Commercially available granulates PMMA and PS - potential problems with the production of polymer optical fibers

IF 0.5 Q4 OPTICS

Photonics Letters of Poland Pub Date : 2020-09-30 DOI:10.4302/PLP.V12I3.1036

Mateusz Józwicki, M. Gargol, Małgorzata Gil-Kowalczyk, P. Mergo

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引用次数: 0

Abstract

The aim of the study was to verify the usefulness of commercially available granulates of PMMA (poly (methyl methacrylate) and PS (polystyrene) for the production of polymer optical fibers by extrusion method. Samples were subjected to thermal processing in various conditions (different temperatures and exposure time). Thermal (TG/DTG) and spectroscopic (ATR/FT-IR) analyses were carried out to analyze changes in the samples. Based on FT-IR analysis of liquid monomers and granulates the conversion of double bonds was calculated, which gave us a picture of the degree of monomers conversion, crucial information from the technological point of view. Full Text: PDF References O. Ziemann, J. Krauser, P.E. Zamzow, W. Daum, POF Polymer Optical Fibersfor Data Communication (Berlin: Springer 2008). DirectLink P. Stajanca et al. "Solution-mediated cladding doping of commercial polymer optical fibers", Opt. Fiber Technol. 41, 227-234, (2018). CrossRef K. Peters, "Polymer optical fiber sensors—a review", Smart Mater. Struct., 20 013002 (2011) CrossRef J. Zubia and J. Arrue, "Plastic Optical Fibers: An Introduction to Their Technological Processes and Applications", Opt. Fiber Technol. 7 ,101-40 (2001) CrossRef M. Beckers, T. Schluter, T. Gries, G. Seide, C.-A. Bunge, "6 - Fabrication techniques for polymer optical fibres", Polymer Optical Fibres, 187-199 (2017) CrossRef M. Niedźwiedź , M. Gil, M. Gargol , W. Podkościelny, P. Mergo, "Determination of the optimal extrusion temperature of the PMMA optical fibers", Phot. Lett. Poland 11, 7-9 (2019) CrossRef

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商用颗粒PMMA和PS-聚合物光纤生产的潜在问题

本研究的目的是验证市售PMMA（聚甲基丙烯酸甲酯）和PS（聚苯乙烯）颗粒在通过挤出法生产聚合物光纤方面的有用性。样品在各种条件下（不同的温度和暴露时间）进行热处理。进行热分析（TG/DTG）和光谱分析（ATR/FT-IR）以分析样品中的变化。基于对液体单体和颗粒的FT-IR分析，计算了双键的转化率，这为我们提供了单体转化率的图像，这是从技术角度的关键信息。全文：PDF参考文献O.Ziemann，J.Krauser，P.E.Zamzow，W.Daum，数据通信用POF聚合物光纤（柏林：施普林格，2008年）。DirectLink P.Stajanca等人“商业聚合物光纤的溶液介导包层掺杂”，Opt。纤维技术。41227-234，（2018）。CrossRef K.Peters，“聚合物光纤传感器——综述”，Smart Mater。结构。，20 013002（2011）CrossRef J.Zubia和J.Arrue，“塑料光纤：介绍其技术过程和应用”，Opt。纤维技术。7101-40（2001）CrossRef M.Beckers，T.Schluter，T.Gries，G.Seide，C.-A.Bunge，“6-聚合物光纤的制造技术”，《聚合物光纤》，187-199（2017），CrossRef M.Nied罗兹，M.Gil，M.Gargol，W.Podkościelny，P.Mergo，“确定PMMA光纤的最佳挤出温度”，Phot。Lett。波兰11，7-9（2019）CrossRef

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来源期刊

Photonics Letters of Poland OPTICS-

CiteScore

1.40

自引率

0.00%

发文量