Break through the dispersion bottleneck! Exploration of multiple application scenarios of polyurethane carbon black viscosity-reducing dispersants

Break through the dispersion bottleneck! Exploration of multiple application scenarios of polyurethane carbon black viscosity-reducing dispersants

Polyurethane carbon black viscosity-reducing dispersants are functional additives used to optimize the dispersion performance of carbon black in polyurethane systems and reduce the viscosity of the system. They have a wide range of applications, covering multiple industrial fields.

1. Coatings and ink fields

High-performance industrial coatings

Application scenarios: automotive original paint, building exterior wall coatings, industrial anti-corrosion coatings and other fields that require high hiding power, high blackness and weather resistance.

Technical requirements:

When carbon black is used as a pigment, it is easy to cause black spots or color differences on the coating surface due to agglomeration. Dispersants reduce the van der Waals force between carbon black particles, making them evenly dispersed in polyurethane resins, and improving the gloss uniformity of the coating (such as ΔL* value <0.5).

Reducing the viscosity of the system can improve the construction performance. For example, in high-pressure airless spraying, a 30% reduction in viscosity can reduce pumping energy consumption by more than 20%, while avoiding sagging or orange peel phenomena.

UV curing ink and 3D printing materials

Application scenarios: packaging printing, electronic labels, flexible circuit boards, and light-curing 3D printing, which require high curing speed and precision.

Technical requirements:

In UV curing systems, carbon black easily absorbs ultraviolet rays, resulting in incomplete curing. Dispersants improve the compatibility of carbon black and photoinitiators, increase the curing depth (such as from 50μm to 80μm), and reduce the viscosity of ink to support high-speed printing (such as printing speed from 50m/min to 80m/min).

In 3D printing, dispersants can prevent carbon black from settling in photosensitive resins, ensure the bonding force between printed layers, and improve the mechanical properties of products (such as tensile strength increased by 15%).

2. Adhesives and sealants

Structural adhesives and engineering sealants

Application scenarios: automotive windshield bonding, building curtain wall sealing, wind turbine blade bonding, and other occasions that require high strength and high durability.

Technical requirements:

When carbon black is used as a reinforcing filler, uneven dispersion will lead to internal stress concentration in the colloid. Dispersants promote the chemical bonding between carbon black and polyurethane prepolymers, thereby increasing the tensile strength (e.g., from 20MPa to 25MPa) and elongation at break of colloids.

Reducing viscosity can improve the stability of the automated dispensing process. For example, in two-component adhesives, a 20% reduction in viscosity can reduce the pressure fluctuation of the glue valve by 15%, reducing the risk of glue overflow or glue breakage.

Conductive/thermal conductive adhesives and electromagnetic shielding materials

Application scenarios: 5G base station heat dissipation modules, flexible electronic devices, electromagnetic shielding coatings, and other fields that require composite functional fillers.

Technical requirements:

In conductive adhesives, dispersants need to optimize the dispersibility of carbon black (conductive) and silver powder/copper powder (highly conductive) at the same time to avoid conductive network breaks caused by filler sedimentation. For example, by adjusting the hydrophilic-lipophilic balance (HLB) value of the dispersant, the coordinated dispersion of carbon black and metal fillers can be achieved, reducing the volume resistivity from 10⁶Ω·cm to 10³Ω·cm.

In thermal conductive adhesives, dispersants can promote the interfacial bonding of carbon black and alumina/boron nitride, improve thermal conductivity (such as from 1.2W/(m·K) to 1.8W/(m·K)), while maintaining low viscosity to support high filler loading (such as carbon black content of 25%).

3. Polyurethane elastomers and synthetic leather fields

High wear-resistant elastomer materials

Application scenarios: tire treads, industrial conveyor belts, soles and sports equipment, etc., which require high strength and tear resistance.

Technical requirements:

When carbon black is used as a reinforcing agent, uneven dispersion will cause internal defects in the elastomer. Dispersants reduce the surface energy of carbon black particles, promote their uniform distribution between polyurethane molecular chains, improve wear resistance (such as DIN wear loss from 120mg to 80mg) and tear strength.

Reducing processing viscosity can improve the stability of injection molding or extrusion processes. For example, in the production of soles, a 15% reduction in viscosity can reduce the screw torque by 10%, extending the service life of the equipment.

Surface treatment of artificial leather and synthetic leather

Application scenarios: furniture fabrics, automotive interiors, luggage and leather goods, etc., which have high requirements for surface gloss and feel.

Technical requirements:

In the polyurethane surface layer, uneven dispersion of carbon black will cause "pitting" or "fog" on the surface. Dispersants use nano-scale dispersion technology to make the carbon black particle size distribution D50 <50nm, improve the uniformity of blackness (such as L* value <5), and reduce the viscosity of the slurry to support precision coating (such as coating thickness control accuracy ±2μm).

In waterborne polyurethane systems, dispersants must take into account both environmental protection and dispersion efficiency. For example, by introducing biodegradable polyether segments, VOCs emissions can be reduced by 60% while maintaining stable dispersion performance.

4.Special functional materials field

Conductive polyurethane composite materials

Application scenarios: Antistatic floors, flexible sensors, electromagnetic shielding films and other flexible electronic devices that require conductive properties.

Technical requirements:

The dispersant needs to build a continuous conductive network, for example, by adjusting the spacing of carbon black particles (such as <100nm) to make the volume resistivity meet the adjustable range of 10³-10⁶Ω·cm.

In a two-component polyurethane system, the dispersant needs to be compatible with the isocyanate group to avoid affecting the curing reaction kinetics, while maintaining low viscosity to support high filler loading (such as carbon black content of 30%).

Optical black film and absorbing materials

Application scenarios: camera shading film, infrared stealth coating, 5G base station absorber and other fields requiring high light absorption rate.

Technical requirements:

In optical black film, the dispersant needs to make the carbon black particle size <100nm, improve the light scattering efficiency, and achieve a full-band (400-1500nm) light absorption rate >99%.

In absorbing materials, the dispersant needs to synergistically optimize the dispersibility of carbon black and magnetic fillers (such as ferrites), and by adjusting the matching of electromagnetic parameters, the bandwidth of reflection loss <-10dB covers 8-18GHz.

Summary

The application scope of polyurethane carbon black viscosity reducing dispersant covers coatings, adhesives, elastomers, functional materials and other fields. Its core value lies in optimizing carbon black dispersibility and improving material performance and processing efficiency at the same time. In the future, with the growth of green, functional integration and high-precision processing needs, the development of dispersants will evolve towards environmentally friendly, multifunctional and nano-level dispersion technology.