The American ethanol industry, the world’s largest, is about to get a little sweeter. Louisiana Green Fuels (LGF), an international investment group, says it is on schedule to open up the first commercial sucrose-to-ethanol plant in America. LGF, which is 80 percent owned by Inverandino, a Colombian business group, tells Earth2Tech it plans to have four ethanol plants and three sugar mills in operation in Louisiana in the next 10 years pumping out 100 million gallons of sugar-based ethanol a year.

In the wake of hurricanes Katrina and Rita, LGF has been buying up shuttered sugar mills and dormant equipment in the devastated Gulf region, and now owns three mills in Louisiana. Prices were probably pretty good for those hurricane-ravaged mills and LGF says that a sucrose-based ethanol industry could help revitalize the area…

This is a good experiment for the American ethanol industry, which has come under heavy fire for using so much corn for fuel. Sugar can give an eightfold return on the fossil energy used to make it while corn only yields 1.3 times the fossil energy used. Count sugar in as a potential major player in U.S. biofuels market.

All overdue, of course. Northern tier states with an excess of sugar beet product should have been in on this already.

Sugar cane mills can sell the bagasse for cellulosic ethanol production as that ramps up, as well.




  1. rafavica says:

    #31 Scott,

    Many thanks for that

    I just tried to makee a terse reference to a terrific finding (via reddit.com BTW) Of course I’ve missed things.

    One of those would be that you could build a power station that would burn the algae fat in some gas turbine, and the resulting CO2 + H2O would go back into the algae reactor.

    One thing that is not explained in the video is how the CO2 is fed into the bioreactor.

    Another thing is the carbohidrates + proteins subproducts that could be used as fertiliser / cattle feed / ethanol…

    There are other algae biofuel companies:

    http://www.treehugger.com/files/2008/06/algal-biofuels-klm-cruise-ships.php

    But they use open ponds instead of controlled bioreactors.

    It does need SUNLIGHt though… B-)

  2. bobbo says:

    Here’s another one:

    http://www.originoil.com/applications/originoil-benefits.html

    In the links it describes getting light to their algae using LED’s. Sounds more complicated and less efficient than direct sunlight exposure–but the devil is in the details.

    I also like the linked discussion about the energy needed to get the oil out of the algae==an important step regarding efficiency.

    All this stuff has complexities not readily apparent==but answers too.

    Future is looking brighter to me, if we can get there?

  3. Prof.Hans-Jürgen Franke & Prof. Pengcheng Fu says:

    ETHANOL-PRODUCTION WITH BLUE-GREEN-ALGAE
    A SOLUTION AFTER PEAK-OIL AND OIL-CRASH

    University of Hawai’i Professor Pengchen “Patrick” Fu developed an innovative technology, to produce high amounts of ethanol with modified cyanobacterias, as a new feedstock for ethanol, without entering in conflict with the food and feed-production .

    Fu has developed strains of cyanobacteria — one of the components of pond scum — that feed on atmospheric carbon dioxide, and produce ethanol as a waste product.

    He has done it both in his laboratory under fluorescent light and with sunlight on the roof of his building. Sunlight works better, he said.

    It has a lot of appeal and potential. Turning waste into something useful is a good thing. And the blue-green-algae needs only sun and wast- recycled from the sugar-cane-industry, to grow and to produce directly more and more ethanol. With this solution, the sugarcane-based ethanol-industry in Brazil and other tropical regions will get a second way, to produce more biocombustible for the worldmarket.

    The technique may need adjusting to increase how much ethanol it yields, but it may be a new technology-challenge in the near future.

    The process was patented by Fu and UH in January, but there’s still plenty of work to do to bring it to a commercial level. The team of Fu foundet just the start-up LA WAHIE BIOTECH INC. with headquarter in Hawaii and branch-office in Brazil.

    PLAN FOR AN EXPERIMENTAL ETHANOL PLANT

    Fu figures his team is two to three years from being able to build a full-scale
    ethanol plant, and they are looking for investors or industry-partners (jointventure).

    He is fine-tuning his research to find different strains of blue-green algae that will produce even more ethanol, and that are more tolerant of high levels of ethanol. The system permits, to “harvest” continuously ethanol – using a membrane-system- and to pump than the blue-green-algae-solution in the Photo-Bio-Reactor again.

    Fu started out in chemical engineering, and then began the study of biology. He has studied in China, Australia, Japan and the United States, and came to UH in 2002 after a stint as scientist for a private company in California.

    He is working also with NASA on the potential of cyanobacteria in future lunar and Mars colonization, and is also proceeding to take his ethanol technology into the marketplace. A business plan using his system, under the name La Wahie Biotech, won third place — and a $5,000 award — in the Business Plan Competition at UH’s Shidler College of Business.
    Daniel Dean and Donavan Kealoha, both UH law and business students, are Fu’s partners. So they are in the process of turning the business plan into an operating business.

    The production of ethanol for fuel is one of the nation’s and the world’s major initiatives, partly because its production takes as much carbon out of the atmosphere as it dumps into the atmosphere. That’s different from fossil fuels such as oil and coal, which take stored carbon out of the ground and release it into the atmosphere, for a net increase in greenhouse gas.
    Most current and planned ethanol production methods depend on farming, and in the case of corn and sugar, take food crops and divert them into energy.

    Fu said crop-based ethanol production is slow and resource-costly. He decided to work with cyanobacteria, some of which convert sunlight and carbon dioxide into their own food and release oxygen as a waste product.

    Other scientists also are researching using cyanobacteria to make ethanol, using different strains, but Fu’s technique is unique, he said. He inserted genetic material into one type of freshwater cyanobacterium, causing it to produce ethanol as its waste product. It works, and is an amazingly efficient system.

    The technology is fairly simple. It involves a photobioreactor, which is a
    fancy term for a clear glass or plastic container full of something alive, in which light promotes a biological reaction. Carbon dioxide gas is bubbled through the green mixture of water and cyanobacteria. The liquid is then passed through a specialized membrane that removes the
    ethanol, allowing the water, nutrients and cyanobacteria to return to the
    photobioreactor.

    Solar energy drives the conversion of the carbon dioxide into ethanol. The partner of Prof. Fu in Brazil in the branch-office of La Wahie Biotech Inc. in Aracaju – Prof. Hans-Jürgen Franke – is developing a low-cost photo-bio-reactor-system. Prof. Franke want´s soon creat a pilot-project with Prof. Fu in Brazil.

    The benefit over other techniques of producing ethanol is that this is simple and quick—taking days rather than the months required to grow crops that can be converted to ethanol.

    La Wahie Biotech Inc. believes it can be done for significantly less than the cost of gasoline and also less than the cost of ethanol produced through conventional methods.

    Also, this system is not a net producer of carbon dioxide: Carbon dioxide released into the environment when ethanol is burned has been withdrawn from the environment during ethanol production. To get the carbon dioxide it needs, the system could even pull the gas out of the emissions of power plants or other carbon dioxide producers. That would prevent carbon dioxide release into the atmosphere, where it has been implicated as a
    major cause of global warming.
    Honolulo – Hawaii/USA and Aracaju – Sergipe/Brasil – 15/09/2008

    Prof. Pengcheng Fu – E-Mail: pengchen2008@gmail.com
    Prof. Hans-Jürgen Franke – E-Mail: lawahiebiotech.brasil@gmail.com

    Tel.: 00-55-79-3243-2209


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