用于高密度纤维水泥的可持续微纤维素添加剂:注重流变机械性能和性价比分析

Sreenath Raghunath, Mahfuzul Hoque, Behzad Zakani, Akash Madhav Gondaliya and E. Johan Foster
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引用次数: 0

摘要

为应对气候变化(即全球变暖),可通过在水泥基质中加入纤维素纤维(纤维水泥)来减少水泥基建筑材料的二氧化碳足迹。然而,这种材料的设计对制造工艺提出了巨大的技术挑战,并与其流变机械性能密切相关。因此,通常会在纤维水泥浆中添加聚羧酸盐类(源自石油化工)流变改性剂和二氧化硅类(致癌)添加剂。从技术上讲,微纤维素生物材料是一种可行的生态友好型替代材料,能够改变流变-机械性能,但在高密度(8 wt.%纤维)纤维水泥方面尚有待探索。在此,我们采用了形态独特的α-纤维素(AC)和微晶纤维素(MCC)作为流变力学添加剂。纤维水泥中生物材料的总含量高达 12 wt.%,其中微纤维素添加剂(AC/MCC)与纤维素纤维的比例按比例变化。因此,根据组合 1(AC 和纤维)和组合 2(MCC 和纤维)制造了各种复合材料,并对其流变-机械性能进行了表征,以了解这种形态独特的微纤维素的影响。首先,流变分析表明,组合 1 在任何含量下都能降低屈服应力(改善可加工性),其中 4 wt.% AC 含量表明屈服应力最大降低了 30%。其次,抗弯强度分析表明,组合 1 和组合 2 提高了断裂模数(MOR),组合 2(MCC 含量为 6 wt.%)使断裂模数提高了 42%。最后,我们介绍了成本性能比分析(经济角度),强调了这种可持续流变改性剂和添加剂对水泥基复合材料的积极影响--这是在不影响强度重量比的情况下实现低碳建筑材料的可能途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Sustainable micro-cellulosic additives for high-density fiber cement: emphasis on rheo-mechanical properties and cost–performance analysis†

Sustainable micro-cellulosic additives for high-density fiber cement: emphasis on rheo-mechanical properties and cost–performance analysis†

To combat climate change (i.e., global warming), reducing the CO2 footprint of cement-based building materials can be substantiated by incorporating cellulosic fibers into the cement matrix (fiber cement). However, such materials design imposes tremendous technical challenges towards the fabrication process, interlinked to its rheo-mechanical properties. Thus, polycarboxylate-based (petrochemical-derived) rheology modifiers and silica-based (carcinogenic) additives are usually added to the fiber-cement slurry. Micro-cellulosic biomaterials are technically a viable eco-friendly alternative, capable of modifying the rheo-mechanical properties, yet to be explored for high-density (>8 wt% fiber) fiber cement. Herein, we have employed morphologically distinctive alpha-cellulose (AC) and microcrystalline cellulose (MCC) as rheo-mechanical additives. The total content of biomaterials in the fiber cement was up to 12 wt%, where the ratio between the micro-cellulosic additive (AC/MCC) and the cellulosic fibers varied proportionally. As a result, various composites were fabricated based on combinations 1 (AC and fibers) and 2 (MCC and fibers), and their rheo-mechanical properties were characterized to understand the effect of this morphologically distinctive micro-cellulose. Firstly, the rheological analysis revealed that combination 1 reduced the yield stress (improving the workability) at any content – with 4 wt% AC content indicating a maximum reduction in yield stress of 30%. Secondly, flexural strength analysis revealed that combinations 1 and 2 improve the modulus of rupture (MOR), and combination 2 (at 6 wt% MCC content) resulted in a 42% increase in MOR. Finally, we presented the cost-to-performance ratio analysis (economic perspective), highlighting the positive ramifications of this sustainable rheology modifier and additives for the cement-based composite – an avenue for low-embodied carbon building materials without compromising the strength-to-weight ratio.

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