Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand

Chung Jung Lee; Wen Yi Hung; Yi Chun Tu; Chen Hui Tsai; Chin Cheng Huang; Yuan Chieh Wu; Meng Hsiu Hsieh

Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand

Chung Jung Lee, Wen Yi Hung, Yi Chun Tu, Chen Hui Tsai, Chin Cheng Huang, Yuan Chieh Wu, Meng Hsiu Hsieh

Department of Civil Engineering

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

Abstract

Taiwan is located in the seismic zone and the sea bed in the western coastline of Taiwan is deposited with very loose sandy soil and may become liquefying during earthquakes. The current design code of wind turbine foundation does not give the detailed requirements of earthquake resistant design. A series of centrifuge shaking table tests of mono-pile foundations in liquefiable sandy soil was conducted at an acceleration of 80g. According to the test results the following findings were obtained. The maximum bending moment of pile in dry sand occurred at the depth of 4 m (z/L=0.21) and the maximum bending moment of pile in saturated liquefiable sand occurred at the depth of 6.4m (z/L=0.33). The induced bending moment and the pile displacement were higher if the attached mass was fixed at the higher elevation on the mono-pile foundations. The coefficient of horizontal subgrade reaction can be calculated by a p-y curve method. The values of the coefficient of horizontal subgrade reaction in shallow depths decrease while the excess pore water pressures increase during shaking. In the case of non-liquefiable soil, the values of coefficient of horizontal subgrade reaction increase with the increasing number of cycles of shaking.

Original language	English
Title of host publication	5th International Conference on Advances in Experimental Structural Engineering, AESE 2013
Publisher	EUCENTRE
ISBN (Electronic)	9780000000002
State	Published - 2013
Event	5th International Conference on Advances in Experimental Structural Engineering, AESE 2013 - Taipei, Taiwan Duration: 8 Nov 2013 → 9 Nov 2013

Publication series

Name	International Conference on Advances in Experimental Structural Engineering
Volume	2013-November
ISSN (Electronic)	2522-2503

Conference

Conference	5th International Conference on Advances in Experimental Structural Engineering, AESE 2013
Country/Territory	Taiwan
City	Taipei
Period	8/11/13 → 9/11/13

Keywords

Centrifuge shaking table test
Mono-pile foundation
Offshore wind turbine
Seismic responses

Cite this

Lee, C. J., Hung, W. Y., Tu, Y. C., Tsai, C. H., Huang, C. C., Wu, Y. C., & Hsieh, M. H. (2013). Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand. In 5th International Conference on Advances in Experimental Structural Engineering, AESE 2013 (International Conference on Advances in Experimental Structural Engineering; Vol. 2013-November). EUCENTRE.

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title = "Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand",

abstract = "Taiwan is located in the seismic zone and the sea bed in the western coastline of Taiwan is deposited with very loose sandy soil and may become liquefying during earthquakes. The current design code of wind turbine foundation does not give the detailed requirements of earthquake resistant design. A series of centrifuge shaking table tests of mono-pile foundations in liquefiable sandy soil was conducted at an acceleration of 80g. According to the test results the following findings were obtained. The maximum bending moment of pile in dry sand occurred at the depth of 4 m (z/L=0.21) and the maximum bending moment of pile in saturated liquefiable sand occurred at the depth of 6.4m (z/L=0.33). The induced bending moment and the pile displacement were higher if the attached mass was fixed at the higher elevation on the mono-pile foundations. The coefficient of horizontal subgrade reaction can be calculated by a p-y curve method. The values of the coefficient of horizontal subgrade reaction in shallow depths decrease while the excess pore water pressures increase during shaking. In the case of non-liquefiable soil, the values of coefficient of horizontal subgrade reaction increase with the increasing number of cycles of shaking.",

keywords = "Centrifuge shaking table test, Mono-pile foundation, Offshore wind turbine, Seismic responses",

author = "Lee, {Chung Jung} and Hung, {Wen Yi} and Tu, {Yi Chun} and Tsai, {Chen Hui} and Huang, {Chin Cheng} and Wu, {Yuan Chieh} and Hsieh, {Meng Hsiu}",

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Lee, CJ, Hung, WY, Tu, YC, Tsai, CH, Huang, CC, Wu, YC & Hsieh, MH 2013, Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand. in 5th International Conference on Advances in Experimental Structural Engineering, AESE 2013. International Conference on Advances in Experimental Structural Engineering, vol. 2013-November, EUCENTRE, 5th International Conference on Advances in Experimental Structural Engineering, AESE 2013, Taipei, Taiwan, 8/11/13.

Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand. / Lee, Chung Jung; Hung, Wen Yi; Tu, Yi Chun et al.
5th International Conference on Advances in Experimental Structural Engineering, AESE 2013. EUCENTRE, 2013. (International Conference on Advances in Experimental Structural Engineering; Vol. 2013-November).

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

TY - GEN

T1 - Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand

AU - Lee, Chung Jung

AU - Hung, Wen Yi

AU - Tu, Yi Chun

AU - Tsai, Chen Hui

AU - Huang, Chin Cheng

AU - Wu, Yuan Chieh

AU - Hsieh, Meng Hsiu

PY - 2013

Y1 - 2013

N2 - Taiwan is located in the seismic zone and the sea bed in the western coastline of Taiwan is deposited with very loose sandy soil and may become liquefying during earthquakes. The current design code of wind turbine foundation does not give the detailed requirements of earthquake resistant design. A series of centrifuge shaking table tests of mono-pile foundations in liquefiable sandy soil was conducted at an acceleration of 80g. According to the test results the following findings were obtained. The maximum bending moment of pile in dry sand occurred at the depth of 4 m (z/L=0.21) and the maximum bending moment of pile in saturated liquefiable sand occurred at the depth of 6.4m (z/L=0.33). The induced bending moment and the pile displacement were higher if the attached mass was fixed at the higher elevation on the mono-pile foundations. The coefficient of horizontal subgrade reaction can be calculated by a p-y curve method. The values of the coefficient of horizontal subgrade reaction in shallow depths decrease while the excess pore water pressures increase during shaking. In the case of non-liquefiable soil, the values of coefficient of horizontal subgrade reaction increase with the increasing number of cycles of shaking.

AB - Taiwan is located in the seismic zone and the sea bed in the western coastline of Taiwan is deposited with very loose sandy soil and may become liquefying during earthquakes. The current design code of wind turbine foundation does not give the detailed requirements of earthquake resistant design. A series of centrifuge shaking table tests of mono-pile foundations in liquefiable sandy soil was conducted at an acceleration of 80g. According to the test results the following findings were obtained. The maximum bending moment of pile in dry sand occurred at the depth of 4 m (z/L=0.21) and the maximum bending moment of pile in saturated liquefiable sand occurred at the depth of 6.4m (z/L=0.33). The induced bending moment and the pile displacement were higher if the attached mass was fixed at the higher elevation on the mono-pile foundations. The coefficient of horizontal subgrade reaction can be calculated by a p-y curve method. The values of the coefficient of horizontal subgrade reaction in shallow depths decrease while the excess pore water pressures increase during shaking. In the case of non-liquefiable soil, the values of coefficient of horizontal subgrade reaction increase with the increasing number of cycles of shaking.

KW - Centrifuge shaking table test

KW - Mono-pile foundation

KW - Offshore wind turbine

KW - Seismic responses

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M3 - 會議論文篇章

AN - SCOPUS:85057602955

T3 - International Conference on Advances in Experimental Structural Engineering

BT - 5th International Conference on Advances in Experimental Structural Engineering, AESE 2013

PB - EUCENTRE

T2 - 5th International Conference on Advances in Experimental Structural Engineering, AESE 2013

Y2 - 8 November 2013 through 9 November 2013

ER -

Centrifuge modeling on seismic response of mono-pile foundation in liquefiable sand

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