Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/springer-journals/dynamic-and-static-failure-behavior-of-notched-cfrp-laminate-0HcRrCA0Sd
References (15)
-
J. Koyanagi, Y. Adachi, S. Arikawa, S. Yoneyama (2012)
Time-Dependent Internal Damage Progress and Residual Strength in Notched Composite LaminatesJournal of Solid Mechanics and Materials Engineering, 6
-
J. Koyanagi, S. Yoneyama, Katsuyama Eri, P. Shah (2010)
Time dependency of carbon/epoxy interface strengthComposite Structures, 92
-
J. Koyanagi (2012)
Durability of filament-wound composite flywheel rotorsMechanics of Time-Dependent Materials, 16
-
J. Koyanagi, M. Nakada, Y. Miyano (2012)
Tensile strength at elevated temperature and its applicability as an accelerated testing methodology for unidirectional compositesMechanics of Time-Dependent Materials, 16
-
F. Pierron, M.A. Sutton, V. Tiwari (2011)
Ultra high speed DIC and virtual fields method analysis of a three point bending impact test on an aluminum barExp. Mech., 51
-
Yuki Otsuka, M. Sakaguchi, Y. Kurokawa, H. Inoue (2018)
Strain field measurement around the crack tip in Ni-base superalloy using Digital Image Correlation, 84
-
F. Lagattu, J. Brillaud, M. Lafarie-Frenot (2004)
High strain gradient measurements by using digital image correlation techniqueMaterials Characterization, 53
-
J. Koyanagi (2009)
Comparison of a viscoelastic frictional interface theory with a kinetic crack growth theory in unidirectional compositesComposites Science and Technology, 69
-
F. Pierron, B. Green, M. Wisnom, S. Hallett (2007)
Full-field assessment of the damage process of laminated composite open-hole tensile specimens. Part II: experimental resultsComposites Part A-applied Science and Manufacturing, 38
-
H. Aljibori, W. Chong, T. Mahlia, W. Chong, P. Edi, H. Al-Qrimli, Irfan Anjum, R. Zahari (2010)
Load–displacement behavior of glass fiber/epoxy composite plates with circular cut-outs subjected to compressive loadMaterials & Design, 31
-
Raphaël Moulart, F. Pierron, S. Hallett, M. Wisnom (2011)
Full-Field Strain Measurement and Identification of Composites Moduli at High Strain Rate with the Virtual Fields MethodExperimental Mechanics, 51
-
N. Taniguchi, T. Nishiwaki, H. Kawada (2007)
Tensile strength of unidirectional CFRP laminate under high strain rateAdvanced Composite Materials, 16
-
(2007)
Ultra high speed DIC and virtual fields method analysis of a three point -
N. Taniguchi, T. Nishiwaki, H. Kawada (2005)
Evaluating the mechanical properties of a CFRP tube under a lateral impact load using the split Hopkinson barAdvanced Composite Materials, 14
-
Z. Wang, Hongqi Li, J. Tong, M. Shen, F. Aymerich, P. Priolo (2008)
Dual magnification digital image correlation based strain measurement in CFRP Laminates with open holeComposites Science and Technology, 68
- Publisher
- Springer Journals
- Copyright
- Copyright © 2014 by Springer Science+Business Media Dordrecht
- Subject
- Engineering; Continuum Mechanics and Mechanics of Materials; Mechanics; Characterization and Evaluation of Materials; Polymer Sciences
- ISSN
- 1385-2000
- eISSN
- 1573-2738
- DOI
- 10.1007/s11043-013-9224-2
- Publisher site
- See Article on Publisher Site
Abstract
Static and dynamic fracture behavior of notched CFRP laminates are investigated experimentally. The dynamic tensile loading apparatus is developed based on a split Hopkinson bar. Impact tensile tests for notched (open-hole) CFRP specimens are performed. The full-field strain around the hole in the specimen is evaluated employing digital image correlation method using photographs obtained using a high-speed camera at a frame rate of 1,000,000 frames/s. Far-field strain at the failure is obtained from the specimen-mounted strain gauge. Increased strain around the hole is observed over time. A static tensile test for the notched CFRP specimen is then conducted as well. The strain distribution and far-field strain at failure are obtained similarly. The results show that the far-field strain at failure varies with the strain rate. The strain distributions obtained from two tests are compared and a mechanism causing the difference is discussed. The results show that high strain is distributed along the transverse direction to the loading direction from the hole for the impact (high-strain-rate) tests, although high strain exists on the side hole in loading direction for the static tests. The difference is possibly attributable to the difference of internal damage, which depends on the strain rate.
Journal
Mechanics of Time-Dependent Materials – Springer Journals
Published: Nov 1, 2014