A Study of the Seismic Performance of Early Multi-Story Steel Frame Structures with Unreinforced Masonry Infill

Potterton, Kristin

01 January 2009

Steel frame construction with unreinforced masonry infill walls is a common system found in high-rise structures built in the late nineteenth and early twentieth centuries. Recorded performance of this dual system during seismic events shows that the structures are able to resist a high level of lateral loads without collapse, primarily because a majority of damage is confined to the infill walls instead of the gravity carrying frame. To better understand expected performance of this structural system in different seismic risk regions, a prototypical building was analyzed using modal and nonlinear static procedures based on currently accepted evaluation guidelines. Nonlinear results from the computer model were compared with calculated target displacements for seventeen cities likely to have steel frame construction with unreinforced masonry infill in order to determine expected damage levels at varying levels of seismic risk. It was concluded that the structural system studied could experience damage in all seismic risk regions, including post-yield damage of the structure, although in low risk regions that damage is confined entirely to the infill walls. Practicing structural engineers should be aware that in all seismic risk zones existing steel frame buildings with unreinforced masonry infill, while able to resist a high magnitude of displacement without complete structural failure, will require additional lateral support under currently accepted rehabilitation guidelines.

unreinforced masonry infill

infill walls

seismic performance of infill walls

development of steel construction

Structural Engineering

Πειραματική και αναλυτική απόκριση τετραώροφης υφιστάμενης κατασκευής ενισχυμένη με εμφάτνωση από οπλισμένο σκυρόδεμα

Σταθάς, Νικόλαος

21 December 2012

Στόχος της παρούσας διατριβής είναι η εξαγωγή συμπερασμάτων σχετικά με την απόκριση πολυώροφων κατασκευών ενισχυμένων με εμφάτνωση από οπλισμένο σκυρόδεμα και η αναλυτική προσέγγιση αυτών υπολογίζοντας τις χαρακτηριστικές ιδιότητες δυσκαμψίας, αντοχής και ικανότητας παραμόρφωσης του νέου τοιχώματος. Βεβαίως, ελέγχεται και η επίτευξη μονολιθικής σύνδεσης μεταξύ φατνώματος και μελών του περιμετρικού πλαισίου. Για το λόγο αυτό, κατασκευάζεται και δοκιμάζεται πειραματικά μέσω της υβριδικής μεθόδου με υποκατασκευές, ένα τετραώροφο πλαίσιο εμφατνούμενο από οπλισμένο σκυρόδεμα εξασφαλίζοντας την επαρκή σύνδεση του κορμού του τοιχώματος με το υφιστάμενο πλαίσιο. Ακολουθεί η διεξαγωγή μη - γραμμικής δυναμικής ανάλυσης προκειμένου να υπάρξει προσέγγιση των πειραματικών αποτελεσμάτων από τα αναλυτικά, καθώς και ο υπολογισμός των χαρακτηριστικών παραμορφώσεων και δυσκαμψίας του δοκιμίου σύμφωνα με τον Κανονισμό Επεμβάσεων (ΚΑΝ.ΕΠΕ.)και την υιοθέτηση ορισμένων παραδοχών, η αξιοπιστία των οποίων εξετάζεται μέσω της αναλυτικής προσέγγισης εναλλακτικού πειραματικού φορέα. / The aim of this thesis is to reach in conclusions about the response of existing multistorey reinforced concrete structures, retrofitted by reinforced condrete infill wall and also analytically approach that response computing the characteristic properties of stiffness, strength and deformation capacity of the new composite wall. Moreover, the effectiveness of the connection between the web and the surrounding frame members is under investigetion. For the aforementioned purposes, a 4-storey RC frame converted into slnder wall is constructed and tested by pseudo-dynamic method with substructures. In order to compare the experimental with the analytical results, a non-linear dynamic analysis is conducted and the deformation and stiffness of the specimen are determined by the use of some computtional assumptions, which derive from the computational procedure of the characteristic response parameters of the composite wall. Finally, the overall reliability and correctness of those assumptions is examined through the analytical procedure of a different exprimental project.

Εμφάτνωση

Τοιχώματα

690.383

Reinforced concrete infill

Infill walls

Structure retrofitting tecnique

Utfackningsväggar och trafikbuller - En förtätning av Albyberget / Infill walls and traffic noise - A densification of Albyberget

Granqvist, Andreas, Hall, Jonas

January 2017

AUCTORITAS Projektstyrning AB arbetar med att få fram förfrågningsunderlag för två nya flerbostadshus i en miljö som är bullerutsatt. Ett problem som uppstått är att hitta en utfackningsvägg som klarar kraven för buller samt U-värde som samtidigt är ekonomisk försvarbar. Författarna har på uppdrag av AUCTORITAS Projektstyrning AB undersökt 10 olika utfackningsväggar med hänsyn till ljudreduktion, U-värde samt pris. Syftet med arbetet var att utreda de tekniska egenskaperna för utfackningsväggarna. Frågeställningen som behandlades var följande: Hur påverkar olika materialval ljuddämpningen? Vilka utfackningsväggar klarar bullerkraven vid en nybyggnation på Albyberget? Kan problematiken lösas enbart med väggarna eller krävs det ytterligare åtgärder? Är det ekonomiskt försvarbart att välja en tjockare vägg med hänsyn till u-värde istället för att maximera BOA? För att besvara dessa frågor har författarna genomfört laborationer, litteraturstudier samt tagit del av ett referensobjekt, akustikrapporter, energiberäkningsrapporter och kalkylböcker/offerter. Intervju med en person som besitter kunskap inom området buller/akustik har utförts och använts som kompletterande underlag. Resultatet ledde till att en standard träregelvägg på 395 mm som uppfyllde samtliga projektkrav som samtidigt var ekonomisk försvarbar med en kostnad på 1 391 kr/m2 rekommenderades till flerbostadshusen på Albyberget / AUCTORITAS Projektstyrning AB is working on obtaining contract documents for two new apartment buildings in an environment that is exposed to noise. One problem that has arisen is to find an infill wall that meets the requirements for noise and U-value, which at the same time is economically justifiable. The authors, on behalf of AUCTORITAS Projektstyrning AB, have examined 10 different infill walls with regard to noise reduction, U-value and price. The purpose of the work was to investigate the technical properties of the infill walls. The question that was addressed was the following: How does different materials affect the sound attenuation? Which infill walls can handle the noise requirements of a new construction on Albyberget? Can the problem be solved solely with the walls or does it require further action? Is it economically justifiable to choose a thicker wall with regard to u value instead of maximizing the living space? In order to answer these questions, the authors have carried out laboratory work, literature studies and also taken part in a reference object, acoustics reports, energy calculation reports and costing books/offers. An interview with a person with knowledge in the area of noise/acoustics have been completed and used as a complementary basis. The results led to a recommendation of a standard timber frame wall with a thickness of 395 mm, that met all of the project requirements and with a cost of 1 391 kr/m2 to be used in the buildings at Albyberget.

Infill walls

traffic noise

sound attenuation

costing

Utfackningsvägg

trafikbuller

ljudreduktion

kalkyl

Construction Management

Byggproduktion

Nonlinear Analysis Of Rc Frames Retrofitted With Structural Steel Elements

Akpinar, Ugur

01 September 2010

Deficient concrete structures are serious danger in seismic zones. In order to minimize economical and human loss, these structures should be retrofitted. Selecting suitable retrofitting schemes requires detailed investigation of these systems. Considering these facts, this study aims to calibrate analytical models of systems with chevron braces and internal steel frames / and evaluate their seismic performances. First, analytical models of the frames with braces and internal steel frames were prepared and then their responses were compared with cyclic responses of experimental studies. Results of these models were used to determine performance limits by the methods proposed by TEC2007 and ASCE/SEI-41. Then, calibrated models were employed for time history analyses with various scales of Duzce ground motion and analytical results were compared with experimental findings. Seismic performance of these systems was also evaluated by using aforementioned codes. Finally, evaluated retrofitting schemes were applied to a 4-story 3-bay reinforced concrete frame that was obtained from an existing deficient structure and effectiveness of applied retrofitting schemes was investigated in detail.

A Study of the Response of Reinforced Concrete Frames with and without Masonry Infill Walls to Simulated Earthquakes

Jonathan Dean Monical (11852183)

18 December 2021

This study focuses on non-ductile reinforced concrete (RC) frames built outside current practices. These structures are quite vulnerable to collapse during earthquakes. One option to retrofit buildings with poorly detailed RC columns is to construct full-height masonry infill walls to provide additional means to resist loads caused by gravity and increase lateral stiffness resulting in a reduction in drift demand. On the other hand, infill can cause reductions in drift capacity that offset the benefits of reductions in drift demand. Given these two opposing effects, this investigation addresses the following question: are poorly detailed RC frames with masonry infill walls any safer than similar RC frames without infill walls?

Structural Engineering

Reinforced concrete

Masonry infill walls

Drift demand

Drift capacity

Seismic retrofit

Earthquake 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

Investigation Of Strenghthening Techniques Using Pseudo-dynamic Testing

Kurt, Efe Gokce

01 June 2010

Pseudo-dynamic testing was employed to observe the seismic performance of three different retrofit methods on two story three bay reinforced concrete frame structures. The three test frames have hollow clay tile (HCT) infills in the central bay. All of the test frames represent the seismic deficiencies of the Turkish construction practice such as use of plain reinforcing bars, low strength concrete and insufficient confining steel. Two non-invasive and occupant friendly retrofit schemes suggested in the Turkish Earthquake Code, namely use of Fiber Reinforced Polymers and precast concrete panels integrated on the HCT infills and traditional approach of adding concrete infill wall were employed. Specimens were subjected to three different scale levels of North-South component of Duzce ground motion. Reference specimen experienced severe damage at 100% scale level and reached collapse stage due to the loss of integrity of the infill wall and significant damage on the boundary columns. The retrofitted test structures were able to survive the highest level 140% Duzce ground motion. Test results confirmed the success of the retrofit methods for simulated earthquake loads.

Numerical Investigation of Masonry Infilled RC Frames Subjected to Seismic Loading

Manju, M A

January 2016

Reinforced concrete frames, infilled with brick/concrete block masonry, are the most common type of structures found in multi-storeyed constructions, especially in developing countries. Usually, the infill walls are considered as non-structural elements even though they alter the lateral stiffness and strength of the frame significantly. Approximately 80% of the structural cost from earthquakes is attributable to damage of infill walls and to consequent damages of doors, windows and other installations. Despite the broad application and economical significance, the infill walls are not included in the analysis because of the design complexity and lack of suitable theory. But in seismic areas, ignoring the infill-frame interaction is not safe because the change in the stiffness and the consequent change in seismic demand of the composite structural system is not negligible. The relevant experimental findings shows a considerable reduction in the response of infilled frames under reverse cyclic loading. This behaviour is caused by the rapid degradation of stiffness, strength, and low energy dissipation capacity resulting from the brittle and sudden damage of the unreinforced masonry infill walls. Though various national/international codes of practice have incorporated some of the research outcomes as design guidelines, there is a need and scope for further refinement. In the initial part of this work, a numerical modelling and linear elastic analysis of masonry infilled RC frames has been done. A multi-storey multi-bay frame infilled with masonry panels, is considered for the study. Both macro modelling and micro modelling strategies are adopted. Seismic loading is considered and an equivalent static analysis as suggested in IS 1893, 2002 is done. The results show that the stiffness of the composite structure is increased due to the obvious confinement effects of infill panels on the bounding frame. A parametric study is conducted to investigate the influence of size and location of openings, presence/absence of infill panels in a particular storey and elevation irregularity in terms of floor height. The results show that the interaction of infill panel changes the seismic response of the composite structure significantly. Presence of openings further changes the seismic behaviour. Increase in openings increases the natural period and introduce newer failure mechanisms. Absence of infill in a particular storey (an elevation irregularity) makes it drift more compared to adjacent storeys. Since the structural irregularities influence the seismic behaviour of a building considerably, we should be cautious while construction and renovation of such buildings in order to take the advantage of increased strength and stiffness obtained by the presence of infill walls. A nonlinear dynamic analysis of masonry infilled RC frames is presented next. Material non linearity is considered for the finite element modelling of both masonry and concrete. Concrete damage plasticity model is employed to capture the degradation in stiffness under reverse cyclic loading. A parametric study by varying the same parameters as considered in the linear analysis is conducted. It is seen that the fundamental period calculation of infilled frames by conventional empirical formulae needs to be revisited for a better understanding of the real seismic behaviour of the infilled frames. Enhancement in the lateral stiffness due to the presence of infill panel attracts larger force and causes damage to the composite system during seismic loading. Elevation irregularities included absence of infill panels in a particular storey. Soft storey shows a tendency for the adjacent columns to fail in shear, due to the large drift compared to other storeys. The interstorey drift ratios of soft storeys are found to be larger than the limiting values. However this model could not capture the separation at the interfaces and related failure mechanisms. To improve the nonlinear model, a contact surface at the interface is considered for a qualitative analysis. A one bay one storey infilled frame is selected. The material characteristics were kept the same as those used in the nonlinear model. Contact surface at the interface was given hard contact property with pressure-overclosure relations and suitable values of friction at the interface. This model could simulate the compressive diagonal strut formation and the switching of this compressive strut to the opposite diagonal under reverse cyclic loading. It showed an indication of corner crushing and diagonal cracking failure modes. The frame with central opening showed stress accumulation near the corners of opening. Next, the micro modelling strategy for masonry suggested by Lourenco is studied. This interface element can be used at the masonry panel-concrete frame interface as well as at the expanded masonry block to block interface. Cap plasticity model (modified Drucker – Prager model for geological materials) can be used to describe the behaviour of masonry (in terms of interface cracking, slipping, shearing) under earthquake loading. The blocks can be defined as elastic material with a potential crack at the centre. However, further experimental investigation is needed to calibrate this model. It is required to make use of the beneficial effects and improve upon the ill-effects of the presence of infills. To conclude, infill panels are inevitable for functional aspects such as division of space and envelope for the building. Using the lateral stiffness, strength contribution and energy dissipation capacity, use of infill panels is proposed to be a wiser solution for reducing the seismic vulnerability of multi-storey buildings.

Masonry Infilled RC Frames

Seismic Loading

Linear Elastic Analysis

Reinforced Concrete

Young's Modules of Elasticity

Infilled Frames

Infill Walls

Concrete Damage Plasticity Model

seismic vulnerability

Civil Engineering

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