As presented at the recent TechBlick’s Future of Electronics RESHAPED USA event held in Boston, our project, Multilayer Flexible Displays Using Electroluminescent Ink, validated the use of the Voltera NOVA material dispensing system to print a multilayer electroluminescent display on PET and paper using various Saralon inks.
In this article, we explain how this project was achieved, covering the inks and substrates used, the steps we followed, as well as challenges and tips on printing flexible multilayer projects using the direct-ink-write technology.
Contact: sales@voltera.io or +1 888-381-3332 ext: 1
Summary of Materials and Tools
MATERIALS USED
SUBSTRATES USED
Cardstock paper
TOOLS AND ACCESSORIES
Project Overview
Purpose
The purpose of this project was to demonstrate the multilayer capability of Voltera NOVA. We printed a blue light-emitting pattern - the Voltera logo - on two substrates: paper and PET separately, using electroluminescent ink.
Design layout
Electroluminescence operates by exciting a phosphor material with an electric field. An inverter is needed to convert the direct current from the power source into alternating current.
Based on this mechanism, our design positioned a phosphor layer between two conductive layers, incorporating a dielectric ink layer to insulate the phosphor. The printing sequence was as follows:
Layer 1: Base conductive layer
Layer 2: Dielectric layer
Layer 3: Phosphor layer
Layer 4: Top conductive layer
Desired outcome
Once connected to an alternating current (140 V, 1.862 kHz), the phosphor layer should emit blue light, illuminating the Voltera logo with an even glow across both prints.
Functionality
We determined the Voltera logo would be suitable for this project. It is feasible to incorporate designs into larger electronic applications, including billboards, branded merchandise, and control panels.
Printing the electroluminescent Voltera logo
Base conductive layer (1)
This layer consists of a Voltera logo pattern (55.5 mm L × 19.75 mm W) and positive and negative traces that connect to power and ground terminals.
Print settings on NOVA software (1)
Result on paper (left) and on PET (right) (1)
Dielectric layer (2)
This layer features a dielectric Voltera logo pattern which measures 23 mm L × 15 mm W and two dielectric pads. These extra pads help ensure the top conductive layer is appropriately insulated.
Print settings on NOVA software (2)
Result on paper (left) and on PET (right) (2)
Phosphor layer (3)
This layer contains a Voltera logo pattern, slightly smaller than the dielectric layer (by 0.5 mm each way), printed with blue light-emitting ink.
Print settings on NOVA software (3)
Result on paper (left) and on PET (right) (3)
Top conductive layer (4)
Lastly, this layer includes a conductive overlay with an opening at the bottom left to prevent short-circuiting. It measures 29.5 mm L × 21.5 mm W and connects to the ground terminal.
Print settings on NOVA software
Result on paper (left) and on PET (right) (4)
Challenges and advice for printing multilayer electroluminescent displays
Trapped air
Air bubbles can form in inks that have been left unused for an extended period. These bubbles caused the dielectric layer to break when we cured it in the oven.
Mixing the ink with a dual asymmetric centrifugal mixer before printing will eliminate air bubbles. Additionally, it is recommended to allow the dielectric layer to dry naturally at room temperature instead of curing it in an oven.
Uneven glow
During our experiments, some prints exhibited dark areas, leading to an uneven glow. This issue can arise from several factors:
The top conductive layer being too thick
The phosphor layer being too thin or getting scratched off during dispensing of the ink for the top conductive layer
Irregularities in print height
Adding fiducials to each layer helps improve alignment and print quality. In terms of print settings, if the layer is too thick, increasing the print speed, reducing the height (we reduced it to approximately 40 µm), and using a smaller nozzle can be helpful. If the layer is too thin, try to reduce the print speed.
Furthermore, in multilayer projects, changes in height can happen drastically when printing over existing traces. Setting a low probe pitch will make the height map more accurate, ensuring the height transition at the edges of features is accurate and reducing the risk of traces being printed off-course.
Conclusion
The paper substrate provided consistent results throughout our experimentation, due to its absorbent nature. Each layer was smoother on paper than on PET, highlighting the potential of using paper as a substrate in EL display applications.
On the other hand, PET, being flexible and chemically resistant, offers the advantage of suitability for more demanding use cases. As demonstrated by this project, with careful attention and fine-tuning of the print settings, the results of EL display on PET are equally impressive.
Electroluminescent logo final print
EL displays are also intriguing when printed on glass and other non-conductive substrates. As we continue to explore the possibilities of electroluminescent displays, we invite you to view the other application projects we’ve completed using NOVA and V-One.
In the meantime, if you’d like to discuss your designs or our NOVA materials dispensing system, please contact us at sales@voltera.io.
We are Exhibiting in Berlin.
Visit our booth at the TechBlick event on 23-24 October 2024 in Berlin.
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