Evolution of Dislocation Structure and Fatigue Crack Behavior in Fe-Si Alloys during Cyclic Bending Test
スポンサーリンク
概要
- 論文の詳細を見る
The evolution of dislocation structures was investigated by TEM in Fe–Si alloys with 0, 0.5 and 1.0 mass% Si during a cyclic bending test in conjunction with fatigue crack behavior. The addition of Si increased the fatigue strength. The evolution of dislocation structures was significantly influenced by the Si addition. Namely, in the steel without Si the dislocation cell structure develops, whereas in the steel with 1 mass% Si the vein structure develops, which is considered to lead to increased fatigue strength. The dislocation cell structure observed in the steel without Si is postulated to be caused by the easy cross slip of dislocations during cyclic deformation, whereas the vein structure that developed in the steels with Si is inferred to be caused by the difficulty in cross slip due to the decrease in stacking fault energy. Furthermore, the Si added steel shows a characteristic structure in a manner such that the dislocations are free in approximately 0.5 μm zones along grain boundaries. The examinations of the fatigue fracture surface revealed that transgranular fracture takes place in steel without Si, whereas in steel with 1 mass% Si many intergranular cracks were observed just beneath the top surface. The intergranular cracks in the 1 mass% Si steel were thought to be caused by the fact that a) strains are dispersed within grains owing to the vein structure and b) micro cracks are initiated and propagated along grain boundaries due to the dislocation free zones.
- 社団法人 日本鉄鋼協会の論文
- 2009-02-15
著者
-
Takebayashi Shigeto
Steel Research Labs., Nippon Steel Corp.
-
Ushioda Kohsaku
Technical Development Bureau, Nippon Steel Corp.
-
Ushioda Kohsaku
Technical Dev. Bureau Nippon Steel Corp.
-
Ushioda Kohsaku
Technical Development Bureau Nippon Steel Corp.
-
Takebayashi Shigeto
Steel Res. Labs. Nippon Steel Corp.
-
Takebayashi Shigeto
Steel Research Labs. Nippon Steel Corp.
-
GOTO Shoji
Graduate School of Engineering and Resource Science
-
KOMATSU Yoshinari
Graduate School of Engineering and Resource Science, Akita University
-
HOSHINO Akinori
Graduate School of Engineering and Resource Science, Akita University
-
Hoshino Akinori
Graduate School Of Engineering And Resource Science Akita University
-
Komatsu Yoshinari
Graduate School Of Engineering And Resource Science Akita University
関連論文
- Comparison of the Dislocation Density in Martensitic Steels Evaluated by Some X-ray Diffraction Methods
- Deep Drawability of Electro-deposited Pure Iron Having an Extremely Sharp //ND Texture
- Nucleation of the Primary Al Phase on TiAl_3 during Solidification in Hot-Dip Zn-11%Al-3%Mg-0.2%Si-Coated Steel Sheet
- Solidification Structure of the Coating Layer on Hot-Dip Zn-11%Al-3%Mg-0.2%Si-Coated Steel Sheet
- The Effect of S and Mn on the High-temperature Oxidation and Scale Spallation Behavior of Low-carbon Steels
- Analysis of Flange Wrinkle in Square-shell Deep Drawing of Anisotropic Sheet
- Evolution of Dislocation Structure and Fatigue Crack Behavior in Fe-Si Alloys during Cyclic Bending Test
- Modeling of Hydrogen Thermal Desorption Profile of Pure Iron and Eutectoid Steel
- Cold-rolling and Recrystallization Texture Formation in Electro-deposited Pure lron with a Sharp and Homoqeneous γ-fiber
- Comparison of the Dislocation Density in Martensitic Steels Evaluated by Some X-ray Diffraction Methods
- Role of TiAl_3 Fine Precipitate in Nucleation of the Primary Al Dendrite Phase during Solidification in Hot-Dip Zn-11%Al-3%Mg-0.2%Si Coated Steel Sheet
- Blistering Behavior during Oxide Scale Formation on Steel Surface
- The Increase in a Brittle-to-ductile Transition Temperature in Fe-Al Single Crystals
- Influence of Si Addition to the Coating Bath on the Growth of the Al-Fe Alloy Layer in Hot-dip Zn-Al-Mg Alloy-coated Steel Sheets
- Role of Hematite Formation on Blister Generation during High Temperature Oxidation of Steel
- Effect of Carbide Size Distribution on the Impact Toughness of Tempered Martensitic Steels with Two Different Prior Austenite Grain Sizes Evaluated by Instrumented Charpy Test
- Behavior of High-Temperature Embrittlement and Its Mechaism in Heat-Affected Zone of Low-Carbon Alloy Steels