Abstract:Nano-reinforcements in carbon fibre-reinforced polymer (CFRP) have proven to enhance the mechanical properties considering quasi-static, as well as fatigue load and, are a promising option with regard to CFRP performance optimisation. While general knowledge about the nanofiller content and its influence in CFRP is well documented, the use of alignment techniques for a specific orientation of the nano-reinforcements is still insufficiently studied. In this work, the influence of oriented carbon nanofibres (CNF… Show more
“…The detected crack structure in the central aluminum sheet is comparable to the outer aluminum layers, which indicates that the crack development is similar in all aluminum layers and therefore the used methodology is applicable to the investigated structures. With regard to condition monitoring and lifetime prediction, precise investigation of the damage evolution should be possible using intermittent in situ CT testing methods 42 to determine the damage states at e.g., defined crack lengths.Figure 18.Computed tomography scan cross-section images of the constant amplitude tested 3/2 (GC) MB DH5 specimen’s (maximum stress of 200 MPa, after 24.5 × 10 5 cycles, and 250 MPa after 24.6 × 10 5 cycles) front, rear, and center aluminum sheets. DIC deformation images showing the maximum strain overlaid for front and rear to illustrate the detectability of the cracks.…”
Section: Resultsmentioning
confidence: 99%
“…The detected crack structure in the central aluminum sheet is comparable to the outer aluminum layers, which indicates that the crack development is similar in all aluminum layers and therefore the used methodology is applicable to the investigated structures. With regard to condition monitoring and lifetime prediction, precise investigation of the damage evolution should be possible using intermittent in situ CT testing methods 42 to determine the damage states at e.g., defined crack lengths.…”
Section: Condition Monitoring Using Contacting Variant (Ii) During Fa...mentioning
In this work, the monitorability of fatigue damage in notched thermoplastic-based hybrid fiber metal laminate, containing AA6082-T4 sheets and glass and carbon fiber-reinforced polyamide 6, is investigated using constant amplitude tests. Electrical resistance measurement and digital image correlation were combined to determine the initiation and evolution process of fatigue damage. Preliminary to the application of the electrical resistance measurement during fatigue load, basic investigations regarding necessary measurement accuracy and conditions, e.g. temperature and cross-section influence, were conducted to achieve reliable measurement results. Via digital image correlation fatigue crack growth was determined and correlated with the change in electrical resistance for two metal/fiber-reinforced polymer layer configurations (2/1 and 3/2) and notch geometries (drilling hole and double-edge notch). The results show that reliable detection of fatigue-related damage states is possible independent of aluminum sheet treatment (mechanically blasted or anodized surface), with earlier crack initiation and faster propagation for higher metal volume fraction (layer configuration 2/1). For the two investigated notch geometries an overall similar crack behavior was found. The electrical resistance values directly correlate to varieties of crack formation and growth, representing the aluminum sheet damage progress of the laminate well, and enabling the possibility of e.g. a limit value-based failure criterion. However, geometry and crack-related changes in electric current flow and thus current density must be taken into account for targeted monitoring of the laminate condition, as they cause significant changes in electrical resistance.
“…The detected crack structure in the central aluminum sheet is comparable to the outer aluminum layers, which indicates that the crack development is similar in all aluminum layers and therefore the used methodology is applicable to the investigated structures. With regard to condition monitoring and lifetime prediction, precise investigation of the damage evolution should be possible using intermittent in situ CT testing methods 42 to determine the damage states at e.g., defined crack lengths.Figure 18.Computed tomography scan cross-section images of the constant amplitude tested 3/2 (GC) MB DH5 specimen’s (maximum stress of 200 MPa, after 24.5 × 10 5 cycles, and 250 MPa after 24.6 × 10 5 cycles) front, rear, and center aluminum sheets. DIC deformation images showing the maximum strain overlaid for front and rear to illustrate the detectability of the cracks.…”
Section: Resultsmentioning
confidence: 99%
“…The detected crack structure in the central aluminum sheet is comparable to the outer aluminum layers, which indicates that the crack development is similar in all aluminum layers and therefore the used methodology is applicable to the investigated structures. With regard to condition monitoring and lifetime prediction, precise investigation of the damage evolution should be possible using intermittent in situ CT testing methods 42 to determine the damage states at e.g., defined crack lengths.…”
Section: Condition Monitoring Using Contacting Variant (Ii) During Fa...mentioning
In this work, the monitorability of fatigue damage in notched thermoplastic-based hybrid fiber metal laminate, containing AA6082-T4 sheets and glass and carbon fiber-reinforced polyamide 6, is investigated using constant amplitude tests. Electrical resistance measurement and digital image correlation were combined to determine the initiation and evolution process of fatigue damage. Preliminary to the application of the electrical resistance measurement during fatigue load, basic investigations regarding necessary measurement accuracy and conditions, e.g. temperature and cross-section influence, were conducted to achieve reliable measurement results. Via digital image correlation fatigue crack growth was determined and correlated with the change in electrical resistance for two metal/fiber-reinforced polymer layer configurations (2/1 and 3/2) and notch geometries (drilling hole and double-edge notch). The results show that reliable detection of fatigue-related damage states is possible independent of aluminum sheet treatment (mechanically blasted or anodized surface), with earlier crack initiation and faster propagation for higher metal volume fraction (layer configuration 2/1). For the two investigated notch geometries an overall similar crack behavior was found. The electrical resistance values directly correlate to varieties of crack formation and growth, representing the aluminum sheet damage progress of the laminate well, and enabling the possibility of e.g. a limit value-based failure criterion. However, geometry and crack-related changes in electric current flow and thus current density must be taken into account for targeted monitoring of the laminate condition, as they cause significant changes in electrical resistance.
“…They determined that the oriented CNFs influenced the fiber-matrix interface by strengthening it and reducing delamination. Tensile properties, flexural properties, and interlaminar shear strength (ILSS) improved by incorporating CNF in CFRP [ 62 ]. Applications of CNFs include the implementation of branched carbon nanotube/carbon nanofiber composites as supercapacitors for electrode materials [ 63 ] and CNF structures in developing anode materials for sodium-ion batteries [ 64 ].…”
Section: Nanofibers For Reinforcementmentioning
confidence: 99%
“…Various methods exist for adding nanofibers into a composite material. Nanofibers can be dispersed in the matrix before fabricating the composite [ 62 , 66 ]. Another method includes coating fibers with nanofibers to improve the characteristics of the composite.…”
“…Carbon-fiber (CF) -reinforced polymers (CFRPs), which have received considerable attention as composite materials owing to their excellent mechanical properties, have been applied in various fields, such as the automotive industry, architecture, and the aerospace sector. 3,4 However, further investigation is needed to expand their applications toward sustainable development goals. For instance, fatigue tests, in which destructive phenomena are induced by repeated stimulation over a long period, are crucial because they closely replicate application conditions.…”
Although carbon-fiber-reinforced polymers (CFRPs) have excellent mechanical properties and are considered sustainable, an improved understanding of the fatigue behavior of these materials is crucial for expanding their application scope. The aim of this study is to clarify the fatigue mechanism of CFRPs using in situ and offline mapping by small-angle/wide-angle X-ray scattering (SAXS/WAXS) measurements. The resulting findings provide information about the interface between the carbon fibers (CFs) and epoxy matrix, as well as changes in epoxy chain structure and internal structure of the CFs. For example, the in situ SAXS profiles revealed an increase in intensity with cycling, which may be related to void and crack formation. Furthermore, the in situ WAXS profiles indicated that the 0° fibers became less ordered and that some destruction of the turbostratic structure occurred. Offline SAXS/WAXS mapping after fatigue tests with low and high loads revealed information about changes in the epoxy resin and carbon fibers, respectively, as well as the shapes of cracks. In particular, offline mapping confirmed that epoxy chain relaxation occurred rapidly after failure.
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