Design basis for accidentThe RHR mu

Design basis for accident
The RHR must be able to control loss-of-coolant accident (LOCA) of any magnitude from a small break up to a double-ended break of a reactor coolant line (design basis accident).
The sequence of events and consequences of a LOCA are determined by the location, shape and above all, the size of the break. Distinctions must also be made in the countermeasures to be taken. The RHRS is therefore divided into various subsystems which meet the specific requirements resulting from any break cross-section.
Large break
The design basis accident is defined as the complete severance of a main reactor coolant pipe,
with the reactor coolant discharging from the system through twice the cross-section of the
pipe. The pressure of the RCS drops to the equalization pressure within the containment in
about 20 s. The sequence of the countermeasures actuated to contain this accident is as
follows:
•Core flooding by means of accumulator injection, high-pressure safety injection and low pressure
safety injection (function performed respectively the accumulators, the safety
injection (SI) pumps and the RHR pumps).
The accumulators, which automatically inject water into the reactor when its pressure drops
below the accumulator discharge pressure, are designed to flood, with the aid of the RHR and
SI pumps, the reactor pressure vessel so quickly that the permissible temperatures in the
reactor core are not exceeded and that the cladding temperatures drop continuously as
flooding progresses.
For this purpose, a motive-fluid pressure of 25 bar and a Water volume of 85 m3 that can be
safely injected into the reactor core are required. Taking into account failure considerations
and water losses during pressure relief and flooding, the accumulators are designed for 8x34
m3 of borated water.
•Emergency core cooling by low-pressure (LP) safety injection (RHR pump and SI pump
work in parallel).
After core flooding, the decay heat shall be removed without evaporative cooling. For this
purpose, a flow through the core of 306 Kg/s is required.
This flow rate constitutes the design basis of the RHR pumps assuming that only two of the
pumps are available, and that a part of the flow rate is lost through the leak into the reactor
building sump without reaching the core.
As this part of the injected flow of water is not involved in core cooling, the sump water is
cooler than the water in the core. The resulting temperature is below boiling point.
•Emergency core cooling in the recirculation mode (RHR pumps). When the borated water
supply available for low-pressure safety injection is exhausted, a sufficient amount of
water has flowed into the containment sump to allow further heat removal by cooling and
recirculating this water. This changeover takes place after about 1000 seconds. Account
has been taken in this case, too, of the fact that the water injected into the affected loop
section is not available for core cooling. In the recirculation mode, the flow is higher since
there is no backpressure.