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Abstract

The effect of sintering temperature on the characteristics of lightweight aggregate made from steel mill sludge and fly ash by one step was studied. Lightweight aggregates made from fly ash and steel mill sludge mixed at a ratio of 8:2 sintered at 1050, 1100, 1150 and 1200 ^oC were characterised by scanning electron microscope-energy dispersive spectrometer and X-ray diffraction to analyse the microstructure evolution mechanism and its effect on performance. The attained lightweight aggregate has a compressive strength of 4.0 MPa, a bulk density of 721 kg m⁻³ and water absorption of 12.6%. With the increase of sintering temperature, the surface of aggregate becomes denser, and there are abundant closed pores inside. This structure ensures the performance of a high compressive strength, low water absorption and low bulk density of aggregate. The major mineral phases are quartz (SiO₂)，anorthite (CaAl₂Si₂O₈), mullite (Al₆Si₂O₁₃) and hematite (Fe₂O₃) when temperature was between 1100 and 1200 ^oC. The needle-shape mullite interlaced into a network structure on the anorthite matrix, which greatly enhanced the strength of the lightweight aggregate. This study demonstrates that the sintering temperature is one of key factors to determine the performances of lightweight aggregate, and the best sintering temperature is 1150 ^oC.

Keywords

Steel mill sludge fly ash lightweight aggregate the mineral phase sintering temperature

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References

Das

Prakash

Reddy

PSR

, et al. An overview of utilization of slag and sludge from steel industries. Resour Conserv Recy 2007; 50: 40–57.

Narinder

Jehangeer

Francesco

, et al. Advancements in lightweight artificial aggregates: typologies, compositions, applications, and prospects for the future. Sustainability 2024; 16: 9329.

Uche

CKA

Abubakar

Nnamchi

, et al. Polyethylene terephthalate aggregates in structural lightweight concrete: a meta-analysis and review. Discov Mater 2023; 3: 24.

Korol

Głodniok

Hejna

, et al. Manufacturing of lightweight aggregates as an auspicious method of sewage sludge utilization. Materials 2020; 13: 5635.

Chiou

Chen

. Properties of artificial lightweight aggregates made from waste sludge. Comput Concrete 2011; 8: 617–629.

Mañosa

Formosa

Giro-Paloma

, et al. Valorisation of water treatment sludge for lightweight aggregate production. Constr Build Mater 2021; 269: 121335.

Latosińska

Zygadło

. The application of sewage sludge as an expanding agent in the production of lightweight expanded clay aggregate mass. Environ Technol 2011; 32: 1471–1478.

Volland

Kazmina

Vereshchagin

, et al. Recycling of sand sludge as a resource for lightweight aggregates. Constr Build Mater 2014; 52: 361–365.

González-Corrochano

Alonso-Azcárate

Rodas

, et al. Microstructure and mineralogy of lightweight aggregates produced from washing aggregate sludge, fly ash and used motor oil. Cement Concrete Comp 2010; 32: 694–707.

10.

Kadhar

Gopal

Sivakumar

, et al. Optimizing flow, strength, and durability in high-strength self-compacting and self-curing concrete utilizing lightweight aggregates. Materia-Rio De Janeiro 2024; 29: e20230336.

11.

Nakouzi

Mielewski

Ball

, et al. A novel approach to paint sludge recycling: reclaiming of paint sludge components as ceramic composites and their applications in reinforcement of metals and polymers. J Mater Res 1998; 13: 53–60.

12.

Tuan

BLA

Hwang

Lin

, et al. Development of lightweight aggregate from sewage sludge and waste glass powder for concrete. Constr Build Mater 2013; 47: 334–339.

13.

Cheeseman

Virdi

. Properties and microstructure of lightweight aggregate produced from sintered sewage sludge ash. Resour Conserv Recy 2005; 45: 18–30.

14.

Mehmet

Baran

Fuat

, et al. Evaluation and multi-objective optimization of lightweight mortars parameters at elevated temperature via Box-Behnken optimization approach. Materials 2021; 14: 1–19.

15.

Kaya

Köksal

. Physical and mechanical properties of C class fly ash based lightweight geopolymer mortar produced with expanded vermiculite aggregate. Revista De La Construccion 2022; 21: 21–35.

16.

Mandlik

Karale

. Sludge use in concrete as a replacement of cement. Int J Res Eng Appl Manag 2018; 3: 22–27.

17.

Malliou

Katsioti

Georgiadis

, et al. Properties of stabilized/solidified admixtures of cement and sewage sludge. Cement Concrete Comp 2006; 29: 55–61.

18.

Karol

Mateusz

Myroslav

, et al. Modification of lightweight aggregate concretes with silica nanoparticles-A review. Materials 2021; 14: 1–23.

19.

Liu

Wang

, et al. Effect of SiO₂ and Al₂O₃ on characteristics of lightweight aggregate made from sewage sludge and river sediment. Ceram Intl 2018; 44: 4313–4319.

20.

Corrochano

Azcárate

Gonzalez

. Heavy metal chemical fractionation and immobilization in lightweight aggregates produced from mining and industrial waste. Int J Environ Sci Technol 2011; 8: 667–676.

21.

. Treatment and utilization of municipal sludge. Beijing: Science Press, 2003.

22.

Bian

Han

, et al. Mullite whisker reinforced porous anorthite ceramics with low thermal conductivity and high strength. J Eur Ceram Soc 2016; 36: 761–765.

23.

Hong

Chen

Huang

, et al. Fabrication and characterization of lightweight aggregate prepared from steel mill sludge in one step. J Mater Cycles Waste 2022; 4: 1072–1082.

24.

Junaid M

Rehman Z

Kuruc

, et al. Lightweight concrete from a perspective of sustainable reuse of waste byproducts. Constr Build Mater 2022; 319: 126061.

25.

Liu

Wang

Bai

, et al. Effects of sintering temperature on the characteristics of lightweight aggregate made from sewage sludge and river sediment. J Alloy Compd 2018; 748: 522–527.

26.

Mostafa

Shaltout

Abdel-Aal

, et al. Sintering mechanism of blast furnace slag–kaolin ceramics. Mater Design 2010; 31: 3677–3682.

27.

Forray

Drouet

Navrotsky

. Thermochemistry of yavapaiite KFe (SO4) 2: formation and decomposition. Geochim Cosmochim Acta 2005; 69: 2133–2140.

Effect of temperature on microstructure and performance of lightweight aggregate prepared from steel mill sludge and fly ash

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