Embodied carbon of concrete in buildings, Part 2: are the messages accurate?

Q1 Engineering

Buildings & cities Pub Date : 2022-05-25 DOI:10.5334/bc.199

A. Moncaster, T. Malmqvist, T. Forman, Francesco Pomponi, Jane Anderson

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引用次数: 2

Abstract

This paper is the second output of a project that examines the embodied greenhouse gas emissions (‘embodied carbon’) from the use of concrete in buildings. In the current absence of either regulation or widespread industry practice in quantified carbon assessment, it seems likely that messaging will play a powerful role in influencing designers’ perceptions and decisions. Using the UK as a case study, this paper considers the current messages about the carbon implications of concrete in buildings from professional institutions and the cement and concrete trade body. Three mechanisms through which it is claimed carbon emissions are significantly reduced are identified: thermal mass, durability, and carbonation. By assessing each of these in turn against the available scientific literature, it is shown that they are likely to have a far more limited effect on the total impacts than suggested. More accuracy is needed from trade organisations if real carbon reductions are to be achieved. carbon impacts The and concrete more accurate with the messages sharing. claims thermal mass, durability and carbonation effective mechanisms, suggest carbon option, reconsidered. 127 different building superstructure frames of between two and 19 stories and found that the median values for the timber, concrete and steel frames were 119, 185 and 228 kgCO 2 e/m 2 , respectively. A further study conducted a detailed analysis of a medium-rise building using dynamic LCA and found that concrete had the highest initial impact, being somewhat higher than steel and about twice that of timber (Hawkins et al. 2021).

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建筑中混凝土的含碳量，第二部分:信息准确吗?

本文是一个项目的第二个产出，该项目研究了建筑物中使用混凝土所产生的隐含温室气体排放(“隐含碳”)。在目前缺乏量化碳评估的监管或广泛的行业实践的情况下，信息传递似乎将在影响设计师的看法和决策方面发挥强大的作用。以英国为例，本文考虑了专业机构和水泥和混凝土贸易机构关于建筑中混凝土碳影响的当前信息。确定了三种机制，通过声称碳排放显着减少:热质量，耐用性和碳化。通过对照现有的科学文献逐一评估这些因素，结果表明，它们对总影响的影响可能比人们所认为的要有限得多。如果要实现真正的碳减排，贸易组织需要提高准确性。碳影响和混凝土更准确地与信息共享。声称热质量，耐用性和碳化有效机制，建议碳选择，重新考虑。127种不同的二层至19层的建筑上部结构框架，发现木材、混凝土和钢框架的中位数分别为119、185和228 kgCO 2 e/ m2。进一步的研究使用动态LCA对一座中高层建筑进行了详细分析，发现混凝土具有最高的初始影响，略高于钢材，约为木材的两倍(Hawkins et al. 2021)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Buildings & cities

CiteScore

5.40

自引率

0.00%

发文量

审稿时长

25 weeks