Аннотация:
Heat-resistant polymer composites were obtained from 4-[3-(prop-2-yn-1-yloxy)phenoxy]benzene-1,2-dicarbonitrile and carbon fabric by a vacuum infusion molding process. The composite materials demonstrated the retention of mechanical properties down to 80% at 350°C and low inflammability (limiting oxygen index, 75%).
Образец цитирования:
B. A. Bulgakov, K. S. Belsky, S. S. Nechausov, E. S. Afanaseva, A. V. Babkin, A. V. Kepman, V. V. Avdeev, “Carbon fabric reinforced propargyl ether/phthalonitrile composites produced by vacuum infusion”, Mendeleev Commun., 28:1 (2018), 44–46
Образцы ссылок на эту страницу:
https://www.mathnet.ru/rus/mendc1658
https://www.mathnet.ru/rus/mendc/v28/i1/p44
Эта публикация цитируется в следующих 27 статьяx:
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Daria I. Poliakova, Oleg S. Morozov, Sergey S. Nechausov, Ekaterina A. Afanaseva, Boris A. Bulgakov, Alexander V. Babkin, Alexey V. Kepman, Viktor V. Avdeev, “Fast curing phthalonitrile modified novolac resin: Synthesis, curing study and preparation of carbon and glass fibric composites”, Reactive and Functional Polymers, 181 (2022), 105450
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Z. N. Shchekoldina, A. A. Bogolyubov, A. Yu. Zakharov, B. A. Bulgakov, A. V. Babkin, A. V. Kepman, “Development of the technique for quality control of 1,3-bis(3,4-dicyanophenoxy)benzene by HPLC”, Fine Chem. Technol., 16:1 (2021), 88
B. A. Bulgakov, O. S. Morozov, I. A. Timoshkin, A. V. Babkin, A. V. Kepman, “Bisphthalonitrile-based Thermosets as Heat-resistant Matrices for Fiber Reinforced Plastics”, Polym. Sci. Ser. C, 63:1 (2021), 64
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M. V. Yakovlev, O. S. Morozov, E. S. Afanaseva, B. A. Bulgakov, A. V. Babkin, A. V. Kepman, V. V. Avdeev, “Trifunctional thermosetting monomer with propargyl and phthalonitrile groups”, Russ Chem Bull, 69:11 (2020), 2183
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I. A. Timoshkin, V. V. Aleshkevich, E. S. Afanas'eva, B. A. Bulgakov, A. V. Babkin, A. V. Kepman, V. V. Avdeev, “Heat-Resistant Carbon Fiber Reinforced Plastics Based on a Copolymer of Bisphthalonitriles and Bisbenzonitrile”, Polym. Sci. Ser. C, 62:2 (2020), 172
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