1K, 2K, Waterborne, Moisture-Curing, and Blocked Systems: Classification Logic and Identification Methods for Polyurethane Coating Curing Systems
1K, 2K, Waterborne, Moisture-Curing, and Blocked Systems: Classification Logic and Identification Methods for Polyurethane Coating Curing Systems
Introduction
In polyurethane coatings, terms such as “1K, 2K, waterborne, moisture-curing, and blocked systems” are often compared side by side, but they do not belong to the same classification dimension. 1K and 2K describe packaging and application method; waterborne, solventborne, and solvent-free describe the dispersion medium or system form; moisture-curing, baking-curing, and blocked isocyanate systems describe the curing trigger or latent reaction mechanism.
To identify the curing system of a polyurethane coating, several questions should be answered in sequence:
Key Question | Corresponding Dimension |
Do two components need to be mixed before application? | Determines 1K / 2K |
In what medium are the resin or curing agent mainly dispersed? | Determines waterborne / solventborne / solvent-free |
Does film formation mainly rely on physical drying or chemical reaction? | Determines the film-forming and curing mechanism |
What condition triggers curing? | Determines room-temperature reaction / moisture-curing / thermal deblocking / self-crosslinking |
What establishes the final performance? | Determines the contribution of resin properties, crosslink density, and curing completeness |
The transformation of polyurethane coatings from a liquid or dispersed state into a continuous film usually involves solvent or water evaporation, particle coalescence, reactive crosslinking, and related processes. The final performance of the coating film largely depends on whether the drying and curing processes are sufficiently completed.
1. Start with the Classification Dimension: 1K/2K, Waterborne, and Moisture-Curing Are Not the Same Type of Concept
To understand polyurethane coating curing systems, the first basic point is to distinguish what 1K and 2K actually mean: they refer to whether two components need to be mixed before application.
Name | Meaning | Is Pre-Application Mixing Required? | Typical Description |
1K polyurethane | One-component polyurethane system | No on-site mixing of two components is required | The coating is supplied as a single-package system. After application, it may form a film or cure through water evaporation, moisture reaction, self-crosslinking, oxidative drying, or thermal deblocking. |
2K polyurethane | Two-component polyurethane system | Two components must be mixed in a specified ratio before application | Typically consists of Component A resin and Component B polyisocyanate curing agent. After mixing, chemical crosslinking occurs. |
1K indicates a single-package system, while 2K indicates a two-package system. They cannot be directly equated with waterborne, solventborne, moisture-curing, or baking-curing systems.
To avoid confusion, common names of polyurethane coatings can be divided into three dimensions:
Classification Dimension | Specific Terms | Main Question Answered by This Dimension |
Packaging and application method | 1K, 2K | Whether two components must be mixed before application |
Dispersion medium or system form | Waterborne, solventborne, solvent-free, high-solids | In what medium the resin or crosslinking component mainly exists |
Curing trigger | Room-temperature reaction, moisture-curing, baking-curing, blocked curing, self-crosslinking | What condition triggers film formation or crosslinking |
The following table makes this clearer:
Practical Term | Correct Interpretation |
Waterborne 1K polyurethane | Waterborne medium + single-package system |
Waterborne 2K polyurethane | Waterborne medium + two-component system that crosslinks after mixing |
Solventborne 2K polyurethane | Solventborne medium + two-component system that crosslinks after mixing |
1K moisture-curing polyurethane | Single-package system + curing triggered by moisture from air or substrate |
1K blocked isocyanate system | Single-package system + crosslinking after thermal deblocking |
Baking-curing polyurethane | Curing is promoted or triggered by heating; it may be a blocked isocyanate system or another thermosetting system |
2. Distinguishing Film Formation from Curing: Surface Dry Does Not Mean Fully Cured
In coatings, “film formation” and “curing” often occur simultaneously, but they have different meanings.
2.1 Film Formation
Film formation refers to the process in which a coating changes from a liquid, dispersed, or molten state into a continuous coating film. Common film-forming mechanisms include:
Film-Forming Method | Typical Systems |
Solvent evaporation | Solventborne coatings |
Water evaporation | Waterborne coatings |
Polymer particle coalescence | Waterborne polyurethane dispersions, acrylic emulsions |
Cooling after melt flow and leveling | Powder coatings, hot-melt systems |
Formation of a continuous network after reaction | Reactive polyurethane, epoxy, polyurea, and related systems |
2.2 Curing
Curing refers to chemical reactions occurring inside the coating film, causing molecular chain extension, branching, or crosslinking, thereby improving film strength, water resistance, solvent resistance, chemical resistance, and durability. Common curing reactions in polyurethane coatings include:
Curing Reaction | Typical Systems |
Reaction between isocyanate groups and hydroxyl groups | 2K polyurethane, baking-curing polyurethane |
Reaction between isocyanate groups and amine groups | Polyurea or polyurethane-polyurea systems |
Reaction between isocyanate groups and moisture | Moisture-curing polyurethane |
Thermal deblocking of blocked isocyanates followed by reaction | Blocked isocyanate systems |
Self-crosslinking or external crosslinking after film formation | Self-crosslinking PUD, waterborne 2K polyurethane, etc. |
“Dry” should not be simply equated with “fully cured.” Some coating films become surface-dry very quickly, while internal reactions continue. In some waterborne films, even after water has evaporated, water resistance, solvent resistance, and chemical resistance may still need to develop gradually through subsequent crosslinking or conditioning.
3. 2K Polyurethane: Mixed Before Application, Then Crosslinked by Reaction
2K is a common abbreviation for two-component systems in the coatings industry. Its core meaning is that two components must be mixed in a specified ratio before application. A typical 2K polyurethane coating consists of two components:
Component | Typical Composition |
Component A | Hydroxyl-containing resin, polyester polyol, acrylic polyol, polyurethane polyol, or other active-hydrogen-containing components |
Component B | Polyisocyanate curing agent, such as HDI trimer, HDI biuret, IPDI derivatives, etc. |
After the two components are mixed in the prescribed ratio before application, isocyanate groups react with hydroxyl groups, amine groups, or other active-hydrogen-containing groups to form a crosslinked coating film. In typical 2K PU coatings, the NCO–OH reaction is the main reaction, but in a broader sense, active-hydrogen-containing components are not limited to hydroxyl groups.
3.1 Main Characteristics of 2K Polyurethane
Item | Characteristics |
Packaging form | Two components stored separately |
Application method | Mixed in a specified ratio before use |
Curing mechanism | Chemical crosslinking occurs after mixing |
Application limitation | Pot life exists after mixing |
Performance characteristics | Generally higher crosslinking degree and higher potential performance ceiling |
Key control points | Mixing ratio accuracy, mixing uniformity, application temperature and humidity, pot life, film thickness, and curing/conditioning conditions |
3.2 Common Misunderstandings About 2K Polyurethane
① 2K does not mean solventborne.
2K only indicates two-component packaging and pre-application mixing. It does not mean the system must be solventborne. Waterborne 2K polyurethane systems also exist.
② 2K does not mean immediate full curing at room temperature.
A 2K polyurethane begins reacting after mixing, but full curing usually requires a certain amount of time. Surface dry, through dry, and final performance development are not completely synchronized.
③ 2K does not necessarily mean the best performance.
2K systems usually have high performance potential, but final performance still depends on resin structure, curing agent type, NCO/OH equivalent ratio, application conditions, and curing completeness.
4. 1K Polyurethane: Single-Package, but Not Limited to One Curing Mechanism
1K is a common abbreviation for one-component systems in the coatings industry. Its core meaning is that the resin and curing agent do not need to be mixed separately before application. However, 1K polyurethane does not represent one fixed curing mechanism. It may be a physically drying system, a moisture-curing system, a self-crosslinking system, an oxidative-drying system, or a blocked isocyanate baking-curing system.
Type of 1K Polyurethane | Film-Forming or Curing Mechanism | Main Characteristics |
Physically drying PUD | Film formation by particle coalescence after water evaporation | Easy to use, wide application window, performance mainly depends on the resin itself |
Self-crosslinking PUD | Internal crosslinking occurs after film formation | Single-package system; performance can continue to improve after film formation |
Moisture-curing polyurethane | Active NCO reacts with moisture from air or substrate | Single-package system; depends on humidity and moisture diffusion |
Blocked isocyanate system | Participates in crosslinking after thermal deblocking | Stable during storage at room temperature; usually requires baking |
Oxidative-drying PU or PU-modified system | Unsaturated structures undergo oxidative crosslinking with oxygen in air | Suitable for some 1K waterborne PU or PU-modified systems containing unsaturated structures; conventional PUDs generally do not rely on oxidative drying as the main film-forming or curing mechanism |
When evaluating a 1K PU system, it is still necessary to determine whether it is physically drying, moisture-curing, latently crosslinking, or thermally deblocked. All of these systems can be 1K, but their curing mechanisms, application control points, and final performance development are completely different.
5. Waterborne Polyurethane: “Waterborne” Describes the Medium, Not the Curing Mechanism
In waterborne polyurethane, the term “waterborne” means that water is used as the main dispersion medium, dilution medium, or continuous phase. It answers the question “in what medium does the system mainly exist,” rather than “how does the coating film cure.” Common forms of waterborne polyurethane include:
Type | Description |
Waterborne polyurethane dispersion | Commonly referred to as PUD, meaning polyurethane dispersion |
Waterborne 1K polyurethane coating | Usually does not require an externally added curing agent before application |
Waterborne 2K polyurethane coating | A water-dispersible or hydrophilically modified polyisocyanate curing agent is added before use |
Waterborne blocked isocyanate system | Relatively stable at room temperature; undergoes deblocking and crosslinking after heating |
Waterborne polyurethane hybrid system | Such as PU/acrylic, PU/epoxy, PU/silicone, and other hybrid systems |
PUDs typically form continuous films through water evaporation, particle approach, particle deformation, and coalescence. If the system contains self-crosslinking structures or an external crosslinker, further crosslinking may occur after film formation.
Waterborne systems are generally helpful in reducing VOCs and odor, but “waterborne” does not mean “VOC-free.” The actual VOC level still depends on cosolvents, coalescing agents, amine neutralizers, wetting and dispersing agents, and the overall formulation design.
5.1 Waterborne 1K Polyurethane
Waterborne 1K polyurethane is usually based on PUD and does not require the addition of an external curing agent before application. Its typical film-forming process is as follows:
Stage | Process |
1 | Water evaporation |
2 | Dispersed particles gradually approach each other |
3 | Particles deform and coalesce |
4 | A continuous film forms |
5 | Self-crosslinking or post-crosslinking occurs if required |
The advantages of waterborne 1K polyurethane include convenient application, low odor, and fewer pot-life restrictions. It is suitable for systems requiring application convenience, environmental friendliness, and on-site operational stability. However, the final performance of waterborne 1K polyurethane should not be evaluated only by surface-drying speed. Resin structure, soft/hard segment design, minimum film-forming temperature, drying conditions, conditioning time, and the presence or absence of a self-crosslinking mechanism should also be considered.
5.2 Waterborne 2K Polyurethane
Waterborne 2K polyurethane is usually composed of a waterborne hydroxyl-containing resin or dispersion and a water-dispersible or hydrophilically modified polyisocyanate curing agent. The two components are mixed before application, and crosslinking occurs in the waterborne environment after mixing. The key challenge of waterborne 2K polyurethane lies in balancing the reaction and film-forming processes.
Key Issue | Description |
Dispersibility of curing agent | The polyisocyanate must be sufficiently dispersed in the waterborne system |
Competing reactions | The NCO–OH reaction and the NCO–water reaction occur competitively |
Pot life | After mixing, system viscosity, reaction degree, and application properties change over time |
Matching of drying and crosslinking | Water evaporation, particle coalescence, and chemical crosslinking must be coordinated |
Early water resistance | If initial drying is insufficient or crosslinking is incomplete, early water resistance may be weak |
Final performance | Depends on crosslink density, curing completeness, and conditioning conditions |
6. Moisture-Curing Polyurethane: Reaction Involving Moisture from Air or Substrate
Moisture-curing polyurethane is usually a one-component system. It is commonly based on polyurethane prepolymers terminated with active NCO groups. After application, the NCO groups react with moisture from the air or substrate, further forming a cured coating film. The basic process of moisture curing is as follows:
Stage | Reaction Process |
1 | Water molecules attack isocyanate groups, forming unstable carbamic acid |
2 | Carbamic acid decomposes to form amine and carbon dioxide |
3 | The amine further reacts with isocyanate to form urea linkages |
4 | Under conditions such as excess NCO, catalysis, or elevated temperature, urea linkages may further react with NCO to form biuret structures and increase the degree of crosslinking |
This reaction mechanism is the key distinction between moisture-curing polyurethane and ordinary physically drying systems.
6.1 Main Characteristics of Moisture-Curing Polyurethane
Item | Characteristics |
Packaging form | Usually 1K |
Triggering condition | Moisture from air or substrate |
Main reaction | NCO reacts with water, further forming urea linkages and crosslinked structures |
Advantage | Single-package system; no mixing required before application |
Limitations | Strongly affected by humidity, film thickness, ventilation, temperature, and substrate moisture content |
Risks | CO₂ is generated during the reaction; thick films or improper moisture control may cause bubbles, pinholes, or insufficient internal curing |
Moisture-curing polyurethane does not simply form a film by solvent evaporation. Its curing quality depends on whether moisture can enter the coating film, whether NCO groups can react sufficiently, whether CO₂ can escape smoothly, and whether film thickness and environmental humidity are appropriate. Therefore, a moisture-curing system should not be judged only by surface-drying speed; sufficient internal curing must also be considered.
7. Blocked Isocyanate Systems: Stable at Room Temperature, Reactive After Heating
A blocked isocyanate temporarily “protects” isocyanate groups with a blocking agent, making them relatively stable toward hydroxyl groups, water, and other active-hydrogen-containing components at room temperature. When the temperature rises to a certain range, the blocked structure undergoes deblocking or regenerates reactive NCO groups, which then react with hydroxyl groups, amine groups, or other active-hydrogen-containing components to form a crosslinked network. The curing process of a blocked isocyanate system can be summarized as follows:
Stage | Process |
Room-temperature storage stage | NCO is blocked, and the system is relatively stable |
Heating stage | The blocked structure undergoes deblocking, exchange reaction, or regeneration of active NCO |
Reaction stage | NCO reacts with hydroxyl groups, amine groups, or other active-hydrogen-containing components |
Curing stage | A crosslinked coating film is formed |
7.1 Main Characteristics of Blocked Isocyanate Systems
Item | Characteristics |
Packaging method | Can be designed as a single-package system |
Storage stability | Relatively stable at room temperature |
Curing condition | Usually requires heating |
Application characteristics | Suitable for industrial baking coating processes |
Key control points | Deblocking temperature, baking temperature, baking time, catalyst, and completeness of crosslinking reaction |
Limitation | Not suitable for applications where heating is unavailable or low-temperature application is required |
The core value of blocked isocyanate systems is that they balance single-package storage stability with polyurethane crosslinking performance. However, they usually require baking conditions and are therefore more suitable for industrial coating systems with thermal curing capability. It should be noted that the deblocking temperature is not a fixed value; it is influenced by the type of blocking agent, isocyanate structure, catalyst, resin environment, and baking schedule.
8. Multidimensional Identification: Understanding the Actual System from the Product Name
The actual name of a polyurethane coating is usually not based on a single classification. Instead, it is composed of packaging method, medium type, and curing mechanism.
System Label | Main Dimension Described | Typical Meaning | Key Identification Point |
1K | Packaging and application method | Single-package system; no mixing of two components required before application | The curing mechanism cannot be determined from 1K alone. It is still necessary to determine whether it is physically drying, moisture-curing, self-crosslinking, or thermally cured. |
2K | Packaging and application method | Two-component system; must be mixed in a specified ratio before application | Typically involves the reaction of NCO with OH or other active-hydrogen-containing groups. Mixing ratio, mixing quality, pot life, and application conditions must be considered. |
Waterborne | Medium type | Uses water as the main dispersion medium, dilution medium, or continuous phase | Waterborne does not indicate one specific curing mechanism. It may be 1K or 2K. |
Moisture-curing | Curing trigger | Active NCO reacts with moisture from air or substrate | Humidity, film thickness, ventilation, moisture diffusion, and CO₂ release must be considered. |
Blocked isocyanate | Latent reaction mechanism | NCO is blocked and relatively stable at room temperature; after heating, it deblocks and crosslinks | Deblocking temperature, baking schedule, catalyst, and crosslinking completeness must be considered. |
Baking-curing | Curing process condition | Crosslinking reaction is promoted or triggered by heating | Baking-curing is not a single chemical category. It is necessary to further determine whether it is a blocked isocyanate system or another thermosetting system. |
Therefore, when encountering an actual product name, the name should be broken down and understood dimension by dimension.
Name | More Accurate Interpretation |
Waterborne 2K polyurethane | Waterborne medium + two-component packaging + crosslinking after mixing |
1K moisture-curing polyurethane | Single-package system + NCO reaction triggered by moisture from air or substrate |
Waterborne blocked isocyanate baking-curing system | Waterborne medium + blocked isocyanate + curing by thermal deblocking |
1K self-crosslinking PUD (Polyurethane Dispersion) | Single-package system + film formation by water evaporation + self-crosslinking after film formation |
Solventborne 2K polyurethane | Solventborne medium + two-component packaging + room-temperature reactive crosslinking |
9. Steps for Identifying the Curing System of a Polyurethane Coating
To determine which type of curing system a polyurethane coating belongs to, the following sequence can be used.
Step 1: Check the Packaging Method
Identification | Conclusion |
Two components need to be mixed before application | 2K |
No two-component mixing is required before application | 1K |
Only “1K” or “2K” is known | Only the application format can be identified; the curing mechanism cannot be directly determined |
Step 2: Check the Dispersion Medium
Identification | Conclusion |
Water is used as the main dispersion medium or diluent | Waterborne system |
Organic solvent is used as the main medium | Solventborne system |
The solvent content is very low or the system is essentially solvent-free | High-solids or solvent-free system; the reaction mechanism still needs to be further examined |
Step 3: Check the Main Curing Trigger
Triggering Condition | Possible System |
Reaction after mixing two components | 2K polyurethane |
Particle coalescence and film formation after water evaporation | Physically drying PUD |
Further internal crosslinking after film formation | Self-crosslinking or post-crosslinking PUD |
Moisture from air or substrate participates in the reaction | Moisture-curing polyurethane |
Deblocking and crosslinking after heating | Blocked isocyanate system |
Heating promotes the overall reaction | Baking-curing polyurethane or other thermosetting systems |
Step 4: Check How Final Performance Is Established
Performance Development Mechanism | Key Points for Identification |
Mainly relies on physical film formation | Resin structure, degree of particle coalescence, drying conditions |
Relies on chemical crosslinking | Crosslink density, mixing ratio, reaction completeness, conditioning conditions |
Relies on moisture curing | Humidity, film thickness, moisture diffusion, CO₂ release |
Relies on thermal curing | Deblocking temperature, baking temperature, baking time, heat resistance of the substrate |
Relies on self-crosslinking or post-crosslinking | Film-forming conditions, crosslinking trigger conditions, conditioning time |
10. Representative Chemical Classification Tables for Polyurethane Coating Curing Systems: 1K, 2K, Waterborne, Moisture-Curing, Blocked Systems, and Supporting Additives
Table 1: Polyisocyanate Curing Agents for 2K Polyurethane Coatings
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
2K aliphatic polyisocyanate curing agent | 28182-81-2 | Poly(hexamethylene diisocyanate) (PolyHDI) | Viscosity 900–1500 cP, 25 °C | Used for two-component clearcoats based on hydroxyl acrylic resins, weather-resistant coatings, and studies on crosslink density and gel time | |
2K aliphatic biuret-type curing agent | 4035-89-6 | 1,3,5-Tris(6-isocyanatohexyl)biuret | NCO content: 21–22.5% | Used for two-component polyurethane topcoats, chemical-resistant coatings, and experiments on curing rate and hardness development | |
2K aromatic polymeric isocyanate curing agent | 9016-87-9 | Polymethylene polyphenyl polyisocyanate | NCO content ~30%; viscosity ~200 mPa·s, 25 °C | Used for high-solids polyurethane coatings, primers, and adhesive systems to study crosslinking reactions and bonding strength | |
2K aliphatic isocyanurate curing agent | 3779-63-3 | 1,3,5-Tris(6-isocyanatohexyl)-1,3,5-triazinane-2,4,6-trione | ≥95% | Used for weather-resistant polyurethane topcoats, low-yellowing clearcoats, and studies on crosslinked structures and solvent resistance |
Table 2: Isocyanate Raw Materials for 1K Moisture-Curing Systems and Prepolymer Synthesis
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Aliphatic diisocyanate raw material for moisture-curing prepolymers | 822-06-0 | Hexamethylene diisocyanate (HDI) | Moligand™, ≥99% | Used for one-component moisture-curing prepolymers, aliphatic polyurethane resins, and studies on reaction activity in weather-resistant coatings | |
Cycloaliphatic diisocyanate raw material for moisture-curing prepolymers | 4098-71-9 | Isophorone Diisocyanate, mixture of isomers (IPDI) | ≥99% | Used for waterborne polyurethane prepolymers, moisture-curing coatings, and studies on hard-segment structure and yellowing resistance | |
Aromatic diisocyanate raw material for moisture-curing prepolymers | 26471-62-5 | Tolylene Diisocyanate, 2,4- and 2,6-isomers (TDI) | ≥98%, GC | Used for aromatic polyurethane prepolymers, elastic coatings, and studies on the effect of isomer composition on reaction rate | |
Araliphatic diisocyanate raw material for moisture-curing prepolymers | 3634-83-1 | m-Xylylene Diisocyanate (MXDI) | ≥98%, GC | Used for transparent polyurethane coatings, chemical-resistant coatings, and studies on the effect of araliphatic structures on coating-film performance | |
Aromatic diisocyanate raw material for moisture-curing prepolymers | 101-68-8 | 4,4'-MDI (MDI) | ≥98% | Used for moisture-curing polyurethane prepolymers, primers, and studies on hard-segment content and mechanical properties | |
Aromatic diisocyanate raw material for moisture-curing prepolymers | 91-08-7 | Tolylene-2,6-diisocyanate | ≥98% | Used for polyurethane reaction-mechanism studies, isomer reactivity research, and prepolymer end-group control experiments | |
Araliphatic diisocyanate raw material for moisture-curing prepolymers | 2778-42-9 | 1,3-Bis(2-isocyanato-2-propyl)benzene | ≥97%, GC | Used for low-viscosity polyurethane prepolymers, weather-resistant coatings, and studies on the effect of sterically hindered structures on curing reactions | |
Cycloaliphatic diisocyanate raw material for moisture-curing prepolymers | 5124-30-1 | Dicyclohexylmethane 4,4'-Diisocyanate, mixture of isomers (HMDI) | ≥90%, GC | Used for cycloaliphatic polyurethane coatings, yellowing-resistant elastic coating films, and studies on balancing flexibility and hardness |
Table 3: Hydrophilic Chain Extenders, Neutralizers, Amine Chain Extenders, and Process Solvents for Waterborne Polyurethane Systems
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Neutralizer for waterborne polyurethane | 121-44-8 | Triethylamine | Anhydrous grade, ≥99.5%, water ≤50 ppm | Used for neutralization and salt formation in carboxylic-acid-type waterborne polyurethane, dispersion stability, and particle-size control experiments | |
Cosolvent for waterborne polyurethane prepolymers | 872-50-4 | 1-Methyl-2-pyrrolidinone (NMP) | Anhydrous grade, ≥99.5% | Used for dissolving hydrophilic chain extenders, reducing prepolymer viscosity, and improving reaction-system homogeneity before dispersion | |
Process solvent for the acetone process in waterborne polyurethane | 67-64-1 | A486158 | Acetone | Natural, ≥97% | Used for prepolymer dilution in the acetone process for waterborne polyurethane, phase-transfer dispersion, and solvent-removal process experiments |
Amine chain extender for waterborne polyurethane | 107-15-3 | E431349 | Ethylenediamine | Suitable for synthesis | Used for chain extension after water dispersion, introduction of urea linkages, and control of particle size and tensile strength |
Alkanolamine chain extender for waterborne polyurethane | 111-42-2 | D431475 | Diethanolamine (DEA) | Suitable for analysis, guaranteed reagent grade | Used for polyurethane chain extension and end-group modification, hydroxyl-content adjustment, and coating adhesion studies |
Neutralizer and amine catalyst for waterborne polyurethane | 108-01-0 | N,N-Dimethylethanolamine | Distilled grade, ≥99.5% | Used for neutralization of carboxylic-acid-type waterborne polyurethane, dispersion stability, and studies on amine-catalyzed curing rate | |
Neutralizer and acid-value regulator for waterborne polyurethane | 124-68-5 | 2-Amino-2-methyl-1-propanol | BioReagent, ≥95% | Used for waterborne polyurethane neutralization, emulsion pH adjustment, and storage-stability studies | |
Volatile neutralizer for waterborne polyurethane | 1336-21-6 | A112077 | Ammonia solution | Guaranteed reagent, 25–28% | Used for neutralization and salt formation in carboxylic-acid-type waterborne polyurethane dispersions, pH adjustment, emulsion dispersion stability, and coating-film water-resistance studies |
Tertiary amine diol chain extender for waterborne polyurethane | 105-59-9 | N-Methyldiethanolamine | ≥99% | Used for the structural design of cationic or salt-formable polyurethane, and for controlling hydrophilicity and adhesion | |
Cycloaliphatic amine chain extender for waterborne polyurethane | 2855-13-2 | Isophoronediamine, cis- and trans-mixture (IPDA) | ≥99% | Used for post-chain extension of waterborne polyurethane, introduction of polyurea hard segments, and studies on water resistance and mechanical properties | |
Carboxylic-acid-type hydrophilic chain extender for waterborne polyurethane | 10097-02-6 | 2,2-Bis(hydroxymethyl)butyric acid (DMBA) | ≥98% | Used for internal emulsification of anionic waterborne polyurethane, particle-size control, and studies on film-forming water resistance | |
Carboxylic-acid-type hydrophilic chain extender for waterborne polyurethane | 4767-03-7 | 2,2-Bis(hydroxymethyl)propionic acid (DMPA) | ≥98% | Used for preparing anionic waterborne polyurethane dispersions, adjusting solid content, and emulsion-stability experiments |
Table 4: Blocking Agents and Latent Curing Components for Blocked Polyurethane Latent-Curing Systems
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Lactam blocking agent for blocked polyurethane | 105-60-2 | Caprolactam | Chemically pure, CP | Used for preparing blocked isocyanates, baking-curing coatings, and studies on deblocking temperature and storage stability | |
Phenolic blocking agent for blocked polyurethane | 108-95-2 | Phenol | Standard for GC, ≥99.5% | Used for model reactions of phenol-blocked isocyanates, thermal deblocking behavior, and latent curing kinetics experiments | |
Pyrazole blocking agent for blocked polyurethane | 67-51-6 | 3,5-Dimethylpyrazole | ≥99% | Used for low-temperature deblocking isocyanate blocking, powder coatings, and baking-coating reaction studies | |
Oxime blocking agent for blocked polyurethane | 96-29-7 | 2-Butanone oxime | ≥99% | Used for preparing oxime-blocked isocyanates, one-component baking coatings, and studies on latent reaction activity | |
Active-methylene blocking agent for blocked polyurethane | 105-53-3 | Diethyl malonate | ≥99% | Used for active-methylene-blocked isocyanates, low-temperature curing exploration, and studies on deblocking reaction mechanisms | |
Blocked/latent polyurethane uretdione-type isocyanate component | 23501-81-7 | 1,3-Bis(6-isocyanatohexyl)-1,3-diazetidine-2,4-dione | _ | Used for studies on HDI uretdione/latent NCO structures, thermal deblocking or ring-opening reactions, thermally cured coatings, and curing windows |
Table 5: Polyurethane Curing Catalysts, Accelerators, Coalescing Agents, and Formulation Additives
Category | CAS No. | Aladdin Catalog No. | Name | Specification or Purity | Product Features and Applications |
Tertiary amine catalyst for polyurethane | 280-57-9 | 1,4-Diazabicyclo[2.2.2]octane (DABCO, triethylenediamine) | Moligand™, ≥98% | Used for catalyzing the reaction between isocyanate and hydroxyl groups, and for comparative experiments on foaming and coating curing rates | |
Metal carboxylate catalyst for polyurethane | 136-53-8 | Zinc 2-ethylhexanoate | ca. 80% in mineral spirits, 17–19% Zn | Used for polyurethane crosslinking catalysis, promotion of blocked-isocyanate deblocking, and studies on coating-film drying performance | |
Bismuth catalyst for polyurethane | 34364-26-6 | Bismuth(III) neodecanoate | ≥99.9% metals basis, 60% in neodecanoic acid, 15–20% Bi | Used for low-tin polyurethane catalyst systems, curing of two-component coatings, and studies on pot life and surface-drying time | |
Strong basic amine catalyst for polyurethane | 6674-22-2 | 1,8-Diazabicyclo[5.4.0]undec-7-ene (DBU) | ≥99% | Used for promoting deblocking of blocked isocyanates, catalyzing urethane-forming reactions, and low-temperature curing experiments | |
Coalescing agent for waterborne polyurethane | 25265-77-4 | 2,2,4-Trimethyl-1,3-pentanediol 1-monoisobutyrate | ≥99% | Used for film formation in waterborne polyurethane coatings, leveling adjustment, and studies on low-temperature film-forming performance | |
Coalescing and leveling cosolvent for waterborne polyurethane | 29911-28-2 | Dipropylene glycol butyl ether (DPNB) | ≥98%, mixture of isomers | Used for cosolvency in waterborne polyurethane coatings, adjustment of open time, and application leveling experiments | |
Cosolvent and film-formation regulator for waterborne polyurethane | 34590-94-8 | Di(propylene glycol) methyl ether, mixture of isomers | ≥98% | Used for cosolvency in waterborne polyurethane dispersions, viscosity adjustment, and studies on the film-forming process | |
Organotin catalyst for polyurethane | 77-58-7 | Dibutyltin dilaurate (DBTDL) | ≥95% | Used for catalyzing the reaction between isocyanate and hydroxyl groups, curing kinetics of two-component coatings, and pot-life studies | |
Stannous catalyst for polyurethane | 301-10-0 | Tin 2-ethylhexanoate | ≥95% | Used for polyurethane prepolymer synthesis, catalysis of moisture-curing systems, and studies on gel time and hardness development |
Note: The above are representative products from Aladdin. For more product specifications, search by “product name / CAS / catalog number” on the Aladdin official website.
References
[1] Zubair, Z., Shaker, K., & Hafeez, A. Curing and Drying Processes. In: Functional Polyurethane Coatings: Formulations, Properties, and Applications. SpringerBriefs in Materials, Springer, 2026.
[2] SpecialChem. Polyurethane Coatings: How to Formulate Them?
[3] Covestro. Bayhydrol® | PU Dispersions.
[4] Nakao, M. 1K PUR Dispersion with Comparable Performance to 2K Waterborne Coating. American Coatings Association, CoatingsTech Magazine.
[5] Zhou, J.; Liu, Z.; Zhu, Z.; Zeng, Z.; Sun, L. The kinetics of the polyurethane moisture curing reaction: a combined experimental and DFT mechanistic study. Reaction Chemistry & Engineering. First published 30 Sep 2024.
[6] 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.
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