Polymeric Complexes and Composites for Aerospace and Biomedical Applications

Zhang, Rui

01 August 2018

Polymers, among metals and ceramics, are major solid materials which are widely used in all kinds of applications. Polymers are of particular interest because they can be tailored with desirable properties. Polymer-based complexes and composites, which contain both the polymers and other components such as metal oxide/salts, are playing a more and more important role in the material fields. Such complexes and composites may display the benefits of both the polymer and other materials, endowing them with excellent functionalities for targeted applications. In this dissertation, a great deal of research was conducted to synthesize novel polymers and build polymeric complexes and composites for biomedical and aerospace applications. In chapter 3, two methods were developed and optimized to fabricate sub-micron high-performance polymer particles which were subsequently used to coat onto functional carbon fibers via electrostatic interactions, for the purpose of fabricating carbon fiber reinforced polymer composites. In chapter 4, a novel Pluronic® P85-bearing penta-block copolymer was synthesized and formed complexes with magnetite. The complexes displayed non-toxicity to cells normally but were able to selectively kill cancer cells without killing normal cells when subjected to a low-frequency alternating current magnetic field. Such results demonstrated the potential of such polymeric complexes in cancer treatment. Chapter 5 described the synthesis of several ionic graft copolymers primarily bisphosphonate-containing polymers, and the fabrication of polymer-magnetite complexes. The in-depth investigation results indicated the capability of the complexes for potential drug delivery, imaging, and other biomedical applications. Chapter 6 described additional polymer synthesis and particle or complex fabrication for potential drug delivery and imaging, as well as radiation shielding. / PHD / Polymers, metals, and ceramics are three major classes of solid materials that are used every day and everywhere. Polymers are of particular significance because they can be tailored to possess certain desirable properties, and, hence, they are playing a more and more important role as substitutes for metals and ceramics in a wide array of applications. Engineering and high-performance polymers were synthesized with excellent properties for biomedical and aerospace applications. Polymers can be fabricated into composites and complexes which contain not only polymers but also other materials, such as metal oxides/salts, carbon fibers, glass fibers, etc. When composites and complexes are made with sufficient stability, the materials may display the advantages of each component, making them more promising for specific applications. In this dissertation, effort was focused on developing versatile polymer-based complexes and composites for aerospace and biomedical applications. Chapter 3 describes the fabrication of sub-micron high-performance polymer particles by two methods and they were subsequently coated onto functional carbon fibers for making composites. Chapter 4 describes the synthesis of a novel copolymer that formed complexes with magnetite nanoparticles. The complexes were able to selectively kill cancerous cells without killing normal cells when exposed to an external magnetic field, and thus these materials have potential for cancer treatment. Chapter 5 describes the fabrication of phosphonate-bearing ionic copolymer-magnetite complexes and their potential applications in drug delivery, imaging, and other biomedical applications. Chapter 6 describes the synthesis of polymers and their corresponding complexes for potential drug delivery and imaging, as well as potential radiation shielding applications.

high-performance polymer

carbon fiber

suspending agent

ionic copolymer

magnetite

particles

imaging

drug delivery

The effects of tensile preloads on the impact response of carbon/epoxy laminates

Nettles, A. T.

06 June 2008

Low velocity drop weight impact tests were conducted on carbon/epoxy laminates under various magnitudes of uniform tensile stress. The composite plates were 8 ply (+45,0,- 45,90)_s laminates supported in a clamped-clamped/free-free configuration. Tensile preloads from near zero to approximately 60% of ultimate breaking strength were applied to specimens which were impacted at energies of 3.4, 4.5 and 6 Joules (2.5, 3.3 and 4.4 ft- Ibs). The amount of damage induced into the specimen was evaluated using instrumented impact techniques, x-ray inspection and cross-sectional photomicroscopy. Some static indentation tests were performed to examine if the impact events utilized in this study were of a quasi-static nature and also to gain insight into the shape of the deflected surface at various preload/transverse load combinations. Load-displacement curves from these tests were compared to those of the impact tests as was damage determined from x-ray inspection. The finite element technique was used to model the impact event and determine the stress field within the laminae. Results showed that for a given impact energy level, more damage was induced into the specimen as the tensile preload was increased. The majority of damage observed consisted of back face splitting of the matrix parallel to the fibers in that ply, associated with delaminations emanating from these splits. Tensile preloads tended to increase the length of these splits. The analysis showed qualitatively the results of tensile preloads on maximum load of impact, maximum transverse deflection and first failure mode and location. / Ph. D.

composites

impact

damage tolerance

carbon fiber

epoxy

delamination

LD5655.V856 1996.N488

Fatigue, Fracture and Impact of Hybrid Carbon Fiber Reinforced Polymer Composites

Yari Boroujeni, Ayoub

25 January 2017

The excellent in-plane strength and stiffness to-weight ratios, as well as the ease of manufacturing have made the carbon fiber reinforced polymer composites (CFRPs) suitable structural materials for variety of applications such as aerospace, automotive, civil, sporting goods, etc. Despite the outstanding performance of the CFRPs along their fibers direction (on-axis), they lack sufficient strength and performance in the out-of-plane and off-axis directions. Various chemical and mechanical methods were reported to enhance the CFRPs' out-of-plane performance. However, there are two major drawbacks for utilizing these approaches: first, most of these methods induce damage to the carbon fibers and, therefore, deteriorate the in-plane mechanical properties of the entire CFRP, and second, the methods with minimal deteriorating effects on the in-plane mechanical performance have their own limitations resulting in very confined mechanical performance improvements. These methods include integrating nano-sized reinforcements into the CFRPs' structure to form a hybrid or hierarchical CFRPs. In lieu to all the aforementioned approaches, a relatively novel method, referred to as graphitic structures by design (GSD), has been proposed. The GSD is capable of grafting carbon nanotubes (CNTs) onto the carbon fibers surfaces, providing high concentration of CNTs where they are most needed, i.e. the immediate fiber/matrix interface, and in-between the different laminae of a CFRP. This method shows promising improvements in the in-plane and out-of-plane performance of CFRPs. Zinc oxide (ZnO) nanorods are other nano-sized reinforcing structures which can hybridize the CFRPs via their radially growth on the surface of carbon fibers. Among all the reported methods for synthesizing ZnO nanorods, hydrothermal technique is the most straightforward and least destructive route to grow ZnO nanorods over carbon fibers. In this dissertation, the GSD-CNTs growth method and the hydrothermal growth of ZnO nanorods have been utilized to fabricate hybrid CFRPs. The effect of different ZnO nanorods growth morphologies, e.g. size distribution and alignment, on the in-plane tensile performance and vibration attenuation capabilities of the hybrid CFRPs are investigated via quasi-static tension and dynamical mechanical analysis (DMA) tests, respectively. As a result, the in-plane tensile strength of the hybrid CFRPs were improved by 18% for the composite based on randomly oriented ZnO nanorods over the carbon fibers. The loss tangent of the CFRPs, which indicates the damping capability, increased by 28% and 19% via radially and randomly grown ZnO nanorods, respectively. While there are several studies detailing the effects of dispersed nanofillers on the fracture toughness of FRPs, currently, there are no literature detailing the effect of surface GSD grown CNTs and ZnO nanowire -on carbon fiber- on the fracture toughness of these hybrid composites. This dissertation probes the effects of surface grown nano-sized reinforcements on the fracture toughness via double cantilever beam (DCB) tests on hybrid ZnO nanorod or CNT grafted CFRPs. Results show that the surface grown CNTs enhanced the Mode I interlaminar fracture toughness (GIc) of the CFRPs by 22% and 32%, via uniform and patterned growth morphologies, respectively, over the reference composite based on untreated carbon fiber fabrics. The dissertation also explains the basis of the improvements of the fracture toughness via finite element method (FEM). In particular, FEM was employed to simulate the interlaminar crack growth behavior of the hybrid CFRPs under Mode I crack opening loading conditions embodied by the DCB tests. These simulations revealed that the hybrid CFRP based on fibers with uniform surface grown MWCNTs exhibited 55% higher interlaminar strength compared to the reference CFRPs. Moreover, via patterned growth of MWCNTs, the ultimate crack opening resistance of the CFRPs improved by 20%. To mimic the experimental behavior of the various CFRPs, a new methodology has been utilized to accurately simulate the unstable crack growth nature of CFRPs. Several investigations reported the effects of adding nanomaterials-including CNTs- as a filler phase inside the matrix material, on the impact energy absorption of the hybrid FRPs. However, the impact mitigation performance of CFRPs based on ZnO nanorod grafted carbon fibers has not been reported. The dynamic out-of-plane energy dissipation capabilities of different hybrid composites were investigated utilizing high velocity (~90 m/s) impact tests. Comparing the results of the hybrid MWCNT/ZnO nanorod/CFRP with those of reference CFRP, 21% and 4% improvements were observed in impact energy absorption and tensile strain to failure of the CFRPs, respectively. In addition to elevated stiffness and strength, CFRPs should possess enough tolerance not only to monotonic loadings, but also to cyclic loadings to be qualified as alternatives to traditional structural metal alloys. Therefore, the fatigue life of CFRPs is of much interest. Despite the promising potential of incorporating nano-sized reinforcements into the CFRPs structure, not many studies reported on the fatigue behavior of hybrid CFRPs so far. In particular, there are no reported investigations to the effect of surface grown CNTs on the fatigue behavior of the hybrid CFRPs, due to fact that almost all the CNT growth techniques (except for the GSD method) deteriorated the in-plane performance of the hybrid CFRPs. The hybrid ZnO nanorod grafted CFRPs have not been investigated under fatigue loading as well. In this dissertation, different hybrid CFRPs were tested under tension-tension fatigue to reveal the effects of the different nano-reinforcements growth on the fatigue behavior of the CFRPs. A remarkable fatigue damage tolerance was observed for the CFRPs based on uniform and patterned grown CNT fibers. Almost two decades of fatigue life extension was achieved for CFRPs based on surface grown MWCNTs. / Ph. D. / Carbon fiber reinforced polymer composites (CFRPs) are light-weight materials with excellent strength and stiffness along the direction of the fibers. These great mechanical properties have made CFRPs suitable structural materials for variety of applications such as aerospace, automotive, civil, sporting goods, etc. Despite the outstanding performance of the CFRPs along their fibers direction (on-axis), they lack sufficient strength and performance in the out-of-plane and off-axis directions. Various chemical and mechanical methods were reported to enhance the CFRPs’ out-of-plane performance. However, there are two major drawbacks for utilizing these approaches: first, most of these methods induce damage to the carbon fibers and, therefore, deteriorate the in-plane mechanical properties of the entire CFRP, and second, the methods with minimal deteriorating effects on the in-plane mechanical performance have their own limitations resulting in very confined mechanical performance improvements. These methods include integrating nano-sized reinforcements into the CFRPs’ structure to form a hybrid or hierarchical CFRPs. In lieu to all the aforementioned approaches, a relatively novel method, referred to as graphitic structures by design (GSD), has been proposed. The GSD is capable of grafting carbon nanotubes (CNTs) onto the carbon fibers surfaces, providing high concentration of CNTs where they are most needed, i.e. the immediate fiber/matrix interface, and in-between the different layers of a CFRP. This method shows promising improvements in the in-plane and out-of-plane performance of CFRPs. Zinc oxide (ZnO) nanorods are other nano-sized reinforcing structures which can hybridize the CFRPs via their radially growth on the surface of carbon fibers. Among all the reported methods for synthesizing ZnO nanorods, hydrothermal technique is the most straightforward and least destructive route to grow ZnO nanorods over carbon fibers. In this dissertation, the GSD-CNTs growth method and the hydrothermal growth of ZnO nanorods have been utilized to fabricate hybrid CFRPs. The effect of different ZnO nanorods growth morphologies, e.g. size distribution and alignment, on the in-plane tensile performance and vibration damping capabilities of the hybrid CFRPs are investigated via tension and dynamical mechanical analysis (DMA) tests, respectively. As a result, the in-plane tensile strength of the hybrid CFRPs were improved by 18% for the composite based on randomly oriented ZnO nanorods over the carbon fibers. The loss tangent of the CFRPs, which indicates the damping capability, increased by 28% and 19% via radially and randomly grown ZnO nanorods, respectively. Fracture toughness is a measure for the capability of a material to withstand a load in the presence of damage (i.e. crack) in the material’s structure. While there are several studies detailing the effects of dispersed nanofillers on the fracture toughness of FRPs, currently, there are no literature detailing the effect of surface GSD grown CNTs and ZnO nanowire -on carbon fiber- on the fracture toughness of these hybrid composites. This dissertation probes the effects of surface grown nano-sized reinforcements on the fracture toughness via double cantilever beam (DCB) tests on hybrid ZnO nanorod or CNT grafted CFRPs. Results show that the surface grown CNTs enhanced the Mode I interlaminar fracture toughness (G_Ic) of the CFRPs by 22% and 32%, via uniform and patterned growth morphologies, respectively, over the reference composite based on untreated carbon fiber fabrics. The dissertation also explains the basis of the improvements of the fracture toughness via finite element method (FEM). In particular, FEM was employed to simulate the interlaminar crack growth behavior of the hybrid CFRPs under Mode I crack opening loading conditions embodied by the DCB tests. These simulations revealed that the hybrid CFRP based on fibers with uniform surface grown MWCNTs exhibited 55% higher interlaminar strength compared to the reference CFRPs. Moreover, via patterned growth of MWCNTs, the ultimate crack opening resistance of the CFRPs improved by 20%. To mimic the experimental behavior of the various CFRPs, a new methodology has been utilized to accurately simulate the unstable crack growth nature of CFRPs. Several investigations reported the effects of adding nanomaterials - including CNTs - as a filler phase inside the matrix material, on the impact energy absorption of the hybrid FRPs. However, the impact mitigation performance of CFRPs based on ZnO nanorod grafted carbon fibers has not been reported. The dynamic out-of-plane energy dissipation capabilities of different hybrid composites were investigated utilizing high velocity (~90 m/s) impact tests. Comparing the results of the hybrid MWCNT/ZnO nanorod/CFRP with those of reference CFRP, 21% and 4% improvements were observed in impact energy absorption and tensile strain to failure of the CFRPs, respectively. In addition to elevated stiffness and strength, CFRPs should possess enough tolerance not only to monotonic loadings, but also to cyclic loadings to be qualified as alternatives to traditional structural metal alloys. Therefore, the fatigue life (i.e. the number of loading cycles to failure) of CFRPs is of much interest. Despite the promising potential of incorporating nano-sized reinforcements into the CFRPs structure, not many studies reported on the fatigue behavior of hybrid CFRPs so far. In particular, there are no reported investigations to the effect of surface grown CNTs on the fatigue behavior of the hybrid CFRPs, due to fact that almost all the CNT growth techniques (except for the GSD method) deteriorated the in-plane performance of the hybrid CFRPs. The hybrid ZnO nanorod grafted CFRPs have not been investigated under fatigue loading as well. In this dissertation, different hybrid CFRPs were tested under tension-tension fatigue to reveal the effects of the different nano-reinforcements growth on the fatigue behavior of the CFRPs. A remarkable fatigue damage tolerance was observed for the CFRPs based on uniform and patterned grown CNT fibers. Almost two decades of fatigue life extension was achieved for CFRPs based on surface grown MWCNTs.

carbon fiber

hybrid composites

carbon nanotubes

ZnO nanorods

mechanical characterization

finite element modeling

Fatigue

Sensitivity of Offline and Inline Indicators for Fiber Stretching in Continuous Polyacrylonitrile Stabilization

Bogar, Mohsen Sadeghi, Wolf, Jan, Wolz, Daniel Sebastian Jens, Seidel-Greiff, Robert, Dmitrieva, Evgenia, Israel, Noel, Rosenkranz, Marco, Behnisch, Thomas, Müller, Michael Thomas, Gude, Maik

08 November 2024

In carbon fiber (CF) production, the stabilization process step is the most energy- and time-consuming step in comparison with carbonization and graphitization. To develop optimization routes for energy and productivity, the stabilization needs to be monitored continuously via inline analysis methods. To prognose the evolution of high-performance CF, the density of stabilized fibers has been identified as a robust pre-indicator. As the offline analysis of density is not feasible for inline analysis, a density-soft sensor based on the stabilization indices of Fourier Transform Infrared spectrum (FTIR)-analysis and Electron Paramagnetic Resonance (EPR) Spectroscopy could potentially be used for inline monitoring. In this study, a Polyacrylonitrile-based precursor fiber (PF) stabilized in a continuous thermomechanical stabilization line with varying stretching profiles was incrementally analyzed using density, FTIR-based relative cyclization index (RCI), and EPR-based free radical concentration (FRC). Our findings show RCI and EPR dependencies for density, correlated for RCI with sensitivity by stretching to cubic model parameters, while FRC exhibits linear relationships. Therefore, this study identifies two possible soft sensors for inline density measurement, enabling autonomous energy optimization within industry 4.0-based process systems.

info:eu-repo/classification/ddc/670

ddc:670

Elektrophoretische Oberflächenmodifikation von Carbonfasern für eine erhöhte Wechselwirkung zu zement-basierten Matrices

Li, Huanyu

20 February 2025

Concrete is the most essential construction material due to its high availability, low costs, excellent compressive strength, and high durability nature. However, cement-based composites possess some disadvantageous features, notably brittleness and diminished flexural/tensile strength. To surmount these challenges, the integration of reinforcement into cementitious materials becomes imperative. One of the most promising reinforcement materials is high-strength carbon fiber (CF), which manifests in forms such as dispersed short fibers, rebar, and textile to fabricate the carbon fiber-reinforced cementitious composite (CFRC). As opposed to traditional steel-reinforced structural elements, the chemically inert CF does not demand a thick protective cover, which enables the creation of slender-walled, resource-conserving structural components. However, CFRC materials exhibit poor interfacial adhesion between hydrophobic CF and enveloping cementitious matrices, thereby limiting the efficient force transfer at the interface. The commonly used polymeric impregnation for the CF multifilaments is susceptible to degradation under heightened temperatures, a circumstance adverse to structural integrity, particularly in fire scenarios. As an alternative, thermally stable inorganic binders characterized by exceedingly fine particulates emerge as suitable candidates for impregnation. This finely dispersed suspension penetrates the CF roving housing multitudes of filaments, inducing enhancements in bonding interactions among CF filaments as well as between the roving and the cement matrix. The dissertation at hand suggests an innovative approach that utilizes fine mineral particles as a coating material. Its core objective revolves around the advancement of the electrophoretic deposition (EPD) method for nano-silica (NS) onto CF surfaces, with the intention of enhancing interfacial bonding with cementitious matrices. To achieve this, a comprehensive exploration into the effects of voltage, treatment duration, and pH value during surface modification on bond performance and fiber properties is undertaken. The bond-slip behavior of the modified CFs toward the cement matrix depending on the curing ages is systematically studied from various aspects of the single-fiber pullout curves. In extension to the experimental results, a numerical simulation is used to elucidate the stress distribution during the debonding process, while also serving to approximate and describe the force-displacement pullout curves. Furthermore, amorphous silica fume and micro-sized quartz are harnessed for electrophoretic modification of CF surfaces, allowing for a comparative evaluation with NS coating in terms of enhancing bond behavior. The morphological features of modified CF surfaces are scrutinized using scanning electron microscopy. Single fiber tension experiments and thermogravimetric analysis are performed to study the impact of EPD modification on the mechanical properties and temperature sensibility of CFs. Uniaxial quasi-static single-fiber pullout tests are conducted to provide profound insights into the interfacial interaction between CF and surrounding cement matrices at different stages during the pullout process. Within the EPD system, the kinetics of CF electrode reaction and the zeta potential of suspensions are examined through cyclic voltammetry experiments and zeta potential measurements, respectively. These investigations elucidate alterations in the surface chemistry of CFs and the quality of the coating under diverse treatment conditions.

info:eu-repo/classification/ddc/691

ddc:691

Modified Phenol-Formaldehyde Resins for C-Fiber Reinforced Composites: Chemical Characteristics of Resins, Microstructure and Mechanical Properties of their Composites

Kim, Young Eun

06 January 2011

This work correlates the chemistry of phenol-formaldehyde (PF) resins, its functionalities with their microstructural and mechanical properties in composite materials. The main focus is put on the development of the pores in dependence on the chemical composition of the resins and their influence on the structure of the material. Chemical characteristics of the synthesized resins are analyzed and physical/mechanical properties of the matrices based on PF resins are determined. Differences in the chemical properties are detected e.g. by FT-IR and NMR spectroscopy. They indicate the existence of similar molecular basic structure units, but different network conditions of the resins. DSC investigations point on different reaction mechanisms and temperatures; they reveal also their changed thermal behavior. The bulk matrix behavior differs from that of the composite based on the same resin due to the three dimensional stress and strain fields in the composites. The structure of the CFRP composites is strongly depended on the fiber/matrix interaction. The fiber matrix bonding (FMB) strength controls the load transfer via shear forces and therefore the segmentation of the fiber bundles.

PF-Harz

C-Faser

Interface

Verbundwerkstoff

Faser/Matrixbindung (FMB)

PF-resin

Carbon fiber

Interface

Carbon-Fiber Reinforced Plastics

Fiber-Matrix Bonding (FMB)

ddc:620

Phenoplast

Kohlenstofffaserverstärkter Kunststoff

Verbundwerkstoff

Modified Phenol-Formaldehyde Resins for C-Fiber Reinforced Composites: Chemical Characteristics of Resins, Microstructure and Mechanical Properties of their Composites

Kim, Young Eun

06 January 2011

This work correlates the chemistry of phenol-formaldehyde (PF) resins, its functionalities with their microstructural and mechanical properties in composite materials. The main focus is put on the development of the pores in dependence on the chemical composition of the resins and their influence on the structure of the material. Chemical characteristics of the synthesized resins are analyzed and physical/mechanical properties of the matrices based on PF resins are determined. Differences in the chemical properties are detected e.g. by FT-IR and NMR spectroscopy. They indicate the existence of similar molecular basic structure units, but different network conditions of the resins. DSC investigations point on different reaction mechanisms and temperatures; they reveal also their changed thermal behavior. The bulk matrix behavior differs from that of the composite based on the same resin due to the three dimensional stress and strain fields in the composites. The structure of the CFRP composites is strongly depended on the fiber/matrix interaction. The fiber matrix bonding (FMB) strength controls the load transfer via shear forces and therefore the segmentation of the fiber bundles.:1 Introduction 2 Theoretical Overview 2.1 Phenol-Formaldehyde Resins 2.1.1 Overview 2.1.2 Reactions of phenol-formaldehyde resin 2.1.2.1 Addition reaction 2.1.2.2 Condensation reaction 2.1.2.3 Curing 2.1.3 Application of phenol-formaldehyde resin 2.2 Carbon-Fiber 2.2.1 PAN type carbon fiber 2.2.2 Pitch type carbon fiber 2.2.3 Application of carbon fiber 2.3 Composites 2.3.1 Carbon fiber composites 2.3.2 Matrix 2.3.3. Interfaces 2.3.3.1 Carbon fiber side interface between carbon fiber and matrix 2.3.3.2 Matrix side interface between carbon fiber and matrix 2.3.3.3 Toughening of fiber-reinforced polymer 3 Goal and Works 3.1 Problem and Motivation 3.2 Objective and Works plan 4 Experiments and Methods 4.1 Materials 4.1.1 Chemical reagents 4.1.2 Carbon fiber weave 4.2 Synthesis of Resin 4.3 Fabrication of Matrix 4.4. Measurement methods and Experimental approach 4.4.1 Chemical analysis 4.4.2 Microstructure characterization 4.4.3 Mechanical test 5 Chemical characterization of modified phenol-formaldehyde resin 5.1 Fourier Transformed Infrared spectroscopy (FT-IR) 5.1.1 Introduction 5.1.2 Preparation and Measurement 5.1.3 Results and Discussion 5.2 Nuclear Magnetic Resonance spectroscopy (NMR) 5.2.1 Liquid 13C Nuclear Magnetic Resonance spectroscopy 5.2.1.1 Introduction 5.2.1.2 Preparation and Measurement 5.2.1.3 Results and Discussion 5.2.2 Solid 13C CP-MAS Nuclear Magnetic Resonance spectroscopy 5.2.2.1 Introduction 5.2.2.2 Preparation and Measurement 5.2.2.3 Results and Discussion 5.3 Simultaneous Thermal Analysis (STA) 5.3.1 Introduction 5.3.2 Preparation and Measurement 5.3.3 Results and Discussion 5.3.3.1 Simultaneous Thermal Analysis 5.3.3.2 Different Scanning Calorimetry 5.4 Conclusion 6 Microstructural Characterization 6.1 Porosity 6.1.1 Introduction 6.1.2 Preparation and Measurement 6.1.3 Results and Discussion 6.1.3.1 Density 6.1.3.2 Porosity 6.2 Morphology 6.2.1 Introduction 6.2.2 Preparation and Measurement 6.2.3 Results and Discussion 6.2.3.1 Optical Microscopy 6.3.3.2 Scanning Electron Microscopy 6.3.3.2.1 Observation of the bulk matrix 6.2.3.2.2 Structural observation of the composite 6.3 Conclusion 7 Mechanical Properties 7.1 Hardness test 7.1.1 Introduction 7.1.2 Preparation and Measurement 7.1.3 Results and Discussion 7.2 Micro-bending test 7.2.1 Introduction 7.2.2 Preparation and Measurement 7.2.3 Results and Discussion 7.3 Conclusion 8 Summary and Conclusion 8.1 Summary 8.2 Conclusion 9 References

info:eu-repo/classification/ddc/620

ddc:620

FRP:s användning inom brokonstruktioner / FRP's use in bridge structures

Abdi Yussuf, Yusuf, Jalal Ibrahim, Zand

January 2019

I dagsläget är de flesta broar i Sverige tillverkade med betong eller stål. Dessa broar är många gånger förknippade med stora kostnader som ofta beror på underhåll och reparation. FRP, som står för Fiber Reinforced Polymer, är ett relativt nytt material i bärande stommar men är ett väl etablerat material i förstärkningssammanhang. I Europa och i synnerhet Nederländerna finns det flertal broar byggda i FRP. Men på grund av brist på normer och regelverk att luta sig emot sker det sällan någon form av brokonstruktion med FRP i Sverige. Detta examensarbete syftar till att undersöka befintliga normer och studera hur materialet FRP används vid förstärkning och konstruktion av broar. Vidare syftar även arbetet till att undersöka egenskaperna hos FRP som byggmaterial och jämföra det med konventionella material som stål och betong. FRP, också benämnd fiberkomposit, är ett kompositmaterial som kan sammanställas på flera olika sätt. Genom olika material som kombineras och olika tillverkningsprocesser som används kan man på så sätt ge individuell utformning till materialet för dess användning. Fördelarna med FRP är många, men i allmänhet har det god styrka, god beständighet samtidigt som det har en låg vikt. Detta resulterar i att inom brokonstruktion så ger det strukturen en minskad egenvikt, vilket i sin tur underlättar en mängd olika saker. Detta arbete visar på att FRP-material har fördelaktiga egenskaper och kan i vissa situationer vara mer gynnsamt att använda än stål eller betong. Dock som tidigare påpekat saknas det specifika Eurokoder för detta material. Däremot är vi säkra på att introduktionen av en ny Eurokod samt med uppmuntran från myndigheter kommer användningen av FRP inom brokonstruktion utan tvekan öka. / At present, most bridges in Sweden are made with concrete or steel. These bridges are often associated with high costs, which often depend on maintenance and repair. FRP, which stands for Fiber Reinforced Polymer, is a relatively new material in load-bearing structures but is a well- established material in the context of reinforcement. In Europe and in particular the Netherlands, there are several bridges built in FRP. But due to a lack of norms and regulations to lean against, there is rarely any kind of FRP bridge construction in Sweden. The aim of this thesis is to examine existing norms and study how the material FRP is used in the reinforcement and construction of bridges. Furthermore, this thesis also aims to investigate the properties of FRP as building material and compare it with conventional materials such as steel and concrete. FRP, also called fiber-composite, is a composite material that can be assembled in several different ways. Through various materials that are combined and different manufacturing processes used, one can thus provide individual designs for the material. The benefits of FRP are many, but generally it has good strength, good durability while having a low weight. This results in that within bridge construction, it gives the structure a reduced self-weight, which in turn facilitates a variety of things. This thesis shows that FRP materials have advantageous properties and in some situations can be more favorable to use than steel or concrete. However, as previously pointed out, there are no specific Eurocodes for this material. However we are sure that the introduction of a new Eurocode and encouragement from authorities will undoubtedly increase the use of FRP in bridge construction.

FRP

fiber-reinforced polymer

glass fiber

carbon fiber

aramid fiber

structural fiber composites

composites

CFRP

GFRP

FRP

fiber reinforced polymer

glass fiber

carbon fiber

aramid fiber

structural fiber composites

composites

CFRP

GFRP

Infrastructure Engineering

Infrastrukturteknik

Joining Carbon Fiber and Aluminum with Ultrasonic Additive Manufacturing

Gingerich, Mark Bryant

27 September 2016

No description available.

Aerospace Engineering

Automotive Materials

Automotive Engineering

Engineering

Experiments

Materials Science

Polymers

UAM

ultrasonic additive manufacturing

CFRP to metal joining

automotive joining

aluminum

carbon fiber

ultrasonic consolidation

hybrid transition structures

adhesive benchmarking

carbon fiber integration

Explosive emission cathodes for high power microwave devices: gas evolution studies

Schlise, Charles A.

06 1900

Approved for public release, distribution is unlimited / Present-day high power microwave devices suffer from a lack of reliable, reproducible cathodes for generating the requisite GW-level electron beam in a vacuum. Standard explosive emission cathode pulse durations have been limited to 10's or 100's of ns due to the expansion of cathode-generated plasma and the ensuing impedance collapse that debilitates microwave output. Traditional thermionic cathodes do not suffer from this drawback of plasma generation, but have not yet been able to provide the required emission current densities explosive emission cathodes are capable of. It is expected that if the plasma could be made cooler and less dense, explosive emission would be more stable. Cesium iodide (CsI) has been found to slow the impedance collapse in many explosive emission cathodes. Herein we will experimentally examine diode impedance collapse, gas production, and cathode conditioning in an effort to perform an evaluation of explosive cathode performance in a typical thermionic electron gun environment. These results will then be used to help demarcate the parameter space over which these CsI-coated carbon fiber cathodes are viable candidates for the electron beam source in next-generation high power microwave devices. / Lieutenant, United States Navy

Microwaves

Military applications

Cathodes

Electron beams

High power microwaves

Cathodes

Electron beam

Vacuum

Explosive emission

Plasma

Carbon fiber