超声波实时测量技术在固体火箭发动机中的应用

doi:10.3969/j.issn.1000-1093.2016.11.001

兵工学报 ›› 2016, Vol. 37 ›› Issue (11): 1969-1975.doi: 10.3969/j.issn.1000-1093.2016.11.001

• 论文 • 下一篇

超声波实时测量技术在固体火箭发动机中的应用

孙得川¹，权恩²，曹梦成¹

(1.大连理工大学航空航天学院工业装备结构分析国家重点实验室，辽宁大连 116024;2.西安航天动力技术研究所，陕西西安 710025）

收稿日期:2016-04-20 修回日期:2016-04-20 上线日期:2016-12-30
通讯作者: 孙得川 E-mail:dechuans@dlut.edu.cn
作者简介:孙得川（1973—），男，教授
基金资助:
国防“973”计划项目（613239020201）

Application of Ultrasonic Real-time Measurement Technology in Solid Rocket Motor

SUN De-chuan¹, QUAN En², CAO Meng-cheng¹

(1.State Key Laboratory of Structural Analysis for Industrial Equipment, School of Aeronautics and Astronautics,Dalian University of Technology, Dalian 116024, Liaoning, China;2.The Institute of Xi'an Aerospace Solid Propulsion Technology, Xi'an 710025, Shaanxi, China)

Received:2016-04-20 Revised:2016-04-20 Online:2016-12-30
Contact: SUN De-chuan E-mail:dechuans@dlut.edu.cn

摘要/Abstract

摘要： 利用超声波对固体推进剂燃速进行实时测量是先进的燃速测量方法之一。针对超声波技术在固体火箭发动机试车中的应用，对典型固体火箭发动机材料进行测试研究，获得了发动机材料的超声波信号特征。将超声波探头直接安装在发动机壳体外侧部位，测量了固体推进剂在常压燃烧时的厚度变化。针对动态燃速测试，提出了超声波数据处理方法，对固体装药在常压燃烧下的回波进行处理，获得了装药的厚度变化过程和燃速，并分析了燃面附近温度分布对燃速测量的影响。结果表明：用超声波测量金属壳体固体发动机的燃速必须在壳体上开窗使超声波透过壳体和绝热层界面，而对复合材料壳体发动机可将超声波探头直接安装在壳体外侧;燃烧引起的装药表面温度变化对测量的影响可以忽略；该数据处理方法可以有效获得装药厚度变化。

关键词: 兵器科学与技术, 固体火箭发动机, 燃速, 超声波, 数据处理, 温度

Abstract: Ultrasonic measurement of burning rate is an advanced technique. For application of ultrasonic measurement in solid rocket motor test, some typical materials used in solid rocket motor (SRM) are measured by ultrasonic technique, and their ultrasonic signal signatures were obtained. The real-time thickness variation of solid propellant at ordinary pressure is measured by an ultrasonic transducer mounted on the outside of the motor shell. A data processing method is proposed to manipulate the echo wave for real-time measurement of burning rate. The proposed method was successfully used in a hot fire test in which the propellant burns at ordinary pressure. The variation in thickness of propellant and its burning rate at ordinary pressure was obtained. The influence of temperature distribution near burning surface on burning rate test is analyzed. The results show that for motor with metal shell, a window must be made on the metal shell to let enough ultrasonic wave energy penetrate the interface between shell and isolator, and for composite shell motor the probe can be mounted outside the shell directly. The influence of temperature variation near burning face caused by combustion on measurement is negligible. The proposed data processing method can be used effectively to obtain the variation of grain thickness.

Key words: ordnance science and technology, solid rocket motor, burning rate, ultrasonic, data processing, temperature

中图分类号:

TB559

孙得川，权恩，曹梦成. 超声波实时测量技术在固体火箭发动机中的应用[J]. 兵工学报, 2016, 37(11): 1969-1975.

SUN De-chuan, QUAN En, CAO Meng-cheng. Application of Ultrasonic Real-time Measurement Technology in Solid Rocket Motor[J]. Acta Armamentarii, 2016, 37(11): 1969-1975.

参考文献

［1］ Cauty F, Demarais J C. Ultrasonic measurements of the uncured solid propellants burning rate ［C］∥Proceedings of the 21th International Congress of ICT. Karlsruhe, Germany: ICT, 1990:110-114.
［2］ Frederick R J, Traineau J C. Popo M. Review of ultrasonic technique for steady state burning rate measurements ［C］∥36th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. Las Vegas, NV, US:AIAA, 2000.
［3］ Demarais J C I, Cauty F, Erades C. Determination of solid propellant burning rate sensitivity to the initial temperature by the ultrasonic method ［J］. International Journal of Energetic Materials and Chemical Propulsion,1994, 3(1-6):642-653.
［4］ Murphy J J, Krier H. Ultrasound measurements of solid propellant burning rates: theory and application［C］ ∥AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit. Cleveland, OH, US: AIAA,1998.
［5］ Sinclair A N, Jastrzebski M, Safavi-Ardebili V. Ultrasonic evaluation of weak liner/propellant bonding in a rocket motor［C］ ∥16th World Conference on NDT. Montreal, Canada:［s.n.］ , 2004.
［6］ McLean C H, Deininger W D, Marotta B M, et al. Green propellant infusion mission program overview, status, and flight operations ［C］∥51st AIAA/SAE/ASEE Joint Propulsion Conference. Orlando, FL, US: AIAA,2015.
［7］ Redden J J. SLS booster development ［C］∥51st AIAA/SAE/ASEE Joint Propulsion Conference. Orlando, FL, US: AIAA, 2015.
［8］ Anthoine J, Jézéquel P, Prévost M, et al. Variable fuel grains Burn velocities to reduce solid-rocket-motor pressure oscillations［J］. Journal of Propulsion and Power, 2015, 31(1):342-351.
［9］ Jones D A, Mascaro M D, Lineberry D M, et al. An advanced digital cross correlation method for solid propellant burning rate determination ［C］∥51st AIAA/SAE/ASEE Joint Propulsion Conference. Orlando, FL, US:AIAA,2015.
［10］张劲民, 王志强, 袁华. 超声波燃速测试技术在固体推进剂研制中的应用［J］.火炸药学报, 2006, 29(3): 9-12.
ZHANG Jin-min, WANG Zhi-qiang, YUAN Hua. Application of ultrasonic measurement for burning rate in solid propellant development［J］. Chinese Journal of Explosives and Propellants, 2006, 29(3) :9-12.(in Chinese)
［11］孙得川, 周伟, 汪亮. 超声波法测量燃速初探［J］. 固体火箭技术, 2007, 30(4): 362-364.
SUN De-chuan,ZHOU Wei, WANG Liang. Burning rate measurement by means of ultrasonic technique［J］. Journal of Solid Rocket Technology, 2007, 30(4)：362-364.(in Chinese)
［12］孙得川, 张研, 王贺,等. 固液火箭发动机中燃料热解速率的测量与分析［J］. 推进技术, 2010,31 (1): 74-77.
SUN De-chuan, ZHANG Yan, WANG He, et al. Regression rate measurement and analysis for solid fuel in hybrid rocket motor［J］. Journal of Propulsion Technology, 2010 ,31(1):74-77.(in Chinese)
［13］孙得川, 万宏强. 固体推进剂燃速的超声波测量［J］. 西安工业大学学报, 2011,31 (1): 40-43, 52.
SUN De-chuan, WAN Hong-qiang. Ultrasonic technique for burning rate measurement of solid propellant［J］. Journal of Xi'an Technology University, 2011,31(1): 40-43, 52.(in Chinese)
［14］郑晖, 林树清. 超声检测［M］. 第2版. 北京：中国劳动社会保障出版社,2008.
ZHENG Hui, LIN Shu-qing. Ultrasonic inspection and measurement ［M］. 2nd ed. Beijing: China Labor and Social Security Publishing House, 2008.(in Chinese)

[1]	刘朋科，杨雕，许耀峰，宁变芳，王军，刘欢. 火炮身管内膛表层温度及其梯度规律研究[J]. 兵工学报, 2022, 43(6): 1225-1232.
[2]	陈恒帅，朱艳丽，李伟，白杰. 基于热传递仿真的热电池激活阶段热特性[J]. 兵工学报, 2022, 43(5): 1194-1200.
[3]	顾兴鹏，李军伟，乔文生，武胜，韩磊，汪琪，王宁飞. 固相颗粒在C1xb固体火箭发动机中的运动规律[J]. 兵工学报, 2022, 43(3): 489-502.
[4]	刘纯，欧卓成，段卓平，黄风雷. 动态加载下高聚物粘结炸药中椭圆孔洞坍塌引起的热点温度及其半经验解析表达[J]. 兵工学报, 2022, 43(1): 57-68.
[5]	郭靖宇，岳光，吕佳镁，任琳，潘玉田. 基于流体动力学的热压罐框架式模具温度场优化[J]. 兵工学报, 2022, 43(1): 233-240.
[6]	张海军，聂建新，王领，王栋，郭学永，闫石. 端羟基聚醚推进剂慢速烤燃尺寸效应[J]. 兵工学报, 2021, 42(9): 1858-1866.
[7]	官典, 李世鹏, 刘筑, 王宁飞. 横向过载对固体火箭发动机推进剂点火建压过程的影响[J]. 兵工学报, 2021, 42(9): 1877-1887.
[8]	周柏航，陶如意，王浩，阮文俊. 带侵蚀燃烧效应的阶梯多根装药火箭发动机三维内流场特性[J]. 兵工学报, 2021, 42(8): 1604-1612.
[9]	高峰，张泽. 含装药缺陷的固体火箭发动机性能评估综述[J]. 兵工学报, 2021, 42(8): 1789-1802.
[10]	邹利波，于存贵，冯广斌，侯保林，仲建林，刘宪福. 基于温度修正的弹丸挤进身管过程摩擦模型[J]. 兵工学报, 2021, 42(6): 1148-1156.
[11]	马宝印，李军伟，张海龙，赵桂琦，张智慧，席运志，王宁飞. 阻尼环对固体火箭发动机热声振荡的影响[J]. 兵工学报, 2021, 42(5): 930-943.
[12]	顾祖成, 王光华, 卢海涛, 闫文敏. 小口径步枪枪管在连续单发射击下热效应特性[J]. 兵工学报, 2021, 42(4): 734-742.
[13]	许仁翰，周钇捷，狄长安. 基于高速成像的爆炸温度场测试方法[J]. 兵工学报, 2021, 42(3): 640-647.
[14]	庞大千，曾根，李训明，郭磊，赵富强，孙占春. 不同工况下机电复合传动装置行星齿轮系统瞬态温度场[J]. 兵工学报, 2021, 42(10): 2268-2277.
[15]	席运志，王宁飞，李军伟，张智慧. 基于旋转阀的固体火箭发动机燃烧室压强振荡特性[J]. 兵工学报, 2021, 42(1): 33-44.

超声波实时测量技术在固体火箭发动机中的应用

Application of Ultrasonic Real-time Measurement Technology in Solid Rocket Motor

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价