It is of note that waste (used) coo

It is of note that waste (used) cooking oil is now becoming a significant component of biodiesel feedstock. Biodiesel consumption
in UK was 895 million litres in 2010–2011 and domestic production was 200 million litres (22%), out of which 50% was produced
from used cooking oil as feedstock. The proportion of biodiesel produced from used cooking oil rose to 89% in 2011 due to the Renewable Transport Fuel Obligation that requires the use of biodiesel
blend in transport vehicles and financial incentives attached to
the use of sustainable biodiesel feedstock [20]. The predominant
source of used cooking oil is the commercial food sector (businesses and industry that use oil for cooking including hotels and
restaurants) that accounted for 150–200 million litres, while a
small proportion (50–75 million litres) was obtained from domestic households. Similarly in 2011, 967 million gallons of biodiesel
was produced in USA from 7.3 billion pounds of vegetable oils
and animal fats, including 471 million pounds of yellow grease
(used cooking oil). Production and yellow grease utilization rose
in 2013 to 1339 million gallons and 977 million pounds respectively[21,22].
Waste oil in general contains high moisture and free fatty acid
contents that render it unsuitable for catalytic transesterification
[23]. Alkali-catalyzed transesterification is the widely used biodiesel technology because it gives high conversion of triglycerides
under mild reaction conditions but it cannot catalyze simultaneous
esterification and transesterification that is needed for the conversion of unrefined feedstock to FAME. For instance, a pseudo-homogeneous base catalyst (boiler ash) showed 0 wt.% water and 1% FFA
tolerance in transesterification of palm olein as reported by Boey
et al.[24]. The presence of moisture and free fatty acids adversely
affects methyl esters yield due to reaction with catalyst and soap
formation that hinders product separation[15,25]