Alloy Hybrid(合金混合)研究综述
Alloy Hybrid 合金混合 - Herein, a molybdenum oxide-FeCoCu alloy hybrid (MoOx-FeCoCu) catalyst was designed by polyoxometallate (POM) molecular cluster mediated solvothermal alcoholysis and ammonolysis of metal salts followed by pyrolytic reduction treatment. [1] This work mainly focuses on increasing the mechanical strength and improving the corrosion resistance of an aluminum alloy hybrid matrix. [2] 6Si aluminum alloy hybrid composites were produced. [3] The bonding characteristics of aluminum nitride/aluminum alloy hybrid have been assessed, using scanning electron microscopy and energy dispersive X-ray spectroscopy. [4] The synthesized dual particle-reinforced Al7075 alloy hybrid composites were subjected to microstructural studies, mechanical and wear properties testing. [5] In this research, the stir casting technique used to produce ZA-12 alloy hybrid composites reinforced by nanoparticles (SiC and BN) with different weight percentages. [6] In this paper, the mechanical behavior of thin-ply laminate and TC21 titanium alloy hybrid joints with double-lap bolted structure under quasi-static loading was studied experimentally. [7] Findings: The synthesized multiple particles reinforced Al7075 alloy hybrid composites were subjected to microstructural studies and wear properties testing. [8] In this research work, an effort was made to predict the dry sliding wear response of AlMg1SiCu alloy hybrid composites which were reinforced with 10% Silicon carbide particles (SiC) together with weight fractions of 3, 6 and 9% of self-lubricant molybdenum disulphide particles (MoS2) through melt stir casting. [9] The present study investigates aluminium alloy powder (Al7075) of mesh size 60 μm and the reinforcement SiC of varying its weight percentage (2 wt%, 4 wt%, 6 wt%) and keeping constant Al2O3 (2 wt%) of particle size <50 nm has been used to synthesis aluminium alloy hybrid nanocomposites. [10] The designed TiC coating and Ti alloy hybrid might be potential application in artificial joint surfaces and other implants with strong wear-resistance requirements. [11] 2 m diameter, made of graphite–epoxy laminate integrated with Nitinol fibre–reinforced hybrid composite (shape memory alloy hybrid composite) patches, is considered. [12] Results indicate that a small amount of shape memory alloy fibers significantly increases the fundamental frequency and vibration control of the hybrid laminated composite reinforced with shape memory alloy hybrid laminated composite cylindrical shells. [13] A new nonlinear finite element model is proposed for the dynamic analysis of cylindrical sandwich panels with shape memory alloy hybrid composite face sheets and flexible core. [14] In this research stir casting technique is used to produce (ZA-27)alloy hybrid composites reinforced by nano particles (BN and Si3N4) with various weight percentage. [15] This investigation is concerned with the mechanical behavior of Shape Memory Alloy Hybrid Composite Beams (SMAHC), that consist of a circular bar of NiTi alloy incorporated in a 500 mm long cylindrical pipe of polypropylene (PP), with external diameter 50 mm and nominal wall thickness 7 mm, wound with a nylon/epoxy layer. [16] A comparative analysis of the thermal stability of the steel/vanadium alloy hybrid material and its components (steel type AISI 439 and V–10Ti–5Cr alloy) obtained by high-pressure torsion (HPT) at 20 and 400 °C was carried out. [17] The paper presents free vibration of shape memory alloy hybrid composite beams by experimentally. [18] The paper presents the findings of a pioneering study investigating the newly developed polymer-aluminium alloy hybrid foam as fillers of thin-walled square tubes made of aluminium alloy, as an alternative to the conventional closed-cell aluminium foams. [19] In order to attain this goal, shape memory alloy was textile-technically converted into shape memory alloy hybrid yarn using the friction spinning technology. [20] In this work, the behaviour of thermoplastic composites and Shape Memory Alloy Hybrid Composites (SMAHCs) for aeronautical applications is analysed and compared by means of findings from numerical analyses and experimental tests. [21]在此,通过多金属氧酸盐(POM)分子簇介导的溶剂热醇解和金属盐的氨解,然后进行热解还原处理,设计了一种氧化钼-FeCoCu合金杂化(MoOx-FeCoCu)催化剂。 [1] 这项工作主要集中在提高铝合金混合基体的机械强度和耐腐蚀性。 [2] 制备了6Si铝合金杂化复合材料。 [3] 已经使用扫描电子显微镜和能量色散 X 射线光谱评估了氮化铝/铝合金混合材料的结合特性。 [4] 对合成的双颗粒增强 Al7075 合金杂化复合材料进行微观结构研究、机械和磨损性能测试。 [5] 在这项研究中,搅拌铸造技术用于生产由不同重量百分比的纳米粒子(SiC 和 BN)增强的 ZA-12 合金混合复合材料。 [6] 本文对双搭接螺栓结构的薄层板和TC21钛合金混合接头在准静态载荷下的力学行为进行了试验研究。 [7] 结果:合成的多颗粒增强 Al7075 合金混合复合材料进行了微观结构研究和磨损性能测试。 [8] 在这项研究工作中,努力预测了用 10% 碳化硅颗粒 (SiC) 和 3%、6% 和 9% 重量分数的自润滑二硫化钼增强的 AlMg1SiCu 合金混合复合材料的干滑动磨损响应颗粒 (MoS2) 通过熔体搅拌铸造。 [9] 本研究研究了网孔尺寸为 60 μm 的铝合金粉末 (Al7075) 和改变其重量百分比 (2 wt%、4 wt%、6 wt%) 并保持恒定 Al2O3 (2 wt%) 粒径 < 50 nm 已用于合成铝合金杂化纳米复合材料。 [10] 所设计的 TiC 涂层和 Ti 合金混合物可能在人工关节表面和其他具有强烈耐磨性要求的植入物中具有潜在应用。 [11] 考虑由石墨-环氧树脂层压板与镍钛诺纤维增强混合复合材料(形状记忆合金混合复合材料)贴片集成而成,直径为 2 米。 [12] 结果表明,少量形状记忆合金纤维显着提高了形状记忆合金混合叠层复合圆柱壳增强的混合叠层复合材料的基频和振动控制。 [13] 提出了一种新的非线性有限元模型,用于对形状记忆合金混合复合面板和柔性芯材的圆柱形夹芯板进行动态分析。 [14] 在这项研究中,搅拌铸造技术用于生产由不同重量百分比的纳米颗粒(BN 和 Si3N4)增强的 (ZA-27) 合金杂化复合材料。 [15] 本研究涉及形状记忆合金混合复合梁 (SMAHC) 的机械性能,该梁由 NiTi 合金圆棒组成,并结合在 500 毫米长的聚丙烯 (PP) 圆柱形管中,外径为 50 毫米,标称壁厚度 7 毫米,用尼龙/环氧树脂层缠绕。 [16] 对钢/钒合金混合材料及其组分(钢型 AISI 439 和 V-10Ti-5Cr 合金)在 20 和 400°C 下通过高压扭转 (HPT) 获得的热稳定性进行了比较分析。 [17] 本文通过实验研究了形状记忆合金混合复合梁的自由振动。 [18] 本文介绍了一项开创性研究的结果,该研究调查了新开发的聚合物-铝合金混合泡沫作为铝合金制成的薄壁方管的填料,作为传统闭孔铝泡沫的替代品。 [19] 为了实现这一目标,形状记忆合金被纺织技术转化为形状记忆合金混合纱线,使用摩擦纺纱技术。 [20] 在这项工作中,通过数值分析和实验测试的结果分析和比较了用于航空应用的热塑性复合材料和形状记忆合金混合复合材料 (SMAHC) 的行为。 [21]
Memory Alloy Hybrid
2 m diameter, made of graphite–epoxy laminate integrated with Nitinol fibre–reinforced hybrid composite (shape memory alloy hybrid composite) patches, is considered. [1] Results indicate that a small amount of shape memory alloy fibers significantly increases the fundamental frequency and vibration control of the hybrid laminated composite reinforced with shape memory alloy hybrid laminated composite cylindrical shells. [2] A new nonlinear finite element model is proposed for the dynamic analysis of cylindrical sandwich panels with shape memory alloy hybrid composite face sheets and flexible core. [3] This investigation is concerned with the mechanical behavior of Shape Memory Alloy Hybrid Composite Beams (SMAHC), that consist of a circular bar of NiTi alloy incorporated in a 500 mm long cylindrical pipe of polypropylene (PP), with external diameter 50 mm and nominal wall thickness 7 mm, wound with a nylon/epoxy layer. [4] The paper presents free vibration of shape memory alloy hybrid composite beams by experimentally. [5] In order to attain this goal, shape memory alloy was textile-technically converted into shape memory alloy hybrid yarn using the friction spinning technology. [6] In this work, the behaviour of thermoplastic composites and Shape Memory Alloy Hybrid Composites (SMAHCs) for aeronautical applications is analysed and compared by means of findings from numerical analyses and experimental tests. [7]考虑由石墨-环氧树脂层压板与镍钛诺纤维增强混合复合材料(形状记忆合金混合复合材料)贴片集成而成,直径为 2 米。 [1] 结果表明,少量形状记忆合金纤维显着提高了形状记忆合金混合叠层复合圆柱壳增强的混合叠层复合材料的基频和振动控制。 [2] 提出了一种新的非线性有限元模型,用于对形状记忆合金混合复合面板和柔性芯材的圆柱形夹芯板进行动态分析。 [3] 本研究涉及形状记忆合金混合复合梁 (SMAHC) 的机械性能,该梁由 NiTi 合金圆棒组成,并结合在 500 毫米长的聚丙烯 (PP) 圆柱形管中,外径为 50 毫米,标称壁厚度 7 毫米,用尼龙/环氧树脂层缠绕。 [4] 本文通过实验研究了形状记忆合金混合复合梁的自由振动。 [5] 为了实现这一目标,形状记忆合金被纺织技术转化为形状记忆合金混合纱线,使用摩擦纺纱技术。 [6] 在这项工作中,通过数值分析和实验测试的结果分析和比较了用于航空应用的热塑性复合材料和形状记忆合金混合复合材料 (SMAHC) 的行为。 [7]
Aluminum Alloy Hybrid 铝合金混合动力
This work mainly focuses on increasing the mechanical strength and improving the corrosion resistance of an aluminum alloy hybrid matrix. [1] 6Si aluminum alloy hybrid composites were produced. [2] The bonding characteristics of aluminum nitride/aluminum alloy hybrid have been assessed, using scanning electron microscopy and energy dispersive X-ray spectroscopy. [3]这项工作主要集中在提高铝合金混合基体的机械强度和耐腐蚀性。 [1] 制备了6Si铝合金杂化复合材料。 [2] 已经使用扫描电子显微镜和能量色散 X 射线光谱评估了氮化铝/铝合金混合材料的结合特性。 [3]
Aluminium Alloy Hybrid
The present study investigates aluminium alloy powder (Al7075) of mesh size 60 μm and the reinforcement SiC of varying its weight percentage (2 wt%, 4 wt%, 6 wt%) and keeping constant Al2O3 (2 wt%) of particle size <50 nm has been used to synthesis aluminium alloy hybrid nanocomposites. [1] The paper presents the findings of a pioneering study investigating the newly developed polymer-aluminium alloy hybrid foam as fillers of thin-walled square tubes made of aluminium alloy, as an alternative to the conventional closed-cell aluminium foams. [2]本研究研究了网孔尺寸为 60 μm 的铝合金粉末 (Al7075) 和改变其重量百分比 (2 wt%、4 wt%、6 wt%) 并保持恒定 Al2O3 (2 wt%) 粒径 < 50 nm 已用于合成铝合金杂化纳米复合材料。 [1] 本文介绍了一项开创性研究的结果,该研究调查了新开发的聚合物-铝合金混合泡沫作为铝合金制成的薄壁方管的填料,作为传统闭孔铝泡沫的替代品。 [2]
Al7075 Alloy Hybrid Al7075 合金混合
The synthesized dual particle-reinforced Al7075 alloy hybrid composites were subjected to microstructural studies, mechanical and wear properties testing. [1] Findings: The synthesized multiple particles reinforced Al7075 alloy hybrid composites were subjected to microstructural studies and wear properties testing. [2]对合成的双颗粒增强 Al7075 合金杂化复合材料进行微观结构研究、机械和磨损性能测试。 [1] 结果:合成的多颗粒增强 Al7075 合金混合复合材料进行了微观结构研究和磨损性能测试。 [2]
alloy hybrid composite 合金混合复合材料
6Si aluminum alloy hybrid composites were produced. [1] The synthesized dual particle-reinforced Al7075 alloy hybrid composites were subjected to microstructural studies, mechanical and wear properties testing. [2] In this research, the stir casting technique used to produce ZA-12 alloy hybrid composites reinforced by nanoparticles (SiC and BN) with different weight percentages. [3] Findings: The synthesized multiple particles reinforced Al7075 alloy hybrid composites were subjected to microstructural studies and wear properties testing. [4] In this research work, an effort was made to predict the dry sliding wear response of AlMg1SiCu alloy hybrid composites which were reinforced with 10% Silicon carbide particles (SiC) together with weight fractions of 3, 6 and 9% of self-lubricant molybdenum disulphide particles (MoS2) through melt stir casting. [5] 2 m diameter, made of graphite–epoxy laminate integrated with Nitinol fibre–reinforced hybrid composite (shape memory alloy hybrid composite) patches, is considered. [6] A new nonlinear finite element model is proposed for the dynamic analysis of cylindrical sandwich panels with shape memory alloy hybrid composite face sheets and flexible core. [7] In this research stir casting technique is used to produce (ZA-27)alloy hybrid composites reinforced by nano particles (BN and Si3N4) with various weight percentage. [8] This investigation is concerned with the mechanical behavior of Shape Memory Alloy Hybrid Composite Beams (SMAHC), that consist of a circular bar of NiTi alloy incorporated in a 500 mm long cylindrical pipe of polypropylene (PP), with external diameter 50 mm and nominal wall thickness 7 mm, wound with a nylon/epoxy layer. [9] The paper presents free vibration of shape memory alloy hybrid composite beams by experimentally. [10] In this work, the behaviour of thermoplastic composites and Shape Memory Alloy Hybrid Composites (SMAHCs) for aeronautical applications is analysed and compared by means of findings from numerical analyses and experimental tests. [11]制备了6Si铝合金杂化复合材料。 [1] 对合成的双颗粒增强 Al7075 合金杂化复合材料进行微观结构研究、机械和磨损性能测试。 [2] 在这项研究中,搅拌铸造技术用于生产由不同重量百分比的纳米粒子(SiC 和 BN)增强的 ZA-12 合金混合复合材料。 [3] 结果:合成的多颗粒增强 Al7075 合金混合复合材料进行了微观结构研究和磨损性能测试。 [4] 在这项研究工作中,努力预测了用 10% 碳化硅颗粒 (SiC) 和 3%、6% 和 9% 重量分数的自润滑二硫化钼增强的 AlMg1SiCu 合金混合复合材料的干滑动磨损响应颗粒 (MoS2) 通过熔体搅拌铸造。 [5] 考虑由石墨-环氧树脂层压板与镍钛诺纤维增强混合复合材料(形状记忆合金混合复合材料)贴片集成而成,直径为 2 米。 [6] 提出了一种新的非线性有限元模型,用于对形状记忆合金混合复合面板和柔性芯材的圆柱形夹芯板进行动态分析。 [7] 在这项研究中,搅拌铸造技术用于生产由不同重量百分比的纳米颗粒(BN 和 Si3N4)增强的 (ZA-27) 合金杂化复合材料。 [8] 本研究涉及形状记忆合金混合复合梁 (SMAHC) 的机械性能,该梁由 NiTi 合金圆棒组成,并结合在 500 毫米长的聚丙烯 (PP) 圆柱形管中,外径为 50 毫米,标称壁厚度 7 毫米,用尼龙/环氧树脂层缠绕。 [9] 本文通过实验研究了形状记忆合金混合复合梁的自由振动。 [10] 在这项工作中,通过数值分析和实验测试的结果分析和比较了用于航空应用的热塑性复合材料和形状记忆合金混合复合材料 (SMAHC) 的行为。 [11]