Development of a Mathematical Model and Validation for Methane Production Using Cow Dung as Substrate in the Underground Biogas Digester

Obileke, KeChrist; Mamphweli, Sampson; Meyer, Edson L.; Makaka, Golden; Nwokolo, Nwabunwanne

doi:10.3390/pr9040643

Cited by 15 publications

(5 citation statements)

References 31 publications

(45 reference statements)

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“…The solids reported in the study were digestible and degradable; hence, the values of the TS and VS in the post digested sample (PDS) were much lower than the predigested sample (PRDS). These findings were similar to the report of [12] who reported lower TS and VS in the post digestion sample and higher pre-digestion samples(PRDS) The results on total solids were correlated to the quantity and quality of biogas in the cow dung This observation is correlated to the report of [13][14] who reported higher quantity of biogas yield from reactors with TS 7.4% and 9.2% as against rectors with TS 2.65%, 4.6% and 6.2% .This study was carried out to investigate the best ratio of water to cow dung (based on the moisture content of the cow dung) for biogas production. The production of flammable biogas commenced within 78 hours of charging.…”

Section: Discussionsupporting

confidence: 91%

Qualitative and Quantitative Means of Production of Biogas from Biodegradable Waste (Cow Dung) for Sustainable Energy

Gift,

Onyinyechi

2023

JABB

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Aims: This study was carried out by analyzing the quantitative and qualitative of the biogas produced from cow dung by degrading mechanism. 32L of bioreactors was used for the study. Methodology: The bioreactors were constructed to imitate the fixed batch prototype. The study lasted for 30 days and it was carried out at the National Centre for Energy Research and Development, University of Nigeria,Nsukka. Slurry was prepared in bioreactors. The substrates in the bioreactors were water and cow dung (intestinal and abdominal waste). The pH, the total solids (TS), volatile solids (VS) and total volatile fatty acid (VFA) characteristics of the substrate before and after digestion were determined using standard method. Quantitative and qualitative analysis of biogas production was by liquid displacement and gas Analyzer methods Results: The results of the TS, VS and VFA were 400 mg/l, 92mg/l and 16.7 mg/l respectively in the predigested samples and 92 mg/l, 17.4mg/l and 28.3mg/l respectively in the post digested samples. The quantity of biogas produced at the first week was 8.5liters, 7.5litre and 6.1liter from the 4th day, 5th day and 8th days. The qualitative analysis showed that the prominent biogas produced was methane. Conclusion: The results of the research concluded that high quantity of biogas can be produced using cow dung. Approaches and technology for more efficient biogas producing consortia are proposed.

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Section: Discussionsupporting

confidence: 91%

Qualitative and Quantitative Means of Production of Biogas from Biodegradable Waste (Cow Dung) for Sustainable Energy

Gift,

Onyinyechi

2023

JABB

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“…The biogas fermenter can be modeled considering its volume and the required rate of generation of gas based on the amount of sludge. The volume of the biogas fermenter (V d ) can be written as [51],…”

Section: Biogas Fermentermentioning

confidence: 99%

Optimal Design and Performance Analysis of a Digitally Controlled Biogas Power Generation System Suitable for DC Microgrid

Barui

Mondal²

2023

Smart Grids and Energy

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Renewable energy sources are gradually becoming an alternative to fossil fuel-based power sources. It helps in overcoming the energy crisis and minimizing the emission of toxic gases as well as ensuring a step towards achieving a carbon-neutral environment. For the uninterrupted supply of power in the area of the weak distribution of electricity, clean energy sources are proven to be a feasible solution for electrification. This work aims to design a unique concept of a biogas-fuelled powergenerating system and analysis performance that can enhance renewable-based power generation. The optimization of the biopower generation system has been carried out through the HOMER software. The power plant's performance with a digital control system has been investigated in MATLAB at fully loaded conditions. The efficacy of the system has been validated experimentally on a hardware setup resulting in an increase in power generation efficiency of about 14%. A comparative experimental study has been presented to exhibit the benefit of the designed system over the conventional bio-power generation system like the minimization of power losses and reduced no of associated equipment as required in the conventional system. Besides that, the estimated cost of the design of the power plant and its payback period has also been investigated for a limited period of years. It has been revealed that the proposed design of the Biogas power plant and its performance is substantially efficient and can be recommended for utilization in a microgrid or any small-scale power generating system.

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“…The following parameters were examined and reported as follows: pH: 7.83 at 30 • C; total solids: 130,800 g/L; volatile solids: 110,467 g/L; chemical oxygen demand: 42,583 g/L [9].…”

Section: Physiochemical Properties Of the Substratementioning

confidence: 99%

Economic Analysis of Biogas Production via Biogas Digester Made from Composite Material

et al. 2022

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This study seeks to evaluate the economic implication of a biogas digester built from composite material to ascertain its cost effectiveness. The feasibility study conducted indicates that a brick made only of fixed dome digester costs between USD 3193.99 and USD 4471.59. This high cost is attributed to the construction material, thus prompting the need to use materials of lower cost for affordability and sustainability. Hence, the digester under study was made from composite material comprising high-density polyethylene (HDPE), bricks and cement. The inlet and outlet chambers were built using bricks and cement, while the digestion chamber was made from HDPE material. From the economic analysis conducted, the total initial investment cost of the biogas digester was reported to be USD 1623.41 with an internal rate of return (IRR) of 8.5%, discount payback period (DPP) of 2 years and net present value (NPV) of USD 1783.10. The findings equally revealed that the estimated quantity of biogas could replace 33.2% of liquefied petroleum gas (LPG) cooking gas. Moreover, the biogas daily yield of 1.57 m3 generates approximately 9.42 kWh of electricity, which costs about USD 1.54. Thus, the study recommends the use of composite material of plastics and bricks in constructing the biogas digester, as it is cost effective and sustainable.

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Development of a Mathematical Model and Validation for Methane Production Using Cow Dung as Substrate in the Underground Biogas Digester

Cited by 15 publications

References 31 publications

Qualitative and Quantitative Means of Production of Biogas from Biodegradable Waste (Cow Dung) for Sustainable Energy

Qualitative and Quantitative Means of Production of Biogas from Biodegradable Waste (Cow Dung) for Sustainable Energy

Optimal Design and Performance Analysis of a Digitally Controlled Biogas Power Generation System Suitable for DC Microgrid

Economic Analysis of Biogas Production via Biogas Digester Made from Composite Material

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