Alloy Produced(合金生产)研究综述
Alloy Produced 合金生产 - The alloy produced by arc melting contains only biocompatible elements and has an attractive combination of mechanical properties with a tensile strength of 1050 MPa and Young's modulus of 66 GPa. [1] Finally, SEM images were taken from the inner surfaces of the machined holes and the fractured surfaces from tensile test, and information about the machinability of this alloy produced with PM was presented. [2] The plastic deformation of the alloy produced using vacuum arc remelting was investigated through a room-temperature compression test at different strain rates. [3] This work investigated the surface deformation structures of turbine blade root of single crystal nickel-based superalloy produced under different creep feed grinding conditions. [4] After tempering, starting from as-built and from quenched condition, a dispersion of nano-sized V and Cr-rich second phases was formed in the microstructure, achieving hardness values comparable to those obtained by the same alloy produced by conventional methods. [5] It was found that the peculiar microstructure of the alloy produced by additive manufacturing is responsible for good high-temperature strength of the material up to 150 °C. [6] The 2524-T3 aluminium (Al) alloy produced by ALCOA may be used as skin material by the aircraft industry. [7] The alloy produced by laser powder bed fusion was not susceptible to pitting in the considered environments and had a good localized corrosion resistance, slightly higher than that of traditional wrought material. [8] After casting, the alloy produced under each condition was partially melted to a 0. [9] %) alloy produced at different cooling rates by means of different casting processes such as Belt Casting, Twin Roller and Single Roller Melt Spinning techniques was studied. [10] Various test techniques, including optical microscopy, scanning electron microscope, X-ray diffraction, tensile tests, and hardness were used to examine the effect of this alloy produced by the gravity and squeeze casting processes. [11] The results of chemical composition showed that the alloy produced has good quality and low content of gaseous impurities, such as oxygen and nitrogen. [12] Emission factors vary with the type of rare earth metal or alloy produced and from one facility to another, ranging from 165. [13] The alloy manufactured via LPBF is found to be significantly stronger and more ductile than the same alloy produced by casting. [14]通过电弧熔炼生产的合金仅包含生物相容性元素,并且具有 1050 MPa 的拉伸强度和 66 GPa 的杨氏模量的机械性能的有吸引力的组合。 [1] 最后,从机加工孔的内表面和拉伸试验的断裂表面拍摄了 SEM 图像,并提供了有关用 PM 生产的合金的可加工性的信息。 [2] 通过在不同应变率下的室温压缩试验研究了真空电弧重熔合金的塑性变形。 [3] 本工作研究了在不同蠕变进给磨削条件下生产的单晶镍基高温合金涡轮叶片根部的表面变形结构。 [4] 回火后,从竣工状态和淬火状态开始,在微观结构中形成纳米级富V和Cr第二相的分散体,其硬度值可与传统方法生产的相同合金获得的硬度值相媲美。 [5] 发现通过增材制造生产的合金的特殊微观结构是材料在高达 150°C 时具有良好的高温强度的原因。 [6] 由 ALCOA 生产的 2524-T3 铝 (Al) 合金可用作飞机工业的蒙皮材料。 [7] 激光粉末床熔合生产的合金在所考虑的环境中不易出现点蚀,并且具有良好的局部耐腐蚀性,略高于传统锻造材料。 [8] 铸造后,在每种条件下生产的合金部分熔化至 0。 [9] %) 合金通过不同的铸造工艺(例如带式铸造、双辊和单辊熔体旋压技术)在不同冷却速率下生产。 [10] 各种测试技术,包括光学显微镜、扫描电子显微镜、X 射线衍射、拉伸试验和硬度,用于检查重力和挤压铸造工艺生产的这种合金的效果。 [11] 化学成分分析表明,所生产的合金质量好,氧、氮等气态杂质含量低。 [12] 排放因子因生产的稀土金属或合金的类型以及从一个设施到另一个设施而异,从 165 不等。 [13] 发现通过 LPBF 制造的合金比通过铸造生产的相同合金更坚固且更具延展性。 [14]
selective laser melting 选择性激光熔化
The presented paper investigates strength, ductility, hardness, and microstructure of the AlSi10Mg alloy produced by the selective laser melting (SLM). [1] The addition of Sc and Zr into an Al–Mg–Mn alloy produced by selective laser melting exhibited exceptional properties. [2] In the present work, an ML based framework is proposed to predict the evolution of local strain distribution, plastic anisotropy and failure during tensile deformation of AlSi10Mg aluminum alloy produced by selective laser melting (SLM). [3] This work investigates the corrosion behavior of AlSi10Mg alloy produced by selective laser melting (SLM) and the counterparts heat-treated at 450–550 °C in 3. [4] The present study aims to evaluate the effect of post-heat treatment on the corrosion performance of AlSi10Mg alloy produced by selective laser melting (SLM). [5] Titanium alloy produced by selective laser melting (SLM) requires surface treatment to improve its bioactivity. [6] Friction stir processing (FSP) was successfully applied to AlSi10Mg alloy produced by selective laser melting. [7]本文研究了通过选择性激光熔化 (SLM) 生产的 AlSi10Mg 合金的强度、延展性、硬度和微观结构。 [1] 将 Sc 和 Zr 添加到通过选择性激光熔化生产的 Al-Mg-Mn 合金中表现出优异的性能。 [2] nan [3] 这项工作研究了通过选择性激光熔化 (SLM) 生产的 AlSi10Mg 合金和在 3 中在 450-550°C 热处理的对应物的腐蚀行为。 [4] 本研究旨在评估后热处理对选区激光熔化 (SLM) 生产的 AlSi10Mg 合金的腐蚀性能的影响。 [5] nan [6] nan [7]
direct metal laser
The purpose of the present paper was to investigate the effect of shot peening on the condition of the surface layer and abrasion resistance of specimens made of Ti-6Al-4V titanium alloy produced by Direct Metal Laser Sintering (DMLS) process. [1] This study investigates the influence of temperature and duration of solution and ageing treatment on microstructure, hardness and density of AlSi10Mg alloy produced by direct metal laser sintering. [2] The influence of strain-induced martensitic transformation on the mechanical properties of a Co–28Cr–6Mo alloy produced using the direct metal laser sintering additive manufacturing technique was analyzed. [3] We employed phase-filed models to simulate microstructure evolution and solidification behaviour of AlSi10Mg alloy produced using direct metal laser sintering (DMLS) technique. [4]本论文的目的是研究喷丸处理对直接金属激光烧结 (DMLS) 工艺生产的 Ti-6Al-4V 钛合金试样表面层状况和耐磨性的影响。 [1] 本研究研究了温度、固溶时间和时效处理对直接金属激光烧结生产的AlSi10Mg合金组织、硬度和密度的影响。 [2] nan [3] nan [4]
high pressure die 高压模具
This article investigates the fatigue performance of A356-T6 aluminum alloy produced by high pressure die cast (HPDC) under different loading conditions. [1] 67 wt% Gd addition on the microstructure and tensile properties of Mg–4Al–5RE (where RE represents La–Ce mischmetal) alloy produced by sand casting (SC), permanent mold casting (PMC), and high-pressure die casting (HPDC). [2] 6Mn alloy produced using high-pressure die casting technique (HPDC). [3]本文研究了高压压铸(HPDC)生产的A356-T6铝合金在不同载荷条件下的疲劳性能。 [1] 添加 67 wt% Gd 对砂型铸造 (SC)、永久型铸造 (PMC) 和高压压铸 (HPDC) 生产的 Mg-4Al-5RE(其中 RE 代表 La-Ce 混合金属)合金的微观结构和拉伸性能有影响)。 [2] nan [3]
high cycle fatigue 高周疲劳
The fatigue and fracture behavior of an ultrafine-grained near β Ti-5Al-5V-5Mo-1Cr-1Fe alloy produced by radial shear rolling and subsequent aging was investigated by very high cycle fatigue (VHCF) testing with the stress ratio R = –1. [1] Fracture behavior of VT22 near β titanium alloy produced by radial shear rolling and subsequent aging was studied in very high cycle fatigue tests with ultrasonic vibration frequency. [2] The high-cycle and very-high-cycle fatigue (VHCF) behaviors of AlSi10Mg alloy produced by additive manufacturing (AM) were studied. [3]通过超高周疲劳 (VHCF) 试验研究了径向剪切轧制和随后时效生产的超细晶近 β Ti-5Al-5V-5Mo-1Cr-1Fe 合金的疲劳和断裂行为,应力比 R = – 1. [1] 在超声振动频率的超高周疲劳试验中研究了径向剪切轧制和随后时效生产的 VT22 近 β 钛合金的断裂行为。 [2] nan [3]
laser powder bed 激光粉床
0°, 90°, 67° hatch angle and a chessboard with 67° hatch angle strategy (CB + 67°), were adopted to study the microstructure and mechanical anisotropy of Hastelloy X superalloy produced by Laser Powder Bed Fusion (LPBF). [1] Here, based on three-dimensional representative volume elements, a crystal plasticity model is applied and solved using the fast Fourier transform method for the AlSi10Mg alloy produced by laser powder bed fusion. [2] The AlSi10Mg alloy produced by laser powder bed fusion (LPBF) possesses a novel microstructure and higher mechanical properties compared with its casting counterpart. [3]采用0°、90°、67°孵化角和67°孵化角策略(CB+67°)的棋盘,研究了激光粉末床融合(LPBF)生产的哈氏合金X高温合金的微观结构和力学各向异性。 [1] 在此,基于三维代表体积元,采用快速傅里叶变换方法对激光粉末床熔合制备的AlSi10Mg合金应用并求解了晶体塑性模型。 [2] nan [3]
electron beam melting 电子束熔化
High-current pulsed electron-beam (PEB) treatment was applied as a surface finishing procedure for Ti–35Nb–7Zr–5Ta (TNZT) alloy produced by electron beam melting (EBM). [1] This study presents a model for Ti6Al4V alloy produced by applying electron beam melting as continuum media with orthotropic elastic and plastic properties and its application in total hip replacement (THR). [2]采用大电流脉冲电子束 (PEB) 处理作为通过电子束熔化 (EBM) 生产的 Ti-35Nb-7Zr-5Ta (TNZT) 合金的表面处理工艺。 [1] 本研究提出了将电子束熔化作为具有正交各向异性弹性和塑性特性的连续介质生产的 Ti6Al4V 合金模型及其在全髋关节置换术 (THR) 中的应用。 [2]
powder bed fusion 粉床融合
6) heat-treatable alloy produced by laser-based powder bed fusion (LPBF, also known as selective laser melting). [1]6)激光基粉末床熔合(LPBF,又称选择性激光熔化)生产的可热处理合金。 [1]
Alsi10mg Alloy Produced 生产Alsi10mg合金
The presented paper investigates strength, ductility, hardness, and microstructure of the AlSi10Mg alloy produced by the selective laser melting (SLM). [1] In parallel, the creep response of an AlSi10Mg alloy produced by additive manufaturing and tested in the as-deposited condition was investigated at temperatures ranging from 150 to 225 °C. [2] Here, based on three-dimensional representative volume elements, a crystal plasticity model is applied and solved using the fast Fourier transform method for the AlSi10Mg alloy produced by laser powder bed fusion. [3] The AlSi10Mg alloy produced by laser powder bed fusion (LPBF) possesses a novel microstructure and higher mechanical properties compared with its casting counterpart. [4] For this reason, the properties of CERANOD®—PEO coating on an AlSi10Mg alloy produced by SLM were investigated on different AM surfaces, i. [5] The high-cycle and very-high-cycle fatigue (VHCF) behaviors of AlSi10Mg alloy produced by additive manufacturing (AM) were studied. [6] This work investigates the corrosion behavior of AlSi10Mg alloy produced by selective laser melting (SLM) and the counterparts heat-treated at 450–550 °C in 3. [7] ΔK diagrams of the AlSi10Mg alloy produced by SLM. [8] The present study aims to evaluate the effect of post-heat treatment on the corrosion performance of AlSi10Mg alloy produced by selective laser melting (SLM). [9] This study investigates the influence of temperature and duration of solution and ageing treatment on microstructure, hardness and density of AlSi10Mg alloy produced by direct metal laser sintering. [10] We employed phase-filed models to simulate microstructure evolution and solidification behaviour of AlSi10Mg alloy produced using direct metal laser sintering (DMLS) technique. [11] Potentiodynamic tests were performed on AlSi10Mg alloy produced using laser powder bed fusion. [12] Friction stir processing (FSP) was successfully applied to AlSi10Mg alloy produced by selective laser melting. [13]本文研究了通过选择性激光熔化 (SLM) 生产的 AlSi10Mg 合金的强度、延展性、硬度和微观结构。 [1] 同时,研究了通过增材制造生产并在沉积状态下测试的 AlSi10Mg 合金在 150 至 225°C 的温度范围内的蠕变响应。 [2] 在此,基于三维代表体积元,采用快速傅里叶变换方法对激光粉末床熔合制备的AlSi10Mg合金应用并求解了晶体塑性模型。 [3] nan [4] nan [5] nan [6] 这项工作研究了通过选择性激光熔化 (SLM) 生产的 AlSi10Mg 合金和在 3 中在 450-550°C 热处理的对应物的腐蚀行为。 [7] SLM生产的AlSi10Mg合金的ΔK图。 [8] 本研究旨在评估后热处理对选区激光熔化 (SLM) 生产的 AlSi10Mg 合金的腐蚀性能的影响。 [9] 本研究研究了温度、固溶时间和时效处理对直接金属激光烧结生产的AlSi10Mg合金组织、硬度和密度的影响。 [10] nan [11] nan [12] nan [13]
Titanium Alloy Produced 生产的钛合金
Fracture behavior of VT22 near β titanium alloy produced by radial shear rolling and subsequent aging was studied in very high cycle fatigue tests with ultrasonic vibration frequency. [1] The heat-affected coarsening of β-grains in titanium alloy produced by additive manufacturing (AM), which would be important for the achievement of fine β-grain like forging, was completely neglected in the past. [2] The purpose of the present paper was to investigate the effect of shot peening on the condition of the surface layer and abrasion resistance of specimens made of Ti-6Al-4V titanium alloy produced by Direct Metal Laser Sintering (DMLS) process. [3] In this paper, laser ultrasonic technology, as an advanced nondestructive testing method, is applied to measure residual stress in TC4 titanium alloy produced by LAM for the first time. [4] Numeric simulation of compression test was carried out for a high-porous structure of a titanium alloy produced by additive manufacturing method with non-equiaxial performance of pore cells. [5] Titanium alloy produced by selective laser melting (SLM) requires surface treatment to improve its bioactivity. [6] This study proves that the pulsed electric current provoked a fast recrystallization and phase transformation process of a titanium alloy produced by equal channel angular pressing. [7]在超声振动频率的超高周疲劳试验中研究了径向剪切轧制和随后时效生产的 VT22 近 β 钛合金的断裂行为。 [1] 过去完全忽略了增材制造 (AM) 生产的钛合金中 β 晶粒的热影响粗化,这对于实现精细 β 晶粒锻造具有重要意义。 [2] 本论文的目的是研究喷丸处理对直接金属激光烧结 (DMLS) 工艺生产的 Ti-6Al-4V 钛合金试样表面层状况和耐磨性的影响。 [3] 本文首次将激光超声技术作为一种先进的无损检测方法应用于LAM生产的TC4钛合金的残余应力测量。 [4] nan [5] nan [6] nan [7]
Aluminum Alloy Produced 生产的铝合金
This article investigates the fatigue performance of A356-T6 aluminum alloy produced by high pressure die cast (HPDC) under different loading conditions. [1] To evaluate the different material models, uniaxial and biaxial tensile tests and hydraulic bulging tests are carried out on a 5182-O aluminum alloy produced by Kobelco. [2] , Gaussian process, decision tree, random forest, gradient boosting, and multi-layer perceptron) were evaluated for the prediction of the ultimate tensile strength (UTS) in joints of AISI 1045 steel and 2017-T4 aluminum alloy produced by rotary friction welding with laser assistance. [3] In the present work, an ML based framework is proposed to predict the evolution of local strain distribution, plastic anisotropy and failure during tensile deformation of AlSi10Mg aluminum alloy produced by selective laser melting (SLM). [4] In this study, 6056 aluminum alloy produced through continuous casting direct rolling (CCDR) was investigated. [5] Lap joints of AA2014 aluminum alloy produced by friction stir welding and subjected to post weld heat treatment have been studied. [6] This work investigates the mechanical behavior of A357 aluminum alloy produced by SLM in the as built and artificially aged conditions. [7]本文研究了高压压铸(HPDC)生产的A356-T6铝合金在不同载荷条件下的疲劳性能。 [1] 为了评估不同的材料模型,对由 Kobelco 生产的 5182-O 铝合金进行了单轴和双轴拉伸试验和液压胀形试验。 [2] nan [3] nan [4] nan [5] 研究了采用搅拌摩擦焊制备AA2014铝合金搭接接头并进行焊后热处理。 [6] 这项工作研究了 SLM 生产的 A357 铝合金在竣工和人工时效条件下的力学行为。 [7]