Role of timber in the seismic resilience of existing URM buildings

Rizzi, Ermes

24 April 2020

The main topic of the thesis is the role of timber in the seismic resilience of unreinforced masonry (URM) buildings. The research addressed both existing timber components that can be encountered in URM buildings and timber-based retrofit solutions. The work presented herein can be split into two main phases. In the first part of the research, the in-plane behavior of traditional wooden floors was analyzed by means of numerical static and dynamic simulations. Modelling strategies with different refinement levels were proposed and implemented to assess diaphragm in-plane strength and flexibility. Modelling was undertaken considering as-built diaphragms first and was then extended to diaphragms retrofitted by means of timber-based techniques. The influence of diaphragm construction details on their in-plane response was evaluated and timber-based retrofitting solutions were observed to be effective in mitigating in-plane diaphragm flexibility and in increasing in-plane diaphragm strength. The second part of the PhD work was dedicated to investigate new retrofit solutions for URM buildings based on the use of engineered timber panels mechanically connected to the masonry. The first step saw the experimental testing of different types of timber-to-masonry connections considering both screw-type fasteners and adhesive anchors. In the second stage, full-scale masonry walls were tested in the as-built, retrofitted and repaired configurations, highlighting the benefits of the proposed technique on the in-plane response of the masonry walls.

Seismic Performance of Unreinforced Masonry Walls Retrofitted with Post-tensioning Tendons

Lazzarini, Daniel Louis

01 June 2009

Unreinforced masonry (URM) structures have historically been regarded as structurally unsound in response to seismic events. The tendency for URM walls to collapse out-of-plane in a brittle manner is continually cause for concern. Retrofit of these walls is necessary in order to prevent severe damage and injury to occupants. This paper is concerned with the retrofit of unreinforced masonry (URM) walls in response to out-of-plane loading. A retrofit design was developed and verified through structural testing. The selected retrofit technique incorporates vertical coring of URM walls to allow for the insertion of a single post-tensioning (PT) tendon. Tendons are spaced at a regular interval and anchored at the top of the wall parapet and at the lower diaphragm level. Tensioning of the tendons imparts a compressive stress to the wall that effectively increases the wall cracking moment strength, ultimate moment strength and displacement capacity. Additionally, the insertion of PT tendons allows the wall to behave in a ductile manner in response to out-of-plane ground motion. Extensive research was conducted in order to accurately portray the material properties and construction methods of unreinforced masonry walls in San Luis Obispo, California. Various mortar mix designs were generated and tested so that a mix design could be selected to best reflect the target URM structures. Seismic parameters were generated to reflect a URM structure in San Luis Obispo. An unreinforced masonry wall was constructed by a professional mason using the established mortar mix proportions and salvaged bricks from the 1920 era. Having a pin-pin unsupported height of 11 feet, the wall constructed for testing was reflective of the configuration of URM walls in many downtown San Luis Obispo structures. The wall was loaded in the out-of-plane direction by 4 equal point loads mimicking a uniformly distributed load. The testing program consisted of cycling the wall through target internal moments and target displacements. It was verified through testing that post-tensioning tendons can be successfully introduced in URM walls to resist out-of-plane bending. Testing showed that the addition of PT tendons significantly increased the wall’s cracking moment capacity, giving it the elastic strength to resist twice the forces imposed by the design-level ground motion. PT tendons also increased the nominal strength of the wall, allowing the wall to achieve large displacements without collapse. It was also found that PT tendons provided a restoring force to the wall returning it to almost no residual displacement after each displacement cycle. Thus, the URM wall retrofitted with PT tendons demonstrated significant integrity as a structural system, providing for improved strength and ductility with no residual displacement.

URM

post-tensioning

out-of-plane

brick

retrofit

Architectural Engineering

Graduation and retention of underrepresented minorities and male transfer students who enroll in an academic retention program

Jackson, Jermaine

25 November 2020

In this study, the research problem was underrepresented minority (URM) male and female transfer students and male transfer students of all ethnicities who were placed on academic suspension, thus removing their chances of being retained and graduating. The purpose of this study was to see to what extent there were relationships between the dependent variables retention and graduation and the independent variables ethnicity, gender, and enrollment in a retention program. A total of 295 participants were included in the study: 119 students who chose to enroll in the retention program and 176 students who chose not to enroll. Descriptive statistics were run to report the demographic data. A binary logistic regression was used to examine the relationship between the demographic variables (i.e., ethnicity, male, retention program enrollment, retention first year, and graduation from a period of 2014–2016). The results yielded that ethnicity had no effect on retention or graduation. Also, the male gender had no effect on retention or graduation. Students were more likely to be retained if they enrolled in a retention program as compared to those who did not enroll. Also, students were more likely to graduate if they enrolled in a retention program as compared to those who chose not to enroll. The study concluded with a summary of the findings as well as limitations of the study. Recommendations were discussed for practitioners and policy makers to include information for students, faculty, and advisors to encourage career exploration. Future research recommendations included expanding the study to all students, conducting a qualitative study to see why students chose not to enroll in a retention program, and examining the participants’ current program of study.

Retention Program

Community College

Transfer Student

Graduation

Males

URM

Increasing the Blast Resistance of Concrete Masonry Walls Using Fabric Reinforced Cementitious Matrix (FRCM) Composites

Perez Garcia, Ramon

07 May 2021

Unreinforced masonry (URM) walls are often used as load-bearing or infill walls in buildings in many countries. Such walls are also commonly found in existing and heritage buildings in Canada. URM walls are strong structural elements when subjected to axial loading, but are very vulnerable under out-of-plane loads. This type of loading may come from different sources , including seismic or blast events. When subjected to blast, wall elements experience large pressures on one of their faces due to the high pressure produced in the air when an explosion takes place. This wave of compressed air travels in a very short time and hits the wall causing immense stresses, which result in large shear and bending demands that may lead to wall failure, and the projection of debris at high velocities that can injure building occupants. This failure process is highly brittle due to the very low out-of-plane strength that characterize such walls. In the past years, many investigations have been carried out to enhance the structural behaviour of unreinforced masonry walls under out-of-plane loading. Different strengthening methods have been studied, which include the use of polyurea coatings, the application of advanced fiber-reinforced polymer (FRP) composites or the use of concrete overlays in combination with high performance reinforcement. Fabric-reinforced cementitious matrix (FRCM) is a new composite material that overcomes some of the drawbacks of FRP. This composite material consists of applying coatings which consist of one or more layers of cement-based mortar reinforced with a corresponding open mesh of dry fibers (fabric). This material has been studied as a strengthening technique to improve in-plane and out-of-plane capacity of existing URM walls as well as other structural elements, mostly under seismic actions. This thesis presents an experimental and analytical study which investigates the effectiveness of using FRCM composites to improve the out-of-plane resistance of URM walls when subjected to blast loading. As part of the experimental program, three large-scale URM masonry walls were constructed and strengthened with 1,2 and 3 layers of FRCM using unidirectional carbon fabrics. In all cases the specimens were built as load-bearing concrete masonry (CMU) walls. To increase shear resistance, two of the walls were also grouted with a flowable self-compacting concrete (SCC) mortar. Blast tests were conducted using the University of Ottawa Shock Tube and the results are compared with control walls tested in previous research at the University of Ottawa. The experimental results show that the FRCM retrofit significantly improved the blast performance of the URM load-bearing walls, allowing for increased blast capacity and improved control of displacements. The performance of the retrofit was found to be dependent on the number of retrofit layers. As part of the analytical research, Single Degree of Freedom (SDOF) analysis was carried out to predict the blast behaviour of the strengthened walls. This was done by computing wall flexural strength using plane sectional analysis and developing idealized resistance curves for use in the SDOF analysis. In general, the analysis procedure is found to produce reasonably accurate results for both the resistance functions and wall mid-height displacements under blast loading.

FRCM

Fabric Reinforced Cementitious Matrix

Composites

URM walls

Blast

Masonry walls

Exploring Blended Learning Supports for First-Generation and Underrepresented Minoritized Undergraduate Students

Gardner, Krista Marie

22 June 2023

First-generation students are frequently underrepresented minoritized (URM), low-income students (Douglas, 2019; Postsecondary National Policy Institute [PNPI], 2021). They are often highly motivated (Haney, 2020) but frequently experience unique or exacerbated challenges in post-secondary education (Moore et al., 2018; Soria et al., 2020). These challenges may continue into online spaces. In the first paper of this dissertation, we performed a scoping literature review and uniquely identified and categorized the challenges of these students in the online environment. We placed these challenges within the model of student engagement by Borup et al. (2020) to offer theoretical perspective for potentially better student support. In the second paper of this dissertation, we captured the experience of a partnership between a university and nonprofit organization, formed to improve the support of first-generation and URM undergraduate student success. Through semistructured interviews of eight university and nonprofit representatives, we found a reflection of best practices and student needs, as well as perspectives on how partnerships can collaboratively support student success. In the third paper of this dissertation, through semistructured interviews, we explored the perspectives of 12 first-generation and URM undergraduate students experiencing a unique set of supportive interventions. These student perspectives are essential to ensure not only that student support programs are optimal, but also to make certain that institutions avoid no-impact, low-impact, or even negative-impact interventions.

first-generation students

minorities

online learning

undergraduate students

student engagement

Education

Preparing First-Generation College Students for Doctoral Persistence: A Formative Evaluation of the McNair Scholars Program

Martinez, Michelle Waiters

01 January 2014

There is little diversity among earned doctorates in the United States. First-generation college students are especially at-risk for not matriculating to a doctoral degree. This applied dissertation provided an understanding of the obstacles faced by first-generation college students in doctoral programs by studying alumni of the McNair Scholars Program. The study examined the components of the McNair Scholars Program that can help ameliorate obstacles faced by first-generation college students as they enroll and persist into graduate school. This study utilized a sequential exploratory mixed methods approach to evaluate the components of the McNair Scholars Program that prepared students for successful persistence into graduate school and subsequent completion of an earned doctorate.

Doctoral Persistence

First Generation College Students

Graduate Students

Low Income Students

McNair Scholars Program

Underrepresented Minority Students (URM)

Education

The seismic analysis of a typical South African unreinforced masonry structure

Van Der Kolf, Thomas

04 1900

Thesis (MEng)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: South Africa has some regions which are susceptible to moderate seismic activity. A peak ground acceleration of between 0.1g and 0.15g can be expected in the southern parts of the Western Cape. Unreinforced Masonry (URM) is commonly used as a construction material for 2 to 4 storey buildings in underprivileged areas in and around Cape Town. URM is typically regarded as the material most vulnerable to damage when subjected to earthquake excitation. In this study, a three-storey URM building was analysed by applying seven earthquake time-histories, that can be expected to occur in South Africa, to a finite element model. Experimental data was used to calibrate the in- and out-of-plane stiffness of the URM. A linear modal dynamic analysis and non-linear implicit dynamic analysis were performed. The results indicated that tensile cracking of the in-plane piers was the dominant failure mode. The building relied on the postcracking capacity to resist the 0.15g magnitude earthquake. It is concluded that URM buildings of this type are at risk of failure especially if sufficient ductility is not provided. The results also showed that connection failure must be investigated further. Construction and material quality will have a large effect on the ability of typical URM buildings to withstand moderate magnitude earthquakes in South Africa. / AFRIKAANSE OPSOMMING: Sekere gebiede in Suid-Afrika het ’n risiko van matige seismiese aktiwiteit. Aardbewings met maksimum grondversnellings van tussen 0.1g en 0.15g kan in die suidelike gedeeltes van die Wes- Kaap voorkom. Twee- tot vier-verdieping onbewapende messelwerkgeboue kom algemeen voor in die lae sosio-ekonomiese gebiede van Kaapstad. Oor die algemeen word onbewapende messelwerkgeboue as die gebou-tipe beskou wat die maklikste skade opdoen tydens aardbewings. In hierdie studie is sewe aardbewings, wat tipies in Kaapstad verwag kan word, identifiseer en gebruik om ’n tipiese drie-verdieping onbewapende messelwerkgebou te analiseer. Eksperimentele data is gebruik om die materiaaleienskappe in die in-vlak asook uit-vlak rigtings te kalibreer. Beide ’n liniêre modale en nie-liniˆere implisiete dinamiese analises is uitgevoer. Die resultate dui daarop dat die dominante falingsmode die kraak van in-vlak messelwerk-tussenkolomme is. Die gebou moes sy plastiese kapasiteit benut om die 0.15g aardbewing te kan weerstaan. Die gevolgtrekking is dat dié tipe onbewapende messelwerkgeboue ’n risiko inhou om mee te gee, veral as genoegsame vervormbaarheid nie verskaf word nie. Die resultate toon ook dat konneksie-faling verder ondersoek moet word. Kwaliteit van vakmanskap en van materiaal het ’n groot invoed op die vermoë van onbewapende messelwerkgeboue om aardbewings van matige intensiteit in Suid-Afrika te weerstaan.

Seismic Analysis

Reinforced Masonry

Structural analysis (Engineering)

Earthquake resistant design

Dissertations -- Civil engineering

Buildings -- Earthquake effects

Unreinforced Masonry (URM)

UCTD

Theses -- Civil engineering

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

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

Performance of Polyurea Retrofitted Unreinforced Concrete Masonry Walls Under Blast Loading

Ciornei, Laura

January 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