Optimal design and operation of an Organic Rankine Cycle (ORC) system driven by solar energy with sensible thermal energy storage

Haoshui Yu,Henrik Helland,Xingji Yu,Truls Gundersen,Gürkan Sin

doi:10.1016/j.enconman.2021.114494

Abstract

In this study, the optimal design and operation of an Organic Rankine Cycle (ORC) system driven by solar energy is investigated. A two-tank sensible thermal energy storage system is configured to overcome the intermittency of solar energy. A circulating fluid, also termed as heat transfer fluid (HTF) that connects the solar collector and the ORC system plays a critical role in this system. The mass flowrate of the HTF determines both the temperature of the HTF and the amount of heat absorbed from the solar collector. A simulation-based optimization model is developed in this work. Process simulation of the ORC is performed in Aspen HYSYS, and the mathematical models of the energy storage system and the parabolic trough collector are developed in Matlab. The optimal design of the system including the hot tank temperature, cold tank temperature, mass flowrate of the HTF, and operating conditions of the ORC are determined simultaneously based on the simulation-based optimization framework. The control strategy of the solar collector can be determined as well. The system efficiency of the solar energy driven ORC system is maximized with the proposed optimal operation strategy. With the simulation-based optimization framework, the system efficiency of the recuperative ORC power plant with toluene as the working fluid is increased from 17.9% to 24.8% compared with a previous study in the literature. The recuperative ORC performs much better than the basic ORC. Toluene performs best among all the investigated working fluids ignoring the problem with vacuum condensation. The cycle type (subcritical vs. supercritical) exerts great influence on the system performance. The supercritical ORC can improve the thermal efficiency by 11.3% and the overall system efficiency by 10.8% compared with the subcritical ORC with n-pentane as the working fluid.

Highlights

Pressing climate change along with technological advancements has spurred the growth of renewable energy installations in the last decade [1]
This study investigates the optimal design and operation of a solar energy driven Organic Rankine Cycle (ORC) system with a parabolic trough collector and a twotank sensible thermal energy storage system
The energy storage system and the ORC system have been optimized simultaneously to achieve the best performance of the total system

Summary

Introduction

Pressing climate change along with technological advancements has spurred the growth of renewable energy installations in the last decade [1]. The greenhouse gas emissions from conventional power generation are receiving increasing attention. Friendly and energyefficient power generation technologies represent a general trend in the future energy market. Solar energy utilization is a promising way to generate electricity because of its abundance and availability [2]. Electricity production from solar energy has been proven to be a viable option for green energy production. Among various solar energy tech nologies, concentrated solar power (CSP) is attractive due to its high efficiency, low operating cost, and flexible scale-up potential [3]

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Conclusion