Effects of Grinding Methods and Water-to-Binder Ratio on the Properties of Cement Mortars Blended with Biomass Ash and Ceramic Powder

• Published in: Materials Vol. 16; no. 6; p. 2443
• Main Authors: Pantić, Vladan, Šupić, Slobodan, Vučinić-Vasić, Milica, Nemeš, Tomas, Malešev, Mirjana, Lukić, Ivan, Radonjanin, Vlastimir
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 18.03.2023; MDPI
• Subjects: Agricultural wastes; Ashes; Binders (materials); Biomass; By products; Cement; Cement hydration; Cement industry; ceramic powder; Ceramic powders; Ceramics; Ceramics industry; Construction; corn cob ash; Depletion; Dilution; dilution effect; Ecological footprint; Emissions; Factories; Feasibility studies; Grinding; Industrial plant emissions; Industrial wastes; Laboratories; Literature reviews; Manufacturing; Masonry; Mechanical properties; Methods; mortar; Mortars (material); Natural resources; Physical properties; Powders; Power plants; Raw materials; Roofing; SCM; Steel production; Sustainable development; Technology assessment; Water absorption; water-to-binder ratio; Serbia; corn cob ash; water-to-binder ratio; mortar; SCM; ceramic powder; dilution effect
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma16062443

To combat environmental challenges-such as the depletion of natural resources and a high carbon footprint-and contribute to the effort of achieving zero-waste technology and sustainable development, the use of agricultural and industrial wastes in the cement industry has created a research interest. This study explores the potential of two types of harvest residue ash (HRA) and three types of ceramic waste (CP) as supplementary cementitious materials (SCMs) through: (1) the characterization of raw materials and (2) examining the physical properties and mechanical performance of cement-based mortar samples prepared with 10%, 30% and 50%wt of the selected SCMs ground into powder form as cement replacement. Two main variables were the water-to-binder ratio (w/b) and the effect of different grinding procedures. Experimental results demonstrated that flexural and compressive strengths were not significantly impaired by SCM additions of up to 50%, but higher replacement levels led to an increased permeability and higher capillary water absorption due to the dilution effect. Also, a lower w/b was shown to effectively reduce the porosity of mortar and increase its mechanical properties, allowing for higher shares of SCMs to be utilized. This study verifies the technical feasibility of cob corn ash and ceramic powder application as SCMs in mortar formulations, further promoting the practice of incorporating industrial and agricultural by-products in greener cementitious composites.