Finite Element Analysis for In-Plane Crushing Behaviour of Aluminium Honeycombs

A number of finite element simulations were performed to analyze the in-plane crushing behaviour of aluminium honeycombs and the results are presented and discussed. The simulations include both X1 and X2 cases. All the analyses are quasi-static, and can be divided into three groups, which are designed to investigate the effects of cell size, foil thickness and yield stress of the foil material, respectively, on the structural response of honeycombs. The result indicates that these factors can significantly affect the plateau stresses of honeycomb cellular structures in both directions, and the plateau stresses in X2 direction are slightly smaller than those in X1 direction. The simulation results were further compared with published theoretical predictions and show higher values. The difference was then analyzed and a new expression for the plateau stress of honeycombs was suggested.

基于电子顺磁共振波谱法的土壤环境持久性自由基的检测方法研究

本研究以不同类型土壤为研究对象,分别对电子顺磁/自旋共振波谱仪(EPR/ESR,X-波段连续波)的中心磁场、微波功率、调制幅度等主要测试参数进行调试与优选,确立EPR测定土壤环境持久性自由基(EPFRs)的仪器参数优选方法及参考值。结果表明,根据样品实测频率ν(约9.82 GHz)与EPFRs的g因子可设置谱仪中心磁场约3502 G。微波功率可采用微波功率饱和曲线法、微波衰减相邻6 dB信号比较法优选,两法各有优缺点,建议结合选用。若与27 dB相比,微波衰减设置为≤15 dB,低场峰(g=2.0030~2.0035)有由于功率饱和而引起其自旋浓度被不同程度抑制的趋势,并且27 dB左右(25~30 dB)被认为是该峰的较优微波衰减值。然而,高场峰(g=2.0004)对其响应存在差异,高衰减值为较佳。此外,调制幅度应小于峰-峰宽(3.28 G),若兼顾研究较窄峰(约1 G),1 G较为适宜。本EPR谱仪测试参数优选方法可确保g因子的准确度、EPR图谱的分辨率与超精细分裂等信息的可靠性,为土壤与环境固态样品EPFRs的测定提供科学依据,促进该项技术的应用与发展。

CNT对树脂基和金属基材料的力学增强性能对比

碳纳米管(CNT)不仅具有质量轻、强度高等优异的力学性能,而且化学性质稳定、耐酸碱腐蚀,因此被广泛应用于复合材料中.为探究不同基体中CNT力学增强差异的原因,对CNT增强树脂基和铝合金基两种复合材料进行了准静态拉伸、三点弯和动态冲击实验,进一步揭示了CNT在不同基体中的增强机制.研究结果表明:CNT可以有效提高树脂材料拉伸强度和冲击吸能,并且发现当CNT质量分数为0.7%时增强效果最佳;而对于铝合金,添加CNT会降低材料强度,并且CNT质量分数越高,材料拉伸强度越低.金属基和树脂基加入CNT后力学增强效果不同的本质在于CNT与基体的界面结合性不同,树脂基初始状态为液体,固化后CNT可以填充在基体网络缝隙中,进而增强材料力学性能;而铝合金基为粉体,机械力分散使CNT产生损伤且CNT的存在导致粉体间缝隙变大,进而削弱材料力学性能.研究成果可为CNT复合材料的制备与优化提供参考.