Abstract
This paper analyzes a novel, cost-effective planar waveguide solar concentrator design that is inspired by cellular hexagonal structures in nature with the benefits of facile installation and low operation and maintenance cost. A coupled thermal and optical analysis of solar irradiation through an ideal hexagonal waveguide concentrator integrated with a linear receiver is presented, along with a cost analysis methodology, to establish the upper limit of performance. The techno-economic model, coupled with numerical optimization, is used to determine designs that maximized power density and minimized the cost of heat in the temperature range of 100–250 °C, which constitutes more than half of the industrial process heat demand. Depending on the incident solar irradiation and the application temperature, the cost of heat for the optimal design configuration ranged between 0.1–0.27 $/W and 0.075–0.18 $/W for waveguide made of ZK7 glass and polycarbonate, respectively. A techno-economic analysis showed the potential of the technology to achieve cost as low as 80 $/m2 and 61 $/m2 for waveguide made of ZK7 glass and polycarbonate material, respectively, which is less than half the cost of state-of-the-art parabolic trough concentrators. Overall, the hexagonal waveguide solar concentrator technology shows immense potential for decarbonizing the industrial process heat and thermal desalination sectors.
Highlights
Concentrated solar thermal (CST) technology utilizes focused sunlight to heat liquids or gases for process heat or power generation applications
A combined thermal and optical transport model for solar concentration inside a hexagon-shaped waveguide was developed to analyze its feasibility for concentrated solar thermal applications
The optical model is derived from an analytical framework that is based on a perfect total internal reflection of incident irradiation within the waveguide with no optical losses while accounting for ray attenuation due to absorption in the waveguide
Summary
Concentrated solar thermal (CST) technology utilizes focused sunlight to heat liquids or gases for process heat or power generation applications. The drawbacks that limit the widespread implementation of these focusing technologies include tracking errors; high capital, operational and maintenance costs related to drive systems, support structures, wirings, etc.; massive form factor of sun-tracking mirrors; and, large land area requirement [4,5]. The cost effectiveness of the waveguide solar thermal concentration approach is primarily attributed to the reduction or exclusion of tracking cost that makes the system compact, and the flat planar form factor that enhances land-use efficiency as the collectors can be spaced closely (with no shading concerns), leading to increased power generation capability for a given land area. The waveguides could be placed closer to ground, thereby eliminating or minimizing the heavy metallic structures that are currently needed to support troughs and heliostats against wind loading
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