The impact of climate change on degradation in historical building envelopes: Progress in research using hygrothermal models

IF 3.5 2区 综合性期刊 0 ARCHAEOLOGY Journal of Cultural Heritage Pub Date : 2024-10-28 DOI:10.1016/j.culher.2024.10.005
Isabeau Vandemeulebroucke , Bruno Vanderschelden , Kaat Janssens , Steven Caluwaerts , Nathan Van Den Bossche
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Abstract

The durability of historical building envelopes is affected by changing climate conditions. The impact of climate change on degradation phenomena can be assessed by means of hygrothermal simulations. Often, studies only use a single climate projection, and thus only consider a single evolution of the climate system. However, an ensemble of multiple climate projections is necessary to assess the uncertainty of the results. This paper presents an overview of three types of uncertainties in climate projections (i.e. uncertainty due to the greenhouse gas emission scenario, climate variability, and the climate model itself), and their influence on the degradation of building envelopes. In total, the study includes the results of 16,088 1-dimensional hygrothermal simulations of solid masonry walls, prior to and after the application of a thermal retrofit, in Delphin 5 and 6. Firstly, scenario uncertainty is studied for 3 emission scenarios (one climate model) in Brussels (Belgium). The ensemble members agree on the change in freeze-thaw damage. The spread of the percentage of cases, i.e. combinations of building and exposure parameters, with an increasing freeze-thaw risk is 6%. Though, the change in wood decay is uncertain with a spread of 51%. Secondly, climate variability may cause a large uncertainty in freeze-thaw damage. In Ottawa (Canada), the spread between ensemble members (i.e. 15 realisations of one model) of the change in freeze-thaw damage goes up to 100% for individual cases. Thirdly, model uncertainty is assessed in Hamburg (Germany). Towards the end of the 21st century, the spread in percentage of cases is ca. 20% for increasing freeze-thaw damage, mould growth, and wood decay. When evaluating the change for global warming level +1.5°C, +2°C, and +3°C together, the spread increases. The risk for freeze-thaw damage in the masonry increases (decreases) in 0–52 % (8-77%) of the simulated cases. For mould growth on the interior surface of uninsulated walls, the risk increases (decreases) in 0-19% (0-10%) of the cases. Wood decay of embedded beam heads is projected to increase (decrease) in 14-42% (0-18%) of the cases. Furthermore, this paper presents three approaches on how to assess the impact of climate change on historical buildings. The generic response-based degradation atlas answers the question ‘How does climate change impact the degradation risks in the overall collection of historical buildings?’. Secondly, case-specific decision trees are used to assess which cases are most at risk, and to identify how climate change and parameter variations affect degradation risks. Finally, the in-depth Superior Advanced Minimum Requirement Approach (SAMiRA) is employed when an even more exhaustive assessment of the risk for degradation in building envelopes is required, e.g. qualification of renovation strategies. This offers a step-by-step framework that stewards the selection of simulation parameters. This paper provides an overview of how hygrothermal simulations can support decision making in heritage conservation practices, and demonstrates 3 approaches with a trade-off between specificity and (computational) cost.

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气候变化对历史建筑围护结构退化的影响:使用湿热模型的研究进展
历史建筑围护结构的耐久性受到不断变化的气候条件的影响。气候变化对退化现象的影响可以通过湿热模拟来评估。通常情况下,研究只使用单一的气候预测,因此只考虑气候系统的单一演变。然而,为了评估结果的不确定性,有必要对多种气候预测进行组合。本文概述了气候预测中的三类不确定性(即温室气体排放情景、气候变异性和气候模型本身造成的不确定性)及其对建筑围护结构退化的影响。这项研究包括在 Delphin 5 和 6 中对实心砌体墙进行热改造之前和之后的 16088 次一维湿热模拟的结果。首先,对布鲁塞尔(比利时)的 3 种排放情景(一种气候模型)进行了情景不确定性研究。组合成员就冻融破坏的变化达成了一致。冻融风险增加的情况(即建筑和暴露参数组合)的百分比分布为 6%。不过,木材腐朽的变化并不确定,其分布为 51%。其次,气候多变性可能会导致冻融损害的不确定性较大。在渥太华(加拿大),冻融损害变化的集合成员(即一个模型的 15 个实现)之间的差异在个别情况下高达 100%。第三,在汉堡(德国)对模型的不确定性进行了评估。到 21 世纪末,冻融破坏、霉菌生长和木材腐烂程度增加的案例百分比差异约为 20%。如果同时评估全球变暖水平+1.5°C、+2°C 和 +3°C时的变化情况,这种扩散会加剧。在 0-52 %(8-77%)的模拟案例中,砌体冻融破坏的风险增加(减少)。对于未隔热墙体内表面的霉菌生长,0-19%(0-10%)的情况下风险会增加(降低)。嵌入式梁头的木材腐朽预计会在 14-42%(0-18%)的情况下增加(减少)。此外,本文还介绍了评估气候变化对历史建筑影响的三种方法。基于通用响应的退化图集回答了 "气候变化如何影响整个历史建筑群的退化风险?其次,针对具体案例的决策树用于评估哪些案例风险最大,并确定气候变化和参数变化如何影响退化风险。最后,当需要对建筑围护结构的退化风险进行更加详尽的评估时,例如对翻新策略进行鉴定时,将采用深入的高级最低要求方法(SAMiRA)。该方法提供了一个指导模拟参数选择的逐步框架。本文概述了湿热模拟如何支持遗产保护实践中的决策制定,并展示了在特异性和(计算)成本之间进行权衡的 3 种方法。
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
Journal of Cultural Heritage
Journal of Cultural Heritage 综合性期刊-材料科学:综合
CiteScore
6.80
自引率
9.70%
发文量
166
审稿时长
52 days
期刊介绍: The Journal of Cultural Heritage publishes original papers which comprise previously unpublished data and present innovative methods concerning all aspects of science and technology of cultural heritage as well as interpretation and theoretical issues related to preservation.
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