Photothermal performance of vitreous products from high-temperature melting of hazardous waste

• Published in: Journal of cleaner production Vol. 455; p. 142352
• Main Authors: Yu, Mengxiong, Tang, Lu, Shen, Dongsheng, Gu, Foquan, Wang, Lulu, Long, Yuyang
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 25.05.2024
• Subjects: Heat; High-temperature molten vitreous; Photothermal heating; Photothermal performance; Heat; Photothermal performance; Photothermal heating; High-temperature molten vitreous
• ISSN: 0959-6526; 1879-1786
• DOI: 10.1016/j.jclepro.2024.142352

High-temperature molten vitreous (HTMV), as the primary means of hazardous waste disposal, was produced in large quantities. Exploring its potential in photothermal applications could extend its high-value. Herein, the HTMV was used to explore the photothermal performance potential. It indicates that the HTMV possesses significant photothermal conversion capability, capable of increasing the tested water temperature by 6.65 °C. The HTMV mass and water volume are critical factors affecting the water temperature outcomes. The HTMV exhibits distinct conversion capabilities when applied at different application scenarios on the test object. Application on the bottom primarily focuses on photothermal conversion with high heat production efficiency, while side application additionally demonstrates excellent thermal insulation properties. Based on heat balance and backpropagation neural network predictions, optimal scheme of HTMV on both inside and outside bottom application scenarios of the heated object can achieve a maximum heat input of 660.6 kJ m−2 and 570.1 kJ m−2, respectively, and reduce carbon emissions by 0.062 kg CO2 m−2 and 0.054 kg CO2 m−2. This study not only provides a foundation for the further application of HTMV but also opens a new direction for the development of photothermal conversion materials, which is of great significance in advancing sustainable energy technology. [Display omitted] •HTMV from hazardous waste shows photothermal potential.•HTMV Attached as bottom can additionally increase water temperature by 6.65 °C.•660.6 kJ m−2 heating and 0.062 kg CO2/m2 reduction can be realized.