Modelling of the flow at the rotor disc in a geothermal turbine of 110 MW

To elucidate an excessive erosion damage produced by solid particles in the fourth stage rotor disc of a 110 MW double ¯ow geothermal turbine, a bi-dimensional modelling investigation has been conducted. The study was based on a set of results from a computational model using a Reynolds stress, RSM, turbulence model. The predicted results con®rmed characteristic ¯ow conditions that may play a main role in the serious erosion of the fourth stage rotor disc governor side, which has been detected in periodic overhauls. The results show a jet of vapour that hits the disc transition radius surface at velocities around 112 m/s. These conditions are produced by the ¯ow outgoing from the labyrinth seal, which passes through a drastic cross-section reduction in the last seal strip. The ¯ow was then simulated introducing speci®c changes to the geometry and the grid in order to modify the ¯ow patterns favourably. Actually, the suggested changes have been envisaged indeed to be practically feasible of being implemented. The new results showed that it is possible to reduce the erosion process up to 86% by increasing the distance from the labyrinth seal to the rotor disc, which produces a 38% velocity reduction of the vapour ¯ow in that zone. The design proposed in this work produces a ¯ow pattern of a lower velocity on disc surface together with a modi®ed angle of ¯ow incidence. Furthermore, the proposed design also reduces a recirculating ¯ow at the exit of the last seal strip. Based on these results, an analysis of erosion against velocity demonstrates that the redesigned rotor disc proposed here leads to the duplication of the time period used at present between maintenance repairs.