User:Milton Beychok/Sandbox

Biomass, a source of renewable energy, is biological material such as wood, wood waste, municipal solid waste, straw, sugar cane, algae, and many other byproducts derived from agricultural and forestry production as well as other sources. Since biomass derives from plants generated by solar energy in the photosynthesis process, it can also be defined as the biological material on Earth that has stored solar energy in the chemical bonds of the organic material.

The fossil fuels (coal, petroleum and natural gas) are currently thought to have been formed from prehistoric, ancient biomass buried deeply underground over millions of years of geological time. Therefore, they are not considered to be renewable sources of energy

Biomass fuel for electric power production
The direct combustion of biomass for producing heat and electric power provides a ready disposal mechanism for municipal, agricultural, and industrial organic wastes. In 2009, about 11,350 megawatts (MW) of electric power, amounting to 1.1% of the summertime electrical supply in the United States was generated by burning biomass that included: wood, wood waste, municipal solid waste (MSW), landfill gas, and agricultural byproducts and waste.

The New Hope Power Partnership in Florida is the largest biomass power plant in North America. It generates 140 MW of power using uses sugar cane fiber (bagasse) and recycled wood as fuel. It has been in operation for more than 10 years.

Production of liquid transportation fuels
There are several processes available for converting the chemical energy contained in biomass into liquid automotive transport fuels such as biodiesel and ethanol.

Ethanol fuel:

Ethanol fuel is ethyl alcohol (C2H5OH) and it is most often used as an automotive motor fuel, mainly as an additive for gasoline. Ethanol can be produced by fermentation of sugar cane, bagasse, sugar beets, barley, potatoes, corn and many other grains as well as many agricultural byproducts and wastes.

The worldwide production of ethanol for automotive fuel in 2007 was 52,000,000,000 litres (13,700,000,000 gallons). From 2007 to 2008, the share of ethanol in global gasoline use increased from 3.7% to 5.4%. In 2009, worldwide ethanol fuel production reached 73,900,000,000 litres (19,500,000,000 gallons) and was expected to reach 85,900,000,000 litres (22,700,000,000 gallons) in 2010.

Ethanol fuel is widely used in Brazil and in the United States, and together both countries were responsible for about 86 percent of the world's ethanol fuel production in 2009.

Biodiesel fuel:

Biodiesel refers to a diesel fuel produced by chemically reacting lipids such as vegetable oils or animal fats with an alcohol such as methyl alcohol (CH3OH). The resulting biodiesel consists of esters of long-chain fatty acids. The process is known as "transesterification" and it may be carried out by several methods: the common batch process, supercritical processes and ultrasonic methods.

In 2009, the worldwide production of biodiesel was 17,900,000,000 litres (4,730,000,000 gallons). The three countries with the largest annual biodiesel production were Germany (16%), France (12%) and the United States (11%).

Biomass gasification to produce syngas
Gasification is a process that reacts carbon-containing materials (such as coal or biomass) at high temperatures with reagent gases (namely, steam, pure oxygen and/or air) to produce a mixture of carbon monoxide (CO) and hydrogen (H2) commonly called syngas (a contraction of synthesis gas). It has been in use since the early 1800s when coal and peat were gasified to produce what was then called town gas for lighting and cooking ... later to be replace by electricity and natural gas. As of 2010, 412 modern industrial-scale gasifiers were in operation in 29 countries worldwide (see adjacent table).

The syngas may be directly burned as a fuel, converted into methyl alcohol or hydrogen, subjected to methanation to produce synthetic natural gas (SNG), or converted into synthetic liquid hydrocarbons via the Fischer-Tropsch process.

The vessel in which the gasification process takes place is called a gasifier. There are various types of gasifiers in current use, including:


 * Counter-current fixed bed gasifier: This gasifier is a vertical, cylindrical vessel containing a bed of carbon-containing material (e.g., coal or biomass) through which steam, oxygen and/or air flow upward. Although commonly referred to as a fixed bed gasifier, the crushed coal or biomass is fed into the the gasifier through a lock hopper mounted on top of the gasifier and the carbonaceous material slowly moves downward as it is converted into syngas, which is removed from the upper portion of the gasifier,  and ash or slag removed from the bottom of the gasifier.


 * Co-current fixed bed gasifier: This gasifier is also a vertical cylindrical vessel, which is quite similar to the  counter-current gasifier type except that the steam, oxygen and/or air enter at the top of the bed, flow downward co-current with the slowly moving bed of carbonaceous material, and the product syngas is removed below the bed.


 * Fluidized bed gasifier: This gasifier is again a vertical, cylindrical vessel. It differs from the fixed bed reactors in that the feedstock biomass is very finely crushed before it enters the gasifier and the reaction bed of ground biomass is fluidized by the reagent gases (steam, oxygen and/or air) flowing upward through the bed. The fluidization of the reaction bed increases the height of the bed (as compared to the fixed bed gasifiers) and the finely crushed biomass results in much more biomass surface area being exposed to the reagent gases. The product syngas contains fine particles of crushed biomass which are removed by routing the syngas through a cyclone to recover the fines and recycle them back into the reaction bed.


 * Entrained flow gasifier: This gasifier, like the other three discussed above, is also a vertical, cylindrical vessel. The feedstock biomass is finely crushed and flows downward co-currently with pure oxygen. Air is seldom used as a reagent gas in a an entrained gasifier. The gasification reactions take place in a dense cloud of fine biomass particles. The syngas exits from the bottom section of the gasifier and is routed through a cyclone (and perhaps a water scrubber) for removal of the fines. Entrained gasifiers operate at temperatures of about 1000 to 1800 °C and at pressures of 30 to 70 bar which is a much higher pressure than is the case for the other types of gasifiers. The adjacent Fig. 1 depicts an entrained flow gasifier of the type discussed here.

Gasification chemistry
It is difficult to state exactly what chemical reactions occur during gasification. However, most researchers have reached agreement on the primary reactions and the syngas composition ranges shown just below:

Fischer-Tropsch synthesis of liquid hydrocarbons
Fischer-Tropsch synthesis is a catalytic chemical process developed in the 1920s to convert a mixture of carbon monoxide and hydrogen (i.e., syngas), into hydrocarbon molecular chains of varying lengths. The process is relatively simple: syngas is fed at high temperatures through catalysts (usually the transition metals cobalt or iron) which facilitate the hydrocarbon formation. When paired with gasification of fossil fuels or bomass, which produces syngas, the Fischer-Tropsch process can be viewed as a method to transform any available carbon source into hydrocarbon liquids consisting of molecules having from 5 to 20 carbon atoms.

The process was invented by Franz Fischer and Hans Tropsch working in Germany's Kaiser Wilhelm Institute in the 1920's. It was first commercialized in Germany in 1936 and it was used extensively by Germany during World War II to produce synthetic fuels. In fact, the Fischer-Tropsch process was used to produce about 25 % of Gernmany's wartime production of automobile fuel. Later, facing isolation during the apartheid era (1948 - 1990), South Africa turned to coal gasification and the Fischer-Tropsch process to supply significant quantities of its hydrocarbon fuel needs. Since that time, the process has been extensively improved and refined.