Study on the Cutting Damage Mechanism of Aramid Honeycomb Based on the Progressive Damage Model

Yang, Yuxing; Bao, Yan; Wang, Jinlong; Chen, Chen

doi:10.3390/ma15124063

Cited by 4 publications

(2 citation statements)

References 25 publications

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“…Extensive studies have focused on specific energy absorption and crush force efficiency to enhance damage tolerance [15,16]. Zhang et al [17] analysed deformation defects due to cell wall buckling, while Yang et al [18] proposed a progressive damage model, highlighting the contributions of opening-mode cracking and sliding-mode cracking to honeycomb breakage. The strong plasticity of aramid fibre was identified as a factor leading to uncut fibre and burr damages.…”

Section: Introductionmentioning

confidence: 99%

A comparative analysis of 3D woven honeycomb-based aircrew helmet liners against Nomex and Aluminum alternatives

Singh,

Behera,

Thakur

et al. 2024

Phys. Scr.

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This study investigates the energy dissipation efficiency of an aircrew helmet liner developed using 3D woven honeycomb structural composites compared to different commercially available honeycomb liner materials such as Nomex, and Aluminium. In contrast to liners with discrete density differences, the use of a honeycomb-based liner reduces the concern about delamination, back face deformation and fracture propagation. The research involves comparing several parameters related to crashworthiness, such as specific energy absorption (SEA), crush force efficiency (CFE), and margin of safety, which are crucial for head protection and ensuring helmet injury tolerance. These parameters play a vital role in assessing the ability of different configurations of the honeycomb liner during impacts. Flatwise compression and dynamic impact tests were conducted to evaluate the helmet liner's performance while maintaining consistency in the helmet shell component. Finite element analysis (FEA) and 3D X-ray Tomography techniques were utilized to analyse the back face deformation (BFD) at high-velocity impact and the internal damage resulting from impacts on the helmet liners, respectively. The results revealed that the 3D woven honeycomb liner configuration performs optimally in terms of energy absorption by demonstrating sufficient and balanced competency across these three critical factors. Additionally, the simulation result revealed that the 3D woven honeycomb liner exhibits wave propagation. This phenomenon enhances its energy absorption capacity and reduces back-face deformation attributed to its crushing behaviour. This research offers valuable insights for improving the performance of aircrew helmet liners, with a particular focus on utilizing 3D woven honeycomb liners featuring 3D woven solid structure to maintain exceptional structural integrity.

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Section: Introductionmentioning

confidence: 99%

A comparative analysis of 3D woven honeycomb-based aircrew helmet liners against Nomex and Aluminum alternatives

Singh,

Behera,

Thakur

et al. 2024

Phys. Scr.

View full text Add to dashboard Cite

show abstract

“…1 Due to their high stiffness and strength, honeycomb structures are widely used in the aerospace and automobile fields. [2][3][4] The mechanical properties of the honeycomb sandwich structure are strongly related to the material of the face-sheet, the core and the adhesive.…”

Section: Introductionmentioning

confidence: 99%

Study on the failure behavior of Nomex honeycomb sandwich panels under three-point bending load: Experiments and meso-scale simulation

Ma,

Li,

et al. 2023

Jnl of Sandwich Structures & Materials

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The failure behavior and load-carrying capacity of Nomex honeycomb sandwich panels under three-point bending are experimentally and numerically studied. The failure modes observed in experiments are core shear failure and face-sheet/core debonding. A detailed model considering Nomex paper and resin coating is built with Abaqus/explicit simulation. The Hill 1948 quadratic anisotropic yield criteria are adopted to describe the plastic behavior of Nomex paper and the principal stress criteria are used for predicting the failure of resin coating. The effectiveness of the proposed meso-scale model is validated by comparing the experimental and the numerical results. The effects of geometric parameters on the bending behaviors are discussed in detail. It is shown that the ultimate force and bending stiffness of Nomex honeycomb sandwich panels is significantly influenced by the core orientation, resin thickness and cell size. The cutting position has no effect on the ultimate force and bending stiffness.

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Modeling of thin-walled edge cutting angle in end milling of honeycomb cores

Li,

Duan,

Wang

et al. 2024

Composite Structures

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Study on the Cutting Damage Mechanism of Aramid Honeycomb Based on the Progressive Damage Model

Cited by 4 publications

References 25 publications

A comparative analysis of 3D woven honeycomb-based aircrew helmet liners against Nomex and Aluminum alternatives

A comparative analysis of 3D woven honeycomb-based aircrew helmet liners against Nomex and Aluminum alternatives

Study on the failure behavior of Nomex honeycomb sandwich panels under three-point bending load: Experiments and meso-scale simulation

Modeling of thin-walled edge cutting angle in end milling of honeycomb cores

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