Spelling suggestions: "subject:"1ateral spreading"" "subject:"1ateral preading""
1 |
Dynamic Pile-Soil Interaction in Laterally Spreading SlopesKaewsong, Raejee 27 January 2009 (has links)
The collapse of buildings and infrastructure is an unfortunate consequence of major earthquakes (e.g., the 1964 Alaskan earthquake, the 1995 Kobe earthquake in Japan and the 2007 Pisco earthquake in Peru). Liquefaction-induced lateral spreading is known to be one cause of severe damage to deep foundation systems. However, the dynamic soil-structure interaction between liquefied soil and piles is extremely complex and further work is required to define the appropriate design pressures and to understand the mechanisms at work.
This thesis presents the findings of an experimental program carried out using the large geotechnical centrifuge at C-CORE in St John’s Newfoundland, to investigate the mechanism of lateral spreading and its implications for dynamic soil-pile interaction. Soil and pile responses were measured using accelerometers, pore pressure transducers, and digital imaging using a high speed camera. Using these images, transient profiles of slope deformation were quantitatively measured using Particle Image Velocimetry (PIV). These tests illustrate the potential for earthquake shaking to excite the natural frequency of the liquefied soil column, which can lead to increased transient lateral pressures on piles in liquefiable ground. This study recommends that this potential for “auto tuning” should be anticipated in design and proposes a new limiting pseudo-static backbone p-y curve for use in the design of piles subjected to lateral spreading ground deformation. / Thesis (Master, Civil Engineering) -- Queen's University, 2009-01-27 10:09:43.902
|
2 |
Analysis of a Lateral Spreading Case History from the 2007 Pisco, Peru EarthquakeGangrade, Rajat Mukesh 21 June 2013 (has links)
On August 15, 2007, Pisco, Peru was hit by an earthquake of Magnitude (Mw) = 8.0 which triggered multiple liquefaction induced lateral spreads. The subduction earthquake lasted for approximately 100 seconds and showed a complex rupture. From the geotechnical perspective, the Pisco earthquake was significant for the amount of soil liquefaction observed. A massive liquefaction induced seaward displacement of a marine terrace was observed in the Canchamana complex. Later analysis using the pre- and post-earthquake images showed that the lateral displacements were concentrated only on some regions. Despite the lateral homogeneity of the marine terrace, some cross-sections showed large displacements while others had minimal displacements. The detailed documentation of this case-history makes it an ideal case-study for the determination of the undrained strength of the liquefied soils; hence, the main objective of this research is to use the extensive data from the Canchamana Slide to estimate the shear strength of the liquefied soils. In engineering practice, the undrained strength of liquefied soil is typically estimated by correlating SPT-N values to: 1) absolute value of residual strength, or 2) residual strength ratio. Our research aims to contribute an important data point that will add to the current understanding of the residual strength of liquefied soils. / Master of Science
|
3 |
EPOLLS: An Empirical Method for Prediciting Surface Displacements Due to Liquefaction-Induced Lateral Spreading in EarthquakesRauch, Alan F. 05 May 1997 (has links)
In historical, large-magnitude earthquakes, lateral spreading has been a very damaging type of ground failure. When a subsurface soil deposit liquefies, intact blocks of surficial soil can move downslope, or toward a vertical free face, even when the ground surface is nearly level. A lateral spread is defined as the mostly horizontal movement of gently sloping ground (less than 5% surface slope) due to elevated pore pressures or liquefaction in undelying, saturated soils. Here, lateral spreading is defined specifically to exclude liquefaction failures of steeper embankments and retaining walls, which can also produce lateral surface deformations. Lateral spreads commonly occur at waterfront sites underlain by saturated, recent sediments and are particularly threatening to buried utilities and transportation networks. While the occurrence of soil liquefaction and lateral spreading can be predicted at a given site, methods are needed to estimate the magnitude of the resulting deformations.
In this research effort, an empirical model was developed for predicting horizontal and vertical surface displacements due to liquefaction-induced lateral spreading. The resulting model is called "EPOLLS" for Empirical Prediction Of Liquefaction-induced Lateral Spreading. Multiple linear regression analyses were used to develop model equations from a compiled database of historical lateral spreads. The complete EPOLLS model is comprised of four components: (1) Regional-EPOLLS for predicting horizontal displacements based on the seismic source and local severity of shaking, (2) Site-EPOLLS for improved predictions with the addition of data on the site topography, (3) Geotechnical-EPOLLS using additional data from soil borings at the site, and (4) Vertical-EPOLLS for predicting vertical displacements. The EPOLLS model is useful in phased liquefaction risk studies: starting with regional risk assessments and minimal site information, more precise predictions of displacements can be made with the addition of detailed site-specific data. In each component of the EPOLLS model, equations are given for predicting the average and standard deviation of displacements. Maximum displacements can be estimated using probabilities and the gamma distribution for horizontal displacements or the normal distribution for vertical displacements. / Ph. D.
|
4 |
Impacts of liquefaction and lateral spreading on bridge pile foundations from the February 22nd 2011 Christchurch earthquakeWinkley, Anna Margaret Mathieson January 2013 (has links)
The Mw 6.2 February 22nd 2011 Christchurch earthquake (and others in the 2010-2011 Canterbury sequence) provided a unique opportunity to study the devastating effects of earthquakes first-hand and learn from them for future engineering applications. All major events in the Canterbury earthquake sequence caused widespread liquefaction throughout Christchurch’s eastern suburbs, particularly extensive and severe during the February 22nd event. Along large stretches of the Avon River banks (and to a lesser extent along the Heathcote) significant lateral spreading occurred, affecting bridges and the infrastructure they support.
The first stage of this research involved conducting detailed field reconnaissance to document liquefaction and lateral spreading-induced damage to several case study bridges along the Avon River. The case study bridges cover a range of ages and construction types but all are reinforced concrete structures which have relatively short, stiff decks. These factors combined led to a characteristic deformation mechanism involving deck-pinning and abutment back-rotation with consequent damage to the abutment piles and slumping of the approaches.
The second stage of the research involved using pseudo-static analysis, a simplified seismic modelling tool, to analyse two of the bridges. An advantage of pseudo-static analysis over more complicated modelling methods is that it uses conventional geotechnical data in its inputs, such as SPT blowcount and CPT cone resistance and local friction. Pseudo-static analysis can also be applied without excessive computational power or specialised knowledge, yet it has been shown to capture the basic mechanisms of pile behaviour. Single pile and whole bridge models were constructed for each bridge, and both cyclic and lateral spreading phases of loading were investigated. Parametric studies were carried out which varied the values of key parameters to identify their influence on pile response, and computed displacements and damages were compared with observations made in the field. It was shown that pseudo-static analysis was able to capture the characteristic damage mechanisms observed in the field, however the treatment of key parameters affecting pile response is of primary importance. Recommendations were made concerning the treatment of these governing parameters controlling pile response. In this way the future application of pseudo-static analysis as a tool for analysing and designing bridge pile foundations in liquefying and laterally spreading soils is enhanced.
|
5 |
The performance of lateral spread sites treated with prefabricated vertical drains : physical and numerical modelsHowell, Rachelle Lee 25 October 2013 (has links)
Drainage methods for liquefaction remediation have been in use since the 1970's and have traditionally included stone columns, gravel drains, and more recently prefabricated vertical drains. The traditional drainage techniques such as stone columns and gravel drains rely upon a combination of drainage and densification to mitigate liquefaction and thus, the improvement observed as a result of these techniques cannot be ascribed solely to drainage. Therefore, uncertainty exists as to the effectiveness of pure drainage, and there is some hesitancy among engineers to use newer drainage methods such as prefabricated vertical drains, which rely primarily on drainage rather than the combination of drainage and densification. Additionally, the design methods for prefabricated vertical drains are based on the design methods developed for stone columns and gravel drains even though the primary mechanisms for remediation are not the same. The objectives of this research are to use physical and numerical models to assess the effectiveness of drainage as a liquefaction remediation technique and to identify the controlling behavioral mechanisms that most influence the performance of sites treated with prefabricated vertical drains. In the first part of this research, a suite of three large-scale dynamic centrifuge tests of untreated and drain-treated sloping soil profiles was performed. Acceleration, pore pressure, and deformation data was used to evaluate the effectiveness of drainage in reducing liquefaction-induced lateral deformations. The results showed that the drains reduced the generated peak excess pore pressures and expedited the dissipated of pore water pressures both during and after shaking. The influence of the drains on the excess pore pressure response was found to be sensitive to the characteristics of the input motion. The drainage resulted in a 30 to 60% reduction in the horizontal deformations and a 20 to 60% reduction in the vertical settlements. In the second part of this research, the data and insights gained from the centrifuge tests was used to develop numerical models that can be used to investigate the factors that most influence the performance of untreated and drain-treated lateral spread sites. Finite element modeling was performed using the OpenSees platform. Three types of numerical models were developed - 2D infinite slope unit cell models of the area of influence around a single drain, 3D infinite slope unit cell models of the area of influence around a single drain, and a full 2D plane strain model of the centrifuge tests that included both the untreated and drain-treated slopes as well as the centrifuge container. There was a fairly good match between the experimental and simulated excess pore pressures. The unit cell models predicted larger horizontal deformations than were observed in the centrifuge tests because of the infinite slope geometry. Issues were identified with the constitutive model used to represent the liquefiable sand. These issues included a coefficient of volumetric compressibility that was too low and a sensitivity to low level accelerations when the stress path is near the failure surface. In the final part of this research, the simulated and experimental data was used to examine the relationship between the generated excess pore water pressures and the resulting horizontal deformations. It was found that the deformations are directly influenced by both the excess pore pressures and the intensity of shaking. There is an excess pore pressure threshold above which deformations begin to become significant. The horizontal deformations correlate well to the integral of the average excess pore pressure ratio-time history above this threshold. They also correlate well to the Arias intensity and cumulative absolute velocity intensity measures. / text
|
6 |
Πλευρική εξάπλωση στην παραλιακή ζώνη του Ληξουρίου και Αργοστολίου κατά τους σεισμούς της Κεφαλονιάς στις 26-1- & 03-2-2014Κεχαγιάς, Γιώργος 26 April 2015 (has links)
H πλευρική εξάπλωση είναι ένα εντυπωσιακό-καταστροφικό φαινόμενο,
επακόλουθο της ρευστοποίησης, που οδηγεί στην εδαφική αστοχία. Στην περίπτωση
κεκλιμένων εδαφών ή εδαφών που καταλήγουν σε ελεύθερο μέτωπο, προκαλείται
έντονη ρηγμάτωση της επιφάνειας του εδάφους και Πλευρική Εξάπλωση, Lateral
Spreading, (δηλαδή οριζόντια μετακίνηση) του εδαφικού υλικού (παραμορφώσεις
πολύπλοκης μορφής), στην περιοχή της όχθης υδάτινων ρευμάτων ή άλλων
θαλασσίων μετώπων και η εξάπλωση αυτών σε μεγάλη απόσταση προς τα ανάντι.
Αντικείμενο της παρούσας Διατριβής αποτελεί η μελέτη της εκτεταμένης
πλευρικής εξάπλωσης που πραγματοποιήθηκε υπό συνθήκες ελευθέρου μετώπου
προς την κατεύθυνση της ακτογραμμής στο Δυτικό Κρηπίδωμα του Λιμένα
Ληξουρίου και στην παραλιακή ζώνη του Αργοστολίου κατά τους σεισμούς της
Κεφαλονιάς στις 26-1-2014 (Mw=6.1) και στις 03-2-2014 (Mw=6.0).
Η Διατριβή περιλαμβάνει παρουσίαση των διαθέσιμων γεωτεχνικών
δεδομένων για το λιμένα Ληξουρίου και εκτιμήσεις του μεγέθους της πλευρικής
εξάπλωσης με βάση τα σύγχρονα εμπειρικά μοντέλα του Youd et al. (2002) και την
τροποποίηση αυτού, Youd et al. (2013). Γίνεται επίσης, σύγκριση της μετρηθείσας
οριζόντιας μετακίνησης με τις προβλέψεις των οριζόντιων μετακινήσεων των δύο
μοντέλων. Για τον έλεγχο της ρευστοποιησιμότητας του εδάφους -με χρήση του
αριθμού κτύπων NSPT - με σκοπό τον υπολογισμό του αθροιστικού ρευστοποιήσιμου
πάχους Τ15, χρησιμοποιήθηκε η μεθοδολογία των Idriss and Boulanger (2006).
Τέλος, παρουσιάζονται τα διαγράμματα μετρημένης οριζόντιας αθροιστικής
μετακίνησης - απόστασης από το ελεύθερο μέτωπο για την παραλιακή ζώνη του
Αργοστολίου. Λόγω έλλειψης γεωτεχνικών δεδομένων για το Αργοστόλι δεν έγινε
δυνατή η σύγκριση των μετρημένων τιμών με τις εκτιμηθείσες από εμπειρικά
μοντέλα. Ωστόσο, οι τιμές αυτές μπορούν να αποτελέσουν χρήσιμη προσθήκη στην
υφιστάμενη βάση δεδομένων για βελτίωση των εμπειρικών μοντέλων και καλύτερη
εφαρμογή τους στον ελλαδικό χώρο. / Lateral Spreading along the coastal line of Liksouri and Argostoli during the earthquakes in Cephalonia in January 26 & February 3, 2014.
|
7 |
Kinematic and inertial loading-based seismic assessment of pile foundations in liquefiable soil / 液状化地盤における杭基礎の地盤変位・慣性力に基づく地震時挙動の評価SAHARE, ANURAG RAHUL 24 September 2021 (has links)
京都大学 / 新制・課程博士 / 博士(工学) / 甲第23484号 / 工博第4896号 / 新制||工||1765(附属図書館) / 京都大学大学院工学研究科社会基盤工学専攻 / (主査)教授 渦岡 良介, 教授 木村 亮, 准教授 澤村 康生 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM
|
8 |
Lateral Spreading Mechanics of Column-Supported EmbankmentsHuang, Zhanyu 07 November 2019 (has links)
Column-supported embankments (CSE) enable accelerated construction on soft soils, high performance, and protection of adjacent facilities. The foundation columns transfer embankment and service loading to a competent stratum at depth such that loading on the soft soil can be reduced. This has the beneficial effects of reducing settlement and lateral displacement, and improving stability. Selection of column type depends on the design load, cost, constructability, etc., although unreinforced concrete columns are commonly used. A load transfer platform (LTP) is often included at the embankment base. This is a layer of coarse-grained fill that may include one or more layers of geosynthetic reinforcement. The LTP improves vertical load transfer to columns by mobilizing the shear strength of the LTP fill and the membrane effect of the geosynthetic. The geosynthetic reinforcement also responds in tension to lateral spreading.
Herein, lateral spreading is defined as the lateral displacements occurring in response to lateral earth pressures in the embankment and foundation. Excessive lateral spreading can lead to bending failure of the concrete columns, tensile failure of the geosynthetic reinforcement, and instability of the system. Design procedures recommend inclusion of geosynthetic reinforcement to mitigate lateral spreading, with assumptions for the lateral thrust distribution, failure mode, and calculation of geosynthetic tensile capacity. The necessity and sufficiency of these assumptions have not been fully validated. In addition, unreinforced concrete columns have low tensile strength and can fail in bending, but recommendations for calculating column bending moments are not available. This research examines the limitations in CSE lateral spreading design with the goal of advancing fundamental understanding of lateral spreading mechanics.
The research was performed using three-dimensional finite difference analyses. Limiting conditions for lateral spreading analysis were identified using case history records, and an undrained-dissipated approach was validated for the numerical analysis of limiting conditions (i.e., undrained end-of-construction and long-term excess pore pressure dissipated). The numerical model was calibrated using a well-documented case history. Additional analyses of the case history were performed to examine the lateral earth pressures in the foundation, column bending moments, and geosynthetic contribution to resisting lateral spreading. A parametric study was conducted to examine the lateral thrust distribution in 128 CSE scenarios. A refined substructure model was adopted for analyzing peak geosynthetic tensions and strains. Lastly, failure analyses were performed to examine the effect of different CSE design parameters on embankment failure height, failure mode, and deformations.
The research produced qualitative and quantitative information about the following: (1) the percent thrust resistance provided by the geosynthetic as a function of its stiffness; (2) the geosynthetic contribution to ultimate and serviceability limit states; (3) the change in lateral thrust distribution throughout the embankment system before and after dissipation of excess pore water pressures; (4) the column-soil interactions involved in embankment failure; and (5) identification of two failure modes in the undrained condition. Design guidance based on these findings is provided. / Doctor of Philosophy / Column-supported embankments (CSEs) have been designated by the Federal Highway Administration as a critical technology for new highway alignment projects and widening of existing highways. CSEs enable accelerated construction and high performance in weak soils, which are factors critical to project success. In a CSE, columns are installed in the weak soil, followed by rapid construction of the soil embankment that provides the necessary elevation and foundation for the roadway. The columns transfer most of the embankment and traffic loading to a competent soil stratum at depth. Concrete without steel reinforcement is commonly used to construct the columns, although material selection depends on cost, constructability, expected load, etc. Layers of geosynthetic reinforcement can also be included at the embankment base. The geosynthetics help to transfer loads to the columns and resist excessive movement that could lead to instability. The entire embankment system should be designed for safety and economy.
This research was motivated by uncertainties in design to mitigate lateral spreading. Lateral spreading refers to lateral displacements occurring in response to lateral earth pressures in the embankment and foundation. Excessive lateral spreading can lead to failure of the columns, geosynthetic reinforcement, and the entire embankment system. This research aims to advance fundamental understanding of lateral spreading in CSEs and to re-evaluate current design assumptions. Corresponding design guidance is provided.
|
9 |
Stopbank Performance during the 2010 - 2011 Canterbury Earthquake SequenceBainbridge, Sophie Elizabeth January 2013 (has links)
In the period between September 2010 and December 2011, Christchurch was shaken by a series of strong
earthquakes including the MW7.1 4 September 2010, Mw 6.2 22 February 2011, MW6.2 13 June 2011 and MW6.0
23 December 2011 earthquakes. These earthquakes produced very strong ground motions throughout the city
and surrounding areas that resulted in soil liquefaction and lateral spreading causing substantial damage to
buildings, infrastructure and the community. The stopbank network along the Kaiapoi and Avon River suffered
extensive damage with repairs projected to take several years to complete. This presented an opportunity to
undertake a case-study on a regional scale of the effects of liquefaction on a stopbank system. Ultimately, this
information can be used to determine simple performance-based concepts that can be applied in practice to
improve the resilience of river protection works.
The research presented in this thesis draws from data collected following the 4th September 2010 and 22nd
February 2011 earthquakes. The stopbank damage is categorised into seven key deformation modes that were
interpreted from aerial photographs, consultant reports, damage photographs and site visits. Each deformation
mode provides an assessment of the observed mechanism of failure behind liquefaction-induced stopbank
damage and the factors that influence a particular style of deformation.
The deformation modes have been used to create a severity classification for the whole stopbank system, being
‘no or low damage’ and ‘major or severe damage’, in order to discriminate the indicators and factors that
contribute to ‘major to severe damage’ from the factors that contribute to all levels of damage a number of
calculated, land damage, stopbank damage and geomorphological parameters were analysed and compared at
178 locations along the Kaiapoi and Avon River stopbank systems.
A critical liquefiable layer was present at every location with relatively consistent geotechnical parameters (cone
resistance (qc), soil behaviour type (Ic) and Factor of Safety (FoS)) across the study site. In 95% of the cases the
critical layer occurred within two times the Height of the Free Face (HFF,). A statistical analysis of the
geotechnical factors relating to the critical layer was undertaken in order to find correlations between specific
deformation modes and geotechnical factors. It was found that each individual deformation mode involves a
complex interplay of factors that are difficult to represent through correlative analysis.
There was, however, sufficient data to derive the key factors that have affected the severity of deformation. It
was concluded that stopbank damage is directly related to the presence of liquefaction in the ground materials
beneath the stopbanks, but is not critical in determining the type or severity of damage, instead it is merely the
triggering mechanism. Once liquefaction is triggered it is the gravity-induced deformation that causes the
damage rather than the shaking duration.
Lateral spreading and specifically the depositional setting was found to be the key aspect in determining the
severity and type of deformation along the stopbank system. The presence or absence of abandoned or old river
channels and point bar deposits was found to significantly influence the severity and type of deformation. A
review of digital elevation models and old maps along the Kaiapoi River found that all of the ‘major to severe’
damage observed occurred within or directly adjacent to an abandoned river channel. Whilst a review of the
geomorphology along the Avon River showed that every location within a point bar deposit suffered some form
of damage, due to the depositional environment creating a deposit highly susceptible to liquefaction.
|
10 |
Measuring liquefaction-induced deformation from optical satellite imageryMartin, Jonathan Grant 11 September 2014 (has links)
Liquefaction-induced deformations associated with lateral spreading represent a significant hazard that can cause substantial damage during earthquakes. The ability to accurately predict lateral-spreading displacement is hampered by a lack of field data from previous earthquakes. Remote sensing via optical image correlation can fill this gap and provide data regarding liquefaction-induced lateral spreading displacements. In this thesis, deformations from three earthquakes (2010 Darfield, February 2011 Christchurch, and 2011 Tohoku Earthquakes) are measured using optical image correlation applied to 0.5-m resolution satellite imagery. The resulting deformations from optical image correlation are compared to the geologic conditions, as well as field observations and measurements of liquefaction. Measurements from optical image correlation are found to have a precision within 0.40 m in all three cases, and results agree well with field measurements. / text
|
Page generated in 0.075 seconds