Experimental and Numerical Failure Analysis of Adhesive Joint of Glass Fiber Reinforced Polymer Composite

Takács, László; Szabó, Ferenc János

doi:10.3311/ppme.15106

Cited by 8 publications

(5 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The patch can have an octagonal [1], circular [2], and rectangular [3] form. In addition to numerical simulation, experimental studies of joints [4] and reinforced plates for strength [5] are also carried out.…”

Section: Introductionmentioning

confidence: 99%

Axisymmetric Stress State of Adhesive Joint of a Circular Patch with a Plate Weakened by a Circular Cut-out

Kurennov

Smetankina

Barakhov

2023

Period. Polytech. Mech. Eng.

View full text Add to dashboard Cite

Adhesive lap joints are widely used in modern structures. Known analytical mathematical models of the stress state of lap joints describe the joints of straight beams or cylindrical coaxial pipes. It is assumed that the stress state of these structures depends on only one coordinate. The study of the stress state of plates with defects, which are reinforced by patches, in most cases requires the use of at least two-dimensional mathematical models. In this work, it is shown that the axial symmetry of the plate, the cut-out, the patch, and the applied load makes it possible to reduce the problem to a one-dimensional problem in the polar coordinate system. An adhesive lap joint with circular symmetry is considered for the first time. The stress-strain state of the structure is described in an analytical form. Comparison of the results of calculating the stress state of the joint with the results of finite element modelling showed good adequacy of the proposed mathematical model.

show abstract

Section: Introductionmentioning

confidence: 99%

Axisymmetric Stress State of Adhesive Joint of a Circular Patch with a Plate Weakened by a Circular Cut-out

Kurennov

Smetankina

Barakhov

2023

Period. Polytech. Mech. Eng.

View full text Add to dashboard Cite

show abstract

“…The demand for high-performance, recyclable structural components has promoted the development of thermoplastic composite technologies. Thermoplastic polymers offer the advantages of recyclability, easy joining methods [1], and the possibility to produce multi-functional and smart materials [2], and short fibers are often used as reinforcement to improve their strength and stiffness [3,4]. In most cases, short fiber-reinforced composites (SFCs) are processed by injection molding (IM).…”

Section: Introductionmentioning

confidence: 99%

Comparison of the accuracy of analytical models for basalt fiber–reinforced poly(lactic acid) composites prepared by injection molding and fused filament fabrication

Tóth

Kovács

2022

Int J Adv Manuf Technol

View full text Add to dashboard Cite

We compared the accuracy of analytical models for short fiber–reinforced composites prepared by injection molding and fused filament fabrication (FFF). The microstructural features define the strength of the composites, and they are greatly dependent on the processing conditions. We collected data on fiber length, orientation, and porosity via X-ray micro-computed tomography (µ-CT) and determined the critical fiber length experimentally. We used this data as input for the modified rule of mixtures and the modeling framework based on the Halpin–Tsai method, and found that the cumulative error for FFF is more than twice that for injection-molded composites. We also showed that experimentally determined matrix strength for FFF gives a lower strength limit which is applicable for engineering parts. We presented a new approach for the modeling of the tensile strength of neat FFF products, in which the printed structure is divided into contact zones and bulk material zones. The matrix strength calculated this way was found to approximate the experimental results with an error of 5%.

show abstract

“…Most human and animal tissues (e.g., tendon, muscle, bone, nerve, vein/artery, and skin or pellicle tissues) have a fibrous structure (Moore 1999 ; Neumann et al 2019 ). Similar to artificial fibrous materials, such as textiles or fiber-reinforced composites (Bovier 2012 ; Fondrk et al 1988 ; Gibson 2016 ; Hull 1996 ; Kollar 2003 ; Kovács and Romhány 2018 ; Takács and Szabó 2020 ; Vardai et al 2019 ; Yin 2018 ), they are usually examined by using continuum phenomenological models (Fondrk et al 1988 ; Nordin 2022 ; Pollintine et al 2009 ) like the anisotropic linear elastic approach for hard materials and the isotropic Neo-Hookean and the anisotropic Fung and Holzapfel–Gasser–Ogden's (HGO) hyper-elastic models for soft materials (Huh et al 2019 ; Sun and Sacks 2005 ). The mechanical features of fibrous materials, however, strongly depend on the statistical geometrical and mechanical properties of the building elements like fibrils, fibers, and bundles of them such as macro-fibrils, yarns or rovings, as well as on the connection between the fibers and their environment.…”

Section: Introductionmentioning

confidence: 99%

Nonlinear fiber-bundle-cells-based phenomenological modeling of human tissue samples

Vas

Péter

Bognár

et al. 2022

Biomech Model Mechanobiol

View full text Add to dashboard Cite

Certain assemblies of fibers, called fiber bundles, play a crucial role in the statistical macroscale properties of fibrous structures like natural or artificial materials. Based on the concept of using idealized statistical fiber bundle cells (FBCs) as model elements, the software named FiberSpace was developed by us earlier for the phenomenological modeling of the tensile test process of real fibrous structures. The model fibers of these FBCs had been considered linear elastic, which was suitable for modeling certain textiles and composites. However, the biological tissues are multilevel structures with fiber-like building elements on every structural level where the fiber elements on the dominant level are statistical bundles of elementary fibers. Hence, their modeling required us to introduce model fibers of nonlinear mechanical behavior and derive the proper mathematical formulas for the calculation of the expected tensile force processes of the FBCs. Accordingly, we developed a new version of FiberSpace. The proposed nonlinear FBCs-based modeling method is essentially phenomenological that decomposes the measured and averaged stress–strain curve into the weighted sum of the responses of different idealized nonlinear FBCs. However, this decomposition can give certain information about the fibrous structure and some details of its damage and failure sub-processes. A special application of nonlinear E-bundles, where the measured stress–strain curve is expanded into a product-function series, may give another type of description for the failure process and can be applied to single measurements of structured failure process containing significant peaks and drops as well. The fitted phenomenological FBC models provide a decomposition of the measured force–strain curve, which enables to construct informative damage and failure maps. The applicability of the phenomenological modeling method and the fitting procedure is demonstrated with the tensile test data of some human and animal tissues, such as facial nerves and tendons.

show abstract

Experimental and Numerical Failure Analysis of Adhesive Joint of Glass Fiber Reinforced Polymer Composite

Cited by 8 publications

References 22 publications

Axisymmetric Stress State of Adhesive Joint of a Circular Patch with a Plate Weakened by a Circular Cut-out

Axisymmetric Stress State of Adhesive Joint of a Circular Patch with a Plate Weakened by a Circular Cut-out

Comparison of the accuracy of analytical models for basalt fiber–reinforced poly(lactic acid) composites prepared by injection molding and fused filament fabrication

Nonlinear fiber-bundle-cells-based phenomenological modeling of human tissue samples

Contact Info

Product

Resources

About