3D printed fiber optic faceplates by custom controlled fused deposition modeling

Wang, Ye; Gawedzinski, John; Pawłowski, M.; Tkaczyk, Tomasz S.

doi:10.1364/oe.26.015362

Cited by 32 publications

(20 citation statements)

References 33 publications

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“…Only the following technologies have been reported for glass fabrication: SLS/SLM, FDM, SLA, DLP, TPP, and DIW, as well as SL. Among them, although FDM is mostly used to prepare glass crafts due to the characteristics of the processing technology, it cannot be widely used in the optical field [25][26][27]. While the SLS/SLM technique provides good control of the crystal structure and achieves nearly 100% material utilization [24], the processing process generates vapor bubbles, which limits the optical transparency of the glass.…”

Section: Classification Of 3d Printing Glass Technologiesmentioning

confidence: 99%

Overview of 3D-Printed Silica Glass

et al. 2022

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Not satisfied with the current stage of the extensive research on 3D printing technology for polymers and metals, researchers are searching for more innovative 3D printing technologies for glass fabrication in what has become the latest trend of interest. The traditional glass manufacturing process requires complex high-temperature melting and casting processes, which presents a great challenge to the fabrication of arbitrarily complex glass devices. The emergence of 3D printing technology provides a good solution. This paper reviews the recent advances in glass 3D printing, describes the history and development of related technologies, and lists popular applications of 3D printing for glass preparation. This review compares the advantages and disadvantages of various processing methods, summarizes the problems encountered in the process of technology application, and proposes the corresponding solutions to select the most appropriate preparation method in practical applications. The application of additive manufacturing in glass fabrication is in its infancy but has great potential. Based on this view, the methods for glass preparation with 3D printing technology are expected to achieve both high-speed and high-precision fabrication.

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Section: Classification Of 3d Printing Glass Technologiesmentioning

confidence: 99%

Overview of 3D-Printed Silica Glass

et al. 2022

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“…Furthermore, DLP 3D printer works at room temperature saving time and energy compared with FDM and DIW printers. [ 80 ] A complete stepwise workflow of a typical DLP 3D printer is shown in Figure . The first step is the model‐generation process using CAD.…”

Section: D Printingmentioning

confidence: 99%

“…3D printing has been studied for ophthalmic devices. [ 80,88,93,105,118,119 ] The upcoming challenge is to manufacture smart CLs with 3D printing. The advantage of 3D printing over other methods is that one can create chambers within the wall of the lenses which can be utilized for multiplexed sensing capability.…”

Section: D Printing Of Smart Cls: Future Challengesmentioning

confidence: 99%

Prospects for Additive Manufacturing in Contact Lens Devices

et al. 2020

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Additive manufacturing (3D printing) has the ability to architect structures at microscale, giving rise to the development of functional contact lenses (CLs) with inbuilt sensing capabilities. 3D printing technology enables fabrication of CLs without surface geometry restrictions. Spherical, nonspherical, symmetric, and asymmetric lenses can be manufactured in an integrated production process. Advantages of 3D printing over conventional techniques include fast and easy production, one‐step manufacturing, and no post processing such as grinding or polishing. In addition, and most significantly, 3D printing can create chambers within the wall of the lenses by taking the advantage of computer‐aided modeling and layer‐by‐layer deposition of the materials. These inbuilt chambers can be used for loading drugs and sensing elements. The computer‐aided design modeling can allow for manufacturing of patient‐specific CLs. This article focuses on the 3D‐printing approaches and the challenges faced in fabricating CLs. 3D‐printing technology as a technique for manufacturing of CLs is discussed, in addition to the manufacturing challenges and the possible solutions to overcome the obstacles.

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“…Later, inspired by this work, other colleagues demonstrated chalcogenide glass filaments of 1.75 mm diameter, fabricated from a preform of the same material which is then used to draw glassy fiber using the direct extrusion on a FDM printer [ 18 ]. The layer-by-layer deposition using FDM printer has been used to additively fabricate optics such as air-clad fiber optic faceplates [ 19 ], lenses [ 20 , 21 ], gratings [ 22 ], cuvettes [ 23 ] and many more. The 3D-printed element has been widely accepted and utilized in many sensory applications.…”

Section: Introductionmentioning

confidence: 99%

Low-Cost 3D Printer Drawn Optical Microfibers for Smartphone Colorimetric Detection

et al. 2022

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A fused deposition modeling (FDM) 3D printer extruder was utilized as a micro-furnace draw tower for the direct fabrication of low-cost optical fibers. An air-clad multimode microfiber was drawn from optically transparent polyethylene terephthalate glycol (PETG) filament. A custom-made spooling collection allows for an automatic variation of fiber diameter between ϕ ∼ 72 to 397 μm by tuning the drawing speed. Microstructure imaging as well as the 3D beam profiling of the transmitted beam in the orthogonal axes was used to show good quality, functioning microfiber fabrication with uniform diameter and identical beam profiles for orthogonal axes. The drawn microfiber was used to demonstrate budget smartphone colorimetric-based absorption measurement to detect the degree of adulteration of olive oils with soybean oil.

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3D printed fiber optic faceplates by custom controlled fused deposition modeling

Cited by 32 publications

References 33 publications

Overview of 3D-Printed Silica Glass

Overview of 3D-Printed Silica Glass

Prospects for Additive Manufacturing in Contact Lens Devices

Low-Cost 3D Printer Drawn Optical Microfibers for Smartphone Colorimetric Detection

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