Industry-leading precision: our technologies deliver the most accurate battery performance data available.
Comprehensive product range: from µA-level cell research to 1.2MW pack testing, we cover all testing needs.
Future-proof solutions: designed to adapt to evolving battery technologies from lithium-ion to solid-state.
Intelligent integration: software + hardware + AI interconnected platform for seamless operation.
Global services network: whether in North America, Europe, Asia, or other regions, you can find traces of our services, ensuring that clients receive timely support anywhere.
Proven reliability: trusted by 60,000+ clients worldwide.
The core support for power batteries entering the high-voltage era. Our CE-6000 series enables testing for 800V platforms and megawatt flash-charging technologies.
2026 marks the year 800V high-voltage platforms become mainstream, with penetration expected to reach 15%. The global 800V EV market is projected to grow at a 32.3% CAGR through 2032.
Simultaneously, battery technology is advancing toward megawatt-level flash charging. BYD's 1.5MW Blade Battery and CATL's 6-minute Shenxing battery are pushing test equipment to unprecedented limits.
The CE-6000 series is NEWARE's next-generation high-precision platform specifically designed for high-power module and pack testing. It addresses all challenges of ultra-high-voltage testing with breakthrough innovations.
Flexible DC/AC module configurations with full copper-busbar architecture. Easy upgrades as battery technology evolves.
>96% conversion efficiency. Discharge energy is preferentially consumed by other channels, reducing operational costs.
Multiple layers of protection including insulation monitoring, arc detection, and redundant emergency stop circuits.
Standard CAN/RS485 interfaces with full DBC support. Seamless coordination with BMS and environmental chambers.
Comprehensive performance testing of battery packs for 800V electric vehicles, including capacity and cycle life.
Validation of ultra-fast charging performance at up to 1.2MW, evaluating thermal management and durability.
Testing of high-voltage battery clusters for grid-scale applications including peak shaving and frequency regulation.
-F model supports forced discharge to 0V and below, enabling comprehensive safety and abuse testing.
The critical defense line against battery safety hazards. Our revolutionary potentiostatic method reduces test time from weeks to hours, directly measuring microampere-level self-discharge current.
Self-discharge—the "invisible killer" hidden inside batteries—is a leading cause of capacity loss, pack imbalance, and thermal runaway. All lithium-ion batteries lose 1-5% capacity per month, but defective cells with micro-shorts show significantly higher rates.
The traditional ΔOCV method requires 2-6 weeks of storage to detect meaningful voltage differences, tying up massive inventory and delaying process feedback. This approach is increasingly inadequate for modern high-volume manufacturing.
When a battery is held at a constant voltage exactly equal to its open-circuit voltage (OCV), the external current required to maintain this voltage precisely equals the battery's internal self-discharge current.
This elegant principle allows us to bypass the slow voltage decay process entirely. Instead of waiting weeks for voltage changes, we measure the self-discharge current directly in minutes or hours.
0.1μA current resolution and ±0.02% F.S. accuracy. 7-digit voltage measurement with ±0.01% F.S. stability.
Up to 32 channels per unit. Enables 100% screening of production lines with minimal floor space.
±0.1°C temperature accuracy eliminates temperature-related variations. No external environmental chambers required.
Proprietary algorithms based on median subtraction and fitting methods effectively remove electrical noise.
100% screening of all cells before assembly to remove defective units with abnormal self-discharge.
Quick validation of large batches of cells from suppliers, reducing inspection time from weeks to days.
Rapid assessment of new electrode materials, electrolytes, and cell designs for self-discharge characteristics.
Matching cells with nearly identical self-discharge rates to minimize pack imbalance and extend life.
The heart of high-precision battery testing. Our revolutionary bipolar circuitry enables seamless zero-crossing, eliminating current interruption during charge-discharge transitions.
No loop switching required during charge-discharge transition. Current transitions smoothly without waveform distortion, ensuring accurate test results.
Extremely short current switching time enables tracking of complex dynamic pulses and HPPC tests with millisecond precision.
Single topology design with fewer fault points. Eliminates equipment failure caused by circuit switching and interruption.
Supports CC, CV, CP, CR and pulse modes. Implements complex programmable test sequences for all battery types.
Ensures smooth current transitions at current reversal points, producing accurate CV curves without artifacts from switching actions.
Eliminates voltage rebound during current steps, enabling true and accurate measurement of battery internal resistance.
Accurately reproduces charge and discharge pulses, providing reliable data for battery power performance characterization.
Tracks real-world driving cycles (NEDC, WLTP) with millisecond precision, evaluating battery performance under actual conditions.
Contact our technical team today to discover how NEWARE's core technologies can accelerate your battery R&D and production.