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Images, UC QuakeStudies

A view down Worcester Street towards the Regent Theatre building. Tiles have fallen away from the Regent Theatre's red dome. In the foreground the Clarendon Hotel can be seen, with a large crack where the facade has pulled away from the rest of the building.

Images, UC QuakeStudies

A photograph captioned by BeckerFraserPhotos, "As we went by, we recorded the current state of the site of the urgent demolition in Redcliffs from last week. To our surprise when processing the photo, we noticed how damaged the surrounding houses are, particularly the house with the red tiles".

Images, UC QuakeStudies

Damage to the front gable of the Durham Street Methodist Church. Masonry has fallen from the top of the gable, and the resulting gap has been weather proofed with plywood, tarpaulins and metal tiles. The steel bracing propping the whole front wall can be seen at the bottom of the photograph.

Images, UC QuakeStudies

A photograph of the front of Crack'd for Christchurch's partially-completed armchair artwork.Crack'd for Christchurch comments, "We took quotes from some of the letters sent to us and a local ceramicist, Cecelia Freire De Mance, donated her time and wonderful skills to turn these into ceramic tiles to be broken up for the chair. This one reads, 'treasures in our everyday living...'."

Images, eqnz.chch.2010

Known by the locals as the "Manager's House" of the large brick and tile works which was situated nearby. Established by the Austin brothers in 1863 the brickworks were named after the town of Farnley in Yorkshire England, from where the family had come. I remember the brickworks as a child and I think they were demolished in the 1970's. Very sa...

Images, eqnz.chch.2010

Known by the locals as the "Owner's House" of the large Farnley Brick and Tile Works which was situated nearby. Established by the Austin brothers in 1863 the brickworks were named after the town of Farnley in Yorkshire England, from where the family had come. I remember the brickworks as a child and I think they were demolished in the 1970's. V...

Images, eqnz.chch.2010

Another house has gone from Seabreeze Close, Pacific Park, Bexley, leaving just the concrete base, a few floor tiles and the smashed toilet (throne). Houses are being demolished (85%) or deconstructed/shifted (15%) as a result of land damage in the major earthquakes of 4th September 2010, 22nd February 2011, 13th June 2011 and 23rd December 2...

Images, eqnz.chch.2010

20110821_1708_1D3-280 Six months on A house in Bexley damaged in the February earthquake still looks like this six months later.

Images, UC QuakeStudies

An image of 'Polar Opposite': a cartoon cat and dog. 'Polar Opposite' is one of the 'Festive Besties, a series of characters created by All Right? for their 2015 Christmas e-cards. All Right? used the image as a Facebook cover photo on 18 December 2015 at 9:27am with the caption, "Who's your Polar Opposite? Hint: Like avo and Marmite, it'll be someone who you're an unlikely pair with! Thank them and your other 2015 Besties today with our fab FREE tiles: allright.org.nz/festive".

Images, UC QuakeStudies

An image of 'Terrific Tinsel', an 'All Rightie' wrapped in Christmas decorations. 'Terrific Tinsel' is one of the 'Festive Besties, a series of characters created by All Right? for their 2015 Christmas e-cards. All Right? used the image as a Facebook cover photo on 17 December 2015 at 10:10am with the caption, "Who's your Terrific Tinsel? Hint: It'll be someone who brings sparkle to any situation and isn't afraid to stand out! Thank them and your other 2015 Besties today with our fab FREE tiles: allright.org.nz/festive".

Images, UC QuakeStudies

An image of 'Jazzy Jandal': an 'All Rightie' riding a giant jandal like a surfboard. 'Jazzy Jandal' is one of the 'Festive Besties', a series of characters created by All Right? for their 2015 Christmas e-cards. All Right? used the image as a Facebook cover photo on 19 December 2015 at 5:41pm with the caption, "Who's your Jazzy Jandal? Hint: It'll be someone who is #1 for laid-back fun! Thank them and your other 2015 Besties today with our fab FREE tiles: allright.org.nz/festive".

Images, UC QuakeStudies

An image of 'Energetic Elf': an 'All Rightie' with elf ears carrying a stack of presents. 'Energetic Elf' is one of the 'Festive Besties', a series of characters created by All Right? for their 2015 Christmas e-cards. All Right? used the image as a cover photo on 20 December 2015 at 5:22pm, with the caption, "Who's your Energetic Elf? Hint: It'll be someone who puts in the hard graft, often behind the scenes! Thank them and your other 2015 Besties today with our fab FREE tiles: allright.org.nz/festive".

Images, UC QuakeStudies

An image of 'Brandy Snap': an 'All Rightie' wearing a brandy snap costume. 'Brandy Snap' is one of the 'Festive Besties, a series of characters created by All Right? for their 2015 Christmas e-cards. All Right? used the image as a Facebook cover photo on 20 December 2015 at 8:45am with the caption, "Who's your Brandy Snap? Hint: It'll be someone with a tough exterior and sweet insides to say it like it really is! Thank them and your other 2015 Besties today with our fab FREE tiles: allright.org.nz/festive".

Images, UC QuakeStudies

An image of 'Sparkly Spud': an 'All Rightie' harvesting a giant potato. 'Sparkly Spud' is one of the 'Festive Besties, a series of characters created by All Right? for their 2015 Christmas e-cards. All Right? used the image as a Facebook cover photo on 19 December 2015 at 7:40am with the caption, "Who's your Sparkly Spud? Hint: It'll be someone who is a new friend - tasty, sweet and signal that a new season of fun is just around the corner! Thank them and your other 2015 Besties today with our fab FREE tiles: allright.org.nz/festive".

Research papers, University of Canterbury Library

Non-structural elements (NSEs) have frequently proven to contribute to significant losses sustained from earthquakes in the form of damage, downtime, injury and death. In New Zealand (NZ), the 2010 and 2011 Canterbury Earthquake Sequence (CES), the 2013 Seddon and Cook Strait earthquake sequence and the 2016 Kaikoura earthquake were major milestones in this regard as significant damage to building NSEs both highlighted and further reinforced the importance of NSE seismic performance to the resilience of urban centres. Extensive damage in suspended ceilings, partition walls, façades and building services following the CES was reported to be partly due to erroneous seismic design or installation or caused by intervening elements. Moreover, the low-damage solutions developed for structural systems sometimes allow for relatively large inter-story drifts -compared to conventional designs- which may not have been considered in the seismic design of NSEs. Having observed these shortcomings, this study on suspended ceilings was carried out with five main goals: i) Understanding the seismic performance of the system commonly used in NZ; ii) Understanding the transfer of seismic design actions through different suspended ceiling components, iii) Investigating potential low-damage solutions; iii) Evaluating the compatibility of the current ceiling system with other low-damage NSEs; and iv) Investigating the application of numerical analysis to simulate the response of ceiling systems. The first phase of the study followed a joint research work between the University of Canterbury (UC) in NZ, and the Politecnico Di Milano, in Italy. The experimental ceiling component fragility curves obtained in this existing study were employed to produce analytical fragility curves for a perimeter-fixed ceiling of a given size and weight, with grid acceleration as the intensity measure. The validity of the method was proven through comparisons between this proposed analytical approach with the recommended procedures in proprietary products design guidelines, as well as experimental fragility curves from other studies. For application to engineering design practice, and using fragility curves for a range of ceiling lengths and weights, design curves were produced for estimating the allowable grid lengths for a given demand level. In the second phase of this study, three specimens of perimeter-fixed ceilings were tested on a shake table under both sinusoidal and random floor motion input. The experiments considered the relationship between the floor acceleration, acceleration of the ceiling grid, the axial force induced in the grid members, and the effect of boundary conditions on the transfer of these axial forces. A direct correlation was observed between the axial force (recorded via load cells) and the horizontal acceleration measured on the ceiling grid. Moreover, the amplification of floor acceleration, as transferred through ceiling components, was examined and found (in several tests) to be greater than the recommended factor for the design of ceilings provided in the NZ earthquake loadings standard NZS1170.5. However, this amplification was found to be influenced by the pounding interactions between the ceiling grid members and the tiles, and this amplification diminished considerably when the high frequency content was filtered out from the output time histories. The experiments ended with damage in the ceiling grid connection at an axial force similar to the capacity of these joints previously measured through static tests in phase one. The observation of common forms of damage in ceilings in earthquakes triggered the monotonic experiments carried out in the third phase of this research with the objective of investigating a simple and easily applicable mitigation strategy for existing or new suspended ceilings. The tests focused on the possibility of using proprietary cross-shaped clip elements ordinarily used to provide seismic gap as a strengthening solution for the weak components of a ceiling. The results showed that the solution was effective under both tension and compression loads through increasing load bearing capacity and ductility in grid connections. The feasibility of a novel type of suspended ceiling called fully-floating ceiling system was investigated through shaking table tests in the next phase of this study with the main goal of isolating the ceiling from the surrounding structure; thereby arresting the transfer of associated seismic forces from the structure to the ceiling. The fully-floating ceiling specimen was freely hung from the floor above lacking any lateral bracing and connections with the perimeter. Throughout different tests, a satisfactory agreement between the fully-floating ceiling response and simple pendulum theory was demonstrated. The addition of isolation material in perimeter gaps was found effective in inducing extra damping and protecting the ceiling from pounding impact; resulting in much reduced ceiling displacements and accelerations. The only form of damage observed throughout the random floor motion tests and the sinusoidal tests was a panel dislodgement observed in a test due to successive poundings between the ceiling specimen and the surrounding beams at resonant frequencies. Partition walls as the first effective NSE in direct interaction with ceilings were the topic of the final experimental phase. Low-damage drywall partitions proposed in a previous study in the UC were tested with two common forms of suspended ceiling: braced and perimeter-fixed. The experiments investigated the in-plane and out-of-plane performance of the low-damage drywall partitions, as well as displacement compatibility between these walls and the suspended ceilings. In the braced ceiling experiment, where no connection was made between ceiling grids and surrounding walls no damage in the grid system or partitions was observed. However, at high drift values panel dislodgement was observed on corners of the ceiling where the free ends of grids were not restrained against spreading. This could be prevented by framing the grid ends using a perimeter angle that is riveted only to the grid members while keeping sufficient clearance from the perimeter walls. In the next set of tests with the perimeter-fixed ceiling, no damage was observed in the ceiling system or the drywalls. Based on the results of the experiments it was concluded that the tested ceiling had enough flexibility to accommodate the relative displacement between two perpendicular walls up to the inter-storey drifts achieved. The experiments on perimeter-fixed ceilings were followed by numerical simulations of the performance of these ceilings in a finite element model developed in the structural analysis software, SAP2000. This model was relatively simple and easy to develop and was able to replicate the experimental results to a reasonable degree. Filtering was applied to the experimental output to exclude the effect of high frequency noise and tile-grid impact. The developed model generally simulated the acceleration responses well but underestimated the peak ceiling grid accelerations. This was possibly because the peak values in time histories were affected by impact occurring at very short periods. The model overestimated the axial forces in ceiling grids which was assumed to be caused by the initial assumptions made about the tributary area or constant acceleration associated with each grid line in the direction of excitation. Otherwise, the overall success of the numerical modelling in replicating the experimental results implies that numerical modelling using conventional structural analysis software could be used in engineering practice to analyse alternative ceiling geometries proposed for application to varying structural systems. This however, needs to be confirmed through similar analyses on other ceiling examples from existing instrumented buildings during real earthquakes. As the concluding part of this research the final phase addressed the issues raised following the review of existing ceiling standards and guidelines. The applicability of the research findings to current practice and their implications were discussed. Finally, an example was provided for the design of a suspended ceiling utilising the new knowledge acquired in this research.