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Innovative Technology

Boundless Innovation, Unending Exploration

Revolutionary battery technology unlocks green potential
Driving the world towards a zero-carbon future and empowering a better life

  • High Energy Density Technology

    Where High Energy Reaches
    Horizons become boundless with an energy density of 380 Wh/kg

    Optimized by30%

    * Data is provided by the Ampace Laboratory. Please refer to actual usage for accuracy.

  • Battery Technology For Long Life

    Cycles With Constancy
    Reliability Proven Over Time
    Maximum service life of up to 20,000 cycles

    Optimized by120%

    * Data is provided by the Ampace Laboratory. Please refer to actual usage for accuracy.

  • Ultra-Fast Charging Technology

    Flash Charge Eases Worries
    Freedom in an Instant
    Charging to 80% in only 5 minutes

    Optimized by240%

    * Data is provided by the Ampace Laboratory. Please refer to actual usage for accuracy.

  • Wide Temperature Range Technology

    Wide Temperature Range
    Composure in All Seasons
    Stable output across extreme temperatures from -40℃ to 80℃

    Optimized by 25%

    * Data is provided by the Ampace Laboratory. Please refer to actual usage for accuracy.

  • True Safety Technology

    Comprehensive Safeguards
    Ensuring Unwavering Safety
    100% safety standard coverage throughout the entire lifecycle

    100%

    * Data is provided by the Ampace Laboratory. Please refer to actual usage for accuracy.

  • Smart Management Technology

    Millisecond Precision
    Whole Day Assurance
    24/7 full-cycle battery monitoring

    24H

    * Data is provided by the Ampace Laboratory. Please refer to actual usage for accuracy.

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High Energy Density TechnologyBattery Technology For Long LifeUltra-Fast Charging TechnologyWide Temperature Range TechnologyTrue Safety TechnologySmart Management Technology
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  • High Energy Density Technology
  • Battery Technology For Long Life
  • Ultra-Fast Charging Technology
  • Wide Temperature Range Technology
  • True Safety Technology
  • Smart Management Technology
  • com_icon13.svg
    High Energy Density Technology

    Where High Energy Reaches, horizons become boundless

    380WH/KG
    energy density
    • High-Nickel Technology

      Leading High-Nickel 811 system with Ni% > 90%, combined with particle gradation optimization technology and anti-gelation technology, ensuring material and electrode sheet processability while significantly increasing energy density, effectively balancing high standards of safety and reliability.

    • High-Silicon Technology

      Si/Gr novel composite material, paired with targeted process technology and directional pore structure technology, improving the kinetics and mitigating the hard expansion issues of Si materials while effectively enhancing cell energy density and power performance.

    • High-Voltage Technology

      Achieved through particle size design and crystal phase matching, combined with oxidation-resistant electrolyte technology. By continuously expanding the voltage upper limit to extract more active lithium, energy density is significantly increased, achieving optimal cost-performance.

    • Lightweight Current Collector Technology

      A special material composite process enables lightweight current collectors, significantly boosting cell energy density. This is paired with electrode sheet etching and stacking technologies to effectively address the kinetic challenges associated with lightweight current collectors.

    • * The above data are from Ampace Lab.

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    Battery Technology For Long Life

    Cycles With Constancy, Reliability Proven Over Time

    20000cycles
    Maximum service life
    • Low Lithium Loss Anode

      The "Low Lithium Loss Technology" significantly reduces active lithium consumption during cell operation, markedly enhancing the stability of the anode material's surface and bulk structure, thereby meeting the performance requirements for ultra-long battery life.

    • Passivated Cathode

      Constructs a self-dormant passivation film on the electrode through cathode FIC coating technology. This reduces activity during storage and reactivates upon use, akin to animal hibernation, greatly minimizing degradation.

    • Bio-Inspired Self-Healing Electrolyte

      Automatically repairs defects in the Solid Electrolyte Interphase (SEI) film, ensuring its integrity and stability. It exhibits adaptive protective characteristics, improving the cell's cycling and storage performance.

    • Electrode Microstructure Design

      Employs meticulous design at the electrode sheet level to construct "high-speed channels for ions and electrons", reducing lithium-ion diffusion resistance and slowing down capacity fade.

    • Expansion Force Adaptive Management

      Introduces flexible expansion force management technology to achieve adaptive control of cell expansion force. This maintains the expansion force of cells within an optimal range throughout the usage cycle, thereby extending battery life.

    • Battery Life Compensation

      Performs targeted "replenishment" and "detoxification" at different stages based on battery life requirements. This strategy slows capacity degradation, prolongs cell life, and unlocks higher value.

    • * The above data are from Ampace Lab.

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    Ultra-Fast Charging Technology

    Flash Charge Eases Worries. Freedom in an Instant.

    80%
    only 5 minutes
    • Multi-Dimensional Conductive Framework

      Utilizes advanced zero-dimensional, one-dimensional, and two-dimensional carbon nanomaterials to construct a multi-level electronic network framework (point, line, and plane dimensions). This increases electron transport pathways, enhances the conductive response speed of active materials, and significantly accelerates the lithium-ion intercalation/deintercalation rate.

    • Self-Oriented Graphite

      Starting from material particle shape and crystal phase structure, a type of graphite is designed that can self-align into an optimal orientation within the electrode sheet. This shortens the conduction path length for lithium ions within the electrode, prevents lithium plating and dendrite formation during rapid charging, thereby enabling ultra-fast lithium-ion transport.

    • Ultra-Low Resistance Electrolyte

      By introducing a novel electrolyte formulation with ultra-low viscosity and high conductivity, the shuttling resistance of lithium ions at the liquid phase and solid-liquid interface is significantly reduced, facilitating fast charging.

    • High-Wettability Separator

      A novel separator combining ultra-high porosity and high wettability effectively enhances liquid retention capacity, substantially lowers lithium-ion transport resistance, and ensures unimpeded shuttling of lithium ions through the separator.

    • Heterogeneous Electrode Sheet

      Constructs a heterogeneous electrode sheet structure that regulates the number of lithium-ion transport channels at the solid-liquid interface while simultaneously reducing the solid-phase diffusion path length for lithium ions, achieving effects comparable to three-dimensional porous electrodes.

    • Online Tracking Technology

      Incorporates intelligent algorithm technology to enable online tracking of cell state of health (SOH) and charging capability. It allows for adaptive charging rate adjustment during use and provides a user interface for interaction.

    • * The above data are from Ampace Lab.

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    Wide Temperature Range Technology

    Wide Temperature Range, Composure in All Seasons

    -40~80
    extreme temperatures
    • Low-Temperature Resistant Cells

      A novel anode material with higher reaction activity, combined with a cathode featuring multi-dimensional lithium-ion transport channels and a novel electrolyte with an ultra-low freezing point, significantly reduces the shuttling resistance for lithium ions within the electrode materials and electrolyte. This dramatically enhances the cell's charge/discharge performance in low temperatures, enabling reliable operation in extreme cold environments.

    • Self-Heating Components

      The introduction of cell-integrated self-heating structural components enables closed-loop temperature management, keeping the cell consistently within its optimal operating temperature range and expanding its adaptability to extremely cold conditions.

    • Cell Temperature Control

      Pulse heating technology ensures maximum uniformity in cell heating, overcoming the uneven heating typical of conventional heating film methods. This preserves cell "youth" and combats aging.

    • SOC Rapid Correction

      Based on an equivalent circuit model and an Extended Kalman Filter (EKF) algorithm, this enables high-precision State of Charge (SOC) estimation and rapid correction of SOC errors caused by hardware factors.

    • SOP Dynamic Adjustment

      Utilizing online impedance intelligent algorithm technology in conjunction with a State of Power (SOP) calculation model, it achieves real-time SOP value acquisition under any environmental or operating condition, ensuring no safety incidents occur due to insufficient power.

    • * The above data are from Ampace Lab.

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    True Safety Technology

    Comprehensive Safeguards, Ensuring Unwavering Safety.

    100%
    Safety
    • High-Safety Cell Main Materials

      High-throughput screening of the "material genome database" is performed. Elemental doping is employed to maintain energy density while simultaneously increasing the difficulty of oxygen release, enhancing material thermal stability. Furthermore, in conjunction with modified electrolyte formulations, this effectively reduces reaction heat generation at the solid-liquid interface, significantly improving the battery's thermal safety.

    • High-Safety Cell Auxiliary Materials

      A proprietary advanced nano-coating technology forms a stable, dense safety interface layer on the electrode surface. This greatly reduces the surface activity of the materials and markedly increases the cell's thermodynamic stability. Combined with high-safety composite current collectors, it also effectively minimizes reactions between the Al layer and the anode, significantly boosting the cell's thermal safety and puncture resistance.

    • Non-Combustible Structure

      Utilizing materials with ultra-high heat resistance and ultra-low thermal conductivity, combined with structural designs for turbulent flow cooling, pressure relief, and explosion venting, a combined design of flame propagation-resistant materials and safety structures is achieved. This results in a non-combustible structure, enhancing pack-level safety performance.

    • Cabinet-Level Explosion Prevention

      Addressing the safety requirements of cabinet products, technologies such as real-time safety monitoring, active pressure relief, passive directional explosion venting, and fire suppression linkage are employed. This provides comprehensive, multi-layered protection against thermal runaway scenarios within the cabinet, achieving cabinet-level explosion prevention.

    • Abnormal Expansion Management

      Throughout the pack product lifecycle, the cell's expansion state is managed via structural design. This establishes a structural early-warning mechanism for abnormal cell expansion, enhancing product safety performance.

    • Big Data Early Warning

      Through analysis, mining, and extraction of deep data features, the inherent relationships among characteristic variables are identified. Combined with signal detection and transmission technology, a real-time fault detection system is created to achieve battery early warning, ensuring even the most minor anomalies cannot remain hidden.

    • * The above data are from Ampace Lab.

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    Smart Management Technology

    Millisecond Precision, Whole Day Assurance

    24H
    Monitoring
    • Cell Health Monitoring

      Combining battery mechanisms with test data to construct an open-loop battery life prediction model, which is then continuously calibrated in real time through actual usage data. This enables high-precision health forecasting and real-time estimation.

    • Intelligent Fast-Charging Strategy

      Supported by an intelligent Battery Management System (BMS) fast-charging strategy, it sensitively identifies temperature and State of Charge (SOC) to enable rapid charging within the battery's healthy operating range while protecting it from potential damage caused by fast charging.

    • Battery Life Optimization

      Based on quantitative analysis of battery aging stress factors and adaptive control of these stressors during usage, the actual service life of the battery is optimized.

    • Wireless BMS

      By implementing wireless communication within the battery pack, it simplifies sampling harnesses, reduces the risk of connector failures, improves pack assembly efficiency and reliability, lowers technical complexity and overall cost, and provides better support for future intelligent management solutions.

    • Cloud BMS

      Integrating BMS with IoT functionality to form a Cloud BMS. Through machine learning training on collected data, it achieves round-the-clock battery protection. Furthermore, it supports Over-The-Air (OTA) software updates throughout the battery's entire lifecycle, making it safer, longer-lasting, and more efficient.

    • Residual Value Assessment

      Leveraging the Cloud BMS, it couples battery models with aging models to estimate cell aging parameters online and obtain information on material degradation levels. This enables precise assessment of the aging state and prediction of the cell's remaining useful life.

    • * The above data are from Ampace Lab.