Photobioreactor design: Mixing, carbon utilization, and oxygen accumulation

Weissman, Joseph C.; Goebel, R.P.; Benemann, John R.

doi:10.1002/bit.260310409

Cited by 316 publications

(183 citation statements)

References 10 publications

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“…Openculture systems normally cannot use supplied CO 2 effectively, which easily escaped from the culture media due to the shallow depths and poor CO 2 mass transfer efficiency, and CO 2 fixation efficiency ranged from 10 to 30% (Weissman et al, 1988). Carbon fixation would be increased only when the CO 2 residence time was increased in bioreactors (Cheng et al, 2006).…”

Section: Frontiers In Energy Research | Bioenergy and Biofuelsmentioning

confidence: 99%

Current Status and Outlook in the Application of Microalgae in Biodiesel Production and Environmental Protection

et al. 2014

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Section: Frontiers In Energy Research | Bioenergy and Biofuelsmentioning

confidence: 99%

Current Status and Outlook in the Application of Microalgae in Biodiesel Production and Environmental Protection

et al. 2014

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“…Torzillo et al, 1986;Richmond, 1987Richmond, , 1990Richmond etal., 1993;Benemann, 1989;Benemann et al, 1987;Weissman et al, 1988;Kyle, 1989). For identical biomass productivities, the higher cell densities obtained with biophotoreactors result in reduced harvesting volumes and thus in reduced processing (partition solid/liquid) costs.…”

Section: What Culture Technology To Choose?mentioning

confidence: 99%

“…Chaumont et al (1991a) have patented a system using recycling balls for continuous cleaning of the inner surface of their tubular photobioreactor. The main problems encountered in the operation of photobioreactors are the control of oxygen concentration (Weissman et al, 1988) and overheating in summer which may require special and costly precautions (Torzillo et al, 1986). In order to combine the advantages of both systems, Richmond (1987) proposed a culture concept made of a tubular reactor, where the algae culture would heat quickly at the beginning and the end of the light phase, connected to an open-channel race-way where overheating would be controlled by circulating the culture.…”

Section: What Culture Technology To Choose?mentioning

confidence: 99%

Biotechnology of algal biomass production: a review of systems for outdoor mass culture

1993

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Microalgae are very efficient solar energy converters and they can produce a great variety of metabolites. Man has always tried to take advantage of these properties through algal mass culture. Despite the fact that many applications for microalgae have been described in the literature, these microorganisms are still of minor economic importance. Industrial reactors for algal culture are at present, all designed as open race-ways (shallow open ponds where culture is circulated by a paddle-wheel). Technical and biological limitations of these open systems have given rise to the development of enclosed photoreactors (made of transparent tubes, sleeves or containers and where light source may be natural or artificial). The present review surveys advances in these two technologies for cultivation of microalgae. Starting from published results, the advantages and disadvantages of open systems and closed photobioreactors are discussed. A few open systems are presented for which particularly reliable results are available. Emphasis is then put on closed systems, which have been considered as capital intensive and are justified only when a fine chemical is to be produced.

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“…Many advanced and complicated solutions for the cultivation of microalgae have been proposed [12][13][14][15] . If cheaper construction of a reactor for the cultivation of photoautotrophic organisms with a better utilization of nutrients could be used instead of technically advanced solutions, greater economic sustainability could be achieved [16][17][18][19] . Two reactors that differ in their construction, ratio of illuminated surface (A) to volume (V), and operating costs were used.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Growth Yield of Spirulina maxima in Photobioreactors

Saeid

Chojnacka

2016

Chem.Biochem.Eng.Q.

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The paper deals with the evaluation of the parameters for the cultivation of Spirulina maxima in two reactors (large-laboratory scale (LL) and semi-technical scale (ST)), whose illuminated areas in respect of the illuminated volume are different, and with the operating costs. We evaluated the growth yield coefficients for Spirulina maxima cultures. In the LL, the following factors were identified: Y O 2 /X -65.5; Y X/CO 2 -0.0806; Y X/P 2 O 5 -0.0082, while in the ST: Y O 2 /X -583; Y X/CO 2 -0.017; Y X/P 2 O 5 -0.0023. Although the reactor in the ST was equipped with many devices that should have improved the efficiency of cultivation, the obtained result was lower compared to the culture conducted in the LL. It was proved that it was possible to perform the cultivation of Spirulina maxima under temperate climate conditions in simply constructed, low cost reactors.

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Photobioreactor design: Mixing, carbon utilization, and oxygen accumulation

Cited by 316 publications

References 10 publications

Current Status and Outlook in the Application of Microalgae in Biodiesel Production and Environmental Protection

Current Status and Outlook in the Application of Microalgae in Biodiesel Production and Environmental Protection

Biotechnology of algal biomass production: a review of systems for outdoor mass culture

Evaluation of Growth Yield of Spirulina maxima in Photobioreactors

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