Cheap, versatile, and turnkey fabrication of microfluidic master molds using consumer-grade LCD stereolithography 3D printing

Colin, Vincent G.; Travers, Theo; Gindre, Denis; Barille, Régis; Loumaigne, Matthieu

doi:10.1007/s00170-021-07329-3

Cited by 13 publications

(11 citation statements)

References 32 publications

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“…The corresponding angle can be visualized and roughly estimated by taking an image of the edge of a channel (see Section SI-9 †). Additionally, as shown previously, 23 the pixel geometry of the LCD matrix used in the lithographic projection can lead to small ripples on the channel surface.…”

Section: Microfabricationmentioning

confidence: 67%

On-chip light sheet illumination for nanoparticle tracking in microfluidic channels

Travers,

Delhaye,

Werts

et al. 2024

Anal. Methods

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Section: Microfabricationmentioning

confidence: 67%

On-chip light sheet illumination for nanoparticle tracking in microfluidic channels

Travers,

Delhaye,

Werts

et al. 2024

Anal. Methods

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“…In addition, LCD printing results in remarkably high resolution thanks to the advanced liquid crystal display technology, and it also has the obvious advantage of low equipment costs and simple postprocessing. [ 36 ] However, compared with the DLP printer, the LCD screen has a short service life, and the light intensity is weaker. [ 25 ] At present, the physical applications brought about by LCD printing technology have been radiated to many fields such as soft robotics, tissue engineering, and mold manufacturing.…”

Section: Common Vat Photopolymerization Techniquesmentioning

confidence: 99%

Progress in Photocurable 3D Printing of Photosensitive Polyurethane: A Review

Fei

Rong

Zhu

et al. 2023

Macromol. Rapid Commun.

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In recent years, as a class of advanced additive manufacturing (AM) technology, photocurable 3D printing has gained increasing attention. Based on its outstanding printing efficiency and molding accuracy, it is employed in various fields, such as industrial manufacturing, biomedical, soft robotics, electronic sensors. Photocurable 3D printing is a molding technology based on the principle of area‐selective curing of photopolymerization reaction. At present, the main printing material suitable for this technology is the photosensitive resin, a composite mixture consisting of a photosensitive prepolymer, reactive monomer, photoinitiator, and other additives. As the technique research deepens and its application gets more developed, the design of printing materials suitable for different applications is becoming the hotspot. Specifically, these materials not only can be photocured but also have excellent properties, such as elasticity, tear resistance, fatigue resistance. Photosensitive polyurethanes can endow photocured resin with desirable performance due to their unique molecular structure including the inherent alternating soft and hard segments, and microphase separation. For this reason, this review summarizes and comments on the research and application progress of photocurable 3D printing of photosensitive polyurethanes, analyzing the advantages and shortcomings of this technology, also offering an outlook on this rapid development direction.

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“…Medical implants like orthodontic models are an emerging area for the application of LCD printing apart from conventional prototyping needs in the engineering field (Colin et al , 2021; Lo Giudice et al , 2022; Mohamed et al , 2019; Sotov et al , 2021). The orthodontic models printed with SLA and DLP are suitable for medical applications (Lo Giudice et al , 2022; Ko et al , 2021; Martín-Montal et al , 2021).…”

Section: Introductionmentioning

confidence: 99%

Optimization of dimensional accuracy and surface roughness in m-SLA using response surface methodology

Singh

Jain

Chaudhary

et al. 2023

RPJ

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Purpose This paper aims to investigate the dimensional accuracy and surface roughness of printed masked stereolithography (m-SLA) parts. The fabricated specimens of photosensitive polymer resin have complex shapes and various features. The influence of four process parameters of m-SLA, including layer height, exposure time, light-off delay and print orientation, is studied on response characteristics. Design/methodology/approach The Box–Behnken design of response surface methodology is used to examine the effect of process parameters on the shrinkage of various geometrical dimensions like diameter, length, width, and height of different features in a complex shape. Additionally, a multi-response optimization has been carried out using the desirability function to minimize the surface roughness and printing time and maximize the dimensional accuracy. Findings The layer height and print orientation influence the surface roughness of parts. An increase in layer height results in increased surface roughness, and the orientation parallel to the z-axis of the machine gives the highest surface roughness. The dimensional accuracy of m-SLA parts is influenced by layer height, exposure time, and print orientation. Although not significant in dimensional accuracy and surface roughness, the light-off delay can affect printing time apart from other parameters like layer height and print orientation. Originality/value The effect of layer height and print orientation on dimensional accuracy, printing time, and surface roughness is investigated by researchers using simple shapes in other vat photopolymerization techniques. The present work is focused on studying the effect of these parameters and additional parameters like light-off delay in complicated geometrical parts in m-SLA.

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Cheap, versatile, and turnkey fabrication of microfluidic master molds using consumer-grade LCD stereolithography 3D printing

Cited by 13 publications

References 32 publications

On-chip light sheet illumination for nanoparticle tracking in microfluidic channels

On-chip light sheet illumination for nanoparticle tracking in microfluidic channels

Progress in Photocurable 3D Printing of Photosensitive Polyurethane: A Review

Optimization of dimensional accuracy and surface roughness in m-SLA using response surface methodology

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