Development of Sensible Heat Storage Materials Using Sand, Clay and Coal Bottom Ash  

作　　者：Boubou Bagre Ibrahim Kolawole Muritala Tizane Daho Makinta Boukar Yomi Woro Gounkaou Babajide Epe Shari Aissatou Ndiaye Antoine Bere Adamou Rabani Boubou Bagre;Ibrahim Kolawole Muritala;Tizane Daho;Makinta Boukar;Yomi Woro Gounkaou;Babajide Epe Shari;Aissatou Ndiaye;Antoine Bere;Adamou Rabani(Doctoral Research Program-Climate Change and Energy, Université Abdou Moumouni (WASCAL-DRP-CCE), Niamey, Niger;Laboratoire de Physique et de Chimie de l’Environnement, Université Joseph KI-ZERBO, Ouagadougou, Burkina Faso;Institute of Low-Carbon Industrial Processes, German Aerospace Center (DLR), Zittau, Germany)

机构地区：[1]Doctoral Research Program-Climate Change and Energy, Université Abdou Moumouni (WASCAL-DRP-CCE), Niamey, Niger [2]Laboratoire de Physique et de Chimie de l’Environnement, Université Joseph KI-ZERBO, Ouagadougou, Burkina Faso [3]Institute of Low-Carbon Industrial Processes, German Aerospace Center (DLR), Zittau, Germany

出　　处：《Materials Sciences and Applications》2022年第12期603-626,共24页材料科学与应用期刊（英文）

摘　　要：In this paper, the mechanical and thermal properties of a sand-clay ceramic with additives coal bottom ash (CBA) waste from incinerator coal power plant are investigated to develop an alternative material for thermal energy storage (TES). Ceramic balls are developed at 1000°C and 1060°C using sintering or firing method. The obtained ceramics were compressed with a compression machine and thermally analyse using Decagon devise KD2 Pro thermal analyser. A muffle furnace was also used for thermal cycling at 610°C. It was found that the CBA increased the porosity, which resulted in the increase of the axial tensile strength reaching 3.5 MPa for sand-clay and ash ceramic. The ceramic balls with the required tensile strength for TES were selected. Their volumetric heat capacity, and thermal conductivity range respectively from 2.4075 MJ·m-3·°C-1 to 3.426 MJ·m-3·°C-1 and their thermal conductivity from 0.331 Wm-1·K-1, to 1.014 Wm-1·K-1 depending on sand origin, size and firing temperature. The selected formulas have good thermal stability because the most fragile specimens after 60 thermal cycles did not present any cracks. These properties allow envisioning the use of the ceramic balls developed as filler material for thermocline thermal energy storage (structured beds) in Concentrating Solar Power plants. And for other applications like solar cooker and solar dryer.In this paper, the mechanical and thermal properties of a sand-clay ceramic with additives coal bottom ash (CBA) waste from incinerator coal power plant are investigated to develop an alternative material for thermal energy storage (TES). Ceramic balls are developed at 1000°C and 1060°C using sintering or firing method. The obtained ceramics were compressed with a compression machine and thermally analyse using Decagon devise KD2 Pro thermal analyser. A muffle furnace was also used for thermal cycling at 610°C. It was found that the CBA increased the porosity, which resulted in the increase of the axial tensile strength reaching 3.5 MPa for sand-clay and ash ceramic. The ceramic balls with the required tensile strength for TES were selected. Their volumetric heat capacity, and thermal conductivity range respectively from 2.4075 MJ·m-3·°C-1 to 3.426 MJ·m-3·°C-1 and their thermal conductivity from 0.331 Wm-1·K-1, to 1.014 Wm-1·K-1 depending on sand origin, size and firing temperature. The selected formulas have good thermal stability because the most fragile specimens after 60 thermal cycles did not present any cracks. These properties allow envisioning the use of the ceramic balls developed as filler material for thermocline thermal energy storage (structured beds) in Concentrating Solar Power plants. And for other applications like solar cooker and solar dryer.

关 键 词：Ceramic Ball SAND CLAY Coal Bottom Ash Thermal Energy Storage Material THERMOCLINE Concentrating Solar Power Plant 

分 类 号：TQ1[化学工程]