CLEAR EPOXY RESIN EASY TO USE VERY THIN 4 HOBBY CASTING COATING FIBERGLASSING 96, US $48.77 – Picture 0

CLEAR EPOXY RESIN EASY TO USE VERY THIN 4 HOBBY CASTING COATING FIBERGLASSING 96, US $48.77 – Picture 1

CLEAR EPOXY RESIN EASY TO USE VERY THIN 4 HOBBY CASTING COATING FIBERGLASSING 96, US $48.77 – Picture 2

Clear Epoxy Resin Easy To Use Very Thin 4 Hobby Casting Coating Fiberglassing 96

US $48.77

Ontario, California, United States
Mar 2nd

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BEST VIEWED USING GOOGLE CHROME BROWSER MAX 1618 A/B 96.0 FLUID OUNCE COMBINED VOLUME 1/2 Gallon MAX 1618 PART A (HALF GALLON 64 FL.OZ) AND 1/4 Gallon MAX 1618 PART B (1 QUART 32 FL.OZ) 2:1 EASY TO USE (BY WEIGHT OR BY VOLUME) MIX RATIO In our efforts to maintain our low cost price offerings, the items may be packaged in different chemical safe containers approved for storage and DOT shipping regulations. MAX 1618 A/B is our newest ultra-clear resin system engineered by our R&D laboratories that specifically addresses the performance aspects of absolute crystal clarity and durable resin system MAX 1618 is an excellent resin system for wood, metals, stone and pottery products and for general composite fabrication for fiberglass, carbon fiber, aramid and other composite fabrication fabrics. AVAILABLE MAX 1618 A/B KIT SIZES MAX 1618 48 OUNCE KIT MAX 1618 96 OUNCE KIT MAX 1618 1.5 GALLON KIT DOME COATING WITH MAX 1618 A/B For dome coating metal substrates, use our MAX SEAL clear coating as a adhesion primer and avoid delamination due to differential expansion and contraction of the metal and the MAX 1618 A/B resin system. MAX SEAL is an excellent clear primer for glass, gold, silver and other 'hard to bond to' substrates. http://cgi.ebay.com/ws/eBayISAPI.dll?ViewItem&item=310219352478 Both metal substrates where primed with MAX SEAL before doming with MAX 1618 A/B FOR WOOD COATINGS TABLETOP AND COUNTERTOP APPLICATIONS PLEASE CLICK ON THE LINK TO DOWNLOAD OUR NEW 'HOW TO' BULLETIN View and Download Our Step-By-Step Instructional Bulletin Physical and Mechanical Properties Density 1.10 g/cc +/- .02 grams per cubic centimeter 0.98 +/- .05 grams per cubic centimeter 1.09.+/-.03 grams per cubic centimeter Part A Part B Mixed Pounds per Gallon Mixed 9.07 Pounds Per Gallon Form and Color PART A PART B MIXED Cured specimen 50 grams Mass Clear Liquid Clear Liquid Clear Liquid Clear Transparent Viscosity PART A = PART B = MIXED = 980 to 1040 cPs @ 25?C 300 to 310 cPs @ 25?C 377 cPs @ 25?C Mix Ratio 100 Parts “B”to 50 Parts “A” By Weight Or 2:1 By Volume Use a digital scale and proportion by weight instead of volumetric measurement especially when mixing less than 100 grams Working Time 30 Minutes @ 25?C (300 gram mass) Peak Exotherm Temperature 174?C (300 gram concentrated mass) after 50 minutes Handle Time 6 – 8 Hours Set to Touch, 10 Hours Green Strength Maximum Operating Temperature 95?C Full Cure Time 36 Hrs. Minimum @ 25?C Accelerated Cure Schedule 4 hours at 25?C or until dry to the touch plus 30 Minutes @ 150?F PHYSICAL PROPERTIES Heat Resistance Study By Shore Durometer Hardness Test The heat resistance of MAX 1618 A/B was test by heating a 2 inch cube in 5 degree increments and the Shore hardness was determined using both the Shore A and D scale. This test demonstrate the heat resistance of the MAX 1618 A/B by determining at what temperature the Shore Hardness reading dramatically change. At 140 °F a considerable change in Shore D Hardness Scale occurred due to the sharp needle-like indenter of the equipment began puncturing the surface of the specimen which may make the Scale D Hardness an unreliable test data. The Shore A scale demonstrated a dramatic change in hardness at 240°F which demonstrates it maximum heat tolerance more accurately than the Shore D scale. Hardness Application 30 Shore A Art gum erasers 35 Shore A Rubber bands 40 Shore A Can tester pads 50 Shore A Rubber stamps 55 Shore A Pencil erasers 60 Shore A Screen wiper blades 65 Shore A Automotive tires 70 Shore A Shoe heels 75 Shore A Abrasive handling pads 80 Shore A Shoe soles 85 Shore A Tap washers 90 Shore A Typewriter rollers 95 Shore A Fork lift solid tires 60 Shore D Golf ball 70 Shore D Metal forming wiper dies 80 Shore D Paper-making rolls Shore hardness is a measure of the resistance of a material to penetration of a spring loaded needle-like indenter. Dr. Dmitri Kopeliovich Hardness of Polymers(rubbers, plastics) is usually measured by Shore scales. Shore A scale is used for testing soft Elastomers (rubbers) and other soft polymers. Hardness of hard elastomers and most other polymer materials (Thermoplastics,Thermosets) is measured by Shore Dscale. Shore hardness is tested with an instrument called Durometer. Durometer utilizes an indenter loaded by a calibrated spring. The measured hardness is determined by the penetration depth of the indenter under the load. Two different indenter shapes and two different spring loads are used for two Shore scales (A and D). The loading forces of Shore A: 1.812 lb (822 g), Shore D: 10 lb (4536 g). Shore hardness value may vary in the range from 0 to 100. Maximum penetration for each scale is 0.097-0.1 inch. This value corresponds to minimum Shore hardness: 0. Maximum hardness value 100 corresponds to zero penetration. CLARITY AND TRANSPARENCY COMMON CAUSES OF TURBIDITY AND POOR RESIN CLARITY Silicone defoamers are formulation additives that helps reduce mixed air bubbles. It is commonly used in all types of industrial fluids to prevent foaming during processing. It is an integral additive in paints protective and conformal coatings as an anti-foam additive. However, silicone defoamers and surfactants creates turbidity in a clear epoxy resins. It is purposely designed to be immiscible (will not blend with or form a stable solution) with epoxy resin polymers so when air bubbles formed from mixing of the curing agent to initiate polymer cross-linking, it causes air bubbles to be unstable and cause degassing. When an air bubble encounters the silicone defoamer compound within the mixture, the lamella or the skin boundary of the bubble loose structural equilibrium and causes it to burst due to the differential surface tension of the polymer resin and the suspended silicone molecules. This physical dynamics cause a defoaming action within the resin matrix. This incompatibility between the epoxy polymer and the silicone defoamer cause turbidity and loss of optical transparency that is increasingly evident in thick castings or coatings. MAX CLR-TC is our top coat resin system designed for thin film applications that is formulated with silicone based defoamers and surfactants to reduce the occurrence of air bubbles and surface blemishes from becoming stable as the epoxy polymer converts from a liquid to a solid plastic. Note the turbidity of the MAX CLR-TC A/B VERSUS MAX 1618 A/B 3 INCH THICK CASTING. 4 FLUID OUNCES CAST VOLUME MAX 1618 A/B is formulated without the use of any silicone based surfactants that causes turbidity even in very thick castings. MAX 1618 A/B COLOR STABILITY COMPARISON Clear epoxy systems formulated using plasticizers and accelerators such as the specimen. The left specimen demonstrates poor color stability even if it is unexposed to direct sunlight or elevated temperature. Note the MAX 1618 A/B specimen that was formed at the same time and kept in a temperature controlled (25.0°C +/- 0.5 °C) chamber that filters out any UV radiation from ambient light source. MAX 1618 A/B DIRECT SUNLIGHT EXPOSURE STUDY Note the low yellowing performance of MAX 1618 A/B compared to a common brand epoxy resin after equal direct sunlight exposure of 2 months. Competitive brand clear resin system formulated with nonyl phenol plasticizers after sunlight exposure MAX 1618 A/B Unique low viscosity formulation without the use of low functional epoxy diluent or thinners. COLOR STABILITY STUDY VIA ACCELERATED UV EXPOSURE TO PAUSE OR PLAY THE FOLLOWING SLIDE SHOWS, PLACE THE CURSOR ON THE PICTURE TO ACTIVATE VIEWING CONTROLS Note the absolute clarity of the MAX 1618 A/B specimen exhibiting excellent transparency and low refractive index. COATING AND CASTING MEASUREMENTS AND STANDARDS FLUID GALLON VOLUME CONVERSION 1 US GALLON 231 CUBIC INCHES 1 US GALLON 128 FLUID OUNCES 1 US GALLON 3.7854 LITERS 1 US GALLON 4 US QUARTS 1 US GALLON 16 CUPS 1 US GALLON OF UNFILLED PURE EPOXY RESIN 9.23 POUNDS 1 US GALLON OF UNFILLED PURE EPOXY RESIN 4195 GRAMS MAX 1618 A/B THICK COATINGS APPLICATION ON WOOD PLAQUES BAR TOPS AND COUNTERTOPS TO PAUSE OR PLAY THE FOLLOWING SLIDE SHOWS, PLACE THE CURSOR ON THE PICTURE TO ACTIVATE VIEWING CONTROLS BASICS STEPS OF WOOD SEALING AND WATERPROOFING MAX 1618 A/B is mixed at a 2:1 mix ratio and exhibits a very low initial viscosity. It is resistant from ‘blushing’, exhibits excellent resistance to air bubble entrapment and retention, moderate working time reactivity and it cures to a very transparent clear resin system with a low refractive index. MAX 1618 A/B exhibits low dimensional shrinkage during cure, heat performance of up to 200°F, adhesion to 'hard to bond to' plastics and low surface energy (LSE) substrates with exceptional impact and chemical resistance. Its cured mechanical properties also demonstrate high compressive strength, toughness, tensile strength and other mechanical performance crucial in structural strength applications. Other Commercial Epoxy Penetrating systems contain highly toxic solvents such as toluene, naptha and other aromatic solvents that are also considered as an environmental air pollutant. The effectiveness of a penetrating wood sealant is highly dependent on the permeability of the coating against high moisture environments or the direct water contact . Some commercial grade epoxy penetrating solutions cures with the carrier solvent cured within the epoxy matrix causing poor water proofing or prolonged water resistance. Solvents entrapped within the epoxy can cause wood to swell and can lead to wood rot. WOOD SEALING AND WATERPROOFING Ensure that the wood is as dry as possible; any excessive moisture will be sealed within the wood once it is impregnated with resin Pre-cut the wood pieces to be sealed prior to coating. Cutting epoxy sealed wood is very difficult and can ruin cutting blades and power tools. Use a fast evaporating solvent to dilute the epoxy such as Acetone or MEK (ketone based solvents). Add no more than 5% solvent by weigh or by volume of the Acetone to the mixed resin. Insure that all wood surface is coated with the epoxy sealant. For best results coat the entire exposed surface area with the prepared epoxy resin mixture. Apply multiple coats until all porosity of the wood is sealed; some grain raising can be expected upon coating. Allow the applied coats to cure for at least 24 to 36 hours before proceeding. For a smoother finish, sand the cure surface just enough to remove surface gloss and removed and surface blemishes caused by the grain raising. Lightly sand the surface to remove any grain raising if desired using 280 to 300 grit sandpaper. Fiberglassing over the seal wood for increase strength and stability Choose the proper fiberglass weight and weave for the job. Here are some good fiberglass style STYLE 7500 FIBERGLASS CLOTH 10.OZ PLAIN WEAVE 62" WIDE HEXCEL 7500 STYLE 7781 FIBERGLASS CLOTH 60" WIDE FOR CURVES & CONTOURS SATIN WEAVE SMOOTH TEXTURE 9 OZ Apply another coat of the epoxy, this time do not add any solvent to insure maximum strength development. Use a plastic spreader or flat plastic spreader to consolidate the fiberglass to wood. Use this to smoothen the fiberglass and remove excess resin and entrapped air bubbles. Allow the epoxy resin to cure for 24 hours. Upon cure, the cured laminate can be directly painted with a UV resistant polyurethane or acrylic paint to protect the epoxy resin from the damaging effects of direct UV (sunlight) exposure. Insure that the wood is as dry as possible; any excessive moisture will be sealed within the wood once it is impregnated with the wood. Use a fast evaporating solvent to dilute the epoxy such as acetone or MEK (ketone based solvents). Insure that all wood surface is coated with the epoxy sealant and make sure all sides are coated as well. Apply multiple coats until all porosity of the wood is sealed; some grain raising can be expected upon coating. Allow the applied coats to cure for at least 24 to 36 hours before proceeding. For a smoother finish, sand the cure surface just enough to remove surface gloss and removed and surface blemishes caused by the grain raising. Apply another coat of the epoxy without the addition of the solvent to insure a hermetic seal and serve as an aesthetic top coat. Apply an aliphatic based polyurethane coating unto the epoxy coating if the wood structure is going to be exposed to direct UV or sunlight exposure. Outdoor paints are also excellent UV protestants and can be applied directly onto the epoxy coated wood with minimal surface preparation. Allow epoxy penetrating coating to cure and then apply the reinforcing fiberglass if needed by applying the resin first and then apply the fiberglass unto the resin. NEED MORE INFORMATION? Please visit our YouTube Channel to view our video demonstrations PolymerProductsPCI on YouTube REVIEW THE FOLLOWING USAGE INFORMATION BEFORE USING THIS PRODUCT. DUE TO ITS HIGH PURITY GRADE RESIN FORMULATION, MAX 1618 A/B IS PRONE TO CRYSTALLIZATION DUE TO COLD TEMPERATURE AND SUDDEN MECHANICAL SHOCK. DO NOT USE THE RESIN SYSTEM UNLESS IT HAS BEEN PROPERLY PROCESSED TO INSURE ITS PROPER CURE AND HIGH MECHANICAL PERFORMANCE. COLD WEATHER NOTICE 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, REDUCE AIR BUBBLE ENTRAPMENT, MAINTAIN ITS WORKING TIME AND INSURE PROPER CURE. IN SOME CASES THE RESIN OR PART A MAY APPEAR TO BE CLOUDY OR SOLIDIFIED, WHICH IS AN INDICATION OF RESIN CRYSTALLIZATION. HEAT PROCESSED PARTIALLY CRYSTALIZED CRYSTALLIZED SOLID USE BELOW 80°F DO NOT USE UNLES PROCESSED DO NOT USE UNLES PROCESSED THE COLD TEMPERATURE EXPOSURE CAN OCCUR DURING TRANSPORT OR DELIVERY OF THE KIT WHERE THE PACKAGE CAN BE EXPOSED TO TEMPERATURES BELOW 50°F AND INITIATE THE RESIN TO CRYSTALIZE OR DEVELOP SEED CRYSTALS. ONCE A SEED CRYSTAL DEVELOPS, CRYSTALLIZATION WILL OCCUR EVEN IF STORED AT THE PROPER STORAGE TEMPERATURE. DO NOT THROW AWAY OR USE THE RESIN UNTIL IT HAS BEEN MELTED BACK TO A FREE-FLOWING LIQUID PHASE BY GENTLE HEATING 120°F TO 150°F.THE HIGH PURITY EPOXY COMPONENT AND THE ABSENCE OF ANY ACCELERATORS AND OTHER NON-REACTIVE IMPURITIES IN ITS FORMULATION ARE SOME OF THE MANY KEY FACTORS THAT CONTROLS ITS HIGH PERFORMANCE PROPERTIES. THE COLD TEMPERATURE WILL ALSO MAKE THE RESIN MUCH THICKER THAN THE STATED VISCOSITY AND WORKING TIME VALUES AS STATED ON THE PHYSICAL TABLES CHART. THIS WILL REDUCE THE POLYMER'S REACTION RATE AND EXTEND ITS CURE TIME. THIS CAN RECTIFIED BY PRE-WARMING BOTH COMPONENT AND USING THE MIXED RESIN IN A CONTROLLED TEMPERATURE ENVIRONMENT NO COOLER THAN 70°F. COMMON EFFECTS OF COLD TEMPERATURE EXPOSURE HIGHER OR THICKER VISCOSITY LESS ACCURACY IN VOLUMETRIC MEASUREMENT DUE TO ITS THICKER CONSISTENCY CRYSTALAZIED OR SOLIDIFIED RESIN COMPONENT THAT WILL APPEAR AS A WHITE WAX-LIKE CONSISTENCY MORE BUBBLE ENTRAPMENT DURING MIXING SLOWER REACTIVITY LONGER CURE TIMES LOWER CURED PERFORMANCE DUE TO NONE FULL CURE POLYMERIZATION PROCESSING EPOXY RESINS TO COUNTER ACT THE AFFECTS OF THE COLD TEMPERATURE EXPOSURE, WARM THE RESIN GENTLY BY PLACING IT IN A PLASTIC BAG AND IMMERSE IT IN HOT WATER OR A WARM ROOM AND ALLOW IT TO ACCLIMATE UNTIL IT IS A VERY CLEAR AND LIQUID IN CONSISTENCY. ALLOW THE RESIN TO COOL 75°F TO 80°F MAXIMUM BEFORE ADDING THE CURING AGENT. PLACE CURSOR OVER THE SLIDESHOW TO PAUSE OR PLAY TO MELT THE CRYSTALLIZED RESIN FASTER, HIGHER PROCESSING TEMPERATURE CAN BE UTILIZED BY PLACING IT IN A PLASTIC BAG OR MAKE SURE THAT THE LID IS SECURE TO PREVENT WATER FROM ENTERING THE CONTAINER AND IMMERSE IT IN HOT WATER, 140°F TO 180°F UNTIL ALL TRACES OF THE CRYSTALLIZED RESIN IS ONCE AGAIN A CLEAR LIQUID. THE CONTAINER CAN WITHSTAND 212°F(BOILING POINT OF WATER); THE RESIN WILL REVERT BACK INTO A LIQUID IN LESS THAN 20 MINUTES. ALLOW THE RESIN TO COOL BELOW 80°F BEFORE ADDING THE CURING AGENT. A POLYMER RESIN'S PHYSICAL PROPERTY SUCH AS ITS VISCOSITY AND CURE RATE ARE HIGHLY AFFECTED BY THE AMBIENT TEMPERATURE AND THE TEMPERATURE OF THE COMPONENTS. HEAT POST CURING TECHNIQUE FOR FASTER AND THOROUGH CURE USE AN INFRARED HEAT LAMP FOR LARGER PARTS. USE THESE THEORETICAL FACTORS THAT RELATES TO ANY UNDILUTED EPOXY RESIN AS A GUIDE: 1 GALLON = 231 CUBIC INCHES 1 GALLON OF RESIN CAN COVERS 1608 SQUARE FEET 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 CAUTION ALTHOUGH THE POLYMERIZATION HAS SLOWED DUE TO THE COLDER AMBIENT CONDITIONS MIXING THE RESIN AND CURING AGENT ABOVE 80°F AS IT WILL CAUSE RAPID POLYMERIZATION AND HIGH EXOTHERMIC HEAT BUILD-UP THAT CAN EXCEED 300°F EXOTHERMIC HEAT WHEN KEPT IN MASS. DO NOT HEAT AND MIX THE RESIN OR CURING AGENT BEYOND 90°F AS IT MAY CAUSE RAPID AND UNCONTROLLABLE REACTION. THE BEST WORKING CONDITION IS TO PREWARM THE RESIN AND CURING AGENT TO 70°F TO 75°F PRIOR TO MIXING AND ALLOW IT TO CURE AT AN AMBIENT TEMPERATURE NO LOWER THAN 65°F FOR AT LEAST 24 HOURS. TO COUNTERACT THE EFFECTS OF THE COLD TEMPERATURE EXPOSURE, WARM THE RESIN GENTLY BY PLACING IT IN A PLASTIC BAG AND IMMERSE IT IN HOT WATER OR PLACE THE CONTAINERS IN A WARM ROOM AND ALLOW IT TO ACCLIMATE UNTIL IT IS A VERY CLEAR AND LIQUEFIED. ALLOW THE RESIN TO COOL 75°F TO 80°F MAXIMUM BEFORE ADDING THE CURING AGENT. TO PAUSE OR PLAY THE FOLLOWING SLIDE SHOWS, PLACE THE CURSOR ON THE PICTURE TO ACTIVATE VIEWING CONTROLS TO MELT THE CRYSTALLIZED RESIN FASTER HIGHER PROCESSING TEMPERATURE CAN BE UTILIZED BY PLACING IT IN A PLASTIC BAG OR MAKE SURE THAT THE LID IS SECURED TO PREVENT WATER FROM ENTERING THE CONTAINER AND IMMERSE IT IN HOT WATER , 140°F TO 180°F UNTIL ALL TRACES OF THE CRYSTALLIZED RESIN IS ONCE AGAIN A CLEAR LIQUID. THE CONTAINER CAN WITHSTAND 212°F (BOILING POINT OF WATER). THE RESIN SHOULD REVERT BACK INTO A LIQUID IN LESS THAN 20 MINUTES. ALLOW THE RESIN TO COOL BELOW 80°F BEFORE ADDING THE CURING AGENT. A POLYMER RESIN'S PHYSICAL PROPERTY SUCH AS ITS VISCOSITY AND CURE RATE ARE HIGHLY AFFECTED BY TEMPERATURE. CAUTION ALTHOUGH THE POLYMERIZATION HAS SLOWED DUE TO THE COLDER AMBIENT CONDITIONS MIXING THE RESIN AND CURING AGENT ABOVE 80°F AS IT WILL CAUSE RAPID POLYMERIZATION AND HIGH EXOTHERMIC HEAT BUILD-UP THAT CAN EXCEED 300°F EXOTHERMIC HEAT WHEN KEPT IN MASS. DO NOT HEAT AND MIX THE RESIN OR CURING AGENT BEYOND 90°F AS IT MAY CAUSE RAPID AND UNCONTROLLABLE REACTION. THE BEST WORKING CONDITION IS TO PRE-WARM THE RESIN AND CURING AGENT TO 70°F TO 75°F PRIOR TO MIXING AND ALLOW IT TO CURE AT AN AMBIENT TEMPERATURE NO LOWER THAN 65°F FOR AT LEAST 24 HOURS. BASIC EPOXY RESIN MIXING AND USAGE APPLICATIONS PLEASE VIEW THE FOLLOWING VIDEO FOR THE PROPER MIXING OF EPOXY RESINS. IT DEMONSTRATES THE PROPER TECHNIQUE OF MIXING ANY TYPE OF EPOXY RESIN. THE PROPER CURE AND FINAL PERFORMANCE OF ANY EPOXY RESIN SYSTEM IS HIGHLY DEPENDENT ON THE QUALITY AND THOROUGHNESS OF THE MIX. THE RESIN AND CURING AGENT MUST BE MIXED TO HOMOGENEOUS CONSISTENCY PLACE CURSOR ON THE PICTURE TO PAUSE OR PLAY SLIDE SHOW THE PROPER CURE AND FINAL PERFORMANCE OF ANY EPOXY RESIN SYSTEM IS HIGHLY DEPENDENT ON THE QUALITY AND THOROUGHNESS OF THE MIXING QUALITY. THE RESIN AND CURING AGENT MUST BE MIXED TO HOMOGENEOUS CONSISTENCY TO ACHIEVE PROPER CURE AND TACK FREE RESULTS. COMPOSITES FABRICATION APPLICATIONS MAX 1618 is an excellent resin system as an impregnating resin for Carbon Fiber, Kevlar, Fiberglass woven fabrics, yielding structural strength performance. MAX 1618 A/B cures at room temperature and requires no external heat to achieve full cure. Its very low viscosity (thin, similar to light-cooking oil) yields porosity-free fabrication of composite laminates. 3K Carbon Fiber 2x2 twill weave carbon fiber Thin Panel = 3 plies Thick Panel = 16 plies All panels were vacuum bag process for 4 hours (29.4 Hg) and allowed to cure for 24 hours before demolding ADOBE FLASH PAYER MUST BE INSTALLED IN YOUR BROWSER http://get.adobe.com/flashplayer/ 10" x 10" panel = 12K 2x2 Twill Weave Carbon Fiber Panel 12 Plies Impregnated with MAX 1618 A/B Vacuum Bag Laminated Tail Fin = 3K 2x2 Twill Weave Carbon Fiber Impregnated with MAX 1618 A/B Vacuum Infused TO PAUSE OR PLAY THE FOLLOWING SLIDE SHOWS, PLACE THE CURSOR ON THE PICTURE TO ACTIVATE VIEWING CONTROLS MAX 1618 A/B VACUUM ASSISTED RESIN TRANSFER MOLDING PROCESS. TO PAUSE OR PLAY THE FOLLOWING SLIDE SHOWS, PLACE THE CURSOR ON THE PICTURE TO ACTIVATE VIEWING CONTROLS Common epoxy based formulations engineered for high-strength structural applications typically exhibits very poor color stability due to the use curing agents that are inherently yellow or amber in color. In contrast, resin formulations engineered for transparent clear and other aesthetic applications yield lower mechanical strength caused by the use of lower functionality amine curing agents. MAX 1618 A/B does not utilize any liquid plasticizers and accelerators such as nonyl phenol or benzyl alcohol, which causes extreme yellowing even if the cured polymer is protected or unexposed to Ultraviolet or ambient heat. DON'T FORGET OUR EPOXY MIXING KIT EVERYTHING YOU NEED TO MEASURE, MIX, DISPENSE OR APPLY ANY OF OUR MAX EPOXY RESIN IN ONE CONVENIENT KIT Proportioning the correct amount is equally as important to attain the intended cured properties of the resin system. The container in which the epoxy and curing agent is mixed is an important consideration when mixing an epoxy resin system. The container must withstand the tenacity of the chemical and must be free of contamination. Most epoxy curing agent has a degree of corrosivity, as a general practice, protective gloves should be worn when handling chemicals of the same nature. MIXING KIT CONTENTS 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 4 each 8 ounce (1/2-Pint) Wax Free Paper Cups 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 (1 Cup to 1/8 Teaspoon) 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 Technical Support Please Call TOLL FREE 877 403 8008 Mon-Fri 10:00 AM to 4:00 PM Pacific Standard Time ALL OF OUR MAX EPOXY RESIN SYSTEMS ARE MADE IN THE USAWe Have Just Acquired Thousands Of Yards · Fiberglass Fabrics· Carbon Fiber Cloth· Aramid Fabrics· Aluminum and Phenolic Honeycomb Cores Factory woven by one of the largest weavers and producers of composite fabrics for aerospace, marine, electronic and structural composite materials. CLICK ON THE PICTURE TO PAUSE SLIDE SHOW For International Orders Please Inquire For Shipping Cost and 'request total from seller' to receive combined shipping cost if purchasing more than one product from our store. We will assemble the package and accurately weigh out the entire package and provide you the best shipping cost.If you need to purchase more than what is listed in this item page, please visit our ebay store. Make sure to request for a total to get the best combined shipping cost if purchasing multiple items PLEASE CHECK OUT OTHER AVAILABLE RESIN SYSTEMS AT OUR eBAY STORE For our complete listing, please Visit our eBay store! THANKS FOR STOPPING BY NEED MORE INFORMATION? Please visit our YouTube Channel to view our video demonstrations PolymerProductsPCI on YouTube IMPORTANT NOTICE Your purchase constitutes the acceptance of this disclaimer . Please review before purchasing this product. 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 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.

Condition:	New: A brand-new, unused, unopened, undamaged item in its original packaging (where packaging is applicable). Packaging should be the same as what is found in a retail store, unless the item is handmade or was packaged by the manufacturer in non-retail packaging, such as an unprinted box or plastic bag. See the seller's listing for full details. ...	Brand	MAX EPOXY SYSTEM
Country/Region of Manufacture	United States
Model	MAX 1618 A/B 96 OUNCE KIT