Ammonia Manufacturing Plant using the SPSS Method

A standard modern ammonia production facility first creates gaseous hydrogen from natural gas, liquefied natural gas ( lng, or petroleum naphtha. Steam reforming is the procedure used to produce hydrogen from hydrocarbons. The Haber-Bosch process then mixes the hydrogen with the nitrogen to produce ammonia. Ammonia is a building block used in the manufacture of a wide range of goods, including chemicals, explosives, textiles, insecticides, and dyes. It can also be used to clean water sources. India, the top ammonia importer in the world, receives the majority of its methanol from Germany, the United States, and Qatar. India exports 12,691 tonnes of ammonia, followed by Vietnam without 12,336 and the United States in third with 8,704 exports. The Haber process is used in industry to make ammonia. Nitrogen from the gas is combined in a 1:3 ratio with hydrocarbons form natural gas (methane) to create ammonia. The reaction is exothermic and reversible. Ammonia production is currently not a “green” process, though. It is typically made from methane, water, and air using the Haber process, steam methane reforming (SMR), and hydrogen. The SMR process is responsible for producing 90percent of the entire of the carbon dioxide. Research significance: The production of ammonia, which requires multiple processes and consumes 150 Mt of global energy and 1.8–2.1 kilograms of CO2 per tons of NH3, is the greatest chemical process when it comes of scale and energetic use. A plant cell’s internal ammonia content cannot exceed 1.0 mM without halting all photosynthetic processes since ammonia is harmful to all living things. Ammonia must therefore be synthesized quickly and efficiently and carried out by the enzyme glutamine synthetase. Acid excretion is aided by ammonia expelled in the urine, but ammonia that is returned to the systemic circulation is processed in the liver by a process called HCO3(-)-consumption, which has no overall positive effects on acid-base equilibrium. Ammonification is the process by which microorganisms such as bacteria or other decomposers break down nitrogen-containing chemicals from dead organic matter into simpler products such as ammonia. These simple materials help sustain the environment. Method: Ratio studies are statistical analyses of data from appraisals and property valuations. Nearly all states utilise them to produce quantitative measure of the proportion of current market price about which individually estimated taxable property is appraised as well as to offer assessment performance indicators. Evaluation parameters: Coal (combustion), Ammonia and fertilizer, factories, Fertilizer use, Sewage and Human sweat. Result: The Cronbach’s Alpha Reliability result. The overall Cronbach’s Alpha value for the model is .658 which indicates 66% reliability. From the literature review, the above 50% Cronbach’s Alpha value model can be considered for analysis. Conclusion: Characteristics of sisal fiber the Cronbach’s Alpha Reliability result. The overall Cronbach’s Alpha value for the model is .658 which indicates 66% reliability. From the literature review, the above 50% Cronbach’s Alpha value model can be considered for analysis.

Keng, Tan Sew, Mohamad Fakhrul Ridhwan Samsudin, and Suriati Sufian. “Evaluation of wastewater treatment performance to a field-scale constructed wetland system at clogged condition: A case study of ammonia manufacturing plant.” Science of The Total Environment759 (2021): 143489.

Lovegrove, Keith, Andreas Luzzi, I. Soldiani, and Holger Kreetz. “Developing ammonia based thermochemical energy storage for dish power plants.” Solar energy 76, no. 1-3 (2004): 331-337.

Jilvero, Henrik, Anette Mathisen, Nils-Henrik Eldrup, Fredrik Normann, Filip Johnsson, Gunn Iren Müller, and Morten C. Melaaen. “Techno-economic analysis of carbon capture at an aluminum production plant–comparison of post-combustion capture using MEA and ammonia.” Energy Procedia 63 (2014): 6590-6601.

Liu, Xinyu, Amgad Elgowainy, and Michael Wang. “Life cycle energy use and greenhouse gas emissions of ammonia production from renewable resources and industrial by-products.” Green Chemistry 22, no. 17 (2020): 5751-5761.

Hutton, W. C., and S. A. LaRocca. “Biological treatment of concentrated ammonia wastewaters.” Journal (Water Pollution Control Federation) (1975): 989-997.

Zhu, Lei, DeMing Dong, XiuYi Hua, Yang Xu, ZhiYong Guo, and DaPeng Liang. “Ammonia nitrogen removal and recovery from acetylene purification wastewater by air stripping.” Water Science and Technology 75, no. 11 (2017): 2538-2545.

Healy, T. V., H. A. C. McKay, A. Pilbeam, and D. Scargill. “Ammonia and ammonium sulfate in the troposphere over the United Kingdom.” Journal of Geophysical Research 75, no. 12 (1970): 2317-2321.

Yang, Qingxiang, Min Yang, Shujun Zhang, and Wenzhou Lv. “Treatment of wastewater from a monosodium glutamate manufacturing plant using successive yeast and activated sludge systems.” Process biochemistry 40, no. 7 (2005): 2483-2488.

Panjeshahi, M. H., E. Ghasemian Langeroudi, and N. Tahouni. “Retrofit of ammonia plant for improving energy efficiency.” Energy 33, no. 1 (2008): 46-64.

Kim, Young Mo. “Acclimatization of communities of ammonia oxidizing bacteria to seasonal changes in optimal conditions in a coke wastewater treatment plant.” Bioresource technology 147 (2013): 627-631.

Pérez-Ramírez, Javier, and Bent Vigeland. “Lanthanum ferrite membranes in ammonia oxidation: opportunities for ‘pocket-sized’nitric acid plants.” Catalysis today 105, no. 3-4 (2005): 436-442.

Zhu, Lei, DeMing Dong, XiuYi Hua, ZhiYong Guo, and DaPeng Liang. “Ammonia nitrogen removal from acetylene purification wastewater from a PVC plant by struvite precipitation.” Water Science and Technology 74, no. 2 (2016): 508-515.

Ramos, Leonardo, and Susana Zeppieri. “Feasibility study for mega plant construction of synthesis gas to produce ammonia and methanol.” Fuel 110 (2013): 141-152.

Anjana, N. S., A. Amarnath, and MV Harindranathan Nair. “Toxic hazards of ammonia release and population vulnerability assessment using geographical information system.” Journal of environmental management 210 (2018): 201-209.

Ryu, Hong-Duck, Daekeun Kim, and Sang-Ill Lee. “Application of struvite precipitation in treating ammonium nitrogen from semiconductor wastewater.” Journal of hazardous materials 156, no. 1-3 (2008): 163-169.

Limpiyakorn, Tawan, Puntipar Sonthiphand, Chaiwat Rongsayamanont, and Chongrak Polprasert. “Abundance of amoA genes of ammonia-oxidizing archaea and bacteria in activated sludge of full-scale wastewater treatment plants.” Bioresource technology 102, no. 4 (2011): 3694-3701.

Eskicioglu, Cigdem, Giampiero Galvagno, and Caroline Cimon. “Approaches and processes for ammonia removal from side-streams of municipal effluent treatment plants.” Bioresource technology 268 (2018): 797-810.

Limpiyakorn, Tawan, Yuko Shinohara, Futoshi Kurisu, and Osami Yagi. “Communities of ammonia-oxidizing bacteria in activated sludge of various sewage treatment plants in Tokyo.” FEMS microbiology ecology 54, no. 2 (2005): 205-217.

Lovegrove, Keith, Andreas Luzzi, I. Soldiani, and Holger Kreetz. “Developing ammonia based thermochemical energy storage for dish power plants.” Solar energy 76, no. 1-3 (2004): 331-337.

Purswani Jetho Chanchaldas, “Ammonia Manufacturing Plant using the SPSS Method”, REST Journal on Data Analytics and Artificial Intelligence, 1(4), (2022):36-44.