This page is intended to be an all-inclusive guide to getting your PCB made and assembled on the OEDK's PCB milling machine. If you learn a better or faster way of doing any of the things listed here (or believe there should another section) feel free to add it in so that others can benefit from your knowledge.
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The PCB mill is great way to prototype PCBs because it is able to:
Unfortunately the PCB Mill has a few limitations. It can not do:
The PCB Mill is located in the OEDK Room #131 (Solder Lab) along with the [electronic components], Stereo Microscope, and Solder Oven
The parts for the PCB MIll can be checkout from [Carlos Amaro]. They include:
The software for the PCB Mill accpets standard Gerber files for traces and features as well as NC Drill Files for the holes that need to made
If you are making a really simple PCB then you might be tempted to just put all the traces on the "Top" layer of the PCB, however think really hard before you do this. The pads of the component you are going to use will be replicated on both sides of the board (assuming you take into consideration dealing with a copper clad --- BUT the traces only connect to 1 of the pads -- specifically the pad on the layer that the traces were drawn on.
[Some Pictures and Examples]
Unlike a PCB order from a normal [PCB house] PCBs on the PCB Mill are made by isolating the desired trace from the plate of copper (known as the "copper clad"). This can cause problems because according to your design there is only a thin trace of copper between any 2 points amongst a sea of essentially nothing (more specifically nothing conductive that would get in the way). With the isolation method that the PCB Mill uses, you have to make sure that your layout program of choice knows that there is copper everywhere else. Otherwise components will
In a normal PCB from a PCB House PCBs will have plated through holes. That means that every drill is plated with copper so that the pad on the top is physically and electrically connected to the pad on the bottom. This means that you can run a trace to the top pad or the bottom pad without any consideration. With the PCB milling machine the top and bottom pads ARE NOT connected. So lets say you have a normal through-hole resistor. It needs 2 holes for it to connect correctly, the drill will pass through the top layer of copper then the FR4 fiberglass material between the copper layers and finally through the last layer of copper. The pads are then isolated on either side of the
Always drill FIRST then mill. Doing it the other way around may result in the drill pulling up an etched trace and destroying the work of the milling process (especially for thin traces) |
The easiest way to verify the correct drill depth is to insert the drill into the collet all the way up the collar (the little brightly colored plastic ring that should be on all the drills, should have the drill size marked on the same ring in white). Use the jog function of the mill to move the head so that the drill bit itself is just to the left of the copper clad board but the foot of the head is still squarely on the copper clad. Use your hand (NOT the head down command in the jog window) to gently lower the head until you either reach the bottom of the head stroke or the drill touches the material. If the drill touches the material before the head bottoms out you need to adjust the Up/Down adjustment ring on the head until the drill just barely grazes the aluminum sacrificial board. Now adjust the lower limit of the head so it will go down just a little a more into the sacrificial board. Ideally you want the conical section at the top of the drill head to be fully embedded into the sacrificial board so that only the uniform section of the drill goes through the copper clad.
Once you believe that you have set the drill depth correctly, jog the drill head to a spare spot on the copper clad, turn on the drill spindle to reasonable speed and then activate the "head down" command in the jog window. Inspect the hole to insure that it has fully and cleanly penetrated the entire copper clad, but has not gone too far (more than 1/4 of the way) into the sacrificial board.
Go ahead and run through all the drills that you need to do on the entire board. Since the drill bit collars are gaurenteed to all be at the same height, you do not need to readjust the drill depth for every new hole size you have to drill.
If your drill does not have a collar (AKA you got it from ELEC 342 or the likes...grrr....) then you will have to re-adjust the drill depth for every drill that you use or insert all the drills all the way to bottom of the drill collet (or get the bits from the OEDK).
Always mill the traces AFTER you drill the holes, doing it the other way may result in the drill pulling up an etched trace and destroying the work of the milling process. |
The easiest way to set or verify the correct mill depth is to insert the mill all the way into the collet. Be careful with the end mill as jogging the head while the end mill is too low, will result in snapping the end mill on the edge of the copper clad. The end mills are extremely delicate.
In order for the end mill to properly cut through the copper layer of the board the machine needs to know how fast (think inches in a the X direction per second) to move the end mill.
If the end mill is moving too quickly then the copper may appear "torn off" instead of cleanly milled away. This could lead to inadvertent shorts through the isolation layer between traces. It will also require considerably more effort to clean up after you are done milling the board.
The primary factor that effects the mill feed rate is the thickness of the copper that is on the copper clad. A thicker copper layer will provide lower resistance to an electrical resistance, but will take slightly longer to mill through (aka the feed rate needs to be slower).
The following feed rate table is a good starting point for settings, however you may need to adjust the values depending on how deeply you mill into the FR4. Always perform test mills and feel the edges of the cuts that the mill makes in order to judge for yourself if the feed rate is too fast.
No harm can come from setting the feed rate too slowly (it'll just take a little longer), but you can permanently damage the machine, end mill, and PCB board if the feed is to HIGH. |
The best way to clean a copper clad board after milling all the traces and drilling the holes is with de-ionized water and light abrasive such as a fiberglass scour or brush.
You should always clean the board after milling to reduce the number of copper shards left over by the milling and drilling process. While a good cleaning will not guarantee complete removal of artifacts such as copper shards, it certainly reduces the chance of such artifacts being present (especially smaller artifacts such as copper dust or fiberglass dust).
Beware that excessive cleaning will result excessive oxidation of the copper on the board. If you do not plan on soldering your components onto the board soon after you have cleaned the board, the fresh copper on the copper clad board will rapidly oxidize and make soldering harder if not nearly impossible. To mitigate the effects of oxidation on soldering effectiveness be sure to clean the board before soldering and use plenty of flux. While most solder has a inner resin flux core that is essential to soldering, you may find that the heavy oxidation that builds up on bare copper may require extra flux. Use a flux pen to apply a small amount of solder on the pad immediately prior to soldering just that pad do not apply flux to the entire board, it will dry up and move around on you and likely defeat the purpose.
Ultrasonic cleaners (such as the one in the machine shop) can be used for this purpose, but care must be taken that the bowl does not have random metal shavings or dust that have collected from cleaning machined items. These particulate may embed themselves in the isolation between traces and cause shorts. Always rinse the board after cleaning with the ultrasonic cleaner, failure to do so will result in a sticky mess and impossible soldering. This is because the cleaner uses a solution of water and industrial detergent, the detergent will leave a thin film behind that is intended to be rinsed away. Do not forget this step!
Due to the imperfect nature of the PCB milling machine, once a board is finished milling and drilling there can often times be little bits of copper
Tools you will need: