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- Feb 1, 2015
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- 9,578
Some time ago, I had a need to make some gaskets for an outboard motor that I was rebuilding. I have made gaskets the old fashioned way, cutting them out with an Exacto knife and gasket punches but that wouldn't cut it for the highly detailed gaskets that I needed. A better way was required.
Back in 2015, I had the opportunity to purchase a digital microscope. With the microscope mounted in the spindle of my Tormach CNC, I would have the tool that I needed to trace the outlines of the gaskets. The procedure was basically to pick up coordinates of key features of the needed gasket and put those points into a CAD drawing. By connecting the dots, this allowed me to easily and accurately reverse engineer the gasket. I used the drawing to create a solid model which was imported into my CAM software.
Here is the thread to that build.
https://www.hobby-machinist.com/threads/another-lathe-dro-install.34106/
The problem with making a gasket is that it can't be cut with a milling cutter. I made a drag knife which worked reasonably well but the gasket had to be glued to a backing material in order to make cuts of small details. Not the best.
Then I got the idea of cutting the gasket using a laser. I found a reasonably priced 4.5w blue laser on the internet. A bracket and adapter to fit a 1/2" tool holder were made for the laser. The laser needed to be turned off and on with the CNC controller. The easy way out was to use the flood coolant control circuit. This circuit switches 120 vac. through a relay but I needed to control the 12 volt supply to the laser. A second relay with a 120 vac. coil provided for this.
The outboard project got sidetracked and the laser got shelved for the time. This past week, I had the need for a gasket to repair a small engine. Although I have had the setup for some time, I had never used it in this capacity before so some experimenting was in order.
A two main operating parameters needed to be determined; the focal point of the beam, and the feed rate. I focused the laser at the shortest possible distance so the focal point would be as small as possible. The 4.5 w. laser is extremely dangerous and another benefit of a short focus is that the beam rapidly diverges at greater distances. Nevertheless, to prevent accidental exposure of the eyes to the beam, red safety glasses must be worn whenever the beam is on. This creates a problem as the blue laser beam is almost completely blocked so you can't see to focus the beam properly.
To get around that problem, I wrote a small G code program which increased the operating distance by .05" steps. In setting up my work on the Tormach CNC, I have a digital dial indicator mounted in a TTS holder and to reference out my workpiece, I lower the indicator until it zeroes and set my work zero at that height. Then I determine my tool offsets relative to the indicator.
I ran my program, using and arbitrary 10 ipm feed and in examining the result, it was clear that a complete burn through my gasket material was occurring at a distance between .28" and .39". I opted for setting the operating distance at .33" relative to my indicator.
That settled, I decided to go for it and use the same feed speed as my test program and actually cut a gasket. The gasket turned out well, nearly as crisp as a die cut gasket, and true to the mating parts, thanks to the spindle microscope optical comparator. Yet another tool to add to the arsenal.
Going further, the gasket that I cut was a .02" thick dark paper. Different gasket materials will have different optimal feed rates. Too fast and there won't be complete penetration. Too slow and you could actually start the gasket on fire. Every material would most likely have to be tested to optimize the feed. To that end, I wrote another G code program to vary the feed rate in steps ranging from 40 ipm down to 2 ipm.
Another factor would be the backing plate. I used a white ceramic tile in this work but the ceramic will absorb heat locally. Another option to explore would be to use a metal backing plate. The metal is more likely to reflect the beam but it has better heat dissipation properties.
As to other possible uses, one that comes to mind is making printed circuit boards. I use the CNC to mill printed circuit patterns but I am limited by the smallest diameter end mill that I can run. The smallest that I have run so far has been .024". The laser isn't powerful enough to burn the copper pattern but the thought was to coat the copper with an etching resist and burn the pattern in the resist. Then the board would be etched using traditional chemical etching.
This photograph shows the results of the focus calibration program. The castellated path makes it easy to determine where the best performance occurs.
This photograph shows the laser setup. The part the gasket is being made for is in the bottom center of the photo.
This photograph shows the laser setup with two cut gaskets in place. The laser generates no cutting forces so holding down of material is strictly for keeping it flat. In setting up the work, I set my z axis zero as described above. For the x and y axes, I used a pointer mounted in the spindle. The laser is offset from the spindle axis by .9" in the y direction so I offset my work by that much to center the laser.
This photograph is of the cut gasket.
Back in 2015, I had the opportunity to purchase a digital microscope. With the microscope mounted in the spindle of my Tormach CNC, I would have the tool that I needed to trace the outlines of the gaskets. The procedure was basically to pick up coordinates of key features of the needed gasket and put those points into a CAD drawing. By connecting the dots, this allowed me to easily and accurately reverse engineer the gasket. I used the drawing to create a solid model which was imported into my CAM software.
Here is the thread to that build.
https://www.hobby-machinist.com/threads/another-lathe-dro-install.34106/
The problem with making a gasket is that it can't be cut with a milling cutter. I made a drag knife which worked reasonably well but the gasket had to be glued to a backing material in order to make cuts of small details. Not the best.
Then I got the idea of cutting the gasket using a laser. I found a reasonably priced 4.5w blue laser on the internet. A bracket and adapter to fit a 1/2" tool holder were made for the laser. The laser needed to be turned off and on with the CNC controller. The easy way out was to use the flood coolant control circuit. This circuit switches 120 vac. through a relay but I needed to control the 12 volt supply to the laser. A second relay with a 120 vac. coil provided for this.
The outboard project got sidetracked and the laser got shelved for the time. This past week, I had the need for a gasket to repair a small engine. Although I have had the setup for some time, I had never used it in this capacity before so some experimenting was in order.
A two main operating parameters needed to be determined; the focal point of the beam, and the feed rate. I focused the laser at the shortest possible distance so the focal point would be as small as possible. The 4.5 w. laser is extremely dangerous and another benefit of a short focus is that the beam rapidly diverges at greater distances. Nevertheless, to prevent accidental exposure of the eyes to the beam, red safety glasses must be worn whenever the beam is on. This creates a problem as the blue laser beam is almost completely blocked so you can't see to focus the beam properly.
To get around that problem, I wrote a small G code program which increased the operating distance by .05" steps. In setting up my work on the Tormach CNC, I have a digital dial indicator mounted in a TTS holder and to reference out my workpiece, I lower the indicator until it zeroes and set my work zero at that height. Then I determine my tool offsets relative to the indicator.
I ran my program, using and arbitrary 10 ipm feed and in examining the result, it was clear that a complete burn through my gasket material was occurring at a distance between .28" and .39". I opted for setting the operating distance at .33" relative to my indicator.
That settled, I decided to go for it and use the same feed speed as my test program and actually cut a gasket. The gasket turned out well, nearly as crisp as a die cut gasket, and true to the mating parts, thanks to the spindle microscope optical comparator. Yet another tool to add to the arsenal.
Going further, the gasket that I cut was a .02" thick dark paper. Different gasket materials will have different optimal feed rates. Too fast and there won't be complete penetration. Too slow and you could actually start the gasket on fire. Every material would most likely have to be tested to optimize the feed. To that end, I wrote another G code program to vary the feed rate in steps ranging from 40 ipm down to 2 ipm.
Another factor would be the backing plate. I used a white ceramic tile in this work but the ceramic will absorb heat locally. Another option to explore would be to use a metal backing plate. The metal is more likely to reflect the beam but it has better heat dissipation properties.
As to other possible uses, one that comes to mind is making printed circuit boards. I use the CNC to mill printed circuit patterns but I am limited by the smallest diameter end mill that I can run. The smallest that I have run so far has been .024". The laser isn't powerful enough to burn the copper pattern but the thought was to coat the copper with an etching resist and burn the pattern in the resist. Then the board would be etched using traditional chemical etching.
This photograph shows the results of the focus calibration program. The castellated path makes it easy to determine where the best performance occurs.
This photograph shows the laser setup. The part the gasket is being made for is in the bottom center of the photo.
This photograph shows the laser setup with two cut gaskets in place. The laser generates no cutting forces so holding down of material is strictly for keeping it flat. In setting up the work, I set my z axis zero as described above. For the x and y axes, I used a pointer mounted in the spindle. The laser is offset from the spindle axis by .9" in the y direction so I offset my work by that much to center the laser.
This photograph is of the cut gasket.