Coating, Application process: Difference between revisions
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==Description== | ==Description== | ||
A thin layer deposited or applied on the surface of an object (substrate). The primary purpose of applying a coating is to improve an objects critical properties and to create a protective barrier against deterioration of the surface. Secondary purposes may be aesthetic. Coatings may be applied as liquids, gases or solids e.g. powder coatings. | A coating is a thin layer deposited or applied on the surface of an object (substrate). The primary purpose of applying a coating is to improve an objects critical properties and to create a protective barrier against deterioration of the surface. Secondary purposes may be aesthetic. Coatings may be applied as liquids, gases or solids e.g. powder coatings. | ||
Revision as of 15:19, 23 May 2026
Note: This record is in process
Description
A coating is a thin layer deposited or applied on the surface of an object (substrate). The primary purpose of applying a coating is to improve an objects critical properties and to create a protective barrier against deterioration of the surface. Secondary purposes may be aesthetic. Coatings may be applied as liquids, gases or solids e.g. powder coatings.
Coating Application Processes
| Coating Process | Description | Key Differences/Advantages | Common Problems & Limitations | Typical Materials Used |
|---|---|---|---|---|
| Anodizing | An electrolytic passivation process where the metal surface is converted into a durable, decorative, and corrosion-resistant oxide layer. | Coating grows from the substrate itself rather than being applied over it; offers unmatched aesthetic durability. | Limited primarily to aluminum and its alloys; colors can fade under prolonged UV exposure; can be expensive. | Aluminum, titanium, magnesium, and niobium. |
| E-coating (Electrophorectic) | Parts are dipped into a bath of liquid (water-based) paint electrified to cause the coating to deposit evenly on the metal surface. | Offers superior edge-to-edge coverage and targeted, uniform film thicknesses. | Upfront equipment costs are high; usually limited to conductive materials (metals); requires dip tanks; primer required | Acrylic latex |
| Epoxy, 2 part mixture | Excellent chemical/moisture resistance; High durability | Some types are brittle; UV degradation (chalking); pot life limits; Stability is dependent on careful mixing and application. Curing time recommended | ||
| Painted Coating | A continuous process where liquid coating is transferred from a container | Simple equipment- Good for small areas or touch-up- Low overspray; | Mechanical complexity; requires precise fluid mechanics (viscosity control) to avoid streaking, ribbing, or uneven thickness.Slower for large areas- May not achieve uniform film thickness | Alkyds, Acrylics, Latex, Epoxy Esters; Liquid coatings (varnishes, lacquers, plastisols, and water-based adhesives) |
| Powder Coating | Dry, finely ground powder is applied electrostatically to a grounded part, then melted and cured in an oven. | No solvents; 100% solids; creates a thicker, tougher, and more uniform finish than liquid paint; excellent durability | Difficult to achieve thin coats; color changes require time-consuming equipment cleaning; requires heat-resistant substrates.Requires oven curing; not suitalbe for large strucures; special equipment needed | Thermoset/thermoplastic powders (Polyester, Epoxy, Acrylic, Polyurethane).Epoxy polyester, polyurethane powders |
| Spray, conventional | Fast coverage, Uniform film; Good for complex shapes | Overspray and drifting; Requires ventilation; Not ideal for outdoors | Alkyds, acrylics, epoxies, Urethane | |
| Spray, thermal | Metallic or ceramic material is melted by combustion or electric arc, then sprayed at high velocity onto the prepared substrate. | Excellent for wear and corrosion resistance; high deposition rate; no size limits for the part; immmediate use after application | High equipment noise and heat; requires highly skilled operators; potential for poor bonding if the surface is improperly prepared; porous substrates needs sealing prior to coating | Metals (zinc, zluminum), metal alloys, ceramics, and some plastics. |
| Tape/wrapsystems | Good for pipelines; electyrical insulation; fast field application | Susceptible to mechanical damage; needs good surface | Polyvinylchloride, polyethylene, polyolefin, butyl, ethylenepropylenediamine monomer(EPDM),nylon, glass fibers. | |
| Thermoplastic | plastics dissolved in solvents that cure by solvent evaporation | Process is faster | Vinyls, chlorinated rubbers; latex emulsions | |
| Thermoset (oxidation) | Liquid coatings usually dissolved in solvents that cure by crosslinking with oxygen. Can be accellerated with metallic salts | The process is slow for solvent evaporation and curing | Oxidation continues over the lifetime of the coating casuing cracking embrittlement and deterioration | Drying oils, catalyzed epoxy resins, polyurethanes, vinyl ester |
| Vapor Deposition | Vaporized materials are deposited on a substrate molecule-by-molecule inside a vacuum chamber. | Creates ultra-thin, precise, and highly dense protective layers; no limitations on substrate materials. | High processing costs; geometric line-of-sight limitations (recessed areas may not be coated easily); limited coating thickness. | Titanium nitride (TiN), chromium nitride (CrN), diamond-like carbon (DLC), and various metals/alloys. |
Resources and Citations
- Gilbert Gedeon, 'Coating Types and Selection, Course for Professional Engineers, CED Engineering Link