RioRand 350W 6-60V 3-Phase PWM DC Brushless Motor Speed Controller with Hall Sensor – for 120° Electric Angle Brushless DC Motors, DIY Robotics, Electric Tools & PLC Systems

So far it works well. I need to address the direction control on the Hall model. The motor will run in a couple different phase wiring orders, if you have it in the wrong order the reverse direction switch does not work. Once you fix that, it reverses perfectly.

Note - many of the questions/answers displayed for this item are actually for the Hall Sensor version so please be careful and don't assume all those answers apply to this module. This listing is for the "Hall-less" version, meaning it's for controlling a 3-phase DC motor that only has 3 wires and does NOT use hall sensor monitoring. Some errors I noted in the Q/A section: - some Q/A indicate the module has "soft-start" - it does not, but see my easy hack to add it below* - some say to "remove the jumper" to use the external analog speed control - there is no jumper on this module, just be sure to set the on-board speed pot to zero (full ccw) - some say this module will not work with a Hall-less motor - that is WRONG, it is specifically designed to work with hall-less motors. - there are several different wiring diagrams shown in the listing, but the one that has pictures of the motor and power supply is what I used and seems to be correct. I used this controller to operate the fan motor from an EGO leaf blower that was trashed because the internal controller died. My fan motor has 3 leads - red, blue, and yellow, which connect to the controller terminals red to red, blue to blue, and yellow to green. I'll use this fan blower with some 18v cordless tool batteries as a sweeper in my shop and patio, and 18v yields plenty of air flow for that purpose. * I made a simple modification to perform a soft-start function, using a 470uf capacitor and a 1k resistor (see photo and video). Some experimenting proved that the external potentiometer speed control reaches maximum motor speed at about 4.6v, which can be achieved by placing a 1k resistor from the 5v terminal to the analog speed input. By adding the capacitor, the voltage on the speed input slowly rises when power is applied, so that the motor speed ramps up from zero to full speed in about a second, greatly reducing the strain on the power supply, controller, and the motor. If you want a slower start-up you can increase the size of the capacitor, but leave the resistor at 1k. If you increase the resistance above 1000Ω the motor will never reach full speed.

I first bought two of these for controlling hoverboard motors in a project. Wiring them wasn't too difficult, once I figured out the correct phase wires for my motors. For anybody who can't figure this out: take the 6 or 8 screws off the inside of the hoverboard wheel, then use two flat screwdrivers to pry the cover off the wheel. Inside should be a label for each phase wire. I set up my pots and switches for brake/reverse. Don't use the stop function, just use brake. Everything was working as intended. Once proof of concept was achieved, I needed to use an arduino with PWM control to use an RC receiver. This is where my problems began. First of all, I'm new to arduino so it was a bit of a learning experience. I have other programming language experience so it helped a lot. Once I got my code setup, I jumped my J1 on the board and hooked up everything else. Plugged in power, and the LED instantly turned on then off again. Uh oh. Well, I'll spare the details but two boards later everything is working. I'm still not sure what exactly went wrong the first two times but my best guess is that I accidentally shorted something else when jumping J1 or something. Third board works fantastic though with PWM control with a remote control/arduino. SUMMARY This board is a great value for the price, just be aware that if anything goes wrong or if you need any details about this board, good luck finding it. There's basically no documentation for this board other than the listing on Amazon.

I have been saving some 3 phase motors....BLDC and PMSM type, for a long time. This board is awesome. I can easily drive 24V PMSMs (see video). It stays winter cool to the touch! I want to stress that I'm no where NEAR the 380W limit of this thing. I hope another reviewer can attest to the max capabilities. But if you're looking at driving small to medium size BLDC or PMSM, this is a great option. I was going to upload a nice video of a gorgeous BLDC from a tape drive, but it's enormous. I'll just upload pictures...It drove a nice fat motor too (see photos). For anyone wondering, you can run hard drive motors, too. Looking forward to using these for some projects to reclaim bad or old hard drives! I actually tested this on a WD raptor spindle and some other seagate disk spindles. Works great. You just need to figure out which motor contact is the center tap. Remove this from what you connect. The remaining three should connect to UVW. It will spin just fine without a common terminal. Definitely usable. I didn't try the PWM control feature yet. I've been using the onboard potentiometer to control speed. If you want to use PWM or DC voltage for this, remove the jumper. It's not clear, but I think that's what it does. Connection a pot as shown in the photos gives you DC voltage control (like the onboard pot), and pumping a square wave into it instead will give you PWM control. The way the PWM input works, it probably just low-pass-filters the input signal. If it's PWM, it gets converted to DC voltage. If it's DC voltage, it goes through the filter the same way. If you want to run a BLDC or PMSM motor by variable speed (without speed feedback) this board is going to do it for you.

These motor controllers work well with big DC motors. You can only run one motor off of each one. You do not have to use all of the pins to control the device with arduino or esp32. R_ls and L_ls can be left with no connection. The enable pins can simply have 5v applied directly or can be switched. The only thing that might be of concern is the heat sink is on the other side of the board from the mosfets. I really don't think that they will dissipate any heat the unit heats up under high load.

es funcional y cumple con su cometido sin embargo al arranque tiene un pequeño retraso de 1 segundo

Really simple and good to use

Works well. It does get hot so I'm using a small fan. Running a rad fan on one and coolant pump on the other.

Used on a hoverboard motor and works well.