Wrinkle Containment and Pressure Uniformity Control for Dry Film

Wrinkle Containment and Pressure Uniformity Control for Dry Film
4-7-09
Wrinkle Containment and Pressure
Uniformity Control for Dry Film
Resist Lamination
by Jeffrey G. Stark, Sensor Products Inc.
and Karl H. Dietz.
In lamination of a printed circuit board, we are trying to achieve good contact between the resist and the
substrate surface by making the resist flow to conform to the surface topography. Flow is achieved by
lowering the resist viscosity through heat, and by applying a pressure differential for a certain time to
cause the flow. The pressure may be transmitted to the lamination rolls pneumatically, hydraulically,
mechanically, or a combination of these means.
Insufficient pressure and/or non-uniform pressure can lead to lamination defects such as dry film resist
wrinkles or open defects in print & etch due to poor resist conformation caused by insufficient nip
pressure (see References 1-9). So it is desirable to have a way of measuring nip pressure magnitude and
uniformity. Pressurex® (see reference 10) surface pressure indicating film measures the actual force
profile at the interface of the roller set. The pressure indicating film is placed between the two rolls before
closing the nip. After closing the nip, and applying the pressure, you can then observe the image captured
by the pressure indicating film revealing both the pressure distribution and magnitude (“footprint” as it is
commonly called).
Pressurex® measures pressure from 2 to 43,200 PSI (0.14 - 3,000 kg/cm2). When placed between
contacting surfaces, it instantaneously and permanently changes color directly proportional to the actual
pressure applied. The precise pressure magnitude is easily determined by comparing color variation
results to a color correlation chart (conceptually similar to interpreting Litmus paper).
1
1
Figure 1: Pressurex® Film Reveals the Nip Roller Pressure Profile in the Lamination Press
When performing the process of dry film lamination upon a composite structure or photopolymer and
polyester film to a metal-clad dielectric the possibility of the photoresist wrinkling or bubbling often exists.
By carefully monitoring both pressure magnitude and distribution within your lamination rollers with
pressure indicating films, wrinkling induced defects can be reduced significantly. Over tightened or loose
or worn rolls chucks can cause roller misalignments and imperfect nips - both of which are the primary
contributors to intermittent wrinkling
The force on the resist is not measured directly. A pressure gauge measures pressure applied to the
pneumatic cylinders which close the lamination rolls.
The actual force on the resist depends on the design of the roll loading system, taking into account the
actual area of the cylinders and the mechanical leverage, if any, of the system. Since the force is applied
to the resist through an elastomeric roll covering, it is distributed as pressure (force per unit area) which is
dependent on the width of the board and the width of the roll nip’s footprint is influenced by the total force
applied, the roll diameter, and the thickness and durometer of the roll covering. The pressure across the
footprint varies from zero at the edges to some peak pressure at the center of the nip where the roll
covering is compressed the greatest. The average of this pressure profile (roughly described by a
parabola) is about 2/3 of the peak pressure. When referring to nip pressure, we are usually discussing
this average pressure instead of peak pressure, because it is simpler to determine. To keep things simple,
however, we will talk about nip forces in terms of force per unit length of board width (pounds per inch or
Kilograms per centimeter), ignoring the actual width of the footprint.
This test can also be conducted while a resist covered copper-clad laminate is inserted between the rolls.
This test gives insight into a potential problem with “bowing” of rolls, especially with thicker boards, and
the test can measure the effectiveness of so called “crowned rolls” (Ref. 2) in counteracting bowing and in
achieving a uniform pressure profile across the panel (see discussion below). Roll bending is illustrated in
Figure 2.
2
Figure 2: Illustration of Roll Bending (Exaggerated)
Whether roll bending is negligible or whether it is a significant factor that affects lamination quality
depends on a variety of parameters. Hot roll laminators that work at relatively low loads and feature large
diameter rolls are less prone to roll bending. Roll bending affects outerlayer lamination more than
innerlayer lamination because the thickness of the multilayer boards is great enough to allow roll bending.
Thin boards or panels permit the rolls to touch on either side of the panel, reducing the tendency to bend.
The model suggests that the thickness of the dielectric core, plus copper, plus resist thickness must be
greater than 22 mils (550 micron) before roll bending defects are noticed. When roll bending occurs, the
center of the panel is laminated at a lower pressure than the edges, and a higher abundance of open and
dish-down defects will be noted in a print & etch application along the center of the panel in machine
direction.
To measure improved resist conformation at higher pressures we used AOI to test for circuitry defects
which are associated with poor resist conformation, such as “opens”, nicks, dish-downs, and line thinning
on a print & etch test pattern, at air pressures of 4 Bars and 7 Bars with an ASL-24 automatic sheet
laminator (see Table 1). The two pressures correspond to forces of 36 lbs/in and 62 lbs/in, respectively.
At the higher pressure, defects were reduced 79% from the lower pressure level. While this is a significant
reduction, it is difficult to take advantage of the higher pressure because the lamination rolls bend under
the increased pressure.
This roll bending results in an uneven roll footprint on the resist: the footprint is narrow at the center of the
rolls and wider at the ends. This means that the pressure on the resist at the center is less than at the
ends. Laminator suppliers are aware of this phenomenon and try to build the rolls as sturdy as is practical.
Residual roll bending can be compensated for with rolls which are “crowned” (Ref. 2). A crowned roll has
a rubber covering which is thicker in the center than at the edges and changes gradually from center to
edge, resulting in a curved profile. In this case we found that the correct amount of crown for the ASL-24
was in the range of 3-4 mils (75-100 microns). Figures 3 and 4 illustrate footprints caused by a bending
straight roll and that of a crowned roll.
Fig. 3: Nip Pressure Profile with Straight Rolls
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Fig. 4: Nip Pressure Profile with Crowned Rolls
Table 1 shows how crowning reduces the circuitry defect count both in the low and high pressure modes,
the best case being high pressure and crowned rolls. Rubber suppliers such as Robinson Rubber and
Abba Rubber International, Inc. are able to supply such crowned rolls.
Cylinder Pressure
(Bars)
Average Nip
Loading
(lbs/in)
Defect Count*
(Standard Roll
Construction)
Defect Count*
(Crowned Rolls)
4
36
1.00
0.15
7
62
0.18
0.05
Table 1: Effect of Roll Pressure and Profile on Conformation Related Defects
*(Defect counts are normalized for comparison; 1= highest count)
Figure 5 maps the “open” defects for different pressures and roll profiles. The beneficial effect of higher
pressure is evident. Also, for straight rolls that are bending, one can see the high abundance of opens in
the center of the board in machine direction where the pressure is lowest due to roll bending.
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Fig. 5: Open Circuit Defects as a Function of Pressure and Roll Profile
With regard to maximizing the applied nip loading, the equipment design is the limiting factor. The
strength of the rolls and the roll-loading mechanism usually limit the load, although available air pressure
can be a constraint at some locations. The available force can be concentrated in a very narrow footprint
by reducing roll diameter and the thickness of the roll covering, but this aggravates the roll strength and
bending issue.
Lamination wrinkles related directly or indirectly to high pressure or uneven pressure
It should be noted that a properly aligned and maintained laminator is the first step towards wrinkle-free
lamination (see Figure 6).
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Fig. 6: Properly Aligned Laminator
Many of the sources potentially contributing to wrinkling problems may not actually result in wrinkles if the
laminator is adequately aligned and maintained.
Figure 7 shows lamination wrinkles pointing in one direction. Likely causes are rolls closing on right side
before left side, or the closing force is greater on the right hand side.
Resist Roll
Roll Core
Dancer Bar
Vacuum
Plate
Trimmer
Knife
Hot Roll
Board
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Fig. 7: Lamination Wrinkles (Possible Causes: Lamination Rolls Closing on Right Side Before Left
Side; Closing Force Greater on the Right Side)
A general rule is that wrinkles, on a reasonably maintained laminator, are a problem only when laminating
wide (>510mm; >20”) resist or when laminating very thin (< 0.2mm;<0.008”) laminate.
Roll bending.
Laminator rolls bend when subjected to lamination loading. The bending causes higher driving speeds at
the edges than in the center of the panel. While it usually does not affect the panels, except for very thin
laminate, it can drive the resist film in a way that the film edges tend to move toward the middle, resulting
in lamination wrinkles. If the loading is high enough to “iron out” the wrinkles during the time the film is
being held by the vacuum bar, the wrinkles may not appear until the very end of the cut sheet when the
film is dropped by the vacuum bar. At this point there is no restraint of the trailing edge and the last inch or
so is likely to gather and wrinkle. Frequently, “comet tails” on tooling holes are caused by a combination of
roll bending and poor control of the resist trailing edge.
Uneven air cylinder pressures (clamp pressures).
The clamp pressures (these are the air cylinders closing the rolls) must be set at the same pressure for
wrinkle-free lamination. This source may be one of the biggest causes of long wrinkles starting mostly at
the middle of the panel and moving back at a small angle to the lamination direction. The gauges are not
always reliable indicators for the actual pressure. A periodic independent pressure check is advisable.
Post-lamination (PL) wrinkles
La
(M min
Di ach ation
rec ine
tio )
n
These wrinkles appear after lamination and run in machine direction (see Fig. 8).
Fig. 8: Post-Lamination Wrinkles (Exaggerated)
The PL wrinkles can have a variety of causes one of which can be excessive lamination pressure. PL
wrinkles are caused by heat and stress in the polyester base. While the need for good conformation
requires as high a lamination pressure as possible, this pressure can add to the stress in the base. It would
be better to use two nips set at medium pressures and temperatures than one nip at high pressure and
high temperature if PL wrinkles are a problem. The second nip should be directly after the first one to
minimize heat loss between nips. Note that this arrangement would be more useful on multilayer panels
than on innerlayers.
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References
1. The Role of Dry-Film Lamination in the Making of Ultra-Fine Pitch PC Boards, Edward Hagan,
Technical Paper S12-4, Proceedings, Printed Circuits Expo ’98, Long Beach, CA, April 26-30, 1998
2. Using Crowned Rolls to Compensate for Roll Bending, E. F. Hagan, Technical Bulletin TB-9739 Rev.
1.0 (7/97), DuPont Photopolymer & Electronic Materials
3. "Effects of Lamination Parameters on Dry Film Photoresist Conformation", Edward F. Hagan,
Technical Paper F9, Proceedings, IPC Works '96, October 19-25, 1996, Naples, FL
4. Fine Lines in High Yields, (Part XXVIII): Advances in Hot Roll Lamination of Dry Film Photoresist
(Part A), Karl H. Dietz, CircuiTree Magazine, December 1997, pg. 60
5. Fine Lines in High Yields, (Part XXIX): Advances in Hot Roll Lamination of Dry Film Photoresist (Part
B), Karl H. Dietz, CircuiTree Magazine, January 1998, pg. 18
6. Dry Film Lamination Process Effects of Lamination Parameters on Wrinkling and Dimensional
Properties of Dry Film and Copper-Clad Laminate, E. Hagan & K. Dietz, Technical PaperFilm S05-2,
Proceedings, IPC Printed Circuit Expo ’99, March 14-18, 1999, Long Beach, CA
7. The Process of Dry Film Lamination (Part I), Karl. H. Dietz & Edward F. Hagan, PC Fab, September
1999, Vol. 22, No. 9, pg. 42
8. The Process of Dry Film Lamination (PartII), Karl. H. Dietz & Edward F. Hagan, PC Fab, October
1999, Vol. 22, No. 10, pg. 38
9. Fine Lines in High Yields, (Part CXXXV) : The Effects of Lamination Roll Mechanics on Conformation,
Karl H. Dietz, CircuiTree Magazine, December 2006, pg. 64
10. Pressurex Measurement System, Sensor Products Inc., 300 Madison Avenue, Madison, NJ 07940, USA
(http://www.sensorprod.com/pcb)
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