World's First Ultra-Thin Multilayer Circuit Board 126
neutron_p writes "Seiko Epson has developed the world's first 20-layer circuit board. Multilayer circuit boards are normally produced by using a photolithography. However, the industry has struggled to produce thin, lightweight, high-density multilayer circuit boards. Seiko Epson uses an inkjet-based manufacturing process, which has many advantages over a traditional photolithography process."
Not again (Score:3, Funny)
Great. Now I'm going to have to run out in the middle of the night to buy overpriced Epson inkjet refills in two aisles.
And the paperjams on a PCB? Insane.
Re: (Score:3, Funny)
Re:Not again (Score:4, Informative)
In all seriousness, I find it interesting that this process cuts down "a large volume of photoresist, developer, etchants, stripping agents and other chemicals" needed for the process.
However, is this based on earlier processes or IBM's improvements in recent years?
In 2001 [ibm.com]. "Michael Cummings, James Fuller, Jr., Timothy Krush, Mike Longo, Thomas Lyons, Curt Miller, Paul Speranza, William Wike, James Wilson, and Michael Wozniak of Endicott, New York, share $50,000 for developing and qualifying a new process that eliminated solvent use from the manufacture of ultra fine pitch (UFP) wire bond chip carrier products. A first in the industry, the team's innovations included the investigation and qualification of a dry film resist that achieves UFP's stringent photolithography specifications, while being compatible with existing printed wire board manufacturing steps. Benefits include, on an annual basis, avoiding 5.2 million pounds of chemical use, 5.6 million pounds of industrial and hazardous waste generation and off-site transport, and 110,000 pounds of process air emissions while saving over $5.6 million."
More info on here as well. [state.ny.us]
Re:Not again (Score:1, Insightful)
"Thanks for finding my Aston-Martin, here's a chocolate-chip cookie for you to share with the rest of the police department."
Re:Not again (Score:2, Insightful)
Anyone know if it's bendable? (Score:3, Insightful)
Re:Anyone know if it's bendable? (Score:5, Insightful)
I want the consumer version. This would make it much easier for the hobbiest like myself to make boards. Just print and use. I could see printing out the board on a thin film and then glueing it to a normal thickness material. The only problem I see is how to solder to it. It's a conductive ink so you might need a low-temperature solder or some other method so as to not burn it.
Re:Anyone know if it's bendable? (Score:3, Interesting)
Resistors at least should be printable too (Score:2)
At well-controlled inkjet resolutions, at least some resistors and capacitors (e.g. power rail decouplers) should be printable as well.
Re:Anyone know if it's bendable? (Score:2, Insightful)
And If you're struggling to fit a board into a housing, chances are that you will use surface-mount components quite heavily.
This problem is alleviated somewhat if the PCB is flexible, because you could solder the components in place before bending the PCB into it's desired shape.
Re:Anyone know if it's bendable? (Score:1)
Re:Anyone know if it's bendable? (Score:1, Interesting)
Re:Anyone know if it's bendable? (Score:3, Informative)
Re:Anyone know if it's bendable? (Score:2)
Re:Anyone know if it's bendable? (Score:2)
will this make it to the consumer? (Score:4, Interesting)
Because I think this could be another significant price reduction for people who want to try their hand at manufacturing hardware/embedded devices in their garage.. buy a 150 dollar inkjet, some special paper and conductive/insulator ink, and print up all your designs.
and the less barrier there is to entry in an industry, the more the competition, and the faster/better the growth.
Re:will this make it to the consumer? (Score:2, Informative)
Re:will this make it to the consumer? (Score:4, Informative)
Re:will this make it to the consumer? (Score:1)
Re:will this make it to the consumer? (Score:2)
True for now (Score:2)
Once the technology catches on, then it may be able to branch to other uses.
That being said, has anyone ever tried to make a conductive fluid and inject it into a standard printer? It would have to be low viscosity or it'll clock the heads, but if one had
Re:will this make it to the consumer? (Score:3, Informative)
Somebody post a how-to when you figure this out.
Re:will this make it to the consumer? (Score:3, Informative)
The issue (especially for fine pitch stuff) is drilling and soldering. Especially if you have a double-sided (or multi-layer) board. For big components (traditional resistors, capacitors) drilling's not too bad, but when you have to drill holes for bga sockets, or even 40-pin ribbon conn
Re:will this make it to the consumer? (Score:2)
I currently make do with the laserjet and clothes iron method, but it is less than perfect, it takes me a couple of tries to get a good transfer.
Re:will this make it to the consumer? (Score:1)
I haven't had a multi-layer PCB made in over a decade, back then it was totally outside the hobbiest price range. Anyone got some current pricing data on this?
Re:will this make it to the consumer? (Score:2)
Oh boy, (Score:4, Interesting)
Re:Oh boy, (Score:2)
Why are you guys talking abotu handling these things? I probably have no idea what I'm talking about but maybe someone could enlighten me.
Re:Oh boy, (Score:3, Informative)
now if they can get optical chips working then we may well see 3d designs as they dont have that mutch of a problem with heat buildup...
At last my inversor! (Score:1)
Thank you Seiko Epson!
This is not... (Score:1, Informative)
Re:This is not... (Score:1)
If I bothered to RTFA I'd probably see that the novelty is that it's a 20 layer HDI substrate.
But that isn't reflected in the lame wording of the post.
Re:This is not... (Score:2)
Re:This is not... (Score:2)
However, the article says "... the company believes is the world's first 20-layer circuit board". I've held, in my own hand, boards with more layers than this. It's not the world's first 20 layer board!
Re:This is not... (Score:2, Informative)
what the company believes is the world's first 20-layer circuit board.
I have held in my hand 28 layer PCBs. Now if they said it was 20 signal layers, not including ground and power planes, so it would be more like 40 to 50 layers, now that would be something.
However I give them full props for the thinness and the printing technology.
Inkjets and Epson (Score:4, Funny)
Inkjets + Epson == PCB printers
It would be amazing to be able to print out PCBs rather than sending your diagrams to a shop. Even if this doesn't work for a production system, it would be great for hobbyists to create throwaway prototypes of circuits before sending those designs in.
Also this brings a new way of "compiling" your circuit boards
Finally, those kids in college can really see their circuits in action rather than as blinking circles in some circuit simulator !. It's a real good feeling
<old_voice>
"Those days we didn't have zeros and ones either - all we had was Vcc , ground and everything in between... and we liked it"
</old_voice>
Re:Inkjets and Epson (Score:1)
I'm not eating any sandwiches at your place.
Sorry.
Re:Inkjets and Epson (Score:2)
And of course, the kids are missing out on the fun of spending an entire lunchbreak trying to debug a simple circuit (a logic analyser) where some of the kit parts have had their polarity reversed (PNP transistors instead of NPN transistors) without anyone bothering to check.
This won't replace conventional PCBs (Score:5, Interesting)
The main advantage of this new technology is that it is relatively cheaper to produce a small quantity of boards because there is no high cost of making masks. Most of the money today is made with consumer electronics where there is a requirement of large series of identical boards so this is no longer such an advantage (the starting cost of mask is almost zero after 1000 or so boards).
The article also does not mention how this type of circuit board is compatible with electronic components. I guess you can not solder SMDs to a trace that is composed of tiny silver particles. This probably means that a totaly new technology for mounting electronic components needs to be developed. The classical soldered spot is one of the most reliable components in electronics and I don't believe any new technology will surpass that anytime soon (this is not so unimportant, considering that an average circuit can have 100s or 1000s of soldered spots).
how about..... (Score:3, Insightful)
Re:This won't replace conventional PCBs (Score:1)
Re:This won't replace conventional PCBs (Score:1)
research [berkeley.edu]
use in solar cell production [nanosolar.com]
Re:This won't replace conventional PCBs (Score:2)
Though maybe it was developed too late... Dual core comming and all.
Re:This won't replace conventional PCBs (Score:4, Insightful)
I can see this technology as starting point of a pcb manufacturing revolution. Connectors directly molded on to the pcb.
Re:This won't replace conventional PCBs (Score:2)
This new technology could certai
A happy side effect (Score:2)
If Epson was really concerned with environmental issues, they wouldn't manufacture mass-amounts of printers which are basically more economically feasible to send to a landfill than refill...
And no, I'm not trolling: lots of companies will go ahead with a project and say "lookie at me, I'm environmentally friendly" whilst in the background slipping poisonous chemicals into a nearby lake or something
Re:This won't replace conventional PCBs (Score:2)
Historically, the failure of solder points on circuit boards was the most frequent cause of failure of early integrated ciccuit based electronic equipment.
Re:This won't replace conventional PCBs (Score:3, Funny)
And here I thought that most of the money was made on large, government operated printing presses. I guess those counterfieters are busier than ever with their little ink jet machines and laser printers.
Re:This won't replace conventional PCBs (Score:1)
As if.. (Score:4, Insightful)
Once upon a time there were technicians that could take any piece of consumer electronics, and given a good repair manual, trouble shoot the problem and replace the offending component.
This creates a monopoly of sorts - since repair is impossible, the manufacturer has sole control over their product, so their profit margin increases. It behooves them to create products that cannot be repaired.
Dan East
Re:As if.. (Score:1)
Re:As if.. (Score:4, Interesting)
I totally agree. I wonder what is better for environment: produce liquid chemical waste by making conventional circuit boards or produce a lot (potentially toxic) solid waste composed of discarded devices that can not be repaired.
Chemicals involved in circuit board manufacturing aren't that toxic at all. Photoresist is developed with NaOH or KOH, both of which will decompose when exposed to carbon dioxide in the atmosphere. HCl that is used for etching copper will also be neutralized by, for example, limestone in the environment.
Once upon a time there were technicians that could take any piece of consumer electronics, and given a good repair manual, trouble shoot the problem and replace the offending component.
I can't believe that today I give big bucks for an expensive instrument (e.g. osciloscope in my case) and don't even receive a circuit board chart. Not so long ago you got a circuit board chart with a cheap FM radio... And guess what? That radio is still working after 30 years (and three or four minor repairs).
Re:As if.. (Score:2)
Re:As if.. (Score:2)
Ah yes, and then they developed the integrated circuit with 10,000 transistors on them. And we are in the millions today. It just isn't possible anymore to be able to repair individual components in a modern day computer with the current level of minituriziation. The only way we could do that would be to go back to havin
Re:As if.. (Score:2)
By making the components so small, and still having good reliability, the costs saved per unit can actually add up to be more than making a large repairable unit.
Which would you rather have: A unit that costs $10, with an expected lifespan of 5 years, or a unit that costs $20, with life expected until the first repair needed of 5 years, and a repair cost of $5?
Now, the ratios change around and such, but for most consumer goods, at $20-30 an hour for a repair tech, it has to be
Re:As if.. (Score:1)
The components cannot be replaced... no
Image an equivalent to the "print on demand" commercials. Replacement parts which are "printed" or created on demand. There is no need to maintain a stockage of replacement parts. Customer (or repair shop) calls up and says "I need this part," the vendor simply prints and ships.
Will it be used this way? Hard to say. I'm guessing that probability will be proprotional to cost of total cost of end item.
Re:As if.. (Score:2)
Re:As if.. (Score:2)
Re:As if.. (Score:2)
This creates a monopoly of sorts - since repair is impossible, the manufacturer has sole control over their product, so their profit margin increases. It behooves them to create products that cannot be repaired.
I thought it was always like this. I've never see people repair any consumer electronics. What really comes to mi
Re:As if.. (Score:2)
Ewan
Printed boards (Score:5, Interesting)
Firstly, thin layers of silver particles mean very limited power supplies. The thin layers of insulation will also limit the working voltage. This can be overcome so some extent by printing multiple layers, but that may cause problems in the drying/curing process.
Secondly, the thin layer of insulation will result in significantly higher capacitance between layers. This will probably limit high frequency applications and result in every other layer being a ground plane to limit coupling in other applications.
Still, it's a step in the right direction.
Keith.
Re:20 Layers and it dose what? (Score:1)
With todays CPU dies having something like 700 pins it's getting pretty darn difficult to connect them up using a 4 layer board. The ability to route them over 20 layers would mean we could design much smaller PCBs.
There is still a long way to go though, both in taking this technology from the laboratory to production, and in developing high density packaging for dies which can still dissipate enough heat to keep working.
Just my afternoon thoughts,
Keith.
Smaller PCBs? (Score:2)
Not the first? (Score:2, Informative)
dont you understand???? (Score:5, Interesting)
Re:dont you understand???? (Score:1)
The implications of 3d inkjet printing are perhaps more in the questions inspired than in what is produced at this time. What will be the effect of open source hardware? What happens when a desktop peripheral as economical as your printer manufactures custom computer circuitry, solar cells and batteries as cheap as wallpaper? A desktop peripheral printing all the circuits needed for it's own next generation. Or when distributors
Not the first 20 layer board (Score:5, Informative)
What looks to be new is the fast, cheap, and hopefully environmentaly friendly way to make boards. Also, from the picture, this has to be the thinnest 20 layer board by far - a distinct advantage in light weight hand held devices. But the thin board raises some questions for board designers such as "what is the trace impedance". However, that's one of many details that we won't know the answer to until the technology is commercialized (oooo, a nounized verb!!!)
Re:Not the first 20 layer board (Score:1)
but perhaps the first one NOT to use
wirewrap (reflecting on a distant past
with DEC VAX backplanes and boards).
One of an earlier generation of prototype
PWBs was to route out thin wires and epoxy
over for the next layer -- expensive way to
get that 9 layer board, but great for 1 ofs.
Unfortunately (or fortunate for Epson), the
inkjet printer industry's use of "smart"
ink cartridges (and the DMCA) will kill off
any homebrew adaptaion of this technology.
I have a PostScript HP inkj
Re:Not the first 20 layer board (Score:1)
-[adjectivize]--> commercial
-[verblate]--> commercialize
--[tensify preteritic]-> commercialized
walk halfway to destination. repeat.
The "world's first 20-layer" statement is absurd! (Score:4, Informative)
Hello,
The article...
http://www.physorg.com/news1789.html
"Seiko Epson Corporation today announced that it has succeeded in leveraging its proprietary inkjet technology to develop what the company believes is the world's first 20-layer circuit board."
No. Not even close. I have personally worked on circuit boards of as many as 48 layers, as long ago as 1985. The math coprocessor for the Sperry-1100/90 (code named "Eagle") had a motherboard that was roughly 20" x 36" in size, had forty-eight layers, was about 1/2" thick, had solid silver bus bars laminated in each side, weighed about forty pounds, and was so hard that if you knocked on it with your knuckle, it would ring like a bell.
There is no possibility that the people at Epson believe they've built the world's first twenty layer board. Twenty layer boards are a little uncommon, but far from record-breaking.
Sincerely,
BrakesForElves
Founder and past President
FASTechnologies, Inc. www.fastec.com
Re:The "world's first 20-layer" statement is absur (Score:1)
Dyconex [dyconex.com] manufacture 30-layer boards, and have done for years. Not quite as big as your 48-layer board, but still enough to debunk the claim in the article.
Re:The "world's first 20-layer" statement is absur (Score:2)
Re:The "world's first 20-layer" statement is absur (Score:3, Informative)
THEY HAVE CHANGED IT!!! (Score:3, Informative)
Has become....
"Seiko Epson Corporation today announced that it has succeeded in leveraging its proprietary inkjet technology to develop ultra-thin 20-layer circuit board."
Nice job!
Re:The "world's first 20-layer" statement is absur (Score:2)
"Seiko Epson Corporation today announced that it has succeeded in leveraging its proprietary inkjet technology to develop ultra-thin 20-layer circuit board. "
Nice. (Score:3, Interesting)
First the circuit is printed.
Next the conductive cement is printed.
Finally a component transfer drum 'prints' the components on to the board.
The drum could made of a plastic on a rapid prototype machine and mounted in a loader (drum rotates and components are dropped into pockets)
for small runs. For large runs the drum would serve as a pattern for something that woudl hold up longer.
The result is a very rapid transition from CAD/modeling stage to large scale production.
Refinements for projects you know from the get go are going to be big would include printed resistors and capacitors. A series of printers with multiple heads for the various 'ink' flavors would work best for this. Resistance with a few ink mixes and pattern/width for values within ranges. In this scenario you only need to 'print' active devices and larger inductors and capacitors. All else is done with the ink.
I bet this technology will be up and running before then end of 2005 and cranking out helmet electronics for military, wrist watch cell phones, and some really cool Cracker Jack(tm) toys.
addendum to nice (Score:3, Interesting)
one could print other chemistry (battery, sensor, display, etc) right on the board. I can see ultra thin $3 wristwatches where the watch and battery are integrated into the band.
Let me get this strait?! (Score:2)
Of course, they've used some other special 'ink' then the regular printer-ink; a conductive /non-conductive -ink to 'print' the PCB. *neat'o*
As, Avian visitor (257765), (#10684903) [slashdot.org] said " it is relatively cheaper to produce a small quantity of boards" thus "Most of the money today is made with consumer electronics where there is a requirement of large series of identical boards so this is no longer such an adva
s/produce PCBs/produce Multilayer-PCBs/ (Score:2)
Ultra thin circuit boards suck. (Score:2, Interesting)
Ultra thin boards break their solder joints very easily. Thermal cycling seems to affect thinner boards more than thicker ones and leads to bad solder joints. Unless the resulting boards are small and have a LOT of mounting points they flex and break, especially if the boards are large.
Unless the thing can flex like an acor
neutron_p (Score:4, Informative)
http://slashdot.org/search.pl?query=neutron_p [slashdot.org]
Do we have another Roland on our hands? Why not just post a link to the original story on the original news site?
Printing (Score:3, Informative)
Another problem with multi-layer boards is vias {a via is a plated-through hole just used for connecting one layer to another, not carrying a component lead}. The way the plating process works means that all copper layers will be joined to each other. So you can't join, say 1-2 and 4-5 at the same hole; and you soon run out of sites if you aren't very careful. So more than 10 layers is rare, because there is usually a better way to do what you were trying to do.
Still, with 20 layers it's possible to print actual coils, not just bent bits of wire that only look like a coil at UHF and above, and capacitors. A printed coil ought to be more reliable than a wound one. Perhaps we'll start seeing more circuits that use real inductances!
Multiplayer (Score:2)
Where's my E&M textbook? (Score:3, Interesting)
'Nother silly press release (Score:2, Informative)
Ink stability (Score:1)
A good laugh (Score:1)
PCB Manufacturing
Order Quality PCBs 2 to 24 Layers. 12-Hour Turns & Same-Day Shipping.
Apparently Epson's breakthrough in layer counts caught on in record time!
Re:any cost considerations? (Score:1)
Re:any cost considerations? (Score:1, Interesting)
Re:any cost considerations? (Score:1)