Thursday, 5 July 2018

DESIGN METHODS FOR BEAMS AND COLUMNS



DESIGN METHODS FOR BEAMS AND COLUMNS


A number of different design methods have been used for reinforced concrete construction. The three most common are working-stress design, ultimate-strength

design, and strength design method. Each method has its backers and supporters.



For actual designs the latest edition of the ACI Code should be consulted.

Beams

Concrete beams may be considered to be of three principal types: (1) rectangular beams with tensile reinforcing only, (2) T-beams with tensile reinforcing

only, and (3) beams with tensile and compressive reinforcing.

Rectangular Beams with Tensile Reinforcing Only This type of beam includes

slabs, for which the beam width equals 12 in (305 mm) when the moment and

shear are expressed per foot (m) of width. The stresses in the concrete and steel

are, using working-stress design formulas,


CONCRETE FORMULAS
Cross section of beam Stress diagram
 
FIGURE 5.1 Rectangular concrete beam with tensile reinforcing only

ABLE 5.1Guides to Depth of Reinforced
Concrete Beam*
Member
d
Roof and floor slabsl/25
Light beamsl/15
Heavy beams and girdersl/12–l/10
*is the span of the beam or slab in inches (millimeters

The width of a beam should be at least l/32.

TABLE 5.2 Coefficients Kkj, and for Rectangular Sections*

Values of Kkj, and for commonly used stresses are given in Table 5.2.

T-Beams with Tensile Reinforcing Only When a concrete slab is constructed

monolithically with the supporting concrete beams, a portion of the slab acts as the

upper flange of the beam. The effective flange width should not exceed (1) onefourth the span of the beam, (2) the width of the web portion of the beam plus 16

times the thickness of the slab, or (3) the center-to-center distance between beams.

T-beams where the upper flange is not a portion of a slab should have a flange

thickness not less than one-half the width of the web and a flange width not more
than four times the width of the web. For preliminary designs, the preceding
formulas given for rectangular beams with tensile reinforcing only can be used,
because the neutral axis is usually in, or near, the flange. The area of tensile
reinforcing is usually critical.
Beams with Tensile and Compressive Reinforcing Beams with compressive
reinforcing are generally used when the size of the beam is limited. The
allowable beam dimensions are used in the formulas given earlier to determine
the moment that could be carried by a beam without compressive reinforcement.
The reinforcing requirements may then be approximately determined from

Checking Stresses in Beams Beams designed using the preceding approximate

formulas should be checked to ensure that the actual stresses do not exceed the

allowable, and that the reinforcing is not excessive. This can be accomplished by

determining the moment of inertia of the beam. In this determination, the

concrete below the neutral axis should not be considered as stressed, whereas the

reinforcing steel should be transformed into an equivalent concrete section. For

tensile reinforcing, this transformation is made by multiplying the area Aby n,
the ratio of the modulus of elasticity of steel to that of concrete. For compressive
reinforcing, the area Asc is multiplied by 2(– 1). This factor includes allowances
for the concrete in compression replaced by the compressive reinforcing and for
the plastic flow of concrete. The neutral axis is then located by solving

FIGURE 5.2 Transformed section of concrete beam

  1. Columns
The principal columns in a structure should have a minimum diameter of 10 in
(255 mm) or, for rectangular columns, a minimum thickness of 8 in(203 mm) and
a minimum gross cross-sectional area of 96 in(61,935 mm2).
Short columns with closely spaced spiral reinforcing enclosing a circular
concrete core reinforced with vertical bars have a maximum allowable load of


Short Columns with Ties The maximum allowable load on short columns
reinforced with longitudinal bars and separate lateral ties is 85 percent of that given