Email : collin@runingpower.com
Technical Resources for Industrial Lithium Battery Applications
Runing Power provides comprehensive technical resources to help engineers, procurement specialists, and fleet managers make informed decisions about LiFePO₄ battery integration. Access product datasheets, safety certificates, and in-depth technical articles covering low-temperature performance, high-rate AGV battery communication protocols, energy storage system design, and global compliance standards (EU Battery Regulation, UN38.3, CE/UL).
Technical Library – Datasheets, Certifications & Compliance Documents
Access critical technical documentation for Runing Power LiFePO₄ battery products—from detailed specification sheets to international safety certifications and EU Battery Regulation compliance resources.
Product Datasheets
- 48V 28Ah – 48V 100Ah AGV & Robotics Battery Specifications (discharge curves, cycle life, mechanical drawings)
- 28.8V 100Ah Low-Temperature LiFePO₄ Battery Datasheet (-35℃ discharge performance)
- 48V 40Ah / 51.2V 40Ah Golf Cart Battery Datasheet (Bluetooth SOC monitoring specs)
- 48V 50Ah / 100Ah Rack-Mount ESS Datasheet (scalable storage, EMS integration)
- UN38.3 Test Summary (air/sea transport compliance – effective January 1, 2026, mandatory 30% SoC for air shipment now applies to batteries packed with equipment)
🔗 External reference: UNECE UN38.3 Official Testing Manual (dofollow authority link) - MSDS (Material Safety Data Sheets for LFP chemistry)
- CE Declaration of Conformity (LVD, EMC, RoHS)
- ISO 9001:2015 Quality Management Certificate
- GB/T 31484 / 31485 / 31486 Test Reports (China national EV battery safety standards)
Safety & Transport Certifications
EU Battery Regulation (EU) 2023/1542 Resource Center
The EU Battery Regulation fully replaced the old Battery Directive on August 18, 2025, imposing stringent requirements on industrial battery exporters. Since August 2024, industrial batteries >2kWh have required carbon footprint declarations. From February 18, 2027, the Battery Passport becomes mandatory, disclosing material sources, carbon footprint, recycled content, and performance data.
External resources: Full text of EU Battery Regulation 2023/1542 (EUR-Lex) (dofollow) | European Commission Batteries Portal (nofollow reference)
Downloadable resources: EU Battery Regulation 2023/1542 – Compliance Checklist for Exporters · Carbon Footprint Declaration Methodology Guide (EU PEF-compliant) · Supply Chain Due Diligence Requirements Summary · Battery Passport Readiness Assessment Template
Need a specific document? Contact our compliance team at tech@runingpower.com (internal contact)
Knowledge Center – Technical Articles & Industry Insights
In-depth technical articles written by Runing Power engineers. Each article addresses real-world challenges faced by industrial lithium battery users, with actionable insights based on actual product data.
Low-Temperature LiFePO₄ Battery Performance – From -20℃ to -35℃
Cold storage, freezer warehouses, refrigerated logistics – Self‑heating BMS technology vs. external heater systems: energy efficiency comparison. Discharge capacity retention data across temperature ranges (models retain >85% at -20℃). Impact of freeze–thaw cycles on LFP pouch cells (polarization resistance increased approximately 40.57 mΩ at -10℃ test conditions). Electrolyte formulation for low-temperature lithium transport. Real-world case study: German cold storage AGV fleet – 99.5% uptime at -25℃.
🔗 External reference: MDPI Batteries journal – Freeze‑thaw cycling effects on LFP cells (nofollow academic reference)
Air freight, shipping regulations, safety compliance – 8-test sequence for UN38.3 certification: altitude simulation (-40℃ to 75℃ thermal cycle), vibration, shock, external short circuit (55℃), overcharge, forced discharge, and 3-meter stack test (2026). Effective January 1, 2026, the mandatory 30% maximum SoC limit for air shipment now applies not only to loose batteries (UN3480) but also to batteries packed with equipment (UN3481). Shipment documentation requirements: test summary, packaging specifications, dangerous goods declaration. Third-party testing lab qualification requirements (CNAS/CMA).
🔗 External authority link: IATA Dangerous Goods Regulations (Lithium Battery Section) (dofollow)
UN38.3 Transport Compliance – What 2026 Rule Changes Mean for Lithium Battery Shippers
RS485 vs. CAN Bus – Choosing the Right Communication Protocol for AGV Battery Integration
AGV battery, industrial robotics, BMS communication – Technical comparison: CAN (1 Mbps, deterministic, collision detection) vs RS485 (Modbus RTU, up to 10 Mbps, simplex). Compatibility with major AGV controllers (Siemens, Beckhoff, KUKA, SICK). Dual‑channel redundancy for safety‑critical signals – ensures SOC accuracy above 95% through advanced coulomb counting algorithms. AGV control systems utilize various communication protocols; BMS data transmission failures often occur when vehicle controllers and custom voltage platforms cannot properly exchange real-time battery status.
🔗 Internal link to related products: View our AGV battery portfolio · AGV battery solution page
Fleet operations, battery upgrade ROI – LiFePO₄ initial investment: $17,000–$20,000+ (48V 100Ah) vs. lead‑acid: $2,000–$6,000. LiFePO₄ lifespan: 3,000–5,000+ cycles / 10+ years; lead‑acid: 300–500 cycles / 2–5 years. LiFePO₄ requires zero maintenance (no watering, no equalization, no terminal cleaning); lead‑acid requires frequent watering, cleaning, acid handling. Weight difference: LiFePO₄ 48V 100Ah pack ~20 kg vs. equivalent lead‑acid pack 350–400 kg. Real fleet result: 96‑cart fleet upgrade – 70% lower maintenance cost, daily runtime doubled from 6 hours to 12 hours. Safety: LiFePO₄ (no flammable gas emissions, no acid leaks) vs. lead‑acid (hydrogen gas, corrosion hazards).
🔗 External reference: DOE historical battery cost data (nofollow reference)
LiFePO₄ vs. Lead‑Acid – Total Cost of Ownership Comparison for Golf Cart Fleets
EU Battery Regulation 2023/1542 – What Industrial Battery Exporters Need to Know for 2025–2027 Compliance Timeline
Export regulations, market access compliance – Comprehensive analysis of five critical compliance areas: Safety & sustainability (stationary ESS must pass EN IEC 62619 and UL 1973, including thermal runaway propagation testing). Carbon footprint (for EV batteries and industrial batteries >2kWh, carbon footprint declaration is required, calculated according to EU PEF methodology). Battery Passport (mandatory for >2kWh industrial batteries from 2027, disclosing material sources, carbon footprint, recycled content, and performance data). Extended Producer Responsibility (registration in EU member states or PRO membership required for battery collection, treatment, and recycling). Supply chain due diligence (cobalt, lithium, nickel must comply with human rights and environmental risk management standards).
🔗 Internal resources: EU compliance document downloads · Our certifications page
Our technical documentation library is organized by product category and application area. For immediate assistance:
- 📄 Download Datasheets – browse product‑specific specification sheets at Technical Library
- 📖 Access Certificates – view and download safety certifications, UN38.3 test summaries, EU compliance documentation
- ✍️ Technical Support – direct email to our engineering team for documentation requests beyond the library
Contact our technical documentation team: tech@runingpower.com
