JPH10339794A - Gas waste treatment facility - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the configuration of a facility and to improve reliability by providing a catalyst for recombining hydrogen and oxygen in an exhaust gas in an air extractor or at the upstream of the extractor. SOLUTION: Hydrogen gas and oxygen gas in a non-condensation gas being extracted from a main steam condenser 1 by a first ejector are recombined in a recombination equipment 4. A cooler 2b condenses a main steam for driving the first ejector 2a. As a result, a rare gas hold-up tower 9 achieves dry conditions required for using activated carbon. Water of an exhaust gas being treated in an air extractor 2 is eliminated by a pre-cooler 6 and a dryer 7, the exhaust gas is guided from a pre-filter 9 to the rare gas hold-up tower 9, thus reducing the amounts of nuclides with short half-lives in a rare gas. In a facility, three conventional equipment is abolished to simplify its configuration. Also, hydrogen gas does not flow to the downstream side of the first ejector 2a, is combusted in the main steam condenser 1 even in the case of hydrogen combustion, and the heat can be fully eliminated in the main steam condenser 1, thus preventing the influence of hydrogen combustion to the facility and improving the reliability.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas waste treatment facility for a boiling water nuclear power plant, and more particularly to a gas waste treatment facility suitable for removing hydrogen / oxygen from gas waste.

[0002]

2. Description of the Related Art A conventional gaseous waste treatment facility is composed of a facility for treating hydrogen / oxygen and a facility for attenuating rare gases with time, as described in the Nuclear Handbook (Ohm Co., 1989). I have.

FIG. 2 shows a schematic configuration of a conventional gaseous waste treatment facility. In a boiling water nuclear power plant, the turbine is driven directly by the main steam generated in the nuclear reactor. The main steam contains hydrogen gas and oxygen gas generated by the radiolysis of reactor water, and rare gas which is a fission product such as a small amount of radioactive krypton and xenon generated from fuel. The concentration of hydrogen gas and oxygen gas in the main steam is on the order of ppm and does not pose a problem of hydrogen combustion.

[0004] After the turbine is driven, the main steam is returned to water in the main condenser 1 and supplied again into the nuclear reactor. In the main condenser 1, hydrogen gas, oxygen gas and rare gas remain as gases due to non-condensability. The gas in these main condensers is reduced to a hydrogen concentration of 4 vol% (vol%) or less by a steam driven air extractor 2 and guided to a downstream processing system.

[0005] In the air extractor 2, the main condenser 1 having a large capacity is used.
A large amount of water vapor is required to extract gas from water.
For this reason, the air extractor 2 is composed of a two-stage ejector (a first ejector and a second ejector) and a cooler therebetween.

The gas treated by the air extractor 2 is supplied to a preheater 3
The hydrogen gas and the oxygen gas react by the catalytic action of the recombiner 4 and are condensed as steam in the exhaust gas condenser 5. The condensed water condensed in the exhaust gas condenser 5 is returned to the main condenser 1. Exhaust gas components at this time are mostly air mixed in the main condenser 1,
Contains a very small amount of noble gas.

Next, the exhaust gas passes through a precooler 6, a dryer 7, and a pre-filter 8, and is led to an activated carbon type rare gas hold-up tower 9. The rare gas hold-up tower 9 attenuates nuclides having a short half-life in the rare gas by utilizing the characteristic that the equilibrium adsorption amount of the rare gas to activated carbon is larger than that of oxygen or nitrogen. The exhaust gas that has passed through the rare gas hold-up tower 9 passes through the particle filter 10 and the vacuum pump 11 and is discharged into the atmosphere from the main exhaust pipe 12 together with the ventilation exhaust of each building.

[0008]

In the above prior art, the hydrogen gas and the oxygen gas are transported out of the main condenser 1 by mixing the steam with the air extractor 2, heated by the preheater 3 and then recombined. The recombination on the catalyst in the vessel 4 complicates the treatment process and configuration.

An object of the present invention is to provide a gaseous waste treatment facility which can improve reliability with a simple structure.

[0010]

According to a first aspect of the present invention, an exhaust gas is extracted from a condenser of a boiling water nuclear power plant using an air extractor, and the extracted exhaust gas is treated. In the gaseous waste treatment facility, a catalyst for recombining hydrogen and oxygen in the exhaust gas is provided inside the air extractor or upstream of the air extractor.

According to a second aspect of the present invention, in a gas waste treatment facility for treating exhaust gas extracted from a condenser of a boiling water nuclear power plant, hydrogen and oxygen contained in the exhaust gas are connected to an exhaust gas outlet of the condenser. A recombiner for recombining, an air extractor disposed downstream of the recombiner for extracting the exhaust gas from the condenser, and an air extractor disposed downstream of the air extractor and containing the exhaust gas. A rare gas removing device for removing the rare gas.

Conventional hydrogen / oxygen recombination catalysts have been considered to have reduced activity due to water or steam. But,
According to recent findings, by making the catalyst hydrophobic,
The activity hardly decreases even under the saturation condition (100% relative humidity). Therefore, the hydrogen gas and the oxygen gas can be recombined by installing a hydrophobic catalyst or a catalyst having a hydrophobic property in a region where the relative humidity is high in the air extractor or on the upstream side of the air extractor. .

On the upstream side of the air extractor, hydrogen combustion is likely to occur because hydrogen gas and oxygen gas are present at an equivalent ratio of approximately 2: 1. The amount of heat generated by the combustion of the hydrogen gas and the oxygen gas can be expressed by the following chemical formula 1.

[0014]

Embedded image H ₂ + (Ｏ) O ₂ = H ₂ O + 57.8 kcal / mol The above-mentioned exotherm is the same even when the catalyst is recombined. Therefore, when the catalyst is used in a state where the amount of water vapor is small, it is necessary to cool the atmosphere around the catalyst to a temperature lower than the natural ignition temperature of hydrogen (about 560 ° C. under 1 atm). However, even if the fire is ignited, the flame proceeds into the main condenser on the upstream side where hydrogen gas is present, and even if it generates heat, there is no problem because the heat removal performance in the main condenser is sufficient.

As described above, by providing a hydrophobic catalyst in the air extractor or on the upstream side of the air extractor, hydrogen gas can be safely treated.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the gas waste treatment equipment according to the present invention will be described below with reference to FIG. The present embodiment is an example in which non-condensable gases in three main condensers 1 are collectively processed.

The gaseous waste treatment equipment includes a recombiner 4 connected to the main condenser 1, an air extractor 2, a pre-cooler 6, a dryer 7, and an air extractor disposed downstream of the recombiner 4. Filter 8,
It is composed of a rare gas hold-up tower 9, a particle filter 10, a vacuum pump 11, and the like. The air extractor 2 includes a first ejector 2a for extracting non-condensable gas in the main condenser 1.
And a cooler 2b.

The hydrogen gas and the oxygen gas in the non-condensable gas extracted from the main condenser 1 by the first ejector 2 a are recombined in the recombiner 4. In order to extract exhaust gas (non-condensable gas) from the large-capacity main condenser 1, the first ejector 2a
Is driven by main steam. The cooler 2b provided downstream of the first ejector 2a condenses the main steam for driving the first ejector 2a. Thereby, the rare gas hold-up tower 9 on the downstream side achieves the dry condition necessary for using the activated carbon.

The exhaust gas component that has passed through the air extractor 2 is mostly air mixed into the main condenser 1 and contains a very small amount of rare gas. The exhaust gas treated by the air extractor 2 is led to a rare gas hold-up tower 9 through a pre-cooler 6, a dryer 7, and a pre-filter 8. The pre-cooler 6 and the dryer 7 remove moisture in the exhaust gas.

The rare gas hold-up tower 9 attenuates nuclides having a short half-life in the rare gas by utilizing the characteristic that the amount of equilibrium adsorption of the rare gas on activated carbon is larger than that of oxygen or nitrogen. The exhaust gas that has passed through the rare gas hold-up tower 9 passes through a particle filter 10 and a vacuum pump 11,
The air is discharged from the main exhaust pipe 12 to the atmosphere together with the ventilation exhaust of each building.

Next, the recombiner 4 will be described. The recombiner 4 contains a hydrophobic catalyst, and is cooled so that the temperature around the catalyst does not exceed the auto-ignition temperature of hydrogen. The catalyst is a platinum catalyst comprising a stainless steel (SUS) screen and a hydrophobic, large surface area carrier. In addition, a catalyst obtained by subjecting a noble metal catalyst of palladium or platinum supported on alpha alumina, titanium oxide, or the like to a hydrophobic treatment by Teflon coating or the like can be used. The shape of the catalyst may be granular, reticulated, spongy, perforated, or the like, and has a structure capable of removing reaction heat generated on the catalyst. Alternatively, platinum may be plated on a metal such as SUS.

FIG. 3 shows an embodiment of the recombiner 4. This recombiner includes a lattice-shaped SUS plate 4b carrying a hydrophobic noble metal catalyst on the surface thereof, and a container 4a containing the SUS plate 4b.
Consists of Reaction heat generated by the catalyst is removed by heat conduction by the SUS plate 4b and cooling of the outside of the container 4a. The grid-like SUS plate 4b is formed in three stages, and the grids are shifted to improve the contact efficiency between the exhaust gas (reactive gas) and the catalyst.

Considering the aging of the catalyst, the flow of the exhaust gas is preferably from the top to the bottom. The amount of catalyst depends on the performance of the catalyst, but is about 5 m for a typical boiling water reactor.
The surface area of the catalyst layer ² is required. Regarding the flow rate of the exhaust gas in the recombiner 4, the reaction efficiency of the catalyst increases as the flow rate increases, but it should not exceed about 9 m / s of the flame propagation speed of hydrogen combustion at the equivalent ratio. Thus, even if hydrogen combustion occurs, it is not necessary to propagate the flame downstream.

According to this embodiment, the second ejector, preheater, and exhaust gas condenser of the conventional air extractor can be omitted.
The configuration of the gas waste treatment facility can be simplified.

Also, the hydrogen gas does not flow downstream of the first ejector 2a of the air extractor 2, and even if hydrogen combustion occurs, it burns in the main condenser 1 and this heat is transferred to the main condenser 1. Since it can be sufficiently removed within 1, there is no influence of hydrogen combustion on the equipment.
That is, the reliability of the equipment can be improved.

In this embodiment, an example has been described in which the main steam is used for driving the first ejector 2a. However, compressed air may be used. In this case, since it is not necessary to remove moisture as in the case of the main steam, the cooler 2b, the precooler 6, and the dryer 7 can be omitted. This further simplifies the configuration of the gaseous waste treatment facility.

Next, a second embodiment of the gas waste treatment equipment according to the present invention will be described with reference to FIG. FIG. 4 omits the configuration after the precooler 6 in FIG. 1. This embodiment differs from the first embodiment in that the recombiner 4 is installed at the outlet (outside) of each main condenser 1. Other configurations are the same as those of the first embodiment.

In the present embodiment, a recombiner 4 is provided in two air extraction holes for each of the three main condensers 1. That is, six recombiners 4 are provided. Therefore, the surface area of the catalyst per one recombiner 4, a typical boiling water reactor, because of about 5 m ^2/6 = about 0.8 m ^2, the recombiner 4 can be downsized At the same time, the heat removal amount of the recombiner 4 can be reduced to 1/6.

Also in this embodiment, similarly to the first embodiment, the configuration of the gas waste treatment facility can be simplified, and the reliability of the facility can be improved. Further, in the present embodiment, since the recombiner 4 is installed at the outlet (outside) of the main condenser 1, the heat of the recombiner 4 can be removed by the main condenser 1. Heat removal equipment can also be omitted. In addition, since the hydrogen gas can be processed at a place closer to the generation source, safety can be further improved.

Next, a third embodiment of the gas waste treatment equipment according to the present invention will be described with reference to FIG. In FIG. 5, the configuration after the precooler 6 in FIG. 1 is omitted. This embodiment is different from the first embodiment in that a hydrophobic catalyst 16 is provided in the main condenser 1 and that the air extractor 2 is connected to the first ejector 2a.
This is the point that it is composed only of. Other configurations are the same as those of the first embodiment.

In this embodiment, the hydrogen gas and the oxygen gas in the main condenser 1 are recombined on the catalyst 16. Therefore, most of the residual gas components in the main condenser 1 are air mixed in the main condenser 1 and a very small amount of rare gas is contained therein. For this reason, since the amount of exhaust gas extracted from the main condenser 1 in the first ejector 2a is small, compressed air is used to drive the first ejector 2a. By using compressed air,
A cooler can be omitted from the air extractor 2.

The installation position of the catalyst 16 is as follows.
The coating may be applied not only to the inner outlet portion but also to the inner wall surface or the surface of the inner pipe. Since compressed air is used, the pre-cooler 6
And the dryer 7 can also be omitted. Furthermore, since the amount of exhaust gas extracted is small, the first ejector 2a can be omitted.

Also in this embodiment, similarly to the first embodiment, the configuration of the gaseous waste treatment facility can be simplified and the reliability of the facility can be improved. Further, in this embodiment, since the hydrogen gas can be treated in the main condenser 1 having a large heat removal capacity, the safety can be further improved.

Next, a fourth embodiment of the gas waste treatment equipment according to the present invention will be described with reference to FIG. In FIG. 6, the configuration after the precooler 6 in FIG. 1 is omitted. This embodiment differs from the first embodiment in that the recombiner 4 is omitted and that the catalyst 16 is installed in the cooler 2b of the air extractor 2. Other configurations are the same as those of the first embodiment.

In this embodiment, the hydrogen gas and the oxygen gas in the exhaust gas extracted from the main condenser 1 by the first ejector 2a are recombined by the catalyst 16 provided in the cooler 2b. Most of the exhaust gas component treated by the cooler 2b is air mixed into the main condenser 1, and contains a very small amount of rare gas.

The catalyst 16 may be applied to any one of the outlet, the inner surface, and the surface of the internal pipe in the cooler 2b. Also,
It may be installed at the outlet outside the cooler 2b.

Also in this embodiment, similarly to the first embodiment, the configuration of the gas waste treatment facility can be simplified, and the reliability of the facility can be improved. Further, in the present embodiment, since the hydrogen gas can be processed in the cooler 2b having a large heat removal capacity, safety can be further improved.

[0038]

According to the present invention, the configuration of the gas waste treatment equipment can be simplified and the reliability can be improved.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a first embodiment of a gas waste treatment facility according to the present invention.

FIG. 2 is a schematic configuration diagram of a conventional gas waste treatment facility.

FIG. 3 is a schematic configuration diagram showing one embodiment of a recombiner according to the present invention.

FIG. 4 is a schematic configuration diagram showing a second embodiment of the gas waste treatment equipment according to the present invention.

FIG. 5 is a schematic configuration diagram showing a third embodiment of the gas waste treatment equipment according to the present invention.

FIG. 6 is a schematic configuration diagram showing a fourth embodiment of the gas waste treatment equipment according to the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Main condenser, 2 ... Air extractor, 2a ... 1st ejector,
2b ... cooler, 3 ... preheater, 4 ... recombiner, 5 ... exhaust gas condenser, 6 ... precooler, 7 ... dryer, 8 ... pre-filter, 9 ... rare gas hold-up tower, 10 ... particle filter , 11: vacuum pump, 12: main exhaust pipe, 16: catalyst.

Claims (5)

[Claims] 1. A gas waste treatment facility for extracting exhaust gas from a condenser of a boiling water nuclear power plant using an air extractor and treating the extracted exhaust gas, wherein hydrogen and oxygen in the exhaust gas are recombined. A gas waste treatment facility, wherein a catalyst for causing the gas extractor is installed inside the air extractor or upstream of the air extractor. 2. A gas waste treatment facility according to claim 1, wherein a hydrophobic catalyst is used as said catalyst. 3. A gas waste treatment facility for treating exhaust gas extracted from a condenser of a boiling water nuclear power plant, which is connected to an exhaust gas outlet of the condenser for recombining hydrogen and oxygen in the exhaust gas. A recombiner, an air extractor disposed downstream of the recombiner for extracting the exhaust gas from the condenser, and a rare gas in the exhaust gas disposed downstream of the air extractor. A gas waste treatment facility, comprising: a rare gas removing device for removing. 4. The air extractor according to claim 3, further comprising: an ejector driven by main steam of the nuclear power plant to extract the exhaust gas; and a condenser for condensing the main steam driven by the ejector. Gas waste treatment equipment characterized by the following. 5. The gas waste treatment facility according to claim 3, wherein the recombiner includes a hydrophobic catalyst for recombining hydrogen and oxygen in the exhaust gas.