Novel Design and Comparison of Structural and Modal Analyses of Auxetic Geometry versus Honeycomb Geometry
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U. Kemiklioğlu
Abstract
Auxetic structures are popular, since they have many applications in defense, textile and sport industries. The advantages of providing comfort and protection to people for the impact energy increase the usability of auxetic structures in these areas. Within the scope of this study, two structures were designed as honeycomb and auxtetic structures with lateral displacements in opposite directions. The auxetic and honeycomb structures were modeled in Ansys software by keeping the boundaries of these two structures close to each other. Structural and modal analysis were applied to these structures and the auxetic structure gave better results in terms of the tensile strength.
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Articles in the same Issue
- Contents
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- Fiber Length Distribution in Twin-Screw Extrusion of Fiber-Reinforced Polymer Composites: A Comparison between Shear and Extensional Mixing
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- Basic Study of Extensional Flow Mixing for the Dispersion of Carbon Nanotubes in Polypropylene by Using Capillary Extrusion
- Pulsed IR Heating of Thermoplastic Sheets for Thermoforming Applications
- Novel Design and Comparison of Structural and Modal Analyses of Auxetic Geometry versus Honeycomb Geometry
- Effect of Introducing Long Chain Branching on Fiber Diameter and Fiber Diameter Distribution in Melt Blowing Process of Polypropylene
- Study on the Relationship between the Bonding Surface and Mechanical Properties of PLA/Epoxy Laminated Composites
- A Study on Thermal and Electrical Conductivities of Ethylene-Butene Copolymer Composites with Carbon Fibers
- Model Approach for Displaying Dynamic Filament Displacement during Impregnation of Continuous Fibres Based on the Theory of Similarity – Theory and Modelling
- Using Symbolic Regression Models to Predict the Pressure Loss of Non-Newtonian Polymer-Melt Flows through Melt-Filtration Systems with Woven Screens
- Preparation and Photo-Oxidation Aging Behavior of Oriented Polylactic Acid
- Numerical Simulation and Process Optimization of a 3D Thin-Walled Polymeric Part Using Injection Compression Molding
- PPS News
- Seikei-Kakou abstracts
- PPS Membership application
Articles in the same Issue
- Contents
- Regular Contributed Articles
- Fiber Length Distribution in Twin-Screw Extrusion of Fiber-Reinforced Polymer Composites: A Comparison between Shear and Extensional Mixing
- The Effect of Nanosilicates on the Performance of Polyethylene Terephthalate Films Prepared by Twin-Screw Extrusion
- Synergistic Effect between Modified Graphene Oxide and Ammonium Polyphosphate on Combustion Performance, Thermal Stability and Mechanical Properties of Polylactic Acid
- Basic Study of Extensional Flow Mixing for the Dispersion of Carbon Nanotubes in Polypropylene by Using Capillary Extrusion
- Pulsed IR Heating of Thermoplastic Sheets for Thermoforming Applications
- Novel Design and Comparison of Structural and Modal Analyses of Auxetic Geometry versus Honeycomb Geometry
- Effect of Introducing Long Chain Branching on Fiber Diameter and Fiber Diameter Distribution in Melt Blowing Process of Polypropylene
- Study on the Relationship between the Bonding Surface and Mechanical Properties of PLA/Epoxy Laminated Composites
- A Study on Thermal and Electrical Conductivities of Ethylene-Butene Copolymer Composites with Carbon Fibers
- Model Approach for Displaying Dynamic Filament Displacement during Impregnation of Continuous Fibres Based on the Theory of Similarity – Theory and Modelling
- Using Symbolic Regression Models to Predict the Pressure Loss of Non-Newtonian Polymer-Melt Flows through Melt-Filtration Systems with Woven Screens
- Preparation and Photo-Oxidation Aging Behavior of Oriented Polylactic Acid
- Numerical Simulation and Process Optimization of a 3D Thin-Walled Polymeric Part Using Injection Compression Molding
- PPS News
- Seikei-Kakou abstracts
- PPS Membership application
