Sahand Rahemipoor , Mohamad Bayat , Masoud Hasany , Mohammad Mehrali , Kristoffer Almdal , Navid Ranjbar , Mehdi Mehrali
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引用次数: 0
摘要
本研究探讨了在可 3D 打印砂浆中用微胶囊相变材料(MEPCM)替代沙子的潜力,为改善 3D 打印建筑物的热性能提供了一种可行的方法。添加微胶囊相变材料后,水泥基砂浆的流变性能和早期硬化演化都得到了明显改善,无需使用粘指剂即可用于 3D 打印应用。在硬化砂浆中,微结构分析和热循环实验证实,MEPCM 在水泥基环境中保持完整和稳定。经过处理的砂浆的热性能(包括潜热和导热性)得到了改善,可用于节能应用。尽管如此,随着 MEPCM 浓度的增加,砂浆的抗压强度大幅下降,但仍保持在 20 兆帕以上。三维有限元法(FEM)和一维还原阶次模型(ROM)的模拟结果与热设置中打印墙体的实验数据非常吻合,验证了一维 ROM 模拟可用于长期预测。在一项案例研究中,在真实天气条件下,与不含 MEPCM 的砂浆相比,用 MEPCM 替代 80% 砂的印刷墙的能耗降低了 40%。
Microencapsulated phase change material in 3D-printable mortars
The present study investigates the potential of replacing sand with microencapsulated phase change materials (MEPCM) in 3D-printable mortar to provide a promising way to improve thermal performance in 3D-printed buildings. Adding MEPCM significantly enhanced the rheological properties and early hardening evolution of cementitious mortar for 3D printing applications without the need for viscosity modifier agents. In hardened mortars, microstructural analysis and thermal cycling experiments confirmed that MEPCM remained intact and stable within the cementitious environment. The thermal properties of the treated mortars, including latent heat and thermal conductivity, were improved for energy-saving applications. Despite this, the compressive strength of the mortars dropped considerably by increasing the concentration of MEPCM while a strength of above 20 MPa was maintained. Simulation results from 3D Finite Element Method (FEM) and 1D reduced order model (ROM) closely matched the experimental data from printed walls in a thermal setup, validating the use of 1D ROM simulations for long-term predictions. In a case study, a printed wall where MEPCM replaced 80 % of the sand showed a ∼40 % reduction in energy consumption compared to mortar without MEPCM under real weather conditions.
期刊介绍:
The journal Energy Conversion and Management provides a forum for publishing original contributions and comprehensive technical review articles of interdisciplinary and original research on all important energy topics.
The topics considered include energy generation, utilization, conversion, storage, transmission, conservation, management and sustainability. These topics typically involve various types of energy such as mechanical, thermal, nuclear, chemical, electromagnetic, magnetic and electric. These energy types cover all known energy resources, including renewable resources (e.g., solar, bio, hydro, wind, geothermal and ocean energy), fossil fuels and nuclear resources.