Komplexní teoretická analýza metody sloupku pro zjišťování zbytkových napětí / Comprehesive Theoeretical Analysis of Ring-Core Method for Residual Stress Determination

Civín, Adam

January 2012

Comprehensive analysis of the ringcore method used for the determination of the residual stresses in mechanical components is presented in this thesis. Principles, advantages, disadvantages and applicability of this semidestructive experimental method are discussed too. At the same time the ringcore method is compared with the hole drilling method, which is used more frequently. All aspects of the ringcore method are analyzed by the finite element method. FE simulations, performed on the universal numerical model, verified principles of the integral method and the incremental strain method. FE simulations also provided basic information for the uncertainty analysis, which significantly affects the accuracy of the residual stress measurement. The main goal, which the present work deals with, is to create a global overview of all ringcore methods´ aspects elaborated in a clear and complex form.

Seismic Retrofit of Load Bearing URM Walls with Internally Placed Reinforcement and Surface-Bonded FRP Sheets

Sabri, Amirreza

22 June 2020

Concrete block masonry is a common building material used worldwide, including Canada. Reinforced masonry buildings, designed according to the requirements of recent building codes, may result in seismically safe structures. However, unreinforced masonry (URM) buildings designed and constructed prior to the development of modern seismic design codes are extremely vulnerable to seismic induced damage. Replacement of older seismically deficient buildings with new and seismically designed structures is economically not feasible in most cases. Therefore, seismic retrofitting of deficient buildings remains to be a viable seismic risk mitigation strategy. Masonry load bearing walls are the most important elements of such buildings, potentially serving as lateral force resisting systems. A seismic retrofit research program is currently underway at the University of Ottawa, consisting of experimental and analytical components for developing new seismic retrofit systems for unreinforced masonry walls. The research project presented in this thesis forms part of the same overall research program. The experimental component includes design, construction, retrofit and testing of large-scale load bearing masonry walls. Two approaches were developed as retrofit methodologies, both involving reinforcing the walls for strength and deformability. The first approach involves the use of ordinary deformed steel reinforcement as internally added reinforcement to attain reinforced masonry behaviour. The second approach involves the use of internally placed post-tensioning tendons to attain prestressed masonry behaviour. The analytical component of research consists of constructing a Finite Element computer model for nonlinear analysis of walls and conducting a parametric study to assess the significance of retrofit design parameters. The results have led to the development of a conceptual retrofit design framework for the new techniques developed, while utilizing the seismic provisions of the National Building Code of Canada and the relevant CSA material standards.

Masonry

Seismic

Retrofit

Urm

Wall

Earthquake

Frp

Reinforcement

Internally Placed

Load Bearing

Experimental

Analytical

Sap2000

Finite element

Fem

Prestressing

Amir

Amir sabri

Saatcioglu

Sika

Seismic retrofit

Post-tensioning

Nonlinear

Design

Retrofit design

Masonry design

Frp design

Polyurea

Epoxy Injection

Surface Treatment

Seismic retrofitting

Wall Test

Mortar

Shear

Instrumentation

Drift

Strain Gauge

Shell

Shell Elements

Stress Contour

Concrete

Steel

Block

Concrete block

Sap

Flextur

Surface

Bond

Post tensioning

Sheet

Unreinforced masonry