Experimental Investigations into Earthquake Resistance of Steel Frame Retrofitted by Low-Yield-Point Steel Energy Absorbers

Shao, Jianhua; Wang, Kai; Kaewunruen, Sakdirat; Cai, Wenwen; Wang, Zhanguang

doi:10.3390/app9163299

Cited by 11 publications

(6 citation statements)

References 40 publications

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“…Shao et al [17] presented the world's first steel frame retrofitted by novel metallic bending energy absorbers that were made of low-yield-point steel with the yield strength of approximately 100 MPa. New results were achieved by conducting comprehensive shaking-table tests on a quarter-scaled model of a two-story, one-span building structure that was subjected to incremental intensity levels of input earthquake records.…”

Section: Retrofitting To Mitigate Extreme Risksmentioning

confidence: 99%

Special Issue “Extreme Sciences and Engineering”

Kaewunruen

Remennikov

2021

Applied Sciences

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Section: Retrofitting To Mitigate Extreme Risksmentioning

confidence: 99%

Special Issue “Extreme Sciences and Engineering”

Kaewunruen

Remennikov

2021

Applied Sciences

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“…The passive metallic dampers that are attached indirectly to the CBF braces, between the chevron brace and floor beam, are widely used in practical projects, especially for rehabilitation uses. Figure 1 illustrates the common flexural mechanism dampers including single‐axis, 1 tapered cantilever, 2 ADAS, 3 TADAS, 4 parabolic, 5 slit, 6 X‐shaped, 7 double X‐shaped, 8 comb‐teeth, 9 and shear‐flexural dampers 7 . For these types of dampers, one or more connected dampers may be used together to resist large imposed forces.…”

Section: Introductionmentioning

confidence: 99%

Investigating the behavior of an innovative butterfly‐shaped damper: An experimental and numerical study

Van,

Ghamari

2023

Structural Design Tall Build

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SummaryThe concentrically braced frame (CBF) suffered from low dissipating energy capacity although it pertains to a high lateral elastic stiffness and ultimate strength. To overcome the shortcoming, in this paper, an innovative damper made of two butterfly‐shaped plates installed at the end of the diagonal member of the CBF was considered experimentally and numerically. Also, the required equations were presented to design the system. In an experimental study, the damper showed stable hysteresis loops without any degradation in stiffness and strength up to a rotation of 12% (0.12 rad). This rotation capacity is 50% greater than the AISC limitation. Also, the numerical study indicated that by increasing the angle of main plates, the structural parameters are improved as ultimate strength (Fu), 47% to 90%; stiffness (K), 64% to 97%; energy absorption (E), 23% to 11%; and overstrength (Ω), 59% to 96%. By reduction of the damper's height, the parameters Fu, K, E, and Ω are increased by 47% to 76%, 23% to 64%, 49% to 93%, and 23% to 27%, respectively. Moreover, although the geometry of the damper affected the elastic stiffness, the stiffness in the nonlinear zone was independent of the geometry of the damper. Correspondingly, the slenderness limitations were suggested as 15 for height to thickness ratio and 22 for wide to thickness ratio.

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“…Various seismic structures and energy dissipation materials, such as foamed aluminum [11,12] and low-yield-point steel [13], which replaced the traditional reinforced concrete construction [14][15][16][17], have been discovered and utilized as scholars continued their research on seismic performance. Low-yield-point (LYP) steel, as a new material with better inelastic deformation capacity, superior elongation, and low yield-strength ratio, has been increasingly utilized and developed in energy dissipation and vibration damping structures such as steel plate shear walls and dampers [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation into Failure Modes of Low-Yield-Point Steel Plate Shear Walls

Liu

Shao

Tang³

et al. 2022

Applied Sciences

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Two specimens of low-yield-point steel plate shear walls used for the experimental investigation into different failure modes of the structure were respectively carried out by the horizontal and vertical loading tests in this paper. The results derived from the horizontal loading test for specimen 1 demonstrated that both the infill panel and the frame column were seriously damaged as the loading level increased with continuous and steady strain growth, in which maximum out-of-plane displacement and strain of the infill panel reached 31.8 mm and 11,735 με respectively, whereas the strain of the frame column reached 13,117 με. Moreover, the structural bearing capacity decreased extremely slowly and the specimen still had a high strength when the controlled displacement of the specimen exceeded 3.28 times the yield displacement, which indicated that the ductility of the structure was excellent. The results of a vertical loading experiment for specimen 2 indicated that the maximum deformation of both the infill panel and frame column occurred in the middle-upper part of the members, with a maximum out-of-plane displacement of 95 mm and 70 mm, respectively. The dramatic out-of-plane bulging phenomenon along the width of the infill plate under the vertical load and the seriously torsional deformation of the frame column were observed.

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Experimental Investigations into Earthquake Resistance of Steel Frame Retrofitted by Low-Yield-Point Steel Energy Absorbers

Cited by 11 publications

References 40 publications

Special Issue “Extreme Sciences and Engineering”

Special Issue “Extreme Sciences and Engineering”

Investigating the behavior of an innovative butterfly‐shaped damper: An experimental and numerical study

Experimental Investigation into Failure Modes of Low-Yield-Point Steel Plate Shear Walls

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