功能材料
功能材料
공능재료
JOURNAL OF FUNCTIONAL MATERIALS
2012年
10期
1299-1302
,共4页
复合材料%电磁场效应%数值模拟%材料微结构%Poynting矢量
複閤材料%電磁場效應%數值模擬%材料微結構%Poynting矢量
복합재료%전자장효응%수치모의%재료미결구%Poynting시량
composites%electromagnetic field effect%numerical simulation%material microstructure%Poynting vec- tor
为了解决现有数值模拟方法不能计算叠层复合材料分层吸收率、分层反射率及多角度反射率的问题,借助可以表征能量流动方向和大小的Poynting矢量,按研究项目要求建立了由碳纤维、石墨颗粒和聚苯乙烯树脂组成的叠层复合材料微结构有限元模型,通过程序设计结合有限元数值模拟的方法实现了电磁场效应的计算。结果表明,所设计的叠层复合材料在宽频范围内具有稳定的电磁场效应。在工作频率2~18GHz范围内,该结构吸收率高达50%以上,而垂直反射率只有10%左右。斜反射率随反射角度增大而减小。迎波第一层的吸收率和反射率均大于第二层。数值模拟结果满足研究项目要求。研究方法对任意叠层材料微结构均具有适用性。
為瞭解決現有數值模擬方法不能計算疊層複閤材料分層吸收率、分層反射率及多角度反射率的問題,藉助可以錶徵能量流動方嚮和大小的Poynting矢量,按研究項目要求建立瞭由碳纖維、石墨顆粒和聚苯乙烯樹脂組成的疊層複閤材料微結構有限元模型,通過程序設計結閤有限元數值模擬的方法實現瞭電磁場效應的計算。結果錶明,所設計的疊層複閤材料在寬頻範圍內具有穩定的電磁場效應。在工作頻率2~18GHz範圍內,該結構吸收率高達50%以上,而垂直反射率隻有10%左右。斜反射率隨反射角度增大而減小。迎波第一層的吸收率和反射率均大于第二層。數值模擬結果滿足研究項目要求。研究方法對任意疊層材料微結構均具有適用性。
위료해결현유수치모의방법불능계산첩층복합재료분층흡수솔、분층반사솔급다각도반사솔적문제,차조가이표정능량류동방향화대소적Poynting시량,안연구항목요구건립료유탄섬유、석묵과립화취분을희수지조성적첩층복합재료미결구유한원모형,통과정서설계결합유한원수치모의적방법실현료전자장효응적계산。결과표명,소설계적첩층복합재료재관빈범위내구유은정적전자장효응。재공작빈솔2~18GHz범위내,해결구흡수솔고체50%이상,이수직반사솔지유10%좌우。사반사솔수반사각도증대이감소。영파제일층적흡수솔화반사솔균대우제이층。수치모의결과만족연구항목요구。연구방법대임의첩층재료미결구균구유괄용성。
In order to solve the problem that the present research method of numerical simulation can not calcu- late the layered absorptivity, layered reflectivity and the multi angle reflectivity of laminated composites, the fi- nite element model of laminated composites microstructure was therefore established, which was composed of carbon fibers, graphite particles and polystyrene meeting the requirement of research program, making use of Poynting vector which characterizes the direction and size of energy flow. By combining the program design and finite element method (FEM), the calculation of electromagnetic field effect were thus realized. Research results show that the designed laminated composites have a stable electromagnetic field effect in a wide frequency range: in the work frequency ranging from 2GHz to 18GHz, the absorptivity of the laminated composites could reach as high as 50%, while the normal reflectivity reaches only 10%. The oblique reflectivity decreases as the reflection angle increases. The absorptivity as well as the reflectivity of the first layer is much larger than the second layer. The results of numerical simulation meet the requirements set by the research program. The re- search method is applicable for any laminated composites microstructures.