基于木材的3D打印:纤维素和木质素3D打印建筑元素的潜力和局限性

Christopher Bierach, Alexsander Alberts Coelho, Michela Turrin, Serdar Asut, Ulrich Knaack
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引用次数: 0

摘要

在紧迫的可持续发展目标下,建筑业渴望可再生和可回收的生物材料,因为纤维素是一种纤维;木质素是一种植物来源的低成本聚合物,具有显著的性能,但其价格仍处于初级阶段。最近的研究表明,通过使用增材制造,可以对材料进行几何定制和局部控制,将纤维素和木质素结合成一种可再生的生物基材料,用于建筑环境。然而,先前的研究也强调了需要解决的关键问题。一个主要的挑战是缺乏关于木质素和纤维素与不同粘合剂的组合的知识,以获得适用于3D打印的糊状物,从而产生适用于建筑环境的材料。为了克服这一挑战,本研究旨在探索纤维素、木质素和粘合剂的各种组合,并使用安装在机械臂上的粘土挤出机研究所得糊状物的可挤出性。对几种组合进行了探索、评估和比较。得分最高的四种配方被用于生产拉伸和三点弯曲测试、吸水率和保持率测试以及显微镜分析的样品。总体结果表明,使用甲基纤维素作为粘合剂开发的混合物的机械性能与刚性聚合物泡沫(如常用作隔热板的泡沫)相似。此外,在初步评估中得分最高的材料混合物被进一步应用于制造具有不同几何形状的样品,以评估其潜力和与制造工艺相结合的局限性。最后,制作了两个演示者来探索不同几何配置的打印过程:设计概念窗框和结构节点,并进行3D打印作为概念验证。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Wood-based 3D printing: potential and limitation to 3D print building elements with cellulose & lignin

Under urgent sustainability targets, the building industry craves for renewable and recyclable biomaterials as cellulose is a fiber; Lignin is a plant-derived low-cost polymer with remarkable properties, yet its valorization is in its infancy. Recent studies have shown potentials to combine cellulose and lignin into a renewable bio-based material for the built environment, with the use of additive manufacturing to allow geometric customization and local control of material. However, previous studies also highlighted crucial issues to be solved. One main challenge is the lack of knowledge on combinations of lignin and cellulose with different binders to achieve a paste suitable for 3D printing, leading to a material applicable in the built environment. To contribute overcoming the challenge, this research aimed to explore various combinations of cellulose, lignin, and binders and to study the extrudability of the resulting paste using a clay extruder installed on a robotic arm. Several combinations were explored, evaluated, and compared. The four recipes with the highest scores were used to produce samples for tensile and three-point bending tests, water absorption and retention tests, and microscope analysis. The overall outcome has shown similarities between the mechanical properties of the mixture developed using methylcellulose as the binding agent and rigid polymer foams, such as the ones commonly used as insulation panels. Moreover, the material mix with the highest score in the preliminary assessment was further applied to fabricate samples with varied geometries to assess its potential and limitations combined with the fabrication process. Finally, two demonstrators were produced to explore the printing process for different geometric configurations: conceptual window frame and structural node were designed, and 3D printed as proof of concept.

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