Trying to build a PCB Hot-Plate to Reflow PCBs

If you're making the pcbs separate then connect to the "heater" with screwed-in wires rather than needing to solder onto it, it'll eliminate the chance of that solder melting too!

My first idea when i saw this: "why not add an extra layer to any pcb to make it reflow itself". Turns out you already thought of it. Great video. Super interesting concept.

My first impression: Let the heater reflow it's own circuit

U should get rid of the holes. They are counterproductive since they lower thermal mass and heat is distributed unevenly to reflow PCB. Anyway good project as always !

Set Zones In the next iteration. So you're controller can use only smaller sections depending on size of PCB to be reflowed. You might be able to use a PCB on edge as Underside Supports For your "heater" pcb. Past all that this is such a simple design I hope it works out.

Idea for version 2: Insulation. Add some refactory material and a housing around the PCB heater so heat radiating off it is reflected back like a toaster oven.

Me, who can't even solder two wires with a soldering iron: "Huh, interesting."
Edit: Carl, your videos are super cool. Could you make a video about basic electronic engineering or electronic engineering tips? Thanks for the heart btw.

This is one of my top ten youtube channels, thank you for your time to make these videos!

Thanks for including the part number of that thermocouple amplifier IC! Haven't used thermocouples in any of my projects yet, but thanks to you I now have a starting point for putting something together 🙂

Great idea! A cool addition would be to split the board into heating zones. You could control which zones receive power using transistors or something like that. That way you don't have to heat the whole thing for a tiny PCB. It would both speed up the heating speed, limit the power usage and make the thing a bit safer.

Man, that’s such great use of existing technology in a novel way. Great job! 💜

Great concept! This could be a great tindie product! Excited for version 2 too!

This is a really great idea! I look forward to part 2

I thought I was the only one using a 3D printer heatbed as preheater XD

I am super excited to see how the self-soldering PCB works out!

*The first line of that video has maybe described more of My days than I may admit*

Lol. I literally was thinking about this yesterday :D great video!

Hey Carl, great video. This went exactly where I thought you were taking it in the last episode. I'm glad it worked, and agree with your planned upgrades. The warping could be mitigated with pilot holes for bolting it to a test bed (akin to a motherboard test bench) that way the middle can have some support while heating.
Keep up the great work, and I am glad you are doing well.

A thick layer of anodizing is often used to create the dielectric layer of an aluminum PCB.... which is something I find to be pretty interesting. The copper traces can also be added to that dielectric layer via either electroplating or sputtering techniques to avoid having any polymer resins that would lower temperature ratings.

This is really cool I was thinking of doing something similar to this with super caps from Kapton strips!

you gave me a good idea bro.
you are a smart man. thank you.

Wonderful idea.... looking forward to v2 ...

I'm not sure if anyone suggested it but add PCB legs. You can plot small notches for the legs to slide into with a small amount of room for expansion. I would put them in a cross configuration to support the center. This should help with the sagging. It will also get the heat off the surface you are working on and gives you a place to mount the electronics. Maybe a faceplate for temp control and screen. Then you can also plot a small hole in the center of the heating surface to put a thermocouple into the center from the bottom. Additionally, with the 3d concept, add a PCB arm on the top with a screw pivot and a point like a finger that aligns with the center. Add ample areas on the pivoting finger to blob on solder for weight then you don't have to tape the PCB down.

Very Nice Project 👍
I liked it👌

Well done, nice video, thanks for sharing it with us :)

Awesome Idea!

Fantastic Idea!

The folks at PCBWay much be so excited to get his orders.

Suggestion #1: Build an FR4 Frame around it to mount the components on and suspend the Al-core in the center. [X]
#2: the slots in the Al-core are not necessary, the heat conductivity of the aluminium is good enough to cool it from below, mount a fan underneigh.
#3: make your layout more flexible, to compensate for manufactoring errors or to allow different supply voltages you could allow to modify the resistance by separating/shorting tracks via (high temp) solder-jumpers

Excellent heating tool is the plasic pipes heat welder plumbers use.Desoldering led from backlight stripes,reballing bga chips and reflows small sizes pcb.And its price is very affordable.

I was thinking about turning a broken clothing iron into a PCB reflow device.
This video helps out a lot.

Dude that's brilliant idea

Carl Excellent !!

I'm looking forward to V2. I'm doing all my SMD soldering by hand, and would love something like this!

Self reflowing PCB! That would be an amazing project

Self re-flowing PCBs: our robot masters of the future will thank you for your contribution :) Interesting stuff, take care.

Very great idea !, Nice video 👍👍

You know what they say, you learn something new every day. I learned today that the guy from the cap and ball channel has a second channel and likes electronics.

Bit of an off-topic comment, and I know this is months old now, but this reminds me of that PCB CNC machine. I don't remember the name of it or who makes it, and I'm not having luck finding that information currently. But it 'print' a circuit, using a proprietary paste, onto a PCB blank, typical fiberglass or flexible materials, and would bake the paste into traces; iirc, it could also drill for vias, but I would have to fact check this. I remember arguing that the machine was overpriced, the proprietary paste was most definitely overpriced, and that it would be fairly easy to DIY such a machine, assuming you could attain a similar paste, as the paste extruder was just a plunger mechanism, iirc, or possibly a blocked screw extruder. This reflow plate, and using a 3D printer as the CNC, and with a different tool being the paste extruder, proves that my concept of a DIY variant of this machine is, in fact, possible, and quite easy to accomplish; only problem, again, being the paste. The only difference, iirc, in both the original and DIY machines, would be that the pasted board needs to be facing the hot plate, with a holding mechanism that also forms a cavity, so that it creates what's essentially an oven, so that the paste properly bakes.
Of course, these machines would not be close to a true copper trace PCB, but it would be better than, say, a conductive 3D printer filament, as it's a more permanent, baked-on solution. I believe this PCB-making machine would also be able to reflow solder, as the baking temperature is much higher than solder reflow temperatures, making it a multi-use machine. Further this by also incorporating a pick and place machine, have a tool changer, and a separate non-heated bed for component layout, though this would be a hybrid manual-automated machine, as the machine wouldn't be able to select components without a predetermined layout or without machine learning and artificial intelligence to pick random components from random placements to be placed in correct orientations and board placements, or have laser cut part arrangement boards to make pick and placing simpler; alternatively, for home production machines, the possibility of a tape reel dispenser in the pick and place head. Essentially, one idea could turn into a home factory in one machine, after initial prototyping is done of course. An ambitious idea, yes, but it also seems entirely possible to do, as each separate component does already exist, it would just be combining them all into a single machine, as tool changing in this form can exist, and the 'dual bed' design would just be an extended axis, which does also exist; so what would stop this from not being feasible, other than the solder paste issue?
I've seen so many project products fail to come to fruition, or become a very niche product at most, because everything is hand assembled, and in the orders of hundreds of products, this takes a long time with a single person or small team. A combination machine like this, a desktop factory, would expedite this process, at least in bulk time as it can run continuously, and a print farm would further expedite the process. This would also be a direct link between rapid prototyping and production, something not often seen in the CNC world. It makes sense for a machine like this to exist for small-scale production, done out of someone's hobby room or small business.

Damn, what a great idea 👍

Cool project! As sugested I also believe the PCB slots should go away to get a more even temperature across the surface :)

If you make a self-reflowing PCB, you could have a tiny LED or something on the end that only lights up if the entire circuit has reflowed properly. Or maybe even a resistor connected to the thermal regulator so it knows to switch to the main microcontroller from now on. That way it automatically reflows the first time you turn it on and then it's done. You can pass power through the circuit when heating too, so maybe it's possible to do an "If isComplete applyCoolingAndEnd(); Else keepHeating(); waitUntilReflowComplete();" so that you can automatically stop it at just the right time before you get bridges

Very nice!

It might be interesting to have several heating elements that could be controlled individually so that you could optimize a consistent temperature across the whole board.

Nice, We expecting more like this...

REFLOWCEPTION!!!! GL MATE :D

Tip: don't suspend pcb heater in air, support it by glass wool pads it will provide insulation and support

Well, older rep rap 3d printers had pcb’s as bed heaters though they didn’t reach such temperatures. Good work!

i use an electrical induction stove and an steel plate and works marvelous it has temperature sensor and is quite accurate maybe u can make a similar concept but in small format

Like your bench & table set up! Great video! Have you ever tried to make a flow/reflow surface using quartz heaters, such as found in some toaster ovens? Thanks

You could divide the long track into maybe 4 tracks and make a pad pattern that lets you change the wiring (all in series/ all in parallel/ series-parallel combination) so you can tune the resistance and experiment better!

Consider also that aluminum and pcb have different expansion coefficients... Which might lead to bending. (I think that removing holes facilitates the rise in temperatuee as it looks less like a radiator)

genius!!!

Very interesting, has huge potential for tinkering

with such a slow profile, you could probably use just a proportional heater, maybe with a bit of differential control, but that should be fine, and reduce the whole PID tuning, and code size !

For rigidity I would add something mechanical as a cross brace, to give it either a U or a T shape cross section. thin aluminum in an L shape and rivets would be a very stiff and low effort solution, but would wick away some of the heat. If its too much heat you'd have to find something that could be attached (rivets or otherwise) with a low heat transfer coefficient.

You looks like the PCB version of "Alex" .. 😋
nice video, thanks for the info

Hello Carl, Nice project. 1. My idea is to implement fan/s to cool the PCB board after reflowing. You can installed from below and connect to controller who can turn On the fan/s after finishing the reflowing. After the dropping the temperature to about 30°C it can stop automatically. Just nice future which I will like it to have. If the fan/s is installed from bellow is good to have more holes on the heater ( like many bigger vias). 2. I think that you holes are too wide and too long and heat maybe will not distribute evenly. Maybe is good to be 1-2 millimeters wide and about 10 millimeters long. 3. Other think is I like to have real time reflow profile on the computer screen or similar. I like to have loading/edit/run reflow profiles thru the network LAN or Wi-Fi. 4. I s good to have two surfaces for small PCB and big PCB boards. Lets say into the big surface you can separate one area about 4x4 inches for small PCBs. You can switch between areas small or full. This is not too much related to the saving of the electricity but to protect your finger from burning when handle the boards:). If you have cooling fan not burnet fingers:)). Let me know what do you think about it.

if you mount the pcb heater directly you may need to give it some expansion room, it seems that is the source of your bending when it is heating up

the spec sheet said Vg threshold is 3-5 , so the mosfet will turn off at a max voltage of 5 V and a min voltage of 3V, so 5 V logics is unliekly to work , you could get better mosfet like IRF150 or IRF540N , because 2-4 Vg threshold wil work better with 5V logics.There are also mosfet with logic input like FQP30N06L or IRL serie. the could go as low as 1 - 2.5 , which could also work with 3.3V logics. Use the right compoenet could save so much trouble

My first impression... Get some nichrome wire and lay it out in a nice spiral on a copper plate maybe 3mm thick... Use a layer of fiberglass and epoxy between the copper and nichrome...

What microcontrollers you prefer and why

Hey, nice video. How did you managed the layer stack on Altium for the Al substrate?
Any tips would be appreciated, thanks

I think the aluminium backing is acting as a Big heatsink, pumping and dissipating most of the heath on the back of the plate.
Maybe try removing the slots and put the pcb to be reflowed on the aluminium side? And add some insulation on the other side to focus the heath to the reflowed pcb?

Nice project Carl. Why don't you try it with silicone heating pAds which can work with ac mains and an AC SSR and go up to 230c

How would it behave if you put 2 panels face to face, and powered both (using the aluminum back as the heater surface)
Wouldn’t that be the same, resistance-wise, as cutting the board in half?

I know nothing, but would it be useful to split into zones? More efficient, better control perhaps?

If you make a self reflowing PCB and add some sort of vibrating actuator (that is glued on and controlled away from the self-reflowing section) you could have a self depopulating PCB. Might be useful for semi-secure devices.

Super crazy🤩🤩🤩

Can u make a video or series on how to design pcbs

Carl, could you share what product is the table mat you have (the blue one?) Thanks a lot and keep doing the great work!

Suggestion for V2. Serial or USB data-logging and control, so you can graph the temperature on the computer, and easily set thermal profiles.

You could take a look at the E3D high temperature heatbeds, they go to 200°C with a max of 250°C. Maybe cheaper to just make control for that than trying to remake the huge PCB as well.

Isn't the heatbed showed at the beginning of the video exactly the same what you had made..? It also has aluminium substrate

Try an alu (or copper if you can afford it) plate on top as a heat spreader. Should allow the heat to spread across the current gaps and provide more thermal mass. Just be sure to tweak your PID values after! :)

Wouldnt it heat more/better if you powered it from a constant current regulator instead of a constant voltage?

You could put a few small holes in the pcb and design a small clip or use wire to hold the thermocouple onto the pcb. Then you dont have to use the tape.

If your firmware uses floating point math, you can regain a lot of memory by switching to integer math and avoiding the floating point library. It's a pain but it works, and once it works, it's done.

Probably it's a bad idea but i wonder if it's possible to make a PCB with a grid of very fine heat cells, like a TFT screen but cells produces heat in stead of light? I don't know if it's possbile or achievable but i think it would be great to aim directly to the soldering areas with a high accuracy. It would prevent components from damage and it makes the process more managable.

What are J1 and J2 and that plastic thing you removed once the soldering was done?

That aluminum pcb flexing made me think of a linear pcb actuator. Maybe something for you to try in the future?

Allium designer is fantastic and my preferred tool but industry standard not quite. I'm stuck with Pads standard plus it's alright I would kill for an Alltium licence...

If you change from the default (for aluminum backed PCBs) ENIG to HASL (lead free), it's cheaper on PCBWay's website.
I'm wondering if it would be better to specify black soldermask, given this is essentially a heating element.

Maybe you can add type-c connector and usb pd chip for power supply. Like new small hot-plate.

Very interesting work! May i ask, how much was your Altium license?

0:11 Mr Prusa's great idea

good

Please no slits or holes. Very nice project, would be great as a PCB preheater. You could even divide the whole field into smaller selectable zones.

It would be interesting to integrate a thermocouple in the PCB or even use the PCB as one of the 2 metals. A possible option would be a type T (copper-constantan).

Could patrons eventually have access to the finish schematic to make it themselves? Because, an typical hot plate for reflow is more expensive and much much bigger.

You can try using some peltier module .

Another fantastic idea! Good use of inner layers & (soon to be) ground "planes". Ever figure out how the resistance was so far off of your estimate? Was it the sharp u-turns?

Next version: Making a PCB ( to assemble PCBs )

Hi! Very good idea!. What you need to do is a PCB with a printed pancake coil. Then, make a driver so that everything works as a heat inductor.
Place the PCB side with the printed coil facing down, and attach a thin stainless steel sheet connected to the ground on the top side. This will heat up and dissipate electromagnetic waves, thus preventing the components you are trying to weld from being affected.
Hola! Muy buena idea!. Lo que necesitas hacer es una PCB con una bobina tipo panqueque impresa. Luego, fabricarle un driver para que funcione todo como un inductor de calor.
Coloca la cara de la PCB con la bobina impresa hacia abajo, y anexa del lado de arriba una hoja de acero inoxidable delgada conectada a masa. Ésta se calentará y disipará las ondas electromagneticas, evitando asi que sean afectados los componentes que intentes soldar.

You might consider a layer of heat resistant insulation under the board to minimize heat loss.

Ohh ohh ohh, make a circuit board that is self soldering. Have coil layers under the components that you power up to melt the solder. I know it's useless for mass production shiz but it would be good for small runs and one offs for people who don't have a reflow oven. Oh wait, just finished the video, your already on it. Good job.

due to known relation of copper resistance and temperature, you may not even need a thermal sensor

Could one take a normal PCB and lay a piece of metal on top of it?

add caroussel to do "10" pcb's, pcb is suspended between 2 arms, stopper+slope on heater gently drops that pcb,
add sweeper to shift the cooling pcb to a bin ...

Hello did you be share the Gerber files,?