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New Approach on Improving Mechanical Properties of Hybrid Composite by Adding Mica as Natural Fiber with Glass Fiber Reinforced Epoxy Composites | ||
| Kerbala Journal for Engineering Sciences (KJES) | ||
| Article 1, Volume 3, Issue 1, 2023, Pages 1-14 PDF (557.09 K) | ||
| Document Type: Research Article | ||
| DOI: 10.63463/kjes1066 | ||
| Authors | ||
| Mohammed Rashad* 1; Gailan Ismail Hassan2 | ||
| 1Erbil Polytechnic University, Erbil Technical Engineering College, Mechanical and Energy Engineering Department, Erbil, Iraq | ||
| 2Mechanical & Energy Technical Eng., Erbil Technical Eng. College, Erbil Polytechnic University, Erbil, Iraq | ||
| Abstract | ||
| A new attempt development of new hybrid composite materials has been studied. Increasing the mechanical and physical properties of composite materials to lower their weight and cost is the most frequent problem in engineering projects. This study's goal is to enhance the mechanical and physical characteristics of composite materials. Also due to this, hybrid composite materials have received recent attention. In this work, hybrid composite materials were created to enhance mechanical and physical characteristics. In this investigation, glass fiber and mica fiber were both employed as synthetic and natural fibers, respectively. The influence of mica as natural fiber with glass fiber as synthetic reinforcement by weight percent (wt%) on the mechanical properties of hybrid composite materials were investigated. Epoxy resin (thermosetting polymer) reinforced by various wt % of glass fiber/mica fiber, such as (0-0, 15-0, 10-5, 7.5-7.5, 5-10, 0-15 %), as well as samples created by hand lay-up method. In addition, glass fiber and mica fiber in long fiber unidirectional form are utilized; mechanical properties such as tensile, flexural and impact strength have been tested. As the results of this study, both glass fiber and mica fiber increased mechanical properties, although glass fiber has a greater effect than mica fiber but also using mica fiber make great improvement between 26% to 67%. Composites reinforced with 15% glass fiber had a better value of mechanical properties compared to others. Additionally, the hybrid composite made of glass fiber and mica fiber performed well in all tests, enhanced mechanical characteristics, which decreased the cost of making composites. | ||
| Keywords | ||
| Mechanical properties; hybrid composites; Mica fiber; Glass fiber | ||
| Full Text | ||
|
تمت دراسة نهج جدید لتطویر مواد مرکبة هجینة جدیدة. تعتبر زیادة الخواص المیکانیکیة والفیزیائیة للمواد المرکبة لخفض وزنها وتکلفتها هی المشکلة الأکثر شیوعًا فی المشاریع الهندسیة. تهدف هذه الدراسة إلى تعزیز الخصائص المیکانیکیة والفیزیائیة للمواد المرکبة. بسبب هذا أیضًا ، حظیت المواد المرکبة الهجینة باهتمام حدیث. فی عملنا ، تم إنشاء مواد مرکبة هجینة لتحسین الخصائص المیکانیکیة والفیزیائیة. فی هذا التحقیق ، تم استخدام کل من الألیاف الزجاجیة وألیاف المیکا کألیاف طبیعیة وصناعیة ، على التوالی. تم دراسة تأثیر المیکا کألیاف طبیعیة مع الألیاف الزجاجیة کمقویات اصطناعیة بنسبة الوزن (بالوزن٪) على الخواص المیکانیکیة للمواد المرکبة الهجینة. راتنجات الایبوکسی (بولیمر متصلب بالحرارة) معززة بنسبة وزن مختلفة من الألیاف الزجاجیة / ألیاف المیکا ، مثل (0-0 ، 15-0 ، 10-5 ، 7.5-7.5 ، 5-10 ، 0-15٪) ، وکذلک العینات تم إنشاؤها بطریقة وضع الید. بالإضافة إلى ذلک ، یتم استخدام الألیاف الزجاجیة وألیاف المیکا فی شکل ألیاف طویلة أحادیة الاتجاه ؛ تم اختبار الخواص المیکانیکیة مثل قوة الشد والانثناء والتأثیر. نتیجة لهذه الدراسة ، زادت الألیاف الزجاجیة وألیاف المیکا من الخصائص المیکانیکیة ، على الرغم من أن الألیاف الزجاجیة لها تأثیر أکبر من ألیاف المیکا ولکن أیضًا باستخدام ألیاف المیکا تحسن بشکل کبیر بین 26٪ إلى 67٪. کانت المرکبات المقواة بنسبة 15٪ من الألیاف الزجاجیة ذات قیمة میکانیکیة أفضل مقارنة بغیرها. بالإضافة إلى ذلک ، کان أداء المرکب الهجین المصنوع من الألیاف الزجاجیة وألیاف المیکا جیدًا فی جمیع الاختبارات ، مما أدى إلى تحسین الخصائص المیکانیکیة ، مما قلل من تکلفة صنع المرکبات. | ||
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