Optimal Synthesis of Sal (<i>Shorea robusta</i>) Oil Biodiesel Using Recycled Bentonite Nanoclay at High Temperature

Sultana, Nazmun; Hajra, Bhaskar; Saxena, V. K.; Guria, Chandan

doi:10.1021/acs.energyfuels.5b02227

Cited by 13 publications

(2 citation statements)

References 39 publications

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“…The pre-filtered air was obtained by passing the compressed air through a sterile type 0.2 mm poly tetrafluoro ethylene membrane-based capsule filter (Whatman™ SteriVENT). A high pressure and high temperature (HPHT) autoclave (capacity, 0.5 l; Material of construction, SS-316) with automatic temperature control were used to carry out oxidation at elevated pressure and temperature [29]. As oxidation proceeds, autoclave pressure falls and the pressure in the autoclave was maintained constant by passing air continuously using an auto-controlled solenoid valve.…”

Section: Methodsmentioning

confidence: 99%

Liquid Phase Selective Catalytic Oxidation of Oleic Acid to Azelaic Acid Using Air and Transition Metal Acetate Bromide Complex

Hajra

Sultana

Guria

et al. 2017

J Americ Oil Chem Soc

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Industrially important di‐carboxylic acids are synthesized from mono‐carboxylic unsaturated and unsaturated fatty acids. In this study, the aim is to perform the simultaneous catalytic oxidative C=C cleavage of oleic acid (OA) to azelaic acid and pelargonic acid, and oxidation of the terminal methyl group in pelargonic acid to azelaic acid using cobalt‐ and manganese‐acetate as catalyst, hydrogen bromide as co‐catalyst and air in acetic acid at elevated pressure (2.8–5.8 barg) and temperature (353–383 K). Oxygen solubility is determined under varying pressure, temperature and OA loading. The effect of OA loading, pressure and temperature on OA conversion and azelaic acid selectivity is studied by varying one variable at a time; however, the presence of the synergistic effect of the catalyst and co‐catalyst is investigated by central composite design assisted response surface methodology. Oxidation of terminal methyl group in saturated fatty acid is also confirmed by the oxidation of stearic acid to octadecanedioic acid using identical oxidation conditions of OA. Oxidation products of fatty acids are quantified by gas chromatographic analysis. The innovation of the work is thus the ability of the catalytic system to perform a total oxidation of a terminal methyl group of the hydrocarbon chain. OA oxidation kinetics relating to catalyst and co‐catalyst concentration along with oxygen solubility at elevated temperature and pressure is established. The frequency factor and activation energy for OA oxidation is determined using the Arrhenius equation.

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Section: Methodsmentioning

confidence: 99%

Liquid Phase Selective Catalytic Oxidation of Oleic Acid to Azelaic Acid Using Air and Transition Metal Acetate Bromide Complex

Hajra

Sultana

Guria

et al. 2017

J Americ Oil Chem Soc

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“…Reaction mass was heated to 200°C at atmospheric pressure. The paper also discussed various feed conditions for SOME production but do not state one single most favorable condition . In another approach to produce SOME, the alkali‐based transesterification was performed using 0.5% ( w /w) KOH as catalyst, 65°C reaction temperature, and 90‐min reaction time with constant stirring at 450 rpm, followed by washing .…”

Section: Production/process Techniquesmentioning

confidence: 99%