Technical articles

Understanding Polyester Resins for Coatings: Structure Design, Key Indicators, and Coating Film Performance

1. The Intrinsic Relationship Between Polyester Resin Structure and Coating Film Performance

 

In a coating system, the resin is the primary film-forming material that forms a continuous coating film. Pigments, fillers, additives, solvents, or aqueous media can affect application, leveling, appearance, storage stability, and certain end-use properties. However, the hardness, flexibility, adhesion, chemical resistance, weatherability, and hydrolysis resistance of the coating film are first and foremost closely related to the chemical structure of the resin itself.

 

Polyester resins are widely used in industrial coatings, coil coatings, powder coatings, packaging coatings, metal finishing, and some polyurethane coating systems because they offer strong structural design flexibility. By selecting different acid components, alcohol components, functional groups, molecular weights, glass transition temperatures, and branching structures, different balances can be achieved among hardness, flexibility, adhesion, chemical resistance, weatherability, hydrolysis resistance, and application performance.

 

To understand polyester resins for coatings, it is necessary to understand the following logic:

 

 Why changing the structure of the acid or alcohol component changes the hardness, flexibility, and chemical resistance of the coating film;

 

 Why resins that are all called polyester resins can differ significantly: some are suitable for post-forming, some for high-hardness coatings, and some for outdoor weather-resistant systems;

 

 Why polyester resins usually have good adhesion and flexibility, yet still require attention to hydrolysis resistance and alkali resistance;

 

 Why judging whether a polyester resin is suitable for a coating system cannot be based on the resin name alone, but must consider acid value, hydroxyl value, Tg, molecular weight, viscosity, degree of branching, and curing system.

 

The core value of polyester resins for coatings is not to maximize a single property, but to achieve a balanced combination of properties through molecular structure design.

 

2. What Is a Polyester Resin for Coatings?

 

Polyester resin is a class of polymers whose main chain contains ester bonds. It is typically prepared by polycondensation of polycarboxylic acids, polyacid anhydrides, or their derivatives with polyols. Its core structural unit can be simplified as:—C(=O)–O—

 

—CO–O— is the ester bond. Ester bonds give polyester resins a certain polarity, an adhesion basis, and structural tunability. At the same time, they also make polyesters susceptible to hydrolysis under water, acid, alkali, or high-temperature and high-humidity conditions.

 

Polyester resins for coatings are different from polyester materials used in plastics. Plastic-grade polyesters, such as polyethylene terephthalate, usually emphasize melt processing, mechanical strength, dimensional stability, and crystallinity. Polyester resins for coatings, by contrast, place greater emphasis on film formation, leveling, adhesion, flexibility, curing reactivity, and overall coating film performance.

 

Typical polyester resins for coatings are mostly low- to medium-molecular-weight film-forming resins that contain reactive functional groups such as hydroxyl or carboxyl groups and have appropriate viscosity. Depending on the functional groups and application methods, polyester resins for coatings may include hydroxyl-functional polyesters, carboxyl-functional polyesters, waterborne polyesters, polyesters for powder coatings, and polyesters for coil coatings. This article focuses on the structure–property relationship of saturated polyester resins commonly used in coatings.

 

3. Which Structural Factors Determine Polyester Resin Performance?

 

The performance of polyester resins for coatings is not determined by a single factor, but by the combined effect of multiple structural variables.

 

Structural factor

Main meaning

Main influence

Ester bonds and main-chain structure

Basic backbone of the polyester

Affects polarity, adhesion, hydrolysis resistance, and structural design space

Acid components

Aromatic acids, aliphatic acids, cycloaliphatic acids, and anhydrides

Affect rigidity, flexibility, chemical resistance, and durability

Alcohol components

Diols, triols, and other polyols

Affect flexibility, hydrolysis resistance, branching degree, and viscosity

Reactive functional groups

Hydroxyl and carboxyl groups; unsaturated double bonds are mainly used in free-radical curing systems such as unsaturated polyesters or polyester acrylates

Determine curing reactivity, crosslink density, and adhesion

Molecular weight and distribution

Resin chain length and distribution range

Affect viscosity, leveling, mechanical strength, and application adaptability

Tg

Glass transition temperature, reflecting segmental mobility

Affects hardness, blocking resistance, flexibility, and storage stability

Linear or branched structure

Whether the molecular chain contains branches

Affects flowability, reactivity, film fullness, and crosslinking ability

Curing system

Reaction with amino resins, isocyanates, TGIC, HAA, etc.

Determines the final crosslinked network and coating film performance

 

These factors are not simply additive. For example, increasing resin rigidity is usually beneficial for hardness, heat resistance, and some aspects of chemical resistance, but it may reduce bending, impact resistance, and post-forming performance. Increasing functional group content can enhance curing reactivity, but may also increase system viscosity, polarity, and water absorption tendency. The essence of polyester resin design is to balance multiple structural factors.

 

4. Ester Bonds: The Source of Polyester Advantages and Hydrolysis Risk

 

The ester bond is the most important structural unit in polyester resins. It gives the resin a certain polarity, enabling polyester to provide good wetting and interaction with metals, pretreated substrates, some polar plastic substrates, and pigments and fillers. This is one of the important reasons why polyester resins usually show good adhesion.

 

Ester bonds also provide a broad structural design space. By changing the acid and alcohol components connected on both sides of the ester bond, the rigidity or flexibility, polarity, hydrophobicity, weatherability, chemical resistance, and hydrolysis resistance of the molecular chain can be adjusted.

 

However, ester bonds also bring an issue that must be taken seriously: hydrolysis risk. Hydrolysis refers to the cleavage of ester bonds under the action of water, acid, alkali, or other media, resulting in a decrease in resin molecular weight or damage to the crosslinked structure of the coating film. Waterborne polyesters, especially amine-neutralized systems, require particular attention to ester-bond hydrolysis under slightly alkaline conditions. Hydrolysis of ester bonds may lead to gloss loss, whitening, blistering, adhesion loss, reduced coating film strength, and even reduced stability of aqueous dispersions.

 

Effect brought by ester bonds

Influence on coating performance

Certain polarity

Helps wetting, pigment/filler dispersion, and adhesion

Structure can be adjusted through acid/alcohol monomers

Helps design different levels of hardness, flexibility, and durability

Can form rigid or flexible segments

Helps balance mechanical properties

Can hydrolyze under specific conditions

Requires attention to water resistance, humidity and heat resistance, alkali resistance, and storage stability

 

5. How Acid Components Affect Hardness, Flexibility, and Chemical Resistance

 

Acid components are an important source of the polyester resin main chain and directly affect the rigidity, flexibility, chemical resistance, and durability of the resin backbone. Common acid components include aromatic dibasic acids, aliphatic dibasic acids, cycloaliphatic dibasic acids, and anhydrides.

 

5.1 Aromatic Acids: Improving Rigidity, Hardness, and Heat Resistance

 

Common aromatic acids or anhydrides include terephthalic acid, isophthalic acid, and phthalic anhydride.

 

Aromatic structures contain benzene rings, which have strong molecular rigidity and restrict polymer chain segment movement. Therefore, introducing aromatic acids usually helps improve the rigidity, Tg, hardness, heat resistance, stain resistance, and certain aspects of chemical resistance of polyester resins. For industrial baking enamels, metal coatings, some powder coatings, and high-hardness coatings, aromatic structures are often an important way to increase coating film rigidity.

 

However, when the proportion of aromatic structures is too high, the coating film may become brittle, and flexibility, impact resistance, and post-forming performance may decrease. For coil coatings, stamped-part coatings, packaging coatings, and other systems requiring bending, hemming, stamping, or forming, excessive rigidity increases the risk of cracking.

 

It should be noted that aromatic structures do not necessarily mean “inherently weather-resistant.” Aromatic acids have a clear role in improving rigidity and heat resistance, but outdoor weatherability also depends on the specific monomer structure, curing system, pigments and fillers, UV stabilization system, and coating film density. Weatherability cannot be judged based solely on the presence of aromatic structures.

 

5.2 Aliphatic Acids: Improving Flexibility and Impact Performance

 

Aliphatic dibasic acids such as adipic acid contain relatively flexible carbon-chain structures. Introducing such structures into the polyester main chain can increase segmental mobility, giving the coating film better flexibility, impact resistance, bending performance, and low-temperature toughness. The higher the proportion of aliphatic segments, the more likely the resin is to show softness, low Tg, and good processability. However, if there are too many flexible segments, coating film hardness, blocking resistance, stain resistance, and solvent resistance may decrease.

 

5.3 Cycloaliphatic Acids: Providing a Balance Among Rigidity, Low Yellowing, and Durability

 

Cycloaliphatic structures are intermediate between rigid aromatic structures and flexible aliphatic structures. Cycloaliphatic monomers represented by 1,4-cyclohexanedicarboxylic acid (1,4-CHDA) and 1,4-cyclohexanedimethanol (CHDM) do not contain benzene-ring conjugated structures. They can provide a design space different from that of aromatic monomers in terms of low color, yellowing control, hardness/flexibility balance, and durability such as chemical resistance, humidity and heat resistance, and hydrolysis resistance. However, the specific effects still depend on isomer composition, acid/alcohol ratio, resin molecular weight, and curing system.

 

Cycloaliphatic monomers can be used in polyester systems requiring a balance of hardness, flexibility, low color, chemical resistance, and hydrolysis resistance. They provide polyester design with a structural option different from aromatic acids and aliphatic acids, allowing the resin to achieve a new balance among rigidity, segmental mobility, and durability.

 

6. How Alcohol Components Affect Hydrolysis Resistance, Flexibility, and Application Performance

 

Polyols are another important structural source for polyester resins. They affect not only molecular-chain flexibility, but also hydrolysis resistance, weatherability, branching degree, viscosity, and application performance.

 

6.1 Neopentyl Glycol: Improving Hydrolysis Resistance and Overall Durability

 

Neopentyl glycol (NPG) is an important diol commonly used in polyester resins for coatings. NPG has a neopentyl structure and relatively large steric hindrance. Polyester structures formed with NPG generally help improve hydrolysis resistance, humidity and heat resistance, chemical stability, and overall durability. Therefore, NPG is often used in the structural design of polyester polyols for industrial coatings, powder coatings, coil coatings, and polyurethane coatings. The role of NPG can be summarized as follows:

 

 It helps improve the hydrolysis resistance of polyester structures;

 It improves coating film water resistance, humidity and heat resistance, and chemical stability;

 It helps achieve a balance between hardness and flexibility;

 It is suitable for the structural design of weather-resistant and highly durable polyester resins.

 

The final hydrolysis resistance, weatherability, and chemical resistance of polyester resins also depend on acid component selection, acid value control, resin molecular weight, hydroxyl value or functionality design, crosslinking completeness, pigment/filler system, coating film density, and actual service environment.

 

6.2 Flexible Diols: Improving Bending, Impact, and Low-Temperature Toughness

 

Diols such as diethylene glycol, 1,6-hexanediol, and 1,5-pentanediol usually help lower Tg and improve coating film bending performance, impact resistance, and low-temperature toughness. Short-chain and regular diols such as ethylene glycol and 1,4-butanediol may increase polarity, segment regularity, or crystallization tendency. Their influence on flexibility, hardness, and water resistance must be judged together with the acid component and the overall formulation.

 

The proportion of flexible diols must be controlled. When there are too many flexible segments, resin Tg decreases, and the coating film may show insufficient hardness, poor blocking resistance, reduced stain resistance, or inadequate chemical resistance. Flexible diols are important for coil coatings, packaging coatings, and post-formable metal coatings. However, for high-hardness, high-stain-resistance, or high-solvent-resistance systems, they must be used in combination with rigid monomers and crosslinking design.

 

6.3 Trifunctional Alcohols: Increasing Branching Degree and Crosslinking Potential

 

Trimethylolpropane (TMP) is a common triol used in polyester resins for coatings. TMP contains three hydroxyl groups and can introduce branching points into the polyester structure, increasing the average functionality of the resin and its subsequent crosslinking potential.

 

Moderate introduction of TMP helps improve coating film hardness, fullness, crosslinking density, chemical resistance, and solvent resistance. It also helps high-solids systems maintain certain reactivity at relatively low molecular weight. However, if the TMP dosage is too high or the branching degree is not properly controlled, resin viscosity may increase significantly, affecting leveling, application performance, and storage stability. In severe cases, it may also increase the risk of gelation during synthesis.

 

7. How Functional Groups Determine Curing Reactions and Crosslinked Networks

 

Polyester resins for coatings usually contain reactive functional groups. Common functional groups include hydroxyl groups, carboxyl groups, and unsaturated double bonds. Functional groups determine whether the resin can participate in subsequent crosslinking reactions, and they also affect adhesion, compatibility, curing speed, and final coating film performance.

 

7.1 Hydroxyl Groups: Determining the Crosslinking Reactivity of Hydroxyl-Functional Polyesters

 

Hydroxyl groups can react with amino resins, isocyanates, blocked isocyanates, or other suitable curing agents to form crosslinked structures. Hydroxyl content is usually expressed as hydroxyl value, generally in mg KOH/g.

 

The higher the hydroxyl value, the more hydroxyl groups are usually available per unit mass of resin to participate in crosslinking. The curing-agent ratio and crosslink density design must therefore be adjusted accordingly. The influence of hydroxyl groups on coating film performance is mainly reflected in the following:

 

 Improving crosslinking reactivity;

 Enhancing interaction with polar substrates;

 Improving the basis for adhesion;

 Affecting system polarity, viscosity, and compatibility;

 Affecting final crosslink density and coating film compactness.

 

More hydroxyl groups are not always better. Excessive hydroxyl content may lead to overly strong system polarity, increased water absorption, higher viscosity, or reduced application adaptability. A reasonable hydroxyl value must be determined according to curing-agent type, curing conditions, application method, and target performance.

 

7.2 Carboxyl Groups: Determining the Reactivity and Water Dispersibility of Carboxyl-Functional Polyesters

 

Carboxyl groups can increase resin polarity and adhesion, and can also act as reactive functional groups in crosslinking. Carboxyl content is usually expressed as acid value, generally in mg KOH/g.

 

For powder coatings, carboxyl-functional polyesters commonly react with triglycidyl isocyanurate (TGIC), β-hydroxyalkylamide (HAA), or other curing agents to form crosslinked networks. TGIC and HAA are both common curing routes for polyester powder coatings. HAA reacts with carboxyl groups while releasing water; therefore, in thick films, systems with insufficient degassing, or unsuitable curing windows, attention should be paid to differences in pinhole risk, water resistance, and chemical resistance.

 

Acid value must be balanced among reactivity, dispersibility, and water resistance. If the acid value is too low, there may be insufficient carboxyl reaction sites, or inadequate neutralization and dispersibility in waterborne systems. If the acid value is too high, resin hydrophilicity and water absorption tendency increase, and coating film water resistance, humidity and heat resistance, and chemical stability may decline.

 

7.3 Unsaturated Double Bonds: Suitable for Free-Radical Curing Systems

 

Unsaturated double bonds can participate in free-radical reactions, allowing the resin to form a crosslinked network. Unsaturated polyesters and polyester acrylates often use this characteristic to form cured coating films.

 

However, the reaction mechanism, curing speed, oxygen inhibition, volumetric shrinkage, and formulation design of unsaturated polyesters and polyester acrylates are different from those of conventional hydroxyl-functional and carboxyl-functional polyesters. Therefore, when discussing conventional saturated polyester resins for coatings, the performance logic of unsaturated polyesters should not be directly applied to all polyester systems.

 

8. How Molecular Weight, Tg, and Branching Structure Affect Application and Coating Film Performance

 

Acid components, alcohol components, and functional groups determine the chemical basis of polyester resins, while molecular weight, Tg, and branching structure further determine the resin’s application adaptability and coating film performance.

 

8.1 Molecular Weight: Affecting Viscosity, Leveling, and Mechanical Strength

 

Molecular weight is an important structural parameter of polyester resins. Generally speaking, as molecular weight increases, chain entanglement becomes stronger, and coating film strength and toughness may improve. However, viscosity also increases, and leveling, high-solids application performance, and sprayability may decrease.

 

When molecular weight is too low, resin viscosity is low, and application and leveling are easier, but coating film mechanical strength, solvent resistance, and durability may be insufficient. When molecular weight is too high, coating film strength may improve, but application viscosity increases, and appearance and leveling may be affected.

 

Molecular weight level

Common characteristics

Lower molecular weight

Low viscosity, easier to increase solids content, good leveling, but coating film strength may be insufficient

Medium molecular weight

Good balance among film formation, application, and mechanical properties

Higher molecular weight

Better mechanical strength and toughness, but higher viscosity

Broad molecular weight distribution

More complex application and coating film performance; must be judged together with viscosity and curing system

 

8.2 Tg: Affecting Hardness, Blocking Resistance, Flexibility, and Storage Stability

 

Glass transition temperature, abbreviated as Tg, is an important indicator for evaluating resin segmental mobility. When Tg is high, the resin is closer to a glassy state at room temperature, and the coating film usually shows higher hardness, better blocking resistance, and better stain resistance. When Tg is low, resin segments move more easily, and the coating film is usually more flexible, with better bending and impact performance.

 

Higher Tg

Lower Tg

Higher hardness

Better flexibility

Better blocking resistance

Better low-temperature toughness

Better stain resistance

Lower film-formation stress

Bending performance may decrease

Surface hardness may be insufficient

Coating film may be more brittle

Blocking resistance may decrease

 

Tg is not simply “the higher the better” or “the lower the better.” For powder coatings, an excessively low Tg may cause storage caking. For coil coatings that require post-forming, an excessively high Tg may cause cracking during bending. A reasonable Tg depends on the application scenario, application method, curing system, and target performance.

 

8.3 Linear and Branched Structures: Affecting Flow, Fullness, and Crosslinking Ability

 

Polyester resins can have either linear or branched structures.

 

Linear polyester molecular chains are relatively regular and usually have good flexibility, flowability, and processing adaptability. Coil coatings, packaging coatings, and metal coatings requiring post-forming usually place greater emphasis on bending, impact, and forming performance, and therefore often require linear or moderately branched structures.

 

Branched polyesters contain branch structures introduced by multifunctional monomers. Moderate branching can increase average functionality, increase the number of crosslinking points, and improve hardness, fullness, chemical resistance, and solvent resistance. However, excessive branching increases resin viscosity and affects leveling, application performance, and storage stability.

 

Structure type

Advantages

Risks

Linear polyester

Good flexibility, good leveling, good processing performance

Hardness and chemical resistance may be insufficient

Moderately branched polyester

Relatively strong reactivity and good overall performance

Viscosity and storage stability must be controlled

Highly branched polyester

High functionality and high crosslinking potential

Higher viscosity, more difficult leveling and application

 

9. Explaining Core Coating Film Properties from Structure

 

The performance of polyester coating films is not determined by a single structural factor alone, but by the combined effects of resin structure, curing system, pigments and fillers, additives, application method, and substrate condition. Resin structure provides the performance foundation, while formulation and processing determine the final performance.

 

Coating film property

Main structural source

Risks requiring attention

Adhesion

Polar structures such as ester bonds, hydroxyl groups, and carboxyl groups; good wetting; complete curing

Substrate contamination, insufficient pretreatment, excessive internal stress, or overly high polarity causing reduced water resistance

Flexibility

Aliphatic flexible segments, suitable molecular weight, low or moderate Tg, suitable crosslink density

Hardness, blocking resistance, stain resistance, and solvent resistance may decrease

Hardness

Aromatic or cycloaliphatic structures, higher Tg, higher crosslink density

Coating film may become brittle; impact, bending, and post-forming performance may decrease

Chemical resistance

Stable backbone, dense crosslinking, low water absorption, suitable curing system

Ester-bond hydrolysis risk under strong alkali, high temperature and humidity, or long-term water-vapor exposure

Hydrolysis resistance

Sterically hindered monomers, low hydrophilicity, reasonable acid value, good crosslinking

Excessive acid value, alkaline environment, or improper storage conditions for waterborne systems may increase risk

Weatherability

Stable monomers, low-yellowing structures, weather-resistant pigments and fillers, light stabilization system, dense coating film

Outdoor weathering grade cannot be judged based only on the name “polyester”

Application performance

Molecular weight, viscosity, solids content, branching degree, solvent or waterborne system design

Excessive viscosity affects leveling; excessively low molecular weight affects coating film strength

 

10. Structural Design Trade-Offs in Different Application Scenarios

 

The value of polyester resins lies in performance balance. Different coating applications have different requirements for resin structure, and it is not appropriate to judge all resins by the same set of indicators.

 

Application scenario

Key performance requirements

Polyester structure design focus

Coil coatings

Bending, stamping, adhesion, weatherability, no cracking after post-forming

Moderate Tg, reasonable flexible segments, good adhesion and curing completeness, weather-resistant monomers when necessary

Powder coatings

Storage stability, melt leveling, curing reaction, mechanical properties, and weatherability

Control Tg, acid value or hydroxyl value, branching degree, and curing-agent matching, such as carboxyl polyester/TGIC, carboxyl polyester/HAA, hydroxyl polyester/blocked isocyanate systems

Packaging coatings

Adhesion, flexibility, media resistance, processing resistance, and regulatory suitability

Focus on flexibility, media resistance, low migration risk, and complete curing

Industrial baking coatings

Hardness, appearance, chemical resistance, application efficiency

Hydroxyl-functional polyesters are often cured with amino resins or isocyanates; balance Tg, viscosity, and crosslink density

Metal protective coatings

Adhesion, corrosion resistance, humidity and heat resistance, chemical resistance

Require the combined effect of resin polarity, coating film density, pigment/filler system, and substrate pretreatment

Outdoor weather-resistant coatings

Gloss and color retention, anti-chalking, humidity and heat resistance, stain resistance

Select stable monomers, control yellowing-prone structures, and combine with weather-resistant pigments and light stabilization systems

 

For example, coil coatings emphasize post-forming performance, so the resin must not be too brittle. Powder coatings emphasize storage stability and melt leveling, making Tg and viscosity control very important. Packaging coatings emphasize flexibility, media resistance, and regulatory suitability. Industrial baking coatings focus more on hardness, appearance, chemical resistance, and application efficiency. Excellent polyester resin design does not maximize one property to an extreme, but allocates structural factors reasonably according to application requirements.

 

11. Understanding Technical Indicators of Polyester Resins

 

Technical indicator

Representative meaning

Main influence

Key points for judgment

Acid value, AV

Carboxyl group content

Reactivity, water dispersibility, adhesion, water resistance

Must be judged together with resin type and curing system

Hydroxyl value, OHV

Hydroxyl group content

Curing-agent ratio, crosslink density, hardness, solvent resistance

Not the higher the better; polarity, viscosity, and water absorption must be controlled

Tg

Segmental mobility

Hardness, blocking resistance, flexibility, storage stability

Requirements differ among powder coatings, coil coatings, and industrial baking coatings

Molecular weight

Resin chain length and entanglement degree

Viscosity, leveling, mechanical strength, film formation

Must be judged together with solids content and application method

Viscosity

Resin flow and application adaptability

Spraying, roll coating, leveling, appearance

Affected by temperature, solvent, waterborne system, and solids content

Solids content

Nonvolatile content

VOC emissions, application efficiency, film-thickness control

Must be judged together with viscosity and application window

Average functionality

Average number of reactive functional groups per molecule

Crosslinking ability, hardness, chemical resistance, curing speed

Must be judged together with acid value, hydroxyl value, and molecular weight

Residual acid or low-molecular-weight substances

Unreacted or residual small-molecule components

Storage stability, odor, water resistance, humidity and heat resistance

Especially important for waterborne, packaging, and high-durability systems

 

To judge whether a polyester resin is suitable for a coating system, the following questions should be considered at the same time:

 

 Is the resin hydroxyl-functional, carboxyl-functional, or another reactive type?

 Is the curing-agent type compatible?

 Are the acid value, hydroxyl value, and average functionality suitable for the target crosslink density?

 Is Tg suitable for storage, application, and service temperature?

 Are molecular weight and viscosity suitable for the target application method?

 Does resin polarity balance adhesion and water resistance?

 Does the monomer structure meet weatherability, chemical resistance, or post-forming requirements?

 Can the curing conditions form a complete and stable crosslinked network?

 

12. Summary of the Structure–Property Relationship

 

The performance of polyester resins for coatings comes from the synergistic effects of ester bonds, acid components, alcohol components, functional groups, molecular weight, Tg, linear or branched structures, and curing systems.

 

Structure design direction

Common performance change

Increasing aromatic structures

Improves hardness, heat resistance, and some aspects of chemical resistance, but flexibility and post-forming performance may decrease

Increasing aliphatic flexible segments

Improves flexibility, impact performance, and low-temperature toughness, but hardness and stain resistance may decrease

Introducing cycloaliphatic structures

Helps balance rigidity, low yellowing, chemical resistance, and durability

Using sterically hindered diols such as NPG

Helps improve hydrolysis resistance, humidity and heat resistance, and overall durability

Increasing hydroxyl value or acid value

Increases reactive sites, but water absorption, viscosity, and storage stability must be controlled

Increasing molecular weight

Improves mechanical strength and toughness, but viscosity increases

Increasing Tg

Improves hardness and blocking resistance, but flexibility may decrease

Moderate branching

Improves reactivity, film fullness, and coating film density, but excessive branching affects leveling and application

 

13. Classification Tables of Representative Monomers and Additives Related to Structure–Property Research of Polyester Resins for Coatings

 

Table 1. Rigid Acid Components, Aromatic/Cycloaliphatic Anhydrides, and Special Durability-Oriented Structural Monomers

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or Purity

Product Features and Applications

Aromatic anhydrides

85-44-9

P116466

Phthalic anhydride

Premium grade reagent, ≥99%

Introduces phthalate structures to adjust resin polarity, adhesion, hardness, and coating film fullness. Suitable for synthetic experiments involving saturated polyesters, alkyd resins, and coating resins.

Aromatic dibasic acids

121-91-5

I104311

Isophthalic acid (IPA)

AR, ≥99%

Introduces isophthalic structures to improve polyester backbone rigidity, heat resistance, chemical resistance, and coating film hardness. Suitable for research on powder coatings, coil coatings, and durable polyester resins.

Cycloaliphatic dibasic acids

1076-97-7

C100837

1,4-Cyclohexanedicarboxylic acid (CHDA)

≥99%, mixture of cis- and trans-

Introduces cycloaliphatic dicarboxylic acid structures, helping balance rigidity, flexibility, low yellowing, and hydrolysis resistance. Suitable for the design of weather-resistant polyesters, waterborne polyesters, and powder coating resins.

Aromatic tetrafunctional anhydrides

89-32-7

P109616

Pyromellitic dianhydride (PMDA)

≥99%

Provides a high-functionality aromatic anhydride structure and can be used for exploratory research on high-heat-resistant, highly branched, or crosslinked structures. In conventional saturated coating polyesters, it should be used at low levels and with caution to avoid excessively high viscosity, uncontrolled branching, or gelation risk.

Aromatic dicarboxylate esters

120-61-6

D106859

Dimethyl terephthalate

≥99%

Serves as a terephthalate-structured diester monomer for polyester synthesis via transesterification, improving resin rigidity, heat resistance, and mechanical strength. Suitable for experiments on coating polyester synthesis processes and structural regulation.

Aromatic dibasic acids

100-21-0

P108506

Terephthalic acid (PTA)

≥99%

Introduces terephthalic acid structures to improve polyester main-chain rigidity, Tg, hardness, and heat resistance. Suitable for research on high-hardness powder coatings, industrial baking coatings, and chemically resistant polyester resins.

Heteroaromatic dibasic acids

3238-40-2

F119129

2,5-Furandicarboxylic acid (FDCA)

≥98%

Introduces furandicarboxylic acid structures, providing rigidity, a bio-based structural source, and relatively high polarity. Suitable for research on sustainable polyesters, coil coating polyesters, and structural replacement in coating resins. During application, attention should be paid to color, solvent compatibility, synthesis temperature, molecular weight, and crystallization risk at high usage levels.

Cycloaliphatic anhydrides

85-42-7

C124721

1,2-Cyclohexanedicarboxylic anhydride

≥97%, cis + trans

Introduces cycloaliphatic anhydride structures to adjust polyester hardness, flexibility, yellowing resistance, and coating film appearance. Suitable for synthetic experiments involving cycloaliphatic polyesters, weather-resistant coatings, and low-color resins.

Aromatic trifunctional anhydrides

552-30-7

B104832

Trimellitic anhydride

≥97%

Provides an aromatic trifunctional anhydride structure that can introduce branching points and carboxyl-reactive sites, improving crosslinking potential, hardness, and chemical resistance. Suitable for research on carboxyl-functional polyesters, powder coating resins, and branched polyesters.

 

Table 2. Flexible Aliphatic Acid Components, Unsaturated Acid Components, and Ring-Opening Polyester Monomers

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or Purity

Product Features and Applications

Aliphatic dibasic acids

124-04-9

A108267

Adipic acid

Pharmaceutical grade, PharmPure™, ≥99.6%

Introduces flexible aliphatic diacid segments to improve polyester flexibility, impact performance, and bending performance. Suitable for research on coil coatings, packaging coatings, and post-formable polyester resins.

Unsaturated dibasic acids

97-65-4

I106140

Itaconic acid

Chemically pure (CP), ≥99%

Provides unsaturated double bonds and carboxyl structures for introducing reactive sites and expanding resin functionalization possibilities. Suitable for experiments on unsaturated polyesters, bio-based polyesters, and modified coating resins.

Long-chain aliphatic dibasic acids

111-20-6

S108452

Sebacic acid

Chemically pure (CP), ≥98%

Introduces long-chain flexible diacid structures, lowering resin Tg and improving coating film flexibility, low-temperature toughness, and impact resistance. Suitable for research on flexible polyesters and elastic coating resins.

Aliphatic dibasic acids

110-15-6

S431423

Succinic acid

Moligand™, suitable for synthesis

Introduces short-chain aliphatic diacid structures to adjust polyester flexibility, polarity, and bio-based structural content. Suitable for comparative experiments on biodegradable polyesters, coating polyesters, and resin structures.

Long-chain aliphatic dibasic acids

123-99-9

A108440

Azelaic acid

Moligand™, industrial grade, ≥85% (GC)

Introduces long-chain aliphatic diacid structures to improve coating film flexibility, impact resistance, and low-temperature performance. Suitable for research on flexible polyesters, bend-resistant coatings, and modified resins.

Unsaturated anhydrides

108-31-6

M116389

Maleic anhydride

AR, ≥99% (GC)

Introduces cis-unsaturated anhydride structures, providing double bonds and carboxyl-reactive sites. Suitable for research on unsaturated polyesters, modified polyesters, and free-radical-curable coating resins.

Unsaturated dibasic acids

110-17-8

F110742

Fumaric acid

≥99.5%

Introduces trans-unsaturated diacid structures, improving the reactivity and segment rigidity of unsaturated polyesters. Suitable for research on free-radical-curable resins, modified polyesters, and crosslinked networks.

Lactone ring-opening monomers

502-44-3

C109521

ε-Caprolactone

≥99%

Introduces polycaprolactone flexible segments through ring-opening polymerization, improving polyester flexibility, low-temperature toughness, and film-forming elasticity. Suitable for research on flexible coating resins, polyurethane modification, and block polyesters.

 

Table 3. Diol Monomers for Segment Regulation

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or Purity

Product Features and Applications

Aliphatic diols

110-63-4

B1508458

1,4-Butanediol (BDO)

Anhydrous grade, ≥99%

Introduces linear aliphatic diol structures to adjust polyester flexibility, crystallization tendency, mechanical strength, and film-forming performance. Suitable for research on polyester polyols, coating resins, and elastic segments.

Short-chain diols

107-21-1

E119700

Ethylene glycol

Anhydrous grade, ≥99.8%

Introduces short-chain diol structures to improve polyester segment regularity, polarity, and hardness. Suitable for basic polyester synthesis, structural comparison, and coating resin performance research.

Aliphatic diols

504-63-2

P432773

1,3-Propanediol

Suitable for synthesis

Introduces three-carbon diol segments to adjust polyester flexibility, polarity, and bio-based structural content. Suitable for research on coating polyesters, flexible resins, and sustainable materials.

Side-group diols

57-55-6

P432968

1,2-Propanediol

Basic grade reagent, for preparation

Introduces diol structures containing a pendant methyl group to adjust polyester segment regularity, viscosity, flexibility, and resin solubility. Suitable for coating polyester synthesis and research on side-group effects.

Ether diols

111-46-6

D476199

Diethylene glycol

UltraBio™, ultrapure grade, ≥99% (GC)

Introduces ether bonds and flexible segments, lowering resin Tg and improving film-forming flexibility and low-temperature performance. Suitable for experiments on flexible polyesters, coating resins, and structural regulation of waterborne systems. Ether bonds and relatively high hydrophilicity may affect water resistance, humidity and heat resistance, and chemical resistance, so the dosage should be controlled.

Long-chain aliphatic diols

629-11-8

H103708

1,6-Hexanediol

≥98%

Introduces six-carbon flexible diol segments to improve polyester flexibility, water resistance, impact performance, and film toughness. Suitable for research on flexible polyesters, polyurethane coatings, and bend-resistant coatings.

Sterically hindered diols

126-30-7

N103689

Neopentyl glycol (NPG)

≥99%

Introduces neopentyl sterically hindered structures to improve polyester hydrolysis resistance, humidity and heat resistance, chemical resistance, and hardness/flexibility balance. Suitable for research on powder coatings, coil coatings, and weather-resistant polyester resins.

Bio-based rigid diols

652-67-5

I157515

Isosorbide

≥98% (GC)

Introduces bicyclic rigid diol structures to improve polyester Tg, hardness, heat resistance, and bio-based content. Suitable for research on high-Tg polyesters, heat-resistant coating resins, and sustainable polyesters.

Side-group diols

2163-42-0

M141411

2-Methyl-1,3-propanediol

≥98%

Introduces branched aliphatic diol structures to adjust resin viscosity, flexibility, water resistance, and application adaptability. Suitable for research on high-solids polyesters, coil coatings, and industrial baking coating resins.

Aliphatic diols

111-29-5

P105588

1,5-Pentanediol

≥97%

Introduces five-carbon flexible diol segments to adjust polyester flexibility, low-temperature toughness, and film-forming performance. Suitable for research on flexible coating polyesters, polyester polyols, and structural comparison experiments.

Cycloaliphatic diols

105-08-8

C105684

1,4-Cyclohexanedimethanol (CHDM)

≥99%, mixture of cis and trans

Introduces cycloaliphatic diol structures to adjust polyester segment rigidity, heat resistance, chemical resistance, low color, and hardness/flexibility balance. Suitable for research on high-solids polyesters, coil coatings, powder coatings, and weather-resistant coating resins.

 

Table 4. Multifunctional Branching Monomers, Waterborne Functional Monomers, and Special Hydroxyl Monomers

 

Category

CAS No.

Aladdin Cat. No.

Name

Specification or Purity

Product Features and Applications

Triol branching monomers

56-81-5

G755728

Glycerol

Anhydrous grade, UltraBio™, molecular biology grade, ≥99.5% (GC)

Provides trihydroxyl structures that can introduce branching points and multifunctional reactive sites, adjusting polyester crosslinking potential, viscosity, and coating film fullness. Suitable for synthetic experiments on branched polyesters and coating resins.

Tetraol branching monomers

115-77-5

P103696

Pentaerythritol (regulated explosive precursor)

AR, ≥98%

Provides tetrahydroxyl structures to increase polyester branching degree, average functionality, and crosslinking potential. Suitable for research on high-solids resins, branched polyesters, alkyd resins, and high-hardness coating films.

Trifunctional heat-resistant hydroxyl monomers

839-90-7

T162476

Tris(2-hydroxyethyl) isocyanurate (THEIC)

≥98% (N)

Introduces isocyanurate rings and polyhydroxyl structures to improve resin heat resistance, crosslinking potential, and coating film hardness. Suitable for research on heat-resistant polyesters, powder coatings, and highly durable coatings.

Waterborne functional diols

4767-03-7

B104539

2,2-Bis(hydroxymethyl)propionic acid (DMPA)

≥98%

Provides both hydroxyl and carboxyl structures, enabling the introduction of hydrophilic sites and neutralizable carboxyl groups. Suitable for research on waterborne polyesters, waterborne polyurethanes, dispersion stability, and acid value control.

Triol branching monomers

77-99-6

T110597

Trimethylolpropane (TMP)

≥98%

Provides trihydroxyl branching points to increase polyester average functionality, crosslink density, hardness, and solvent resistance. Suitable for research on high-solids polyesters, powder coating resins, and industrial baking coating resins.

Sulfonate hydrophilic monomers

6362-79-4

S115342

Sodium 5-sulfoisophthalate (5-SSIPA)

≥98%

Introduces sulfonate hydrophilic groups and isophthalic structures to improve polyester water dispersibility, ionic stability, and compatibility with pigments and fillers. Suitable for research on waterborne polyesters and water-dispersible coating resins.

Sulfonate dicarboxylate esters

3965-55-7

D101418

Dimethyl 5-sulfoisophthalate sodium salt

≥98%

Provides sulfonate hydrophilic structures and diester reactive sites for introducing ionic hydrophilic units via transesterification. Suitable for experiments on waterborne polyesters, water-dispersible resins, and hydrophilic modification.

 

Waterborne functional monomers such as DMPA, 5-SSIPA, and sulfonate dicarboxylate esters help improve water dispersibility and particle stability. However, excessive hydrophilic groups increase water absorption tendency and may reduce coating film water resistance, humidity and heat resistance, salt-spray resistance, and chemical resistance. Therefore, dispersion stability must be balanced with final durability.

 

Note: The above products are representative Aladdin products. More product specifications can be searched on the Aladdin website using the product name, CAS number, or catalog number.

 

References

 

[1] Wicks, Z. W.; Jones, F. N.; Pappas, S. P.; Wicks, D. A. Organic Coatings: Science and Technology. 3rd ed. Wiley, 2007.

 

[2] Chemical Dynamics. Fundamentals of Polyester Resins. 2020.

 

[3] Eastman Chemical Company. Eastman NPG Glycol Technical Data Sheet.

 

[4] Eastman Chemical Company. Improved Hydrolytic Stability of Waterborne Polyester Resins with Eastman 1,4-CHDA and Eastman TMPD Glycol.

 

[5] SI Analytics. Determination of Hydroxyl Value (DIN EN ISO 4629-2) and Acid Value (DIN EN ISO 2114).

 

[6] SpecialChem. Glass Transition Temperature of Coatings: Essential Concepts.

 

[7] allnex. TGIC Powder Coating and HAA Polyester Resins.

 

[8] Sherwin-Williams Coil Coatings. Metal Coating Comparison Guide.

 

[9] Koleske, J. V., ed. Paint and Coating Testing Manual: 15th Edition of the Gardner-Sward Handbook. ASTM International, 2012.

 

[10] allnex. Powder Coating Resins.

 

For more related articles, please see below.

 

A Panorama Guide to Synthetic Resins: Definitions & Polymerization Mechanisms, Classification Frameworks, Common Resins and Applications, Packaging Codes, and a Selection Roadmap (Tables 1–3)

Categories: Technical articles

Da — when not otherwise indicated, molecular weight units are daltons.   Mw — weight-average molecular weight.   Mn — number-average molecular weight.

Products are supplied for research and development use only. Not for use in humans, animals, diagnosis, or therapy.

Cite this article

Aladdin Scientific. "Understanding Polyester Resins for Coatings: Structure Design, Key Indicators, and Coating Film Performance" Aladdin Knowledge Base, updated May 27, 2026. https://www.aladdinsci.com/us_en/faqs/understanding-polyester-resins-for-coatings-en.html
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