Dictionary:
can·ti·le·ver (kăn'tl-ē'vər, -ĕv'ər)  |
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| Britannica Concise Encyclopedia: cantilever |
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A linear structural member supported both transversely and rotationally at one end only; the other end of the member is free to deflect and rotate. Cantilevers are common throughout nature and engineered structures; examples are a bird's wing, an airplane wing, a roof overhang, and a balcony. See also Wing.
A horizontal cantilever must be counterbalanced at its one support against rotation. This requirement is simply achieved in the design of a playground seesaw, with its double-balanced cantilever. This principle of counterbalancing the cantilever is part of the basic design of a crane, such as a tower crane (see illustration). More commonly, horizontal cantilevers are resisted by being continuous with a backup span that is supported at both ends. This design is common for cantilever bridges; all swing bridges or drawbridges are cantilevers. See also Bridge.
Cantilever configuration in the form of a tower support crane.
Vertical cantilevers primarily resist lateral wind loads and horizontal loads created by earthquakes. Common vertical cantilevers are chimneys, stacks, masts, flagpoles, lampposts, and railings or fences. All skyscrapers are vertical cantilevers. One common system to provide the strength to resist lateral loads acting on the skyscraper is the use of a truss (known as bracing). See also Buildings; Shear; Truss.
Some of the largest cantilevers are used in the roofs of airplane hangars. It has become common practice to include cantilevers in the design of theaters and stadiums, where an unobstructed view is desired; balconies and tiers are supported in the back and cantilevered out toward the stage or playing field so that the audience has column-free viewing. See also Beam; Roof construction.
| Architecture: cantilever |
1. A beam, girder, truss, or structural member or surface that projects horizontally beyond its vertical support, such as a wall or column.
2. A projecting bracket used for carrying the cornice or extended eaves of a building.
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| Columbia Encyclopedia: cantilever |
| Occultism & Parapsychology Encyclopedia: Cantilever |
A theory of the physical action of ectoplasm during the phenomenon of telekinesis, or the movement of objects without contact or other physical means. The theory was developed by the psychical investigator Dr. W. J. Crawford, who attempted to measure the movement of ectoplasm during his investigations of the Goligher Circle in Belfast, Ireland, between 1917 and 1920.
| Wikipedia: Cantilever |
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A cantilever is a beam supported on only one end. The beam carries the load to the support where it is resisted by moment and shear stress.[1] Cantilever construction allows for overhanging structures without external bracing. Cantilevers can also be constructed with trusses or slabs.
This is in contrast to a simply supported beam such as those found in a post and lintel system. A simply supported beam is supported at both ends with loads applied between the supports.
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Cantilevers are widely found in construction, notably in cantilever bridges and balconies (see corbel). In cantilever bridges the cantilevers are usually built as pairs, with each cantilever used to support one end of a central section. The Forth Bridge in Scotland is a famous example of a cantilever truss bridge.
Temporary cantilevers are often used in construction. The partially constructed structure creates a cantilever, but the completed structure does not act as a cantilever. This is very helpful when temporary supports, or falsework, cannot be used to support the structure while it is being built (e.g., over a busy roadway or river, or in a deep valley). So some truss arch bridges (see Navajo Bridge) are built from each side as cantilevers until the spans reach each other and are then jacked apart to stress them in compression before final joining. Nearly all cable-stayed bridges are built using cantilevers as this is one of their chief advantages. Many box girder bridges are built segmentally, or in short pieces. This type of construction lends itself well to balanced cantilever construction where the bridge is built in both directions from a single support.
In an architectural application, Frank Lloyd Wright's Fallingwater used cantilevers to project large balconies. The East Stand at Elland Road Stadium in Leeds was, when completed, the largest cantilever stand in the world[citation needed] holding 17,000 spectators.The roof built over the stands at Old Trafford Football Ground uses a cantilever so that no supports will block views of the field. The old, now demolished Miami Stadium had a similar roof over the spectator area. The largest cantilever in Europe is located at St James' Park in Newcastle-Upon-Tyne, the home stadium of Newcastle United F.C.[2][3]
 The Forth Bridge, a cantilever truss bridge. |
 This concrete balanced cantilever bridge under construction employs movable cantilevers to support formwork. |
 A notable cantilever balcony of the Fallingwater house, by Frank Lloyd Wright. |
 A balcony created by a cantilever slab. |
 A cantilevered railroad deck and fence on the Canton Viaduct |
 A cantilever barn from rural Appalachia |
Less obvious examples of cantilevers are free-standing radio towers without guy-wires and chimneys, which resist being blown over by the wind through cantilever action at their base.
Another use of the cantilever is in fixed-wing aircraft design, pioneered by Hugo Junkers in 1915. Early aircraft wings typically bore their loads by using two (or more) wings in a biplane configuration braced with wires. They were similar to truss bridges, having been developed by Octave Chanute, a railroad bridge engineer. The wings were braced with crossed wires so they would stay parallel, as well as front-to-back to resist twisting. The cables generated considerable drag, and there was constant experimentation on ways to eliminate them.
It was also desirable to build a monoplane aircraft, as the airflow around one wing negatively affects the other in a biplane model. Early monoplanes used either struts (as do some current light aircraft), or cables (as do some modern home-built aircraft). The advantage in using struts or cables is a reduction in weight for a given strength, but with the penalty of additional drag. This reduces maximum speed, and increases fuel consumption.
The most common current wing design is the cantilever. A single large beam, called the main spar, runs through the wing, typically nearer the leading edge at about 25 percent of the total chord. In flight, the wings generate lift, and the wing spars are designed to carry this load through the fuselage to the other wing. To resist fore and aft movement, the wing will usually be fitted with a second smaller drag-spar nearer the trailing edge, tied to the main spar with structural elements or a stressed skin. The wing must also resist twisting forces, done either by a monocoque "D" tube structure forming the leading edge, or by the aforementioned linking two spars in some form of box beam or lattice girder structure.
Cantilever wings require a much heavier spar than would otherwise be needed in cable-stayed designs. However, as the size of an aircraft increases, the additional weight penalty decreases. Eventually a line was crossed in the 1920s, and designs increasingly turned to the cantilever design. By the 1940s almost all larger aircraft used the cantilever exclusively, even on smaller surfaces such as the horizontal stabilizer.
Cantilevered beams are the most ubiquitous structures in the field of microelectromechanical systems (MEMS). MEMS cantilevers are commonly fabricated from silicon (Si), silicon nitride (SiN), or polymers. The fabrication process typically involves undercutting the cantilever structure to release it, often with an anisotropic wet or dry etching technique. Without cantilever transducers, atomic force microscopy would not be possible. A large number of research groups are attempting to develop cantilever arrays as biosensors for medical diagnostic applications. MEMS cantilevers are also finding application as radio frequency filters and resonators.
Two equations are key to understanding the behavior of MEMS cantilevers. The first is Stoney's formula, which relates cantilever end deflection δ to applied stress σ:
where ν is Poisson's ratio, E is Young's modulus, L is the beam length and t is the cantilever thickness. Very sensitive optical and capacitive methods have been developed to measure changes in the static deflection of cantilever beams used in dc-coupled sensors.
The second is the formula relating the cantilever spring constant k to the cantilever dimensions and material constants:
where F is force and w is the cantilever width. The spring constant is related to the cantilever resonance frequency ω0 by the usual harmonic oscillator formula 
. A change in the force applied to a cantilever can shift the resonance frequency. The frequency shift can be measured with exquisite accuracy using heterodyne techniques and is the basis of ac-coupled cantilever sensors.
The principal advantage of MEMS cantilevers is their cheapness and ease of fabrication in large arrays. The challenge for their practical application lies in the square and cubic dependences of cantilever performance specifications on dimensions. These superlinear dependences mean that cantilevers are quite sensitive to variation in process parameters. Controlling residual stress can also be difficult.
 MEMS cantilever in resonance[4] |
A cantilever rack is a type of warehouse storage system consisting of the vertical column, the base, the arms, and the horizontal and/or cross bracing. These componenets are fabricated from both roll formed and structural steel. The horizontal and/or cross bracing are used to connect two or more columns together. They are commonly found in lumber yards, woodworking shops, and plumbing supply warehouses.
A folding cantilever tray is a type of stacked shelf that can unfolded to allow convenient access to items on multiple tiers simultaneously. The shelves can be collapsed when not in use for more compact storage. Because of these proporties folding cantilever trays are often used in luggage and toolboxes.
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| Translations: Cantilever |
Dansk (Danish)
n. - konsol, udligger
v. tr. - udhængende, fritbærende
v. intr. - blive støttet af udliggere
Nederlands (Dutch)
kraagligger, bevestigen d.m.v. kraagligger
Français (French)
n. - (Archit) corbeau, console, (Aviat) cantilever, (Constr) porte-à-faux
v. tr. - construire une console
v. intr. - former (qch) en saillie
Deutsch (German)
n. - (Archit.) Träger, Tragbalken, (Ingenieurw.) überlanges horizontales Strukturelement (Brücken)
v. - planen, bauen (in Form eines Trägers)
Ελληνική (Greek)
n. - πρόβολος, δοκάρι που στηρίζεται στο ένα άκρο του
Italiano (Italian)
trave a sbalzo
Português (Portuguese)
n. - viga (f) em balanço, suporte (m) em calhas
Русский (Russian)
консоль, кронштейн
Español (Spanish)
n. - viga voladiza, canecilla, consola
v. tr. - colocar una viga voladiza
v. intr. - colocar una viga voladiza
Svenska (Swedish)
n. - kantilever, konsol
中文(简体)(Chinese (Simplified))
悬臂, 利用悬臂支撑, 利用悬臂建造, 把...建成悬臂式, 如悬臂向外伸出
中文(繁體)(Chinese (Traditional))
n. - 懸臂
v. tr. - 利用懸臂支撐, 利用懸臂建造, 把...建成懸臂式
v. intr. - 如懸臂向外伸出
한국어 (Korean)
n. - 외팔보
v. tr. - 외팔보로 지지하다
v. intr. - 외팔보로 지지되다
العربيه (Arabic)
(الاسم) عارضه مثبته من طرف واحد
עברית (Hebrew)
n. - תומכה, קורה תומכת
v. tr. - תמך באמצעות קורה
v. intr. - בלט (קורה)
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Copyrights:
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 | Dictionary. The American Heritage® Dictionary of the English Language, Fourth Edition Copyright © 2007, 2000 by Houghton Mifflin Company. Updated in 2009. Published by Houghton Mifflin Company. All rights reserved. Read more |
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| Britannica Concise Encyclopedia. Britannica Concise Encyclopedia. © 2006 Encyclopædia Britannica, Inc. All rights reserved. Read more |
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| Sci-Tech Encyclopedia. McGraw-Hill Encyclopedia of Science and Technology. Copyright © 2005 by The McGraw-Hill Companies, Inc. All rights reserved. Read more |
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| Architecture. McGraw-Hill Dictionary of Architecture and Construction. Copyright © 2003 by McGraw-Hill Companies, Inc. All rights reserved. Read more |
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| Columbia Encyclopedia. The Columbia Electronic Encyclopedia, Sixth Edition Copyright © 2003, Columbia University Press. Licensed from Columbia University Press. All rights reserved. www.cc.columbia.edu/cu/cup/. Read more |
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| Occultism & Parapsychology Encyclopedia. Encyclopedia of Occultism and Parapsychology. Copyright © 2001 by The Gale Group, Inc. All rights reserved. Read more |
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| Wikipedia. This article is licensed under the Creative Commons Attribution/Share-Alike License. It uses material from the Wikipedia article "Cantilever". Read more |
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