断熱鋳型式連続鋳造法で作製した鍛造用 Al-Si 系合金の組織と高温強度に及ぼす銅濃度の影響

Naoya Sugatani; Masayoshi Dohi; Seungwon Lee; Taiki Tsuchiya; Kenji Matsuda

doi:10.2464/jilm.73.9

断熱鋳型式連続鋳造法で作製した鍛造用 Al-Si 系合金の組織と高温強度に及ぼす銅濃度の影響

Translated title of the contribution: Effect of Cu concentration on high-temperature mechanical properties and microstructures of Al-Si alloy for forging fabricated by continuous casting process with the heat-insulating-mold

Naoya Sugatani^*, Masayoshi Dohi, Seungwon Lee, Taiki Tsuchiya, Kenji Matsuda

^*Corresponding author for this work

Materials Design and Engineering

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

2 Scopus citations

Abstract

Al-Si alloy billets with 0, 2, 4, and 6 mass%Cu have been fabricated by the Heat-Insulating-Mold method. The microstructures and high-temperature mechanical properties at 423 K, 523 K, and 623 K have been investigated. Increasing Cu concentration changed the types of constituent particles and increased their area fraction. 0.2% proof stress (σ_0.2) and ultimate tensile strength (σ_UTS) increased with increasing Cu concentration at each temperature. SEM observation showed that precipitates increased with increasing Cu concentration and remained in the matrix below 523 K but dissolved into the Al matrix at 623 K. The former suggested that the precipitates contributed to the strength below 523 K. On the other hand, significant work-hardening was confirmed until 0.2% strain at 623 K, which suggested that the constituent particles contributed to the strength just like particle-reinforced composites. The work-hardening rate and the amount of work-hardening increased with increasing Cu concentration and correlated with the interparticle spacing of the constituent particles. It indicated that decreasing interparticle spacing enhanced constraining matrix deformation, and it led to an increase of σ_0.2

Translated title of the contribution	Effect of Cu concentration on high-temperature mechanical properties and microstructures of Al-Si alloy for forging fabricated by continuous casting process with the heat-insulating-mold
Original language	Japanese
Pages (from-to)	9-16
Number of pages	8
Journal	Keikinzoku/Journal of Japan Institute of Light Metals
Volume	73
Issue number	1
DOIs	https://doi.org/10.2464/jilm.73.9
State	Published - 2023

ASJC Scopus subject areas

Mechanics of Materials
Mechanical Engineering
Metals and Alloys
Materials Chemistry

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@article{456142d9f27f4aea817b0ee5ea484879,

title = "断熱鋳型式連続鋳造法で作製した鍛造用 Al-Si 系合金の組織と高温強度に及ぼす銅濃度の影響",

abstract = "Al-Si alloy billets with 0, 2, 4, and 6 mass%Cu have been fabricated by the Heat-Insulating-Mold method. The microstructures and high-temperature mechanical properties at 423 K, 523 K, and 623 K have been investigated. Increasing Cu concentration changed the types of constituent particles and increased their area fraction. 0.2% proof stress (σ0.2) and ultimate tensile strength (σUTS) increased with increasing Cu concentration at each temperature. SEM observation showed that precipitates increased with increasing Cu concentration and remained in the matrix below 523 K but dissolved into the Al matrix at 623 K. The former suggested that the precipitates contributed to the strength below 523 K. On the other hand, significant work-hardening was confirmed until 0.2% strain at 623 K, which suggested that the constituent particles contributed to the strength just like particle-reinforced composites. The work-hardening rate and the amount of work-hardening increased with increasing Cu concentration and correlated with the interparticle spacing of the constituent particles. It indicated that decreasing interparticle spacing enhanced constraining matrix deformation, and it led to an increase of σ0.2",

keywords = "aluminum-silicon alloy, copper concentration, forging, high-temperature mechanical property, microstructure",

author = "Naoya Sugatani and Masayoshi Dohi and Seungwon Lee and Taiki Tsuchiya and Kenji Matsuda",

note = "Publisher Copyright: {\textcopyright} 2023 The Japan Institute of Light Metals.",

year = "2023",

doi = "10.2464/jilm.73.9",

language = "日本",

volume = "73",

pages = "9--16",

journal = "Keikinzoku/Journal of Japan Institute of Light Metals",

issn = "0451-5994",

publisher = "Keikinzoku Gakkai/Japan Institute of Light Metals",

number = "1",

}

TY - JOUR

T1 - 断熱鋳型式連続鋳造法で作製した鍛造用 Al-Si 系合金の組織と高温強度に及ぼす銅濃度の影響

AU - Sugatani, Naoya

AU - Dohi, Masayoshi

AU - Lee, Seungwon

AU - Tsuchiya, Taiki

AU - Matsuda, Kenji

PY - 2023

Y1 - 2023

N2 - Al-Si alloy billets with 0, 2, 4, and 6 mass%Cu have been fabricated by the Heat-Insulating-Mold method. The microstructures and high-temperature mechanical properties at 423 K, 523 K, and 623 K have been investigated. Increasing Cu concentration changed the types of constituent particles and increased their area fraction. 0.2% proof stress (σ0.2) and ultimate tensile strength (σUTS) increased with increasing Cu concentration at each temperature. SEM observation showed that precipitates increased with increasing Cu concentration and remained in the matrix below 523 K but dissolved into the Al matrix at 623 K. The former suggested that the precipitates contributed to the strength below 523 K. On the other hand, significant work-hardening was confirmed until 0.2% strain at 623 K, which suggested that the constituent particles contributed to the strength just like particle-reinforced composites. The work-hardening rate and the amount of work-hardening increased with increasing Cu concentration and correlated with the interparticle spacing of the constituent particles. It indicated that decreasing interparticle spacing enhanced constraining matrix deformation, and it led to an increase of σ0.2

AB - Al-Si alloy billets with 0, 2, 4, and 6 mass%Cu have been fabricated by the Heat-Insulating-Mold method. The microstructures and high-temperature mechanical properties at 423 K, 523 K, and 623 K have been investigated. Increasing Cu concentration changed the types of constituent particles and increased their area fraction. 0.2% proof stress (σ0.2) and ultimate tensile strength (σUTS) increased with increasing Cu concentration at each temperature. SEM observation showed that precipitates increased with increasing Cu concentration and remained in the matrix below 523 K but dissolved into the Al matrix at 623 K. The former suggested that the precipitates contributed to the strength below 523 K. On the other hand, significant work-hardening was confirmed until 0.2% strain at 623 K, which suggested that the constituent particles contributed to the strength just like particle-reinforced composites. The work-hardening rate and the amount of work-hardening increased with increasing Cu concentration and correlated with the interparticle spacing of the constituent particles. It indicated that decreasing interparticle spacing enhanced constraining matrix deformation, and it led to an increase of σ0.2

KW - aluminum-silicon alloy

KW - copper concentration

KW - forging

KW - high-temperature mechanical property

KW - microstructure

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U2 - 10.2464/jilm.73.9

DO - 10.2464/jilm.73.9

M3 - 学術論文

AN - SCOPUS:85151008745

SN - 0451-5994

VL - 73

SP - 9

EP - 16

JO - Keikinzoku/Journal of Japan Institute of Light Metals

JF - Keikinzoku/Journal of Japan Institute of Light Metals

IS - 1

ER -

断熱鋳型式連続鋳造法で作製した鍛造用 Al-Si 系合金の組織と高温強度に及ぼす銅濃度の影響

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