Modeling Hydrodynamic Behaviors in Detonation

Tang, P.K.

doi:10.1002/prep.19910160508

Cited by 7 publications

(9 citation statements)

References 3 publications

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“…We have shown in the past that when the BKW EOS is utilized to simulate the aluminum plate push experiments previously described, the calculation overestimates the experiment in later time, indicating a more energetic condition in the low pressure region since this does not happen when a tantalum plate is used (6). Using the new JWL EOS and the reactive burn model, Fig.…”

Section: Products Jwl Equation Of Statementioning

confidence: 87%

PBX 9502 Products Equation of State

Tang

1997

Propellants Explo Pyrotec

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We constructed a Jones‐Wilkins‐Lee (JWL) equation of state (EOS) for the PBX 9502 detonation products based on a standard one by lowering the Chapman‐Jouguet (CJ) pressure. We found that a slow component exists in the chemical reaction rate, and the global hydrodynamic behavior as exhibited by the standard EOS reflects such an effect. By reducing the CJ pressure, we effectively remove the contribution of the slow reaction from the standard EOS, and the new EOS should represent the detonation products better. In conjunction with a reactive burn model which includes a slow component, the products EOS performs better than the standard EOS.

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Section: Products Jwl Equation Of Statementioning

confidence: 87%

PBX 9502 Products Equation of State

Tang

1997

Propellants Explo Pyrotec

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“…It is commonly known that the macrokinetics of energy release in detonating HEs with a high content of carbon (e.g., TNT, TATB, and TNT-RDX mixtures) is characterized by two time scales: fast and slow (see, e.g., [10][11][12]). The fast kinetics is related to disintegration of the initial HE molecules and to formation of stable diatomic and triatomic molecules of detonation products and small carbon clusters (10 to 100 atoms).…”

Section: Discussionmentioning

confidence: 99%

Kinetics of electrical conductivity of TATB detonation products as an indicator of growth of carbon nanoparticles

Gorshkov

Grebenkin

Zherebtsov

et al. 2007

Combust Explos Shock Waves

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Two stages of growth of electrical conductivity of detonation products of plasticbonded TATB are registered: a fast stage with a characteristic time of 0.1 µsec, which is commensurable with the time of chemical reactions, and a subsequent slow stage, which lasts for 0.5-1.0 µsec until specimen unloading begins. Under the assumption of the thermal mechanism of conductivity emergence, the second stage could be caused by an increase in temperature due to slow energy release in the course of growth of carbon nanoparticles in explosion products.

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“…Frost, the predicted detonation properties and cylinder wall velocities for TATB-based explosives show larger discrepancies with experiment than do the other explosives. Some of these discrepancies are clearly due to nonideal behavior, which has been observed in the effect of diameter on detonation velocity [23] [24] and the effect of charge length on the energy imparted to a target [40] - [42]. Second, the velocity histories of thin plates accelerated by LX 14 also show effects due to the reaction zone [21].…”

Section: Discussionmentioning

confidence: 99%

“…The velocity (or energy) imparted to the target by the explosive is observed to increase with the length of the charge. Tang [42] has shown that these data can be reproduced using a two-step reactive burn model; about 85?40 of the energy is released by a fast reaction, which takes 20 ns, while the rest of the energy is released by a slow reaction that requires an additional 240 ns. The total reaction zone length in Tang's model is about 0.2 cm, which is comparable to the wall thickness in the cylinder tests.…”

Section: Cylinder Test Predictions Using Panda Eosmentioning

confidence: 99%

“…3.1, TATB-based explosives exhibit nonideal behavior in that the infinite diameter detonation velocity is not attained for charge diameters as large as 13 cm [23] [24]. Nonideal behavior has also been seen in interface velocity and plate-push experiments on TATB explosives [40][41] [42]. The velocity (or energy) imparted to the target by the explosive is observed to increase with the length of the charge.…”

Section: Cylinder Test Predictions Using Panda Eosmentioning

confidence: 99%

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Prediction of explosive cylinder tests using equations of state from the PANDA code

Kerley¹,

Christian-Frear²

1993

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The PANDA code is used to construct tabular equations of state (EOS) for the detonation products of 24 explosives having CHNO compositions. These EOS, together with a reactive bum model, are used in numerical hydrocode calculations of cylinder tests. The predicted detonation properties and cylinder wall velocities are found to give very good agreement with experimental data. Calculations of flat plate acceleration tests for the HMX-based explosive LX14 are also made and shown to agree well with the measurements. The effects of the reaction zone on both the cylinder and flat plate tests are dkcussed. For TATB-based explosives, the differences between experiment and theory are consistently larger than for other compositions and may be due to nonideal (finite diameter) behavior.

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Modeling Hydrodynamic Behaviors in Detonation

Cited by 7 publications

References 3 publications

PBX 9502 Products Equation of State

PBX 9502 Products Equation of State

Kinetics of electrical conductivity of TATB detonation products as an indicator of growth of carbon nanoparticles

Prediction of explosive cylinder tests using equations of state from the PANDA code

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