Powerhobby 1s 3.7v LiPo Battery Paraboard
Powerhobby 1s 3.7v LiPo Battery Paraboard est en rupture de stock et sera expédié dès qu’il sera de retour en stock.
Powerhobby 1s 3.7v LiPo Battery Paraboard est en rupture de stock et sera expédié dès qu’il sera de retour en stock.
Description
Description
PowerHobby 1s 3.7v LiPo Battery Paraboard
Description
Charge multiple compatible 1S 3.7V LiPo batteries from a suitable charger with the Powerhobby Parallel Charging Board. The board provides six Micro Pico connections and six JST-PH connections, allowing up to six matching batteries to be connected for parallel charging.
Its compact PCB design is suitable for batteries used in popular micro helicopters, quadcopters, drones, and aircraft. The board is compatible with models such as the Blade Inductrix, Glimpse, mCP X, Nano QX 3D, Nano CP X, and Nano QX when equipped with the corresponding battery connector.
A compatible LiPo balance charger and a properly configured charging lead are required. All batteries connected simultaneously must have the same cell count, chemistry, connector polarity, and similar voltage.
Features
- Parallel charging board for 1S 3.7V LiPo batteries
- Allows up to six compatible batteries to be charged together
- Six Micro Pico battery connectors
- Six JST-PH battery connectors
- Compact and durable PCB construction
- Suitable for micro helicopters, drones, and aircraft
- Black finish
- Compact 60 x 25 x 15mm design
Includes
- One Powerhobby 1S LiPo Parallel Charging Board
Compatible Applications
- Blade Inductrix
- Blade Glimpse
- Blade mCP X
- Blade Nano QX 3D
- Blade Nano CP X
- Blade Nano QX
- Other compatible 1S models using Micro Pico or JST-PH connectors
Specifications
- Battery chemistry: LiPo
- Battery voltage: 3.7V
- Cell count: 1S
- Micro Pico outputs: Six
- JST-PH outputs: Six
- Dimensions: 60 x 25 x 15mm
- Color: Black
- Part number: PHB5003
- UPC: 735816691684
This is a connection board only and is not a standalone charger. Connect only batteries with matching specifications and similar resting voltages.


