Epoxy resin boat building marine grade fiberglass 10GAL

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Epoxy resin boat building marine grade fiberglass 10GAL

5 gallons of PART A in 5 Gallon Plastic Pail
5 gallons of PART B in 5 Gallon Plastic Pail
Items may be packaged in different container as shown
* NONE SAG OR THIXOTROPIC VERSION FOR BONDING AND ADHESIVE APPLICATIONS
* MEDIUM VISCOSITY GRADE HIGHEST PERFORMANCE OF THE THREE
* LOW VISCOSITY VERSION EASE OF USE SUITABLE FOR COMPOSITE FABRIC IMPREGNATING
THIS LOW VISCOSITY VERSION IS FORMULATED TO PROVIDE EASE OF USE SUITABLE FOR FIBERGLASS WET-OUT AND IMPREGNATING APPLICATIONS FOR WOOD SEALING AND COMPOSITES FABRICATING
Lower Viscosity For Easy Wet And Dry Lay-up Application
* Brush, Roller Coat, Trowel Applied
* Bonds Steel, Aluminum, Soft Metals, Concrete, Ceramic
* High Performance Resin For Composites Fabrication
* Excellent Balance of Strength and Flexibility
* Excellent Water/Salt Water Resistant for Marine/Aero Applications
* Low Shrinkage And Dimensional Stability
* Wide range of service temperature
MAX BOND THIXOTROPIC, MAX BOND MEDIUM VISCOSITY, MAX BOND LOW VISCOSITY
please click on the following links below.
MAX BOND LOW VISCOSITY VERSION
The box dimension is 13 x13 x15 for each box.
Both Part A and Part B are D.O.T. None regulated and is considered none hazardous goods.
The Zip Code of origin is 91761 and then enter your Zip Code or COUNTRY OF DESTINATION for international orders.
WHICH EPOXY IS BEST FOR YOUR APPLICATION? Epoxy based polymers are one of the most versatile thermoset resins that can be modified into a multitude of applications and fit very specific task as demanded by the application. It offers ease of use and generally safer to handle over other types of thermoset resins which makes it the choice material for many high performance composites. New ideas demand new technology in material science and the skill to compose its constituent into a synergistic composite. What is impact testing?Impact testing is one of the most revealing test methods that demonstrate a material's ability to resist and withstand a high-rate of pressure loading, its behavior during and after the impact can define its maximum mechanical property and conditional limits upon its destruction. Why is Impact Testing Important?The impact resistance of an object provides the ultimate measure of its resistance to its definitive destruction. Governed by the many laws and dynamics of physics, a skilled chemist or materials engineer can determine the design equilibrium and ultimate performance by careful analysis of the material s disassociation and the manner of its destruction. With this knowledge, other aspects of mechanical performance can be accurately derived and through skilful engineering one can determine:
* The impact energies the part can be expected to see in its lifetime
* The type of impact that will deliver that energy, and then
* Design the construction that will resist such assaults over the projected life span.
During summer months or when mixing in high humidity environments, lower the mix ratio to 100 parts Part A Resin to 75 to 80 parts Part B Curing Agent by weight or by volume.
This will provide a higher degree of blush resistance for coating applications.
If the MAX BOND LOW VISCOSITY is going to be utilized as an adhesive, maintain the 1:1 mix ratio. As an adhesive, humidity is not a concern since the mixed resin is isolated from moisture by the substrates being bonded together.
DURING COLDER SEASON, THE EPOXY RESIN AND THE CURING AGENT WILL BE THICKER OR HIGHER IN VISCOSITY. TEMPER BOTH COMPONENTS TO AT LEAST 23oC TO 25oC BEFORE MIXING. A GOOD METHOD IS TO PLACE THE BOTTLES IN A WARM ROOM FOR 24 HOURS OR PLACE THE CONTAINERS IN A PLASTIC BAG, SEAL AND PLACE IT IN A HOT WATER BATH FOR 2 TO 3 HOURS. ALLOW THE RESIN KIT TO ACCLIMATE BACK TO ROOM TEMPERATURE BEFORE MIXING. THIS WILL THIN THE RESIN TO THE CONSISTENCY AS SHOWN ON THE VIDEO DEMONSTRATION.
USE THESE THEORETICAL FACTORS THAT RELATES TO ANY UNDILUTED EPOXY RESIN AS A GUIDE:
1 MIL OR 0.001 INCH CURED COATING THICKNESS
1 GALLON OF RESIN IS 128 OUNCES
1 GALLON OF MIXED EPOXY RESIN IS 9.23 POUNDS
1 GALLON OF RESIN IS 3.7854 LITERS
CLICK ON THE SLIDE SHOW TO ACTIVATE PAUSE AND PLAY CONTROLS
PICTURES CONTRIBUTED BY MR. DAVY M.
Pictures contributed by Mr. Lee R.
PLEASE VIEW THE FOLLOWING VIDEO PRESENTATION,
ALTHOUGH THE FEATURED EPOXY RESIN SYSTEM IS DIFFERENT THAN THE
THE GENERAL TECHNIQUE AND PROPER MIXING PROCEDURE IS APPLICABLE.
USE THIS MIX TECHNIQUE TO ELIMINATE TACKY SPOTS, UNCURED SECTIONS AND POOR MECHANICAL PERFORMANCE THAT IS CAUSED BY POOR MIXING AND INCORPORATION OF THE RESIN AND CURING AGENT.
Bonds To Steel, Aluminum, Soft Metals, Concrete, Ceramic, Fiberglass, Composites
Non-Critical Mix Ratio, Equal Parts by Volume,
Brush, Roller Coat, Trowel Applied
Excellent Balance of Strength and Flexibility
Excellent Water/Salt Water Resistant for Marine/Aero Applications
Low Shrinkage, Wide range of service temperature
Conforms To Aerospace /Military/Naval Specifications
Conforms To (FDA) Food and Drug Administration
Direct/Indirect food contact coatings/adhesive
CFR 175.300, CFR 176.170, CFR 175.105
MAX BOND LV A/B is a two-part epoxy/polyamide based adhesive system especially formulated to provide structural bond strength to a variety of substrates. It is a low viscosity version of MAX BOND A/B providing improved ease of use and faster fabric wetting. It is well suite for use in low temperature or cold weather environments.
Epoxy/Polyamide based resins are one of the best systems to use for applications that will be subject to water immersion and marine environments. It provides excellent resistance to saltwater, acidic and caustic exposure and retains its physical properties even after prolonged water immersion. MAX BOND LV A/B is 100 % reactive solids and does not contain Ozone Depleting Chemicals (ODC).
MAX BOND LV A/B will cure even in humid and low temperature conditions. It is generally room temperature cured but can be snap cured at elevated temperatures for a short period of time.
MAX BOND LV A/B demonstrates structural bond strengths to a variety of substrates commonly used in composites industry such as, steel, aluminum and soft metals, fiberglass, concrete and ceramic and most plastics. MAX BOND LV A/B performs well in wide range of service temperature and resists cracking and delamination due to cyclic vibration, thermal expansion and contraction
Dispense equal parts of Part A and Part B and mix thoroughly until a homogenous consistency is achieved. The mixture will turn translucent milky amber but will clarify when applied in a thin film during curing. Transfer the mixed resin into another clean container and mix for another minute and use.
For mix metering application, ensure that an equal flow rate of Part A and Part B is achieved. A 24 element static mixer provides excellent mix results. Attach the static mixer and dispense and discard approximately 1-ounce material before using the material. Dispense the material in on corner of the component casing and allow the material to completely flow through out. This technique will reduce voids and air entrapment.
Equal parts by weight or by volume
65 Minutes @ 77 F (25 C) (200 gm mass)
2 Hrs. @ room temperature plus
10 Day Soak Test @ 77 F (25 C)
MAX BOND LV A/B is self-leveling and easily poured into place and is well suited for mixed meter-dispensing equipment or mix and pour techniques. Large mixes of up to 300 grams are possible without generating excessive exothermic temperatures.
The working time is approximately 90 minutes for a 100-gram total mass and less if mixed in large volumes.
For Laminating or Reinforcing with Fiber Fabric Materials.
MAX BOND LV A/B works well as a laminating resin for composite fabrics such as canvas, fiberglass, carbon fiber, Aramid fiber and other hybrid and synthetic fabrics. Apply a thin layer of the mixed MAXBOND LV A/B unto the pre-cleaned substrate to be reinforced. Apply a layer of fiberglass and aide the resin to wet-out the fiberglass using a brush and apply subsequent layers of fabric sandwiching a layer of resin until the desire thickness is achieved. Use a rubber squeegee to remove excess resin. Allow curing for 24 hours. If using a vacuum bag technique or a platen press, please review our Lay-up sequence for bagging operations bulletin.
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TYPES OF FABRIC WEAVE STYLE AND SURFACE FINISHING
Is a very simple weave pattern and the most common style. The warp and fill yarns are interlaced over and under each other in alternating fashion. Plain weave provides good stability, porosity and the least yarn slippage for a given yarn count.
The eight-harness satin is similar to the four-harness satin except that one filling yarn floats over seven warp yarns and under one.
This is a very pliable weave and is used for forming over curved surfaces.
The four-harness satin weave is more pliable than the plain weave and is easier to conform to curved surfaces typical in reinforced plastics. In this weave pattern there is a three by one interfacing where a filling yarn floats over three warp yarns and under one.
Twill weave is more pliable than the plain weave and has better drivability while maintaining more fabric stability than a four or eight harness satin weave. The weave pattern is characterized by a diagonal rib created by one warp yarn floating over at least two filling yarns.
COMMERCIAL FIBERGLASS-FABRIC WEAVERFinishing Cross Reference AndResin Type Compatibility
Satin Weave Style For Contoured Parts Fabricating
These styles of fabrics are one of the easiest fabrics to use and it is ideal for laying up cowls, fuselages, ducts and other contoured surfaces with minimal distortions. The fabric is more pliable and can comply with complex contours and spherical shapes. Because of its tight weave style, satin weaves are typically used as the surface ply for heavier and courser weaves. This technique helps reduce fabric print through and requires less gel coat to create a smoother surface.
SATIN WEAVE TYPE CONFORMITY UNTO CURVED SHAPESCLICK ON THE SLIDE SHOW TO PAUSE OR PLAY Plain Weaves, Bi-axial, Unidirectional Styles For Directional High Strength Parts
Use this weave style cloth when high strength parts are desired.
It is ideal for reinforcement, mold making, aircraft and auto parts tooling, marine and other composite lightweight applications.
PLAIN WEAVE STYLE FOR HIGH STRENGTH
CLICK ON THE PICTURE TO PAUSE OR PLAY SLIDE SHOW
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A POLYMER RESIN'S PHYSICAL PROPERTY SUCH AS ITS VISCOSITY AND CURE RATE ARE HIGHLY AFFECTED AND INFLUENCED BY TEMPERATURE.
DURING THE COLDER SEASONS THE RESIN AND CURING AGENT SHOULD BE WARMED TO AT LEAST 75 F to 80 F (21 C to 27 C) PRIOR TO USE TO REDUCE ITS VISCOSITY TO REDUCE AIR BUBBLE ENTRAPMENT AND MAINTAIN ITS WORKING TIME AND PROPER CURE.
THE HIGH PURITY EPOXY COMPONENT AND THE ABSENCE OF ANY ACCELERATORS IN ITS FORMULATION ARE SOME OF THE MANY KEY FACTORS THAT CONTROLS ITS COLOR STABILITY.
THE COLD TEMPERATURE WILL ALSO MAKE THE RESIN MUCH THICKER THAN THE STATED VISCOSITY AND WORKING TIME VALUES STATED ON THE PHYSICAL TABLES CHART. THIS WILL REDUCE THE POLYMER'S REACTION RATE AND EXTEND ITS CURE TIME.
THIS CAN RECTIFIED BY USING THE MIXED RESIN IN A WARM ROOM AT TEMPERATURES NO LOWER THAN 70 F .
COMMON AND NOTICABLE THE EFFECTS OF COLD TEMPERATURE EXPOSURE
* HIGHER OR THICKER VISCOSITY
* LESS ACCURACY IN VOLUMETRIC MEASUREMENT DUE TO ITS THICKER CONSISTENCY
* CRYSTALLIZED OR SOLIDIFIED RESIN COMPONENT THAT WILL APPEAR AS A WHITE WAX-LIKE CONSISTENCY
* MORE BUBBLE ENTRAPMENT DURING MIXING
* LOWER CURED PERFORMANCE DUE TO NONE FULL CURE POLYMERIZATION
ALTHOUGH THE POLYMERIZATION HAS SLOWED DUE TO THE COLDER AMBIENT TEMPERATURE,
ONCE THE MIXTURE HAS BEGUN POLYMERIZING AND BUILD UP HEAT IT CAN STILL CAUSE A RUN-AWAY-REACTION
IF NOT USED PROPERLY. MIXING THE RESIN AND CURING AGENT ABOVE 80 F AILL ALSO CAUSE RAPID POLYMERIZATION
AND HIGH EXOTHERMIC HEAT BUILD-UP CAN OCCUR THAT CAN
EXCEED 300 F EXOTHERMIC HEAT WHEN KEPT IN MASS.
PROPER AMBIENT CONDTION FOR ANY RESIN TO CURE PROPERLY
75 F TO 80 F AND A RELATIVE HUNIDITY BELOW 40%
TEMPERATURES BELOW 50 F AND MAY CRYSTALIZE THE RESIN COMPONENT OR PART A.
THIS CAN BE EASILY REVERSE WITH NO ADVERSE AFFECT ON ITS CURED MECHANICAL PERFORMANCE OR SHELF LIFE.
PROCESSING EPOXY RESINS TO COUNTERACT AFFECTS OF COLD TEMPERATURE EXPOSURE
TO COUNTER ACT THE AFFECTS OF THE COLD TEMPERATURE EXPOSURE, WARM THE RESIN GENTLY BY PLACING IT IN A SEAL PLASTIC BAG
AND IMMERSE IT IN HOT WATER OR A WARM ROOM AND ALLOW IT TO ACCLIMATE UNTIL IT IS UNIFORMLY AT 75 F TO 80 F MAXIMUM BEFORE
1. PLACE THE BOTH CONTAINERS IN A HOT BOX OR A WARM ROOM AND ELEVATE THE AMBIENT CURE TEMPERATURE TO AT LEAST 75 F TO 80 F.
2. EXPOSE BOTH RESIN AND CURING AGENT UNDER SOLAR HEAT FOR SEVERAL HOURS
3. PLACE BOTH COMPONENTS UNDER DIRECT SOLAR HEAT FOR SEVERAL HOURS UNTIL IT IS WARM TO THE TOUCH.
UPON IT HAS CURE TO THE TOUCH, A SHORT HEAT POST CURE USING INFRARED LAMPS
MAX GPE OPAQUE PIGMENTED EPOXY SYSTEM FOR COLORED CASTING, COATING, IMPREGNATING
MAX BOND LOW VISCOSITY FOR STRUCTURAL STRENGTH APPLICATIONS
ADOBE FLASH PLAYER MUST BE INSTALLED IN YOUR COMPUTER TO VIEW THE FOLLOWING SLIDE SHOWS AND VIDEOS.
MAX GPE FOR GENERAL CONSTRUCTION LOW COST APPLICATIONS
MAX CLR HP CRYSTAL CLEAR HIGH PERFORMANCE APPLICATION
MAX HTE FOR HIGH TEMPERATURE RESISTANCE APPLICATIONS
Specimens were cured 3 Hours at 25 C plus 2 Hours At 155 CCLICK ON THE PICTURE TO PAGE OR PLAY Step Three: Proper Lay-Up TechniquePre-lay-up notes
* Lay out the fabric and precut to size and set aside
* Avoid distorting the weave pattern as much as possible
* For fiberglass molding, insure the mold is clean and adequate mold release is used
* View our video presentation above "MAX EPOXY RESIN MIXING TECHNIQUE"
* Mix the resin only when all needed materials and implements needed are ready and within reach
Mix the proper amount of resin needed and be accurate proportioning the resin and curing agent. Adding more curing agent than the recommended mix ratio will not promote a faster cure.
Over saturation or starving the fiberglass or any composite fabric will yield poor mechanical performance.
COMPUTING FABRIC TO RESIN RATIO BY WEIGHT
AN ACCURATE DIGITAL SCALE IS HIGHLY RECOMENDED RATHER THAN GOING BY FABRIC DATA AND VOLUMETRIC RESIN MEASURING AND PROPORTIONING.
WEIGH ALL FABRICS TO BE USED TO DETERMINE FABRIC TO RESIN RATIO
A good rule of thumb is to maintain a minimum of 30 to 35% resin content by weight, this is the optimum ratio used in high performance
prepreg (or pre-impregnated fabrics) typically used in aerospace and high performance structural application.
This will insure that the fabricated laminate will be below 40% resin content depending on the waste factor accrued during fabrication.
Place the entire precut fiberglass to be used on a scale to determine the weight ratio between the resin and fabric composition.
Typical fabric weights regardless of weave pattern
1 yard of 8 OSY fabrics at 38 inches wide weighs 224 grams
1 yard of 10 OSY fabrics at 38 inches wide weighs 280 grams
Ounces per square yard or OSY is also know as aerial weight which is the most common unit of measurement for composite fabrics.
If a scale is available, measuring by weight will insure accurate composite fabrication and repeatability, rather than using OSY data.
To determine how much resin is needed to adequately impregnate the fiberglass, use the following equation:
(Total Weight of Fabric divided by 60%)X( 40%)= weight of mixed resin needed
1 SQUARE YARD OF 8-OSY FIBERGLASS FABRICS WEIGHS 224 GRAMS
(224 grams of dry fiberglass / 60%) X 40% = 149.33 grams of resin needed
So for every square yard of 8-ounce fabric,
It will need 149.33 fluid ounces of mixed resin.
Computing for resin and curing agent requirements based on
MIX RATIO OF RESIN SYSTEM IS 2:1 OR
(2+1)=3 or (66.67%+33.33%)=100% or (2/3+1/3)= 3/3
149.33 x 66.67%= 99.56 grams of Part A RESIN
149.33 x 33.33%= 49.77 grams of Part B Curing Agent
99.56 + 49.77 = 149.33 A/B MIXTURE
Common Factors Of 100% Solids (Zero volatiles and unfilled epoxy resin)
1 gallon of resin = 4239 grams (1.12 g/cc)
1 fluid ounce of resin = 33.17 grams
BASIC FIBERGLASS FLAT PANEL LAY UP TECHNIQUE
Apply the mixed resin unto the surface and
then lay the fabric and allow the resin to saturate the fabric.
This is one of the most common processing error that yields sub-standard laminates.
By laying the fiberglass unto a film of resin, less air bubbles are entrapped during the wetting-out stage.
Air is pushed up and outwards instead of forcing the resin through the fabric which will entrap air bubbles. This technique will displace air unhindered and uniformly disperse through out the fiberglass with minimal mechanical agitation or spreading.
Note the slide show presentation
PLACE CURSOR ON THE PICTURE TO PAUSE AND PLAY SLIDE SHOW
Typical Fiberglass Reinforcing Technique Unto A Wood Substrate
ROOM TEMPERATURE CURED MAX EPOXY RESIN
USED FOR STRUCTURAL APPLICATIONS
TOP AND BOTTOM LAYER 9 OUNCE 4 HARNESS SATIN WEAVE
15 LAYERS CORE 24-OUNCE FIBERGLASS PLAIN WEAVE ROVING
FOR CARBON FIBER CRYSTAL CLEAR HIGH PERFORMANCE
SINGLE PLY 12-OUNCE 2X2 TWILL WEAVE CARBON FIBER
Given enough time and the proper selection of the fabric's surface treatment (fabric to resin compatibility), a dry fabric will seek a state equilibrium and distribute the applied resin and naturally release air bubbles entrapped within the laminant.
It is then very important that the proper viscosity, working time and surface treatment of the fabric must considered.
Given enough time and the proper selection of the fabric's surface treatment (fabric to resin compatibility),
a dry fabric will seek a state of equilibrium and distribute the applied resin and naturally release air bubbles entrapped within the laminant.
There are also fabricating techniques that can be employed to yield high performance laminate.
Depending on the size of the part, processes such as high pressure pressing, vacuum bagging and vacuum assisted resin transfer molding are superior methods over hand dry lay-up.
Air voids or porosity within the laminate is typically where failure propagates when load is applied
(fracturing, compression failure, tearing, torque, tensile strength, creep).
Optimum cured properties can take up to 7 days depending on the ambient cure condition.
The ideal temperature cure condition of most room temperature epoxy resin is 22 to 27 degrees Celsius at 20% relative humidity.
Higher ambient curing temperatures will promote faster polymerization and development of cured mechanical properties.
Improving mechanical performance via post heat cure
A short heat post cure will further improve the mechanical performance of most epoxy resins. Allow the applied resin system to cure at room temperature until for 18 to 24 hours and if possible, expose heat cure it in an oven or other source of radiant heat (220 F to 250 F) for45 minute to an hour. You can also expose it to direct sunlight but place a dark colored cover, such as a tarp or cardboard to protect it from ultraviolet exposure.
In general room temperature cured epoxy resin has a maximum operating temperature of 250 F and 160 F or lower
if it is under stress or load.
A short heat post cure will insure that the mixed epoxy system is fully cured,
especially for room temperature cured system that can take up to 7 days to 100% cure
Some darkening or yellowing of the epoxy resin may occur if over exposed to high temperature (>250 F). This color darkening is mostly caused by thermal oxidation process in which FREE RADICAL compounds are created via thermal energy (heat).
The affinity of an amine compound (curing agent) to moisture and
carbon dioxide creates a carbonate compound and forms what is called amine blush.
Amine blush is a wax-like layer that forms as most epoxies cure.
If the epoxy system is cured in extreme humidity (>70%).
It will be seen as a white and waxy layer that must be removed by
physical sanding of the surface followed by an acetone wipe.
Although we have formulated the MAX CLR, MAX BOND and MAX GPE product line to be resistant to amine-blush,
it is recomended not to mix any resin systems in high humidity conditions, greater than 70%.
Always make sure that the substrate or material the epoxy resin system is being applied to
is as dry as possible to insure the best cured performance..
Latent epoxy resins are systems that are mixed together at room temperature and will begin polymerization but it will not achieve full cure unless it is exposed to a heat cure cycle. In general, these are high performance systems that demonstrate exceptional performance under extreme conditions such as high mechanical performance under heat and cryogenics temperatures, chemical resistance or any environment that epoxy room temperature system perform marginally or poorly.
Upon the mixing of the resin and curing agent polymerization will begin and will only achieve partial cure. Some resins may appear cured or dry to the touch, this state is called 'B-Stage Cure' ,but upon application of force will either be gummy or brittle almost glass-like and will dissolve in most solvents. The semi-cured resin must be exposed to an elevated temperature for it to continue polymerization and achieve full cure.
This type of epoxy system will not polymerized unless it is exposed to the activation temperature of the curing agent which can be as low as 200F and as high as 400F. In most instances these epoxy system can be stored at room temperature and remain liquid for up to six months and longer
USE AN INFRARED HEAT LAMP FOR LARGER PARTS IF A PROCESS OVEN IS NOT AVAILABLE
POSSIBLE HEAT CURING TECHNIQUES
If an oven is not available to provide the needed thermal post cure, exposing the assemble part to direct solar heat
(sun exposure) for a period will provide enough heat cure for the part to be handled. Other heat curing such as infrared heat lamps can be used if a heat chamber or oven is not available.
3 Hours (after 24 hours room temperature) solar exposure Infrared heat bulb 3 hour exposure (200oF average)vacuum bag cure
DON'T FORGET OUR EPOXY MIXING KIT
Our Epoxy Mixing Kit comes with all the necessary utensils and protective gloves needed for mixing, dispensing or applying any of our
MAX EPOXY SYSTEM in one convenient kit.
* Measure Mix Ratio Accurately By Volume
The plastic mixing tubs are made from High Density Polyethylene (HDPE), which withstands the tenacity of the epoxy resin and curing agent.
Upon cure, any residue demolds easily from the plastic tubs and can be reused.
Our MAX EPOXY MIXING KIT comes with 5 pairs of powder free Latex Gloves to protect the user from direct contact with the epoxy resin system that will reduce sensitization or contact dermatitis
4 each 32 ounce (1 Quart) clear HDPE plastic tubs
4 each 16 ounce (1 pint) clear HDPE plastic tubs
4 each clear HDPE plastic Lids for the plastic tubs
5 pairs one size fits all Powder Free Latex Gloves (Large)
6 Piece HDPE Plastic Measuring Spoon Kit
(1 tablespoon to 1/8 teaspoon)
10 Piece HDPE Plastic Measuring Cup
2 each None Sterile Graduated 10 cc Syringes
1 pack of Wooden Stir Sticks (100 disposable Chopsticks)
1 pack Assorted Size Bristle Brush (5 per pack)
For our complete listing, please click the logo
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PolymerProducts, The Epoxy Experts
The user should thoroughly test any proposed use of this product and independently conclude satisfactory performance in the application. Likewise, if the manner in which this product is used requires government approval or clearance, the user must obtain said approval.The information contained herein is based on data believed to be accurate at the time of publication. Data and parameters cited have been obtain through publish information, PolymerProducts and Polymer Composites Inc. laboratories using materials under controlled conditions. Data of this type should not be used for specification for fabrication and design. It is the user's responsibility to determine this Composites fitness for use. There is no warranty of merchantability of fitness of use, nor any other express implied warranty. The user's exclusive remedy and the manufacturer's liability are limited to refund of the purchase price or replacement of the product within the agreed warranty period. PolymerProducts and its direct representative will not be liable for incidental or consequential damages of any kind. Determination of the suitability of any kind of information or product for the use contemplated by the user, the manner of that use and whether er there is any infringement of patents is the sole liability of the user.