Abstract
During the production process of commercial carbon fiber reinforced polymers (CFRPs), a silane coupling agent is added to the carbon fiber at the sizing step as a binder to enhance the product’s physical properties. While improving strength, the silane coupling agent results in a silane residue on recovered carbon fibers (rCF) after recycling, which is a disadvantage when using recovered carbon fibers in the manufacture of new materials. In this study, the rCF is recovered from waste carbon fiber reinforced polymers (CFRPs) from the bicycle industry by a microwave pyrolysis method, applying a short reaction time and in an air atmosphere. Moreover, the rCF are investigated for their surface morphologies and the elements present on the surface. The silicon element content changes with pyrolysis temperature were 0.4, 0.9, and 0.2%, respectively, at 450, 550, and 650 °C. Additionally, at 950 °C, silicon content can be reduced to 0.1 ± 0.05%. The uniformity of microwave pyrolysis recycle treatment was compared with traditional furnace techniques used for bulk waste treatment by applying the same temperature regime. This work provides evidence that microwave pyrolysis can be used as an alternative method for the production of rCFs for reuse applications.
Highlights
In recent decades, carbon fiber-reinforced polymers (CFRPs) have been extensively utilized in various applications of the aerospace industry, transportation, infrastructure [1,2,3], energy, sport industries, defense, medical sector, and electronics [4,5]
Thermogravimetric Analysis (TGA) Analysis of carbon fiber reinforced polymers (CFRPs) Waste element (C,It O, and Si) of the core layer is measured using a Hitachi TM 4000 Plus is important to understand the thermal decomposition curve of the CFRPs’ waste ment with assess capability and uniformity for fromOxford bicycle frame waste, since causeto each batch removal of CFRP could be from different source
It can be defined that the decomposition temperHitachiature
Summary
Carbon fiber-reinforced polymers (CFRPs) have been extensively utilized in various applications of the aerospace industry, transportation, infrastructure [1,2,3], energy, sport industries, defense, medical sector, and electronics [4,5]. The physical properties of CFRPs have led to increased use of these materials as replacements for more conventional options, including steel, aluminum, alloys, etc These physical properties include low density and lightweight, superior strength to weight ratios and elastic modulus [6,7,8], stiffness, low expansion or shrinkage, thermal stability [9,10,11,12], electrical conductivity, superior resistance to corrosion and chemical attack, and exceptional endurance of physico–chemical properties [13,14,15,16]. Composites are engineered materials that compose of carbon fibers (CFs) acting as reinforcing matrix materials within versed thermosetting polymer to form structures. [18].
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