What is a Polymer Coating?
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A polymer coating is a thin layered coating or paint made with polymers that provide superior adherence and protection from corrosion. A polymer is a molecule made by joining together many small molecules called monomers that are made up of a large number of similar units. This can include synthetic organic materials like resins and plastics.
As a leading coatings solution provider, our commitment encourages us to stay on top of the latest advancements in the coating industry. This article gives a brief history of where it all began, industry growth, and the advantages of optimal performance when using the right polymer coating.
Chapter 1
Brief History of Polymer Technology in the Coating Industry
image credit: chemical structure of Epoxy prepolymer, Wikipedia (cc-by-sa-2.5)
When looking at the history of polymer coatings, we can reflect on the workings of Herman Mark, who established the Polymer Research Institute in , which became the center for polymer research in the United States. Or, we could start in when a German chemist, Hermann Staudinger, won the Nobel Prize for Chemistry for demonstrating that polymers are long-chain molecules (giant molecules).
Staudinger's work laid the foundation for the expansion of the plastics industry. The chemical composition and structure of these giant molecules made them suitable for industrial applications.
The door opened for polymers when Aerospace composite requirements needed high strength, lightweight, corrosion resistance, and cost-effective materials. Different polymers were considered to meet these performance requirements. A few polymers that were studied include:
Phenolics - extremely brittle, lack of toughness, high solvent content and difficult to apply (requires three heat cures during application)
Polyester - low physical properties, poor bonding
Vinyl Ester - high styrene content (not good to breath) - extremely flammable and toxic during application and cure, sensitive to atmospheric moisture and temperature, short shelf life (3 months), high cure shrinkage - leading to being very brittle, one-third the strength of epoxy resins, poor bonding
Epoxies - high strength, high bond, low surface energy, chemical resistance
Epoxy polymers, a class of thermosetting polymers, became the best choice. They are stable, tough, and resistant to corrosive chemicals. Epoxies are high performing adhesives and useful industrial surface coatings.
Most surface coatings are based on synthetic polymers, industrially produced, and form tough, durable films when applied to surfaces.
Chapter 2
What is a Polymer Coating, Industry News and Growth
A polymer coating is a coating or paint made with polymers that provide superior adherence and protection from corrosion, according to Corrosionpedia. To fully understand a polymer coating, one needs to comprehend the actions of a polymer. Looking at the definition of a polymer noted by Wikipedia, a polymer is a molecule made from joining together many small molecules called monomers.
This type of chemical reaction (bonding together into a larger molecule) creates the functional behavior of the coatings. At APC, our chemical coatings are high-performance specialty coatings that can resist corrosive acids, alkalis, and solvents at various temperatures.
Industrial Coatings Industry News
"Global demand for industrial coatings is projected to touch $105.5 billion by , growing by a rate compounded annually at 6.1% between and ". [source]
Over the last ten years, research has brought us closer to functional coatings that are easy to use, self-cleaning, antibacterial, or consist of antifouling properties. One of polymer coating's most substantial advantages is it has little or no impact on other properties when being used. For example, when coatings are applied for protection purposes to transport and store chemicals, safety and mechanical strength are not compromised.
Coatings are resistant and durable. Because they are primarily used for protection against the elements (e.g., water, corrosion, environment), they must meet high-performance requirements.
Chapter 3
Use of Polymer and a Polymer Coating
Polymers have unique properties that can be fitted for different uses. Polymers can be man-made (synthetic) and/or natural (e.g., rubber, shellac, cellulose). Depending on their desired use, they can be used for scratch and abrasion resistance, elasticity, or brittleness.
Polymer coatings are everywhere. They are used in your home for protecting tables and furniture and for cars, hospitals, and healthcare environments, to name a few.
Machine Design shared an example of a polymer strong enough to withstand repeated sterilization cycles and also be machined easily. "The polymer&#;s thermal and dimensional stability, together with its resistance to chemicals and non-absorption of water, make it a good choice for parts that will require repeated disinfections and steam sterilization."
As a leader in industrial coating, our polymers are fine-tuned to influence protective properties.
Use of a polymer coating depends on:
- operating temperature
- wear and tear of environment
- type of corrosion
Quality surface preparation and application methods play a central role between the coating and substrate and offer resistance to the elements.
Chapter 4
Polymer Coating Advantages for Optimal Performance (
Real-life Example)
A chemical coating is a covering applied to the surface of an object, also known as the substrate. For example, coatings such as polymer paints and lacquers perform a two-fold function: to protect the substrate and as decoration.
Functional coatings change the surface properties of the layer underneath. It can be applied for adhesion, wettability, corrosion resistance, and wear resistance.
1. Adhesion - binds together dissimilar surfaces
2. Wettability - is the ability of a liquid to maintain contact with a solid surface
3. Corrosion resistance - some metals are more resistant to corrosion (the conversion of refined metal to a chemically-stable form), than others. You can protect metals from oxidation (corrosion) by applying polymer paints or coatings.
4. Wear resistance - wear rate varies depending on its stage (early, middle, or old). The fundamental cause of wear resistance is chemical reactions between the worn material and the corroding medium. [source: Stachwaik, Gwidon W.; Batchelor, Andrew W. (). Engineering tribology (3rd ed.). Elsevier Inc]
Advanced Coatings for Optimal Performance (Real-world Example)
Hutchison Ports TNG, provides comprehensive solutions for ship repair services in the Gulf of Mexico. One of their specialized repair works includes cleaning and painting of hulls, decks, tanks, cargo holds, vessels interiors, and chains.
Watch the video below as they apply advanced coatings for a greater ship performance.
Their project applications include:
- glass fiber reinforced coatings - to protect against cavitation and corrosion
- antifouling coatings - to optimize the efficiency of the boat's fuel consumption
- chemically resistant polymer coatings - for the storage of chemical products
These coatings improve operational efficiency, reduce port time, and increase bottom line profits.
Chapter 5
Safety Procedures For Handling a Polymer Coating
The application of a polymer coating to various surfaces requires specific procedures. It's crucial to protect yourself or employees who are applying coatings with these step-by-step guidelines:
Step 1: Use experienced people in the application of industrial coatings
Step 2: Ensure proper ventilation of the workplaces
Step 3: Apply skin lotion (barrier cream) containing lanolin to hands, arms, and face prior to working with coating
Step 4: Furnish proper safety equipment and clothing for each worker when using these products
Step 5: Wear protective clothing
When mixing, prepping, or repairing: wear rubber gloves, protective overalls, chemical goggles, and gas/vapor purifying respirators.
When spraying: wear rubber gloves, protective overalls, plastic boots, protective hood, and full face positive air pressure mask. Tape closed all openings.
Step 6: Use soap and water only to clean any coating off
Step 7: Reapply skin lotion after washing
Step 8: Use cortisone cream if any reddening of your skin occurs
Conclusion
Polymer coatings and technology is growing exponentially. Chemical coatings are utilized for a variety of purposes and performance requirements.
At APC, we understand the challenges you face every day and we continue to develop and improve our coatings and technologies.
HumenChem contains other products and information you need, so please check it out.
As a quality, premier coatings solutions provider, we provide innovative, value-added coatings for the protection of your assets.
In an industrial coating, resins act as the binder or film-forming agent. Resins hold the other components together and provide the film&#;s structural integrity. Their role is to provide a protective layer on the substrate, help the coating adhere to various surfaces, and resist various environmental factors, like moisture, UV light and chemicals. Resins can be derived from natural/organic sources or synthesized chemically.
Comparing Advantages and Disadvantages of Resin Classifications
When comparing resins used in industrial coatings, it's essential to consider the properties they impart to the coating, their performance in different environments, and their suitability for specific applications. Here are some common resins used in industrial coatings and how they compare:
Alkyd Resins
Properties: Alkyd resins are derived from plant oils or synthetic oils and offer good adhesion and flexibility. They are commonly used in oil-based paints.
Applications: Used in both industrial and architectural coatings.
Advantages: Good flexibility and adhesion, typically less expensive.
Disadvantages: Slower drying times, less resistance to moisture and chemicals compared to epoxies and polyurethanes.
Acrylic Resins
Applications: Used in decorative coatings, clear finishes, and in situations where color stability and aesthetic appeal are crucial.[SM1] As environmental restrictions increase, acrylics are being used more commonly in industrial applications.
Advantages: Excellent UV stability, good color retention, and clarity.
Disadvantages: Less chemical resistance and mechanical durability than epoxies and polyurethanes.
Epoxy Resins
Applications: Commonly used in industrial flooring, protective coatings for metal, and on equipment that requires corrosion-resistance. Epoxies provide a tough, durable coating that can withstand harsh conditions.
Advantages: High durability, good chemical resistance, mechanical strength, and strong adhesion.
Disadvantages: Limited UV resistance (can yellow or degrade over time), longer curing times, and can be brittle if not formulated properly.
Polyurethane Resins
Applications: Often used in automotive and truck body coatings, high-traffic areas, and outdoor applications where UV stability is important.
Advantages: Excellent flexibility, impact resistance, UV resistance, abrasion resistance, and corrosion resistance (when used with the correct primer). For example, Sheboygan Paint Company&#;s Uraguard® polyurethane topcoat system, when used with our solvent-based epoxy primer, resists corrosion for more than 5,000 hours!
Disadvantages: Can be more expensive, and some formulations may have lower chemical resistance compared to epoxies.
Polyesters
Applications: Widely used in a variety of applications, common uses include outdoor products, marine equipment, furniture, and windows/doors.
Advantages: Durability, weather resistance, chemical resistance, aesthetic flexibility with a wide range of finishes, ease of application, and cost effectiveness.
Disadvantages: Susceptibility to scratching, sensitivity to extreme temperatures, limited flexibility, maintenance requirements over time.
Melamines
Applications: Popular choice for a variety of applications, including furniture, cabinetry, and countertops.
Advantages: Durability, ease of maintenance, aesthetic versatility, cost effectiveness, consistent quality.
Disadvantages: Potential compromised edge wear (prone to chipping or peeling), difficult to repair, limited customization, lack of heat-resistance.
Fast-drying Thermoplastics
Applications: Used in various applications when high throughput and efficiency are top priority.
Advantages: Quick application, rapid curing, quicker processing times allowing for enhanced productivity, reduced handling time, improved efficiency, consistency, durability, easy to repair.
Disadvantages: Limited temperature resistance, potential for poor adhesion, chemical sensitivity, prone to surface imperfections, limited depth of coating, overcoating challenges.
Lacquer wood coating (incl. nitrocellulose lacquer)
Applications: Popular choice for protecting indoor wood products and for woodworking projects.
Advantages: High gloss, smooth finish, fast drying time, wide range of finishes, highly customizable, easy to apply, easy to repair, durability and resistance. Nitrocellulose lacquer, in particular, provides a durable finish that is resistant to scratches and stains. It also has good resistance to water and chemicals when properly cured.
Disadvantages: Yellows over time, vulnerable to chemicals, limited outdoor use, contain VOCs, less flexibility for wood movement
Silicone Resins
Applications: Ideal for high-temperature environments, such as in industrial ovens and furnaces, and for protecting outdoor products from extreme weather.
Advantages: Excellent heat resistance, water repellency, and weatherability.
Disadvantages: Generally more expensive, require proper primers for good adherence.
Phenolic Resins
Applications: Used in high-temperature environments and in chemical processing industries.
Advantages: Excellent chemical resistance, durability, and high heat tolerance.
Disadvantages: Can be brittle and may have limited flexibility compared to other resins.
Choosing the Right Resin
When selecting a resin for industrial coatings, consider the following factors:
1. Environment: Will the coating be exposed to extreme temperatures, chemicals, or UV light?
2. Durability requirements: How much abrasion or impact resistance is needed?
3. Flexibility vs. hardness: Is flexibility or rigidity more critical for the application?
4. Application method: How will the coating be applied (e.g., spray, brush, roll, dip, etc.)?
5. Production requirements: Will the coating be used in a high throughput production environment, requiring fast curing, efficient application, and quick handling times?
6. Cost: What is the budget for the coating material and application process?
Each resin type has its strengths and is suited for specific applications. Evaluating these properties in the context of your project will help you make an informed decision. The experienced scientists and technical service representatives at Sheboygan Paint Company have decades of experience advising customers on the best coating for each application. We look forward to the opportunity to work with you to solve your paint line challenges! Call us at 800.773. or visit shebpaint.com today!
For more Resin&Polymer For Industrial Coatingsinformation, please contact us. We will provide professional answers.
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