TWO-WHEELER LITHIUM BATTERIES

ELECTRIC Two-Wheeler Lithium Batteries · LiFePO₄ · Smart BMS

Fast-Charge LiFePO₄ Batteries for E‑Scooters & E‑Mopeds

Cut weight versus lead‑acid, keep power consistent across the ride, and recharge in ~2–3 hours. Smart BMS with CAN/RS485/BLE/GPS enables hot‑swap, remote updates, and precise SOC.

Why Upgrade to ELECTRIC Two‑Wheeler Lithium Batteries?

Drop the Dead Weight

Typical lithium‑ion specific energy is 100–265 Wh/kg vs 33–42 Wh/kg for lead‑acid—so you can carry the same usable energy with far less mass. Expect snappier throttle response, better hill climbs, and easier handling.

Power that Stays Consistent

LiFePO₄’s flat discharge curve maintains steadier voltage across most of the SOC window, so acceleration and lighting remain confident until the last miles of range.

Fast Turnaround

Validated 0.5–1C profiles enable ~2–3 hour charging with the right charger and thermal management—ideal for delivery fleets and swap stations.

Product Lineup & Specifications

Model	Nominal Voltage	Chemistry	Capacity (Ah)	Max Charge Current	Max Cont. Discharge	Peak (3 s)	Dimensions (mm)	Weight (kg / lbs)	Interfaces
SPF48V20	51.2 V (16S)	LiFePO₄	20	15 A (TBC)	20 A	40 A	275×155×115	8.5 / 18.7	CAN, RS485, GPS, BLE
SPF48V30	51.2 V (16S)	LiFePO₄	30	15 A (TBC)	30 A	50 A	193×153×328	13.8 / 30.4	CAN, RS485, GPS, BLE
SPF60V30	64.0 V (20S)	LiFePO₄	30	15 A (TBC)	30 A	50 A	193×153×354	18.5 / 40.8	CAN, RS485, GPS, BLE

Notes: LFP cell nominal ≈ 3.2 V → 16S ≈ 51.2 V; 20S ≈ 64.0 V. Charging via CC/CV per BMS limits. Values marked TBC to be confirmed in the final validation report.

Compliance & Shipping

UN 38.3 Ready

All lithium batteries are shipped with UN 38.3 testing completed. We provide a Test Summary for your forwarder and airline checks.

IATA & PHMSA Documentation

Packing instructions, MSDS, labels, and the latest guidance references are included in your shipping file.

Traceable Batches

Each lot includes serial tracking, QR codes for event logs, and links to firmware baselines for post‑market support.

Smart BMS, Smarter Operations

Every pack integrates a Smart BMS with CAN/RS485/Bluetooth/GPS, coulomb counter + fuel gauge, and safeguards such as anti‑spark and hot plug‑in/out. Accurate SOC removes guesswork for riders, and remote updates keep the system current without pull‑backs to service depots.

Open interfaces for easy controller/charger integration
Swap‑ready mechanical & electrical design
Diagnostics: SOH, cycle count, event logs

Built for Real‑World Two‑Wheeler Operations

E‑scooters & e‑mopeds: predictable voltage and torque across most of the ride.
Battery swapping networks: hot‑swap connectors, GPS for fleet ops, remote updates.
Last‑mile logistics: 2–3 h charging fits into cycle breaks and shift patterns.
Municipal & campus fleets: low downtime, accurate SOC reporting.

Frequently Asked Questions

How much lighter are these than lead‑acid?

Lithium’s typical 100–265 Wh/kg vs ~33–42 Wh/kg for lead‑acid means equivalent energy at far less weight. Savings vary with enclosure and options.

Why is power more consistent at lower state of charge?

LiFePO₄’s flatter discharge curve keeps the system voltage steadier across most SOC, maintaining throttle feel and lighting performance.

Can we reliably charge in 2–3 hours?

Yes,given the correct charger, BMS limits around 0.5–1C, and thermal management. We supply validated profiles with the engineering pack

What about safety?

LFP is more tolerant to abuse versus many high‑nickel chemistries. Nonetheless, we rely on system‑level protections, QA, and UN 38.3 testing.

Upgrade Your Platform

Request a quote and receive the engineering pack (mechanical drawings, connector pinouts, CAN DBC, RS485 map, charge/discharge curves, UN 38.3 Test Summary). Pilot units are available for validation.