Electric vehicle battery system data

A blue electric car is parked in a lot and is connected to a small yellow charging trailer labeled with eCharge. The setting includes a few trees without leaves, and a building with blue and white panels in the background.

A sleek, white electric vehicle is parked at a futuristic-looking charging station. The environment has a modern design with circular overhead structures emitting blue light, enhancing the technological ambiance. The car's headlights are distinct, and there's a digital display screen nearby indicating a status related to charging.

Comprehensive data collection for EV battery performance analysis.

Battery performance and technology progress data

Energy density improvement: In 2020, the energy density of mainstream ternary lithium batteries is about 240 Wh/kg, in 2024, CATL Kirin batteries will reach 255 Wh/kg, and Tesla 4680 batteries (mass production in 2023) will reach 297 Wh/kg;

The energy density of solid-state battery pilot products (such as Toyota 2025 models) has reached 360 Wh/kg, and the goal is to exceed 500 Wh/kg in 2030. Charging efficiency:

Ultra-fast charging technology (such as Xiaopeng S4 charging pile) supports 480kW power, and the ternary lithium battery can be charged for 10 minutes to increase the driving range by 250km;

The future of electric vehicle battery systems

With the maturity of solid-state batteries, AI management algorithms, and closed-loop recycling systems, battery systems will become a key node in "zero-carbon transportation" and "energy Internet", reshaping the global energy and manufacturing landscape.

Innovative Data Solutions for Battery Management

We specialize in comprehensive data collection and analysis for electric vehicle battery management systems, ensuring optimal performance and reliability through advanced data processing techniques.

A black electric vehicle is connected to a charging station on a street, with a blue cable linking the car to the unit. The setting is an urban area at night, with surrounding buildings and illuminated windows. The paving is made of bricks, and there's a bush visible in the foreground.

A close-up view of an electric vehicle charging port with the charger plugged in. The car appears to be white, and the charging cable has a visible label with a company name. The tail light is partially visible with a red lens and a sleek design. The scene suggests a modern and clean aesthetic typical of electric vehicles.

The battery system of electric vehicles is developing towards high energy density, high safety, long life, fast charging and low carbonization. Through material innovation, system integration and intelligent management, the pain points of battery life, cost and safety are gradually solved. At the same time, the industry chain needs to jointly promote battery recycling and resource circulation to achieve sustainable development of the electric vehicle industry.