Behavior of reactive powder concrete containing recycled glass powder reinforced by steel fiber

IF 1.7 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of the Mechanical Behavior of Materials Pub Date : 2022-01-01 DOI:10.1515/jmbm-2022-0025

Z. Hussain, N. Aljalawi

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引用次数: 6

Abstract

Abstract Environmental sustainability is described as one that avoids the depletion or deterioration of natural resources, while also allowing for the preservation of long-term environmental quality. By practicing environmental sustainability, we may assist to guarantee that the requirements of today’s population are satisfied without risking the capacity of future generations to meet their own needs in the future. Engineers in the field of concrete production are becoming increasingly interested in sustainable development, which includes the utilization of the locally available materials in addition to using the agricultural and industrial waste in construction industry as one of the possible solutions to the environmental and economic issues. This study investigated the effect of partial substitution of cement with recycled glass powder (0, 15, 20, and 25%) by weight of cement at various ages (on compressive strength) after determining the optimal ratio of replacement. This optimal ratio is used to study its effect on some mechanical properties (such as flexural strength, absorption, and dry density) of reactive powder concrete containing 1% micro steel fiber (SRPC), and furthermore, utilizing steam curing for 5 h at 90°C after hardening the sample directly. Reactive powder concrete (RPC) has been designed with the use of the local cement, silica fume, and super plasticizer with a water/cement ratio of 0.20 in order to achieve a compressive strength of 137.09 MPa at the age of 28 days. When recycled glass powder replacement (20%) was utilized, the findings revealed that the compressive strength of RPC improved by 4.2%, the flexural strength increased by 15.3%, the dry density increased by 0.61%, and the absorption was reduced by 32% at 28 days after the test results were compared to the reference mix.

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钢纤维增强再生玻璃粉活性粉末混凝土的性能

摘要环境可持续性被描述为避免自然资源的枯竭或恶化，同时也允许保持长期的环境质量。通过实践环境可持续性，我们可以帮助确保满足当今人口的需求，而不会危及子孙后代满足其未来需求的能力。混凝土生产领域的工程师对可持续发展越来越感兴趣，可持续发展包括利用当地可用的材料，以及利用建筑业中的农业和工业废物，作为解决环境和经济问题的可能方案之一。本研究在确定了最佳替代比例后，研究了在不同龄期用再生玻璃粉（0、15、20和25%）部分替代水泥（对抗压强度）的影响。利用该最佳配比研究了其对含1%微钢纤维（SRPC）的活性粉末混凝土某些力学性能（如抗弯强度、吸收和干密度）的影响直接硬化样品后，在90°C下加热h。活性粉末混凝土（RPC）的设计使用了当地水泥、硅灰和水灰比为0.20的超级增塑剂，以达到137.09的抗压强度 28日龄时为MPa。当使用再生玻璃粉替代物（20%）时，研究结果表明，在试验结果与参考混合物相比后28天，RPC的抗压强度提高了4.2%，弯曲强度提高了15.3%，干密度提高了0.61%，吸收率降低了32%。

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

Journal of the Mechanical Behavior of Materials Materials Science-Materials Science (miscellaneous)

CiteScore

3.00

自引率

11.10%

发文量

审稿时长

30 weeks

期刊介绍： The journal focuses on the micromechanics and nanomechanics of materials, the relationship between structure and mechanical properties, material instabilities and fracture, as well as size effects and length/time scale transitions. Articles on cutting edge theory, simulations and experiments – used as tools for revealing novel material properties and designing new devices for structural, thermo-chemo-mechanical, and opto-electro-mechanical applications – are encouraged. Synthesis/processing and related traditional mechanics/materials science themes are not within the scope of JMBM. The Editorial Board also organizes topical issues on emerging areas by invitation. Topics Metals and Alloys Ceramics and Glasses Soils and Geomaterials Concrete and Cementitious Materials Polymers and Composites Wood and Paper Elastomers and Biomaterials Liquid Crystals and Suspensions Electromagnetic and Optoelectronic Materials High-energy Density Storage Materials Monument Restoration and Cultural Heritage Preservation Materials Nanomaterials Complex and Emerging Materials.