Thermal and Mechanical Properties of Isotactic Polypropylene/TiO_2 Particulate Composites

Particulate composites based on isotactic polypropylene(iPP) and titanium dioxide(TiO 2) have been prepared and their morphology and thermal behavior investigated by scanning electron microscopy(SEM), differential scanning calorimetry(DSC) and thermogravimetric analysis(TGA). Tensile tests were performed to assess the influence of TiO 2 on the mechanical properties of the iPP.

Electrical Properties and Applications of (ZrO_2)_(0.92)(Y_2O_3)_(0.08) Electrolyte Thin Wall Tubes Prepared by Improved Slip Casting Method

mole fraction) yttria-stabilized zirconia electrolyte thin wall tubes were p repared by i mproved slip casting method. The length and wall thickness of the tubes are 266 mm and 0.4～0.9 mm, respectively and the relative density is 96.7%. The microstr ucture and electrical properties of samples sintered at different temperatures w ere studied using SEM and ac impedance spectroscopy. The effect of sintered dens ity, grain and grain boundary on the electrical properties of the samples was analyzed. The research results show that the density of the samples increase s gradually with increasing sintering temperatures. The microstructure of sample s strongly influences its electrical properties, and the electrical properti es of samples enhance with the increase of sintered density. The ionic conductiv ity of grain and grain boundary is increased as the sintering temperature incre ases. Better sinterability of the samples was obtained at the sintering temperat ure of 1650 ℃. The maximum open circuit voltage and short circuit current for s ingle cell is 0.946 V and 1.84 A, respectively. The maximum output power of sing le cell is 0.46 W at the temperature of 850 ℃.

Properties and Chemical Treatment of Banana Fiber

Comparing to some other fibers,the mechanical andsome physical properties of banana fiber,constituent ofbanana fiber have been studied in this paper,mean-while,for improving some characteristics of banana fi-ber,the chemical treatments were used to modify the fi-ber.The results show that the coarse and brittle bananafiber,will be difficult to process in traditional spinningsystem.

Preparation of CNT/AlS i10Mg composite powders by high-energy ball milling and their physical properties

This study investigated the effects of carbon nanotube （CNT） concentration on the micro-morphologies and laser absorption proper- ties of CNT/AlSi10Mg composite powders produced by high-energy ball milling. A scanning electron microscope, X-ray diffractometer, laser particle size analyzer, high-temperature synchronous thermal analyzer, and UV/VIS/NIR spectrophotometer were used for the analysis of micro- graphs, phases, granulometric parameters, thermal properties, and laser absorption properties of the composite powders, respectively. The results showed that the powders gradually changed from flake- to granule-like morphology and the average particle size sharply decreased with in- creases in milling rotational speed and milling time. Moreover, a uniform dispersion of CNTs in AlSi10Mg powders was achieved only for a CNT content of 1.5wt%. Laser absorption values of the composite powders were also observed to gradually increase with the increase of CNT concentration, and different spectra displayed characteristic absorption peaks at a wavelength of approximately 826 nm.

Effects of the ion-beam voltage on the properties of the diamond-like carbon thin film prepared by ion-beam sputtering deposition

Diamond-like carbon （DLC） thin film is one of the most widely used optical thin films. The fraction of chemical bondings has a great influence on the properties of the DLC film. In this work, DLC thin films are prepared by ion-beam sputtering deposition in Ar and CH4 mixtures with graphite as the target. The influences of the ion-beam voltage on the surface morphology, chemical structure, mechanical and infrared optical properties of the DLC films are investigated by atomic force microscopy （AFM）, Raman spectroscopy, nanoindentation, and Fourier transform infrared （FTIR） spec- troscopy, respectively. The results show that the surface of the film is uniform and smooth. The film contains sp2 and sp3 hybridized carbon bondings. The film prepared by lower ion beam voltage has a higher sp3 bonding content. It is found that the hardness of DLC films increases with reducing ion-beam voltage, which can be attributed to an increase in the fraction of sp3 carbon bondings in the DLC film. The optical constants can be obtained by the whole infrared optical spectrum fitting with the transmittance spectrum. The refractive index increases with the decrease of the ion-beam voltage, while the extinction coefficient decreases.

Diffusion Brazing of Mechanically Alloyed Oxide Dispersion Strengthened Materials

The present research exploits diffusion brazing of mechanically alloyed Y 2O_3 dispersion strengthened nick-el-base MA760 and iron-base MA956 alloys using B-and P-containing thin foil and sputter coated interlayers.Microstructures of diffission brazed interface before and after recrystallization annealing were investigated usingoptical metallography, electron microprobe analysis, and transmission electron microscopy. It has been foundthat B and P have a strons influence on the recrystallization behavior of these materials. Too high B or P levelsin the interlayers caused recrystallization of the base alloys during brazing process which was operated at temperatures below normal recrystallization points.

POST－DEFORMATION TENSILE PROPERTIES IN A RAPIDLY SOLIDIFIED POWDER METALLURGY MR64 ALLOY

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FeCoNiTi_(x)中熵合金组织性能及其在硬质合金中的应用

FeCoNi中熵合金相比传统合金具有优异的性能,但其室温强度不高,限制了其应用。通过机械合金化和放电等离子烧结工艺制备FeCoNiTi_(x)(x=0,0.25,0.50,0.75,1)中熵合金块体,重点研究了各元素机械合金化顺序以及Ti含量对FeCoNiTi_(x)中熵合金显微组织和性能的影响,并初步探讨了FeCoNiTi_(x)中熵合金作为黏结剂在WC基硬质合金中的应用。结果表明:机械合金化过程中FeCoNi基体相为FCC相,添加Ti元素后形成Laves相和钛氧化物相,因此FeCoNiTi_(x)中熵合金物相由FCC相、Laves相和钛氧化物相组成。随着Ti含量的增加,FeCoNiTi_(x)合金密度、硬度和强度均上升,塑性先增强后减弱。FeCoNiTi_(0.50)中熵合金表现出良好的力学性能,其显微硬度、屈服强度、压缩强度和压缩应变分别为531 HV、1 987.57 GPa、2 114.85 GPa和20.5%。添加少量Ti元素可提升FeCoNi合金的耐腐蚀性。FeCoNiTi_(x)黏结剂在WC基硬质合金中能稳定存在,抑制WC烧结过程中脱碳相的形成。WC-FeCoNiTi_(0.50)硬质合金表现出较好的力学性能,其显微硬度与断裂韧性分别为1 834 HV与15.12 MPa·m^(1/2)。

冻融循环及各向异性对原状黄土动力特性的影响研究

【目的】为了研究冻融循环作用和各向异性对西宁地区原状黄土力学特性及变形的影响,【方法】借助冻融循环试验箱和GDS双向动态三轴仪,开展冻融循环试验和施加半正弦波形式的循环荷载动力特性试验,采用修正H-D模型分析冻融循环次数、与沉积方向呈不同角度对西宁地区黄土动力特性参数的影响。【结果】结果显示:(1)随着冻融循环次数的增加,动剪切强度呈现出先减小后增加的趋势;黄土Gd-1增长阈值呈现出先增大后减小的趋势;黄土阻尼比λ呈现出先增加后减小的趋势。(2)与沉积方向呈不同角度的土样动剪切强度具有差异性,即由大到小为0°>60°>90°>45°;Gd-1增长阈值由大到小为45°>90°>60°>0°;黄土阻尼比λ由大到小为45°>90°>60°>0°。【结论】结果表明:(1)随着冻融循环次数的增加,土体结构强度和刚度均表现出先减弱后增强的趋势,土体抵抗变形消耗的动能则呈相反趋势。(2)各向异性影响黄土的动剪切强度、刚度及阻尼比,与沉积方向呈45°土体动剪切强度最低,刚度最弱,土体发生变形消耗动能最多。(3)冻融循环作用影响土体在不同方向的力学特性,随冻融循环次数的增加,与沉积方向呈45°时土体各向异性表现明显,其结构损伤程度最大。

岩石-混凝土组合体单轴压缩力学与破坏特征数值模拟研究

目的为研究单轴压缩条件下混凝土组分骨料含量、强度等级、占比和界面倾角对岩石-混凝土组合体力学与破坏特征的影响,方法结合凸多边形随机骨料生成投放程序与RFPA2D分析系统,构建组合体数值模型并进行数值模拟。结果组合体的破坏类型可分为由混凝土组分破坏并延伸至花岗岩组分或两种组分及界面共同破坏引起的“两体Ⅰ型和Ⅱ型破坏”,由混凝土组分单独破坏或混凝土组分和界面共同破坏引起的“单体Ⅰ型和Ⅱ型破坏”。对界面处应力状态进行分析,从理论上解释了沿界面宏观裂纹的形成原因;组合体抗压强度接近混凝土的抗压强度,其值与混凝土组分强度等级正相关而与占比负相关;组合体弹性模量数值模拟结果与理论值吻合较好,且与骨料含量和强度等级正相关,与混凝土组分占比和界面倾角负相关;组合体泊松比与骨料含量和混凝土组分占比负相关,强度等级对其影响较小;组合体抗压强度和泊松比均随界面倾角的增加先减小后增加。结论构建了含骨料岩石-混凝土组合体数值模型,并运用RFPA2D分析系统对4种组合方式组合体进行数值模拟,可通过提高混凝土组分强度、降低混凝土组分占比与材料间的界面倾角提升组合体的力学特性。研究结果可为地下或坝体等工程的稳定性分析提供参考依据。

Mg-Gd-Y-Sm-X-Zr(X=La、Ce、Sr、Sb)合金显微组织及性能研究

以纯镁及镁基中间合金为原材料制备Mg-Gd-Y-Sm-X-Zr(X=La、Ce、Sr、Sb)合金,采用维氏硬度计、电感耦合等离子体原子发射光谱仪、金相显微镜、扫描电子显微镜和拉伸测试试验机等设备对试样进行测试。研究了Mg-Gd-Y-Sm-X-Zr(X=La、Ce、Sr、Sb)合金经固溶时效处理后的维氏硬度,稀土元素Gd、Y含量对Mg-Gd-Y-Sm-La-Zr合金时效态维氏硬度的影响,以及铸态、固溶时效态Mg-8Gd-3Y-2Sm-0.15La-0.5Zr合金的显微组织结构、时效硬化特性和力学性能。结果表明,La为最佳强化元素;Gd/Y质量比为8/3的合金维氏硬度优于Gd/Y质量比为6/4和9/2的合金;铸态Mg-8Gd-3Y-2Sm-0.15La-0.5Zr合金的晶粒尺寸主要集中在20~45μm,时效16h时其硬度达到峰值132.87HV;该合金时效态的抗拉强度和屈服强度达到了259.02MPa和240.31MPa,相对于铸态分别提升了42.32%和51.87%。

纳米微晶碳纤维改性复合材料的强度与力学性能研究

对碳纤维进行硅烷化改性处理,考察了硅烷化改性对碳纤维性能的影响。结果表明,改性后纤维素的长度和宽度都未发生明显变化;改性碳纤维的单丝拉伸强度会随着硅烷化纳米微晶纤维素(AMEO-NCC)含量提升而先增后减,单丝拉伸强度最大值在硅烷化纳米微晶纤维素质量分数为0.3%时取得(3.74 GPa)。硅烷化纳米微晶纤维素改性碳纤维复合材料的室温力学性能相较去除上浆剂碳纤维复合材料和涂覆环氧树脂的碳纤维复合材料都有不同程度提升,且硅烷化纳米微晶纤维素改性碳纤维复合材料的层间剪切强度、弯曲模量和弯曲强度会随着硅烷化纳米微晶纤维素含量增加而先增后减,最大值在硅烷化纳米微晶纤维素质量分数为0.3%时取得。

保温平台对高温固化环氧碳纤维复合材料性能影响

热压罐成型工艺是当前航空航天领域复合材料制件生产成型的重要方法之一。而在固化复杂的大型制件时,除了在不同温度阶段采用不同的升温速率外,通常还会增加保温平台来减少不同区域的冲温和热滞后现象。测试了一种高温固化环氧树脂碳纤维复合材料在不同保温温度和保温时间下的力学性能的变化。结果表明,当保温时间较短时,保温温度的变化对力学性能影响较小。当保温时间较长时,保温温度的高低对力学性能的影响很大:保温温度较低时,树脂的凝胶点温度较高,力学性能变化不大;随着保温温度的升高,凝胶点温度先降低后升高,力学性能也呈现先降低后提高的趋势。

含纳米二氧化硅的聚乙烯改性沥青混合料疲劳和力学性能研究

【目的】通过制备不同纳米二氧化硅掺量的复合改性沥青来研究纳米二氧化硅对聚乙烯改性沥青混合料性能的影响。【方法】通过四点弯曲疲劳试验、劲度模量试验、间接拉伸强度试验来分析纳米二氧化硅复合改性沥青混合料的性能。【结果】试验结果表明:当纳米二氧化硅掺量从1%增加到4%时,混合料的疲劳寿命、劲度模量和间接拉伸强度先增大后减小;当纳米二氧化硅掺量为3%时,混合料在20℃和30℃时的疲劳性能均最优;当纳米二氧化硅掺量为2%时,劲度模量和间接拉伸强度最优,且短期老化后的间接拉伸强度降幅最小。【结论】综合考虑各项性能指标,纳米二氧化硅的最佳掺量为2%~3%,此时复合改性沥青混合料疲劳和力学性能可提高40%以上。

铌钒微合金化HRB500E钢筋轧制工艺研究

使用Gleeble 3800热模拟仪研究铌钒微合金化HRB500E钢筋的连续冷却相变行为,并在不同加热温度下进行生产试制。热模拟试验结果显示,钢筋加热至1 200℃,在1 050℃变形,冷却速率为0.8℃/s的工艺下,铁素体体积分数为43.7%,铁素体晶粒尺寸为10.8μm,珠光体体积分数为56.3%,珠光体团尺寸为22.4μm。实际生产中,加热至1 200℃,在1 000℃上冷床空冷,HRB500E钢筋显微组织由铁素体和珠光体组成,屈服强度大于500 MPa,抗拉强度大于650 MPa,强屈比大于1.25,断后伸长率大于16.0%,最大力总延伸率大于9.0%,符合国家标准要求。

Nano-SiO_(2)改性水泥净浆结石体力学特性试验研究

岩土领域复杂的工程地质环境和工程地质灾害对注浆材料的性能提出了更高的要求。利用电液伺服岩石真三轴试验机开展了普通425水泥结石体、添加纳米二氧化硅浆液结石体的单轴压缩试验。试验结果表明,添加纳米二氧化硅后,浆液结石体力学性能得到明显提升,且纳米二氧化硅含量在3%时效果最好。与普通水泥浆液结石体相比,添加3%纳米二氧化硅的浆液结石体单轴抗压强度增加了56.3%,弹性模量增加了29.2%。试验结果可以为复杂地质环境下的工程项目注浆设计和施工提供参考。

边坡锚固用碳纤维增强复合材料的热固化工艺与性能研究

采用热固化方法制备了边坡锚固用碳纤维增强复合材料。研究了电加热固化、传统微波间接加热固化和优化后微波间接加热固化复合材料的力学及热学性能。结果表明,在电加热固化和微波间接加热固化过程的升温过程中没有出现放热峰,说明碳纤维增强复合材料在电加热固化作用下已经发生完全固化。相较于电加热固化工艺,微波间接加热固化在碳纤维增强复合材料完全固化前提下所消耗的能量仅为前者的24.97%,所需要的时间为前者的60%。微波间接加热固化碳纤维增强复合材料的拉伸性能、压缩性能、弯曲性能和层间剪切性能都高于电加热固化试样,层间剪切性能平均值相较于电加热固化提高了49.71%。

光束摆动对T2紫铜激光搭接焊缝成形及力学性能的影响

目的采用激光光束摆动方式改善T2紫铜激光焊接的焊缝质量,提高T2紫铜搭接焊接头的力学性能。方法对比不同摆动模式下T2紫铜搭接焊接头的焊缝成形,测试圆形摆动模式下摆动频率和摆动幅度对接头横截面形状的影响。采用显微镜观察分析焊缝金相组织,并研究摆动工艺参数对显微硬度、抗剪力的影响规律,最终得到最佳的工艺参数组合。结果相对于常规激光焊接和横向、无穷摆动模式,圆形摆动模式下T2紫铜焊缝成形最好。圆形摆动模式下,摆动频率从100 Hz增大到600 Hz时,熔深相应减小,熔宽变化不大;摆动幅度从0 mm增大到2 mm时,熔深相应减小,熔宽增大。接头断裂形式一般为焊缝边缘断裂,且接头光束摆动重熔区域等轴晶有所增加。当摆动频率由100 Hz增大到500 Hz时,结合面熔宽变化不大,显微硬度相应增大,接头得到强化,抗剪力由2.07 kN增大至2.32 kN;当摆动幅度从0 mm增大到1.2 mm时,显微硬度有所降低,结合面熔宽由0.332 mm增大到1.347 mm,抗剪力随之由1.35 kN增大至2.36 kN。结论圆形光束摆动模式下,当A=1 mm,f≥300 Hz或f=300 Hz,1 mm≤A≤1.5 mm时,能明显改善T2紫铜表面焊缝质量;激光光束的摆动有利于增大结合面熔宽,从而提高T2紫铜搭接焊接头的力学性能。

一种高密度碳氢燃料替代模型及其热物性分析

针对一种应用于高超声速飞行器再生冷却的高密度碳氢燃料,提出适用于其超临界态流动及换热特性研究的替代燃料模型。基于实验获得的碳氢燃料高温裂解的产物组分及现有航空煤油替代模型,提出三组分替代模型,以多物性参数分子摩尔质量、密度、运动黏度、比热容和导热系数为遴选指标,通过多目标优化寻出一种替代燃料模型(71.1%反式十氢化萘、19.4%正十二烷、9.5%正十三烷)。基于碳氢化合物的混合热物性参数数据库(NIST SUPERTRAPP),通过二次开发对替代燃料模型的超临界态热物性进行预测和分析,发现在临界压力2.8MPa,临界温度700K附近,该种碳氢燃料的热物性参数变化最明显,并且随着压力的升高,变化逐渐变小。

落叶松不同器官化学组分及其生物炭理化性质研究

为实现落叶松采伐剩余物的多级、高值利用及炭化还林、改良土壤提供理论依据,探究了落叶松不同器官(树干边材、树枝、树皮、树叶和松果)材料的主要化学组分,分析了其热解特性及其生物炭的基本理化性质,分离并测定落叶松各器官纤维素、半纤维素、木质素、苯醇抽提物和灰分含量,并表征各器官材料的热稳定性。将落叶松不同器官材料分别在500、700、900℃下炭化并表征各生物炭的理化性质。落叶松树干边材中综纤维素含量最高、松针中木质素和灰分含量最高、树枝中苯醇抽提物含量最高。落叶松的热解过程分为干燥、快速热降解和煅烧3个阶段,主热解反应发生在200~400℃,热重结果及炭得率分析均表明,松针的残炭率最高。同一组织器官的生物炭产率和表面官能团种类均随炭化温度的升高而逐渐减少;而同一组织器官生物炭的pH值随炭化温度上升而逐渐升高。5种生物炭的比表面积情况为:树皮炭>树干炭>松果炭>松针炭>树枝炭。落叶松边材的纤维素含量最高,适宜用作造纸制浆等原材料,松针的木质素含量较高,适宜用于提取化学品。树干边材、树皮和树枝适合炭化还林,其中树皮炭的炭得率较高、比表面积较大,pH值呈强碱性且化学性质比较稳定,可用于改良酸性土壤。