Dwindling petroleum supplies and growing environmental concerns are significantly impacting the cost of petro-fuel and its infrastructure. The search for alternative fuel sources has led to ethanol, a gasoline substitute that is already in the marketplace as Gasohol and E-85. But large-scale production of corn-based ethanol is controversial as it threatens the world’s food supply. There are alternatives, however: Brazil uses sugar cane, which is up to six times more productive in energy conversion. After the energy crisis of the 1970s, there was a lot of misinformation about the cost of individual ethanol production. In order to achieve energy independence from gasoline, ethanol lends itself to small-scale production, and especially to cooperative ventures in rural communities, often using “waste” feedstock. Alcohol Fuel is a practical, grassroots book that will give readers all the information they need, covering every aspect of making and using ethanol for fuel, including: *Permitting and planning *Budgeting and setup *Sourcing feedstocks *Finding and building distillation equipment *Storage and safety *Practical applications for converting motor vehicles, farm equipment, and space-heating systems The practical, user-friendly information on basic equipment needs, fermentation recipes, and distillation designs will be of interest to readers looking for information, as well as to those ready to make the switch. Richard Freudenberger was research director of Mother Earth News, where he managed the Alcohol Fuel Program and developed solar and renewable solar and energy projects. He is publisher and technical editor of BackHome magazine and lives in Hendersonville, North Carolina.
Six volumes bound under one cover make this the most comprehensive book ever written on alcohol fuel production, use, policy, history, ecology, politics and economic perspectives. Thoroughly addresses both past and present controversies, myths and misconceptions that permeate the public debate. It contains the most exhaustive treatment of potential energy crops to be found anywhere. Crops for all climates and soil types are detailed including cellulosic materials. Unique feedstocks that can have global impact like ocean kelp, cattails used for treating sewage, and creative waste products are covered. Design and construction of alcohol plants from 2 gallons per hour to 50 gallons per hour including detailed distillery design data is described in laymen?s terms for easy construction. Case histories of actual plants are covered in interviews of operations built by the author?s students.The book compares qualities of alcohol versus gasoline and diesel. In exceptional detail, conversion of gasoline, diesel, aircraft, motorcycle, two stroke, and utility engines are described. Using alcohol to produce electricity and hot water as well as cooking and cooling are also addressed. Business models for micro and small plants are laid out enabling the reader to design their own business.The author?s original concept of Community Supported Energy projects in which communities establish driver owned alcohol stations and then contract with farmers to supply the station are outlined clearly so activists can organize them. Profusely illustrated with 514 charts, photos and drawings. The book is thoroughly documented with 473 endnotes and a 6300 entry index.
This book offers a broad understanding of bioethanol production from sugarcane, although a few other substrates, except corn, will also be mentioned. The 10 chapters are grouped in five sections. The Fuel Ethanol Production from Sugarcane in Brazil section consists of two chapters dealing with the first-generation ethanol Brazilian industrial process. The Strategies for Sugarcane Bagasse Pretreatment section deals with emerging physicochemical methods for biomass pretreatment, and the non-conventional biomass source for lignocellulosic ethanol production addresses the potential of weed biomass as alternative feedstock. In the Recent Approaches for Increasing Fermentation Efficiency of Lignocellulosic Ethanol section, potential and research progress using thermophile bacteria and yeasts is presented, taking advantage of microorganisms involved in consolidating or simultaneous hydrolysis and fermentation processes. Finally, the Recent Advances in Ethanol Fermentation section presents the use of cold plasma and hydrostatic pressure to increase ethanol production efficiency. Also in this section the use of metabolic-engineered autotrophic cyanobacteria to produce ethanol from carbon dioxide is mentioned.