Daicel Company continues to broaden its lineup of specialty polymers for molding and additive manufacturing, combining sustainability with processing efficiency. The brand new CAFBLO, a marine-biodegradable cellulose acetate resin, provides to the vary of cycloaliphatic epoxies and caprolactone (meth)acrylates engineered for 3D printing and associated purposes requiring transparency, mechanical power, and thermal stability.
By mixing CAFBLO’s biodegradable cellulose acetate with superior epoxy and caprolactone supplies, Daicel desires to supply a variety of polymer choices for each eco-friendly and high-quality manufacturing.
The corporate’s portfolio helps various industrial purposes—from injection-molded shopper items to precision-engineered 3D printed elements—whereas aligning with international demand for recyclable and energy-efficient supplies.
Designed for processability
CAFBLO is an eco-friendly materials designed for 3D printing in pellet type utilizing FGF strategies (LFAM), enabling the manufacturing of large-scale objects similar to sculptures and furnishings. It permits designers to leverage its transparency and suitability for secondary processing.
CAFBLO is primarily constructed from cellulose acetate, acetic acid, and biodegradable plasticizers, making it extremely biodegradable. As a pure, extremely biodegradable materials, it’s characterised by each transparency and recyclability. CAFBLO can be extremely biodegradable in seawater, the place its uncooked supplies are damaged down by microorganisms and ultimately transformed into water and carbon dioxide.
With the accelerating adoption of 3D printing throughout manufacturing sectors, Daicel focuses on supplies that keep consistency in mechanical efficiency and processing habits. The corporate’s polymers are formulated for low shrinkage and speedy solidification, enabling the manufacturing of purposeful prototypes and end-use elements.
Cycloaliphatic epoxies for high-transparency and heat-resistance
Within the US, the main focus is on Daicel’s Celloxide and Cyclomer strains, with its choices now extending to incorporate UV-curable and cationic polymerization programs.
Daicel’s resin supplies for 3D printing deal with low viscosity, excessive transparency, and odor resistance, in addition to favorable cationic polymerization traits. Components can be utilized to tailor the toughness of the printed elements, whereas the supplies’ continued post-UV crosslinking will increase general sturdiness and power effectivity in curing. The corporate emphasizes dependable provide and high quality management to assist international industrial 3D printing operations.
Celloxide 2021P, a difunctional cycloaliphatic diepoxide, options low viscosity and really low halogen content material. The resin supplies excessive transparency, a excessive glass transition temperature (Tg), and robust mechanical properties after curing, making it appropriate for coatings, encapsulants, and optical-grade 3D printing formulations.
Cyclomer M100 is a methacrylate monomer containing a cycloaliphatic epoxy group, combining low viscosity with excessive cationic reactivity. It helps purposes that require speedy curing, good dimensional stability, and exact sample replica in photo-curable resin programs.
Caprolactone-modified acrylates for tunable flexibility
Daicel additionally produces an intensive vary of Placcel caprolactone (meth)acrylate derivatives that present formulation flexibility for UV-curable and 3D printing resins. These embody Placcel FA1DDM, FA2D, FA4DT, FA5, and FA10L, that are caprolactone-modified acrylates providing decreased inhibitor content material and managed viscosity profiles.
For methacrylate-based programs, merchandise similar to Placcel FM1, FM1D, FM2D, FM3, and FM5 are caprolactone-modified methacrylates with adjustable mechanical and curing properties. Placcel HEMAC1, a carbonate-modified methacrylate, is designed for enhanced flexibility and adhesion in resin blends.
These supplies are engineered to enhance elasticity, transparency, and chemical resistance in photopolymer programs whereas sustaining environment friendly curing habits beneath UV or thermal processes.
