Effects of deep excavations on circular tunnels in fine-grained soils

Karki, Rajendra

30 May 2006

This thesis presents a study of the effects of deep excavations on adjacent metro or utility tunnel in soft to medium soil. The main objective of the thesis is to develop a method of estimating these effects quantitatively. Extensive review of relevant literature published in the past four decades was conducted in order to understand the trends and the key developments in this area. It was revealed from the literature review that the concurrent use of the Observational Method and the finite element method for monitoring and controlling of ground deformations around the excavation has become a norm for deep excavation projects. Several design charts and guidelines for estimation of effects of deep excavations on adjacent raft foundations or pile foundations were found in the literature; however, no such charts or guidelines were found for estimation of effects of deep excavations on existing circular tunnels. Consequently, the development of these guidelines was established as one of the objectives of this study. <p>The initial phase of the research was focused on detailed study and analysis of two well-documented case studies the Chicago Subway Renovation Project, USA and the Tan Tock Seng Hospital Deep Excavation, Singapore. The back analyses of these two case studies were carried out using the finite element software PLAXIS. Exact site conditions and input parameters for the soil and the structural components were incorporated as much as possible. Appropriate adjustments in some of the input parameters were necessary to achieve good match between the computed and the observed results. <p> The back analyses were followed by parametric studies to identify important variables controlling the mechanisms of soil-structure interaction. The variables identified from the parametric studies of the two case studies were: soil stiffness, tunnel lining thickness, the depth of the excavation, and the location of tunnel. These variables were used to conduct a series of finite element analyses using simplified geometry and ground conditions for the purpose of formulating preliminary design charts. Results from these analyses were recorded in terms of in-plane and out-of-plane distortion of tunnel lining as well as additional shear forces and bending moments induced in the tunnel lining due to an adjacent deep excavation. The results were made non-dimensional before presenting them as contour plots. These contour plots constitute preliminary design charts, which can be used for the estimation of tunnel lining deformation caused by adjacent deep excavation.<p> Based on the results of this study, it can be concluded that a finite element program (such as PLAXIS) that is able to model construction processes associated with tunnelling and deep excavation in urban environment can be an invaluable tool in exploring the mechanism of ground deformation around the deep excavation and in quantifying the effects of ground deformation on existing adjacent structures. The modeller must, however, be aware of the fact that ways of modelling a particular construction process could be different for various finite element programs. It is important to interpret the instructions given in the manual of the program correctly. <p>Detailed back analyses of well-documented deep excavation case histories are vital from the point-of-view of building confidence in the selected finite element program. Such analyses also have the potential to identify key variables influencing the soil-structure interaction. <p> Preliminary design charts proposed in this thesis are very convenient for obtaining approximate values of tunnel lining deformation caused by adjacent deep excavation. Non-dimensional nature of these design charts makes it possible to be used for any depth of the deep excavation and for tunnels of any size, depth of cover, and distance from the vertical face of the excavation. These design charts can be used by engineers and contractors for initial estimation, selection and preliminary design of excavation support system, and are particularly useful during the planning phase. Town planners and project managers, who need to decide on the feasibility, damage control and risk management aspects of a deep excavation project, may also find these design charts equally useful. It should, however, be kept in mind that the estimates obtained from these design charts are highly approximate and as such, should be taken as guidelines for decision making processes. These estimates do not replace site specific detailed analysis and monitoring.

parametric study

design charts

finite element method

circular tunnel

Deep excavation

soil-structure interaction

Effects of deep excavations on circular tunnels in fine-grained soils

Karki, Rajendra

30 May 2006

This thesis presents a study of the effects of deep excavations on adjacent metro or utility tunnel in soft to medium soil. The main objective of the thesis is to develop a method of estimating these effects quantitatively. Extensive review of relevant literature published in the past four decades was conducted in order to understand the trends and the key developments in this area. It was revealed from the literature review that the concurrent use of the Observational Method and the finite element method for monitoring and controlling of ground deformations around the excavation has become a norm for deep excavation projects. Several design charts and guidelines for estimation of effects of deep excavations on adjacent raft foundations or pile foundations were found in the literature; however, no such charts or guidelines were found for estimation of effects of deep excavations on existing circular tunnels. Consequently, the development of these guidelines was established as one of the objectives of this study. <p>The initial phase of the research was focused on detailed study and analysis of two well-documented case studies the Chicago Subway Renovation Project, USA and the Tan Tock Seng Hospital Deep Excavation, Singapore. The back analyses of these two case studies were carried out using the finite element software PLAXIS. Exact site conditions and input parameters for the soil and the structural components were incorporated as much as possible. Appropriate adjustments in some of the input parameters were necessary to achieve good match between the computed and the observed results. <p> The back analyses were followed by parametric studies to identify important variables controlling the mechanisms of soil-structure interaction. The variables identified from the parametric studies of the two case studies were: soil stiffness, tunnel lining thickness, the depth of the excavation, and the location of tunnel. These variables were used to conduct a series of finite element analyses using simplified geometry and ground conditions for the purpose of formulating preliminary design charts. Results from these analyses were recorded in terms of in-plane and out-of-plane distortion of tunnel lining as well as additional shear forces and bending moments induced in the tunnel lining due to an adjacent deep excavation. The results were made non-dimensional before presenting them as contour plots. These contour plots constitute preliminary design charts, which can be used for the estimation of tunnel lining deformation caused by adjacent deep excavation.<p> Based on the results of this study, it can be concluded that a finite element program (such as PLAXIS) that is able to model construction processes associated with tunnelling and deep excavation in urban environment can be an invaluable tool in exploring the mechanism of ground deformation around the deep excavation and in quantifying the effects of ground deformation on existing adjacent structures. The modeller must, however, be aware of the fact that ways of modelling a particular construction process could be different for various finite element programs. It is important to interpret the instructions given in the manual of the program correctly. <p>Detailed back analyses of well-documented deep excavation case histories are vital from the point-of-view of building confidence in the selected finite element program. Such analyses also have the potential to identify key variables influencing the soil-structure interaction. <p> Preliminary design charts proposed in this thesis are very convenient for obtaining approximate values of tunnel lining deformation caused by adjacent deep excavation. Non-dimensional nature of these design charts makes it possible to be used for any depth of the deep excavation and for tunnels of any size, depth of cover, and distance from the vertical face of the excavation. These design charts can be used by engineers and contractors for initial estimation, selection and preliminary design of excavation support system, and are particularly useful during the planning phase. Town planners and project managers, who need to decide on the feasibility, damage control and risk management aspects of a deep excavation project, may also find these design charts equally useful. It should, however, be kept in mind that the estimates obtained from these design charts are highly approximate and as such, should be taken as guidelines for decision making processes. These estimates do not replace site specific detailed analysis and monitoring.

parametric study

design charts

finite element method

circular tunnel

Deep excavation

soil-structure interaction

Vibrationer i bjälklag : Förenklad metod för dimensionering

Lemón, Jacob, Paczkowski, Michal

January 2014

Arkitekter och byggnadskonstruktörer har alltid strävat mot egna lösningar. Även om byggmetoderna är lika för tidsperioden, skiljer sig byggnaderna åt. Utvecklingen inom byggindustrin går samtidigt mot bjälklag som byggs slankare och med längre spännvidder för att utnyttja materialets styrka och samtidigt skapa öppna planlösningar. Detta sänker bjälklagens egenfrekvenser, vilket gör att de riskerar att sammanfalla med lastfrekvenser från personer som vistas på bjälklaget, vilket i sin tur leder till kraftigt förstärkta vibrationer. Responsen i strukturen kan bli så stor att människor känner stort obehag när de befinner sig på bjälklaget. Dagens byggnadskonstruktörer ställs därför inför nya utmaningar där den dynamiska responsen för bjälklaget behöver analyseras utifrån kraven som ställs för att uppfylla människans komfort. Detta examensarbete sammanfattar kraven och normerna som gäller för byggnader med hänsyn till vibrationer i bjälklag. Både nationella och internationella normer och standarder studeras. Det fastställs att den internationella standarden ISO 10137 är det dokument som byggnadskonstruktörer i Sverige bör använda sig av eftersom eurokoderna hänvisar till denna standard. För att ge en bättre förståelse för de krav som ställs på bjälklag studeras hur det kommer sig att människan känner obehag av vibrationer. Undersökningen kompletteras med en sammanställning av de laster som förekommer i byggnader och dämpningen som kan förväntas i strukturen. En exakt analys av bjälklagets dynamiska egenskaper tar lång tid att genomföra. Därför har det tillverkats ett enkelt verktyg för verifikation av ett bjälklags dynamiska respons med hänsyn till människans komfort. Verktyget kan användas som en första kontroll av ett bjälklag och består av designkurvor som avser responsen som uppkommer till följd av de mest förekommande lasterna i bostads- och kontorsbyggnader: en person som går, springer eller hoppar från en viss höjd. Vidare bygger designkurvorna på ett antagande om att bjälklaget kan uppföra sig som ett system med en frihetsgrad, vilket möjliggjorde en stor parametrisk studie i programmet Matlab. I studien varierades egenfrekvensen, den modala massan, dämpningen och lastfrekvensen. Tack vare variationen av indata och den förenklade modellen kan designkurvorna, som är resultatet av över 200 000 000 simuleringar, användas för alla typer av bjälklag. För att lättare kunna använda designkurvorna har enkla ekvationer hittats som kan användas för att approximativt beräkna den första egenfrekvensen av bjälklaget. Ekvationerna som har sammanställts i en formelsamling gäller för bjälklag med olika storlek och upplagsförhållanden samt både isotropiska och ortotropiska materialegenskaper. Formelsamlingen har kompletterats med ytterliggare en parametrisk studie som beskriver andelen av den modala massan i jämförelse med bjälklagets totala massa. Studien har genomförts med hjälp av programmet Matlab och finita elementmetoden. För att använda designkurvorna beräknas bjälklagets första egenfrekvens och modalmassa med hjälp av formelsamlingen. När egenfrekvensen och modalmassan är kända kan designkurvorna användas för att läsa av ett frekvensviktat accelerationsvärde. Accelerationerna kan sedan jämföras mot komfortkraven beskrivna av ISO 10137. Metoden sparar tid och resurser när snabba beslut angående människans komfort ur vibrationssynpunkt behöver fattas.

Floors

vibrations

design

ISO

design charts

Bjälklag

vibrationer

dimensionering

ISO

designkurvor

Civil Engineering

Samhällsbyggnadsteknik

Rehabilitation of Exterior RC Beam-Column Joints using Web-Bonded FRP Sheets

Mahini, Seyed Saeid

Unknown Date

In a Reinforced Concrete (RC) building subjected to lateral loads such as earthquake and wind pressure, the beam to column joints constitute one of the critical regions, especially the exterior ones, and they must be designed and detailed to dissipate large amounts of energy without a significant loss of, strength, stiffness and ductility. This would be achieved when the beam-column joints are designed in such a way that the plastic hinges form at a distance away from the column face and the joint region remain elastic. In existing frames, an easy and practical way to implement this behaviour following the accepted design philosophy of the strong-column weak-beam concept is the use a Fibre Reinforced Plastic (FRP) retrofitting system. In the case of damaged buildings, this can be achieved through a FRP repairing system. In the experimental part of this study, seven scaled down exterior subassemblies were tested under monotonic or cyclic loads. All specimens were designed following the strong-column weak-beam principal. The three categories selected for this investigation included the FRP-repaired and FRP-retrofitted specimens under monotonic loads and FRP-retrofitted specimen under cyclic loads. All repairing/retrofitting was performed using a new technique called a web-bonded FRP system, which was developed for the first time in the current study. On the basis of test results, it was concluded that the FRP repairing/retrofitting system can restore/upgrade the integrity of the joint, keeping/upgrading its strength, stiffness and ductility, and shifting the plastic hinges from the column face toward the beam in such a way that the joint remains elastic. In the analytical part of this study, a closed-form solution was developed in order to predict the physical behaviour of the repaired/retrofitted specimens. Firstly, an analytical model was developed to calculate the ultimate moment capacity of the web-bonded FRP sections considering two failure modes, FRP rupture and tension failure, followed by an extended formulation for estimating the beam-tip displacement. Based on the analytical model and the extended formulation, failure mechanisms of the test specimens were implemented into a computer program to facilitate the calculations. All seven subassemblies were analysed using this program, and the results were found to be in good agreement with those obtained from experimental study. Design curves were also developed to be used by practicing engineers. In the numerical part of this study, all specimens were analysed by a nonlinear finite element method using ANSYS software. Numerical analysis was performed for three purposes: to calculate the first yield load of the specimens in order to manage the tests; to investigate the ability of the web-bonded FRP system to relocate the plastic hinge from the column face toward the beam; and to calibrate and confirm the results obtained from the experiments. It was concluded that numerical analysis using ANSYS could be considered as a practical tool in the design of the web-bonded FRP beam-column joints.

Reinforced concrete

Reinforcement

Bar

strong-column weak-beam principal

Exterior Beam-Column Joints

Core

Small scale modelling

Experimental

Test set-up

Control

Plain specimen

Rehabilitation

Retrofitting

retrofitted

Repair

Repaired

Repairing

Strengthening

Controlling

Relocating

Plastic hinge

Pre-cracking

Cracking

Crushing

Post-cracking

Crack

Cracked

Penetration

Damaged

Pre-cracked

Web-Bonded

Wrapping

De-bonding

Fibre Reinforced Plastic

FRP

Sheets

Composite

Confinement

Monotonic loads

Cyclic loading

Loads

Displacement control

Load control

Regime

Phase

Loading sequence

Procedure

Available ductility factor

Curvature ductility factor

Ultimate

First yield

Flexural yielding

Strength

Moment

Stiffness

Failure mechanism

Modes

Sudden

Brittle failure

Measured beam-tip displacement

Deflection

Numerical analysis

ANSYS

Solid65

Solid45

Link8

Non-linear Finite Element (FE)

Convergence criteria

Analytical

Closed from

FRP rupture

tension failure

Compression failure

Minimum thickness

Maximum thickness

Compressive

Tensile

Steel

Ratio

Design charts

Effective Moment of Inertia

Compatibility

Strain

Stress