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- Title
High Speed Impact Testing of UHMWPE Composite Using Orthogonal Arrays.
- Authors
Hannah, T.; Martin, V.; Ellis, S.; Kraft, R. H.
- Abstract
Background: Ultra high molecular weight polyethylene composites are fiber based composites used in armor applications. While some characterization has been conducted experimentally, this study varies multiple parameters simultaneously to investigate material response under a wide range of conditions. Objective: This work focuses on characterizing the response of Dyneema® HB26 hard laminate composites under high-speed impacts to examine the influence of plate diameter, clamping pressure, and plate spacing on target performance. Additionally, micro Computer Tomography scans are used to nondestructively evaluate the damage evolution in the targets. Methods: These scan results are used in concert with more traditional armor performance metrics to evaluate the effect of various parameters using the method of orthogonal array analysis. This technique allows for multiple variables to be investigated in the same test series, saving time and budget while still providing quality results across a range of variables and variable values. Results: We conclude that of the parameters investigated, the plate spacing parameter has the largest effect on performance, followed by the plate diameter. Bolt torque was found to not have a significant impact on results, indicating that an edge clamping pressure is not critical to material response. Additionally, by examining the high resolution scans, we can quantify the damage with an effective damage angle and that this angle is a good predictor of performance. Conclusion: Finally a damage theory involving the effective bending strength of the plates is discussed as an explanation for all of the results observed in this test series.
- Subjects
IMPACT testing; ORTHOGONAL arrays; PERSONAL computers; BOLTED joints; FIBROUS composites; BENDING strength; LAMINATED materials; DIAMETER
- Publication
Experimental Mechanics, 2024, Vol 64, Issue 6, p823
- ISSN
0014-4851
- Publication type
Article
- DOI
10.1007/s11340-024-01064-y