堆放设计对废弃混凝土碳化的影响:对中国碳管理的启示。

IF 3.7 4区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL
Panxiu Wang, Dawei Wang, Asim A Ditta, Xiao Qi
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引用次数: 0

摘要

提高废弃混凝土的固碳能力对于实现建筑行业的碳中和至关重要。虽然现有研究主要集中在混凝土固碳的理论分析上,但对废弃混凝土在不同环境条件下的堆放阶段的固碳潜力探索却关注有限。为了填补这一知识空白,我们开发了一个针对废弃混凝土堆放阶段的二氧化碳吸收计算模型。该模型研究了破碎尺寸、堆放方法和环境条件对总碳封存能力和效率的影响,找出了最有利的方法。我们的研究结果如下(1) 增加废弃混凝土的破碎粒度可提高固碳能力,但会延长固碳时间。要达到理想的固碳效率,5-20 毫米的破碎粒度被认为是最佳粒度。(2) 最佳堆放方法是采用半径和角度较小的桩。(3) 高温和高湿度会加快固碳速度。可采取浇水、覆盖等切实可行的措施来提高固碳效果。(4) 2021 年,中国废弃混凝土的固碳潜力呈现出由东南向西北和东北地区递减的趋势。最大固碳潜力可中和当年建筑业产生的 4% 的碳排放量。这项研究为准确评估废弃混凝土的固碳潜力和制定有效的固碳策略奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Influence of stockpile design on carbonation of waste concrete: Implications for carbon management in China.

Enhancing the sequestration capacity of waste concrete is crucial for achieving carbon neutrality within the construction industry. Although existing studies primarily focus on theoretical analysis of concrete carbon sequestration, limited attention has been paid to explore the potential of waste concrete sequestration during stockpiling phase under varying environmental conditions. To fill this knowledge gap, we developed a CO2 uptake calculation model tailored for the stockpiling phase of waste concrete. This model investigates the impact of crush size, stacking method and environmental conditions on the total carbon sequestration capacity and efficiency, identifying the most advantageous approach. Our findings reveal the following: (1) Increasing the crush size of waste concrete enhances its carbon sequestration capacity, albeit extends the sequestration duration. A crush size of 5-20 mm is deemed optimal for achieving the desired sequestration efficiency. (2) The optimal stacking method involves smaller piles with reduced radii and angles. (3) High temperatures and humidity levels accelerate the sequestration rate. Practical measures such as watering and covering can be employed to enhance carbon sequestration. (4) In 2021, China's waste concrete exhibited a declining sequestration potential from the southeast to the northwest and northeast regions. The maximum sequestration potential has the capacity to neutralize up to 4% of the carbon emissions generated by the construction industry in that year. This research provides a foundation for accurate assessment and the development of effective carbon sequestration strategies for waste concrete.

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来源期刊
Waste Management & Research
Waste Management & Research 环境科学-工程:环境
CiteScore
8.50
自引率
7.70%
发文量
232
审稿时长
4.1 months
期刊介绍: Waste Management & Research (WM&R) publishes peer-reviewed articles relating to both the theory and practice of waste management and research. Published on behalf of the International Solid Waste Association (ISWA) topics include: wastes (focus on solids), processes and technologies, management systems and tools, and policy and regulatory frameworks, sustainable waste management designs, operations, policies or practices.
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