GE-34 design of retaining walls accounting for paramatric uncertainties

Eurocode 7 had been introduced to supersede British Standards and used in geotechnical designs of civil engineering works in Singapore’s construction industry since 2015. It employs limit state design by applying partial factors to characteristic parameter values to achieve the appropriate degree of...

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Main Author: Xue, Haoyue
Other Authors: Low Bak Kong
Format: Final Year Project
Language:English
Published: 2016
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Online Access:http://hdl.handle.net/10356/68079
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-680792023-03-03T17:02:59Z GE-34 design of retaining walls accounting for paramatric uncertainties Xue, Haoyue Low Bak Kong School of Civil and Environmental Engineering DRNTU::Engineering Eurocode 7 had been introduced to supersede British Standards and used in geotechnical designs of civil engineering works in Singapore’s construction industry since 2015. It employs limit state design by applying partial factors to characteristic parameter values to achieve the appropriate degree of reliability. However, uncertainties are unavoidable in geotechnical engineering and they arise from various aspects including geotechnical properties, loadings, design methodologies and so on. Hence, a complementary reliability-based design approach to Eurocode 7 is introduced and analyzed in this research project. Reliability-based design is based on computing reliability index (β) to reveal reliability level and probability of failure for designs. It explicitly reflects the combined effects of parameters’ uncertainties and correlation structures. Among various methods to compute reliability index, a practical and conceptually simple spreadsheet based first-order reliability based method (FORM) (Low and Tang, 2007) is used by the author for analyses at Microsoft Excel platform. Additionally, a computer simulation program @RISK to run Monte Carlo Simulation is demonstrated. It provides a simple and convenient way to practitioners to access the reliability analyses and provides additional check to reliability-based design as a safety measure. This research project illustrates retaining wall cases on embedded wall and anchored sheet pile wall with Eurocode 7 design approach, reliability-based design approach and Monte Carlo Simulation. Calibration of EC7 partial factors are studied and compared with the ratios of mean values to design point values from reliability based design. Sensitivity of design parameters to different case configurations is addressed. Additionally, probabilistic methods to determine characteristic values are studied and discussed. Results from different approaches are generally in line and it is demonstrated that design approaches of Eurocode 7 are aiming at sufficiently safe design. While EC7 is conceptually easy for practitioners to apply, reliability design approach and Monte Carlo Simulation can be adopted to provide additional checks and insights to uncertainties of parameters and ensure sufficient reliability is obtained. Bachelor of Engineering (Civil) 2016-05-24T04:39:59Z 2016-05-24T04:39:59Z 2016 Final Year Project (FYP) http://hdl.handle.net/10356/68079 en Nanyang Technological University 56 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering
spellingShingle DRNTU::Engineering
Xue, Haoyue
GE-34 design of retaining walls accounting for paramatric uncertainties
description Eurocode 7 had been introduced to supersede British Standards and used in geotechnical designs of civil engineering works in Singapore’s construction industry since 2015. It employs limit state design by applying partial factors to characteristic parameter values to achieve the appropriate degree of reliability. However, uncertainties are unavoidable in geotechnical engineering and they arise from various aspects including geotechnical properties, loadings, design methodologies and so on. Hence, a complementary reliability-based design approach to Eurocode 7 is introduced and analyzed in this research project. Reliability-based design is based on computing reliability index (β) to reveal reliability level and probability of failure for designs. It explicitly reflects the combined effects of parameters’ uncertainties and correlation structures. Among various methods to compute reliability index, a practical and conceptually simple spreadsheet based first-order reliability based method (FORM) (Low and Tang, 2007) is used by the author for analyses at Microsoft Excel platform. Additionally, a computer simulation program @RISK to run Monte Carlo Simulation is demonstrated. It provides a simple and convenient way to practitioners to access the reliability analyses and provides additional check to reliability-based design as a safety measure. This research project illustrates retaining wall cases on embedded wall and anchored sheet pile wall with Eurocode 7 design approach, reliability-based design approach and Monte Carlo Simulation. Calibration of EC7 partial factors are studied and compared with the ratios of mean values to design point values from reliability based design. Sensitivity of design parameters to different case configurations is addressed. Additionally, probabilistic methods to determine characteristic values are studied and discussed. Results from different approaches are generally in line and it is demonstrated that design approaches of Eurocode 7 are aiming at sufficiently safe design. While EC7 is conceptually easy for practitioners to apply, reliability design approach and Monte Carlo Simulation can be adopted to provide additional checks and insights to uncertainties of parameters and ensure sufficient reliability is obtained.
author2 Low Bak Kong
author_facet Low Bak Kong
Xue, Haoyue
format Final Year Project
author Xue, Haoyue
author_sort Xue, Haoyue
title GE-34 design of retaining walls accounting for paramatric uncertainties
title_short GE-34 design of retaining walls accounting for paramatric uncertainties
title_full GE-34 design of retaining walls accounting for paramatric uncertainties
title_fullStr GE-34 design of retaining walls accounting for paramatric uncertainties
title_full_unstemmed GE-34 design of retaining walls accounting for paramatric uncertainties
title_sort ge-34 design of retaining walls accounting for paramatric uncertainties
publishDate 2016
url http://hdl.handle.net/10356/68079
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