Sequential heat release: an innovative approach for the control of curing profiles during composite processing based on dual‐curing systems

Romero, María de los Ángeles; Fernández‐Francos, Xavier; Ramis, Xavier

doi:10.1002/pi.5743

Cited by 11 publications

(26 citation statements)

References 49 publications

(223 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although a UV post‐curing stage can partially mitigate this problem, curing schedules should be planned so as to avoid these spatial gradients along part dimensions and minimize deformation, cracking, or delamination. [ 16,17 ] Herein, we report the successful incorporation of an epoxy‐anhydride network into a poly(acrylate) network through a two‐step process: a visible light 3D printing followed by thermal curing of the epoxy‐anhydride. Compared to the other papers mentioned, the novelty of the work is twofold: the utilization of visible light in lieu of UV irradiation, and the use of a thermally triggered radical initiator which ensures that all remaining acrylate monomers end up polymerizing at the thermal stage, concurrently with epoxy‐anhydride reaction.…”

Section: Introductionmentioning

confidence: 99%

Epoxy Doped, Nano‐scale Phase‐separated Poly‐Acrylates with Potential in 3D Printing

Konuray

Altet

Bonada

et al. 2021

Macro Materials & Eng

Self Cite

View full text Add to dashboard Cite

An efficient method to improve the mechanical performance of a commercially available photocure resin is described wherein the resin is modified with a mixture of a cycloaliphatic epoxy and an anhydride curing agent. Photocured samples are thermally treated in a subsequent step to cure the epoxy to obtain an interpenetrated polymer network (IPN) and also complete reaction of the acrylate monomers remaining from the photocure. The latter is accomplished by a thermal radical initiator added earlier into the formulation together with the epoxy‐anhydride. The thermal properties and microstructure of the resulting IPN are analyzed. Uniform and quantitative conversions are obtained, with glass transition temperatures comparable to conventional epoxies. The liquid, uncured samples containing different amounts of epoxy are stable at 30 °C for several weeks. In the fully cured epoxy‐rich materials, nano‐scale phase separation is observed by atomic force microscopy. This is corroborated by the existence of multiple relaxations determined by dynamic mechanical analysis analysis. Specimens from a formulation containing 50% by weight of epoxy‐anhydride are 3D printed in a customized masked image processing stereolithography, thermally treated, and are subjected to compression tests. Results show that Young's modulus increases by 900% over the neat resin.

show abstract

Section: Introductionmentioning

confidence: 99%

Epoxy Doped, Nano‐scale Phase‐separated Poly‐Acrylates with Potential in 3D Printing

Konuray

Altet

Bonada

et al. 2021

Macro Materials & Eng

Self Cite

View full text Add to dashboard Cite

show abstract

“…Dual-curing mixtures of acrylates and epoxy materials are common in commercial SLA printing [6], and a dual-cure process was recently commercialised by Carbon Co. [18,19] in their continuous liquid interface process. Additionally, multi-component/dual-curing polymer IPNs have been investigated for a range of applications including acrylate urethane for automotive coatings [20] and have been utilised for the control of reaction exotherms in industrial processing of thermoset resins [21].…”

Section: Introductionmentioning

confidence: 99%

Morphology Control in a Dual-Cure System for Potential Applications in Additive Manufacturing

et al. 2019

View full text Add to dashboard Cite

The polymerisation, morphology and mechanical properties of a two-component in-situ reacting system consisting of a rubbery dimethacrylate and a rigid epoxy polymer were investigated. The methacrylate component of the mixture was photocured using UV light exposure and, in a second curing process, the mixture was thermally postcured. The polymers formed a partially miscible system with two glass transition temperature (Tg) peaks measured using dynamic mechanical thermal analysis (DMTA). The composition and relative rate of reaction of the two orthogonal polymerisations influenced the extent of miscibility of the two polymer-rich phases and the samples were transparent, indicating that the two phases were finely dispersed. The addition of a glycidyl methacrylate compatibiliser further increased the miscibility of the two polymers. The utility of this polymer system for additive manufacturing was investigated and simulated through layer-by-layer processing of the mixture in two steps. Firstly, the methacrylate component was photocured to solidify the material into its final shape, whilst the second step of thermal curing was used to polymerise the epoxy component. With the use of a simulated photomask, a simple shape was formed using the two orthogonal polymerisation stages to produce a solid object. The mechanical properties of this two-phase system were superior to a control sample made only of the methacrylate component, indicating that some reinforcing due to polymerisation of the epoxy across the interfaces had occurred in the postcuring stage.

show abstract

“…Reshaping ability of the intermediate materials can also be used for the assembly of complex shapes or the production of complex shape structures [ 35 ]. Control of the intermediate extent of curing can be exploited in some composite processing applications [ 36 ]. Advanced optical applications based on dual-curing systems have also been reported [ 37 ].…”

Section: Introductionmentioning

confidence: 99%

Enhancement of 3D-Printable Materials by Dual-Curing Procedures

et al. 2020

Self Cite

View full text Add to dashboard Cite

Dual-curing thermosetting systems are recently being developed as an alternative to conventional curing systems due to their processing flexibility and the possibility of enhancing the properties of cured parts in single- or multi-stage processing scenarios. Most dual-curing systems currently employed in three-dimensional (3D) printing technologies are aimed at improving the quality and properties of the printed parts. However, further benefit can be obtained from control in the curing sequence, making it possible to obtain partially reacted 3D-printed parts with tailored structure and properties, and to complete the reaction by activation of a second polymerization reaction in a subsequent processing stage. This paves the way for a range of novel applications based on the controlled reactivity and functionality of this intermediate material and the final consolidation of the 3D-printed part after this second processing stage. In this review, different strategies and the latest developments based on the concept of dual-curing are analyzed, with a focus on the enhanced functionality and emerging applications of the processed materials.

show abstract

Sequential heat release: an innovative approach for the control of curing profiles during composite processing based on dual‐curing systems

Cited by 11 publications

References 49 publications

Epoxy Doped, Nano‐scale Phase‐separated Poly‐Acrylates with Potential in 3D Printing

Epoxy Doped, Nano‐scale Phase‐separated Poly‐Acrylates with Potential in 3D Printing

Morphology Control in a Dual-Cure System for Potential Applications in Additive Manufacturing

Enhancement of 3D-Printable Materials by Dual-Curing Procedures

Contact Info

Product

Resources

About