AI in Solar TrackingIntelligent Solar Technology
Discover how artificial intelligence and machine learning have revolutionized solar tracking systems, making them smarter, more adaptive, and more efficient than ever before.
Software Intelligence in Sun Tracking
Traditional solar tracking systems often rely on bulky and complex mechanical components, such as gears and motors, to adjust the angle of solar panels throughout the day. These systems can be expensive to install and maintain, and are prone to wear and tear over time. In contrast, Mechatron's gearless technology eliminates the need for these mechanical parts, creating a more reliable and cost-effective solution.
The key to Mechatron's gearless technology lies in its advanced software automation, which continuously monitors and adjusts the angle of the solar panels mounted on its massive platform.
Furthermore, Mechatron's software automation is equipped with built-in intelligence that allows it to adapt to changing weather conditions and seasonal variations. This means that the system can make real-time adjustments to optimize energy production, even on cloudy days or during the winter months when the sun is lower in the sky.
In addition to improving energy efficiency, Mechatron's gearless technology also offers increased durability and longevity. Without the need for mechanical components, the system is more resistant to wear and tear, resulting in lower maintenance costs and a longer lifespan for the solar panels.
Built-in Intelligence Features
Overall, Mechatron's gearless technology software automation represents a major leap forward in the field of solar energy technology. Some of the main features of built-in intelligence are listed below:
| Self-slippage when wind torque exceeds 35KNm brake limit, innovative mechanical system that protects the tracker from catastrophic damages | |
| Self-return to alignment position after a slippage event expires | |
| Self-stow when grid power is lost due to eccentric dead load placement and safety valve feature, protects the whole system by flattening the platform when power is lost | |
| Intelligent decision of platform tilt based on sustainable wind speeds | |
| Utilize quadrature encoder to provide 1-degree granular azimuth motion | |
| Intelligent collaboration of snow and wind sensors software routines for platform protection under extreme weather conditions |