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Algae photobioreactor for mass production of biodiesel 3

It is not necessary that if anything to do about Algae is happening it must be in San Diego. It can be Las Banos, Laguna. If you dont know where it is, it is in Philipines.Actually you never know, when and where a great solution to the algae culivation is going to be found.Here is news from Philipines. Take it with a pinch of  salt as I have briefed already.
This is not a breakthru news. But news from philipines that there are lots of action in algae.

Scientists at the College of Engineering and Agro-Industrial Technology (CEAT) and Institute of Biological Science of the College of Arts and Sciences (ULPB have developed an unassuming, and somewhat crude looking equipment that could mass produce biodiesel fuel from algae, commonly known as pond scum.

The contraption, called photobioreactor, houses and cultivates algae, providing them a suitable environment for growth and supplying light, nutrients, air and heat to the culture, UPLB scientists said.

Today, solution to the problems of cultivating algae  or at least some part it, could very well be found in the CEAT complex in the form of an unassuming, if somewhat crude looking equipment.
The photobioreactor, which comes in two prototype variants, was developed by CEAT with Prof. Rex B. Demafelis, convenor of the UPLB Alternative Energy RDE, at the helm.
The development of the photobioreactors was funded by the Philippine Council for Aquatic and Marine Research and Development or PCAMRD under the program leadership of Dr. Milagrosa M. Goss, a UPLB Professor Emeritus.

Phototrophs are organisms that carry out the process of photosynthesis to acquire energy like plants, planktons, certain bacteria, and algae.
The design and fabrication of the photobioreactor prototypes fell on the able hands of Prof. Demafelis. With the help of CEAT undergraduate students, he came up with two prototypes: an internally illuminated vertical column photobioreactor and an externally illuminated vertical column draft-tube airlift photobioreactor. The externally illuminated photobioreactor uses natural light (direct sunlight or any ambient light) while the internally illuminated prototype uses artificial light.

Inside the closed vessel, algal cells grow in aqueous suspension where they have more efficient access to water, carbon dioxide, and dissolved nutrients. Through the photobioreactors, microalgae are capable of producing large amounts of biomass and usable oil which can then be turned into biodiesel.

Prof. Demafelis said that after establishing the viability of C.vulgaris (algae specie) as a fuel feedstock, they validated its efficacy through the engineering design of the photobioreactors.

We are confident that once we have the oil we can convert it to biodiesel. Where do we get the oil? Everything points to third generation biofuel feedstock,he said.

Certain requirements of photobioreactors such as cooling, mixing, and control of oxygen accumulation make these systems more expensive to build and operate than ponds.
But the photobioreactors developed by CEAT are noteworthy for their simplicity and use of cheap, if not somewhat crude materials, that work effectively just the same.

Moreover, they can be easily constructed and replicated, Demafelis said.

The best part is that baseline results of the prototypes have been very encouraging so far. Compared to conventional methods like batch system, the photobioreactor prototypes showed good benchmark results in the laboratory setting.
 For one thing, algae harvest is far bigger. And because it is a continuous system, it is cost-efficient in terms of productivity volume and mass of harvested algae, he stressed, UPLB scientists said.

Conversely, like other photobioreactors of its kind, CEAT?s photobioreactors are prone to innate disadvantages of such systems like contamination.
But Prof.Demafelis says the practical solution is to simply seed the microalgae continuously so it will overcome the contaminants.

The basic technology is commendable enough as it is but Demafelis insists that there's more to be done to further enhance the design and efficiency of the photobioreactors.

He said they are looking forward to eliminating the artificial light because it is energy intensive.

Eventually, they also want to make use of raw materials that have negative cost index such as water effluents, waste water, and agri-run off which contain the necessary nutrients for the algae to thrive.(PNA)
Sun October 03 2010 11:35:21 PM by Jacintha Prof Demafelis  |  CEAT  |  photobiorector 2151 views

Comments - 2

  • Vinaygade wrote:
    Mon October 04 2010 07:09:12 AM


    Vote Up! 2 Vote Down! 0

  • Jacintha wrote:
    Wed October 06 2010 09:34:38 AM

    The fact that the volume of algae harvested is large and the process is continuous makes it cost effective

    Vote Up! 0 Vote Down! 0

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