Cementitious Composites with Cellulose Nanomaterials and Basalt Fiber Pellets: Experimental and Statistical Modeling

IF 4 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Fibers Pub Date : 2024-01-17 DOI:10.3390/fib12010012

O. M. Hosny, A. Yasien, M. Bassuoni, K. Gourlay, A. Ghazy

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Abstract

The production of high-performance fiber-reinforced cementitious composites (HPFRCCs) as a durable construction material using different types of fibers and nanomaterials critically relies on the synergic effects of the two materials as well as the cementitious composite mixes. In this study, novel HPFRCCs were developed, which comprised high content (50%) slag by mass of the base binder as well as nano-silica (NS) or nano-crystalline cellulose (NCC). In addition, nano-fibrillated cellulose (NFC), and basalt fiber pellets (BFP), representing nano-/micro- and macro-fibers, respectively, were incorporated into the composites. The response surface method was used in this study’s statistical modeling part to evaluate the impact of key factors (NS, NCC, NFC, BFP) on the performance of 15 mixtures. The composites were assessed in terms of setting times, early- and late-age compressive strength, flexural performance, and resistance to freezing-thawing cycles, and the bulk trends were corroborated by fluid absorption, thermogravimetry, and microscopy tests. Incorporating NS/NCC in the slag-based binders catalyzed the reactivity of cement and slag with time, thus maintaining the setting times within an acceptable range (maximum 9 h), achieving high early- (above 33 MPa at 3 days) and later-age (above 70 MPa at 28 days) strength, and resistance to fluid absorption (less than 2.5%) and frost action (DF above 90%) of the composites. In addition, all nano-modified composites with multi-scale fibers showed notable improvement in terms of post-cracking flexural performance (Residual Strength Index above 40%), which qualify them for multiple infrastructure applications (i.e., shear key bridge joints) requiring a balance between high-strength properties, ductility, and durability.

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纤维素纳米材料和玄武岩纤维颗粒水泥基复合材料：实验和统计建模

使用不同类型的纤维和纳米材料生产高性能纤维增强水泥基复合材料（HPFRCC）作为一种耐用的建筑材料，关键在于这两种材料以及水泥基复合材料混合物的协同效应。本研究开发了新型 HPFRCC，其中包括高含量（50%）矿渣（按质量计）、纳米二氧化硅（NS）或纳米结晶纤维素（NCC）作为基础粘结剂。此外，复合材料中还加入了纳米纤维素（NFC）和玄武岩纤维颗粒（BFP），分别代表纳米/微米纤维和大纤维。本研究的统计建模部分采用了响应面法，以评估关键因素（NS、NCC、NFC、BFP）对 15 种混合物性能的影响。对复合材料的凝结时间、早期和晚期抗压强度、抗弯性能和抗冻融循环性能进行了评估，并通过吸液、热重和显微测试证实了其体积趋势。在矿渣基粘结剂中掺入 NS/NCC 可随着时间的推移催化水泥和矿渣的反应性，从而将凝结时间保持在可接受的范围内（最长 9 小时），使复合材料获得较高的早期强度（3 天时高于 33 兆帕）和后期强度（28 天时高于 70 兆帕），以及抗流体吸收性（低于 2.5%）和抗冻性（DF 超过 90%）。此外，所有采用多尺度纤维的纳米改性复合材料在开裂后挠曲性能（残余强度指数高于 40%）方面都有显著改善，可用于多种需要在高强度性能、延展性和耐久性之间取得平衡的基础设施应用（如剪力键桥接缝）。

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

Fibers Engineering-Civil and Structural Engineering

CiteScore

7.00

自引率

7.70%

发文量

审稿时长

11 weeks

期刊介绍： Fibers (ISSN 2079-6439) is a peer-reviewed scientific journal that publishes original articles, critical reviews, research notes and short communications on the materials science and all other empirical and theoretical studies of fibers, providing a forum for integrating fiber research across many disciplines. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Electronic files or software regarding the full details of the calculation and experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material. The following topics are relevant and within the scope of this journal: -textile fibers -natural fibers and biological microfibrils -metallic fibers -optic fibers -carbon fibers -silicon carbide fibers -fiberglass -mineral fibers -cellulose fibers -polymer fibers -microfibers, nanofibers and nanotubes -new processing methods for fibers -chemistry of fiber materials -physical properties of fibers -exposure to and toxicology of fibers -biokinetics of fibers -the diversity of fiber origins