Your search keyword '"HONEYCOMB structures"' showing total 11 results

1. Mechanical property of all-composite diamond honeycomb sandwich structure based on interlocking technology: Experimental tests and numerical analysis.

Author

Song, Shijun, Xiong, Chao, Yin, Junhui, and Zhang, Sa

Subjects

*SANDWICH construction (Materials), *HONEYCOMB structures, *NUMERICAL analysis, *DIAMONDS, *COMPRESSIVE strength, *ELECTRON field emission

Abstract

In this study, a three-rib intersecting composite diamond honeycomb structure is fabricated by interlocking technology. The mechanical properties of the composite interlocked diamond honeycomb (CIDH) and corresponding sandwich structure (CIDHSS) are experimentally tested. The stiffness, strength, and failure characteristics of CIDH and CIDHSS are analyzed. The results show that CIDH has better mechanical properties than the interlocked Kagome and square honeycombs. The edge effect limits the edge compressive strength and stiffness of CIDH. Debonding is the main failure mode that limits both bending and compressive strength of CIDHSS. The reinforced plate added to the edge effectively improves the anti-debonding ability. [ABSTRACT FROM AUTHOR]

Published

2024

2. Crashworthiness performance of hybrid energy absorbers using PET-G honeycomb structure.

Author

Silva, Rita de Cássia, Castro, Gabriel Martins, Oliveira, Alessandro Borges de Sousa, Brasil, Augusto C. M., and Luz, Sandra M.

Subjects

*HONEYCOMB structures, *ENERGY consumption, *DYNAMIC testing, *FILLER materials, *AXIAL loads

Abstract

The authors report an experimental investigation on square thin-walled energy absorbers with different topologies and materials. The material was steel SAE 1010 and aluminum AL 6160. Some samples non-filled and filled with polymeric material received patterned windows placed in opposite faces with specific dimensions: 20x20, 15x30, and 20x30 mm2. Quasi-static axial loading crushes hollow specimens and hybrid specimens filled with PET-G honeycomb. The core filling was printed using the FDM technique. The crashworthy ability of specimens was evaluated based on the specific energy absorption (SEA), load ratio (LR) and structural efficiency (η), which showed that windowed-filled specimens with 20x30 mm2 perform better. The maximum increase of SEA was 212%, LR decreased from 4.02 to 1.78 and η increased from 0.45 to 0.89 for steel energy absorbers and in the same manner, the values for aluminum specimens were 123%, 2.97 to 1.28 and 0.46 to 0.71. The effects of the patterned windows and their combination with the honeycomb core for both metallic materials show that such a topology improved the performance in two factors. The windows reduced the peak force, and the PET-G honeycomb furnished a smoothing to the region at the end of the fold formation, contributing to the crashworthy ability. Future work envisages experimental testing of the samples in dynamic tests. [ABSTRACT FROM AUTHOR]

Published

2024

3. Mechanical property enhancement in additively manufactured NiTi doubleasymmetric honeycombs with bioinspired graded design.

Author

Luhao Yuan, Dongdong Gu, Kaijie Lin, Xin Liu, Keyu Shi, He Liu, Han Zhang, Donghua Dai, Jianfeng Sun, Jie Wang, and Wenxin Chen

Subjects

*HONEYCOMBS, *HONEYCOMB structures, *NICKEL-titanium alloys, *HYSTERESIS loop, *WALL design & construction, *MECHANICAL energy, *FUNCTIONALLY gradient materials

Abstract

The cuttlebone is known for its ability to possess high specific stiffness, progressive failure and lightweight from the porous chambered structure. Inspired by the microstructural characteristics of cuttlebone and incorporating the wall gradient design, a series of double-asymmetric honeycombs were designed and processed by LPBF. Results indicated that bionic structural units with the junction design can maintain the integrity of the residual parts after local buckling and failure, improving the load-bearing capacity. The double-asymmetric honeycomb with gradation parameter a = 2/3 achieved a maximum specific compressive strength of 70.64 MPa cm3/g. As a decreases, there is an increase in specific energy absorption and a narrowing of the hysteresis loop. The as-build honeycomb had undergone stress-induced martensite transformation during compression. The dissipated mechanical energy (ME) decreased with the increasing cycle number and the decreasing a. The results provide design guidelines and process strategies for developing high-performance honeycombs. [ABSTRACT FROM AUTHOR]

Published

2024

4. Energy absorption characteristics and optimization of three-beam star honeycomb.

Author

Gao, Yuan and Huaiwei, Huang

Subjects

*POISSON'S ratio, *HONEYCOMB structures, *DEFORMATIONS (Mechanics), *ABSORPTION, *GENETIC algorithms

Abstract

With the increase of demands for anti-collision performance in many fields, the negative Poisson's ratio structure has attracted the attention of researchers due to its light weight and high shear stiffness. Therefore, a new negative Poisson's ratio (NPR) structure named three-beam star honeycomb (TBSH) is proposed based on the classical star honeycomb (CSH). The stress equation of TBSH is derived by energy method, and its deformation characteristics and mechanical properties are studied. The results show that the structural deformation modes are different under different impact velocities, and TBSH has more obvious NPR effect. In addition, the influence of geometrical parameters on energy absorption of structures is also investigated. Finally, the thickness gradient is introduced into this structure, and the thickness gradient is optimized by multi-island genetic algorithm (MIGA). After optimization, the specific energy absorption (SEA) of the structure is significantly improved, while the initial peak stress (IPS) is decreased. The new structure proposed in this paper is expected to provide a novel design thinking and optimization idea for superstructure design. [ABSTRACT FROM AUTHOR]

Published

2023

5. Structural design and characteristics of a non-pneumatic tire with honeycomb structure.

Author

Zang, Liguo, Wang, Xingyu, Yan, Pengwei, and Zhao, Zhendong

Subjects

*HONEYCOMB structures, *STRUCTURAL design, *NEWTON-Raphson method, *PERFORMANCE of tires, *FINITE element method

Abstract

The structure of non-pneumatic tire is complex and various, but its performance is superior to ordinary tire, so it has broad prospects. In this paper, a design method of honeycomb structure was proposed based on tangent method, and the hexagonal and circular honeycomb structure were established. The rules of displacement, radial stiffness and ground pressure of honeycomb structure with different density were studied. Meanwhile, the most basic bearing performance of non-pneumatic tire was analyzed by finite element method under static conditions. The results show that the radial stiffness of honeycomb increases with the increase of density. When the density is small, the bearing capacity of circular structure is stronger than that of hexagonal structure, the ground pressure decreases with the increase of density and the maximum stress of the two is located on the honeycomb structure. When the density is high, the maximum stress is on the contact surface between the rim and the inner circumference. This study provides a reference for other types of non-pneumatic tire structure design and builds the foundation to study contact performance analysis of non-pneumatic tire under complex working conditions. [ABSTRACT FROM AUTHOR]

Published

2022

6. In-plane impact dynamics of honeycomb structure containing curved reentrant sides with negative Poisson's ratio effect.

Author

Shen, Jianbang, Ge, Jingran, Xiao, Junhua, and Liang, Jun

Subjects

*POISSON'S ratio, *HONEYCOMB structures, *FINITE element method

Abstract

Honeycomb structure containing curved reentrant sides with negative Poisson's ratio (NPR) was designed and the impact dynamics behaviors were studied by finite element method. The Poisson's ratio and the energy absorption capacity of the honeycomb structure with different arc angle were studied under different compression velocities. The results show that the Poisson's ratio of the honeycomb structure can reach −0.373 with arc angle of 180°. The energy absorption capacity of the honeycomb structure increased with an increasing compression velocity, and the deformation mode changed from X type to V type and I type. When the compression velocity is low, the dynamic response curve of the honeycomb structure with arc angle of 180° has the characteristics of two-stage plateau region. When the compression velocity is high, the energy absorption capacity of the honeycomb structure increased with an increasing arc angle. When the arc angle is higher than 120°, the honeycomb structure has NPR effect, and the energy absorption capacity of the honeycomb structure is better than the honeycomb structure with other arc angles. [ABSTRACT FROM AUTHOR]

Published

2022

7. Multi-objective optimization of the honeycomb core in a honeycomb structure using uniform design and grey relational analysis.

Author

Cheng, Yung-Chang, Yeh, Huai-Chun, and Lee, Cheng-Kang

Subjects

*GREY relational analysis, *HONEYCOMB structures, *HONEYCOMBS, *UNIFORM spaces, *KRIGING, *MAXIMUM entropy method, *DEAD loads (Mechanics), *MATHEMATICAL optimization

Abstract

This study increases the strength of a honeycomb structure under a static load using an innovative and integrated multi-objective optimization procedure. Using a uniform design of experiment, a group of simulation experiments is generated. Finite-element analysis is utilized to determine the maximum von Mises stresses in the honeycomb core for three ASTM testing simulations. Kriging interpolation is used to produce three surrogate models that correspond to the three maximum von Mises stresses using the results of the simulation experiments in the uniform design. To allow three maximum von Mises stresses be reduced simultaneously, grey relational analysis, entropy weighting analysis and a genetic algorithm are used to resolve this multi-objective optimization problem. Compared with the original design, the optimal design induces 5.07, 17.31 and 10.54% improvements for ASTM C297, C364 and C365 testing simulations, respectively. Consequently, the integrated multi-objective optimization technique produces a stronger honeycomb core in the honeycomb structure. [ABSTRACT FROM AUTHOR]

Published

2022

8. Preparation of agglomeration-free composite energetic microspheres taking PMMA-PVA with honeycomb structure as template via the molecular collaborative self-assembly.

Author

Jia, Xinlei, Xu, Lanjuan, Hu, Yingying, Li, Chao, Geng, Xiaoheng, Guo, Haiying, Liu, Xuewen, Tan, Yingxin, and Wang, Jingyu

Subjects

*HONEYCOMB structures, *CHEMICAL templates, *MOLECULAR self-assembly, *AGGLOMERATION (Materials), *SCANNING electron microscopy, *MICROSPHERES

Abstract

We proposed with excitement a novel molecular co-assembly (MCSA) that can effectively overcome the agglomeration of energetic materials. Through the coordinated self-assembly of polymethyl methacrylate-polyvinyl acetate (PMMA-PVA) with honeycomb-like structure and nanoparticles, a controlled and orderly distribution of nitroamine explosive (cyclotetramethylenetetranitramine, HMX; cyclotrimethylenetrinitramine, RDX; and hexanitrohexaazaisowurtzitane, CL-20) structure was achieved, above all, resolving the agglomeration problem availably. The modification ability of PMMA to RDX, HMX, and CL-20 at different temperatures was simulated by Materials Studio, which provided guidance for the ambient temperature of collaborative self-assembly. In order to compare the priority of the morphology and performance, RDX/PMMA-PVA, HMX/PMMA-PVA, and CL-20/PMMA-PVA composite particles with the same PMMA content were also fabricated by water suspension coating method, respectively. Structural characterizations and thermal stability of the composites were systematically studied by scanning electron microscopy (SEM), X-ray diffraction (XRD), fourier-transform infrared (FT-IR) spectra, and differential scanning calorimeter (DSC). Moreover, the safety performance was analyzed by qualitative testing of impact sensitivity and friction sensitivity. The solid spherical PBX prepared via collaborative self-assembly all exhibited a perfect spherical structure, smooth, and flat coating, without any agglomeration. They had the same crystalline structure as the uncoated explosives, simultaneously demonstrating lower impact sensitivity and higher energy performance. The application of collaborative self-assembly technology has broken through the key technical bottleneck of the shell material being easy to form a separate phase in the desensitization coating of explosives, availably resolved the problems of particle exposure and low coverage during the coating, thus possessing vital significance for reference in the design and fabrication of PBXs with core-shell structure. [ABSTRACT FROM AUTHOR]

Published

2021

9. Bionic Prototyping of Honeycomb Patterned Polymer Composite and Its Engineering Application.

Author

Korde, Jay M., Shaikh, Mohsin, and Kandasubramanian, Balasubramanian

Subjects

*HONEYCOMB structures, *POLYMERIC composites, *STIFFNESS (Engineering), *AEROSPACE engineering, *THREE-dimensional printing, *BIOLOGICAL systems

Abstract

Polymeric honeycombs have always enticed researchers due to their lightweight, high stiffness-to-weight ratio, and well developed energy absorption characteristics, owing which they find themselves extensively used in automotive and aerospace engineering. Simultaneously, additive manufacturing methodologies offers enticing pathway for prototyping of functional materials starring complex heterogeneous structural designs with varying wall thickness inspired from biological systems, paving way for augmenting the mechanical and physical properties for specifically tailored applications. We have portrayed potential and possible challenges for 3D printing for prototyping of polymeric honeycomb composites, not constrained by existing engineering principles, offering designer proficiency to build resilient architectures. [ABSTRACT FROM AUTHOR]

Published

2018

10. Formation of honeycomb polysulfone film with controlled wettability by surfactant-assisted electric breath figure.

Author

Fei, Ben, Lu, Di-Lai, and Shen, Qing

Subjects

*ELECTRIC potential, *BIOMEDICAL materials, *ELECTRIC capacity, *HONEYCOMB structures, *LAMINATED materials

Abstract

A surfactant-assisted electric breath figure method, SAEBF, was applied to form the polysulfone, PSF, film. Experimentally, the sodium dodecyl-benzenesulfonate, SDDBS, was employed and the voltage was varied. FESEM images showed that the SAEBF formed PSF films have the honeycomb structure and the pore diameter was reduced with the applied voltage increase. Water contact angle on the honeycomb PSF film surfaces was found to increase with the applied voltage increase and there has a critical voltage at about 0.6 kV among those applied voltages because the applied voltage at lower or higher caused the film surface in hydrophilic or hydrophobic, respectively. A related mechanism was discussed. [ABSTRACT FROM AUTHOR]

Published

2018

11. X-ray diffraction from hexagonal dislocation networks.

Author

Kopp, Viktor S. and Kaganer, Vladimir M.

Subjects

*X-ray diffraction, *DISLOCATION motion, *SIMULATION methods & models, *DISPLACEMENT (Mechanics), *HONEYCOMB structures

Abstract

We built the honeycomb networks of misfit dislocations by combining angular dislocations. Two different models of the disorder in the dislocation network are explored, the random shifts of nodes and random sources of distortion. The displacement fields of disturbed dislocation networks are used to simulate the X-ray diffraction patterns by Monte Carlo method. We find that substantial disorder is needed for random shifts to be experimentally observable as diffuse scattering. The model of random distortion sources produces comparable diffuse scattering with the dislocation network looking closer to the initial perfect structure. The diffraction patterns due to distorted honeycomb dislocation networks are compared with the ones due to triangular networks of straight dislocations. The disorder parameters of the latter networks can be chosen to produce diffraction patterns similar to the former. [ABSTRACT FROM PUBLISHER]

Published

2014