EPOXY RESIN PERMANENT GLUE 4 METALS WOOD FIBERGLASS PLASTIC TILE CONCRETE STONE

Description

MAX BOND MEDIUM VISCOSITY A/B
32 Ounce Kit
16 ounce PART A -RESIN
16 ounce PART B -CURING AGEN
T
EPOXY SYSTEM FOR STRUCTURAL BONDING APPLICATIONS
1:1 Mix Ratio
90 Minute Working Time
This resin system is epoxy/polyamide-based.
The resin/curing agent combination is extensively tested and used epoxy adhesive
in industrial manufacturing and assembly.
The consistency or viscosity of the mixed resin is similar to honey or molasses.
DESCRIPTION
MAX BOND Medium Viscosity A/B is a two-part, epoxy-based resin system specially formulated to yield structural bond strength to metals, plastics, wood, concrete, tile, and composite substrates (Carbon Fiber, Fiberglass, Kevlar, Quartz, Basalt FRP).
It is mixed 1:1 by weight or by volume and offers up to 60 minutes of working time (200-gram mass). The mixture is applied by brush, roll coater, trowel, or injected into place. For meter-mix dispensing, use an 18 element static mixer to achieve a homogeneous consistency. MAX BOND Medium Viscosity A/B cures at room temperature or heat cured for faster processing. It cures clear (slight amber color) when used as a laminating adhesive for transparent substrates such as glass and plastic films.
MAX BOND Medium Viscosity A/B is an excellent adhesive for marine applications such as boat building and repairs, architectural construction, aerospace composites, and non-conductive adhesive for the electronics industry. Upon cure, MAX BOND Medium Viscosity A/B demonstrates excellent impact resistance, minimal loss of adhesion from continuous water immersion, cyclic vibrations, and seasonal temperature changes from -40°C to 90°C.
MAX BOND Medium Viscosity A/B demonstrates structural bond strengths to a variety of substrates commonly used in composites industry such as steel, aluminum, soft metals, fiberglass, concrete, ceramic and most plastics. MAX BOND Medium Viscosity A/B performs well in wide range of service temperature and resists cracking and delamination due to cyclic vibration, thermal expansion, and contraction. It is an undiluted epoxy resin formulation that yields high mechanical performance and compliance to military specifications listed below.
MAX BOND A/B Conforms To Hundreds of Aerospace /Military/Naval Materials Specifications
MIL-A-8623 T1
MS-511
MMM-A-134 Type1 and Type 2
OS-9923A
Boeing BMS-5-29
NASA Requirements For Low Outgassing Properties -ASTM E 595
Less Than 1% TML And CVCM
Brush, Roller Coat, Trowel Applied
Bonds Steel, Aluminum, Soft Metals, Concrete, Ceramic, Fiberglass, Composites
Excellent Impact Resistance
Excellent Balance of Strength and Flexibility
Excellent Water/Salt Water Resistant For Marine/Aerospace Applications
Low Shrinkage For Excellent Dimensional Stability
Wide range of service temperature
THIS KIT IS PACKAGED WITH YORKER CAPS FOR CONTROLLED DISPENSING.
Use these Yorker caps to dispense the material with ease and minimize over pouring and reduce spills. We do not recommend using
dispensing pumps. The curing agent or part B of any epoxy resin system is sensitive to moisture and carbon dioxide, which will react with the curing agent and form carbamate crystals (salt-like crystals that form on the tip of the pump) and reduce reactivity.
Carbamate crystals that form on the pump when the curing agent is exposed to ambient moisture and carbon dioxide.
These crystals are insoluble in epoxy resin resulting in contamination and causes poor cure and amine-blushing.
RESIN CRYSTALLIZATION FROM PROLONGED STORAGE OR COLD WEATHER EXPOSURE
The resin component or the PART A may crystallize due to cold temperature exposure.
Please inspect the resin component for any solidified crystals which will appear as waxy solid or cloudiness on the bottom of the PART A bottle.
An information postcard is included with each package.
View the following video for identification and processing.
DO NOT USE UNLESS PROCESSED TO REVERT ANY CRYSTALLIZED RESIN BACK TO A LIQUID STATE AND AVOID POOR CURED RESULTS.
PHYSICAL AND MECHANICAL PROPERTIES
Density (Mixed)
1.10 g/cc
Form and Color Cured
Translucent Straw Color
Shelf Life
12 Months
Viscosity Mixed
15,540 cPs @
77°F
(25°C)
Mix Ratio
Equal parts by weight or by volume
Working Time
90 Minutes @
77°F
Peak Exotherm
180 °F
to
190°F
200 gram
mass
Cure Time
36 Hrs. Minimum
Accelerated Cure Schedule
2 Hrs. @
212°F
(
100°C
)
Hardness
85 to 90 Shore D
Tee-Peel Strength
6.3 Pounds
Per Inch Width
Compressive Strength
15,800 psi @
77°F
(25°C)
Tensile Shear Strength
4,100 psi @
77°F
(25°C)
2,200 psi @
-112°F
(-80
°C
)
1450 psi @
212°F
(100°C)
Elongation
2.3% Maximum Yield
Tensile Strength
8500 psi (Ultimate @ break)
CHEMICAL RESISTANCE TEST
10 Day Soak Test @
77°F
(
25°C
) 3% Salt Water
Sulfuric Acid 30%
Nitric Acid
Ammonia 10%
Sodium Hydroxide
Anti-Freeze
Motor Oil Soak
Skydrol
WEIGHT CHANGE %
1.23
1.9
3.8
3.7
10.00
No Effect
No Effect
No Effect
No Effect
No Effect
ELECTRICAL PROPERTIES
Volume Resistivity
2.7 x 1012 Ohms-cm (Ω-cm)
Dielectric Strength
510 Volts/Mil @ 60 Hz.
Dielectric Constant
3.23 @ 60 Hz
SERVICE TEMPERATURE
- 40 ⁰C to 90°C
MIXING EPOXY RESINS
Please View The Following Video For The Proper Mixing Of Epoxy Resins.
It Demonstrates The Proper Technique Of Mixing Any Type Of Epoxy Resin System.
Evidence Of Poor Mixing
Tacky Cure Due To Poor Mixing
Video will open in a new window
[isdntekvideo]
The proper cure and final performance of any epoxy resin system are highly dependent on the quality and thoroughness of the mixing quality. The resin and curing agent must be mixed to homogeneous consistency to achieve a proper cure and tack-free results.
Proper Mixing Technique Mixing
How To Mix Epoxy Resin For Food Contact Coating. Avoid Tacky Spots, Minimize Air Bubble When Mixing - YouTube
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Coverage Yield Per Gallon
Use these theoretical factors to determine coverage as a guide for resin usage.
Determine the length x width x thickness in inches to obtain the cubic volume inch of the mixed resin needed.
Use the following equation:
1 gallon of resin can cover 1608 square feet Per 1 mil or 0.001-inch coating thickness on a smooth and none absorbent substrate
(a pane of glass for example).
Calculation
(length x width x coating thickness)/ 231 cubic inches per gallon = cubic-inches of coating need
For Example
50 inches x 36 inches x 0.010 (10 mils) = 18 cubic inches
18/231= .0779 gallon of mixed resin needed to cover the surface area
Use these factors to convert gallon needed into volumetric or weight
Measurements use the following factors by the gallon needed:
FOR EXAMPLE:
231 X .0779 = 17.99 CUBIC INCHES Or 4195 GRAMS X .0779 = 326.79 GRAMS
Surface Preparation
METALS
Degrease – Wipe laying surfaces with Methyl Ethyl Ketone (MEK) or acetone to remove all oil, dirt, and grease.
Etch – For optimum results, metal parts should be immersed in a chromic acid bath solution consisting of:
Sodium dichromate – 4 parts by weight
Sulfuric acid – 10 parts by weight
Water – 30 parts by weight
The solution should be held at a temperature of 160°F (71°C), and the parts left immersed for 5 to 7 minutes.
Rinse – remove metal parts from etching bath and rinse in clean cold water (de-ionized water is recommended). If thoroughly clean, metal surfaces so treated will hold a thin film of water.
Dry – To accelerate drying, items to be bonded can be placed in an air-circulating oven.
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.
GLASS
Degrease – 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.
WOOD
Sand – 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.
PLASTIC
(see Flame Treating below)
Clean – 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.
The quality of adhesion of any coating or adhesive application is dependent on how well the surface is prepared.
The resin system must be able to properly 'wet-out' the surface to form a continuous film.
A surface demonstrating poor wettability prevents the liquid resin from forming a cohesive bond. Improper surface wetting yields poor adhesion and will delaminate during use.
Wetting is the ability of a liquid to interfaces or wet-out a solid surface; its dynamics is expressed as surface tension.
A surface that demonstrates low surface tension, such as waxed surface, oily surface or slick plastics like Teflon will prevent the liquid resin to wet-out and cause poor adhesion.
Testing For Surface To Yield Structural Bond Adhesion
Testing And Preparing Surface Before Applying Epoxy Coating Or Adhesive. - YouTube
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Flame Treating Of Plastic To Improve Adhesion.
Obtaining adequate bond strength when bonding plastic-to-plastic substrates or plastic to dissimilar substrates is often a challenge for epoxy bonding.
In general plastic surfaces demonstrates poor ‘wettability’ or the ability of a liquid to form a continuous film, must be treated before application.
These types of substrates or are called LSE or Low Surface Energy substrates.
In general, most thermoplastic surfaces fall into this category. Teflon or its generic name PTFE and other polyethylene derivatives such as HDPE, LDPE, UHMW and olefinic-based plastics demonstrate poor liquid wettability due to its low surface energy. To create a viable bondable surface condition for these types of plastics, it must be surface treated by creating a superficial oxidized surface to increase its dynamic surface tension. Various types of physical treatment can be used to increase the surface energy of plastics, mostly through oxidation of the superficial layer.
Flame treatment is the most widely used and cost-effective pre-treatment for polyethylene (HDPE, LDPE, UHMW) and polyolefin-based plastics prior to polymer bonding or printing. The resulting change of the surface by creating an oxidized layer onto the substrate greatly improves the ability of liquids wet-out the surface thus creating a strong adhesive bond between the surface and the coating.
A Flame Treating process consists of exposing the surface to a suitable oxidizing flame for a period in the range 0.2 to 3.0 seconds. This treatment brings about a change to the polymer surface that increases its surface energy allowing fluids to effectively wet-out the surface and permits a strong adhesive molecular and mechanical bond.
Flame Treating Using A Commercially Available Propane Torch
Adjust the propane torch so that a low oxygen burning flame is achieved and pass over the area to be treated several times until a slight haze is noticed on the surface of the substrate.
A Dyne pen is used to view the improve surface wetting of the untreated and flame treated UHMW plastic.
Flame Treating the plastic substrate will make adhesion possible and create a strong bond.
Flame Treated
Surface
Ideal
For Bonding
Load Testing For Tensile Shear Strength of the  Adhesion
Types of mechanical load and stress points
Joint and Bonding And Design Suggestions
To Make This Resin System To An Opaque Color Add 3% To 5% Of Our Max Epoxy Pigment Paste.
MAX COLOR KIT
https://www.ebay.com/itm/
311946633043
Adding Color With MAX Color Pigment Concentrates
DON'T FORGET OUR EPOXY MIXING KIT
Click The Link To Add To Order
https://www.ebay.com/itm/222623932456
EVERYTHING 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.
T
he 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 Cups
4 Each 16-ounce (1 Pint) Clear HDPE Plastic Mix Cups
5 Pairs One Size Fits All Powder-Free Latex Gloves
2 Each Graduated Syringes
Wooden Stir Sticks
Foam Brush
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 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.
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 there is any infringement of patents is the sole liability of the user.