Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates

Kshitiz Risal; Kunal Mondal; Jared Cantrell; Tadesse G. Wakjira; Mustafa Mashal

doi:10.2749/ghent.2025.1991

Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates

Kshitiz Risal
, Kunal Mondal
, Jared Cantrell
, Tadesse G. Wakjira
, Mustafa Mashal

Nuclear Materials Packaging, Transportat

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

U-shape flexural plates (UFPs) have gained significant attention in seismic structural design due to their ability to provide stable hysteresis behaviour and serve as effective energy-dissipating devices. Concurrently, Additive Manufacturing (AM) has advanced significantly, enabling the production of metallic components with mechanical properties comparable to those of conventionally manufactured cold-rolled materials. This study aims to explore the seismic response of single and double UFP fabricated through Laser Powder Based Fusion (LPBF) and conventional cold rolled 316L stainless steel (SS). The experimental results are evaluated based on force-displacement hysteresis behaviour, energy dissipation capacity, load-carrying capacity, and stiffness degradation. The findings confirm the efficacy of AM-fabricated UFPs for seismic energy dissipation. Additionally, the results suggest the potential for further improvement through the optimization of AM process parameters, such as laser scan speed, hatch spacing, and layer thickness, to enhance hysteretic performance and energy dissipation characteristics.

Original language	English
Title of host publication	IABSE Congress Ghent 2025
Subtitle of host publication	The Essence of Structural Engineering for Society, Proceedings
Editors	Davide Leonetti, Bert Snijder, Bart De Pauw, Bart De Pauw, Sander van Alphen
Publisher	International Association for Bridge and Structural Engineering (IABSE)
Pages	1991-1996
Number of pages	6
ISBN (Electronic)	9783857482106
DOIs	https://doi.org/10.2749/ghent.2025.1991
State	Published - 2025
Event	2025 International Association for Bridge and Structural Engineering, IABSE 2025 - Ghent, Belgium Duration: Aug 27 2025 → Aug 29 2025

Publication series

Name	IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings

Conference

Conference	2025 International Association for Bridge and Structural Engineering, IABSE 2025
Country/Territory	Belgium
City	Ghent
Period	08/27/25 → 08/29/25

Funding

The authors would like to acknowledge the funding that was provided by Idaho State University for the research. They would also like to thank Mr. Suraj Prasad Dahal, Mr. Arpan Adhikari, and Mr. Joe Shurtleff for the assistance they provided with the lab work. Dr. Kunal Mondal wants to thank Oak Ridge National Laboratory for support.

Keywords

316L Stainless Steel
Additive Manufacturing (AM)
Energy Dissipation
U-shaped Flexural Plates (UFPs)

Access to Document

10.2749/ghent.2025.1991

Cite this

Risal, K., Mondal, K., Cantrell, J., Wakjira, T. G., & Mashal, M. (2025). Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates. In D. Leonetti, B. Snijder, B. De Pauw, B. De Pauw, & S. van Alphen (Eds.), IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings (pp. 1991-1996). (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings). International Association for Bridge and Structural Engineering (IABSE). https://doi.org/10.2749/ghent.2025.1991

Risal, Kshitiz ; Mondal, Kunal ; Cantrell, Jared et al. / Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates. IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. editor / Davide Leonetti ; Bert Snijder ; Bart De Pauw ; Bart De Pauw ; Sander van Alphen. International Association for Bridge and Structural Engineering (IABSE), 2025. pp. 1991-1996 (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings).

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abstract = "U-shape flexural plates (UFPs) have gained significant attention in seismic structural design due to their ability to provide stable hysteresis behaviour and serve as effective energy-dissipating devices. Concurrently, Additive Manufacturing (AM) has advanced significantly, enabling the production of metallic components with mechanical properties comparable to those of conventionally manufactured cold-rolled materials. This study aims to explore the seismic response of single and double UFP fabricated through Laser Powder Based Fusion (LPBF) and conventional cold rolled 316L stainless steel (SS). The experimental results are evaluated based on force-displacement hysteresis behaviour, energy dissipation capacity, load-carrying capacity, and stiffness degradation. The findings confirm the efficacy of AM-fabricated UFPs for seismic energy dissipation. Additionally, the results suggest the potential for further improvement through the optimization of AM process parameters, such as laser scan speed, hatch spacing, and layer thickness, to enhance hysteretic performance and energy dissipation characteristics.",

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Risal, K, Mondal, K, Cantrell, J, Wakjira, TG & Mashal, M 2025, Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates. in D Leonetti, B Snijder, B De Pauw, B De Pauw & S van Alphen (eds), IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings, International Association for Bridge and Structural Engineering (IABSE), pp. 1991-1996, 2025 International Association for Bridge and Structural Engineering, IABSE 2025, Ghent, Belgium, 08/27/25. https://doi.org/10.2749/ghent.2025.1991

Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates. / Risal, Kshitiz; Mondal, Kunal; Cantrell, Jared et al.
IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. ed. / Davide Leonetti; Bert Snijder; Bart De Pauw; Bart De Pauw; Sander van Alphen. International Association for Bridge and Structural Engineering (IABSE), 2025. p. 1991-1996 (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates

AU - Risal, Kshitiz

AU - Mondal, Kunal

AU - Cantrell, Jared

AU - Wakjira, Tadesse G.

AU - Mashal, Mustafa

PY - 2025

Y1 - 2025

N2 - U-shape flexural plates (UFPs) have gained significant attention in seismic structural design due to their ability to provide stable hysteresis behaviour and serve as effective energy-dissipating devices. Concurrently, Additive Manufacturing (AM) has advanced significantly, enabling the production of metallic components with mechanical properties comparable to those of conventionally manufactured cold-rolled materials. This study aims to explore the seismic response of single and double UFP fabricated through Laser Powder Based Fusion (LPBF) and conventional cold rolled 316L stainless steel (SS). The experimental results are evaluated based on force-displacement hysteresis behaviour, energy dissipation capacity, load-carrying capacity, and stiffness degradation. The findings confirm the efficacy of AM-fabricated UFPs for seismic energy dissipation. Additionally, the results suggest the potential for further improvement through the optimization of AM process parameters, such as laser scan speed, hatch spacing, and layer thickness, to enhance hysteretic performance and energy dissipation characteristics.

AB - U-shape flexural plates (UFPs) have gained significant attention in seismic structural design due to their ability to provide stable hysteresis behaviour and serve as effective energy-dissipating devices. Concurrently, Additive Manufacturing (AM) has advanced significantly, enabling the production of metallic components with mechanical properties comparable to those of conventionally manufactured cold-rolled materials. This study aims to explore the seismic response of single and double UFP fabricated through Laser Powder Based Fusion (LPBF) and conventional cold rolled 316L stainless steel (SS). The experimental results are evaluated based on force-displacement hysteresis behaviour, energy dissipation capacity, load-carrying capacity, and stiffness degradation. The findings confirm the efficacy of AM-fabricated UFPs for seismic energy dissipation. Additionally, the results suggest the potential for further improvement through the optimization of AM process parameters, such as laser scan speed, hatch spacing, and layer thickness, to enhance hysteretic performance and energy dissipation characteristics.

KW - 316L Stainless Steel

KW - Additive Manufacturing (AM)

KW - Energy Dissipation

KW - U-shaped Flexural Plates (UFPs)

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DO - 10.2749/ghent.2025.1991

M3 - Conference contribution

AN - SCOPUS:105021081150

T3 - IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings

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BT - IABSE Congress Ghent 2025

A2 - Leonetti, Davide

A2 - Snijder, Bert

A2 - De Pauw, Bart

A2 - van Alphen, Sander

PB - International Association for Bridge and Structural Engineering (IABSE)

T2 - 2025 International Association for Bridge and Structural Engineering, IABSE 2025

Y2 - 27 August 2025 through 29 August 2025

ER -

Risal K, Mondal K, Cantrell J, Wakjira TG, Mashal M. Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates. In Leonetti D, Snijder B, De Pauw B, De Pauw B, van Alphen S, editors, IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings. International Association for Bridge and Structural Engineering (IABSE). 2025. p. 1991-1996. (IABSE Congress Ghent 2025: The Essence of Structural Engineering for Society, Proceedings). doi: 10.2749/ghent.2025.1991

Seismic Performance of Conventional and Additively Manufactured U-Shaped Flexural Plates

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