Effect of Inlet Throttling on Thermohydraulic Instability in a Large Scale Water-based RCCS: An Experimental Study
Authors
Lv, Qiuping; Jasica, Matthew; Lisowski, Darius; Ooi, Zhiee Jhia; Hu, Rui; Farmer, Mitch
Abstract
The objective of the present experimental study is to investigate the effect of inlet throttling on the thermohydraulic stability of a large scale water-based Reactor Cavity Cooling System (RCCS). The test was performed using the water-based Natural convection Shutdown heat removal Test Facility (NSTF) at Argonne, which represented a 1/2 axial scale and 12.5(degrees) sector slice of the full scale Framatome 625 MWt SC-HTGR RCCS concept. A two-phase steady state was first established through direct condensate refill, followed by increased inlet throttling over 10 stages, corresponding to a loss coefficient K over the range of 0.05-653. With the inlet throttling gradually increased, the system experienced a unique transition process between stabilization and destabilization. Through a stability analysis, three instability mechanisms were identified in the present test, including a compound mechanism due to both natural circulation oscillations (NCOs) and density wave oscillations (DWOs), Type -II DWOs, and geysering.