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Prediction and sensitivity analysis under different performance indices of R1234ze ORC with Taguchi's multi-objective optimization

Sadık Ata, Ali Kahraman, Remzi ŞAHİN

2020Case Studies in Thermal Engineering29 citationsDOIOpen Access PDF

Abstract

In this study, parametric optimization and sensitivity analysis of performance parameters were performed for the Organic Rankine Cycle (ORC) system at 120 °C heat source temperature. R1234ze, which is called the new-generation fluid, was used in the ORC design. Performance parameters have been selected considering Energy, Exergy, Economy (Turbine performance) and Environmental (Thermodynamic sustainability indices) factors. Six performance indices used in the orthogonal design with Taguchi-ANOVA. These are; thermal efficiency, turbine power, exergy efficiency, total irreversibility, Volume Flow Ratio (VFR) and Environmental Effect Factor (EEF). Such control factors as ΔTPP,e - ΔTPP,c -Tc,i -Tsup – ƞt – ƞp were selected for the statistical analysis. Sensitivity levels were determined under all performance indices for the designed ORC. It has been determined that indices affect control factors differently. According to the results of the parametric optimization, it was determined that the parameter affecting the ORC performance the most was ΔTPP,e. The effect of ΔTPP,e on ORC performance is stated as 39.72%. EES numerical analysis results were compared with the derived predictive equations using different statistical methods with regression method. When these equations obtained for all objective functions are evaluated, the average MAPE, RRMSE and R2 values were determined as 4.1%, 4.29% and 94.1%, respectively.

Topics & Concepts

Taguchi methodsOrganic Rankine cycleExergyExergy efficiencySensitivity (control systems)MathematicsWorking fluidTurbineParametric statisticsProcess engineeringEnvironmental scienceStatisticsPower (physics)Electricity generationThermodynamicsEngineeringMechanical engineeringPhysicsElectronic engineeringThermodynamic and Exergetic Analyses of Power and Cooling SystemsAdvanced Thermodynamic Systems and EnginesAdvanced Thermodynamics and Statistical Mechanics