time-dependent fracture (viscofracture) of asphalt mixtures in compression. By using the dissipated pseudostrain energy-balance principle, the damage density and true stress are determined and both are demonstrated to increase with load cycles in the tertiary stage. The increased true stress yields extra viscoplastic strain, which is the reason why the permanent deformation is accelerated by the occurrence of cracks. To characterize the evolution of the viscofracture in the asphalt mixtures in compression, a pseudo J-integral Paris’ law in terms of damage density is proposed and the material constants in the Paris’ law are determined, which can be employed to predict the fracture of asphalt mixtures in compression.
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Acknowledgments
The writers acknowledge the financial support of the Federal Highway Administration to the Asphalt Research Consortium (ARC).
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Information & Authors
Information
Published In
Journal of Materials in Civil Engineering
Volume 25 • Issue 9 • September 2013
Pages: 1189 - 1197
Copyright
© 2013 American Society of Civil Engineers.
History
Received: Mar 8, 2012
Accepted: Aug 23, 2012
Published online: Aug 30, 2012
Discussion open until: Jan 30, 2013
Published in print: Sep 1, 2013
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