Analysis on Temperature Profiles upon High Speed Impact of Reactive Structural Materials |
Jung, Sang-Hyun
(The 4th Research and Development Institute, Agency for Defense Development)
Cho, Soo Gyeong (The 4th Research and Development Institute, Agency for Defense Development) Bae, Gwang Tae (The 4th Research and Development Institute, Agency for Defense Development) Lee, Kibong (The 4th Research and Development Institute, Agency for Defense Development) |
1 | S. G. Cho, D.-I. Cheong, E. M. Goh, and J. H. Chung, "Technical Review on Reactive Structural Materials," Defense Science & Technology Plus, Vol. 165, pp. 1-11, 2012. |
2 | R. M. Lioyd, "Conventional Warhead Systems. Physics and Engineering Design," American Institute of Aeronautics and Atronautics, Vambridge, USA, 1998, Chapter 6. |
3 | "Advanced Energetic Materials," National Research Council of the National Academies, National Academies Press, Washington D.C., USA, 2004, Chapter 4. |
4 | B. E. Homan, K. L. McNesby, J. Ritter, J. Colburn, and Andrew Brant, "Characterization of the Combustion Behavior of Aluminum-Nickel Based Reactive Materials," ARL-TR-5125, Army Research Laboratory, 2009. |
5 | R. V. Reeves, A. S. Mukasyan, and S. F. Son, "Thermal and Impact Reaction Initiation in Ni/Al Heterogeneous Reactive Systems," J. Phys. Chem. C, Vol. 114, pp. 14772-14780, 2010. |
6 | H. F. Wang, Y. F. Zheng, Q. B. Yu, Z. W. Liu, and W. M. Yu, "Impact-induced Initiation and Energy Release Behavior of Reactive Materials," J. Appl. Phys., Vol. 110, pp. 074904-1-074904-6, 2011. DOI |
7 | J. M. Densmore, M. M. Biss, B. E. Homan, and K. L. McNesby, "Thermal Imaging of Nickelaluminum and Aluminum-polytetrafluoroethylene Impact Initiated Combustion," J. Appl. Phys., Vol. 112, pp. 084911-1-084911-5, 2012. DOI |
8 | X. R. Zhang, A. S. Shi, L. Qiao, J. Zhang, Y. G. Zhang, and Z. W. Guan, "Experimental Study on Impact-initiated Characters of Multifunctional Energetic Structural Materials," J. Appl. Phys., Vol. 113, pp. 083508-1-083508-10, 2013. DOI |
9 | J. J. Ritter, A. L. Brant, J. W. Colburn, B. E. Homan and K. L. McNesby, "Characterization Techniques Employed to Determine the Energy Release of Reactive Materials," ARL-TR-5125, Army Research Laboratory, 2010. |
10 | E. L. Dreizin, "Metal-based Reactive Nanomaterials," Prog. Energy Combust. Sci., Vol. 35, pp. 141-157, 2009. DOI |
11 | L. Michalski, K. Eckersdorf and J. McGhee, "Temperature Measurement," John Wiley & Sons, Chichest, England, Chapter 7, 1991. |
12 | P. R. N. Childs, "Practical Temperature Measurement," Butterworth-Heinemann, Oxford, Great Britain, Chapter 9, 2001. |
13 | Vision Research, "v7.3 Spectral Response," http://www.visionresearch.com/uploads/Docs/SpectralResponse/V7.3SensorSpectralResponse.pdf. |
14 | S. Goroshin, D. F. Frost, J. Levine, A. Yoshinaka and F. Zhang, "Optical Pyrometry of Fireballs of Metallized Explosives," Propel. Explos. Pyrotech. Vol. 31, pp. 169-181, 2006. DOI |
15 | K. L. McNesby, B. E. Homan, R. A. Benjamin, V. M. Boyle, J. M. Densmore and M. M. Biss, "Invited Article: Quantitative Imaging of Explosions with High-speed Cameras," Rev. Sci. Instrum., Vol. 87, pp. 051301-1-051301-14, 2016. DOI |
16 | J. M. Densmore, B. E. Homan, M. M. Biss, and K. L. McNesby, "High-speed Two-camera Imaging Pyrometer for Mapping Fireball Temperatures," Appl. Opts., Vol. 50, pp. 6267-6271, 2011. DOI |
17 | D. R. Lide, "Handbook of Chemistry and Physics," 84th Ed., CRC Press, 2004. |
18 | K. L. Cashdollor and I. A. Zlochower, "Explosion Temperatures and Pressures of Metals and Other Element Dust Clouds," J. Loss Prev. Process Indust., Vol. 20, pp. 337-348, 2007. DOI |