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Optimizing a falling particle receiver geometry using CFD simulations to maximize the thermal efficiency

Brantley Mills, Benjamin Schroeder, Lindsey Yue, Reid Shaeffer, Clifford K. Ho

2020AIP conference proceedings18 citationsDOIOpen Access PDF

Abstract

A strategy to optimize the thermal efficiency of falling particle receivers (FPRs) in concentrating solar power applications is described in this paper. FPRs are a critical component of a falling particle system, and receiver designs with high thermal efficiencies (∼90%) for particle outlet temperatures >700°C have been targeted for next generation systems. Advective losses are one of the most significant loss mechanisms for FPRs. Hence, this optimization aims to find receiver geometries that passively minimize these losses. The optimization strategy consists of a series of simulations varying different geometric parameters on a conceptual receiver design for the Generation 3 Particle Pilot Plant (G3P3) project using simplified CFD models to model the flow. A linear polynomial surrogate model was fit to the resulting data set, and a global optimization routine was then executed on the surrogate to reveal an optimized receiver geometry that minimized advective losses. This optimized receiver geometry was then evaluated with more rigorous CFD models, revealing a thermal efficiency of 86.9% for an average particle temperature increase of 193.6°C and advective losses less than 3.5% of the total incident thermal power in quiescent conditions.

Topics & Concepts

Computational fluid dynamicsAdvectionThermalParticle (ecology)Power (physics)MechanicsComputer scienceSimulationPhysicsThermodynamicsGeologyOceanographySolar Thermal and Photovoltaic SystemsSolar-Powered Water Purification MethodsPhotovoltaic System Optimization Techniques
Optimizing a falling particle receiver geometry using CFD simulations to maximize the thermal efficiency | Litcius