DHARM
CAISSONS AND WELL FOUNDATIONS 797
From equations 19.40 and 19.43,
P =
()
()
HWmKI.
D
+ vv
+′
βμ =
βμμ
θ
1
2
Using Eq. 19.46,
P =
2 mI
D
v(/) /MI Mr= ...(Eq. 19.48)
where r = (/)D.
I
mIv
2
Also H + βμW =
M
r
()1+′βμμ
Simplifying,
H + βμW =
M
r
M
r
+
βμμ′
or βμW μμ
M
r
FHG − ′I
KJ
= M
r
−H
or β =
(/)
()
Mr H
W M
r
−
L −′
NM
O
QP
μμμ
...(Eq. 19.49)
As – 1 < β < 1, we have
M
r
WHM
r
F ()+′− ()11W
HG
I
KJ
<<F −′+
HG
I
KJ
μμ μ μμ μ
The vertical soil reaction is given by
σz = Kvθ(x + xc)
Also W – μ′P = σθzv cdA=+K zz ()x x dA
or W – μ′P = KvθxcA
or Kvθxc =
()WP
A
−′μ
∴σz = Kx
WP
v A
θ +()−′μ ...(Eq. 19.50)
The stresses at the toe and the heel are given by
pt =
()WP
A
−′ +KvFB
HG
I
KJ
μ θ
2
...(Eq. 19.51 (a))
ph =
()WP
A
−′ −Kv FB
HG
I
KJ
μ θ
2
...(Eq. 19.51 (b))
Substituting the value of Kvθ from Eq. 19.45,
pt =
()WP
A
MB
I
−′μ +
2
...(Eq. 19.52 (a))
ph =
()WP
A
MB
I
−′
−
μ
2
...(Eq. 19.52 (b))
For the soil to remain in the elastic state, the maximum pressure at any depth should
not exceed the passive resistance.