Litcius/Paper detail

Thermal analysis and optimal fluid selection for the novel integrated vapor compression cycle and ORC system for ultra-low grade waste heat recovery using the desuperheating method

Muhammad Asim, Sheheryar Khan, Shahid Ali Khan, Taha Baig, Muhammad Imran, Abdul Wasy Zia, Fahid Riaz, Michael K.H. Leung

2024Energy Nexus9 citationsDOIOpen Access PDF

Abstract

• Novel integrated VCC ORC system presented for ultra-low grade waste heat recovery. • Performance analysis using the desuperheating heat recovery method is applied to the integrated systems. • Different pairs of working fluids are modelled for the integrated system. • The most suitable working fluid pairs are identified. This research investigates the thermal performance and working fluid selection from ultra-low-grade waste heat recovery. The study examines the desuperheating method of a novel integrated Vapor Compression Cycle (VCC) and the organic Rankine Cycle (ORC) system for electricity generation. Two cooling methods are analysed and compared, water-cooled VCC-water-cooled ORC and air-cooled VCC -air-cooled ORC. The study was conducted on a vapor compression system with 35-kW refrigeration capacity and evaluated various performance indices. The results indicate that for the water-water cooled system, R407c-R141b is the potential working fluid, achieving an overall coefficient of performance (COP sys ) of 3.20, ORC thermal efficiency of 7.56 %, and net electricity output of 0.28 kW. R410a-R141b is recommended in the air-air-cooled system due to its higher ORC thermal efficiency (7.67 %) than the water-water-cooled system (7.56 %), resulting in a power output of 0.44 kW. Sensitivity analysis reveals that desuperheating is preferable for obtaining higher ORC thermal efficiency. Increasing the condensing water temperature improves net electricity and ORC thermal efficiency. Furthermore, a higher mass flow rate of condensing water enhances system COP and system exergy efficiency but decreases ORC thermal efficiency.

Topics & Concepts

Vapor-compression refrigerationProcess engineeringWaste heat recovery unitWaste heatSelection (genetic algorithm)Heat recovery ventilationMaterials scienceWaste managementThermalEnvironmental scienceWorking fluidCompression (physics)Nuclear engineeringPetroleum engineeringComputer scienceMechanical engineeringEngineeringThermodynamicsComposite materialHeat exchangerRefrigerantPhysicsArtificial intelligenceThermodynamic and Exergetic Analyses of Power and Cooling SystemsAdsorption and Cooling SystemsRefrigeration and Air Conditioning Technologies