Fast and accurate flow calculation and performance prediction of multistage
axial flow turbines at design and off-design conditions were performed usi
ng a compressible steady state inviscid through-flow code with high fidelit
y loss and mixing, models. The code is based on a stream function model and
a finite element solution procedure. A new design system has been develope
d which optimizes hub and shroud geometry and inlet and exit flow field par
ameters for each blade row of a multistage axial flow turbine. Optimization
was performed using a hybrid constrained optimization code that switches a
mong the modules automatically in order to avoid local minima and to accele
rate design convergence rate. By automatically varying a relatively small n
umber of geometric variables per turbine stage it is possible to find an op
timal radial distribution of flow parameters at the inlet and outlet of eve
ry blade row. Thus, an optimized meridional flow path can be found that is
defined by the optimized shape of the hub and shroud while keeping blade sh
apes intact. The multistage design optimization system has been demonstrate
d using an actual two-stage axial gas turbine as an example. The comparison
of computed performance of an already very high efficiency initial design
and its optimized design demonstrates more than I per cent improvement in t
he turbine efficiency at design and significant off-design conditions. The
entire design optimization process is feasible on a typical single-processo
r computer workstation or a personal computer.