In this study, biomass resource is chosen as a renewable energy source based on the abundance of oil palm waste generated monthly. The aim of this study is to find an optimal value of torrefection process on the torrefied biochar from oil palm empty fruit bunches (OPEFB) in order to produce biomass energy source by using the Box-Behnken design of response surface methodology (RSM). The OPEFB has been torrefied based on the three independent variables which are particle size (250, 500 and 750µm), holding temperature (200, 250 and 300°C) and residence time (30, 60 and 90 minutes). Torrefied biochar are being optimized in regards of six dependent variables which are mass yield, moisture content, volatile matter, ash content, fixed carbon and calorific value. The optimization process from the RSM shows that the most optimal value for OPEFB torrefied biochar is at 750µm (particle size), 274°C (holding temperature) and 90 minutes (residence time) of torrefaction process in order to produce a high energy content of biomass.
Currently, the primary energy supply in Malaysia is dominant by non-renewable energy sources such oil, natural gas and coal which contributed to the scarcity of these sources and occurrence of global warming. This phenomenon raises the public concerns to diversify the energy sources to sustain energy availability. To address these predicaments, biomass sources is among the prominent alternative energy sources since it is renewable and possesses minimal harms to the environment. Thus, the woody plant with high growth rate and high energy content that can be used to serve as potential biomass energy sources. In this study, small diameter (5-8cm) of wild Acacia mangium species have been determined and compared accordingly three (3) different portions (bottom, middle and top) and two (2) different particle sizes (0.5 and 1.5mm). The analysis conducted to determine the properties of raw material of Acacia mangium as biomass energy sources were proximate, physical and energy content properties. The result obtained for the energy content analysis of small diameter wild Acacia mangium has a mean calorific value range from 16.35 to 18.35MJ/kg between portions and particle sizes. In order to determine the effect of portions and particle sizes on each of the proximate, physical and energy content properties, two-way ANOVA was performed. It shows that both the portions and particle sizes have significant effect on calorific value (energy content) of small diameter wild Acacia mangium at 99% of confidence level. In a nutshell, the biomass energy properties of small diameter wild Acacia mangium with different portions and particle sizes were being determined.
Renewable energy produced from biomass is a green way to reduce the greenhouse effect. Fast-growing wood species, as the energy source, create independent and fast harvesting cycle for energy fuel stock. The aim of this study was to determine the effect of tree diameter at breast height (DBH) of a local wood species i.e. leucaena leucocephala, on char yield during pyrolysis. The calorific value (CV) of bio char was also determined in order to analyse the bio char product produced by pyrolysis process. The tree samples were classified into three DBH i.e. 4, 8 and 12 cm and only tree stem was selected for pelletization. The wood pellets were pyrolyzed at 300, 400, 500, 600 and 700 °C with 40 °C/min of heating rate and holding time of 30 min in inert condition. The largest difference percentage of bio char yield production is only 1 % while the largest difference of CV is 0.7 MJ/kg which happened at temperature 300 °C. In this study, it was found that any DBH does not give any significant effect to the production of bio char as well as its CV.
Bamboo has a very rapid growth rate and has been considered a promising non-wood biomass material that has the potential as a feedstock for charcoal production. This study was carried out to elucidate the physico-chemical and energy characteristic of bamboo charcoal produced from two (2) different species which were Aur Kuning Bamboo and Beting Bamboo. Each bamboo was carbonized at a temperature of 300 to 400oC for a duration of two hours. It was found that the density and volatile matter content of bamboo charcoal have decreased, while the ash content, fixed carbon (FC) content and calorific value (CV) have increased after being converted into charcoal. The results show that Aur Kuning Bamboo has good quality bamboo charcoal in comparison with Beting Bamboo in terms of its FC and CV content. Based on the average value, the FC (82.10%) and CV of Aur Kuning Bamboo (27.23%) were higher than FC (70.42%) and CV (26.05%) of Beting Bamboo with 16.59% (FC) and 4.53% (CV) different. Statistical analysis showed that there was a significant effect for different species of bamboo and a significant correlation between physical and energy properties. In conclusion, Aur Kuning Bamboo harvested from Sarawak wild forest has a higher potential to be a feedstock for charcoal production that will be useful for various applications in the near future.
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