Fabrication and investigation of nano particle, fibre and nanotube multiscale reinforced aluminium matrix composites

纳米粒子、纤维和纳米管多尺度增强铝基复合材料的制备与研究

• 批准号: RGPIN-2019-05054
• 负责人: Nganbe, Michel
• 金额: $ 2.04万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=714732
• 关键词: Fabrication; investigation; nano; particle; fibre

Depleting natural resources and increasing environmental concerns are current major challenges. In addition, increases in mobility, performance, speed and safety are constant demands. These challenges have made high-performance lightweight materials fundamental concepts of today's technology, particularly in automotive, aerospace and defence. Therefore, the proposed research program aims at developing lightweight, gradient, multiscale reinforced aluminium matrix composites using fibres, nanotubes and nanoparticles. A novel and cost efficient laminate squeeze casting technique will be developed. The required squeeze pressure will be achieved using primarily differences in thermal expansions of the set-up components with little to no need for presses or other compaction equipment. This enables easy technology transfer to industry. In this technique, thin pre-fabricated aluminium green layers melt and infiltrate the sandwiched fiber layers over short distances, minimising temperature and pressure drops that are challenges often encountered in standard liquid infiltration using 3D preforms. Research will focus on carbon fiber as primary reinforcement, while carbon and boron nitride nanotube will be studied as reinforcement of the fiber-matrix interface to improve bonding. Additional hardening of the aluminium matrix will be achieved using primarily Al2O3 nanoparticles introduced in the greens by mechanical alloying and powder metallurgy. Functional gradients will be introduced by varying the concentrations of reinforcements across the composite thickness. This will increase the efficiency of the composites by matching properties to specific load distributions across components. The composites will be characterised using optical and scanning electron microscopy as well as X-ray diffraction. Bend and impact testing will be used to study the strength, stiffness, impact fracture resistance and failure modes. To guide further improvements, relationships will be established between fabrication parameters, microstructure, and mechanical properties using physics-based, neural network, finite element and meshless modelling. The proposed research will have a major economic impact for Canada as the world's third largest producer of primary aluminium, with an annual output estimated at 3.2 million tonnes, exports totaling over $12.7 billion in 2017, and over 10,000 direct jobs for primary aluminium production alone. It aims at expanding Canada's capacity to manufacture value-added aluminium products. The emphasis is on new composites for highly demanding applications in automotive, aerospace and defence. Near pressureless fabrication aims at matching manufacturing practices which will facilitate industry adoption and increase the technological impact of metal matrix composites. Overall, the targeted high performance-to-weight ratios will contribute to increased efficiency, mobility and safety as well as to reduced energy consumption and environmental impact.

自然资源枯竭和环境问题日益严重是当前的主要挑战。此外，对机动性、性能、速度和安全性的要求也在不断提高。这些挑战使得高性能轻质材料成为当今技术的基本概念，特别是在汽车、航空航天和国防领域。 因此，拟议的研究计划旨在开发轻质，梯度，多尺度增强铝基复合材料使用纤维，纳米管和纳米粒子。将开发一种新型的、具有成本效益的叠层挤压铸造技术。所需的挤压压力将主要利用设置组件的热膨胀差异来实现，几乎不需要压力机或其他压实设备。这使得技术很容易向工业转移。在这种技术中，薄的预制铝绿色层在短距离内熔化并渗透夹层纤维层，从而最小化温度和压降，这是使用3D预制件的标准液体渗透中经常遇到的挑战。研究将集中在碳纤维作为主要增强材料，而碳和氮化硼纳米管将作为纤维-基体界面的增强材料进行研究，以改善粘合。通过机械合金化和粉末冶金，将主要使用引入生坯中的Al 2 O3纳米颗粒来实现铝基质的额外硬化。功能梯度将通过改变复合材料厚度上的增强物浓度来引入。这将通过将属性与组件之间的特定负载分布相匹配来提高复合材料的效率。复合材料将使用光学和扫描电子显微镜以及X射线衍射进行表征。弯曲和冲击试验将用于研究强度、刚度、抗冲击断裂性和失效模式。为了指导进一步的改进，将使用基于物理的神经网络、有限元和无网格建模来建立制造参数、微观结构和机械性能之间的关系。 拟议的研究将对加拿大产生重大经济影响，加拿大是世界第三大原铝生产国，年产量估计为320万吨，2017年出口总额超过127亿美元，仅原铝生产就有超过10，000个直接就业岗位。该项目旨在扩大加拿大生产高附加值铝产品的能力。重点是为汽车、航空航天和国防领域的高要求应用开发新型复合材料。近无压制造的目的是匹配的制造实践，这将促进工业采用和增加金属基复合材料的技术影响。总体而言，目标高性能重量比将有助于提高效率、机动性和安全性，并降低能耗和环境影响。