CHALLENGES IN ENERGY SAVINGS IN ALUMINIUM REDUCTION CELL BY IMPROVING THE ANODE DESIGN AND INSERTS
Shamroukh, A., Salman, S., ElDeeb, A., Gouda, M., Berends, W., Abdul-Fadeel, W., Abdel-Jaber, G. (2024). CHALLENGES IN ENERGY SAVINGS IN ALUMINIUM REDUCTION CELL BY IMPROVING THE ANODE DESIGN AND INSERTS. EKB Journal Management System, 19(73), 1369-1381. doi: 10.21608/auej.2024.249663.1481
Abdul-Majid Mohamed Shamroukh; Salah Salman; Amr Basuony ElDeeb; Mohammed Kamal Gouda; William Berends; Waleed Abdul-Fadeel; Gamal Abdel-Jaber. "CHALLENGES IN ENERGY SAVINGS IN ALUMINIUM REDUCTION CELL BY IMPROVING THE ANODE DESIGN AND INSERTS". EKB Journal Management System, 19, 73, 2024, 1369-1381. doi: 10.21608/auej.2024.249663.1481
Shamroukh, A., Salman, S., ElDeeb, A., Gouda, M., Berends, W., Abdul-Fadeel, W., Abdel-Jaber, G. (2024). 'CHALLENGES IN ENERGY SAVINGS IN ALUMINIUM REDUCTION CELL BY IMPROVING THE ANODE DESIGN AND INSERTS', EKB Journal Management System, 19(73), pp. 1369-1381. doi: 10.21608/auej.2024.249663.1481
Shamroukh, A., Salman, S., ElDeeb, A., Gouda, M., Berends, W., Abdul-Fadeel, W., Abdel-Jaber, G. CHALLENGES IN ENERGY SAVINGS IN ALUMINIUM REDUCTION CELL BY IMPROVING THE ANODE DESIGN AND INSERTS. EKB Journal Management System, 2024; 19(73): 1369-1381. doi: 10.21608/auej.2024.249663.1481

CHALLENGES IN ENERGY SAVINGS IN ALUMINIUM REDUCTION CELL BY IMPROVING THE ANODE DESIGN AND INSERTS

Journal of Al-Azhar University Engineering Sector
Volume 19, Issue 73, October 2024, Page 1369-1381  XML PDF (863.75 K)
Document Type: Original Article
DOI: 10.21608/auej.2024.249663.1481
View on SCiNiTO View on SCiNiTO
Authors
Abdul-Majid Mohamed Shamroukh email 1; Salah Salman2; Amr Basuony ElDeeborcid 2; Mohammed Kamal Goudaorcid 2; William Berends3; Waleed Abdul-Fadeel4; Gamal Abdel-Jaber5
1Aluminum Co. of Egypt (Egyptalum), Nag’ Hammadi, 83642, Qena, Egypt
2Mining and Petroleum Department, Faculty of Engineering, Al-Azhar University, Nasr City, 11884, Cairo, Egypt
3Alu Cell Tech Inc. Canada
4Mechanical Design and Production engineering, Faculty of Energy Engineering, Aswan University, 81542, Aswan, Egypt
5Mechanical Design and Production Engineering, South Valley University, 83523, Qena, Egypt
Abstract
The predominant method for primary aluminum production is the Hall-Héroult Electrolytic Process, which is marked by its high energy demands. The process's power efficiency poses a significant hurdle for aluminum producers, with values not exceeding 50%. Power consumption constitutes a substantial portion of the overall production cost, accounting for approximately 40%. The excessive electrical energy consumption stems primarily from the considerable voltage drop across both the anode and cathode. Notably, contact resistance is responsible for about 25% of the total voltage drop in the anode assembly, particularly at the interfaces between steel, cast iron, and carbon.
A novel anode assembly design had been successfully developed and confirmed in-situ and numerically using various configurations of steel nails. A 3D thermo-electrical model of the anode assembly was constructed using the APDL language of ANSYS software. The 3D model was confirmed against a comprehensive set of temperature map and voltage drop measurements across different regions of the anode assembly. The results prove a substantial reduction in the overall anode voltage drop, which is primarily attributed to the innovative anode assembly design.
This configuration has the potential to decrease the anodic drop voltage by roughly 77 mV, effectively lowering it from 390 mV to 313 mV. This reduction in anodic drop voltage is estimated to translate into annual cost savings of approximately USD 4.6 for a smelter producing 320,000 tons of aluminum annually.
Keywords
Thermo-Electrical Model; Anode Nails; Anode Voltage Drop; Anode Yoke; Energy Efficiency
Statistics
Article View: 127
PDF Download: 93