A platform for research: civil engineering, architecture and urbanism
Sustainable incorporation of waste granite dust as partial replacement of sand in autoclave aerated concrete
Highlights Mutagenic natured waste granite dust is produced as industrial processing waste. Micro-forensics evident the pozzolanic nature of granite dust platelets. Waste granite dust forms densely packed and foiled/plate-like tobermorite crystals. Added dust dose improves the durability and strength.
Abstract Granite dust produced in the marble processing industry is fatal to human health and uneconomical to dispose because of limited disposal sites, especially in the urban regions. It contaminates the air and contributes to the particulate matter, which causes several respiratory and cardiovascular diseases. Granite dust could valuably be incorporated as partial sand replacement in autoclave aerated concrete (AAC), thereby reducing health and environmental hazards, and controlling sand depletion by fulfilling sand demand. The recent research explores the potential feasibility of adding waste granite dust (WGD) into AAC by replacing 5, 10, 15 and 20% fractional weight of sand. Micro-forensic investigations revealed these granite dust platelets as angular and flaky in shape, rough and abrasive in texture alongside amorphous crystallography with an average grain size of 15.08 µm. In conjunction with AAC, the addition of WGD effectively modified the physical, mechanical, microstructural and thermal behavior of concrete mixtures alongside their resistance to aggressive acids. The maximum increase in the compressive strength was observed to be 42% for the mix containing 20% replacement of fine aggregates by WGD, which may be attributed to the relatively refined microstructure, bearing tobermorite formation and pozzolanic actions, as evidenced in the scanning electron micrographs and thermograms. It further increased their resistance to the strong acids, which was 54% and 32% higher than that of the reference mix, when exposed to 5% solution of sulphuric acid (H2SO4) and hydrochloric acid (HCl), respectively. Conclusively, the use of WGD as partial replacement of sand provided an eco-friendly and sustainable option for AAC.
Sustainable incorporation of waste granite dust as partial replacement of sand in autoclave aerated concrete
Highlights Mutagenic natured waste granite dust is produced as industrial processing waste. Micro-forensics evident the pozzolanic nature of granite dust platelets. Waste granite dust forms densely packed and foiled/plate-like tobermorite crystals. Added dust dose improves the durability and strength.
Abstract Granite dust produced in the marble processing industry is fatal to human health and uneconomical to dispose because of limited disposal sites, especially in the urban regions. It contaminates the air and contributes to the particulate matter, which causes several respiratory and cardiovascular diseases. Granite dust could valuably be incorporated as partial sand replacement in autoclave aerated concrete (AAC), thereby reducing health and environmental hazards, and controlling sand depletion by fulfilling sand demand. The recent research explores the potential feasibility of adding waste granite dust (WGD) into AAC by replacing 5, 10, 15 and 20% fractional weight of sand. Micro-forensic investigations revealed these granite dust platelets as angular and flaky in shape, rough and abrasive in texture alongside amorphous crystallography with an average grain size of 15.08 µm. In conjunction with AAC, the addition of WGD effectively modified the physical, mechanical, microstructural and thermal behavior of concrete mixtures alongside their resistance to aggressive acids. The maximum increase in the compressive strength was observed to be 42% for the mix containing 20% replacement of fine aggregates by WGD, which may be attributed to the relatively refined microstructure, bearing tobermorite formation and pozzolanic actions, as evidenced in the scanning electron micrographs and thermograms. It further increased their resistance to the strong acids, which was 54% and 32% higher than that of the reference mix, when exposed to 5% solution of sulphuric acid (H2SO4) and hydrochloric acid (HCl), respectively. Conclusively, the use of WGD as partial replacement of sand provided an eco-friendly and sustainable option for AAC.
Sustainable incorporation of waste granite dust as partial replacement of sand in autoclave aerated concrete
Zafar, Muhammad Saeed (author) / Javed, Usman (author) / Khushnood, Rao Arsalan (author) / Nawaz, Adnan (author) / Zafar, Tayyab (author)
2020-03-23
Article (Journal)
Electronic Resource
English
AAC , Autoclave Aerated Concrete , WGD , Waste Granite Dust , H<inf>2</inf>SO<inf>4</inf> , Sulphuric Acid , HCl , Hydrochloric Acid , OPC , Ordinary Portland Cement , ASTM , American Society for Testing Materials , SEM , Scanning Electron Microscopy , XRD , X-ray Diffraction , EDX , Energy Dispersive X-ray Spectroscopy , C-S-H , Calcium Silicate Hydrate , Ca(OH)<inf>2</inf> , Calcium Hydroxide , Ca/Si , Calcium to Silica Ratio , TGA , Thermogravimetric Analysis , Autoclave aerated concrete , Waste granite dust , Tobermorite , Eco-friendly , Sustainable
European Patent Office | 2022
|Autoclave aerated concrete block produced from waste glass and production method thereof
European Patent Office | 2016
|Impact response of Autoclave Aerated Concrete/FRP sandwich structures
British Library Conference Proceedings | 2005
|