Interfacial Toughening Of Carbon Fiber Reinforced Polymer (CFRP) Matrix Composites Using MWCNTs/Epoxy Nanofiber Scaffolds

Wable, Vidya Balu

05 1900

Indiana University-Purdue University Indianapolis (IUPUI) / This study represents a cost-effective method to advance the physical and mechanical properties of carbon fiber-reinforced polymer (CFRP) prepreg composite materials, where electrospun multiwalled carbon nanotubes (CNTs)/epoxy nanofibers fabricated and deposited in between the layers of traditional CFRP prepreg composite. CNT-aligned epoxy nanofibers were uniformly formed by an optimized electrospinning method. Electrospinning is considered one of the most flexible, low-cost, and globally recognized methods for generating continuous filaments from submicron to tens of nanometer diameter. Nanofilaments were incorporated precisely on the layers of prepreg to accomplish increased adhesion and interfacial bonding, leading to increased strength and enhancements in more mechanical properties. As a result, the modulus of the epoxy and CNT/epoxy nanofibers were revealed to be 3.24 GPa and 4.84 GPa, leading to 49% enhancement. Furthermore, interlaminar shear strength (ILSS) and fatigue performance at high-stress regimes improved by 29% and 27%, respectively. Barely visible impact damage (BVID) energy improved considerably by up to 45%. The thermal and electrical conductivities were also increased considerably because of the highly conductive CNT networks present in between the CFRP layers. The newly introduced approach was able to deposit high content uniform CNTs at the ply interface of prepregs to enhance the CFRP properties, that has not been achieved in the past because of the randomly oriented high viscosity CNTs in epoxy resins.

Electrospinning

Aligned CNT/epoxy nanofibers

Nanofiber scaffolds

Enhanced CFRP composites

INTERFACIAL TOUGHENING OF CARBON FIBER REINFORCED POLYMER (CFRP) MATRIX COMPOSITES USING MWCNTS/EPOXY NANOFIBER SCAFFOLDS

Vidya Balu Wable (10716303)

10 May 2021

This study represents a cost-effective method to advance the physical and mechanical properties of carbon fiber-reinforced polymer (CFRP) prepreg composite materials, where electrospun multiwalled carbon nanotubes (CNTs)/epoxy nanofibers fabricated and deposited in between the layers of traditional CFRP prepreg composite. CNT-aligned epoxy nanofibers were uniformly formed by an optimized electrospinning method. Electrospinning is considered one of the most flexible, low-cost, and globally recognized methods for generating continuous filaments from submicron to tens of nanometer diameter. Nanofilaments were incorporated precisely on the layers of prepreg to accomplish increased adhesion and interfacial bonding, leading to increased strength and enhancements in more mechanical properties. As a result, the modulus of the epoxy and CNT/epoxy nanofibers were revealed to be 3.24 GPa and 4.84 GPa, leading to 49% enhancement. Furthermore, interlaminar shear strength (ILSS) and fatigue performance at high-stress regimes improved by 29% and 27%, respectively. Barely visible impact damage (BVID) energy improved considerably by up to 45%. The thermal and electrical conductivities were also increased considerably because of the highly conductive CNT networks present in between the CFRP layers. The newly introduced approach was able to deposit high content uniform CNTs at the ply interface of prepregs to enhance the CFRP properties, that has not been achieved in the past because of the randomly oriented high viscosity CNTs in epoxy resins.

Mechanical Engineering

Electrospinning

Aligned CNT/epoxy nanofibers

Nanofiber scaffolds

Enhanced CFRP composites

FRP Strengthening of Steel I-Beams with Web Openings

Humagain, Santosh

January 2021

No description available.

Civil Engineering

FEA

ANSYS

steel beams

web openings

FRP

CFRP

AFRP

BFRP

strengthening

熱可塑性を利用した薄層化CFRTP積層板の衝撃損傷修復と圧縮強度の関係

金﨑, 真人

24 September 2014

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第18586号 / 工博第3947号 / 新制||工||1607(附属図書館) / 31486 / 京都大学大学院工学研究科機械理工学専攻 / (主査)教授 北條 正樹, 教授 北村 隆行, 教授 琵琶 志朗 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

複合材料

修復

薄層

衝撃後圧縮

CFRP

500

層間高靭化CFRPの静的・疲労き裂進展およびその高靭化に関する破壊力学的研究

佐藤, 成道

25 January 2016

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19412号 / 工博第4128号 / 新制||工||1636(附属図書館) / 32437 / 京都大学大学院工学研究科機械理工学専攻 / (主査)教授 北條 正樹, 教授 北村 隆行, 教授 琵琶 志朗 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

複合材料

破壊靭性

はく離

疲労

CFRP

500

Joining of Metal and Fiber Reinforced Polymers Using Ultrasonic Additive Manufacturing

Guo, Hongqi

January 2021

No description available.

Mechanical Engineering

Ultrasonic additive manufacturing

CFRP joining

Hybrid structure

Aluminum alloy

Finite Element Evaluation Of The Effects Of Lateral Anchorage Strips On The Behavior Of Cfrp-strengthened Rc Beams

Perez, Jose Javier

01 January 2005

In this thesis, a fully nonlinear finite element study of the flexural behavior of doubly reinforced concrete beams strengthened using different Carbon Fiber Reinforced Polymer (CFRP) composite strengthening configurations has been carried out. Prior to the study, a total of six beams were constructed, pre-cracked, strengthened and tested to failure under a four-point loading condition (Zhao and O'Riordan-Adjah, 2004). Then, for the purpose of this thesis work, detailed three dimensional finite element models were created not only to correlate the results obtained from the experiments, but also to predict the load capacity, failure modes and crack pattern of reinforced concrete (RC) beams strengthened using Fiber Reinforced Polymer (FRP) composites. Knowing the behavior for each of the materials that compose the beam (concrete, steel, bonding material or interface, and FRP laminates) and how to get their properties, an accurate and representative finite element model can be created. Tests and analytical (FE) results showed that the strengthened configuration plays an important role in the overall strength, failure mechanisms, and, more significantly, the ductile behavior of the beams. Considerable increases in the load-carrying capacity of the RC beams were observed. Increases that range from 12% (using FRP only on the bottom of the beam) to 35% (FRP on the bottom + 45 degrees sides' configuration as explained later) compared to the control beam before ultimate failure were obtained. Failure modes were also affected since the beam with only FRP on the bottom failed completely by debonding of the laminate while the beams with side FRP anchorage strips failed by a combination of composite debonding on the sides and concrete crushing. Finally, ductile behavior of the beams was greatly improved due to the application of the strengthening material on the side of the concrete beams, serving as an anchorage to the bottom fabric. The accuracy of the model has been validated comparing the results obtained from the six beam tests to the ones determined using the FE approach. Good agreement between the two has been found.

CFRP

RC beams

strengthening

finite element

lateral anchorage

Civil Engineering

Engineering

Flexural Mechanical Durability Of Concrete Beams Strengthened By Externally Bonded Carbon Fiber Reinforced Polymer Sheets

Olka, Michael

01 January 2009

About 77,600 bridges throughout the United States in the Federal Highway Association (FHWA) bridge database are listed as structurally deficient. This has created a need to either replace or strengthen bridges quickly and efficiently. Due to high costs for total replacement of deficient bridges, strengthening of existing bridges is a more economical alternative. A technique that has been developing over the past two decades is the strengthening of bridges using carbon fiber reinforced polymer (CFRP) sheets. The CFRP sheets are attached to the bottom of the bridge girders using structural adhesives so that the CFRP becomes an integral part of the bridge and carries a portion of the flexural loading. The CFRP sheets allow for an increase in the capacity of the bridge with minimal increase in the weight of the structure due to CFRP having a low density. Because the CFRP is expected to be an integral component and carry some of the long-term loading it is important to understand the long-term durability of the composite section. This thesis is part of a larger project, in which the long-term durability of the CFRP composite on concrete beams is investigated experimentally. The CFRP strengthened beams are exposed to fatigue testing and thermal-humidity cycling followed by failure testing. The testing scheme for this experiment allows for the investigation of the individual effects of fatigue and thermal-humidity loading as well as to explore the effects from combined fatigue and thermal-humidity loading. The investigation of the combined effects is a unique aspect of this experiment that has not been performed in prior studies. Results indicate that a polyurethane-based adhesive could provide a more durable bond for the CFRP-concrete interface than possible with epoxy-based adhesives.

carbon fiber

durability

fatigue

CFRP

composite

long-term

Civil Engineering

Engineering

Size effect on shear strength of FRP reinforced concrete beams

Ashour, Ashraf, Kara, Ilker F.

07 December 2013

yes / This paper presents test results of six concrete beams reinforced with longitudinal carbon fiber reinforced polymer (CFRP) bars and without vertical shear reinforcement. All beams were tested under a two-point loading system to investigate shear behavior of CFRP reinforced concrete beams. Beam depth and amount of CFRP reinforcement were the main parameters investigated. All beams failed due to a sudden diagonal shear crack at almost 45°. A simplified, empirical expression for the shear capacity of FRP reinforced concrete members accounting for most influential parameters is developed based on the design-by-testing approach using a large database of 134 specimens collected from the literature including the beams tested in this study. The equations of six existing design standards for shear capacity of FRP reinforced concrete beams have also been evaluated using the large database collected. The existing shear design methods for FRP reinforced concrete beams give either conservative or unsafe predictions for many specimens in the database and their accuracy are mostly dependent on the effective depth and type of FRP reinforcement. On the other hand, the proposed equation provides reasonably accurate shear capacity predictions for a wide range of FRP reinforced concrete beams.

Circularity in Thermal Recycling for Sustainable Carbon Fibers / Cirkularitet i Termisk Återvinning för Hållbara Kolfiber

Corvo Alguacil, Marina

January 2023

The research field of composite materials is particularly fascinating due to the design freedom they offer and the infinite number of constituent combinations, including those that are already explored, and many more that are yet to be tried. One composite material that holds great potential contains carbon in its fiber shape. Carbon fibers possess unique properties that excel in mechanical aspects, as well as interesting electrical and thermal properties that are yet to be fully explored. These fibers are readily available on the market and can be introduced as reinforcement in various lengths and orientations, yielding diverse results depending on the intended effect. Although carbon fiber reinforced polymer composites (CFRP) are present on the market for quite some time, specifically in high-performance applications, they are predominantly used when their performance outweighs their cost. Meanwhile, carbon fiber composite waste is starting to cumulate in noticeable amounts. This waste originates from both, production scrap and end-of-life scenarios, as components introduced in service life in the past 30 years are being decommissioned and discarded. Unfortunately, the prevalent solution for handling this waste is landfilling, due to its ease, affordability, and accessibility. Consequently, substantial amounts of composite waste are accumulating worldwide. Furthermore, it has finally come to our attention that our planet's resources are finite. Our exploitation of these resources has been largely devoid of consideration for the needs of future generations. As a result, recently, sustainability has emerged as a key enabler for a circular economy, driven by increasing environmental concerns and demands from customers and users for market transformation. The implementation of sustainable practices is now underway, albeit at a gradual pace.   In summary, we find ourselves facing a trifold predicament: a splendid material being underutilized due to production costs, the cumulative generation of CFRP waste resulting from a lack of foresight and suitable alternatives, and the urgent need to transition towards a circular economy due to resource depletion. This research work aims to address all three challenges by developing an integrated solution.   The current work demonstrates that it is possible to recycle carbon fiber model composites through a two-step pyrolysis treatment, a fully mature recycling technology. The study has been done in two stages which are presented in two journal papers included in the thesis. The primary objective of the first paper is to identify and optimize process parameters that maximize the retention of mechanical properties in the recovered fibers. The overall results achieved show good retention value; with over 90% retention on stiffness and 90% on strength. Encouraging results from initial experimental work, have spurred the research focus towards further investigation. Thus, the second paper reports on repetitive manufacturing and recycling cycles of two sets of identical model composites by using the two most effective recycling treatments identified through the parameter optimization. The mechanical performance and structural changes of the recycled fibers are characterized and analyzed. Although further analysis is required, current mechanical behavior shows recovered fibers suitable for secondary applications after two recycling cycles, with an abrupt decay in fiber properties after the third cycle.   With the waste challenge under control, through successful recycling of composite waste, it is time to find concrete applications for this research. Having recycled carbon fibers (rCF) with comparable performance to virgin carbon fibers (vCF) opens up opportunities for rCF mats and other intermediate products to compete in previously inaccessible markets.

pyrolysis

carbon fiber

composites recycling

CFRP

polymer composites

sustainability

Composite Science and Engineering

Kompositmaterial och -teknik