Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory
The detonation reaction zone of nitromethane (NM) has been extensively studied both experimentally and theoretically. The measured particle velocity profile of NM shows the existence of a sharp spike followed by a rapid drop over the first 5-10 ns (fast reaction). The sharp spike is followed by a gr...
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sg-ntu-dr.10356-1483572021-05-15T20:11:00Z Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory Štimac, Barbara Chan, Serene Hay Yee Kunzel, Martin Muhamed Suceska Energetics Research Institute Science::Physics Nitromethane Reaction Zone The detonation reaction zone of nitromethane (NM) has been extensively studied both experimentally and theoretically. The measured particle velocity profile of NM shows the existence of a sharp spike followed by a rapid drop over the first 5-10 ns (fast reaction). The sharp spike is followed by a gradual decrease (slow reactions) which terminate after approximately 50-60 ns when the CJ condition is attained. Based on experimental data, the total reaction zone length is estimated to be around 300 μm. Some experimental observations, such as the reaction zone width and the diameter effect, can be satisfactorily reproduced by numerical modelling, provided an appropriate reaction rate model is known. Here we describe the model for numerical modelling of the steady state detonation of NM. The model is based on the coupling thermochemical code EXPLO5 with the Wood-Kirkwood detonation theory, supplemented with different reaction rate models. The constants in the rate models are calibrated based on experimentally measured particle velocity profiles and the detonation reaction zone width. It was found that the model can describe the experimentally measured total reaction time (width of reaction zone) and the particle velocitytime profile of NM. It was found also that the reaction rate model plays a key role on the shape of the shock wave front. In addition, the model can predict the detonation parameters (D, pCJ, TCJ, VCJ, etc.) and the effect of charge diameter on the detonation parameters. Published version 2021-05-10T03:55:22Z 2021-05-10T03:55:22Z 2020 Journal Article Štimac, B., Chan, S. H. Y., Kunzel, M. & Muhamed Suceska (2020). Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory. Central European Journal of Energetic Materials, 17(2), 239-261. https://dx.doi.org/10.22211/cejem/124193 1733-7178 https://hdl.handle.net/10356/148357 10.22211/cejem/124193 2-s2.0-85087726400 2 17 239 261 en Central European Journal of Energetic Materials © 2020 Institute of Industrial Organic Chemistry. All rights reserved. This paper was published in Central European Journal of Energetic Materials and is made available with permission of Institute of Industrial Organic Chemistry. application/pdf |
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Science::Physics Nitromethane Reaction Zone Štimac, Barbara Chan, Serene Hay Yee Kunzel, Martin Muhamed Suceska Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory |
| description |
The detonation reaction zone of nitromethane (NM) has been extensively studied both experimentally and theoretically. The measured particle velocity profile of NM shows the existence of a sharp spike followed by a rapid drop over the first 5-10 ns (fast reaction). The sharp spike is followed by a gradual decrease (slow reactions) which terminate after approximately 50-60 ns when the CJ condition is attained. Based on experimental data, the total reaction zone length is estimated to be around 300 μm. Some experimental observations, such as the reaction zone width and the diameter effect, can be satisfactorily reproduced by numerical modelling, provided an appropriate reaction rate model is known. Here we describe the model for numerical modelling of the steady state detonation of NM. The model is based on the coupling thermochemical code EXPLO5 with the Wood-Kirkwood detonation theory, supplemented with different reaction rate models. The constants in the rate models are calibrated based on experimentally measured particle velocity profiles and the detonation reaction zone width. It was found that the model can describe the experimentally measured total reaction time (width of reaction zone) and the particle velocitytime profile of NM. It was found also that the reaction rate model plays a key role on the shape of the shock wave front. In addition, the model can predict the detonation parameters (D, pCJ, TCJ, VCJ, etc.) and the effect of charge diameter on the detonation parameters. |
| author2 |
Energetics Research Institute |
| author_facet |
Energetics Research Institute Štimac, Barbara Chan, Serene Hay Yee Kunzel, Martin Muhamed Suceska |
| format |
Article |
| author |
Štimac, Barbara Chan, Serene Hay Yee Kunzel, Martin Muhamed Suceska |
| author_sort |
Štimac, Barbara |
| title |
Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory |
| title_short |
Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory |
| title_full |
Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory |
| title_fullStr |
Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory |
| title_full_unstemmed |
Numerical modelling of detonation reaction zone of nitromethane by EXPLO5 code and wood and kirkwood theory |
| title_sort |
numerical modelling of detonation reaction zone of nitromethane by explo5 code and wood and kirkwood theory |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/148357 |
| _version_ |
1701270615416111104 |