Data-driven optimization study of the multi-relaxation-time lattice Boltzmann method for solid-liquid phase change

Sharp phase interfaces and accurate temperature distributions are important criteria in the simulation of solid-liquid phase changes.The multi-relaxation-time lattice Boltzmann method(MRT-LBM)shows great numerical performance during simulation;however,the value method of the relaxation parameters needs to be specified.Therefore,in this study,a random forest(RF)model is used to discriminate the importance of different relaxation parameters to the convergence,and a support vector machine(SVM)is used to explore the decision boundary of the convergent samples in each dimensional model.The results show that the convergence of the samples is consistent with the sign of the decision number,and two types of the numerical deviations appear,i.e.,the phase mushy zone and the non-physical heat transfer.The relaxation parameters chosen on the decision boundary can further suppress the numerical bias and improve numerical accuracy.

Stochastic Second-Order Two-Scale Method for Predicting the Mechanical Properties of Composite Materials with Random Interpenetrating Phase

In this paper,a stochastic second-order two-scale(SSOTS)method is proposed for predicting the non-deterministic mechanical properties of composites with random interpenetrating phase.Firstly,based on random morphology description functions(RMDF),the randomness of the material properties of the constituents as well as the correlation among these random properties are fully characterized through the topologies of the constituents.Then,by virtue of multiscale asymptotic analysis,the random effective quantities such as stiffness parameters and strength parameters along with their numerical computation formulae are derived by a SSOTS strategy combined with the Monte-Carlo method.Finally,the SSOTS method developed in this paper shows an excellent computational accuracy,and therefore present an important advance towards computationally efficient multiscale modeling frameworks considering microstructure uncertainties.

A phase inversion based sponge-like polysulfonamide/SiO_2 composite separator for high performance lithium-ion batteries

In this work,a sponge-like polysulfonamide(PSA)/SiO_2 composite membrane is unprecedentedly prepared by the phase inversion method,and successfully demonstrated as a novel separator of lithium-ion batteries(LIBs).Compared to the commercial polypropylene(PP) separator,the sponge-like PSA/SiO_2 composite possesses better physical and electrochemical properties,such as higher porosity,ionic conductivity,thermal stability and flame retarding ability.The LiCoO_2/Li half-cells using the sponge-like composite separator demonstrate superior rate capability and cyclability over those using the commercial PP separator.Moreover,the sponge-like composite separator can ensure the normal operation of LiCoO_2/Li half-cell at an extremely high temperature of 90 °C,while the commercial PP separator cannot.All these encouraging results suggest that this phase inversion based sponge-like PSA/SiO_2 composite separator is really a promising separator for high performance LIBs.

Tungsten nanoparticle-strengthened copper composite prepared by a sol–gel method and in-situ reaction

Tungsten nanoparticle-strengthened Cu composites were prepared from nanopowder synthesized by a sol–gel method and in-situ hydrogen reduction.The tungsten particles in the Cu matrix were well-dispersed with an average size of approximately 100–200 nm.The addition of nanosized W particles remarkably improves the mechanical properties,while the electrical conductivity did not substantially decrease.The Cu–W composite with 6 wt%W has the most comprehensive properties with an ultimate strength of 310 MPa,yield strength of 238 MPa,hardness of HV 108 and electrical conductivity of 90%IACS.The enhanced mechanical property and only a small loss of electrical conductivity demonstrate the potential of this new strategy to prepare W nanoparticle-strengthened Cu composites.

In-situ TiC_P/Al Composites Prepared by TE/QP Method

An in-situ TiCp/Al composite was prepared by a thermal explosion/quick pressure method （TE/QP）. The effect of Al content on the reaction temperature as well as the reaction rate has been studied. Phase constituents and the microstructure of the composites and the particle size of the reinforcement were analysed using X-ray diffraction （XRD） and scanning electron microscopy （SEM）. The results have shown that TiCp/Al composite with 40～70 vol. pct TiC particle reinforcement and high relative density can be directly obtained by TE/QP. TiC is the only reaction product when Al content in Al-Ti-C system is no more than 60 vol. pct, but Al3Ti phase will also form when Al content is more than 60 vol. pct. Increasing Al content prolongs the initial reaction time, reduces the highest reaction temperature and the reaction rate, and decreases the size of TiC particles. In addition, the microstructure of TiCp/Al composite and the structure of interface between TiCp and Al are studied using SEM and transmission electron microscopy （TEM）. The results show that the in-situ synthesized TiC particle has fcc cubic structure. The orientation between TiC particles and Al matrix can be described as （220）Al//（022）TiC and [112]Al//[011]TiC. Results of the mechanical property tests reveal that the ultimate strength （σ） and modulus （E） are 687 MPa and 142 GPa respectively when the Al content is 40 vol. pct. On contrary, 6 elongation increases by 3.2% with increasing Al content.

Fabrication and properties of Si/Al interpenetrating phase composites for electronic packaging

In order to improve the thermal properties of MMCs for electronic packaging,the concept of fabrication MMCs with particular interpenetrating phases(IPCs) was proposed. Based on the diffusion theory of reinforcement element in matrix alloys of some particular PMMCs,a novel fabrication method to produce IPCs was proposed. The Si/Al composites(65%Si,volume fraction) with interpenetrating phases were fabricated successfully by squeeze casting and hot press sintering technology. Microstructure observations indicate that the reinforcements Si are of three-dimensional continuous network and the composites are compact without obvious defects. The average linear thermal expansion coefficient(CTE) between 20 ℃ and 100 ℃ of the Si/Al IPCs is 8.27×10-6/K,and the thermal conductivity(TC) is 124.03 W/(m·K),and the composites can meet the demands of electronic packaging. ROM model and Turner model can be used to predict the CTEs of IPCs,and the experimental CTEs are between their theoretical and calculated values.

Hf含量对湿化学法制备超细W-Y_(2)O_(3)复合材料显微组织与性能的影响

本文在现有W-Y_(2)O_(3)材料基础上,引入微量Hf4+掺杂入Y_(2)O_(3),调节Y_(2)O_(3)与W晶粒之间的界面关系,从而改善W基材料的综合性能。通过改变Y与Hf元素的掺杂比例,获得纳米级W基复合粉体,在氢气气氛下常规烧结制备W-Y_(2)(Hf)O_(3)复合材料。采用SEM、TEM等表征手段对W-Y_(2)(Hf)O_(3)复合材料的性能进行表征分析,研究Y与Hf元素在材料中的作用规律。结果表明:掺杂Hf元素有利于后续氢气还原,在第二相掺杂量不变条件下,当Hf含量增加时,所获得的粉体粒径减小,W-3Y-7Hf的粒径约为100 nm,明显小于传统制备的W-Y_(2)O_(3)粉体。烧结后的块体晶粒尺寸细化,显微硬度和相对密度随之增大,成分为W-3Y-7Hf烧结块体显微硬度最高,为513.7HV_(0.2),致密度为97.6%。在钨基材料中同时添加Y与Hf元素会在钨晶粒的晶界与晶内处形成复合第二相氧化物Y_(2)Hf_(2)O_(7)颗粒,尺寸更小,弥散强化作用更强;其中,W-3Y-7Hf中第二相氧化物颗粒尺寸仅为200 nm左右,与钨晶界产生良好的界面结合关系,形成半共格界面。

焚烧飞灰火山灰活性测试及评价方法研究

生活垃圾焚烧飞灰的资源化利用正受到关注,火山灰活性是其应用的重要性能,但目前缺乏可靠的火山灰活化评价方法。鉴于粉煤灰与焚烧飞灰均是焚烧产物,借鉴现有粉煤灰的火山灰活性评价方法,从物质组成(成分结构分析法)、胶凝性能(强度指数法)和化学反应(结合水含量法)三个角度对两种焚烧飞灰(炉排炉、流化床)进行火山灰活性测试和分析,同时与三个等级粉煤灰的测试结果进行对比。结果表明:成分结构分析法和强度指数法均可用于评价焚烧飞灰的火山灰活性,而结合水含量法不适用;非晶相硅铝含量可以作为火山灰活性的表征指标,与强度指数具有一定相关性;强度指数法测试结果受非晶相硅铝与钙相对含量的影响,对于焚烧飞灰,14 d胶砂强度指数即可反映其火山灰活性,而对于粉煤灰,需要考虑采用90 d甚至更长龄期的强度指数来进行评价。

超轻质石英/酚醛复合材料烧蚀行为与多物理场数值模拟

基于超轻质石英/酚醛复合材料的烧蚀防热机制,建立了包含二氧化硅相变的复合材料烧蚀多物理场模型,预测了超轻质石英/酚醛复合材料的表背面温度、热解度、不同层厚度及孔隙压力分布。数值模拟通过计算获得了表面二氧化硅液态层厚度变化规律,模型预测的温度结果与烧蚀实验中测量结果吻合。根据各项传热模式的热流分析结果可见,对防/隔热机制影响最主要的是热辐射、热阻塞和二氧化硅气化。针对超轻质石英/酚醛复合材料的典型服役工况,采用0.5~2.5 MW/m^(2)之间热流密度作为环境输入参数,研究了不同热流密度条件下超轻质石英/酚醛复合材料的烧蚀行为,结果表明:超轻质石英/酚醛复合材料表面烧蚀后退量随热流密度的增加而增加;热流密度小于1.5 MW/m^(2)时表面液态层厚度随热流密度的增加而增加,热流密度大于1.5 MW/m^(2)时表面液态层厚度基本保持不变。该模型为深入研究超轻质石英/酚醛复合材料的烧蚀机制提供一定的指导。

半干法制备千克量级α-半水石膏粉及工艺能耗计算

以磷石膏、脱硫石膏为原料,采用半干法工艺实现α-半水石膏粉千克量级制备试验,采用SEM场发射扫描电镜和马尔文激光粒度仪分析α-半水石膏粉形貌和粒径分布,对两种α-半水石膏粉物相组成分析和力学性能强度进行对比。结果表明:两种α-半水石膏粉中半水石膏相转化率在90%左右,晶体长径比接近于1,磷石膏基α-半水石膏粉力学性能最佳,其2 h抗折强度2.6 MPa,绝干抗压强度13.6 MPa。计算半干法工艺能耗,与传统煅烧法对比能耗降低约29.5%,工艺简单、绿色化,证明半干法工艺量产制备α-半水石膏粉在工业上可行性,为大规模消耗利用化学石膏提供科学基础。

液相法制备超细铂及其复合粉的研究进展

铂及其复合粉因具有独特的性能,广泛应用于电子信息、能源、汽车等高端制造领域。随着我国高端装备制造业的高质量、快速发展,对铂及其复合粉性能提出了更高的要求,需求也日益增大。综述了目前制备铂及其复合粉应用最广泛的液相法的研究现状,重点总结了溶胶-凝胶法、水热法、微乳液法、液相化学还原法的研究进展,以及各制备方法的优势及面临的问题,并对铂等贵金属超细粉体的高效制备发展方向进行了展望。

铝基复合材料制备方法及成型工艺的最新进展

介绍了铝基复合材料当前的发展状况,总结了铝基复合材料的多种制备方法。增强相不同,铝基复合材料的制备方法也不同。铝基复合材料的增强相按照其不同的形貌特征主要分为颗粒增强相、纤维增强相、片状增强相。首先介绍了铝基复合材料的典型制备方法,之后以三种增强相为中心,对其成型工艺进行了说明,列举了不同方法当前的研究进度,最后总结了各种方法在目前研究中存在的问题,并对不同增强相的铝基复合材料的发展前景进行了展望。

双连续结构陶瓷-金属复合材料研究现状及展望

双连续相复合材料的两相组织在三维空间呈各自连续的状态,二者互相缠绕、互为支撑、强弱互补,由于双连续相复合材料具有特有的拓扑结构,复合材料通常表现出独特的力学性能、耐磨性能、热力学性能、耐高温性能、减震性能。因此,对其进行深入地研究具有重大的意义。主要介绍了国内外双连续相陶瓷-金属复合材料的结构、性能特点、成型方法,对比了不同陶瓷相与金属复合所表现出的结构特性和性能特点,并展望了该结构材料的应用前景及发展趋势。

辣椒碱微乳的制备及其质量评价

为了提高辣椒碱溶解度和生物利用度将其制备成微乳,经溶解度实验和伪三元相图确定微乳处方组成和表面活性剂与助表面活性剂的最佳质量比(Km);以粒径和载药量为考察指标,采用星点设计-响应面法优化辣椒碱微乳处方;并对最优处方制备的辣椒碱微乳进行质量评价。辣椒碱微乳最优处方为辣椒碱5.12%,油酸乙酯5.82%,曲拉通X-100和无水乙醇(K_(m)=3∶1)28.54%,加纯化水至5.0 g;制得的微乳为O/W型澄清透明的均一液体,其形态为表面光滑的球形;CAP微乳粒径为16.5±0.17 nm,多分散指数为0.387±0.02,Zeta电位为-12.1±0.12 m V,粘度为33±1.73 m Pa·s;冻融稳定性和离心稳定性良好;红外光谱和差示扫描量热分析表明辣椒碱被包裹在微乳中。将辣椒碱制备成辣椒碱微乳,溶解度得以提高,解决了其水溶性低的问题,为辣椒碱的开发与应用提供一定的参考。

液相置换法制备硅/碳复合材料及其储锂性能

通过镁热还原SiO_(2)实现了纳米硅的制备,随后通过液相置换法将其与葡萄糖复合经过热处理获得硅/碳复合材料(Si/C)。在将制备的材料作为锂离子电池的负极材料,测试发现该材料展示了优异的循环性能(在100 mA/g的电流密度下,循环50次的比容量能维持在800 mAh/g左右)、高的倍率性能(在4200 mA/g的电流密度下保持在385 mAh/g的比容量)和不错的循环稳定性(在840 mA/g的电流密度下,循环120次其容量亦能维持在约459 mAh/g),远高于纯硅和纯碳的容量。可见碳的介入有效改善了硅的导电性,提升了其储锂性能,为Si/C复合材料在高性能锂离子电池的应用提供了一种新的策略。

用于红外和雷达波隐身的水泥基复合材料

红外和雷达波隐身主要是通过降低目标的红外辐射信号和雷达回波信号来提高目标的隐蔽性。将相变材料与炭黑封装为相变单元,并将其与膨胀珍珠岩-磁粉/水泥复合材料结合,研制出一种兼具红外和雷达波隐身的双功能水泥基复合材料,对其吸波性能和热性能进行试验与仿真研究。结果表明:炭黑对相变材料相变温度的影响较小,潜热仅降低了约1.9%;500次冷热循环后,相变材料的潜热留存率为78.3%,循环稳定性较好。相变单元和膨胀珍珠岩均可以提高水泥基复合材料的吸波能力,且反射损耗在-5~-15 dB可调。相变单元通过吸收大量热量来降低目标外表面温度,削弱红外辐射。相变材料的加入会增加水泥基复合材料的热导率,但相变材料高储热密度和珍珠岩低热导率的共同作用使得水泥基复合材料的隔热效应更加显著,从而降低目标的红外辐射信号。仿真结果表明:磁损耗仅出现在水泥基体中,相变单元通过电阻损耗来影响水泥基复合材料的吸波性能。热量传递在相变单元处受阻,传导热通量在相变单元边缘处的传输过程出现弯曲。当相变材料相变完成后,热量趋于均匀分布。因此,水泥基复合材料可通过损耗电磁波来降低雷达回波信号,通过相变材料吸收目标的热量来降低红外辐射,从而实现不同复杂环境下建筑材料的红外和雷达波等多波段隐身。

伪三元相图联合星点设计-响应面法优选鸦胆子油微乳处方

目的优选鸦胆子油微乳制备工艺。方法优选鸦胆子油微乳由油包水(W/O)型转变为水包油(O/W)型微乳相临界点的测定方法,并初筛微乳油相配比。绘制伪三元相图,筛选最优乳化剂、助乳化剂、油相组成和Km值。以鸦胆子油的用量(%)、Km为考察因素,以微乳的平均粒径(nm)和多分散系数(PDI)为评价指标,采用星点设计-响应面法优选制备工艺。分别从电镜观察、类型鉴别、高速离心(转速为5000 r/min)、室温静置(30 d和60 d)方面考察按最优工艺制备的鸦胆子油微乳的理化性质。结果与目测法相比,电导率-含水量曲线法测定临界点更精确,且微乳的平均粒径和PDI更小,体系更稳定。微乳最优制备工艺为鸦胆子油8.66%、油酸8.66%、聚氧乙烯氢化蓖麻油60.81%、无水乙醇21.87%、Km值为2.78,含水量为71.01%。该工艺下测得微乳的平均粒径为(14.22±0.25)nm,PDI为0.066±0.004。鸦胆子油微乳外观圆整,为O/W型,且稳定性良好。结论该优选工艺操作简便,结果稳定可靠,可为鸦胆子油微乳的工业化生产提供借鉴。

管状复合炭膜的制备及其气体渗透性能

以中空纤维陶瓷膜为载体,聚芳醚酮为聚合物前驱体,采用浸涂-相转化结合的方法制备复合炭膜,探讨了制膜工艺对复合炭膜结构及性能的影响.结果发现,铸膜液浓度和提拉速率对膜的完整性影响较大,在15%质量分数铸膜液和2 cm/min提拉速率的条件下,可制备出表面膜层完整均一且兼具较高气体渗透通量的复合炭膜;通过控制制备前驱体膜过程中蒸发温度和蒸发时间,复合炭膜分离层缺陷大幅减少,气体分离选择性得到了显著提升.以15%铸膜液和2 cm/min提拉速率,在60℃蒸发温度及10 s蒸发时间的制膜工艺条件下制备出的复合炭膜,其O_(2)/N_(2)、CO_(2)/N_(2)和CO_(2)/CH_(4)选择性分别为5.62、26.27、25.10,O_(2)、CO_(2)渗透通量分别可达252、1177 GPU.

石蜡基新型导热型复合相变材料的制备及性能研究

相变材料作为被动式热管理方式用于动力电池热管理系统是一个新兴的发展方向,与传统空冷、液冷等方式相比,具有高效、节能、温度波动小、防止热失效等优点。但是传统相变复合材料(PCM)的绝缘性及导热性不足,在应用于电池热管理技术(BTM)时可能会导致性能及安全问题。为了改善PCM的绝缘性及其导热性,研究主要以石蜡为相变材料,二氧化硅和活性炭构筑二元的SiO_(2)/C导热骨架,并采用环氧树脂(ER)作为基材,以提高相变复合材料的可加工性,制备了一种新型的导热型相变复合材料(CPCM)。该复合材料集环氧树脂(ER)的成型性,活性炭(C)的吸附性和石蜡(PA)的高潜热,使得所获得的CPCM具有良好的性能。此外,通过制备不同组分的CPCM,并对其相变潜热、热稳定性、绝缘性能进行测试表征,分析了加入不同比例的SiO_(2)对CPCM性能的影响。研究结果表明,以SiO_(2)质量分数的10%为中间值,当使用SiO_(2)比例继续增加时,活性炭会吸附大量SiO_(2)而产生团聚现象;而当加入SiO_(2)的比例低于质量分数10%时,团聚现象消失。通过差热扫描热量仪(DCS)、热重量分析仪(TGA)和电导率仪对产品进行分析表明,在SiO_(2)质量分数增加时,其相变潜热逐渐降低,但总体幅度不大。而体积电阻率则随着SiO_(2)质量分数的增加而增加。

9批正品龙骨药材的年代测定及年代与成分的相关性分析

采用^(14)C测年法对采集的龙骨样品进行了年代测定,选取其中9批符合化石年代的正品龙骨,采用X射线粉末衍射技术(XRD)和电子探针微区分析技术对样品的物相组成及元素赋存形态进行了分析,结果显示龙骨的主体物相为羟磷酸钙,部分样品为羟磷酸钙和碳酸钙共存;样品中的羟磷酸钙以羟基磷灰石为主要存在形式,碳酸钙则多以方解石型碳酸钙存在,少部分以白云石形式存在。采用ARF、ICP-AES、ICP-MS、AES法对9批正品龙骨样品进行了元素含量的测定,结果显示:龙骨中钙磷的比值均大于2,推测因化石形成过程中,骨骼的有机磷在地质过程中较多被分解而造成;9批龙骨的微量元素具有大致相同的分配模式:Sc、V、Cr、Co、Ni、Cu六种元素相对原始地幔均为亏损,Ba、Sr、As为异常富集,元素U为高度富集;9批龙骨中的稀土元素分布也具有大致相同的分配模式,表现为轻稀土富集型,Ce负异常,Eu部分正异常、部分负异常,Y轻微正异常;6批年代在4.35万年以前的龙骨,稀土元素总量明显高于3批年代在1.8~3.7万年之间的样品,推测一方面与其埋藏成岩环境有关,另一方面与其埋葬年代更为久远有关。