CC-CV

Articles, guides, and products tagged "CC-CV" — a combined view of every catalogue resource on this topic.

User guide

Lithium-ion e-scooter battery engineering: electrochemistry, BMS, thermal runaway, safety standards and life cycle

Engineering deep-dive into lithium-ion batteries — paralleling the behavioural «Charging and battery care» guide: intercalation physics and why graphite-LiCoO₂ yields a 3.7 V nominal cell, while LFP gives 3.2 V; why NMC delivers 200–250 Wh/kg vs. 90–160 in LFP; 18650 / 21700 / 26650 / pouch / prismatic formats — geometry, Wh/L density, heat dissipation; full BMS architecture — protection MOSFETs, passive vs. active balancing, coulomb-counting vs. Kalman SoC estimation, CAN/UART/SMBus telemetry; thermal runaway physics — Arrhenius kinetics, SEI decomposition at 80 °C, separator melt at 130 °C, cathode breakdown at 200 °C, exothermic cascade, propagation prevention through cell spacing and ceramic separator; complete comparative matrix of safety standards — UL 2271 (light EV battery pack), UL 2272 (e-scooter system), UL 2849 (e-bike system), EN 50604-1 (Europe LEV), EN 17128 (Europe PLEV), IEC 62133-2 (cell-level), UN 38.3 (transport — 8 tests from altitude through vibration), UN R136 (type approval); life-cycle physics — cycle aging (DoD effect, capacity fade vs. internal resistance growth), calendar aging (Arrhenius), end-of-life criteria (80% SoH industry threshold); series-parallel voltage topology 10S2P → 13S3P → 16S4P and why 36/48/52/60/72 V became standard.

16 min read

User guide

E-scooter charger engineering: SMPS topologies (flyback / forward / LLC), CC-CV algorithm, galvanic isolation (PC817 + TL431), IEC 62368-1 hazard-based safety, EMC (CISPR 32, FCC Part 15B), efficiency standards (US DoE Level VI, EU CoC Tier 2, Energy Star), connectors (GX16 / XLR-3 / XLR-4 / barrel jack), protection circuits

Engineering deep-dive into the only AC-domain peripheral of an e-scooter — the charger as a switched-mode power supply (SMPS) that takes 100-240 V RMS sinusoidal mains and delivers 42 / 54.6 / 67.2 / 84 / 100.8 / 126 V DC through a CC-CV charging algorithm. Why a 42-V Xiaomi M365 charger (71 W, 1.7 A) gets away with a flyback topology, while an 84-V Dualtron Thunder 3 fast-charger (840 W, 10 A) requires an LLC-resonant half-bridge with ZVS/ZCS soft-switching. Why galvanic isolation via the PC817 optoisolator (5000 V RMS withstand) plus the TL431 precision shunt regulator is the standard architecture for feedback across the safety-critical barrier. Why IEC 62368-1:2018 hazard-based safety engineering with ES1/ES2/ES3 (electric source) + PS1/PS2/PS3 (power source) + TS (touch surface) replaced legacy IEC 60950-1 in EU/UK in December 2020. Why CISPR 32 Class B residential limits (150 kHz-30 MHz conducted, 30 MHz-1 GHz radiated) run ~10 dBμV/m below Class A industrial. Why US DoE Level VI (federally mandatory since 2016) caps no-load to 0.100 W on chargers ≤49 W, and the upcoming Level VII (~2027) cuts that another −25 %. Why 5 output-connector types (GX16 with locking ring, voltage-only XLR-3, voltage+BMS-data XLR-4, cheap-but-failure-prone DC barrel 5.5×2.1 mm and 5.5×2.5 mm, experimental USB-C PD) determine field-replaceability versus vendor lock-in. And why a 50,000-100,000-hour MTBF Class A figure is fundamentally an Arrhenius-rule function of electrolytic-capacitor thermal stress (life doubles per 10 °C lower internal temperature).

17 min read