On the Prediction and Theory of the Temperature Increase of Low Pressure Last Stage Moving Blades During Low Volume Flow Conditions, and Limiting it Through Steam Extraction Methods

Beevers, Adam; Havakechian, Said; Megerle, Benjamin

doi:10.1115/1.4030258

Cited by 13 publications

(1 citation statement)

References 5 publications

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“…Bosdas et al 8 studied the pressure fluctuations of suction and pressure surfaces under small flow rate condition. Adam et al 9 described the driving factors of temperature rise under windage condition based on the experimental and computational fluid dynamics (CFD) results, but they just studied the flow field of the last few stages and did not consider the influence of the upstream flow on the downstream flow. Parvizinia et al 10 established the 2-D geometric model of the last stages of 11 MW steam turbine.…”

Section: Introductionmentioning

confidence: 99%

Analysis on strength performance of the last stage blade in steam turbine under low mass flow conditions

Wang

Shi

Cao

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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Under low mass flow conditions, the velocity field and temperature field are very complicated in the low-pressure cylinder (LPC) of steam turbine, which seriously affects the safe operation of blades. In order to study the safety of the last stage blade under low mass flow conditions, the non-equilibrium condensation model is used to numerically simulate the flow of low-pressure cylinder. The strength performance of the last stage rotor blade is analyzed by the fluid–solid coupling method. The results show that the vortex appears in the flow passage as the load decreases. The last two stages are most affected by the vortex. Under low mass flow conditions, the exhaust steam temperature of LPC rises. Under 5% low-pressure turbine heat-acceptance (LPTHA) condition, the temperature rise has affected the last three stage blades. The maximum temperature is located at the tip exit edge of suction surface of stator blade of the last stage. With the load decreasing, the maximum equivalent stress and maximum deformation show the law of first decreasing and then increasing. Under 10% low-pressure turbine heat-acceptance condition, the maximum equivalent stress is 827.96 MPa, which is over the design value. Under 5% LPTHA condition, the maximum deformation is 6.6301 mm, which is also far beyond the design value. The research results can provide a reference for the operation of steam turbine under low mass flow conditions.

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Section: Introductionmentioning

confidence: 99%