Interlaminar Reinforcement Mechanism in a Beetle Fore-Wing
スポンサーリンク
概要
- 論文の詳細を見る
An interlaminar peeling test was conducted for an A. dichotoma beetle fore-wing with the interlaminar reinforcement mechanism being investigated. The load-displacement curves indicated the presence of many load peaks with the number of load peaks being equal to the number of trabeculae found in the chitin fiber laminae. This result suggested that each trabecula fracture contributed to a single load peak, which then combined to provide the interlaminar strength. The increment of interlaminar strength due to the trabeculae in the chitin fiber laminae was approximately 30 times in a local region and 3 times in a whole region larger compared to that of the chitin fiber laminae without trabeculae. The chitin fibers were found to be connected between the chitin fiber laminae with the trabeculae being curved and continuous, whilst the trabeculae bonded chitin fiber laminae were distributed in two dimensions within the chitin fiber lamina plane. Furthermore, a strong reinforcement mechanism in nature was clarified with a model for the reinforcement mechanism being proposed.
- 一般社団法人日本機械学会の論文
- 2001-12-15
著者
-
Saito Kenji
Kyoto Institute of Technology
-
Kurashiki Ken
Kyoto Institute Of Technology
-
Chen Jinxiang
National Aerospace Laboratory
-
NI QingQing
Kyoto Institute of Technology
-
IWAMOTO Masaharu
Kyoto Institute of Technology
-
Ni Qing-Qing
Kyoto Institute of Technology
関連論文
- J-8 DEVELOPMENT OF SIMULATION FOR HOT FORGING OF GEARS : Constitutive Equation in Considering Visco-Plasticity(Session: Simulation)
- Interlaminar Reinforcement Mechanism in a Beetle Fore-Wing
- An Evaluation Method of J-Integral for Porous Polymeric Materials : Series A : Solid-Mechanics, Strength of Materials
- Effects of Temperature and Void on Elasto-Plastic Fracture Toughness of Porous and Polymeric Material : Series A : Solid-Mechanics, Strength of Materials
- Micromechanical Analysis of Crack Closure Mechanism for Intelligent Material Containing TiNi Fibers : 2nd Report, Numerical Calculation of Stress Intensity Factor in the Process of Shape Memory Shrinkage of TiNi Fibers(Fracture Mechanics)
- Micromechanical Analysis of Crack Closure Mechanism for Intelligent Material Containing TiNi Fibers : 1st Report, Modeling of Crack Closure Mechanism and Analysis of Stress Intensity Factor(Fracture Mechanics)