The basic equations for the working-stress de-
sign of a rectangular beam reinforced solely in ten-
sion arek
-Jw(21)
J = 1 - f (22)M = Qd = Vifckjbd
2
(23) ™™J "•
Stress 3
^
resultM=y*fck(3-k)bd
2
(24)M=Tjd=fsAJd (25)M=fspjbd^2 (26)/^P(3-yt)W^2
M
=^V-(27)
, = f (28)>-2*lb (29)k = [2pn + (pw)^2 ]^0 -^5 - PW (30)For a given set of values offc,fs, and «, Mis directly proportional to the beam proper-
ty bd^2. Let K denote the constant of proportionality. Then
M = Kbd^2 (31)where
K=V2fckj=fspj (32)The allowable flexural stress in the concrete and the value of w, which are functions of
the ultimate strength/,', are given in the ACI Code, as is the allowable flexural stress in
the steel. In all instances in the following procedures, the assumption is that the reinforce-
ment is intermediate-grade steel having an allowable stress of 20,000 lb/in^2 (137,900
kPa).
Consider that the load on a beam is gradually increased until a limiting stress is in-
duced. A beam that is so proportioned that the steel and concrete simultaneously attain
their limiting stress is said to be in balanced design. For each set of values offc
f
and^,
there is a corresponding set of values of K 9 k, j, and p associated with balanced design.
These values are recorded in Table 1.