E. A. Ogiriki scite author profile

E. A. Ogiriki

4Publications

28Citation Statements Received

40Citation Statements Given

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Cranfield University

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Creep-Life Usage Analysis and Tracking for Industrial Gas Turbines

Saturday

Ogiriki

et al. 2017

Journal of Propulsion and Power

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Creep life usage analysis and tracking of first stage turbine rotor blades of an aero-derivative industrial gas turbine engine is investigated in this study. An engine performance model is created while blade thermal and stress models are developed for the calculation of the blade material temperatures and stresses at different sections of the blade. A creep life model is developed based on the Larson-Miller Parameter method by taking inputs from the thermal and stress models. An integrated creep life estimation system is developed by bringing together the engine performance model, the blade thermal and stress models, the creep life model and a data acquisition and pre-processing model. Relative creep life consumption analysis using new concepts developed in this research is introduced for the analysis of creep life consumption of the gas turbine engine operating for a period of time; these concepts include Equivalent Creep Life (ECL) and Equivalent Creep Factor (ECF). The developed algorithms have been applied to the creep life tracking of an aero derivative gas turbine engine using its field test data. The results show that it is able to provide a quick evaluation and tracking of engine creep life consumption and provide very useful information for gas turbine operators to support their operation optimization and creep life consumption monitoring.

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Effect of Fouling, Thermal Barrier Coating Degradation and Film Cooling Holes Blockage on Gas Turbine Engine Creep Life

Ogiriki¹,

Li²,

Nikolaidis³

et al. 2015

Procedia CIRP

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Prediction and Analysis of Impact of Thermal Barrier Coating Oxidation on Gas Turbine Creep Life

Ogiriki

Nikolaidis

2016

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Thermal barrier coatings (TBCs) have been widely used in the power generation industry to protect turbine blades from damage in hostile operating environment. This allows either a high turbine entry temperature (TET) to be employed or a low percentage of cooling air to be used, both of which will improve the performance and efficiency of gas turbine engines. However, with continuous increases in TET aimed at improving the performance and efficiency of gas turbines, TBCs have become more susceptible to oxidation. Such oxidation has been largely responsible for the premature failure of most TBCs. Nevertheless, existing creep life prediction models that give adequate considerations to the effects of TBC oxidation on creep life are rare. The implication is that the creep life of gas turbines may be estimated more accurately if TBC oxidation is considered. In this paper, a performance-based integrated creep life model has been introduced with the capability of assessing the impact of TBC oxidation on the creep life and performance of gas turbines. The model comprises of a thermal, stress, oxidation, performance, and life estimation models. High pressure turbine (HPT) blades are selected as the life limiting component of gas turbines. Therefore, the integrated model was employed to investigate the effect of several operating conditions on the HPT blades of a model gas turbine engine using a creep factor (CF) approach. The results show that different operating conditions can significantly affect the oxidation rates of TBCs which in turn affect the creep life of HPT blades. For instance, TBC oxidation can speed up the overall life usage of a gas turbine engine from 4.22% to 6.35% within a one-year operation. It is the objective of this research that the developed method may assist gas turbine users in selecting the best mission profile that will minimize maintenance and operating costs while giving the best engine availability.

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Prediction and Analysis of Impact of TBC Oxidation on Gas Turbine Creep Life

Ogiriki

Nikolaidis

2015

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Thermal Barrier Coatings (TBC) have been widely used in the power generation industry to protect turbine blades from damage in hostile operating environment. This allows either a high Turbine Entry temperature (TET) to be employed or a low percentage of cooling air to be used, both of which will improve the performance and efficiency of gas turbine engines. However, with continuous increases in turbine entry temperature aimed at improving the performance and efficiency of gas turbines, TBCs have become more susceptible to oxidation. Such oxidation has been largely responsible for the premature failure of most TBCs. Nevertheless, existing creep life prediction models that give adequate considerations to the effects of TBC oxidation on creep life are rare. The implication is that the creep life of gas turbines may be estimated more accurately if TBC oxidation is considered. In this paper, a performance-based integrated creep life model has been introduced with the capability of assessing the impact of TBC oxidation on the creep life and performance of gas turbines. The model comprises of a thermal, stress, oxidation, performance, and life estimation models. High Pressure Turbine (HPT) blades are selected as the life limiting component of the gas turbine. Therefore the integrated model was employed to investigate the effect of several operating conditions on the HPT blades of a model gas turbine engine using a Creep Factor approach. The results show that different operating conditions can significantly affect the oxidation rates of TBCs which in turn affect the creep life of HPT blades. For instance, TBC oxidation can speed up the overall life usage of a gas turbine engine from 4.22% to 6.35% within one year operation. It is the objective of this research that the developed method may assist gas turbine users in selecting the best mission profile that will minimize maintenance and operating costs while giving the best engine availability.

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E. A. Ogiriki

Creep-Life Usage Analysis and Tracking for Industrial Gas Turbines

Effect of Fouling, Thermal Barrier Coating Degradation and Film Cooling Holes Blockage on Gas Turbine Engine Creep Life

Prediction and Analysis of Impact of Thermal Barrier Coating Oxidation on Gas Turbine Creep Life

Prediction and Analysis of Impact of TBC Oxidation on Gas Turbine Creep Life

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