Frieder Hecker scite author profile

The supercritical carbon dioxide (sCO2) heat removal system, which is based on a closed Brayton cycle with sCO2 as a working fluid, is an innovative, self-propelling and modular heat removal system for existing and future nuclear power plants. By changing the number of CO2 cycles, the heat removal capacity can be adapted. In this paper, up to four sCO2 cycles are analyzed in interaction with a pressurized water reactor, using the thermal-hydraulic system code ATHLET and considering a long-term station blackout and loss of ultimate heat sink scenario with conservatively high and low decay heat curves. The presented start-up procedure for the heat removal system might require further optimization due to the non-linear thermal gradients. Independent from the start-up, a heat removal system with three or four CO2 cycles keeps the primary loop temperatures sufficiently low. However, with only three cycles, the core is almost uncovered, and the danger of recriticality may occur due to cold leg deboration. Controlling the turbine inlet temperature via the turbomachinery speed and subsequent shutdown of single cycles successfully adapts the operation of the heat removal system to the declining decay heat. This enables reliable decay heat removal for more than 72 h.

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Conceptual design and qualification of highly effective heat exchangers for heat removal sCO2 Brayton cycle to increase the safety of nuclear power plants

Tioual-Demange¹,

Voirin²,

Hofer³

et al. 2021

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Simulation and analysis of a self-propelling heat removal system using supercritical CO2 at different ambient temperatures

Hofer¹,

Ren²,

Hecker³

et al. 2021

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Frieder Hecker

Simulation, analysis and control of a self-propelling heat removal system using supercritical CO2 under varying boundary conditions

Start-up, operation and thermal-hydraulic analysis of a self-propelling supercritical CO₂ heat removal system coupled to a pressurized water reactor

Conceptual design and qualification of highly effective heat exchangers for heat removal sCO2 Brayton cycle to increase the safety of nuclear power plants

Simulation and analysis of a self-propelling heat removal system using supercritical CO2 at different ambient temperatures

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Frieder Hecker

Simulation, analysis and control of a self-propelling heat removal system using supercritical CO2 under varying boundary conditions

Start-up, operation and thermal-hydraulic analysis of a self-propelling supercritical CO2 heat removal system coupled to a pressurized water reactor

Conceptual design and qualification of highly effective heat exchangers for heat removal sCO2 Brayton cycle to increase the safety of nuclear power plants

Simulation and analysis of a self-propelling heat removal system using supercritical CO2 at different ambient temperatures

Contact Info

Product

Resources

About

Start-up, operation and thermal-hydraulic analysis of a self-propelling supercritical CO₂ heat removal system coupled to a pressurized water reactor