Study of biodiesel production from waste cooking oil by ethyl transesterification and its purification with the use of activated carbons derived from olive pits
Conference Paper
Overview
Overview
abstract
The authors are grateful to the Foundation for Science and Technology (FCT, Portugal) for financial support through national funds
FCT/MCTES (PIDDAC) to CIMO (UIDB/00690/2020 and UIDP/00690/2020) and SusTEC (LA/P/0007/2021).
The world production of biodiesel in 2020 reached approximately 46 million tons, with 10% of the total amount
representing biodiesel from waste cooking oils (WCO) [1]. The cost of conventional biodiesel production is
higher than of diesel from petroleum, since it is carried out mainly from high quality virgin oils. It is estimated
that 70 to 80% of the total cost of biodiesel production is associated with the cost of the raw materials [2]. With
this perspective, biodiesel production from WCO has become an economic opportunity to help address global
renewable energy challenges [3]. The wet washing method, which uses water to purify the esters, is the most
commonly used purification process in biodiesel production. Despite being an efficient method, wet washing
generates huge amounts of wastewater, on the other hand, dry washing methods uses an appropriate adsorbent to
selectively adsorb certain impurities from the liquid phase onto its surface, avoiding the use of water in the
purification step and offering several advantages, including simple integration into an existing industrial plant,
shorter purification time and lower effluent generation.
In this work, the goal is to optimize the production of biodiesel from WCO vía the ethylic route through its
purification by adsorption with a focus on glycerol removal, applying various natnral adsorbents, physically and
chemically activated with acid and basic agents, and obtained from residual sources ofbiomass (olive pits). The
optimized conditions for the production of biodiesel were found using a response surface methodology with 3
parameters: alcohoVoil molar ratio, reaction temperature and catalyst concentration. Four types of activated
carbon were produced from the same precursor (olive pits) and then characterized. The two most efficient
materials for glycerol removal were selected by means of equilibrium adsorption studies. Mterwards, kinetic
adsorption batch studies (see Table 1) were carried out at 3 different temperatures for each of the two selected
adsorbents (CA-800°C and CA-ZnCh) using the same adsorbent concentration (5% wt/wt). The dry washing
proved to be efficient in drastically reducing water consumption and effluent generation, in addition, an energy
consumption reduction is achieved since there is no need to heat the biodiesel to remove moistnre caused from
the wet washing process.