Smart Power Distribution Board – Hi Base
Easy Switching named as: Hi-Base
The Hi-Base Power Distribution Card allows you to perform switching operations easily from an enclosed enviroment. Thanks to the magnetic switching method, you can turn on and off your system safely with a magnet. Provides ease of use and safety with the automatic shutdown feature by the processor in adverse situations.
Instant Intervention from Microcontroller
The power distribution card, Hi-Base, allows you to turn on and off your device remotely with the logic signal from the microcontroller. In short, by connecting the microcontrollers digital pin to On-Off JST port on Hi-Base, you can remotely turn off the system when you apply HIGH from the port and power on the system when you apply LOW.
High Voltage is not a deal!
Hi-Base offers a logic level voltage measurement with voltage output port. Hi-Base is compatible with 6-48 Vdc input voltage and a variety of battery types from 2s to 12s. Therefore, it makes it ideal for use in a wide range of applications.
High Performance and Durability
Hi-Base has a maximum current and 60 Amp continuous current capacity of up to 120 Amps. Designed for projects requiring high power, it stands out from other pdb boards with its small size, wide voltage range and battery type variety. Thus, it provides a solution suitable for all kinds of energy management needs, from DIY projects to industrial applications.
JST Outputs For Ease of Use
Who needs a hard to find weird named connector when you have micro JST. This is why all of the outpus on Hi-Base are only micro JST
Voltage sensor output offers real-time voltage monitoring.
Hall sensor output precisely measures the direction and turns system ON/OFF
Thermistor output follows temperature changes instantaneously.
You can also manage the card remotely with the On/Off output,its a lovely feature rc cars, rc boats and rc planes. For example, turn off by applying 5V and turn on with 0V. This card not only makes energy management simple, convenient and effective, but also gives superior adaptation and precision to your projects. With a compact size of 45 x 45 mm, Hi-Base is coming to open new horizons in your projects!
Power Distribution Card Hi-Base Specifications
| Main Features | |
|---|---|
| Voltage Measurement | It allows the user to monitor the voltage change in detail. |
| Magnetic switching | It allows the device to turn on and off through a magnetic field, without requiring physical contact. |
| External switch | It allows users to control the device through an external key. |
| Cooling | Not included – Done by user |
| Electrical Characteristic | |
| Maximum Current | 120 Amps (tested up to 120 amps.) |
| Continuous Current | 60 Amps |
| Input Voltage | 6-48 Vdc |
| Types of Battery | 2s to 12s |
| Physical Property | 45 x 45 mm |
What’s in the box?
- Hi-Base Power Distribution Card
- Hall Effect Sensor
- 14 Awg Black Silicone Cable (8cm)
- 14 Awg Red Silicone Cable (8cm)
- Male XT90 Connector
- Female XT90 Connector
Frequently Asked Questions
How many motors can I solder to the output line?
You can make as many connections as you want but don’t exceed 120 amps on the output line. All you need to calculate here is the total maximum current load of the devices you will install. As an example, you can connect 6 motor drives (10Ax6=60A) operated with a minimum current here. If you connect 12, that will be 120 amps, if sufficient cooling is done, this will not be an issue.
How exactly does the magnetic switching system work?
The switching system on the main line turns off the entire power system with a magnetic sensor. It turns on with a magnetic pole that is brought in front of the sensor, and turns off with the inverse pole.
Does it cause problems for me to use high current continuously?
Keep in mind that although it does not pose an electronic problem, it will cause high current to heat in the system. Therefore, if the current is pulled over 80 amps above 1 minute without interruption, the system can be severely heated with high current. You can provide extra cooling by adding a heatsink on the mosfets. However, we would like to point out that we have tested the power distribution card for 10 minutes at 60 amps of current. At higher currents, we recommend that you establish a precautionary mechanism that will monitor the temperature of your system with built in NTC Sensor.
