Effect of initial temperature on the interior ballistics of a 120-mm mortar system

Heath T. Martin, J. Eric Boyer, Kenneth K. Kuo

    Research output: Contribution to journalArticle

    8 Citations (Scopus)

    Abstract

    In this study, the effect of the initial temperature of a 120-mm mortar system on its interior ballistics was investigated using four different experiments: temperature-conditioned closed bomb firings for determining the temperature sensitivity of the ignition cartridge's M48 double-base propellant and instrumented firings of temperature-conditioned flash tubes, ignition cartridges, and an instrumented mortar simulator (IMS). The results of these experiments reveal that, for initial temperatures of-12 °C and greater, the mortar system and its subcomponents exhibited regular initial-temperature- dependent behavior, with increasing initial temperature causing monotonically increasing propellant burning rates and monotonically decreasing ignition delays, which produce monotonically increasing system pressures and pressure differentials in theflashtube, ignition cartridge, and IMS. However, some anomalous behavior was discovered for temperatures around -46°C. At this initial temperature, the closed bomb firings indicated that brittle fracture of the M48 propellant granules used in the ignition cartridge occurs. This phenomenon explains the occurrence in the IMS firings of dramatically increased variation in pressure-time behavior and projectile muzzle velocity for charge 4 firings as compared to higher temperatures, as well as the occurrence of maximum tube pressures for -46° C firings, being greater than those for 21 °C firings for charge 0. However, one of the -47°C closed bomb firings does not exhibit evidence of grain fracture and yet produces a higher propellant burning rate than the -12° C firings, suggesting that a fundamental change in reaction kinetics or flame structure is occurring at extremely low temperatures. This supposition is bolstered by evidence of a liquid layer existing on the surface of M48 propellant granules ejected from the ignition cartridge during the -46°C firings - a phenomenon that does not occur at the higher initial temperatures and is not theorized to occur in double-base solid propellant combustion. Based on the flash tube experiments alone, the flash tube was determined to have a weak effect on the initial-temperature-dependent behavior of the mortar system; however, IMS testing with two different flash tube configurations revealed significant differences in longitudinal pressure wave amplitude and projectile muzzle velocity in charge 4 firings between the two configurations at -46°C, suggesting that the uniformity of combustion product discharge from the flash tube could significantly affect the performance of the mortar at low temperatures.

    Original languageEnglish (US)
    Article number031408
    JournalJournal of Applied Mechanics, Transactions ASME
    Volume80
    Issue number3
    DOIs
    StatePublished - May 28 2013

    Fingerprint

    interior ballistics
    Ballistics
    Mortar
    cartridges
    flash lamps
    ignition
    propellants
    Ignition
    Propellants
    simulators
    Temperature
    temperature
    double base propellants
    burning rate
    Simulators
    projectiles
    solid propellant combustion
    Projectiles
    occurrences
    combustion products

    All Science Journal Classification (ASJC) codes

    • Condensed Matter Physics
    • Mechanics of Materials
    • Mechanical Engineering

    Cite this

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    title = "Effect of initial temperature on the interior ballistics of a 120-mm mortar system",
    abstract = "In this study, the effect of the initial temperature of a 120-mm mortar system on its interior ballistics was investigated using four different experiments: temperature-conditioned closed bomb firings for determining the temperature sensitivity of the ignition cartridge's M48 double-base propellant and instrumented firings of temperature-conditioned flash tubes, ignition cartridges, and an instrumented mortar simulator (IMS). The results of these experiments reveal that, for initial temperatures of-12 °C and greater, the mortar system and its subcomponents exhibited regular initial-temperature- dependent behavior, with increasing initial temperature causing monotonically increasing propellant burning rates and monotonically decreasing ignition delays, which produce monotonically increasing system pressures and pressure differentials in theflashtube, ignition cartridge, and IMS. However, some anomalous behavior was discovered for temperatures around -46°C. At this initial temperature, the closed bomb firings indicated that brittle fracture of the M48 propellant granules used in the ignition cartridge occurs. This phenomenon explains the occurrence in the IMS firings of dramatically increased variation in pressure-time behavior and projectile muzzle velocity for charge 4 firings as compared to higher temperatures, as well as the occurrence of maximum tube pressures for -46° C firings, being greater than those for 21 °C firings for charge 0. However, one of the -47°C closed bomb firings does not exhibit evidence of grain fracture and yet produces a higher propellant burning rate than the -12° C firings, suggesting that a fundamental change in reaction kinetics or flame structure is occurring at extremely low temperatures. This supposition is bolstered by evidence of a liquid layer existing on the surface of M48 propellant granules ejected from the ignition cartridge during the -46°C firings - a phenomenon that does not occur at the higher initial temperatures and is not theorized to occur in double-base solid propellant combustion. Based on the flash tube experiments alone, the flash tube was determined to have a weak effect on the initial-temperature-dependent behavior of the mortar system; however, IMS testing with two different flash tube configurations revealed significant differences in longitudinal pressure wave amplitude and projectile muzzle velocity in charge 4 firings between the two configurations at -46°C, suggesting that the uniformity of combustion product discharge from the flash tube could significantly affect the performance of the mortar at low temperatures.",
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    Effect of initial temperature on the interior ballistics of a 120-mm mortar system. / Martin, Heath T.; Boyer, J. Eric; Kuo, Kenneth K.

    In: Journal of Applied Mechanics, Transactions ASME, Vol. 80, No. 3, 031408, 28.05.2013.

    Research output: Contribution to journalArticle

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    AU - Kuo, Kenneth K.

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