Details of Biodiesel from Non-Edible Plants and Biodiesel Production
Received: 04-Jun-2022 / Manuscript No. bsh-22-68266 / Editor assigned: 06-Jun-2022 / PreQC No. bsh-22-68266 (PQ) / Reviewed: 20-Jun-2022 / QC No. bsh-22- 68266 / Revised: 23-Jun-2022 / Manuscript No. bsh-22-68266 (R) / Published Date: 30-Jun-2022 DOI: 10.4172/bsh.1000118
Abstract
Biodiesel from non-edible plants will contend economically with fossil oil diesel fuels as a future prospective fuel. The bio-oil was extracted from the non-edible seed kitul by soxhlet extraction victimisation resolvent as associate degree organic solvent then additional, the oil was analyzed for wet content, pH, relative density, density, viscosity, chemical reaction price, ratio, peroxide price, acid variety, free carboxylic acid and iodine price. The results showed that the bio-oil content was twenty one.57% and characterised by GC-MS that showed hexadecanoic acid and monounsaturated fatty acid as dominant fatty acids. The bio-oil extracted from the plant seeds was reborn into biodiesel victimisation KOH catalyst and therefore the biodiesel yield was calculated as eighty two.
Keywords: Bio-diesel; Base catalyst; Kitul linn; Chemistry analysis
Keywords
Bio-diesel; Base catalyst; Kitul linn; Chemistry analysis
Introduction
Recently, World energy demand is predicted to extend thanks to the increasing urbanization, higher living standards and increasing population [1]. At a time once society is changing into more and more awake to the declining reserves of fossil fuels beside the environmental issues, it’s become apparent that bio-diesel is destined to create a considerable contribution to the long run energy demands of the domestic and industrial economies. Biodiesel could be a substance of alkyl organic compound derived from raw or used vegetable oils and animal fats and it’s thought-about as “carbon oxide neutral” as a result of the entire dioxide discharged throughout combustion is sequestered out of the atmosphere throughout crop growth. Biodiesel could be a product of nice interest for its environmental characteristics. It perishable, non-toxic, and renewable and doesn’t harm water quality. It the benefits of dramatically reduced sulphate and organic compound emissions and reduces stuff. As a future prospective fuel [2], biodiesel should contend economically with fossil oil diesel fuels and victimisation more cost-effective feedstock containing fatty acids like indigestible oils, animal fats, waste food oil and by-products of the refinement vegetables oils is a way of reducing the biodiesel production prices. 2 forms of renewable energy ar promising like alcohol made because the product of fermentation victimisation microorganism sources and biodiesel from plant oils. Plant derived seed oil play an important role within the production of bio-diesel. Non-edible vegetable oils that are called the second-generation feed stocks will be thought-about as promising substitutions for ancient edible food crops for the assembly of biodiesel. The utilization of non-edible plant oils is extremely vital thanks to the tremendous demand for edible oils as food supply. Moreover, edible oils’ feedstock prices are so much pricy to be used as fuel [3]. Therefore, production of biodiesel from nonedible oils is efficient thanks to overcome all the associated issues with edible oils.
Caryota urens belongs to the family Palmae. It consists of Twentyseven species and cosmopolitan throughout the Asian Countries. Genus Caryota species are used for the treatment of rheumatic swellings and snake bite. The bark and seeds were accustomed treat boils and therefore the root is employed for tooth ailments. Palm sap collected from the inflorescence is hard with mixed inoculant of yeast to get mixed drink. However, no reports are given regarding C. urens crude as potential feedstock for biodiesel (Table 1).
S. No | Physical properties | Caryota urens |
---|---|---|
1 | Colour | Light Brown |
2 | Odour | Agreeably Oily |
3 | Moisture (%) | 3.52 |
4 | Oil Content (%) | 21.57 |
5 | Specific Gravity | 0.86 |
6 | Physical State at RT | Liquid |
7 | Density (g/cm3) | 0.93 |
8 | Viscosity, at 40ºC, centistokes | 3.5 |
Table 1: Physical properties of Caryota urens seed oil.
The gift is principally centered on the chemistry analysis and input of carboxylic acid present within the seeds of kitul. The physical and chemical properties of the bio-oil were analyzed [4]. Biodiesel was made from the oil of kitul victimisation basic catalyst and therefore the made biodiesel was characterised by GC-MS.
Materials and ways
Assortment of stuff and extraction of bio-oil from the seeds of kitul
Fresh kitul plant seeds were collected from VIT University, Tamil Nadu, and India. The plant seeds were washed with water and kernels were separated from seeds. The seeds were dried within the Hot-Air kitchen appliance for regarding three hours [5]. Once drying, kernels were separated from seeds. The separated kernels were finely grounded. The bio-oil was extracted victimisation Soxhlet extractor. The crude bio-oil is extracted with 200mL of resolvent as a solvent for regarding seventy two hours at 80ºC. Then the extract was targeted victimisation rotary evaporator at 50ºC. Extracts were keep at 20ºC till additional use.
Characterization of genus caryota seed oil
The percentage (%) yield of the seed oil was calculated gravimetrically.
Odour, colour, and physical state of the oil were calculable by sensory analysis [6]. They were characterised for relative density victimisation relative density bottle, hydrogen ion concentration make up my mind victimisation hydrogen ion concentration meter, wet content by the kitchen appliance dry technique, ash content by heating to status in chamber, kinematic consistency employing a measuring instrument, ratio victimisation archimandrite measuring device. Alternative properties analyzed were the chemical reaction values determined by titrimetry technique. Acid value, iodine price, and peroxide price were determined by titrimetry in step with Food and Agriculture Organization.
Gas action: An Agilent 6890 gas chromatograph was equipped with a straight deactivated a pair of millimetre direct widget liner and a 15m Alltech EC-5 column (250 μ I.D., 0.25μ film thickness). A split injection was used for sample introduction and therefore the split magnitude relation was set to 10:1 [7]. The kitchen appliance temperature program was programmed to start out at 35ºC, hold for two minutes, then ramp at 20ºC per minute to 300ºC and hold for five minutes (Table 2). The {helium |He| atomic number a pair of |chemical element| element| noble gas| inert gas| argonon} carrier gas was set to 2 ml/minute rate (constant flow mode).
S. No | Chemical properties | Caryota urens |
---|---|---|
1 | pH | 7.27 |
2 | Iodine value (g/100g) | 121.02 |
3 | Acid value (mgKOH/g) | 5.2 |
4 | Saponification value (mgKOH/g) | 107.18 |
5 | Peroxide value (meq/kg) | 7.89 |
6 | Refractive index | 0.72 |
Table 2: Chemical properties of Caryota urens seed oil.
Mass qualitative analysis: A JEOL GCmate II bench high doublefocusing magnetic sector spectroscope operational in lepton ionization (EI) mode with TSS-20001 package was used for all analyses [8-10]. Low-resolution mass spectra were non heritable at a physical phenomenon of a thousand (20% height definition) and scanning from m/z twenty five to m/z 700 at zero.3 seconds per scan with a zero.2 second inter-scan delay. High resolution mass spectra were non heritable at a physical phenomenon of 5000 (20% height definition) and scanning the magnet from m/z sixty five to m/z 750 at one second per scan. Qualitative associate degree alyses were performed on an hour, high resolution spectroscope Samples were introduced into the lepton ionisation supply employing a drawn small capillary at a rate of one ml/min [11]. The spectroscope was operated in positive particle mode with a sprig voltage of two.4 kV, a capillary temperature of 250, a capillary voltage of twenty nine.0 V, a 1.5-u particle isolation window, and a 100-ms most inject time. The common Scans of the MS spectra just about a hundred scans were averaged for the MS2 and MS3 spectra.
Mass qualitative analysis library search: Identification of the elements of the refined compound was matching their recorded spectra with the info bank mass spectra of National Institute of Standards and Technology library V eleven provided by the instruments package. Supported the GC-MS spectral knowledge, six fatty acids were known and additional the bio-oil are reborn into biodiesel victimisation transesterification method [12]. The Bio-oil from kitul was reborn into biodiesel victimisation NaOH catalyst. The made biodiesel yield was calculated gravimetrically.
Results and Discussion
The bio-oil content of kitul was calculated and was found to be twenty one.57%. This oil may be used for biodiesel production that might be extremely economical. The oils had pleasantly oily odour and really dark in color, which could fade throughout Tran’s esterification. Physical state of the oil was liquid at temperature. Relative density of the oil was zero [13, 14].86, that is near to the quality vary of zero.87- 0.90 for biodiesel. Density and alternative gravities ar vital parameters for fuel injection systems. The values should be maintained among tolerable limits to permit best air to fuel ratios for complete combustion. Wet content of the oil was in limit to the ASTM customary. The results of the physical properties ar tabulated in (Table 3).
Fatty acid | Percentage composition (%) |
---|---|
Stearic Acid | 15.7 |
Palmitic Acid | 41.24 |
Myristic Acid | 8.01 |
Lauric Acid | 0.24 |
Oleic Acid | 28.48 |
Linoleic acid | 0.63 |
Caprylic acid | 4.31 |
Table 3: Fatty acid profile of Caryota urens seed oil.
The results of the chemical properties ar tabulated in [15]. The hydrogen ion concentration price of the oil was neutral. Iodine price could be a live of the unsaturation of fats and oils. High iodine price of the indicated high unsaturated oil content, therefore creating it to exist in liquid state. The iodine price of bio-oil was among the bounds of normal. Chemical reaction price is employed in checking adulteration that was found to be lesser than the ASTM customary [16, 17]. The ratio of oils all depends on their mass, carboxylic acid chain length, degree of unsaturation, and degree of conjugation. Triglycerides have higher refractive indices than do their constituent free acids. Values of ratio for various oils usually vary between one.447 and 1.482. Of these chemistry properties recommend that the seed oil adoptable for biodiesel production.
Fatty acid composition of kitul seed analyzed by GC-MS was shown in represents the GC-MS spectra of dominant fatty acids gift within the bio-oil. Carboxylic acid profile shows that the kitul seed oil has dominating fatty acids that simply gets reborn into their individual alkyl esters throughout Tran’s esterification [18]. It had been found that hexadecanoic acid and monounsaturated fatty acid concentration were high of regarding forty one.24% and 28.48% severally. It had been clear that almost all of the fatty acids gift were saturated fatty acids which may be reborn into sensible biodiesel. This bio-oil was then subjected for Tran’s esterification reaction for changing it into biodiesel.
Since the definite quantity of the oil was found to five.20, it had been subjected to single stage esterification followed by Tran’s esterification. In esterification, the oil was reacted with alcohol with hr of oil weight taken and 1ml of targeted vitriol [19, 20]. The reaction was applied for 1hour at 60ºC. Post esterification, the oil was Trans esterified by combining alcohol in a very molar magnitude relation of 1:3, with five-hitter of KOH as catalyst. This reaction was applied for two hours below continuous stirring of 350 revolutions per minute at 60ºC. Once the reaction was completed, the mixture was allowed to settle within the separating funnel, wherever the biodiesel was collected at high and alcohol at all-time low. This biodiesel obtained from kitul Linn seed oil, was then washed and subjected for varied testing and applications. Most yield of biodiesel achieved from this bio-oil was found to be eighty two.
Conclusion
The following conclusions were created by biodiesel production; (i) the assembly of biodiesel from the various feed stocks was known from the literature and optimum mixing ratios was conjointly known; (ii) The chemistry properties of bio-oil clearly confirmed that the bio-oil from kitul will be used for biodiesel production; (iii) all seven fatty acids were identified victimisation GC-MS spectral knowledge and these fatty acids were solely chargeable for biodiesel production; ((v) the proportion yield achieved was 82%; (v) Finally, finished the made biodiesel are accustomed check their performance and emission characteristics in engine.
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Citation: Panja S (2022) Details of Biodiesel from Non-Edible Plants and Biodiesel Production. Biopolymers Res 6: 118. DOI: 10.4172/bsh.1000118
Copyright: © 2022 Panja S. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
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