IPC-D-279 EN.pdf - 第134页
wave soldering) and delamination at the conformal coating/ metal interface may allow contaminants to become entrapped and blistering of the conformal coating. This may contribute to electrochemical corrosion or migration…
surface to prevent moisture from collecting. All conformal
coatings are permeable to moisture. The key issue is to
prevent the moisture from collecting at an interface
between adjacent conductors. Moisture will collect at an
interface if there is a loss of adhesion due to: a) thermal
stresses or b) the presence of contaminates which will trap
moisture. As contaminates trap moisture they vesicate the
coating providing a gap for corrosion to form. Moisture,
coupled with contamination to increase the conductivity,
creates an electrolytic cell between conductors which
results in corrosion. Conformal coating also prevents shorts
of adjacent conductors by loose metal fragments.
N-4.1 Selection of Coating Selection of conformal coat-
ing depends on the use environment, the design of the
electronic enclosure, and the manufacturing facilities avail-
able. In the worst environment, exposure to saltwater and
temperature cycling, the assembly may require potting or
encapsulation instead of conformal coating to be reliable.
The use environment needs to be understood in terms of
the temperature range, exposure to corrosives, chemicals
and solvents, and permissible outgassing. The design of the
enclosure also has an effect. An enclosure which is cooled
by fan drawing air from the outside is different than an
enclosure which is sealed or purged with dry nitrogen.
Some conformal coatings have been formulated to be cured
rapidly with ultra-violet light; in some cases a secondary
heat cure may be required.
N-4.2 Thermal Stress Design Considerations Thermal
cycling may cause a number of problems with conformal
coating. If the coating fills the gap beneath a component
which does not have sufficient stress relief in the leads, the
stresses, generated by the temperature excursions and a
mismatch in the coefficients of thermal expansion, may
fatigue the solder joints and result in solder joint failure.
Hard coatings like epoxy may apply excessive stresses to
glass bodied components and can crack them. Some coat-
ings like polyurethanes and silicones may be soft at room
temperature, but if they are cooled below the glass transi-
tion temperature, their elastic modulus may increase sev-
eral orders of magnitude. This may generate excessive
stresses like epoxies coatings. These stresses may be mini-
mized by selecting a coating with a T
g
lower than the low-
est exposure temperature and applying the coating in the
proper thickness. (Each coating has a recommended thick-
ness.)
Obtain the information on CTE, Modulus and T
g
from the
conformal coating supplier. Examine the design with this
information in mind.
Before application or re-application of any conformal coat-
ing, the surface of the PWA and the components must be
free of materials (water soluble, ionic contaminants, greasy,
oily or particulate), which might interfere with wetting, or
trap moisture; otherwise, mealing or vesication will occur
with subsequent corrosion and dendrite formation between
adjacent conductors.
N-4.3 Chemical Stress Design Considerations Some
coatings are not stable in hot, humid conditions and may
revert to a gel. Select reversion resistant polyurethanes.
Parylene coating will be attacked by oxygen and crack if
exposed for extended periods at temperatures above 125°C.
Silicones are attacked by some solvents; in addition, traces
of silicone may interfere with subsequent bonding and
painting operations. Acrylic conformal coatings are
removed by most cleaning solvents including alcohol. Do
not select acrylic coating where solvent resistance is
required.
N-4.4 Space Environment Design Considerations
Some conformal coatings outgas significantly, making
them unsuitable for spacecraft. Fluorescent chemicals
added to the conformal coating outgas and may cause prob-
lems where optical clarity is paramount in systems with
lenses, mirrors and viewing ports.
N-4.5 Manufacturing Considerations There are several
key steps in applying conformal coating, the most impor-
tant being the cleanliness. An ionograph, although useful
for process control, is not sufficiently sensitive to detect a
level of ionic contamination which will cause vesication
(blistering). Non-ionic contaminates, such as silicone, will
interfere with adhesion of epoxy and polyurethane confor-
mal coatings. The cleaning process should include cleaning
with both polar and non-polar solvents. Other process con-
trols should include proper mixing, application and curing
of the coating.
The conformal coating may contain solvents which affect
the adhesion or integrity of component and printed board
markings, labels and legends.
Conformal coating of PWAs fabricated on fluorinated plas-
tics will require pre-treatment to improve adherence to the
substrate. The coating will increase the effective dielectric
constant between surface conductors (reduce high fre-
quency performance).
N-4.6 Other Design Considerations Conformal coating
on test pads results in diminished test accessibility; testabil-
ity buss methodologies and structures may be required to
permit effective and efficient fault coverage. (See IPC-SM-
782.)
Reduced heat extraction from the PWA (and increased
junction temperatures) may result if conformal coating cov-
ers heat sinks such as card edge clamps and cold plates.
Where solder coated conductor surfaces are overcoated
with rigid CC, the solder melts or reflows during subse-
quent processing (particularly hot air solder leveling or
IPC-D-279 July 1996
122
wave soldering) and delamination at the conformal coating/
metal interface may allow contaminants to become
entrapped and blistering of the conformal coating. This
may contribute to electrochemical corrosion or migration.
Conformal coating removal must be performed in a manner
which:
• provides a mechanically and electrically sound, dry,
clean surface to which conformal coating material will
be applied;
• minimally degrades the underlying solder mask or its
adherence to the printed board. (Some CC removal
solvents also attack some solder mask materials;
excessive temperature during removal of epoxy or
polyparaxylylene CC may degrade the underlying sol-
der mask, or where the solder mask or laminate have
absorbed substantial water from the air, may cause
delamination of the solder mask from the laminate or
delamination within the laminate);
• minimally degrades the surrounding conformal coating
or its adherence to the printed board. (CC removal sol-
vents do not remain on the surface but can permeate
the CC film and may affect the CC- solder mask inter-
face; CC removal solvent residue if not effectively
removed may lead to latent corrosion failures; thermal
removal of epoxy coatings with soldering iron, hot air
or laser, can char or otherwise degrade the surrounding
area. Mechanical abrading techniques can be used to
remove CCs and solder mask and to remove thermally
damaged coatings if ESD damage is not a concern);
• does not degrade or contaminate components which
are to remain in place. (CC removal solvents may con-
tain corrosive, polar or ionic materials and can attack
the polymers of which components are made; solvent
stress cracking may develop in the long term. See IPC-
R-700.)
Conformal coating rework or repair must be performed in
a manner which restores the functionality of the coating
with respect to adherence to the printed board and compo-
nents and with respect to freedom from delamination,
voids, and inclusions. (See IPC-R-700.)
N-5.0 COMMON CRITICAL PROPERTIES OF SOLDER
MASK AND CONFORMAL COATINGS
Conformal Coatings:
• Provide mechanical protection for the surface mount
(SM) PWA during assembly, test and service;
• Provide a smooth, chemically stable surface to reduce
SM PWA susceptibility to effects of condensing atmo-
sphere and electrochemical corrosion/migration during
test and service;
• Permeable to water vapor
CCs are dependent upon these factors for effective perfor-
mance under humid conditions:
• a clean underlying substrate surface free of water
soluble materials prior to application (to prevent
mealing, vesication, growth of metallic dendrites).
Non-polar solvents do not effectively remove these
soils;
• a clean underlying substrate surface free of solvent,
greasy, oily, particulate and other materials which
interfere with adhesion of the film (to prevent
delamination and growth of metallic dendrites). Polar
solvents or water without detergents do not effec-
tively remove these soils. Additional, ultrasonic
energy may be required to remove and suspend par-
ticulates as well as contaminants in cracks and crev-
ices (see IPC-CH-65);
• a dry substrate free of excess moisture and solvents
(whose vaporization during exposure to the heat of
assembly processes may result in delamination of the
coating from the substrate);
• complete encapsulation of conductors - film forma-
tion with no voids bridging conductors and no voids
along conductor edges;
• mutual compatibility of solder mask and conformal
coating where both are used;
• a proper cure for a strong, coherent film free of
cracks, voids and inclusions. (See IPC-S-816, IPC-
PE-740.)
Some cleaning solvents such as chlorinated hydrocarbons
and alcohols attack or swell some solder mask formulations
and some conformal coatings.
Leaking capacitor electrolytes such as sulfuric acid, dim-
ethyl formamide, and gamma butyrolactone, particularly at
high use temperatures may degrade some coatings; these
electrolytes are also used to remove conformal coatings.
Liquid flux entrapment in PTHs and PTVs may be mini-
mized by the selective deposition in and filling of the bar-
rels with liquid solder mask material or liquid conformal
coating material. Filling of the barrels with liquid solder
also accomplishes the same purpose.
Solder joint reliability under temperature cycling or power
cycling conditions may be reduced if the solder mask
touches the bottom of the component or conformal coating
filling the printed board - component gap. (See IPC-SM-
785.)
Degree of outgassing must be quantified and appropriate,
particularly for space applications, where outgassing is a
vital concern around optical surfaces such as lenses, mir-
rors and detector faceplates. Outgassing is also important
where unsealed relays, switches or separable connectors
are used; micromovement or electrical arcing can form
semi-insulating deposits of carbon or silica materials on the
contacts.
July 1996 IPC-D-279
123
N-6.0 JUNCTION COATINGS, ‘‘GLOB-TOPS’’
A specialized category of coatings includes the semicon-
ductor junction, chip or die coatings such as the screen
printed epoxies or polyimides, spun on polyimides, and
chemically vapor deposited poly-paraxylylene which are
deposited on the chip in wafer form and patterned; ‘‘glob-
top’’ epoxies and silicones which are deposited on the
interconnected chip; chemically vapor deposited poly-
paraxylylene which are deposited on the chip and wire-
bonds, unpatterned; and special purpose pyrolized sili-
cones. The application of junction coating material over
contamination creates a corrosion timebomb.
Junction coatings are intended to provide:
• Mechanical environment protection from scratches of
the chip surface and disturbance of interconnections.
• ‘‘Reliability without hermeticity’’ by excluding liquid
water and by limiting halide and alkali metal content
to very low levels under hot water extraction condi-
tions.
• Low stress upon cool down, where the coating is
cured.
• In some cases, protection for DRAMs from alpha par-
ticle upset.
• In the case of poly-paraxylylene, increased bond wire
strength.
• In some cases, ‘‘planarization’’ of the chip surface in
preparation for encapsulation by thermoset molding.
Junction coatings may also introduce additional reliability
concerns such as:
• Shear stress on the surface of the chip during cool
down.
• Compressive stress on conductors on the chip surface,
increasing possibility of hillocks and voids.
• Shear stress on ball bonds during temperature cycling
with the junction coating is about as thick as the bond
is high.
IPC-D-279 July 1996
124