Statistical investigation of pivotal physical and chemical factors on the performance of ceramic-based microbial fuel cells

Q2 Engineering Energy Harvesting and Systems Pub Date : 2022-04-01 DOI:10.1515/ehs-2021-0073
Vajihe Yousefi
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引用次数: 2

Abstract

Abstract The performance of four different commercial ceramic separators is inspected using response surface methodology (RSM). The thickness (A), porosity (B), SiO2 (C), and Al2O3 (D) contents of ceramics are statistically significant (P-value<0.05) for both responses of the maximum power density (MPD) and the coulombic efficiency (CE). The interactions of AB and AC have significant influences on the MPD. For highly porous ceramics, including the unglazed wall ceramic (MFC-UGWC, 30.45% porosity) and Yellow ceramic (MFC-Y, 28.9% porosity), the MPD and CE are boosted by raising the thickness of membranes. The MPD and CE values have been enhanced from 225.07 to 321.11 mW/m2 and from 51 to 68%, respectively, by thickening the UGWC from 3 to 9 mm. Similarly, the power performance and CE of the MFC-Y have been grown by 32% and 148.6%, respectively. However, both the MPD and CE responses have been reduced from 106.89 to 57.65 mW/m2 and from 29 to 18.3% for the denser unglazed floor ceramic (UGFC, 11% porosity) as a consequence of thickness increment from 3 to 6 mm. Furthermore, the chemical composition of ceramics has a crucial impact on the overall performance. Richer ceramics in SiO2 are utilized, the higher performance is achieved.
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影响陶瓷基微生物燃料电池性能的关键物理和化学因素的统计研究
摘要采用响应面法(RSM)对四种不同的商用陶瓷分离器的性能进行了测试。陶瓷的厚度(A)、孔隙率(B)、SiO2 (C)和Al2O3 (D)含量对最大功率密度(MPD)和库仑效率(CE)的响应均有统计学意义(p值<0.05)。AB和AC的相互作用对MPD有显著影响。对于高多孔陶瓷,包括无釉壁陶瓷(MFC-UGWC,孔隙率30.45%)和黄色陶瓷(MFC-Y,孔隙率28.9%),增加膜的厚度可以提高MPD和CE。通过将UGWC厚度从3 mm增加到9 mm, MPD和CE值分别从225.07 mW/m2增加到321.11 mW/m2和从51%增加到68%。同样,MFC-Y的功率性能和CE分别增长了32%和148.6%。然而,由于厚度从3毫米增加到6毫米,密度更大的无釉地板陶瓷(UGFC,孔隙率11%)的MPD和CE响应都从106.89 mW/m2减少到57.65 mW/m2,从29%减少到18.3%。此外,陶瓷的化学成分对整体性能有至关重要的影响。SiO2含量越高,陶瓷的性能越好。
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来源期刊
Energy Harvesting and Systems
Energy Harvesting and Systems Energy-Energy Engineering and Power Technology
CiteScore
2.00
自引率
0.00%
发文量
31
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