Fazlur Rahman Khan: Difference between revisions
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==Innovations== |
==Innovations== |
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Dr. Fazlur Khan's design innovations improved the construction of high-rise buildings, enabling them to withstand enormous forces generated on these super structures. These new designs opened an economic door for contractors, engineers, architects, and investors, providing vast amounts of real estate space on minimal plots of land. |
Dr. Fazlur Khan's design innovations improved the construction of high-rise buildings, enabling them to withstand enormous forces generated on these super structures. These new designs opened an economic door for contractors, engineers, architects, and investors, providing vast amounts of real estate space on minimal plots of land. |
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[[Image:Johnhancock.jpg|left|thumb|The [[John Hancock Center]], designed by Fazlur Khan and completed in 1969.]] |
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He is noted for his efficient designs for Chicago’s 100-story [[John Hancock Center]] and 110-story [[Sears Tower]], the tallest building in the world in its time and still the tallest in the United States since its completion in 1974. He is also responsible for designing notable buildings in Bangladesh. |
He is noted for his efficient designs for Chicago’s 100-story [[John Hancock Center]] and 110-story [[Sears Tower]], the tallest building in the world in its time and still the tallest in the United States since its completion in 1974. He is also responsible for designing notable buildings in Bangladesh. |
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[[Image:Sears Tower and 311 South Wacker.jpg|right|thumb|[[Sears Tower]], designed by Fazlur Khan, was the tallest building in the world at the time of its construction]] |
[[Image:Sears Tower and 311 South Wacker.jpg|right|thumb|[[Sears Tower]], designed by Fazlur Khan and completed in 1974, was the tallest building in the world at the time of its construction]] |
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Khan's central innovation in [[skyscraper design and construction]] was the idea of the [[Tube (structure)|"tube" and "bundled tube"]] structural systems for tall buildings.[http://darkwing.uoregon.edu/~struct/resources/pencil/systems/sys13.htm][http://darkwing.uoregon.edu/~struct/resources/pencil/systems/sys14.htm] Afteer 1965, this new structural system of framed tubes was influential in [[skyscraper design and construction]]. Khan defined the framed tube structure as "a three dimensional space structure composed of three, four, or possibly more frames, braced frames, or shear walls, joined at or near their edges to form a vertical tube-like structural system capable of resisting lateral forces in any direction by cantilevering from the foundation."<ref>{{Cite web| title = Evolution of Concrete Skyscrapers| accessdate = 2007-05-14| url = http://www.civenv.unimelb.edu.au/ejse/Archives/Fulltext/200101/01/20010101.htm }}</ref> Closely spaced interconnected exterior columns form the tube. Horizontal loads, for example wind, are supported by the structure as a whole. About half the exterior surface is available for windows. Framed tubes allow fewer interior columns, and so create more usable floor space. Where larger openings like garage doors are required, the tube frame must be interrupted, with transfer girders used to maintain structural integrity. The first building to apply the tube-frame construction was in the DeWitt-Chestnut apartment building which Khan designed in [[Chicago]]. This laid the foundations for the tube structures used in most later skyscrapers, as can been seen in the [[construction of the World Trade Center]]. |
Khan's central innovation in [[skyscraper design and construction]] was the idea of the [[Tube (structure)|"tube" and "bundled tube"]] structural systems for tall buildings.[http://darkwing.uoregon.edu/~struct/resources/pencil/systems/sys13.htm][http://darkwing.uoregon.edu/~struct/resources/pencil/systems/sys14.htm] Afteer 1965, this new structural system of framed tubes was influential in [[skyscraper design and construction]]. Khan defined the framed tube structure as "a three dimensional space structure composed of three, four, or possibly more frames, braced frames, or shear walls, joined at or near their edges to form a vertical tube-like structural system capable of resisting lateral forces in any direction by cantilevering from the foundation."<ref>{{Cite web| title = Evolution of Concrete Skyscrapers| accessdate = 2007-05-14| url = http://www.civenv.unimelb.edu.au/ejse/Archives/Fulltext/200101/01/20010101.htm }}</ref> Closely spaced interconnected exterior columns form the tube. Horizontal loads, for example wind, are supported by the structure as a whole. About half the exterior surface is available for windows. Framed tubes allow fewer interior columns, and so create more usable floor space. Where larger openings like garage doors are required, the tube frame must be interrupted, with transfer girders used to maintain structural integrity. The first building to apply the tube-frame construction was in the DeWitt-Chestnut apartment building which Khan designed in [[Chicago]]. This laid the foundations for the tube structures used in most later skyscrapers, as can been seen in the [[construction of the World Trade Center]]. |
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Another innovation that Khan developed was the concept of X-bracing. This concept reduced the lateral load on the building by transferring the load into the exterior columns. This allows for a reduced need for interior columns thus creating more floor space. This concept can be seen in the John Hancock Center, built in 1969 |
Another innovation that Khan developed was the concept of X-bracing. This concept reduced the lateral load on the building by transferring the load into the exterior columns. This allows for a reduced need for interior columns thus creating more floor space. This concept can be seen in the John Hancock Center, built in 1969 One of the most famous buildings of the [[Structural Expressionism|structural expressionist]] style, the skyscraper's distinctive X-bracing exterior is actually a hint that the structure's skin is indeed part of its 'tubular system'. This idea is one of the architectural techniques the building used to climb to record heights (the tubular system is essentially the spine that helps the building stand upright during wind and earthquake loads). This X-bracing allows for both higher performance from tall structures and the ability to open up the inside floorplan (and usable floor space) if the architect desires. Original features such as the skin, pioneered by Fazlur Khan, have made the John Hancock Center an architectural icon. |
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The first [[sky lobby]] was also designed by Khan for the John Hancock Center. Later buildings with sky lobbies include the [[World Trade Center]], [[Petronas Twin Towers]] and [[Taipei 101]]. The 44th-floor sky lobby of the John Hancock Center also features the first [[high-rise]] indoor [[swimming pool]], which remains the highest in America.<ref name=Emporis>[http://www.emporis.com/en/wm/bu/?id=116876 John Hancock Center], [[Emporis]]</ref> |
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==Professional Milestones== |
==Professional Milestones== |
Revision as of 00:04, 13 September 2008
Fazlur Rahman Khan | |
---|---|
Born | April 3 1929 |
Died | March 27, 1982 | (aged 52)
Nationality | Bangladeshi |
Education | BUET |
Occupation | Engineer |
Engineering career | |
Discipline | Civil, |
Significant design | Sears Tower |
Fazlur Rahman Khan (Bengali: ফজলুর রহমান খান Fozlur Rôhman Khan) (April 3, 1929 - March 27, 1982), born in Dhaka, Bengal (now Bangladesh), was a Bangladeshi American structural engineer. He is regarded as the "Einstein of structural engineering" and considered "the greatest structural engineer of the second half of the 20th century" for his constructions of the Sears Tower and John Hancock Center, and for his designs of structural systems that remain fundamental to all high-rise skyscrapers, including the tube structure, X-bracing and sky lobby designs.[1]
Biography
Fazlur Rahman Khan hails from the village of Bhandarikandi in Shibchar Upazila, Madaripur District, Dhaka Division. He was born on 3 April 1929, in Dhaka. His father, Khan Bahadur Abdur Rahman Khan, was a renowned educationist and high government official in the education department.
Khan completed his undergraduate coursework at the Bengal Engineering College, University of Calcutta (Now Bengal Engineering & Science University, Shibpur). He received his bachelor’s degree from the University of Dhaka in 1951 while placing first in his class. A Fulbright Scholarship and a Pakistani government scholarship enabled him to travel to the United States in 1952 where he pursued advanced studies at the University of Illinois at Urbana-Champaign. In three years Khan earned two Master's degrees — one in structural engineering and one in theoretical and applied mechanics — and a PhD in structural engineering.
In 1955, employed by Skidmore, Owings and Merrill, he began working in Chicago, Illinois.
One of the foremost structural engineers of the 20th century, Fazlur Khan epitomized both structural engineering achievement and creative collaborative effort between architect and engineer. He believed that "only when architectural design is grounded in structural realities — thus celebrating architecture's nature as a constructive art, rooted in the earth — can the resulting aesthetics … have a transcendental value and quality."
Fazlur Khan's personal papers are held by the Ryerson and Burnham Archives at The Art Institute of Chicago.
Education
As a boy, Khan's father instilled in him the importance of an education, not only early education but a continued education. For this reason, Khan went to undergraduate school and then graduate school. Although Khan was finished with school and now in the workforce, he still continued to learn. He taught himself how to program the new computer system which SOM purchased in 1961. He then taught his colleagues how to use the new programs.
Khan realized the value of his education and encouraged his daughter Yasmin along a similar path. However, he did not push her into structural engineering, she found her passion for this on her own. Her experiences with her father influenced her education and her work. Yasmin later wrote many articles and books including Engineering Architecture: The Vision of Fazlur R. Khan, a tribute to her father.
Personal Interests
Outside of work, Khan enjoyed spending time with his family (wife Liselotte and daughter Yasmin). He enjoyed singing, poetry, and table tennis. He was also heavily involved with creating public opinion and garnering emergency funding for Bengali people during the 1971 Bangladesh Liberation War. He created the Chicago-based organization known as Bangladesh Emergency Welfare Appeal.
Innovations
Dr. Fazlur Khan's design innovations improved the construction of high-rise buildings, enabling them to withstand enormous forces generated on these super structures. These new designs opened an economic door for contractors, engineers, architects, and investors, providing vast amounts of real estate space on minimal plots of land.
He is noted for his efficient designs for Chicago’s 100-story John Hancock Center and 110-story Sears Tower, the tallest building in the world in its time and still the tallest in the United States since its completion in 1974. He is also responsible for designing notable buildings in Bangladesh.
Khan's central innovation in skyscraper design and construction was the idea of the "tube" and "bundled tube" structural systems for tall buildings.[1][2] Afteer 1965, this new structural system of framed tubes was influential in skyscraper design and construction. Khan defined the framed tube structure as "a three dimensional space structure composed of three, four, or possibly more frames, braced frames, or shear walls, joined at or near their edges to form a vertical tube-like structural system capable of resisting lateral forces in any direction by cantilevering from the foundation."[2] Closely spaced interconnected exterior columns form the tube. Horizontal loads, for example wind, are supported by the structure as a whole. About half the exterior surface is available for windows. Framed tubes allow fewer interior columns, and so create more usable floor space. Where larger openings like garage doors are required, the tube frame must be interrupted, with transfer girders used to maintain structural integrity. The first building to apply the tube-frame construction was in the DeWitt-Chestnut apartment building which Khan designed in Chicago. This laid the foundations for the tube structures used in most later skyscrapers, as can been seen in the construction of the World Trade Center.
Another innovation that Khan developed was the concept of X-bracing. This concept reduced the lateral load on the building by transferring the load into the exterior columns. This allows for a reduced need for interior columns thus creating more floor space. This concept can be seen in the John Hancock Center, built in 1969 One of the most famous buildings of the structural expressionist style, the skyscraper's distinctive X-bracing exterior is actually a hint that the structure's skin is indeed part of its 'tubular system'. This idea is one of the architectural techniques the building used to climb to record heights (the tubular system is essentially the spine that helps the building stand upright during wind and earthquake loads). This X-bracing allows for both higher performance from tall structures and the ability to open up the inside floorplan (and usable floor space) if the architect desires. Original features such as the skin, pioneered by Fazlur Khan, have made the John Hancock Center an architectural icon.
The first sky lobby was also designed by Khan for the John Hancock Center. Later buildings with sky lobbies include the World Trade Center, Petronas Twin Towers and Taipei 101. The 44th-floor sky lobby of the John Hancock Center also features the first high-rise indoor swimming pool, which remains the highest in America.[3]
Professional Milestones
- In 1961, was made a Participating Associate in Skidmore, Owings & Merrill; in 1966 he became an Associate Partner and in 1970 a General Partner - the only engineer partner at the time.
- Received an Alumni Honor Dada from the University of Illinois, Urbana-Champaign (1972), an Honorary Doctor of Science from Northwestern University (1973), and an Honorary Doctor of Engineering from Lehigh University (1980).
- In 1973, elected to the National Academy of Engineering.
- He was cited five times among 'Men Who Served the Best Interests of the Construction Industry' by Engineering News-Record (for 1965, 1968, 1970, 1971, and 1979); and in 1972 he was named 'Construction's Man of the Year'. He was posthumously honored with the International Award of Merit in Structural Engineering from the International Association for Bridge and Structural Engineering and a Distinguished Service Award from the AIA Chicago Chapter (both in 1982).
- In 1983 the American Institute of Architects recognized Fazlur Khan's contributions with an AIA Institute Honor for Distinguished Achievement. The same year he was honored with the Aga Khan Award for Architecture "for the Structure of the Hajj Terminal, An Outstanding Contribution to Architecture for Muslims," which was completed over the last years of his life.
- He was honored posthumously by the Structural Engineers Association of Illinois with the John Parmer Award in 1987 and with the commissioning of a sculpture by the Spanish artist Carlos Marinas, which is located in the lobby of the Sears Tower.
- In 1998 the city of Chicago named the intersection of Jackson and Franklin Streets (at the foot of the Sears Tower) “Fazlur R. Khan Way.”
- Made contributions in creating public opinion and amassing emergency fund for the people of Bangladesh during its War of Liberation. The Government of Bangladesh posthumously awarded him Independence Day Medal 1999 in recognition of his contributions, and a commemorative postal stamp was published in his memory.
- He was honored posthumously by The Bangladeshi-American Foundation, Inc. (BAFI) in May 2005 as the most famous Bangladeshi-American of 20th Century.
Other Honors
- Among Khan's other accomplishments, he received the Wason Medal (1971) and Alfred Lindau Award (1973) from the American Concrete Institute (ACI); the Thomas Middlebrooks Award (1972) and the Ernest Howard Award (1977) from ASCE; the Kimbrough Medal (1973) from the American Institute of Steel Construction; the Oscar Faber medal (1973) from the Institution of Structural Engineers, London; the AIA Institute Honor for Distinguished Achievement (1983) from the American Institute of Architects; and the John Parmer Award (1987) from Structural Engineers Association of Illinois (Engineering Legends, Richard Weingardt).
Quotes
"The technical man must not be lost in his own technology; he must be able to appreciate life, and life is art, drama, music, and most importantly, people." Fazlur Khan (Engineering Legends, Richard Weingardt)
References
- ^ Ali Mir (2001), Art of the Skyscraper: the Genius of Fazlur Khan, Rizzoli International Publications, ISBN 0847823709
- ^ "Evolution of Concrete Skyscrapers". Retrieved 2007-05-14.
- ^ John Hancock Center, Emporis
Further reading
- Weingardt, Richard G. "Engineering Legends: Great American Civil Engineers." ASCE Press, 2005.
- Khan, Y. S. "Engineering Architecture: the vision of Fazlur R. Khan." New York: W. W. Norton & Company, 2004.
External links
- Website dedicated to Fazlur Rahman Khan
- [3]
- "Evolution of Concrete Skyscrapers". Retrieved 2007-05-14.
- Fazlur Rahman Khan at Structurae
- 1929 births
- 1982 deaths
- Civil engineers
- Bangladeshi people
- People from Chicago, Illinois
- Structural engineers
- Bangladeshi Americans
- Bangladeshi Muslims
- American Muslims
- Aga Khan Award for Architecture winners
- Dhaka University alumni
- University of Calcutta alumni
- University of Illinois at Urbana-Champaign alumni
- Burials at Graceland Cemetery (Chicago)