Transversely homogeneous, uniformly sheared, turbulent flow was allowe
d to reach its asymptotic structure in a straight wind tunnel section
and then it was passed through a sequence of two curved sections and a
final straight section. The: cross-sectional shape of the entire wind
tunnel was rectangular, while the two curved sections had circular ce
ntre lines with the same radius but opposing curvatures. In all cases,
the mean strain rate due to curvature was relatively weak (+/-5%), co
mpared to the mean shear rate, but its effects on the turbulence kinet
ic energy and structure were substantial; streamwise pressure gradient
effects were negligible. The turbulence structure approached approxim
ately self-similar states towards the downstream ends of each curved s
ection but the main interest of the present study was the rate of adju
stment of the turbulence following a stepwise change in curvature. It
has been shown that the adjustment of the shear stress anisotropy, whi
ch is a sensitive indicator of structural changes, can be approximated
by a first-order system response, whose time constant scales with the
inverse mean shear and is independent of the curvature parameter. Uni
formly sheared flow results were used for an interpretation of the str
ucture of curved turbulent boundary layers, both during adjustment and
in a fully developed state.