High Temperature Flow Visualization and Aerodynamic Window Protection of a 100-kWth Solar Thermochemical Receiver-reactor for ZnO Dissociation
Copyright policy )High Temperature Flow Visualization and Aerodynamic Window Protection of a 100-kWth Solar Thermochemical Receiver-reactor for ZnO Dissociation
A 100-kWth receiver-reactor designed for the thermal dissociation of ZnO into metallic Zn is separated from atmosphere by use of a transparent quartz window, through which concentrated solar radiation is admitted. Protection of such windows from reactant and product particle deposition is critical for successful reactor operation. Usingin-situ visualization techniques, the effectiveness of an auxiliary flow of inert gas in aerodynamically protecting a 600-mm-diameter quartz window mounted on the receiver-reactor has been directly assessed during high-temperature experimentation. This work has shown that: (i) high-temperature, in-situ flow visualization is possible and effective in assessing flow patterns developed inside the reactor;(ii) there exist three characteristic flow patterns inside the reactor that can be dynamically controlled by use of a set of tangential and radially oriented jets; and (iii) a region of stable protective flow, under a wide range of experimental and operational conditions, is capable of repeatedly and fully suppressing detrimental particle depositions on the quartz window.
International Conference on Concentrating Solar Power and Chemical Energy Systems, SolarPACES 2014
Energy Procedia, 69
ISSN:1876-6102
- Paul Scherrer Institute Switzerland
- ETH Zurich Switzerland
- Department of Mechanical and Process Engineering Switzerland
- Department of Mechanical and Process Engineering Switzerland
Vortex flow, solar thermochemical reactor, zinc oxide, Solar thermochemical reactor, concentrated solar power, Energy(all), Zinc oxide, High temperature flow visualization; Solar thermochemical reactor; Concentrated solar power; Zinc oxide; Vortex flow, High temperature flow visualization, Concentrated solar power, vortex flow
Vortex flow, solar thermochemical reactor, zinc oxide, Solar thermochemical reactor, concentrated solar power, Energy(all), Zinc oxide, High temperature flow visualization; Solar thermochemical reactor; Concentrated solar power; Zinc oxide; Vortex flow, High temperature flow visualization, Concentrated solar power, vortex flow
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