మా గ్రూప్ ప్రతి సంవత్సరం USA, యూరప్ & ఆసియా అంతటా 3000+ గ్లోబల్ కాన్ఫరెన్స్ ఈవెంట్లను నిర్వహిస్తుంది మరియు 1000 కంటే ఎక్కువ సైంటిఫిక్ సొసైటీల మద్దతుతో 700+ ఓపెన్ యాక్సెస్ జర్నల్లను ప్రచురిస్తుంది , ఇందులో 50000 మంది ప్రముఖ వ్యక్తులు, ప్రఖ్యాత శాస్త్రవేత్తలు ఎడిటోరియల్ బోర్డ్ సభ్యులుగా ఉన్నారు.
ఎక్కువ మంది పాఠకులు మరియు అనులేఖనాలను పొందే ఓపెన్ యాక్సెస్ జర్నల్స్
700 జర్నల్స్ మరియు 15,000,000 రీడర్లు ప్రతి జర్నల్ 25,000+ రీడర్లను పొందుతున్నారు
Mbugua JK, Ajuliu PK, Mbui DN, Mwaniki JM, Waswa AG
Population growth and urbanization has led to increased waste production in landfills. These landfills and slaughterhouses release greenhouse gases to the atmosphere and therefore, waste treatment and management is vital. In this study, Nairobi market wastes and bovine abattoir wastes were treated via anaerobic digestion and microbial fuel cell technologies to produce biogas and electricity, respectively. Proximate analysis was carried out on Nairobi market wastes before inoculating with rumen fluid from Dagoretti slaughterhouse waste at psychrophilic anaerobic digestion for a thirty days’ hydraulic retention time. Similarly, the waste was treated using microbial fuel cells inoculated with slaughterhouse waste in a dual chamber microbial fuel cell for thirty days. The daily cumulative biogas production was measured volumetrically while voltage and current from the cells was recorded using a multi-meter.
The results obtained showed that blank rumen fluid generated 1800 mL and 0.061 V of biogas and voltage, respectively. The biogas produced from the rumen-fluid inoculated fruit market wastes was in the range of 300 to 3500 mL while voltage ranged from 0.010 to 0.701 V. The amount of biogas and voltage generated was dependent on the proximate properties of the waste, operation conditions like pH, temperature and moisture content of the waste. This means that, using similar digester/anodic chamber, the maximum cumulative biogas generated of 3500mL translate to 21 V.A. Therefore, this study concluded that both anaerobic digestion and microbial fuel cell technologies are appropriate in conversion of waste to green energy.