بررسی بهبود عملکرد رزینهای اپوکسی با استفاده از نانومواد کربنی
محورهای موضوعی :سید مرتضی نقیب 1 , سیامک ایمانیان 2
1 - فناوری های نوین
2 - دانشگاه علم و صنعت
کلید واژه: رزین اپوکسی نانومواد کربنی هدایت حرارتی بازدارندگی شعله هدایت الکتریکی,
چکیده مقاله :
اپوکسی، یکی از مهمترین پلیمرهای ترموست، در طیف گستردهای از کاربردها به عنوان چسب، پوشش، و ماده زمینه برای ساختار کامپوزیتها به علت عملکرد فوق العاده، قابلیت عملآوری و هزینه کم، استفاده میشود. به دلیل برتر بودن خواص نانومواد کربنی در هدایت حرارتی، بازدارندگی شعله، ثبات مکانیکی، هدایت الکتریکی و سازگاری با محیط زیست، این نانومواد توجه جهانی را به خود جلب کردهاند. در مقاله حاضر یک بررسی از ادبیات گذشته در مورد بهبود عملکرد رزین اپوکسی با افزودن نانومواد کربنی ارائه شده است. ارتباط عملکرد ساختاری برای اپوکسی اصلاح شده با نانومواد مختلف کربنی از نزدیک مورد تجزیه و تحلیل قرار گرفته است. بهبود عملکرد مکانیکی، الکتریکی، هدایت حرارتی و بازدارندگی شعله برای اپوکسی رزین بررسی شده است. چالشها و فرصتهای موجود در کامپوزیت نانومواد کربنی عاملدار شده- اپوکسی، نیز مورد بحث قرار گرفته است. هدف این تحقیق ارائه یک درک جامع از رزینهای اپوکسی چند منظوره شامل نانومواد کربنی تا به امروز و ارزیابی چشم انداز آینده آن است. همچنین ارتباط و مقایسه ساختار و عملکرد نانومواد کربنی مختلف مورد ارزیابی قرار گرفته است. بهبود خواص مکانیکی، الکتریکی، هدایت حرارتی و بازدارندگی شعله اپوکسی- نانوپرکنندههای کربنی، به طور دقیق بررسی شده است. در نهایت، نتیجهگیری و چشم انداز آینده و امید به تسهیل پیشرفت در پایان مقاله ارائه شده است.
Epoxy, one of the most important thermosetting polymers, is used in a wide range of applications as adhesives, coatings, and materials for composite structures due to its outstanding performance, low processing capacity and low cost. Due to the superior properties of carbon nanomaterials in thermal conductivity, flame retardation, mechanical stability, electrical conductivity and environmental compatibility, these nanomaterials have attracted global attention. In the present article, a review of past literature on improving the performance of epoxy resin by adding carbon nanomaterials is presented. The correlation of structural performance for epoxy modified with various carbon nanomaterials has been closely analyzed. Improvement of mechanical, electrical, thermal conductivity and flame deterioration for epoxy resin has been investigated. Challenges and opportunities in the composite of functionalized nano-materials epoxy are also discussed. The purpose of this research is to provide a comprehensive understanding of the multi-purpose epoxy resins including carbon nanomaterials to date and assess its future prospects. Also, the relationship and comparison of the structure and performance of various carbon nanomaterials has been evaluated. The improvement of mechanical, electrical, thermal conductivity and carbon dioxide epoxy flame retardant properties has been thoroughly investigated. Finally, the conclusions and prospects for the future and the hope of facilitating progress are presented at the end of the paper.
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