Enhancement of High-Resolution 3D Inkjet-Printing of Optical Freeform Surfaces Using Digital Twins

3D-inkjet-printing is just beginning to take off in the optical field. Advantages of this technique include its fast and cost-efficient fabrication without tooling costs. However, there are still obstacles preventing 3D inkjet-printing from a broad usage in optics, e.g., insufficient form fidelity. In this article, we present the formulation of a digital twin by the enhancement of an optical model by integrating geometrical measurement data. This approach strengthens the high-precision 3D printing process to fulfil optical precision requirements. A process flow between the design of freeform components, fabrication by inkjet printing, the geometrical measurement of the fabricated optical surface, and the feedback of the measurement data into the simulation model was developed, and its interfaces were defined. The evaluation of the measurements allowed for the adaptation of the printing process to compensate for process errors and tolerances. Furthermore, the performance of the manufactured component was simulated and compared with the nominal performance, and the enhanced model could be used for sensitivity analysis. The method was applied to a highly complex helical surface that allowed for the adjustment of the optical power by rotation. We show that sensitivity analysis could be used to define acceptable tolerance budgets of the process.

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Rapid prototyping of a novel and flexible paper based oxygen sensing patch via additive inkjet printing process

RSC Advances ◽

10.1039/c9ra02883h ◽

2019 ◽

Vol 9 (39) ◽

pp. 22695-22704 ◽

Cited By ~ 7

Author(s):

Dinesh Maddipatla ◽

Binu B. Narakathu ◽

Manuel Ochoa ◽

Rahim Rahimi ◽

Jiawei Zhou ◽

...

Keyword(s):

Rapid Prototyping ◽

Inkjet Printing ◽

Manufacturing Process ◽

Biomedical Applications ◽

Food Packaging ◽

Oxygen Sensing ◽

Low Cost ◽

Printing Process ◽

Cost Efficient ◽

First Time

A paper-based low cost and rapid prototypable flexible oxygen sensing patch was developed for the first time using a cost-efficient additive inkjet print manufacturing process for wearable, food packaging, pharmaceutical and biomedical applications.

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Additive manufacturing of thin electrolyte layers via inkjet printing of highly-stable ceramic inks

Journal of Advanced Ceramics ◽

10.1007/s40145-020-0439-9 ◽

2021 ◽

Author(s):

Zhongqi Zhu ◽

Zhiyuan Gong ◽

Piao Qu ◽

Ziyong Li ◽

Sefiu Abolaji Rasaki ◽

...

Keyword(s):

Inkjet Printing ◽

Polyacrylic Acid ◽

Storage Period ◽

Structural Quality ◽

Solid Loading ◽

Ultrasonic Dispersion ◽

Promising Alternative ◽

Printing Process ◽

High Solid ◽

High Solid Loading

AbstractInkjet printing is a promising alternative for the fabrication of thin film components for solid oxide fuel cells (SOFCs) due to its contactless, mask free, and controllable printing process. In order to obtain satisfying electrolyte thin layer structures in anode-supported SOFCs, the preparation of suitable electrolyte ceramic inks is a key. At present, such a kind of 8 mol% Y2O3-stabilized ZrO2 (8YSZ) electrolyte ceramic ink with long-term stability and high solid loading (> 15 wt%) seems rare for precise inkjet printing, and a number of characterization and performance aspects of the inks, such as homogeneity, viscosity, and printability, should be studied. In this study, 8YSZ ceramic inks of varied compositions were developed for inkjet printing of SOFC ceramic electrolyte layers. The dispersing effect of two types of dispersants, i.e., polyacrylic acid ammonium (PAANH4) and polyacrylic acid (PAA), were compared. The results show that ultrasonic dispersion treatment can help effectively disperse the ceramic particles in the inks. PAANH4 has a better dispersion effect for the inks developed in this study. The inks show excellent printable performance in the actual printing process. The stability of the ink can be maintained for a storage period of over 30 days with the help of initial ultrasonic dispersion. Finally, micron-size thin 8YSZ electrolyte films were successfully fabricated through inkjet printing and sintering, based on the as-developed high solid loading 8YSZ inks (20 wt%). The films show fully dense and intact structural morphology and smooth interfacial bonding, offering an improved structural quality of electrolyte for enhanced SOFC performance.

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Multicomponent oxide thin-film transistors fabricated by a double-layer inkjet printing process

Thin Solid Films ◽

10.1016/j.tsf.2011.04.149 ◽

2011 ◽

Vol 520 (4) ◽

pp. 1334-1340 ◽

Cited By ~ 8

Author(s):

Antonis Olziersky ◽

Anna Vilà ◽

Juan Ramón Morante

Keyword(s):

Thin Film ◽

Double Layer ◽

Inkjet Printing ◽

Thin Film Transistors ◽

Oxide Thin Film ◽

Printing Process ◽

Multicomponent Oxide

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The Study on Color Quality Attributes of IMR with PET on White Ink by UV Inkjet

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1004-1005.799 ◽

2014 ◽

Vol 1004-1005 ◽

pp. 799-802 ◽

Cited By ~ 1

Author(s):

Chang Lang Chen ◽

Yu Tung Chang ◽

Sheng Hao Taso ◽

Weichieh Hsu

Keyword(s):

Inkjet Printing ◽

Screen Printing ◽

Quality Attributes ◽

Gravure Printing ◽

Printing Process ◽

Color Quality ◽

Study Results ◽

Color Differences ◽

Pet Film ◽

Better Than

The In-Mold Roller is a revolutionary printing process by which objects are 3D decorated. Products decorated by In-Mold Roller are waterproof and protected from fading. What’s more, these kinds of decorations strongly increase the beauty, desirability and value of the objects. The In-Mold Roller is now using either of gravure printing and screen printing to print PET film. However, there are some problems with these two techniques. This research is to investigate potential usages of combining In-Mold Roller with digital UV inkjet printing in 3D decoration, e.g. in personalized printing services. Study results found that when the coverage and the resolution of inkjet printing become higher, the SIDs will become higher as well. When transferred to ABS, SIDs in each combination will increase. Each combination of inkjet conditions, with the isolation of white ink, color differences are less variant. TVIs of white ink decrease 30% to 40% halftone and display in “M” type. In print contrast, C and K colors of each combination are better than M and Y colors. After transferred into print contrast, each combination of PC will be higher about 2 to5. When transferred to ABS, color variances of each combination are not huge, and color differences are about 3to5.

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Research on Thermal Inkjet Technology Based on CFD

Materials Science Forum ◽

10.4028/www.scientific.net/msf.1032.101 ◽

2021 ◽

Vol 1032 ◽

pp. 101-107

Author(s):

Yi Fei Wang ◽

Zhong De Shan ◽

Hao Qin Yang ◽

Yong Xin Ren ◽

Ling Han Meng

Keyword(s):

Simulation Model ◽

Inkjet Printing ◽

Cfd Simulation ◽

Test Method ◽

Physical Parameters ◽

Printing Process ◽

Orthogonal Test Method ◽

Fluent Software ◽

Comparison Of The Results ◽

Thermal Inkjet Printing

In this paper, a thermal inkjet printing simulation model is established in the CFD simulation platform, and the influence of inkjet driver parameters and ink physical parameters on the printing process is studied by numerical simulation. The evaporation-condensation model is coupled with the VOF multiphase flow model in Fluent software to establish a thermal inkjet printing process simulation model. Based on the orthogonal test method, we investigate the influence of fluid physical parameters (ink viscosity, surface tension) and inkjet driver parameters (heater temperature value) on droplet formation by changing the physical parameters of the material and the boundary conditions of the model. Through the comparison of the results, exploring the adjustment rules of thermal inkjet technology and obtaining the optimal combination of material and process parameters for high-quality ink drop formation.

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CHAPTER 4. Unwanted Reactions of Polymers During the Inkjet Printing Process

Reactive Inkjet Printing - Smart Materials Series ◽

10.1039/9781788010511-00059 ◽

2017 ◽

pp. 59-87

Author(s):

Joseph S. R. Wheeler ◽

Stephen G. Yeates

Keyword(s):

Inkjet Printing ◽

Printing Process

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Design and Research of a Color Discrimination Method for Polycrystalline Silicon Cells Based on Laser Detection System

Applied Sciences ◽

10.3390/app9204468 ◽

2019 ◽

Vol 9 (20) ◽

pp. 4468

Author(s):

Zijian Chen ◽

Shiyu Wang ◽

Lian Zhang ◽

Zenghong Ma

Keyword(s):

Polycrystalline Silicon ◽

Detection System ◽

Measurement Data ◽

Optical Power ◽

Color Discrimination ◽

Laser Detection ◽

Coaxial System ◽

Power Meter ◽

Optical Shutters ◽

Silicon Cell

In this paper, a method of color discrimination based on sample sensitivity to light wavelength is proposed based on the reflection spectra of a large number of samples and the statistical calculation of the measurement data. A laser detection system is designed to realize the color discrimination. For the color discrimination of polycrystalline silicon cells, the most sensitive wavelength, 434 nm, and the least sensitive wavelength, 645 nm, of polycrystalline silicon cells is obtained according to this method. A laser detection system was built to measure the polycrystalline silicon cells. This system consists of two lasers, optical shutters, collimating beam expanding systems, an optical coaxial system, sample platform, collecting lens, and optical power meter or optical sensor. Two laser beams of different wavelengths are beamed coaxially through the optical coaxial system onto a polycrystalline silicon cell and are reflected or scattered. The reflected or scattered lights are collected through a lens with a high number aperture and received separately by the optical power meter. Then the color value of the polycrystalline silicon cell in this system is characterized by the ratio of light intensity data received. The system measured a large number of previous polycrystalline silicon cells to form the different color categories of polycrystalline silicon cells of this system in the computer database. When a new polycrystalline silicon cell is measured, the color discrimination system can automatically classify the new polycrystalline silicon cell to a certain color category in order to achieve color discrimination.

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