Shipping container architecture
Shipping container architecture is a form of architecture that uses steel intermodal containers (shipping containers) as the main structural element. It is also referred to as cargotecture or arkitainer, portmanteau words formed from "cargo" and "architecture". This form of architecture is often associated with the tiny-house movement as well as the sustainable living movement.
The use of containers as building materials has been growing in popularity due to their strength, wide availability, low cost, and eco-friendliness.[1][2]
Advantages
Due to their shape and material, shipping containers have the ability to be customized in many different ways and can be modified to fit various purposes. Standardized dimensions and various interlocking mechanisms make these containers modular, allowing them to be easily combined into larger structures that follow modular design. This also simplifies any extensions to the structure as new containers can easily be added on to create larger structures. When empty, shipping containers can be stacked up to 12 units high.
Because shipping containers are designed to be stacked in high columns and to carry heavy loads, they are also strong and durable. They are designed to resist harsh environments, such as those on ocean-going vessels. Shipping containers conform to standard shipping sizes, which makes pre-fabricated modules easily transportable by ship, truck, or rail.
Shipping container construction is still less expensive than conventional construction, despite metal fabrication and welding being considered specialized labor (which usually increases construction costs). Unlike wood-frame construction, attachments must be welded or drilled to the outer skin, which is more time-consuming, and requires different job site equipment.
As a result of their widespread use, new and used shipping containers are available globally. This availability makes building tiny or container houses more affordable. Depending on the desired specifications and materials used, a container home will often cost less compared to a traditional house[3]
Shipping container construction requires fewer resources, meaning the quantity of traditional building materials needed (e.g. bricks and cement) are reduced. When upcycling shipping containers, thousands of kilograms of steel are saved. For example, a 12 metres (39 ft) long shipping container weighs over 3,500 kilograms (7,700 lb).
Disadvantages
Containers used for human occupancy in an environment with extreme temperature variations will normally have to be better insulated than most brick, block, or wood structures because steel conducts heat very well. Humidity can also affect steel structures, so when moist interior air condenses against the steel, it becomes humid and forms rust if the steel is not sealed and insulated.
While in service, containers may be damaged by friction, handling collisions, and the force of heavy loads overhead during ship transits. Additionally, although the two ends of a container are extremely strong, the roof is not. In the case of a 20 feet (6.1 m)-long container, the roof is built and tested only to withstand a 300 kilograms (660 lb) load, applied to an area of 61 cm by 30.5 cm (2 ft by 1 ft) in the weakest part of the roof.[4] Companies inspect containers, and condemn them if they present cracked welds, twisted frames, or pin holes, among other faults.
Shipping containers possess the capacity to be organized into modular arrangements, thereby creating expansive structures. Nevertheless, deviating from the established standard dimensions, typically 20 feet (6.1 m) or 40 feet (12 m) in length, can engender inefficiencies in terms of both temporal and financial resources. Containers surpassing the 40 feet (12 m) length threshold may encounter challenges during navigation within residential vicinities.
The transportation and construction of shipping container structures can be expensive due to size and weight, and often require the use of cranes or forklifts. This is in contrast to more traditional construction materials like brick or lumber, which can be handled manually and used for construction even at elevated heights.
Obtaining building permits for shipping container homes can be troublesome in regions where municipalities are not familiar with shipping container architecture, because the use of steel for construction is usually for industrial rather than residential structures. In the United States, some shipping container homes have been built outside of various city zoning areas, where no building permits are required.
Chemicals
To meet Australian government shipping quarantine requirements, most container floors are treated with insecticides containing copper (23–25%), chromium (38–45%) and arsenic (30–37%) when manufactured. Chromium and arsenic are known carcinogens. If shipping containers are repurposed for human habitation, these floors should be safely removed, disposed, and replaced. Because shipping containers can carry a wide variety of industrial cargo, spillages or contamination may also occur inside the container, and will have to be cleaned before habitation. Before human habitation, ideally all internal surfaces should be abrasive blasted to bare metal, and re-painted with a non-toxic paint system. Solvents released from paint, and sealants used in manufacture, might also be harmful to human health.
Examples
The use, size, location and appearance of structures based on shipping containers vary widely.
When futurist Stewart Brand needed a place to assemble the material he would use to write How Buildings Learn, he converted a shipping container into an office space in the early 1990s. The conversion process is described in How Buildings Learn itself.
In 2000, the firm Urban Space Management completed a project called Container City I in the Trinity Buoy Wharf area of London. The firm has gone on to complete additional container-based building projects, with more underway. In 2006, the Dutch company Tempohousing finished, in Amsterdam, the biggest container village in the world: 1,000 student homes from modified shipping containers from China.[5]
In 2002, standard ISO shipping containers began to be modified for use as stand-alone on-site wastewater treatment plants. This use of containers creates a cost-effective, modular, and customizable solution to on-site wastewater treatment, eliminating the need for construction of a separate building to house the treatment system.[6]
In 2006, Southern California Architect Peter DeMaria designed the first two-story shipping container home in the U.S., as an approved structural system under the strict guidelines of the nationally recognized Uniform Building Code (UBC). Named the Redondo Beach House, it inspired the creation of Logical Homes, a cargo container–based pre-fabricated home company. In 2007, Logical Homes created its flagship project, the Aegean, for the Computer Electronics Show in Las Vegas, Nevada.
In 2006, Village Underground constructed a series of not-for-profit artists' workspaces in Shoreditch, London. Developing the concept further, Auro Foxcroft constructed recycled shipping container architecture that incorporated retired London Underground carriages.
In 2007, entrepreneur Brian McCarthy developed prototypes of shipping container housing for maquiladora workers in Mexico.[7]
Application in the Live Event & Entertainment Industry
In 2010, German architect and production designer Stefan Beese used six 12 metres (39 ft)-long shipping containers to create a large viewing deck and VIP lounge area for the Voodoo Music Experience, New Orleans, as a substitute for typical grand stand scaffolding. The containers double as storage space for other festival components throughout the year. The two top containers are cantilevered 2.7 metres (8.9 ft) on each side, creating two balconies that are prime viewing locations. Each container was perforated with cutouts spelling the word "VOODOO".
In the United Kingdom, walls of containers filled with sand have been used as large sandbags to protect against flying debris from exploding ceramic insulators in electricity substations.
In October 2013, two barges owned by Google with superstructures made out of shipping containers received media attention amid speculation about their purpose.[8]
Markets
Empty shipping containers are commonly used as market stalls and warehouses in the countries of the former USSR.
The biggest shopping mall or organized market in Europe is made up of alleys formed by stacked containers, on 69 hectares (170 acres) of land, between the airport and the central part of Odesa, Ukraine. Informally named "Tolchok", and officially known as the Seventh-Kilometer Market, it has 16,000 vendors and employs 1,200 security guards and maintenance workers.
In Central Asia, the Dordoy Bazaar in Bishkek, Kyrgyzstan is almost entirely composed of double-stacked containers. It is popular with travelers coming from Kazakhstan and Russia for the cheap prices and plethora of knock off designers.
In 2011, the Cashel Mall in Christchurch, New Zealand reopened in a series of shipping containers, months after it had been destroyed in the earthquake that devastated the city's central business district.[9] Starbucks Coffee has also built a store using shipping containers.[10] A pop-up shopping mall called Boxpark was also created in Shoreditch, London, in 2011, followed by other locations in the Greater London area.[11] A pop-up shopping mall, Common Ground, was created in Seoul, South Korea in 2016.[12]
Other Uses
Shipping containers have also been used as:
- Affordable housing[13]
- Press boxes
- Emergency hurricane shelters for thoroughbred horses
- Concession stands
- Fire training facility[14]
- Military training facility
- Emergency shelters
- School buildings[15]
- Apartment and office buildings
- Artists' studios
- Stores[16]
- Moveable exhibition spaces on rails
- Telco hubs
- Bank vaults
- Medical clinics
- Radar stations
- Shopping malls[17]
- Sleeping rooms
- Recording studios
- Abstract art
- Transportable factories
- Modular data centers (e.g. Sun Modular Datacenter, Portable Modular Data Center)
- Experimental labs
- Combatant temporary containment (ventilated)[18]
- Bathrooms
- Showers
- Starbucks stores (e.g. 6350 N. Broadway, Chicago, IL 60660 USA)[19]
- Workshops
- Intermodal sealed storage on ships, trucks, and trains
- House foundations on unstable seismic zones
- Elevator/stairwell shafts
- Block roads and keep protesters away, as photo journalized during the Pakistan Long March
- Hotels[20]
- Construction trailers
- Mine site accommodations
- Exploration camp
- Aviation maintenance facilities for the United States Marine Corps when loaded onto the SS Wright (T-AVB-3) or the SS Curtiss (T-AVB-4)
- RV campers
- Food trucks
- Hydroponics farms
- Battery storage units
- Temporary prisons[21]
- Intensive-care units in temporary hospitals during the COVID-19 pandemic[22]
Alternative Housing & Architecture
The abundance and relative cheapness of these containers during the last decade comes from the deficit in manufactured goods coming from North America in the last two decades. These manufactured goods come to North America from Asia and, to a lesser extent, Europe, in containers that often have to be shipped back empty, or "deadhead", at considerable expense. It is often cheaper to buy new containers in Asia than to ship old ones back. Therefore, new applications are sought for the used containers that have reached their North American destination.
Containers have been utilized by architects and individuals to build diverse structures, including homes, offices, apartments, schools, dormitories, artists studios, and emergency shelters. Additionally, containers have found use as swimming pools and temporary secure spaces on construction sites and other venues.
CONEX containers were developed by Malcom McLean to standardize the intermodal shipping unit. CONEX containers may or may not meet the requirements of local building codes. As they are not field erected, a registered engineer or architect must verify that the containers comply with the structural requirements of the building code. The 2021 ICC[23] code was amended to address CONEX containers.
Phillip C. Clark filed for a United States patent on November 23, 1987, described as "Method for converting one or more steel shipping containers into a habitable building at a building site and the product thereof". This patent was granted August 8, 1989 as patent 4854094. The patent documentation shows what are possibly the earliest recorded plans for constructing shipping container housing and shelters by laying out some very basic architectural concepts. Regardless, the patent may not have represented novel invention at its time of filing. Paul Sawyers previously described extensive shipping container buildings used on the set of the 1985 film Space Rage Breakout on Prison Planet.
Other examples of earlier container architecture concepts include a 1977 report entitled "Shipping Containers as Structural Systems",[24] investigating the feasibility of using 20 feet (6.1 m) shipping containers as structural elements by the US military.
During the 1991 Gulf War, containers saw considerable nonstandard uses, not only as makeshift shelters, but also for housing of US soldiers. The shipping containers were equipped with air conditioning units and provided shelter as well as protection from artillery shelling.
It has been rumored that some shipping containers were used for transportation of Iraqi prisoners of war, with holes cut in the containers to allow for ventilation. Containers continue to be used for military shelters, often additionally fortified by adding sandbags to the side walls, to protect against weapons such as rocket-propelled grenades ("RPGs").
Media
Shipping container architecture has inspired the reality television series Containables (DIY) and Container Homes (HGTV), in addition to being featured in episodes of Grand Designs (Channel 4) and Amazing Interiors (Netflix).
See also
References
- Dawson, Rachel (3 November 2021). "Are Container Homes Sustainable? | 5 Great Ways to Make an Eco-Friendly Container Home | Container Home Hub". Retrieved 6 December 2022.
- Kiil, Rene (11 April 2021). "Why and How Shipping Container Houses are Environmentally-Friendly?". Eco-friendly, Pre-built and Mobile Tiny House I Popuphut. Retrieved 6 December 2022.
- "5 Reasons why Shipping Container Homes are Popular in Other countries". Neuvasa: Fully Furnished Luxury Container Homes. 3 April 2021. Retrieved 8 April 2021.
- "Shipping containers and Building Code Requiremrnts". www.residentialshippingcontainerprimer.com. Retrieved 3 August 2020.
The roof load test is 660 lbs over an area of 2' x 1' applied to the weakest part of the roof. The load is usually applied at the center of the containers positioned with the 2' dimension aligned longitudinally. Thus the roof is able to support an imposed load of a minimum of 330 lbs/sq. ft. The design is easily capable of supporting the basic snow loads of 30 lbs per sq. ft. evenly distributed.
- Cookson, Robert (21 January 2009). "Hotel changes the landscape of building". Financial Times. Retrieved 5 May 2021.
- "US Patent for System and method of manufacturing transportable buildings Patent (Patent # 10,633,877 issued April 28, 2020) - Justia Patents Search". patents.justia.com. Retrieved 22 August 2023.
- "Shipping containers could be 'dream' homes for thousands". CNN. 24 September 2008. Archived from the original on 12 December 2008. Retrieved 5 May 2021.
- Daniel Terdiman (25 October 2013). "Is Google building a hulking floating data center in SF Bay?". CNET. Archived from the original on 30 October 2013.
- Matthew Backhouse (29 October 2011). "Container mall open for business". New Zealand Herald.
- Falk, Tyler (17 January 2012). "Starbucks opens store made from recycled shipping containers". SmartPlanet. Retrieved 19 May 2014.
- Fry, Simon (26 January 2017). "Boxing clever: The firms based in shipping containers". BBC.
- Wong, Lucy (8 November 2016). "World's largest shipping container shopping mall pops up in Seoul". inhabitat.
- Constantineau, Bruce (31 July 2013). "Vancouver social housing built from shipping containers". Vancouver Sun. Retrieved 5 May 2021.
- "Building a Fire Training Facility". Retrieved 20 December 2016.
- "Costa Mesa Waldorf School is Made From 32 Recycled Shipping Containers". 30 September 2014. Retrieved 20 December 2016.
- Garone, Elizabeth (3 November 2014). "A New Use for Shipping Containers: Stores". Wall Street Journal. ISSN 0099-9660. Retrieved 20 December 2016.
- "This shopping mall in Seoul is made entirely of shipping containers". Business Insider. Retrieved 20 December 2016.
- "Escape From An Eritrean Prison". NPR.org. Retrieved 20 December 2016.
- "Broadway & Devon: Starbucks Coffee Company". www.starbucks.com. Retrieved 30 August 2017.
- "Shipping Container Hotel". HuffPost. Retrieved 20 December 2016.
- Aaltonen, Riikka (14 July 2017). "Tältä näyttää Suomen ensimmäinen siirrettävä moduulivankila – Oulun poliisilaitoksen väistötilat saivat käyttöönottoluvan torstaina". Kaleva (in Finnish). Oulu, Finland. Retrieved 27 September 2018.
- Wainwright, Oliver (27 March 2020). "Architect in Italy turns shipping containers into hospitals for treating Covid-19". The Guardian.
- "2019 ICC G5 GUIDELINE FOR THE SAFE USE OF ISO CONTAINERS | ICC DIGITAL CODES". codes.iccsafe.org. Retrieved 19 September 2022.
- Shipping Containers as Structural Systems (Report).
Further reading
- Books
- Kotnik, Jure (2008). Container Architecture. p. 240. ISBN 978-8496969223
- Sawyers, Paul (2005, 2008). Intermodal Shipping Container Small Steel Buildings. p 116. ISBN 978-1438240329
- Bergmann, Buchmeier, Slawik, Tinney (2010). Container Atlas: A Practical Guide to Container Architecture. p. 256. ISBN 978-3899552867
- Minguet, Josep Maria (2013). Sustainable Architecture: Containers2. p. 111. ISBN 978-8415829317
- Kramer, Sibylle (2014). The Box Architectural Solutions with Containers. p. 182. ISBN 978-3037681732
- Broto, Carles (2015). Radical Container Architecture. p. 240. ISBN 978-8490540558
- Journals
- Broeze, Frank (1 December 2000). The Globalisation of the Oceans. Liverpool University Press. doi:10.5949/liverpool/9780973007336.001.0001. ISBN 978-0-9730073-3-6.
- Helsel, Sand 'Future Shack: Sean Godsell's prototype emergency housing redeploys the ubiquitous shipping container' Architecture Australia, September–October 2001
- Myers, Steven Lee 'From Soviet-Era Flea Market to a Giant Makeshift Mall', The New York Times, May 19, 2006