Biofuels and Their Production Through Different Catalytic Routes

Biswas, Shelly

doi:10.15255/cabeq.2016.897

Cited by 14 publications

(5 citation statements)

References 68 publications

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“…Vegetable oils are suitable substrates for hydrocarbon biofuel production as they have, similar to petroleum derivatives, high energy density and a simple chemical composition [ 16 ]. Vegetable oils can be directly used in diesel engines, but high viscosity and low volatility may cause engine problems [ 17 , 18 ]. On the other hand, the appropriate treatment of vegetable oils allows the production of hydrocarbon biofuels that are fully compatible with fossil fuel derivatives.…”

Section: Introductionmentioning

confidence: 99%

Green Diesel Production by Catalytic Hydrodeoxygenation of Vegetables Oils

Nolfi

Gallucci

Rossi

2021

IJERPH

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Non-renewable fossil fuels and the air pollution associated with their combustion have made it necessary to develop fuels that are environmentally friendly and produced from renewable sources. In addition, global warming and climate change have brought to the attention of many countries the need to develop programs and reforms, such as the 2030 Agenda of the United Nations and the European Green Deal, that finance and promote the conversion of all socio-economic activities in favor of sustainable and environmentally friendly development. These major projects include the development of non-polluting biofuels derived from renewable sources. Vegetable oils are a renewable source widely used to produce biofuels due to their high energy density and similar chemical composition to petroleum derivatives, making them the perfect feedstock for biofuel production. Green diesel and other hydrocarbon biofuels, obtained by the catalytic deoxygenation of vegetable oils, represent a sustainable alternative to mineral diesel, as they have physico-chemical properties similar to derived oil fuels. The catalyst, temperature, hydrogen pressure, and the type of vegetable oil can influence the type of biofuel obtained and its properties. The main aspects discussed in this review include the influence of the catalyst and reaction conditions on the catalytic deoxygenation reaction.

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Section: Introductionmentioning

confidence: 99%

Green Diesel Production by Catalytic Hydrodeoxygenation of Vegetables Oils

Nolfi

Gallucci

Rossi

2021

IJERPH

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“…It is not adequate for biodiesel to meet entire needs and necessities; it should likewise battle fnancially with fossil diesel at largescale creation [12]. According to the previous studies [17][18][19], the main factors infuencing biodiesel yield after transesterifcation are reaction temperature, alcohol to oil molar ratio, time of reaction, mixing intensity, and amount of catalyst loaded. Hence, in the present study, the production of biodiesel through the reaction of the C. M. seed oil with ethanol within the sight of a heterogeneous catalyst, CaO is investigated, and optimum biodiesel conversion is analyzed at the ideal mix of process variables such as ethanol to oil proportion, amount of catalyst loaded, time of reaction, and reaction temperature.…”

Section: Te Croton Macrostachyus Hochst Ex Delile Descriptionmentioning

confidence: 99%

Amalgamation and Optimization of FAEE Biodiesel Fuel from Croton macrostachyus hochst. ex Delile Seed oil Utilizing Solid Calcium Oxide-Chicken Eggshell Squander as a Heterogeneous Catalyst

Solomon

Aklilu

Ancha

2022

International Journal of Analytical Chemistry

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Identification of better yielding nonedible feedstocks and process improvements with locally prepared chemicals is the way forward for improving biodiesel economic viability. Synthesis of fatty acid ethyl ester (FAEE) biodiesel from Croton macrostachyus hochst. ex delile (C. M.) seed oil is investigated through the transesterification method including oil extraction and CaO-chicken eggshell waste as a heterogeneous catalyst and ethanol, which has not yet been investigated earlier. The effects of catalyst load from 2% to 6% (w/w) of the weight of oil, ethanol to oil ratio from 9 : 1 to 12 : 1(v/v), reaction temperature from 60 to 80 ℃ , and reaction time variation from 0.45 to 2 hr have been explored. The yield has been investigated, with the oil content of the C. M. seed being 46.85% realized through the solvent extraction route. The central composite design (CCD) using a design expert is employed to investigate the effects of different process parameters for biodiesel synthesis and to find the optimum conditions for maximizing the yield. The conversion to biodiesel via the calcium oxide-heterogeneous catalyzed transesterification route has achieved 91% yield under the optimum conditions. The optimum result predicted by the model is found to be 91.036% at a catalyst loading of 5.802 wt.%, reaction temperature of 76.117 ℃ , a reaction time of 1.969 hr, and ethanol to oil molar ratio of 11.55 with a desirability value of 1.000. The FTIR spectrum confirms the composition and functional groups of synthesized biodiesel under optimum reaction conditions. Physicochemical properties of synthesized C. M. biodiesel are determined, and the results when compared with the biodiesel standard specifications are within the range prescribed. The result showed that C. M. could be a very viable feedstock for the biodiesel industry, which could be exploited as an alternative fuel source.

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“…Vegetable oils are suitable substrates for hydrocarbon biofuel production as they are similar to petroleum derivatives, high energy density and a simple chemical composition (Zhao et al, 2017). Vegetable oils can be directly used in diesel engines, but high viscosity and low volatility may cause engine problems (Biswas et al, 2017;Lestari et al, 2009). On the other hand, the appropriate treatment of vegetable oils allows the production of hydrocarbon biofuels that are fully compatible with fossil fuel derivatives.…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, the appropriate treatment of vegetable oils allows the production of hydrocarbon biofuels that are fully compatible with fossil fuel derivatives. Biodiesel, produced by transesterification of vegetable oils, and green diesel (or renewable diesel), obtained by the catalytic deoxygenation of vegetable oils, are alternative fuels to mineral diesel due to their favorable eco-friendliness as compared to the conventional fuels generally (Biswas et al, 2017). Catalytic cracking, involves adding catalysts along with moderate temperature and pressures, the temperature ranges between 475 to 530 0 C, pressure 20 (atm) and it is used to obtain biofuel with octane number 65-70 as compared to thermal cracking process (pyrolysis), where it operates usually at very high temperatures and pressure, the temperature ranges between 500-700 0 C, pressure 70 (atm), used for vis-breaking and delayed coking processes (Madhusha, 2017).…”

Section: Introductionmentioning

confidence: 99%

Catalytic conversion of castor seed oil to diesel range hydrocarbons using NiO –CuO catalyst supported on ZSM-5

Abubakar,

Sokoto,

Muhammad

et al. 2024

CaJoST

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Bio-oils are an alternative fuel that can be produced from organic resources such as vegetable oils in which castor seed oil is an example. In this research work castor seed oil was converted to diesel range hydrocarbons using NiO-CuO/ZSM-5 as catalyst. The catalyst was synthesized using wet impregnation method which was characterized using Fourier Transform Infrared (FT-IR) and Energy Dispersive X-ray Fluorescence (EDXRF). The castor seed oil was extracted by using hot water stirring method. The extracted raw oil and catalytically cracked bio-oil were also characterized by FT-IR. The optimum yield of bio-oil 80.70 % was attained at the temperature of 300 0C, reaction time 60 mins and catalyst loading of 2 wt% respectively. The Bio-oil was also characterized using GC-MS to determine the molecular compositions of the raw, thermally and catalytically cracked bio-oil. However, this makes castor seed oil a good feedstock for bio-oil production with little modifications on its properties. This indicates that the products can be used as an alternative fuel in diesel engines.

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Biofuels and Their Production Through Different Catalytic Routes

Cited by 14 publications

References 68 publications

Green Diesel Production by Catalytic Hydrodeoxygenation of Vegetables Oils

Green Diesel Production by Catalytic Hydrodeoxygenation of Vegetables Oils

Amalgamation and Optimization of FAEE Biodiesel Fuel from Croton macrostachyus hochst. ex Delile Seed oil Utilizing Solid Calcium Oxide-Chicken Eggshell Squander as a Heterogeneous Catalyst

Catalytic conversion of castor seed oil to diesel range hydrocarbons using NiO –CuO catalyst supported on ZSM-5

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