Thermo-mechanical modeling of thermal stress during multi-cycle intense pulsed light sintering of thick conductive wires on 3D printed dark substrate

[Display omitted] •The finite element analysis is used to study the in-situ evolution and reduction of thermal stresses during IPL sintering.•Larger thermal stress is generated at the upper surface of the silver and near the silver-substrate interface.•The maximum thermal stress generated during the...

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Bibliographic Details
Published in:Results in physics 2023-01, Vol.44, p.106192, Article 106192
Main Authors: Li, Xin, Lei, Ming, Mu, Quanyi, Ren, Keliang
Format: Article
Language:English
Subjects:
FE modeling
Hybrid 3D printing
IPL sintering
Thermal stress
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Summary:[Display omitted] •The finite element analysis is used to study the in-situ evolution and reduction of thermal stresses during IPL sintering.•Larger thermal stress is generated at the upper surface of the silver and near the silver-substrate interface.•The maximum thermal stress generated during the first sintering cycle and cooling to room temperature stage.•The multi-cycle sintering method reduces thermal stress and thus failures that occurs during the sintering process.•A higher total energy combined with multi-cycle sintering method is proposed to reduce the maximum thermal stress. Due to its advantage of rapid, selective and no contact sintering, the intense pulsed light (IPL) sintering of the conductive wires is promising to simplify the hybrid printing of the fully printed electronics. However, this fast IPL sintering process is often plagued with reproducibility of the results and morphological deterioration in the product. Since exposure to high-intensity light generates temperature gradient inside samples, accurate prediction of the thermally induced residual stresses is the key issue in improving the reproducibility of the IPL sintering. In this study, we investigated how total light energy, light exposure cycle and cooling time affect the thermal stress. The finite element analysis was used to study the in-situ evolution and reduction method of thermal stresses during multi-cycle IPL sintering of thick conductive wires on 3D printed substrate, and the experiments were used to verify the analytic results. The position and sintering stage that generated the maximum thermal stress was found, then light exposure cycle and cooling time were varied to reduce the maximum thermal stress. Finally, a higher total energy combined with multi-cycle sintering method was proposed to reduce the maximum thermal stress and obtain good sintering performance. The proposed method is reliable for optimizing the pulsed light setting. This work provides an insight for optimizing the sintering methodology to improve the IPL sintering stability.
ISSN:2211-3797
2211-3797
DOI:10.1016/j.rinp.2022.106192