Detonation Performance of Four Groups of Aluminized Explosives

Xiang, Dalin; Rong, Jili; He, Xuan

doi:10.22211/cejem/67238

Cited by 21 publications

(12 citation statements)

References 10 publications

(5 reference statements)

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“…[ 37 ] The sign of the n Al / n O coefficient is negative, indicating that the detonation heat decreases as aluminum atoms to oxygen atoms number ratio increases, indicative of insufficient oxygen to burn the aluminum particles completely, leading to incomplete burning aluminum and releasing less heat. This finding confirms the results of experimental assessments in reference [ 30 ] , where an increase in aluminum content would lead to maximum detonation heat, which if increased would decrease the detonation heat. Another point that can be deduced from the model observation is that the number of aluminum atoms in the three variables of Equation (1) are present i.e.…”

Section: Contribution Of Different Variables Of This Modelsupporting

confidence: 91%

“…To compare the results obtained here with that of different methods, deviations of measured values from calculated values also calculated as well. The predicted values of heat tabulated in Table 1 and Table 5, are compared to KHT code prediction [ 31 ] and the method presented by Keshavarz et al [ 35 ] As observed in Table 1 and Table 5, although the KHT code prediction in most cases is better than this newly improved correlations, Equation (1), the advantages here are its easiness and reliability in specific which cannot be ignored. Moreover, the KHT code is not an effective method to be applied in predicting the detonation of RDX/AP‐based aluminized explosive's heat, while these newly proposed models obtain acceptable results in these cases.…”

Section: The Model Validationmentioning

confidence: 99%

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The New Descriptors Effective on the Detonation Performance of Aluminized Explosives

Zohari

Roosta

Shariati

2020

Zeitschrift anorg allge chemie

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The relationship between detonation velocity and the elemental composition of components of aluminized explosives are assessed through quantitative structure‐property relationship (QSPR). Here, two new reliable, simple models are proposed for estimating aluminized explosives detonation heat and velocity based on molecular structure by applying QSPR. In this methodology it is assumed that these two detonation parameters can be presented as a function of elemental composition, density and several structural parameters. This new correlation of heat detonation has determination coefficient of 0.930, root mean square deviation (RMSD) of 324.4 and average absolute deviation (AAD) of 446kJ·kg–1 for 36 aluminized explosives with different molecular structures as the training set. The predictive power of this new correlation is checked through a cross validation method. Statistical parameters reveal relatively good result for this correlation. Also, the determination coefficient of detonation velocity for the other new model is 0.960 and it has 151.1 (RMSD) and 107.9 m·s–1 (AAD) for 42 aluminized explosives with different molecular structures as training set. Reliability and validity of new correlation investigated (Q2Ext = 0.948, Q2LOO = 0.938, and Q2LMO = 0.937). The good ability of this new model for prediction detonation velocity of aluminized explosives are confirmed.

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Section: Contribution Of Different Variables Of This Modelsupporting

confidence: 91%

Section: The Model Validationmentioning

confidence: 99%

The New Descriptors Effective on the Detonation Performance of Aluminized Explosives

Zohari

Roosta

Shariati

2020

Zeitschrift anorg allge chemie

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“…The Al powders used in production of the HMX-based Aluminized explosives [35] is in average size of 13 mm. There are 5 % (mass fraction) inert binders in the aluminized explosive, and its influence on Q can be neglected due to the small content.…”

Section: Hmx-based Aluminized Explosivesmentioning

confidence: 99%

“…The molecular formula of RDX is C 3 H 6 N 6 O 6 , and its enthalpy of formation is 61.446 kJ/mol. The average size of Al additives in RDX-based aluminized explosive [35] is 13 mm and the content of the inert binder is 5 %. The calculated detonation velocities of the new method are listed in Table 3.…”

Section: Rdx-based Aluminized Explosivesmentioning

confidence: 99%

A New Method for Predicting the Detonation Velocity of Explosives with Micrometer Aluminum Powders

Zhao

Qin

et al. 2018

Propellants Explo Pyrotec

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In the present study we carried out a thermodynamic analysis for explosives with micrometer aluminum (Al) powders, and found that the acceleration of Al powders and heat exchange between Al powders and the detonation products may have a significant influence on the detonation velocity. Relying on velocity disequilibrium between the two phases at the C−J plane and heat absorption of inert Al powders in the detonation zone, this paper has introduced a new method to study the detonation velocity of explosives with micrometer Al additives. The method is a closed system of algebraic equations and the detonation velocity can be solved efficiently by numerical codes. The detonation velocities predicted by the new method are in excellent agreement with experimental data of RDX‐, HMX‐, NM‐ and TNT‐based aluminized explosives, and the heat exchange has been proved significant on the detonation velocity, while the acceleration of Al powders is of little effect.

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“…The activation energy, pre-exponential factor and the best kinetic model for decomposition of explosives were determined according to the ICTAC kinetic committee recommendations [16]. Although thermal behavior and decomposition kinetic of RDX were reported by several researchers [17][18][19][20], to the best of the authors' knowledge, no study has yet been reported on the kinetic triplets for decomposition process of RDX in the presence of HMX and irganox 1010.…”

Section: Introductionmentioning

confidence: 99%

The Effect of HMX Impurity and Irganox Antioxidant on Thermal Decomposition Kinetics of RDX by TG/DSC Non‐Isothermal Method

Sinapour

Damiri

Ravanbod

et al. 2019

Propellants Explo Pyrotec

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The non‐isothermal TG/DTG/DSC technique has been used to study the thermal decomposition of RDX as pure and impure (contain 5 wt. % HMX) in the absence and presence of 5 wt. % irganox 1010 antioxidant under nitrogen atmosphere at different heating rates (4, 6, 8, and 10 °C min−1). The DSC curves show an exothermic peak for decomposition of RDX exactly after its melting point. The activation energy (Ea) for thermal decomposition of pure and impure RDX in the absence and presence of irganox was calculated using non‐isothermal isoconversional methods of KAS, OFW, and Friedman for different conversion fraction (α) values in the range of 0.1–0.9. The pre‐exponential factor (A) and the kinetic model have been determined by means of the compensation effect and the selected model is confirmed by the nonlinear fitting method. The activation energies for thermal decomposition of pure RDX in the absence and presence of irganox are 240.5 to 246.2 and 330.0 to 350.6 kJ mol−1 with the reaction model of R3 and D2, respectively, whereas; the Ea values for decomposition of impure RDX in the absence and presence of antioxidant are 172.1 to 173.0 and 195.3 to 214.2 kJ mol−1, respectively, with the reaction model of R2 for both of them.

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Detonation Performance of Four Groups of Aluminized Explosives

Cited by 21 publications

References 10 publications

The New Descriptors Effective on the Detonation Performance of Aluminized Explosives

The New Descriptors Effective on the Detonation Performance of Aluminized Explosives

A New Method for Predicting the Detonation Velocity of Explosives with Micrometer Aluminum Powders

The Effect of HMX Impurity and Irganox Antioxidant on Thermal Decomposition Kinetics of RDX by TG/DSC Non‐Isothermal Method

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