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Solar energy generates power without harmful environmental impacts, such as releasing greenhouse gases like carbon dioxide. The water beneath the solar panels provides a cooling effect, enhancing energy conversion efficiency.

The Solar Floating Power Plant for Sustainable City Development supports 11 of the UN's Sustainable Development Goals.

By optimizing the surface area, it is not necessary for farmers to buy additional land to create green energy. Compared with other infrastructures, this implementation is both environmentally and economically sustainable.  

This structure and configuration also optimizes space for farmers, who can take advantage of it to develop new activities: fishing and aquaculture. These resources help to diversify the soil and create new activities. 

This vertical farming systems use tiered racks to maximize space, enabling users to grow a variety of essential vegetables in minimal areas. Powered by solar panels, the system ensures efficient energy use and resource conservation, making it ideal for large-scale applications.

Integrated sensors continuously monitor plant health and environmental conditions, ensuring optimal growth and yield for both individual and large-scale operations.

This solution is ideal for busy individuals and families living far from markets, offering a convenient way to access fresh, homegrown vegetables without frequent trips. Solar panels ensure uninterrupted operation, even in areas with limited grid access, enabling large-scale production for communities. 

This project is a multidisciplinary collaboration involving engineering, agriculture, and environmental science. Engineers design and implement the vertical farming structures and automation systems, while agricultural experts focus on organic cultivation practices. Environmental scientists ensure sustainability by optimizing resource use and minimizing environmental impact. 

For this sustainable building, 28 solar panels have been installed on the rooftop at an angle of 45 degrees to optimize this source of renewable energy.

Vertical axis wind turbines can capture wind from any direction. 6 wind turbines have been installed along the edges and one at the back of the terrace in order to support the solar panel roof structure.

Rainwater is gathered from the rooftop, which serves as the catchment area. The roof has a slight slope to direct water into open channels on the sides, which lead to a main pipe connected to a storage tank. Leaf screens are installed in the main pipe to prevent debris from entering the tank. The stored water can be used for long-term purposes.

Base isolators are used to reduce transmission of seismic forces from earth to structures during earthquakes. These dampers are better than the traditional ones in which only the vertical motion can be resisted and building sometimes buildings gets destroyed due to planer motion. 

Maglev wind turbines can be installed on residential roofs, allowing homeowners to generate clean energy and reduce utility costs. These turbines promote green energy adoption and are part of a growing movement towards sustainable power generation. They are adaptable for small-scale needs and can be combined with other renewable sources like solar power for more reliable energy production.

Maglev wind turbines generate 20% more energy than conventional turbines and reduce operational costs by 50%. With minimal maintenance needs, no lubrication, less friction and noise, and ground-level installation for easy access, they also have a long lifespan, enhancing sustainability.

This project embodies originality by integrating advanced technologies like IoT and AI into a cohesive system for smart irrigation. Its real-time monitoring and mobile app interface empower farmers with immediate data access and remote control, enhancing efficiency.

Irrigation is optimized and the project has a positive impact by conserving water through smart irrigation systems, reducing energy consumption with IoT and AI, and limiting chemical use by optimizing water delivery to plants. It also preserves soil health and biodiversity with minimal field disturbance, contributing to long-term sustainable farming practices.

The obstacle avoidance mechanism ensures uninterrupted operation, showcasing innovative problem-solving in agricultural automation. The intelligent watering mechanism, utilizing moisture sensors for targeted irrigation, optimizes water usage and promotes plant health creatively. Data-driven insights provided by the system enable farmers to make informed decisions, enhancing productivity and resource management.