Making PCB Motor v3

You could increase the torque even more, like, A LOT, by putting a piece of iron on top of the rotor, right on the back of the magnets. Brushless motors have so called "back iron" which is the iron ring where the magnets stick to. Yeah that's not alluminium. The magnetic circuit otherwise closes behind the magnets in the air which has a very high reluctance. You can cut such a piece from the iron of an old transformer with big scissors. Since this piece of iron will provide structure you could save part of the gained weight by slimming the aluminium part. This is my field of expertise.

I can smell a quadcopter business card on the horizon

Your work is super cool Carl. Keep it up!

The delta would be usable with half the voltage.
Scaling up motors to the industrial scale, 3 phase motors come as user configurable as Star or Delta.
In Australia, the single phase power is 240Vac while 3 phase is 415Vac.
When using a single phase to 3 phase inverter to drive a motor, it is normal to connect the motors in the delta config. but when used on the 415Vac 3 phase, we connect them in the star config.
In your demo, you were using 5V, so there is no reason why it shouldn't work at 2.5V in the delta config.
Nice job by the way.

That was excellent, and I appreciate your sense of humor integrated with the technical information. I wish I found your channel sooner.

Hmm is getting better and better! Good job!

Carl, your work is really amazing, especially because you do innovations. Infact your videos, compared with the others, are really mind stimulating. Thank you so much ☺️

Cool stuff. The first thing that comes to mind in terms of practical applications when seeing this version is the LSU polygon motor in a laser printer. It's a motor that spins up a polygon mirror attached to it. The mirror then deflects the printer's laser beam to make it cycle through the page in a predictable manner.
I think you'll need at least 15000 RPM for this motor to be practical in that role, and that speed needs to be sustained and incredibly stable. On the upside - no need for high torque whatsoever. With your setup, the mirror and the magnet housing might as well be the same piece, so the only thing the motor would have to spin up is itself.
The same type of mirror unit can be used in a variety of laser devices, such as laser projectors or LIDAR-like sensors.

love the fact that you use your skills to create original new stuff, i can relate.

I have watched a few of your videos, and I absolutely love them😃 You make videos and projects like no one else keep it up!

I like the way you build your motors. *HAMMERS EVERYTHING*

You are such a pleasure to watch and learn from. We send our best wishes to you.

Impressive work!

This is much look better than last time

Excellent work. Top of the world technology development. Keep rolling.

Superb video as always 🤩. Waiting for its final prototype. Keep it up sir

Excellent job

With a proper driver and commutation using hall sensors, the basics involved are this:
Current = Torque. Speed = Voltage.
A proper motor driver will reduce current when the commutation is in phase with no lag, so low heat and high efficiency at all speeds. At higher velocity, the current for the torque remains constant if you ignore friction and induced current loss in the conductive magnets.
This motor control can be performed with an inefficient class AB analog amplifier/driver to feed the commuted 3 phase drive to the motor using 3 hall sensors and 4 quadrant analog multipliers to generate drive signals to the amplifier which is configured not as a voltage amplifier, but a voltage to current amplifier. Motor drag, is responded with a change of current to maintain the correct speed by adjusting current to change torque. As the motor runs slow or faster, the voltage to current amplifier automatically adjusts voltage based on motor back EMF to apply the correct committed torque at all speeds.
For higher efficiency, a high speed PWM voltage to current driver can be used instead to produce the 3 phase currents required. If you change from a 3 phase design to a 90 degree 2 phase design, cheap stepper motor drivers can be used to run constant current, thus constant torque and constant heating in the motor at all speeds. Use higher supply voltages for higher maximum speed. To grasp the concepts, stepper motors are inexpensive in smaller sizes along with off the shelf stepper motor drivers. Play with and learn stepper motor driver theory and technology to transfer to your PCB motor designs. You can buy 3 phase versions, but they are less common and more costly.
www.amazon.com/dp/B00PNEQ79Q?tag=duckduckgo-d-20&linkCode=osi&th=1&psc=1
Stay away from the arduino stepper H Bridge drivers. They are made for slow speeds such as 3D printers. To learn motor drive and view waveforms, get a real CNC style stepper motor driver.
www.amazon.com/Usongshine-Stepper-Controller-Leadshine-2-Phase/dp/B07PHLJM22/ref=sr_1_36?dchild=1&keywords=stepper+motor+controller&qid=1592375778&s=electronics&sr=1-36
You set the desired current in dip switches, and your maximum speed is limited by your maximum voltage used. If 1 Amp is too much, you can buy smaller motor drivers.

Good research Carl 👏👏

It looks more stable than the last one!

nice work, interesting research

Smash assembly, I love it!

#60.
These motors are very cool and have so many uses. It's hard to find good info about them, so Thanks for making these vids.

great job, keep going and waiting for dron

yeah the new pcb motor look more promising. Good Job !

This channel is underrated.

You have a really charming style! Keep it up!

Very good progress! As stated by others, you need back iron to couple the magnets and complete the magnetic circuit. This will also keep the magnets from being demagnitized as easily.

Excellent video 👌

i love that miller!

I really like this project. I'm going to be thanks about tall the possible variations and potential design changes all day now.🤯

and the coolest diy i've ever seen

Consider that aluminum will have eddy currents through it and consider halbach array of magnets too! Just a thought, don't judge :)

Would probably really benefit from a ferromagnetic core in the windings somehow. Maybe with vias and a ground plane? Connecting all the magnets together in a ground plane, to create a closed loop magnetic field. Not having one is like putting resistors in your magnetic field, the field needs something to kling on to.

There's the right way to set a bearing with a nice press that doesn't put undue stress on the bearing, and then there's they way everyone actually does it, which is HAMMER :D

Have you considered making increases to the rotor field strength? Would help with coupling and certainly improve efficiency ( = less heating! :D)
For example, you could put magnets on both side of the stator, or use a Halbach array like Cristoph Laimer's 3d-printed motor.

Much Respect 💪

Awesome idea! This could also be really interesting to make a linear motor on a PCB. I figure PCB milling should be quite precise enough as a crude linear guide. You could make the coils wider horizontally, add a chip to only power the active coils and maybe add some iron to increase the force. I don't really have much knowledge about motors though.
This could be cool for something like a stewart platform. 6 legs just with their distance to the ground would define the 6dof position of the robot. So with 8 legs that can freely swing you should be able to make a simple robot that can lift two legs while the other 6 keep is fixed, then move all platofmr, lift 2 legs and let them swing back to vertical.

You can re magnetize the magnets by heating them and exposing them to a magnetic field then cooling them. You can also add a second pcb on the other side of the rotor to double the power of your motor. Just add a longer shaft. That is the beauty of an axial motor.

Very nice!, except for adding iron to define magnetic path, maybe also try rotor with no indentation to minimize air resistance or drag, the loss is related to drag and square speed.

Yes! I've been waiting for another video on pcb motors. Still want to do a pcb drone.

If you set rotor whis ferromagnetic or magnets on opposite side of coils pcb, it increases torque more then two times.

I wanna live like this guy.

Quality Content

Super I like your project

The low resistance of the delta configuration is not a problem, it is necessary for higher speeds but you will need a smarter driver that has current limiting

So amazing

consider changing the magnet housing to a non-conductive material (other than plastic of course) or use laminated sheets of aluminium epoxied together perpendicular to the pcb. the eddy currents in the housing is giving issues with heat and sapping a lot of the power. adding iron would make this worse. iron is only good for flux coupling and since the magnets are already so close the coils there is no point. any additional metal on the rotor would do little to the flux linkage other than leak power. iron is usually used around coils to help concentrate the flux into a particular axis. around magnets not much happens. consider stiffer thermo-setting plastics such as delrin if possible. delrin is easy to machine even on small mills and lathes.

Awesome!

Very good

That is great work)) would like to see something like this underwater 🤔

I know this is an old vid... however, try to incorporate fan blades into the rotor to try cooling the PCB

You would need need "Water cooled PCB motor" 😂

i will love to see a video of your setup like which software you use or which tool you recommand :)

Great content! I am wondering how this design would work as a power generator? Maybe this is an idea for another video? Cheers

amazing

To get the most out of your magnets you need to confine their flux to pass through the stator as much as possible. To achieve this you should use a magnetically permeable material (a steel washer perhaps?) to back the rotor and make the rotor double sided.
If you could source them, halbach arrays would be ideal. Not sure how realistic that is at this scale.. Trapezoidal or sector magnets would also let you use the space under the disc more efficiently. Maybe you can get the HDD magnets from an oldschool iPod or something.
Given the choice of using more of the space you have for magnets or just a higher grade, more magnetic material is usually the way to go. imho.

Very cool work. Just wondering if the switch to using aluminum for the rotor causes eddy currents, and if that might reduce the efficiency of the motor?

Good genius! 👍

Impressive

Very interesting! I like the direction this is going.
Have you considered putting thermal epoxy as a heatsink on rear of pcb where the coil areas are?
Also you can get magnets that are rated to 125+ celcius. "Polymagnets" can generate greater force than standard magnets, Correlated Magnetics make polymagnets.

I wonder if you could sandwich the rotter between 2 PCBs on top and 2 PCBs on bottom. This will trap your spindle between 2 PCBs on either side (higher stability) . Then use the outer exposed disk for mounting blades to instead of shaft. Might be interesting to do push pull between top and bottom PCBs due to heat. Also if u cut small curved vain into the aluminum you can have it self cool to a point.

Can you please tell about Calculations regarding BLDC Motor design and windings?

Very interresting project. I like how you combine electrical engineering with mechanical part design. have you thought of having both of the winding sides accessible like in an classical Induction motor so that you could switch from star to delta at will?

You get 100 likes from me..!!! Keep it up brother 🙂👌👌

I like to use such motor in a cassette tape housing (on a custom PCB inside) that turns the wheels or use one of them as generator to drive the second wheel. The magnets are in the surroundings of the wheels and coils are around the holes. The reason I want to do this is to make BT-adapter without noisy rotating gears. Some cassettedecks requires the motion of both wheels, that is why there are gears inside such adapter. It would be fantastic when this can be done without batteries at all, so when one wheel is driven by the cassettedeck, the other automaticly spins (slower of course due energy loss). That would be amazing! A nice application, right? (or stupid idea?)

Proset King :)

Eddy currents in the aluminium will definitely reduce the efficiency. If you want something that can take the heat, has good mechanical properties and is non conductive use GFRP or in other words: Mill out a thick FR4 PCB. It will be lighter, stronger and more efficient than aluminium if done right.

WOW PCB motor is great idea for making switched reluctance motor. It does not contain magnets. It could be 2 PCBs. One you have and second with coils, capacitors and possibly some logic. It would run at much higher temperatures without magnets, processing much more energy. good for quad.

Awesome Idea :) , next step is to build smallest PCB step motor and next 3d printer from them, and next print small 3d printed engine :)

If you put a lot of coils onto a lager pcb, could you make something like a marble track? Or a clock, where the small metal ball shows the time.

Very intrasting! You powerfull )

Costs a bit more, but use a 4-layer (or more) PCB, and maybe some iron-covers around the backside of the coils.

Any room for heatsinking the back side of the PCB?
If you mill another magnet rotor, maybe cut some grooves / fins into it so there is a slight cooling effect without much if any extra drag.

You should use magnetics simulation such as JMAG or Maxwell (expensive) or MotorAnalysis (free) to simulate and optimize your design further.

Could you protect the magnets with a thin layer of thermal insulation? Maybe a paint with aerogel powder or insulating film.

that's nice

Awesome

2:01 "GIMME PCB!!"
Ehi for the heat, what about a little fan (maybe in plastic) on the back of the motor pcb? The height increases, but the performance will decrease less.
Or maybe a different design of the rotor: fan shaped, so it will cool itself without any other extra parts.

On the metal thing that holds the magnets, couldn't you add some fins to the back of it when it spins to help cool it?

I you are looking for interesting project ideas: I would love to see a miniature linear induction motor with a solid secondary

You could also stack 2 coil pcb's on top of each other, increasing the torque by 175%?

So what if you placed two magnet arrays on either side of the PCB? Like a reversed axial brushless motor?

Hello! Amazing work) What is the layer size of the PCB, the copper layers and isolations for v1 and v3 pcb motors?
Thanks!)

Could you please share a video using PCB motors in order to achieve similar functionality as that of celluveyor

Have you thought about designing one with an attachable heat sink? There is an article that seems to talk about how motor performance can be negatively impacted by high heat.
Maybe you put as many vias in the extra room of the PCB as possible to also help with cooling.

Is there any way to add a fan or directional air flow holes into the aluminum to cool the PCB? Maybe in the divots or area between the magnets.
I know nothing of this just trying to help.

Hi Karl, you have magnets, winding, bearing, but you do not have a cores which is key in motors. basically iron to close and guide the magnetic field and use the best of your coils, imagine an electromagnet without core, it would be many times less strong ! At least it will improve the torque. PM me if you don't see what I mean.

Nice work on thinning out the PCB and getting a higher RPM. And were those shafts were a type of pogo pin? They certainly looked like pogo pins and that was a genius use for them.

Try to add magnets at different side of pcb for more torque. And sure avoid the high temperature. Also try to insert copper inside of pcd. It's a multilayer pcb like used in graphical card where we have more than 7 layers.

Very interesting and fascinating.
I personally would like to see some simulation of the generated magnetic field. Maybe one can throw an optimizer at the shape of the spirals to optimize the generated field? From the previous video it looked like you choose the shape quite arbitrary? I would be surprised if the shape wouldn't have a big influence over the power output of the motor. But i'm just a commenter on the internet that doesn't really know much about that topic, so...

Hey carl nice work. Really got me some ideas. As tip. Have you considered making the rotor also out of pcb material? From manufacturing its simpler.
Furthermore i wonder if the motor works also good as a generator. Would you be willed to provide one piece for a test?

Wye and delta are completely equivalent except for the voltage which differs by a factor of 1,73 (sqrt(3))

All N-type magnets should be 80 °C, higher temp magnets have a M for 100 °C, H , SH, UH, EH and AH types have even higher max temps :)
I love those tiny motors you make, have to build one myself just for fun one day ;)
Edit: I just found a better list but they are only reference values:
type, max usage temp, curie point
N 80 °C * 310 °C
(*N52 for example max 65°C )
M 100 °C 340 °C
H 120 °C 340 °C
SH 150 °C 340 °C
UH 180 °C 350 °C
EH 200 °C 350 °C
AH 230 °C 350 °C

Should make the rotors out of steel it can help pipe the magnetic flux around back the the windings

truly amazing!
I always wonder: what are your practical uses for such mini motors?

What about creating the rotor with fins, to aid cooling & prevent overheating of the magnets? Also, have you looked into graphite as a washer option?...

Great video and loads of interesting comments. But was I the only one alarmed at the figure of 80C in the spec of the magnets? I'm aware of the Curie point and that hot magnets lose their power, but never thought it was that low. If I simmer a neodymium magnet in water at near 100C for an hour will it become useless?

Could you use a couple of vias as a core of the coils? You seem, to already have two vias in the middle, but there seems to be space for a couple more?

When designing a motor, you want the winding resistance to be as low as possible in order to minimize losses. Since the motor runs on AC, the current will be limited by the winding inductance.
You could drastically increase the efficieny and torque of your motor by using an iron core and rotor, thereby decreasing the magnetic resistance and increasing the inductance.