Warm redrawing of AA6082 sheets and investigations into the effect of aging heat treatment on cup wall strength

S. S. Panicker; K. S. Prasad; G. Sawale; S. Hazra; B. Shollock; S. K. Panda

doi:10.1016/j.msea.2019.138445

Warm redrawing of AA6082 sheets and investigations into the effect of aging heat treatment on cup wall strength

S. S. Panicker, K. S. Prasad, G. Sawale, S. Hazra, B. Shollock, S. K. Panda^*

^*Corresponding author for this work

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

10 Citations (Scopus)

Abstract

In this work, novel warm deep drawing and redrawing test setups were designed and developed, and a process sequence was proposed to enhance the forming depth of AA6082 sheet. The complete redrawing of the cup was ensured by maintaining the temperature of redrawing die and binder at 200 °C and water-circulated cooling punch near to room temperature. The warm redrawing negated the sudden thinning and strain localization at cup corner, producing an overall draw ratio of 3.38. Further, the fully redrawn cups were subjected to solution heat treatment (SHT) and subsequent different artificial aging cycle to evaluate the impact on post-forming strength. The post-forming cup wall strength was characterized using Vickers microhardness test and ring hoop tensile test (RHTT). Approximately 30% improvement in microhardness of redrawn cup wall was obtained as compared to that of the undeformed sheet, and it was due to the significant grain refinement occurred during the warm deep drawing and subsequent redrawing process as characterized by SEM and EBSD techniques. Moreover, it was observed that the heat treatment had a pronounced effect on both the hardness and ultimate hoop tensile strength of the cup wall, and the peak aged cup wall hardness and tensile strength were 119 VHN and 316.8 MPa, respectively. As verified by TEM micrographs, the precipitation of coherent large needle-shaped β′′ precipitate was responsible for the significant improvement in the strength during the aging treatment. However, the presence of plate-shaped incoherent β-Mg₂Si precipitate marginally decreased the total elongation at peak aged condition. Finally, the fractographs of redrawn and different artificially aged RHTT samples were analyzed to comprehend the nature of failure.

Original language	English
Article number	138445
Journal	Materials Science and Engineering A
Volume	768
DOIs	https://doi.org/10.1016/j.msea.2019.138445
Publication status	Published - 19 Dec 2019

Keywords

Heat treatment
Microhardness
Microtexture
Ring hoop tensile test
TEM analyses
Warm redrawing

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10.1016/j.msea.2019.138445

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title = "Warm redrawing of AA6082 sheets and investigations into the effect of aging heat treatment on cup wall strength",

abstract = "In this work, novel warm deep drawing and redrawing test setups were designed and developed, and a process sequence was proposed to enhance the forming depth of AA6082 sheet. The complete redrawing of the cup was ensured by maintaining the temperature of redrawing die and binder at 200 °C and water-circulated cooling punch near to room temperature. The warm redrawing negated the sudden thinning and strain localization at cup corner, producing an overall draw ratio of 3.38. Further, the fully redrawn cups were subjected to solution heat treatment (SHT) and subsequent different artificial aging cycle to evaluate the impact on post-forming strength. The post-forming cup wall strength was characterized using Vickers microhardness test and ring hoop tensile test (RHTT). Approximately 30% improvement in microhardness of redrawn cup wall was obtained as compared to that of the undeformed sheet, and it was due to the significant grain refinement occurred during the warm deep drawing and subsequent redrawing process as characterized by SEM and EBSD techniques. Moreover, it was observed that the heat treatment had a pronounced effect on both the hardness and ultimate hoop tensile strength of the cup wall, and the peak aged cup wall hardness and tensile strength were 119 VHN and 316.8 MPa, respectively. As verified by TEM micrographs, the precipitation of coherent large needle-shaped β′′ precipitate was responsible for the significant improvement in the strength during the aging treatment. However, the presence of plate-shaped incoherent β-Mg2Si precipitate marginally decreased the total elongation at peak aged condition. Finally, the fractographs of redrawn and different artificially aged RHTT samples were analyzed to comprehend the nature of failure.",

keywords = "Heat treatment, Microhardness, Microtexture, Ring hoop tensile test, TEM analyses, Warm redrawing",

author = "Panicker, {S. S.} and Prasad, {K. S.} and G. Sawale and S. Hazra and B. Shollock and Panda, {S. K.}",

year = "2019",

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T1 - Warm redrawing of AA6082 sheets and investigations into the effect of aging heat treatment on cup wall strength

AU - Panicker, S. S.

AU - Prasad, K. S.

AU - Sawale, G.

AU - Hazra, S.

AU - Shollock, B.

AU - Panda, S. K.

PY - 2019/12/19

Y1 - 2019/12/19

N2 - In this work, novel warm deep drawing and redrawing test setups were designed and developed, and a process sequence was proposed to enhance the forming depth of AA6082 sheet. The complete redrawing of the cup was ensured by maintaining the temperature of redrawing die and binder at 200 °C and water-circulated cooling punch near to room temperature. The warm redrawing negated the sudden thinning and strain localization at cup corner, producing an overall draw ratio of 3.38. Further, the fully redrawn cups were subjected to solution heat treatment (SHT) and subsequent different artificial aging cycle to evaluate the impact on post-forming strength. The post-forming cup wall strength was characterized using Vickers microhardness test and ring hoop tensile test (RHTT). Approximately 30% improvement in microhardness of redrawn cup wall was obtained as compared to that of the undeformed sheet, and it was due to the significant grain refinement occurred during the warm deep drawing and subsequent redrawing process as characterized by SEM and EBSD techniques. Moreover, it was observed that the heat treatment had a pronounced effect on both the hardness and ultimate hoop tensile strength of the cup wall, and the peak aged cup wall hardness and tensile strength were 119 VHN and 316.8 MPa, respectively. As verified by TEM micrographs, the precipitation of coherent large needle-shaped β′′ precipitate was responsible for the significant improvement in the strength during the aging treatment. However, the presence of plate-shaped incoherent β-Mg2Si precipitate marginally decreased the total elongation at peak aged condition. Finally, the fractographs of redrawn and different artificially aged RHTT samples were analyzed to comprehend the nature of failure.

AB - In this work, novel warm deep drawing and redrawing test setups were designed and developed, and a process sequence was proposed to enhance the forming depth of AA6082 sheet. The complete redrawing of the cup was ensured by maintaining the temperature of redrawing die and binder at 200 °C and water-circulated cooling punch near to room temperature. The warm redrawing negated the sudden thinning and strain localization at cup corner, producing an overall draw ratio of 3.38. Further, the fully redrawn cups were subjected to solution heat treatment (SHT) and subsequent different artificial aging cycle to evaluate the impact on post-forming strength. The post-forming cup wall strength was characterized using Vickers microhardness test and ring hoop tensile test (RHTT). Approximately 30% improvement in microhardness of redrawn cup wall was obtained as compared to that of the undeformed sheet, and it was due to the significant grain refinement occurred during the warm deep drawing and subsequent redrawing process as characterized by SEM and EBSD techniques. Moreover, it was observed that the heat treatment had a pronounced effect on both the hardness and ultimate hoop tensile strength of the cup wall, and the peak aged cup wall hardness and tensile strength were 119 VHN and 316.8 MPa, respectively. As verified by TEM micrographs, the precipitation of coherent large needle-shaped β′′ precipitate was responsible for the significant improvement in the strength during the aging treatment. However, the presence of plate-shaped incoherent β-Mg2Si precipitate marginally decreased the total elongation at peak aged condition. Finally, the fractographs of redrawn and different artificially aged RHTT samples were analyzed to comprehend the nature of failure.

KW - Heat treatment

KW - Microhardness

KW - Microtexture

KW - Ring hoop tensile test

KW - TEM analyses

KW - Warm redrawing

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DO - 10.1016/j.msea.2019.138445

M3 - Article

AN - SCOPUS:85072731982

SN - 0921-5093

VL - 768

JO - Materials Science and Engineering A

JF - Materials Science and Engineering A

M1 - 138445

ER -

Warm redrawing of AA6082 sheets and investigations into the effect of aging heat treatment on cup wall strength

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Keywords

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