Abstract
Metal cloth seals have been used increasingly in gas turbines due to their flexibility and superior leakage performance. Leakage performance of a metal cloth seal depends on operating conditions, slot and geometric dimensions. These parameters need to be investigated for the best leakage performance. In this study, pressure drop and critical geometric parameters of typical cloth seal form are investigated with an experimental setup. Slot depth, cloth width, sealing gap, shim thickness, surface roughness, pressure drop, offset and mismatch are selected parameters for the screening experiments. Sixteen experiments were conducted following a two-level Resolution IV fractional factorial experiment design for eight parameters. The results indicated that strong parameters for the leakage performance are pressure drop, cloth width, slot depth and offset. Leakage rate is increased with an increase in slot depth, gap, shim thickness, pressure drop and mismatch. During screening experiments, the experiment with minimum flow rate has 86% lower leakage rate than the experiment with maximum flow rate. For main experiments, a Box-Behnken experiment design is applied to analyze nonlinear effects of four strong parameters on the leakage rate. A closed-form equation is derived based on the data and presented in this study.
Highlights
Gas turbines operate with high pressure ratios and temperatures for increased efficiency
After the experiments are completed, cloth seal leakage performance is evaluated as a function of geometric dimensions under varying pressure conditions
Gas turbines are required to operate at ever increasing efficiency levels
Summary
Gas turbines operate with high pressure ratios and temperatures for increased efficiency. High-performance seals are required to meet efficiency demands. Inefficient sealing results in more power consumption by the compressor and reduces the temperature of the main hot gas flow due to cold parasitic leakage flow [1]. Due to relative motion between adjacent stationary components (transition ducts, nozzles, shrouds, etc.), novel seal designs are required to cope with wear, leakage, and excessive stresses. Metallic solid plate seals are insufficient to meet the demands in terms of wear, compliancy and leakage when adjacent components have relative motion in axial or radial directions [2]. Thick solid plate seals cannot flex and close the clearance between seal surface and slot surface under offset and Energies 2020, 13, 5884; doi:10.3390/en13225884 www.mdpi.com/journal/energies
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