GEMS TECHNOLOGY
GEMS is our proprietary EV technology which was tested and proven on numerous numbers of commercial EVs. AVEVAI plan in near future is to commercialize GEMS technology by integrating it within IONA Brand vehicles, making it more competitive by significantly increasing the vehicle efficiency for up to 50% and bringing down the overall TCO of the vehicle.
How it works?
Supercapacitors will become the preferred and highly effective solution for capturing regenerative braking energy, surpassing other methods in the field. This technology will provide numerous advantages and functionalities that will significantly contribute to the overall performance and efficiency of electric vehicles.
One key aspect of supercapacitors will be their ability to capture and store regenerative braking energy with exceptional efficiency. When a vehicle decelerates or brakes, the energy generated during this process will be harnessed and stored in the supercapacitor. Compared to alternative methods, supercapacitors will excel in quickly and efficiently capturing this energy, ensuring minimal energy loss during the conversion process.
To ensure optimal utilization of the captured energy, supercapacitors will employ dynamic and nanosecond algorithmic control. This sophisticated control system will allow for precise and efficient discharge of the stored energy. Depending on the requirements, the discharged energy can either be used to power various devices or redirected back to the main battery tray for recharging. This flexibility will enable efficient energy management, maximizing the overall efficiency and range of electric vehicles.
The ability to capture and reuse braking energy will have significant implications for the driving range of electric vehicles. By effectively capturing and utilizing this otherwise wasted energy, the driving range of an electric vehicle will be extended. This reduction in energy waste will not only optimize the performance of the vehicle but also promote sustainability by reducing the reliance on external energy sources.
Supercapacitors will possess a remarkable power density, enabling them to discharge the stored energy at high momentarily ampere levels. This high-power output will be crucial during the initial stages of vehicle acceleration when overcoming inertia demands a substantial amount of energy. By providing this instantaneous high-power discharge, supercapacitors will play a vital role in enabling electric vehicles to overcome inertia and achieve smooth acceleration.
Moreover, this ability to assist in overcoming inertia will offer an added advantage in terms of battery life. By offloading the initial high-power demands from the main battery to the supercapacitor, the strain on the battery will be reduced. Consequently, the lifespan of the battery will be extended, ensuring long-term reliability and cost-effectiveness for the vehicle owner.
In conclusion, supercapacitors will revolutionize the capturing and utilization of regenerative braking energy in electric vehicles. Their exceptional efficiency in capturing energy, dynamic discharge control, extended driving range, high power density, and ability to protect and prolong battery life will make them the preferred and indispensable component in the future of electric vehicle technology. As the demand for efficient and sustainable transportation continues to grow, supercapacitors will undoubtedly play a pivotal role in driving the future of electric mobility.