Find the information such as human life, natural resource,agriculture,forestry, biotechnology, biodiversity, wood and non-wood materials.
Blog List
Wednesday, 1 March 2017
Anaerobic treatment of palm oil mill effluents: potential contribution to net energy yield and reduction of greenhouse gas emissions from biodiesel production
Published Date
Journal of Cleaner Production 1 February 2014, Vol.64:619–627,doi:10.1016/j.jclepro.2013.07.056
Author
Soni Sisbudi Harsono a,b,,,
Philipp Grundmann c
S. Soebronto d
aDepartment of Technology Assessment and Substance Cycles, Leibniz-Institute for Agricultural Engineering Bornim (ATB), 14469 Potsdam, Germany
bDepartment of Agricultural Engineering, Faculty of Agricultural Technology, University of Jember (UNEJ), East Java, Indonesia
cDepartment of Technology Assessment and Substance Cycles, Leibniz-Institute for Agricultural Engineering, Potsdam-Bornim (ATB), 14469 Potsdam, Germany
dResearch Development PT. Asam Jawa, North Sumatra, Indonesia
Received 17 April 2013. Revised 12 July 2013. Accepted 29 July 2013. Available online 6 August 2013.
Highlights
•
Treating POME generate electricity and heat.
•
Energy output and net energy yields are 0.44 and 0.42 MJ kg−1 biodiesel, respectively.
•
Potential GHG emission reduction is 658 g CO2eq kg−1 biodiesel or 15.96 g CO2eq MJ−1.
Abstract The effluents from palm oil mills for biodiesel production are generally treated in open ponds, causing large amounts of greenhouse gas (GHG) emissions. This study assesses the use of palm oil mill effluents (POME) as feedstock to produce biogas via anaerobic digestion. Biogas from POME can be converted into electricity and heat to eventually reduce the greenhouse gas (GHG) emissions of biodiesel production from palm oil. This study is using two system boundaries, firstly, system a “gate-to-gate” concerning the POME treatments, and secondly a “cradle-to-gate/total combustion” when we assess the impact of varying POME treatments within the biodiesel chain. The research draws on field and experimental data from palm oil and biogas production in Sumatra, Indonesia. The findings show that the energy output from the conversion of POME to methane via anaerobic digestion and the subsequent combustion of the methane in a combined heat-power plant exceeds the energy consumption of the palm oil milling process. Treating POME in an anaerobic digester and using the biogas to generate electricity and heat has the potential to significantly reduce the GHG emissions of biodiesel production from palm oil. In the studied case, the energy output from the conversion of POME to electricity and heat is 0.44 MJ kg−1biodiesel and the net energy yield is 0.42 MJ kg−1biodiesel. The ratio of energy output to energy input of the conversion process is about 23.1. The potential reduction of GHG emissions is 658 g CO2-eq kg−1biodiesel or 15.96 g CO2-eq MJ−1. This is equivalent to about 33% of the total GHG emissions of biodiesel production from palm oil. Against this background we recommend to further develop and implement the treatment of POME in anaerobic digestion combined with the purposeful use of the methane, electricity and heat produced from the POME. This can make a significant contribution toward meeting international targets of emissions reduction for biodiesel production. Keywords
No comments:
Post a Comment