Using an Optimized oxygen circulation path design and a rational valve pressure setup for safety valve opening and closing, the oxygen generated in the battery charging process can be compounded promptly and efficiently, thus overcoming valve-controlled battery water loss and better guaranteeing battery service life
The adoption of high purity lead, calcium and tin alloys and the strict management of the production process to stop the inclusion of impurities have reduced the probability of side reaction and resulted in a monthly self-discharge rate of no more than 2%.
By adopting a computer-aided high power polar plate structure design with proper partitioning, the batteries exhibit more than 30% better high power discharge performance compared with conventional batteries in short-term backup power application
The optimized polar plate structure design in combination with a properly increased active substance specific area enable batteries to support 0.4CA high current charging and achieve a 90% recharge within 3 hours.
The whole series of batteries uses ABS housing covers that conform to UL-V0 requirements and minimize the impact for customer of any serious risk.
The ultra-high power batteries adopt pure lead expanded grid technology which greatly increases high rate performance while simultaneously saving on materials and reducing energy consumption in production, making it friendlier to the enviroment than conventional technology.
Optimization of the alloy composition of battery polar plates and fine-tuning of the curing process and electrolyte parameters has effectively improved the theoretical life of batteries to as long as 12 years.