Preparation and microwave absorption performance of SiC aerogel via sol-gel and carbonization reduction process OA

SiC aerogel presents several advantageous features like lightweight and high temperature resistance when applied as microwave absorbing material.In this paper,SiC aerogel was prepared eventually followed by the sol-gel and carbonization reduction process.The results showed that the effective electromagnetic microwave absorption capacity of SiC aerogel was highly increased after being pyrolyzed at 1500℃,which presented a minimum reflection loss value of-57.80 dB at 3.10 mm and 9.86 GHz.Besides,the electromagnetic parameters of SiC aerogel with different paraffin ratios were discussed as well as the varying electromagnetic microwave absorption performances.The minimum reflection loss value first rose then fell as the SiC/paraffin ratio increased,which demonstrated the importance of SiC content.This study establishes the theoretical foundation for the subsequent functional application of SiC aerogel.

一种基于Al_(2)O_(3)/SiC气凝胶的热防护系统隔热性能研究

飞行器再入大气层时,高速气流的冲刷作用会在其表面产生极高热流密度和压力,这种双重载荷可能对飞行器的结构材料造成严重的热损伤,甚至导致飞行事故。针对该问题,文章设计了以Al_(2)O_(3)/SiC复合气凝胶作为隔热层的轻质三明治结构热防护系统,并通过氧−乙炔烧蚀试验对典型高温条件下该热防护系统的隔热性能进行测试,结果显示:热防护系统的线烧蚀率和质量烧蚀率随隔热层厚度的增加而逐渐减小,当系统厚度为14 mm时,线烧蚀率和质量烧蚀率分别为0.0019 mm·s^(-1)和0.0031 g·s^(-1),且烧蚀形貌整体性较好,说明热防护系统具有优异的隔热及力学性能。同时,通过有限元仿真方法对热防护系统进行热力耦合分析,对烧蚀试验结果进行了验证。

基于SiC气凝胶的热防护结构隔热性能分析及优化

针对高速飞行器长航时会面临非烧蚀型大面积热防护的问题,以SiC气凝胶作为隔热层的轻质防隔热一体化结构,考虑隔热材料热导率的温度相关性,建立瞬态传热模型。采用有限差分法中的Crank-Nicolson方法,计算并讨论了不同条件下结构的隔热性能,并与隔热层为陶瓷纤维隔热毡的结构进行对比,分析了SiC气凝胶在结构中的隔热特性及优势。进而对SiC气凝胶的厚度尺寸进行优化,求解在满足约束条件下SiC气凝胶的最小厚度。结果表明使用SiC气凝胶的热防护结构,在相同结构厚度下隔热能力提升约40%,在隔热效果相同时厚度降低约65%。通过与有限元分析软件的对比,证明了厚度优化设计的数值解法的准确性。

纤维素气凝胶骨架负载SiC提升环氧复合材料非线性电导特性与热力学特性

掺杂SiC颗粒的聚合物材料可以表现出优异的非线性电导特性,并广泛应用于电场梯度材料。然而,由于非线性复合材料中填料含量较高,优异的非线性电导特性以牺牲机械特性为代价。因此,如何在极低SiC填充量下实现非线性电导特性和机械特性的协同优化对实际工程应用而言尤为重要。该文首先利用硅烷偶联剂对SiC进行表面改性,然后在纤维素气凝胶骨架上成功实现自组装,并通过真空辅助浸渍法制备了非线性电导环氧复合材料,实现了其导热性能、机械性能和非线性电导特性的协同提升。研究结果表明:该复合材料在极低SiC填充量下(体积分数4.47%)表现出优异的非线性电导特性,且不同SiC体积分数下纤维素气凝胶骨架负载的SiC/环氧复合材料可以大大拓宽开关场阈值的范围。在体积分数10.58%下,该复合材料阈值场强为2.49 kV/mm,非线性系数为4.54。同时,导热特性和动态热机械特性测试表明,由于相互连接的3D结构,新型复合材料储能模量提高约100%,交联密度高达15.9×10^(–3 )mol/cm^(3),热导率提升至0.69 W/(m·K)。该方法为制备具有优异热力学性能的电场梯度复合材料提供了新的思路。

SiC掺杂改性SiO_(2)气凝胶的制备及其隔热性能研究

以正硅酸乙酯和甲基三乙氧基硅烷为共聚硅源,加入干燥控制化学添加剂N,N-二甲基甲酰胺,酸催化制备硅溶胶,并添加遮光剂SiC,混合均匀后在碱性条件下老化得到SiC掺杂改性双硅源体系SiO_(2)溶胶,再利用疏水改性、溶剂交换等后处理工艺,常压干燥得到SiC掺杂改性SiO_(2)气凝胶。考察了双硅源体系SiO_(2)气凝胶的组织性能、表面形貌、物质构成和孔结构等,进一步分析了不同SiC掺杂量和温度条件对SiO_(2)气凝胶隔热性能的影响。结果表明,SiC掺杂改性双硅源体系SiO_(2)气凝胶的导热系数在700℃条件下可低至0.0482W/(m·K),且具有良好的高温隔热性能。

类气凝胶结构的碳-碳化硅制备研究

以酚醛树脂和正硅酸乙酯为先驱物,甲酰胺为助溶剂,硫酸为催化剂,经过溶胶-凝胶过程和碳热还原过程,在常压条件下,得到碳-碳化硅(C-SiC)类气凝胶。对样品进行透射电镜(TEM)、傅里叶变换红外光谱分析(FTIR)、X射线粉末衍射法(XRD)、热重分析(TG)以及N2吸附-脱附(BET法)等表征。结果表明,在氩气保护并经1800℃热处理,所得样品具有类似气凝胶的骨架结构,由粒径均小于50nm的C-SiC颗粒连接构成,平均孔径尺寸约为100nm,对N2的吸附、脱附呈现Ⅱ型孔结构特征。

Ultralight and hyperelastic SiC nanofiber aerogel spring for personal thermal energy regulation

Multifunctionalization is the development direction of personal thermal energy regulation equipment in the future.However,it is still a huge challenge to effectively integrate multiple functionalities into one material.In this study,a simple thermochemical process was used to prepare a multifunctional SiC nanofiber aerogel spring(SiC NFAS),which exhibited ultralow density(9 mg/cm3),ultralow thermal conductivity(0.029 W/(m·K)at 20℃),excellent ablation and oxidation resistance,and a stable three-dimensional(3D)structure that composed of a large number of interlacing 3C-SiC nanofibers with diameters of 300–500 nm and lengths in tens to hundreds of microns.Furthermore,the as-prepared SiC NFAS displayed excellent mechanical properties,with a permanent deformation of only 1.3%at 20℃after 1000 cycles.Remarkably,the SiC NFAS exhibited robust hyperelasticity and cyclic fatigue resistance at both low(~-196℃)and high(~700℃)temperatures.Due to its exceptional thermal insulation performance,the SiC NFAS can be used for personal thermal energy regulation.The results of the study conclusively show that the SiC NFAS is a multifunctional material and has potential insulation applications in both low-and high-temperature environments.

SiO_2气凝胶复合材料隔热性能实验研究

SiO_2气凝胶复合材料是一种隔热性能优异的纳米多孔材料,本文对非稳态和大温差条件下该材料的隔热性能进行了实验研究,分析了SiC颗粒和SiO_2中空玻璃球对材料隔热性能的影响。研究发现:微米级SiC颗粒具有良好的遮光能力;添加一定含量的微米级SiO_2中空玻璃有利于改善材料的隔热性能,但添加量过大会导致气相导热的贡献增加,从而使得材料隔热性能下降。