© 2018 Springer Nature B.V. This study compares seismic losses considering initial construction costs and direct-repair costs for New Zealand steel moment-resisting frame buildings with friction connections and those with extended bolted-end-plate connections. A total of 12 buildings have been designed and analysed considering both connection types, two building heights (4-storey and 12-storey), and three locations around New Zealand (Auckland, Christchurch, and Wellington). It was found that buildings with friction connections required design to a higher design ductility, yet are generally stiffer due to larger beams being required to satisfy higher connection overstrength requirements. This resulted in the frames with friction connections experiencing lower interstorey drifts on most floors but similar peak total floor accelerations, and subsequently incurring lower drift-related seismic repair losses. Frames with friction connections tended to have lower expected net-present-costs within 50 years of the building being in service for shorter buildings and/or if located in regions of high seismicity. None of the frames with friction connections in Auckland showed any benefits due to the low seismicity of the region.
Observations made in past earthquakes, in New Zealand and around the world, have highlighted the vulnerability of non-structural elements such as facades, ceilings, partitions and services. Damage to these elements can be life-threatening or jeopardise egress routes but typically, the main concern is the cost and time associated with repair works. The Insurance Council of New Zealand highlighted the substantial economic losses in recent earthquakes due to poor performance of non-structural elements. Previous inspections and research have attributed the damage to non-structural elements principally to poor coordination, inadequate or lack of seismic restraints and insufficient clearances to cater for seismic actions. Secondary issues of design responsibility, procurement and the need for better alignment of the various Standards have been identified. In addition to the compliance issues, researchers have also demonstrated that current code provisions for non-structural elements, both in New Zealand and abroad, may be inadequate. This paper first reviews the damage observed against the requirements of relevant Standards and the New Zealand Building Code, and it appears that, had the installations been compliant, the cost of repair and business interruption would have been substantially less. The second part of the paper highlights some of the apparent shortcomings with the current design process for non-structural elements, points towards possible alternative strategies and identifies areas where more research is deemed necessary. The challenge of improving the seismic performance of non-structural elements is a complex one across a diverse construction industry. Indications are that the New Zealand construction industry needs to completely rethink the delivery approach to ensure an integrated design, construction and certification process. The industry, QuakeCentre, QuakeCoRE and the University of Canterbury are presently working together to progress solutions. Indications are that if new processes can be initiated, better performance during earthquakes will be achieved while delivering enhanced building and business resilience.
Following the recent earthquakes in Chile (2010) and New Zealand (2010/2011), peculiar failure modes were observed in Reinforced Concrete (RC) walls. These observations have raised a global concern on the contribution of bi-directional loading to these failure mechanisms. One of the failure modes that could potentially result from bidirectional excitations is out-of-plane shear failure. In this paper an overview of the recent experimental and numerical findings regarding out-of-plane shear failure in RC walls are presented. The numerical study presents the Finite Element (FE) simulation of wall D5-6 from the Grand Chancellor Hotel that failed in shear in the out-of-plane direction in the February 2011 Christchurch earthquake. The main objective of the numerical study was to investigate the reasons for this failure mode. The experimental campaign includes the recent experiments conducted in the Structural Engineering Laboratory of the University of Canterbury. The experimental study included three rectangular slender RC walls designed based on NZS3101: 2006-A3 (2017) for three different ductility levels, namely: nominally ductile, limited ductile and ductile. The numerical results showed that high axial load combined with bi-directional loading caused the out-of-plane shear failure in wall D5-6 from the Grand Chancellor Hotel. This was also confirmed and further investigated in the experimental phase of the study.
Natural hazard reviews reveal increases in disaster impacts nowhere more pronounced than in coastal settlements. Despite efforts to enhance hazard resilience, the common trend remains to keep producing disaster prone places. This paper explicitly explores hazard versus multi-hazard concepts to illustrate how different conceptualizations can enhance or reduce settlement resilience. Understandings gained were combined with onthe-ground lessons from earthquake and flooding experiences to develop of a novel ‘first cut’ approach for analyzing key multi-hazard interconnections, and to evaluate resilience enhancing opportunities. Traditional disaster resilience efforts often consider different hazard types discretely. However, recent events in Christchurch, a New Zealand city that is part of the 100 Resilient Cities network, highlight the need to analyze the interrelated nature of different hazards, especially for enhancing lifelines system resilience. Our overview of the Christchurch case study demonstrates that seismic, hydrological, shallow-earth, and coastal hazards can be fundamentally interconnected, with catastrophic results where such interconnections go unrecognized. In response, we have begun to develop a simple approach for use by different stakeholders to support resilience planning, pre and post disaster, by: drawing attention to natural and built environment multi-hazard links in general; illustrating a ‘first cut’ tool for uncovering earthquake-flooding multi-hazard links in particular; and providing a basis for reviewing resilience strategy effectiveness in multi-hazard prone environments. This framework has particular application to tectonically active areas exposed to climate-change issues.
Natural catastrophes are increasing worldwide. They are becoming more frequent but also more severe and impactful on our built environment leading to extensive damage and losses. Earthquake events account for the smallest part of natural events; nevertheless seismic damage led to the most fatalities and significant losses over the period 1981-2016 (Munich Re). Damage prediction is helpful for emergency management and the development of earthquake risk mitigation projects. Recent design efforts focused on the application of performance-based design engineering where damage estimation methodologies use fragility and vulnerability functions. However, the approach does not explicitly specify the essential criteria leading to economic losses. There is thus a need for an improved methodology that finds the critical building elements related to significant losses. The here presented methodology uses data science techniques to identify key building features that contribute to the bulk of losses. It uses empirical data collected on site during earthquake reconnaissance mission to train a machine learning model that can further be used for the estimation of building damage post-earthquake. The first model is developed for Christchurch. Empirical building damage data from the 2010-2011 earthquake events is analysed to find the building features that contributed the most to damage. Once processed, the data is used to train a machine-learning model that can be applied to estimate losses in future earthquake events.
Field trips are one of the most critical pieces of learning for students in sciences like geology, biology, and geography. Virtual field trips (VFT) are being increasingly considered as sophisticated and effective forms of teaching, especially with the rise of new technologies and the growing demand for more inclusive classroom environments. This research developed a virtual field trip for Tertiary students in an introductory-level geology course (GEOL 113: Environmental Geohazards) at the University of Canterbury. This initiative was in partnership with LEARNZ – a highly esteemed virtual fieldtrip team run by CORE Education that creates successful VFTs for Primary and Secondary students in New Zealand. Key components of the Tertiary VFT include a student acting as the virtual field trip teacher interviewing experts and leading the field trip, web-based background material, online assessment, and photos. In two successive academic years, students participated in the VFT during lectures and as pre class assignments prior to a one-day earthquake hazards workshop. In 2016, the virtual field trip used the LEARNZ web platform and occurred synchronously with the class; in 2017 the virtual fieldtrip reused the video, images and word documents from the previous year with the addition of a Google Earth component and with no reliance on the LEARNZ web platform. The goals of the trip were designed to prepare students for the earthquake hazards workshop, in which students analysed earthquake impacts over varying timescales and then applied that knowledge to develop strategies for the recovery of three crucial industries (dairy, mining, or tourism) on the West Coast of New Zealand’s South Island. In both years, number of clicks data showed that students interacted with online material far more during this week of the course than any other. Following the synchronous version in 2016, the students who were surveyed reported (1) they enjoyed the trip, (2) they found background material useful for preparation for the trip and the workshop, and (3) the additional work was at the appropriate level. Despite predominantly positive responses from the students, we experienced some negative feedback from participating staff mainly associated with stress and technical difficulties in running the synchronous VFT. With the asynchronous trip in 2017, staff reported a highly positive overall experience, with a perceived enhanced interaction with class during lecture time, and an increased and enhanced engagement with course material outside of class. The student survey again showed that the majority of students surveyed enjoyed the virtual fieldtrip, and that it was useful preparation for the workshop. Additionally, they reported an improved link between earth processes and society, which was a key overarching aim for the course. We propose that the synchronous version poses more excitement and immersion in the field environment, whereas the reuse of the asynchronous version increases the utility (and hence value for money) of the trip, and minimises technical difficulties and lecturer stress. Additionally, re-using the material in the asynchronous version offered opportunities to improve and supplement the past content, such as the incorporation of following an annotated trip path in Google Earth. As recommendations for others interested in developing virtual fieldtrips, we report that the design of a virtual fieldtrip should include (1) Goal-aligned content and assessment for both practice and marks, (2) a student and instructor experience that is authentic and flexible to both the people and the place. We suggest that these aims can be achieved whatever the budget or timeframe and make our material freely available at https://serc.carleton.edu/index.html.