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Scale up of biohydrogen production by a pure strain; Clostridium butyricum TM-9A at regulated pH under decreased partial pressure

Author

Listed:
  • RamKumar, N.
  • Anupama, Pulikkal D.
  • Nayak, Tanmaya
  • Subudhi, Sanjukta

Abstract

Clostridium butyricum TM-9A strain was employed as pure strain for scale up of fermentative hydrogen production in batch mode. In laboratory scale batch fermentations, 46 mmol/L hydrogen produced from molasses at optimum pH, molasses concentration and C/N ratio of; 7.5, 2.5%, and 10, respectively. Scale up of molasses fermentation by TM-9A strain in 13.5 L scale bioreactor under decreased partial pressure at regulated pH, enhnaced the hydrogen titer titer from 46 mmol H2/L (in laboratory scale) to 73 mmol H2/L (1.58 fold increase). Hydrogen productivity was 1650 mL/L. Scale up of glucose fermentation by TM-9A in 13.5 L scale bioreactor at optimumcondition produced; 71.9 mmol H2/L (1634 mL/L). The biogas was composed of 65–60% H2 and 35–40% CO2. Hydrogen yield of TM-9A from glucose and molasses in the proto scale fermentation process was, 3.335 mole H2/mole glucose and 73 mmol H2/9 g of COD reduced, respectively. These studies imply that Clostridum butyricum TM-9A strain has significant potential for hydrogen production from spent organic matter in pilot scale.

Suggested Citation

  • RamKumar, N. & Anupama, Pulikkal D. & Nayak, Tanmaya & Subudhi, Sanjukta, 2021. "Scale up of biohydrogen production by a pure strain; Clostridium butyricum TM-9A at regulated pH under decreased partial pressure," Renewable Energy, Elsevier, vol. 170(C), pages 1178-1185.
  • Handle: RePEc:eee:renene:v:170:y:2021:i:c:p:1178-1185
    DOI: 10.1016/j.renene.2021.01.106
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