Study on the Hot Workability of SiCp/Al Composites Based on a Critical Strain Map

Yuan Zhanwei; Li Fuguo; Wang Chunwei

doi:10.1007/s11665-017-2860-y

Study on the Hot Workability of SiCp/Al Composites Based on a Critical Strain Map

Yuan Zhanwei, Li Fuguo, Wang Chunwei

School of Materials Sience and Engineering

Chang'an University

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We used the isothermal compression test (conducted in a Gleeble-3500 system) to study the hot deformation behaviors of SiCp/Al composites over a wide range of temperatures (623-773 K) and strain rates (0.001-10 s⁻¹). A 3D hot-processing map was constructed based on the Malas stability criteria and experimental data. An artificial neural network model of four hot work quality characteristic parameters (strain rate sensitivity m, its derivative m′, temperature sensitivity s, and its derivative s′) were established. A new hot-processing map, known as a hot-processing critical strain map, has been proposed based on the smallest strain prior to instability. Two optimized processing regions at 623-660 K, 0.05-0.075 s⁻¹ and 720-773 K, 0.04-0.18 s⁻¹ were determined based on this map.

Original language	English
Pages (from-to)	4197-4205
Number of pages	9
Journal	Journal of Materials Engineering and Performance
Volume	26
Issue number	9
DOIs	https://doi.org/10.1007/s11665-017-2860-y
State	Published - 1 Sep 2017

Keywords

ANN
critical strain map
deformation instability
hot-processing map
SiCp/Al composite

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10.1007/s11665-017-2860-y

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title = "Study on the Hot Workability of SiCp/Al Composites Based on a Critical Strain Map",

abstract = "We used the isothermal compression test (conducted in a Gleeble-3500 system) to study the hot deformation behaviors of SiCp/Al composites over a wide range of temperatures (623-773 K) and strain rates (0.001-10 s−1). A 3D hot-processing map was constructed based on the Malas stability criteria and experimental data. An artificial neural network model of four hot work quality characteristic parameters (strain rate sensitivity m, its derivative m′, temperature sensitivity s, and its derivative s′) were established. A new hot-processing map, known as a hot-processing critical strain map, has been proposed based on the smallest strain prior to instability. Two optimized processing regions at 623-660 K, 0.05-0.075 s−1 and 720-773 K, 0.04-0.18 s−1 were determined based on this map.",

keywords = "ANN, critical strain map, deformation instability, hot-processing map, SiCp/Al composite",

author = "Yuan Zhanwei and Li Fuguo and Wang Chunwei",

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AU - Fuguo, Li

AU - Chunwei, Wang

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Y1 - 2017/9/1

N2 - We used the isothermal compression test (conducted in a Gleeble-3500 system) to study the hot deformation behaviors of SiCp/Al composites over a wide range of temperatures (623-773 K) and strain rates (0.001-10 s−1). A 3D hot-processing map was constructed based on the Malas stability criteria and experimental data. An artificial neural network model of four hot work quality characteristic parameters (strain rate sensitivity m, its derivative m′, temperature sensitivity s, and its derivative s′) were established. A new hot-processing map, known as a hot-processing critical strain map, has been proposed based on the smallest strain prior to instability. Two optimized processing regions at 623-660 K, 0.05-0.075 s−1 and 720-773 K, 0.04-0.18 s−1 were determined based on this map.

AB - We used the isothermal compression test (conducted in a Gleeble-3500 system) to study the hot deformation behaviors of SiCp/Al composites over a wide range of temperatures (623-773 K) and strain rates (0.001-10 s−1). A 3D hot-processing map was constructed based on the Malas stability criteria and experimental data. An artificial neural network model of four hot work quality characteristic parameters (strain rate sensitivity m, its derivative m′, temperature sensitivity s, and its derivative s′) were established. A new hot-processing map, known as a hot-processing critical strain map, has been proposed based on the smallest strain prior to instability. Two optimized processing regions at 623-660 K, 0.05-0.075 s−1 and 720-773 K, 0.04-0.18 s−1 were determined based on this map.

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KW - deformation instability

KW - hot-processing map

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ER -

Study on the Hot Workability of SiCp/Al Composites Based on a Critical Strain Map

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Keywords

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