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Make sure to check on the Vermont Bioenergy Initiative website for more national bioenergy events as we will be updating this list!

 

 

 

Nick Meyer of North Hardwick Dairy, an Organic Valley milk producer, was able to reduce energy costs and increase self-sufficiency by growing sunflowers for biodiesel and meal while maintaining a wind turbine to help cover electricity needs.

Nick Meyer of North Hardwick Dairy, an Organic Valley milk producer, was able to reduce energy costs and increase self-sufficiency by growing sunflowers for biodiesel and meal while maintaining a wind turbine to help cover electricity needs.

We all know food gives us energy. But we might sometimes lose sight of the amount of energy involved in producing, processing and delivering that food to our plates. Everything requires energy: from tractors plowing and planting to producing fertilizer or compost; from milking cows and keeping that milk cold to storing and transporting vegetables. This energy costs farms real money and it is sometimes a major category of expense. Energy costs are typically one of the highest for farms, rivaling feed costs on dairy farms and labor costs on vegetable farms.

As Vermont experiences growth in food-related businesses and jobs, decisions about energy become more and more important. This has been part of Vermont’s Farm to Plate Strategic Plan and the associated network of people working on implementing that plan. The plan includes goals related to energy, including; reducing farm production expenses, reducing adverse environmental impacts from farm and food system activities, reducing energy use, and increasing renewable energy use in the food system.

One example of how this is actually working is a group called the Farm to Plate Energy Cross Cutting Team: a group of energy specialists from Efficiency Vermont, the Agency of Agriculture, UVM’s Rubenstein School and UVM Extension, The Vermont Bioenergy Initiative, USDA NRCS and private companies. The team meets regularly to learn from each other and take on specific projects such as the recent set of seven “Energy Success Stories” which were released at the 2014 Farm Show,  showcasing farms, businesses, vendors, installers, and technical assistance providers who have made a difference with energy efficiency savings and renewable energy production.

Chaired by Efficiency Vermont planning manager, JJ Vandette, the energy team will continue to address the Farm to Plate Efficiency and Renewable Energy Goal to decrease overall food system energy consumption and increase food system renewable energy production and the Farm to Plate Environmental Impacts Goal to decrease adverse environmental impacts from farming and food system activities—while helping to decrease production expenses—also a goal of the Farm to Plate Strategic Plan.

The team is always interested in having new members. If you have an interest in energy, especially energy on farms and in the food system, we’d love to hear from you. JJ Vandette can be reached at jvandette@veic.org or 802.540.7915.

Data sources and analysis at www.vtfarmtoplate.com/getting-to-2020.

Bioenergy; Biomass to Biofuels

Bioenergy: Biomass to Biofuels; is an innovative new textbook that provides insight into the potential and current advances and benefits of biofuel. Contributions include an extensive list of well-respected university extension programs, such as The University of Vermont Research Extension, as well as numerous national organizations including the US Department of Energy’s National Renewable Energy Laboratories. The text is edited by Anju Dahiya, cofounder of General Systems Research, LLC and lead biofuels instructor at the University of Vermont’s Rubenstein School of Environment and Natural Resources, both of which stand as leaders in cutting-edge topics such as microbial fuels and biogas. The chapters of the book are divided into solid, liquid and gaseous biofuels, and further explore cost-effective production as well as discussions covering economics, environment and policy.

Organized into seven accessible sections, Bioenergy: Biomass to Biofuels begins with an in-depth overview of the transformation of biomass into biofuels. Once the basics are covered, readers move on to the technical applications of solid feedstocks, such as wood and grass, and their transformation into biofuels. The following section discusses biomass to liquid biofuels—text focuses on oilseeds, cellulose ethanol, and algae as feedstocks. Anaerobic digestion is explored in a section outlining gaseous fuels and bioelectricity and focuses primarily on livestock manure feedstocks. Throughout the chapters, the tradeoffs and benefits of these different feedstocks are outlined through deeper analysis.

Multiple chapters focus in detail on conversion pathways for cost effective biofuel production. The myriad of topics include basic biodiesel production efficiency, converting petroleum-based infrastructure into biorefineries, reducing enzyme cost through varying combinations, and sustainable aviation biofuels. The text concludes with a robust section that connects biofuels to a big picture perspective—economics, sustainability, environmental implications, and policy are examined closely in relation to renewable resources, future uncertainties, and entrepreneurship.

Bioenergy: Biomass to Biofuels is structured to meet the needs of professionals finding their way in the field, students in need of an introduction, and instructors establishing a course on biofuels. Case studies on provided topics are found at the end of every section and are based on documented implementation projects. Bioenergy: Biomass to Biofuels is available for purchase on the Elsevier publisher website. Editor Anju Dahiya, owner of General Systems Research in Burlington, Vermont and is a Vermont Bioenergy Initiative grant recipient to advance research and applications of converting algae into biofuel.

baling switchgrass

Baling switchgrass at Meach Cove Farm in Shelburne, Vermont. Photo Credit Vermont Bioenergy Initiative

 

Montpelier, VT – A new report evaluating grass biomass energy as a potential heating fuel has been released. Grass Energy in Vermont and the Northeast summarizes current research on the agronomy and usage potential of grass as a biofuel, and points to next steps for the region to fully commercialize this opportunity. The report was released last week by the Vermont Bioenergy Initiative, a program of the Vermont Sustainable Jobs Fund. The full report can be found on the Vermont Bioenergy Initiative website.

“There have been several independent assessments over the years of the various aspects of growing and burning grass for energy, but we were missing the step of linking it all together. We needed to put into one place what is currently known about grass energy, and get our remaining questions on paper,” says Sarah Galbraith, program manager of the Vermont Bioenergy Initiative. “It is very possible that grass as a heating fuel could enter into Vermont’s growing suite of renewable energy options. There are still uncertainties, but this report provides a series of recommendations and next steps for Vermont and the Northeast.”

The assessment for the report was conducted by members from Wilson Engineering Services and Ernst Conservation Seeds, and a former staff of Pennsylvania State University Cooperative Extension, who together conducted a literature review and interviews with experts in the field. The report was reviewed by the Vermont Agency of Agriculture, Food and Markets, University of Vermont Extension, Biomass Energy Resource Center, and the Vermont Sustainable Jobs Fund.

Grass for biofuels grow at the UVM Hort Farm in South Burlingon, Vermont. Photo credit Vermont Bioenergy Initiative

Grass for biofuels grow at the UVM Hort Farm in South Burlingon, Vermont. Photo credit Vermont Bioenergy Initiative

Grass Energy in Vermont and the Northeast includes key recommendations on models of grass energy that will work best for Vermont. Regional and closed loop processing were two models recommended, both involving farmers growing and harvesting grass, but differing in where the grass is processed into fuel and where it is used. The regional processing model calls for aggregating grass from a 50-mile radius at a central processing facility, where the grass is made into and used as fuel, or sold to local users. The closed loop model suggests farmers growing and processing grass on-site for on-farm or community use. Other models, like mobile on-farm processing and processing fuel for the consumer pellet market have significant hurdles to overcome if they are to be successful in Vermont.

Despite hurdles in some of the models presented, the report points to grass energy being a good option overall. “Native, warm-season grasses grown as a heating fuel are a viable energy crop for Vermont farmers wishing to diversify. Once the grasses are well-established, the input costs are minimal—especially compared to corn,” states Alexander DePillis, senior agriculture development coordinator for Vermont’s Agency of Agriculture, Food and Markets, an instrumental partner throughout planning for and publishing the grass energy report. “Grass thermal energy has the potential to help cut Vermont’s overall fuel bills while helping us meet the overall goal of the Comprehensive Energy Plan—for Vermont to obtain 90% of its energy from renewable sources by 2050.”

Perennial grasses can be grown on marginal lands not well suited for continuous row crop production and in open rural land currently not in agricultural production. The grass energy benefits reviewed in the report include retaining energy dollars in the local community, reducing greenhouse gas emissions from heating systems, improving energy security, providing a use for marginal farmland, and reducing pollution in soil and run-off from farms. Recommendations include a concerted effort in Vermont to plant grasses for energy on extended buffer strips along Lake Champlain, thereby reducing its nutrient load. Grass is a perennial crop harvested annually that can help level the increasing demand for forest biomass, while adding water quality and wildlife benefits by controlling erosion, reducing fertilizer use and providing cover and food for migrating and nesting birds.

In 2008, the Vermont Bioenergy Initiative began to explore the potential for grasses grown in Vermont to meet a portion of the state’s heating demand and reduce the consumption of non-renewable fossil fuels. The Grass Energy in Vermont and the Northeast report was initiated by the Vermont Sustainable Jobs Fund to aid in strategic planning for future grass energy program directives. The Vermont Bioenergy Initiative and subsequent grass energy report are funded by appropriations from the US Department of Energy secured by the Office of Senator Patrick Leahy.

The Vermont Bioenergy Initiative (www.vermontbioenergy.com) draws the connection between diversified agriculture and local renewable energy production for on-farm and community use. Aiming to supply farm inputs and reduce fossil fuel consumption, this program supports research, technical assistance, and infrastructure development in emerging areas of bioenergy. Since 2003 the program has focused on biodiesel production and distribution for heating and transportation, oil crops for on-farm biodiesel and feed, grass for heating, and algae production for biofuels and wastewater management. The Vermont Bioenergy Initiative is a program of The Vermont Sustainable Jobs Fund, a non-profit organization which provides financing, technical assistance and other resources to Vermont businesses who develop products and services and create jobs in the fields of renewable energy, and sustainable agriculture and forestry.

 

 

A report published this week in Nature Climate Change indicated that ethanol made from corn residue can reduce soil carbon and increase CO2 emissions, indicating the harvested leftovers from corn are “worse than gasoline for global warming,” according to the Associated Press, who released the study results.

In Vermont the term “biofuel” and “bioenergy” are commonly used to refer to woody biomass (e.g., chips and pellets), anaerobic digestion (e.g., new manure and food scrap digester at Vermont Tech), and on-farm biodiesel production.

A scale-appropriate model of local bioenergy production for in-state use is being pioneered by farmers and researchers. These emerging renewable energy resources include switch grass for heating, algae production for biofuels and wastewater management, and oilseed crops for on-farm biodiesel production, equipment use, and animal feed. Since 2003, the Vermont Bioenergy Initiative has been funding research, technical assistance, and demonstration projects—along with its partners at the University of Vermont Extension—in order to develop the infrastructure to connect diversified agriculture and local renewable energy production for on-farm and community use. A new website www.VermontBioenergy.com provides a series of written and video resources in these emerging fields of bioenergy.

John Williamson makes biodiesel at State Line Biofuels in North Bennington, Vermont

John Williamson makes biodiesel at State Line Biofuels in North Bennington, Vermont

“Local oilseed biodiesel production for local use is profoundly different from national and international models of biofuel production. While corn-based ethanol and palm oil biodiesel are gaining negative attention for their impacts on the environment and food security, biofuels that are produced and used locally help transition away from unsustainable models of food and fuel production,” states Sarah Galbraith, program manager of the Vermont Bioenergy Initiative. “Local production for local use works well in conjunction with sustainable food production.”

Vermont is particularly dependent on fossil fuels for heating and transportation, sending its energy dollars largely out of state. In the case of locally produced biodiesel, three products can be made from one crop: animal feed, organic fertilizer, and biofuel for heat, transportation, and farm equipment.

US corn-based ethanol mandates are bringing additional acres into mono-crop production, in some cases converting sensitive natural areas like native grasslands and forestland into farmland. In contrast, local bioenergy production for local use incorporates rotational crops like sunflowers and soybeans into acres already in production. Vermont farms growing oilseed crops for biodiesel production are doing so on long-established cropland in the context of diversified and sustainable food production.

The ethanol mandates are raising grain costs nationally, making feed expensive for Vermont dairy farmers. Local bioenergy production, however, means farmers produce their own feed, fuel, and fertilizer for on-farm use, at a fraction of the cost and at more stable prices.

The Vermont Bioenergy Initiative’s newly launched website features an in depth look at oilseed production and biodiesel operations with case studies, research, and educational videos. The website also features similar resources for grass energy and algae for biofuel and wastewater management as well as information on other biofuels being produced and used in Vermont. www.VermontBioenergy.com

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The Vermont Bioenergy Initiative draws the connection between diversified agriculture and local renewable energy production for on farm and community use. Aiming to supply farm inputs and reduce fossil fuel consumption, this program supports research, technical assistance, and infrastructure development in emerging areas of bioenergy. Since 2003 the program has focused on biodiesel production and distribution for heating and transportation, oil crops for on-farm biodiesel and feed, grass for heating, and algae for biofuels and wastewater management. The Vermont Bioenergy Initiative works with biodiesel producers including State Line Biofuels and the Farm Fresh Fuel Project at Borderview Farm and grass pellet research through UVM Extension and is supported financially by US Department of Energy congressional appropriations secured by US Senator Patrick Leahy. The Vermont Bioenergy Initiative is a program of the Vermont Sustainable Jobs Fund—a non-profit organization created by the Vermont Legislature in 1995 to accelerate the development of Vermont’s green economy in the fields of renewable energy, sustainable agriculture and forestry.

 

sid bosworthThe University of Vermont Extension Northwest Crops and Soils team held their annual Field Day on Thursday, August 1, 2013 from 10:00am to 3:30pm at Borderview Research Farm in Alburgh, Vermont.

Dr. Heather Darby led more than 200 attendees on a tour of research stations at the farm. The theme of this year’s field day was “Strategic Farming – Gearing Up for Weather Extremes.” Tour stops included brief overviews frhannahom researchers and technicians focused on cover crops, irrigation systems, sunflowers for cooking oil and biodiesel, wheat varieties, aerial seeding, hops variety trials and demonstration of a mechanized hops harvester, and demonstration of an oilseed press.

Vermont Bioenergy Initiative was in attendance with the Bioenergy Now! videos along with copies of the report, Vermont On-Farm Oilseed Enterprises: Production Capacity and Breakeven Economics written by Netaka White, formerly of VSJF and now of Full Sun Company, and Chris Callahan with UVM Extension.

More than 20 attendees, many of them farmers, attended the demonstration of the two oilseed presses at Borderview Farm by Hannah Hardwood of UVM Extension and Roger Rainville, owner along with his wife, Claire, of Borderview Farm.