Description: MAX GRE A/BGASOLINE RESISTANT EPOXY SYSTEM1 Quart PART A Resin Component1 Pint PART B Curing Agent48 Fluid Ounce Combined Volume PRODUCT HIGHLIGHTSExcellent Chemical Resistance Superior Impact Resistance And Durability Outstanding Adhesion To Metals And FRP TanksPrevents Rust And OxidationGasoline Resistant Repair For Metal Tanks And Composite Fuel Cells E85 Gasoline And Bio-Diesel BlendSecondary And Containment LiningsImpregnating Resin For Carbon Fiber & Fiberglass Gasoline Tank Fabrication Ethanol gasoline and diesel blends are more susceptible to water absorption due to the high ethanol content in modern fuels.The water molecule readily absorbs acid (H+) ions forming an electrolyte solution, creating high corrosion activity when the ethanol fuel blend comes in contact with metals. MAX GRE A/B is electrically non-conductive, shielding the metal substrate making the metal less suceptable to coorosion. MAX GRE A/B also is also acid resistant thus reducing oxidation or rusting of the metal tank. Both steel(Fe) or aluminum(Al) tanks metal tanks are more susceptable to oxidation or corrosion. Normal 0 false false false MicrosoftInternetExplorer4 PHYSICAL PROPERTIES & MECHANICAL PROPERTIES Density 1.10 G/CC Form and Color Clear Liquid Viscosity 2500-3000 cPs @ 25ºC Mixed Mix Ratio 2:1 100 Parts “A” to 50 Parts “B” Working Time 45 – 50 Minutes @ 25°C(100 Gram Mass) Peak Exotherm 70°C (100 Gram Mass) Thin Film Set Time 4 to 6 Hours Handle Time 8 Hours Cure Time 2 to 7 days @ 25°C Accelerated Cure Time 8 hours at room temperature plus 1 hours at 100 Hardness 80 ± 5 Shore D Tee-Peel Strength 3.4 Lbs. per inch Width Tensile Shear Strength 2,935 psi @ 25°C 1,970 psi @ -40°C 1250 psi @ 100°C Elongation 3.0% @ 25°C Flexural Strength 13,000 psi Flexural Modulus 344,000 psi Heat Deflection Temp. 70°C CHEMICAL RESISTANCE PERFORMANCE Full Immersion At 15°C to 30°C MEASURED PERCENT CHANGE IN WEIGHT REAGENT 10 Days 100 Days Deionized Water 0.09 % 0.03 % Sea Water 0.01 % 0.08 % Methanol 15% 3.93 % Destroyed Ethanol 50% 0.98 % 0.82 % Toluene 0.40 % 2.86 % Xylene 0.24 % 2.55 % Gasoline (E85 Blend) 0.10 % 0.03 % MEK 2.96% Destroyed 10% Lactic Acid 0.81 % 0.42 % 10% Acetic Acid 0.11 % 0.45 % 70% Sulfuric Acid 0.08 % 0.14 % 50% Sodium Hydroxide 0.00 % 0.10 % 10% Sodium Hypochlorite 0.51 % 1.36 % ELECTRICAL AND THERMAL CONDUCTIVITY PROPERTIES Volume Resistivity 4.7 X 1013 Ohms-Cm Dielectric Strength 510 Volts/Mil 60 Cycles Dielectric Constant 4.0 (10 kHz) Dissipation Factor 0.014 (10 kHz) Thermal Conductivity (Unfilled) 40°-45°C 0.25 W F/mK The substrate, metal or otherwise must be cleaned appropriately to remove oily residue by chemical degreasing. Use acetone to degrease the surface and ensure that the substrate is dry and free from contamination before application. Do not use rubbing alcohol or denature alcohol; acetone works best for degreasing and removing surface residue that affects adhesion. Remove loose or flaking rust, and for the best adhesion performance, abrade or sandblast so the MAX GRE A/B coating is in direct contact with the metal substrate. For aluminum substrates, chromic acid etching or sanding to bare metal is recommended for bonding and coating applications. An aluminum etching solution formulation is posted below. Use the same water bead test to determine the wettability of the substrate. If the water does not form a continuous film as demonstrated in the video, the surface requires more surface modification, until the surface yields good wetting. The Following Surface Preparation Procedures Are Recommended. METALS AND CONCRETEDegrease Metals– Wipe surface with lint-free rag dampened with Methyl Ethyl Ketone (MEK) or acetone to remove all oil, dirt, and grease. Degrease Concrete- Use 2 cups of TSP (trisodium phosphate) detergent per 5 gallons of hot water and scrub with a stiff deck brush. Rinse with water and allow to dry.Etch Metals – For optimum results, metal parts should be immersed in a chromic acid bath solution consisting of: Sodium Dichromate4 Parts By WeightSulfuric Acid10 Parts By WeightWater30 Parts By Weight The solution is held at 160°F (71°C), and the parts left immersed for 5 to 7 minutes. Rinse – remove metal parts from etching bath and rinse with clean water. (distilled water is recommended).Etch Concrete- Use commercially sold concrete etching solution (hydrochloric acid based works best). Neutralized per instructions, rinse and allow to dry thoroughly.ALTERNATE PROCEDURE Degrease, scour and dry – Often etching as outlined above is not practical. The metal surfaces may be cleaned by degreasing as noted above, scouring with an alkaline cleanser followed by rinsing and drying.Degrease and dry – Degrease the surface as noted above, sand or sandblast the surface lightly but thoroughly. Rinse with acetone or Methyl Ethyl Ketone (MEK), and dry.GLASSDegrease – With MEK as above, or with a strong boiling solution of a good grade household detergent.Etch – For optimum results, degreasing can be followed by the chromic acid bath outlined above.WOODSand – Bonding surfaces should be sanded lightly, but thoroughly to remove all external contamination.Clean – Carefully remove all dust, or particles of wood from sanded areas. A stiff and clean brush or compressed air can be used.PLASTICClean – Remove all dirt, oil, or other surfaces contaminated with detergent soap or degreasing solvent and water, followed by thorough rinsing and drying. A solvent that does not have a detrimental effect may also be used.Sand – Surfaces to be bonded should be sanded lightly, but thoroughly to remove surface sheen.Clean – Carefully remove all dust or particles of plastic from the sanded area. A clean brush, lint-free cloth, or compressed air may be used. Mixing And Application Precaution: As with industrial chemicals of the same nature, avoid direct skin contact using protective gloves and eyewear. Ensure the work area is well ventilated and extinguish any flame source to prevent fuel vapors accidental ignition vapor fuels.Click On The Image To View The Video DemonstrationHow To Mix Epoxy Resin For Food Contact Coating. Avoid Tacky Spots, Minimize Air Bubble When Mixing - YouTubeVideo will open in a new windowUsing the eBay App? Paste link into a browser window:MAX GRE A/B is mixed 2:1 by weight or by volume and offers a 35 to 45 minute working time. Use a scale to measure the proper mix ratio accurately, which dramatically affects cured chemical resistance, especially when mixing small batch sizes. The mixed consistency is similar to cooking oil. MAX GRE is self-leveling and will continue to flow until the MAX GRE resin gels or converts to a solid. Coatings: Apply The MAX GRE Using A Brush Or Roller Coat.The ideal coating thickness to create a hermetic barrier is 0.015-inch or 15 mils and may require several applications to achieve the target coating thickness. Allow the first coat to cure for 5 to 6 hours at 75°F and repeat the application directly on top of the previous application. Once the desired thickness is achieved, allow the MAX GRE to fully cure 36 to 48 hours at 25°C to 30°C before use. To use the MAX GRE as an adhesive, prepare the substrates to its bare condition so the MAX GRE is directly applied and in full contact with the base substrate. Ensure bond foot-print is relative to the amount of force that is expected. Mix the proper amount of the resin and curing agent for the application. Bondline control media such as ‘Potter’s Glass Bead’ is typically mixed with the MAX GRE to meter the ideal bondline thickness of 5 to 7 mils. Apply the mixed MAX GRE on both substrates to be bonded and assemble. Apply sufficient clamping force to ensure both substrates are mated until the MAX GRE cures. Allow to cure for 12 to 18 hours at room temperature for the the MAX GRE to be tack-free and handleable. Allow the MAX GRE to fully cure for 36 to 48 hours at 25°C to 30°C before use with fuels. Potting Compound: MAX GRE A/B Is Self Leveling And Suitable For Thick Potting Or Casting Application MAX GRE also works well as a potting compound for encapsulating fuel level sensors. It is suitable up to a ¾-inch thick casting or embedding. Upon cure, MAX GRE is non-conductive and provides electrical insulation for low voltage signals for gauges and meters. MAX GRE bonds well to copper wires and holds connections in place. It is resistant to pull-outs from expansion and contraction coefficients and mechanical vibration from average use and environment. Impregnating Resin For Fiberglass Or Carbon Fiber As an impregnating resin for composite fabrication, use silane or volan treated fabrics for the best epoxy resin compatibility and wet-out. Saturate the fabric with the mixed MAX GRE at 33 percent resin content. Allow to fully cure for 48 hours at 25°C to 30°C before use. Observe composite fabricating guidelines for making fuel cells. Review COMPOSITE FABRICATING BASICS Below For More Details MAX GRE Chemical Resistance Test Cured MAX GRE Specimens in E85 Gasoline Continuous Immersion Test Specimens have been in complete immersion in E85 gasoline and diesel E85 fuel since 06/15/2009 with no change in is cured properties. The stability in weight or hardness (Shore Durometer) of the MAX GRE demonstrates its superior chemical resistance to modern fuels. No Change In Weight Or Durometer Hardness Demonstrating Its Chemical Resistance Properties.Hardness Test After Continuous Immersion In Fuel Testing the Shore Durometer Hardness of the specimens determines if the cures resin is being affected by the gasoline immersion. The weights and Durometer Hardness of the specimens were measure before and after the immersion test and any changes in are recorded. After several years of continuous gasoline immersion, the MAX GRE test specimens exhibits no change in weight or hardness. Poor chemicals resistance will bloat the specimens, increasing in mass and reduce in Shore Durometer Hardness. MAX GRE A/B has proven its excellent resistance against various petroleum fuels.Testing For Weight Change, Durometer Hardness After Continuous Gasoline Immersion. Negligible Change In Weight (Less Than 0.03%) Measured, Demonstrating Excellent Gasoline And Diesel (E85 Grade) Resistance. June 2009Start DateMarch 2014No appreciable change in dimension, weight, Durometer HardnessFebruary 2017No appreciable change in dimension, weight, Durometer HardnessNovember 2019No appreciable change in dimension, weight, Durometer HardnessNovember 2020No appreciable change in dimension, weight, Durometer Hardness Customer Refurbish And Repaired Gasoline Tank With MAX GRE A/BSurface Preparation, Fiberglass Patch Rust-Through Cavity Repair And Integral Sealing of Metal Tank Compliments Of Jeff @ElderyIron Click On The Image To View The Video Demonstration Repairing a Gas Tank with Gasoline Resistant Epoxy 1981 Dodge Colt - YouTubeVideo will open in a new windowUsing the eBay App? Paste link into a browser window:Click On The Image To View The Video DemonstrationPrepping the Obsolete 1981 Dodge Colt Gas Tank For Repair - YouTubeVideo will open in a new window Coverage Calculation 48 Ounce Kit Coverage At 0.030 Inch Coating Thickness = 20 Square Feet 48 Ounce Kit Coverage With 10 Ounce Per Square Yard Fiberglass Cloth With 70/30 Fabric To Resin Ratio By Weight = 6.5 Square Yards Of 10 Ounce Fiberglass Per This 48 Fluid Ounce Kit. Best Style Fabric For Patching; 7781 Style 8 Harness Satin Weave Use this satin weave style fiberglass fabric that offers excellent draping over curved and corners.This weave style is also much tighter and has less opening between the fiberglass yarn.Once impregnated with the MAX GRE resin, the laminate is impermeable and provides better hermetic sealing. Free Shipping! https://www.ebay.com/itm/223385247088 During the colder season, use and infrared lamp to increase the ambient temperature to minimize slow cure due to the colder temperatures. IR Lamps works best for warming large areas. Best Style Fabric For Patching And Fabricating Fuel Tanks Weave Style 7781 8 Harness Satin Weave https://www.ebay.com/itm/223669319695 MAX GRE With Carbon FIber Carbon Fiber Motorcycle Gas Tank Fabricated With MAX GRE A/B COMPOSITE FABRICATING BASIC GUIDELINES By definition, a fabricated COMPOSITE material is a manufactured collection of two or more products intentionally combined to form a new homogeneous material that is uniquely greater than the sum of its individual parts. This method is also defined as a SYNERGISTIC COMPOSITION. COMPOSITE MATERIAL COMPOSITIONREINFORCING FABRIC & IMPREGNATING RESIN PLUS 'ENGINEERED PROCESS'EQUALSCOMPOSITE LAMINATE WITH THE BEST WEIGHT TO STRENGTH PERFORMANCE With respect to the raw materials selection -fabric and resin, the fabricating process and the and curing and test validation of composite part, these aspects must be carefully considered and in the engineering phase of the composite. Step One: Fabric SelectionTYPES OF FABRIC WEAVE STYLE AND SURFACE FINISHING FOR RESIN TYPE COMPATIBILITY Fabrics are generally considered ”balanced” if the breaking strength is within 15% warp to fill and are best in bias applications on lightweight structures. “Unbalanced” fabrics are excellent when a greater load is required one direction and a lesser load in the perpendicular direction. Weaves: Plain weave means the warp and fill threads cross alternately. This is the most common weave. 4 Harness (4 HS Satin or crowfoot) weave means the fill thread floats over three warp threads, then under one warp thread.This weave is more pliable than the plain weave, therefore conforms to complex curves more easily. 8 Harness (8 HS Satin) weave means the fill thread floats over seven warp threads, then under one warp thread. his weave is the most pliable fiberglass weaves. 2 x 2 Twill weave means the fill thread floats over two warp threads, then fewer than two warp threads. This weave is found most commonly in carbon fabrics and is more pliable than plain weave. Most fabrics are stronger in the warp than the fill because higher tension is placed on the warp fiber keeping it straighter during the weaving process. Rare exceptions occur when a larger, therefore stronger thread is used in the fill direction than the warp direction. PLAIN WEAVEIs 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. 8 HARNESS SATIN WEAVEThe 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. 4 HARNESS SATIN WEAVEThe 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. 2x2 TWILL WEAVETwill 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.SATIN WEAVE TYPE CONFORMITY UNTO CURVED SHAPES HOW TO SELECT THE BEST FIBERGLASS WEAVE FOR CURVED \u0026 CONTOURED SURFACE- 8 HARNESS SATIN WEAVEVideo will open in a new windowUsing the eBay App? Paste link into a browser window: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.7544 Fiberglass - YouTubeFIBERGLASS FINISHING FOR RESIN COMPATIBILITY Finishing Cross Reference And Resin Type Compatibility RESIN COMPATIBILITYBurlington IndustriesClarkSchwebelJ.P StevensUniglass IndustriesEpoxy, PolyesterVOLAN AVOLAN AVOLAN AVOLAN AEpoxy, PolyesterI-550CS-550S-550UM-550Phenolic, MelamineI-588A1100A1100A1100Epoxy, PolyimideI-589Z6040S-920UM-675EpoxyI-399CS-272AS-935UM-702Epoxy CS-307 UM-718Epoxy CS-344 UM-724Silicone112112 n-pH (neutral pH) AVAILABLE FIBERGLASS, CARBON FIBER, AND KEVLAR FABRICSStyle 120 1.5-OUNCE FIBERGLASS PLAIN WEAVE 5 YARDShttps://www.ebay.com/itm/222623985867Style 120 1.5-OUNCE FIBERGLASS PLAIN WEAVE 10 YARDShttps://www.ebay.com/itm/311946399588Style 7532 7-OUNCE FIBERGLASS PLAIN WEAVE 5 YARDShttps://www.ebay.com/itm/222624899999Style 7500 10 OUNCE FIBERGLASS PLAIN WEAVE 3 YARDShttps://www.ebay.com/itm/222624968104Style 7500 10 OUNCE FIBERGLASS PLAIN WEAVE 5 YARDShttps://www.ebay.com/itm/311946460378Style 3582 14 OUNCE FIBERGLASS SATIN WEAVE 5 YARDShttps://www.ebay.com/itm/312023587290Style 3582 14 OUNCE FIBERGLASS SATIN WEAVE 10 YARDShttps://www.ebay.com/itm/222753506374HEXCEL 1584 26 OUNCE FIBERGLASS SATIN WEAVE 3 YARDShttps://www.ebay.com/itm/311947365010HEXCEL 1584 26 OUNCE FIBERGLASS SATIN WEAVE 5 YARDShttps://www.ebay.com/itm/222629157570FIBERGLASS 45+/45- DOUBLE BIAS 3 YARDShttps://www.ebay.com/itm/311947299244 CARBON FIBER FABRIC 3K 2x2 TWILL WEAVE 6 OZ. 3 YARDShttps://www.ebay.com/itm/311947275431CARBON FIBER FABRIC 3K PLAIN WEAVE 6 OZ 3 YARDShttps://www.ebay.com/itm /311947292012 KEVLAR 49 HEXCEL 351 PLAIN WEAVE FABRIC 2.2 OZhttps://www.ebay.com/itm/222623951106 Step Two: Choose The Best Epoxy Resin System For The Application The epoxy resin used in fabricating a laminate will dictate how the FRP will perform when load or pressure is implied on the part.To choose the proper resin system, consider the following factors that is crucial to a laminate's performance.SIZE AND CONFIGURATION OF THE PART(NUMBER OF PLIES AND CONTOURED, FLAT OR PROFILED)CONSOLIDATING FORCE(FREE STANDING DRY OR HAND LAY-UP, VACUUM BAG OR PLATEN PRESS CURING)CURING CAPABILITIES(HEAT CURED OR ROOM TEMPERATURE CURED)LOAD PARAMETERS(SHEARING FORCE, TORSIONAL AND DIRECTIONAL LOAD, BEAM STRENGTH)ENVIRONMENTAL EXPOSUREThe principal role of the resin is to bind the fabric into a homogeneous rigid substrate(OPERATING TEMPERATURE, AMBIENT CONDITIONS, CHEMICAL EXPOSURE, CYCLIC FORCE LOADING)MATERIAL AND PRODUCTION COST(BUYING IN BULK WILL ALWAYS PROVIDE THE BEST OVERALL COSTS) These factors will dictate the design and the composition of the part and must be carefully considered during the design and engineering phase of the fabrication. TOP SELLING IMPREGNATING RESIN SYSTEM MAX BOND LOW VISCOSITY A/B Marine Grade Boat Building Resin System, Fiberglassing/Impregnating, Water Resistance, Cured Structural StrengthMAX BOND LOW VISCOSITY 32-Ounce kithttps://www.ebay.com/itm/311947109148MAX BOND LOW VISCOSITY 64-Ounce Kithttps://www.ebay.com/itm/311947125422MAX BOND LOW VISCOSITY 1-Gallon Kithttps://www.ebay.com/itm/311947117608MAX BOND LOW VISCOSITY 2-Gallon kithttps://www.ebay.com/itm/311946370391MAX BOND LOW VISCOSITY 10-Gallon Kithttps://www.ebay.com/itm/222624960548MAX 1618 A/B Crystal Clear, High Strength, Lowest Viscosity (Thin), Durability & Toughness, Excellent Wood Working ResinMAX 1618 A/B 48-Ounce Kithttps://www.ebay.com/itm/222627258390MAX 1618 A/B 3/4-Gallon Kithttps://www.ebay.com/itm/222625113128MAX 1618 A/B 3/4-Gallon Kithttps://www.ebay.com/itm/222627258390MAX 1618 A/B 1.5-Gallon Kithttps://www.ebay.com/itm/311946441558MAX CLR A/B Water Clear Transparency, Chemical Resistance, FDA Compliant For Food Contact, High Impact, Low ViscosityMAX CLR A/B 24-Ounce Kithttps://www.ebay.com/itm/222623963194MAX CLR A/B 48-Ounce Kithttps://www.ebay.com/itm/311947320101MAX CLR A/B 96-Ounce Kithttps://www.ebay.com/itm/222625329068MAX CLR A/B 96-Ounce Kithttps://www.ebay.com/itm/222625338230MAX CLR A/B 1.5-Gallon Kithttps://www.ebay.com/itm/222626972426MAX GRE A/B GASOLINE RESISTANT EPOXY RESIN Resistant To Gasoline/E85 Blend, Acids & Bases, Sealing, Coating, Impregnating ResinMAX GRE A/B 48-Ounce Kithttps://www.ebay.com/itm/311946473553MAX GRE A/B 96-Ounce Kithttps://www.ebay.com/itm/311947247402MAX HTE A/B HIGH-TEMPERATURE EPOXY Heat Cured Resin System For Temperature Resistant Bonding, Electronic Potting, Coating, BondingMAX HTE A/B 80-Ounce Kithttps://www.ebay.com/itm/222624247814MAX HTE A/B 40-Ounce Kithttps://www.ebay.com/itm/222624236832 Step Three: Proper Lay-Up Technique -Putting It All Together Pre-lay-up notesLay out the fabric and pre-cut to size and set asideAvoid distorting the weave pattern as much as possibleFor fiberglass molding, ensure the mold is clean and an adequate mold release is usedView our video presentation above "MAX EPOXY RESIN MIXING TECHNIQUE"Mix the resin only when all needed materials and implements needed are ready and within reachMix 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. When mechanical load or pressure is applied to the composite laminate, the physical strength of the fabric should bear the stress and not the resin. If the laminate is over saturated with the resin it will most likely to fracture or shatter instead of rebounding and resist damage. Don’t how much resin to use to go with the fiberglass?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. For general hand lay-ups, calculate using 60% fabric weight to 40% resin weight as a safety factor. This will ensure that the fabricated laminate will be below 40% resin content depending on the waste factor accrued during fabrication. Place the entire pre-cut fiberglass to be used on a digital scale to determine the fabric to resin weight ratio.Measuring by weight will ensure accurate composite fabrication and repeatability, rather than using OSY (ounce per square yard) data.THE USE OF A WEIGHING SCALE IS HIGHLY RECOMMENDED Purchase this scale with any of our product offering and the shipping cost of the scale is free. https://www.ebay.com/itm/222630300203A 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. For general hand lay-ups, calculate using 60% fabric weight to 40% resin weight as a safety factor. This will ensure that the fabricated laminate will be below 40% resin content depending on the waste factor accrued during fabrication.Place the entire pre-cut fiberglass to be used on a digital scale to determine the fabric to resin weight ratio. Measuring by weight will ensure accurate composite fabrication and repeatability, rather than using OSY data. 1 ounce per square yard is equal to 28.35 grams 1 square yard equals to 1296 square inches (36 inches x 36 inches)FOR EXAMPLE1 yard of 8-ounces per square yard (OSY) fabric weighs 226 grams 1 yard of 10-ounces per square yard (OSY) fabric weighs 283 grams Ounces per square yard or OSY is also known as aerial weight, which is the most common unit of measurement for composite fabrics. 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 neededMASTER EQUATION (fw/60%)x(40%)= RN FOR EXAMPLE 1 SQUARE YARD OF 8-OSY FIBERGLASS FABRIC WEIGHS 226 GRAMS (226 grams of dry fiberglass / 60%) X 40% = 150.66 grams of resin needed So for every square yard of 8-ounce fabric, it will need 150.66 grams of mixed resin. Computing For Resin And Curing Agent Amount 150.66 grams of resin needed MIX RATIO OF RESIN SYSTEM IS 2:1 OR 50 PHR (per hundred resin) 2 = 66.67% (2/3) + 1 = 33.33%(1/3) (2+1)=3 or (66.67%+33.33%)=100% or (2/3+1/3)= 3/3 150.66 x 66.67%= 100.45 grams of Part A RESIN 150.66 x 33.33%= 50.21 grams of Part B CURING AGENT 100.45 + 50.21 = 150.66 A/B MIXTUREGENERAL LAY-UP PROCEDURE Apply the mixed resin onto the surface and then lay the fabric and allow the resin to saturate through the fabric.NOT THE OTHER WAY AROUNDThis is one of the most common processing error that yields sub-standard laminates. By laying the fiberglass onto a layer of the prepared resin, fewer 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 pockets unhindered and uniformly disperse the impregnating resin throughout the fiberglass.HAND LAY-UP TECHNIQUE Eliminating air entrapment or void porosity in an epoxy/fiberglass lay-up processFiberglass Hand Lay Up For Canoe and Kayak Building- Cedar Strip Kayak Fiberglassing - YouTubeVideo will open in a new windowBasic Hand Lay-up FiberglassingVideo will open in a new windowVACUUM BAGGING PROCESS For performance critical application used in aerospace vehicles, composite framing for automotive vehicles and marine vessels,a process called 'Vacuum Bagging' is employed to ensure the complete consolidation of every layer of fabric. The entire lay-up is encased in an airtight envelope or bagging. A high-efficiency vacuum pump is used to draw out the air within the vacuum bag to create a negative atmospheric pressure.Once a full vacuum (29.9 Inches of Mercury) is achieved, the negative pressure applies a compacting force of 14.4 pounds per square inch. (maximum vacuum pressure at sea level) is applied to the vacuum bag transferring the force to the entire surface area of the laminate. Vacuum pressure is maintained until the resin cures to a solid. For room temperature curing resin system, the vacuum pump is left in operation for a minimum of 18 hours.External heat can be applied to the entire lay-up, thus accelerating the cure of the resin system. The vacuum force also removes any entrapped air bubble between the layers of fabric and eliminate what is called, porosity or air voids.Porosity within a laminate creates weak spots in the structure where mechanical failure originates when force or load is applied to the structure. The standard atmosphere (symbol: atm) is a unit of pressure defined as 101325 Pa (1.01325 bar), equivalent to 760 mm Mercury or 29.92 inches Mercury or14.696 pounds per square inch of pressure. FiberglaSs And Carbon Fiber Vacuum Bagging and Flat Panel Laminate - YouTubeVideo will open in a new window AUTOCLAVE CURING PROCESSAutoclave curing processing is the most common method used in large-scale production of composite products.The aerospace industry, which includes space exploration rockets and vehicles, satellites, and military airplane utilizes this composite fabrication process due to the critical nature of the application. The mechanical demands of the composite are often pushed to the upper limits and autoclaved process yields composites with the best weight to strength ratio.BASIC OPERATION OF THE AUTOCLAVE PROCESSIn the autoclave process, high pressure and heat are applied to the part through the autoclave atmosphere,with a vacuum bag used to apply additional pressure and protect the laminate from the autoclave gases. The cure cycle for a specific application is usually determined empirically and, as a result, several cure cycles may be developed for a single material system,to account for differences in laminate thickness or to optimize particular properties in the cured part.The typical autoclave cure cycle is a two-step process.First, vacuum and pressure are applied while the temperature is ramped up to an intermediate level and held there for a short period of time.The heat reduces the resin viscosity, allowing it to flow and making it easier for trapped air and volatiles to escape.The resin also begins wetting the fibers at this stage. In the second ramp up, the temperature is raised to the final cure temperature and held for a sufficient length of time to complete the cure reaction.During this step, the viscosity continues to drop, but preset temperature ramp rates and hold times then stabilize viscosity at a level that permits adequate consolidation and fiber wetting,while avoiding excessive flow and subsequent resin starvation. These control factors also slow the reaction rate, which prevents excessive heat generation from the exothermic polymerization process.Upon completion, the cured mechanical performance of the composite is often much stronger and lighter compared to a hand lay-up, or vacuum bagged composite laminate. VACUUM INFUSION PROCESSVacuum Infusion Process is also known in the composites industry as Vacuum Assisted Resin Transfer Molding or VARTM.Similar to the Vacuum Bagging Process where the negative pressure is used to apply consolidation force to the laminate while the resin cures, the resin is infused into the fabric lay-up by sucking the impregnating resin and thus forming the composite laminate.The VARTM Process produces parts that require less secondary steps, such as trimming, polishing or grinding with excellent mechanical properties. However, the vacuum infusion requires more additional or supplemental related equipment and expendable materials. So the pros and cons of each presented composite fabrication process should be carefully determined to suit the user's capabilities and needs. Please view the following video demonstration which explains the process of Vacuum Infusion or VARTM process.MAX 1618 A/B VACUUM ASSISTED RESIN TRANSFER MOLDING PROCESSCARBON FIBER VACUUM INFUSION WITH EPOXY RESIN - VACUUM BAGGING WITH MAX 1618 EPOXY RESIN - YouTubeVideo will open in a new windowStep Four: Proper CuringMAX EPOXY RESIN SYSTEM product line is resistant to amine-blush, however,it is recommended not to mix any resin systems in high humidity conditions, greater than 60%.Always make sure that the substrate or material the epoxy resin system is being applied to is well prepared as possible to ensure the best-cured performance. Always review the published data and information for proper usage, application, and general safety information. Our expert staff of engineers is always available for consultation and assistance. Allow the lay-up to cure for a minimum of 24 to 36 hours before handling.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°C - 27°C 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 sources of radiant heat (220°F to 250°F) for 45 minute to an hour.You can also expose it to direct sunlight but place a dark colored cover, such as a plastic tarp or cardboard to protect it from ultraviolet exposure.In general room temperature cured epoxy resin has a maximum operating temperature of 160°F or lower.A short heat post cure will ensure that the mixed epoxy system is fully cured, especially for room temperature cure system that can take up to 7 days to achieve 100% cureSome darkening or yellowing of the epoxy resin may occur if overexposed to high temperature (>250°F). AMINE BLUSHThe 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. OTHER TYPES OF EPOXY RESIN CURE MECHANISMLATENT CURING SYSTEMSLatent 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 conditionssuch as high mechanical performance under heat and cryogenic 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 a 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. HEAT ACTIVATED CURING SYSTEMSThis type of epoxy system will not polymerize unless it is exposed to the activation temperature of the curing agent which can be as low as 200°F and as high as 400°F. In most instances, our MAX EPOXY SYSTEMS epoxy system can be stored at room temperature and remain liquid for up to six months and longer. TESTING THE COMPOSITEDETERMINATION OF THE FABRIC-RESIN RATIO TESTING FABRIC TO RESIN RATIO VIA RESIN BURN OUT - YouTubeVideo will open in a new windowULTIMATE COMPRESSIVE STRENGTH ULTIMATE COMPRESSIVE STRENGTH TEST OF FIBERGLASS LAMINATE TOOLING BOARD. - YouTubeVideo will open in a new window6500 Pounds To Failure Mechanical Load Divided By 0.498 Square Inch = 13,052 psi Maximum Compressive Strength. Determination Of the Fabric To Resin (FTR) Ratio The specimen test was weighed and burned to obtain the fiberglass weight. The difference in weight before and after the resin burnout can be used to calculate FTR ratio.SPECIMEN EXAMINATION AFTER COMPRESSION TEST - YouTubeVideo will open in a new window************************************************************DON'T FORGET OUR EPOXY MIXING KITClick The Link To Add To Order https://www.ebay.com/itm/222623932456EVERYTHING YOU NEED TO MEASURE, MIX, DISPENSE OR APPLY 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 1 Each Digital Scale -Durable, Accurate Up To 2000.0 Grams 4 Each 32-ounce (1 Quart) Clear HDPE Plastic Mix Cups4 Each 16-ounce (1 Pint) Clear HDPE Plastic Mix CupsOne Size Fits All Powder-Free Latex Gloves 2 Each Graduated SyringesWooden Stir SticksAssorted Size Foam Brush IMPORTANT NOTICEYour 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 the 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 obtained through published information, PolymerProducts and Polymer Composites Inc. laboratories using materials under controlled conditions. Data of this type should not be used for a specification for fabrication and design. It is the user's responsibility to determine this Composites fitness for use. There is no warranty of merchantability for 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. Polymer Composites Inc. 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 there is any infringement of patents is the sole liability of the user.
Price: 44.17 USD
Location: Ontario, California
End Time: 2024-08-25T19:11:57.000Z
Shipping Cost: 0.72 USD
Product Images
Item Specifics
Restocking Fee: No
Return shipping will be paid by: Buyer
All returns accepted: Returns Accepted
Item must be returned within: 30 Days
Refund will be given as: Money Back
Expiration Date: Does Not Expire
Industry+Type: Fuel Tank Restoration Fabrication & Repairs
Anti Corrosion Coating: Aluminum And Steel Tanks
MPN: 4913263162599
Resistant To E85 Gasoline And Diesel Fue: Use As A Coating Sealer, Adhesive, Void Fill
Modified Item: No
Bonds To Aluminum & Steal Tanks: Hermetic Sealer, Barrier Coating
California Prop 65 Warning: IMPORTANT HANDLING INFORMATION POSTED ON THE DESCRIPTION PAGE This product contains less than 0.1% (trace amounts) of a chemical known to the State of California to cause cancer.
Brand: MAX GRE A/B GASOLINE RESISTANT EPOXY
View The Description Page Below: Use & Application Instruction & Repair Video Demon
Model: MAX GRE A/B 48 OUNCE KIT
Potting Compound For Sealing Fuel Sender: Will Not Conduct Electricity
Country/Region of Manufacture: United States
Impregnating Resin: For Fiberglass And Carbon Fiber Fabrics
