Conformal-Coating-Process-Characterization-Considerations.pdf - 第6页
NordsonASYMTEK.com Conformal Coating Proc ess Characteriz ation Considerati ons Page 6 Through first ch aracterizing the equipment capabil ities, the manu facturer is able to best develop a high yield, maximum throughput…
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Conformal Coating Process Characterization Considerations Page 5
potential for cross contamination to other processes, and ventilation of the vapors.
Finally, the cure mechanism is determined by the material as well, be it acrylics,
urethanes, silicones, or epoxies. The time to cure is related to the material itself, and
automated equipment selection depends on the cure mechanisms of the specific
material. To minimize the time to cure and the associated work in process as well as
line length, designers need to look at the specific
coatings and not the equipment.
A high reliability coating process occurs most
efficiently when there is characterization of the
equipment prior to introducing the final product. The
equipment used to apply the conformal coating has
numerous input parameters to optimize the process;
some of these are the applicator selection, nozzle
orifice size, pressure causing the fluid to flow, the
transversing speed of the applicator, height of the
applicator from the substrate, and the overlap of
each pass, to name a few of the most critical. The
output of these variable settings provides the
coating thickness, repeatability, throughput, and
defects, such as bubbles and voids.
Curing the Coating
The equipment used to cure the coating material also has input variables depending on
the cure mechanism. For thermal cure materials these are typically the temperature of
the oven, belt speed, temperature ramps, and for some materials, the humidity inside
the oven. For UV cure materials they are the height of the UV lamp and the speed the
board passes through the oven. The output of these variable settings, in conjunction
with the material thickness, provides the throughput of the cured product as well as
defects, such as incomplete cure or over cure defects.
Input parameters to
optimize the process
include the applicator
selection, nozzle
orifice size, pressure
causing the fluid to
flow, the transversing
speed of the
applicator, height of
the applicator from
the substrate, and
the overlap of each
pass.
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Conformal Coating Process Characterization Considerations Page 6
Through first characterizing the equipment capabilities, the manufacturer is able to best
develop a high yield, maximum throughput process for the end product. There are
variables associated with coating a specific board due to board topography, keep-out
areas, surface wetting, cleanliness, moisture retention, and component placement.
Decoupling the equipment characterization from the final product enables higher
reliability coating processes in a shorter and less costly development timeframe.
Shorter because it is a simpler process without confounding variables, and less costly
because of engineering time-savings as well as reduced potential scrap product
generated in process development. Each coating material has slightly different
rheological characteristics. Understanding how those interact with the equipment input
variables subsequently provides the best manufacturing processes.
The majority of manufacturers who have successful coating operations manufacture
more than one product. With multiple products there is a need to develop a process
that works with many different selectivity requirements. By initially developing a
coating process that is end-product independent, it allows companies to introduce new
products more quickly because each product is not a unique project.
Final Considerations
Finally, the conformal coating process is a very dynamic process because there are
many tolerances that are inherent to it. Some of these are associated with the
acceptable limits of material viscosity variations, substrate surface energy affecting
wetability, surface cleanliness, fixture tolerances, and the coating equipment’s own
tolerances on volumetric dispensing. All of these processes can be characterized for
high yield; however, it is advantageous to have a basic characterization process that
can be referenced to have a standard to work from. The equipment can be selected to
have closed-loop heaters to control the viscosity, software controlled pressure
regulators to dynamically adjust the spray patterns based on closed-loop monitoring,
fiducial recognition for increased placement accuracy, bar code scanners for
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Conformal Coating Process Characterization Considerations Page 7
automated program selection, and many additional options as defined by the process
requirements.
Characterizing the equipment prior to introduction of the final product also helps to
ensure that the initial process is defined in the center of the process window, allowing
for the widest range of variation, which is much easier to do when it is defined outside
of a specific product. It also decouples trouble-shooting issues from the incoming
product (upstream issues) or issues with the coating process itself. This
understanding minimizes the need for process support and increases the number of
good parts being produced per shift. Automated selective coating equipment is very
reliable and designed to run in 24/7 environments; the challenges are with the process
itself. By considering the need for and type of coating at the design phase, and
properly characterizing the equipment, helps ensure that the product can be
manufactured utilizing automated equipment and at the lowest cost.
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