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

Campbell, Jonathan A.; Inglis, Harrison; WeiLong, Elson Ng; McKinley, Cheylan; Lewis, David A.

doi:10.3390/polym11030420

Cited by 14 publications

(12 citation statements)

References 35 publications

(40 reference statements)

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“…In the field of dual-cure systems for use in additive manufacturing, different promising approaches have already been pursued. Next to the common pure acrylate systems, many resin systems for SLA are based on the usage of the epoxy acrylates [ 14 ] or linking elements, which contain both an epoxy and an acrylate group, such as, e.g., 4-vinyl-1-cyclohexene 1,2-epoxide [ 15 ] or glycidyl methacrylate (GMT) [ 16 ]. While these systems use a dual-cure approach, the usage of these linking elements or acrylated epoxies is problematic as it results in low mechanical properties and weak light aging resistance [ 17 ] next to typical UV-acrylate problems such as the inhibition by oxygen.…”

Section: Introductionmentioning

confidence: 99%

A Dyciandiamine-Based Methacrylate-Epoxy Dual-Cure Blend-System for Stereolithography

Romeis

Drummer

2021

Polymers

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In this research, an epoxy-based dual-cure system is developed and characterized for SLA additive manufacturing. Dual-cure systems consist of UV-curable acrylates and thermal active components. The second curing step offers an additional degree of freedom to design specific material properties. In this study, a blend of varying concentrations of an epoxy/curing agent mix, respectively, DGEBA, DICY and photocurable methacrylate, was used to create a material that is printable in the SLA process into a UV-cured or green part and subsequently thermally cured to achieve superior thermal and mechanical properties. Calorimetric measurements were performed to determine the reactivity of the thermal reaction at different concentrations of epoxy. The fully cured specimens were tested in mechanical and dynamic mechanical measurements, and the results showed a significant improvement in tensile stress and glass transition temperature with rising epoxy concentrations. Fractured surfaces from tensile testing were investigated to further characterize the failure of tested samples, and thermal degradation was determined in TGA measurements, which showed no significant changes with an increasing epoxy concentration.

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Section: Introductionmentioning

confidence: 99%

A Dyciandiamine-Based Methacrylate-Epoxy Dual-Cure Blend-System for Stereolithography

Romeis

Drummer

2021

Polymers

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“…Especially in the aerospace sector, parts previously manufactured by traditional means are being replaced by additively manufactured lowweight polymer components. Although AM was previously primarily used to produce prototypes, it has now developed sufficiently for customized mass production of functional parts [8,9]. AM technologies can be classified into seven main categories [10,11] under which polymers can be 3D printed via polymerization, powder-bed-based processes, and extrusion-based processes [12].…”

Section: Introductionmentioning

confidence: 99%

Experiment-Based Process Modeling and Optimization for High-Quality and Resource-Efficient FFF 3D Printing

2020

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This article reports on the investigation of the effects of process parameters and their interactions on as-built part quality and resource-efficiency of the fused filament fabrication 3D printing process. In particular, the influence of five process parameters: infill percentage, layer thickness, printing speed, printing temperature, and surface inclination angle on dimensional accuracy, surface roughness of the built part, energy consumption, and productivity of the process was examined using Taguchi orthogonal array (L50) design of experiment. The experimental results were analyzed using ANOVA and statistical analysis, and the parameters for optimal responses were identified. Regression models were developed to predict different process responses in terms of the five process parameters experimentally examined in this study. It was found that dimensional accuracy is negatively influenced by high values of layer thickness and printing speed, since thick layers of printed material tend to spread out and high printing speeds hinder accurate deposition of the printed material. In addition, the printing temperature, which regulates the viscosity of the used material, plays a significant role and helps to minimize the dimensional error caused by thick layers and high printing speeds, whereas the surface roughness depends very much on surface inclination angle and layer thickness, which together determine the influence of the staircase effect. Energy consumption and productivity are primarily affected by printing speed and layer thickness, due to their high correlation with build time.

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“…The

vs epoxy content graph shows a quasi linear correlation considering only the high

for the cream resin. This trend is typically observed for blends forming the so-called interpenetrated network [ 23 ].…”

Section: Results and Discussionmentioning

confidence: 73%

Epoxy Based Blends for Additive Manufacturing by Liquid Crystal Display (LCD) Printing: The Effect of Blending and Dual Curing on Daylight Curable Resins

et al. 2020

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Epoxy-based blends printable in a Liquid Crystal Display (LCD) printer were studied. Diglycidyl ether of bisphenol A (DGEBA) mixed with Diethyltoluene diamine (DETDA) was used due to the easy processing in liquid form at room temperature and slower reactivity until heated over 150 ° C. The DGEBA/DETDA resin was mixed with a commercial daylight photocurable resin used for LCD screen 3D printing. Calorimetric, dynamic mechanical and rheology testing were carried out on the resulting blends. The daylight resins showed to be thermally curable. Resin’s processability in the LCD printer was evaluated for all the blends by rheology and by 3D printing trials. The best printing conditions were determined by a speed cure test. The use of a thermal post-curing cycle after the standard photocuring in the LCD printer enhanced the glass transition temperature T g of the daylight resin from 45 to 137 ° C when post-curing temperatures up to 180 ° C were used. The T g reached a value of 174 ° C mixing 50 wt% of DGEBA/DETDA resin with the photocurable resin when high temperature cure cycle was used.

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

Cited by 14 publications

References 35 publications

A Dyciandiamine-Based Methacrylate-Epoxy Dual-Cure Blend-System for Stereolithography

A Dyciandiamine-Based Methacrylate-Epoxy Dual-Cure Blend-System for Stereolithography

Experiment-Based Process Modeling and Optimization for High-Quality and Resource-Efficient FFF 3D Printing

Epoxy Based Blends for Additive Manufacturing by Liquid Crystal Display (LCD) Printing: The Effect of Blending and Dual Curing on Daylight Curable Resins

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