Abstract
The cement industry is responsible for 8% of global CO2 production. Therefore, a clear trend has been observed recently to replace to some extent the main binder of cement composites with environmentally friendly or recycled materials with a lower carbon footprint. This paper presents the effect of brick powder (BP) on the physico-chemical and mechanical properties of cement mortars. The effect of a short-term thermal shock on morphology and strength properties of green mortars was investigated. BP addition caused increase in porosity and decrease in compressive and flexural strength of mortars. The best results were obtained for samples with 5% wt. BP addition. Above this addition the strength decreased. The mechanical performance of the samples subjected to thermal loading increased compared to the reference samples, which is the result of a process called as the “internal autoclaving”. The BP addition positively affects the linear shrinkage, leading to its reduction. The lowest linear shrinkage value was achieved by the mortar with the highest BP addition. An intelligent modeling approach for the prediction of strength characteristics, depending on the ultrasonic pulse velocity (UPV) is also presented. To solve the model problem, a supervised machine-learning algorithm in the form of an SVM (support vector machines) regression approach was implemented in this paper. The results indicate that BP can be used as a cement replacement in cement mortars in limited amounts. The amount of the additive should be moderate and tuned to the features that mortars should have.
Highlights
The brick powder (BP) addition gradually promoted its flow. These results suggest that the increase in porosity of hardened mortars is caused by the BP addition, and the differences in microstructure are due to its physical properties
C fc and fcf based on ultrasonic pulse velocity (UPV), which can be applied in practice
The present study investigated the physical and mechanical properties of mortars with BP under thermal shock conditions
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Cement production has a negative impact on the environment [1,2,3]. This is related to the use of a huge amount of geological natural resources in the form of aggregates, and the fact of high energy consumption in the clinker firing process in cement production [4,5]. The cement industry accounts for 7–8% of global CO2 emission [6,7]
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