Failure Mechanisms, Application Limitations, and Systematic Improvement Directions for Polyester Coatings
Failure Mechanisms, Application Limitations, and Systematic Improvement Directions for Polyester Coatings
1. Application Positioning of Polyester Coatings
Polyester resins are widely used in coatings because they can provide a good balance among adhesion, flexibility, hardness, appearance, application adaptability, and cost. Polyester coatings are commonly used in powder coatings, coil coatings, industrial baking coatings, home appliance coatings, architectural aluminum profiles, metal products, and some packaging coatings. Among them, polyester resin is also a common and important resin type in powder coatings, and both TGIC and HAA curing systems are widely used in polyester powder coatings.
The reliability of polyester coatings mainly depends on the following factors:
① Resin structure, such as ester bond density, steric hindrance, hydrophilicity, acid value, hydroxyl value, and molecular weight;
② Curing system, such as curing agent type, reaction activity, crosslinking completeness, and curing window;
③ Coating film structure, such as crosslinking uniformity, film thickness, pinholes, craters, pigment and filler distribution, and interfacial bonding;
④ Substrate condition, such as degreasing, phosphating, chromating, zirconium treatment, silane treatment, or the quality of other pretreatments;
⑤ Application conditions, such as spraying parameters, baking profile, actual workpiece temperature, drying rate, and ambient humidity;
⑥ Service environment, such as water, heat, acids, alkalis, UV, salt spray, cleaning agents, pollutants, and mechanical damage.
Therefore, improvement of polyester coatings should not rely only on a single resin or a single additive. Instead, coatings should be systematically designed around “failure mechanism—typical manifestation—control focus—verification method.”
2. Overview of the Main Failure Mechanisms of Polyester Coatings
The main limitations of polyester coatings can be summarized into the following categories. It should be noted that these limitations do not mean that polyester resins have poor performance. Rather, they indicate that polyester coatings must be designed according to the application environment, application conditions, and protection objectives.
Failure Scenario | Core Mechanism | Typical Manifestations | Control Focus | Recommended Verification Methods |
Damp heat, water immersion, or high-humidity environment | Water diffusion, plasticization, ester bond hydrolysis, weakened interfacial bonding | Whitening, gloss loss, blistering, adhesion loss, peeling | Low-water-absorption resin, appropriate acid value/hydroxyl value, sufficient curing, film thickness control, pretreatment | Damp heat test, water immersion test, adhesion after aging, water resistance test |
Contact with alkaline media | Alkaline hydrolysis or saponification of ester bonds; interface damaged by high-pH media | Softening, tackiness, chalking, discoloration, blistering, edge peeling | Alkali-resistant structure, dense crosslinking, primer isolation, verification with actual media | Alkali solution immersion, cleaning agent test, adhesion after damp heat exposure |
Outdoor aging | Combined effects of UV, moisture, oxygen, temperature variation, pollutants, and pigment stability | Gloss loss, discoloration, chalking, surface roughness, cracking | Weather-resistant polyester, weather-resistant pigments, UV absorbers, HALS, film thickness, and application quality | QUV, xenon arc aging, natural exposure, gloss retention, color difference, chalking grade |
Insufficient curing | Insufficient temperature or time; incomplete crosslinking reaction | Low hardness, poor MEK resistance, poor water resistance, poor solvent resistance, unstable adhesion | Actual workpiece temperature, curing profile, activity matching between resin and curing agent | Oven temperature profile, MEK rub test, hardness, impact, adhesion, DSC |
Over-curing | Thermal aging, embrittlement, or yellowing caused by excessive temperature or excessive time | Reduced impact resistance, cracking on bending, yellowing, gloss change, reduced intercoat adhesion | Control the over-baking window; avoid excessive crosslinking and thermal aging | Over-baking test, impact, bending, color difference, gloss |
Powder application defects | Imbalance among melting, flow, degassing, and gelation rate | Orange peel, pinholes, craters, thin edge coverage, storage caking | Particle size, melt viscosity, degassing, spraying parameters, heating program | Appearance, film thickness distribution, pinhole detection, cross-section observation, storage stability |
Failure of waterborne systems | Film formation affected by water evaporation, hydrophilic groups, pH, dispersion stability, and drying process | Craters, whitening, water marks, flash rusting, reduced water resistance, storage thickening | Dispersion stability, pH, conductivity, drying profile, crosslinking efficiency, flash rust control | pH/conductivity, damp heat, water resistance, flash rusting, storage stability |
Application difficulty of high-solids systems | Difficult to balance low VOC, low viscosity, flow, sag resistance, and crosslinking performance | Poor flow, orange peel, sagging, narrow application window, reduced durability | Molecular weight, branched structure, low-viscosity resin, additives, and application viscosity window | Application viscosity, sagging, flow, mechanical and chemical resistance after curing |
Insufficient metal corrosion protection | Water, oxygen, and ions enter through coating defects or interfaces, causing under-film corrosion | Edge rusting, scratch creep, blistering, under-film corrosion, peeling after salt spray | Pretreatment, primer, anticorrosive pigments, film thickness, edge protection, multi-coat system | Salt spray, cyclic corrosion, scratch creep, adhesion after aging |
3. Chemical Medium-Induced Failure: Hydrolysis, Alkaline Hydrolysis, and Insufficient Chemical Resistance
3.1 Hydrolysis Is an Important Potential Failure Mechanism for Polyester Coatings in Damp Heat or Strong Acid/Alkali Environments
The main chain of polyester resin contains ester bonds. Ester bonds are relatively stable in ordinary dry environments, but hydrolysis may occur under the combined effects of moisture, heat, acidic conditions, or alkaline conditions. The hydrolysis rate of polyester materials is usually affected by pH, hydrophilicity, temperature, structural morphology, and polymer structure. Under sufficient moisture, temperature, acid/alkali conditions, or long-term exposure, hydrolysis may cause polymer chain scission and reduce the cohesive strength, mechanical properties, and adhesion retention of the coating film. Hydrolytic failure of polyester coating films usually proceeds through the following process:
① Moisture enters the coating film;
② The coating film swells or becomes plasticized;
③ Ester bonds gradually undergo hydrolysis;
④ Polyester chain segments or the crosslinked network are damaged;
⑤ The cohesive strength of the coating film and interfacial adhesion decrease;
⑥ Whitening, gloss loss, blistering, cracking, peeling, or under-film corrosion occurs.
It should be noted that heat itself is not a hydrolyzing agent, but elevated temperature accelerates moisture diffusion and chemical reaction rates. Acids and alkalis may act as catalysts or promoters. Water-induced coating failure includes not only visible phenomena such as blistering, corrosion, and peeling, but also hidden processes such as water diffusion, swelling, plasticization, hydrolysis, and interfacial bonding damage. In actual coatings, hydrolysis may occur in parallel with water diffusion, plasticization, interfacial weakening, and under-film corrosion.
The hydrolysis sensitivity of polyester is closely related to the resin structure. By selecting monomers with better hydrolysis resistance, reducing hydrophilicity, minimizing water-soluble residues, optimizing acid value and hydroxyl value, and improving crosslinking completeness, the stability of polyester coating films in damp heat or water immersion environments can be significantly improved.
3.2 The Risk Is Higher in Alkaline Environments
Under alkaline conditions, polyester is more prone to alkaline hydrolysis or saponification. Hydroxide ions in alkaline media attack ester bonds, causing polyester chain segments to break at the ester bond sites and generating hydroxyl and carboxylate end groups. Compared with neutral water environments, strong alkali or high-temperature alkaline environments are generally more destructive to polyester coating films. Special attention should be paid to the alkali resistance of polyester coatings in the following environments:
① Areas in contact with freshly mixed concrete, wet cement slurry, or mortar;
② Alkaline leachate, damp cement dust, or high-pH construction environments;
③ Equipment or metal panels that are in long-term contact with alkaline cleaning agents;
④ Industrial alkaline pollution environments;
⑤ High-temperature alkaline solutions, washing systems, or cleaning conditions;
⑥ Locations where architectural metal panels are in long-term contact with alkaline materials.
When alkali resistance is insufficient, the coating film may show gloss loss, tackiness, softening, color change, chalking, blistering, adhesion loss, or edge peeling. Such problems are usually not simply surface defects, but the result of chemical medium-induced damage to the resin structure, coating film crosslinked network, and coating/substrate interface.
3.3 Other Manifestations of Insufficient Chemical Resistance
In addition to water and alkalis, acidic media, organic solvents, cleaning agents, oils, food media, and high-temperature damp heat environments may also affect polyester coating films. Different media cause damage in different ways.
Medium Type | Possible Effects |
Water and damp heat | Water diffusion, swelling, plasticization, hydrolysis, adhesion loss |
Acidic media | Acid-catalyzed hydrolysis, gloss loss, discoloration, interfacial damage |
Alkaline media | Alkaline hydrolysis, saponification, softening, chalking, peeling |
Organic solvents | Swelling, softening, gloss loss, reduced rub resistance |
Cleaning agents | Surface gloss loss, color change, softening, or adhesion loss |
Oils and pollutants | Penetration, adhesion, difficult cleaning, localized discoloration |
3.4 Improvement Directions
To improve the chemical stability of polyester coatings, the following aspects should be controlled:
Improvement Direction | Function |
Optimize resin structure | Select monomers with better hydrolysis resistance, increase steric hindrance around ester bonds, and reduce hydrolysis sensitivity |
Reduce water absorption tendency | Control hydrophilic groups, water-soluble residues, and migratable components to reduce moisture ingress |
Optimize acid value and hydroxyl value | Avoid risks caused by residual acidic components, free hydrophilic groups, or acid-base imbalance in the formulation |
Improve crosslinking completeness | Form a denser and more uniform coating film structure to improve water resistance, solvent resistance, and chemical resistance |
Control film thickness and pinholes | Improve barrier properties and reduce the ingress of water, oxygen, and ions |
Optimize pigments and fillers | Improve barrier properties and reduce medium migration pathways |
Strengthen pretreatment | Improve interfacial stability and reduce the risk of blistering and under-film corrosion |
Conduct actual-medium testing | Carry out immersion, damp heat, cleaning agent exposure, and post-aging evaluation according to the actual contact medium |
Note: Increasing the degree of crosslinking is not always better. Excessive or non-uniform crosslinking may make the coating film brittle, increase internal stress, reduce impact resistance, or cause cracking during bending. A more reasonable goal is to improve the completeness and uniformity of crosslinking and its compatibility with the application scenario.
4. Outdoor Aging Failure: Combined Effects of UV, Moisture, Oxygen, and System Factors
4.1 Outdoor Aging Is Not Caused by a Single Factor
The weatherability of polyester coatings varies greatly and cannot be simply summarized as “polyester is weather-resistant” or “polyester is not weather-resistant.” There are significant differences in outdoor performance among standard polyester, weather-resistant polyester, super-durable polyester, polyurethane-modified systems, acrylic systems, and fluorocarbon systems. Evaluation of the weatherability of polyester coatings requires comprehensive consideration of resin structure, curing system, pigments, additives, film thickness, pretreatment, and application quality.
Outdoor aging is usually caused by the combined effects of the following factors:
① Ultraviolet light, i.e., UV;
② Moisture, condensation water, and damp heat cycling;
③ Oxygen and photo-oxidation reactions;
④ Temperature variation and thermal cycling;
⑤ Acid rain, salts, and industrial pollutants;
⑥ Stability of pigments and additives;
⑦ Degree of coating film curing;
⑧ Film thickness and edge coverage;
⑨ Quality of substrate pretreatment.
4.2 Typical Manifestations of Weathering Failure
The aging manifestations of outdoor polyester coatings mainly fall into three categories:
Type | Typical Manifestations | Main Causes |
Appearance changes | Gloss loss, discoloration, chalking, surface roughness | Photo-oxidation of the surface resin layer, insufficient weather resistance of pigments, additive failure |
Structural deterioration | Embrittlement, fine cracks, cracking, reduced impact or bending performance | Aging of the coating film crosslinked network, increased internal stress, degradation of polymer chain segments |
Interfacial failure | Blistering, adhesion loss, localized peeling | Moisture vapor penetration, insufficient pretreatment, insufficient film thickness, weakened interfacial bonding |
4.3 Improvement Directions
The weatherability of polyester coatings should be improved from the perspective of the complete system:
Improvement Direction | Function |
Use weather-resistant or super-durable polyester | Improve the inherent UV resistance, oxidation resistance, and damp heat resistance of the resin |
Select weather-resistant pigments | Avoid accelerated fading, discoloration, or chalking caused by low-weatherability pigments |
Use a light stabilization system | UV absorbers and HALS can delay photo-aging |
Optimize pigment-to-binder ratio | Prevent premature exposure of pigments and fillers due to insufficient resin encapsulation |
Improve curing completeness | Reduce the ingress of moisture vapor and oxygen into the coating film and improve performance retention after aging |
Control film thickness | Ensure barrier performance, appearance retention, and edge coverage |
Optimize pretreatment and primer | Reduce adhesion loss and under-film corrosion after aging |
Conduct post-aging evaluation | Focus on changes in gloss retention, color difference, chalking grade, adhesion, impact, and bending performance |
UV absorbers and hindered amine light stabilizers can improve weathering performance, but they cannot replace weather-resistant resins, weather-resistant pigments, appropriate film thickness, and reliable application. If the resin structure, pigment stability, or curing conditions are unreasonable, it is difficult to achieve long-term stable performance by relying only on light stabilizers.
5. Curing-Related Failure: Under-Curing, Over-Curing, and the Low-Temperature Curing Window
5.1 Insufficient Curing Weakens Coating Film Performance
Many polyester coatings are thermosetting systems and need to form a crosslinked structure under specific temperature and time conditions. For powder coatings, the heating process usually includes melting, flow, degassing, and curing at the same time. Curing evaluation should not only look at the oven set temperature. It should also focus on the actual workpiece temperature, the holding time after the workpiece reaches the target temperature, and the actual reaction degree of the coating film.
If the curing temperature is insufficient, the curing time is insufficient, the actual workpiece temperature does not meet the requirement, or the reaction activity of the curing agent does not match the resin, under-curing may occur.
Common manifestations of insufficient curing include:
① Low hardness;
② Poor methyl ethyl ketone rub resistance. Methyl ethyl ketone is abbreviated as MEK and is also known as butanone;
③ Reduced water resistance and chemical resistance;
④ Surface tackiness;
⑤ Unstable adhesion;
⑥ Insufficient impact and bending performance;
⑦ Faster performance degradation after aging.
5.2 Over-Curing Can Also Cause Failure
Excessively high curing temperature or excessively long curing time does not necessarily bring better performance. Over-curing may lead to:
① Embrittlement of the coating film;
② Reduced impact resistance;
③ Cracking during bending;
④ Yellowing;
⑤ Gloss change;
⑥ Reduced intercoat adhesion;
⑦ Thermal aging of certain pigments or additives.
The key to curing control is to find a balance among temperature, time, melt flow, degassing, reaction rate, and final performance.
5.3 Value and Challenges of Low-Temperature Curing
Low-temperature curing polyester powder coatings can reduce baking energy consumption, shorten production cycle time, and help expand powder coating applications on heat-sensitive substrates such as heavy metal parts, medium density fiberboard (MDF), engineered wood, some plastics, and composite materials. The development of low-temperature curing technology is also related to energy conservation, sustainable production, and the coating needs of heat-sensitive substrates.
However, low-temperature curing is not simply a matter of lowering the baking temperature. When the temperature is reduced, resin melting, flow, degassing, and crosslinking reactions may all be affected.
Challenge | Possible Problems |
Insufficient melting | Orange peel, poor flow, rough surface |
Insufficient reaction | Reduced hardness, water resistance, and chemical resistance |
Reaction too fast | Insufficient flow time, increased pinholes or craters |
Insufficient degassing | Bubbles, pinholes, thick-film defects |
Reduced storage stability | Powder caking or premature reaction |
Increased cost | Higher cost of high-activity resins, curing agents, or catalysts |
5.4 Improvement Directions
Curing-related problems should be controlled from the following aspects:
Control Direction | Function |
Measure actual workpiece temperature | Confirm real curing conditions instead of relying only on oven settings |
Establish a curing profile | Identify the relationship among time, temperature, and performance |
Optimize the reaction activity of resin and curing agent | Avoid under-curing, overly rapid gelation, or over-curing |
Control the melt-flow window | Ensure sufficient flow before complete crosslinking |
Optimize the heating program | Reduce pinholes, bubbles, and localized over-baking |
Match substrate heat capacity | Use different curing strategies for thick parts, thin parts, and heat-sensitive substrates |
Conduct post-curing performance tests | Verify by hardness, MEK, impact, bending, adhesion, and water resistance |
6. New Failure Risks in Low-VOC Systems: Powder, Waterborne, and High-Solids Systems
Low VOC is an important development direction for polyester coatings. Due to their highly designable structure, polyester resins play an important role in powder coatings, coil coatings, high-solids coatings, and some waterborne systems. However, low-VOC systems are not simply about reducing solvent. They also change issues related to film formation, application, drying, storage, and stability.
Waterborne coatings have been widely used in architectural, automotive, and other fields, but in some high-performance applications, waterborne systems may still face challenges in performance, cost, or commercial replacement.
6.1 Failure Risks of Polyester Powder Coatings
Polyester powder coatings offer advantages such as low VOC, high material utilization, and high application efficiency. They are usually electrostatically sprayed in solid powder form onto conductive substrates and are especially common on metal substrates. However, powder systems are highly sensitive to melt viscosity, particle size, flow, degassing, gelation rate, spraying parameters, and baking program.
Defect | Main Causes | Control Methods |
Orange peel | High melt viscosity, insufficient flow time, unreasonable particle size distribution, curing too fast | Reduce melt viscosity; optimize leveling agent, particle size, and heating profile |
Pinholes | Gas release, substrate porosity, insufficient degassing in thick films, gelation too fast | Control film thickness, use degassing agents, optimize preheating and baking program |
Craters | Surface contamination, poor wetting, incompatible additives | Improve pretreatment, control contamination sources, optimize wetting and leveling system |
Thin edge coverage | Electrostatic shielding, sharp-edge effect, insufficient coating of complex structures | Optimize spraying voltage, gun distance, particle size, and touch-up spraying process |
Storage caking | Low resin Tg, high storage temperature, excessive fines, or moisture absorption | Increase Tg, control particle size, use anti-caking additives, improve storage and transportation conditions |
β-Hydroxyalkylamide, abbreviated as HAA, is a commonly used TGIC-free curing agent for carboxyl-functional polyester powder coatings. TGIC refers to triglycidyl isocyanurate. HAA releases water when curing carboxyl-functional polyester. Therefore, under conditions of thick film, insufficient degassing, or overly rapid gelation, attention should be paid to the risk of surface defects such as pinholes and bubbles.
6.2 Failure Risks of Waterborne Polyester
Waterborne polyester uses water as the main dispersion medium, which helps reduce VOC. However, waterborne conversion does not automatically improve performance. The high surface tension of water, evaporation process, hydrophilic groups, pH changes, dispersion stability, and drying conditions all affect film formation quality.
Problem | Formation Causes | Control Methods |
Craters and poor flow | High surface tension of water, insufficient wetting, contamination, or incompatible additives | Optimize wetting agents, leveling agents, and substrate cleanliness |
Whitening or water marks | Moisture retention, uneven drying, incomplete film formation | Optimize drying profile and application environment |
Flash rusting | Contact between water and metal substrate; insufficient initial protection | Use flash rust inhibitors; improve pretreatment and drying speed |
Reduced water resistance | Excessive hydrophilic groups, residual moisture, or insufficient crosslinking | Control hydrophilicity and improve crosslinking efficiency |
Storage thickening or settling | pH drift, insufficient dispersion stability, microbial effects, or electrolyte effects | Control pH, water quality, conductivity, preservative system, and dispersion system |
Pigment flooding and floating | Poor pigment dispersion or unstable additive system | Optimize wetting/dispersing agents and pigment/filler system |
Waterborne polyester systems require special attention to pH, hydrophilic groups, and storage stability. If the system contains excessive hydrophilic structures, or if crosslinking efficiency is insufficient, the water resistance, damp heat resistance, and long-term adhesion of the coating film may decrease.
6.3 Failure Risks of High-Solids Polyester
High-solids polyester reduces VOC by increasing solids content and reducing solvent. However, after solids content is increased, it becomes more difficult to balance system viscosity, flow, sagging, application, and crosslinking. The core contradictions of high-solids systems are:
① Reducing VOC requires reducing solvent;
② Reducing viscosity may require reducing molecular weight;
③ Maintaining mechanical strength requires sufficient molecular weight and crosslinked structure;
④ Maintaining flow requires appropriate application viscosity and open time;
⑤ Improving chemical resistance requires sufficient crosslinking and a dense coating film.
If molecular weight is simply reduced to lower viscosity, coating film strength and durability may decrease. If functionality or crosslink density is increased, viscosity may rise again and application properties may deteriorate.
Improvement directions for high-solids polyester include:
① Designing low-viscosity polyester resins;
② Controlling molecular weight and molecular weight distribution;
③ Using an appropriate branched structure;
④ Selecting low-viscosity crosslinking components or suitable co-solvents;
⑤ Introducing reactive low-viscosity components when necessary, while verifying migration, VOC, curing compatibility, and final coating film performance;
⑥ Optimizing flow, sag resistance, and defoaming systems;
⑦ Controlling curing reaction rate;
⑧ Establishing an application viscosity window according to the spraying method.
The common feature of powder, waterborne, and high-solids systems is that they can reduce VOC, but they also require more precise resin design, formulation control, and application management.
7. Limitations in Metal Corrosion Protection Applications: Polyester Is More Suitable as a Topcoat or as Part of a Coating System
Polyester coatings can be used to protect metal products. However, in severe corrosive environments, a single-layer polyester coating film usually cannot provide complete heavy-duty corrosion protection. Polyester is more suitable as a decorative layer, a weather-resistant layer, or a component of a composite system, rather than independently providing adhesion, rust prevention, barrier protection, corrosion inhibition, and chemical resistance in all corrosive scenarios.
Organic coatings are not completely impermeable. Water, oxygen, and ions may pass through the coating or enter the coating/metal interface through defects, thereby causing under-film corrosion. Common failures of polyester coatings on metal substrates include edge rusting, corrosion creep from scratches, under-film corrosion, blistering, adhesion loss, peeling after salt spray exposure, and premature failure at welds, holes, and sharp edges. These problems are often related to the following factors:
Cause | Impact |
Insufficient pretreatment | Weak interfacial bonding; blistering and peeling are likely after water ingress |
Insufficient edge film thickness | Sharp edges, welds, and holes become corrosion initiation sites |
Insufficient anticorrosive performance of primer | Difficult to prevent corrosion spread after moisture vapor and ions enter |
Pinholes or craters in the coating film | Localized barrier failure |
Insufficient curing | Reduced coating film density and chemical resistance |
Damage not repaired | Accelerated corrosion spread from scratches |
Service environment too severe | Exceeds the design capability of a single-layer polyester coating |
When used for metal protection, polyester coatings should be considered as part of a complete corrosion protection system. A more reliable design usually includes:
① Appropriate degreasing, phosphating, chromating, zirconium treatment, silane treatment, or other pretreatments;
② A primer with anticorrosive capability;
③ Sufficient dry film thickness;
④ Protection of edges, welds, holes, and cut edges;
⑤ A dense, pinhole-free topcoat;
⑥ A multi-coat system;
⑦ Scribed salt spray, cyclic corrosion, and adhesion testing after aging.
8. Application Verification: From Single Tests to Failure-Scenario Verification
Failure of polyester coatings does not necessarily come from the resin itself. It may also come from the formulation, application process, substrate, curing, or service environment. Reliable evaluation should not focus only on initial performance, but also on performance retention after aging and real service scenarios.
8.1 Post-Aging Performance Should Be Emphasized
When evaluating polyester coatings, the following items should be emphasized:
Test Item | Evaluation Significance |
Adhesion after aging | Determines whether the interface remains stable |
Impact performance after aging | Determines whether the coating film has become brittle |
Bending performance after aging | Determines reliability after forming, thermal cycling, or long-term use |
Water resistance after damp heat exposure | Determines coating film integrity after moisture vapor exposure |
Appearance and adhesion after chemical exposure | Determines performance retention after contact with media |
Gloss retention and color difference | Determines the degree of outdoor aging |
Chalking grade | Determines the degree of surface resin degradation |
Scratch corrosion creep | Determines corrosion protection capability after damage |
MEK, hardness, and degree of curing | Determines whether curing is sufficient |
Film thickness and edge coverage | Determines barrier performance and the risk of weak areas |
8.2 Composite Environmental Verification Is Closer to Real Failure
Real service environments are usually not affected by a single factor. Outdoor metal parts may be exposed simultaneously to ultraviolet light, moisture vapor, salts, temperature variation, pollutants, and mechanical damage during use. Therefore, salt spray testing alone, damp heat testing alone, or aging testing alone usually reflects only one type of risk and cannot fully represent the actual failure process.
Verification of polyester coatings should combine test conditions according to the service scenario. For example, outdoor weatherability should focus on ultraviolet light and condensation cycling. Metal corrosion protection should focus on salt spray, wet-dry cycling, and corrosion creep from scratches. Formed parts should focus on adhesion and corrosion resistance after bending, impact, or forming. Areas that are cleaned frequently should include evaluation of appearance, gloss, and adhesion after contact with cleaning agents.
When evaluating polyester coatings, the focus should shift from single initial performance tests to “performance retention after aging” and “failure verification under composite environments.” Key results to observe include gloss retention, color difference, chalking, blistering, adhesion loss, scratch creep, and edge corrosion.
8.3 Application Process Data Are Key Evidence for Determining Failure Causes
Many failures of polyester coatings are not caused by incorrect resin selection, but by insufficient application process control. For example, insufficient curing reduces the density and chemical resistance of the coating film, insufficient film thickness weakens barrier performance, poor pretreatment leads to adhesion loss after damp heat or salt spray exposure, and insufficient edge coverage increases the risk of localized corrosion.
During failure analysis, key process data should be recorded and retained, including baking oven temperature profile, actual workpiece temperature, film thickness distribution, edge coverage, pretreatment quality, powder particle size distribution, pH value and conductivity of waterborne coatings, application viscosity, temperature and humidity of the spraying environment, as well as post-curing results for hardness, methyl ethyl ketone (MEK) rub test, impact, bending, and adhesion.
9. Classified Application Tables of Representative Chemicals Related to Polyester Coating Limitations, Failure Mechanisms, and Improvement Directions
Note: The following products are mainly intended as references for polyester coating structure design, failure mechanism studies, formulation screening, or testing and evaluation. For actual industrial applications, the target system, regulatory requirements, SDS/COA, compatibility, dispersibility, migration risk, and long-term performance verification should also be considered.
Table 1. Polyester Resin Structure Design and Bio-Based Monomers
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Polyester structural monomer | 504-63-2 | 1,3-Propanediol | Suitable for synthesis | Diol monomer; used for flexible segment design of polyester resins, hydroxyl value regulation, and screening of hydrolysis-resistant structures | |
Bio-based polyol source | 8001-79-4 | C434218 | Castor oil | European Pharmacopoeia (Ph.Eur) | Hydroxyl-containing natural oil; used in bio-based polyester modification, flexibility regulation, and research on introducing hydrophobic segments |
Unsaturated dicarboxylic acid monomer | 97-65-4 | Itaconic acid | Chemically pure (CP), ≥99% | Double-bond-containing dicarboxylic acid; used in unsaturated polyester synthesis, functional modification, and studies on crosslinking reaction activity | |
Long-chain aliphatic dicarboxylic acid | 111-20-6 | Sebacic acid | Chemically pure (CP), ≥98% | Long-chain dicarboxylic acid; used to regulate polyester flexibility, hydrophobicity, low-temperature impact performance, and chemical resistance | |
Aliphatic dicarboxylic acid | 110-15-6 | Succinic acid | PharmPure™, ChP, JP, ACS, NF, crystalline | Dicarboxylic acid monomer; used in aliphatic polyester synthesis, acid value regulation, and sustainable polyester structure design | |
Hydroxy acid monomer | 50-21-5 | DL-Lactic acid | AR, 85–90% | Hydroxycarboxylic acid; used in polyester segment construction, degradable polyester research, and evaluation of ester bond hydrolysis sensitivity | |
Bio-based rigid diol | 652-67-5 | Isosorbide | ≥98% (GC) | Rigid diol; used in bio-based polyester synthesis, hardness and glass transition temperature regulation, and heat-resistant structure design | |
Bio-based aromatic dicarboxylic acid | 3238-40-2 | 2,5-Furandicarboxylic acid (FDCA) | ≥98% | Furan dicarboxylic acid; used in bio-based polyester synthesis and research on barrier properties, hardness, and heat resistance | |
Unsaturated anhydride monomer | 2170-03-8 | Itaconic anhydride (ITA) | ≥95% | Anhydride-type functional monomer; used in polyester functionalization, introduction of crosslinking sites, and regulation of reaction activity |
Table 2. Monomers and Additives Related to Waterborne Polyester Systems: Dispersion, Film Formation, and Storage Stability
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Waterborne film formation and rheology control | 25322-68-3 | Polyethylene oxide | Viscosity 65–115 cps | Water-soluble polyether; used in waterborne polyester film formation, rheology control, and studies on moisture diffusion and hydrophilicity effects | |
Storage stability of waterborne systems | 532-32-1 | Sodium benzoate | Pharmaceutical grade, PharmPure™ | Aqueous-phase preservative component; used for storage stability, antimicrobial preservation, and formulation stability evaluation of waterborne polyester systems | |
Neutralizing agent and acid-base adjustment | 121-44-8 | Triethylamine | Anhydrous, ≥99.5%, water ≤50 ppm | Organic amine neutralizing agent; used for neutralization of carboxyl-functional polyester, acid value adjustment, and preparation of waterborne dispersion systems | |
Neutralizing agent for waterborne resins | 108-01-0 | N,N-Dimethylethanolamine (DMEA) | Refined grade, ≥99.5% | Tertiary amine neutralizing agent; used in waterborne polyester dispersion, acid-base balance, and studies on post-drying water resistance | |
Internal emulsifying monomer for waterborne systems | 4767-03-7 | 2,2-Bis(hydroxymethyl)propionic acid (DMPA) | ≥98% | Carboxyl-containing diol; used in internal emulsification of waterborne polyester and waterborne polyurethane systems, and in studies on the balance between hydrophilicity and water resistance | |
Sulfonate-type waterborne monomer | 6362-79-4 | Sodium 5-sulfoisophthalate (5-SSIPA) | ≥98% | Sulfonate dicarboxylic acid; used in water-dispersible polyester synthesis and research on ionic stability, water resistance, and dispersibility | |
Sulfonate-type polyester monomer | 3965-55-7 | Dimethyl 5-sulfoisophthalate sodium salt | ≥98% | Sulfonate dimethyl ester monomer; used in waterborne polyester copolymerization, dispersion stability, and regulation of hydrophilic group content |
Table 3. Chemicals Related to Curing Control and Failure Testing of Polyester Coatings
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Solvent for curing degree evaluation | 78-93-3 | B1506362 | Methyl ethyl ketone (regulated precursor chemical) | For HPLC, ≥99.7% | Solvent for resistance testing; used to evaluate curing degree, crosslinking completeness, and rub resistance of polyester coating films |
Test medium for alkali-induced failure | 1310-73-2 | S431793 | Sodium hydroxide | Anhydrous, ≥98%, pellets | Strong alkali reagent; used in research on alkaline hydrolysis, saponification, alkali immersion resistance, and adhesion decay of polyester coating films |
Phase transfer and reaction control | 1643-19-2 | Tetrabutylammonium bromide | Ion-pair chromatography grade, ≥99% | Quaternary ammonium salt reagent; used in polyester functionalization reactions, phase-transfer catalysis, and studies on the impact of ionic residues | |
Test medium for acid-induced failure | 7647-01-0 | H399545 | Hydrochloric acid (regulated precursor chemical) | ACS, ≥37% | Strong acid reagent; used in control experiments on acid-catalyzed hydrolysis, acid immersion resistance, and medium-induced failure of polyester coating films |
Powder degassing additive | 119-53-9 | Benzoin | ≥99.5% | Degassing component for powder coatings; used in studies on pinhole control, thick-film degassing, and melt-flow defects | |
Curing catalyst | 693-98-1 | 2-Methylimidazole | ≥98% | Imidazole catalyst; used in polyester composite curing, gel time control, and low-temperature curing reaction window studies | |
Curing agent for carboxyl-functional polyester | 6334-25-4 | N,N,N',N'-Tetrakis(2-hydroxyethyl)adipamide | ≥97% | Hydroxyalkylamide curing agent; used in polyester powder curing, TGIC-free systems, and thick-film pinhole evaluation |
Table 4. Chemicals Related to Metal Corrosion Protection System Design and Corrosion Failure Evaluation for Polyester Coatings
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Flash rust inhibition and corrosion inhibition | 7632-00-0 | S433709 | Sodium nitrite | Anhydrous, ACS, ≥97% | Nitrite corrosion inhibitor; used in flash rust control for waterborne polyester systems and initial corrosion inhibition research on steel substrates |
Anticorrosive pigment | 13939-25-8 | Aluminum tripolyphosphate | P₂O₅ content 60–70% | Phosphate anticorrosive pigment; used in polyester primer corrosion protection, under-film corrosion inhibition, and salt spray performance evaluation | |
Corrosive medium | 7647-14-5 | Sodium chloride | AR, ≥99.5% | Chloride salt medium; used in salt spray testing, immersion corrosion, scratch creep, and edge corrosion evaluation | |
Anticorrosive pigment | 7779-90-0 | Zinc phosphate hydrate | AR, ≥99% | Zinc phosphate pigment; used in metal primer corrosion protection, interfacial stability, and adhesion studies after salt spray exposure | |
Corrosion inhibition and flash rust control | 10102-40-6 | Sodium molybdate dihydrate | AR, ≥99% | Molybdate corrosion inhibitor; used in flash rust inhibition in waterborne coatings and corrosion control at metal interfaces | |
Metal corrosion inhibitor | 95-14-7 | Benzotriazole | ≥99% | Triazole corrosion inhibitor; used in metal interface protection, anti-tarnish protection of copper and alloys, and under-coating corrosion research |
Table 5. Chemicals Related to Weathering Stabilization and Thermal-Oxidative Aging Control of Polyester Coatings
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Phenolic antioxidant | 128-37-0 | 2,6-Di-tert-butyl-p-cresol (BHT) | Chemically pure (CP) | Hindered phenolic antioxidant; used in research on thermal-oxidative aging inhibition, yellowing control, and storage stability of polyester resins | |
Hindered amine light stabilizer | 129757-67-1 | Bis(1-octyloxy-2,2,6,6-tetramethyl-4-piperidyl) sebacate | Monomer ≥65% | Low-basicity hindered amine; used in polyester coating films for photo-oxidation inhibition, chalking delay, and outdoor weatherability evaluation | |
Benzotriazole UV absorber | 2440-22-4 | 2-(2-Hydroxy-5-methylphenyl)benzotriazole | ≥99% | UV absorber; used in studies on gloss loss, discoloration, photo-aging, and surface chalking of polyester coating films | |
Benzotriazole UV absorber | 70321-86-7 | 2-(2H-Benzotriazol-2-yl)-4,6-bis(1-methyl-1-phenylethyl)phenol | ≥98% (HPLC) | High-molecular-weight UV absorber; used in polyester topcoat weatherability, low-migration light stabilization, and color difference control studies | |
Benzotriazole UV absorber | 3896-11-5 | 2-(5-Chloro-2-benzotriazolyl)-6-tert-butyl-p-cresol | ≥98% (HPLC) | Benzotriazole light-stabilizing component; used in the evaluation of UV aging, gloss retention, and yellowing of polyester coatings | |
Liquid UV absorber | 104810-48-2 | Poly(ethylene glycol) 300 ester of 3-[3-(2H-benzotriazol-2-yl)-4-hydroxy-5-tert-butylphenyl]propionic acid | ≥98% | Liquid light-stabilizing component; used in weatherability, compatibility, and migration studies of waterborne and high-solids polyester systems | |
Composite light stabilizer | 63843-89-0 | Bis(1,2,2,6,6-pentamethyl-4-piperidyl) [[3,5-di-tert-butyl-4-hydroxyphenyl]methyl]butylmalonate | ≥98% | Component containing hindered amine and phenolic structures; used in studies on synergistic photo-oxidative stabilization and weathering aging of polyester coatings | |
Phosphite antioxidant | 31570-04-4 | Tris(2,4-di-tert-butylphenyl) phosphite | ≥98% | Secondary antioxidant; used in polyester processing thermal stability, peroxide decomposition, and yellowing control studies | |
Hindered amine light stabilizer | 52829-07-9 | Bis(2,2,6,6-tetramethyl-4-piperidyl) sebacate | ≥98% | Hindered amine light stabilizer; used in UV aging, chalking delay, and outdoor exposure evaluation of polyester coating films | |
Phenolic antioxidant | 6683-19-8 | Pentaerythritol tetrakis(3,5-di-tert-butyl-4-hydroxyhydrocinnamate) | ≥98% | High-molecular-weight hindered phenolic antioxidant; used in research on thermal-oxidative stability and baking yellowing control of polyester resins | |
Phenolic antioxidant | 2082-79-3 | Antioxidant 1076 | ≥98% | Hindered phenolic antioxidant; used in thermal-oxidative aging, storage stability, and processing stability studies of polyester resins | |
Hindered amine light stabilizer | 41556-26-7 | Bis(1,2,2,6,6-pentamethyl-4-piperidyl) sebacate | ≥95% (GC), sum of monoester and diester | Liquid hindered amine light stabilizer; used in polyester topcoat weatherability, gloss retention, and low-temperature compatibility studies | |
Triazine UV absorber | 153519-44-9 | UV Absorber UV400 | ≥85% | Triazine light-stabilizing component; used in long-term weatherability, color difference control, and gloss retention evaluation of polyester coating films | |
Liquid UV absorber | 104810-47-1 | UV Absorber 1130 | ≥84% (HPLC) | Liquid benzotriazole light-stabilizing component; used in weatherability and compatibility evaluation of waterborne and solventborne polyester systems |
Note: The above are representative Aladdin products. For more product specifications, search by “product name/CAS/catalog number” on the Aladdin official website.
References
[1] Wicks, Z. W.; Jones, F. N.; Pappas, S. P.; Wicks, D. A. Organic Coatings: Science and Technology. 3rd ed. Wiley, 2007.
[2] Koleske, J. V., ed. Paint and Coating Testing Manual: 15th Edition of the Gardner-Sward Handbook. ASTM International, 2012.
[3] Jones, F. N. “Alkyd Resins and Polyester Resins.” Journal of Coatings Technology, 1995.
[4] Hydrolytic Stability of Unsaturated Polyesters. ScienceDirect chapter.
[5] Sabet-Bokati, K.; Plucknett, K. “Water-induced failure in polymer coatings: Mechanisms, impacts and mitigation strategies.” Polymer Degradation and Stability, 2024.
[6] Allnex. “TGIC Powder Coating and HAA Polyester Resins.”
[7] Powder Coated Tough. “Polyester Powder Coatings: TGIC vs. HAA.”
[8] Pieters, K.; Mekonnen, T. H. “Progress in waterborne polymer dispersions for coating applications: commercialized systems and new trends.” RSC Sustainability, 2024.
[9] Corrosion Under Organic Coatings. Springer Nature Link.
For more related articles, see below:
