Optimal rapid multidisciplinary response networks: RAPIDDISK

The role of uncertainty in information rich design systems is critical to the development of advanced propulsion systems. Future turbine engines would have lower lifetime operating costs similar to current evolving automotive systems. Detailed multi-physics models (thermo-fluid, structural and mecha...

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Veröffentlicht in:	Structural and multidisciplinary optimization 2005-03, Vol.29 (3), p.213-231
Hauptverfasser:	Nagendra, S, Staubach, J B, Suydam, A J, Ghunakikar, S J, Akula, V R
Format:	Artikel
Sprache:	eng
Schlagworte:	Artificial intelligence Automotive engines Automotive parts Bayesian analysis Boundary conditions Embedded systems Evolution Fuel consumption Knowledge based engineering Machine learning Mechanical systems Neural networks Operating costs Optimization Predictions Preliminary designs Propulsion systems Turbine disks Turbine engines Turbines
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container_title	Structural and multidisciplinary optimization
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creator	Nagendra, S Staubach, J B Suydam, A J Ghunakikar, S J Akula, V R
description	The role of uncertainty in information rich design systems is critical to the development of advanced propulsion systems. Future turbine engines would have lower lifetime operating costs similar to current evolving automotive systems. Detailed multi-physics models (thermo-fluid, structural and mechanical systems) and an operational environment are enablers of rapid correction and model-based predictive analyses. Bayesian machine learning paradigms are developed to identify the behavior of turbo-machinery components for preliminary design. The embedded models approach enables systematic evolution from individual components level to the advanced engine. The embedded models approach enables systematic evolution from individual components level to the advanced engine. A rapid response strategy is proposed, for design of turbine disks by using multidisciplinary optimization and neural networks. iSIGHT optimization software is interfaced with ANSYS to find optimum designs for a given set of design boundary conditions (rpm, live rim load, thermals, etc.). The optimum designs obtained from iSIGHT for different set of design conditions are used for machine learning and design knowledge recognition using the neural network technique. The trained network is used to predict responses for design boundary conditions. Responses predicted by the neural network are validated using ANSYS. Discrete design points are chosen from the wide design space of turbine disks. A hierarchical neural network approach provides an ability to quickly train the network and predict responses (weight, stresses, burst margin, etc.) for applied design conditions. This basic building process involves four steps starting from identifying design boundary conditions to the prediction of design shape for the disk. Sensitivity-based scaling rules are developed, to accommodate different materials for the disk. The technique is developed in RAPIDDISK, which provides an optimal preliminary shape and design attributes for a turbine disk.
doi_str_mv	10.1007/s00158-004-0472-2
format	Article
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subjects	Artificial intelligence Automotive engines Automotive parts Bayesian analysis Boundary conditions Embedded systems Evolution Fuel consumption Knowledge based engineering Machine learning Mechanical systems Neural networks Operating costs Optimization Predictions Preliminary designs Propulsion systems Turbine disks Turbine engines Turbines
title	Optimal rapid multidisciplinary response networks: RAPIDDISK
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