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BIOCHEMICAL ENGINEERING PROCESSES

BIOCHEMICAL ENGINEERING PROCESSES. Fermentation. Eqn 1 and 2. Enzyme and microbial fermentations. TYPICAL BIOPROCESS FLOW SHEET. Fig. 1.1. Schematic diagram of a tower bioreactor system with perforated plates and co-current air liquid flow .

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BIOCHEMICAL ENGINEERING PROCESSES

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  1. BIOCHEMICAL ENGINEERING PROCESSES

  2. Fermentation

  3. Eqn 1 and 2 Enzyme and microbial fermentations

  4. TYPICAL BIOPROCESS FLOW SHEET

  5. Fig. 1.1. Schematic diagram of a tower bioreactor system with perforated plates and co-current air liquid flow.

  6. Fig. 1.2. Schematic diagram of a tower bioreactor system with multiple impellers and liquid down comer and counter-current air liquid flow

  7. Fig. 1.3. ICI Deep Shaft Unit

  8. 6CO2 + 6H2O C6H12O6 + 6O2 Biomass-to-Bioenergy Routes Conversion processes Photosynthesis Biomass Biofuels and Bioenergy Application Anaerobic fermentation Heat Heating Wet biomass (organic waste, manure) Biogas H2, CH4 Gasification Combustion Hydrolysis Fuel gas Electricity Solid biomass (wood, straw) Electrical devices Hydrolysis Extraction co2 Ethanol Butanol Sugar and starch plants (sugar-cane, cereals) Sugar fermentation Transport Liquid biofuels Crushing Refining Oil crops and algae (sunflower, soybean) Methyl ester (biodiesel) Pure Oil

  9. THE PRODUCTION OF ETHANOL FROM CELLULOSIC BIOMASS

  10. Hydrolysisis the chemical reaction that converts the complex polysaccharides in the raw feedstock to simple sugars. In the biomass-to-bioethanol process, acids and enzymes are used to catalyze this reaction. Hydrolysis

  11. Fermentationis a series of chemical reactions that convert sugars to ethanol. The fermentation reaction is caused by yeast or bacteria, which feed on the sugars. Ethanol and carbon dioxide are produced as the sugar is consumed. Fermentation

  12. 1. Biomass Handling. Biomass goes through a size-reduction step to make it easier to handle and to make the ethanol production process more efficient. For example, agricultural residues go through a grinding process to achieve a uniform particle size. Biomass Handling

  13. 2. Biomass Pretreatment. In this step, the hemicellulose fraction of the biomass is broken down into simple sugars. A chemical reaction called hydrolysis occurs when dilute sulfuric acid is mixed with the biomass feedstock. In this hydrolysis reaction, the complex chains of sugars that make up the hemicellulose are broken, releasing simple sugars. The complex hemicellulose sugars are converted to a mix of soluble five-carbon sugars, xylose and arabinose, and soluble six-carbon sugars, mannose and galactose. A small portion of the cellulose is also converted to glucose in this step. Biomass Pretreatment

  14. 3. Enzyme Production. The cellulase enzymes that are used to hydrolyze the cellulose fraction of the biomass are grown in this step. Alternatively the enzymes might be purchased from commercial enzyme companies. Enzyme Production

  15. Cellulose Hydrolysis. In this step, the remaining cellulose is hydrolyzed to glucose. In this enzymatic hydrolysis reaction, cellulase enzymes are used to break the chains of sugars that make up the cellulose, releasing glucose. Cellulose Hydrolysis.

  16. 5. Glucose Fermentation. The glucose is converted to ethanol, through a process called fermentation. Fermentation is a series of chemical reactions that convert sugars to ethanol. The fermentation reaction is caused by yeast or bacteria, which feed on the sugars. As the sugars are consumed, ethanol and carbon dioxide are produced. Glucose Fermentation

  17. 6. Pentose Fermentation. The hemicellulose fraction of biomass is rich in five-carbon sugars, which are also called pentoses. Xylose is the most prevalent pentose released by the hemicellulose hydrolysis reaction. In this step, xylose is fermented using Zymomonasmobilis. Pentose Fermentation

  18. 7. Ethanol Recovery. The fermentation product from the glucose and pentose fermentation is called ethanol broth. In this step the ethanol is separated from the other components in the broth. A final dehydration step removes any remaining water from the ethanol. Ethanol Recovery

  19. 8. Lignin Utilization. Lignin and other byproducts of the biomass-to-ethanol process can be used to produce the electricity required for the ethanol production process. Burning lignin actually creates more energy than needed and selling electricity may help the process economics. Lignin Utilization

  20. Cellulose hydrolysis. The crystalline structure of cellulose makes it difficult to hydrolyze to simple sugars, ready for fermentation. Researchers are developing enzymes that work together to efficiently break down cellulose.

  21. Pentose fermentation. While there are a variety of yeast and bacteria that will ferment six-carbon sugars, most cannot easily ferment five-carbon sugars, which limits ethanol production from cellulosic biomass. Researchers are using genetic engineering to design microorganisms that can efficiently ferment both five- and six-carbon sugars to ethanol at the same time.

  22. Fermentation of Molasses to Ethanol

  23. The word Ferment comes from a Latin word meaning “to boil” The term was used due to the rapid evolution of gas (Carbon Dioxide) during alcohol fermentations. The yeast converts sugar into ethanol and carbon dioxide. The conversion of sugar to ethanol creates heat. Fermentation of Molasses to Ethanol

  24. To achieve a high rate of ethanol production requires a large number of cells. Growing large numbers of yeast consumes sugar which then can not be used for ethanol formation. High sugar concentrations reduce the rate at which the yeast grow. High ethanol concentrations reduce the rate at which yeast grow and the rate at which they produce ethanol. Complications

  25. Molasses contains many of the nutrients necessary for yeast to grow and produce ethanol. Ammonium Sulfate is commonly added as a nitrogen source for the yeast. Additional Nutrients

  26. Flow sheet Molasses to Ethanol

  27. The separation of ethanol from water requires a considerable amount of energy. Estimates range from 2.5 to 5 kg of steam per litre of anhydrous ethanol produced. The production of ethanol produces a lot of waste materials. Particularly CO2 and waste water. Energy Requirements & Wastes

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