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SYNRAD, INC. - http://www.synrad.com
Thursday, February 3, 2005
Issue 105
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Cutting Clear Polyester (PETF) Film
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Stripping Fluoropolymer Wire Insulation
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Marking Plastic Automotive Parts
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SYNRAD's sealed CO2 lasers are used in a variety of industrial processes including cutting, welding, drilling, and marking. This news brief showcases some of the interesting materials and products that are processed daily by Synrad's line of CO2 lasers and marking heads.
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Cutting Clear Polyester (PETF) Film
Whether produced in the form of a fiber, film or plastic, polyester or polyethylene terephthalate (PET) is increasingly found in various products including clothing, beverage bottles, photographic-quality printing film, and food grade packaging, to name just a few examples.
In particular, PETF – a semi-crystalline polyester film – has a variety of uses depending on its thickness, which is measured in mils (1 mil = 0.001 inch). Thin gauge, 1.5 mil material, is flexible enough to serve as a protective coating when laminated over products while thicker gauge films are specified depending on a product’s desired rigidity. In some cases, a polyethylene layer is added to create a polyester/polyethylene laminate.
In our first application (Figure 1), large sheets of 7-mil clear polyester film were cut on an XY table. Our cutting setup consisted of a 50 W Synrad sealed CO2 laser with the beam delivered through a 2.5” focusing optic, which provided a 0.004” (100 micron) beam diameter with a 0.07” (1.8 mm) depth of focus. We used air, at a pressure of 5 PSI, as an assist gas. This setup allowed us to cut the polyester film at line speeds of 2000 inches per minute (IPM). The cut edge was clean and burr-free; however, because PETF exhibits exceptional clarity, cut edges sometimes appear “cloudy” due to the deposition of vaporized residue. If this occurs, careful adjustment of fume extraction or the use of secondary cleaning procedures easily eliminates this issue.
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Figure 1. This clear polyester film was cut using 50W of laser power.
Figure 2. An FH Marking Head and 60W laser was used to cut small parts from the polyester film.
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The second application (Figure 2) shown here involves cutting small parts from sheets of 7-mil PETF using an FH Series marking head. The marking head was fitted with a 125 mm focusing lens (0.007” / 180 micron spot) and aligned to a 60 W Synrad CO2 laser. Although the part shape could have been imported into WinMark Pro as a CAD drawing, this object was created entirely in WinMark using WinMark Pro’s new capability to draw elliptical objects. At a power level of 60 W and a velocity of 30 inches per second (1800 IPM), parts were cut out at the rate of one every 0.17 seconds.
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Stripping Fluoropolymer Wire Insulation
Fluoropolymers are thermoplastic polymers where some or all of the hydrogen has been replaced by fluorine. These materials (TFE, PFA, PVDF, etc.) are resistant to high temperatures (including fire), chemicals, weathering, and abrasion. They also exhibit low coefficients of friction, high dielectric strength, and are chemically inert. Taken together, these properties define the ideal material for insulating electrical wire.
Note that an actual integrated CO2 wire stripping machine would create a complete cut around the wire circumference so that the insulation could be pulled off in preparation for termination. In some specialized applications involving ribbon or multi-connector cable, the beam may be scanned across the wire to strip selected conductors at predetermined points so that individual conductors are connected to only certain components along the wiring path.
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10 AWG and 26 AWG wires after ablating (cutting) the insulation.
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The connection to CO2 lasers is twofold: First, fluoropolymers are easily vaporized by CO2 lasers; and two, copper and aluminum wire are reflective at the 10.6 micron wavelength. Because the wire is not nicked or damaged by the laser beam, wire stripping is an excellent application for Synrad CO2 lasers. This application highlights a proof-of-concept test for stripping 10 AWG and 26 AWG fluoropolymer-coated wire.
To obtain a 0.004” (100 micron) focused spot size, our cutting setup consisted of an XY table, a firestar f201 200W laser, a 2.5” focusing lens, and air assist set to 5 PSI.
The 26 AWG (thin wire) has a 0.003” (0.08 mm) thick insulation coating that we ablated at a speed of 900 inches per minute (IPM) using 50 watts of power. At the 100 W power level, we achieved a cut velocity of 2000 IPM.
When stripping the 0.0135” (0.34 mm) thick fluoropolymer coating from the 10 AWG (thick wire), we cut through the coating at a speed of 900 IPM using 100 W and cut at a speed of 1800 IPM using 200 W of power.
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Marking Plastic Automotive Parts
The plastic socket, from an automotive assembly, shown in the photo to the right produced an engraved mark with some contrast. The beam from a 10W Synrad laser was steered with an FH Series marking head and focused through a 200 mm FH lens (290 micron spot / 5mm depth of field). The 0.25"-high date code was marked at a speed of 10 inches per second in a cycle time of 0.33 seconds.
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This plastic socket was marked with a simple
date code using 10W.
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Browse Synrad's Applications Database
Search our online library for more applications of Synrad's sealed CO2 laser technology. Sort by material, process, or industry.
http://www.synrad.com/search_apps/Default.htm
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Contact Us:
Synrad, Inc.
4600 Campus Place
Mukilteo, WA 98275
Tel: 1-425-349-3500
Fax: 1-425-349-3667
E-mail: synrad@synrad.com
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Copyright (c) 2005 SYNRAD, Inc. All rights reserved.
SYNRAD and Synrad product names are trademarks or registered trademarks of SYNRAD, Inc. All other trademarks or registered trademarks are the property of their respective owners.
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