If
you are a frequent flier, you are probably very familiar with the flight attendant's
pre-flight announcement-how the seat belt works, how to put on your oxygen mask,
your seat cushion can be used as a flotation device and check for the nearest
exit. In the past several years, the airlines have added another announcement
to the end of the pre-flight message-turn off all portable electronic devices
until the captain has turned off the fasten seat belt sign.
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| This
turbine is used to power all of Cybershield's robotic cells. It's mounted about
20 ft high on the wall and about 60 ft from the closest robotic cell. There is
another turbine that is used to power the HVLP spray guns in the manual booths.
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EMI/RFI
For someone electronically challenged like myself, it was hard to understand how
my CD player, laptop computer or cell phone could have any affect on the airplane.
So, why did the airlines add this announcement? The reason is EMI and RFI, or
electromagnetic interference and radio frequency interference. When electronic
devices are in use, they emit electromagnetic and/or radio waves. When several
electronic devices are in close proximity to each other, the waves from one device
can hinder the performance of the other. Therefore, your personal electronic devices
can interfere with the electronic devices that run the plane.
In order to prevent EMI and RFI, electronic devices are manufactured with a shield.
Shielding is a technique used to control the interference between electronic devices
by preventing the transmission of electromagnetic and radio waves. Shielding can
be accomplished in a variety of ways, but two of the more common methods are plating
and painting.
EMI and RFI shielding paints contain metallic flakes, since the coating needs
to be conductive. The metallic flakes are usually nickel, copper, silver or some
combination of those metals. While using conductive paints is a relatively inexpensive
method for EMI and RFI shielding, the paints are still quite expensive-about $125-255/gal-when
compared to more common decorative paints.
Shielding
Plastic Components
Cybershield of Georgia, Inc. (Canton, GA) is a high-end, high-volume job shop
that shields a variety of plastic components for cell phones, radar guns, computers
and a variety of other electronics. The company uses a variety of processes to
shield these parts, including selective electroless plating, all over electroless
plating and conductive painting, but the important process for this article is
the conductive painting.
Other
Steps in the Shielding Process
In addition to conductive painting, Cybershield performs a number of other steps
in the shielding process.
Selective Electroless Plating. The company selectively plates electroless
copper and nickel on specified surfaces only, usually the inside of a plastic
enclosure. The selective plating process uses a special autocatalytic basecoat,
which is applied by the turbine-powered HVLP spray guns mentioned in the article,
to the areas where plating is desired. The chemical makeup of the basecoat allows
copper metal to be drawn out of solution and deposited uniformly. A subsequent
layer of nickel plating provides environmental stability for the highly conductive
copper and enhances scratch and wear resistance.
All Over Electroless Plating. This process allows all surfaces to be electroless
plated with pure metallic copper followed by a tough nickel topcoat. From a shielding
perspective, no other post-molding shielding process can provide the same applied
uniform thickness. This process also allows a multitude of decorative paints to
be applied.
Dispensed Gasketing. Cybershield has the ability to robotically dispense
liquid conductive gaskets with exceptional placement and bead profile accuracy.
This process provides a highly conductive shielding solution for plated, metallized
or conductive painted plastic and/or metallic substrates. The gasketing material
can be applied as narrow as 0.4 mm, which allows for more critical packaging space
for PCB traces and board component placement for a smaller overall package design. |
Cybershield
has four robotic cells and eight manual booths on a conveyorized line. Before
painting, the plastic parts receive a quick anti-static blow-off. In the robotic
cells, the parts are then palletized with a specially designed mask placed on
top. Each cell has two pallets that shuttle in and out to feed parts to the robot
for painting. In the manual booths, parts are fed to the painter by a rack on
a conveyor. The rack is then taken off the conveyor by the painter and placed
under another specially designed mask. Once the parts are painted, the painter
hangs the rack back on the conveyor. Painted parts from either the robotic cells
or the manual booths then go through an infrared cure oven and numerous quality
checks to ensure that all parts meet the strict demands of Cybershield's customers.
Turbine-Powered
HVLP Spray Guns
One of the most important parts of either the robotic cells or the manual booths
is the spray gun. Years ago, Jon Pack, plant manager at Cybershield, had the option
of using compressed-air or turbine-powered HVLP spray guns. Even though the upfront
cost of the turbine-powered HVLP spray guns was significantly higher than the
initial cost of the compressed-air HVLP spray guns, Mr. Pack decided to install
the Turbo-Coatair turbine-powered HVLP spray guns from Can-Am
Engineered Products Inc. Why did he do it? Because the turbine-powered spray
guns would greatly increase Cybershield's transfer efficiency and improve the
effectiveness of its shields.
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| Yes,
this robot is actually painting. (Although it is hard to tell even when you're
standing right next to it.) The turbine-powered HVLP spray gun on this robot uses
such a low pressure that there is virtually no overspray.
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With compressed
air spray guns, the paint is blasted by high velocity air from numerous small
holes in the face of conventional air caps. This creates a large amount of turbulence,
which is created by the instantaneous expansion of the high pressure air as it
passes through the holes in the air cap. The excessive turbulence and high velocity
of the air over-atomize a significant portion of the paint, creating a fine cloud
of atomized paint. Because the paint particles are so fine, they ride the air
currents in the spray booth, missing the part they are supposed to coat and creating
a great deal of overspray. Also, because the velocity of the air, and consequently
the paint, some of the larger particles that do strike the part bounce off the
part because they are moving so fast.
However, the turbine-powered HVLP spray guns installed by Cybershield use a soft,
slow airflow to atomize the coating into relatively uniform droplets and carry
the coating to the part. The turbine allows Cybershield to use an air pressure
of 3.5-6.0 psi, significantly lower than the air pressure one would see from a
compressed-air spray gun.
The soft airflow and relatively uniform droplets provide Cybershield with a number
of benefits. The most significant advantage is the increased transfer efficiency.
In fact, Cybershield uses such a low pressure that you can't see any paint in
the spray booth at all; all you see is paint coating the part. The increased transfer
efficiency results in lower paint costs, fewer air emissions when the application
requires solvent-borne paint and reduced filter replacement because of the reduced
overspray. According to Robert Brewer, engineering supervisor at Cybershield,
the increased transfer efficiency saves a considerable amount of money.
Another important advantage for Cybershield is that its air and energy costs are
reduced. With compressed air spray guns, the company needed 25 hp to power its
four robotic cells. Now, the company uses just one turbine to generate 7.5 hp
to power the same four robotic cells. A similar result has occurred with the manual
booths where only one turbine is used to power all the manual booths. Plus, the
turbines can be turned off when they are not in use. "We also save on energy
costs. And, the compressed air requirements are drastically reduced by having
the turbine system," stated Mr. Brewer.
One other advantage for Cybershield is the improved finish the turbine-powered
HVLP spray guns provide. Recessed areas and corners are easier to coat because
the softer airflow of the turbine-powered spray guns doesn't cause the paint to
bounce back, which is a common occurrence with compressed-air spray guns. Also,
because the paint is so uniformly atomized a more even coating can be applied,
which is crucial in the world of EMI and RFI shielding.
Unlike many plant managers, Mr. Pack had the foresight to look beyond the high
initial cost of the turbine-powered system to the return on investment Cybershield
would get from the reduced paint and application costs. And, if you're thinking
that the system is only a benefit to Cybershield because its paint costs are so
high, think again. Cybershield is also using the same turbine-powered system for
decorative coating of the parts it is currently shielding.
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For More on this
Topic, Check Out Our Online Supplement:
Turbine-powered HVLP
spray guns are well-suited for high-solids and very dense coatings. Check out
this study to see what one manufacturer thought.
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