An entry from Gallivanta's blog for 4 November 2012 entitled, "Sanitarium Factory Garden".
Oscar von Sierakowski’s factory and shop was built on the corner of Colombo and Tuam Streets in 1906. It boasted that it was the largest wire work factory in the colonies, producing decorati…
A photograph of the factory building at 5 Olliviers Street.
Kerry Munro was at his glass factory when the earthquake struck.
A photograph of a window of the factory building at 5 Olliviers Street.
A photograph of the earthquake damage to the factory building at 5 Olliviers Street.
Scene set at Santa Claus' 'Online Christmas Orders Dept' at the North Pole. One elf remarks 'ANOTHER Marmite order from New Zealand'. The sole Marmite factory in New Zealand was damaged in the Christchurch Earthquake of 2011. Further aftershocks led to the shutting down of the factory until late 2012. The remaining stocks ran out, leading to panic buying at inflated prices by Marmite aficionados. Quantity: 1 digital cartoon(s).
Santarium is cutting 36 jobs in Christchurch as it pulls out of manufacturing Weetbix in the city. The final engineering report on the site says the factory's tower block is an earthquake risk, and demolition starts tomorrow.
Photograph captioned by Fairfax, "Makana Chocolate Factory. From left pastry chef/chocolatier Mel Chen, Marlborough Red Cross vice president Edity McKay and Makana retail manager Heloise Shand. Edith accepted a cheque for $4,000 from Makana to go to the Christchurch earthquake fund".
Cleaning up Manning Signs of the silt from liquefaction. Three fellow workers man the shovels while two building engineers talk to the boss (hidden). After doing the car park we then turned our hands to the inside of the factory, once clearance was given that we could go inside.
A video about people buying marmite from the Fresh Choice supermarket in Merivale. The supermarket has a secret stash of marmite which they have made available to customers in exchange for a bank note. The bank notes will be donated to the Christchurch Women's Refuge. Marmite went missing from supermarket shelves across the country after the 22 February 2011 earthquake damaged the factory in Christchurch.
A review of the week's news including... National MP Todd Barclay falls on his sword while Labour is in damage control, the decision to not prosecute the Pike River Mine CEO is to be contested in the Supreme Court, the lawyer for Akshay Chand says she sought bail on his behalf believing his mother and aunt would monitor his every movement, The Education Ministry is forced to apologise for its flawed handling of school closures and mergers after the 2011 Canterbury earthquake, The Health Minister is forced to defend his embattled Ministry following a major budget blunder, employment lawyers aren't surprised another health sector group is taking a pay equity claim, Ministry for Primary Industries officials come under fire at a packed Stewart Island public meeting on the cull of the island's farmed oysters, it's Plan B for a crowd funded initiative that wants to take control of Dunedin's Cadbury factory and All Black great Sir Colin 'pinetree' Meads has been immortalised in bronze.
Previous earthquakes demonstrated destructive effects of soil-structure interaction on structural response. For example, in the 1970 Gediz earthquake in Turkey, part of a factory was demolished in a town 135 km from the epicentre, while no other buildings in the town were damaged. Subsequent investigations revealed that the fundamental period of vibration of the factory was approximately equal to that of the underlying soil. This alignment provided a resonance effect and led to collapse of the structure. Another dramatic example took place in Adapazari, during the 1999 Kocaeli earthquake where several foundations failed due to either bearing capacity exceedance or foundation uplifting, consequently, damaging the structure. Finally, the Christchurch 2012 earthquakes have shown that significant nonlinear action in the soil and soil-foundation interface can be expected due to high levels of seismic excitation and spectral acceleration. This nonlinearity, in turn, significantly influenced the response of the structure interacting with the soil-foundation underneath. Extensive research over more than 35 years has focused on the subject of seismic soil-structure interaction. However, since the response of soil-structure systems to seismic forces is extremely complex, burdened by uncertainties in system parameters and variability in ground motions, the role of soil-structure interaction on the structural response is still controversial. Conventional design procedures suggest that soil-structure interaction effects on the structural response can be conservatively ignored. However, more recent studies show that soil-structure interaction can be either beneficial or detrimental, depending on the soil-structure-earthquake scenarios considered. In view of the above mentioned issues, this research aims to utilise a comprehensive and systematic probabilistic methodology, as the most rational way, to quantify the effects of soil-structure interaction on the structural response considering both aleatory and epistemic uncertainties. The goal is achieved by examining the response of established rheological single-degree-of-freedom systems located on shallow-foundation and excited by ground motions with different spectral characteristics. In this regard, four main phases are followed. First, the effects of seismic soil-structure interaction on the response of structures with linear behaviour are investigated using a robust stochastic approach. Herein, the soil-foundation interface is modelled by an equivalent linear cone model. This phase is mainly considered to examine the influence of soil-structure interaction on the approach that has been adopted in the building codes for developing design spectrum and defining the seismic forces acting on the structure. Second, the effects of structural nonlinearity on the role of soil-structure interaction in modifying seismic structural response are studied. The same stochastic approach as phase 1 is followed, while three different types of structural force-deflection behaviour are examined. Third, a systematic fashion is carried out to look for any possible correlation between soil, structural, and system parameters and the degree of soil-structure interaction effects on the structural response. An attempt is made to identify the key parameters whose variation significantly affects the structural response. In addition, it is tried to define the critical range of variation of parameters of consequent. Finally, the impact of soil-foundation interface nonlinearity on the soil-structure interaction analysis is examined. In this regard, a newly developed macro-element covering both material and geometrical soil-foundation interface nonlinearity is implemented in a finite-element program Raumoko 3D. This model is then used in an extensive probabilistic simulation to compare the effects of linear and nonlinear soil-structure interaction on the structural response. This research is concluded by reviewing the current design guidelines incorporating soil-structure interaction effects in their design procedures. A discussion is then followed on the inadequacies of current procedures based on the outcomes of this study.