Solar Tracking System Solution
PowerFit utilizes a flat uniaxial drive system and a single vertical array layout for its components. The bracket is compatible with single and double-sided modules and can be installed with framed or frameless varieties. With its innovative design, it offers improved wind and snow resistance when applied to larger PV modules.
PowerFit-Blade is Boviet's next generation single-axis, multi-point, parallel drive tracker, optimized for high-power components on the market. Its elaborate design reduces the use of components, thus improving construction and installation efficiency. With outstanding performance, PowerFit-Blade can be installed in high-wind areas. Installation of double-sided components, together with intelligent tracking algorithms, enables PowerFit-Blade to achieve up to 8% higher power generation compared to PowerFit.
Powerfit-Agr PV tracker is a breakthrough solution that combines solar photovoltaics with agriculture. With its unique rotation range, it does not interfere with harvest seasons and improves cultivation efficiency when used in agricultural settings. Compared to fixed-angle brackets, this design not only maximizes power generation but also introduces solar technology to agriculture, providing sustainable and efficient energy solutions for farms.
Powerway Smart Tracking Solutions
Tracking bracket, tracking bracket controller, communication controller, intelligent algorithm, and monitoring platform. It can also be flexibly matched with other equipment such as power station SCADA and inverters to form a complete photovoltaic tracking system solution.
PowerSmart One astronomical tracking algorithm
Part1 Intelligent Tracking Algorithm
Increase power generation under cloudy weather and other weather conditions
Based on meteorological and system operating data, real-time dynamic optimization of the optimal tracking angle is carried out to increase power generation in high scattering radiation weather conditions.
Part2 Intelligent Anti-Tracking Algorithm
Reduce power generation losses caused by shadows in complex terrain.
Utilizing system operation data to optimize interference training and utilizing perception technology to identify obstructions, constructing three-dimensional terrain. Based on machine learning algorithms, iteratively deciding on the optimal group of backtracking angles to output the overall power generation, effectively improving power generation during the backtracking stage.