Optical, thermal and thermo-mechanical model for a larger-aperture parabolic trough concentrator system consisting of a novel flat secondary reflector and an improved absorber tube.

• A novel flat reflector was incorporated into a PTC to improve overall performance. • An optimal diameter of the AT was also studied to meet the 580 °C outlet temperature and maximum temperature below 600 °C. • AT's optimal diameter was 70 mm for this design reaching a 75% optical efficiency and 60.8% thermal efficiency at DNI = 1000 W/m2. • The optical efficiency could be increased by 4–12% and improved the uniformity by 2%–22% through adding a novel FR. Using a larger-aperture parabolic trough concentrator can reduce cost and improve cycle efficiency. At present, the maximum output temperature of the typical parabolic trough concentrator systems is lower than the set 580 °C. Here a novel flat reflector was incorporated into the absorber tube to improve the intercept factor and optical efficiency and hence the overall performance. At the same time, the optimal diameter of the collector tube was also researched to meet the outlet temperature exceeding the set 580 °C and the absorber tube's maximum temperature below 600 °C. A large-aperture parabolic trough concentrator (8 m aperture wide with 80° half rim-angle) is used as a case to demonstrate the effect of a flat reflector and advantages of the optimal absorber tube. Results obtained through simulations show that, in the large-aperture parabolic trough concentrator system with the flat reflector, the optimal diameter of the absorber tube was 70 mm for this design reaching 75% optical efficiency and 60.8% thermal efficiency at DNI = 1000 W/m2 and 53% daily average thermal efficiency for DNI = 400–1000 W/m2. Through adding a flat reflector, the optical efficiency and the uniformity were increased by 4–12% and 2–22% respectively, but the benefit gradually decreases with increasing the absorber tube diameter. To meet the requirement of outlet temperature more than 580 °C and absorber tube's maximum temperature below 600 °C and reduce the thermal strain, a scheme of adjusting flow rate was incorporated. [ABSTRACT FROM AUTHOR]