Abstract
The pebble bed high temperature gas-cooled reactor is a promising generation-IV reactor, which uses large fuel pebbles and helium gas as coolant. The pebble bed flow is a fundamental issue for both academic investigation and engineering application, e.g., reactor core design and safety analysis. This work performed a review of recent progress on pebble flow study, focusing on the important issues like pebble flow, gas phase hydrodynamics, and inter-phase heat transfer (thermal hydraulics). Our group’s researches on pebble flow have also been reviewed through the aspects of phenomenological observation and measurement, voidage distribution, geometric and parameter optimization, pebble flow mechanisms, flow regime categorization, and fundamentals of modelings of pebble flow and radiation. Finally, the major problems or possible directions of research are concluded which would be some of our focuses on the pebble bed flow study.
Highlights
The pebble bed high temperature gas-cooled reactor is a promising generation-IV reactor, which uses large fuel pebbles and helium gas as coolant
The TRISO particles are scattered in a sphere of graphite matrix of a diameter Df = 5.0 cm to form the fuel zone, which is surrounded by a 5 mm thick fuel free zone composed of graphite matrix
The UO2 kernel of about Dk = 0.5 mm is surrounded by a TRISO coating consisting of the buffer pyrocarbon layer, the inner high-density pyrocarbon layer (IPyC), the silicon carbon guinan@mail.tsinghua.edu.cn (SiC) layer, and the outer high-density pyrocarbon layer (OPyC)
Summary
A commercial-scale 200 MWe high temperature gas-cooled reactor pebble bed module project (HTR-PM, Fig. 3 (Sun et al, 2018)) is under construction at Shandong Province in China. The HTR-PM nuclear power plant has two pebble-bed modular reactors, which are connected to one steam-turbine generator. The total power of them is 500 MWt, and the electrical generating efficiency. The reactor core of HTR-PM is a randomly packed pebble bed of 3.0 m in diameter and 11 m in height on average, containing roughly 420,000 spherical fuel elements with a diameter of 6.0 cm (Zheng et al, 2018). The pebble flow characteristics could be of great importance for the HTR-PM
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