ADVANCED OPTICAL DIAGNOSTIC TECHNOLOGY APPLICATION PROGRESS IN COMBUSTION TESTING OF ENERGETIC MATERIALS
Keywords:
Physical chemistry, Combustion of energetic materials, Optical diagnostic technology, Laser-induced fluorescence, Laser absorption spectroscopy, Schlieren methodAbstract
Based on different optical principles, laser-induced fluorescence (LIF), coherent anti-Stokes Raman scattering (CARS), particle imaging velocimetry (PIV), and tunable are reviewed from three aspects: light scattering, optical emission and absorption, and imaging. Testing principles of optical diagnostic technologies such as semiconductor laser absorption spectroscopy (TDLAS), laser-induced breakdown spectroscopy (LIBS), radiation method, remote sensing Fourier transform infrared spectroscopy (RS-FTIR) and schlieren method, and their use in combustion tests of energetic materials The application progress of optical diagnostic technology in combustion testing is analyzed. The superiority of optical diagnostic technology compared with other traditional contact diagnostic methods and the applicability, measurement objects, advantages and disadvantages of various optical diagnostic methods are analyzed; the microscopic combustion products, flame temperature, The development prospects of testing technologies such as combustion flow field velocity and flame structure in combustion diagnosis of energetic materials; it is pointed out that future work should combine multi-diagnostic methods and develop multi-dimensional measurements to obtain richer and multi-dimensional microscopic data information.References
[1] HEDMAN TD, CHO K Y, SATIJAA. Experimental observation of the flame structure of a bimodal ammonium perchlorate composite propellant using 5kHzPLIF. Combustion and Flame, 2012, 159(1): 427-437.
[2] ISERTS, HEDMAN T D, LUCHTRP. Oxidizer coarseto-fine ratio effect on microscale flame structure in a bimodal composite propellant. Combustion and Flame, 2016, 163: 406-413.
[3] HEDMAN T D, REESE D A, CHO K Y. An experimental study of the effects of catalyst sonanammonium perchlorate based composite propellantusing5 kHzPLIF. Combustion and Flame, 2012, 159(4): 1748-1758.
[4] YANG Y, ZHU T, YAN Z. A study on combustioncharacteristicsofinsensitivetriple-base propellant. Applied Sciences, 2023, 13(9): 5462.
[5] PARR T, HANSON-PARR D. Cyclotetramethylene tetranitramine/glycidyl azide pol ymer/butanetriol trinitrate propellant flame structure. Combustion and Flame, 2004, 137(1/2): 38-49.
[6] Yan Zhiyu, Wang Liangchen, Song Chen. Optical diagnosis of RDX focus ignition and reaction processes. Journal of Explosives, 2021, 44(4):468-473.
[7] RUESCH M, POWELL M S, SATIJA A. Burning rate and flame structure of cocrystalsofCL-20 and a polycrystalline composite crystal of HMX/AP. Combustion and Flame, 2020, 219: 129-135.
[8] CHO K, POURPOINTT, SON S. High repetition rate OH planar laser induced fluorescence of gelled propellant droplet. 47th AIAA/ASME/ SAE/ASEE Joint Propulsion Conference and Exhibit: New York: AIAA, 2011.
[9] CHO K Y, POURPOINTTL, SON SF. Micro explosion investigation of mono methyl hydra zine gelled droplet with OH planar laser-induced fluorescence. Journal of Propulsion and Power, 2013, 29 (6): 1303-1310.
[10] PETERSON B, BAUM E, B?HM B. Spray induced temperature stratification dynamics in a gasoline direct-injection engine. Proceedings of the Combustion Institute, 2015, 35(3): 2923-2931.
[11] PETERSON B, BAUM E, DREIZLER A. An experimental study of the detailed flame transport in a SI engine using simultaneous dual-plane OH-LIF and stereoscopic PIV. Combustion and Flame, 2019, 202: 16-32.
[12] Yuan Xun, Yu Xin, Peng Jiangbo. Research on 3DLIF visualization technology of supersonic flame. Experimental Fluid Mechanics, 2022, 36(4): 30-36.
[13] Liu Jingru, Hu Zhiyun. Application of laser-based measurement technology in combustion flow field diagnosis. China Optics, 2018, 11: 531-549.
[14] SOLOUKHIN R I, OPPENHEIM A K, BOWEN J R. Two-dimensional imaging of flame temperature using laser-induced fluorescence. Dynamics of Flames and Reactive Systems, 1984: 714-721.
[15] LAURENDEAU N M. Temperaturemeasurements by light-scattering methods. Progress in energy and Combustion Science, 1988, 14(2): 147-170.
[16] Lu Yongxu. Research on propellant combustion temperature measurement method based on two-color plane laser-induced fluorescence technology. Mianyang: Southwest University of Science and Technology, 2022.
[17] VILMART G, DORVAL N, ATTAL-TRETOUTB. Detection of iron and aluminum atomic vapors by LIF technique: application to solid propellant combustion ∥33rd AIAA Aerodynamic Measurement Technology and Ground Testing Conference. New York: AIAA, 2017.
[18] VILMART G. Detection of vapors of metal atoms per induced fluorescence by laser(LIF): application has there propulsion solid. French: University Paris Saclay (Cam UE), 2017.
[19] BUCHER P, YETTER R A, DRYER F L. Flames structure measurement of single, isolated aluminum particles burning in air. Symposiumon Combustion, 1996, 26(2):1899-1908.
[20] BUCHER P, YETTER R A, DRYER F L. PLIF speciesandratiometric temperature measurements of aluminum particlecombustioninO2, CO2 andN2 O oxidizers, and comparison with model calculations. Symposiumon Combustion, 1998, 27(2): 2421-2429.
[21] Peng Jiangbo, Cao Zhen, Yu Xin. Application of time-resolved AlO-PLIF imaging technology. Solid Rocket Technology, 2021, 44(1):106-111.
[22] CHEVALIERPH, DORVALN, DEVILLERSR W. Investigation of aluminum drop let combustion in solid propellant flames: Al-PLIF experiments and numerical simulation ∥AIAA Propulsion and Energy 2021Forum: American Institute of Aeronautics and Astronautics. New York:AIAA, 2021.
[23] VILMART G, DORVAL N, ATTALTRETOUTB. Detection of aluminum vapors b y laser-induced fluorescence for solid propellant combustion ∥33rd AIAA Aerodynamic Measurement Technology and Ground Testing Conference. New York: AIAA, 2017.
[24] VILMART G, DORVAL N, DEVILLERS R. Imaging aluminum particles in solid-propellant flames using5kHzLIF of AI atoms. Materials, 2019, 12 (15): 2421.
[25] VILMARTG, DORVALN, ORAIN M. Detection of iron atoms by emission spectroscopy andlaser-induced fluorescence in solid propellant flames. Applied Optics, 2018, 57(14): 3817.