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Behaviour and design of stainless steel structures in fire

不锈钢结构在火灾中的行为和设计

基本信息

批准号：
EP/V034405/1
负责人：
Merih Kucukler
金额：
$ 41.71万
依托单位：
University of Warwick
依托单位国家：
英国
项目类别：
Research Grant
财政年份：
2021
资助国家：
英国
起止时间：
2021 至无数据
项目状态：
未结题

来源：
https://gtr.ukri.org/projects?ref=EP%2FV034405%2F1
关键词：
Behaviour design stainless steel structures

项目摘要

Owing to its unique combination of excellent corrosion resistance, low maintenance requirements and high performance in fire and under impact loading, stainless steel manifests itself an appropriate and advantageous construction material for projects where corrosion resistance, durability, maintenance costs or resistance to fire or extreme loading are of importance. Stainless steel is also highly recyclable and reusable, making it a sustainable construction material. Traditionally, due to its initial high material cost, stainless steel has been regarded as an option limited to specialist and prestige applications. However, with increased awareness on whole life-cycle costing and sustainability, rather than simply initial expenditure, the use of stainless steel in the construction and offshore industries has been increasing. At elevated temperatures, stainless steel displays higher strength and stiffness retention relative to carbon steel with different material stress-strain response, leading to considerably enhanced structural performance for stainless steel structural elements relative to those made of carbon steel in fire. However, thus far, this high performance of stainless steel structural elements in fire has been neither scientifically well explored, nor has a design guidance leading to its efficient exploitation been developed. In fact, the current British and European structural steel fire design standard Eurocode 3 Part 1.2 recommends the design methods originally developed for carbon steel members for the fire design of stainless steel structural members. This unsurprisingly leads to very inaccurate estimations of the response of stainless steel structures in fire, precluding the efficient use of their high performance at elevated temperatures by structural engineers in practice. For projects where thermal protection is not used to showcase the attractive appearance of stainless steel, inefficient fire design rules, which may govern cross-section sizes, lead to excessive material use and thus very uneconomic solutions. With the aim of achieving a step-change in understanding the response of stainless steel structural elements at elevated temperatures and in their fire design, the proposed research will involve comprehensive numerical studies on the behaviour of stainless steel structural elements in fire and lead to the development of statistically validated design guidance able to exploit the high performance of stainless steel structures at elevated temperatures. The proposed research will not only consider structural elements made of traditional stainless steel grades but also those made of a number of novel, cost-effective and high performance stainless steel grades recently introduced into the market for structural engineering applications; for the first time, elevated temperature material tests will be carried out on these stainless steel grades in this project. Possessing a number of novel aspects such as involving the first comprehensive investigations on the response of stainless steel plates, sections, columns and beams in fire and the elevated temperature material tests on new stainless steel grades whose elevated temperature material properties are unknown, it is envisaged that the proposed project will fill an important gap of knowledge with respect to the behaviour and design of stainless steel structures in fire. In this project, all the design guidance will be prepared adopting the Eurocode 3 Part 1.2 philosophy; it is anticipated that the project will generate design methods suitable for incorporation into the future versions of Eurocode 3 Part 1.2.

由于其优异的耐腐蚀性，低维护要求和高性能的火灾和冲击载荷的独特组合，不锈钢本身表现出一个适当的和有利的建筑材料的项目，耐腐蚀性，耐用性，维护成本或耐火性或极端负荷是重要的。不锈钢也是高度可回收和可重复使用的，使其成为可持续的建筑材料。传统上，由于其最初的高材料成本，不锈钢一直被认为是一种仅限于专业和信誉应用的选择。然而，随着对全生命周期成本和可持续性的认识的提高，而不仅仅是初始支出，不锈钢在建筑和海上工业中的使用一直在增加。在高温下，不锈钢相对于碳钢显示出更高的强度和刚度保持率，具有不同的材料应力-应变响应，导致不锈钢结构元件相对于由碳钢制成的那些元件在火灾中的结构性能显著增强。然而，到目前为止，不锈钢结构元件在火灾中的这种高性能既没有得到科学的充分探索，也没有开发出有效开发的设计指导。实际上，现行的英国和欧洲结构钢防火设计标准Eurocode 3 Part 1.2推荐了最初为碳钢构件开发的设计方法，用于不锈钢结构构件的防火设计。这就导致了对不锈钢结构在火灾中的响应的非常不准确的估计，从而妨碍了结构工程师在实践中有效地利用其在高温下的高性能。对于不使用热保护来展示不锈钢吸引人的外观的项目，低效的防火设计规则可能会控制横截面尺寸，导致过多的材料使用，从而导致非常不经济的解决方案。为了实现在高温下理解不锈钢结构元件的响应及其防火设计方面的逐步变化，拟议的研究将涉及对不锈钢结构元件在火灾中的行为进行全面的数值研究，并导致统计验证的设计指南的发展，能够利用不锈钢结构在高温下的高性能。拟议的研究将不仅考虑由传统不锈钢牌号制成的结构元件，而且还考虑由最近引入市场用于结构工程应用的一些新颖，具有成本效益和高性能的不锈钢牌号制成的结构元件;在该项目中，将首次对这些不锈钢牌号进行高温材料试验。具有许多新颖的方面，例如首次对不锈钢板、型材、柱和梁在火灾中的反应进行了全面研究，并对高温材料性能未知的新不锈钢牌号进行了高温材料试验，据设想，拟议的项目将填补一个重要的知识空白方面的行为和设计的不锈钢结构，火在本项目中，所有设计指南将采用欧洲规范3第1.2部分的理念编制;预计该项目将产生适合纳入欧洲规范3第1.2部分未来版本的设计方法。