Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses

Liheng Gao; Tianfeng Zhou; Gang Wang; Peihuan Li; Yubing Guo; Xibin Wang

doi:10.1117/12.2654916

Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses

Liheng Gao, Tianfeng Zhou^*, Gang Wang, Peihuan Li, Yubing Guo, Xibin Wang

^*Corresponding author for this work

Beijing Institute of Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Citation (Scopus)

Abstract

Precision glass molding (PGM) technology is one of the best methods for processing optical glass lenses, but the incomplete filling in the PGM process has a negative impact on the accuracy of the fabricated aspherical glass microlenses (AGM). It is found that the main reason for this phenomenon is trapped gas between the mold and the glass preform during PGM process. This study observed the gas trapping morphology of the prepared AGM, theoretically analyzed and numerically simulated the formation of trapped gas, and developed the method of eliminating trapped gas induced filling defects. Specifically, in the molding process, the gas trapped in the molding chamber is difficult to be released. We proposed to lower the temperature of the glass and mold to make the softened glass return to the glass state, so that the gas can flow between the two surfaces to achieve the purpose of releasing the trapped gas. When the pressure gas is released, a second molding can effectively improve the filling effect. We call this process cooled down molding (CDM). Experimental results prove that CDM can effectively improve the filling rate in a short period of time and filling defects can be effectively eliminated by designing CDM molding process.

Original language	English
Title of host publication	Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022
Editors	Xuejun Zhang, Hongbo Sun, Yuegang Fu, Lingbao Kong, Dawei Zhang, Donglin Xue, Changxi Xue
Publisher	SPIE
ISBN (Electronic)	9781510661264
DOIs	https://doi.org/10.1117/12.2654916
Publication status	Published - 2023
Event	Advanced Optical Manufacturing Technologies and Applications 2022, AOMTA 2022 and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2022 - Changchun, China Duration: 29 Jul 2022 → 31 Jul 2022

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	12507
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Advanced Optical Manufacturing Technologies and Applications 2022, AOMTA 2022 and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2022
Country/Territory	China
City	Changchun
Period	29/07/22 → 31/07/22

Keywords

Aspherical glass microlenses
Cooled down molding
Glass molding
Trapped gas

Access to Document

10.1117/12.2654916

Cite this

Gao, L., Zhou, T., Wang, G., Li, P., Guo, Y., & Wang, X. (2023). Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses. In X. Zhang, H. Sun, Y. Fu, L. Kong, D. Zhang, D. Xue, & C. Xue (Eds.), Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022 Article 125070Q (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12507). SPIE. https://doi.org/10.1117/12.2654916

Gao, Liheng ; Zhou, Tianfeng ; Wang, Gang et al. / Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses. Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022. editor / Xuejun Zhang ; Hongbo Sun ; Yuegang Fu ; Lingbao Kong ; Dawei Zhang ; Donglin Xue ; Changxi Xue. SPIE, 2023. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{25822dc9959b43c084bfc17a3de2e61b,

title = "Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses",

abstract = "Precision glass molding (PGM) technology is one of the best methods for processing optical glass lenses, but the incomplete filling in the PGM process has a negative impact on the accuracy of the fabricated aspherical glass microlenses (AGM). It is found that the main reason for this phenomenon is trapped gas between the mold and the glass preform during PGM process. This study observed the gas trapping morphology of the prepared AGM, theoretically analyzed and numerically simulated the formation of trapped gas, and developed the method of eliminating trapped gas induced filling defects. Specifically, in the molding process, the gas trapped in the molding chamber is difficult to be released. We proposed to lower the temperature of the glass and mold to make the softened glass return to the glass state, so that the gas can flow between the two surfaces to achieve the purpose of releasing the trapped gas. When the pressure gas is released, a second molding can effectively improve the filling effect. We call this process cooled down molding (CDM). Experimental results prove that CDM can effectively improve the filling rate in a short period of time and filling defects can be effectively eliminated by designing CDM molding process.",

keywords = "Aspherical glass microlenses, Cooled down molding, Glass molding, Trapped gas",

author = "Liheng Gao and Tianfeng Zhou and Gang Wang and Peihuan Li and Yubing Guo and Xibin Wang",

note = "Publisher Copyright: {\textcopyright} 2023 SPIE.; Advanced Optical Manufacturing Technologies and Applications 2022, AOMTA 2022 and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2022 ; Conference date: 29-07-2022 Through 31-07-2022",

year = "2023",

doi = "10.1117/12.2654916",

language = "English",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Xuejun Zhang and Hongbo Sun and Yuegang Fu and Lingbao Kong and Dawei Zhang and Donglin Xue and Changxi Xue",

booktitle = "Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022",

address = "United States",

}

Gao, L, Zhou, T, Wang, G, Li, P, Guo, Y & Wang, X 2023, Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses. in X Zhang, H Sun, Y Fu, L Kong, D Zhang, D Xue & C Xue (eds), Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022., 125070Q, Proceedings of SPIE - The International Society for Optical Engineering, vol. 12507, SPIE, Advanced Optical Manufacturing Technologies and Applications 2022, AOMTA 2022 and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2022, Changchun, China, 29/07/22. https://doi.org/10.1117/12.2654916

Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses. / Gao, Liheng; Zhou, Tianfeng; Wang, Gang et al.
Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022. ed. / Xuejun Zhang; Hongbo Sun; Yuegang Fu; Lingbao Kong; Dawei Zhang; Donglin Xue; Changxi Xue. SPIE, 2023. 125070Q (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 12507).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses

AU - Gao, Liheng

AU - Zhou, Tianfeng

AU - Wang, Gang

AU - Li, Peihuan

AU - Guo, Yubing

AU - Wang, Xibin

PY - 2023

Y1 - 2023

N2 - Precision glass molding (PGM) technology is one of the best methods for processing optical glass lenses, but the incomplete filling in the PGM process has a negative impact on the accuracy of the fabricated aspherical glass microlenses (AGM). It is found that the main reason for this phenomenon is trapped gas between the mold and the glass preform during PGM process. This study observed the gas trapping morphology of the prepared AGM, theoretically analyzed and numerically simulated the formation of trapped gas, and developed the method of eliminating trapped gas induced filling defects. Specifically, in the molding process, the gas trapped in the molding chamber is difficult to be released. We proposed to lower the temperature of the glass and mold to make the softened glass return to the glass state, so that the gas can flow between the two surfaces to achieve the purpose of releasing the trapped gas. When the pressure gas is released, a second molding can effectively improve the filling effect. We call this process cooled down molding (CDM). Experimental results prove that CDM can effectively improve the filling rate in a short period of time and filling defects can be effectively eliminated by designing CDM molding process.

AB - Precision glass molding (PGM) technology is one of the best methods for processing optical glass lenses, but the incomplete filling in the PGM process has a negative impact on the accuracy of the fabricated aspherical glass microlenses (AGM). It is found that the main reason for this phenomenon is trapped gas between the mold and the glass preform during PGM process. This study observed the gas trapping morphology of the prepared AGM, theoretically analyzed and numerically simulated the formation of trapped gas, and developed the method of eliminating trapped gas induced filling defects. Specifically, in the molding process, the gas trapped in the molding chamber is difficult to be released. We proposed to lower the temperature of the glass and mold to make the softened glass return to the glass state, so that the gas can flow between the two surfaces to achieve the purpose of releasing the trapped gas. When the pressure gas is released, a second molding can effectively improve the filling effect. We call this process cooled down molding (CDM). Experimental results prove that CDM can effectively improve the filling rate in a short period of time and filling defects can be effectively eliminated by designing CDM molding process.

KW - Aspherical glass microlenses

KW - Cooled down molding

KW - Glass molding

KW - Trapped gas

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DO - 10.1117/12.2654916

M3 - Conference contribution

AN - SCOPUS:85147198644

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022

A2 - Zhang, Xuejun

A2 - Sun, Hongbo

A2 - Fu, Yuegang

A2 - Kong, Lingbao

A2 - Zhang, Dawei

A2 - Xue, Donglin

A2 - Xue, Changxi

PB - SPIE

T2 - Advanced Optical Manufacturing Technologies and Applications 2022, AOMTA 2022 and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2022

Y2 - 29 July 2022 through 31 July 2022

ER -

Gao L, Zhou T, Wang G, Li P, Guo Y , Wang X. Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses. In Zhang X, Sun H, Fu Y, Kong L, Zhang D, Xue D, Xue C, editors, Advanced Optical Manufacturing Technologies and Applications 2022; and 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, AOMTA and YSAOM 2022. SPIE. 2023. 125070Q. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2654916

Generation mechanism and elimination method of gas trapping defect during precision glass molding for aspherical glass microlenses

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