Polynomials and Neural Networks for Gas Turbine Monitoring: a Comparative Study

Loboda, Igor; Feldshteyn, Yakov

doi:10.1515/tjj.2011.020

Cited by 11 publications

(10 citation statements)

References 14 publications

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“…For the "No noise" scheme, the input data is ideally accurate, and 0 Z ε is an approximation error. It varies for different variables, but its level is comparable to the errors of the baseline for measured variables (Loboda and Feldshteyn 2011). The error 04 Z ε is very small (corresponds to a computer error) because the variable 4 Z (high pressure turbine efficiency) is constant at baseline conditions.…”

Section: Algorithms For Estimating Unmeasured Quantitiesmentioning

confidence: 94%

Estimation and monitoring of unmeasured gas turbine variables

Miró-Zárate

Loboda

Pérez-Ruiz

et al. 2019

Transactions of the Canadian Society for Mechanical Engineering

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This work proposes a universal data-driven approach to compute and monitor gas turbine unmeasured variables. To this end, a large amount of unmeasured and measured data is first computed at steady state for both baseline and faulty engine conditions using a nonlinear thermodynamic model. On the data generated, polynomial models that relate the unmeasured quantities with the measured variables are then determined. These data-driven models allow the computation of unmeasured variables and their deviations. Accuracy analysis is conducted separately for baseline and current estimates of unmeasured variables and for deviation estimates. All the results prove that the estimates are exact enough. Thus it is possible to obtain a universal fast and accurate method for computing important unmeasured gas turbine quantities that is suitable for practical applications. The method promises a drastic increase in the diagnostic capabilities of online monitoring systems.

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Section: Algorithms For Estimating Unmeasured Quantitiesmentioning

confidence: 94%

Estimation and monitoring of unmeasured gas turbine variables

Miró-Zárate

Loboda

Pérez-Ruiz

et al. 2019

Transactions of the Canadian Society for Mechanical Engineering

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“…Three variations are proposed using simulated data with no-fault scenarios through ProDiMES and the model with the lowest total error is selected for the fault recognition stage. A baseline model can be developed based on a thermodynamic model or artificial neural networks (Loboda and Feldshteyn, 2010). The first option needs complex algorithms while the second one requires considerable execution time for training.…”

Section: Introductionmentioning

confidence: 99%

Gas Turbine Diagnostic Algorithm Testing Using the Software ProDiMES

Felipe-Altamirano

Loboda

Cisneros-Azuara

et al. 2017

IIT

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Since gas turbines are very complex and potentially unreliable machines, the improvement of their monitoring systems becomes an essential part. Considering this necessity, the present paper performs a gas turbine diagnostic algorithm testing. The methodology proposed is formed by three stages. In the first stage, the commercial software ProDiMES (Propulsion Diagnostic Method Evaluation Strategy) is used to simulate an engine fleet and generate data with fault and no-fault conditions. In the second stage, a baseline model testing is implemented to improve the healthy engine performance approximation. Finally, a fault recognition stage based on a pattern recognition technique (Multi-Layer Perceptron) performs the diagnosis and calculates the probability of correct diagnostic decisions. The results obtained show that: a) the software ProDiMES is an easy and convenient tool to evaluate gas turbine diagnostic methods, b) the baseline model testing is a key step because it allows reducing the errors that can negatively influence the diagnostic process and c) the algorithm correctly performs the fault recognition task.

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“…The two standard methods use directly engine data for condition monitoring, however these methods can be sensitive to the quality and quantity of example data. Some advanced methods for turbine engine condition monitoring were brought out, such as CASE-based reasoning, the expert systems with fuzzy logic rules and neural network methods [4][5][6][7]. However, the CASE-based reasoning approach was limited by the variation in operational behavior between classes of engine, and the expert systems were attempted to improve the generality by the combination of databases from multiple engines.…”

Section: Introductionmentioning

confidence: 99%

Research on Method for Monitoring Service Life of Hot-End Components in Gas Turbine based on Condition Analysis

Liang¹,

Huang²,

Li³

et al. 2015

Proceedings of the 2015 6th International Conference on Manufacturing Science and Engineering

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The service life of hot-end components in gas turbine for gas-fired power plant is hard to detect and evaluate. The relationship between temperature characteristics of hot-end components and the power load is established using the basic theory of gas turbine power cycle. The operating mode of gas turbine unit is distinguished and determined through the use of electricity load and the rotor rotational speed. The equivalent operation hours and service life loss of the gas turbine and its hot-end components under various conditions are obtained by calculation. Research results show that the method for monitoring service life of hot-end components in gas turbine based on power load analysis can realize the real-time monitoring and assessment of the service life loss and residual life for hot-end components through the measuring parameters from the unit control system, which is advantageous for timely and accurately assessment of the reliability and cumulative life loss of hot-end components, and so to provide the reliable operation of the gas turbine hot-end components.

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Polynomials and Neural Networks for Gas Turbine Monitoring: a Comparative Study

Cited by 11 publications

References 14 publications

Estimation and monitoring of unmeasured gas turbine variables

Estimation and monitoring of unmeasured gas turbine variables

Gas Turbine Diagnostic Algorithm Testing Using the Software ProDiMES

Research on Method for Monitoring Service Life of Hot-End Components in Gas Turbine based on Condition Analysis

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