Hydraulic Structures: Fourth Edition

fore now applied only to smaller and less vulnerable concrete dams, or for

purposes of preliminary analysis. For high dams, or dams in situations

where seismicity is considered critical, more sophisticated procedures are

necessary. In such circumstances seismological appraisal of the dam site

should be followed by a comprehensive dynamic response analysis, as dis-

cussed in Chopra (1988).

PSEUDOSTATIC ANALYSIS

Pseudostatic inertia and hydrodynamic loads are determined from seismic

coefficients
hand
vas detailed below.

INERTIA FORCES: MASS OF DAM

Horizontal force is

Pemh
hPm (3.14a)

and vertical force is

Pemv
vPm. (3.14b)

As with self-weight load, Pm, inertia forces are considered to operate

through the centroid of the dam section. The reversible direction of the

forces will be noted; positive is used here to denote inertia forces opera-

tive in an upstream and/or a downward sense, as indicated in Figs 3.1 and

3.4.

HYDRODYNAMIC INERTIA FORCES: WATER REACTION

An initial estimate of these forces can be obtained using a parabolic

approximation to the theoretical pressure distribution as analysed in

Westergaard (1933).

Relative to any elevation at depth z 1 below the water surface, hydro-

dynamic pressure pewhis determined by

pewhCe
h (^) wzmax(kN m^2 ). (3.15)
In this expression zmaxis the maximum depth of water at the section of
dam considered. Ceis a dimensionless pressure factor, and is a function of
z 1 /zmaxandu, the angle of inclination of the upstream face to the vertical.
Indicative values of Ceare given in Table 3.1.
The resultant hydrodynamic load is given by
Pewh0.66Ce
hz 1 w(z 1 /zmax)1/2 (3.16)

130 CONCRETE DAM ENGINEERING