Influence of Production Variables on Eco-Friendly Briquettes from Coconut and Bambara Nut Shells

This study investigates the influence of production variables on the properties of molasses-induced fuel briquettes from Coconut (Cocos nucifera L.) and Bambara nut (Vigna subterranea L. Verdc.) shells. The milled samples of both raw materials were mixed with molasses at ratios 100:20, 100:25, 100:30 and 100:35 by weight respectively, and briquetted using a Jack press at an average pressure of 1.2KN/m2. A 3x4 factorial experiment in completely randomized design was used. The briquettes produced were subjected to both physical and combustion tests. The tests revealed that majority of the variations in briquette properties were largely influenced by the type of biomass residues used while molasses’ content also contributed significant effect atp < 0.05. Coconut shell briquettes had higher compressed density though lower in relaxed form (0.80 g·cm-3vs 0.78 g·cm-3) when compared to Bambara nut shell briquettes (0.77 g.cm-3vs0.75 g.cm-3). Both physical and combustion properties were significantly improved when both bio-residue mixtures were used. Briquettes from the mixtures had the highest average fixed carbon and heating values of 85.21% and 32.80 MJ·kg-1 respectively, though it was 83.83% and 32.12 MJ·kg-1for coconut shell briquette and 82.18% and 32.03 MJ·kg-1for Bambara nut shell briquette. Therefore, based on physical and combustion characteristics, the best Bambara nut briquettes and its mixture with coconut shell were produced when molasses content was 30%. In contrast, the best coconut shell briquette was produced when molasses content was 35%. These two level are therefore recommended for production of quality briquettes from these agro-residues

Evaluation of Elemental and Chemical Compositions of Some Fuelwood Species for Energy Value

Fuelwood species are a crucial part of the ecosystem; they provide energy for cooking, heating, and lightening for both domestic and industrial uses. As a result of their value, there is a need for frequent evaluation of elemental and chemical compositions for management and conservation purposes. Since fuelwood is the most common and cheapest source of energy in both rural and urban areas in northern Nigeria, the study area is facing serious challenges due to indiscriminate felling of trees for energy use, irrespective of species quality for combustion. Therefore, ten fuelwood species were selected for this study. The selected trees were harvested at Dbh level, replicated three times. Four fuel materials were obtained from each tree sample; these include wood without bark (100% wood sample), wood with 5% bark inclusion, wood with 10% bark inclusion, and whole bark samples and they were evaluated for their inherent elemental and chemical compositions by employing ASTM and TAPPI methods. The results showed that there were significant differences in the tree species and fuel material types obtained from all the ten fuelwood species used. The results of carbon content ranges from 49.54% in A. sieberiana to 50.98% in A. leiocarpus. Meanwhile, the addition of 5% and 10% bark reduces carbon content of wood by 1.25% and 2.74%, respectively. Nitrogen content ranged from 0.31% in A. leiocarpus to 1.00% in A. sieberiana. Among the fuel materials used, isolated bark contained approximately 0.45% nitrogen content compared with wood without bark. Among the tree species, hydrogen content ranged from 3.99% in P. reticulatum to 4.66% in C. arereh. The variation in sulphur contents ranged from 0.24% in C. arereh to 0.93% in A. sieberiana. Lignin content ranged from 10.68% in A. sieberiana to 25.39% in A. leiocarpu and extractive content values ranged from 7.31% in A. leiocarpus to 19.33% in P. reticulatum. Meanwhile, the fuelwood species observed in this study with higher percentage of carbon, hydrogen, and lignin and lower nitrogen and sulphur and extractive content possessed quality fuel value and thereby were encouraged to be incorporated in fuelwood plantation establishment programs (A. leiocarpus, C. molle, C. arereh, and B. aegyptiaca). Lower energy fuelwood species should be allowed for environmental amelioration and carbon sequestration. However, bark contents should be removed for better heating and low ash production during combustion

Energy biomass characteristics of chosen plants

The chosen energy plants species: willow, mallow and Miscanthus are presented. Result of analysis of combustion heat and heating value of these species biomass indicate on possibility of their utilization as fuel for combustion and energy and heat production