PETN spark-gap detonators

• Published in: Journal of energetic materials Vol. 39; no. 1; pp. 60 - 73
• Main Authors: Chen, Kenneth C., Warne, Larry K.
• Format: Journal Article
• Language: English
• Published: Philadelphia Taylor & Francis 02.01.2021; Taylor & Francis Ltd
• Subjects: arc radius; Criteria; Detonation; detonator; Detonators; Diameters; Differential equations; Electric arcs; equation of State; Hydrodynamic equations; Lorentz plasma; Mathematical analysis; Nonlinear differential equations; Nonlinear equations; Ordinary differential equations; PETN; Pop-Plot; shock; Similarity solutions; spark-gap
• ISSN: 0737-0652; 1545-8822
• DOI: 10.1080/07370652.2020.1756986

The well-developed theory of Lorentz plasma that is dominated by electron-ion interactions is used to calculate the PETN arc characteristics. The spark-gap discharge current is a ramp with 10 to 25 ns rise time to peak and remaining constant subsequently. The approximate formulas for the arc channel conductivity, arc temperature, arc radius, and shock pressure from the arc are obtained from a system of nonlinear ordinary differential equations, which is the similarity solution of hydrodynamic equations similar to the Braginskii approximation. These arc parameters are given for the peak current ranging from 100 A to 1000 A and with different rise times. Representative cases are compared to the nonlinear ordinary differential equation code results. The shock pressures at the peak current are comparable to those from a typical commercial EBW bridgewire burst reported in the literature; the arc radius at the peak current is comparable to a typical bridgewire diameter of 0.0375 mm (e.g., RISI detonators, RP-1, and RP-80). The relevant Pop-Plot for low-density PETN is converted into an empirical detonation criterion, which is applicable to explosives subject to shocks of variable pressure. This criterion is then used to determine the detonation thresholds, which are comparable with test data obtained by Tucker, et al.