Construct a battery "digital twin" model to preview temperature distribution, stress strain, and thermal runaway path during the design stage to achieve "risk preview in advance during the design stage."

Model-based design methodology, from algorithm development to embedded code generation, simulation testing in different scenarios to maintain algorithm integrity and efficiency

Achieve millisecond-level abnormal response through multi-modal sensors, providing full-process protection from intrinsic safety to emergency fire protection

Combining battery thermal management and thermal runaway path simulation to identify risks in advance and initiate warnings

Supports millisecond-level autonomous protection for overcharge, over-discharge, short circuit, over-temperature and other abnormalities

Real-time monitoring of cell temperature differences, dynamic adjustment of voltage and temperature, and delaying performance degradation

Based on the multi-model fusion algorithm, real-time and accurate estimation of SOC/SOH/SOP is achieved, reducing false power standards and mileage anxiety.

The embedded system is deeply integrated with battery chemistry, and the sleep power consumption is as low as μA level. It can wake up instantly when needed, realizing the transition from "passive energy consumption" to "active intelligent control".

Supports full life cycle data upload and analysis, and continuously optimizes BMS strategies through remote diagnosis and firmware upgrades to adapt to different usage scenarios and aging states.

Through topology optimization and advanced material application, the module weight is reduced while ensuring strength.

Waterproof, dustproof, shockproof, adaptable to complex and harsh working conditions

Cooperate with universities to tackle cutting-edge technologies such as high-performance lithium battery safety management and control, photovoltaic energy storage and cloud monitoring