This system shows how microalgae are grown using light and nutrients in a controlled environment, helping us explore new ways to produce clean energy, useful products, and solutions for a healthier planet.
This hydroponic system demonstrates the Nutrient Film Technique (NFT), where plants grow without soil, relying on a continuous flow of nutrient-rich water for efficient and sustainable food production.
This geodesic dome greenhouse houses a hydroponic system based on the Nutrient Film Technique (NFT), providing an innovative and sustainable model for food production under controlled environmental conditions.
This integrated greenhouse showcases multiple hydroponic techniques, including horizontal and vertical systems, enabling comparative studies on sustainable crop production and resource efficiency.
This geodesic dome greenhouse houses a hydroponic system based on the Nutrient Film Technique (NFT), providing an innovative and sustainable model for food production under controlled environmental conditions.
This integrated greenhouse showcases multiple hydroponic techniques, including horizontal and vertical systems, enabling comparative studies on sustainable crop production and resource efficiency.
This LED-assisted photobioreactor uses red and blue light to optimize photosynthesis, providing a controlled environment for cultivating microalgae and advancing research in bioenergy, food, and biotechnology.
Students are engaged in hands-on experiments, using laboratory tools and digital monitoring to practice data collection and analysis in real-world research settings.
This training activity illustrates the feeding process of a bioreactor, where organic material is added to cylindrical tanks to support research and education in renewable energy and waste management.
This aquaculture facility features large-scale rearing tanks designed to provide water quality and controlled conditions for the sustainable cultivation of fish and other aquatic species.
Classroom sessions provide the theoretical foundation for aquaponics and biofiltration, complementing hands-on activities with scientific knowledge and system design principles.
This render is for a facility to produce 35 tons/year of trout and about 250 thousands veggies/year plus 20 ton of strawberries/year. Investment is about US$ 750,000 valued for America. Investment can change depending on your local materials and workforce.
This render is for a facility able to produce 6 tons fish /year, 30 thousands veggies per year, and 4 tons of tomatoes per year. Investment is US$ 75,000.
As part of our project activities, visits are being conducted to aquaponic facilities established in collaboration with our partner educational institutions. These visits aim to strengthen cooperation, share technical knowledge, and support the development of sustainable aquaponic practices. Lettuce and various aromatic plants are cultivated in the facility.
Here we are stocking lettuces in the aquaponic system at the technical high school in Canela town. The team also lifts the rafts to check root development, which is an essential step for tracking plant growth and ensuring healthy nutrient uptake in aquaponic systems.
Here we are stocking lettuces in the aquaponic system at the technical high school in Canela town. A project sign displaying the name of our initiative and the logos of our partner institutions is also visible, highlighting the collaborative effort behind this educational setup.