Characterization of process and machine dynamics on the precision replication of microlens arrays using microinjection moulding

Adv search

Characterization of process and machine dynamics on the precision replication of microlens arrays using microinjection moulding

Hao-Yang Zhang , Nan Zhang , Wei Han , Hong-Gang Zhang , Michael D. Gilchrist , Feng-Zhou Fang

Advances in Manufacturing ›› 2021, Vol. 9 ›› Issue (3) : 319 -341.

PDF

Advances in Manufacturing ›› 2021, Vol. 9 ›› Issue (3) : 319 -341. DOI: 10.1007/s40436-020-00341-y

Article

Characterization of process and machine dynamics on the precision replication of microlens arrays using microinjection moulding

Author information +

¹ State Key Laboratory of Precision Measuring Technology and Instruments, Laboratory of MicroNano Manufacturing Technology (MNMT), Tianjin University, 300072, Tianjin, People’s Republic of China

² Centre of MicroNano Manufacturing Technology (MNMT-Dublin), School of Mechanical and Materials Engineering, University College Dublin, Belfield, Dublin 4, Ireland

³ Key Laboratory of Computational Optical Imaging Technology, Chinese Academy of Sciences, 100094, Beijing, People’s Republic of China

^b nan.zhang@ucd.ie

^f fzfang@tju.edu.cn

Hao-Yang Zhang is a joint Ph.D. candidate in the Laboratory of MicroNano Manufacturing Technology at Tianjin University and the Centre of MicroNano Manufacturing Technology at University College Dublin. His research concerns precision injection moulding of optics and microfluidics, nanoimprinting and process simulation.

[graphic not available: see fulltext]

Nan Zhang is a Lecturer/Assistant Professor in Manufacturing and Design in the School of Mechanical and Materials Engineering at University College Dublin. His team works in three areas: precision fabrication of polymeric microfluidics, functional surfaces and medical devices, and atomic and close to atomic scale manufacturing. He is the chair of 6th International Conference on Polymer Replication on the Nanoscale.

[graphic not available: see fulltext]

Wei Han is a Senior Engineer working in the Key Laboratory of Computational Optical Imaging Technology of Chinese Academy of Sciences. Her main research interests include optical inspection and spectral imaging technology.

[graphic not available: see fulltext]

Hong-Gang Zhang is a Ph.D. candidate in the Centre of MicroNano Manufacturing Technology (MNMT) at University College Dublin. His research interests include the development of precision electroforming process, micro/nanofabrication and functional nanocomposite electrodeposition.

[graphic not available: see fulltext]

Michael D. Gilchrist is Full Professor of Mechanical Engineering at University College Dublin. He served as Head of UCD’s School of Mechanical & Materials Engineering from 2011-18. His research interests are focussed on micro/nanomanufacturing with polymers, particularly via moulding and forming processes. He is also interested in soft tissue biomechanics and the response of biological tissue to mechanical forces.

[graphic not available: see fulltext]

Feng-Zhou Fang is a joint Professor working in the Laboratory of MicroNano Manufacturing Technology at Tianjin University and the Centre of MicroNano Manufacturing Technology at University College Dublin. His research interests are in the areas of optical freeform design and manufacturing, visual optics and implants manufacturing, ACSM, ultra-precision manufacturing and metrology. He is the editor-in-chief of Nanomanufacturing and Metrology.

[graphic not available: see fulltext]

Show less

History +

PDF

Abstract

Injection moulding has shown its advantages and prevalence in the production of plastic optical components, the performance and functionality of which rely on the precision replication of surface forms and on minimizing residual stress. The present work constitutes a systematic and comprehensive analysis of practical microlens arrays that are designed for light-field applications. Process parameters are screened and optimized using a two-stage design of experiments approach. Based on in-line process monitoring and a quantitative and qualitative evaluation being carried out in terms of geometric accuracy, surface quality and stress birefringence, the replication is shown to relate directly to machine settings and dynamic machine responses. The geometric accuracy and stress birefringence are both largely associated with screw displacement and peak cavity pressure during the packing stage, while surface quality is closely related to cavity temperature. This study provides important insights and recommendations regarding the overall replication quality of microlens arrays, while advanced injection moulding solutions may be necessary to further improve the general replication quality.

Keywords

Optics / Process monitoring / Form / Roughness / Residual stress / Sensor

Cite this article

Download citation ▾

Hao-Yang Zhang, Nan Zhang, Wei Han, Hong-Gang Zhang, Michael D. Gilchrist, Feng-Zhou Fang. Characterization of process and machine dynamics on the precision replication of microlens arrays using microinjection moulding. Advances in Manufacturing, 2021, 9(3): 319-341 DOI:10.1007/s40436-020-00341-y

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Huang C, Li L, Yi AY. Design and fabrication of a micro Alvarez lens array with a variable focal length. Microsyst Technol, 2009, 15(4): 559-563.

[2]	Fang FZ, Zhang N, Zhang X (2016) Precision injection molding of freeform optics. Adv Opt Technol 5(4). https://doi.org/10.1515/aot-2016-0033

[3]	Cirino GA, Granado RM, Mohammed-Brahim T, et al. Assessment of replication fidelity of optical microstructures by hot embossing. Int J Adv Manuf Technol, 2017, 88(1/4): 303-316.

[4]	Zhang HY, Fang FZ, Gilchrist MD, et al. Filling of high aspect ratio micro features of a microfluidic flow cytometer chip using micro injection moulding. J Micromech Microeng, 2018, 28(7): 075005.

[5]	Xue B, Geng Y, Wang D, et al. Improvement in surface quality of microchannel structures fabricated by revolving tip-based machining. Nanomanuf Metrol, 2019, 2(1): 26-35.

[6]	Cai Y, Xu Z, Wang H, et al. A sequential process for manufacturing nature-inspired anisotropic superhydrophobic structures on AISI 316L stainless steel. Nanomanuf Metrol, 2019, 2(3): 148-159.

[7]	Chen J, Cheng J, Zhang D, et al. Precision UV imprinting system for parallel fabrication of large-area micro-lens arrays on non-planar surfaces. Precision Eng, 2016, 44: 70-74.

[8]	Hou T, Zheng C, Bai S, et al. Fabrication, characterization, and applications of microlenses. Appl Opt, 2015, 54(24): 7366-7376.

[9]	Pang K, Song L, Fang FZ, et al. An imaging system with a large depth of field based on an overlapped micro-lens array. CIRP Annals Manuf Technol, 2016, 65(1): 471-474.

[10]	Bäumer S. Handbook of plastic optics, 2010, Hoboken: Wiley Online Library.

[11]	Li S, Yuan Y, Liu B, et al. Influence of microlens array manufacturing errors on light-field imaging. Opt Commun, 2018, 410: 40-52.

[12]	Stevens RF, Miyashita T. Review of standards for microlenses and microlens arrays. Imaging Sci J, 2010, 58(4): 202-212.

[13]	Guevara-Morales A, Figueroa-López U. Residual stresses in injection molded products. J Mater Sci, 2014, 49(13): 4399-4415.

[14]	Manaf ARA, Yan J. Improvement of form accuracy and surface integrity of Si-HDPE hybrid micro-lens arrays in press molding. Precision Eng, 2017, 47: 469-479.

[15]	Dick L, Risse S, Tunnermann A. Injection molded high precision freeform optics for high volume applications. Adv Opt Technol, 2012, 1(3): 39-50.

[16]	Lou C, Chiang Y, Cheng H, et al. A novel and rapid fabrication for microlens arrays using microinjection molding. Polym Eng Sci, 2011, 51(2): 391-402.

[17]	Weng C, Lee WB, To S. Birefringence techniques for the characterization of residual stresses in injection-moulded micro-lens arrays. Polym Testing, 2009, 28(7): 709-714.

[18]	Tsai K, Hsieh C, Lo W. A study of the effects of process parameters for injection molding on surface quality of optical lenses. J Mater Process Technol, 2009, 209(7): 3469-3477.

[19]	Kirchberg S, Chen L, Xie L, et al. Replication of precise polymeric microlens arrays combining ultra-precision diamond ball-end milling and micro injection molding. Microsyst Technol, 2012, 18(4): 459-465.

[20]	Weng C, Lee WB, To S. A study of the relevant effects on the maximum residual stress in the precision injection moulding of microlens arrays. J Micromech Microeng, 2010, 20(3): 035033.

[21]	Montgomery DC. Design and analysis of experiments, 2017, Hoboken: Wiley

[22]	Kamal MR, Isayev AI, Liu SJ. Injection molding: technology and fundamentals, 2009, Munich: Hanser Gardner Publications.

[23]	Macías C, Meza O, Pérez E. Relaxation of residual stresses in plastic cover lenses with applications in the injection molding process. Eng Fail Anal, 2015, 57: 490-498.

[24]	Lee YB, Kwon TH, Yoon K. Numerical prediction of residual stresses and birefringence in injection/compression molded center-gated disk. Part I: Basic modeling and results for injection molding. Polymer Eng Sci, 2002, 42(11): 2246-2272.

[25]	Ramesh K. Digital photoelasticity: advanced techniques and applications, 2000, 2000, Berlin: Springer.

[26]	Zhang N, Gilchrist M. Characterization of thermo-rheological behavior of polymer melts during the micro injection moulding process. Polym Testing, 2012, 31(6): 748-758.

[27]	Kobayashi T, Sera H, Wakabayashi T, et al. Surface flattening and nanostructuring of steel by picosecond pulsed laser irradiation. Nanomanuf Metrol, 2018, 1(4): 217-224.

[28]	Michaeli W, Heßner S, Klaiber F, et al. Geometrical accuracy and optical performance of injection moulded and injection-compression moulded plastic parts. CIRP Ann Manuf Technol, 2007, 56(1): 545-548.

[29]	Kayano Y, Zouta K, Takahagi S, et al. Replication properties and structure of PC in micromolding with heat insulator mold using zirconia ceramic. Int Polym Proc, 2011, 26(3): 304-312.

[30]	Siegmann A, Buchman A, Kenig S. Residual stresses in polymers III: The influence of injection-molding process conditions. Polym Eng Sci, 1982, 22(9): 560-568.

[31]	Zhang N, Choi SY, Gilchrist MD. Flow induced crystallization of poly (ether-block-amide) from the microinjection molding process and its effect on mechanical properties. Macromol Mater Eng, 2014, 299(11): 1362-1383.

[32]	Lai HE, Wang PJ. Study of process parameters on optical qualities for injection-molded plastic lenses. Appl Opt, 2008, 47(12): 2017-2027.

[33]	Zhang N, Zhang HY, Stallard CP, et al. Replication integrity of micro features using variotherm and vacuum assisted microinjection moulding. CIRP J Manuf Sci Technol, 2018, 23: 20-38.

Funding

China Scholarship Council http://dx.doi.org/10.13039/501100004543

National Natural Science Foundation of China http://dx.doi.org/10.13039/501100001809(61675149)

Science Foundation Ireland(15/RP/B3208)

AI Summary AI Mindmap

PDF

155

Accesses

0

Citation

Detail

Sections

Recommended

/

〈

〉