Biodiesel production is the process of producing the biofuel, biodiesel, through the chemical reactions of transesterification and esterification.[1] This process renders a product (chemistry) and by-products.

The fats and oils react with short-chain alcohols (typically methanol or ethanol). The alcohols used should be of low molecular weight. Ethanol is the most used because of its low cost, however, greater conversions into biodiesel can be reached using methanol. Although the transesterification reaction can be catalyzed by either acids or bases, the base-catalyzed reaction is more common. This path has lower reaction times and catalyst cost than those acid catalysis. However, alkaline catalysis has the disadvantage of high sensitivity to both water and free fatty acids present in the oils.[2]

Biorefinery process steps

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The major steps required to synthesize biodiesel are as follows:

Feedstock pretreatment

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Common feedstock used in biodiesel production include:

Lignocellulose generates byproducts that act as enzyme inhibitors, such as acetic acid, furfural, formic acid, vanillin, and these chemical inhibitors affect cell growth.[4]

Recycled oil is processed to remove impurities from cooking, storage, and handling, such as dirt, charred food, and water. Virgin oils are refined, but not to a food-grade level. Degumming to remove phospholipids and other plant matter is common, though refinement processes vary.[better source needed][5] Water is removed because its presence during base-catalyzed transesterification results in the saponification (hydrolysis) of the triglycerides, producing soap instead of biodiesel.[citation needed]

A sample of the cleaned feedstock is then tested via titration against a standardized base solution, to determine the concentration of free fatty acids present in the vegetable oil sample.[citation needed] The acids are then either removed (typically through neutralization), or are esterified to produce biodiesel[citation needed] (or glycerides[citation needed]).

Reactions

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Base-catalyzed transesterification reacts lipids (fats and oils) with alcohol (typically methanol or ethanol) to produce biodiesel and an impure coproduct, glycerol.[6] If the feedstock oil is used or has a high acid content, acid-catalyzed esterification can be used to react fatty acids with alcohol to produce biodiesel. Other methods, such as fixed-bed reactors,[7] supercritical reactors, and ultrasonic reactors, forgo or decrease the use of chemical reaction that reduces the quality of substance in chemistry.

Product purification

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Products of the reaction include not only biodiesel, but also the byproducts soap, glycerol, excess alcohol, and trace amounts of water. All of these byproducts must be removed to meet the standards, but the order of removal is process-dependent.

The density of glycerol is greater than that of biodiesel, and this property difference is exploited to separate the bulk of the glycerol coproduct. Residual methanol is typically recovered by distillation and reused. Soaps can be removed or converted into acids. Residual water is also removed from the fuel.

Reactions

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Base-catalysed transesterification mechanism

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The transesterification reaction is base catalyzed. Any strong base capable of deprotonating the alcohol will work (e.g. NaOH, KOH, sodium methoxide, etc.), but the sodium and potassium hydroxides are often chosen for their cost. The presence of water causes undesirable base hydrolysis, so the reaction must be kept dry.

In the transesterification mechanism, the carbonyl carbon of the starting ester (RCOOR1) undergoes nucleophilic attack by the incoming alkoxide (R2O) to give a tetrahedral intermediate, which either reverts to the starting material, or proceeds to the transesterified product (RCOOR2). The various species exist in equilibrium, and the product distribution depends on the relative energies of the reactant and product.

 

Production methods

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Supercritical process

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An alternative, catalyst-free method for transesterification uses supercritical methanol at high temperatures and pressures in a continuous process. In the supercritical state, the oil and methanol are in a single phase, and reaction occurs spontaneously and rapidly.[8] The process can tolerate water in the feedstock, free fatty acids are converted to methyl esters instead of soap, so a wide variety of feedstocks can be used. Also the catalyst removal step is eliminated.[9] High temperatures and pressures are required, but energy costs of production are similar or less than catalytic production routes.[10]

Ultra- and high-shear in-line and batch reactors

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Ultra- and High Shear in-line or batch reactors allow production of biodiesel continuously, semi- continuously, and in batch-mode. This drastically reduces production time and increases production volume.[citation needed]

The reaction takes place in the high-energetic shear zone of the Ultra- and High Shear mixer by reducing the droplet size of the immiscible liquids such as oil or fats and methanol. Therefore, the smaller the droplet size the larger the surface area the faster the catalyst can react.[citation needed]

Ultrasonic reactor method

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In the ultrasonic reactor method, the ultrasonic waves cause the reaction mixture to produce and collapse bubbles constantly; this cavitation simultaneously provides the mixing and heating required to carry out the transesterification process.[citation needed] Use of an ultrasonic reactor for biodiesel production can drastically reduce reaction time and temperatures, and energy input.[citation needed] Using such reactors, the process of transesterification can run inline rather than using the time-consuming batch processing.[citation needed] Industrial scale ultrasonic devices allow for processing of several thousand barrels per day.[clarification needed][citation needed]

Lipase-catalyzed method

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Large amounts of research have focused recently on the use of enzymes as a catalyst for the transesterification. Researchers have found that very good yields could be obtained from crude and used oils using lipases. The use of lipases makes the reaction less sensitive to high free fatty-acid content, which is a problem with the standard biodiesel process. One problem with the lipase reaction is that methanol cannot be used because it inactivates the lipase catalyst after one batch. However, if methyl acetate is used instead of methanol, the lipase is not in-activated and can be used for several batches, making the lipase system much more cost-effective.[11]

Volatile fatty acids from anaerobic digestion of waste streams

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Lipids have been drawing considerable attention as a substrate for biodiesel production owing to its sustainability, non-toxicity and energy efficient properties. However, due to cost reasons, attention must be focused on the non-edible sources of lipids, in particular oleaginous microorganisms. Such microbes have the ability to assimilate the carbon sources from a medium and convert the carbon into lipid storage materials. The lipids accumulated by these oleaginous cells can then be transesterified to form biodiesel.[12]

See also

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References

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  1. ^ Leung, Dennis Y.C.; Wu, Xuan; Leung, M.K.H. (April 2010). "A review on biodiesel production using catalyzed transesterification". Applied Energy. 87 (4): 1083–1095. Bibcode:2010ApEn...87.1083L. doi:10.1016/j.apenergy.2009.10.006.
  2. ^ Anastopoulos, George; Zannikou, Ypatia; Stournas, Stamoulis; Kalligeros, Stamatis (2009). "Transesterification of Vegetable Oils with Ethanol and Characterization of the Key Fuel Properties of Ethyl Esters". Energies. 2 (5 June 2009): 362–376. doi:10.3390/en20200362.
  3. ^ a b c d e f g h Boonyarit, Jeerapan; Polburee, Pirapan; Khaenda, Bongkot; Zhao, Zongbao; Limtong, Savitree (23 March 2020). "Lipid Production from Sugarcane Top Hydrolysate and Crude Glycerol with Rhodosporidiobolus fluvialis Using a Two-Stage Batch-Cultivation Strategy with Separate Optimization of Each Stage". Microorganisms. 8 (3): 453. doi:10.3390/microorganisms8030453. PMC 7143989. PMID 32210119. Biodiesel can be divided into three generations based on the feedstock which generates the fuel. First-generation biodiesel is produced from edible plant oils, such as palm oil, soybean oil, and coconut oil, and second-generation biodiesel is produced from nonedible plant oils, such as jatropha, animal fats and waste oils [...] The most recent generation of biodiesel is derived from microbial lipids. Using recovered animal fats and frying oils of the second generation as feedstock for biodiesel can efficiently reduce the price of the fuel; however, the amount of these fats and oils is limited on an industrial scale and cannot meet the increasing needs of biodiesel production
  4. ^ Boonyarit, Jeerapan; Polburee, Pirapan; Khaenda, Bongkot; Zhao, Zongbao; Limtong, Savitree (23 March 2020). "Lipid Production from Sugarcane Top Hydrolysate and Crude Glycerol with Rhodosporidiobolus fluvialis Using a Two-Stage Batch-Cultivation Strategy with Separate Optimization of Each Stage". Microorganisms. 8 (3): 453. doi:10.3390/microorganisms8030453. PMC 7143989. PMID 32210119. [P]retreatment and hydrolysis of lignocellulosic biomasses usually produce inhibitory compounds, such as acetic acid, furfural, and 5-hydroxymethylfurfural, formic acid, and vanillin, which could have negative effects on growth, metabolism, and product formation of microorganisms
  5. ^ Bryan, Tom (July 1, 2005). "Pure and Simple". Biodiesel Magazine (online). Retrieved December 18, 2019. Volga, S.D.-based South Dakota Soybean Processors is now offering SoyPure, a trademarked pretreated virgin soybean oil tailored for biodiesel production. Meanwhile, a large customer is about to come on line in neighboring Minnesota.
  6. ^ Boonyarit, Jeerapan; Polburee, Pirapan; Khaenda, Bongkot; Zhao, Zongbao; Limtong, Savitree (23 March 2020). "Lipid Production from Sugarcane Top Hydrolysate and Crude Glycerol with Rhodosporidiobolus fluvialis Using a Two-Stage Batch-Cultivation Strategy with Separate Optimization of Each Stage". Microorganisms. 8 (3): 453. doi:10.3390/microorganisms8030453. PMC 7143989. PMID 32210119. Crude glycerol (CG), a byproduct from biodiesel production plants which has been shown to have some inhibitory compounds to microorganism growth, is currently being explored as a possible large-scale carbon source in lipid production by many researchers. [...] The shaking speed supplies the oxygen required for yeast growth in the culture broth, and, as a result, different speeds resulted in different levels of oxygen dissolution. [...] shaking speed was found to be the factor with the highest influence on cell mass and lipid concentration
  7. ^ C Pirola, F Manenti, F Galli, CL Bianchi, DC Boffito, M Corbetta (2014). "Heterogeneously catalyzed free fatty acid esterification in (monophasic liquid)/solid packed bed reactors (PBR)". Chemical Engineering Transaction 37: 553-558. AIDIC
  8. ^ Bunkyakiat, Kunchana; et al. (2006). "Continuous Production of Biodiesel via Transesterification from Vegetable Oils in Supercritical Methanol". Energy and Fuels. 20 (2). American Chemical Society: 812–817. doi:10.1021/ef050329b.
  9. ^ Vera, C.R.; S.A. D'Ippolito; C.L. Pieck; J.M.Parera (2005-08-14). "Production of biodiesel by a two-step supercritical reaction process with adsorption refining" (PDF). 2nd Mercosur Congress on Chemical Engineering, 4th Mercosur Congress on Process Systems Engineering. Rio de Janeiro. Archived from the original (PDF) on 2009-02-05. Retrieved 2007-12-20.
  10. ^ Kusdiana, Dadan; Saka, Shiro. "Biodiesel fuel for diesel fuel substitute prepared by a catalyst free supercritical methanol" (PDF). Archived from the original (PDF) on 2013-10-19. Retrieved 2007-12-20.
  11. ^ Du, Wei; et al. (2004). "Comparative study on lipase-catalyzed transformation of soybean oil for biodiesel production with different acyl acceptors". Journal of Molecular Catalysis B: Enzymatic. 30 (3–4): 125–129. doi:10.1016/j.molcatb.2004.04.004.
  12. ^ Singh, Gunjan; Jeyaseelan, Christine; Bandyopadhyay, K. K.; Paul, Debarati (October 2018). "Comparative analysis of biodiesel produced by acidic transesterification of lipid extracted from oleaginous yeast Rhodosporidium toruloides". 3 Biotech. 8 (10): 434. doi:10.1007/s13205-018-1467-9. ISSN 2190-572X. PMC 6170317. PMID 30306003.

Further reading

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