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学者姓名:廖娟
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Abstract :
Lattice structures have attracted significant scholarly attention due to their exceptional mechanical properties, including lightweight characteristics and high strength. Their multifunctionality, such as energy absorption and vibration reduction, adds to their versatility. While extensive research has been conducted on the vibration reduction performance of plate-type, shell-type, and truss-type lattice structures, studies on cylindrical lattice structures are comparatively limited. To achieve broadband vibration suppression in cylindrical structures, this study proposes a novel cylindrical structure based on pyramid cells. The vibration suppression performance and the bandgap formation mechanism of the pyramid cylindrical lattice skeleton structure are examined, with a quantitative analysis of the influence of structural parameters on vibration suppression performance using normalized indicators. Results indicate that the structure demonstrates multiple bandgaps within the 0-1500 Hz range, exhibiting substantial vibration attenuation capabilities. Additionally, adjusting parameters enables the bandgap to shift toward lower frequencies. Finally, the experimental verification of finite element model has been performed by comparing the vibration transmission curves with a maximum relative error of -7.48% at the resonance peak. This work offers valuable insights for the application of cylindrical lattice structures in vibration and noise control fields.
Keyword :
bandgap bandgap pyramidal cylinder lattice structure pyramidal cylinder lattice structure vibration suppression performance vibration suppression performance
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| GB/T 7714 | Xue, Xin , Zeng, Qin , Wu, Fang et al. Vibration and Bandgap Characteristics Analysis of Pyramid Cylinder Lattice Skeleton Structure [J]. | ADVANCED ENGINEERING MATERIALS , 2025 , 27 (7) . |
| MLA | Xue, Xin et al. "Vibration and Bandgap Characteristics Analysis of Pyramid Cylinder Lattice Skeleton Structure" . | ADVANCED ENGINEERING MATERIALS 27 . 7 (2025) . |
| APA | Xue, Xin , Zeng, Qin , Wu, Fang , Liao, Juan , Zhang, Mangong . Vibration and Bandgap Characteristics Analysis of Pyramid Cylinder Lattice Skeleton Structure . | ADVANCED ENGINEERING MATERIALS , 2025 , 27 (7) . |
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Metallic sandwich panels featuring cellular metal cores are widely utilized across various sectors due to their exceptional load-bearing efficiency and design versatility. However, their application is often limited by the challenge of shaping complex geometries. This study introduces a novel thin sandwich panel incorporating stainless steel wire mesh (SSWM) core, designed to offer both lightweight properties and enhanced flexibility. Mechanical properties and forming limit diagrams of the sandwich sheet are assessed through tensile tests and Nakajima forming tests. The study investigates how the SSWM stacking angle and strain paths influence the panel's failure behavior and formability. Comparative analyses with monolithic stainless steel sheets of identical dimensions are also conducted. The findings reveal that the sandwich sheet exhibits comparable formability to the monolithic sheet in the tension-compression stain zone, with about 32% higher average specific tensile strength compared to the monolithic counterpart. Importantly, the formability and failure characteristics of the sandwich panel are significantly influenced by in-plane shear deformation of the SSWM core, which is primarily dictated by the SSWM stacking angle and strain paths. Notably, the sandwich sheet with 45 degrees stacking angle demonstrates superior plasticity and formability.
Keyword :
failure behaviors failure behaviors formability formability sandwich panels sandwich panels stainless steel wire mesh stainless steel wire mesh
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| GB/T 7714 | Liao, Juan , Qian, Jinhang , Cao, Houchen et al. Formability and Failure Behavior of a Thin Sandwich Panel with Stainless Steel Wire Mesh [J]. | ADVANCED ENGINEERING MATERIALS , 2025 , 27 (4) . |
| MLA | Liao, Juan et al. "Formability and Failure Behavior of a Thin Sandwich Panel with Stainless Steel Wire Mesh" . | ADVANCED ENGINEERING MATERIALS 27 . 4 (2025) . |
| APA | Liao, Juan , Qian, Jinhang , Cao, Houchen , Xue, Xin . Formability and Failure Behavior of a Thin Sandwich Panel with Stainless Steel Wire Mesh . | ADVANCED ENGINEERING MATERIALS , 2025 , 27 (4) . |
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Acoustic metastructures (AMs) are a type of artificial engineering materials composed of various micro-meso structure subwavelength units. They can exhibit distinct and exotic performances such as low mass, low volume, low frequency, and broadband through appropriate structural designs, which provide novel means for the exploration of physical interpretation in terms of individual case. Thus, the design strategies of AMs for unprecedented properties are of growing interest and attention. Beginning with the recent advances in structural design, a comprehensive review of the physical mechanisms and structural characteristics of four typical AMs, i.e., Helmholtz resonators, membrane-type AMs, coiling-up space structures, and lattice structures, is performed. Meanwhile, various engineering application potentials associated with regard to performance evolutions including sound absorption and noise reduction, acoustic cloaking, and acoustic lenses are introduced, as well as the corresponding design optimization strategies. Finally, the current scientific and technical challenges and the developmental trends of AMs are summarized. This review work aims to provide a design roadmap for next-generation AMs and a trigger on unsuspected physical mechanisms.
Keyword :
acoustic metastructures acoustic metastructures acoustic wave control acoustic wave control applications applications physical mechanisms physical mechanisms structural design structural design
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| GB/T 7714 | Wu, Fang , Zheng, Chao , Wei, Yuhan et al. Current Progress of Acoustic Metastructures: Design Strategy and Prospective Application [J]. | ADVANCED ENGINEERING MATERIALS , 2025 , 27 (10) . |
| MLA | Wu, Fang et al. "Current Progress of Acoustic Metastructures: Design Strategy and Prospective Application" . | ADVANCED ENGINEERING MATERIALS 27 . 10 (2025) . |
| APA | Wu, Fang , Zheng, Chao , Wei, Yuhan , Xue, Xin , Liao, Juan . Current Progress of Acoustic Metastructures: Design Strategy and Prospective Application . | ADVANCED ENGINEERING MATERIALS , 2025 , 27 (10) . |
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Incremental forming technology is gaining increasing attention from various industrial sectors owing to its adaptability and potential for customization. Nonetheless, some challenges such as poor geometric precision are impeding the industrial widespread of this method. Hybridization, cooperation between mechanisms/processes/energies/approaches, has lately emerged as a powerful approach to elevate the manufacturing competence. To this end, hybridization idea has been implemented in the area of incremental forming to address the pertinent challenges, and conducive outcomes have been achieved. The present article reviews advancements made in hybrid incremental forming. The article begins with a comparative analysis of contemporary and traditional incremental forming processes from multiple viewpoints. Subsequently, recent developments in energy-assisted incremental forming processes, categorized into cryogenic temperature-assisted, thermal-assisted and special energy field-assisted techniques (which encompass ultrasonic, electric, and electromagnetic fields), are summarized. The mechanisms through which special energy fields interact with materials and their subsequent impact on the forming quality of workpieces are systematically examined. Additionally, the benefits and drawbacks of various assisted methods are analyzed. Furthermore, the current state of research regarding the hybridization of incremental forming with other forming processes is outlined, which offers novel avenues for enhancing productivity and the quality of workpiece deformation. Lastly, the prospective advancements in hybrid incremental forming technology are presented to support its application in large-scale industrial contexts.
Keyword :
Energy field-assisted Energy field-assisted Hybrid forming Hybrid forming Incremental forming Incremental forming Thermal-assisted Thermal-assisted
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| GB/T 7714 | Liao, Juan , Huang, Youchun , Lu, Xinyang et al. Hybrid incremental forming processes: a review [J]. | INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY , 2025 , 136 (7-8) : 3077-3109 . |
| MLA | Liao, Juan et al. "Hybrid incremental forming processes: a review" . | INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY 136 . 7-8 (2025) : 3077-3109 . |
| APA | Liao, Juan , Huang, Youchun , Lu, Xinyang , Jiang, Yongtao , Hussain, Ghulam . Hybrid incremental forming processes: a review . | INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY , 2025 , 136 (7-8) , 3077-3109 . |
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The plasticity of magnesium alloys is inherently constrained by their hexagonal close-packed (HCP) crystal structure and limited slip system at room-temperature, which restricts their widespread application across various industries. Therefore, identifying an effective method to enhance the plasticity and formability of magnesium alloys remains essential. In this study, the mechanical behavior of AZ31B Mg alloy was examined under the combined influence of ultrasonic vibration (UV) and a thermal field. Tensile tests incorporating UV and thermal assistance were performed on the sheets at amplitudes ranging from 0 to 50.7 mu m and strain rates between 10-2 and 10-4 s-1 at a temperature of 150 degrees C. Microstructural evolution during deformation was analyzed using optical microscopy (OM) and electron backscattered diffraction (EBSD). The results indicate that under hybrid energy fields, the interaction between UV and strain rate significantly affects the flow stress, elongation, and the critical strain required for dynamic recrystallization (DRX) in Mg alloys. Furthermore, microstructural analysis reveals that the incorporation of UV within the thermal field facilitates intra-grain rotation and deformation, promotes DRX, particularly continuous DRX, and enables dislocation migration from the grain boundary to the grain interior. Consequently, a notable improvement in plasticity is observed across the tested strain rate range when UV is applied at suitable amplitudes. However, excessive amplitudes lead to contrasting variations in mechanical behavior, DRX extent, and dislocation movement. Additionally, the underlying mechanisms responsible for these effects have been clarified.
Keyword :
Hybrid energy fields Hybrid energy fields Magnesium alloy Magnesium alloy Microstructure evolution Microstructure evolution Strain rate Strain rate Ultrasonic vibration Ultrasonic vibration Warm deformation Warm deformation
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| GB/T 7714 | Liao, Juan , Zhang, Yue , Huang, Youchun et al. Ultrasonic vibration-induced macro-micro behaviors of AZ31 magnesium alloy sheet during warm tension at various strain rates [J]. | MATERIALS TODAY COMMUNICATIONS , 2025 , 46 . |
| MLA | Liao, Juan et al. "Ultrasonic vibration-induced macro-micro behaviors of AZ31 magnesium alloy sheet during warm tension at various strain rates" . | MATERIALS TODAY COMMUNICATIONS 46 (2025) . |
| APA | Liao, Juan , Zhang, Yue , Huang, Youchun , Xue, Xin . Ultrasonic vibration-induced macro-micro behaviors of AZ31 magnesium alloy sheet during warm tension at various strain rates . | MATERIALS TODAY COMMUNICATIONS , 2025 , 46 . |
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Magnesium (Mg) alloys are becoming popular in lightweight manufacturing due to their low density and high specific strength. However, insufficient slip systems result in poor plasticity of Mg alloys at room temperature. Therefore, an ultrasonic energy field combined with thermal field is introduced to assist the deformation of AZ31 Mg alloy to improve its plasticity. Firstly, ultrasonic vibration (UV)-assisted tensile tests at different temperatures (130–150 °C) are conducted to investigate the effect of UV on material behaviour and the activation of dynamic recrystallization (DRX). Then, the influences of UV on the mechanical properties and microstructure of the material at 150 °C are investigated by varying the parameters of ultrasound amplitude, strain rate, and vibration interval. The results reveal that applying UV can activate DRX at a relatively lower temperature compared with that without UV. Superimposing a certain amount of ultrasonic energy on this material at warm conditions reduces flow stress and increases elongation. In the intermittent ultrasonic vibration (IUV) tests, the DRX percentage and elongation first increase and then decrease as the vibration interval increases. The elongation of specimens with appropriate vibration intervals even exceeds that of specimens with continuous ultrasonic vibration (CUV). However, CUV is more effective than IUV in reducing ultimate tensile strength at different amplitudes or strain rates. © 2024
Keyword :
Dynamic recrystallization Dynamic recrystallization Elongation Elongation High strength alloys High strength alloys Magnesium alloys Magnesium alloys Microstructure Microstructure Plasticity Plasticity Strain rate Strain rate Tensile strength Tensile strength Tensile testing Tensile testing Ultrasonic effects Ultrasonic effects Ultrasonic waves Ultrasonic waves Vibrations (mechanical) Vibrations (mechanical)
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| GB/T 7714 | Huang, Youchun , Zhang, Yue , Liao, Juan . Effects of process parameters on the mechanical properties and microstructure in ultrasonic vibration-assisted warm tensile deformation of AZ31 magnesium alloy [C] . 2024 : 378-383 . |
| MLA | Huang, Youchun et al. "Effects of process parameters on the mechanical properties and microstructure in ultrasonic vibration-assisted warm tensile deformation of AZ31 magnesium alloy" . (2024) : 378-383 . |
| APA | Huang, Youchun , Zhang, Yue , Liao, Juan . Effects of process parameters on the mechanical properties and microstructure in ultrasonic vibration-assisted warm tensile deformation of AZ31 magnesium alloy . (2024) : 378-383 . |
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The purpose of this paper is to examine the effect of processing parameters and subsequent heat treatments on the microstructures and bonding strengths of Ti-6Al-4V/AA1050 laminations formed via a non-equal channel lateral co-extrusion process. The microstructural evolution and growth mechanism in the diffusion layer were discussed further to optimize the bonding quality by appropriately adjusting process parameters. Scanning electron microscopes (SEM), energy dispersive spectrometer (EDS), and Xray diffraction (XRD) were used to characterize interfacial diffusion layers. The shear test was used to determine the mechanical properties of the interfacial diffusion layer. The experimental results indicate that it is possible to co-extrusion Ti-6Al-4V/AA1050 compound profiles using non-equal channel lateral co-extrusion. Different heat treatment processes affect the thickness of the diffusion layer. When the temperature and time of heat treatment increase, the thickness of the reaction layers increases dramatically. Additionally, the shear strength of the Ti-6Al-4V/AA1050 composite interface is proportional to the diffusion layer thickness. It is observed that a medium interface thickness results in superior mechanical performance when compared to neither a greater nor a lesser interface thickness. Microstructural characterization of all heat treatments reveals that the only intermetallic compound observed in the diffusion layers is TiAl3. Due to the inter-diffusion of Ti and Al atoms, the TiAl3 layer grows primarily at AA1050/TiAl3 interfaces. (c) 2023 China Ordnance Society. Publishing services by Elsevier B.V. on behalf of KeAi Communications Co. Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/ licenses/by-nc-nd/4.0/).
Keyword :
Co -extrusion Co -extrusion Heat treatment Heat treatment Intermetallic compounds Intermetallic compounds Microstructure Microstructure Shear strength Shear strength
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| GB/T 7714 | Liao, Juan , Tian, Mengmeng , Xue, Xin . Interface property of dissimilar Ti-6Al-4V/AA1050 composite laminate made by non-equal channel lateral co-extrusion and heat treatment [J]. | DEFENCE TECHNOLOGY , 2024 , 33 : 197-208 . |
| MLA | Liao, Juan et al. "Interface property of dissimilar Ti-6Al-4V/AA1050 composite laminate made by non-equal channel lateral co-extrusion and heat treatment" . | DEFENCE TECHNOLOGY 33 (2024) : 197-208 . |
| APA | Liao, Juan , Tian, Mengmeng , Xue, Xin . Interface property of dissimilar Ti-6Al-4V/AA1050 composite laminate made by non-equal channel lateral co-extrusion and heat treatment . | DEFENCE TECHNOLOGY , 2024 , 33 , 197-208 . |
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As a novel elastic-porous damping material fabricated through entangled wire mesh, W-shape elastic-porous metallic damper (W-EPMD) is considered an ideal damping element for coated pipeline system due to the micro dry friction between metal wires, which induces energy dissipation. The complex interwoven cellular formations of metallic wire mesh pose challenges in characterizing its dynamic characteristics. In this work, the dynamic properties of the pipeline system covered with W-EPMD under various impact conditions, including the acceleration response and impact isolation coefficient, were investigated by numerical simulations and experimental analysis. Constitutive models used to characterize the hysteresis behavior of W-EPMD were introduced, comprising Yeoh and Bergstrom-Boyce models, and parameter identification were conducted through quasistatic experiments. The reliability of the established numerical model was confirmed through drop impact experiments. The results demonstrate that there is a maximum discrepancy of 9.1 % between the simulation predictions and experimental results of the stress-strain curve. The impact isolation coefficient of the pipeline system covered with W-EPMD exhibits a fluctuating trend with the rise of the pulse peak, while the maximum compression of W-EPMD steadily increases. During the pipeline impact process, the increased density of W-EPMD reduces the impact resistance of the pipeline system, while excessively low density leads to over-compression and structural damage to W-EPMD. Furthermore, the discrepancy of the acceleration response between experimental and numerical results under various excitation signals remain within 6 %, demonstrating that the hysteresis model effectively characterizes the impact resistance characteristics of the pipeline system covered the W-EPMD.
Keyword :
Elastic-porous metallic damper Elastic-porous metallic damper Hysteresis model Hysteresis model Impact resistance characteristics Impact resistance characteristics Pipeline system Pipeline system
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| GB/T 7714 | Xue, Xin , Ge, Shaoxiang , Chen, Yilin et al. Impact resistance characteristics of pipeline system covered with W-shape elastic-porous metallic damper [J]. | ENGINEERING STRUCTURES , 2024 , 323 . |
| MLA | Xue, Xin et al. "Impact resistance characteristics of pipeline system covered with W-shape elastic-porous metallic damper" . | ENGINEERING STRUCTURES 323 (2024) . |
| APA | Xue, Xin , Ge, Shaoxiang , Chen, Yilin , Wei, Yuhan , Liao, Juan . Impact resistance characteristics of pipeline system covered with W-shape elastic-porous metallic damper . | ENGINEERING STRUCTURES , 2024 , 323 . |
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Herein, a novel material design strategy is proposed: an interpenetrating composite composed of a woven orthogonal spiral metal skeleton and polyurethane (PU) elastomer. This interpenetrating composite combines rigidity and flexibility, exhibiting excellent elasticity and deformation recovery. The deformation behavior and mechanical properties of the composites under various loading conditions are investigated through experiments and numerical simulations. Different degrees of warping behaviors occur in composites with various structural parameters under uniaxial tension. Alternating rotations and double spiral arrangements can significantly limit the warping phenomenon, with a maximum reduction of 78%. The bending load capacity is regularly increased by increasing the wire diameter and decreasing the pitch. Increasing the number of loaded spiral wires enhances the bending load capacity of the composites. Uniaxial compression tests demonstrate that the composites have excellent load-carrying capacity and strain recovery, with compressive strength 1.5 times that of pure PU. Cyclic compression tests further illustrate the excellent energy consumption capacity and stability of the composites. Overall, the introduction of orthogonal spiral skeletons into the composites demonstrates the potential to achieve enhanced load-carrying capacity and large strain recovery simultaneously.
Keyword :
interpenetrating composites interpenetrating composites mechanical properties mechanical properties orthogonal spiral metal skeleton orthogonal spiral metal skeleton tensile warpage tensile warpage
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| GB/T 7714 | Xue, Xin , Ye, Zixiong , Liu, Xinzhe et al. Mechanical Behaviors of Orthogonal Spiral Metal Skeleton-Polyurethane Elastomer Composites under Complex Loading Modes [J]. | ADVANCED ENGINEERING MATERIALS , 2024 , 26 (24) . |
| MLA | Xue, Xin et al. "Mechanical Behaviors of Orthogonal Spiral Metal Skeleton-Polyurethane Elastomer Composites under Complex Loading Modes" . | ADVANCED ENGINEERING MATERIALS 26 . 24 (2024) . |
| APA | Xue, Xin , Ye, Zixiong , Liu, Xinzhe , Liao, Juan , Zhang, Mangong . Mechanical Behaviors of Orthogonal Spiral Metal Skeleton-Polyurethane Elastomer Composites under Complex Loading Modes . | ADVANCED ENGINEERING MATERIALS , 2024 , 26 (24) . |
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The purpose of this paper is to examine the effect of processing parameters and subsequent heat treatments on the microstructures and bonding strengths of Ti-6Al-4V/AA1050 laminations formed via a non-equal channel lateral co-extrusion process.The microstructural evolution and growth mechanism in the diffusion layer were discussed further to optimize the bonding quality by appropriately adjusting process parameters.Scanning electron microscopes(SEM),energy dispersive spectrometer(EDS),and X-ray diffraction(XRD)were used to characterize interfacial diffusion layers.The shear test was used to determine the mechanical properties of the interfacial diffusion layer.The experimental results indicate that it is possible to co-extrusion Ti-6Al-4V/AA1050 compound profiles using non-equal channel lateral co-extrusion.Different heat treatment processes affect the thickness of the diffusion layer.When the temperature and time of heat treatment increase,the thickness of the reaction layers increases dramatically.Additionally,the shear strength of the Ti-6Al-4V/AA1050 composite interface is propor-tional to the diffusion layer thickness.It is observed that a medium interface thickness results in superior mechanical performance when compared to neither a greater nor a lesser interface thickness.Micro-structural characterization of all heat treatments reveals that the only intermetallic compound observed in the diffusion layers is TiAl3.Due to the inter-diffusion of Ti and Al atoms,the TiAl3 layer grows pri-marily at AA1050/TiAl3 interfaces.
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| GB/T 7714 | Juan Liao , Mengmeng Tian , Xin Xue . Interface property of dissimilar Ti-6Al-4V/AA1050 composite laminate made by non-equal channel lateral co-extrusion and heat treatment [J]. | 防务技术 , 2024 , 33 (3) : 197-208 . |
| MLA | Juan Liao et al. "Interface property of dissimilar Ti-6Al-4V/AA1050 composite laminate made by non-equal channel lateral co-extrusion and heat treatment" . | 防务技术 33 . 3 (2024) : 197-208 . |
| APA | Juan Liao , Mengmeng Tian , Xin Xue . Interface property of dissimilar Ti-6Al-4V/AA1050 composite laminate made by non-equal channel lateral co-extrusion and heat treatment . | 防务技术 , 2024 , 33 (3) , 197-208 . |
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