JP2000241587A - Processing method for radioactive gas waste - Google Patents

Abstract

PROBLEM TO BE SOLVED: To operate an exhaust gas system in a period that vacuum of main condenser can not be ensured during plant startup, termination and plant outage. SOLUTION: When the vacuum pressure in main condenser lowered below a set value in a dehumidifier using hollow-fiber membrane, gas is sucked with a vacuum pump for purging and the exhaust gas is returned to upstream of the exhaust gas condenser 5 to independently operate. If differential pressure is measured in accordance with the due point monitoring at the outlet of the dehumidifier and it rises over a reference value, it is switched to a standby apparatus. By this, a dehumidifier using hollow-fiber membrane can operate an exhaust gas processing system independently without exhausting purge gas to the main condenser.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radioactive gas waste treatment and treatment method in which a method for removing moisture in a dehumidifier is improved.

[0002]

2. Description of the Related Art In general, a coolant in a boiling water reactor is irradiated with neutrons while passing through a reactor core, and is partially decomposed into oxygen and hydrogen, and furthermore, ³ H, ¹⁶ N, ¹⁹ O and the like occur. In addition, Kr and Xe
Such radioactive rare gases leak, and these rare gases are mixed into the coolant and sent to the turbine system. In addition, there is leakage from the outside air into the turbine main condenser.

[0003] Due to these radioactive gas wastes (hereinafter simply referred to as exhaust gas), it is necessary to maintain the soundness of the inside and the surroundings of a turbine system in a boiling water nuclear power plant by providing shielding facilities like a nuclear reactor. .

Since the exhaust gas is generally non-condensable, it stays in the steam system, particularly in the turbine main condenser. For this reason, conventionally, exhaust gas remaining in the turbine main condenser is bled by an air extractor, and guided to an activated carbon type rare gas hold-up tower for treatment.

FIG. 2 shows an example of a radioactive waste treatment facility installed in a conventional nuclear power plant. Exhaust gas retained inside a turbine main condenser is extracted by an air extractor 1 and extracted by a preheater. 3, recombiner 4 and exhaust gas condenser 5
To perform a hydrogen gas recombination and volume reduction process.

The exhaust gas guided from the air extractor 1 to the hydrogen recombining device 2 is first preheated by a preheater 3 to a temperature at which oxygen and hydrogen contained in the exhaust gas are efficiently recombined, and then downstream recombiner. 4, and hydrogen and oxygen in the exhaust gas are converted into steam by a recombination reaction. Further, in the exhaust gas condenser 5 downstream thereof, the water vapor in the exhaust gas is condensed by the cooling water by the external cooling water to become almost water and separated from the exhaust gas, and the separated water is sent to a turbine main condenser (not shown). Will be returned.

On the other hand, the exhaust gas from which water has been separated and removed is shown in FIG.
As shown in (2), after the moisture is sufficiently removed by the dehumidifier 6, it is guided to the activated carbon rare gas hold-up tower 7. The radioactive gas remaining in the exhaust gas (mainly X
e, Kr, etc.) are adsorbed on activated carbon, and after a long hold-up, are discharged from the exhaust pipe 9 to the atmosphere by the vacuum pump 8. In FIG. 2, reference numeral 10 denotes an activated carbon type rare gas hold-up tower room, 11 denotes an air conditioner, and 12 and 13 denote ducts.

[0008] These devices are each separated into airtight or similar rooms, and each room is air-conditioned. In particular, as shown in FIG. 2, separately from the general air conditioning of the activated carbon type rare gas hold-up tower room 10 and the like, air conditioning is performed from the dedicated air conditioning equipment 11 through the ducts 12 and 13, and the activated carbon is maintained to maintain the activated carbon adsorption performance. Noble gas hold-up tower inlet piping
The inside of 14 can be kept at a constant temperature.

FIG. 3 shows details around the conventional dehumidifier 6 shown in FIG. 2. In FIG. 3, a dehumidifier indicated by reference numeral 16 is a dehumidifier incorporating a hollow fiber membrane 17 having a large water vapor transmission coefficient.
A part of the primary gas dried by the dehumidifier 16 on the secondary side of the hollow fiber membrane 17 is used for purging on the secondary side of the hollow fiber membrane 17, and the secondary side is set at a pressure lower than the primary side pressure by the vacuum pressure of the main condenser. By suctioning the water, a partial pressure difference of steam is provided between the primary side and the secondary side of the hollow fiber membrane 17 to perform dehumidification.

In FIG. 3, reference numeral 18 denotes a purge gas flow meter, 19 denotes a purge gas amount adjusting valve, 20 denotes a purge gas pressure adjusting valve, 21 denotes a purge gas pressure adjustment, 22 denotes a dehumidifier outlet pressure gauge, and 24 denotes a dehumidifier outlet flow rate. Reference numeral 25 denotes a dehumidifier outlet flow control valve.

[0011]

In the conventional radioactive gas waste treatment method, the vacuum pressure of the main condenser is used as a method of sucking the secondary side of the dehumidifier 16 to a pressure lower than the primary side pressure. However, when the vacuum pressure of the main condenser cannot be secured at the time of starting and stopping the plant, there is a problem that the gas waste treatment system cannot be operated. In addition, there is also a problem that the independent operation of the gas waste treatment system cannot be performed because the vacuum pressure of the main condenser cannot be ensured even at the time of the periodic inspection.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and can continuously remove moisture in exhaust gas without using the vacuum pressure of a main condenser, thereby obtaining high reliability. It is an object of the present invention to provide an apparatus for treating radioactive gas waste.

[0013]

SUMMARY OF THE INVENTION According to the present invention, a radioactive gas waste generated in a nuclear power plant is led from a main condenser through an air extractor to a hydrogen recombiner to perform hydrogen gas recombining and volume reduction processing. At the same time, the exhaust gas from the hydrogen recombiner device is guided to a dehumidifier having a built-in hollow fiber membrane having a high vapor permeability coefficient, and a secondary gas of the primary fiber dried by the dehumidifier is provided on the secondary side of the hollow fiber membrane. Part is used for purging, and after removing moisture, it is guided to an activated carbon type noble gas hold-up tower to perform a delay treatment. The part is used for purging, and the secondary side is suctioned to a pressure lower than the primary side by a vacuum pump for purging, thereby providing a partial pressure difference of steam between the primary side and the secondary side of the hollow fiber membrane, and is discharged from the vacuum pump for purging. Characterized in that to allow the independent operation of the gaseous waste treatment system even during plant shutdown by returning the secondary waste gas from a connected circulation line on the upstream side of the turbine main condenser.

[0014] Further, when the humidity below a required percentage cannot be obtained due to the operation state of the dehumidifier, the humidity is detected by a dew point meter installed in the system and switched to a dehumidifier having a spare hollow fiber membrane built-in. , Ensuring the performance.

Further, when the differential pressure decreases or increases due to the operation state of the dehumidifier, the differential pressure is detected by a differential pressure gauge installed in the system, and the performance is switched to a dehumidifier having a built-in spare hollow fiber membrane. It is characterized by securing.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the method for treating radioactive gas waste according to the present invention, a dehumidifier 16 incorporating a hollow fiber membrane 17a having a large water vapor transmission coefficient as shown in FIG.
a is used, is drawn by the air extractor 1 shown in FIG. 2, and passes through the hollow fiber membrane 17a of the dehumidifier 16a.

In this state, a part (for example, 20%) of the primary gas dried by the dehumidifier 16a is used for purging, supplied to the outside of the hollow fiber membrane, and the vacuum pump 38 for purging is used. Or to a pressure lower than the primary side.

As a result, the difference in partial pressure of water vapor between the primary side and the secondary side of the hollow fiber membrane 17a is increased, thereby improving the water vapor transmission performance and removing the water vapor in the exhaust gas most efficiently.
That is, the water vapor component in the exhaust gas is removed through the hollow fiber membrane, and the humidity of the exhaust gas is less than a required percentage, for example, 40%.
% Or less.

The exhaust gas sucked by the purging vacuum pump 38 is returned to the circulation line 40 connected upstream of the condenser so that the gas waste treatment system can be operated independently even when the plant is stopped. It is possible.

When the humidity of the required percentage or less cannot be obtained due to the state of the dehumidifier 16a, the humidity is detected by a dew point meter installed in the system, and a spare hollow fiber membrane is detected.
By switching to the dehumidifier 16b having the built-in 17b, the dehumidifying performance can be secured.

When the pressure difference increases or decreases due to the state of the dehumidifying device, the pressure difference is detected by a differential pressure gauge installed in the system, and the dehumidifying device is switched to a dehumidifying device having a spare hollow fiber membrane. Can be secured.

One embodiment of the method for treating radioactive gas waste according to the present invention will be described with reference to FIGS. FIG. 1 shows a configuration around a dehumidifier 16 (16a, 16b) in an exhaust gas treatment apparatus. In the figure, dehumidifiers 16a, 16b are dehumidifier inlet valves 31a, 31b and dehumidifier outlet valves 32a, 32b.
, And only one system is operated during normal operation.

The wet exhaust gas to be treated (temperature: 40 ° C., dew point: 100%, pressure: 0.8 at) flows from the exhaust gas condenser 5 to the dehumidifiers 16a, 16b. In each of the dehumidifiers 16a and 16b, as shown in FIG.
a and 17b are attached, and the exhaust gas sucked by the purge vacuum pump 38 is supplied to each of the hollow fiber membranes 17 and 17b.
a, 17b.

During operation with the dehumidifier 16a, the temperature of the exhaust gas is measured by the dehumidifier outlet dew point meter 23, and when the temperature exceeds the permissible dew point of the system (for example, -20 ° C.), an alarm is issued, or By closing the inlet valve 31a and the outlet valve 32a of the dehumidifier a and opening the dehumidifier inlet valve 31b and the outlet valve 32b to switch the operation unit, the moist exhaust gas is prevented from flowing to the activated carbon rare gas hold-up device. To

The pressure in the system is measured by a condenser outlet pressure gauge 27. When the system pressure exceeds the system operation set pressure (for example, atmospheric pressure), the condenser outlet circulating water line valve 24 is opened to open the condenser. By adjusting the outlet circulation line pressure adjustment valve 30, the pressure of the system is kept within a set value.

The dehumidifier inlet flow meter 28 ensures a flow rate suitable for the throughput of each of the dehumidifiers 16a and 16b by adjusting the dehumidifier inlet flow rate regulating valve 19, thereby performing a stable operation of the system.

The interior of each of these dehumidifiers 16a and 16b is shown in FIG.
As shown in FIG. 7, a part (for example, 20%) of the primary gas dried by the dehumidifiers 16a and 16b is used for purging, and the purge gas amount is changed from the purge gas flow meter 18 to the dehumidifier inlet flow meter 28.
The amount corresponding to about 20% of the exhaust gas treatment amount measured by the above is ensured by adjusting the purge gas amount adjustment valve 20.

The pressure of the purge gas is regulated by the purge gas pressure regulating valve 20 according to the set pressure of the purge gas manometer 36, while the plant is in operation, by the main condenser, and when the plant is stopped, the vacuum pump for purging. 36 allows suction at a lower pressure than the primary side.

The exhaust gas sucked by the purge vacuum pump is circulated to the upstream of the exhaust gas condenser 5 by the circulation line 40, so that the off-gas (OG) system can be operated independently even when the plant is stopped. .

As a result, the water vapor in the exhaust gas flowing through the hollow fiber membranes 17a and 17b is separated and removed through the hollow fiber membranes 17a and 17b, and the relative humidity of the exhaust gas is reduced to a required percentage, for example, approximately 40%. It is as follows. This is because the exhaust gas supplied to the activated carbon type rare gas hold-up tower 7 needs to have a relative humidity of 40% or less.

Further, the purge gas can be selected by switching the purge gas inlet valves 34a, 34b and the purge gas outlet valves 35a, 35b with respect to the operation system of the processing apparatus.

Next, a method of removing moisture in each of the dehumidifiers 16a and 16b will be described. In FIG. 1, the dehumidifier 16a
Assuming that the system on the side is being processed, the condenser 5
The exhaust gas cooled by the steam and condensed is dehumidified by the vacuum pump 8 (see FIG. 2) which sucks the system, and is supplied to the dehumidifier inlet valve 31.
The liquid is guided to the dehumidifying device 16a via a, and passes through the hollow fiber membrane 17a.

At this time, the inside of the dehumidifier 16a is adjusted to an appropriate flow rate of the dried purge gas by the purge gas amount control valve 19, and the purge gas is flowed into the dehumidifier 16a via the purge gas inlet valve 34a. Improve.

In order to evacuate the interior of the dehumidifier 16a to maintain a pressure lower than the pressure of the primary system, a purge vacuum pump 38 is used, and a purge gas pressure gauge 36 is supplied through a purge gas outlet valve 35a. The pressure is adjusted by the purge gas pressure adjusting valve 20 according to the set value. As a result, an appropriate evacuation is performed, so that the water vapor component in the exhaust gas flowing through the hollow fiber membrane 17a is removed by passing through the hollow fiber membrane 17a and returned to the upstream side of the turbine main condenser via the circulation line 40. It is.

For this reason, the exhaust gas after passing through the dehumidifier 16a has a relative humidity of a required percentage, for example, 40%.
The delay process is performed by being guided to the activated carbon rare gas hold-up tower 7 (see FIG. 2) via the dehumidifier outlet valve 32a.

If a trouble or the like occurs in the dehumidifier 16a and the dew point meter 23 at the outlet of the dehumidifier 16a becomes larger than the set value, the dehumidifier inlet valve 31a, the dehumidifier outlet valve 32a, the purge gas inlet valve 34a and the purge gas The outlet valve 35a is closed. At the same time, the dehumidifier inlet valve 31b, the dehumidifier outlet valve 32b, the purge gas inlet valve 34b, and the purge gas outlet valve
35b is opened, and the system is switched to the dehumidifier 16b side.

If a trouble or the like occurs in the dehumidifier 16a and the differential pressure gauge 33 of the dehumidifier 16a deviates from an allowable value, the dehumidifier inlet valve 31a, the dehumidifier outlet valve 32a, the purge gas inlet valve 34a and the purge gas outlet 34a. The valve 35a is closed.
At the same time, the dehumidifier inlet valve 31b and the dehumidifier outlet valve 32
b, purge gas inlet valve 34b and purge gas outlet valve 35b
Is opened, and the system is switched to the dehumidifying device 16b side.

[0038]

According to the present invention, when the plant is started and stopped,
Also, the exhaust gas system can be operated during a period in which the vacuum of the turbine main condenser cannot be secured while the plant is stopped. Further, air that is not dehumidified during the operation during the periodic inspection does not flow into the rare gas hold-up system.

[Brief description of the drawings]

FIG. 1 is a system diagram showing the surroundings of a dehumidifier for explaining an embodiment of a method for treating radioactive gas waste according to the present invention.

FIG. 2 is a system diagram showing a conventional radioactive gas waste treatment facility.

FIG. 3 is a system diagram showing the periphery of a dehumidification tower in FIG. 2;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Air extractor, 2 ... Hydrogen recombiner, 3 ... Exhaust gas preheater, 4 ... Exhaust gas recombiner, 5 ... Exhaust gas condenser, 6 ... Dehumidifier, 7 ... Activated carbon type rare gas hold-up tower, 8 ... Vacuum pump, 9 exhaust pipe, 10 activated carbon rare gas hold-up tower room, 11 air conditioning equipment, 12, 13 duct, 14 activated carbon rare gas hold-up tower inlet piping, 15 dehumidifier inlet flow control valve , 16, 16a, 16b ... dehumidifier, 17, 17a, 17b
... hollow fiber membrane, 18 ... purge gas flow meter, 19 ... purge gas amount adjustment valve, 20 ... purge gas pressure adjustment valve, 21 ... purge gas pressure adjustment valve outlet valve, 22 ... dehumidifier outlet pressure gauge, 23 ... dehumidifier outlet dew point meter, 24: Dehumidifier outlet flow meter, 25: Dehumidifier outlet flow control valve, 26: Condenser outlet thermometer, 27: Condenser outlet pressure gauge, 28: Dehumidifier inlet flow meter, 29: Condenser outlet circulation Line valve, 30… Condenser outlet circulation line pressure regulating valve, 31
… Dehumidifier inlet valve, 32… Dehumidifier outlet valve, 33… Dehumidifier differential pressure gauge, 34… Purge gas inlet valve, 35… Purge gas outlet valve, 36… Purge gas pressure gauge, 37… Purge vacuum pump inlet valve, 38… Purge Vacuum pump, 39… Vacuum pump outlet check valve for purging, 40… Circulation line.

Claims (4)

[Claims] 1. A radioactive gas waste generated from a nuclear power plant is led from a main condenser through an air extractor to a hydrogen recombiner to perform recombining of hydrogen gas and volume reduction by an exhaust gas condenser. In addition, after the exhaust gas from the exhaust gas condenser is guided to a dehumidifier to remove moisture, the radioactive gas waste treatment method of performing a delay treatment by leading to an activated carbon rare gas hold-up tower, wherein the dehumidifier Using a dehumidifier incorporating a hollow fiber membrane having a large water vapor transmission coefficient, a part of the primary gas dried by the dehumidifier on the secondary side of the hollow fiber membrane is used for purging, and the vacuum of the main condenser is used. Pressure, or when the vacuum pressure of the main condenser is low, such as during a plant stop, by suctioning the secondary side from the primary side pressure to a low pressure by a purge vacuum pump, the primary side of the hollow fiber membrane and the secondary side Partial pressure of steam on the side A method for treating radioactive waste, comprising setting a difference and returning secondary exhaust gas discharged from the purging vacuum pump from a circulation line connected upstream of the exhaust gas condenser. 2. When the humidity of a required percentage or less cannot be obtained due to the state of the dehumidifying device, the humidity is detected by a dew point meter installed in the system, and the device is switched to a dehumidifying device having a built-in spare hollow fiber membrane. 2. The method according to claim 1, wherein
The method for treating radioactive waste described in the above. 3. The state of the dehumidifier is detected by a dew point meter installed in the system, and the relative humidity of the radioactive gas waste is adjusted to an appropriate purge gas amount so as to be within a required percentage range. The method for treating radioactive waste according to claim 1 or 2, wherein: 4. The dehumidifier according to claim 1, wherein the state of the dehumidifier is detected by a differential pressure gauge installed in a system, and when a differential pressure abnormality occurs in the system, the system is switched to a preliminary dehumidifier. 3. The method for treating radioactive waste according to 3.