Biodiesel feedstocks differ from pe

Biodiesel feedstocks differ from petro-diesel in that they are
highly viscous and thus not suitable for direct use in modern diesel
engines and thus require conversion to meet regulatory standards.
The technology for conversion of vegetable oils, animal fats and
microalgal oil are primarily (1) direct use, (2) blending with petro-
diesel, (3) micro-emulsions with solvents or alcohols, (4) pyrolysis,
and (5) transesterification [37].
Converting biological lipid into biodiesel using transesterification
is most commonly used feasible methods for many years. This
was done in South Africa and other countries using converted vegetable
oil (biodiesel) to power heavy vehicles before World War II
[38] and has been received considerable attention in the past few
decades. However the well established chemical catalysed transesterification
(alcoholysis) process of biofuel production technology
does have its demerits. Overall the process is highly energy intensive
thus increasing in terms of production cost, the catalyst needs
to be removed from the production by purification or separation
steps, alkaline water from washing may cause difficulties such as
saponification, water and free fatty acids result in loss of conversion
yield product due to saponification because the operation stability
is very sensitive and glycerol is technically difficult to remove
in downstream recovery and may require easier process steps to
simplify product recovery [2,39]. Biocatalysed/Enzymatic catalysed
esterification is a viable process and effective method for catalysing
parent oils containing high levels of free fatty acids as they
can be converted to alkyl esters without presence of organic solvents.
Other benefits include utilisation of moderate reaction conditions
thus decrease energy consumption. More desirable enzyme
activities involves improved alcohol to oil ratio requirements for
production and makes product recovery much easier [28,39]. However,
for large scale continuous higher volume biodiesel production,
this may have challenges which need to be addresses to
make it economically viable. This is not an ideal energy balance situation
as the reaction proceeds using competitive high enzyme
production rates, and does not run the reaction to completeness
[15,39]. High-tech thermal conversion processes, maximize energy
conversion of biomass into superior biofuels, has come to the vanguard
as a promising neutral carbon energy processes for reshaping
liquid fuels production. This contributes dramatically tobiofuels production as an essential alternative sustainable, renewable,
environmentally friendly process, that is no threat to food
security and has economic potential due to diminishing levels of
fossil fuels [23,28]. Much data has been generated at laboratory
scale as an academic exercise but not much has been published
in way of technology transfer to large scale.