Fischer Tropsch Synthesis Wastewater Treatment Study using DW SIM
M. Shireesha1, Aradhyula Jatin Bhanu Shankar2, P. Sarath3, Kunchala Vishwajeeth4, Danam Sohan Subodh5, Shaik Imarn6

1M. Shireesha, Department of Chemical Engineering, Anurag University, Ghatkesar, Medchal (Dist.), Hyderabad, Telangana, India.

2A. Jatin Bhanu Shankar, Department of Chemical Engineering, Anurag University, Ghatkesar, Medchal (Dist.), Hyderabad, Telangana, India.

3P. Sarath, Department of Chemical Engineering, Anurag University, Ghatkesar, Medchal (Dist.), Hyderabad, Telangana, India.

4D. Sohan Subodh, Department of Chemical Engineering, Anurag University, Ghatkesar, Medchal (Dist.), Hyderabad, Telangana, India.

5Shaik Imran, Department of Chemical Engineering, Anurag University, Ghatkesar, Medchal (Dist.), Hyderabad, Telangana, India.

6K. Vishwajeeth, Department of Chemical Engineering, Anurag University, Ghatkesar, Medchal (Dist.), Hyderabad, Telangana, India.  

Manuscript received on 15 July 2023 | Revised Manuscript received on 08 August 2023 | Manuscript Accepted on 15 November 2023 | Manuscript published on 30 November 2023 | PP: 1-6 | Volume-13 Issue-5, November 2023 | Retrieval Number: 100.1/ijsce.I97010812923 | DOI: 10.35940/ijsce.I9701.13051123

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Abstract: This project focuses on utilizing DWSIM to treat wastewater from the Fisher Tropsch Process. A well-known technique for transforming synthesis gas, a combination of carbon monoxide and hydrogen, into liquid hydrocarbons is the Fischer-Tropsch process. However, this procedure creates wastewater, which if not adequately treated, includes a variety of chemicals that can be detrimental to aquatic life. To get rid of these contaminants and satisfy regulatory standards, the Fischer-Tropsch process requires water treatment. The most often employed therapeutic modalities are physical, pharmacological, and biological therapies. In order to maintain the Fischer-Tropsch process’ sustainability and environmental friendliness, efficient and effective water treatment is essential. The Fischer-Tropsch process can continue to be an effective way to make liquid hydrocarbons while minimizing its negative effects on aquatic habitats with the right water treatment. As a result, the goal of this research is to examine the treatment process, determine the chemical oxygen demand (COD) level of Fischer Tropsch water obtained by distillation, reduce its concentration, and prepare the water for neutralization.

Keywords: Wastewater Treatment, Fischer-Tropsch Process, Synthesis Gas, Liquid Hydrocarbons, Chemical Contaminants, Aquatic Life, Physical Therapy, Pharmacological Therapy, Biological Therapy, Regulatory Standards, Sustainability, Environmental Friendliness, Chemical Oxygen Demand (COD), Distillation, Neutralization.
Scope of the Article: Biological & Evolutionary Computation