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Airlift fermenter
- 1. SAM HIGGINBOTTOM UNIVERSITY OF AGRICULTURE TECHNOLOGY AND SCIENCES PRAYAGRAJ, U.P,211008 Prepared By: Ravi Rastogi 16BPH081 AIRLIFT FERMENTER Submitted to: DR. SONAM BHATIA FHS,SHUATS
- 2. A bioreactor is a closed vessel with suitable organization for agitation, aeration, pH and temperature control and inlet and outlet to add nutrients and to remove the waste biomass along with their products. The major difference between fermenter and bioreactor is that the bioreactor is a vessel that facilitates various types of biochemical reactions whereas fermenter is the vessel facilitating fermentation only. Therefore, fermenter is only a type of bioreactor. BIOREACTOR
- 3. Introduction: Air Lift (or Gas Lift) bioreactors are an alternative to mechanically agitated systems that reduce shear stress and heat generation by eliminating the mechanical agitator. It is a pneumatic system and a batch process system. Two types of airlift fermenters : A. Internal loop airlift bioreactor B. External loop airlift bioreactor Internal loop bioreactor has a single container with a central draft tube that creates interior liquid circulation channels. External loop bioreactor possesses an external loop so that the liquid circulates through separate independent channels. Airlift Bioreactor
- 5. In a typical airlift bioreactor, entire reactor is divided into 2 halves by a Draft tube: inner gassed region ( Riser): gas is passed through it. outer ungassed region ( Down comer) Mean density gradient between riser and downcomer regions causes continuous circulation.
- 6. RISER: Connected gas injection- upward air flow. DOWNCOMER: degassed media+cells. BASE: Connected to Perforated nozzle bank/ plate/ Sparger to pump pressurized air. HEAD SPACE: Gas release region, flocculation, foam accumulation etc. GAS SEPARATOR: Facilitates gas/liquid recirculation Maximizes gas residence time Reduces gas friction in downcomer.
- 7. There are essentially four design variants. These are;
- 8. Working mechanism: • An airlift bioreactor works by agitating the contents of the bioreactor pneumatically using gas. The gas used for agitation can act to either, introduce new molecules to the mixture inside of the bioreactor, or remove specific metabolic molecules produced by microorganisms • Airlift bioreactors have a built in bubble column designed to release gas into the bioreactor. Gas is usually injected into the bubble column at the bottom of the bioreactor . • Mixing occurs as the bubbles rise through the bubble column to the top of the bioreactor.
- 9. • There are two separate channels within an airlift bioreactors; one channel for gas/liquid up-flow and one channel for gas/liquid down-flow. • Both channels create a closed gas/liquid circuit, and has a mechanism for removing gaseous substances at the top of the bioreactor called the gas separator.
- 10. It has a single container with a central draft tube. Simple in design. No temperature variation as in two stage bioreactor. No separate reactors or chambers for growth and bioprocesses. Both occur in the same reactor. Not suitable for temperature dependent formation of products as it is difficult to fluctuate temperature in a same vessel unlike two tower airlift bioreactor. TOWER BIOREACTOR
- 11. The processes in which product formation is depend on the temperature, two stage airlift fermenters are used. Two fermenters one having temperature at 30 °C and the other having temperature at 42°C are used. From one fermenter (30°C) growing cells are pumped into another fermenter (42°C). It is difficult to increase the temperature of same vessel from 30°C to 42°C immediately. Both vessels are connected to each other by pump and transfer tubes. Growth of microorganism occur in first vessel at 30 °C and the proper bioprocessing occur in second bioreactor
- 12. Steam generator Different airfilter at inlets and outlets are present to prevent contamination.
- 13. For aerobic bioprocessing technologies. Due to high efficiency, airlift bioreactors are sometimes preferred for the processes like methanol production and waste water treatment. Biological processes involving biocatalysts as solids. To produce single cell proteins from fragile cells. USES:
- 14. Advantages: • Simple design with no moving parts or agitator for less maintenance, less risk of defects . • Easier sterilization (no agitator shaft parts) • Low Energy requirement vs stirred tank : Obviously doesn’t need the energy for the moving parts (agitator shaft). • Very low cost as no mechanical agitators and extra cooling equipment are required. • Ideal for the aerobic cultures since oxygen mass transfer coefficient is high.
- 15. • Greater heat-removal vs stirred tank: At the Airlift bioreactor it doesn’t need the heat plate to control the temperature, because the Draught-Tube which is inside the bioreactor can be designed to serve as internal heat exchanger. It is difference to the Stirred tank bioreactor that needs the heat coat or plate surrounding the tank to make warm bioreactor. It is clear enough that the Airlift bioreactor has greater heat-removal compare to Stirred tank • Low shear therefore can be used for plant and animal cells .
- 16. Disadvantages: • Inefficient in breaking of foams when foaming occurs due to lack of blades/shafts as compared to stirred tank. • No bubble breakers which are produced from air supply(sparger) • Greater air throughput and higher pressures needed : The agitation on the Airlift bioreactor is controlled by the supply air. To adjust the supply air then the higher pressure needed. And if the higher pressure of air needed then more energy consumption needed. And more cost must pay.
- 18. THANK YOU !