Process Simulation and Design of Sulfuric Acid Production via Double Contact Process
shokry, F., osama, A., Salama, A., Reda, A., Noshy, E., Magdy, M., Elshafey, R., Bassyouni, M., Zarraa, R. (2025). Process Simulation and Design of Sulfuric Acid Production via Double Contact Process. EKB Journal Management System, 68(12), 443-454. doi: 10.21608/ejchem.2025.362901.11346
fathy shokry; Ahmed osama; Ahmed Salama; Amira Reda; Elsayed Noshy; Maram Magdy; Rwan Elshafey; Mohamed Bassyouni; R. M. Zarraa. "Process Simulation and Design of Sulfuric Acid Production via Double Contact Process". EKB Journal Management System, 68, 12, 2025, 443-454. doi: 10.21608/ejchem.2025.362901.11346
shokry, F., osama, A., Salama, A., Reda, A., Noshy, E., Magdy, M., Elshafey, R., Bassyouni, M., Zarraa, R. (2025). 'Process Simulation and Design of Sulfuric Acid Production via Double Contact Process', EKB Journal Management System, 68(12), pp. 443-454. doi: 10.21608/ejchem.2025.362901.11346
shokry, F., osama, A., Salama, A., Reda, A., Noshy, E., Magdy, M., Elshafey, R., Bassyouni, M., Zarraa, R. Process Simulation and Design of Sulfuric Acid Production via Double Contact Process. EKB Journal Management System, 2025; 68(12): 443-454. doi: 10.21608/ejchem.2025.362901.11346

Process Simulation and Design of Sulfuric Acid Production via Double Contact Process

Egyptian Journal of Chemistry
Volume 68, Issue 12, December 2025, Page 443-454  XML PDF (1.64 MB)
Document Type: Original Article
DOI: 10.21608/ejchem.2025.362901.11346
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Authors
fathy shokry1; Ahmed osama2; Ahmed Salama2; Amira Reda2; Elsayed Noshy2; Maram Magdy2; Rwan Elshafey2; Mohamed Bassyouniorcid 3; R. M. Zarraa email 4
1portfouad - portsaid
2Department of Chemical Engineering, Faculty of Engineering, Port Said University, Port Said 42526, Egypt
3Department of Chemical Engineering, Port Said University
4Petrochemical Engineering Department, Faculty of Engineering, Pharos University in Alexandria, Alexandria, Egypt.
Abstract
This study examined the production of 98% sulfuric acid using the double contact process, optimized for environmental sustainability and process efficiency. The methodology involved burning sulfur to generate sulfur dioxide (SO₂), then catalytically oxidizing it into sulfur trioxide (SO₃) using vanadium pentoxide across five fixed-bed reactors. The SO₃ produced was absorbed sequentially to form sulfuric acid with intermediate and final absorption stages ensuring optimal conversion and purity. Process simulations conducted via Aspen Plus V11 focus on mass and energy balances, emphasizing energy recovery from exothermic reactions through waste heat boilers and comprehensive heat exchanger networks. The SO₃ produced was absorbed sequentially, resulting in a final sulfuric acid concentration of 98%, with an intermediate absorption efficiency of 99.5%. Process simulations conducted via Aspen Plus V11 showed a total energy recovery of 7.5 MW through waste heat boilers and heat exchanger networks, contributing to overall energy efficiency This study, highlighted key environmental strategies, including advanced emission controls such as scrubbers and neutralization pits, to effectively address the release of sulfur oxides and other pollutants. Environmental strategies included advanced emission controlled such as NaOH scrubbers, reducing SO₂ emissions to below 200 mg/m³ and mitigating acid mist emissions to less than 10 mgH₂SO₄/Nm³. Results showed that strategic process design and rigorous operational controls were crucial for maximizing production efficiency while minimizing environmental footprint, offering insights into scalable and sustainable industrial chemical production.
Keywords
Sulfuric acid; Double contact double conversion; Process Design; Energy conservations; Advanced emission controls
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