Objective With the rapid progress of urbanization, energy consumption in the construction industry has become increasingly concerning. Traditional autoclaved aerated concrete, though widely used, requires high energy during production, conflicting with low-carbon and energy-saving goals. Thus, developing non-autoclaved aerated concrete with low energy consumption and good thermal insulation is a key research direction. This study also seeks to enhance the use of solid waste, particularly waste glass powder. Waste glass, difficult to degrade, poses environmental risks if improperly handled. Incorporating waste glass powder in non-autoclaved aerated concrete not only mitigates environmental pollution but also improves its properties, such as lowering thermal conductivity and increasing compressive strength. This approach aligns with sustainability goals and promotes waste recycling. The research ultimately aims to prepare lightweight, high-strength, energy-efficient, and heat-insulating nonautoclaved aerated concrete,contributing to low-carbon, eco-friendly construction.
Methods In this study, orthogonal tests were conducted with two analysis approaches: range analysis and matrix correlation analysis. First, taking dry density and compressive strength as performance indicators, a L16(44) orthogonal experiment was designed examining four factors: cement content, aluminum powder content, polypropylene (PP) fiber content, and water-material ratio. Then, range analysis method was used to determine the influence of each factor on the performance of aerated concrete. Matrix analysis was applied to calculate the comprehensive weight of different levels of each influencing factor on multiple performance indicators to determine the optimal ratio for non-autoclaved aerated concrete. In addition, different amounts of glass powder (15%,20%,25%, and 30%) were used to replace fly ash, and their effects on performance indicators such as dry density, compressive strength, and thermal conductivity were investigated.
Results and Discussion Aluminum powder had the most significant impact on the dry density and compressive strength of nonautoclaved aerated concrete. With the increase in aluminum powder content, more bubbles formed in the concrete during the gas generation process, weakening the bonding strength between aggregates. As a result, it led to a gradual decrease in dry density and compressive strength. Cement content was identified as the second most influential factor: with the increase in cement content, the compressive strength increased initially but then decreased. This occurred because a certain increase in cement would promote aggregate reaction to generate more hydration products, thereby improving the compressive strength of aerated concrete.However, excessive cement content resulted in excessive hardening and shrinkage, negatively affecting compressive strength.The increase in water-material ratio and PP fiber content showed minimal impact on dry density, with a slight influence on compressive strength. The optimal mix ratio of the foundation was determined to be 24% cement content, a 0. 44 water-material ratio,0. 13% aluminum powder content, and 0. 4% PP fiber content. The introduction of glass powder as a substitute for fly ash reduced the thermal conductivity and improved the strength of aerated concrete. At a replacement rate of 25%, the basic properties of aerated concrete were optimal, with a dry density of 592 kg/m³, a compressive strength of 2. 6 MPa, and a thermal conductivity of 0. 071 94 W/(m·K).
Conclusion This study shows that aluminum powder, cement, water-to-material ratio, and PP fiber have varying impacts on the dry density and compressive strength of non-autoclaved aerated concrete, with aluminum powder having the most notable effect. Incorporating glass powder as a fly ash substitute significantly enhances both thermal conductivity and compressive strength. The optimal material performance is achieved when the substitution rate of glass powder reaches 25%. While the thermal insulation of the prepared non-autoclaved aerated concrete exceeds current national standards, its compressive strength remains relatively low and requires further optimization. Overall, the study underscores the potential of non-autoclaved aerated concrete for energy efficiency, environmental sustainability, and material performance improvements. However, additional research is necessary to address the compressive strength limitations for practical engineering applications.
Keywords:non-autoclaved aerated concrete; glass powder; dry density; compressive strength; thermal conductivity; orthogonal test
[1]SHON C S, MUKANGALI I, ZHANG D, et al. Evaluation of non-autoclaved aerated concrete for energy behaviors of a residential house in Nur-Sultan, Kazakhstan[J]. Buildings,2021,11(12):610-610.
[2]STEL’MAKH S A, SHCHERBAN’E M, BESKOPYLNY A N, et al. Influence of recipe factors on the structure and properties of non-autoclaved aerated concrete of increased strength[J]. Applied Sciences,2022,12(14):6984-6984.
[3]DONG M H, RUAN S Q, ZHAN S L, et al. Utilization of red mud with high radiation for preparation of autoclaved aerated concrete (AAC): performances and microstructural analysis[J]. Journal of Cleaner Production,2022,347.
[4]KUNCHARIYAKUN K, ASAVAPISIT S, SINYOUNG S. Influence of partial sand replacement by black rice husk ash and bagasse ash on properties of autoclaved aerated concrete under different temperatures and times[J]. Construction and Building Materials,2018,173:220-227.
[5]PENG Y Z, LIU Y J, ZHAN B H, et al. Preparation of autoclaved aerated concrete by using graphite tailings as an alternative silica source[J]. Construction and Building Materials,2021,267.
[6]ÇELIK A İ, ÖZKILIÇ Y O, ZEYBEK Ö, et al. Mechanical behavior of crushed waste glass as replacement of aggregates[J].Materials,2022,15(22):8093-8093.
[7]DEEPA PK R B, MATOS A M, DELGADO J. Eco-friendly concrete with waste glass powder: a sustainable and circular solution[J]. Construction and Building Materials,2022,355.
[8]李卓才,柯国军,宋百姓,等. 废玻璃粉的火山灰活性[J]. 中国粉体技术,2014,20(4):74-79.
LI Z C, KE G J, SONG B X, et al. Pozzolanic activity of waste glass powders[J] China Powder Science and Technology,2014,20(4):74-79.
[9]LU J X, SHEN P L, ZHENG H B, et al. Development and characteristics of ultra high-performance lightweight cementitious composites (UHP-LCCs)[J]. Cement and Concrete Research,2021,145.
[10]SUN J B, YUE L, XU K, et al. Multi-objective optimisation for mortar containing activated waste glass powder[J]. Journal of Materials Research and Technology,2022,18:1391-1411.
[11]YI J, TUNG-CHAI L, KIM H M, et al. A critical review of waste glass powder:multiple roles of utilization in cement-based materials and construction products[J]. Journal of Environmental Management,2019,242:440-449.
[12]BELKADI A A, KESSAL O, BERKOUCHE A, et al. Experimental investigation into the potential of recycled concrete and waste glass powders for improving the sustainability and performance of cement mortars properties[J]. Sustainable Energy Technologies and Assessments,2024,64.
[13]李方,杨健,李粒珲. 废玻璃粉作为辅助胶凝材料对砂浆性能影响及作用机理[J]. 硅酸盐通报,2022,41(9):3208-3218.
LI F, YANG J, LI L H. Effect and mechanism of waste glass powder as supplementary cementitious material on mortar properties[J]. Bulletin of the Chinese Ceramic Society,2022,41(9):3208-3218.
[14]YOUNSI A, MAHI M A, HAMAMI A E A, et al. High-volume recycled waste glass powder cement-based materials: role of glass powder granularity[J]. Buildings,2023,13(7).
[15]熊志文,柯国军,陶望,等. 废玻璃粉对水泥基材料流动性能的影响[J]. 中国粉体技术,2021,27(1):80-89.
XIONG Z W, KE G J, TAO W, et al. Influence of waste glass powder on fluidity of cement-based materials[J]. China Powder Science and Technology,2021,27(1):80-89.
[16]NASRY O, SAMAOUALI A, BELAROUF S, et al. Thermophysical properties of cement mortar containing waste glass powder[J]. Crystals,2021,11(5):488-488.
[17]BOUKHELF F, CHERIF R, TRABELSI A, et al. On the hygrothermal behavior of concrete containing glass powder and silica fume[J]. Journal of Cleaner Production,2021,318.
[18]WALCZAK P, MAŁOLEPSZY J, REBEN M, et al. Utilization of waste glass in autoclaved aerated concrete[J]. Procedia Engineering,2015,122:302-309.
[19]SZUDEK W, GOŁEK Ł, MALATA G, et al. Influence of waste glass powder addition on the microstructure and mechanical properties of autoclaved building materials[J]. Materials,2022,15(2):434-434.
[20]THAKUR A, KUMAR S. Mechanical properties and development of light weight concrete by using autoclaved aerated concrete (AAC) with aluminum powder[J]. Materials Today: Proceedings,2022,56(P6):3734-3739.
[21]杨磊, 何廷树,盖国胜,等. 纤维特性对砂加气混凝土力学性能和微观结构的影响[J]. 硅酸盐通报,2018,37(6):1813-1817.
YANG L, HE T S, GAI G S, et al. Effect of fiber properties on mechanical properties and microstructure of sand aerated concrete[J]. Bulletin of the Chinese Ceramic Society,2018,37(6):1813-1817.
[22]王善冬. 免蒸压加气混凝土制备与性能研究[D]. 南京:东南大学,2016.
WANG S D. Research on preparation and performance of autoclav-free aerated concrete[D]. Nanjing: Southeast University,2016.
