KR101713158B1 - Passive type scrubber nozzle - Google Patents

Abstract

The present invention relates to a passive type scrubber nozzle for removing a nuclear fission product at a serious accident of a nuclear power plant, which includes a reducer into which a gas is inputted and whose diameter is decreased in a direction in which the gas is inputted and progresses, a throat into which a cleaning solution is inputted from a gap by forming an inlet with the gap with an outlet part of the reducer and which has a constant diameter from the inlet to an outlet, and a diffuser which is extended from the throat and has a diameter which is increased in a direction in which the gas and liquid are inputted and progress. The scrubber nozzle is immersed in the cleaning solutions and the cleaning solution is inputted from a cleaning solution inlet formed between the reducer and the throat and is mixed with the gas inputted from the reducer.

Description

{PASSIVE TYPE SCRUBBER NOZZLE} FOR NUCLEAR POWER PLANT KNOWLEDGE FUEL PRODUCT

The present invention relates to a passive scrubber nozzle for removing fission products when a serious accident occurs in a nuclear power plant.

The present invention relates to a passive scrubber nozzle for removing fission products when a serious accident occurs in a nuclear power plant. FIG. 1 is a view for removing aerosols and gaseous products in the form of a fission product generated in a nuclear power plant, in which the wet filtration system includes a nuclear fission product flowing through an inlet pipe in a state of being immersed in a cleaning liquid pool It consists of a scrubber nozzle to remove, a depletion device (Cyclone) to remove droplets from the water surface, a metal fiber filter to remove fine aerosols, and a molecular sieve to remove gas products

The inside of the facility is initially filled with a cleaning liquid at a certain height, and a part of the aerosol and gas products are primarily filtered by the scrubber nozzle at a lower level than the cleaning liquid. The gas flowing through the nozzle is pressurized The pressure inside the nozzle is lowered due to the lowering of the pressure due to the change process, and the cleaning liquid is sucked through the water inlet of the nozzle according to the pressure difference between the head and the nozzle according to the level of the cleaning liquid pool, Collapses in contact with the gas and becomes a microdroplet to adsorb aerosol and gas products

The scrubber nozzle, which is characterized by this principle, is similar to the venturi nozzle used to remove environmental pollutants, but the existing venturi nozzle is forced to be injected from the outside using a pump to suck the cleaning liquid. However, the power supply can not be supplied to the nuclear power plant. Therefore, it is not possible to force the cleaning liquid to be injected using a device requiring a power source such as a pump. However, in this scrubber nozzle, the driving force capable of introducing the cleaning liquid even in the absence of external power is divided into the pressure drop due to the velocity of the vapor containing the fission products flowing into the scrubber nozzle and the velocity due to the non-condensable gas, It is necessary to operate by the passive removal method obtained by using the above-mentioned method.

In this connection, Korean Patent Registration No. 100800217 'Nuclear Engineering System and Method for Decompression of Nuclear Engineering System' has been disclosed, but this is related to a device for reducing the pressure of containment building of a nuclear power plant and is not a passive scrubber nozzle.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a scrubber nozzle operated in a passive removal mode.

As a passive scrubber nozzle for removing nuclear fission products at the nuclear power plant,

A reducer with a reduced diameter towards the direction in which the gas is introduced and the gas is introduced

An inlet is formed at an interval from the outlet portion of the reducer so that the cleaning liquid can be drawn in from the gap and the diameter from the inlet to the outlet is constant,

A diffuser extending from the throat and having a diameter widened in a direction in which gas and liquid enter and travel

The scrubber nozzles may be submerged in the cleaning liquid and may combine with the gas introduced from the reducer into the scrubbing liquid inlet from the scrubbing liquid inlet formed between the reducer and the throat.

 The inlet of the throat may further include a slit cover extending in a direction to surround the outside of the reducer.

The end of the diffuser may be clogged and the side surface of the end may be opened so that the micro liquid is discharged to the discharge port formed on the side surface of the end of the diffuser.

The outlet cross-sectional area of the reducer is less than the cross-sectional area of the inlet of the throat and does not directly contact, and the velocity of the droplet at the outlet of the reducer may not exceed 250 m / s.

 The cross sectional area of the reducer may be any one of a rectangle, a circle, and an ellipse.

 The slit cover may be formed at an angle enough to form a substantially constant gap with the outlet of the reducer.

 In order to make the slit cover integral with the reducer, the throat or the diffuser, the slit is made to have a quadrilateral shape by placing the welding legs symmetrically at the end portion between the outer surface of the reducer and the slit cover, It may be to make it uniform while continuing to the lot.

The slit space formed by the slit cover may be symmetrical so that both sides achieve an even flow rate decomposition.

 The outlet of the reducer and the inlet of the throat may be spaced apart to control the degree of separation to control the suction area of the cleaning fluid.

 The exit cross-sectional area of the reflector header is symmetrical, and the exit total area is larger than the diffuser area but larger than the diffuser angle to form an arc shape and holes at the top to relieve the overpressure in the nozzle.

According to the present invention, there is provided an effect of providing a scrubber nozzle capable of passive operation.

1 to 10 are diagrams showing an embodiment according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings. FIG. 2 shows the principle of a passive scrubber nozzle. In a state in which the scrubber nozzle is locked to the cleaning liquid pool, a gas such as steam containing non-fission products and non-condensable gas flows through the nozzle, and the outside of the nozzle is submerged in the cleaning liquid. The nozzle consists of a reducer, a throat and a diffuser. When a gas flow is formed through a reducer, the pressure is reduced by reducing the cross-sectional area of the flow in the reducer, The speed of the motor is increased. Therefore, if the pressure of the cleaning liquid inlet located at the bottom of the throat (the head from the nozzle outlet to the cleaning liquid inlet) is larger than the internal pressure at the time of gas flow formation, the external cleaning liquid is sucked, In order to obtain a high filtration efficiency, the amount of the cleaning liquid sucked is appropriate, and as the liquid droplet is finer to increase the adsorption area of the sucked cleaning liquid, the glass Do.

However, the above two variables are contradictory to each other. In order to form a fine liquid droplet as the cleaning liquid sucked, the speed difference between the inner gas flow and the suction cleaning liquid must be large. When the inner gas flow becomes large, the static pressure inside the nozzle increases and the suction amount of the cleaning liquid decreases .

In a typical passive scrubber nozzle, the cleaning liquid inlet is perforated perpendicularly to the throat wall surface. However, in this case, the flow resistance increases when the cleaning liquid is sucked from the suction port, so that the suction of the cleaning liquid is not smooth or a part of the gas flowing in the nozzle And is discharged to the outside of the nozzle through the suction port. In contrast, in the present invention, in order to reduce the flow resistance at the time of sucking the cleaning liquid and to prevent the internal gas from being discharged to the outside of the nozzle through the suction port, the cleaning liquid suction port is set to be equal to the angle of the reducer, And has a slit-shaped suction port so as to be sucked in the diagonal direction, and a skirt guides the cleaning liquid toward the suction port.

A scrubber nozzle using a similar principle has been proposed by AREVA, but differs from the present invention in its form. AREVA's scrubber nozzles consist only of reducers and diffusers and do not have a throat. The present invention consists of three parts: a reducer, a throat, and a diffuser. The throat is designed so that the droplets generated by the pressure distribution on the inner wall of the throat are evenly distributed after the cleaning liquid is sucked through the cleaning liquid inlet And it has an advantage of improving the adsorption efficiency of the fission product at the nozzle and securing the throat length, thereby prolonging the contact time for adsorbing the fission product in the fine droplet.

FIG. 3 shows static pressure change characteristics at each position due to the internal gas flow from the inlet to the outlet of the passive scrubber nozzle of the present invention. The pressure from the nozzle inlet to the reducer decreases as the flow area decreases and the pressure drop occurs. The pressure lost from the reducer to the throat tip is partially recovered. As the flow area increases in the diffuser, Recovered.

4 shows the pressure loss characteristics according to the internal gas flow rate from the inlet to the outlet of the passive scrubber nozzle according to the present invention. The pressure loss increases as the internal gas flow rate increases. In addition, when comparing the pressure loss in the wet condition when the inside of the nozzle is mixed with the gas containing the fissile product and the gas containing the fission products by the dry condition and the inhalation of the cleaning liquid under the same condition of the internal gas flow rate And the pressure loss in the mixed fluid state increases.

FIG. 5 shows the flow characteristics of the cleaning liquid sucked through the cleaning liquid inlet according to the inlet gas flow rate in the passive scrubber nozzle of the present invention. The scrubber nozzle is immersed in the cleaning liquid pool, and the flow rate of the cleaning liquid sucked decreases as the internal gas flow rate increases under the same condition of the head from the nozzle outlet to the water surface. As the gas flow rate increases inside the nozzle, the static pressure inside the nozzle increases, and the pressure difference due to the head outside the nozzle decreases, and the flow rate of the cleaning liquid decreases.

The suction of the cleaning liquid is achieved when the head of the liquid level at the cleaning liquid inlet of the scrubber nozzle is larger than the sum of the static pressure due to the gas flow in the nozzle and the pressure due to the flow resistance upon suction of the cleaning liquid. Therefore, the higher the water level of the cleaning liquid, the lower the pressure of the gas inside the nozzle, and the smaller the suction force of water, the greater the suction amount. FIG. 6 shows the characteristics of the cleaning liquid suction flow rate according to the variation of the water level from the nozzle outlet to the cleaning liquid surface under the condition that the passive scrubber nozzle of the present invention is immersed in the cleaning liquid pool and the gas flow rate inside the nozzle is the same. The cleaning liquid sucking flow rate increases as the liquid level of the cleaning liquid increases.

In order to maintain the performance characteristics and fission product adsorption efficiency of the passive scrubber nozzle shown in FIGS. 2 to 6, the gas velocity in the throat of the nozzle should be 250 m / s or less. When the gas velocity in the throat exceeds 250 m / s, the pressure gradient in the throat is reversed, so that the characteristics of the passive scrubber nozzle can not be maintained. Therefore, the passive scrubber nozzle of the present invention operates at a gas speed of 250 m / s or less at the reducer outlet.

Also, the throat inlet cross sectional area ratio according to the reducer outlet cross-sectional area can increase the flow rate at the same rate irrespective of the solution speed. In the nozzle design of FIG. 1, the slit and throat portions are raised simultaneously Effect can be obtained. However, the scrubber nozzles must always have a smaller suction flow rate than the internal gas flow rate, and the best filtration characteristics are obtained in the range of 0.001 to 0.005 based on 0.003 (99.7% gas, 0.3% solution) have.

FIG. 8 shows the three-dimensional shape of the passive scrubber nozzle. FIG. 9 shows that the gas inlet and the cleaning liquid inlet are combined at the point where the gas in the internal space where the fluid flows and the cleaning liquid are mixed together to determine the cross section of the throat. 10, the length h from the outlet of the reducer to the inlet of the throat is equal to or larger than 0, and the area of the rinsing liquid inflow opening for sucking the rinsing liquid is determined according to h.

Claims (10)

As a passive scrubber nozzle for removing nuclear fission products at the nuclear power plant,
A reducer with a reduced diameter towards the direction in which the gas is introduced and the gas is introduced
An inlet is formed at an interval from the outlet portion of the reducer so that the cleaning liquid can be drawn in from the gap and the diameter from the inlet to the outlet is constant,
And a diffuser extending from the throat and having a diameter widened in a direction in which gas and liquid enter and move
The scrubber nozzles are immersed in the cleaning liquid, and the cleaning liquid is introduced from the cleaning liquid inlet formed between the reducer and the throat and merged with the gas introduced from the reducer
Wherein the inlet of the throat further includes a slit cover extending in a direction to surround the outer periphery of the reducer, wherein an end of the diffuser is closed and a side face of the end is opened, Passive scrubber nozzle for removal of nuclear fission product delete delete The nuclear power plant cogeneration system according to claim 1, wherein the outlet cross sectional area of the reducer is less than the cross sectional area of the inlet of the throat and does not directly contact and the velocity of the droplet at the outlet of the reducer is not more than 250 m / Passive scrubber nozzle for removal The passive scrubber nozzle according to claim 4, wherein the cross-sectional area of the reducer is any one of a quadrangle, a circle, and an ellipse. The passive scrubber nozzle according to claim 1, wherein the slit cover is formed at an angle substantially equal to the outlet of the reducer, for removing nuclear fission products at the nuclear power plant, 7. The slit cover as claimed in claim 6, wherein the slit cover is formed so as to have a square shape of a slit inlet shape by being placed symmetrically at the end portion between the outer surface of the reducer and the slit cover so as to be integrally formed with the reducer, the throat or the diffuser, Passive scrubber nozzles for the removal of nuclear fission products at nuclear power plants.
The passive scrubber nozzle as claimed in claim 7, wherein the slit space defined by the slit cover is symmetrical so that both sides are subjected to even flow rate decomposition,
The passive scrubber nozzle for removing nuclear fission products of nuclear power plants according to claim 8, wherein the outlet of the reducer and the inlet of the throat are spaced apart to control the degree of separation to control the suction area of the cleaning liquid.
10. The method of claim 9, wherein the exit cross-sectional area of the reflector header is symmetrical, the outlet total area is larger than the diffuser area but larger than the diffuser angle and formed in an arc shape, Passive Scrubber Nozzle for Removal of Fissile Product

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