RU2626620C1 - Emergency system of boric acid solution supply to active zone of npp reactor - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: emergency system for boric acid solution supply to the core of the NPP reactor contains a storage tank with a solution of boric acid, pipelines, emergency feed pump, a suction pipeline that connects the pump sump with the system tank and the standard stock tanks of boric acid solution, a pressure pipeline connected to a regular pipeline supplying boric acid solution to the reactor core, recirculation pipelines, overflow and drainage and tank filling, pipelines of the system are equipped with adjusting, shut-off equipment and instrumentation. The system is provided with an autonomous source of boric acid and an autonomous supply of boric acid solution to the active zone of the reactor, one end of which is connected to a pressure pipeline immediately in front of the reactor and the other to an autonomous source of boric acid through a connection device and an autonomous feed pump.

EFFECT: invention makes it possible to provide the parking concentration of boric acid in the primary circuit in case of failures with complete blackout.

4 cl, 1 dwg

Description

The invention relates to nuclear energy, the field of its application is the reactor installation (RU) of water-water type power units of nuclear power plants (NPPs), and it can be used as an emergency cooling system for the reactor beyond design basis accidents associated with complete blackout of the NPP, and accidents with loss of the final absorber (external heat removal).

A known emergency system for supplying cooling water to the reactor, based on the principle of natural circulation, a backup system and a post-decay heat cooling system for the reactor (see DE 2521269 A, G21C 15/18, published in 1976). The emergency power system described in this source contains a backup circuit and a post-decay heat cooling circuit for a pressure-cooled reactor. In the circuit there is a post-decay heat cooler with a boric acid reservoir connected in parallel to it, in front of which a parallel circuit is connected from the pump and the pipeline closed by the valve. When the primary cooling circuit is intact, the pump pumps water through the after-decay heat cooler. In the event of an accident, the damper opens and natural circulation occurs through the after-decay heat cooler. To reduce the reactivity of the primary coolant by opening the corresponding valves in front of the boric acid reservoir, a pump can be connected, which makes it possible to feed boric acid into the primary cooling circuit. After the boric acid reservoir and the post-decay heat cooler, there is one single common choke with an adjustable transmission cross section. Such natural circulation systems are complex and are unlikely to be adapted to various cases of damage.

The closest technical solution to the invention is an emergency power supply and boronization system for a reactor cooled by water under pressure (see RU 2150153, G21C 15/18, G21C 9/00, publ. 2000), including standard reservoirs of stock of a solution of boric acid, pipelines with emergency feed pumps supplying a concentrated solution of boric acid from standard sources to the reactor core, a system for feeding containers with water, check valves, shut-off and throttling devices, valves.

The disadvantage of this system is that the action of the power system and the supply of boric acid solution for the reactor core is limited in time. The duration of this system is determined by the stock available in regular sources of stock of a solution of boric acid.

If there is a delay in stopping the chain reaction when the nuclear power is turned off or the chain reaction is interrupted altogether, in the event of a complete blackout of the nuclear power plant and / or the possibility of dampening by standard systems (in case of an earthquake, tornado or other strong destructive factors) is lost, the heat generated in the core, will not be allotted - the core will melt with all the ensuing consequences.

Based on the known systems for limiting damage in the event of an accident caused by a pressurized water reactor, the invention is based on the task of such an emergency cooling system for the reactor core (RU) of a nuclear power plant, taking into account the conventional design of redundancy reactors, so that additional reliability can be achieved at low cost and the amount of cooling water injected could be consistent with the progress of the accident.

The basis of the invention is the task of creating a system for emergency cooling of the reactor core (primary circuit) by supplying a concentrated solution of boric acid from autonomous sources to the core, the design of which allows the parking concentration of boric acid in the primary circuit of the reactor during accidents with complete blackout when there is no possibility supply of boric acid solution by standard systems, as well as in accidents with loss of the final heat sink (all cooling systems) and the impossibility of skholazhivaniya through steam generators.

As a solution to the problem, an emergency system is proposed for supplying a boric acid solution to the active zone of a nuclear power plant reactor, containing a reserve tank with a boric acid solution, tank filling pipelines from standard nuclear power plant systems, an emergency feed pump, a suction pipe connecting the pump inlet to the system tank and standard station tanks stocks of boric acid solution, pressure pipe connected to a regular pipeline for supplying boric acid solution to the reactor core, pipelines for recirculation, overflow and drainage and filling tank, pipelines of the system are equipped with regulating, shut-off and control and measuring equipment, according to the invention, the system is equipped with an autonomous source of boric acid and an autonomous pipeline for supplying a concentrated solution of boric acid to the reactor core, one end of which is connected to the pressure pipe directly in front of the reactor, and the other to an autonomous source of boric acid through a connecting device and a feed pump.

Also according to the invention, a motor pump connected to external autonomous sources of boric acid is used as an autonomous feed pump.

Also according to the invention, reinforced hoses are used as a connecting device for the motor pump and external stand-alone sources of boric acid.

According to the invention, a flexible connecting pipe with a device for quick connection is also used as a connecting device.

The introduction of these differences makes it possible to achieve additional reliability of nuclear power plants at beyond design basis accidents at low cost, matching the amount of cooling water introduced with the course of the accident.

The essence of the proposed technical solution is illustrated by the drawing, which shows the emergency cooling system of the active zone of the nuclear power plant.

The emergency system for supplying a boric acid solution to the reactor core of a nuclear power plant contains a tank 1 of a stock of concentrated boric acid solution, an emergency feed pump 2, a suction 3, a pressure 4 pipelines. The pump 2 is equipped with a recirculation pipe 5 with shutoff valves 6 and a throttle 7, which reduces the pressure in the pipeline. Pressure gauges are installed at the pressure and inlet of pump 2. Tank 1 is equipped with a level sensor 9, overflow and drainage piping 10 with shut-off valves 11, 12. Overflow and drainage pipelines 10 are connected to pipelines 13 of the tank farm system. The suction pipe 3 connects the suction of the pump 2 with the tank 1, as well as the standard station tanks stock of a solution of boric acid. The suction of pump 2 is separated from the tanks by shutoff valves 15 and 16. Pressure line 4 through a non-return valve 17, double shutoff valves 18, 19 and a shutter 20 between them are connected to a standard pipe 21 for supplying boric acid solution to the primary circuit of the reactor plant. An autonomous pipeline 22 for supplying a concentrated solution of boric acid to the first reactor circuit at nuclear power plants with double shut-off valves 23, 24 and a shutter 25 between them is connected at one end to the pressure pipe 4 by tapping it, and the other through a connecting device 26 and an autonomous feed pump 34, as the motor pump is used, it is connected to an autonomous source 35 with a solution of boric acid. Reinforced sleeves are used as a connecting device of the motor pump 34 and an autonomous source, and a flexible connecting pipe with devices for quick connection is used as a connecting device. Autonomous pipeline 22 is equipped with shutoff valves 27, 28 for venting and a drainage pipe 29 with shutoff valves 30. Tanks of regular stock (not shown in the drawing) are connected by a pipe 39, a pipe 36 with shutoff valves 16 and 31 with a suction pipe 2 in front of pump 2. To remove air from the system installed air vents 37, 38.

The filling of the system - tank 1 is carried out from the boron concentrate and fresh boric acid preparation system, through pipeline 39, then through pipelines 36 with open fittings 31, 16.

Drainage of the tank 1, if necessary, is carried out through the shut-off valves 32 and the check valve 33 into a regular stock tank of boric acid 14.

To prevent crystallization of boric acid in the tank 1, the system provides for the recycling of boric acid by switching on a regular low-power station pump according to the following scheme. The valves 11, 12 open, the standard station pump and the boric acid solution from the pump are turned on through the pipelines 13 of the tank farm, the valves 12, tank 1, the valves 11 and then to the pump inlet circulate in a closed circuit, while mixing boric acid in the tank 1 of the system .

If there is a signal that a complete blackout of the nuclear power plant has occurred and / or the possibility of dampening by standard systems (as a result of an earthquake, tornado, or other strong destructive factors) has been lost, the signal for the operator to supply a concentrated solution of boric acid to the primary reactor circuit at the nuclear power plant is put into operation .

The emergency system for supplying a solution of boric acid in the reactor core of a nuclear power plant operates as follows.

Before start-up, all valves in the system are closed. At the start signal of the system, the plug 20 is moved to the open position, the fittings 15 on the suction pipe 3, the fittings 6 on the recirculation pipe 5, the air vents 37 and the fittings 18 on the pressure pipe 4 open. Water from the tank 1 fills the suction 3 and pressure 4 pipelines to the fittings 19, while the air is removed from the system through the air vents 37. After filling the path, the air vents 37 are closed and the pump 2 is turned on, while the solution is circulated through the recirculation pipe 5 and the throttle installed on it 7, which provides the position of the operating point of the pump 2, in the working area QH characteristics. When the reading on the pressure gauge 8 reaches 18-20 MPa, the operator opens the valve 19 on the pressure pipe 4 and closes the valve 6 on the circulation pipe 5, after which the boric acid solution is supplied to the primary circuit of the switchgear. The supply of the solution is carried out until the value on the level gauge 9 reaches a minimum, which indicates the emptying of the tank 1. At the signal of the level gauge, the operator closes the valve 19 and turns off the pump 2. At this stage, the system can be completed and considered complete, since the volume the injected boric acid solution supplied from tank 1 to the first circuit of the reactor facility is sufficient to achieve a parking concentration of boric acid in the primary circuit of the reactor facility.

Then, other systems are connected that are designed to dampen the switchgear through the secondary circuit, however, if they cannot be operated, the system for supplying a concentrated solution of boric acid from autonomous sources to the primary circuit can also be used in the process of cooling the switchgear as follows.

Since the tank 1 is empty, the valve 15 closes, the air vent 38 opens, the pipeline 36 is filled with boric acid coming from the tanks of the regular supply of boric acid to the nuclear power plants via the pipeline 39 of boric concentrate and fresh boric acid. After filling the pipe 36, the air vent 38 closes and the valve 16 opens.

Considering that at this point the system worked out at the first stage of operation and the pipelines are in a filled state, to supply boric acid solution to the primary circuit of the switchgear, it is enough to start pump 2 and, when the pressure on gauge 8 is reached, the current value of the valve, open valve 19. B Further, it is necessary to control the operation of pump 2 by a pressure gauge 8 and level gauges in the tanks of the regular supply of boric acid, after emptying it is necessary to close the valve 19 and turn off the pump 2.

If the stocks of regular tanks of boric acid solution are not enough to completely cool down the switchgear, then the system provides the ability to connect an external standalone source 35 and a standalone feed pump - motor pump 34 for the final cool down switchgear. To do this, it is necessary in advance (when approaching the level of emptying of the stock tanks of boric acid) to prepare a motor pump 34 and a tank of an autonomous source of boric acid 35 (any tanks available and brought to the station), connect them together with reinforced sleeves and connect this whole structure to the connecting system device 26.

For the autonomous system to work, open the valve 23, the plug 25 and through the air vents 27, 28 to conduct gas removal from the pipelines, and then close the air vents 27, 28. The system is prepared for start-up and can be started by turning on the pump - motor pump 34 and opening the valve 24.

Using the proposed emergency core cooling system for the reactor core of the nuclear power plant allows for the supply of boric acid solution at all possible emergency operating modes, which significantly increases the reliability and safety of operation without increasing the metal and energy intensity of auxiliary equipment of the nuclear power plant.

Claims (4)

1. An emergency system for supplying a boric acid solution to the reactor core of a nuclear power plant, containing a reserve tank with a boric acid solution, tank filling pipelines from standard nuclear power plant systems, an emergency feed pump, a suction pipe connecting the pump inlet to the system tank and standard station stock tanks of boric solution stock acids, a pressure pipeline connected to a standard pipeline for supplying a boric acid solution to the reactor core, recirculation, overflow and drainage and tank filling pipelines, system pipelines equipped with control, shut-off and control and measuring equipment, characterized in that the system is equipped with an autonomous source of boric acid and an autonomous pipeline for supplying a boric acid solution to the reactor core, one end of which is connected to the pressure pipe directly in front of the reactor, and the other to the autonomous source of boric acid through a connecting device and a stand-alone feed pump. 2. An emergency system for supplying a boric acid solution to the reactor core of a nuclear power plant according to claim 1, characterized in that a motor pump is used as an autonomous feed pump connected to external autonomous sources of boric acid. 3. An emergency system for supplying a boric acid solution to the reactor core of a nuclear power plant according to claim 2, characterized in that reinforced hoses are used as a connecting device for the motor pump and external autonomous sources of boric acid. 4. An emergency system for supplying a solution of boric acid to the reactor core of a nuclear power plant according to claim 1, characterized in that a flexible connecting pipe with a device for quick connection is used as a connecting device.

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