That was really interesting. It was good of them to shoot the video for you and they actually did a decent job of it.

Wow, pcb manufacture is an incredible process. So time consuming and repetitive and complex. Very good to see, thanks Dave.

Of the hundreds of your videos that I have watched Dave, that was the bees knees mate! Thankyou for all the time and effort you put into your superb videos :) Much love from the UK!

Thanks for adding the design and hard edge video links Dave, was confused until I refreshed :)

The reason they electroplated the copper the second time was to increase the copper up to the required thickness. The copperclad they use only has a thin layer of copper on it. That allows them to etch them faster and have finer traces.

Great video Dave - especially given that it is your PCB in the videos.

If you are in Auckland you should ask if you can get a tour. Richard has given our company a few tours of the workshop. Its cooler to see in person, and you get to ask all the questions! He's a nice guy, very helpful.

Wow, the CNC electrical continuity tester is one I never thought of. Amazing. All of the processes are amazing. Something to work towards. Excellent video.

How can someone Thumbs Down this easy to understand informative Video ??? It must no doubt be over their tiny little heads. Yeah the costs have come drastically down since I had my 1st prototype professional PCBs made. The 10pc 2" X 3" double sided PCBs cost me near $400 Cnd about 30 years ago. Today I can get the same PCBs made for less than $2.00 each delivered... from China

Dave your video was a blessing is disguise to me yesterday evening! I got to learn some info, and it cured my sleeplessness ;)

I really enjoyed this video. Quite interesting what processes are used and in what order they are done. Thanks for sharing it with us!

I'm really surprised that most of this isn't automated completely.

Really interesting to see this entire process - also it's ridiculous how much manual work still goes into this!

They are very inexpensive to produce. This was one of the better videos that I've seen showing the entire process.

This process seems to be tiny compared to what I do every day at work. We make multi layer panels and start off with inner layer cores that are etched, punched, scanned (I am an AOI scanner), lay up, press, flash, then drill. And the electroless lines at my work are massive, the panels are carried by a massive crane from tank to tank. Theses panels are also very small, the panels we process can be as big as 36x34 inches down to 18x24 inches. You didn't get to show the full process sadly, but it's nice to see a process shown online.

Fascinating! I love episodes that give us a peek into the world of electronics manufacture!

was waiting a long time for such a video again(Back to the basics) well done , love it

Card edge connectors are hard gold which is a galvanic process. You pay a premium for combining the normal chem. NiAu for SMD and the galvanic Hard Gold for the card edge connector. This is important as you should not solder on Hard Gold, as Gold easily alloys with tin, forming a bridle joint.

This is a very interesting process. It'll be great if you could make a video showing the complete updated process for comparison.

Interesting to see how different companies do this.

One of the most interesting videos I've seen recently, time flew very fast.

Damn that's a lot of work....

We actually do the film process in my Schools clean room.... mainly cause most of this equipment is insanely expensive and places have donated all the equipment. Its still very cool way of learning the manufacturing process and working in a clean room

The machine used to make the film for the photolithography is called an imagesetter. It's the same type of machine used for making masks for photoetching of printing plates, and once used to make semiconductor photomasks as well.

I wonder how many more amazing videos like this one are 'waiting to be edited'. I bet a lot of those will never see the light of day. Ts, ts, ts...

Wonderful video to watch, very informative!

Very informative video Dave, thanks!

As someone who's done some basic screen printing, it's really interesting to me how they print over an entire board and expose the "paint" instead of exposing an emulsion on the screen.

My old job - CNC drilling. The boards i used to drill were normally pinned in 3's. An old cassette tape media for the CNC program.

Thanks for making this video. I have been looking for something like this for a couple of years, but have always only found how are PCBs being populated with components.

This is fascinating! Why anyone would down-vote resists explanation. The only part that I didn't follow was the thru-hole plating. How does the metal build up in the thru-holes?

This was a great video. Thanks Dave!

Awesome! Full of data and demo!

I am surprised at how much manual labor goes in to this. I thought the reason you could get PCB production so cheap these days was that it had become highly automated.

Good video. Loved it. Roller/HAL tinning is still done by many, though, it seems.

10:42 I have heard from some manufacturers that they have a rather thin base layer of copper, and by electrolysis they deposit the amount of copper required for the desired thickness. That way when there is the etching step, there is only the thin layer of copper to be etched away. I was really hoping to see more on how the through hole plating works, its still not totally clear for me and my home brew process is quite lacking....

Very interesting! Thanks, Dave!

That was very interesting and fun to watch!

Hopefully, we'll be 3d printing them some day.

Exactly I wonder whats going on with non plated holes, and get the conclusion like explanation here - thanks!

Considering the price I'm amazed at how much work goes into making a board, especially how much of the work is manually loading the boards. For the price you pay I'd have expected a lot more automation.

You should send your board files to cheaper "hobbyist" type PCB fabs like pcbway, dirtypcbs and elecrow to compare the results. That would be neat.

You can do a simple silkscreen on your homemade DIY boards by toner transferring it on after etching. Pretty much essential if you have over 50 components.

excellent video. thank you Dave !!

The film imaging engine is an Agfa SelectSet 7000 imagesetter. It has the capability of imaging 1200, 2400 or 3600 dpi on film up to 25.6 inches wide. I used one about 20 years ago in a printing pre-press shop.

I honestly wasn't expecting it to be that much work, very impressive. I'll never complain about the price of a high-end motherboard again.. :)

Very nice Dave. Thank you! I love seeing these kind of videos :) Hope to order boards for my Tron Identity Disk project soon. Will be using the Elektor print service (Eurocircuits).

That is absolutely amazing how all those processes can lead to a board so cheap.... Its unbelievable

The bare panel has maybe 0.25oz copper on it. So they photo-plot the negative, so they can build up the thickness on the traces to the desired thickness. Then they etch off the unwanted copper. This minimizes under-cut during the etching process.

Thanks Dave for this video! Very informative and accurate! However, I'll suggest that you should do a video on how to do your own PCB's at home. I started that way many years ago and it made me a better PCB designer since a I'm able to better understand what is the fabrication process and it's limitations. Even though you do not have plated thru hole on a home PCB, it is possible to design the board by taking that into account and avoiding top pad connection underneat capacitors, connectors and IC's and using vias instead. When I'm doing my own PCB, I'm using the toner transfer from a laser printer onto bare pcb boards and it's surprisingly alot better than the photo imaging process that I was using 15 years ago. It is a lot less expensive and the failure rate is really low. I can easily etch traces down to 10 mils using toner transfer!

You use the electroplating after film development to be more efficient in the use of the copper. The base board has only a thin copper layer of 1µm or less. On the exposed parts the copper is electroplated to the desired thickness. Afterwards you only have to etch away the thin base plating which is faster and consumes less copper in total. You could even skip the tin-plating step here: eletroplating to a thickness of 18µm and then etching away 1µm of copper over the whole board will consume all copper between the traces, but the thickness of the traces would only be reduced by 1µm to the standard 17µm. No risk of underetching here as well - yet another advantage of this method.

Wow that is an interesting process. I compare that to a home made and home etched PCB and there just is no comparison. Nice one Dave.

one of my favorites!

Developer! Developer! Developer! Developer!

I use to work in a PCB factory - I printed the ident layers -AMA!

As a Texan, I'm surprisingly amused by your Australian euphemisms. The "How you doin'" and "Bobs' your uncle" completely elude me as to their origin, but I'm determined to find out! I just figured out who this "Bobby Dezzla (Dazzler)" fella is..... Great video as always. This is very informative. I watched a video on how to do PCBs at home, but sending it off seems the proper way to get it done. Still, it's a fun home project once or twice.

OSHPark rocks! I used to etch my own PCBs since I was 10 (ah, the ferric chloride stains in the bathroom sink. My Mom just "loved" me for it...), but now, there's no point in making a mess.

interesting to see the process

One of the reasons the panel is bigger is for the tree to connect to the panel while maintaining electrical continuity. If they weren't bigger, the trees would NOT conduct electricity through the photoresist mask during the electroplating portion of manufacturing your board.

This is brilliant. Thanks so mutch!

Thx, Dave. Thumbs up! Simple, not overloaded video about bad to health work. Don't you whant to make a video about 4-layer board tracing basics? For example, with 2 external signal layers and 2 internal power layers.

I think they pattern-plate (tin-plate) the design before etching so the etchant doesn't get into your vias and cause problems. I'm not sure how you'd be able to protect the vias with etch-resist otherwise.

For vias, would they drill out the hole and then plate it? Or is it more like a rivet that gets punched in?

really informative David

I'm trying to make simple LDI with laser module from a laser printer. Still far from success - currently I'm fighting with PLL for laser synchronization, but the amount of things I learned during that - priceless.

There is a lot more handcraft going to this than I would have thought. I guess they use more automated process when you are doing bigger batch.

How are those sheets not sticking to the ink when he places them on the fresh uv ink to be exposed, @ 13:05 and 15:25 ? it looks like they are already cured because they don't stick. this is where I always make a mess with my boards. anybody know what's going on there?

10:40 This is the actual plating that builds up the traces and the ground plate. If you didn't do this step, your traces would only be as thick as the copper coating on the fiberglass board. To keep costs of the boards down, the copper coating is extremely thin. Where I worked, this particular process took like 45 minutes. That is a copper-sulfate bath with a copper source in it. Where I worked they used these long thin "baskets" filled with copper nuggets.

how is pcbb formed

Thanks Dave! Very interesting! :)

I used to work in a PCB factory when I was a kid and it is quite simple. The design is laid out and and through photo-lithography a negative is exposed onto double sided copper coated fiberglass so that the only thing showing are the traces and holes which are drilled automatically after the photo-lithography. The boards are then attached to "trees" and washed in a mild acid bath. From there is goes into a copper-sulfate bath and electroplated where only the exposed areas of the large board (which may contain many duplicates of the same small board) is plated. When it's done, the thickness is checked on several parts of the board to make sure the electroplating was even and built up to the right thickness. At this point, the boards are still 100% covered with copper, but most of the board has a blue photoresist layer on it so that only the traces are exposed. Then they are washed again in a mild acid bath. From there they get plated with tin-lead, so that all exposed areas of the board (mostly traces and ground planes) are covered in tin-lead. Then, the trees are transferred into an acid bath which removes the photoresist layer from the board. Then the trees are put into an etching bath that dissolves all the exposed copper. The trees are then moved once again into a a mild acid cleaning bath. Then they are put into yet another bath witch removes the tin-lead layer. This is all done by hand. The trees are picked up and transferred to the various baths and screwed onto large bars at the top of the baths. The bars act to hold the trees (which the boards are clamped to) and the trees are fully conductive from the bars and the boars are slightly larger than the total used space so that the trees are always in full electrical contact with the boards. If there are any gold-plated card edge connectors on the boards, they go through the same process, but this is done mostly by hand (on a small scale) because you only want to gold plate what needs to be gold plated. After this, the boards are shipped to a another factory that can do the pick and place. The place I worked for did mostly low volume, but very high quality industrial boards. I remember one of the main customers was an automobile shop diagnostic equipment manufacturer (this was like 25 years ago, but I want to say Bear was a big customer). They no longer exist. They use a lot of chemicals and once in a while will accidentally created a bunch of chlorine gas. The copper plating using "copper nuggets" which are essentially 1" thick extruded bars cut every 1.5". The tin-lead plating used solid bars of tin-lead. Sulfuric acid was heavily used as well as some much milder acids. There is constant cleaning of the boards and you always have to wear gloves to keep your skin and oil off the boards (and to protect your own hands from all these chemicals). This is old tech, but there really wasn't anything especially complicated about it. Chemists would periodically take samples from the various baths and concentrate or distilled water would be added as needed.

Interesting video in a long time :)

Cool vid Dave. Would love if you could do one called 'EEVBOG #1000 How Is An IC Manufactured?'

GOOD Stuff Dave! Awesome information. I used to "burn" mine on the patio. And every one of them sucked. LOLOL Life in 2017 is awesome.

Very interesting, thanks Dave

12:15 No Dave, what they are doing is exactly how this was done when I worked in a PCB factory (like 1990). They even use similar trees. This was always done with negative photo-lithography. TBH, I'm quite surprised that this hasn't really changed at all. The only difference I can see so far is that this facility is setup for smaller board runs. It's a shame you probably don't have any gold plating on your board (for card edge connectors). It's done much more efficiently so you don't lose any of the gold. They also keep the card edge connector/gold plating stuff under lock and key. People used to steal the copper nuggets, but they really weren't worth much, but gold is. I never even saw one because I had no access to the gold plating department.

How electrolytic plating can create copper layer inside FR4 holes/vias which are not conductive?

Handling the boards and chemicals without gloves. Must be a high quality manufacturing facility...

ALWAYS do the automated electrical test. Whew. I learned that the hard way. :)

That's a gorgeous PCB !!!

11:20 are you sure that they cover traces with tin before etching copper? The tin will melt in reflow oven right under the solder mask and the solder mask will peel off.

I think I got the reason for negative photo resist masking for the copper layer - tinning. That is the only way they can electroplate the tin on the copper layer in one go. If they use positive photo resist and a total cover of tin, then they will have to apply tin before the mask and then they will have to do a dual etching of tin first and copper later. If they do copper etching first, then they have to electroplate tin trace by trace as there needs an electric connection between the copper and the plating solution.

Please where can I buy a red mask user in the video ؟

What do they do differently for small production runs (like prototype boards)? The router seems like the slower part of the process, how do they deal with boards that have a few billion vias? Are small vias processed any differently than your larger plated through-hole?

Hi Dave, the older videos you talked about are not clickable, also no links for them in the description (e.g. 2:15). Anyway, great video as usual. Thanks !

Theres lots of people doing through hole with soldermask and liquid tin at home. As long as you have a decent cnc machine or laser printer your good to go. Its great for prototyping and then when you got finished it send it off.

You had this footage for 4 years?

I wonder if they even do this in America still. This is a labor intensive and is virtually unchanged since I was working in a PCB factory in 1990. The way we did this stuff, when the electroplating was happening, you mostly just sat there and waited for the thing to finish. Sometimes, when we were busy, we would load the trees, but that was only if we had the spare trees and the very first tank, which was a weak acid/water mix, was free. We spent a good portion of the day just waiting for the electroplating to finish. It's usually about an hour. You move the trees from the copper to the tin-lead, give the ones in the tin lead to the next guy, move the ones from the cleaning bath to the copper bath and load the water/acid bath and all this only takes about 15 minutes, so you really just sit around or clean or other make-work for 30-45 minutes (the specs determine how long the main copper bath lasts, usually about 1 hour). Moving those trees around was hard work and you had to wear these large rubber aprons and there was no air-conditioning. It hurt your back and you sweat your ass off. The environmental people would show up all hours of the day and night for spot checks. The floor was a "board walk" All the wiring for the DC current used for the machines were under the board walk and it also kept the floor dry from constantly moving the trees from one bath to the next. The liquids would pour off the boards when took the trees out to move them to the next process and there would have been puddles of acids on the floor without that "board walk" design..

Just sent my gerbers off to PCBZone! Can't wait

How can you go round this place and decide not to upload the footage straight away or within a few weeks at least? Makes me wonder what else is stored on that computer. Very interesting though. So thankyou

10:34 Wow this is in fact a brilliant idea. This may be why they get straight wires.

How does the electrolysis bath plate the holes? Aren't the holes just naked glass fiber and resin?

How do they make the vias and buried/blind vias for multilayer boards?

From the looks of it, around 11:10 they've added more copper and increased the trace thickness (before the tinning process)

How is indentify plated or unplated holes in the gerber file? Someone know how to specify it on Eagle cad?

You can get prototyping equipment that can rival or beat value pcb mfg, 3 grand and some manual work instead of automation at certain parts and a rather low throughput (a few boards an hour) are the only barriers

For my electronics project I got two quotes, one from pcbzone.net and one from JLCPCB. One was 50x more expensive than the other.

It might've been a photoimaged process but both the solder mask and the silk screen paints were put on the boards with a silk screen they just used it for it's ability to leave a good even layer not for actually any of the imaging that's where the photo imaging comes in

Wow! What a great video!

How about more than 2 layers? Any video on that? Thans Dave.