generation
Butanol is formed by the fermentation of sugar-containing materials with some bacteria. In butanol production, all substances that can be converted into fermentable sugars, except for simple sugars, can be used as substrates [94]. Sugar-containing raw materials (molasses, sugar cane, sugar beet and various fruits) can be fermented by microorganisms without any pretreatment. Raw materials containing starch and cellulose require pretreatments such as enzymatic hydrolysis and/or acid hydrolysis to convert starch and cellulose into sugars that can be used by microorganisms [95].
Biobutanol is formed by acetone, butanol and ethanol fermentation of Clostridium spp. Acetone butanol and ethanol fermentation, also called ABE or solvent, are among the earliest known fermentations that are applied industrially. One of the most important advantages of Clostridium is that it can metabolize many sugars, including decomposition products, as a source of carbon in lignocellulosic renewable agricultural wastes as ethanol-producing microorganisms cannot utilize those wastes before pretreatment step. They have high amylolytic activity; they can directly ferment starchy raw materials without the need for pretreatment, unlike yeasts. Many renewable agricultural products and wastes such as rice, barley, wheat straws, corn bran and cobs, lignocellulosic substances such as bran, corn, potatoes, starch substrates such as kassava and molasses can be used in ABE production [96].
Butanol has very important physicochemical advantages compared to ethanol as a renewable energy source. Considering it as fuel, butanol has a higher energy value than ethanol. The energy content of butanol (105,000 BTU/gallon) is close to the energy content of the gasoline (114,000 BTU/gallon). The energy content of ethanol (84,000 BTU/gallon) is quite low compared to butanol and gasoline [97].
1.6 Biogas and Syngas Conversion Techniques
The gasification process is the transition of the organic components to the gas phase by exposure to the thermochemical transformation process and to obtain volatile, flammable components as a result of the secondary reactions that occur. As a result of the gasification process, in addition to these volatile components, a semi-char (char) and a tar are formed that will give the energy necessary for the process if they are burned by air. Gasification of biomass is the process of turning solid fuels into a combustible gas. The product contains dense carbon monoxide, carbon dioxide, hydrogen, methane, water and nitrogen as well as ash and tar [98].
Biogas is a flammable gas obtained as a result of processing biomass. Unlike other flammable gases (e.g., natural gas), biogas is obtained only from animal or vegetable, i.e., organic raw materials. Biological wastes, organic wastes originating from the food industry, energy plants such as corn or sugar beet and animal feces in animal husbandry can be used as a substrate in biogas [99].
Various types and groups of microorganisms are involved in the conversion of complex organic compounds into biogas in oxygenated biogas production processes. The decomposition of these complex organics in an oxygen-free environment takes place in four stages: hydrolysis, acid production, acetic acid production and biogas as a result of methane production. In Figure 1.4, the decomposition process is schematized.
As a result of anaerobic decomposition, 50-80% CH4 (methane) and 20-50% CO2 (carbon dioxide) and a mixture of gases containing very small amounts of hydrogen, carbon monoxide, nitrogen, oxygen and hydrogen sulfide are formed. This biologically produced gas is defined as biogas. The gas composition depends on the raw materials used and environmental conditions. The thermal value of biogas (natural gas) containing 99% CH4 is 37.3 MJ/m3, and the thermal value of biogas containing 65% CH4 is 24.0 MJ/m3 [99, 100].
Anaerobic degradation is the conversion of biomass into other products and by-products by microorganisms in an oxygen-free environment. Anaerobic processes have been used for years to produce energy from biomass in both developed and developing countries. The energy obtained by burning agricultural and animal wastes in developing countries is used as a source of warming and conventional energy. In developed countries, these wastes are fermented in central biogas production facilities and significant amounts of energy are produced and used from methane gas [101].
The main processes of processing biomass as biogas can be described independently of the composition of the substrates used as follows: Using bacteria and other microorganisms, biomass is decomposed in a biogas facility. As the final products of this multi-stage fermentation process, methane (45-70%) and carbon dioxide (25-55%) are formed, especially in a humid environment free from air and light [102].
Figure 1.4 The decomposition process of biogas [99].
The availability of biogas as energy depends primarily on the ratio of methane in biogas. The produced biogas is generally converted into electrical energy, which can be used locally or delivered to the electricity grid in combined heat and power station (cogeneration). It is also possible to use the heat generated during the combustion phase to heat the buildings or greenhouses near the facility, dry the straw, cool the milk or climate the barns [103].
Biogas is predominantly methane and carbon dioxide gas formed as a result of biodegradation (anaerobic fermentation) of organic substances in oxygen-free conditions. Conversion of various organic materials to methane and carbon dioxide is carried out by mixed microbiological flora. As a result of this oxygen-free degradation, methane gas is formed by a threestep process. Oxygen-free degradation (anaerobic fermentation) basically has three stages; fermentation and hydrolysis, the formation of acetic acid and finally the formation of methane gas [104].
In the first stage, high molecular weight solid and dissolved organic materials (cellulose, starch, hemicellulose, fat, protein, etc.) are hydrolyzed with the extracellular enzymes of the bacteria and converted into lower molecular weight organic substances. The second phase of acid production is converted into volatile fatty acids and then to acetic acid by the acid bacteria of low molecular weight organic substances. In the final stage, CH4 methane is produced by breaking down the acetic acid produced during the acid production phase or by synthesizing CO2 and H2 [105].
Syngas, also known as synthetic gas or synthesis gas, can be produced from carbon-containing biomass (wood gas), plastics, coal and urban waste or similar materials. Synthesis gas is created by gasification or pyrolysis of carbon-containing materials. Gasification includes materials subjected to high temperatures to maintain the reaction by providing thermal energy with limited combustion in the control of oxygen. Gasification operation can be performed in a gasifier reactor or alternatively it can be carried out in places where there are underground coal mines. If the raw material that turns into gas is a recently obtained biological resource such as wood or organic waste, the gas produced by the gas converter is considered to be renewable fuel [106].
Synthesis gas has half the energy content of natural gas. It cannot be burned directly but can be used as a fuel source. Another usage area of syngas is hot steam or electricity
