The system combines the benefits of existing technology in robotics and engineering with agriculture. The robotic harvester and transporter allows full automation reducing labor costs when desired. When minimizing land area is important, units can be stacked on top of each other, automation plays a critical role in eliminating the risk and expenses associated with humans working high above the ground level.

The modular design has a great advantage due to the facts that a plant can be changed and fixed at any time if a disease is detected. This protects the entire production from getting destroyed, which holistically makes the system practical, economic and distinctive compared to other systems.

A unit can be easily stacked on top of another unit. This requires a “Base Unit” at floor level, with “Stacked Units” sitting on top of each other, creating what we call a “Tower”.

The Base Unit houses the majority of the controls, monitoring, and specific equipment. This allows an enormous gain in land area usage.

Each Tower will share a common nutrition tank, and controlling parameters, and as such, most compatible crops.

With the aid of machine learning, a “branch” of artificial intelligence, the proprietary software utilizes data from current market prices, plant’s growth patterns, resources usage, logistics processes and more, to determine and design an optimal crop planting schedule that maximizes financial gain.

Unlike traditional vertical farming systems, this modular and stackable unit allows users to conduct mass ‘crop planting’ indoors, within a controlled environment.

The technology allows any crop that can support its own weight to grow within the fully automated system that prepares a crop-specific soil bed, sows seeds and monitors growth while providing species specific (UV) light and watering cycles before robotic harvesting.

The conveyer system rotates, with proprietary artificial intelligence software resetting the system for the next harvest cycle.

Burning green waste to manufacture biocarbon, vermicompost, and other additives can lead to a more effective soil mixture and planting outcomes through several mechanisms. The combustion process converts organic matter into stable forms of carbon, enriching the soil with Biocarbon, which improves soil structure, water retention, and nutrient availability. Vermicompost derived from the decomposition of organic residues by earthworms enhances soil biodiversity and microbial activity, promoting nutrient cycling and plant health, thereby facilitating more successful and sustainable planting practices.

By harnessing renewable energy sources and employing UV disinfection, this proprietary system minimizes environmental impact while maximizing the efficacy of soil additives, resulting in a more efficient and environmentally friendly approach to soil management and planting practices.

Growing fruit and vegetable seedlings in a vertical farming system offers several technological advantages.

Vertical farming systems provide precise control over environmental factors such as light, temperature, humidity, and nutrient levels, optimizing growth conditions for seedlings. ISB systems allow for efficient space utilization, enabling higher density planting and maximizing crop yields in limited urban environments.

Units can be automated and equipped with sensors and monitoring devices, allowing for real-time data collection and analysis to optimize growing conditions and ensure uniform seedling growth, resulting in healthier and more robust plants upon transplanting.