Biolubricant synthesis from waste cooking oil via enzymatic hydrolysis followed by chemical esterification

Chowdhury, Avisha; Mitra, Debasis; Biswas, Dipankar

doi:10.1002/jctb.3874

Cited by 77 publications

(50 citation statements)

References 23 publications

(41 reference statements)

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“…Different catalysts have been used to hydrolyze VOs/fatty esters. Avisha et al discovered a novel synthetic method to produce biolubricants by using the two-step process of Candida rugosa lipase-mediated hydrolysis of waste cooking oil (WCO) to FFAs followed by Amberlyst 15H esterification of them with octanol [95]. The octyl esters thus produced have been used as the desired biolubricant.…”

Section: Hydrolysismentioning

confidence: 99%

Chemically Modifying Vegetable Oils to Prepare Green Lubricants

2017

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Chemically modifying vegetable oils to produce an alternative to petroleum-based materials is one of the most important emerging industrial research areas today because of the adverse effects of petroleum products on the environment and the shortage of petroleum resources. Biolubricants, bioplasticizers, non-isocyanate polyurethanes, biofuel, coating materials, biocomposites, and other value-added chemicals can easily be produced by chemically modifying vegetable oils. This short review discusses using vegetable oils or their derivatives to prepare lubricants that are environmentally safe. Chemically modified vegetable oils are generally used as base fluids to formulate environmentally friendly lubricants. Reports of their application as sustainable additives have attracted special attention recently because of their enhanced multifunctional performances (single additives perform several functions, i.e., viscosity index improver, pour point depressant, antiwear products) and biodegradability compared with commercial additives. Here, we have reviewed the use of chemically modified vegetable oils as base fluids and additives to prepare a cost-effective and environmentally friendly lubricant composition.

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Section: Hydrolysismentioning

confidence: 99%

Chemically Modifying Vegetable Oils to Prepare Green Lubricants

2017

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“…(3) As a matter of fact, friction/lubrication is even more critical today: it is about the sustainability of the earth. (4,5) Good green tribological materials have several important features in common: (1) environmentally friendly (from nature), e.g., natural oils, including soybean oil and coconut oil, and plant cellulose; (6,7) (2) biologically decomposable; (8) (3) widely applicable; (9)(10)(11)(12) (4) easy to prepare; (13,14) and (5) reliable tribological performance. (15)(16)(17) In contrast to traditional petrochemical oil products, the lubrication performance characteristics (friction and wear reduction) of green tribological materials that meet the above requirements are not as good as those of the former.…”

Section: Introductionmentioning

confidence: 99%

Parameter Effect on Tribology Performance of Biopolymer Composite Green Lubricant

2017

Sensors and Materials

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In this paper, the effects of loading capacity and sliding speed on the tribology properties of composite films formed by a high-concentration MoS 2 additive and the biopolymer hydroxypropyl methylcellulose (HPMC) are demonstrated. The main mechanisms that affect the coefficient of friction are the real contact area and the formation of the transfer layer. Reducing the real contact area will decrease the overall coefficient of friction, while the formation of the transfer layer is a dominant factor for high-load and high-sliding-speed conditions, which results in a stable coefficient of friction. The self-lubrication phenomenon occurring after the formation of the transfer layer is mostly responsible for the excellent tribology properties of the MoS 2 /HPMC composite material.

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“…However, most researches related to waste cooking oils are focused on the use of fatty acids from WCO for the production of biodiesel 19,20 . There is few literatures reported chemical modification of WCO to produce bio-lubricants 21,22 .…”

Section: Introductionmentioning

confidence: 99%