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Images for insulation; more images...

Images, UC QuakeStudies

A photograph of a room in the Diabetes Centre. The panelling has been removed from the walls, exposing the wooden framing, insulation, and wires underneath. Tarpaulins have been draped over the furniture.

Images, UC QuakeStudies

Broken panelling on a building on Colombo Street has exposed the interior of the walls. The photographer comments, "Seen in the Christchurch Earthquake Red Zone. If you saw this anywhere else in the world you would have thought that it was a piece of modern art".

Images, UC QuakeStudies

A house on Canterbury Street in Lyttelton with a damaged outer wall. The bricks have fallen away to expose the insulation. Cracks can be seen running diagonally along the remaining wall. Fencing and tape have been placed around the building to warn people off.

Images, UC QuakeStudies

A photograph of a room in the Diabetes Centre. The panelling has been removed from the walls, exposing the wooden framing, insulation, and wires underneath. Several drawer units have been stacked in the middle of the room.

Images, UC QuakeStudies

A photograph of a corridor in the Diabetes Centre. The panelling has been taken off the walls in some of the adjoining rooms, exposing the wooden frames, insulation, and wires underneath. Plastic sheeting has been used to cover the carpet and furniture throughout.

Research papers, University of Canterbury Library

Asset management in power systems is exercised to improve network reliability to provide confidence and security for customers and asset owners. While there are well-established reliability metrics that are used to measure and manage business-as-usual disruptions, an increasing appreciation of the consequences of low-probability high-impact events means that resilience is increasingly being factored into asset management in order to provide robustness and redundancy to components and wider networks. This is particularly important for electricity systems, given that a range of other infrastructure lifelines depend upon their operation. The 2010-2011 Canterbury Earthquake Sequence provides valuable insights into electricity system criticality and resilience in the face of severe earthquake impacts. While above-ground assets are relatively easy to monitor and repair, underground assets such as cables emplaced across wide areas in the distribution network are difficult to monitor, identify faults on, and repair. This study has characterised in detail the impacts to buried electricity cables in Christchurch resulting from seismically-induced ground deformation caused primarily by liquefaction and lateral spread. Primary modes of failure include cable bending, stretching, insulation damage, joint braking and, being pulled off other equipment such as substation connections. Performance and repair data have been compiled into a detailed geospatial database, which in combination with spatial models of peak ground acceleration, peak ground velocity and ground deformation, will be used to establish rigorous relationships between seismicity and performance. These metrics will be used to inform asset owners of network performance in future earthquakes, further assess component criticality, and provide resilience metrics.