Post on 04-Mar-2020
Scope of this Manual
A revolutionary new polyester material and process technique
has been developed that produces a production and
process-ready composite tool in typically 80% less time than
conventional polyester tools. These tools, used in the production
of open mold fiberglass hand lay-up/spray-up and resin transfer
molding (RTM) parts, have for years required weeks of
painstaking, labor intensive, hand lay-up of one or two layers at
a time of resin-impregnated fiberglass mat reinforcement.
This new material represents a breakthrough in reducing the
lead time from concept design to part production.
This manual documents the proper techniques and procedures in
constructing composite molds made from Polylite® Profile Tooling
Polyester Resin and demonstrates the cost effectiveness of the
resin compared to traditional polyester resins.
» Introduction
Intended Audience
Both pattern and tool makers will find this manual useful in the construction of composite tools and prototype parts.
Part Detailers, Industrial Designers and Engineers will also find the manual informative in designing parts that are truly
production ready.
Reichhold
Reichhold is the world’s largest supplier of unsaturated polyester & vinyl ester resins used by the automotive, boat-building,
wind energy, industrial, corrosion, flame retardant, leisure and tool making industries. For further information about
Reichhold’s product offerings contact your nearest Reichhold representative.
Copyright 2008, Reichhold Inc. All rights reserved.
» Table of Contents
A1 Polylite® Profile System Advantages
A2 System Comparison
B1 Resin Compound Formulation
B2 System Recommendations
B3 Approved Application Equipment
B4 Approved Fillers | Approved Glass Reinforcement
C1 Resin Compound Mix Proportions
C2 Promoter to Resin Mix
C3 Promoter Levels Versus Gel Time and Temperature
C4 Initiator Levels Versus Gel Time and Temperature
C5 Slave Arm Recalibration
D1 Tool Construction Technology
D2–D9 Tool Construction Technology—Steps
E1–E11 Trouble shooting
F1–F2 Typical Polylite® Profile Resin Properties
F3 Typical Polylite® Profile Resin Physical Properties
G1–G10 Technical Tips
H1–H2 Casting
I1 Packaging / Safety / Quality / Storage
I2 Polylite® Profile Distributors
I3 Corporate Headquarters
Polylite® Profile 33540 Series is a non-promoted, non-thixotropic,
unsaturated polyester laminating resin. Polylite Profile 33540
Series is suitable for construction of FRP tooling. The resin is
formulated for room-temperature curing with Superox® 46750
peroxide initiator and is to be used with specific alumina
trihydrate fillers. Polylite Profile 33540 Series must be promoted
with Reichhold 46559 cobalt-based promoter solution prior to
initiation.
» Polylite® Profile System Advantages
A1-a
33540 Series
FEATURES BENEFITS
Tools can be built in 80% less time Significantly reduces labor costs
Production start-up time reduced
Makes prototype tools rapidly and economically
Low Shrinkage Tool reproduces master exactly
Resulting tool is stress free
Print through and surface distortion eliminated
Pre-release potential minimized
Tool post-finishing reduced
Rapid Barcol hardness development Tool demolds faster
Visual color change during cure Built-in quality control indicator
Fillable to 50% with ATH Lower composite cost
Increased composite stiffness
Improved heat transfer
SPC/SQC Controlled Consistent performance batch to batch
Polyilte® Profile 33541 Series is a promoted, non-thixotropic,
unsaturated polyester laminating resin. Polyilte Profile 33541
Series is suitable for construction of FRP tooling. The resin is
formulated for room-temperature curing with Superox® 46750
peroxide initiator and is to be used with specific alumina
trihydrate fillers.
» Polylite® Profile System Advantages33541 Series
A1-b
FEATURES BENEFITS
Tools can be built in 80% less time Significantly reduces labor costs
Production start-up time reduced
Makes prototype tools rapidly and economically
Low Shrinkage Tool reproduces master exactly
Resulting tool is stress free
Print through and surface distortion eliminated
Pre-release potential minimized
Tool post-finishing reduced
Rapid Barcol hardness development Tool demolds faster
Visual color change during cure Built-in quality control indicator
Fillable to 50% with ATH Lower composite cost
Increased composite stiffness
Improved heat transfer
Pre-Promoted No additional promoters needed
SPC/SQC Controlled Consistent performance batch to batch
Polyilte® Profile 33542 Series is a promoted, thixotropic,
unsaturated polyester laminating resin. Polyilte Profile 33542
Series is suitable for construction of FRP tooling. The resin is
formulated for room-temperature curing with Superox®
46709 peroxide initiator or other approved peroxide initiators.
» Polylite® Profile System Advantages33542 Series
A1-c
FEATURES BENEFITS
Tools can be built in 80% less time Significantly reduces labor costs
Production start-up time reduced
Makes prototype tools rapidly and economically
Low Shrinkage Tool reproduces master exactly
Resulting tool is stress free
Print through and surface distortion eliminated
Pre-release potential minimized
Tool post-finishing reduced
Rapid Barcol hardness development Tool demolds faster
Visual color change during cure Built-in quality control indicator
Pre-filled with ATH Lower composite cost
Increased composite stiffness
Improved heat transfer
Pre-Promoted No additional promoters needed
SPC/SQC Controlled Consistent performance batch to batch
» System Comparison
33540 Series | 33541 Series | 33542 Series
A2
This chart represents two major areas of benefits using the Polylite® Profile Tooling System versus standard resin used in production tooling. A typical tool can be produced at a system cost
savings of approximately 50% compared to conventional laminating resins and tool making methods. The savings is passed on in both labor and materials. In addition to a system cost saving,
a production time savings of up to 80% is also realized by using the Polylite Profile system.
100%
90%
80%
70%
60%
50%
40%
30%
20%
10%
0%
SYSTEM COST TOTAL TIME
� StandardNon-Filled Resin
� All Polylite ProfileTooling Systems
System cost isreduced by 50%with the PolyliteProfile System
Production timeis reduced by 80%with PolyliteProfile System
» Resin Compound Formulation33540 Series
B1-a
COMPOUND
Polylite® Profile 33540 Series Resin 100 parts
Alumina Trihydrate Filler 100 parts
Reichhold 46559 Promoter 0.4–0.8 parts, based on resin weight
Superox® 46750 Peroxide Initiator 1.25 parts, based on resin weight
Fiberglass Roving 18–22% of laminate weight
TYPICAL EXAMPLE
When mixing a 55 gallon drum of resin (net weight 300 Ibs), the following formulation should be followed:
Polylite Profile 33540 Series 300 lbs (136.08 kg)
Alumina Trihydrate Filler 300 lbs (136.08 kg)
Reichhold 46559 Promoter 1.5 lbs (.680 kg)
» Resin Compound Formulation33541 Series
B1-b
COMPOUND
Polylite® Profile 33541 Series 100 parts
Alumina Trihydrate Filler 100 parts
Superox® 46750 Peroxide Initiator 1.25 parts, based on resin weight
Fiberglass Roving 18–22% of laminate weight
TYPICAL EXAMPLE
When mixing a 55 gallon drum of resin (net weight 300 Ibs), the following formulation should be followed:
Polylite Profile 33541 Series 300 lbs (136.08 kg)
Alumina Trihydrate Filler 300 lbs (136.08 kg)
» Resin Compound Formulation33542 Series
B1-c
Mix Requirements
Note: Superox® 46709 Peroxide Initiatior is not to be mixed intothe resin/filler mix but metered through the chopper gun.
COMPOUND
Polylite® Profile 33542 Series Prefilled & Promoted 100 parts
Superox 46709 Peroxide Initiator 1.25 parts, based on resin weight
Fiberglass Roving 18–22% of laminate weight
TYPICAL EXAMPLE
When mixing a 55 gallon drum of resin (net weight 300 Ibs), the following formulation should be followed:
Polylite Profile 33542 Series 300 lbs (136.08 kg)
Polylite Profile must be agitated or mixed well to ensure even filler distribution. A “bunghole” mixer is not an
acceptable mixer. A “gear driven agitator” or similar agitator/mixer for a 55 gallon drum is needed to properly mix
Polylite 33542-25 before use.
» System Recommendations33540 Series
B2-a
EQUIPMENT
Airless, initiator injected spray-up chopper system
Pressurized gun for gel coat application
Air compressor
Mixing tank with mixing blade
Aluminum or plastic serrated roller
Laminate thickness gauge
Gelcoat thickness gauge
Brush
Scales
Graduated cylinder
OSHA approved canister-type respirator for paint and vapors
Face shield or chemical goggles
Impervious gloves
Overalls or paper “clean” suit
MATERIALS
Polylite® Profile 33540 Series, non-promoted, low shrink polyester tooling resin
Alumina Trihydrate Filler
Initiator, i.e. Superox® 46750 Initiator
Mold release agent
Tooling gelcoat with appropriate initiator
Continuous fiberglass gun roving or chopped strand mat.
Core material, i.e. balsa wood
Structural support materials, i.e. steel, wood
Reichhold 46559 promoter solution
» System Recommendations33541 Series
B2-b
EQUIPMENT
Airless, initiator injected spray-up chopper system
Pressurized gun for gel coat application
Air compressor
Mixing tank with mixing blade
Aluminum or plastic serrated roller
Laminate thickness gauge
Gelcoat thickness gauge
Brush
Scales
Graduated cylinder
OSHA approved canister-type respirator for paint and vapors
Face shield or chemical goggles
Impervious gloves
Overalls or paper “clean” suit
MATERIALS
Polylite® Profile 33541 Series, promoted, low shrink polyester tooling resin
Alumina Trihydrate Filler
Superox® 46750 Initiator
Mold release agent
Tooling gelcoat with appropriate initiator
Continuous fiberglass gun roving or chopped strand mat.
Core material, i.e. balsa wood
Structural support materials, i.e. steel, wood
» System Recommendations33542 Series
B2-c
EQUIPMENT
Airless, initiator injected spray-up chopper system
Pressurized gun for gel coat application
Air compressor
Mixing tank with mixing blade
Aluminum or plastic serrated roller
Laminate thickness gauge
Gelcoat thickness gauge
Brush
Scales
Graduated cylinder
OSHA approved canister-type respirator for paint and vapors
Face shield or chemical goggles
Impervious gloves
Overalls or paper “clean” suit
MATERIALS
Polylite® Profile 33542 Series, promoted, filled, low shrink polyester tooling resin
Superox® 46709 Initiator
Mold release agent
Tooling gelcoat with appropriate initiator
Continuous fiberglass gun roving or chopped strand mat.
Core material, i.e. balsa wood
Structural support materials, i.e. steel, wood
» Approved Application Equipment
33540 Series | 33541 Series | 33542 Series
B3
MANUFACTURER PRODUCT SUGGESTED SPRAY TIPS SUGGESTED AIR PRESSURE SETTINGS
Venus—Magnum H.LS. PG 1116 Portable Chopper 6503 10 psi above non-filled settings
Division of PMC, Inc. P21 Pump (11:1) with Abrasives 6504
1862 Ives Avenue Application Package
Kent, WA 98032
(206) 854-2660
Binks Manufacturing Company 102-2400 Century Spray Gun N/A N/A
9201 West Belmont Avenue Model 105-1 326 Portable Chopper
Franklin Park, IL 60131-2887 B6-“D” (20:1) Pump
(708) 671-3000
Graco Composites Equipment INDy or Formula System LPA2-147-5240 (Airless Tip) Resin 60–70 psi
8400 Port Jackson Ave. NW Pump (11:1) LPA2-147-5250 (Airless Tip) Atomized Air 35–40 psi
North Canton, OH 44720 B-410/B-510 Chopper 23005-J5 (Non-Atomized Tip) AAC 60 psi
330-494-1313 INDy or Formula Dispense Gun 23005-J4 (Non-Atomized Tip)
with Air Assist Containment
(Internal or External Mix)
» Approved Fillers | Approved Glass Reinforcement
33540 Series | 33541 Series | 33542 Series
B4
Approved Fillers Approved Glass Reinforcement
PRODUCT MANUFACTURER
A-208 Alumina Trihydrate R. J. Marshall Company
(Not used with 33452 Series) 26776 W. Twelve Mile Road
Southfield, Ml 48034-7807
(800) 338-7900
PRODUCT MANUFACTURER
Hybon® 700 HTX PPG Industries, Inc.
MPM® 11⁄2 oz chopped strand mat One PPG Place
MPM® 3⁄4 oz chopped strand mat Pittsburgh, PA 15272
(412) 434-3250
ME-3021 Roving Owens Corning Fiberglass Corporation
Fiberglass Tower
Toledo, OH 43659
(419) 248-8000
» Resin Compound Mix Proportions
33540 Series | 33541 Series
C1
This chart provides a reference a point for determining material mix proportions of Polylite® Profile Tooling System and Alumina Trihydrate. For example, 300 lbs of Polylite Profile will require
300 lbs of Alumina Trihydrate filler.
1000
900
800
700
600
500
400
300
200
100
010 (4.54)
50 (22.68)
50 (22.68)
250 (113.40)
250 (113.40)
300 (136.08)
300 (136.08)
500 (226.80)
500 (226.80)
10 (4.54)
� Polylite Profile33540 and 33541 Series
� Alumina Trihydrate lbs (kg)
» Promoter to Resin Mix33540 Series
C2
Resin Weight lbs (kg) 10 (4.54) 45 (20.43) 250 (113.40) 300 (136.08) 450 (204.12)
Promoter Solution @ 0.4% gm (ml) 18.2 (19.5) 81.7 (87.9) 454.0 (488.2) 544.8 (585.8) 817.2 (878.7)
Promoter Solution @ 0.5% gm (ml) 22.7 (24.4) 102.2 (109.8) 567.5 (610.2) 681.0 (732.3) 1021.5 (1,098)
Promoter Solution @ 0.6% gm (ml) 27.2 (29.3) 122.6 (131.8) 681.0 (732.3) 817.2 (878.7) 1225.8 (1,318.)
Promoter Solution @ 0.7% gm (ml) 31.7 (34.2) 143.1 (153.7) 794.5 (854.3) 953.4 (1,025.2) 1430.1 (1,537.3)
Promoter Solution @ 0.8% gm (ml) 36.2 (39.1) 163.6 (175.6) 908.0 (976.3) 1,089.6 (1,171.7) 1634.4 (1,756.6)
This table will assist in calculating the correct quantity of
Reichhold Promoter 46559 to be added to Polylite® Profile
33540 Series resin.
Warning
Care must be taken to avoid direct mixing of any organic
peroxide with metal soaps, amine, or any other polymerization
accelerator or promoter. Violent decomposition will result ifthis is not followed.
» Promoter Levels Versus Gel Time and Temperature33540 Series
C3
This chart provides a reference point for determining the level of promoter to be used with a filled Polylite® Profile resin system. For example, with an initiator level of 1.25%, Reichhold 46559
promoter level of .45%, will provide a gel time of approximately 18 minutes at 77°F (25°C).
This chart show the variance temperature has on gel time at varied promoter levels.
80
70
60
50
40
30
20
10
00.00 0.20 0.25 0.35 0.40 0.45 0.50 0.75 1.25 1.50
PROMOTER LEVEL %
Initiator @ 1.25% 46750
GEL
TIME,MINUTES
90°F (31.2°C)
77°F (25.0°C)
65°F (18.3°C)�
�
�
�
�
�
�
�
�
�
�
�
�
�
�
�
�
+
+
+
+
+
+
» Initiator Levels Versus Gel Time and Temperature33540 Series
C4
This chart provides a reference point for determining the level of initiator to be used with a filled Polylite® Profile resin system. For example, an initiator level of 1.25% (based on resin weight),
at 65°F (18.3°C) will provide a gel time of approximately 39 minutes.
This chart shows the variance temperature has on gel time at varied initiator levels for one type of system.
80
70
60
50
40
30
20
10
00.50 0.75 1.00 1.25 1.75 2.5 3.5
I N I T I ATOR L E V E L %
GELTIM
E,MINUTES
90°F (31.2°C)
77°F (25.0°C)
65°F (18.3°C)
�
�
+
�
�
�
�
�
�
�
�
�
�
+
+
+
+
+
Promoted @ .45% 46559
» Slave Arm Recalibration
33540 Series | 33541 Series | 33542 Series
C5
Resin/Filler Ratio Slave-Arm Setting% Superox® 46750 (33540 and 33541)% Superox® 46709 (33542)
1:1 0.75 1.14
1:1 1.00 1.51
1:1 1.25 1.90
1:1 1.50 2.30
1:1 1.75 2.70
This table provides general guidelines for the pump/slave-arm recalibration.Most application equipment dispenses materials using positive
displacement pumps and mechanical slave-arms to ensure
accuracy. Because peroxide initiator slave-arm adjustments are
typically set for non-filled materials, recalibration is required to
ensure proper metering.
Note: Accurate equipment calibration should always be
performed prior to use. This should be accomplished by
independently dispensing, collecting and weighing the resin
compound and peroxide initiator.
Warning
Do not use Superox® 46750 with the Polylite® 33542 Series
» Tool Construction Technology
33540 Series | 33541 Series | 33542 Series
D1
Use serrated rollers and brushes to remove air and thoroughly work the resin into the reinforcement.
Several layers of chopped material or specialized reinforcement can be added to the laminate depending upon
the requirements of the application. Again, as in hand lay-up, structural core materials can be incorporated within
the laminate construction.
The spray-up process
As in the hand lay-up process, a release agent followed by a
sprayed-on gelcoat is first applied to the master. When the
gelcoat has cured according to the manufacturer’s instructions,
the spray up process can begin. Prior to applying the filled
tooling system, Reichhold recommends the application of a skin
coat using our premium Hydrex® resin. This skin coat should be
applied at a minimum 0f 1.5–2 ounces of CSM or its equivalent.
The next step in the spray-up process is to apply an initiated
compound mist coat (no glass) of the tooling resin followed by
spraying glass fiber reinforcement and resin compound through
a chopper gun. This gun simultaneously chops a continuous
fiberglass roving into suitable length (typically 11⁄2 inches) and
mixes initiator into the sprayed and filled resin compound.
Shorter glass fibers (1⁄2 inch ) can be used with smaller or
complicated tools to minimize glass bridging in sharp corners.
Additionally, long glass fibers (2 inches) can be used in flat tools
or in tools that require higher strength.
» Tool Construction Technology—Steps
33540 Series | 33541 Series
D2-a
Mixing Guide per 100 lbs of Resin
Polylite® Profile 33540 and 33541 series 100 lbs
Alumina Trihydrate Filler 100 lbs
Reichhold 46559 Promoter (use with 33540) 0.5 lbs
Superox® 46750 Initiator 1.25 lbs
(use with 33540 and 33541 series only)
Recommended Clean-up of Spray Equipment
Regardless of the equipment used, the pumping system should be periodically flushed. It is recommended that clean,
unfilled “neat” resin be used for this process. Solvents should not be used as the initial flushing agent. Flushing first
with neat resin will remove or purge the filled resin from the pump. Then, if required, solvent can be used to flush the
pump clean. To ensure good working conditions, follow manufacturers equipment recommendations for clean-up.
STEP 1—MASTER PLUG
A. Construct master plug and finish to exact dimensions and surface smoothness
B. Apply appropriate release agent to the surface (following manufacturer’s directions exactly).
» Tool Construction Technology—Steps33542 Series
D2-b
Tooling System Components
Polylite® Profile 33542 Series
Superox® 46709 Initiator
Recommended Clean-up of Spray Equipment
Regardless of the equipment used, the pumping system should be periodically flushed. It is recommended that clean,
unfilled “neat” resin be used for this process. Solvents should not be used as the initial flushing agent. Flushing first
with neat resin will remove or purge the filled resin from the pump. Then, if required, solvent can be used to flush the
pump clean. To ensure good working conditions, follow manufacturers equipment recommendations for clean-up.
STEP 1—MASTER PLUG
A. Construct master plug and finish to exact dimensions and surface smoothness
B. Apply appropriate release agent to the surface (following manufacturer’s directions exactly).
» Tool Construction Technology—Steps33540 Series
D3-a
Safety Requirements
Always wear a face shield or chemical goggles along with
impervious gloves to prevent skin contact with chemicals.
A canister-type respirator must be worn to prevent the inhalation
of vapors or spray mists.
STEP 2—RESIN COMPOUNDING
A. Measure Polylite® Profile 33540 Series accurately into a mixing container large enough to hold all materials
needed for the compound. High-shear mixing container is not required. Note: Resin temperature and work area
must be maintained at a minimum 65°F (18.3°C) to ensure complete cure.
B. The quantity prepared should be of sufficient size to be used in eight hour period. Filler settling may occur;
therefore, periodic or constant low-speed agitation is suggested. Should the mix be undisturbed for periods
greater than four hours, remixing is recommended.
C. Add required amount of Reichhold 46559 promoter solution to the unpromoted Polylite® Profile 33540 series resin
and begin low-speed agitation. See Figure 1. Note: do not let condensation drip into the resin. Refer to page C2for suggested promoter levels. See Figure 2 for typical mixing blade and air motor.
D. Mix at moderate speed for 2 minutes or until thoroughly mixed. Resin should have uniform color throughout mix
with no promoter hanging on side of mixing container.
E. Increase agitation to high speed and add alumina trihydrate filler at a steady rate. Blend filler until a 1:1 ratio of
filler to resin is achieved. Scrape sides of the container to prevent filler from hanging to container sides. Refer to
the chart on page C1 for mix proportions.
F. Continue agitation at high speed for 10 minutes then agitate at low speed for 10 minutes to allow entrapped
air to escape.
G. Fill spray gun catalyzer system with Superox® 46750 peroxide initiator. Make sure tank is clean to
prevent contamination.
Figure 1 Figure 2
» Tool Construction Technology—Steps33541 Series
D3-b
Safety Requirements
Always wear a face shield or chemical goggles along with
impervious gloves to prevent skin contact with chemicals.
A canister-type respirator must be worn to prevent the inhalation
of vapors or spray mists.
STEP 2—RESIN COMPOUNDING
A. The quantity prepared should be a sufficient size to be used in an eight hour period. Filler settling may occur;
therefore, periodic or constant low speed agitation is suggested. Should the mix be undisturbed for periods
greater than four hours, remixing is recommended.
B. Mix at moderate speed for 2 minutes or until thoroughly mixed. Resin should have uniform color throughout mix.
C. Increase agitation to high speed and add alumina trihydrate filler at a steady rate. Blend filler until a 1:1 ratio of
filler to resin is achieved. Scrape sides of the container to prevent filler from hanging to container sides. Refer to
the chart on page C1 for mix proportions. See Figures 3 and 4.
D Continue agitation at high speed for 10 minutes then agitate at low speed for 10 minutes to allow entrapped
air to escape.
E. Fill spray gun catalyzer system with Superox® 46750 peroxide initiator. Make sure tank is clean to
prevent contamination.
Figure 3 Figure 4
» Tool Construction Technology—Steps33542 Series
D3-c
Safety Requirements
Always wear a face shield or chemical goggles along with
impervious gloves to prevent skin contact with chemicals.
A canister-type respirator must be worn to prevent the inhalation
of vapors or spray mists.
STEP 2—RESIN COMPOUNDING
A. Remove the lid of the 33542 Series drum. Attach an appropriate mixer.
B. Turn mixer on and agitate for 20–30 minutes
C. Fill spray gun catalyzer system with Superox® 46709 peroxide initiator. Make sure tank is clean to
prevent contamination. See Figures 5 and 6.
Figure 5 Figure 6
» Tool Construction Technology—Steps
33540 Series | 33541 Series | 33542 Series
D4
STEP 3—PRE-APPLICATION QUALITY CONTROL
A. After charging and adjusting the dispensing equipment, test to ensure that the proper gel and cure
characteristics are achieved.
B. Make a test laminate of equivalent cross-sectional thickness simulating the tool (120 mils minimum). Maintain a
glass reinforcement content of 18-22% by weight. One and one half inch (38.1 mm) chopped glass is typically
used, but this may vary to suit the application and end use requirement. See Figures 7–9. Make sure test panel ismoved to a table for curing.
C. If required, adjust the levels of either Superox® 46750 (if using 33540 or 33541) or Reichhold 46559 promoter
(if using 33540 or 33541) or Superox® 46709 (if using 33542) to achieve the desired gel and cure time.
Refer to pages C2 and C4 for assistance.
D. Test laminate should reach a Barcol hardness of 25 within approximately 60 minutes after gelation.
STEP 4—GEL COAT
A. Spray on two or three wet passes of tooling gelcoat to develop a 30-40 mil (0.76-1 .02 mm) thickness and allow
to cure to a tacky feel. See Figures 10.
B. Follow all gelcoat manufacturer’s recommendations for handling and application.
Figure 7
Figure 9 Figure 10
Figure 8
» Tool Construction Technology—Steps
33540 Series | 33541 Series | 33542 Series
D5
Paste Mix Formulation
Resin Compound 40% (volume)
Fumed Silica/Milled Fibers 60% (volume)
Superox® 46750 Initiator 1.25% (weight)
(use with 33450 and 33541 only)
Superox® 46709 Initiator 1.25% (weight)
(use with 33452 only)
STEP 5—FILLER PASTE APPLICATION (OPTIONAL)
A. Apply a skin coat, using Hydrex® 33390 with a minimum of 1.5–2 0z of CSM.
B. If the master has sharp 90° fillets or interior corners, fumed silica and/or milled fibers can be mixed with the resin
compound to form a paste. This paste can be applied to the back side of the skin coat. The paste is catalyzed
with Superox 46750 Peroxide Initiator (if using 33540 and 33541), or Superox 46709 (if using 33542) thoroughly
mixed and applied to the radius areas. This will minimize problems with air entrapment in the radii caused by
glass bridging. Milled fibers add additional strength to the mixture.
The filled resin paste should be applied to a maximum cross-sectional thickness of 120 mils (3.05 mm). Do not
allow the paste to cure before proceeding with the lamination. See chart Initiator Levels Versus Gel Time andTemperature on page C3 for gel time information. See Figures 11–12.
STEP 6—LAMINATE APPLICATION
A. Spray a mist coat of resin compound to an approximate thickness of 10 mils (0.25 mm). This should completely
wet the surface. Only mist an area which can be worked prior to gelation. See Figure 13
B. A brush may be used to assist with resin coverage and removal of entrapped air.
C. Apply a fiber-reinforced resin layer to approximate thickness of 30–45 mils (0.76-1.14 mm) accomplished in one
or two passes. See Figure 14.
Figure 13
Figure 12
Figure 11
Figure 14
» Tool Construction Technology—Steps
33540 Series | 33541 Series | 33542 Series
D6
Warning
Polylite® Profile has been formulated to resist drainage and
slippage on vertical surfaces when applied to a laminate
thickness of 120-130 mils (3.05-3.30 mm). If laminate
applications gel and harden but fail to achieve the characteristic
light color, STOP the construction process and consult the troubleshooting guide or consult your Reichhold representative.
STEP 7—ROLL OUT
A. Remove all entrapped air with a brush or roller after each pass. Carefully inspect and remove air voids in laminate
before proceeding to the next laminate application. Laminate applications must have a minimum thickness of120 mils (3.05 mm) prior to gel and cure. See Figures 15–17.
B. Work out all entrapped air.
Figure 15 Figure 16
Figure 17
» Tool Construction Technology—Steps
33540 Series | 33541 Series | 33542 Series
D7
STEP 8—CURE
A. Allow the exotherm of each 120 mil (3.05 mm) laminate to subside before proceeding with subsequent
applications. See Figure 18. Failure to do so will decrease the working time of subsequent laminations. Becausein-service requirements of tools vary, it may be necessary to apply multiple laminates to achieve the desired
cross-sectional thickness of the completed tool.
B. Scuff sand with 60 grit sand paper, where required, to ensure void-free application of core reinforcement.
C. Repeat Step 6, as needed, to achieve the required composite thickness.
D. After each laminate application, trim excess glass from flange edge of the tool after partial cure is reached
STEP 9—BACKUP CORE REINFORCEMENT
A. Scuff sand with 60 grit sand paper, where required, to ensure void-free application of core reinforcement.
See Figure 19.
B. Tailor and cut core material to fit.
C. Pre-wet core material with resin compound on down side.
D. Apply 120 mils (3.05 mm) of bed laminate. Applied in multiple wet passes.
Figure 18
Figure 19
» Tool Construction Technology—Steps
33540 Series | 33541 Series | 33542 Series
D8
STEP 9—BACKUP CORE REINFORCEMENT (CONT)
E. Apply core material to the tool. If using balsa with a scrim back, score with razor knife to aid in conformance
to the bed laminate. Remove entrapped air under core mat. See Figure 20.
F. Allow the core and bed laminate to cure before proceeding. Check for voids under the core and repair as required.
G. Spray resin compound over core material. See figures 21-22.
H. Spray chop over the core material until a total thickness of 120–150 mils (3.05–3.81 mm) is reached.
Achieve this thickness in multiple wet passes.
I. Roll out all entrapped air.
J. Trim excess glass from the flange edge of tool after partial cure is reached.Figure 20
Figure 21 Figure 22
» Tool Construction Technology—Steps
33540 Series | 33541 Series | 33542 Series
D9
Note:Workplace temperature, materials temperature, promoterconcentration and initiator concentration will influence the cure
rate of Polylite® Profile. A minimum Barcol 934-1 value of 45
should be achieved prior to removing the tool from the master.
STEP 10—ADD BACK-UP REINFORCEMENT STRUCTURE
A. Cut and tailor a backup structure as required to maintain proper support.
B. Scuff sand attachment points on the tool as required to ensure a proper fit.
C. Position structure on the tool and attach by spraying chop around each attachment point. See figure 23.
D. Roll out any entrapped air.
STEP 11—REMOVE MASTER
A. Allow to cure for a minimum of 24 hours before removing the tool from the master.
B. Remove the tool from the master. See Figure 24.
STEP 12—APPLY RELEASE AGENT
A. Prepare tool with appropriate release agent. Follow all manufacturer’s instructions.
Figure 23
Figure 24
» Trouble Shooting33540 Series
E1-a
CAUSES CORRECTIVE ACTION
1. Resin-rich surface Remove excess resin from laminate surface before applying next layer. Abrade surface using60 grit sand paper.
2. Contamination of the laminate surface Remove dust or other contamination from laminate surface before applying next laminate.
3. Laminate under cured Maintain correct promoter and initiator levels.
4. Excessive laminate cure Do not interrupt lamination for extended periods of time or expose non-completed parts toexcessive heat or sunlight.
CAUSES CORRECTIVE ACTION
1. Low resin and/or workplace temperature Maintain work area, master and resin compound temperature of 85°F minimum.
2. Low peroxide initiator levels Maintain a minimum level of 0.8% by volume or 0.6% by weight of Superox® 46750 Peroxide Initiatorbased on resin. Recalibrate dispensing equipment.
3. Thin laminate Maintain promoter level of 0.4–1.0% by weight. Use 46559 promoter
4. Wet filler Replace with dry filler.
Defect: Slow Cure
Description: Laminate takes excessive amount of time to develop hardness
Defect: DelaminationDescription: separation of the composite occurring between laminate layers.
» Trouble Shooting
33541 Series | 33542 Series
E1-b
CAUSES CORRECTIVE ACTION
1. Resin-rich surface Remove excess resin from laminate surface before applying next layer. Abrade surface using60 grit sand paper.
2. Contamination of the laminate surface Remove dust or other contamination from laminate surface before applying next laminate.
3. Laminate under cured Maintain correct initiator levels.
4. Excessive laminate cure Do not interrupt lamination for extended periods of time or expose non-completed parts toexcessive heat or sunlight
CAUSES CORRECTIVE ACTION
1. Low resin and/or workplace temperature Maintain work area, master and resin compound temperature of 85°F minimum.
2. Low peroxide initiator levels Maintain a minimum level of 0.8% by volume or 0.6% by weight of Superox® 46709 or 46750Peroxide Initiator based on resin. Recalibrate dispensing equipment.
3. Thin laminate Maintain thickness of 120 mils (3.05 mm) for each laminate application.
4. Wet Filler Replace with dry filler (33541)
Defect: Slow Cure
Description: Laminate takes excessive amount of time to develop hardness
Defect: DelaminationDescription: separation of the composite occurring between laminate layers.
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E2
FCAUSES CORRECTIVE ACTION
1. Gel coat not fully cured when skin coat is applied Switch to faster curing gel coat. Allow more time for gel coat to cure. Increase work-areatemperature and materials.
2. Long resin gel time allows styrene in skin coat resin to soften gel coat Increase peroxide initiator level in resin. Maintain 1.0–2.0% based on resin. Increase work areatemperature. Check for moisture in filler. Recalibrate dispensing equipment.
3. “Orange peel” imprint in tool Replace or refinish master mold.
4. Air voids in skin coat Apply mist coat and roll out air in skin coat.
5. Excessive “orange peel” during application of tooling gel coat Adjust gelcoat application and/or consult gelcoat manufacturer.
CAUSES CORRECTIVE ACTION
1. Filler content of mix is too high (Does not apply to 33542 Series) Reduce filler content down to 45% minimum through addition of more Polylite® Profile 33540 or33541 Series. Agitate mix to prevent settling of filler.
2. High glass to resin ratio Increase resin line pressure, reduce chopper speed and increase diameter of resin tip.
3. Resin from gun does not wet-out chop Adjust spray angle to ensure complete glass to resin overlap. Re-wet laminate with filled resin mix aftereach application of laminate.
4. Incompatible glass binder or sizing Switch to glass with a binder and/or sizing with better solubility. Use only recommended reinforcements.
Defect: Poor wet-out / workabilityDescription: Saturation of glass fibers is difficult
Defect: “Orange Peel” surface finishDescription: Irregular surface to the gel coat which has the surface texture of an orange
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E3
CAUSES CORRECTIVE ACTION
1. Contamination in resin Inspect resin and air line for contamination (such as oil).
2. Air voids in skin coat Reduce first fiber—reinforced resin layer—to an approximate thickness of 20–30 mils.Remove entrapped air before proceeding to the next laminate application. Laminate applicationsmust have a minimum thickness of 120 mils (305 mm) prior to gel and cure.
• Use 1⁄4 inch long chop in first 20–30 mils of skin coat.
• Reduce filler content to 45% by weight.
• Run 6 blades in chopper—alternate ¼ and ½ inch glass in first 20-30 mils of skin coat. Chop onestrand of roving. Adjust chopper motor speed to maintain proper resin to glass ratio. Adjust resin toglass fan to ensure uniform wet out and composition. Maintain resin compound temperature at29°–32° (85° ± 5°F). Use brush to assist with wet out.
• Roll laminate using brissel type or bubble buster roller. Inadequate mixing of additives duringapplication. Review mixing procedure described in tooling manual.
3. Peroxide initiator droplets Make sure the peroxide initiator flow stops when the trigger on the gun is released. .(blister often contains liquid with a vinegar odor) Keep gun tip clear
4. Inadequate mixing of peroxide initiator Adjust or modify mixing capabilities of equipment. Visually inspect laminate to ensure uniform mixingafter initial catalyzation.
Defect: BlistersDescription: Blisters forming on the surface of the part. The blister may or may not contain a liquid.
» Trouble Shooting33540 Series
E4-a
CAUSES CORRECTIVE ACTION
1.Poor mixing of the peroxide initiator Adjust equipment to ensure peroxide initiator in uniformly mixing with resin. Check viscosity of filledresin mix. Ensure dispensing equipment is suitable for filled resin system.
2. Contamination of resin, filler or glass reinforcement Use different filler, glass or resin. Inspect lines and filters for contamination or restrictions. Inspect glassfor contamination and/or moisture content.
3. Improper peroxide initiator used Use only Superox® 46750. Use of other peroxide initiators can inhibit gel and/or cure.
4. Improper levels of promoter or peroxide initiator. Maintain 0.4–1.0% 46559 promoter and 1.0–2.0% 46750 catalyst. Concentrations are based on resincontent and are by weight.
5. Uneven laminate thickness The laminate will always cure faster in thick and resin-rich areas. To avoid variations in thickness,the gun operator needs to make long sweeping motions when chopping. Frequently monitor laminatethickness in various locations on the part. Maintain a minimum thickness of 120 mils (3.05 mm).
Defect: Spotty CureDescription: Some areas of the laminate will gel and cure faster than other areas. In extreme cases, areas of the laminate may never cure.
CAUSES CORRECTIVE ACTION
1. Excessive laminate thickness Do not apply more than 150 mils (3.81 mm) of laminate in one application.
2. Glass content is too low Maintain glass content of 18–22%.
3. Excessive laminate gel time Maintain proper temperature and levels of peroxide initiator and promoter.
4. Mist coat too thick Maintain mist coat thickness to 10 mils (.25 mm) or less, especially on vertical surfaces.
Defect: Sagging (Sliding)Description: Non-gelled laminate slides down the vertical surface of the master. This causes a ripple to form in the laminate.
» Trouble Shooting
33541 Series | 33542 Series
E4-b
CAUSES CORRECTIVE ACTION
1.Poor mixing of the peroxide initiator Adjust equipment to ensure peroxide initiator in uniformly mixing with resin. Check viscosity of filledresin mix. Ensure dispensing equipment is suitable for filled resin system.
2. Contamination of resin, filler or glass reinforcement Use different filler, glass or resin. Inspect lines and filters for contamination or restrictions. Inspect glassfor contamination and/or moisture content.
3. Improper peroxide initiator used Use only Superox® 46750 (with 33541 only) or 46709 (with 33542 only). Use of other peroxide initiatorscan inhibit gel and/or cure.
4. Low temperature in work area or of materials Maintain a minimum temperature of 85°F
5. Uneven laminate thickness The laminate will always cure faster in thick and resin-rich areas. To avoid variations in thickness,the gun operator needs to make long sweeping motions when chopping. Frequently monitor laminatethickness in various locations on the part. Maintain a minimum thickness of 120 mils (3.05 mm).
Defect: Spotty CureDescription: Some areas of the laminate will gel and cure faster than other areas. In extreme cases, areas of the laminate may never cure.
CAUSES CORRECTIVE ACTION
1. Excessive laminate thickness Do not apply more than 150 mils (3.81 mm) of laminate in one application.
2. Glass content is too low Maintain glass content of 18–22%.
3. Excessive laminate gel time Maintain proper temperature and levels of peroxide initiator.
4. Mist coat too thick Maintain mist coat thickness to 10 mils (.25 mm) or less, especially on vertical surfaces.
Defect: Sagging (Sliding)Description: Non-gelled laminate slides down the vertical surface of the master. This causes a ripple to form in the laminate.
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E5
CAUSES CORRECTIVE ACTION
1. Improper application of gel coat and/or mold preparation Follow manufacturer’s recommendations. Maintain a uniform gel coat thickness of 18–30 mils(0.46–0.76 mm) dry.
CAUSES CORRECTIVE ACTION
1.Improper roll-out or excessively thick Roll out between each 20–40 mils (0.51–1.2 mm) application of chop. Roll out using moderatespeed and pressure.
2. Drainage from low viscosity leaves air voids Review causes under “Drainage”. See page E6-a
3. High viscosity (Does not apply to 33542 series) Retest filled viscosity. Recalculate resin and filler addition. Maintain 1 to 1 ratio by weight. Reduce fillercontent to 45% minimum. Increase filled resin mix temperature to 70°–80°F (21.1°–26.7°C). Do notadd additional monomers. Only Polylite® 33540 or 33541 Series may be added to restore proper filler-to-resin ratio.
4. Resin-starved areas Maintain proper resin mix-to-glass ratio. Pre-wet part with filled resin prior to application of laminate.
5. Short gel time does not allow glass wet-out to be completed Decrease peroxide initiator to minimum of 0.6% by weight or 0.8% by volume. Do not reduce promotercontent below 0.4% by weight.
Defect: Air entrapment/laminate voidsDescription: Air pockets in cured laminate
Defect: Pre-release linesDescription: Pre-release lines are wavy areas typically formed where the surface of parts has released slightly from the mold
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E6
CAUSES CORRECTIVE ACTION
1. Inadequate mixing of peroxide initiator For external mix, use a tip that gives the proper degree of fan to allow for complete mixing.For internal mix, use different static mixer or use extension with air assist
2. Low peroxide initiator and/or promoter concentration. This results Use only recommended type and concentration of promoters and peroxide initiators.in under-cured or non-cured substrate laminates Ensure dispensing equipment is suitable and in proper operating condition.
CAUSES CORRECTIVE ACTION
1.High resin compound mix-to-glass ratio Lower resin line pressure or increase chopper speed on gun. Maintain 41% resin/41% filler/ 18% glass.
2. Low viscosity or thixotropic index Maintain resin to filler ratio of 1 to 1. Use only specific fillers recommended.
3. High resin temperature By cooling resin to 70°–80°F (21.1°–26.7°C), viscosity will be increased.
4. Long laminate gel time Use only recommended type and levels of peroxide initiator and promoters (if using 33540). Recalibratedispensing equipment. Review causes under “Slow Cure” and “Spotting Cure” pages E1-a & b.
5. Filler drop-out in resin Recalculate filler content and if required adjust to 50% by weight. Mix drum to re-disperse filler.Use only recommended fillers.
Defect: DrainageDescription: The resin drains out of the laminate on vertical surfaces forming puddles on the bottom and dry glass on the top. (Excessively large puddles of resin may cause
heat lines and/or pre-release.)
Defect: Resin weepingDescription: Droplets of liquid resin penetrating through gelled laminate
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E7
CAUSES CORRECTIVE ACTION
1. Improper or inadequate preparation of master Use proper release agents. Reapply release agent to master. Apply a parting film (PVA).Employ mold maintenance program.
Use extra layers of wax or parting film (PVA). Follow mold release agentmanufacturer’s recommendations.
2. Design of the master Eliminate reverse drafts or insufficient drafts in master.
3. Over spray or other foreign material on master before gel coat is applied Keep master protected when not in use. Clean and inspect prior to use.
4. Artificial vacuum between master and mold Break with compressed air. Design master with poppets in required areas.
CAUSES CORRECTIVE ACTION
1. Low exotherm Maintain minimum thickness of 120 mils (3.05 mm) for each cure cycle. Maintain minimum materialtemperature of 85°F. Maintain recommended peroxide initiator and promoter concentration. lnspectequipment for restrictions.
2. Low peroxide level Maintain 1-2% Superox® 46750 or 46709 peroxide based on resin used.
3. Poor peroxide mixing Check gun for proper mixing of peroxide initiator.
Defect: No laminate color changeDescription: Laminate fails to turn white upon curing
Defect: Tool sticking on masterDescription: Tools are difficult to remove from master after cure.
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E8
CAUSES CORRECTIVE ACTION
1. Slow cure Review causes under “Slow Cure” and “Spotty Cure.” See pages E1-a, E4-a & b
2. Part demolded before properly cured Do not demold until part has achieved a minimum Barcol hardness of 45.
3. Insufficient gel coat cure or thickness Ensure proper application. See causes under “Fiber print through” above.
CAUSES CORRECTIVE ACTION
1. Laminate exotherm is too low Maintain minimum thickness of 120 mils (3.05 mm). for each cure cycle. Maintain and materials at85°F or higher. Based on resin content, increase Superox 46-750 (33540 or 33541) or Superox 46-709(33542) peroxide initiator to 1–2%.
2. Gel coat not fully cured when laminate is applied Ensure gel coat application conforms to manufacturer’s recommendation. Switch to faster curing gelcoat. Allow more time for gel coat to cure. Increase plant and/or master temperature.
3. Long gel time allows styrene to soften gel coat Increase peroxide initiator concentration. Increase plant/materials temperature.
4. Gel coat is too thin Follow manufacturer’s recommendations.
5. Fiber print pattern in master Replace or refinish master.
6. Excessive shrinkage. Polylite® Profile resin contaminated Discard resin.with other polyester resins
Defect: Fiber print throughDescription: Individual glass fibers can be seen through gel coat
Defect: Post cureDescription: The appearance of fiber or roving print through after the part has been demolded
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E9
CAUSES CORRECTIVE ACTION
1. Cracks Inspect resin and air line for contamination (such as oil).
2. Cracks of various lengths occur in close proximity to radius areas. Reduce first fiber—reinforced resin layer—to an approximate thickness of 20–30 mils.Commonly occurs after second or third forming cycle. Remove entrapped air before proceeding to the next laminate application. Laminate applications
must have a minimum thickness of 120 mils (305 mm) prior to gel and cure.
• Use 1⁄4 inch long chop in first 20–30 mils of skin coat.
• Reduce filler content to 45% by weight.
• Run 6 blades in chopper—alternate ¼ and ½ inch glass in first 20-30 mils of skin coat. Chop onestrand of roving. Adjust chopper motor speed to maintain proper resin to glass ratio. Adjust resin toglass fan to ensure uniform wet out and composition. Maintain resin compound temperature at29°–32° (85° ± 5°F). Use brush to assist with wet out.
• Roll laminate using brissel type or bubble buster roller. Inadequate mixing of additives duringapplication. Review mixing procedure described in tooling manual.
3. Droplets (blister often vinegar odor) Make sure the peroxide initiator flow stops when the trigger on the gun is released. Keep gun tip clear.
4. Peroxide Initiator. Adjust or modify mixing capabilities of equipment. Visually inspect laminate to ensure uniform mixingafter initial catalyzation.
Defect: BlistersDescription: Blisters forming on the surface of the part. The blister may or may not contain a liquid.
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E10
CAUSES CORRECTIVE ACTION
1. Improper roll-out or excessively thick Roll out between each 20-40 mils (0.51 - 1.2 mm) application of chop.Roll out using moderate speed and pressure.
2. Drainage from low viscosity leaves air voids Review causes under “Drainage”. Consult page E6.
3. High viscosity Retest filled viscosity. Recalculate resin and filler addition. Maintain 1 to 1 ratio by weight.Reduce filler content to 45% minimum. Increase filled resin mix temperature to70°–80°F (21.1°–26.7°C). Do not add additional monomers. Only Polylite® 33540 Seriesmay be added to restore proper filler-to-resin ratio.
4. Resin-starved areas Maintain proper resin mix-to-glass ratio. Pre-wet part with filled resin prior to application of laminate.
5. Short gel time does not allow glass wet-out to be completed Decrease peroxide initiator to minimum of 0.6% by weight or 0.8% by volume.Do not reduce promoter content below 0.4% by weight.
Defect: Air entrapment/laminate voidsDescription: Air pockets in cured laminate
» Trouble Shooting
33540 Series | 33541 Series | 33542 Series
E11
CAUSES CORRECTIVE ACTION
1. Pre use microcracking. Excessive force Redesign master plug to ensure sufficient.
2. Used during demolding tool from master Draft angles. Refinish and or apply release agents to master. Rigidize tool to prevent flexing.Reduce air pressure used to assist demold.
Defect: CracksDescription: Cracks of various lengths occur in close proximity to radius areas. Commonly occurs after second or third forming cycle.
CAUSES CORRECTIVE ACTION
1. Excessive gelcoat thickness Reduce cured gelcoat thickness to .007–.012 (0.18–0.305 mm).
2. Inconsistent gelcoat thickness Use thickness gauge during application
3. Thermal shock. Tool exposed to wide temperature differentials Warm tool prior to production. Avoid exposing (storing/staging) hot tools to extreme cold.
4. Gelcoat too rigid Use tougher, higher elongation gelcoat. Consult with gelcoat manufacturer to ensure proper selection.
5. Incomplete cure of gelcoat Follow manufactures applications instruction.
6. Thermoforming cycle time too long. Reduce cycle times; balance vacuum throughout tool. Heat acrylic sheet evenly.Faster cool down of formed acrylic sheet.
7. Uneven thermal expansion of gelcoat. Reduce cycle times. Heat acrylic sheet evenly to avoid hot spots.
Defect: CracksDescription: Various lengths which may occur either in localized areas or throughout the tool.
» Typical Polylite® Profile Resin Properties—Neat
33540 Series | 33541 Series
F1
PROPERTIES UNITS TEST METHOD VALUES
Flash Point, Seta Closed Cup °F (°C) 89 (31.7)
Shelf Life, Minimum Months N/A 3
% Styrene Monomer 18-001 47.5
Weight/Gallon lb (kg) 18-030 8.8 (3.99)
Viscosity, Brookfield Model LVT, cps 18-021 120
#1 Spindle @ 30 RPM
Gel Time, 1.25% Superox® Minutes 18-050 25
46750 Peroxide Initiator and
0.5 parts 46559 Polylite®
promoter by weight
Time to Peak Minutes 18-050 33
Peak Temperature °F (°C) 18-050 415 (212.8)
Color, Liquid 18-043 Clear Amber
Neat resin tested at 77° F ( 25° C )
» Typical Polylite® Profile Resin Properties
33540 Series | 33541 Series | 33542 Series
F2
PROPERTIES UNITS TEST METHOD VALUES
Gel Time Cup Values minutes
Time to Peak minutes
Peak Temperature °F (°C)
Viscosity, Brookfield Model LVF cps 18-021 850
#3 Spindle @ 60 RPM
Weight/Gallon lbs (kg) 18-030 12.3 (5.58)
Linear Mold Shrink in/in (cm/cm) 0.0002 (0.0002)
Specific Gravity ASTM D792 1.48
Tensile Str. Yield lb/in2 (kg/cm2) ASTM D638 7,500 (527)
Flexural Str. Yield lb/in2 (kg/cm2) ASTM D790 14,000 (984)
Elongation @ Break 1% ASTM D638 1.0
Tensile Modulus lb/in2 (kg/cm2) ASTM D638 15.3 x 105 (1.08 x 105)
Compressive Str lb/in2 (kg/cm2) ASTM D695 19,500 (1370)
lzod, Notched, R.T. ft lb/in (kg cm/cm) ASTM D256 29.9 (5.5)
Barcol Hardness 934-1 50
Linear Therm Expan in/in °F (cm/cm °C) ASTM D696 1.2 x 106 (2.16 x 106)
Resin reinforced with 20% chopped glass fibers and tested at 77° F ( 25° C )
See Promoter Levels Versus Gel Time and Temperature Chart on page C3
» Typical Polylite® Profile Resin Physical Properties
33540 Series | 33541 Series | 33542 Series
F3
The following table shows the physical test results using three
filler and glass combinations.
A B C
Tensile Strength, psi 8.58 x 103 1.10 x 104 1.47 x 104
Flexural Strength, psi 1.49 x 104 1.91 x 104 2.11 x 104
% Elongation 1.76 2.09 2.67
Tensile Modulus, psi 9.96 x 105 1.04 x 106 1.059 x 106
Flexural Modulus, psi 7.58 x 105 9.58 x 105 8.84 x 105
Izod IMpact Strength, Notched 11.5 ft – 1b/in 9.8 ft – 1b/in 10.1 ft – 1b/in
LAMINATE CONSTRUCTION
% Glass Content 20 26.7 26.5*
% ATH content 50 45 40
% Polylite® Profile Tooling System 30 28.3 33.5
*Resin was not able to wet out more glass.
PHYSICAL PROPERTY EVALUATION
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G1
SYMPTOM REMEDY
Air Voids in Skin Coat. Reduce first fiber—reinforced resin layer—to an approximate thickness of 20–30 mils. Removeentrapped air before proceeding to the next laminate application. Laminate applications must have aminimum thickness of 120 mils (3.05 MM) prior to gel and cure.
Use 1⁄4 inch long chop in first 20–30 mils of skin coat.
Reduce filler content to 45% by weight. (For 33540 and 33541 series only).
Run 6 blades in chopper–alternate 1⁄4 and 1⁄2 inch glass in first 20–30 mils of skin coat.
Chop one strand of roving. Adjust chopper motor speed to maintain proper resin to glass ratio. Adjustresin to glass fan to ensure uniform wet out and composition
Maintain resin compound temperature at 29°–32° (85°± 5°F). Use brush to assist with wet out.
Roll laminate using brissel type or bubble buster roller.
Inadequate mixing of additives during application. Review mixing procedure described in tooling manual.
Air Voids in Pinch Area of Tool, 90° Corners or Small Deep Draw Areas Thoroughly wet out a sufficient quantity of glass roving with catalyzed resin compound. Place in radiiarea. Remove entrapped air. Do not allow to gel and cure before applying primary laminate.
Use filler paste. Consult page D5.
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G2
SYMPTOM REMEDY
Improved Sprayability Maintain resin compound temperature at 29° (85°± 5°F)
Reduce filler content to 45% by weight. (For 33540 and 33541 Series only )
Convert pump pick-up tube from 3⁄4 inch to 1 inch diameter.
Remove fine mesh filters from pump pick-up tube and other in-line resin filters. Replace with 60–80mesh filters.
Adjust and clean application equipment. At end of each day flush equipment with non-filled Profile resin.Leave pump piston on the down stroke—helps to avoid possible buildup of filler on pump shaft.
Long Compound Gel Time Verify concentration and weights of resin, filler, promoter and peroxide initiator. Maintain FIFO inventory.
Increase Reichhold 46559 promoter to a maximum level of 1.0% by weight. (For 33540 Series only).
Warm resin compound to 29° (85°± 5°F).
Mix 46559 promoter into resin for a longer period of time: 5–10 minutes.
Confirm and use only approved fillers.
Use different lot of filler.
» Technical Tips
33540 Series | 33541 Series
G3-a
SYMPTOM REMEDY
Short Gel Time Resulting From Elevated Work Place Temperatures Reduce amount of Reichhold Promoter (33540) and or initiator (33540 and 33541).
Laminate Slippage Disperse filler using a Cowls mixing blade.
Adjust filler content to 45% by weight and add up to 0.25% by weight fumed silica.
Maintain a 10 mil or less mist coat of resin compound.
Confirm that only approved fillers are in use.
Inadequate Mixing of Initiator or Initiator Streaking Equipment not adjusted properly or in need of cleaning or repair. Take appropriate action.
Warm resin compound to 29°C–32°C (85°F–90°F).
Inspect turbulent mixer used in equipment. Replace with new or more efficient unit. In some equipmenta nylon unit performs better that teflon. Teflon soft enough that flutes can collapse, causing a loss of sealto the chamber and initiator streaming or improper mixing.
Cured Laminate Has Green Colored Surface Over catalyzation. Repair or adjust dispensing equipment.
Review tooling manual for suggested concentration.
Wrong peroxide initiator used. Use only Superox® 46750.
» Technical Tips33542 Series
G3-b
SYMPTOM REMEDY
Short Gel Time Resulting From Elevated Work Place Temperatures Reduce amount of initiator.
Laminate Slippage Disperse filler using a Cowls mixing blade.
Maintain a 10 mil or less mist coat of resin compound.
Confirm that only approved fillers are in use.
Inadequate Mixing of Initiator or Initiator Streaking Equipment not adjusted properly or in need of cleaning or repair. Take appropriate action.
Warm resin compound to 29°C–32°C (85°F–90°F).
Inspect turbulent mixer used in equipment. Replace with new or more efficient unit. In some equipmenta nylon unit performs better that teflon. Teflon soft enough that flutes can collapse, causing a loss of sealto the chamber and initiator streaming or improper mixing.
Cured Laminate Has Green Colored Surface Over catalyzation. Repair or adjust dispensing equipment.
Review tooling manual for suggested concentration.
Wrong peroxide initiator used. Use only Superox® 46709.
» Technical Tips
33540 Series | 33541 Series
G4-a
SYMPTOM REMEDY
Surface Distortion of completed Tool or Part Increase temperature of work place and master part.
Verify concentration and weights of resin, filler, promoter and peroxide initiator.
Inadequate mixing of additive materials. Review mixing procedures and adjust dispensing equipment.Brush or roll mist coat of resin compound.
Over-catalyzation/under-catalyzation. Review manual and make necessary adjustments or equipmentrepairs.
Warm resin compound to 29°–32°C (85°–90°). Maintain temperature during application. Increase workplace temperature.
Improper or inadequate gelcoat cure. Consult manufacturer.
Wrong peroxide initiator used. Use only Superox® 46750.
Raise laminate exotherm by increasing cross sectional thickness of laminate prior to gel and cure.
» Technical Tips33542 Series
G4-b
SYMPTOM REMEDY
Surface Distortion of completed Tool or Part Increase temperature of work place and master part.
Verify concentration and weights of resin and peroxide initiator.
Inadequate mixing of additive materials. Review mixing procedures and adjust dispensingequipment. Brush or roll mist coat of resin compound.
Over-catalyzation/under-catalyzation. Review manual and make necessary adjustments orequipment repairs.
Warm resin compound to 29°–32°C (85°–90°). Maintain temperature during application.Increase work place temperature.
Improper or inadequate gelcoat cure. Consult manufacturer.
Wrong peroxide initiator used. Use only Superox® 46709.
Raise laminate exotherm by increasing cross sectional thickness of laminate prior to gel and cure.
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G5
SYMPTOM REMEDY
Low Laminate Mechanical Properties Correct and confirm that proper initiator and concentration are used.
Increase temperature of work place and resin compound during application.
Reduce filler content to 45% by weight and increase content of glass reinforcement.(For 33540 and 33541 Series only).
Incorporate uni-directional and/or bi-directional glass.
Increase length of chopped glass.
Increase thickness of final laminate.
Cracked Flange Area of Tool Reduce air in skin coat.
Hand lay uni-directional and/or bi-directional glass.
Increase cross sectional thickness of flange with composite.
Reduce filler content to 45% by weight and increase content of glass reinforcement.
Increase length of chopped glass.
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G6
SYMPTOM REMEDY
Sticking—Tool to Master, or Part to Tool Misapplication of materials used to construct master—follow manufacturer’s recommendation.
Use PVA parting film.
Design the master or part with proper draft angles.
Inadequate gelcoat cure. Follow manufactures recommendation.(This can also appear as hazing of gelcoat.)
Gelcoat porosity—review and correct application techniques.
Improper or inadequate use of release agents. Follow manufacturer’s application recommendations.
Repairs—Secondary Bond Thoroughly abrade with 60 grit sand paper and clean. Warm Polylite Profile Series resin compound to29°–32° C (85°–90° F). Use chopped and bi- or uni-directional glass. Use step shingle laminateextending at minimum of 6 inches from edge of repair.
Prepare surface with Atprime®—follow directions for use.
Poor, or Lack of, Adhesion to PVC Core Material PVC core materials have not been evaluated for use with Polylite Profile and are therefore notrecommended at this time.
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G7
The following table will assist the Polylite® Profile user to estimate the amount of material required for a given thickness of composite. Values are based on pounds per square foot of
composite which incorporate a 1:1 ratio resin to filler and 19% by weight chopped continuous strand roving. The term composite refers to resin, filler and chopped strand roving content only.
Thickness (mils) 1.000 .8750 .7500 .6250 .5000 .3750 .2500 .1250
Thickness (inches) 1 7⁄8 3⁄4 5⁄8 1⁄2 3⁄8 1⁄4 1⁄8
Composite, weight 8.15 7./13 6.11 5.10 4.08 3.06 2.04 1.02
Resin, weight, (lbs) 3.30 2.88 2.48 2.04 1.64 1.23 0.82 0.41
Filler, weight, (lbs) 3.30 2.88 2.48 2.04 1.64 1.23 0.82 0.41
Glass, weight, (lbs) 1.55 1.37 1.15 1.02 0.80 0.60 0.40 0.20
Note: Add approximately 10% for waste
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G8
STEP 1
Prior to fabrication, read, view and understand Reichhold’s tooling manual and video. Read and understand all product literature and material safety data sheets.
STEP TWO—MASTER PLUG
A. Construct master plug and finish to exact dimensions and surface smoothness.
B. Apply appropriate release agent to the surface (following manufacturer’s directions exactly).
STEP 3
A. Review the Resin Compounding and Pre-Application Quality Control sections, pages B1-D4.
Thermoformed Acrylic Tool Fabrication
This guide is intended to assist the fabricator with construction of Polylite® Profile tools which will be used to thermoform either cast or extruded acrylic sheet. Only tools fabricated by
glass reinforced spray-up techniques will be reviewed. The guide was compiled from information provided by fabricators and material suppliers. This information represents current
state-of-the-art at the time of printing and is intended for guidance purposes. Final design, application and material selection is the sole responsibility of the fabricator. Because
construction materials differ among composition, application and performance, and due to a variety of thermoforming process conditions, we recommend each user thoroughly
evaluate this tooling system for suitability.
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G9
STEP 4—GEL COAT
A. Spray on two or three passes of a suitable gel coat to develop a 7–12 mu (0.2—0.3 mm) thickness. Thickness of over 12 mu (0.3mm) may result in cracking. Spraying gel coat
to a uniform thickness onto small irregular molds can be difficult. A combination of low spray pressure and small diameter spray tips is suggested. Allow to cure to a tacky feel.
An external heat source may be required to ensure that proper degree of cure is achieved.
B. The use of tough heat resistant gel coats are suggested. These include vinyl ester (aluminum and non-aluminum filled) and isophthalic/neopentyl glycol based products.
C. Follow all gel coat manufacturer’s recommendations for handling and applications.
NOTE: The fabricator may elect not to employ a gel coat. It may be advantageous to eliminate the gel coat when fabricating small irregular shaped molds or molds that are subjected
to temperatures over 176°C (350°F). If a gel coat is not used, a one to two ply 1.5 oz. per square foot Hydrex® Series laminate may be used.
STEP 5—NON FILLED PRIMARY LAMINATE (OPTIONAL)
A. To minimize the potential of air entrapment within the primary laminate, a non-filled laminate may be applied after the gel coat step. This laminate should be applied to a
thickness of 17.5—35 mils (0.44—0.89 mm) using Hydrex 33390 vinyl ester hybrid or Polylite 33346 vinyl ester resin. A resin to glass ratio of 70–75:30–25 should be
maintained. The primary laminate should be permitted to cure 24 hours prior to laminating with the Polylite Profile system. Read and understand both the product bulletin and
material safety data sheet prior to using Hydrex 33390.
STEP 6—LAMINATE APPLICATION
A. Spray a mist coat of resin compound to an appropriate thickness of 10 mils (0.25 mm). This should completely wet the surface. Only mist an area which can be
worked prior to gelation.
B. A brush may be used to assist with coverage and removal of entrapped air.
C. Apply a fiber-reinforced Polylite Profile Tooling resin layer to approximate thickness of 30–45 mils (0.76—1.14mm) accomplished in one or two passes.
» Technical Tips
33540 Series | 33541 Series | 33542 Series
G10
STEP 7—ROLLOUT
A. Remove all entrapped air with a brush or roller after each pass. Carefully inspect and remove air voids in laminate before proceeding to the next laminate application.
Laminate applications must have a minimum thickness of 120 mils (3.05 mm) prior to gel and cure.
B. Work out all entrapped air.
STEP 8—CURE
A. Allow the exotherm of each 120 mils (3.05 mm) laminate to subside before proceeding with subsequent applications. Failure to do so will decrease the working time of
subsequent laminations. Because in-service requirements of tools vary, it may be necessary to apply multiple laminates to achieve the desired cross sectional thickness of the
completed tool.
B. Repeat Step 7, as needed, to achieve the required composite thickness.
C. After each laminate application, trim excess glass from flange edge of the tool after partial cure is reached. The use of backup core reinforcements is not recommended.
STEP 9—VACUUM CHANNELS
A. Construct all vacuum chanels from suitable materials.
B. Laminate vacuum chanels to designated locations throughout tool. After completion of cure pressure test using 3–5 psi of compressed air, repair as required.
STEP 10—ADD BACKUP REINFORCEMENT STRUCTURE
A. Cut and tailor a backup structure as required to maintain proper equipment.
B. Scuff sand attachment points on the tool as required to ensure a proper fit.
C. Position structure on the tool and attach by spraying chop around each attachment point.
» Casting
33540 Series | 33541 Series
H1
PROCEDURE FOR MASS CASTING WITH ALUMINUM POWDER AND SHOT
1. Gel coat mold or plug with aluminum filled gel coat. Allow gel coat to cure to a very light tack.
2. Use a mixer like the type used to make cultured marble or concrete. Do not use blade type mixer used for tooling resins.
Those mixers will not handle the high viscosity.
3. Add resin to mixer.
4. Add 0.4% 46559 promoter (if using 33540) to resins and mix 2 minutes or until completely mixed.
5. Add 0.75-1% 46750 peroxide initiator. Mix for 2 minutes or until completely mixed.
6. With mixer running, add aluminum shot. Weight of shot should be two times the weight of the resin used.
Mix until shot is completely wet-out by resin.
7. With mixer running, add aluminum powder. Weight of powder should be two times the weight of the resin.
Mix until powder is wet-out by resin.
8. Slowly add additional powder until no free resin is observed in the mix. Mix should have the consistency of a marble or concrete mix.
Mix needs to be thick enough to prevent settling of the shot.
Typical ratios are as follows:Resin 16-18%
Aluminum Shot 38-40%
Aluminum Powder 42-44%
9. Allow casting to cool down completely before removing from plug or mold
» Casting
33540 Series | 33541 Series
H2
PROCEDURE TIME
1. Casting forms constructed and master secured, waxed and PVA applied 2 hours
2. Gelcoat applied/cure 2 hours
3. Surfaces brush coated with Profile (20%)/Aluminum powder (80%) mixture. 0.25 hours
Reichhold 46559 promoter 0.5% by weight. Superox® 46750 1.5% by weight..
Gel time 5 minutes.
4. Cavity and flat back section pours were made prior to curing item 3 above.
Each pour consisted of the mixture as outlined above.
a) Polylite 46559 promoter mixed into 33540 0.1 hours
b) Superox 46750 initiator mixed into 33540 and 33541 0.1 hours
c) Aluminum powder added to mix immediately followed by sphery shot 0.2 hours
5. Geltime
Cavity section 0.3 hours
Flat back section 0.3 hours
6. Cavity section allowed to cure 24 hours prior to pouring of flat back section
7. Drill and secure alignment bolts 0.15 hours
PHYSICAL PROPERTIES POLYLITE® PROFILE CAST TOOLING
Compressive strength:
Materials
Polylite Profile Tooling resin 100
Polylite 46559 series promoter (for 33540) 0.3
Aluminum powder 315
Aluminum pellets 350
Superox 46750 catalyst (for 33540 and 33541) 1.0
Compressive strength @ 77°F, psi. 9,465
Compressive modulus, psi. x 10–5 2.53
Compressive strength @ 150°F. psi. 4,438
Compressive modulus, psi. x 10–5 0.95
Compressive strength @ 300°F, psi. 2577
Compressive modulus, psi. x 10–5 0.71
Coefficient of Thermal Expansion, x 10–6/°F 1 9
(-59–300°F)
Thermal Conductivity (K) W/m *K 3.36 @ 165°F
Heat Capacity (Cp), J/kg*K 1 050
Specific gravity gm/cc 2.18
» Packaging / Safety / Quality / Storage
33540 Series | 33541 Series | 33542 Series
I1
Packaging
Non-returnable 55-gallon metal drums or 42,000–44,000 lbs tank truck
MaterIal Safety Data
Read and understand the MATERIAL SAFETY DATA SHEET before using this product.
Material Safety Data Sheets are available from your Reichhold representative. Make certain you
obtain a copy of the Material Safety Data Sheet on this product. Users should request and
understand such information from the suppliers of all materials prior to working with these
materials.
Reichhold Quality Policy
Reichhold is committed to quality performance. We will satisfy the needs of themarketplace with innovative products which maximize value and performance, deliveredto specification and on time.
Storage
To ensure maximum stability and maintain optimum resin properties, Dion®, Hydrex®
and Polylite®, resins should be stored in closed containers maintained below 75°F (23.9°C) and
away from heat sources and sunlight. All storage should conform to local fire and building
codes. Drum stock should be stored away from all sources of flame or combustion. Inventory
levels should be kept to a reasonable minimum with first-in, first-out stock rotation.
Additional information on handling and storing unsaturated polyesters is available in Reichhold’s
Application Bulletin, General Information of Storage and Handling Unsaturated Polyester Resins.
For product information on other Reichhold resins, or Superox® peroxide initiators, please
contact your sales representative or your nearest Reichhold distributor.
Disclaimer
The recommendations made herein are based on our research and experience and that of
others and are believed to be accurate. No guarantee is made to the accuracy or the results
to be obtained from using any of the recommendations. Each manufacturer should make their
own determination on the suitability of any recommendation for their own particular application
and system. Nothing herein shall constitute or be construed as an express or implied warranty
of any recommendation and the manufacturer assumes all risk associated with using any of
the recommendations.
» Polylite® Profile Distributors
33540 Series | 33541 Series | 33542 Series
I2
AlabamaComposites OneMobile888-221-8133
Ashland DistributionMobile800-531-7106
Advanced PlasticsElberta800-327-6136
ArkansasComposites OneVan Buren800-457-7017
ArizonaComposites OnePhoenix800-522-2599
Ashland DistributionChandler888-877-0963
CaliforniaComposites OneW. Sacramento800-654-5223
Composites OneMadera888-588-8520
Composites OneSanta Fe Springs800-237-0087
Ashland DistributionCarson888-877-0963
Ashland DistributionFairfield888-877-0963
ColoradoGeorge C. BrandtCentennial303-584-0717
FloridaComposites OneLakeland800-344-0656
Composites OneMiami800-432-2752
Ashland DistributionMiami800-531-7106
Ashland DistributionTampa800-531-7106
Fiberglass CoatingsSt. Petersburg727-327-8117
GeorgiaComposites OneValdosta800-458-5916
Composites OneLawrenceville800-423-7874
Ashland DistributionDoraville800-531-7106
HawaiiFiberglass HawaiiHonolulu808-847-3951
IllinoisComposites OneWoodstock800-435-6138
Ashland DistributionWillow Springs800-531-7106
IndianaComposites OneGoshen800-348-7503
Ashland DistributionElkhart800-531-7106
KansasAshland DistributionKansas City800-531-7106
LouisianaAshland DistributionBaton Rouge800-531-7106
Advanced PlasticsHarahan504-738-6035
MaineComposites OneRockland207-594-7503
MassachusettsAshland DistributionTewksbury800-531-7106
MichiganAshland DistributionWarren800-531-7106
MinnesotaComposites OneLino Lakes800-457-7011
Ashland DistributionShakopee800-531-7106
MissouriComposites OneNorth Kansas City800-457-7975
Ashland DistributionSt. Louis800-531-7106
New JerseyComposites OneMillville888-722-3371
North CarolinaComposites OneSmithfield919-209-0840
OhioComposites OneAshtabula800-553-5483
Composites OneDayton800-334-7498
Ashland DistributionTwinsburg800-531-7106
OklahomaAshland DistributionTulsa800-531-7106
OregonAshland DistributionPortland888-877-0963
PennsylvaniaComposites OneMonessen800-736-0999
Ashland DistributionMorrisville800-531-7106
Rhode IslandComposites OneBristol800-343-3030
TennesseeComposites OneLa Vergne888-457-3401
Ashland DistributionKnoxville800-531-7106
Advanced PlasticsNashville800-321-0365
TexasComposites OneFort Worth800-752-7839
Composites OneHouston800-451-8459
Ashland DistributionGarland800-531-7106
Ashland DistributionHouston800-531-7106
Johnson FiberglassSouth Houston713-946-8444
UtahComposites OneSalt Lake City800-444-0156
Ashland DistributionClearfield888-877-0963
VirginiaAshland DistributionRoanoke800-531-7106
WashingtonComposites OneVancouver800-255-6006
Composites OneArlington800-283-0809
WisconsinComposites OneDe Pere920-336-5898
Ashland DistributionMenasha800-531-7106
I3
To receive information on the Polylite® Profile Tooling System, Hydrex® high-performance resins or other Reichhold products, call your local Reichhold representative.
Relchhold World Headquarters and Technology CenterPO Box 13582
Research Triangle Park, NC 27709-3582
800.448.3482 (General Information)
800.431.1920 ext. 1 (Product Inquiries)
www.Reichhold.com
» Corporate Headquarters