Preparation of Porous Ceramics with Activated Carbon Impregnated Mullite Precursor and Their Properties

doi:10.19691/j.cnki.1004-4493.2026.01.005

China's Refractories ›› 2026, Vol. 35 ›› Issue (1): 29-37.DOI: 10.19691/j.cnki.1004-4493.2026.01.005

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Preparation of Porous Ceramics with Activated Carbon Impregnated Mullite Precursor and Their Properties

XI Jianfei¹, ZHANG Ling^1,*, NIU Shunan¹, LUO Shitong², DUAN Mingjun²

1 School of Materials and Metallurgy, University of Science and Technology Liaoning, Anshan 114051, China;
2 Haicheng Fengchi Refractory Material Co., Ltd., Haicheng 114200, China

Online:2026-03-15 Published:2026-03-16
Contact: ^*e-mail: 452433876@qq.com
About author:Xi Jianfei, born in 2000, received his master’s degree in materials and chemical engineering from University of Science and Technology Liaoning. His research focuses on the microstructure control and performance optimization of mullite porous ceramics, aiming to address key challenges in high-temperature insulation materials.

Abstract

Abstract: The recycling of waste activated carbon is of great significance in environmental protection. Porous mullite ceramics were prepared by impregnating the mullite precursor with activated carbon, adding a pore-forming agent, and adopting aluminum sulfate octahydrate, ammonia and silica micropowder as raw materials, waste activated carbon after heat treatment as the pore-forming agent, and sodium polyacrylate (PAAS) as the dispersant. The effects of the activated carbon additions (1.5%, 3.0%, 5.2%, and 7.8%, by mass) and PAAS additions (1%, 2%, and 3%, extra adding, by mass) on the physical properties, phase composition and microstructure of the porous ceramics were studied. The results show that: (1) as a pore-forming agent, activated carbon promotes the formation of pores inside the samples, while the apparent porosity of the samples increases significantly with the increasing activated carbon addition; when the activated carbon addition is 7.8%, the apparent porosity of the sample is 65.7%, the cold compressive strength is 4.62 MPa, the peak pore size is around 3.5 μm, and the pore size distribution is uniform; (2) appropriate PAAS helps to improve the dispersion of activated carbon in the samples and the comprehensive performance of the porous mullite ceramics; when the PAAS addition is 2%, the apparent porosity of the sample is 71.8%, the cold compressive strength is 5.53 MPa, the peak pore size is around 3 μm, and the pore size distribution is optimized; however, excessive PAAS increases the liquid phase in the system, resulting in over sintering of mullite and a decrease in the porosity.

Key words: waste activated carbon, porous mullite ceramics, impregnating precursor, dispersant

XI Jianfei, ZHANG Ling, NIU Shunan, LUO Shitong, DUAN Mingjun. Preparation of Porous Ceramics with Activated Carbon Impregnated Mullite Precursor and Their Properties[J]. China's Refractories, 2026, 35(1): 29-37.

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Preparation of Porous Ceramics with Activated Carbon Impregnated Mullite Precursor and Their Properties

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