Alloy Az31b(合金 Az31b)研究综述
Alloy Az31b 合金 Az31b - Plasma electrolytic oxidation (PEO) and a subsequent direct electroless nickel (EN) plating were carried out on magnesium (Mg) alloy AZ31B. [1] Large pulsed electron beam (LPEB) irradiation was employed as a surface treatment of magnesium (Mg) alloy AZ31B to enhance its corrosion and wear resistance. [2]在镁 (Mg) 合金 AZ31B 上进行等离子电解氧化 (PEO) 和随后的直接化学镀镍 (EN)。 [1] 采用大脉冲电子束 (LPEB) 辐照作为镁 (Mg) 合金 AZ31B 的表面处理,以增强其耐腐蚀性和耐磨性。 [2]
Magnesium Alloy Az31b 镁合金 Az31b
In the forming process of magnesium alloy AZ31B, the pulse current can significantly lift the elongation and reduce the flow stress. [1] Purpose: The current study examined magnesium alloy AZ31B specimens manufactured with Additive Manufacturing method (selective laser melting – SLM) to investigate the applicability of this technology for the production of medical devices. [2] The subsequent tensile response of the magnesium alloy AZ31B sheet along the transverse direction and the rolling direction after pre-deformation is simulated. [3] The effect of shot peening on mechanical properties and ballistic resistance of plates from magnesium alloy AZ31B 25 × 300 × 300 mm in size to the piercing action of a projectile (diameter 7. [4] Magnesium alloy AZ31B is an important lightweight, high specific strength material for new generations of energy-effective vehicles. [5] In this study, magnesium alloy AZ31B is used as reinforcement material and graphene nanoparticle is used as reinforcement material. [6] This paper presents results obtained by ISIM Timisoara for FSW welding of magnesium alloy AZ31B. [7] In this study, the optimization of the symmetrical temperature distribution and process loading path for the warm T-shape forming of magnesium alloy AZ31B tube was carried out by finite element (FE) analysis using a fuzzy model. [8] The mechanical response of magnesium alloy AZ31B is addressed thanks to four-point bending tests. [9] In this work, a series of high-rate tension experiments were performed on thin foil specimens of hot rolled magnesium alloy AZ31B using a miniaturized tensile Kolsky bar along an array of angles in the normal-rolling plane at strain rates of nominally 10 4 s − 1. [10] The starting texture from a rolled magnesium alloy AZ31B sheet was obtained using electron backscatter diffraction (EBSD) for initial input into the NVPSC. [11] In this work, we employed a unique solid-state joining process, friction self-piercing riveting (F-SPR), to join carbon fiber composites to the low-ductility magnesium alloy AZ31B. [12] In this study the conversion of plastic work to heat of a hot-rolled magnesium alloy AZ31B is investigated using a mechanism-based approach. [13] This research aims to characterize damage at the sheared edge caused by the blanking operation of magnesium alloy AZ31B sheets. [14] In the present work, an effort has been made to optimize the external magnetic field (EMF) for mechanical properties of magnesium alloy AZ31B weld. [15] In this study, the role of texture on the quasi-static and dynamic response of pure magnesium and magnesium alloy AZ31B is investigated. [16] As a consequence, the conjunction of viscoplastic self-consistent model and twinning and detwinning scheme (VPSC–TDT) is employed to investigate the in-plane anisotropy of magnesium alloy AZ31B-O sheet. [17] As a result, it has been verified that light metal alloys such as magnesium alloy AZ31B with good ductile and fatigue strength can easily be joined with FSSW. [18] The dynamic recrystallization (DRX) behavior of magnesium alloy AZ31B with large initial grain size was investigated. [19] 5 wt% NaCl) on the corrosion behavior of magnesium alloy AZ31B was investigated by using a rotating disc electrode. [20]在镁合金AZ31B的成形过程中,脉冲电流可以显着提升延伸率,降低流动应力。 [1] 目的:目前的研究检查了使用增材制造方法(选择性激光熔化 - SLM)制造的镁合金 AZ31B 试样,以研究该技术在医疗器械生产中的适用性。 [2] 模拟了镁合金AZ31B板材在预变形后沿横向和轧制方向的后续拉伸响应。 [3] 喷丸强化对尺寸为 25 × 300 × 300 mm 的镁合金 AZ31B 板的机械性能和抗弹道性对弹丸(直径 7. [4] 镁合金AZ31B是新一代节能汽车的重要轻量化、高比强度材料。 [5] 本研究采用镁合金AZ31B作为增强材料,石墨烯纳米颗粒作为增强材料。 [6] 本文介绍了 ISIM Timisoara 获得的用于镁合金 AZ31B 的 FSW 焊接的结果。 [7] 在本研究中,通过使用模糊模型的有限元分析,对镁合金 AZ31B 管温 T 形成形的对称温度分布和工艺载荷路径进行了优化。 [8] 由于四点弯曲测试,镁合金 AZ31B 的机械响应得到解决。 [9] 在这项工作中,在热轧镁合金 AZ31B 的薄箔试样上进行了一系列高速拉伸实验,使用小型拉伸 Kolsky 棒沿着正常轧制平面中的一系列角度以标称 10 4 s 的应变速率进行 - 1. [10] 使用电子背散射衍射 (EBSD) 获得轧制镁合金 AZ31B 板的起始织构,用于初始输入到 NVPSC。 [11] 在这项工作中,我们采用了独特的固态连接工艺——摩擦自冲铆接 (F-SPR),将碳纤维复合材料连接到低延展性镁合金 AZ31B。 [12] 在这项研究中,使用基于机理的方法研究了热轧镁合金 AZ31B 的塑性功向热量的转化。 [13] 本研究旨在表征由镁合金 AZ31B 板材的冲裁操作引起的剪切边缘处的损伤。 [14] 在目前的工作中,已经努力优化外部磁场 (EMF) 以改善镁合金 AZ31B 焊缝的机械性能。 [15] 在这项研究中,研究了织构对纯镁和镁合金 AZ31B 准静态和动态响应的作用。 [16] 因此,采用粘塑性自洽模型与孪生和去孪生方案(VPSC-TDT)的结合来研究镁合金AZ31B-O板的面内各向异性。 [17] 结果证实,具有良好延展性和疲劳强度的镁合金AZ31B等轻金属合金可以很容易地与FSSW接合。 [18] 研究了具有大初始晶粒尺寸的镁合金AZ31B的动态再结晶(DRX)行为。 [19] 使用旋转圆盘电极研究了 5 wt% NaCl)对镁合金 AZ31B 腐蚀行为的影响。 [20]
Mg Alloy Az31b
In the present paper two sheet forming processes (the Super Plastic Forming and the Incremental Sheet Forming) have been investigated for manufacturing a resorbable cheekbone implant using the Mg alloy AZ31B. [1] Therefore, this paper presents a breakthrough in tool design through the appropriate control of temperature distribution of the Mg alloy AZ31B tubular material to minimise the wrinkling defects in THF at evaluated temperatures. [2] The work presented herein provides advancements in the understanding of corrosion resistant Mg alloys and is pertinent to the potential use of Mg-Sn alloys in transport applications, battery electrode materials and as a candidate sacrificial anode for the cathodic protection of Mg alloy AZ31B-H24. [3] Diffraction data were collected using synchrotron X-ray scattering (sXRD) and electron back-scattered diffraction (EBSD) during in situ tensile-compressive deformation of Mg alloy AZ31B dogbone samples. [4]在本文中,研究了两种片材成型工艺(超塑性成型和增量片材成型),以使用 AZ31B 镁合金制造可吸收的颧骨植入物。 [1] 因此,本文通过适当控制镁合金 AZ31B 管状材料的温度分布,在评估温度下最大限度地减少 THF 中的起皱缺陷,提出了工具设计的突破。 [2] 本文介绍的工作在对耐腐蚀镁合金的理解方面取得了进展,并与 Mg-Sn 合金在运输应用、电池电极材料和作为 Mg 合金 AZ31B-H24 阴极保护的候选牺牲阳极的潜在用途相关。 [3] 在镁合金 AZ31B 狗骨样品的原位拉伸-压缩变形过程中,使用同步加速器 X 射线散射 (sXRD) 和电子背散射衍射 (EBSD) 收集衍射数据。 [4]
alloy az31b sheet
The subsequent tensile response of the magnesium alloy AZ31B sheet along the transverse direction and the rolling direction after pre-deformation is simulated. [1] The starting texture from a rolled magnesium alloy AZ31B sheet was obtained using electron backscatter diffraction (EBSD) for initial input into the NVPSC. [2] This research aims to characterize damage at the sheared edge caused by the blanking operation of magnesium alloy AZ31B sheets. [3]模拟了镁合金AZ31B板材在预变形后沿横向和轧制方向的后续拉伸响应。 [1] 使用电子背散射衍射 (EBSD) 获得轧制镁合金 AZ31B 板的起始织构,用于初始输入到 NVPSC。 [2] 本研究旨在表征由镁合金 AZ31B 板材的冲裁操作引起的剪切边缘处的损伤。 [3]