Strong Instantaneous Power Burst for Complex Working Conditions
With a power density of 1000-5000W/kg, far exceeding that of lithium batteries (200-500W/kg), supercapacitor modules can output several times the rated power in an instant, meeting the high dynamic demands of unmanned equipment:
When drones perform vertical takeoff/landing or hover and change direction, motors require instantaneous high-power drive. Supercapacitor modules can supply power quickly, avoiding voltage drops or insufficient power caused by large current discharge of lithium batteries.
When unmanned vehicles climb slopes, accelerate rapidly, or cross obstacles, supercapacitors can instantly supplement power to ensure stable body posture. For example, on muddy roads, tire grip can be improved through instantaneous power enhancement to prevent slipping.
"Second-Level" Charging Speed to Improve Work Efficiency
Supercapacitors support high-current fast charging, and the module charging time can be shortened to 1-5 minutes (lithium batteries usually take 30 minutes to 2 hours). Moreover, they do not need to strictly match charger parameters and can be quickly recharged using ordinary fast charging piles. For example:
After completing a delivery, logistics drones can take off again after 2 minutes of fast charging at the station, increasing the daily operation times from 5-8 times with lithium batteries to 15-20 times.
Inspection unmanned vehicles can increase their range by 10 kilometers with 1 minute of fast charging at the base station, which is suitable for scenarios requiring continuous operations such as power grid inspection and factory patrol.
Over One Million Cycles to Reduce Lifecycle Costs
Drones/unmanned vehicles can be charged and discharged 5-20 times a day. Traditional lithium batteries usually have a lifespan of 1000-3000 cycles under high-frequency cycles (needing replacement in about 1-2 years), while supercapacitor modules have a cycle life of over 1 million times. Calculated at 10 charge-discharge cycles per day, they can be used stably for more than 270 years, almost matching the service life of the equipment itself (5-10 years). There is no need for mid-term replacement, and the operation and maintenance cost is reduced by more than 90%.
Stable Operation in Wide Temperature Range for Extreme Environments
Supercapacitors work in a temperature range of -40℃ to 70℃. Through cold-resistant electrolyte and anti-corrosion shell design, the modules can maintain stable performance in extremely cold (such as outdoor in northern winter) and high-temperature (such as deserts, mining areas) environments:
In plateau areas at -30℃, the battery capacity of drones does not decrease significantly, ensuring mapping and search-and-rescue operations are not affected by low temperatures.
In desert oil fields at 60℃, unmanned vehicle modules can maintain normal power output without cooling systems, adapting to scenarios such as oil and gas pipeline inspection.
High Safety and Reliability to Reduce Operational Risks
The charge-discharge process of supercapacitors is physical charge migration without chemical reactions. Modules will not burn or explode under extreme conditions such as puncture, short circuit, and high temperature, only showing performance attenuation. They are especially suitable for:
Forest fire prevention drones (avoiding secondary disasters caused by battery fires);
Unmanned vehicles in chemical parks (adapting to explosion-proof environments and eliminating the risk of electric sparks);
High-altitude operation drones (even if they fall, the modules will not be dangerous due to impact).
High-Frequency Operation Scenarios (Logistics Delivery, Express Sorting)
Pain points: Slow charging of lithium batteries limits the daily operation times of drones/unmanned vehicles, making it difficult to meet the demand for intensive "last-mile" delivery; unmanned vehicles in sorting centers need to operate 24 hours a day, and frequent battery replacement affects efficiency.
Application value: Logistics drones achieve high-frequency takeoffs and landings through "second-level charging". For example, after the deployment of delivery drones in an e-commerce warehouse, the daily delivery volume increased from 80 orders to 200 orders; sorting unmanned vehicles do not need to stop for battery replacement, and the continuous operation efficiency is increased by 30%.
Extreme Environment Operations (Plateau Mapping, Desert Inspection)
Pain points: Low temperatures on plateaus (below -20℃) cause lithium battery capacity to drop by more than 50%, making it impossible to complete long-distance mapping; high temperatures in deserts shorten battery life, leading to frequent failures of unmanned vehicles.
Application value: Plateau mapping drones equipped with supercapacitor modules have stable endurance in -30℃ environments and can complete 20 square kilometers of terrain scanning in a single flight; desert oil field unmanned vehicles can withstand 60℃ high temperatures, operate without failure for 3 consecutive months, and complete 100-kilometer pipeline inspection.
High Safety Demand Scenarios (Forest Fire Prevention, Chemical Inspection)
Pain points: If the lithium battery of a forest fire prevention drone catches fire, it may cause a forest fire; there are flammable and explosive gases in chemical parks, and battery sparks may cause explosions.
Application value: The intrinsic safety of supercapacitors avoids the risk of open flames. Forest fire prevention drones can monitor fire conditions at close range, and unmanned vehicles in chemical parks can move freely in explosion-proof areas without additional explosion-proof modification.
High-Dynamic Operation Scenarios (Emergency Rescue, Event Live Broadcast)
Pain points: Rescue drones need to take off and land quickly and hover to avoid obstacles, requiring large instantaneous motor power; event live broadcast unmanned vehicles need to follow the shoot at high speed and stop suddenly, and delayed power response may miss key shots.
Application value: Earthquake rescue drones can flexibly shuttle through narrow ruins with the instantaneous power of supercapacitors to quickly locate trapped people; racing event unmanned vehicles can accurately follow high-speed vehicles, with the response time of sudden acceleration/braking shortened to 0.1 seconds, and the picture stability increased by 50%.
