A 24 kW metal halide Lamp-Based High-Flux solar simulator

A 24 kW high-flux solar simulator (HFSS) was designed, developed, and characterized to replicate concentrated solar radiation for high-temperature solar thermal applications. The HFSS consists of four 6 kW metal halide lamps, each coupled with ellipsoidal reflectors to achieve focused radiant heat flux at its secondary focal plane. To optimize the HFSS’s optical performance, a Monte Carlo ray tracing simulation was conducted to analyze light propagation within the lamp-reflector system and determine the plane of maximum heat flux. The accuracy of this simulation heavily depends on the arc source geometry, which plays a critical role in modeling the lamp-reflector configuration. The present work evaluates three different arc geometries viz. elliptical, cylindrical, and spherical. The elliptical arc source model, with a minor diameter of 10 mm and a major diameter of 23 mm, exhibited the closest agreement with experimental data. Notably, experimental results revealed that the plane of maximum heat flux did not coincide with the actual secondary focus of the reflector but rather occurred at a virtual secondary focus (VSF) located slightly above it. Experimental measurements recorded peak heat flux of 263 kW/m² for a single-lamp configuration and 647 kW/m² for the four-lamp module, while simulations based on the elliptical arc model predicted corresponding values of 275 kW/m² and 830 kW/m². A total radiant power output of 6.81  kW, corresponding to an energy transfer efficiency of 28.37 %, was recorded on a target area with a diameter of 170  mm at the virtual secondary focus (VSF) plane. These findings contribute to the advancement of HFSS technology, offering improved design methodologies for applications requiring intense and controlled solar irradiation.