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PCB Manufacture: Difference between revisions

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=== Multiple Passes ===
=== Multiple Passes ===
While it is possible to mill a circuit board correctly the first time, doing so typically produces a low-quality board with wide isolation paths, and small (or completely removed) copper traces. For surface mount devices (especially chips), or high performance analog circuitry, higher quality is required.
Setting "zwork = 0" and using a spade bit allows extremely fine isolation paths to be developed after multiple passes. This technique is sometimes helpful for surface mount devices.


The best approach involves making multiple passes.
First touch off the mill's Z axis to 0.0 when it is barely touching the copper clad board. Now execute a PCB milling NCG script. After milling a pass at this depth, all traces should be clearly visible but not electrically isolated.
 
First touch off the mill's Z axis to 0.0 when it is barely touching the copper clad board. Set the maximum feed rate (in EMC2) to 3in/min. Now execute a PCB milling NCG script. After milling a pass at this depth, all traces should be clearly visible but not electrically isolated.


With the first milling pass complete, remove the maximum feed rate restriction, and execute the following gcode commands.
With the first milling pass complete, remove the maximum feed rate restriction, and execute the following gcode commands.
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Now touch off the mill's Z axis to 0.0. Executing the NGC script again will repeat the PCB milling at a slightly lower depth.
Now touch off the mill's Z axis to 0.0. Executing the NGC script again will repeat the PCB milling at a slightly lower depth.


Finally, blow/brush all dust off the PCB, and test traces for electrical isolation with an continuity tester. If none of the traces short circuit, switch to an ohm meter, and make sure all of the traces are completely open circuits. It is not uncommon to find multi-megaohm connections between traces.
Finally, blow/brush all dust off the PCB, and test traces for electrical isolation with a continuity tester. If none of the traces short circuit, switch to an ohm meter, and make sure all of the traces are completely open circuits. It is not uncommon to find multi-megaohm connections between traces.


If the board is not electrically isolated, mill another pass, going slightly deeper. At 6in/minute, this should not take long. Once the board is electrically isolated, mill one more pass to ensure long-term reliability and minimize soldering issues.
If the board is not electrically isolated, mill another pass, going slightly deeper. Once the board is electrically isolated, mill one more pass to ensure long-term reliability and minimize soldering issues.


=== Finishing Off ===
=== Finishing Off ===

Revision as of 17:22, 31 May 2013


Precisely manufacturing circuit boards with the CNC Mill can be high-quality, cheap, and fast.

gEDA

The ideal tool for the artwork is probably gEDA. Start by making a schematic, convert it to a pcb file, export that as a gerber file, and use pcb2gcode to convert to gcode.

pcb2gcode

Place the following lines (or similar) into a file called millproject in the same folder as the gerber files. Then execute pcb2gcode in that folder.

# You may want to uncomment and change those in local project files
front=Project.top.gbr
#back=Project.back.gbr
outline=Project.outline.gbr
drill=Project.plated-drill.cnc


# The board outline is 10mil wide, no holes
fill-outline = yes
outline-width = 0.0433071	#1.10 mm bit.

# parameters for isolation routing / engraving / etching
#offset=1			#voronoi regions (commented out)
offset=0.0433071		#1.10 mm bit.
zwork=0.0492126			#1.25mm above table. Boards usually >1.5mm thick.
zsafe=0.19685			#5mm above table.
mill-feed=2.95276		#75mm/min. Always go slow here.
mill-speed=10000


# parameters for cutting out boards
cutter-diameter=0.0433071		#1.10 mm bit.
zcut=0					#Right on the table.
cut-feed=2.95276			#75mm/min.
cut-speed=10000
cut-infeed=0.00393701			#Lowers Z 0.1mm each pass.


# drilling parameters
zdrill=0			#Right on the table.
zchange=0.19685			#5mm above table.
drill-feed=0.984252		#25mm/min
drill-speed=10000
drill-front=true
milldrill=false

The resulting *.ngc files can be loaded onto the CNC mill's dedicated computer and loaded in the controller software (Mach3).

Cavets

Newer versions of gEDA offer direct pcb file to gcode conversion. This is untested, and does not seem to offer as much control over the results as pcb2gcode.

All areas around the copper traces will need to be grounded, and wires will need to be soldered to power, input, and output connections. Be sure to include enough space in your design to accommodate this.

Milling

Practice

Touch off the Z axis to 0.0 while it is above the milling surface. Then execute your NGC file, and carefully observe the results step by step. Practicing on air this way greatly reduces the risk of making coasters or damaging the mill.

Copper Clad Board

Ideally, we are milling isolation paths between PCB traces on a copper clad board. These boards can be obtained at RadioShack, and other places.

Correct Bit

The narrowest possible spade bit should be used for milling high-quality circuit boards.

Low quality boards may get away with wider spade bits.

Multiple Passes

Setting "zwork = 0" and using a spade bit allows extremely fine isolation paths to be developed after multiple passes. This technique is sometimes helpful for surface mount devices.

First touch off the mill's Z axis to 0.0 when it is barely touching the copper clad board. Now execute a PCB milling NCG script. After milling a pass at this depth, all traces should be clearly visible but not electrically isolated.

With the first milling pass complete, remove the maximum feed rate restriction, and execute the following gcode commands.

g0 x0 y0 z0.25
g0 z-0.001

Now touch off the mill's Z axis to 0.0. Executing the NGC script again will repeat the PCB milling at a slightly lower depth.

Finally, blow/brush all dust off the PCB, and test traces for electrical isolation with a continuity tester. If none of the traces short circuit, switch to an ohm meter, and make sure all of the traces are completely open circuits. It is not uncommon to find multi-megaohm connections between traces.

If the board is not electrically isolated, mill another pass, going slightly deeper. Once the board is electrically isolated, mill one more pass to ensure long-term reliability and minimize soldering issues.

Finishing Off

Large portions of electrically unused copper will surround the desired copper traces. These should be given a low impedance (fat wire, solder blob, etc) connection to ground.

Not only will this maintain the performance of some high-speed amplifiers, it will help shield the circuit from noise.

Examples

Some high-quality board have already been manufactured at HacDC, and will be added to this wiki as examples.