用Scheffe数学模型优化稻壳灰分混凝土抗压强度

IF 0.5 Q4 MATERIALS SCIENCE, COMPOSITES
G. Akeke, C. Nnaji, U. Udokpoh
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引用次数: 1

摘要

作为混凝土重要组成部分的水泥成本高,导致大多数发展中国家的混凝土生产成本高。混合水泥因其使用寿命长、成本效益好,在发达国家越来越受欢迎。稻壳灰(RHA)是稻壳燃烧后产生的残渣,在碾米机中大量存在。RHA因其能耗低、加工和使用期间温室气体排放少、火山灰反应强等优点,已被证明是一种很好的混凝土生产补充胶凝材料。本研究采用Scheffe(4,2)简单点阵设计,建立了优化RHA钢筋混凝土抗压强度的数学模型。RHA作为混凝土中的第二组分,与水、水泥、细骨料和粗骨料一起使用,在水泥中的部分替代率为20%。RHA混凝土的抗压强度是使用Scheffe 's Simplex技术来确定各种成分比以及用于验证Scheffe模型的控制点。使用f统计检验、学生t检验和5%显著性水平的方差分析来评估模型的充分性。统计结果表明,从所建立的舍夫模型得到的数值与控制实验室数据之间具有令人满意的相关性。水、粘结剂(80%水泥和20% RHA)、细骨料和粗骨料配比为0.47:1.0:2.5:4.5时,得到的RHA混凝土最大抗压强度为40.75 N/mm 2,对应的配合比为0.475:1.0:2.75:3.50;最小抗压强度为7.41 N/mm 2。使用已建立的Scheffe 's simplex模型可以高精度地计算混合元素与特定所需抗压强度值的比例,同时还可以通过解决试验混合挑战在更短的时间内给出答案。胶结材料;环境污染。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Compressive strength optimisation of rice husk ash concrete using Scheffe’s mathematical model
The high cost of cement as a significant component of concrete has led to the high cost of concrete production in most developing countries. Because of its longevity and good benefit-to-cost ratio, blended cement has grown in popularity in developed countries. Rice husk ash (RHA) is a residue produced by the burning of rice husk that is abundant in rice mills. RHA has been proven as a good supplementary cementitious material for concrete production due to its low energy requirements, minimal greenhouse gas emissions during processing and service life, and strong pozzolanic reaction. Using Scheffe’s (4, 2) simplex-lattice design, a mathematical model was developed to optimise the compressive strength of RHA reinforced concrete in this research. RHA was used as the second component in concrete, along with water, cement, fine and coarse aggregates, at a partial replacement ratio of 20% in cement. The compressive strength of RHA concrete was determined using Scheffe’s Simplex technique for the various componential ratios as well as the control points that would be used to validate the Scheffe’s model. The model’s adequacy was assessed using the f-statistics test, the student’s t-test, and ANOVA at a 5% significance level. The statistical result shows a satisfactory correlation between the values produced from the developed Scheffe’s model and the control laboratory data. The maximum compressive strength of RHA concrete obtained was 40.75 N/mm 2 corresponding to a mix ratio of 0.475: 1.0: 2.75: 3.50 and the minimum compressive strength obtained was 7.41 N/mm 2 corresponding to a mix ratio of 0.47: 1.0: 2.5: 4.5 for water, binder (80% cement and 20% RHA), fine aggregate, and coarse aggregate, respectively. The ratio of the mix elements to a particular required compressive strength value may be calculated with a high degree of precision using the established Scheffe’s simplex model, while also giving the answer in less time by resolving trial mix challenges. cementitious materials; environmental pollution.
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