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Ignition and combustion of Al–Mg–Li alloy particles at elevated pressures

Yuezu Miao, Shengji Li, Yanjing Yang, Xiaohong Zhang, Xuefeng Huang, Hongyan Li, Zhao Qin

2024Case Studies in Thermal Engineering11 citationsDOIOpen Access PDF

Abstract

Al-Mg-Li ternary alloy particles can be a promising metal additive to replace aluminum in solid propellants to improve combustion efficiency by reducing agglomeration during combustion. In this paper, Al-Mg-Li ternary alloy was prepared and its basic physical and chemical characterization parameters were obtained by SEM-EDS, ICP-AES, and XRD analysis. The ignition and combustion characteristics of single Al-Mg-Li particles under different pressures were investigated by using a self-developed experimental setup. The ignition process and combustion flame structure of Al-Mg-Li particles were significantly affected by the increasing pressure, and the ignition delay and combustion time decreased with increasing pressure. The ignition mode was clearly identified: surface ignition (0.1-0.2 MPa) and gas phase ignition (0.4-1.2 MPa). Al-Mg-Li particles showed white-pink flame during combustion, and the characteristic peaks of AlO, MgO, and Li were identified confirming that the particles performed a gas-phase combustion at pressures above 0.4 MPa. The combustion temperature of Al-Mg-Li particles could exceed 3000 °C when the pressure surpassed 0.6 MPa. The composition of different regions in the condensed combustion products were analyzed. Reaction mechanisms were proposed to reveal the addition of elemental Mg and Li could improve the ignition and combustion characteristics of Al, especially at higher ambient pressures.

Topics & Concepts

CombustionMaterials scienceIgnition systemTernary operationAlloyChemical engineeringPhase (matter)AluminiumAutoignition temperatureMetallurgyAnalytical Chemistry (journal)ThermodynamicsChemistryOrganic chemistryComputer scienceEngineeringPhysicsProgramming languageEnergetic Materials and CombustionRocket and propulsion systems researchHigh-Velocity Impact and Material Behavior