Transforming Waste Perlite into Super Lightweight Ceramsite: Ratios Optimization Via Uniform Design, and Investigating Calcium Fluoride and Silicon Carbide Effects on Foaming DOI
Liang Wang, Yongzhen Wang

Опубликована: Янв. 1, 2023

The utilization of waste perlite powder generated from mining operations in the construction industry represents a significant step towards enhancing environmental sustainability. This study applies uniform design experiments to delve into apparent density characteristics super lightweight ceramsite concerning proportions solid materials, with particular focus on powder. To gain insights density, first- and second-order polynomial equations were developed. These are founded five core raw including powder, fly ash, bentonite, calcium fluoride, silicon carbide, meticulously analyzed using stepwise regression techniques. approach led successful optimization test ratios, achieving envisioned outcomes. Additionally, research explores influence fluoride carbide foaming properties materials under varying maximum sintering temperature conditions. Ultimately, optimized conditions yielded impressive properties, boasting bulk 281 kg/m³, water absorption efficiency 1.2%, compressive strength 2.72 MPa. showcases potential for utilizing industry, not only as sustainable alternative but also means reduce impact. development underlines promise eco-friendly driving forward agenda environmentally responsible building practices.

Язык: Английский

Transforming Waste Perlite into Super Lightweight Ceramsite: Ratios Optimization Via Uniform Design, and Investigating Calcium Fluoride and Silicon Carbide Effects on Foaming DOI
Liang Wang, Yongzhen Wang

Опубликована: Янв. 1, 2023

The utilization of waste perlite powder generated from mining operations in the construction industry represents a significant step towards enhancing environmental sustainability. This study applies uniform design experiments to delve into apparent density characteristics super lightweight ceramsite concerning proportions solid materials, with particular focus on powder. To gain insights density, first- and second-order polynomial equations were developed. These are founded five core raw including powder, fly ash, bentonite, calcium fluoride, silicon carbide, meticulously analyzed using stepwise regression techniques. approach led successful optimization test ratios, achieving envisioned outcomes. Additionally, research explores influence fluoride carbide foaming properties materials under varying maximum sintering temperature conditions. Ultimately, optimized conditions yielded impressive properties, boasting bulk 281 kg/m³, water absorption efficiency 1.2%, compressive strength 2.72 MPa. showcases potential for utilizing industry, not only as sustainable alternative but also means reduce impact. development underlines promise eco-friendly driving forward agenda environmentally responsible building practices.

Язык: Английский

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