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Title: Particle Flow Distribution in a Fluidized-Particles Multitube Solar Receiver

Journal Article · · SolarPACES Conference Proceedings
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A fluidized-particles two-tube solar receiver was tested at ambient temperature at PROMES Laboratory to investigate the influence of an inhomogeneous solar flux density on the particle mass flow rate between the tubes. The principle of this 3rd generation solar receiver is to fluidize the particles in a container, called dispenser, in which the tubes’ bottom are immersed. The fluidized particles are flowing upward the tubes by applying an overpressure in the dispenser. Air velocities are changed inside the tubes, thanks to air mass flow controllers, to represent temperature heterogeneity between the tubes. Air velocities from 0.05 up to 0.52 m/s were tested, both in homogeneous and heterogeneous conditions. In the heterogeneous ones, the differences in air velocity between the tubes aim to mimic a difference in temperature from 20 to 100 % with homogeneous air flow rates injected. The following conclusions were drawn. First, the particle mass flux in the tubes are the same with homogeneous air velocities, each one following a calibration map previously obtained. Second, different air velocities lead to different particle mass flux. Third, the rise of the total particle mass flux diminishes the pressure in the dispenser. Four, this diminution of pressure leads to a decrease of the particle mass flow rate of the tube with the lower air velocity. This influence can lead in some cases to the stop of the fluidized bed circulation in the affected tube.

Sponsoring Organization:
USDOE
Grant/Contract Number:
Award Number 34211
OSTI ID:
2278897
Journal Information:
SolarPACES Conference Proceedings, Journal Name: SolarPACES Conference Proceedings Vol. 1; ISSN 2751-9899
Publisher:
TIB Open PublishingCopyright Statement
Country of Publication:
Country unknown/Code not available
Language:
English

References (13)

Thermal analysis of fluidized particle flows in a finned tube solar receiver journal October 2019
Review of heat transfer fluids in tube-receivers used in concentrating solar thermal systems: Properties and heat transfer coefficients journal March 2016
Gas-Solid Flow in a Fluidized-Particle Tubular Solar Receiver: Off-Sun Experimental Flow Regimes Characterization journal November 2021
Highlights of the high-temperature falling particle receiver project: 2012 - 2016
  • Ho, C. K.; Christian, J.; Yellowhair, J.
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conference January 2017
A comprehensive review of state-of-the-art concentrating solar power (CSP) technologies: Current status and research trends journal August 2018
Experimental hydrodynamic study of gas‐particle dense suspension upward flow for application as new heat transfer and storage fluid journal December 2014
A review of high-temperature particle receivers for concentrating solar power journal October 2016
Fluidization regimes of dense suspensions of Geldart group A fluidized particles in a high aspect ratio column journal March 2023
On-sun demonstration of a 750 °C heat transfer fluid for concentrating solar systems: Dense particle suspension in tube journal August 2015
Types of gas fluidization journal May 1973
On-sun operation of a 150 kW th pilot solar receiver using dense particle suspension as heat transfer fluid journal November 2016
Design and performance of a modular combined cycle solar power plant using the fluidized particle solar receiver technology journal September 2020
Proof of Concept Test of a Centrifugal Particle Receiver journal January 2014

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