Sustainable use of 3D-printed plastic waste as aggregate in self-compacting mortar: A study on rheological, mechanical and thermal performance

IF 5.8 3区环境科学与生态学 0 ENVIRONMENTAL SCIENCES

Environmental Science and Pollution Research Pub Date : 2025-09-03 DOI:10.1007/s11356-025-36902-6

Usman Nazir, Min-Chih Liao, Duy-Hai Vo

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Abstract

Plastic waste poses environmental and health risks, highlighting the need for sustainable reuse in construction. This study introduces a novel solution to plastic waste utilization by: (1) developing rheological testing equipment from plastic using 3D printing technology, and (2) enhancing the rheological performance of self-compacting mortar (SCM) with 3D-printed plastic fine aggregates (3DPFA). SCM mixtures incorporating 5%, 10%, 15%, and 20% 3DPFA as a replacement for natural sand were prepared and tested to evaluate fresh, mechanical, and thermal properties through mini-slump flow, T20 spread time, J-ring flow, V-funnel, compressive strength, UPV, and thermal conductivity tests. Results revealed that incorporating 3DPFA significantly enhanced workability and flow characteristics. The mini-slump spread increased progressively with higher 3DPFA content, showing a 6% improvement at 20% replacement compared to the control. T20 flow time decreased markedly, reaching 2 s at 20% 3DPFA, indicating improved flowability. Similarly, J-ring tests demonstrated enhanced passing ability, with increased spread and reduced height differences, maintaining slump flow differences within acceptable limits. V-funnel flow time reduced from 7 s in the control mix to 5 s with 20% 3DPFA, confirming improved viscosity and flow dynamics. Furthermore, thermal conductivity showed a substantial reduction of up to 22%. These findings highlight a promising pathway for plastic waste valorization in the construction sector.

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3d打印塑料废料作为自密实砂浆骨料的可持续利用：流变学、力学和热性能研究。

塑料废物构成环境和健康风险，突出了在建筑中可持续再利用的必要性。本研究提出了一种塑料废物利用的新解决方案：(1)利用3D打印技术开发塑料流变学测试设备；(2)用3D打印塑料细骨料（3DPFA）增强自密实砂浆（SCM）的流变学性能。将5%、10%、15%和20%的3DPFA作为天然砂的替代品，制备SCM混合物，并通过微坍落度流动、T20扩散时间、j型环流动、v型漏斗、抗压强度、UPV和导热性测试来评估其新鲜、机械和热性能。结果表明，加入3DPFA显著提高了可加工性和流动特性。随着3DPFA含量的增加，微坍落度逐渐增加，与对照组相比，在替换量为20%时，微坍落度提高了6%。T20流动时间明显缩短，在20% 3DPFA时达到2 s，表明流动性有所改善。同样，j型环测试也证明了通过能力的增强，扩展范围增大，高度差减小，将坍落度流动差保持在可接受的范围内。v型漏斗流动时间从对照混合物的7秒减少到20% 3DPFA的5秒，证实了粘度和流动动力学的改善。此外，导热系数也大幅降低了22%。这些发现突出了建筑行业塑料废物增值的有希望的途径。

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

Environmental Science and Pollution Research 环境科学-环境科学

CiteScore

8.70

自引率

17.20%

发文量

6549

审稿时长

3.8 months

期刊介绍： Environmental Science and Pollution Research (ESPR) serves the international community in all areas of Environmental Science and related subjects with emphasis on chemical compounds. This includes: - Terrestrial Biology and Ecology - Aquatic Biology and Ecology - Atmospheric Chemistry - Environmental Microbiology/Biobased Energy Sources - Phytoremediation and Ecosystem Restoration - Environmental Analyses and Monitoring - Assessment of Risks and Interactions of Pollutants in the Environment - Conservation Biology and Sustainable Agriculture - Impact of Chemicals/Pollutants on Human and Animal Health It reports from a broad interdisciplinary outlook.