Fleet Electric Bike Lock OEM IoT Integration Bike Lock For Electric Bike
| Model: | DCS1730 / DCS1738 | Buyer Intent Focus: | Controller And IoT Integration For Fleet Battery Access |
| Target Vehicle Type: | Shared E-Bikes / Rental E-Bikes / Electric Scooters / OEM Fleet Platforms | Fleet Access Value: | Vehicle-Side Remote Battery Lock And Unlock Control |
| Controller Integration Value: | Connects With Controller, IoT Or Battery-Side Power Source | Communication Interface: | UART / RS485 / CAN For OEM Vehicle System Matching |
| Model Selection Logic: | DCS1730 For High Pull-Strength Security / DCS1738 For Smart Remote Battery Management | Battery Status Value: | DCS1738 Direction Supports Battery Presence Detection For Fleet Management |
| High Light: | fleet electric bike lock,electric bike lock oem,iot integration bike lock for electric bike |
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The Fleet Battery Lock is designed for shared e-bikes, rental e-bikes, electric scooters and OEM fleet platforms that need battery access controlled through the vehicle electronics. It supports controller, IoT or battery-side integration so battery lock and unlock actions can be managed by the vehicle system.
For fleet operators, battery access is both a security issue and an operating workflow. A smart battery lock helps keep removable power modules secured inside the vehicle while allowing authorized remote access through the connected control architecture.
DCS1730 is suitable when fleet battery access also needs stronger physical retention, while DCS1738 is suitable when remote management and battery presence detection are the primary selection factors. OEM teams can select the final direction according to controller interface, IoT wiring, battery compartment structure and access logic.
- Fleet Battery Access Control: Designed for shared and rental vehicle battery lock management.
- Controller And IoT Integration: Works with controller, IoT or battery-side systems using source-listed interfaces.
- Remote Lock And Unlock Operation: Supports vehicle-side electronic control of battery compartment access.
- DCS1730 High-Strength Direction: Suitable for fleets requiring stronger removable battery holding security.
- DCS1738 Smart Management Direction: Suitable for remote battery management and battery presence detection.
- Concealed Battery Compartment Mounting: Installs around the rear seat or battery compartment area for cleaner vehicle integration.
- IPX7 Whole-Unit Protection: Supports outdoor fleet operation, washing and wet-use environments.
- No Wheel-Speed Logic Required: Battery access control is independent from wheel speed sensing or brake-lock safety logic.
| Parameter | Specification |
|---|---|
| Reference Models | DCS1730 / DCS1738 |
| Product Category | E Bike Battery Lock |
| Voltage | 5V DC / 48V DC |
| Communication | UART / RS485 / CAN |
| Power Source | Controller / IoT / Battery |
| Electronic Protection Speed | Not Required |
| Speed Sensing Distribution | Not Required |
| Spoke Hole | None |
| Product O.L.D. | None |
| Axle Hole Size | None |
| Hub Axle | None |
| Main Axle Load Strength | None |
| Brake Diameter | None |
| Brake Interface / Braking Performance | None |
| Operating Temperature | -20°C To 65°C |
| Waterproof Rating | IPX7 Whole Unit |
| High Temperature Storage | 80°C ± 2°C For 48 Hours |
| Low Temperature Storage | -30°C ± 2°C For 48 Hours |
| High Temperature And Humidity | 65°C, 95%RH, 48 Hours |
| Salt Spray Test | 72 Hours, Neutral |
| Mounting Position | Rear Seat / Battery Compartment Area |
| Certifications | RoHS / REACH To Be Confirmed Against Final Compliance Documents |
| Reference Model | Product Name | Model Positioning | Pull Test | Fleet Battery Access Use |
|---|---|---|---|---|
| DCS1730 | High Pull-Strength E-Bike Battery Lock | High Pull-Strength / Anti-Theft Battery Security | >=800kgf | Use when fleet battery access also requires stronger battery holding security. |
| DCS1738 | Smart E-Bike Battery Lock | Smart Remote Battery Management | Not Provided | Use when fleet battery access control and battery presence detection are key requirements. |
The lock connects to the vehicle-side control system and performs lock or unlock action after receiving authorized commands. This allows battery access to become part of the fleet vehicle management workflow.
Controller and IoT integration are the main procurement value. The lock can be matched to the vehicle's power supply and communication interface, helping OEM teams coordinate battery access with the rest of the connected vehicle system.
For fleet platforms, final selection should consider both security and operating workflow. DCS1730 emphasizes battery holding strength, while DCS1738 emphasizes smart remote management and battery status support.
This fleet battery lock direction is suitable for shared e-bike fleets, rental e-bike platforms, electric scooter fleets and OEM mobility vehicles that require controlled battery access through controller or IoT integration.
It is especially useful for projects where battery modules need to remain removable for charging or maintenance, while access must be managed through the vehicle's electronic control architecture.
Before sampling or production, confirm controller interface, IoT wiring route, battery compartment size, battery removal path, lock direction, voltage, communication protocol, waterproof requirement and access authorization logic.
Q: What is the main buyer intent of this product page?
A: It targets fleet battery access control through controller and IoT integration.
Q: Which reference models are used?
A: The page references DCS1730 and DCS1738 in the E Bike Battery Lock series.
Q: How should DCS1730 and DCS1738 be selected?
A: DCS1730 is the high pull-strength battery security direction, while DCS1738 is the smart remote battery management direction.
Q: Does it require wheel speed sensing?
A: No. Battery compartment locking does not require electronic protection speed or speed sensing distribution.
Q: What communication interfaces are supported?
A: The reference parameters list UART, RS485 and CAN communication.
Q: What should be confirmed before installation?
A: Confirm controller interface, IoT wiring, battery compartment structure, voltage, communication protocol and lock matching space.
