Development of near-space-vehicle anemometer and calibration tests in low-temperature-low-static-pressure wind tunnel
-
摘要: 本文介绍了一种新型临近空间低速飞行器风速测量装置。风速仪基于旋转测压旋杆、增加测压旋杆两端测压探头动压的原理设计,在临近空间环境和超低动压条件下具有较高的风速测量精度。在中国电子科技集团公司第二十一研究所的临近空间环境模拟风洞中开展了低温低压低风速测量标定试验,试验来流速度范围为5~14m/s。试验结果表明,测量的动压信号与正/余弦函数拟合结果一致性较高,压差测量值的相对量可信度较高。此外,压差幅值信号与来流风速成线性关系,通过线性拟合的方法获得风速仪的测量标定模型。
-
关键词:
- 临近空间 /
- 风速测量 /
- 临近空间环境模拟风洞 /
- 风洞试验
Abstract: A new kind of anemometer to measure the air speed of the near-space low speed vehicle is introduced in this paper. This equipment is designed based on the theory that rotating the measuring arms increases the acquired dynamic pressure. Benefitted from this theory, the anemometer can measure the wind speed with reasonable precision in situations of ultralow dynamic pressure in the near space environment. A series of tests are completed in the near-space environment simulation wind tunnel in the 21th Research Institute of CETC, whose inflow air speed is available from 5 to 14 meters per second. The results show that the measured dynamic pressure curves are coincident with the sine function curves and there is a significant linear correlation between the amplitude of the dynamic pressure and the inflow airspeed. Based on the linear fit method, a calibration model of the anemometer is established. -
图 3 压差信号随时间变化仿真曲线
Figure 3. Simulation curve of the differential dependent on time dynamic pressure
图 5 风速仪试验现场照片
Figure 5. Picture of rotation anemometer in test section of the wind tunnel
图 7 压差测量数据与正弦/余弦拟合结果对比图 (来流温度10℃,旋杆转速500r/min,理论风速10.36m/s)
Figure 7. Comparison of measurements and sine fit results (with inflow temperature of 10℃, pressure-measuring arms rotating rates of 500r/min, and wind speed of 10.36m/s)
图 8 压差测量数据与正弦/余弦拟合结果对比图 (来流温度-60℃,旋杆转速600r/min,理论风速8.7 m/s)
Figure 8. Comparison of measurements and sine fit results (with inflow temperature of-60℃, pressure-measuring arms rotating rates of 600r/min, and wind speed of 8.7m/s)
图 9 理论风速-压差幅值测量值及线性拟合曲线 (来流温度-60℃,旋杆转速600r/min)
Figure 9. Amplitude of differential dynamic pressure data and linear fit results from wind speed (with inflow temperature of-60℃, and pressure-measuring arms rotating rates of 600r/min)
图 10 旋杆转速600r/min时的风速仪标定曲线 (来流温度-60℃,静压7kPa)
Figure 10. Calibration curve of anemometer at rotation rate of 600r/min (with inflow temperature of-60℃, and static pressure of 7kPa)
图 11 旋杆转速500r/min时的风速仪标定曲线 (来流温度-60℃,静压7kPa)
Figure 11. Calibration curve of anemometer at rotation rate of 500r/min (with inflow temperature of-60℃, and static pressure of 7kPa)
表 1 不同温度不同转速下的线性拟合斜率比
Table 1. Fit slope at different test temperatures and rotating rates
来流
温度/℃理论风速
/(m·s-1)旋杆转速
/(r·min-1)斜率
a斜率
比转速比 10 6.3、10.4、13.8 600 1.1261 1.184 1.2 500 0.9513 -60 5.4、8.7、11.6 600 2.3710 1.209 1.2 500 1.9596 
下载: 导出CSV
表 2 不同转速下风速仪的标定系数及误差
Table 2. Calibration coefficients and error in tests
风速标定表 转速600r/min Pearson相关性系数 0.997 数值 标准差 常数项 -2.97107 0.81596 斜率 0.41977 0.02892 转速500r/min Pearson相关性系数 0.998 数值 标准差 常数项 -3.27498 0.75244 斜率 0.50836 0.03151
下载: 导出CSV
-
[1] Young M, Keith L S, Pancotti A. An overview of advanced concepts for nearspace systems[C]//Proceedings of AIAA Joint Propulsion Conference and Exhibit, Colorado, USA, 2009. [2] Kurkcu C, Erhan H, Umut S. Unmanned aerial systems' near space operation concept[C]//Proceedings of 5th International Conference on Recent Advances in Space Technologies, Istanbul, Turkey, 2011. [3] 杨跃能. 平流层飞艇动力学建模与控制方法研究[D]. 长沙: 国防科学技术大学, 2013.Yang Y N. Dynamics modeling and flight control for a stratospheric airship[D]. Changsha:National University of Defense Technology, 2013. [4] 刘刚, 张玉军.平流层飞艇定点驻留控制分析与仿真[J].自动控制与测量, 2008, 27(12):64-66. http://www.cnki.com.cn/Article/CJFDTOTAL-BGZD200812024.htmLiu G, Zhang Y J. Analysis and simulation of stratospheric airship's fixed-point resident control[J]. Automatic Measurement and Control, 2008, 27(12):64-66. http://www.cnki.com.cn/Article/CJFDTOTAL-BGZD200812024.htm [5] 李峰, 叶正寅.平流层飞艇空气动力学研究进展[J].华东交通大学学报, 2008, 25(1):24-27. http://www.cnki.com.cn/Article/CJFDTOTAL-LXJZ201204012.htmLi F, Ye Z Y. Advances in aerodynamics research of stratospheric airship[J]. Journal of East China Jiaotong University, 2008, 25(1):24-27. http://www.cnki.com.cn/Article/CJFDTOTAL-LXJZ201204012.htm [6] 胡国昌, 吴美平.平流层飞艇运动分析与仿真[J].哈尔滨工程大学学报, 2011, 32(11):1501-1508. doi: 10.3969/j.issn.1006-7043.2011.11.019He G C, Wu M P. Motion analysis and simulation of a strotospheric airship[J]. Journal of Harbin Engineering University, 2011, 32(11):1501-1508. doi: 10.3969/j.issn.1006-7043.2011.11.019 [7] 杨乐天, 张石玉, 张卫民. 高空驻空飞行器空速测量研究[C]. 第三届高分辨率对地观测学术年会, 2014: 284-290.Yang L T, Zhang S Y, Zhang W M. Research of anemometer applied in near space aircraft[C]. The 3rd China High Resolution Earth Observation Conference, 2014:284-290. [8] 张成. 临近空间大气认知建模及无人机飞行仿真[D]. 上海: 上海交通大学, 2008.Zhang C. The cognition and modeling of near space atmosphere and unmanned air vehicle flight simulation in variable wind field[D]. Shanghai:Shanghai Jiao Tong University, 2008. [9] 苗景刚, 周江华, 杨新.基于Matlab/Simulink的飞艇全数字仿真系统[J].系统仿真学报, 2009, 21(9):2658-2661. http://www.cnki.com.cn/Article/CJFDTOTAL-XTFZ200909050.htmMiao J G, Zhou J H, Yang X. Airship digital simulation system based on Matlab/Simulink[J]. Journal of System Simulation, 2009, 21(9):2658-2661. http://www.cnki.com.cn/Article/CJFDTOTAL-XTFZ200909050.htm [10] 殷文华, 柳建华, 张良, 等.模拟平流层环境的加载试验风洞测试与控制系统设计[J].航天器环境工程, 2015, 21(1):49-52. http://www.cnki.com.cn/Article/CJFDTOTAL-HTHJ201501009.htm [11] 张东宁, 王洪武, 赛庆毅, 等. 电机用平流层环境模拟实验装置[C]. 第二届高分辨率对地观测学术年会, 2013.Zhang D N, Wang H W, Sai Q Y, et al. An equipment for test motors used in stratosphere[C]. The 2nd China High Resoluation Earth Observation Conference, 2013. -
点击查看大图
计量
- 文章访问数: 88
- HTML全文浏览量: 71
- PDF下载量: 8
- 被引次数: 0
