Description
Lightweight High-Rate Battery Series | ATOMFAIRCOMMERCIAL GRADE · PRODUCTION
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TAILORED SOLUTIONS FOR RESEARCH
Contact our engineering team for technical support or official institutional quotations.
EMAIL: inquiry@atomfair.com
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Manufacturer: Atomfair LLC
Brand: ATOMFAIR®
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These pouch cells require controlled storage and handling to maintain performance and prevent safety hazards. Adherence to charge/discharge rate limits and physical inspection protocols is critical for safe operation.
- Charge Rate Compliance: Adhere to the model-specific maximum charge rates: 6C for AFWR8066133 and 1C for AFWR9066133 and AFWR1074172.
- Discharge Rate Limits: Observe the model-specific maximum discharge rates: 12C for AFWR8066133, 6C for AFWR9066133, and 3C for AFWR1074172.
- Storage Environment: Store cells in a cool, dry environment away from flammable materials and direct sunlight to minimize degradation.
- Cycle Life Management: Expected cycle life is 2000 to 6000 cycles at 80% SOH depending on usage conditions and depth of discharge.
- Physical Integrity Check: Visually inspect pouch cells for swelling, punctures, or electrolyte leakage before each use to detect latent damage.
This guide provides the essential steps for initializing and safely operating the high-rate battery cells. Following these procedures minimizes risk of damage or failure during charging and discharging.
Required Equipment: Digital multimeter, Programmable battery charger, Infrared thermometer or thermal camera, Fireproof storage container
- Inspect Cell Before Handling
Inspect the cell's outer pouch and terminals for any signs of damage or contamination before handling. - Measure Open-Circuit Voltage
Measure the open-circuit voltage to confirm it is within the acceptable range for the model. - Connect to Charger
Connect the cell leads to a programmable power supply set to the model's maximum charge rate. - Monitor Temperature During Charging
Monitor the cell surface temperature during the charge cycle and interrupt if abnormal heating occurs. - Disconnect After Full Charge
Disconnect the cell after full charge and allow it to rest for at least 30 minutes before discharge. - Connect to Load
Connect the cell to the load, ensuring the discharge current does not exceed the model's maximum rated discharge rate. - Store After Discharge
After discharge, store the cell in a cool, dry place at partial state of charge if not used immediately.
How does the trade-off between maximum discharge rate and cycle life scale across the AFWR8066133, AFWR9066133, and AFWR1074172 models?
The 8Ah AFWR8066133 delivers the highest peak discharge at 12C but achieves only 2000 cycles at 80% SOH, while the 17Ah AFWR1074172 offers a lower 3C maximum discharge rate yet reaches 6000 cycles at 80% SOH. The 13Ah AFWR9066133 sits in between with a 6C discharge rate and 3000 cycles at 80% SOH. This inverse relationship means engineers must prioritize either instantaneous power delivery or long-term operational lifespan when selecting a model.
Can the AFWR9066133 or AFWR1074172 models be integrated into existing drone battery management systems designed for 4.2V maximum cell voltage?
No, direct integration may require BMS reconfiguration because the AFWR9066133 operates up to 4.3V and the AFWR1074172 up to 4.35V, exceeding the standard 4.2V cutoff for many legacy lithium-polymer systems. The AFWR8066133 also charges to 4.3V, so all three models demand a BMS and charger rated for the higher upper voltage limit to avoid undercharging or safety issues.
What are the critical handling and storage requirements for these semi-solid electrolyte pouch cells to prevent performance degradation?
These cells require moisture-barrier vacuum-sealed aluminum packaging to protect the semi-solid electrolyte from atmospheric humidity, which can degrade ionic conductivity and cycle life. Charge temperature must be strictly maintained between 0°C and 45°C; charging below 0°C risks lithium plating and internal short circuits. Discharge below -20°C is not permitted for the 8Ah model, which has a -10°C lower limit, while the other two models tolerate -20°C discharge.
This semi-solid electrolyte pouch cell series delivers up to 12C discharge on the 8Ah model and cycle life reaching 6000 cycles at 80% SOH on the 17Ah model, but charge temperatures are limited to 0–45°C and maximum discharge rate declines significantly with higher capacity.
Positive
- Extreme High-Rate Capability: The 8Ah model supports up to 12C discharge, providing instantaneous power delivery for demanding drone and power tool applications.
- Ultra-Long Cycle Life: The 17Ah model achieves 6000 cycles at 80% SOH, substantially reducing battery replacement frequency in long-duration deployments.
Trade-offs
- Restricted Charge Temperature Window: All models require charging between 0°C and 45°C, necessitating thermal management in cold environments to avoid damage or capacity loss.
- Capacity-Dependent Discharge Rate: Maximum discharge rate drops from 12C (8Ah) to 3C (17Ah), so higher-capacity cells cannot deliver the same peak power as smaller ones.
Every advanced material, component, equipment, and instrument in our catalog is backed by rigorous testing. We maintain strict internal quality management frameworks and align with CE conformity metrics to deliver transparent, reproducible performance data via our public open-science repository.
To request raw batch performance data, submit formal vendor registration paperwork, or execute a fast-turnaround R&D manufacturing loop, contact us at inquiry@atomfair.com.
Item is dispatched under the Atomfair Shipping & Delivery Framework (Free worldwide shipping on orders over $59 USD). Return is governed by the Atomfair Return & Refund Policy (7-day technical return window).
