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2222材料工程  2017, Vol. 45 Issue (11): 10-14    DOI: 10.11868/j.issn.1001-4381.2016.000152
  研究论文 本期目录 | 过刊浏览 | 高级检索 |
“超材料”结构吸波复合材料技术研究
礼嵩明1,2, 蒋诗才1,2, 望咏林3, 顾涧潇1,2, 邢丽英1,2,*()
1 中航工业复合材料技术中心, 北京 100095
2 中国航发北京航空材料 研究院 先进复合材料重点实验室, 北京 100095
3 中国航发北京航空 材料研究院, 北京 100095
Study on "Metamaterial" Structural Absorbing Composite Technology
Song-ming LI1,2, Shi-cai JIANG1,2, Yong-lin WANG3, Jian-xiao GU1,2, Li-ying XING1,2,*()
1 AVIC Composite Technology Center, Beijing 100095, China
2 Science and Technology on Advanced Composites Laboratory, AECC Beijing Institute of Aeronautical Materials, Beijing 100095, China
3 AECC Beijing Institute of Aeronautical Materials, Beijing 100095, China
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摘要 

研究了"超材料"结构吸波复合材料的制备技术及其力学性能与电性能。通过突破不同尺寸金属周期结构单元制备、金属周期结构单元转移、含金属周期结构单元吸波复合材料工艺参数优化等关键技术,制备出电性能和力学性能批次间稳定性良好的含多层金属周期结构单元的"超材料"结构吸波复合材料,"超材料"结构吸波复合材料在2~18GHz频率范围具有宽频高吸收的特性。

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礼嵩明
蒋诗才
望咏林
顾涧潇
邢丽英
关键词 超材料结构吸波复合材料力学性能吸波性能    
Abstract

The process technology and the mechanical and electrical properties of the "metamaterial"structural absorbing composites were studied, in which metal periodic structure units were produced on the organic carrier film and then combined with medium. Through the breakthrough of key technologies involving producing different size metal periodic structure, the transfer of metal periodic structure, and optimizing process parameters, the "metamaterial" structural absorbing composite with good wave-absorbing and mechanical stabilities that contained multi-layer metal periodic structure was prepared. The "metamaterial" structural absorbing composite has a high broadband absorbing property in the frequency range of 2-18GHz.

Key wordsmetamaterial    structural absorbing composite    mechanical property    microwave absorbing property
收稿日期: 2016-01-31      出版日期: 2017-11-18
中图分类号:  TB332  
基金资助:国家973课题资助项目(2011CB013403)
通讯作者: 邢丽英     E-mail: vcd4321@sina.com
作者简介: 邢丽英(1965-), 女, 研究员, 博士, 主要从事树脂基复合材料领域研究, 联系地址:北京市81信箱3分箱(100095), E-mail:vcd4321@sina.com
引用本文:   
礼嵩明, 蒋诗才, 望咏林, 顾涧潇, 邢丽英. “超材料”结构吸波复合材料技术研究[J]. 材料工程, 2017, 45(11): 10-14.
Song-ming LI, Shi-cai JIANG, Yong-lin WANG, Jian-xiao GU, Li-ying XING. Study on "Metamaterial" Structural Absorbing Composite Technology. Journal of Materials Engineering, 2017, 45(11): 10-14.
链接本文:  
http://jme.biam.ac.cn/CN/10.11868/j.issn.1001-4381.2016.000152      或      http://jme.biam.ac.cn/CN/Y2017/V45/I11/10
Fig.1  “超材料”结构吸波复合材料示意图
Solvent type Condition Result
95%CH3CH2OH 25℃,15min No damage
CH3COH3 25℃,15min Slight corrosion
18%HCl 40℃,30min No damage
1mol/L CuCl2 40℃,30min No damage
1mol/L NaOH 40℃,30min Slight corrosion
Table 1  有机载体膜耐溶剂实验结果
Infrared heat treatment temperature/℃ Plating power/
kW
Result
Room temperature 9 Completely fallen off
100 9 Partly fallen off
150 9 No fallen off
200 9 Partly fallen off
300 9 Partly fallen off
Table 2  红外热处理温度对附着力的影响
Plasma treatment power/kW Plating power/
kW
Result
0 9 Completely fallen off
0.6 9 Partly fallen off
1.2 9 No fallen off
1.5 9 Partly fallen off
2.0 9 Partly fallen off
Table 3  等离子体处理功率对附着力的影响
Fig.2  边长为6mm的金属周期结构单元
Pretreatment time/h State of absorbent migration
0.5 Absorbent covered about 90% area
1.5 Absorbent covered about 50% area
2.0 Absorbent covered about 30% area
2.5 No absorbent migration
3.0 No absorbent migration
Table 4  预处理时间对吸收剂迁移的影响
Fig.3  “超材料”结构吸波复合材料
Absorbing composite type Batch Tensile strength/
MPa
Tensile modulus/
GPa
Compressive strength/
MPa
Compressive modulus/
GPa
Bending strength/
MPa
Bending modulus/
GPa
Interlaminar shear strength/
MPa
No periodic structure 583 29.0 232 27.9 477 25.8 37.38
Multi-layer 1 568 28.7 226 27.7 479 25.9 37.00
periodic structure 2 564 29.3 228 28.3 477 25.5 36.58
Table 5  不同吸波复合材料室温力学性能测试结果
Fig.4  不同吸波复合材料的吸波性能(厚度5mm)
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