碎片云超高速撞击声发射信号特征分析

庞宝君; 张凯; 林敏; 刘源

doi:10.11858/gywlxb.2014.06.004

碎片云超高速撞击声发射信号特征分析

doi: 10.11858/gywlxb.2014.06.004

哈尔滨工业大学空间碎片高速撞击研究中心，黑龙江哈尔滨 150080

基金项目: 国家空间碎片专题研究项目(kjsp06211)

详细信息

作者简介:
庞宝君(1963—), 男，教授，博士生导师，主要从事空间碎片超高速撞击及航天器防护技术研究. E-mail:pangbj@hit.edu.cn

通讯作者:
张凯(1984-), 男, 博士研究生, 主要从事空间碎片环境下航天器在轨健康监测研究.E-mail:bluerobbin@163.com

中图分类号: O348.8
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出版历程
- 收稿日期: 2012-12-26
- 修回日期: 2013-03-08

Characteristic Analysis of Acoustic Emission Signals Caused by Debris Cloud Impact

Hypervelocity Impact Research Center, Harbin Institute of Technology, Harbin 150080, China

摘要

摘要: 为了掌握带防护屏的航天器结构受空间碎片超高速撞击时的声发射信号特征，利用二级轻气炮发射球形弹丸撞击铝合金双层板结构，获取了碎片云撞击铝合金板舱壁产生的声发射信号，并利用小波包技术和能量熵理论对信号进行了分析。实验结果表明：弹丸初始速度、防护屏厚度及弹丸直径是决定二次碎片云形态及声发射信号特征的重要因素；在本实验工况范围内，小波包能量熵值能够描述声发射信号频率的复杂程度；当弹丸初始速度处于破碎段(3~7 km/s)时，随着初始速度的增大，二次碎片云进一步细化，撞击产生的声发射信号幅值趋于减小、频率成分趋于复杂化，其小波包能量熵值逐渐增大；防护屏厚度对声发射信号的小波包能量熵值影响较大，弹丸直径对其影响较小。研究结果有助于实现对碎片云撞击舱壁结构的损伤模式识别。
- 二次碎片云 /
- 超高速撞击 /
- 声发射 /
- 小波包能量熵
Abstract: In order to understand the characteristics of acoustic emission signals caused by hypervelocity space debris impacting spacecraft with shields, a two-stage light gas gun was used to launch sphere projectiles to impact an aluminum-alloy Whipple shield, the induced acoustic emission signals were acquired, and analyzed by wavelet packet technology and energy entropy theory.The experimental results indicate that, the initial velocity of projectile, bumper thickness and projectile diameter are important factors to decide the form of debris cloud and characteristics of acoustic emission signals.The wavelet packet energy entropy could be used to describe the frequency complexity of debris cloud impact signals.When the initial velocity of projectile increases in the broken section (3-7 km/s), along with which the projectile breaks more completely and the energy entropy of acoustic emission signals increases.Under the experimental conditions, the bumper thickness has greater influence on energy entropy values than the projectile diameter.The wavelet packet energy entropy is helpful to estimate the initial velocity of projectile and the maximum impact damage region, combined with the predicted curve from the Christiansen ballistic limit equation, the damage pattern recognition of the bulkhead could be assessed.
- debris cloud /
- hypervelocity impact /
- acoustic emission /
- wavelet packet energy entropy

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图 1 碎片云撞击信号获取实验示意图

Figure 1. Schematic of signal acquisition experiments for debris cloud impact

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图 2 实验结果与预测曲线的比较

Figure 2. Comparison between experimental results and predicted curve from Eq.(1)

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图 3 不同破碎程度碎片云撞击损伤结果

Figure 3. Impact damage caused by different levels of fragmentation projectiles

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图 4 弹丸不同程度破碎形成的碎片云撞击声发射信号波形

Figure 4. Debris cloud impact signals by projectiles with different fragmentation degrees

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图 5 小波包能量熵值随弹丸初始速度的变化

Figure 5. Wavelet packet energy entropy changing with initial velocity of projectile

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图 6 距离板中心不同位置处信号的小波包能量熵值

Figure 6. Wavelet packet energy entropy versus velocity at different positions

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表 1 实验工况及结果

Table 1. Experimental conditions and results

No.	d_p/ (mm)	t_b/ (mm)	v/ (km/s)	D_max/ (mm)	Damage of the rear wall
1	3.20	0.5	2.78	110	P
2	3.20	0.5	3.25	120	P
3	3.20	0.5	3.52	129	P
4	3.20	0.5	4.24	142	P
5	3.20	0.5	4.63	150	P
6	3.20	0.5	4.92	158	P
7	3.20	1.0	2.50	102	NP
8	3.20	1.0	3.05	126	P
9	3.20	1.0	3.65	133	NP
10	3.20	1.0	4.00	152	NP
11	3.20	1.0	4.45	159	NP
12	3.20	1.0	5.05	165	NP
13	3.20	1.5	2.81	120	NP
14	3.20	1.5	3.05	130	NP
15	3.20	1.5	3.73	148	NP
16	3.20	1.5	4.21	160	NP
17	3.20	1.5	4.46	165	NP
18	3.20	1.5	4.81	170	NP
19	3.97	1.0	2.65	120	P
20	3.97	1.0	3.25	138	P
21	3.97	1.0	3.57	148	P
22	3.97	1.0	4.15	160	NP
23	3.97	1.0	4.55	170	NP
24	3.97	1.0	4.85	180	NP
25	4.76	1.0	2.31	110	P
26	4.76	1.0	3.01	140	P
27	4.76	1.0	3.30	145	P
28	4.76	1.0	3.75	160	P
29	4.76	1.0	4.64	180	P
30	4.76	1.0	5.20	195	P
Note: P－Penetration in the rear wall, NP－No perforated point in the rear wall.

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参考文献(12)

[1]	Miyachi T, Hasebe N, Ito H, et al. Real-time detector for hypervelocity microparticles using piezoelectric material[J]. Adv Space Res, 2004, 34(5): 935-938. doi: 10.1016/j.asr.2003.11.019
[2]	Schäfer F, Janovsky R. Impact sensor network for detection of hypervelocity impacts on spacecraft[J]. Acta Astronaut, 2007, 61(10): 901-911. doi: 10.1016/j.actaastro.2007.02.002
[3]	Prosser W H, Gorman M R, Humes D H. Acoustic emission signals in thin plates produced by impact damage[J]. J Acoust Emiss, 1999, 17(1/2): 29-36.
[4]	唐颀, 庞宝君, 韩增尧, 等.单层板超高速撞击声发射波的频谱特征分析[J].宇航学报, 2007, 28(4): 1059-1064. Tang Q, Pang B J, Han Z Y, et al. Analysis of frequency spectrum character of acoustic emission wave from hypervelocity impact on single-sheet plate[J]. Journal of Astronautics, 2007, 28(4): 1059-1064. (in Chinese)
[5]	刘武刚, 庞宝君, 韩增尧, 等.基于声发射的单层铝板高速撞击损伤类型识别[J].宇航学报, 2011, 32(3): 671-675. Liu W G, Pang B J, Han Z Y, et al. Damage identification of single aluminum plate produced by hypervelocity impact based acoustic emission[J]. Journal of Astronautics, 2011, 32(3): 671-675. (in Chinese)
[6]	管永红, 胡八一, 黄超.基于小波包的爆炸容器振动分析[J].爆炸与冲击, 2010, 30(5): 551-555. Guan Y H, Hu B Y, Huang C. Vibration analysis of an explosion vessel based on wavelet packet transform[J]. Explosion and Shock Waves, 2010, 30(5): 551-555. (in Chinese)
[7]	凌同华, 廖艳程, 张胜.冲击荷载下岩石声发射信号能量特征的小波包分析[J].振动与冲击, 2010, 29(10): 127-130, 255. Ling T H, Liao Y C, Zhang S. Application of wavelet packet method in frequency band energy distribution of rock acoustic emission signals under impact loading[J]. Journal of Vibration and Shock, 2010, 29(10): 127-130, 255. (in Chinese)
[8]	管公顺, 庞宝君, 哈跃, 等.铝合金Whipple防护结构高速撞击实验研究[J].爆炸与冲击, 2005, 25(5): 461-466. Guan G G, Pang B J, Ha Y, et al. Experimental investigation of high-velocity impact on aluminum alloy Whipple shield[J]. Explosion and Shock Waves, 2005, 25(5): 461-466. (in Chinese)
[9]	Christiansen E L. Design and performance equations for advanced meteoroid and debris shields[J]. Int J Impact Eng, 1993, 14(1): 145-156.
[10]	唐颀.超高速撞击板波特性与声发射空间碎片在轨感知技术[D].哈尔滨: 哈尔滨工业大学, 2008: 56-76. Tang Q. Characteristics of plate waves induced by hypervelocity impact and onboard monitoring technique for detection of impact on spacecraft by space debris[D]. Harbin: Harbin Institute of Technology, 2008: 56-76. (in Chinese)
[11]	Rosso O A, Blanco S, Yordanova J, et al. Wavelet entropy: A new tool for analysis of short duration brain electrical signals[J]. J Neurosci Meth, 2001, 105(1): 65-75. doi: 10.1016/S0165-0270(00)00356-3
[12]	印欣运, 何永勇, 彭志科, 等.小波熵及其在状态趋势分析中的应用[J].振动工程学报, 2004, 17(2): 49-53. Yin X Y, He Y Y, Peng Z K, et al. Study on wavelet entropy and its applications in trend analysis[J]. Journal of Vibration Engineering, 2004, 17(2): 49-53. (in Chinese)