The Development of Tubular Photobioreactor for Microalgae Cultivation

https://doi.org/10.22146/ajche.59412

Varit Kunopagarnwong(1), Thongchai Rohitatisha Srinophakun(2*)

(1) Department of Chemical Engineering, Kasetsart University, Bangkok, Thailand
(2) Department of Chemical Engineering, Kasetsart University, Bangkok, Thailand
(*) Corresponding Author

Abstract


In a tubular photobioreactor, microalgae cells obscure one another (Self-shading), leading to the microalgae at the bottom of the tube getting less light. The objective of this research was to design and develop Tubular Photobioreactor with 93.5 liters for microalgae cultivation. The experiments had two steps. The first step was designing the solar receiver by inserting the fin into each tube wall as follows: 12-34, 1-2-3-4, 1234, and 13-24. Then, FLUENT software was used to simulate flow behavior inside the tube by Computational Fluid Dynamics by observing the pressure drop, the amount of energy consumption, and the swirling velocity to select the best fin-type. The best fin-type with the growth rate equation is introduced in the next step to simulate the microalgae's growth and movement using the user-defined function technique. The comparison of a tubular photobioreactor is investigated between fin and without fin by observing biomass production. The results showed that algae's optimum inlet velocity is 0.15 meters per second with the tubes containing fin-type 13-24. When simulating the growth behavior of microalgae, results show that the tubes without fins had lower biomass content than the 13-24 fin-type, which were 0.675 and 0.806 grams per liter, respectively, because the 13-24 fin-type will make well microalgae distribution leading to increase the light distribution too. Tubular photobioreactor fins type 13-24 had more biomass production, up to 19.4 percent.


Keywords


Computational Fluid Dynamics, Microalgae, Tubular Photobioreactor

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References

Aliba, S., 1982. “Growth kinetics of photosynthetic microorganisms”. Adv. Biochem. Eng., 23, 85-156

Bitog, J.P., Lec, I.B, Lee, C.G., Kim, K.S., Hwang, H.S., Hong, S.W., Seo, I.H., Kwon, K.S., and Mostaf, E., 2011. Application of computational fluid dynamics for modeling and designing photobioreactors for microalgae production: A review.” Computer and Electronic in Agriculture, 76, 131 – 147

Brennan, L. and Owende, P., 2010. “Biofuels from microalgae – a review technologies for production, processing and extraction of biofuel and co-products.” Renewable Sustainable Energy, 14, p. 557 – 577

Carvalho A.P, Meireles L.A, and Malcata F.X., 2006. “Microalgal reactor: A review of enclosed system designs and performances.“ Biotechnology Progress, 22, 1490 – 1506

Gimbun J., 2009. “Assessment of the turbulence models for modeling of a bubble column.” Institution of Engineering Journal, 70, 57–64

Kynft J, algae for biofuel [Online] Available: www.algaeforbiofuels.com [1 June 2012].

Merchuk J.C., Gluz M., and Mukmenev I., 2000. “Comparison of photobioreactors for the cultivation of the red Porphyridium sp..” Journal of Chemical Technology and Biotechnology, 75, 1119–1126.

Molina G.E, Fernandez J, Acien F.G., and Yusuf C., 2001. “Tubular photobioreactor design for algal cultures.” Journal of biotechnology, 92, 113–131.

Pinyaporn W., Yusuf C., and Thongchai R.S., 2012. “Optimal hydrodynamic design of tubular photobioreactor,” Journal of Chemical Technology and Biochemical Technology, 88, 55 -61.

Sompech K, Yusuf C, and Thongchai R.S., 2012. “Design of raceway ponds for producing microalgae,” Biofuels, 3, 387–397.

Spolaore, P., Dassan, C.J., Puran, E. and Isembert, A., 2006. “Commercial application of microalgae.” Journal of Bioscience and Bioengineering, 101, 87 – 96

Tamburic B., Zemichael F.W., Crudge P., Mauitland G.C., and Hellgardt K., 2011. “Design of a novel flat–plate photobioreactor system for green algal hydrogen production.” International Journal of Hydrogen Energy, 36, 6578–6591.

Ugwn C.V., Aoyagi H., and Chiyama U., 2008. “Photobioreactors for mass cultivation of algae, Bioresource Technology.” 9, 4021–4028.

van Leeuwen, B. N., 2012. A multiphase simulation model on microalgae cultivation in a cylindrical photobioreactor. Master,s thesis, Delft University of Technology.

Vieira Costam J.A., and Moris M.G., 2011. “The role of biochemical engineering in the production of biofuel from microalgae.” Bioresource Technology, 10, 2-9.

Zhang K., Kurano N., and Miyachi S., 2002. “Optimized aeration by carbon dioxide gas for microalgal production and mass transfer characterization in a vertical flat-plate photobioreactor.” Bioprocess Biosystems Bioengineering, 25, 97-101



DOI: https://doi.org/10.22146/ajche.59412

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ASEAN Journal of Chemical Engineering  (print ISSN 1655-4418; online ISSN 2655-5409) is published by Chemical Engineering Department, Faculty of Engineering, Universitas Gadjah Mada.