Implementing Circular Economy in the Production of Biogas from Plant and Animal Waste: Opportunities in Greenhouse Heating

Several years have passed since the linear economy model proved unsustainable, leading to the transition toward the circular economy (CE) model. Significant amounts of agricultural residues and waste from livestock farming units remain unutilized in fields. The anaerobic digestion (AD) method addres...

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Bibliographic Details
Published in:AgriEngineering 2024-12, Vol.6 (4), p.4675-4687
Main Authors: Argyropoulos, Christos, Thomopoulos, Vasileios, Petrakis, Theodoros, Kavga, Angeliki
Format: Article
Language:English
Subjects:
Agricultural economics
Agricultural wastes
Alternative energy sources
Ambient temperature
Anaerobic digestion
animal manure
Animal wastes
Biogas
Carbon footprint
Circular economy
Climate change
Common Agricultural Policy
Community
corn silage
Crop residues
Cultivation
Economic growth
Economics
Electricity
Electricity consumption
Energy consumption
Energy output
Energy requirements
Farm buildings
Flowers & plants
Fossil fuels
Fruit cultivation
GDP
greenhouse
Greenhouse gases
Greenhouses
Gross Domestic Product
Heat loss
Heating
Livestock
Livestock farming
Plant layout
Raw materials
Renewable resources
Sustainable development
Thermal analysis
Thermal energy
Tomatoes
Weather
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Summary:Several years have passed since the linear economy model proved unsustainable, leading to the transition toward the circular economy (CE) model. Significant amounts of agricultural residues and waste from livestock farming units remain unutilized in fields. The anaerobic digestion (AD) method addresses this issue by generating energy in the form of thermal (TE) and electrical energy (EE). This article examines greenhouse heating using thermal energy from a biogas plant. For this purpose, a thermal load model is developed and applied in two regions, northern (Florina) and central Greece (Trikala), to assess the greenhouse’s energy requirements in areas with differing characteristics, especially during the winter months. Additionally, the economic benefits of a biogas plant from selling electricity to the grid are analyzed. Thermal energy constitutes 59.7% of the system’s total energy output. On average, the generated electrical energy amounts to 518 MW h per month, while thermal energy reaches 770 MW h per month. The biogas plant’s daily electricity consumption ranges from 1564 kW h to 2173 kW h, depending on its needs. Ambient temperatures vary between 0 °C and 37 °C, significantly influencing the greenhouse heating system’s efficiency. The biogas plant also demonstrates financial profitability, earning 504,549 € annually from the sale of surplus electricity. Furthermore, the article explores greenhouse crops in the broader Thessaly region, where tomato cultivation seems to be dominant. Greenhouse heating requirements depend on crop type, location, weather conditions, sunlight exposure, and heat loss based on covering materials. Meanwhile, the thermal energy output that can heat a given greenhouse area is directly proportional to the biogas plant’s capacity.
ISSN:2624-7402
2624-7402
DOI:10.3390/agriengineering6040267