Effect of Temperature on the Microstructure Developed in Aluminum Processed by Equal Channel Angular Extrusion

Wang, Yu-Yun

03 July 2003

none

Misorientation angle

Deformation structure

lamellar

Warm worked structure of commercially pure aluminium under 75% deformation

Lin, Ming-I

29 June 2004

Aluminum (1050) was deformed by plane strain compression (PSC) up to 75% reduction. The total deformation conditions include four temperatures (from 150oC to 300oC) and two strain rates (5¡Ñ10-2s-1 and 5¡Ñ10-4s-1). After the deformation, the specimens were examined by TEM for observing the morphology of the microstructures and measuring various parameters, which includes the sizes and aspect ratios of dislocation cells, as well as the distribution of misorientation angles for dislocation walls.

Warm-worked Deformation Structure

Misorientation

Compression

The deformation structure of commercially pure aluminium deformed by plain strain compression at different temperature.

Lin, Jing-Liang

05 August 2003

none

Plane Strain Compression

Cell

Misorientation

Deformation structure

Microstructure of Flash processed Steel Characterized by Electron Backscatter Diffraction

Wu, Chun-Hsien

07 January 2010

Flash processing is a new heat treatment process being developed to produce steel with relatively high strength and ductility. It involves rapidly heating steel sheet or strip to a temperature in the austenite range and quenching; the entire thermal cycle takes place within 15 seconds. The resulting microstructure is fine and difficult to resolve using standard metallographic techniques. In this investigation, electron backscatter diffraction was used to measure the grain size, grain orientations, and phase fractions in AISI 8620 samples flash processed to a series of different maximum temperatures. The combination of high strength with moderate ductility obtained by flash processing arises from a refined martensitic microstructure. The morphology of the microstructure depends upon the maximum processing temperature; a lower maximum temperature appears to produce a finer prior austenite grain size and an equiaxed martensite structure whereas a higher maximum processing temperature yields a more conventional lath martensite morphology. / Master of Science

EBSD

flash processing

grain size

Misorientation

OIM

none

Wu, I-Wei

15 August 2006

none

Misorientation

Warm-worked Deformation Structure

Plane Strain Compression (PSC)

The effects of deformation temperature on the microstructural development in Al-Mg alloy processed by equal channel angular extrusion

Chen, Yi-Chi

16 August 2002

none

Boundary structure

Equal Channel Angular Extrusion(ECAE)

Misorientation

Deformation structure

Warm worked structure of commercially pure aluminium under 50% deformation

Ding, Shi-Xuan

05 August 2003

none

Plane Strain Compression

Misorientation

Warm-worked Deformation Structure

The boundary distribution charaters of Equal Channel-Angular Extrusion processed aluminium

Wu, Po-Chang

13 August 2003

none

Shear plane

Deformation structure

Equal Channel-Angular Extrusion

Misorientation angle

Study of stress corrosion cracking of alloy 600 in high temperature high pressure water

Leonard, Fabien

January 2010

Stress corrosion cracking (SCC) of alloy 600 is regarded as one of the most important challenges to nuclear power plant operation worldwide. This study investigates two heats of alloy 600 (forged control rod drive mechanismnozzle and rolled divider plate) in order to obtain a better understanding of the effects of the material parameter on the SCC phenomenon. The experimental approach was designed to determine the effect of the manufacturing process (forged vs. rolled), the cold-work (as-received vs. cold-worked) and the strain path (monotonic vs. complex) on SCC of alloy 600. Specimens with different strain paths have been produced from two materials representative of plant components and tested in high temperature (360°C) high pressure primary water environment. The manufacturing process has been proven to have a great effect on the stress corrosion cracking behaviour of alloy 600. Indeed, the SCC susceptibility assessment has demonstrated that the rolled materialis resistant to SCC even after cold work, whereas the forged material is susceptible in the as-received state. Microstructural characterisations have been undertaken to explain these differences in SCC behaviour. The carbide distribution is the main microstructural parameter influencing SCC but the misorientation, in synergy with the carbide distribution, has been proven to give a better representation of the materials SCC susceptibilities.

669

Influence of Deformation Temperature on the Microstructure Development in Al-Mg Alloy Processed by Equal Channel Angular Extrusion

Shen, Shin-yan

02 August 2005

none

Equal Channel Angular Extrusion

high angle grain boundary

misorientation angle

lamellar structure