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Получение полианилина для противокоррозионных композиций на водной основе

Выпуск 24(1) от 2019 года.
Страницы 15-28

Т.Р. Вахитов, С.Р. Салихова, С.Н. Степин


Казанский Национальный Исследовательский Технологический Университет


Ключевые слова: проводящие полимеры, полианилин, лакокрасочные материалы, противокоррозионная защита

Полианилин (ПАНи) является органическим полимерным полупроводником с достаточно вы-
соким уровнем электронной проводимости, который сочетает в себе такие положительные качества, как низкая цена на мономер, отличная устойчивость к воздействиям внешней среды, низкая плотность и обратимые электрические свойства. ПАНи может быть синтезирован в виде сферических частиц, трубок, волокон и более сложных конфигураций, в том числе полых, в зависимости от условий синтеза и выбора исходных компонентов. Одним из множества применений ПАНи является его использование в качестве компонента противокоррозионных лакокрасочных покрытий. Для описания противокоррозионного действия ПАНи в литературе выделяют механизмы анодной и барьерной защиты, а также механизм ингибирования анионами допанта. Однако обусловленная жесткостью цепи макромолекулы нерастворимость ПАНи в растворителях, широко используемых при получении лакокрасочных материалов (ЛКМ), затрудняет его введение в их состав. Получение ПАНи, способного к переработке в водной среде, как экологически наиболее безопасной и удобной в использовании, с сохранением его проводящих свойств является актуальной проблемой, которую пытаются решить многие научные группы по всему миру. В данном обзоре обобщены результаты последних исследований в области синтеза ПАНи, обладающего повышенной гидрофильностью, и применению его в качестве ингибитора коррозии в составе ЛКМ на водной основе.

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