Effect of Quartz Aperture Covers on the Fluid Dynamics and Thermal Efficiency of Falling Particle Receivers

Abstract: Falling particle receivers are an emerging technology for use in concentrating solar power systems. In this work, quartz half-shells are investigated for use as full or partial aperture covers to reduce receiver thermal losses. A receiver subdomain and surrounding air are modeled using ANSYS® Fluent®. The model is used to simulate fluid dynamics and heat transfer for the following cases: (1) open aperture, (2), aperture fully covered by quartz half-shells, and (3) aperture partially covered by quartz half-shel… Show more

“…The G3P3-USA FPR leverages years of experience gained from testing prototype FPRs at SNL [3,[8][9][10], a large body of existing literature on FPR technology [11][12][13], and recent R&D efforts focused on increasing the FPR thermal performance and resilience to operating and environmental conditions (e.g. wind) [4,6,[14][15][16][17][18]. Specifically, a number of different receiver enhancements have been investigated including: hoods/tunnels around the aperture [14], quartz-half shell aperture covers [15,18], novel curtain release patterns [19,20], active air flow over the aperture [16], geometric cavity optimization [14], and multistage features [17].…”

“…wind) [4,6,[14][15][16][17][18]. Specifically, a number of different receiver enhancements have been investigated including: hoods/tunnels around the aperture [14], quartz-half shell aperture covers [15,18], novel curtain release patterns [19,20], active air flow over the aperture [16], geometric cavity optimization [14], and multistage features [17]. Of these features, a hood/tunnel (referred to as a solar nod optimized unobstructing tunnel or SNOUT) coupled with an optimized receiver cavity and multistage features were down-selected for integration into the final G3P3-USA design [2].…”

Development of the Generation 3 Particle Pilot Plant Falling Particle Receiver

“…The G3P3-USA FPR leverages years of experience gained from testing prototype FPRs at SNL [3,[8][9][10], a large body of existing literature on FPR technology [11][12][13], and recent R&D efforts focused on increasing the FPR thermal performance and resilience to operating and environmental conditions (e.g. wind) [4,6,[14][15][16][17][18]. Specifically, a number of different receiver enhancements have been investigated including: hoods/tunnels around the aperture [14], quartz-half shell aperture covers [15,18], novel curtain release patterns [19,20], active air flow over the aperture [16], geometric cavity optimization [14], and multistage features [17].…”

“…wind) [4,6,[14][15][16][17][18]. Specifically, a number of different receiver enhancements have been investigated including: hoods/tunnels around the aperture [14], quartz-half shell aperture covers [15,18], novel curtain release patterns [19,20], active air flow over the aperture [16], geometric cavity optimization [14], and multistage features [17]. Of these features, a hood/tunnel (referred to as a solar nod optimized unobstructing tunnel or SNOUT) coupled with an optimized receiver cavity and multistage features were down-selected for integration into the final G3P3-USA design [2].…”

Development of the Generation 3 Particle Pilot Plant Falling Particle Receiver

Development of a novel tool to simulate solar thermal cogeneration plants using small-capacity tower plants

Numerical study of free-falling particle receivers with curtain and particle interchange for high receiver efficiency and low temperature difference