Y对轴承钢上激光熔覆FeCoCrNi涂层结构和冲蚀磨损的影响

以激光熔覆方法在轴承钢上制得FeCoCrNi-xY高熵合金涂层,并对其处于气体环境中的耐高温冲蚀性进行了测试。研究Y对涂层结构和冲蚀磨损的影响。研究结果表明：随着Y增大,蜂窝形组织开始减少直到全部消失,生成了许多尺寸较小的M颗粒,形成了粒径更小以及分布形态更均匀的Y化物组织。提高Y的加入量后,涂层发生了硬度先减小再增大势,测试得到的硬度值介于720-960 HV范围内。当逐渐提高冲蚀角后,FeCoCrNi-xY涂层发生了冲蚀磨损率持续增大。FeCoCrNixY涂层获得了高于轴承钢的硬度,呈现明显的脆性特点。对FeCoCrNi-0.3Y涂层冲蚀形成了深度更大的犁沟,达到了更高的冲蚀磨损率。当温度提高后,磨损率同样呈现增大现象,不过变化幅度较低。各攻角下的涂层磨损形式并未受到温度的明显影响。     

纳米粒子几何结构对膨胀型防火涂料阻燃和抑烟性能的影响

为了研究纳米粒子几何结构对膨胀型防火涂料阻燃和抑烟性能的影响,以聚磷酸铵(APP)-季戊四醇(PER)-三聚氰胺(MEL)-硼酸三聚氰胺(MB)为阻燃体系,硅丙乳液为成膜物质,分别添加球形纳米二氧化硅(Si O2)、经硅烷偶联剂KH560改性的管状碳纳米管(KH560–CNT)和片状水滑石(LDH)制备了3种水性膨胀型防火涂料。采用小室法、隧道法及模拟大板法研究了涂层的防火阻燃性能,再结合热重分析、扫描电镜分析和能谱分析,考察了涂层的热解性能和炭层结构。结果表明,球形Si O2和片状LDH能有效增强防火涂料的阻燃和抑烟性能,表现出较好的协效作用;管状KH560–CNT则会恶化防火涂料的阻燃和抑烟性能,表现出对抗作用。当纳米填料的质量分数为0.5%时,片状LDH表现出最优的协效作用,火焰传播比值为12.5,烟密度等级为14.1%。这是因为它能促进涂层在燃烧过程中形成更多的含磷和含硼交联结构,有效增强了炭层的致密性、连续性和隔热性能。     

过筛煤粉在铸铁件湿型砂铸造生产中的作用

正确选择煤粉,其性能要求同时具有低灰分、高挥发分和高膨胀指数,以及具有合适的筛分粒度这一关键因素,以确保所生产的铸件没有机械粘砂缺陷和表面质量问题.通过仔细选择、安全操作和加工处理,煤粉仍然是一个优良的、简易的、经济的有效解决方案.煤粉在储存、加工和运输过程中易于调节,然后经过进一步的安全处理,最终被铸造厂使用.尽管煤粉有诸多不足之处,对于最终用户来说,它仍然是经济合算的.而且现代加工和筛分方法确保它在最佳条件下使用.     

Internal surface protection of gas turbine blade by Si‐aluminide coating

A laboratory‐scale slurry silicoaluminizing process has been developed to apply coating into cooling passageways of a first‐stage gas turbine blade. Analytical techniques for characterizing the coatings comprised optical microscopy, SEM, EDS, and XRD. The results of metallographic examinations demonstrated that acceptable coatings had been formed in almost all of the passageways. The amounts of Al and Si in the topcoat were found to be in the ranges of 24–26 wt% and 4.5–6 wt%, respectively. The heat treated coating consisted largely of β‐NiAl phase as the coating matrix with uniform distribution of <2 µm‐size precipitates. In addition, oxidation and hot corrosion performance of the coatings were investigated by cyclic exposure to 1100 °C and the furnace method using a mixture of sodium sulfate‐40 wt% sodium vanadate‐10 wt% sodium chloride at 780 °C, respectively. It was found that the presence of Si in the coating improves both oxidation and hot corrosion Type II properties.     

Coating of TiB2 dispersed Ti50Ni50 superelastic alloy layer onto Ti-6Al-4V alloy by spark and resistance sintering

The spark and resistance sintering (SRS) of a mixture of Ti, Ni, and TiB₂ powders was carried out to form a TiB₂ dispersed TiNi alloy layer onto a Ti-6Al-4V alloy substrate. The strength and delamination resistance of the surface layer were evaluated by three-point bending tests. The results showed that the bending strength of the specimen with the TiNi alloy surface layer without TiB₂ particles sintered at 1273 K was low because the crack initiation occurred at an early stage of loading in a thick interface layer containing brittle Ti-Ti₂Ni eutectic. By decreasing the sintering temperature to 1200 K, the bending strength increased and the crack initiation occurred from the surface because the interface layer was thin and did not contain the brittle Ti-Ti₂Ni eutectic. For the specimens with TiB₂ dispersed TiNi surface layer that was sintered at 1273 K, the bending strength was larger than that of the specimens with TiNi surface layer because the interface layer does not contain the Ti-Ti₂Ni eutectic and compressive residual stress generated in the surface layer during cooling process after SRS suppresses the crack initiation on the surface. The coating of TiB₂ dispersed TiNi alloy onto titanium alloys by SRS provides strong interface to prevent delamination of the surface layer, strong surface due to residual compressive stress, and wear-resistant surface due to the existence of hard TiB₂ particles and superelastic deformation of TiNi matrix.     

BN—SF和BN—HF型皮革涂饰用树脂乳液的研究

本文介绍了用丙烯酸酯类单体与其他单体为原料,通过多元乳液共聚制备BN-SF和BN-HF两种新型皮革涂饰用高分子乳液的方法。并对所得胶乳及胶膜的物化性能进行了测试。论文还讨论了单体的配比,乳化剂的变化对乳液及胶膜性能的影响。实验表明这两类涂饰材料综合性能优良,贮存稳定性好。粒度范围为0.05～0.15)μm。经国内有关厂家成批量应用后表明该材料对皮革的涂饰效果好,涂层性能优良。     

Self-Adhesive Polydimethylsiloxane Foam Materials Decorated with MXene/Cellulose Nanofiber Interconnected Network for Versatile Functionalities

Polydimethylsiloxanes (PDMS) foam as one of next-generation polymer foam materials shows poor surface adhesion and limited functionality, which greatly restricts its potential applications. Fabrication of advanced PDMS foam materials with multiple functionalities remains a critical challenge. In this study, unprecedented self-adhesive PDMS foam materials are reported with worm-like rough structure and reactive groups for fabricating multifunctional PDMS foam nanocomposites decorated with MXene/cellulose nanofiber (MXene/CNF) interconnected network by a facile silicone foaming and dip-coating strategy followed by silane surface modification. Interestingly, such self-adhesive PDMS foam produces strong interfacial adhesion with the hybrid MXene/CNF nano-coatings. Consequently, the optimized PDMS foam nanocomposites have excellent surface super-hydrophobicity (water contact angle of ≈159^o), tunable electrical conductivity (from 10⁻⁸ to 10 S m⁻¹), stable compressive cyclic reliability in both wide-temperature range (from −20 to 200 ^oC) and complex environments (acid, sodium, and alkali conditions), outstanding flame resistance (LOI value of >27% and low smoke production rate), good thermal insulating performance and reliable strain sensing in various stress modes and complex environmental conditions. It provides a new route for the rational design and development of advanced PDMS foam nanocomposites with versatile multifunctionalities for various promising applications such as intelligent healthcare monitoring and fire-safe thermal insulation.     

Highly Crystalline Soluble Acene Crystal Arrays for Organic Transistors: Mechanism of Crystal Growth During Dip‐Coating

The preparation of uniform large‐area highly crystalline organic semiconductor thin films that show outstanding carrier mobilities remains a challenge in the field of organic electronics, including organic field‐effect transistors. Quantitative control over the drying speed during dip‐coating permits optimization of the organic semiconductor film formation, although the kinetics of crystallization at the air–solution–substrate contact line are still not well understood. Here, we report the facile one‐step growth of self‐aligning, highly crystalline soluble acene crystal arrays that exhibit excellent field‐effect mobilities (up to 1.5 cm V^?1 s^?1) via an optimized dip‐coating process. We discover that optimized acene crystals grew at a particular substrate lifting‐rate in the presence of low boiling point solvents, such as dichloromethane (b.p. of 40.0 °C) or chloroform (b.p. of 60.4 °C). Variable‐temperature dip‐coating experiments using various solvents and lift rates are performed to elucidate the crystallization behavior. This bottom‐up study of soluble acene crystal growth during dip‐coating provides conditions under which one may obtain uniform organic semiconductor crystal arrays with high crystallinity and mobilities over large substrate areas, regardless of the substrate geometry (wafer substrates or cylinder‐shaped substrates).     

1310nm大功率高偏振度量子阱超辐射发光二极管

设计并制备了一种斜条脊波导结构压应变高偏振度多量子阱超辐射发光二极管.设计的脊波导出光面TiO2/SiO2四层宽带增透膜的TE模式反射率约为10-6,分析了脊波导角度偏差和膜层厚度偏差对增透膜反射率的影响.实验结果表明,在250 mA直流电流驱动下,所设计的超辐射发光二极管芯片单管输出功率可达22.7 mW,出射光谱FWHM约为37.3 nm,光谱纹波系数低于0.15 dB,TE模式输出光强占主导,偏振度约为19.2 dB.     

Improvement in open circuit voltage of n‐ZnO/p‐Si solar cell by using amorphous‐ZnO at the interface

Several research groups are currently working on n‐ZnO/p‐Si heterojunction solar cell, and recently, Pietruszka et al [Sol. Energ. Mat. Sol. Cells 147 (2016) 164‐170] has reported the highest efficiency of 7.1% for this structure. The main challenge is to enhance the open circuit voltage up to theoretically predicted value of >0.6 V. This paper reports >20% improvement in open circuit voltage of n‐ZnO/p‐Si solar cell by depositing amorphous‐ZnO at the interface at room temperature that possibly improves the passivation and/or avoids oxide formation at the interface during ZnO deposition. Two other materials, aluminum nitride and amorphous‐Si, have also been used as buffer layers to evaluate their effect on suppression of interface states. Furthermore, additional advantage of ZnO as an antireflector has been experimentally verified for different thicknesses of ZnO film.