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For the text cursor of a graphical computer user interface, see Cursor (computers). For the night club, see I-Beam (nightclub).
This I-beam is used to support the first floor of a house.
I-beams (also known as W-beams, for "wide flange", or double-T esp. in Polish and German) are beams with an I- or H-shaped cross-section. The horizontal elements are flanges, while the vertical element is the web. The Euler-Bernoulli beam equation shows that this is a very efficient form for carrying both bending and shear in the plane of the web. On the other hand, the cross-section has a reduced capacity in the transverse direction, and is also inefficient in carrying torsion, for which hollow structural sections are often preferred.
Illustration of a vibrating I-beam.
Contents
1 Overview
2 Design
3 Wide-flange steel materials and rolling processes (U.S.)
3.1 Designation and terminology
4 See also
5 References
6 External links
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Overview
There are two standard I-beam forms:
Rolled I-beam, formed by hot rolling, cold rolling or extrusion (depending on material).
Plate girder, formed by welding (or occasionally bolting or riveting) plates.
I-beams are commonly made of structural steel but may also be formed from aluminium or other materials. A common type of I-beam is the rolled steel joist (RSJ) - sometimes incorrectly rendered as "reinforced steel joist". British and European standards also specify Universal Beams (UBs) and Universal Columns (UCs). These sections have parallel flanges, as opposed to the varying thickness of RSJ flanges. UCs have equal or near-equal width and depth, while UBs are deeper.
I-beams engineered from wood with fiberboard and/or laminated veneer lumber are also becoming increasingly popular in construction, especially residential, as they are both lighter and less prone to warping than solid wooden joists. However there has been some concern as to their rapid loss of strength in a fire if unprotected.
Design
I-beams are widely used in the construction industry and are available in a variety of standard sizes. Tables are available to allow easy selection of a suitable steel I-beam size for a given applied load. I-beams may be used both as beams and as columns.
I-beams may be used both on their own, or acting compositely with another material, typically concrete. Design may be governed by any of the following criteria:
deflection - the stiffness of the I-beam will be chosen to minimise deformation
vibration - the stiffness and mass are chosen to prevent unacceptable vibrations, particularly in settings sensitive to vibrations, such as offices and libraries
bending failure by yielding - where the stress in the cross section exceeds the yield stress
bending failure by lateral torsional buckling - where a flange in compression tends to buckle sideways or the entire cross-section buckles torsionally
bending failure by local buckling - where the flange or web is so slender as to buckle locally
local yield - caused by concentrated loads, such as at the beam's point of support
shear failure - where the web fails. Slender webs will fail by buckling, rippling in a phenomenon termed tension field action, but shear failure is also resisted by the stiffness of the flanges
buckling or yielding of components - for example, of stiffeners used to provide stability to the I-beam's web
Wide-flange steel materials and rolling processes (U.S.)
In the United States, the most commonly mentioned I-Beam is the wide-flange (W) shape. These beams have flanges in which the planes are nearly parallel. Other I-Beams include American Standard (designated S) shapes, in which flange surfaces are not parallel, and H-piles (designated HP), which are typically used as pile foundations. Wide-flange shapes are available in grade ASTM A992, which has generally replaced the older ASTM grades A572 and A36.
Rusty steel I-beam
Ranges of yield strength (where 1 ksi = 1,000 pounds per square inch):
A36 - 36 ksi [36,000psi (248.2MPa)]
A572 - 42 ksi to 60 ksi [42,000psi (289.6MPa) to 60,000psi (413.7MPa)] (50 ksi most common)
A588 - Similar to A572
A992 - 50 ksi to 65 ksi [50,000psi (344.7MPa) to 65,000psi (448.2MPa)]
Wide-flange shapes are produced by the electric arc furnace method and generally contain more than 95% recycled content.
The American Institute of Steel Construction ("AISC") publishes the "Steel Construction Manual" for designing structures of various shapes. It documents the common approaches, ASD and LRFD, (as of 13th ed.) to creating such designs.
Designation and terminology
In the United States, steel I-Beams are commonly specified using the depth and weight of the beam. For example, a "W10x22" beam is approximately 10...(and so on)
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Place of Origin: China Fujian TYPE Power Q.max. H.max. Suct.max Speed HP kW L/min m m r.p.m CPM-130 0.56 0.4 90 22 9 2850 CPM-146 0.75 0.55 100 28 CPM-158 1 0.75 110 32 CPM-180 1.5 1.1 120 42 CPM-200 2 1.5 130 46 TYPE Size PACKAGE DIMENSIONS & GW mm A B H Bitmap Bitmap Kg CPM-130 25?5 310 170 230 8.9 CPM-146
Cold Rolling Tubing Mill Technical Parameter Table Model: LG30-H Blank tube thickness (mm): 2545 Blank tube length (mm): 1.56 Outer diameter of finished tube (mm): 1500-6000 Finished tube thickness (mm) :15-32 Max.length of finished tube(mm): 0.5-5 Number of head route per min.(mm) :30000 Max.extensive coefficient(mm) :5 Number of head route per min.(/min) :40-110 Max.route of head (mm) :605 Rocker length (mm) :1650 Crank radius (mm): 300 Deviation between crank centrerolling-line (mm) :250 Feed range (mm/times): 45-72 Turning angle (degree/times) :866 Rolling-line level (mm): 866 Rolling productivity(m/h): 50 Main motor model: Z2-101 Power of main motor (kw): 55 Speed of main motor (r/min): 1000 Rolling machine dimensions(LXW) (M x M): 15.15*18.82 Total weight (kg): 19000 Model: LG-30*2-H Blank tube thickness (mm): 2540 Blank tube length (mm): 1.53. Outer diameter of finished tube(mm): 1500-6
