A Planar-Cavity Receiver Configuration for High-Temperature Solar Thermal Processes: Preprint

Research output: Contribution to conferencePaper

Abstract

Next generation concentrating solar thermal power (CSP) and novel solar thermochemical systems using concentrating solar thermal (CST) energy require high operating temperatures exceeding those of traditional nitrate-salt CSP systems. Particle-based systems are attractive for next-generation CSP and CST applications owing to high-temperature stability of inert silica- or alumina-based particulate materials, the lack of low-temperature freezing concerns that limit molten salt and/or molten metal heat transfer media, and cost-effective thermal storage using low-cost particulate and containment materials. Open-cavity falling particle receivers have many potential advantages, but face challenges pertaining to scalability, thermal loss, and particle loss through the open aperture, and are infeasible for chemical processes that require a low-oxygen ambient environment. Enclosed receiver configurations can be scalable, avoid particle loss when heating particles, and have potential for future chemical processes; however, particle-based heat transfer media provide substantially lower heat transfer rates than liquid media, and thus enclosed particle receiver designs require novel configurations to limit surface temperatures under the high incident solar flux concentrations necessary for high receiver thermal efficiency at high temperature. This paper introduces the novel planar-cavity enclosed particle receiver configuration in which arrays of planar surfaces are arranged into sub-vertical cavities. Large angles between the panel surface normal vectors and the aperture surface normal allow the incoming solar beam to distribute along the panel walls. Correspondingly, a high incident solar flux concentration at the cavity aperture produces substantially lower absorbed solar flux concentration on any panel wall. Sets of individual vertical cavities can be arranged to form a scalable receiver configuration.
Original languageAmerican English
Number of pages11
StatePublished - 2024
EventThe 29th SolarPACES conference 2023 - Sydney, Australia
Duration: 10 Oct 202313 Oct 2023

Conference

ConferenceThe 29th SolarPACES conference 2023
CitySydney, Australia
Period10/10/2313/10/23

NREL Publication Number

  • NREL/CP-5700-87566

Keywords

  • cavity receiver
  • concentrating solar power
  • solar flux modeling
  • solid particles

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