The DuPont Danisco Cellulosic Ethanol (DDCE) joint venture and the DuPont partnership with Bio Architecture Lab (BAL) to develop macroalgae to butanol capabilities placed first, while the Butamax Advanced Biofuels joint venture placed second in their respective categories. DuPont Applied BioSciences President Craig F. Binetti: “Each venture incorporates game-changing science and tailored business models that maximize our ability to deliver large volumes of biofuels to a global population that is increasingly more interested in alternatives to oil.”

The joint venture of DuPont and Danisco has made rapid progress since it was established in 2008. DDCE has started up a 250,000-gallon demonstration-scale biorefinery in Tennessee and brought the cost of production below $2 per gallon. DDCE expects to announce its first commercial plans this fall. “Cellulosic ethanol is ready for deployment,” DuPont Applied BioSciences President Craig Binetti said.

The Butamax Advanced Biofuels joint venture was voted a clear leader in the development of biobutanol technologies. “The strategic plan for Butamax is to give biorefineries the option to convert from ethanol to biobutanol in the future. The joint venture has started some preliminarily exploratory discussions with ethanol producers in the United States and Brazil.”

The U.S. Department of Energy Advanced Research Projects Agency – Energy (ARPA-E) awarded funding to DuPont and its partner BAL last fall to develop a process to convert macroalgae to biobutanol. The DuPont-BAL partnership placed firstin the category: Transformative Technology: macro algae platforms. “Macroalgae to biobutanol could reduce greenhouse gas emissions by more than 90 percent when compared to petroleum and diversify feedstock routes for advanced biofuels.”

The Tennessee Biofuels Initiative already is creating new jobs and opportunities. “Here in Vonore, DDCE and Genera Energy are well ahead of the curve as we develop the entire value chain, from feedstock to production. We delivered on our promise to investors, customers and the industry by initiating start-up at the end of last year. We are on track to provide the industry with investment-grade packages that meet demands for low-cost, scalability and sustainability”, said DDCE President and CEO Joe Skurla.

It is a major achievement for DDCE, Tennessee’s Biofuels Initiative and for the cellulosic ethanol industry, which is under federal mandate to deliver 36 billion gallons of renewable fuel by 2022, of which 16 billion gallons must come from cellulosic sources.

Kelly Tiller, CEO of Genera Energy and director of external operations for the UT Office of Bioenergy Programs, said, “The University of Tennessee Biofuels Initiative is the only fully integrated program that is working with farmers and agricultural industry to reliably supply the necessary feedstock so bio refineries can produce plentiful, affordable, renewable and sustainable fuels.”

Bio-ethanol is produced from sugars in plantmaterial by the yeast ‘Saccharomyces cerevisiae’. The yeast is the same micro-organism that produces alcohol in beer and wine. Bio-ethanol is produced by preference from raw materials that do not compete with the food production, such as wheat straw or corn leafs and stalks. By releasing the sugars from this material, a lot of acetic acid also produces. Acetic acid can restrain the production of bio-ethanol by the yeast. Another difficulty is that around 4 percent of the sugar will be lost due to the development of the side-product glycerol. The forming of glycerol was long regarded as an inevitable consequence of the production process.

Researchers of the TU Delft got round this problem. Starting point was that the damaging acetic acid can also be converted into alcohol by the yeast. It seems, only one gene is missing in the yeast. By transferring this missing gene from the bacterium E-coli into the yeast, the researchers from TU Delft and the Kluyver Centre for Genomics of Industrial Fermentation obtained a yeast that transfers acetic acid into ethanol. Due to this adjustment the function of the production of glycerol expires in the entire process.

High moisture content also makes the co-product more difficult to handle for shippers. Shipping a high-moisture feed adds to the total weight of the shipment, and product consistency can cause the co-product to stick to the containers, causing difficulties in the unloading process. Generally, the lower the moisture content, the easier it is to transport co-products.

However, removing moisture from co-products requires large, capital intensive dryers and increases energy costs. In addition to the cost of drying, exposing co-products to high temperatures increases the risk of scorching, which can reduce the nutritional content and the overall value of the feed. In some cases, livestock producers feeding low-moisture co-products find animals exhibit lower feed efficiency, which the producers remedy by putting water back into the feed. Drying costs account for most of the price differential between co-products that differ only in moisture content.

Typically, U.S. livestock operations where co-products are used are larger operations (USDA, NASS, 2007). Such operations can use larger quantities of co-products on a regular basis, providing ethanol plants with a continuous and consistent market for their co-product production. Cattle feeding operations where co-products were used averaged 76 percent larger than all cattle operations (1,276 head vs. 725 head) (USDA, NASS, 2007). Hog operations using co-product feed were over three times as large as average operations (10,957 head vs. 3,256 head). One reason for this size differential is that co-products need to be transported from the ethanol production facility as soon as possible to make room for the next batch of co-products, in order to maintain peak ethanol production. Livestock feeding operations that can make use of full truckloads of co-products are more easily able to work with ethanol plants to obtain co-products on a regular basis at attractive prices or perhaps even contract for delivery.

Erickson et al. (2007) observed that returns per head decrease with the distance needed to ship a given proportion of Cargill’s Sweet Bran used in cattle feeding rations, especially if the distances were at least 100 miles from an ethanol plant. Similar results were observed in another Nebraska study (Waterbury et al., 2009). These findings may also reflect the ability of cattle to grow to slaughter size more efficiently on feed with WDGS compared with feed efficiency when cattle are fed DDGS, as well as the fact that co-products are less expensive prior to incurring drying costs.

Since the movement of co-products offsite facilitates ethanol production, ethanol manufacturing plants are anxious to market and transport the co-products as quickly as possible. The most economical situation for ethanol producers is to be able to ship large amounts of high-moisture co-products for short distances, thus, avoiding drying costs as well as maintaining nutritional content and limiting spoilage. Livestock operations situated within 100 miles of ethanol plants therefore have an advantage in being able to obtain and use co-products efficiently.

Transportation technologies are constantly being introduced and improved. For example, unit trains (such as 90- or 110-car trains dedicated to a single type of traffic), are being used to ship co-products to specific locations. Some milling/processing plants have built specialized rail track loops and unloading facilities to move their co-products. Some are able to unload special railroad cars without decoupling them, and rotate the entire car upside down, to dump co-products into pits from which they can be redistributed or mixed with other feed ingredients and fed to livestock.

Most U.S. livestock producers buy their co-products on the spot market and prefer not to buy under contracts (USDA, NASS, 2007). Contracting for co-products may result in a more reliable supply source. In a study focusing on Nebraska cattle feeders, who are generally close to ethanol plants, most co-product was sold in 2007 on a fi xed-price, annual contract basis (Waterbury et al., 2009). However, in 2008, the absence of contracts between ethanol producers and livestock operations may have been motivated by ethanol plants (Mark, 2009). Cost may not be the only reason producers would contract their co-products; consistency and quality of the co-products are also concerns.

Co-products’ quality and content can vary as processors make adjustments in order to optimize production. Because the feed is a byproduct of the processing plant, the nutrient contents of the feed may vary, based on a number of factors in the production process of primary starch related products and oils. However, as the profi t margins from ethanol production decline, ethanol producers have made more efforts recently to manufacture feed co-products that are consistent in quality and content, which can sell at a premium.

Education among livestock operators about how to use co-products as animal feed appears to be a determinant in the widespread use of co-products. Although most respondents in a NASS survey stated that lack of availability of co-products was the primary reason why they did not feed co-products to their animals, 5 percent of producers in every livestock category cited lack of knowledge as the primary reason (USDA, NASS, 2007). There is potential for more co-product use if U.S. livestock operators become more knowledgeable about how best to manage ethanol co-products as animal feed.

Considerations for the Future
The use of co-products in feed for U.S. dairy, meat, and poultry production will be affected by a number of competing factors. The development and growth of the ethanol industry will affect the availability of corn for feed, increasing competition in the corn market. As the ethanol industry grows, there will be a corresponding increase in co-products available to substitute for corn in animal feed.

Ethanol production increased 232 percent between 2003 and 2007, rising from 2.8 billion gallons to 6.5 billion gallons. The Energy Independence and Security Act of 2007 established the Renewable Fuel Standard (RFS) which mandates the use of biofuels at 11.1 billion gallons in 2009 rising to 36 billion gallons in 2022. Some of the 36 billion gallons is to come from cellulosic ethanol and other advanced biofuels. The maximum amount of corn-based ethanol that can be used to meet the RFS increases from 9 billion gallons in 2008, to 15 billion gallons in 2015. If all 15 billion gallons were produced from dry-milling corn, as much as 98 billion pounds of DDG could be produced from 5.6 billion bushels of corn.

Co-products add to the options available to informed livestock producers to develop the best feeding strategies possible. Increased education of and outreach toward livestock and poultry producers about how best to use co-products as animal feed will influence how operators adapt the new co-products to future feed rations. New information on co-products’ nutritional values, distribution possibilities, and other aspects will be disseminated to the livestock industry through extension offices and publicly available research, among other forms of communication.

 Source: Ethanol Co-Product Use in U.S. Cattle Feeding: Lessons Learned and Considerations / FDS-09D-01 – Economic Research Service/USDA (abstract)
Authors: Kenneth H. Mathews, Jr., and Michael J. McConnell

Researcher assessed the water footprint of thirteen crops. Based on these results a responsible choose can be made for a specific crop en production area. The results of the findings were published in the Proceedings of the National Academy of Sciences (PNAS) van June 2nd, 2009.

The researchers assesed the amount of water needed -both irrigation and rainfall- per Gigajoule energy produced. By connecting wateruse to location and climatological information the most optimal location for the specific crop was assessed. ,,This way it is possible to prevent the production of certain crops in less favourable areas, especially in areas where food and water are already scares resources”, according to the researchers.
The results of this research add a new element to the discussion about crop production for biofuels. Up until now this discussion focussed on the competion between food and fuel. ”Beneath that question lies the question how we should utilize our fresh water supplies in the world. Water that is used for either a food crop such as corn or a non-food crop such as jatropha can not be applied for food production or the maintenance of the ecological system.” The water footprint was developed by prof. Arjan Hoekstra and has proven a powerfull aid in this debate. For example, according to Hoekstra’s model, 1 liter diesel needs 14,000 liter of water when produced from soy or canola. However the production in Western Europe requires a lot less water than that in Asia. Usins soy the water footprint is highets in India and most favourable in Italy and Paraguay. Jatropha, popular as a non-food crop for biodiesel production, claims the most water. To produce 1 liter of diesel around 20,000 liter of water is needed.

Bioelectricity
Research shows that the production of bioelectricity has a smaller water footprint than biofuel production. Reason for the difference is the fact that in the first situation the whole plant is utilized whereas for the production of biofuels only part of the plant e.g. sugar, starch, oil or fibre is needed. Improved techniques can make the water footprint of biofuels smaller.
According to the model the production of bioelectricity from sugar beets is most efficient with regard to the water use. Jatropha is ten times less efficient. A litre bioethanol from sugar beets requires 1400 liter water, using Brasilian sugar cane 2500 liter water is needed.

Het onderzoek is uitgevoerd door de groepen Waterbeheer en Thermische Werktuigbouwkunde, die deel uitmaken van het instituut IMPACT van de Universiteit Twente. Het multidisciplinaire onderzoek naar verantwoord waterbeheer en -gebruik vindt verder plaats in het Twente Water Centre (www.water.utwente.nl).

http://www.utwente.nl

Het artikel ‘The water footprint of bioenergy’ van Winnie Gerbens-Leenes, Arjen Hoekstra en Theo van der Meer, verschijnt op 2 juni in de Proceedings of the National Academy of Sciences of the United States of America. Het kan op verzoek toegestuurd worden.

Contactpersoon voor de pers: Prof. Arjen Hoekstra, Twente Water Centre, tel (053)4893880, email a.y.hoekstra@utwente.nl of Communicatie UT, Wiebe van der Veen, tel (053) 4894244 of 06 121 85 692, email w.r.vanderveen@utwente.nl

ANP Pers Support, het ANP is niet verantwoordelijk voor de inhoud van bovenstaand bericht.

ANP Pers Support is een joint venture van het ANP en PR Newswire.

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The project consist of a pilot installation for biobased products and processes. Besides that an educationcentre for proces operators will be part of the activities. Biofuels will be an important product, but the development of for exemple bio-colours, bio-plastics, bio-detergents and bio-chemicals will also be addressed. The project is estimated to cost about 13 million euro.

The partners aim to build the pilot installation in the Ghent harbour and start it up at the beginning of 2010. Scientists will test coproducts from agriculture, such as wheat straw, corn cobs, wood chips, jatropha- and algea oil, as sources for biofuels on an industrial scale. The installation focusses on the use of European expertise from different sectors. The Belgian professor Wim Soetaert is responsible for the project. 
The education centre will be build in Terneuzen. This will cost around eight million euro. From 2011 onwards this centre should provide well educated technical people to meet the needs of the bio energy market.

“We certainly look well set for success at this the ninth annual All-Energy,” says project director, Judith Patten. All-Energy is run in association with the British Wind Energy Association (BWEA), Scottish Renewables (SRF) and Aberdeen Renewable Energy Group (AREG); the Society for Underwater Technology is its learned society patron, and it has more than 30 government departments (from Westminster and Holyrood), trade associations, and professional institutes as official supporting organisations. The two-day event is free to attend for all with a professional / business interest in renewable energy – online registration is at www.all-energy.co.uk