Film Formation and Curing Mechanisms of Polyester Resins for Coatings: From Functional Groups and Curing Systems to Crosslinked Networks
Film Formation and Curing Mechanisms of Polyester Resins for Coatings: From Functional Groups and Curing Systems to Crosslinked Networks
1. The Key to Determining the Film-Formation Route of Polyester Resins Is the Reaction Pathway
Polyester resins used in coatings are not a single, uniform category. Different polyester resins vary in resin structure, reactive functional groups, curing-agent type, application method, and final coating-film structure.
In coating formulation, determining how a polyester resin forms a film should begin with three key questions:
① What reactive functional groups are present on the resin?
② What type of curing agent does it need to react with?
③ Does the final coating film mainly rely on physical film formation, or on chemical crosslinking and curing?
In high-performance industrial coatings, coil coatings, powder coatings, and automotive coatings, polyester resins usually do not simply form films by leaving a resin layer after solvent or water evaporation. Instead, reactive structures such as hydroxyl groups, carboxyl groups, or carbon-carbon double bonds react with curing agents to form a three-dimensional crosslinked network. Compared with uncrosslinked resin films, crosslinked coating films generally offer better solvent resistance, chemical resistance, hardness, heat resistance, and mechanical strength.
2. Classification Logic of Polyester Resins for Coatings
Polyester resins for coatings can be classified from multiple perspectives. These classifications are not necessarily on the same hierarchical level, nor are they mutually exclusive.
Classification Perspective | Representative Types | Key Point for Evaluation |
By reactive functional group | Hydroxyl polyester, carboxyl polyester | What type of curing agent it reacts with |
By reactive structure in the main chain | Saturated polyester, unsaturated polyester | Whether it contains carbon-carbon double bonds capable of free-radical polymerization |
By modified structure | Alkyd resin, polyester acrylate | Whether it is modified with fatty acids, acrylates, or other structures |
By application form | Solventborne polyester, waterborne polyester, powder polyester | How the resin is dispersed, applied, and formed into a film |
By curing method | Amino curing, isocyanate curing, epoxy curing, TGIC curing, HAA curing, oxidative drying, UV curing | The specific film-forming reaction pathway |
For example, a powder polyester can be both a saturated polyester and a carboxyl polyester, and it can react with triglycidyl isocyanurate — TGIC, also known as tris-glycidyl isocyanurate — or β-hydroxyalkylamide (HAA) to form a thermoset powder coating film. A waterborne polyester can also be a hydroxyl polyester and can crosslink with an amino resin under baking conditions.
3. Thermoplastic Film Formation and Thermosetting Film Formation
To understand how polyester resins form films, it is necessary to distinguish between thermoplastic film formation and thermosetting film formation.
3.1 Thermoplastic Film Formation
Thermoplastic film formation mainly relies on solvent evaporation, water evaporation, or melt cooling to form a continuous coating film. During film formation, resin molecules usually do not undergo significant chemical crosslinking. Thermoplastic film formation has the following characteristics:
① The film-forming process is mainly a physical change;
② The coating film may soften again when heated;
③ The coating film may redissolve or swell when exposed to a suitable solvent;
④ Solvent resistance, heat resistance, and chemical resistance are usually lower than those of fully crosslinked thermoset coating films;
⑤ Application and film formation are relatively simple, but use in high-performance industrial coatings is limited.
3.2 Thermosetting Film Formation
Thermosetting film formation relies on chemical reactions between the resin and the curing agent to form a three-dimensional crosslinked network. After curing is complete, the coating film usually no longer melts and is not easily redissolved by the original solvent. Thermosetting film formation has the following characteristics:
① The film-forming process involves chemical reactions;
② The degree of curing directly affects final performance;
③ Solvent resistance, chemical resistance, heat resistance, and mechanical strength are usually better;
④ The amount of curing agent, curing temperature, curing time, catalyst, film thickness, and application conditions must be controlled.
Most high-performance polyester coatings are thermosetting systems, such as hydroxyl polyester/amino resin systems, hydroxyl polyester/isocyanate systems, carboxyl polyester/TGIC systems, carboxyl polyester/HAA systems, and polyurethane powder systems.
4. Saturated Polyesters: Hydroxyl Polyesters and Carboxyl Polyesters Are Core Types
In coating applications, saturated polyesters generally refer to polyester resins whose main chains do not contain aliphatic carbon-carbon double bonds, such as those from maleic acid or fumaric acid, that can participate in free-radical copolymerization. Saturated polyesters are usually prepared by polycondensation of polyacids and polyols. They rely on functional groups such as hydroxyl and carboxyl groups in the molecule to react with curing agents and form thermoset coating films. Saturated polyesters are widely used in powder coatings, coil coatings, industrial baking finishes, packaging coatings, metal decorative coatings, automotive coatings, and transportation coatings.
The performance of saturated polyesters can be adjusted through the acid component, alcohol component, molecular weight, glass transition temperature, hydroxyl value, acid value, and degree of branching. Among these parameters, hydroxyl value and acid value are particularly important indicators in formulation design.
A hydroxyl polyester is a polyester resin containing hydroxyl groups, expressed as —OH. Hydroxyl groups allow the polyester to react with amino resins, isocyanates, or blocked isocyanates to form a crosslinked coating film.
A carboxyl polyester is a polyester resin containing carboxyl groups, expressed as —COOH. Carboxyl groups can react with epoxy-functional curing agents, such as epoxy resins or TGIC, and can also be cured with HAA through esterification crosslinking to form a thermoset coating film.
Hydroxyl polyesters and carboxyl polyesters are two important categories of saturated polyesters used in coatings. Hydroxyl polyesters are commonly used in polyester-amino baking finishes, polyester-polyurethane coatings, and polyurethane powder coatings. Carboxyl polyesters are especially important in powder coatings and are commonly used in polyester/epoxy hybrid powders, TGIC outdoor powders, and HAA outdoor powders.
Type | Main Functional Group | Typical Curing Agents | Common Applications |
Hydroxyl polyester | Hydroxyl —OH | Amino resin, isocyanate, blocked isocyanate | Industrial baking finishes, coil coatings, polyurethane coatings, polyurethane powders |
Carboxyl polyester | Carboxyl —COOH | Epoxy resin, TGIC, HAA | Powder coatings, industrial coatings, some coil-coating systems |
5. Main Curing Systems for Hydroxyl Polyesters
The core feature of hydroxyl polyesters is the reactivity of hydroxyl groups. Hydroxyl groups can react with amino resins, isocyanates, or blocked isocyanates to form different types of crosslinked structures. Different curing systems have different reaction conditions, coating-film properties, and application requirements.
5.1 Curing of Hydroxyl Polyesters with Amino Resins
Amino resins are common thermosetting curing agents in baking coatings. They mainly include melamine-formaldehyde resins, urea-formaldehyde resins, and benzoguanamine resins. Among them, melamine-formaldehyde resins are commonly used in industrial baking finishes, coil coatings, and automotive coatings.
Under heating and acid-catalyzed conditions, hydroxyl polyesters and alkyl-etherified amino resins usually crosslink mainly through transetherification between hydroxyl groups and alkoxymethyl groups in the amino resin. Competing reactions, such as self-condensation of the amino resin, may also occur, ultimately forming a crosslinked network.
This system can be simplified as follows:
Hydroxyl polyester + amino resin + heat + acid catalyst → crosslinked coating film
The hydroxyl polyester/amino resin system has the following characteristics:
① Suitable for baking coatings;
② Relatively fast curing speed;
③ Good coating-film hardness, gloss, and leveling;
④ Good solvent resistance and chemical resistance;
⑤ Suitable for continuous, high-speed coating processes;
⑥ Sensitive to baking temperature, baking time, and catalyst.
This system is commonly used in coil coatings. Coil-coating production requires rapid coating, rapid baking, and stable film formation. Therefore, resin reactivity, amino resin type, acid catalyst, and baking conditions are critical. Insufficient crosslinking can lead to low hardness, poor solvent resistance, and inadequate chemical resistance. Excessive crosslinking or improper baking conditions may cause the coating film to become brittle, crack during bending, or lose post-forming performance.
5.2 Curing of Hydroxyl Polyesters with Isocyanates
The isocyanate group is usually represented as —NCO. Hydroxyl polyesters can react with isocyanates to form urethane bonds, thereby forming polyurethane structures. The basic reaction can be expressed as:
Hydroxyl —OH + isocyanate —NCO → urethane bond
Hydroxyl polyester/isocyanate systems are commonly used in two-component polyurethane coatings. Before application, the hydroxyl polyester base component is mixed with the isocyanate curing agent, after which crosslinking occurs. This system has the following characteristics:
① Can cure at room temperature or at low-to-medium temperatures;
② Provides good film fullness and build;
③ Offers good adhesion, abrasion resistance, and mechanical properties;
④ Provides good chemical resistance;
⑤ Suitable for industrial coatings, wood coatings, automotive refinish coatings, and high-performance topcoats.
For this system, pot life must be carefully controlled. After the base component and curing agent are mixed, the system continues to react and the viscosity gradually increases. Once the pot life is exceeded, leveling, appearance, and coating-film performance may be affected. In addition, isocyanates are sensitive to moisture. Moisture may react with isocyanates as a side reaction and release carbon dioxide, leading to bubbles, pinholes, or reduced performance. Therefore, during application and storage, environmental humidity, solvent water content, and moisture on the substrate surface must be controlled.
5.3 Curing of Hydroxyl Polyesters with Blocked Isocyanates
Blocked isocyanates temporarily block the isocyanate groups, making them less likely to react with hydroxyl groups at room temperature. When heated to a certain temperature, the blocking agent dissociates and releases active isocyanate groups, which then react with hydroxyl polyesters to form polyurethane crosslinked structures. This process can be simplified as follows:
Blocked isocyanate + heat → active isocyanate → reaction with hydroxyl polyester to form a film
Blocked isocyanates are suitable for one-component baking systems and are also commonly used in polyurethane powder coatings. This system has the following characteristics:
① Good storage stability;
② Suitable for one-component baking coatings;
③ Forms polyurethane structures after curing;
④ Provides good leveling, abrasion resistance, chemical resistance, and mechanical properties;
⑤ Requires reaching the deblocking temperature and maintaining sufficient curing time.
Polyurethane powder coatings usually use hydroxyl polyesters in combination with blocked isocyanates or uretdione curing agents. Conventional blocked isocyanates usually involve deblocking and release of the blocking agent. Uretdione curing agents are often regarded as internally blocked isocyanate systems; upon heating, they can release isocyanate groups and react with hydroxyl resins. Because they usually do not rely on the release of an external blocking agent, the risks of odor and pinholes caused by volatile blocking agents are generally lower than those of conventional blocked isocyanate systems.
The film-forming process includes powder melting, leveling, curing-agent deblocking or reaction activation, reaction between hydroxyl groups and isocyanate groups, and formation of a crosslinked network. This system requires attention to deblocking temperature, volatile release, application odor, pinhole risk, and baking conditions. If used for outdoor coatings, the effect of the isocyanate structure on weatherability and yellowing performance should also be considered.
Curing System | Main Reaction | Film-Formation Characteristics | Main Points of Attention |
Hydroxyl polyester/amino resin | Crosslinking between hydroxyl groups and amino resin | Baking cure, good hardness and appearance | Catalyst, baking conditions, flexibility |
Hydroxyl polyester/isocyanate | Reaction between hydroxyl groups and isocyanate groups | Polyurethane structure, good mechanical properties | Pot life, moisture sensitivity, mixing ratio |
Hydroxyl polyester/blocked isocyanate | Reaction between hydroxyl groups and deblocked isocyanate groups | One-component baking or powder systems | Deblocking temperature, volatiles, completeness of cure |
6. Curing Systems of Carboxyl Polyesters in Powder Coatings
Carboxyl polyesters are very important in powder coatings. Powder coatings are usually composed of solid resins, curing agents, pigments and fillers, and additives. They are manufactured into powder through melt extrusion, cooling, grinding, and sieving. During application, powder particles adhere to the substrate surface through electrostatic spraying or similar methods, and then undergo melting, leveling, and crosslinking cure upon heating.
The film-forming process of polyester powder coatings usually includes four stages:
① Thermal softening: after powder particles enter the oven, the resin gradually softens;
② Melt coalescence: powder particles fuse with each other and form a continuous molten film;
③ Leveling and wetting: the molten resin flows, wets the substrate, and forms a relatively smooth surface;
④ Crosslinking cure: resin functional groups react with the curing agent to form an insoluble and infusible thermoset coating film.
The film quality of powder polyesters depends not only on the chemical reaction, but also on melt viscosity, gel time, leveling time, curing temperature, film thickness, pigment and filler dispersion, degassing performance, and substrate temperature.
6.1 Curing of Carboxyl Polyesters with Epoxy Resins
Carboxyl polyesters can react with epoxy groups in epoxy resins to form crosslinked structures. This reaction is an important basis for polyester/epoxy hybrid powder coatings. This system can be simplified as follows:
Carboxyl polyester + epoxy resin → crosslinked coating film
Polyester/epoxy hybrid powder coatings are commonly used for indoor applications, such as household appliances, office furniture, metal shelving, instrument housings, and general metal products. Their advantages include a good balance of leveling, mechanical properties, decorative appearance, and cost. Because epoxy components have limited outdoor weatherability, this system is usually not the preferred powder coating for long-term outdoor exposure.
6.2 Curing of Carboxyl Polyesters with TGIC
TGIC, or triglycidyl isocyanurate, contains multiple epoxy groups and can react with carboxyl polyesters to form a crosslinked network. The carboxyl polyester/TGIC system is one of the classic systems for outdoor weather-resistant powder coatings. This system can be simplified as follows:
Carboxyl polyester + TGIC → crosslinked coating film
Carboxyl polyester/TGIC systems usually have the following characteristics:
① Good outdoor weatherability;
② Good mechanical properties;
③ Good leveling and surface appearance;
④ Mature curing process;
⑤ Suitable for architectural aluminum profiles, metal curtain walls, outdoor facilities, traffic guardrails, agricultural machinery, and outdoor metal products.
For TGIC systems, close attention should be paid to polyester acid value, TGIC dosage, curing temperature, curing time, leveling window, weatherability of pigments and fillers, and safety and regulatory requirements. TGIC-free refers to powder-curing systems that do not use TGIC. A common representative is the HAA/Primid-type system, but TGIC-free systems are not limited to HAA. Specific performance still depends on resin structure, curing-agent type, and formulation design.
6.3 Curing of Carboxyl Polyesters with HAA
HAA is β-hydroxyalkylamide. It is a common TGIC-free curing agent for carboxyl polyester powder coatings. Commercial HAA curing agents are also often referred to as Primid-type curing agents. The core reaction between HAA and carboxyl polyester is esterification crosslinking, and water molecules are released during curing. This process can be simplified as follows:
Carboxyl polyester + HAA + heat → crosslinked coating film + water
Because water is released during curing, HAA systems are more prone to pinholes, bubbles, or surface appearance problems under thick-film application, rapid heating, low-temperature curing, or insufficient degassing conditions. Therefore, HAA systems require careful control of film thickness, heating rate, leveling window, degassing additives, and curing conditions. HAA polyester powder coatings usually have the following characteristics:
① TGIC-free;
② Good outdoor weatherability;
③ Good mechanical properties;
④ Suitable for architectural and general outdoor metal coating;
⑤ Compared with TGIC, HAA/Primid-type systems usually offer advantages in toxicological risk profile and regulatory compliance; however, specific safety, use restrictions, and compliance requirements should still be determined based on the product SDS and the regulations of the target market;
⑥ Pinholes and degassing require close attention during thick-film application.
6.4 Comparison of Common Powder Polyester Systems
Powder System | Resin Type | Curing Agent | Film-Formation Characteristics | Main Applications |
Polyester/epoxy hybrid | Carboxyl polyester | Epoxy resin | Good leveling and decorative appearance, mainly for indoor use | Appliances, furniture, metal products |
Pure polyester TGIC type | Carboxyl polyester | TGIC | Good outdoor weatherability, mature system | Architectural aluminum profiles, outdoor metal parts |
Pure polyester HAA type | Carboxyl polyester | HAA | TGIC-free, releases water during curing | Architectural and general outdoor powders |
Polyurethane powder | Hydroxyl polyester | Blocked isocyanate or uretdione curing agent | Good appearance, leveling, and mechanical properties | High-appearance, high-performance powder coatings |
Both TGIC and HAA can be used in outdoor weather-resistant powder coatings, but they differ in reaction by-products, leveling window, thick-film application, surface appearance, regulatory requirements, and formulation tolerance.
Item | TGIC System | HAA System |
Curing substrate | Carboxyl polyester | Carboxyl polyester |
Main reaction | Reaction between carboxyl groups and epoxy groups | Esterification crosslinking between carboxyl groups and HAA |
TGIC-free? | No | Yes |
Release of small molecules | Usually not characterized by water release | Releases water during curing |
Appearance control | Mature leveling and surface control | Thick films and degassing require close attention |
Outdoor application | Mature application | Widely used |
Regulatory considerations | TGIC safety and hazard-labeling requirements must be considered | Relatively more favorable |
7. Alkyd Resins: Oxidative Film Formation of Typical Air-Drying Polyesters
Alkyd resins are fatty-acid- or oil-modified polyesters. Unlike conventional saturated polyesters, typical air-drying alkyd resins form films through autoxidative chain reactions involving oxygen from the air.
Unsaturated fatty acid segments in alkyd resins undergo autoxidation in air to form hydroperoxides, which then further generate crosslinked structures through free-radical reactions. This process usually requires promotion by metal driers, such as metal carboxylate driers based on cobalt, manganese, iron, zirconium, and other metals. The process can be simplified as follows:
Alkyd resin + oxygen from air + drier → oxidatively crosslinked coating film
Typical air-drying alkyd resins have the following characteristics:
① Can dry at room temperature;
② Good application tolerance;
③ Good wetting of substrates;
④ Good coating-film fullness;
⑤ Relatively moderate cost;
⑥ Drying speed is affected by oxygen, temperature, humidity, film thickness, and driers.
Alkyd resins are commonly used in architectural coatings, wood coatings, metal protective coatings, and general industrial coatings.
It should be noted that oxidative air drying mainly applies to air-drying alkyd resins. Some short-oil or non-drying alkyd resins can also be crosslinked with amino resins, isocyanates, and other curing agents for baking or two-component systems. Therefore, not all alkyd resins should be simply understood as air-oxidation-drying resins.
Item | Typical Air-Drying Alkyd Resin | Conventional Thermosetting Saturated Polyester |
Structural characteristics | Fatty-acid- or oil-modified polyester | Mainly polycondensation of polyacids and polyols |
Film-formation method | Oxidative crosslinking in air | Crosslinking reaction with curing agent |
Oxygen dependence | Usually dependent on oxygen | Usually not dependent on oxygen |
Common applications | Architectural coatings, wood coatings, metal protection | Powder coatings, coil coatings, industrial baking finishes |
Main control factors | Drier, oxygen, film thickness, temperature and humidity | Curing agent, temperature, time, mixing ratio |
8. Unsaturated Polyesters and Polyester Acrylates: Free-Radical Curing of Double Bonds
Both unsaturated polyesters and polyester acrylates rely on carbon-carbon double bonds to participate in free-radical polymerization and form crosslinked structures. However, they differ in resin structure, initiation method, and application scenarios.
8.1 Unsaturated Polyesters
Unsaturated polyesters are polyester resins containing polymerizable carbon-carbon double bonds. They are usually prepared by polycondensation of unsaturated dibasic acids or anhydrides with polyols. Common sources of unsaturated structures include maleic anhydride and fumaric acid.
Unsaturated polyesters are usually used together with reactive diluents. Under the action of initiators and promoters, they undergo free-radical polymerization to form a three-dimensional crosslinked network. In traditional unsaturated polyester systems, styrene is commonly used as a reactive diluent. However, with increasing environmental and occupational health requirements, low-styrene, styrene-free, and low-VOC systems are also being developed. This process can be simplified as follows:
Unsaturated polyester + reactive diluent + initiator → free-radically crosslinked coating film
Unsaturated polyester systems have the following characteristics:
① Fast curing speed;
② Can form relatively high crosslink density;
③ Good coating-film hardness and chemical resistance;
④ Suitable for thick-film or special protective systems;
⑤ Application odor, volume shrinkage, and curing exotherm must be controlled;
⑥ Sensitive to oxygen inhibition, initiator dosage, and formulation stability.
Unsaturated polyesters are valuable in composite surface coatings, gel coats, special thick-film systems, and some industrial protective systems.
8.2 Polyester Acrylates
Polyester acrylates are a class of resins in which acrylate double bonds are introduced into the polyester structure. They are commonly used in radiation-curable coatings.
UV curing systems are usually composed of oligomers, reactive diluents, photoinitiators, and additives. After absorbing UV energy, the photoinitiator generates active free radicals, which initiate polymerization of acrylate double bonds and rapidly form a crosslinked coating film. The curing process includes:
① The photoinitiator absorbs UV energy;
② The photoinitiator generates active free radicals;
③ Free radicals initiate polymerization of acrylate double bonds;
④ Oligomers and reactive diluents crosslink together;
⑤ The coating film rapidly changes from a liquid state to a solid state.
This process can be simplified as follows:
Polyester acrylate + photoinitiator + UV energy → rapidly crosslinked coating film
Polyester acrylate UV-curable systems have the following characteristics: fast curing speed; relatively low energy consumption; suitability for continuous production; ability to produce high-gloss, high-hardness coating films; potential for lower VOC emissions; and sensitivity to light penetration, pigment hiding power, film thickness, and oxygen inhibition.
This article discusses acrylate-based free-radical UV curing. In the field of UV curing, cationic curing systems and hybrid free-radical/cationic systems also exist.
The key to UV curing is not “drying” in the traditional sense, but photoinitiated polymerization. Full curing can be achieved only when light intensity, photoinitiator type and dosage, double-bond concentration, film thickness, and formulation transparency are properly matched. For colored systems, thick-film systems, or systems with high levels of light-blocking pigments, special attention must be paid to the balance between through-cure and surface cure.
8.3 Differences Between the Two Types of Free-Radical Curing Systems
Item | Unsaturated Polyester | Polyester Acrylate |
Main reactive structure | Polymerizable double bonds in the polyester main chain | Acrylate double bonds |
Typical initiation method | Initiator, promoter, heat, or redox initiation | UV or electron-beam curing |
Film-formation characteristics | Can cure thick films and form relatively high crosslink density | Fast curing, suitable for continuous production |
Main concerns | Shrinkage, exotherm, odor, oxygen inhibition | Light penetration, film thickness, pigment hiding power, oxygen inhibition |
Common applications | Composite surface coatings, gel coats, special protective coatings | UV coatings, inks, clearcoats |
9. Waterborne Polyesters: Combining Water-Dispersed Forms with Crosslinking Systems
Waterborne polyesters are resin systems in which hydrophilic groups, ionic groups, or external emulsification methods are introduced so that polyester resins can be stably dispersed in water. Waterborne polyesters are commonly used in waterborne baking finishes, waterborne industrial coatings, waterborne coil coatings, and waterborne packaging coatings.
The key challenge for waterborne polyesters is to balance water-dispersion stability, application leveling, the drying process, and water resistance after curing. Common film-formation routes for waterborne polyesters include: forming a continuous film after water evaporation; baking crosslinking with amino resins; crosslinking with blocked isocyanates; reacting with other suitable crosslinkers; and further curing through self-crosslinking structures.
Waterborne polyester is not a single curing mechanism, but a class of polyester systems that use water as the main dispersion medium. It can be either a physically drying system or a baking-crosslinking system. It can be a hydroxyl polyester, or it can contain carboxyl groups or other hydrophilic structures.
Waterborne polyester systems require close attention to the following factors:
Key Factor | Effect |
Water-dispersion stability | Affects storage, application, and coating-film uniformity |
Neutralizing-agent type | Affects pH, odor, volatility, and water resistance |
Hydrophilic-group content | Affects dispersibility, water resistance, and coating-film compactness |
Curing-agent compatibility | Affects crosslinking uniformity and final performance |
Water evaporation process | Affects leveling, cratering, pinholes, and drying speed |
Baking conditions | Affect degree of crosslinking, chemical resistance, and water resistance |
The difficulty of waterborne polyester systems lies in balancing dispersion stability with final water resistance. Hydrophilic structures help the resin remain stably dispersed in water, but excessive hydrophilic structures may reduce the water resistance of the coating film. Therefore, the film quality of waterborne polyesters depends on the combined effects of resin structure, water evaporation process, curing-agent compatibility, and baking conditions.
10. Summary of Degree of Cure, System Selection, and Film-Formation Logic
Selecting the right resin and curing agent does not guarantee good coating-film performance. Only when curing is sufficient and the reaction is uniform can the structural advantages of the resin be truly translated into coating-film performance.
When curing is insufficient, common problems include insufficient hardness, poor solvent resistance, poor chemical resistance, tacky coating films, reduced water resistance, reduced adhesion, and accelerated outdoor aging.
Overbaking or improper curing conditions may also cause problems, such as coating-film brittleness, cracking during bending, yellowing, loss of gloss, reduced adhesion, increased surface defects, and reduced post-forming performance.
Film formation in polyester coatings is the combined result of resin melting, flow, wetting, degassing, crosslinking, and stress release. For powder coatings, the melt-leveling time must be balanced with the gelation and curing time. For liquid baking coatings, solvent or water evaporation, leveling, and crosslinking reactions must be balanced. When selecting a polyester resin, evaluation should follow the sequence below.
10.1 First, Determine the Application Method
Determine whether the coating is solventborne, waterborne, high-solids, powder, or UV-curable; whether it dries at room temperature, cures at low temperature, or requires high-temperature baking; and whether it is applied by spraying, roller coating, dip coating, electrodeposition, electrostatic powder spraying, or continuous coil coating. The application method directly affects the selection of resin molecular weight, viscosity, glass transition temperature, melt flow, drying speed, and curing window.
10.2 Next, Determine the Target Performance
Coil coatings emphasize flexibility, adhesion, solvent resistance, and post-forming performance. Outdoor powder coatings emphasize weatherability, gloss and color retention, and resistance to chalking. Industrial protective coatings emphasize chemical resistance, abrasion resistance, and corrosion protection. Decorative coatings focus more on appearance, leveling, gloss, and touch. Different target properties require different resin structures and curing systems.
10.3 Then, Determine the Curing System
Hydroxyl polyesters are suitable for reaction with amino resins, isocyanates, or blocked isocyanates. Carboxyl polyesters are suitable for reaction with epoxy resins, TGIC, or HAA. Air-drying alkyd resins are suitable for oxidative drying. Unsaturated polyesters are suitable for free-radical curing. Polyester acrylates are suitable for UV curing. Waterborne polyesters require further determination of whether they are physically drying or crosslinking-curing systems. Powder polyesters require further determination of whether they are carboxyl-curing systems or hydroxyl polyurethane powder systems.
10.4 Finally, Determine the Process Conditions
Consider curing temperature, curing time, pot life, storage stability, film thickness, leveling, pinholes, degassing, substrate temperature, production cycle time, and application environment.
The core differences among different polyester curing systems can be summarized as follows:
Film-Formation Mechanism | Representative Systems | Core Film-Formation Process | Main Points of Attention |
Hydroxyl crosslinking | Hydroxyl polyester/amino resin; hydroxyl polyester/isocyanate | Hydroxyl groups react with crosslinkers to form a network | Catalyst, mixing ratio, curing temperature, pot life |
Carboxyl crosslinking | Carboxyl polyester/epoxy; carboxyl polyester/TGIC; carboxyl polyester/HAA | Carboxyl groups react with epoxy groups or HAA | Acid value, curing-agent dosage, leveling window, degassing |
Oxidative crosslinking | Air-drying alkyd resin | Autoxidative crosslinking of unsaturated fatty acid segments | Drier, oxygen, film thickness, temperature and humidity |
Free-radical crosslinking | Unsaturated polyester; polyester acrylate | Free-radical polymerization of carbon-carbon double bonds | Initiation method, oxygen inhibition, shrinkage, light penetration |
Combination of application form and chemical curing | Waterborne polyester; powder polyester | Further crosslinking after water evaporation or melt leveling | Dispersion stability, leveling, curing window, defect control |
11. Representative Chemicals Related to Polyester Resin Film Formation (Tables 1–5)
Note: The following products are representative chemicals used in research on polyester resin film formation and curing. They are mainly intended for mechanism studies, synthesis research, model curing experiments, or formulation screening. Before industrial scale-up, it is necessary to further verify product grade, SDS information, regulatory requirements, formulation compatibility, and applicable processing conditions.
Table 1. Chemicals Related to Baking Cure of Hydroxyl Polyester/Amino Resin Systems
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Raw material for amino resin synthesis | 108-78-1 | 2,4,6-Triamino-1,3,5-triazine | Suitable for synthesis | Used in research on the synthesis of melamine-formaldehyde amino resins; suitable for crosslinker structure design in hydroxyl polyester baking-crosslinking systems. | |
Raw material for amino resin synthesis | 50-00-0 | Formaldehyde solution | AR, contains 10–15% methanol as stabilizer | Used in the synthesis of amino resins, phenolic resins, and related crosslinking resins; suitable for studying the baking-curing reaction between hydroxyl polyesters and amino resins. | |
Acid catalyst | 6192-52-5 | p-Toluenesulfonic acid monohydrate | Chemically pure (CP), ≥98% | Used for acid-catalyzed curing in hydroxyl polyester/amino resin baking systems; can promote transetherification and condensation crosslinking reactions. | |
Amino resin crosslinker | 3089-11-0 | 2,4,6-Tris[bis(methoxymethyl)amino]-1,3,5-triazine | ≥98% (HPLC) | Used for baking crosslinking of hydroxyl-containing resins such as hydroxyl polyesters and acrylic resins; suitable for curing studies of industrial baking finishes and coil coatings. | |
Structural monomer for amino resins | 91-76-9 | 2,4-Diamino-6-phenyl-1,3,5-triazine | ≥98% (HPLC) | Used in research on the synthesis of benzoguanamine resins and modified amino resins; suitable for adjusting the hardness, flexibility, and chemical resistance of baked coating films. | |
Acid catalyst | 104-15-4 | 4-Toluenesulfonic acid | ≥98% | Used as an acid catalyst in amino resin baking-curing systems; can be used to study the effect of catalyst dosage on the crosslinking rate and coating-film performance of hydroxyl polyesters. | |
Acid catalyst | 27176-87-0 | Dodecylbenzenesulfonic acid (DBSA) | ≥90%, mixture | Used for acid-catalyzed curing in hydroxyl polyester/amino resin systems; suitable for regulating crosslinking speed, storage stability, and coating-film performance in baking coatings. |
Table 2. Chemicals Related to Hydroxyl Polyester/Isocyanate and Blocked Isocyanate Curing
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Polyisocyanate curing agent | 28182-81-2 | Poly(hexamethylene diisocyanate) (PolyHDI) | Viscosity 900–1500 cP (25 °C) | Used in curing studies of two-component hydroxyl polyester polyurethane coatings; can form crosslinked coating films with good abrasion resistance, chemical resistance, and mechanical properties. | |
Blocking agent | 105-60-2 | Caprolactam | Chemically pure (CP) | Used in research on isocyanate blocking reactions; suitable for blocked isocyanate curing agents, one-component baking polyurethane coatings, and polyurethane powder systems. | |
Aliphatic diisocyanate | 822-06-0 | Hexamethylene diisocyanate (HDI) | Moligand™, ≥99% | Used to synthesize aliphatic polyurethane curing agents, biurets, trimers, and blocked isocyanates; suitable for research on weather-resistant hydroxyl polyester polyurethane systems. | |
Blocking agent | 67-51-6 | 3,5-Dimethylpyrazole | ≥99% | Used in research on isocyanate blocking reactions; can be used for the design of one-component baking polyurethane coatings and polyurethane powder curing agents. | |
Blocking agent | 96-29-7 | Butanone oxime | ≥99% | Used in research on the synthesis of blocked isocyanates; suitable for studying deblocking temperature and curing behavior in hydroxyl polyester baking polyurethane systems. | |
Cycloaliphatic diisocyanate | 4098-71-9 | Isophorone diisocyanate, mixture of isomers (IPDI) | ≥99% | Used to synthesize weather-resistant polyurethane resins, blocked isocyanates, and polyurethane curing agents; suitable for research on high-performance hydroxyl polyester coating films. | |
Aromatic diisocyanate | 26471-62-5 | Toluene diisocyanate, 2,4- and 2,6-isomers (TDI) | ≥98% (GC) | Used in research on the synthesis of polyurethane resins and curing agents; suitable for experiments on the reaction between hydroxyl polyesters and isocyanates and the formation of urethane bonds. | |
Aromatic diisocyanate | 101-68-8 | 4,4′-Methylenebis(phenyl isocyanate) (MDI) | ≥98% | Used in research on the synthesis of polyurethane materials and curing agents; suitable for studying hydroxyl polyester reactivity, crosslink density, and mechanical properties of coating films. | |
Isocyanurate-type curing agent | 3779-63-3 | 1,3,5-Tris(6-isocyanatohexyl)-1,3,5-triazine-2,4,6-trione | ≥95% | Used in hydroxyl polyester polyurethane curing systems; suitable for studying the effect of trifunctional isocyanate structures on crosslink density, chemical resistance, and weatherability. | |
Polyurethane catalyst | 77-58-7 | Dibutyltin dilaurate (DBTDL) | ≥95% | Used to catalyze the reaction between hydroxyl groups and isocyanates; suitable for studying curing speed, pot life, and film-formation performance of polyester polyurethane coatings. | |
Cycloaliphatic diisocyanate | 5124-30-1 | Dicyclohexylmethane 4,4′-diisocyanate, mixture of isomers (HMDI) | ≥90% (GC) | Used in research on the synthesis of weather-resistant polyurethane resins and curing agents; suitable for evaluating the coating-film performance of hydroxyl polyester cycloaliphatic polyurethane systems. |
Table 3. Chemicals Related to Carboxyl Polyester/Epoxy, TGIC, and HAA Powder Curing
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Model epoxy compound / epoxy resin raw material | 1675-54-3 | Bisphenol A diglycidyl ether (BADGE) | Moligand™, ≥85% | Can be used as a model epoxy compound for carboxyl/epoxy reactions or as a research raw material related to epoxy resins; suitable for studying crosslinking reactions between carboxyl groups and epoxy groups. | |
Phase-transfer catalyst | 1643-19-2 | Tetrabutylammonium bromide | AR, ≥99% | Used in research on epoxy ring-opening, esterification, and quaternary ammonium salt-catalyzed reactions; suitable for experiments promoting carboxyl polyester/epoxy curing reactions. | |
Epoxy-curing catalyst | 603-35-0 | Triphenylphosphine | ≥99% (GC) | Used to catalyze reactions between carboxyl groups and epoxy groups; suitable for studying reaction activity in polyester/epoxy powder coatings and TGIC curing systems. | |
Epoxy-curing catalyst | 1100-88-5 | Benzyltriphenylphosphonium chloride | ≥99% | Used to catalyze reactions between epoxy resins and carboxyl resins; suitable for studying curing speed, gel time, and degree of crosslinking in powder coatings. | |
Epoxy-curing accelerator | 693-98-1 | 2-Methylimidazole | ≥98% | Used to accelerate epoxy ring-opening curing; suitable for curing studies of polyester/epoxy hybrid powder coatings and epoxy-modified systems. | |
TGIC curing agent | 2451-62-9 | Triglycidyl isocyanurate | ≥98% | Used for curing carboxyl polyester outdoor powder coatings; suitable for studying carboxyl/epoxy reactions, crosslinked structures of weather-resistant powder coating films, and curing windows. | |
HAA curing agent | 6334-25-4 | N,N,N′,N′-Tetrakis(2-hydroxyethyl)adipamide | ≥97% | Used for curing carboxyl polyester TGIC-free powder coatings; suitable for studying esterification crosslinking, water release, pinhole control, and thick-film application performance. |
Table 4. Chemicals Related to Oxidative Drying of Alkyd Resins and Metal Driers
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Auxiliary drier | 22464-99-9 | Zirconium 2-ethylhexanoate | In mineral spirits (~6% Zr) | Used in oxidative drying systems for alkyd resins; can promote late-stage hardening after surface drying and support studies on overall drying performance. | |
Primary drier | 136-52-7 | Cobalt(II) 2-ethylhexanoate solution | 65 wt.% in mineral spirits | Used for oxidative crosslinking of air-drying alkyd resins; can promote surface drying and early-stage oxidation reactions; suitable for studies on drier formulation ratios. | |
Primary drier | 13434-24-7 | Manganese(II) 2-ethylhexanoate | 40% solution in mineral spirits (6% Mn) | Used in oxidative drying systems for alkyd resins; can participate in peroxide decomposition and oxidative crosslinking; suitable for research on cobalt-free or low-cobalt drier systems. | |
Auxiliary drier | 136-51-6 | Calcium 2-ethylhexanoate | 40% in 2-ethylhexanoic acid (3–8% Ca) | Used in alkyd resin drier systems; can improve drier dispersion, pigment wetting, and drying uniformity of coating films. |
Table 5. Chemicals Related to Free-Radical Curing of Unsaturated Polyesters and Polyester Acrylates
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Thermal initiator | 78-67-1 | A104256 | 2,2′-Azobisisobutyronitrile (AIBN) | Recrystallized, ≥99% | Used in research on free-radical polymerization of unsaturated polyesters, acrylates, and vinyl monomers; suitable for experiments on double-bond curing reactions and crosslinked network formation. |
Photoinitiator | 119-61-9 | Benzophenone | Suitable for synthesis | Used in free-radical photocuring systems; a hydrogen-abstraction photoinitiator that usually needs to be used with an amine synergist or another hydrogen donor; suitable for studying photocuring reactions of polyester acrylates. | |
Peroxide initiator | 1338-23-4 | Methyl ethyl ketone peroxide | Active oxygen content 9% | Used for room-temperature or low-to-medium-temperature curing of unsaturated polyesters; suitable for studying initiator dosage, curing speed, and exothermic behavior. | |
Reactive diluent | 100-42-5 | Styrene | CP, contains 10–15 ppm 4-tert-butylcatechol as stabilizer | Used for free-radical crosslinking of unsaturated polyester resins; suitable for resin dilution, copolymerization curing, and adjustment of crosslink density. | |
Peroxide initiator | 94-36-0 | Benzoyl peroxide (BPO) | AR | Used for free-radical initiation in unsaturated polyester, acrylate, and styrene systems; suitable for thermal curing reactions and polymerization kinetics studies. | |
Photoinitiator | 119313-12-1 | 2-Benzyl-2-dimethylamino-1-(4-morpholinophenyl)butanone | ≥98% (HPLC) | Used in ultraviolet curing systems; suitable for photocuring studies of polyester acrylates, colored coatings, and thick films. | |
Photoinitiator | 947-19-3 | 1-Hydroxycyclohexyl phenyl ketone | ≥98% | Used in polyester acrylate photocuring systems; suitable for transparent coatings, clearcoats, and rapid surface curing studies. | |
Photoinitiator | 7473-98-5 | 2-Hydroxy-2-methylpropiophenone | ≥97% | Used in free-radical photocuring systems; suitable for studying surface drying, curing speed, and photoinitiation efficiency of polyester acrylate coating films. | |
Photoinitiator | 75980-60-8 | Diphenyl(2,4,6-trimethylbenzoyl)phosphine oxide | ≥97% | Used in ultraviolet curing systems; suitable for deep-curing studies of polyester acrylate thick films and colored systems. | |
Photoinitiator | 162881-26-7 | Phenylbis(2,4,6-trimethylbenzoyl)phosphine oxide (BAPO) | ≥97% | Used in free-radical photocuring systems; suitable for polyester acrylate thick films, pigmented systems, and high-crosslink-density coatings. | |
Hydroxy acrylate monomer | 818-61-1 | H104535 | 2-Hydroxyethyl acrylate | ≥96%, contains 200–600 ppm MEHQ as inhibitor | Used to synthesize hydroxy acrylic resins and polyester acrylate-modified materials; suitable for hydroxyl reaction studies and research on introducing photocurable double bonds. |
Difunctional acrylate monomer | 13048-33-4 | 1,6-Hexanediol diacrylate (HDDA), stabilized with MEHQ | ≥90% | Used as a reactive diluent and crosslinking component in polyester acrylate photocuring systems; can adjust coating-film hardness, shrinkage, and curing speed. | |
Trifunctional acrylate monomer | 15625-89-5 | Trimethylolpropane triacrylate | ≥85%, contains 600 ppm MEHQ as stabilizer | Used for multifunctional crosslinking in polyester acrylate photocuring systems; suitable for high-crosslink-density, high-hardness, and chemical-resistant coating-film studies. |
Note: The above are representative Aladdin products. For more product specifications, search by “product name/CAS/catalog number” on the Aladdin 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] allnex. Amino Crosslinkers: Technologies.
[3] allnex. TGIC & HAA Polyester Resins for Powder Coating.
[4] UBE Corporation. Trixene® Blocked Isocyanates.
[5] Powder Coating Institute. Technology Interchange: Polyester Powder Coatings: TGIC vs. HAA.
[6] EMS-Griltech. Primid® Crosslinkers for Powder Coatings.
[7] Soucek, M. D.; Khattab, T.; Wu, J. Review of Autoxidation and Driers. Progress in Organic Coatings, 2012, 73, 435–454.
[8] Rolph, M. S.; Markowska, A. L. J.; Warriner, C. N.; O’Reilly, R. K. Blocked Isocyanates: From Analytical and Experimental Considerations to Non-Polyurethane Applications. Polymer Chemistry, 2016, 7, 7351–7364.
[9] Duran, J.; et al. Free-Radical Photopolymerization for Curing Products for Refinish Coatings Market. Polymers, 2022, 14, 2856.
For more related articles, see below.
Formulation Design and Selection of Amine Curing Agents in Epoxy Systems
Understanding Amine Curing Agents: Structure, Types, and Application Selection
