Compression Shear Properties of Bonded–Bolted Hybrid Single-Lap Joints of C/C Composites at High Temperature

Zhang, Yanfeng; Zhou, Zhen-Gong; Tan, Zhiyong

doi:10.3390/app10031054

Cited by 10 publications

(4 citation statements)

References 32 publications

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“…This is due to the excellent thermal stability and resistance to degradation of polyurethane materials. Kwiecie ń et al [29] confirmed resistance of a single polyurethane material (used in this study in research) against various ageing factors, showing also that it presents stable properties in elevated temperatures up to 200 • C. However, it is critical to understand the limits and potential damage modes of polyurethane joints in wood buildings under different temperature conditions [30,31].…”

Section: Introductionmentioning

confidence: 52%

Flexible Polyurethane Adhesives: Predictive Numerical Model Calibration through Experimental Testing at Elevated Temperature

La Scala,

Śliwa-Wieczorek,

Rizzo

et al. 2024

Applied Sciences

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The thermo-mechanical behavior of polyurethane adhesive joints in wood structures is a crucial aspect that needs to be understood to ensure the durability and safety of timber structures, especially in seismic regions. As mass timber, particularly cross-laminated timber, continues to gain popularity as a building material, it is important to pay special attention to the behavior of connections between the timber elements. The use of flexible polyurethane adhesives presents a promising alternative to conventional mechanical connections in seismic-resistant timber structures. This research highlights the potential of polyurethane-based joints at elevated service temperature, offers a promising alternative to traditional wood joints, and suggests viability for post-fire restoration of wood structures. The response at the interface between wood and polyurethane under flexural stresses is also evaluated, underscoring the broader application possibilities of flexible adhesives in wood construction for mechanical and physical improvements.

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Section: Introductionmentioning

confidence: 52%

Flexible Polyurethane Adhesives: Predictive Numerical Model Calibration through Experimental Testing at Elevated Temperature

La Scala,

Śliwa-Wieczorek,

Rizzo

et al. 2024

Applied Sciences

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“…As related to applied clamping torque, bolt heads, and washers compress the adhesive layer. This pressure transferred to the adhesive layer can increase joint strength by slowing the crack spread during loading 46 . In addition, fiber‐tearing is not observed as clamping pressure also limits the formation of interlaminar delaminations within the adherend.…”

Section: Resultsmentioning

confidence: 99%

“…This pressure transferred to the adhesive layer can increase joint strength by slowing the crack spread during loading. 46 In addition, fiber-tearing is not observed as clamping pressure also limits the formation of interlaminar delaminations within the adherend. As a result of these phenomena, which allow the load to concentrate into the adhesive, the deformation of the adhesive increases, and cohesion failure is more common.…”

Section: Evaluation Of Joint Performances For Different Fiber Reinfor...mentioning

confidence: 99%

Comparative analysis of thermoplastic and thermoset adhesives performance and the influence on failure analysis in jointed elium‐based composite structures

Kaybal,

Ulus

2023

Polymer Composites

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The preference for thermoplastic composites over thermoset ones is steadily growing, especially in constructing resilient, lightweight, and fuel‐efficient structures in industrial settings due to their recyclability and superior energy absorption. Elium®, an acrylic‐based thermoplastic resin, offers enhanced stiffness and improved toughness at room temperature. Investigation into elium‐based composites with diverse fiber reinforcements has revealed elium's potential as an alternative to traditional thermoset epoxy resins. This study explores recyclable elium resin as an adhesive for creating curable and non‐permanent joints in various elium‐based composites. Various joining techniques, including adhesive bonding, mechanical joints, and hybrid bolted/bonded connections, were assessed, with hybrid bonded/bolted (HBB) joints emerging as a preferred solution for structures requiring higher load‐carrying capacity. The study's results indicate that, when using elium adhesive, elium‐hybrid bolted/bonded (HBB) joints demonstrate superior mechanical strength compared to their epoxy counterparts, resulting in improved toughness and stiffness values for each type of composite material. In addition, the research demonstrates superior load‐bearing strengths in bonded glass/elium composite joints using elium adhesive compared to bolted joints, with HBB joints featuring elium adhesive displaying even higher load‐bearing strengths. This research highlights the potential of elium‐based composites and adhesives in various industrial applications, enabling the production of lightweight, robust structures with exceptional damage tolerance.Highlights Investigates recyclable elium resin for curable and non‐permanent joints. Elium‐based composites offer lightweight, robust, and damage‐tolerant structures. Elium HBB joints demonstrate superior strength. FTIR analysis reveals distinct chemical signatures and bonding characteristics. Elium adhesive enhances bond strength.

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“…Such failure traits as the chief damage patterns and fiber cracks of the samples were investigated. In the literature, experimental, analytical, and numerical modeling techniques have been used to explore damage mechanisms in composites [14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Study on the Bending Behavior of Satin-Woven SiCf/SiC Composites

Luo

2022

Coatings

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The present research intends to explore the progressive failure in the case of five-harness SiCf/SiC satin-woven sheet composites consisting of twelve layers using a combination of numerical and experimental methods. For derivation and characterization of the bending behavior, a three-point bending procedure was used under conditions of atmospheric temperature. A charge-coupled device (CCD) camera was used to monitor the initiation and evolution of the failures. Variations in the strain fields were quantified following the digital image correlation (DIC) approach, whereas the resultant failure markings were elucidated by conducting microscopic assessments. The 3D finite element modeling (FEM) of the experiment was accomplished via ABAQUS/Explicit, thereby reproducing the material performance. A 3D-modified theory of the Tsai-Wu failure initiation was executed by exploiting the VUMAT subroutine. The evolutionary rule was used to study the complementary failure. A cohesive zone element of the composite interlayer was utilized to mimic the intra-deformation interfacial damage. The DIC-based experimental values of the strain fields agreed favorably with the numerical computations and the strength value error was less than 10%. An in-depth investigation was performed concerning the advantage of the 3D modeling approach to study the applicability of the method for the foreseeable distribution of the complex field parameters (e.g., progressive failure deposition and free edge effect) inside the critical specimen section.

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Compression Shear Properties of Bonded–Bolted Hybrid Single-Lap Joints of C/C Composites at High Temperature

Cited by 10 publications

References 32 publications

Flexible Polyurethane Adhesives: Predictive Numerical Model Calibration through Experimental Testing at Elevated Temperature

Flexible Polyurethane Adhesives: Predictive Numerical Model Calibration through Experimental Testing at Elevated Temperature

Comparative analysis of thermoplastic and thermoset adhesives performance and the influence on failure analysis in jointed elium‐based composite structures

Experimental and Numerical Study on the Bending Behavior of Satin-Woven SiCf/SiC Composites

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