JPS63122997A - Radioactive gas waste processor - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a radioactive gaseous waste treatment device in an atomic couplant, and particularly to an improvement in a hydrogen and oxygen injection control system.

(Prior art) Generally, in a boiling water type atomic coupler plant, a radioactive gas waste treatment device is installed inside the plant, and the radioactivity of the radioactive gas waste generated in the plant is sufficiently attenuated before being released into the atmosphere. I have to.

In addition, in nuclear couplers, hydrogen gas (
H2) is injected and combined with oxygen gas (0□) generated by radiolysis of reactor water in the reactor core to produce water, reducing dissolved oxygen in reactor water and suppressing radiolysis of reactor water. to suppress the generation of hydrogen gas and oxygen gas.

By the way, when hydrogen gas is injected into the secondary system piping, the gaseous waste hydrogen gas consists of the injected part and the radiolyzed part, and the oxygen gas consists of the radiolyzed part and the main condenser. Hydrogen gas and oxygen gas no longer exist in a stoichiometric ratio.

For this reason, in radioactive gas waste processing equipment, a line for supplying oxygen gas is provided upstream of the recombiner, and an equivalent amount of oxygen gas is supplied to recombine hydrogen gas.

FIG. 2 shows a conventional radioactive gaseous waste treatment apparatus of this type, which is designed to attenuate the radioactivity of radioactive gaseous waste from the nuclear reactor system.

The reactor secondary system is connected to the reactor pressure vessel 1 through a closed loop primary system piping 2 to the turbine 3. It is constructed by sequentially connecting a turbine condenser 4 and a condensate purification device 5, and the sub-system piping 2 has a main steam pipe 2A and a water supply pipe 2B, and the turbine condenser 4 has: A radioactive gas waste treatment device is connected.

As shown in FIG. 2, this radioactive gas waste treatment apparatus connects an air extractor 7. Recombiner 8° Condenser 9. Multiple rare gas hold up towers 10° vacuum pumps 11.
and a stack 12 are connected in sequence. A hydrogen supply device 13 is connected to the water supply pipe 2B via a hydrogen injection pipe 14, and an oxygen supply device 15 is connected to the upstream side of the recombiner 8 via an oxygen injection pipe 16.

In the above configuration, from the hydrogen supply device 13 to the water supply pipe 2B
The hydrogen gas injected into the reactor pressure vessel 1 together with hydrogen and other gases generated by radiolysis of water,
Air is extracted by the air extractor 7 through the main steam pipe 2A and the turbine condenser 4, and is led to the radioactive gas waste treatment equipment.

On the other hand, oxygen gas from the oxygen supply bag rit15 is injected into the upstream side of the recombiner 8 through the oxygen injection pipe 16, and hydrogen and oxygen are recombined in the recombiner 8. Then, the recombined hydrogen and oxygen are removed together with water in the condenser 9.

The radioactive rare gas from which water has been removed is subjected to radioactivity attenuation treatment in the rare gas hold up tower 10, and after the radioactivity has been sufficiently attenuated, it is released into the atmosphere from the stack 12 via the vacuum pump 11.

(Problems to be Solved by the Invention) In the conventional radioactive gas waste treatment equipment having the above configuration, this is applied to, for example, an 800,000 KWe class boiling water type atomic couplant, and the hydrogen concentration in the feed water is determined. If you want to set it to 2ppm, the main condenser leakage air amount should be 3ONTrl.
/h, the amount of hydrogen injected from the hydrogen supply device 13 is 1
100N/h, the amount of oxygen injected from the oxygen supply device 15 is 5
ONTIi/h, both of which are in large quantities, will cause a big problem if the injection control is not appropriate.

That is, if the start of oxygen injection is delayed from the appropriate timing when hydrogen injection is started, there is a risk that the hydrogen concentration on the downstream side of the recombiner 8 will fall within the explosive range (4 to 75 vol%), and conversely, If the oxygen injection starts earlier than the appropriate time, there is a risk that gas exceeding the processing capacity of the rare gas hold up tower 10 will flow.

Furthermore, when stopping hydrogen injection, if oxygen injection is stopped later than the appropriate time, there is a risk that gas exceeding the processing capacity of the rare gas hold up tower 10 will flow; If this happens too soon, the hydrogen concentration on the downstream side of the recombiner 8 will fall within the explosive range (4 to 75 vol%).
).

The present invention has been made in consideration of the above points, and an object of the present invention is to provide a radioactive gas waste treatment device that can take measures to prevent hydrogen explosion and maintain the function of rare gas holding capacity during hydrogen injection and when injection is stopped. With the goal.

[Structure of the invention]

(Means for Solving the Problems) The present invention provides a flow meter for detecting the flow rate of radioactive rare gas from the condenser on the upstream side of the rare gas hold up tower, and also provides each hydrogen and oxygen supply device with a flow meter for detecting the flow rate of radioactive rare gas from the condenser. , a controller is provided for controlling the injection of hydrogen and oxygen based on the signal from the flowmeter.

(Function) In the radioactive gas waste treatment apparatus according to the present invention, the flow rate of radioactive rare gas from the condenser is detected by a flow meter, and the hydrogen and oxygen controllers are controlled by signals from this flow meter. be done. Then start injection of hydrogen and oxygen,
The timing of stopping the infusion and the amount of infusion are controlled. For this reason,
It is possible to maintain hydrogen explosion protection and rare gas holding capacity during hydrogen injection and when injection is stopped.

(Example) An embodiment of the present invention will be described below with reference to FIG.

In FIG. 1, reference numeral 1 denotes a reactor pressure vessel, and the reactor pressure vessel 1 is connected to a turbine 3. A turbine condenser 4 and a condensate purification device 5 are connected in sequence to form a reactor-order system. A radioactive gas waste treatment device is connected to the turbine condenser 4 of the nuclear reactor subsystem.

As shown in FIG. 1, this radioactive gas waste treatment system consists of an air extraction device 7. which extracts exhaust gas from a reactor pressure vessel 1 via a turbine condenser 4. Recombiner 8 for recombining this bleed gas and oxygen. Condenser to condense and remove recombined water9. A plurality of rare gas hold up towers 10 for attenuating the radioactive rare gas from the condenser 9. A vacuum pump 11° for sucking rare gas whose radioactivity has been sufficiently attenuated and a stack 12 for releasing the rare gas from the vacuum pump 11 into the atmosphere are successively connected via piping 6. A hydrogen supply device 13 is connected to the water supply pipe 2B via a hydrogen injection pipe 14, and an oxygen supply device 15 is connected to the upstream side of the recombiner 8 via an oxygen injection pipe 16.

The above configuration is basically the same as that of the conventional radioactive gas waste processing apparatus, and in this embodiment, the following configuration is further added.

That is, on the upstream side of the rare gas hold up tower 10,
As shown in FIG. 1, a flow meter 17 is installed to detect the rare gas flow rate from the recombiner 8 side, and each injection pipe
4.16 are each equipped with a regulating valve 18.19 for controlling the injection amount. And these image adjustment valves 18.1
9 is controlled by a signal from the flow meter.

Next, the operation of this embodiment will be explained.

For example, the radioactive gas waste treatment apparatus according to this embodiment is
When applied to a 00,000 KWe class boiling water atomic coupler and trying to reduce the hydrogen concentration in the feed water to 2 ppm, the processing capacity of the rare gas hold up tower 1O is set to 3 ONm/h, and the amount of leakage air from the main condenser is set to 3 ONm/h. If it is 1ONTrl/h, the processing capacity margin of the rare gas hold up tower 10 is 3O-10-2O
NTIt/h.

The hydrogen injected into the water supply pipe 2B, together with the hydrogen generated by radiolysis of water in the reactor pressure vessel 1, is passed through the main steam pipe 2A and the turbine condenser 4 to the air bleeder 7 for radioactive gaseous waste treatment. However, on the downstream side of the recombiner 8, the hydrogen concentration is within the explosive range (4 to 75 vol).
1%), 2ONm/h of oxygen corresponding to the processing capacity margin of the rare gas hold up tower 10 is injected from the oxygen supply device 15 to the upstream side of the recombiner 8. At the same time or after this, 4 ONyd/h of hydrogen equivalent to the amount of injected oxygen is injected from the hydrogen supply device 13 into the water supply pipe 2B in response to a signal from the flow meter 17.

As a result, the injected oxygen and its equivalent amount of hydrogen are recombined in the recombiner 8, and removed as water in the condenser. Therefore, the flow meter 17 again indicates the condenser leakage air amount of 1ONTIt/h. Therefore, the above operation is repeated, and when the amount of hydrogen injection reaches 100 NTIi/h, the regulating valve 18 is fixed. As a result, the hydrogen concentration on the downstream side of the recombiner 8 is within the explosive range (4 to 75v
o1%), and gas that exceeds the processing capacity of the rare gas hold up tower 10 does not flow, making it possible to set the hydrogen concentration in the water supply to 2 ppm.

On the other hand, when stopping hydrogen injection, the hydrogen supply device 13
After stopping the hydrogen supply, the control valve 19 is driven to stop the injection of oxygen from the oxygen supply device 15 in response to a signal from the flow meter 17 indicating that it has reached 3ONm/h, which is the processing capacity of the rare gas hold up tower 10. . As a result, the hydrogen concentration on the downstream side of the recombiner 8 is within the explosive range (4 to 75vo 1%
), and rare gas hold up tower 1
Gas that exceeds the processing capacity of 0 does not flow, making it possible to stop hydrogen injection.

The above effects can be generally expressed as follows.

That is, the processing capacity of the rare gas hold up tower 10 is
Nm/h, the main condenser leakage air amount is xN/h, and the final hydrogen injection amount into the feed water is ANTrt/h, then the main condenser leakage air amount is xN1rl/h. It is detected by the flow meter 17, and the regulating valve 19 is driven by the signal from the flow meter 17, so that (X-x) Nrd/h of oxygen is injected into the upstream side of the recombiner 8.

At the same time or after this, the regulating valve 18 is driven by a signal from the flow meter 17, and 2 (X-x) Nrd/h of hydrogen is injected into the water supply pipe 2B. As a result, the injected oxygen and its equivalent amount of hydrogen are recombined in the recombiner 8 to become water, and the flow meter 17 again indicates xNm!
/h.

Thereafter, the above operation is repeated, and when the amount of hydrogen injected from the hydrogen supply device 13 reaches ANTrt/h, the regulating valve 18
is fixed.

On the other hand, when stopping the hydrogen injection, the hydrogen injection from the hydrogen supply device 13 is first stopped, and then the regulating valve 19 is driven by the signal reaching xNm/h indicated by the flow meter 17, and the oxygen supply device Oxygen injection from 15 is stopped.

In this way, each regulating valve 1
8.19 is controlled, the inlet side of the recombiner 8 is always in an oxygen-rich state, and the hydrogen concentration on the downstream side of the recombiner 8 is prevented from falling within the explosive range. Further, the flow of gas exceeding the processing capacity of the rare gas hold up tower 10 is also prevented.

〔Effect of the invention〕

As explained above, the present invention controls the injection of hydrogen and oxygen based on the rare gas flow rate signal on the upstream side of the rare gas hold up tower. This can prevent the hydrogen concentration on the side from falling within the explosive range, or prevent gas from flowing into the rare gas holding up tower in excess of its processing capacity. Therefore, it is possible to safely process hydrogen and improve operational reliability, and it is also possible to prevent an increase in radioactivity released into the environment.

[Brief explanation of the drawing]

FIG. 1 is a system diagram of a radioactive gas waste treatment apparatus showing an embodiment of the present invention, and FIG. 2 is a system diagram of a conventional radioactive gas waste treatment apparatus. 1... Reactor pressure vessel, 2B... Water supply pipe, 4...
Turbine condenser, 7... Air extractor, 8... Recombiner, 9... Condenser, 10... Rare gas hold up tower, 13... Hydrogen supply device, 14... hydrogen injection pipe,
15...Oxygen supply device, 16...Oxygen injection pipe, 17
...Flowmeter, 18.19...Adjustment valve.

Claims (1)

[Claims] 1. A hydrogen supply device that injects hydrogen into a water supply pipe of a reactor pressure vessel, an air bleeder that bleeds exhaust gas from the reactor pressure vessel via a main condenser, and this bleed gas an oxygen supply device that supplies oxygen, a recombiner that recombines the bleed gas and oxygen, a condenser that condenses the recombined water, and a rare gas that attenuates the radioactive rare gas from the condenser. In the radioactive gas waste treatment equipment equipped with a hold-up tower, a flow meter for detecting the flow rate of the radioactive rare gas is provided upstream of the rare gas hold-up tower, and each supply device is provided with a flow meter for detecting the flow rate of the radioactive rare gas. 1. A radioactive gas waste treatment device characterized by being equipped with controllers for controlling the injection of hydrogen and oxygen based on signals. 2. The controller that controls the injection of hydrogen and oxygen based on the signal from the flow meter has a hydrogen injection amount adjustment valve that controls the amount of hydrogen injection from the hydrogen supply device, and a hydrogen injection amount adjustment valve that controls the amount of oxygen injection from the oxygen supply device. 2. The radioactive gas waste treatment apparatus according to claim 1, further comprising an oxygen injection amount adjustment valve. 3. If the processing capacity of the rare gas hold-up tower is XN, the main condenser leakage air amount is xN, and the final hydrogen injection amount into the feed water is AN, then the oxygen injection amount control valve is (X
-x)N of oxygen to be injected into the upstream side of the recombiner, and the hydrogen injection amount adjustment valve is operated to inject 2(X-x)N of hydrogen into the water supply pipe. A radioactive gas waste treatment apparatus according to claim 2.