These so-called spreadsheet towers populate every major city. They signalled modernity and provided huge profits for those who built them. But these buildings are profligate users of fuels for light, power and services.
Most developed world cities started building skyscrapers after the second world war. These buildings were International Style architecture, unrecognisable is terms of a particular locale, universal in terms of their ubiquitous metal, concrete, glass – and fully air-conditioned. Now they are ageing, their use-by date is up and their balance sheet profitability no longer attracts.
The question is: how do we safely dismantle these high-rise structures, which are generally located in busy cities?
Reminders of the dangers of explosive demolition are tragedies such as the death of 12-year-old Katie Bender. She was struck by flying debris when the Royal Canberra Hospital was razed in 1997 to make way for the new National Museum of Australia.
A recent demolition, and the tallest ever to be unbuilt, is 270 Park Avenue, New York City. Its 52 floors were built in 1960 for the Union Carbide chemical company. The building was for 50 years the tallest ever designed by a female architect (Natalie de Bios of Skidmore, Owings and Merrill. Is that another low hit for gender equality?) Its replacement by architects Norman Foster will be twice as high.
The business of disassembling these skyscrapers is just now developing, but it will gain pace as more become obsolete.
Some still get imploded, but usually, in a busy city, demolition techniques must be unobtrusive, as quiet and clean as possible. The techniques used for cleaning up the World Trade Centre testify to the wastefulness of a more destructive approach.
Plenty of clever techniques to demolish exist. Some start at the base and work up, others in reverse.
The 40-storey Akasaka Prince Hotel in Tokyo was slowly demolished in 2012-13 using a technique where a cap was built on top of the building. It was stripped floor by floor as the cap was lowered, so all the dust, mess and debris was contained and removed with no effect on the environment.
Buildings are wrapped in scaffold and protective fabric then literally dismantled in the reverse order to which they were built. In the process building waste can be recycled and reused rather than dumped.
Reverse building involves removing the glass, then the frames, taking off the wall cladding, then scraping away at the concrete and steel frames bit by bit. Concrete is removed to expose the steel reinforcing bars, which are then separately removed and recycled. In the process unwanted material can be uncovered, like asbestos, which needs particular care in handling.
Interiors are unbuilt the same way – remove floor coverings, cupboards, doors and lightweight walls, strip the electrical wiring and pipes, take out air conditioning and lifts, remove stairs and escalators.
These removalists act smartly, as materials and fabric are recycled and often reused for another building. It is a sustainable way of dealing with the issue. Things that might normally have been reduced to dust and mud by destruction are instead usefully salvaged and recovered for an extended life cycle.
As part of the benefits of this procedure, unbuilding provides large numbers of construction jobs and associated employment in transportation, waste management and recycling.
It also provides new construction sites. This means cities need not expand beyond existing boundaries and the infrastructure of services, roads and public transport need not be extended.
What has interested those involved with this work is the capacity of building designers (let’s call them architects) to creatively improve their buildings in terms of life after use-by date. Techniques are being developed that assist in unbuilding and salvaging materials, even down to basic principles such as ease of access to pipes and wires, modular components and simplified connection practices.
The logic is that clarity of building structure and services makes retrieval simpler. Less complexity of materials and components means a building can be untangled more efficiently.
Fastening devices can be simplified and mechanical (rather than using glues and sealants), toxic materials avoided, materials selected with an afterlife in mind and structures designed for simplicity and accessibility. Also important is a clear set of as-built documents that map the original building so it can be disassembled.
Clear design thinking will have value for unbuilding and recycling in the future.
The construction industry is a main consumer of fuels, timber, steel and other metals, concrete and plastics. That demand drives the logging of forests, mining and extraction, leading to material production and transport that contributes to emissions and pollution.
The UK Green Building Council estimates the construction industry generates about 22% of UK carbon emissions, uses 40% of drinking water, contributes 50% to climate change and over half our landfill waste, and accounts for 39% of global energy use. The US Environmental Protection Agency (EPA) also reports that the industry contributes to asthma and lung cancer by producing radon via contaminated applied finishes (paint).
Driving the need for much greater reuse of old building materials is an awareness of the fragility of our resources and the energy we use to consume them.
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