Hydraulic Structures: Fourth Edition

where a full analysis of the flow conditions and factors influencing them is

really necessary.

The most important factors on which flow over and under the gates

will depend are the geometry of the upstream and downstream water

passage, the geometry and position of the gate and its accessories such as

seals, supports, etc., the upstream head, whether the flow through the gate

is free with atmospheric pressure downstream of it or submerged, the flow

Froude and Reynolds – and possibly even Weber – numbers, the degree of

turbulence of the incoming flow and aeration of the space downstream of

the gates. A detailed treatment of the subject of the prediction of flow con-

ditions and related hydrodynamic forces acting on gates is outside the

scope of this book, but can be found, for example, in Naudascher (1987,

1991). For an example of conditions in case of wicket gates with a partial

opening, see de Bejar and Hall (1998).

Generally the gate design is a difficult area partly because of the com-

plexity of hydraulic conditions indicated above and partly because the

design has to satisfy conflicting demands: vibration damping may conflict

with keeping the forces for the gate operation to a minimum; the need

to avoid vibrations may conflict with the optimum shape and strength

required by the flow conditions and loading; the optimum shape of the

edges and seals may conflict with water tightness of the closed gate, etc.

It is often useful to carry out a potential flow analysis and use this for

the determination of the hydrodynamic force (Rouse, 1950), which (in

some simpler cases) can also be obtained by using the momentum equa-

tion (see Worked example 6.1).

For gates with overflowthe discharge coefficient can be expressed by

the same equation as for an overfall spillway, i.e.

CdQ 

2

3

(2g)1/2bh3/2 (6.2)

wherehis the head of the upstream water level above the crest (or top

edge) of the gate. The total head, H, can also be used in equation (6.2) with

an appropriate change of Cd(for dam crest gates Hh). The coefficient

will depend largely on the geometry of the overflow and the amount of air

which has access to ventilate the nappe. Very broadly, the range of Cdis

similar to that for overfall spillways, i.e. 0.55Cd0.8; for further details

see, for example, Hager (1988) and Naudascher (1987, 1991).

For gates with underflowthe discharge and flow field will depend pri-

marily whether the outflow is free(modular) or drowned. For free flow the

form of equation (4.21b) may be used:

QCdba(2gH)1/2 (6.3)

(ais the gate opening and Hthe upstream head), where the coefficients of

dischargeCdand contraction Ccare related by

280 GATES AND VALVES