Compositional effects on cure kinetics, mechanical properties and printability of dual-cure epoxy/acrylate resins for DIW additive manufacturing

• Published in: Additive manufacturing Vol. 46; p. 102159
• Main Authors: Kopatz, Jessica W., Unangst, Jaclynn, Cook, Adam W., Appelhans, Leah N.
• Format: Journal Article
• Language: English
• Published: United States Elsevier B.V 01.10.2021; Elsevier
• Subjects: Direct-ink write; Dual-cure; Green strength; Interpenetrating polymer networks; MATERIALS SCIENCE; Thermosets; Green strength; Dual-cure; Thermosets; Direct-ink write; Interpenetrating polymer networks
• ISSN: 2214-8604; 2214-7810
• DOI: 10.1016/j.addma.2021.102159

Interest in 3D printing of thermoset resins has increased significantly in recent years. One approach to additive manufacturing of thermoset resins is printing dual-cure resins with direct ink write (DIW). Dual-cure resins are multi-component resins which employ an in situ curable constituent to enable net-shape fabrication while a second constituent and cure mechanism contribute to the final mechanical properties of the printed materials. In this work, the cure kinetics, green strength, printability, and print fidelity of dual-cure epoxy/acrylate thermoset resins are investigated. Resin properties are evaluated as a function of acrylate concentration and in situ UV exposure conditions. The acrylate cure kinetics are probed using photo-differential scanning calorimetry and the impacts of resin composition and UV cure profile on the acrylate extent of conversion are presented. Continuous and pulsed UV cure profiles are shown to affect total conversion due to variances in radical efficiency at different UV intensities and acrylate concentrations. The effects of acrylate concentration on the kinetics of the epoxy thermal cure and the final mechanical properties are also investigated using dynamic mechanical analysis and three-point bend measurements. The glass transition temperature is dependent on formulation, with increasing acrylate content decreasing the Tg. However, the room temperature shear moduli, flexural moduli, strength, strain-to-failure, and toughness values are relatively independent of resin composition. The similarity of the final properties allows for greater flexibility in resin formulation and in situ cure parameters, which can enable the printing of complex parts that require high green strength. We found that the in situ UV print intensities and exposure profiles that are necessary to achieve the best print quality are not, in most cases, the conditions that maximize conversion of the acrylate network. This highlights the importance of developing optimized resin compositions which enable complete cure of the acrylate network by promoting acrylate dark cure or thermal cure. •Investigated the cure kinetics, green strength, and thermomechanical properties of DIW epoxy/acrylate dual-cure resins.•The dependence of acrylate conversion on UV exposure and intensity is determined by acrylate content and radical efficiency.•The green modulus of a printed part depends on the acrylate content and in situ acrylate conversion during printing.•Parameters maximizing acrylate conversion are often different from those that optimize printability and structural stability.