Capacity Quantification of Two-Way Arching Reinforced Masonry Walls under Blast Loads

Wybenga, Brent M.

January 2014

<p>The focus of this study is on evaluating the performance of nine, one-third scale, arching, reinforced masonry (RM) walls subjected to blast loads and three, one-third scale arching, RM walls subjected to out-of-plane static airbag loads. These RM walls were supported on four sides to enforce two-way arching allowing the ability to monitor individual response to varying levels of blast loads and standoff distances. The uniformity of the blast pressure and impulse were ensured by a specifically designed test enclosure, diminishing the wrap-around and clearing effects, allowing valuable data to be documented. The damage levels noted, ranged from Superficial to Blowout compared directly to the CSA S850-12 performance limits. The outcome of this experiment demonstrates the beneficial effect of two-way arching on the flexural behaviour of RM walls under impulsive loading. The use of two-way arching RM walls significantly reduces structural damage and increases out-of-plane resistance, which in turn enhances the overall structural integrity and building preservation. Further, when subjected to blast, two-way arching RM walls considerably reduces debris and their dispersal, thus increasing public safety and minimizing hazard levels. When using the experimental test data results to calibrate finite element models (FEM), more analytical data points can be obtained and therefore getting a larger range of scaled distances and trials. The validation of the LS-DYNA model can be used as an alternative to the costly experimental data, as the information collected concluded that the FEM gave damage patterns and failure modes that were comparable with experimental results. The test data collected provides a better understanding of RM wall response to blast loads and to the ongoing Masonry Blast Performance Database (MBPD) project at McMaster University. The generated MBPD will in turn contribute to masonry design clauses in the future editions of the recently introduced Canadian Standards CSA S850-12 “Design and Assessment of Buildings Subjected to Blast Loads”.</p> / Master of Applied Science (MASc)

arching

blast loading

blast scaling

experimental testing

out-of-plane

reinforced masonry

Civil Engineering

Structural Engineering

Civil Engineering

RESILIENCE-BASED BLAST DESIGN OF REINFORCED CONCRETE MASONRY SYSTEMS

Salem, Shady

January 2018

The use of fully grouted reinforced masonry shear walls (RMSWs) has been growing in several areas around the world owing to their relative ease of construction and their in-plane ductile behavior. However, RMSWs possess low out-of-plane ductility which amplifies the vulnerability of such components under blast loading. Furthermore, the long time and high costs of recovery following devastating (deliberate or accidental) explosions have created a need for resilience-based design for risk mitigation, especially considering the different sources of associated uncertainty. As such, this study aims to lay out the foundations of a probabilistic resilience–based blast analysis and design framework. The framework should have the capability of quantifying the overall building post-blast functionality in order to estimate its recovery cost and time, and thus the building resilience following such a demand. The proposed framework will be specifically applied for RMSW buildings incurring blast loads through a profound investigation for the behavior of rectangular RMSWs as being a primary structural element in reinforced masonry buildings. The investigation will subsume an experimental and analytical evaluation for the performance of load-bearing RMSWs with different in-plane ductility levels subjected to out-of-plane quasi-static loading. This will be followed by a numerical investigation of RMSWs to conclude the blast probabilistic performance of RMSWs that can be applied within the proposed probabilistic resilience-based blast framework. The work in this dissertation presents a key step towards adopting resilience based analysis and design in future editions of blast-resistant construction standards and provides the decisionmakers with a complete insight into post-blast building functionality and its recovery. / Thesis / Doctor of Philosophy (PhD)

resilience surface

reinforced masonry

recovery time

functionality loss

out-of-plane

resistance function

fragility surface

blast risk

Nonlinear analysis

Axial load

Industry Usage, Stakeholder Perceptions, and Usability Characteristics of Hazard Controls Leading  to the Development of a Design Process and Taxonomy for Large Handheld Powered Equipment.

Goldberg, Ari Joseph

28 November 2016

Three studies were conducted to better understand the current status of the industry and create a design process and taxonomy. Study 1 assessed current industry usage of dust control technologies and stakeholder perceptions in the concrete and masonry trades. Study 2 was similar but assessed emission control technologies in the asphalt roofing trade. Study 3 used the information from studies 1 and 2 to select a tool for further evaluation. The handheld cutoff concrete saw was chosen. An iterative design process was utilized to evaluate the saw. The design process and subsequent usability inspection engendered a taxonomy, or set of design recommendations can be applied to large handheld powered tools. / Ph. D. / Three studies were conducted to better understand the current perceptions of risks associated with the construction industry and create a process for designing tools that mange the associated risks. Study 1 and Study 2 assessed current industry use of technologies for managing health hazards present when working in the concrete, masonry, and asphalt roofing industries; and the interested party’s perceptions of the industries. Study 3 used the information from Studies 1 and 2 to select a tool for further evaluation. The handheld cut-off concrete saw was chosen. An iterative design process was utilized to evaluate the saw. The design process and subsequent usability test created a set of design recommendations which can be applied to large handheld powered tools. A telephone survey was conducted to assess the concrete, masonry, and asphalt roofing industries. The survey measured decision makers’ perceptions of health hazard control technologies. Finally, it assessed business factors affecting adoption of the control technologies and projects specifying the use of health hazard control technologies. The results show the concrete and masonry industries understand the risks associated with working in the industry and are more likely to adopt health hazard management technologies. The asphalt roofing industry is unsure if they view heated asphalt to be a health hazard and are more resistant to adopting current technologies. There are more projects specifying the use of control technologies in concrete and masonry and a decreasing number of projects are specifying the use of control technologies in asphalt roofing. The business factors for adopting technologies are the same across industries, specifically worker safety and government regulation. Those looking to have an impact on the construction industry should focus on the concrete and masonry industries over asphalt roofing. In the final study, a design process and guidelines were created for large handheld powered equipment. The researcher used an iterative design process whose goal was to better equip industry with a dust control device, specifically a vacuum based system for the gasoline powered handheld cut-off concrete saw. Results from Studies 1 and 2 influenced the direction of the design process. The design did not yield a prototype fit for testing, so the researcher assessed the usability of a commercially available system. The results were transformed into design guidelines for anyone interested in creating better hazard controls for similar power tools. The guidelines created are: have clear symbols, efficiently provide feedback, provide feedback when attaching parts, make attaching parts easy, have efficient design to reduce dangers inherent with the tool, increase visibility, reduce overexposure to dangers, ensure it is easy to move, and enable a wide variety of users to be able to use the saw. The process used to design the prototype can be used to design similar large handheld powered tools. The design process starts with looking at how the tool is currently used, then brings stakeholders together to discuss the problem, then create prototypes, and finally test the prototypes for performance and/or usability which will create the design guidelines.

Design Taxonomy

Cut-off Saw

Concrete and Masonry Dust

Asphalt Roofing Dust

User Experience

Usability

Ergonomics

Human Factors

Stanovení modulu pružnosti zdiva ve směru ložné spáry / Determination of masonry modulus of elasticity in the direction of bed joints

Kuchař, Martin

January 2015

The determination of strain properties of masonry in the direction parallel to bed joints is a fundamental pre-requisite for designing structures, where masonry is subjected to horizontal stresses (e. g. strengthening with prestressing). The diploma thesis summarized techniques of determination of masonry modulus of elasticity presented in available literature. The goal is to suggest suitable methodology of determination of masonry modulus in direction parallel to the bed joints. In the practical part of the diploma thesis is that methodology verified by experimental test and results of tests are analyzed and discussed.

Stavební průzkum a diagnostika zděné konstrukce / Survey and Diagnostics of Masonry Construction

Bakešová, Martina

January 2015

The aim of my master’s thesis is to develop a brief overview of the historical development of brick, diagnosis methodologies of masonry structures and their application in the practical part for evaluation of structural survey masonry, carried out at the Faculty of Philosophy, Masaryk University in Brno.

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

Bewertung der Schadensanfälligkeit von Mauerwerkskonstruktionen gegenüber Hochwassereinwirkungen / Assessing the flood vulnerability of external wall constructions

Golz, Sebastian

23 June 2016

Klimatische und gesellschaftliche Veränderungsprozesse sind Herausforderungen, die den gegenwärtig zunehmenden Bedarf an Konzepten und Maßnahmen zur Reduzierung hochwasserinduzierter Risiken insbesondere für die gebaute Umwelt unterstreichen. Eine Handlungsalternative bildet die Implementierung konstruktiver Maßnahmen des hochwasserangepassten Bauens, die zu einer Minderung der Schadensanfälligkeit bestehender Gebäude führen. Derzeit fehlen jedoch Verfahren, um die Effekte derartiger Maßnahmen zu beurteilen. Die vorliegende Dissertationsschrift beleuchtet in einer Experimentalstudie zunächst das Systemverhalten gefügter Außenwandkonstruktionen bei definierten Hochwasserbeanspruchungen. Zu den Zielen der Experimentalstudie gehören die Analyse der konstruktionsspezifischen Feuchteverteilung bei mehrtägiger, ein- und zweiseitiger Wasserbeanspruchung sowie die Untersuchung der Wasserdurchlässigkeit. Zu den üblichen Außenwandkonstruktionen, welche durch ihre signifikante räumliche Verbreitung und häufige Ausführung geprägt sind, zählen sowohl ein- als auch mehrschalige Mauerwerkskonstruktionen aus überwiegend mineralischen Baustoffen. Das Versuchsprogramm umfasst acht Schichtenfolgen üblicher Mauerwerkskonstruktionen, die den allgemein anerkannten Regeln der Technik entsprechen. Darauf aufbauend steht die Untersuchung der Wirkungszusammenhänge zwischen dem dokumentierten Feuchteverhalten und dessen nachteiligen Folgen im Mittelpunkt. Die anschließende systematische Ermittlung und Beurteilung der Schadensanfälligkeit bestehender Mauerwerkskonstruktionen basiert auf der Nutzwertmethode, welche die nachteiligen Veränderungen der Eigenschaftswerte anhand von insgesamt elf identifizierten Kriterien bewertet. Auf der Basis der Labor- und Bewertungsergebnisse lassen sich für die untersuchten Baukonstruktionen exemplarische Anpassungsoptionen ableiten, die im Hinblick auf die Minderung zukünftiger Hochwasserschäden eine geeignete Konstruktionslösung darstellen. Anhand des verwendeten methodischen Ansatzes kann somit die Wirkung verschiedener baukonstruktiver Maßnahmen, bezogen auf die Verringerung des Risikos, eingeschätzt werden.

hochwasserangepasstes Bauen

Bauvorsorge

Mauerwerkskonstruktionen

Hochwasserschäden

physical flood vulnerability

wet-proofing

masonry

flood damage to buildings

ddc:624

rvk:ZI 4935

hochwasserangepasstes Bauen

Bauvorsorge

Mauerwerkskonstruktionen

Hochwasserschäden

Capacity assessment of a single span arch bridge with backfill : A case study of the Glomman Bridge

Bjurström, Henrik, Lasell, Johan

January 2009

<p> </p><p>The aim of this Master Thesis is to assess the load carrying capacity of the Glomman Bridge outside of the Swedish city Örebro. The Glomman Bridge is an unreinforced concrete single span arch bridge with backfill. The bridge was constructed in 1923 on assignment from the Swedish National Railways (SJ).</p><p>The failure criteria used in this thesis is that the bridge collapses when any cross section in the concrete arch reaches its ultimate capacity. In reality, the bridge may manage heavier loads than this. When the capacity is reached in a cross section, a hinge is formed and the arch relocates the forces to other parts of the arch that can carry higher stresses. The real bridge will not collapse until a fourth hinge is formed, and by that a mechanism. To be able to calculate the cross section forces in the arch, it was necessary to know the influences of the loads on the arch when they were run along the bridge. For this purpose, influence lines were obtained from a 2D finite element model created in ABAQUS, a general FE-analyses software. A calculation routine to find the least favourable load combination was then created in Matlab, a numerical calculation software. The routine was made to find the worst case among different load cases and to combine the standardized axle pressures with the present number of axles.</p><p>A parametric survey was also performed because the material properties for the different parts of the bridge are very uncertain. In the survey, the initial values were changed one at a time to study the outcome on the load factor. The load factor is the ratio between the ultimate limit load and the actual load. The studied parameters are the compressive strength, the Young's modulus, the density and the Poisson's ratio of the different parts of the bridge. The parameters are studied individually irrespective of possible correlation. The studied parts of the bridge are the backfill, the arch, the abutments and the asphalt. The clearly most important component is found to be the backfill. With increased stiffness or increased Poisson's ratio in the backfill follows increased load factor.</p><p>The equations behind the failure envelope can be derived from equilibrium equations for the unreinforced cross section. The influence lines are normalised with respect to the capacity of the cross section to get the degree of efficiency along the whole length of the arch, instead of the common influence lines that give the cross section forces. This is done because the failure is not caused by large cross section forces but by an exceeded ultimate stress. As the different loads are run along the bridge, the largest positive and negative efficiency for bending moment and normal force are localised. The normalised cross section forces are plotted together with the failure envelope and the load factor is then calculated.</p><p>Several masonry arch bridges were loaded until collapse in a study performed by the British Transport and Road Research Laboratory. One of the bridges in the study, the Prestwood Bridge, has been used in this thesis as a comparison to the Glomman Bridge. The load carrying capacity of the Prestwood Bridge is known, and is used to verify that the method using the failure envelope is applicable.</p><p>To compare the results from the cross section analysis from the failure envelope model to another method, the Glomman Bridge and the Prestwood Bridge were also tested in the commercial software RING 2.0. The method used in RING 2.0 differs from the failure mode in this thesis by calculating the load factor when four different cross sections reach their capacity and the bridge collapses.</p><p>The failure envelope method allows an A/B-value (Axle- and Bogie load) of 102 kN/147 kN when using very poor values of the parameters and 181 kN/226 kN when using a reference case with normal parameters.</p><p>Although the load capacity is found to be acceptable, the uncertainties are still large. To get a more accurate apprehension of the condition of the actual bridge, further research should be carried out, such as e.g. a non-linear model.</p> / <p>Syftet med föreliggande examensarbete är att uppskatta bärförmågan hos bron Glomman utanför Örebro. Glomman är en oarmerad betongvalvbro i ett spann med ovanliggande jordfyllning. Bron byggdes 1926 på uppdrag av Statens Järnvägar (SJ).</p><p>Brottkriteriet i detta examensarbete är att bron går till brott när något tvärsnitt i betongbågen uppnår sin kapacitet. I själva verket är det möjligt att bron kan klara tyngre last än detta. När kapaciteten nås i ett tvärsnitt uppstår en led och bågen omlagrar krafterna till andra bågdelar som klarar större spänningar. Den verkliga bron rasar inte förrän en fjärde led har utvecklats, och därmed en mekanism. För att kunna beräkna tvärsnittskrafterna i bågen, var det nödvändigt att känna till trafiklasternas påverkan på bågen när de kördes över bron. För detta ändamål erhölls influenslinjer från en tvådimensionell finita elementmodell skapad i ABAQUS, ett generellt FE-program. En beräkningsrutin för att finna värsta tänkbara lastkombinering skapades i Matlab, ett numeriskt beräkningsprogram. Rutinen utformades för att hitta värsta fallet bland olika lastfall samt för att kombinera standardiserade axeltryck med det aktuella antalet axlar.</p><p>En parameterstudie utfördes också då materialegenskaperna för de olika delarna i bron är mycket osäkra. I parameterstudien ändrades ingångsvärdena ett åt gången för att studera utslaget på lastfaktorn. Lastfaktorn är förhållandet mellan brottgränslasten och den verkliga lasten. De parametrar som studeras är tryckhållfastheten, <em>E</em>-modulen, densiteten och tvärkontraktionen för de olika brodelarna. Parametrarna studeras enskilt utan hänsyn till eventuell korrelation. De brodelar som studeras är fyllningen, bågen, fundamenten och asfalten. Den klart viktigaste komponenten visar sig vara fyllningen. Med ökad styvhet eller ökad tvärkontraktion i fyllningen följer ökad last­faktor.</p><p>Ekvationerna bakom brottenveloppet kan härledas ur jämviktsekvationer för det oarmerade tvärsnittet. Influenslinjerna normeras med avseende på tvärsnittets kapa­citet för att få ut utnyttjandegraden längs hela bågen. Detta görs då det egentligen inte är för stor tvärsnittskraft som orsakar brott utan för stor spänning. Högsta och lägsta utnyttjandegrad för böjande moment och normalkraft lokaliseras när de olika typlasterna körs över bron. Utnyttjandegraderna placeras i brottenveloppet för att sedan räkna fram en lastfaktor.</p><p>Ett flertal liknande broar har lastats till brott i en studie genomförd av British Transport and Road Research Laboratory. En av broarna i studien, Prestwood Bridge, har använts i denna rapport som jämförelse med Glomman. Då bärförmågan hos Prestwood Bridge är känd används den till att bekräfta att metoden med brott­enveloppet är tillämpbar.</p><p>För att jämföra resultaten från tvärsnittsanalysen i brottenveloppmetoden med en annan metod, testades även Glomman och Prestwood Bridge i det kommersiella programmet RING 2.0. Metoden som används i RING 2.0 skiljer sig från brottmoden i denna rapport genom att istället beräkna lastfaktorn när fyra olika tvärsnitt har uppnått sina kapaciteter och bron kollapsar.</p><p>Metoden med brottenvelopp tillåter ett A/B-värde (Axel- och Boggitryck) på 102 kN/147 kN när mycket dåliga parametervärden används och 181 kN/226 kN när referensfallet med normala parametervärden används.</p><p>Även om bärförmågan kan anses vara acceptabel är osäkerheterna stora. För att få en nogrannare uppfattning om brons faktiska tillstånd bör fortsatta studier utföras, som t.ex. en icke-linjär modell.</p>

Arch bridge

vault

finite element

backfill

failure envelope

masonry

capacity assessment

Bågbro

valv

finita element

fyllning

brottenvelopp

stenvalv

klassningsberäkning

Civil engineering and architecture

Samhällsbyggnadsteknik och arkitektur

Experimental analysis of the efficiency of carbon fiber anchors applied over CFRP to firebrick bonded joints

Caggegi, Carmelo, Caggegi, Carmelo

21 March 2013

In these recent years, the strengthening of masonry building has known a massive use of CFRP sheets. Those composite materials glued on the elements to reinforce are exposed to prematurely debonding crisis due to a tension load which is much smaller than the tensile strength of the CFRP. A way to upgrade failure load of CFRP-to-support bonded joint is to reinforce the cohesion between the fibers and the support by the use of mechanicals anchors built with the same fibers of the composite and fastened in the support like "nails". Research on the use of anchors for masonry supports has been limited and, in this framework, there are no experimental analyses related to the design and the placement of fiber anchors. The aim of this thesis is to provide experimental data to quantify the efficiency of the carbon fiber anchors applied on a reinforced fire brick. This is a ground work to study CFRP to masonry bonded joint fastened by fiber "nails". Specifically, the analysis of the displacement and the strain fields of the reinforced surface have been realized by means of Digital Image Correlation (DIC), an optical appealing method never used to study a FRP to support bonded joint fastened by FRP anchor. The research demonstrates that the use of the CFRP anchor increases the resistance and the ductility of the reinforcements. The latter are important to augment the mechanical features of the structural members and, especially, to increase the safety of people during earthquakes by avoiding the brittle collapse of the strengthened elements. The digital image correlation has been a good tool for the strain field analysis; strengths and weaknesses of this method have been evaluated

[SPI:OTHER] Engineering Sciences/Other

FRP (Fiber Reinforced Polyemer)

Debonding

Carbon fiber anchor

Digital Image Correlation

Experimental test

Masonry

Performance of Polyurea Retrofitted Unreinforced Concrete Masonry Walls Under Blast Loading

Ciornei, Laura

22 August 2012

Unreinforced masonry walls subjected to blast loading are vulnerable to collapse and fragmentation. The objective of this thesis is to conduct experimental and analytical research for developing a blast retrofit methodology that utilizes polyurea. A total of four unreinforced masonry walls were constructed and tested under various shock tube induced blast pressures at the University of Ottawa Shock Tube Testing Facility. Two of the retrofitted walls had surface-sprayed polyurea. The results indicate that the use of polyurea effectively controlled fragmentation while significantly increased the load capacity and stiffness of masonry walls. Polyurea proved to be an excellent retrofit material for dissipating blast induced energy by providing ductility to the system and changing the failure mode from brittle to ductile. Single degree of freedom (SDOF) dynamic analyses were conducted as part of the analytical investigation. The results show that the analytical model provides reasonably accurate predictions of the specimen response.

blast loading

retrofit

polyurea

arching

CMU

SDOF

infill walls

load-bearing

non load-bearing

concrete masonry walls

URM

polymer

elastomer

experimental testing