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Waste Heat Driven Multi-Ejector Cooling Systems: Optimization of Design at Partial Load; Seasonal Performance and Cost Evaluation

Luca Viscito, G Lillo, Giovanni Napoli, A.W. Mauro

2021Energies17 citationsDOIOpen Access PDF

Abstract

In this paper, a seasonal performance analysis of a hybrid ejector cooling system is carried-out, by considering a multi-ejector pack as expansion device. A 20 kW ejector-based chiller was sized to obtain the optimal tradeoff between performance and investment costs. The seasonal performance of the proposed solution was then evaluated through a dynamic simulation able to obtain the performance of the designed chiller with variable ambient temperatures for three different reference climates. The optimized multi-ejector system required three or four ejectors for any reference climate and was able to enhance the system performance at partial load, with a significant increase (up to 107%) of the seasonal energy efficiency ratio. The proposed system was then compared to conventional cooling technologies supplied by electric energy (electrical chillers EHP) or low-grade heat sources (absorption chillers AHP) by considering the total costs for a lifetime of 20 years and electric energy-specific costs for domestic applications from 0.10 to 0.50 €/kWhel. The optimized multi-ejector cooling system presented a significant convenience with respect to both conventional technologies. For warmer climates and with high electricity costs, the minimum lifetime for the multi-ejector system to achieve the economic break-even point could be as low as 1.9 years.

Topics & Concepts

ChillerInjectorCooling loadAbsorption refrigeratorAutomotive engineeringEnvironmental scienceCooling capacityElectricityCoefficient of performanceProcess engineeringRefrigerationEngineeringHeat pumpMechanical engineeringAir conditioningElectrical engineeringHeat exchangerThermodynamicsPhysicsRefrigeration and Air Conditioning TechnologiesAdvanced Thermodynamic Systems and EnginesThermodynamic and Exergetic Analyses of Power and Cooling Systems