Zirconium alloys are commonly used as cladding tubes in water reactors and
undergo complex biaxial creep deformation. The anisotropic nature of these
hcp metals makes it relatively complex to predict their dimensional changes
in-reactor. These alloys exhibit transients in creep mechanisms as stress
levels change. The underlying creep mechanisms and creep anisotropy depend
on the alloy composition as well as the thermomechanical treatment. We desc
ribe here, first the anisotropic biaxial creep of cold-worked and recrystal
lized Zircaloy-4 in terms of Hill's generalized stress formulation. The tem
perature and stress dependencies of the steady-state creep-rate are describ
ed followed by predictive models for transient and transients in creep (due
to sudden stress changes) which incorporate anelastic strain. The effect o
f recrystallization on creep anisotropy is pointed out along with an extens
ion of the model to radiation creep of irradiated cladding. While Zircaloy-
4 exhibited class M creep, Nb additions resulted in class-A creep behavior
with the characteristic stress exponent of 3. Nb-modified Zircaloy sheet re
vealed changes in creep mechanism to class-M type at high stresses, and vis
cous creep at low stresses. implications of these various features in the p
redictions of cladding dimensions during reactor operation as well as durin
g the dry storage of spent fuel will be discussed.