How Do Isocyanates and Polyols Affect the Performance of Polyurethane Coating Films: Structure, Raw Material Selection, and Performance Design Essentials
How Do Isocyanates and Polyols Affect the Performance of Polyurethane Coating Films: Structure, Raw Material Selection, and Performance Design Essentials
Introduction
The performance of polyurethane (PU) coating films originates first and foremost from the structure of the raw materials.
In polyurethane systems, isocyanates and polyols are the two most essential classes of raw materials. Isocyanates provide isocyanate groups, namely NCO groups, —N=C=O, while polyols provide hydroxyl groups, namely OH groups, —OH. The reaction between NCO and OH forms urethane linkages, which constitute the fundamental chemical basis for the formation of polyurethane structures.
R-NCO + R′-OH → R-NH-COO-R′
When analyzing the performance of polyurethane coating films, the following factors should be further considered:
1. Which type of isocyanate is used;
2. Which type of polyol is used;
3. The functionality, molecular weight, structural rigidity, and polarity of the raw materials;
4. The soft/hard segment structure and crosslinked structure formed after combining the raw materials.
Raw Material | Main Function |
Isocyanate | Determines reaction activity, crosslinking capability, hardness, yellowing tendency, and weather resistance |
Polyol | Determines flexibility, hydrolysis resistance, abrasion resistance, chemical resistance, hand feel, and film-forming characteristics |
Chain extender | Adjusts hard segment content, segment regularity, and mechanical strength |
Crosslinking polyol or polyisocyanate | Increases network density and affects hardness, solvent resistance, and chemical resistance |
1. Isocyanates Determine the Reactive Ends and Hard Segment Characteristics of Polyurethane
Isocyanates are among the important reactive raw materials in polyurethane systems. Their core function is to provide NCO groups, which react with hydroxyl groups, amino groups, water, and other active-hydrogen-containing groups. In coatings, isocyanates not only determine reaction activity, but also affect coating film hardness, crosslink density, weather resistance, yellowing tendency, and chemical resistance.
1.1 From the Perspective of Structural Type: Aromatic and Aliphatic Isocyanates Differ Significantly
Common isocyanates used in coatings can be classified into aromatic isocyanates, aliphatic isocyanates, and cycloaliphatic isocyanates.
Type | Common Examples | Structural Characteristics | Effect on Coating Film Performance |
Aromatic isocyanates | TDI, toluene diisocyanate; MDI, diphenylmethane diisocyanate | Contain benzene rings and have relatively strong structural rigidity | High reactivity, good hardness and strength, but yellowing resistance and outdoor weatherability are usually not their advantages |
Aliphatic isocyanates | HDI, hexamethylene diisocyanate | Linear aliphatic structure | Good weather resistance, gloss retention, and color retention; commonly used in high-weatherability coating systems |
Cycloaliphatic isocyanates | IPDI, isophorone diisocyanate; HMDI, hydrogenated MDI | Contain cycloaliphatic structures and combine rigidity with weather resistance | Help improve weather resistance, hardness, and chemical resistance; reactivity is generally lower than that of aromatic isocyanates |
Because aromatic isocyanates contain aromatic rings, they usually have relatively high reactivity and strong rigidity, but they are more prone to yellowing under light exposure. Aliphatic and cycloaliphatic isocyanates are generally more suitable for coating film systems requiring high weather resistance, gloss retention, and color retention.
2. Isocyanate Functionality and NCO Content Affect the Crosslinked Structure
Functionality refers to the number of functional groups in a molecule that can participate in reactions. For isocyanates, provided that the NCO/OH equivalents are properly matched, the reaction proceeds sufficiently, and the system is capable of forming a network structure, higher functionality is more conducive to forming more branched structures or crosslinking points. As the number of crosslinking points increases, the coating film typically exhibits higher hardness, solvent resistance, and chemical resistance, but flexibility, impact resistance, and application tolerance may decrease.
Isocyanate Characteristic | Typical Effect on Coating Film |
Difunctional isocyanate | Mainly forms linear or lightly branched structures, which is beneficial for flexibility |
Polyfunctional isocyanate | Helps form crosslinked networks and improves hardness and chemical resistance |
Higher NCO content | Indicates more reactive NCO equivalents per unit mass, but must be matched with hydroxyl content, functionality, and the target NCO/OH equivalent ratio |
Stronger structural rigidity | Beneficial for hardness and heat resistance, but may reduce flexibility |
In coating formulations, what is commonly used is usually not free low-molecular-weight diisocyanate monomers, but rather polyisocyanate curing agents, isocyanurate trimers, biurets, uretdiones, or prepolymers. These structures can reduce free monomer content and volatile exposure risks, while also providing viscosity, reactivity, and crosslinking capability more suitable for coating applications. It should be noted that NCO-containing isocyanate products still need to be handled, ventilated, protected, stored, and managed in accordance with SDS requirements.
3. Polyols Determine the Flexibility and Main Body Performance of Polyurethane
Polyols are another core class of raw materials in polyurethane structures. Compared with isocyanates, polyols have a more direct influence on coating film flexibility, elasticity, hand feel, hydrolysis resistance, abrasion resistance, and chemical resistance. If isocyanates mainly determine the reactive ends and crosslinking characteristics, then polyols mainly determine the main body performance of polyurethane coating films.
The influence of polyols mainly comes from the following factors: backbone structure; molecular weight; hydroxyl value; functionality; polarity and crystallinity; and glass transition temperature.
4. Polyester Polyols: Improving Strength, Adhesion, and Chemical Resistance
Polyester polyols are usually obtained through polycondensation of polyacids and polyols. Their structures contain ester bonds and show strong intermolecular interactions, which tend to provide polyurethane with good mechanical strength, adhesion, abrasion resistance, oil resistance, and chemical resistance.
Performance Direction | Effect of Polyester Polyols |
Hardness | Usually helps increase hardness |
Mechanical strength | Usually good |
Adhesion | Strong polarity is beneficial for adhesion |
Abrasion resistance | Usually good |
Oil resistance and chemical resistance | Usually good |
Hydrolysis resistance | Hydrolysis stability should be considered for conventional polyester structures |
Polyester-based polyurethane coatings are widely used in automotive, industrial, architectural, and plastic coatings, mainly because of their good mechanical properties, adhesion, oil resistance, and chemical resistance. However, conventional polyester polyols contain ester bonds in their structures and may undergo hydrolysis under humid-heat or strongly alkaline conditions. Therefore, when used in systems requiring high hydrolysis resistance, more hydrolysis-resistant polyester structures should be selected, or other polyol structures should be used instead.
5. Polyether Polyols: Improving Flexibility and Hydrolysis Resistance
Polyether polyols contain ether bonds in the main chain and have relatively flexible chain segments. Compared with conventional polyester polyols, polyether polyols generally provide better low-temperature flexibility and hydrolysis resistance.
Performance Direction | Effect of Polyether Polyols |
Flexibility | Usually good |
Low-temperature performance | Usually good |
Hydrolysis resistance | Usually better than conventional polyester polyols |
Elasticity | Usually good |
Mechanical strength | Should be evaluated together with structure and degree of crosslinking |
Oil resistance and solvent resistance | Usually inferior to highly polar polyester or polycarbonate structures |
Polyether-based polyurethane is suitable for systems requiring flexibility, elasticity, and hydrolysis resistance. However, if the coating film requires higher hardness, oil resistance, or stain resistance, reinforcement is usually needed through isocyanate structure design, crosslinking design, or blending with other resins. The key advantage of polyether polyols lies in their significant value in flexibility and hydrolysis resistance.
6. Polycarbonate Polyols: Improving Hydrolysis Resistance, Weather Resistance, and Abrasion Resistance
Polycarbonate polyols are a class of high-performance polyols whose backbones contain carbonate structures. Compared with conventional polyester and polyether polyols, polycarbonate polyols are generally conducive to improving the hydrolysis resistance, mechanical strength, heat resistance, and durability of polyurethane. However, weather resistance, abrasion resistance, and chemical media resistance still need to be comprehensively evaluated together with the isocyanate type, hard segment structure, crosslink density, and additive system.
Performance Direction | Effect of Polycarbonate Polyols |
Hydrolysis resistance | Usually good |
Weather resistance | Usually good |
Abrasion resistance | Usually good |
Heat resistance | Usually good |
Mechanical strength | Usually good |
Cost | Usually higher than conventional polyester and polyether polyols |
Polycarbonate polyols are commonly used in polyurethane systems with high durability requirements. In actual formulations, however, whether to select polycarbonate polyols should be comprehensively judged according to performance targets, cost requirements, and application conditions.
7. Acrylic Polyols: Improving the Balance of Appearance, Weather Resistance, and Hardness
Acrylic polyols are hydroxyl-containing acrylic resins that commonly react with polyisocyanates to form crosslinked polyurethane coating films. Compared with polyester or polyether polyols, acrylic polyols are generally more favorable for coating film gloss, fullness, color retention, hardness, and chemical resistance. Their performance depends on the acrylic monomer composition, hydroxyl value, acid value, glass transition temperature, and molecular weight.
Structural Factor | Main Influence |
Hydroxyl value | Affects the number of crosslinkable sites and the network density after curing |
Glass transition temperature | Affects hardness, flexibility, and film-forming characteristics |
Monomer composition | Affects weather resistance, adhesion, chemical resistance, and cost |
Molecular weight | Affects viscosity, film formation, drying behavior, and mechanical properties |
8. Chain Extenders and Low-Molecular-Weight Polyols Affect the Hard Segment Ratio
In addition to polymeric polyols, polyurethane systems often use low-molecular-weight diols, diamines, or polyfunctional alcohols as chain extenders or crosslinking components. Among them, diamines mainly form urea bonds when reacting with NCO groups, so strictly speaking, they introduce polyurethane-urea structures. The main function of chain extenders is not to independently provide film-forming properties, but to adjust the hard segment ratio, segment regularity, and intermolecular interactions.
Chain Extender Influence Factor | Effect on Coating Film Performance |
Increased dosage | Increases the hard segment ratio; hardness and strength may increase |
Increased structural rigidity | Beneficial for hardness, heat resistance, and deformation resistance |
Increased functionality | Helps increase crosslink density |
Excessive dosage | May cause the coating film to become brittle, reduce flexibility, or make film formation difficult |
The influence of chain extenders on polyurethane performance should be considered together with the isocyanate type, polyol molecular weight, and overall hydroxyl content.
9. Hydroxyl Value, Functionality, and Molecular Weight Are Key Indicators for Polyol Selection
When selecting polyols, it is not enough to consider only the polyol type; specific indicators must also be evaluated. Even for polyols of the same type, differences in hydroxyl value, molecular weight, and functionality can lead to significant differences in the final coating film performance.
9.1 Hydroxyl Value
Hydroxyl value indicates the hydroxyl group content in a polyol and is commonly expressed in mg KOH/g. The higher the hydroxyl value, the more OH groups per unit mass of polyol are available to participate in the reaction. For reactive polyurethane systems, hydroxyl value affects formulation calculations, crosslink density, hardness, chemical resistance, and coating film brittleness.
Change in Hydroxyl Value | Possible Effect |
Higher hydroxyl value | More crosslinking points; hardness and chemical resistance may increase |
Lower hydroxyl value | Longer chain segments; flexibility may improve |
Excessively high hydroxyl value | May cause the coating film to become too hard, brittle, or shorten the application window |
Excessively low hydroxyl value | May lead to insufficient crosslinking and reduced solvent resistance and chemical resistance |
9.2 Functionality
The higher the functionality, the more branched or crosslinked structures a polyol can form. Difunctional polyols tend to form linear chain segments, while polyfunctional polyols are more likely to form crosslinked networks.
Functionality | Structural Tendency | Effect on Coating Film |
Difunctional | Mainly linear chain segments | Beneficial for flexibility and elasticity |
Trifunctional and above | Increased branching or crosslinking | Beneficial for hardness, solvent resistance, and chemical resistance |
Excessively high functionality | Network becomes too dense | May increase brittleness |
9.3 Molecular Weight
The molecular weight of a polyol affects soft segment length and chain segment mobility. A higher molecular weight is usually beneficial for flexibility and elasticity, while a lower molecular weight provides more reactive sites per unit mass and more readily forms coating films with higher hardness and higher crosslink density.
Change in Molecular Weight | Possible Effect |
Higher molecular weight | Better flexibility, elasticity, and low-temperature performance |
Lower molecular weight | Hardness, strength, and chemical resistance may increase |
Broader molecular weight distribution | May affect viscosity, application properties, and film-forming uniformity |
10. Raw Material Combinations Determine Coating Film Performance
The effects of isocyanates and polyols on polyurethane performance are not simply additive. Actual coating film performance comes from the structural result formed by combining the two. For example:
Raw Material Combination | Coating Film Performance Tendency |
Aliphatic isocyanate + acrylic polyol | Beneficial for weather resistance, gloss and color retention, hardness, and appearance |
Aliphatic isocyanate + polycarbonate polyol | Beneficial for weather resistance, hydrolysis resistance, abrasion resistance, and durability |
Aromatic isocyanate + polyester polyol | Beneficial for hardness, strength, and cost control, but yellowing should be considered |
Cycloaliphatic isocyanate + polyether polyol | Beneficial for flexibility, elasticity, and a certain degree of weather resistance |
High-hydroxyl-value polyol + high-functionality polyisocyanate | Beneficial for hardness and chemical resistance, but brittleness should be considered |
High-molecular-weight polyol + low-crosslinking structure | Beneficial for flexibility and elasticity, but solvent resistance may be limited |
The performance of polyurethane coating films cannot be judged from a single raw material alone. The correct approach is to consider the following factors together: isocyanate type; polyol type; functionality; hydroxyl value, NCO content, and NCO/OH equivalent ratio; molecular weight; soft/hard segment ratio; and crosslinked structure.
11. Different Performance Targets Correspond to Different Raw Material Design Directions
Performance design for polyurethane coating films should work backward from the target performance to the raw material structure.
Target Performance | Raw Material Design Direction |
Improve hardness | Select structures with stronger rigidity, higher-hydroxyl-value polyols, or higher-functionality components |
Improve flexibility | Select higher-molecular-weight polyols, flexible chain segments, or lower-crosslink-density structures |
Improve weather resistance | Prefer aliphatic or cycloaliphatic isocyanates, combined with polyols that offer good weather resistance |
Improve hydrolysis resistance | Select polyether, polycarbonate, or hydrolysis-resistant modified polyester polyols |
Improve abrasion resistance | Use an integrated design based on hard segment structure, crosslink density, and abrasion-resistant polyols |
Improve chemical resistance | Increase crosslink density and select backbone structures with better solvent resistance and chemical resistance |
Improve hand feel and elasticity | Select flexible chain segments and control the hard segment ratio and crosslink density |
Improve appearance and gloss | Select resin structures with good compatibility, stable color, and uniform film formation |
It should be noted that different performance properties often restrict one another. High hardness does not necessarily bring high flexibility; high crosslinking does not necessarily improve impact resistance; and highly weather-resistant raw materials may not meet the lowest-cost requirement. The key to polyurethane formulation design is to find a reasonable balance among target properties, rather than pursuing the maximization of a single performance indicator.
12. Product Classification Tables Related to Performance Control of Polyurethane Coating Films Based on Isocyanate–Polyol Systems — Tables 1–4
Table 1. Isocyanate Curing Agents and Hard Segment Structure Sources
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Aliphatic diisocyanate | 822-06-0 | Hexamethylene diisocyanate (HDI) | Moligand™, ≥99% | Used for preparing weather-resistant polyurethane coating films, aliphatic polyurethane elastic coatings, HDI trimers, and biuret curing agents; suitable for studies on NCO/OH ratio, crosslink density, flexibility, and yellowing resistance. | |
Aliphatic polyisocyanate curing agent | 4035-89-6 | 1,3,5-Tris(6-isocyanatohexyl)biuret | NCO content: 21–22.5% | Used in two-component polyurethane clearcoats, industrial protective coatings, and elastic coating curing systems; related to studies on high-functionality NCO sources, crosslinked film formation, solvent resistance, and abrasion resistance. | |
Aliphatic isocyanurate curing agent | 3779-63-3 | 1,3,5-Tris(6-isocyanatohexyl)-1,3,5-triazinane-2,4,6-trione | ≥95% | Used in HDI trimer-type polyurethane curing systems; suitable for studies on coating film hardness, weather resistance, chemical media resistance, crosslinked network structure, and transparent coating performance. | |
Aliphatic HDI uretdione / latent isocyanate structure | 23501-81-7 | 1,3-Bis(6-isocyanatohexyl)-1,3-diazetidine-2,4-dione | — | Used for HDI uretdione-structure curing agents, thermally activated polyurethane coating films, and low-free-monomer systems; related to storage stability, latent curing, thermal dissociation behavior, and coating film crosslinking behavior. | |
Cycloaliphatic diisocyanate | 4098-71-9 | Isophorone Diisocyanate (mixture of isomers) (IPDI) | ≥99% | Used in weather-resistant polyurethane dispersions, elastic coatings, and transparent coating curing systems; suitable for studies on asymmetric NCO reactivity, hard segment structure, yellowing resistance, and mechanical balance. | |
Cycloaliphatic diisocyanate | 5124-30-1 | Dicyclohexylmethane 4,4′-Diisocyanate (mixture of isomers) (HMDI) | ≥90% (GC) | Used in cycloaliphatic polyurethane coating films, weather-resistant elastic coatings, and waterborne polyurethane prepolymers; related to studies on hard segment regularity, light stability, flexibility, and water resistance. | |
Aromatic diisocyanate | 26471-62-5 | Tolylene Diisocyanate (2,4, 2,6) (TDI) | ≥98% (GC) | Used in aromatic polyurethane coating films, prepolymers, elastomers, and adhesive coatings; suitable for studies on NCO reaction rate, hard segment content, coating film strength, abrasion resistance, and yellowing behavior. | |
Aromatic diisocyanate | 91-08-7 | Tolylene-2,6-diisocyanate | ≥98% | Used for comparing the reactivity of TDI isomers, constructing polyurethane hard segments, and studying coating film curing kinetics, microphase separation, and mechanical properties. | |
Aromatic diisocyanate | 101-68-8 | 4,4′-MDI (MDI) | ≥98% | Used in high-strength polyurethane coating films, elastomers, prepolymers, and reactive coatings; related to studies on rigid hard segments, tensile strength, adhesion, abrasion resistance, and crosslinked structures. | |
Polymeric aromatic polyisocyanate | 9016-87-9 | Polymethylene polyphenyl polyisocyanate | NCO content ~30%; viscosity ~200 mPa·s (25 °C) | Used in highly crosslinked aromatic polyurethane systems, hard coatings, adhesives, and composite material coatings; suitable for studies on high NCO content, network densification, hardness, and chemical resistance. | |
Araliphatic diisocyanate | 3634-83-1 | m-Xylylene Diisocyanate (MXDI) | ≥98% (GC) | Used in polyurethane coating films combining aromatic ring rigidity with aliphatic NCO reaction characteristics; related to studies on transparency, adhesion, hardness, and media resistance. | |
Hindered araliphatic diisocyanate | 2778-42-9 | 1,3-Bis(2-isocyanato-2-propyl)benzene | ≥97% (GC) | Used in low-yellowing araliphatic polyurethane coating films, reactivity-control systems, and elastic coating research; related to sterically hindered NCO groups, pot life, hard segment structure, and weather resistance. |
Table 2. Polyether, Polyester, and Natural Oil Polyol Soft Segment Sources
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Hydrophilic polyether / PEO-type soft segment source | 25322-68-3 | Poly(ethylene oxide) | Viscosity 65–115 cps | Used in hydrophilic polyurethane coating films, waterborne polyurethane modification, and water-absorbing breathable coating studies; related to flexibility, hydrophilicity, ion migration, and surface wetting behavior. When the hydrophilic segment content is high, coating film water resistance should be considered. | |
Polyether diol soft segment | 25322-69-4 | Poly(propylene glycol) (PPG) | Average molecular weight 4000 | Used in flexible polyurethane coating films, elastic coatings, and low-glass-transition-temperature soft segment systems; suitable for studies on chain segment mobility, resilience, hydrolysis resistance, and phase separation. | |
Polyester diol soft segment | 36890-68-3 | Polycaprolactone diol | Average Mₙ 10,000 | Used in highly flexible polyester-type polyurethane coating films, elastomer coatings, and bio-related coating studies; related to crystalline soft segments, abrasion resistance, oil resistance, and mechanical reinforcement. | |
Polyether diol soft segment | 25190-06-1 | Polytetramethylene Ether Glycol (PTHF) | Average Mₙ ~2900 | Used in highly elastic polyurethane coating films, low-temperature-resistant coatings, and abrasion-resistant elastomer systems; suitable for studies on soft segment regularity, tensile recovery, hydrolysis resistance, and microphase separation. | |
Natural oil polyol | 8001-79-4 | Castor oil | Chemically pure (CP) | Used in bio-based polyurethane coating films, flexible protective coatings, and crosslinked alkyd-modified systems; related to studies on hydroxyl functionality, hydrophobicity, flexibility, and adhesion. |
Table 3. Low-Molecular-Weight Polyols, Chain Extenders, Crosslinkers, Hydrophilic Monomers, and Polymerizable Hydroxyl Monomers
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Linear diol chain extender | 110-63-4 | 1,4-Butanediol (BDO) | Anhydrous, ≥99% | Used for polyurethane hard segment chain extension, elastic coating films, and prepolymer post-chain-extension studies; related to hard segment regularity, tensile strength, abrasion resistance, crystallinity, and coating film toughness. | |
Trifunctional crosslinking polyol | 56-81-5 | Glycerol | Anhydrous, UltraBio™, molecular biology grade, ≥99.5% (GC) | Used for trifunctional polyurethane crosslinked networks, branched polyol synthesis, and coating film crosslink density adjustment; related to hardness, water resistance, adhesion, and gel content studies. | |
Short-chain diol chain extender | 107-21-1 | Ethylene glycol | Anhydrous, ≥99.8% | Used for short-chain hard segment construction, polyurethane coating film chain extension, and polyester polyol synthesis; related to studies on hardness, modulus, solvent resistance, and hydrogen bond density. | |
Hydroxy methacrylate monomer | 868-77-9 | 2-Hydroxyethyl methacrylate (HEMA) | Anhydrous, ≥99%, contains 200 ppm MEHQ stabilizer, water ≤0.1% | Used in UV-curable polyurethane acrylates, waterborne polyurethane grafting, and hydroxyl-reactive modification; related to studies on photocuring crosslinking, adhesion, and scratch resistance. | |
Ether-type diol chain extender | 111-46-6 | Diethylene glycol | UltraBio™, ultrapure, ≥99% (GC) | Used in flexible polyurethane chain extension, polyester polyol synthesis, and coating film toughness adjustment; related to ether bond flexibility, low-temperature flexibility, and hydrolysis resistance studies. | |
Tetrafunctional crosslinking polyol | 115-77-5 | P103696 | Pentaerythritol | AR, ≥98% | Used for high-functionality polyurethane crosslinking, alkyd resin polyol construction, and high-hardness coating film studies; related to branched structures, crosslink density, solvent resistance, and heat resistance. |
Cycloaliphatic diol chain extender | 105-08-8 | 1,4-Cyclohexanedimethanol (CHDM) | ≥99%, mixture of cis and trans | Used in cycloaliphatic polyester polyols, weather-resistant polyurethane coating films, and highly transparent coating studies; related to rigid ring structures, heat resistance, hardness, and flexibility balance. | |
Hindered diol chain extender | 126-30-7 | Neopentyl glycol | ≥99% | Used in hydrolysis-resistant polyester polyols, polyurethane coating film chain extension, and powder coating resins; related to branched alkyl structures, water resistance, weather resistance, and coating film hardness. | |
Linear diol chain extender | 629-11-8 | 1,6-Hexanediol | ≥98% | Used in flexible polyurethane coating films, polyester polyol synthesis, and long-chain hard segment chain-extension studies; related to chain segment flexibility, crystallinity, abrasion resistance, and low-temperature performance. | |
Carboxylic acid-type internal emulsifying monomer | 10097-02-6 | 2,2-Bis(hydroxymethyl)butyric acid (DMBA) | ≥98% | Used in waterborne polyurethane internal emulsification, anionic prepolymers, and self-dispersing coating film studies; related to carboxyl content, particle size, dispersion stability, and water resistance. | |
Carboxylic acid-type internal emulsifying monomer | 4767-03-7 | 2,2-Bis(hydroxymethyl)propionic acid (DMPA) | ≥98% | Used in waterborne polyurethane dispersions, anionic hydrophilic chain extension, and waterborne coating film preparation; related to emulsion stability, solids content, film formation, and adhesion studies. | |
Trifunctional crosslinking chain extender | 77-99-6 | 1,1,1-Tris(hydroxymethyl)propane | ≥98% | Used for branched crosslinking in polyurethane coating films, hydroxyl components of two-component coatings, and prepolymer modification; related to network density, hardness, chemical resistance, and scratch resistance. | |
Hydroxy methacrylate monomer | 27813-02-1 | Hydroxypropyl methacrylate (HPMA) | ≥97%, contains 0.02% 4-methoxyphenol stabilizer | Used in polyurethane acrylates, hydroxyl acrylic resins, and photocurable coating film studies; related to hydroxyl reactions, free-radical copolymerization, adhesion, and water resistance. | |
Hydroxy acrylate monomer | 2478-10-6 | 4-Hydroxybutyl Acrylate (4HBA) | ≥97% (GC), contains MEHQ stabilizer | Used in flexible polyurethane acrylates, hydroxyl-reactive acrylic resins, and photocurable coatings; related to flexible chain segments, crosslinking reactions, adhesion, and impact resistance. | |
Hydroxy acrylate monomer | 818-61-1 | H104535 | 2-Hydroxyethyl acrylate | ≥96%, contains 200–600 ppm MEHQ as inhibitor | Used in hydroxyl acrylic resins, polyurethane acrylates, and waterborne coating film modification; related to NCO reaction grafting, photocuring activity, hardness, and adhesion. |
Hydroxy acrylate monomer | 25584-83-2 | Hydroxypropyl Acrylate (mixture of 2-Hydroxypropyl and 2-Hydroxy-1-methylethyl Acrylate) | ≥90% (GC), contains MEHQ stabilizer | Used in hydroxyl acrylic resins, polyurethane acrylates, and waterborne polyurethane graft modification; related to flexibility, photocuring reactions, water resistance, and adhesion. |
Table 4. Polyester Polyols, Alkyd Resins, and Structure-Regulating Monomers
Category | CAS No. | Aladdin Cat. No. | Name | Specification or Purity | Product Features and Applications |
Aromatic anhydride monomer | 85-44-9 | o-Phthalic anhydride | Premium reagent, ≥99% | Used in the synthesis of alkyd resins, aromatic polyester polyols, and hydroxyl resins for polyurethane coatings; related to coating film hardness, adhesion, solvent resistance, and drying performance. | |
Aliphatic dicarboxylic acid monomer | 124-04-9 | Adipic acid | Pharmaceutical grade, PharmPure™, ≥99.6% | Used in aliphatic polyester polyols, flexible polyurethane coating films, and elastic coating studies; related to soft segment flexibility, low-temperature resistance, and abrasion resistance. Hydrolysis stability should be comprehensively improved through diol structure, hydrophobic modification, and formulation design. | |
Aromatic dicarboxylic acid monomer | 121-91-5 | Isophthalic acid | AR, ≥99% | Used in chemical-resistant polyester polyols, hydroxyl resins for polyurethane coatings, and high-hardness coating film studies; related to aromatic ring rigidity, heat resistance, water resistance, and adhesion. | |
Cyclic ester monomer | 502-44-3 | ε-Caprolactone | ≥99% | Used in polycaprolactone polyol synthesis, flexible polyurethane coating films, and degradable polyurethane material studies; related to ring-opening polymerization, crystalline soft segments, abrasion resistance, and elasticity. | |
Aromatic dicarboxylic acid monomer | 100-21-0 | Terephthalic acid (PTA, benzene-1,4-dicarboxylic acid) | ≥99% | Used in high-rigidity polyester polyols, hydroxyl resins for polyurethane coatings, and heat-resistant coating film studies; related to linear aromatic structures, hardness, chemical resistance, and dimensional stability. |
Safety Note: Isocyanates and polyisocyanates are highly reactive and may cause irritation to the skin, eyes, nose, throat, and respiratory tract. They may also pose risks of respiratory or skin sensitization and occupational asthma. Experiments, formulation work, and spraying operations involving free NCO groups should be carried out under good ventilation or local exhaust conditions, and appropriate gloves, goggles, protective clothing, and respiratory protection should be used in accordance with the product SDS.
Note: The products listed above are representative Aladdin products. For more product specifications, please search by product name, CAS number, or catalog number on the Aladdin website.
References
[1] SpecialChem. Polyurethane Paint & Coatings: Uses, Chemistry, Process & Formulation.
[2] Wang, H.; Cao, L.; Wang, X.; Lang, X.; Cong, W.; Han, L.; Zhang, H.; Zhou, H.; Sun, J.; Zong, C. Effects of Isocyanate Structure on the Properties of Polyurethane: Synthesis, Performance, and Self-Healing Characteristics. Polymers, 2024, 16(21), 3045.
[3] Covestro. Polyisocyanates and Prepolymers.
[4] Zhang, Z.; Ni, N.; Xu, Y. Effects of Different Polyols with Functions on the Properties of Polyester Polyol-Based Polyurethane Coatings. Coatings, 2025, 15(1), 61.
[5] SpecialChem. Polyester Polyols for Water-Resistant Polyurethane Coatings.
[6] Liu, N.; Zhao, Y.; Kang, M.; Wang, J.; Wang, X.; Feng, Y.; Yin, N.; Li, Q. The Effects of the Molecular Weight and Structure of Polycarbonatediols on the Properties of Waterborne Polyurethanes. Progress in Organic Coatings, 2015, 82, 46–56.
[7] Tran, K.; Liu, Y.; Soleimani, M.; Lucas, F.; Winnik, M.A. Waterborne 2-Component Polyurethane Coatings Based on Acrylic Polyols with Secondary Alcohols. Progress in Organic Coatings, 2024, 190, 108374.
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