Abstract
Solar-powered direct steam generation (DSG) is attractive for power generation and industrial utilization due to the combination of renewable-energy source and clean energy carrier. An improved SIMPLE algorithm ensuring the dual roles of pressure acting on velocity and density fields is developed to realize thermo-hydraulic completely-coupled modeling of a typical DSG loop with transient phase-change and multiple flow-patterns. The excitation-response characteristics of the loop were investigated under various step-variations of direct normal irradiance (DNI), inlet mass flowrate (min) and inlet temperature (tin). Increasing DNI (decreasing min) is found to narrow the preheating-evaporation regions and expand the superheating region, and vice versa. While under step-variations of tin, the evaporation region almost remains unchanged (about 403 m). The water slides to a lower temperature faster than climbs to a higher one under variations of DNI (up to 670s vs. 2960s) and min (up to 1184s vs. 4420s), simultaneously the outlet temperature (tout) staying a monotonical response-trend. However, under tin variations, tout holds a higher-order trait. The responses of both pressure and velocity are tightly coupled and always hold higher-order trait. The response time of the total mass in the loop is almost 2.5 to 5.5 times as fast as tout.
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