Dynamic Numerical Simulation of Chemical Erosion in Solid Rocket Motor Nozzle

被引：0

作者：

Yu Y. ^{[1
]}

Zhang H. ^{[1
]}

机构：

[1] School of Aerospace Engineering, Beijing Institute of Technology, Beijing

来源：

Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology | 2023年 / 43卷 / 07期

关键词：

chemical erosion; fluid-solid coupling; nozzle; numerical simulation;

D O I：

10.15918/j.tbit1001-0645.2022.207

中图分类号：

学科分类号：

摘要：

To predict nozzle erosion rate and study the chemical erosion in solid rocket motor nozzle, a dynamic erosion model was established by the chemical reaction and dynamic mesh, combined with secondary development on Fluent platform by UDF, and the two-way coupling effect of wall retrogression and internal flow field change of nozzle was realized. Under different propellant aluminum mass fractions, the dynamic erosion model was used to simulate the two dimensional unsteady fluid-solid-thermal coupling process of 70-lb BATES motor nozzle. The results show that, the calculated erosion rates are consistent with experimental data. The erosion rate decreases with the increase of aluminum mass fraction. The dynamic erosion model can predict nozzle erosion rate more accurately. The wall retrogression of nozzle surface changes the flow field and produces higher pressure and temperature near the throat. The concentrations of H2O and CO2 near the throat calculated by the dynamic erosion model are higher. © 2023 Beijing Institute of Technology. All rights reserved.

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页码：693 / 701

页数：8

共 24 条

[1] CAI Guobiao, Development and application of hybrid rocket motor technology: overview and prospect, Journal of Propulsion Technology, 33, 6, pp. 831-839, (2012)
[2] LI Hejun, XUE Hui, FU Qiangang, Et al., Research status and prospect of anti-oxidation coatings for carbon/carbon composites, Journal of Inorganic Materials, 25, 4, pp. 337-343, (2010)
[3] GEISLER R, BECKMAN C, KINKEAD S., The relationship between solid propellant formulation variables and motor performance, Proceedings of 11th Propulsion Conference, (1978)
[4] BIANCHI D, TURCHI A, NASUTI F, Et al., Chemical erosion of carbon-phenolic rocket nozzles with finite-rate surface chemistry, Journal of Propulsion and Power, 29, 5, pp. 1220-1230, (2013)
[5] CHEN Linquan, WANG Liwu, LIU Yongqiong, Et al., Review of nozzle boundary-layer control system for mitigation of nozzle throat erosion, Journal of Solid Rocket Technology, 37, 3, pp. 324-329, (2014)
[6] THAKRE P, YANG V., A comprehensive model to predict and mitigate the erosion of carbon-carbon/graphite rocket nozzles, Proceedings of 43rd AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit, (2007)
[7] BIANCHI D, NASUTI F., Thermochemical erosion analysis of carbon-carbon nozzles in solid-propellant rocket motors, Proceedings of 46th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit, (2010)
[8] KUO K, KESWANI S T., A comprehensive theoretical model for carbon-carbon composite nozzle recession, Combustion Science and Technology, 42, 3-4, pp. 145-164, (1985)
[9] THAKRE P, YANG V., Chemical erosion of carbon-carbon/graphite nozzles in solid-propellant rocket motors, Journal of Propulsion and Power, 24, 4, pp. 822-833, (2008)
[10] ZHANG Bin, LIU Yu, WANG Changhui, Et al., New control mechanism of solid rocket motor nozzle erosion, Science China Press, 12, (2010)

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