权益分类	功能权益	普通用户	{{item.name}}会员
{{category.name}}	{{benefitItem.name}}

Dispersion Strengthened Magnesium Alloys - Solidification of Nanocolloids

弥散强化镁合金 - 纳米胶体的凝固

基本信息

批准号：
EP/W005042/1
负责人：
Hari Babu Nadendla
金额：
$ 96.46万
依托单位：
Brunel University London
依托单位国家：
英国
项目类别：
Research Grant
财政年份：
2022
资助国家：
英国
起止时间：
2022 至无数据
项目状态：
未结题

来源：
https://gtr.ukri.org/projects?ref=EP%2FW005042%2F1
关键词：
Dispersion Strengthened Magnesium Alloys Solidification

项目摘要

Vehicle lightweighting represents a vital strand of an integrated national approach to transport decarbonisation. There is a general agreement that the CO2 emissions from cars needs to be cut by at least 50% to prevent the well-to-wheels carbon emission from the world car fleet rising above 7bn tonnes rather than the more sustainable 4bn tonnes by 2050. The UK Government has set an even higher target of a 60% reduction in transport sector CO2 emissions by 2030. Implementation of lightweighting across all classes of vehicles plays an important role in achieving this target.Magnesium (Mg), as a lightest structural metal combined with superior damping capacity, has tremendous potential in achieving lightweighting in vehicles with improved noise, vibration and harshness performance. Recent Mg market research suggests that the global Mg alloys market will increase from £1 billion in 2018 to £2.8 billion by 2026, at a CAGR of ~12.7% between 2019 and 2026 which is expected to be driven by demand for Mg alloys from the automotive & transportation applications due to fuel efficiency and emission regulations. The automotive industry is aiming to increase Mg content from 8.6kg/car in 2017 to 45kg/car by 2030. Among variety of Mg alloys, aluminium containing Mg (Mg-Al) alloys are being used in automotive sector due to their competitive cost. However, their widespread use in vehicle is hindered by their lower strength. To help realise this growth and to meet the stringent design and safety criteria for lightweighting, it is necessary to enhance the strength of existing cost-effective Mg-Al alloys significantly. The addition of rare-earth (RE) elements and noble metals in magnesium has been successfully utilised to achieve a significant improvement in strength. The alloys that have high RE content exhibit improved strength that meets lightweight design requirement. However, due to the resource scarcity and high cost, the alloys containing RE elements are impractical for their mass structural applications in automotive sector. The role of precipitation hardening in Mg alloys could be fulfilled by ex-situ phase particles, if they are dispersed within the Mg matrix rather than segregated at the grain boundaries. Substantiated by the proof-of-concept study, the proposed research programme aims to develop high strength, cost effective dispersion strengthened magnesium (DSM) alloys. It also investigates the criteria for the stability of nanocolloids, solidification behaviour and establishes process maps suitable for manufacturing DSM alloys using practical casting processes. Technologically, the DSM alloys represent a step change in the manufacturing technology to produce lightweight automotive components. If certain Al and steel are replaced with DSM alloys, the expected weight saving would be significant. In the longer term, it will lead to a significant reduction in CO2 emissions and offer sizable fuel savings. The industrial partners, comprising a materials supplier, component producers, alloy designer and an end user are an added value and help to accelerate the knowledge transfer activity from academia to industry.

车辆轻量化是国家综合运输脱碳方法的重要组成部分。人们普遍认为，到2050年，汽车的二氧化碳排放量需要减少至少50%，以防止世界汽车车队从油井到车轮的碳排放量超过70亿吨，而不是更可持续的40亿吨。英国政府制定了更高的目标，即到2030年将交通运输部门的二氧化碳排放量减少60%。镁合金作为最轻的结构金属，具有优良的上级阻尼性能，在实现车辆轻量化、改善噪声、振动和声振粗糙度方面具有巨大的潜力。最近的镁市场研究表明，全球镁合金市场将从2018年的10亿英镑增加到2026年的28亿英镑，2019年至2026年的复合年增长率约为12.7%，预计这将受到汽车和运输应用对镁合金需求的推动，因为燃油效率和排放法规。汽车行业的目标是到2030年将镁含量从2017年的8.6kg/辆提高到45 kg/辆。在各种镁合金中，含铝镁合金（Mg-Al）由于其具有竞争力的成本而被用于汽车行业。然而，它们在车辆中的广泛使用受到其较低强度的阻碍。为了帮助实现这种增长并满足轻量化的严格设计和安全标准，有必要显着提高现有具有成本效益的Mg-Al合金的强度。在镁中添加稀土（RE）元素和贵金属已成功地用于实现强度的显著改善。具有高RE含量的合金具有更高的强度，满足轻质设计要求。然而，由于资源稀缺和成本高，含有稀土元素的合金在汽车行业的大规模结构应用是不切实际的。如果非原位相颗粒分散在镁基体中而不是在晶界处偏析，则可以实现镁合金中的沉淀硬化作用。通过概念验证研究，拟议的研究计划旨在开发高强度，具有成本效益的弥散强化镁（DSM）合金。它还研究了纳米胶体的稳定性，凝固行为的标准，并建立了适用于使用实际铸造工艺制造DSM合金的工艺图。从技术上讲，DSM合金代表了生产轻质汽车部件的制造技术的一个步骤。如果用DSM合金代替某些铝和钢，预期的重量减轻将是显著的。从长远来看，它将导致二氧化碳排放量的显着减少，并提供可观的燃料节省。工业合作伙伴包括材料供应商、组件生产商、合金设计师和最终用户，这是一种附加价值，有助于加速学术界向工业界的知识转移活动。