Litcius/Paper detail

Optimization of an Organic Rankine Cycle-Based Waste Heat Recovery System Using a Novel Target-Temperature-Line Approach

M. Z. Haq

2021Journal of Energy Resources Technology12 citationsDOI

Abstract

Abstract Organic Rankine cycle (ORC)-based waste heat recovery (WHR) systems are simple, flexible, economical, and environment-friendly. Many working fluids and cycle configurations are available for WHR systems, and the diversity of working fluid properties complicates the synergistic integration of the efficient heat exchange in the evaporator and net output work. Unique guidelines to select a proper working fluid, cycle configuration and optimum operating parameters are not readily available. In the present study, a simple target-temperature-line approach is introduced to get the optimum operating parameters for the subcritical ORC system. The target-line is the locus of temperatures satisfying the pinch-point temperature difference along the length of the heat exchanger. Employing the approach, study is carried out with 38 pre-selected working fluids to get the optimum operating parameters and suitable fluid for heat source temperatures ranging from 100 °C to 300 °C. Results obtained are analyzed to get cross-correlations between key operating and performance parameters using a heat-map diagram. At the optimum condition, optimal working fluid’s critical temperature and pressure, evaporator saturation temperature, effectivenesses of the heat exchange in the evaporator, cycle, and overall WHR system exhibit strong linear correlations with the heat source temperature.

Topics & Concepts

Working fluidOrganic Rankine cyclePinch pointEvaporatorWaste heat recovery unitDegree RankineHeat exchangerHeat recovery ventilationWaste heatProcess engineeringHeat capacity ratePinch analysisThermodynamicsMechanical engineeringEnvironmental scienceMaterials scienceNuclear engineeringEngineeringPlate heat exchangerPhysicsThermodynamic and Exergetic Analyses of Power and Cooling SystemsAdvanced Thermodynamic Systems and EnginesAdvanced Thermodynamics and Statistical Mechanics