Ignition processes and characteristics of charring conductive polymers with a cavity geometry in precombustion chamber for applications in micro/nano satellite hybrid rocket motors

The arc ignition system based on charring polymers has advantages of simple structure,low ignition power consumption and multiple ignitions,which bringing it broadly application prospect in hybrid propulsion system of micro/nano satellite.However,charring polymers alone need a relatively high input voltage to achieve pyrolysis and ignition,which increases the burden and cost of the power system of micro/nano satellite in practical application.Adding conductive substance into charring polymers can effectively decrease the conducting voltage which can realize low voltage and low power consumption repeated ignition of arc ignition system.In this paper,a charring conductive polymer ignition grain with a cavity geometry in precombustion chamber,which is composed of PLA and multiwall carbon nanotubes(MWCNT)was proposed.The detailed ignition processes were analyzed and two different ignition mechanisms in the cavity of charring conductive polymers were revealed.The ignition characteristics of charring conductive polymers were also investigated at different input voltages,ignition grain structures,ignition locations and injection schemes in a visual ignition combustor.The results demonstrated that the ignition delay and external energy required for ignition were inversely correlated with the voltages applied to ignition grain.Moreover,the incremental depth of cavity shortened the ignition delay and external energy required for ignition while accelerated the propagation of flame.As the depth of cavity increased from 2 to 6 mm(at 50 V),the time of flame propagating out of ignition grain changed from 235.6 to 108 ms,and values of mean ignition delay time and mean external energy required for ignition decreased from 462.8 to 320 ms and 16.2 to 10.75 J,respectively.The rear side of the cavity was the ideal ignition position which had a shorter ignition delay and a faster flame propagation speed in comparison to other ignition positions.Compared to direct injection scheme,swirling injection provided a more favorable flow field environment in the cavity,which was beneficial to ignition and initial flame propagation,but the ignition position needed to be away from the outlet of swirling injector.At last,the repeated ignition characteristic of charring conductive polymers was also investigated.The ignition delay time and external energy required for ignition decreased with repeated ignition times but the variation was decreasing gradually.

Generation of micro/nano hybrid surface structures on copper by femtosecond pulsed laser irradiation

The delamination of copper lead frames from epoxy molding compounds(EMC)is a severe problem for microelectronic devices,as it leads to reduced heat dissipation or circuit breakage.The micro/nanoscale surface structuring of copper is a promising method to improve the copper-EMC interfacial adhesion.In this study,the generation of micro/nano hybrid structures on copper surfaces through femtosecond pulsed laser irradiation is proposed to improve interfacial adhesion.The micro/nano hybrid structures were realized by generating nanoscale laser-induced periodic surface structures(LIPSS)on microscale parallel grooves.Several types of hybrid surface structures were generated by changing the laser polarization direction,fluence,and scanning speed.At a specific aspect ratio of microgrooves,a latticed structure was generated on the sides of microgrooves by combining LIPSS formation and direct laser interference patterning.This study provides an efficient method for the micro/nanoscale hybrid surface structure formation for interfacial adhesion improvement between copperand EMC.

Preparation and characterization of biodegradable aliphatic-aromatic copolyesters/nano-SiO_2 hybrids via in situ melt polycondensation

In situ melt polycondensation was proposed to prepare biodegradable aliphatic-aromatic copolyesters/nano-SiO2 hybrids based on terephthalic acid （TPA）, poly（L-lactic acid） oligomer （OLLA）, 1,4-butanediol （BDO） and nano-SiO2. TEM and FT-IR characterizations confirmed that TPA, OLLA and BDO copolymerized to obtain biodegradable copolyesters, poly（butylene terepbthalate-co-lactate） （PBTL）, and the abundant hydroxyl groups on the surface of nano-SiO2 provided potential sites for in situ grafting with the simultaneous resulted PBTL. The nano-SiO2 particles were chemically wrapped with PBTL to form PBTL/nano- SiO2 hybrids. Due to the good dispersion and interfacial adhesion of nano-SiO2 particles with the copolyester matrix, the tensile strength and the Young＇s modulus increased from 5.4 and 5.6 MPa for neat PBTL to 16 and 390 MPa for PBTL/nano-SiO2 hybrids with 5 wt.% nano-SiO2, respectively. The mechanical properties of PBTL/nano-SiO2 hybrids were substantially improved.

Preparation and Characterization of Organic/Inorganic Hybrid Nanofibers

A new class of nanocomposites based on organic and inorganic species integrated at a nanoscale has obtained more attention these years. Organic-inorganic hybrids have both the advantages of organic materials, such as light weight, flexibility and good moldability, and inorganic materials, such as high strength, heat stability and chemical resistance. In this work, PVAc/TiO2 organicinorganic hybrid was prepared by sol-gel process. Eiectrospinning technique was used to fabricate PVAc/TiO2 hybrid nanofibers. The structures and properties of the hybrid nanofibers were characterized by Scanning Electron Microscopy （SEM）, Atomic Force Microscope （AFM）, Differential Scanning Calorimeter （DSC） and Fouriertransform infrared （FTIR） spectra. SEM and AFM were employed to study the topography of the hybrid nanofibers. The chemical structure of the hybrid nanofibers were examined by FTIR. The DSC scans revealed the second order transition temperature of the hybrid materials were higher than PVAc.

Sliding Wear of the Hybrid Kevlar/PTFE Fabric Reinforced Phenolic Composite Filled with Nano-titania

The Kevlar/polytetrafluroethylene（Kevlar/PTFE） fabric composite can be used as a self-lubricating liner of the self-lubricating bearing.Many types of nano-particles can improve the tribological performance of the polymer-based composite.Unfortunately,up to now,published work on the effect of nano-particles on the tribological performance of the fabric composite which can be used as a self-lubricating liner is quite scarce.Therefore,for the purpose of exploring a way to significantly improve the tribological performance of the fabric composite,the tribological performance of the Kevlar/PTFE fabric composite filled with nano-titania is evaluated by using the block-on-ring wear tester.The scanning electron microscopy is utilized to observe the morphologies of worn surfaces of the fabric composites and the counterparts.The tensile properties of the composites are evaluated on the universal material testing machine.The test results show that the addition of nano-titania at a proper mass fraction of the matrix resin improves the wear resistance and the tensile strength,decreases the friction coefficient,and makes the wear volume of the composite reach a relative steady state more quickly;plastic deformation and microcutting are important for the wear of the fabric composite;a lubricating layer is formed on the worn surface of the composite during sliding,and the lubricating layer is critical for the tribological performance of the composite;the formation and properties of the lubricating layer are influenced by the nano-titania particles.The proposed study on the effect of nano-titania on the tribological performance of the Kevlar/PTFE fabric composite,especially on the evolution of the worn surface of the composite,provides the basis for further understanding of the influence mechanism of the nano-particles on the tribological performance of the composite and explores a method of improving the tribological performance of the composite.

Nano-SiO_2表面处理及原位聚合法制备PI/Nano-SiO_2杂化膜

对Nano-SiO2进行两次表面处理,然后进行原位聚合制备聚酰胺酸/Nano-SiO2悬浮液,涂膜并热亚胺化得到PI/Nano-SiO2杂化膜。对Nano-SiO2的表面处理效果进行评价,对聚酰胺酸/Nano-SiO2悬浮液的稳定性、PI/Nano-SiO2杂化膜的性能进行测试。结果表明:Nano-SiO2的二次表面处理均为化学键合;聚酰胺酸/Nano-SiO2悬浮液稳定时间达到60 d,并获得了性能优异的PI/Nano-SiO2杂化膜。

PVA/nano-TiO_2杂化膜的制备与碱回收性能研究

利用γ-巯丙基三乙基硅烷（γ-MPTS）对纳米氧化钛颗粒（p-TiO2）进行了表面修饰引入巯基（—SH）,采用双氧水氧化的方法制备了表面带有—SO3H的纳米氧化钛颗粒（sTiO2）.利用溶液共混的方式将s-TiO2和预交联的PVA溶液混合后涂覆成膜,制备了一系列PVA/nano-TiO2有机-无机杂化膜.对杂化膜的结构测试结果表明其具有良好的机械稳定性,热稳定性和耐碱性：拉伸强度为37.0~53.4MPa,断裂伸长率为43.2%~146.0%;65℃碱液中的溶胀度为205.4%~220.2%,质量损失为10.0%~15.9%.制备的杂化膜含水量（WR）为90.9%~105.6%,离子交换容量（IEC）为0~0.025mmol/g.利用NaOH/Na2WO4体系模拟扩散渗析回收NaOH的结果表明：25℃时OH-渗析系数为0.013~0.015m/h,分离系数为21.8~30.1.

Functional micro‐concrete 3D hybrid structures f abricated by two‐photon polymerization

Arbitrary micro-scale three-dimensional(3D)structures fabrication is a dream to achieve many exciting goals that have been pursued for a long time.Among all these applications,the direct 3D printing to fabricate human organs and integrated photonic circuits are extraordinary attractive as they can promote the current technology to a new level.Among all the 3D printing methods available,two-photon polymerization(2PP)is very competitive as it is the unique method to achieve sub-micron resolution to make any desired tiny structures.For the conventional 2PP,the building block is the photoresist.However,the requirement for the building block is different for different purposes.It is very necessary to investigate and improve the photoresist properties according to different requirements.In this paper,we presented one hybrid method to modify the mechanical strength and light trapping efficiency of the photoresist,which transfers the photoresist into the micro-concretes.The micro-concrete structure can achieve±22%strength modification via a silica nano-particles doping.The structures doped with gold nano-particles show tunable plasmonic absorption.Dye doped hybrid structure shows great potential to fabricate 3D micro-chip laser.

Nanodiamond for Structural Biomimetic Scaffolds

Bio-mechanically active scaffolds for tissue engineering combining hydrophilic polymeric matrix and nano-diamond fillers properties are presented and discussed in this paper. The resulting scaffolding materials revealed re-markable mechanical and biological properties to be exploited in advanced biomedical applications. The novel hybrid material is based on 2 and 5 vol-ume % of detonation nano-diamond particles in a hydrophilic poly-(hydroxyl- ethyl-methacrylate) matrix. According to its mechanical and biological properties, the nanocomposite shows a hybrid nature. The base analytical procedures for the preparation of the hybrid nanocomposites and some preliminary mechanical characteristics are presented. The proposed hybrid system has been considered for potential biomimetic, osteoconductive and osteoinductive scaffolds application in bio-mechanically active bone scaffolds for osteoblast, and stem cell differentiation and growth. These more rigid hybrid nano-composites are predicted to possess improved mechanical strength overcoming the mechanical weaknesses of traditional hydrogels clinically utilized for bone regeneration.

电子封装高温焊料研究新进展

随着先进封装和第三代半导体的快速发展,具有高熔化温度、耐持久温度考验的高温焊料逐渐成为学界追逐的热点,也成为推动电子产业无铅化和升级换代等“卡脖子”问题的瓶颈。本文综述了传统高温Sn-80Au和Pb-Sn焊料、IMC焊料、纳米及纳米-微米混合焊料,提出未来高温焊料在成分上必将以金、银、铜、铝等金属或石墨烯、碳纳米管等轻质、高导热、高熔化温度的碳基材料及其复合材料为主流;在微观尺度上,纳-微米混合焊料既具有纳米焊料的温度效应,又具有颗粒选择的灵活性,能在一定程度上解决纳米焊料的氧化、团聚及烧结时的相转变等问题;基于颗粒焊料的多尺度、颗粒种类选择的多维度,具有低温快速制备、高温长期服役的IMC高温焊料也具有极大的前途。加速高温焊料研发,突破低温封装、高温服役的技术瓶颈,必将极大推动先进封装和功率封装的快速发展。

多元混合体系增强再生混凝土力学性能及体系优化

本研究通过向再生混凝土中掺入纳米SiO_(2)(NS)、玄武岩纤维(BF)和聚丙烯纤维(PPF)的不同组合,开展力学性能试验,研究了不同组合对再生混凝土力学性能的影响,同时基于响应面法建立了BF-PPF二元混合体系和NS-BF-PPF三元混合体系下的强度回归模型。研究结果表明:混合体系对再生混凝土力学性能的增强效果较好,且三元混合体系优于二元混合体系。NS-BF-PPF形成的三维网状支撑结构在多尺度上对再生骨料和新水泥砂浆的孔隙结构进行了填充与增强,并延缓了开裂过程,增强了力学性能。0.3%BF-0.3%PPF二元混合体系下抗压强度和劈裂抗拉强度分别为49.12 MPa和3.48 MPa,较基准组和单掺纤维体系有明显提升。三元混合体系下,3.5%NS对抗压强度提升最高为6.37 MPa;2.5%NS-0.5%BF-0.1%PPF混掺时劈裂抗拉强度达到最高,为3.77 MPa。为使回归模型中抗压强度和劈裂抗拉强度最大,二元混合体系下BF和PPF的最优体积率分别为0.306%和0.3%,三元混合体系下NS、BF和PPF的最优掺量分别为3.5%、0.452%和0.1%。

天然橡胶有机纳米复合材料的研究现状

综述了有机生物纳米填料、混合纳米填料与天然橡胶(NR)的复合材料的制备方法,以及各类有机纳米材料及其改性对NR拉伸性能、热稳定性和导电性等补强的研究现状。所述有机纳米填料与聚合物基体之间良好的相容性及界面作用能够使NR的性能得到明显改善。经功能化改性后的有机纳米填料可更好与NR基体产生相互作用,给NR的性能带来更优异的补强效果,而混合纳米填料可赋予复合材料更为多样的功能性。同时探讨了NR纳米复合材料在未来的应用发展前景,开发出多种功能化的有机纳米填料及使用混合纳米填料制备性能多样的NR纳米复合材料是该领域未来的研究重点。

折/衍混合光学系统在纳型星敏感器中的应用

微纳卫星是一种新兴的微小卫星,与之适配的纳型星敏感器的光学系统应在小型化的同时实现大相对孔径、高成像质量。针对这一需求,由星敏感器的系统设计精度和探测星等分配了光学系统设计参数及指标,设计了一种全视场17°、焦距25 mm、相对孔径1∶1.086、光学系统总长36.4 mm的七片式折衍混合结构的星敏感器光学系统。根据衍射元件的负色散特性,用折衍混合透镜代替常规材料正负透镜组合的方式减少了镜片数量,缩短了光学系统长度,并提高了光学系统的成像质量,使点扩散函数趋于正态分布,有利于质心提取精度的提高。所设计的光学系统在3×3像元内的能量集中度超过90%;最大畸变仅0.013%;全视场垂轴色差小于0.6μm。通过标量衍射理论计算衍射元件在520~780 nm内衍射效率可以达80%以上,通过杂散光分析软件ASAP对系统进行了视场内鬼像分析,系统在多级衍射时探测目标成像光斑路径下的光通量与最亮鬼像光斑路径下的光通量之比大于3.17×10^(4),验证了在极限星等为6.5时满足信噪比大于8.1的结论。最后对所设计的系统进行了公差分析,结果表明加工后该光学系统可满足微纳卫星对星敏感器的使用要求。

纳米羟基磷灰石掺杂PET纤维基肌腱肩袖补片及其体外生物矿化研究

市售人工肌腱-韧带移植物大多采用聚对苯二甲酸乙二醇酯(PET)纤维作为基体材料,但因PET缺乏骨诱导活性易导致腱-骨愈合差的问题。本文采用促骨活性功能粒子——纳米羟基磷灰石(nano-HAp)作为功能组分,借助纳米杂化熔融纺丝技术制备系列nano-HAp负载量的PET/HAp杂化纤维,然后采用机织技术制备了补片形式的PET/HAp杂化纤维基移植物,从形貌、结构、力学性能、细胞相容性等方面系统研究了nano-HAp的引入对PET/HAp杂化材料的影响。结果表明:借助双螺杆共混造粒和复配熔融纺丝工艺,成功制得系列有效负载nano-HAp(0%,0.5%和1.5%(质量分数))的PET/HAp杂化纤维,但因其与PET的相容性较差,nano-HAp添加量为质量分数1.5%时,PET/HAp纤维的力学性能和结晶度明显降低,但制备的杂化纤维断裂强度(≥3 cN/dtex)均满足机织要求;利用PET/HAp杂化纤维编织的补片,其断裂强度((34.6±0.9)MPa)满足替代人体天然肌腱组织(肩袖)的力学强度;体外与成骨细胞(MC3T3-E1)的共培养实验表明,PET/HAp杂化纤维基补片(Patch)具有良好的细胞相容性;体外矿化实验表明,nano-HAp的加入可有效提高纤维基补片上矿化物的沉积,其中nano-HAp负载量为质量分数1.5%杂化纤维所织的补片(Patch-1.5)具有最佳的矿化沉积性能,因此,PET/HAp杂化纤维有望用于促进肌腱韧带修复中的腱-骨愈合。

原位溶胶-凝胶法制备光固化3D打印大豆油基杂化材料及其性能分析

以2.7官能度大豆油多元醇(SBOP)与甲基丙烯酸乙酯二异氰酸酯(MOI)为原料,成功制备了2.7官能度可自由基光固化的大豆油基光敏树脂SBO-2.7A。将SBO-2.7A作为基体树脂,通过添加一定比例活性稀释剂丙烯酸羟乙酯(HEA),制备出了3D打印大豆油基光敏树脂。通过原位溶胶-凝胶法,将不同正硅酸乙酯(TEOS)添加量的大豆油基打印树脂配方进行3D打印成型,优选出最佳的酸性蒸汽后处理条件后,最终制备出具有机械性能提高的打印大豆油基材料。通过红外光谱仪、电子显微镜、哈克旋转流变仪、拉伸试验机等对3D打印树脂的黏度、光固化行为及其对3D打印样品的热力学性能、机械性能等的影响进行分析,结果表明,原位溶胶-凝胶法生成纳米SiO2使得3D打印制品拉伸性能、储能模量均得到提高,其中拉伸强度由起始的9.96 MPa增加到了14.14 MPa,提高了42%;储能模量由293 MPa提高至567 MPa,提高了93.5%。

无机组分对聚酰亚胺杂化薄膜电性能的影响

初步探讨了聚酰亚胺薄膜在电场作用下的电学行为,采用溶胶-凝胶工艺制备了聚酰亚胺/二氧化硅纳米杂化薄膜,并对薄膜进行浸水24h处理,利用原子力显微镜对制备的薄膜进行表面形貌表征,讨论了无机组分SiO2和水对薄膜电性能的影响.结果表明:无机组分的引入及两相间的界面形态将对杂化薄膜的电学性能产生重大的影响;偶联剂的引入使得两相间产生紧密的微相结合,并对电性能产生一定的影响.

水性聚氨酯/SiO_2纳米杂化物改性水性聚氨酯涂膜性能研究

采用溶胶-凝胶法制备出水性聚氨酯(WPU)/SiO2纳米杂化物(WPUS),将WPUS和水性聚氨酯乳液复配制得复合涂膜。通过纳米粒度仪测定了WPUS及不同WPUS含量复合乳液的粒径及其分布;通过原子力显微镜(AFM)、紫外-可见光分光光度计、拉伸实验机、视频高速接触角测量仪和吸水率测试等研究了不同WPUS含量复合涂膜的微观形貌和性能。结果表明:随WPUS含量增大,复合乳液的平均粒径和多分散指数(PDI)逐渐增大,但都保持在100 nm以内;随着WPUS含量从2%增大到10%,涂膜的表面粗糙度增大、SiO2分布变得不均匀,拉伸强度、断裂伸长率都表现出先增大后减小的趋势,在WPUS含量为4%～6%时具有最佳的力学性能;加入WPUS后,复合膜的耐水性提高、透光率减小,但透光率都保持在90%以上,其中700 nm处透光率表现出先减小后增大的趋势。

溶胶凝胶法在聚合物/无机纳米复合材料中的应用

本文对溶胶凝胶法在聚合物 无机纳米复合材料中的应用进行了综述。并对溶胶凝胶法在橡胶增强、光学仪器、功能化涂层以及其它领域中的应用进行了具体的讨论。指出溶胶凝胶过程工艺条件的优化以及分散介质范围的扩大将是溶胶凝胶法在聚合物 无机纳米复合材料中应用的发展方向。

纳米TiO_2改性明胶在合成革后整理中的应用

采用原位有机-无机杂化技术将纳米TiO2引入明胶体系,制备了纳米TiO2的改性蛋白材料,通过扫描电镜(SEM)发现,原位生成的TiO2颗粒直径都在100 nm左右,相对未经改性的明胶具有良好的耐热稳定性。将改性明胶应用于合成革的后整理中,且与传统酪素涂饰的成革在透湿性、表面接触角和抗菌性能等方面的比较研究,结果表明:加入改性明胶涂饰后的成革的透湿性与酪素涂饰后的成革相当;并且由于改性明胶亲水基团的增加,表面接触角与酪素的相当,降低了表面张力,改善了再涂性;经改性明胶涂饰后的合成革还具有良好的抗菌性,这是酪素所不具备的。充分说明改性明胶可以取代酪素在合成革后整理中的应用。另外,改性明胶价格低廉、易于制备,这对促进行业技术进步,提高企业经济效益都有积极的意义。

高模量、低热膨胀系数聚酰亚胺杂化薄膜的制备

通过在聚酰胺酸中加入正硅酸乙酯(TEOS)和硅烷偶联剂(KH550),制备了不同SiO_2含量的PI/SiO_2杂化薄膜。采用FTIR、TMA、SEM以及TGA分析了PI/SiO_2杂化薄膜的性能和结构。结果表明,TEOS经水解缩合与聚酰亚胺(PI)形成了有机-无机杂化网络结构,SiO_2均匀分散在聚酰亚胺基体中;SiO_2和偶联剂的引入提高了杂化薄膜的热稳定性;随着SiO_2含量的增加,PI/SiO_2杂化薄膜的拉伸强度降低,但当SiO_2含量达到20%时,弹性模量增大到3.4GPa。