Dynamic strength and ductility of ultra-high performance concrete with flow-induced fiber alignment

Authors

Andrew B. Groeneveld, Michigan Technological University
Theresa M. Ahlborn, Michigan Technological University
C. Kennan Crane, The United States Army Corps of Engineers
Charles A. Burchfield, The United States Army Corps of Engineers
Eric N. Landis, University of Maine

Document Type

Article

Publication Date

1-1-2018

Abstract

© 2018 The effect of fiber alignment on dynamic strength and ductility of an ultra-high performance concrete has been investigated. A beam was cast to produce a realistic level of flow-induced fiber alignment. Cores were drilled from the beam, and fiber orientation was non-destructively characterized using x-ray computed tomography. Fiber orientations in three orthogonal directions were significantly different at a 95% confidence level, with fibers preferentially aligned in the direction of flow during placement. Cored specimens were then tested in high-strain rate compression using a split-Hopkinson pressure bar. Dynamic compressive strength was independent of fiber orientation for the specimens tested. Ductility, measured by the strain at peak stress, increased with the proportion of fibers oriented perpendicular to the applied load.

Publication Title

International Journal of Impact Engineering

Recommended Citation

Groeneveld, A., Ahlborn, T., Crane, C., Burchfield, C., & Landis, E. (2018). Dynamic strength and ductility of ultra-high performance concrete with flow-induced fiber alignment. International Journal of Impact Engineering, 111, 37-45. http://doi.org/10.1016/j.ijimpeng.2017.08.009
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p/6553