Abstract
A nonuniform and high-strength heat flux load would reduce the working efficiency, safety, and in-service life of a cavity receiver. Four types of concave quartz windows, including conical, spherical, sinusoidal, and hyperbolic tangent, were proposed to be used in the cylindrical cavity receiver of a solar dish concentrator system, which can improve the flux uniformity and reduce the peak concentration ratio of the receiver. For each concave quartz window, 36 structural schemes were offered. Based on the Monte Carlo ray-tracing method, the results showed that the nonuniformity coefficient of the receiver was 0.68 and the peak concentration ratio was 1320.21 by using a plane quartz window. At the same time, when the receiver is in the best optical performance, it is the receiver with sinusoidal, conical, spherical, and hyperbolic tangent quartz windows, respectively. The optical efficiency of the receiver with the above four types of quartz windows was basically the same as that of the receiver with the plane quartz window, but their nonuniformity coefficients were reduced to 0.31, 0.35, 0.36, and 0.39, respectively, and the peak concentration ratio was reduced to 806.82, 841.31, 853.23, and 875.89, respectively. Obviously, the concave quartz window was better than the plane quartz window in improving the flux uniformity. Finally, a further study on the sinusoidal quartz window scheme of all of the above optimal parameter schemes showed that when the installation position of the receiver relative to the dish concentrator was changed, the flux uniformity of the receiver could continue to improve. When the surface absorptivity of the receiver was reduced, the optical efficiency would be reduced. For the parabolic dish concentrator with different focal distance, the concave quartz window can also improve the uniformity of the flux distribution of the cylindrical cavity receiver.
Highlights
Solar energy is a clean and environmentally friendly renewable energy
To evaluate the influence of a concave quartz window on the optical performance of a cavity receiver, it is usually necessary to evaluate the performances of the receiver, including the optical efficiency, local concentration ratio (LCR), and nonuniformity coefficient used to characterize the uniformity of the flux distribution
When the hyperbolic tangent quartz window is used in the cavity receiver, the results of the optical performance of the receiver obtained by the simulation are shown in Figure 8 and Table 8 As shown in Figure 8(a), the scheme with an optical efficiency of lower than 89% is first removed
Summary
Due to the low density of solar radiation received by the earth’s surface, a solar concentrator is an indispensable core device in a solar energy high-grade utilization system. It can obtain high-density solar radiation on a small area of receivers to improve the energy utilization efficiency or reduce the construction cost [1, 2]. A solar dish concentrator/cavity receiver system (SDCR) is a typical high-grade concentrating and heat collecting device that is widely used in the field of solar thermal utilization [3]. Yan et al [9] proposed a mirror rearranging method for a parabolic dish concentrator and a novel discrete dish concentrator [10], which significantly improved the flux
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