JPH01247537A - Method and device for melting and recovering sodium particle - Google Patents

Abstract

PURPOSE:To surely recover Na particles in good yield and to prevent air pollution by sucking an inert gas contg. Na particles into a recovery tank, depositing and collecting the Na particles in the tank by an Na collector, and then dissolving the Na particles in alcohol. CONSTITUTION:A vacuum pump 9 is operated to suck the gaseous Ar contg. Na particles into the Na recovery tank 1 from an Na charging device 5. When the gaseous Ar is passed through the inside of the tank 1, the Na particles are deposited and collected on the metallic fiber 12 consisting of metal wool and placed on a separation plate 11 pierced with many penetrating holes 11a. The gaseous Ar freed of Na particles is discharge by the vacuum pump 9 through a discharge port 6. Alcohol is then introduced from an alcohol feeder 19 through a supply port 16 provided to an upper cover plate 14, and the Na particles deposited on the fiber 12 are dissolved in the alcohol. The obtained soln. is discharged from a discharge port 20 at the bottom.

Description

Detailed Description of the Invention (Industrial Application Field) The present invention relates to a sodium filling method in which a measured amount of molten metal sodium is filled into a sodium solid electrolyte tube used in, for example, a thermoelectric converter or a sodium concentration testing device for sodium alloys. The present invention relates to a sodium particle recovery method and an apparatus for suppressing metal natrirum particles remaining in a sodium measuring tank from being discharged into the atmosphere from a vacuum pump when a container is evacuated through the sodium measuring tank in an apparatus.

(Prior Art) Sodium solid electrolyte tubes used as various electrodes in the thermoelectric converters and the like exhibit their functions by filling the inside with a certain amount of sodium. Assembling this solid electrolyte tube requires a device that measures and fills a predetermined amount of metallic sodium, but this device requires a vacuum state in the sodium measuring tank and sodium solid electrolyte tube prior to the sodium filling operation. It is necessary to depressurize the
It is equipped with a vacuum pump to do this.

(Problem to be Solved by the Invention) However, in the conventional sodium filling device, the sodium measuring tank and the vacuum pump are simply connected by a pipe line, so that sodium deposits adhere to the sodium measuring tank, container, etc. Since metal sodium particles are released into the atmosphere from the vacuum pump along with the inert gas inside, it is not only dangerous to handle metal sodium, which is classified as a Class 3 water-restricted hazardous material under the Fire Service Act, but also environmentally hazardous. pollute,
If metallic sodium enters the vacuum pump, the oil inside the vacuum pump may deteriorate, or the water and sodium in the oil may react to generate hydrogen gas, reducing the vacuum pump's performance. There was a problem in that durability decreased.

The purpose of the present invention is to melt and recover sodium particles that can reliably recover metal sodium particles, prevent air pollution, improve safety, and further improve the sodium recovery efficiency and the durability of vacuum pumps. The object of the present invention is to provide a method and an apparatus thereof.

(Means for Solving the Problems) In order to achieve the above object, the method for melting and recovering sodium particles according to claim 1 includes:
Sucking an inert gas containing sodium particles into the tank from an inlet provided in the recovery tank, and adhering the sodium particles to the sodium collector while passing the inert gas through a sodium collector in the recovery tank, The inert gas is transferred from the discharge port provided in the recovery tank to a decompression pump, and after a predetermined amount of sodium adheres to the collection body, the inlet port and discharge port are closed, and the inert gas is transferred from the supply port provided in the recovery tank. A method is adopted in which alcohol is supplied into the tank, the sodium particles are dissolved in the alcohol, and the dissolved solution is discharged from an outlet provided in the recovery tank.

In order to achieve the above object, the sodium particle melting and recovery apparatus according to claim 2 opens an inlet for inhaling an inert gas containing metal sodium particles into the recovery tank, and contains the metal sodium particles inside the recovery tank. A sodium particle collector for adhesion is provided, the recovery tank is provided with a discharge port for discharging inert gas from which sodium particles have been removed to a pressure reducing pump, and the recovery tank is further provided with a discharge port for discharging inert gas from which sodium particles have been removed to a vacuum pump; A method is adopted in which a supply port and a discharge port for discharging alcohol in which sodium particles are dissolved are opened.

(Function) The method and device for melting and recovering sodium particles according to claims 1 and 2 each adopt the above configuration, so that when the gas in the sodium recovery tank is sucked and depressurized by the pressure reduction pump, the sodium filling process is completed. The inert gas inside the device is sucked into the recovery tank along with the sodium particles. Then, the sodium particles are attached to the sodium collector, and the inert gas is discharged to the vacuum pump side. Therefore, sodium particles are not released into the atmosphere, improving safety. Furthermore, since there is no intrusion of sodium particles into the vacuum pump, its durability is improved.

On the other hand, when a predetermined amount of sodium particles adheres to the sodium collector, the collection operation is stopped and alcohol is supplied from the alcohol supply device into the recovery tank, so that the sodium particles are dissolved by the alcohol and released from the discharge port. It is discharged to the outside. Therefore, the work of cleaning or replacing the sodium collector becomes unnecessary, and it is possible to prevent the efficiency of the collection work from decreasing.

(Example) Next, an example embodying the present invention will be described using FIGS. 1 to 3.

As shown in FIG. 1, an inlet 2 is opened at the outer periphery of the lower part of the sodium recovery tank 1, and the inlet 2 is connected to a thermoelectric converter, etc. through a pipe 3 and a first on-off valve 4. It is connected to a sodium filling device 5 that fills metallic sodium into the solid electrolyte tube to be used. Further, a discharge port 6 is opened at the upper outer periphery of the sodium recovery tank 1, and the discharge port 6 is connected to a pressure reducing pump 9 such as a vacuum pump, for example, via a pipe line 7 and a second on-off valve 8.

Inside the sodium recovery tank 1, there are locking protrusions 10 to 1 at four locations on the same horizontal plane at equal intervals and in four stages above and below.
0 is provided protrudingly, and a large number of through holes 11a are formed in the locking protrusions 10 to 10 of each stage.The function is to separate sodium particles having a relatively large particle size, and to support the sodium collector 12 as described below. Separation plates 11, which also serve as two separate plates, are supported horizontally. A recess 11b through which the locking projection 10 passes is formed on the outer periphery of the separation plate 11.
0 and the recess zb, move the separation plate 11 downward, rotate the plate 11, and place the i! on the locking protrusion lO! I try to put it there.

Between the separation plates 11, metal fiber bodies 12, which are formed into a thick plate shape by collecting a large number of metal wools and serve as sodium particle collectors to which small-sized sodium particles are attached, are placed in multiple stages. ing.

On the other hand, a cover plate 14 is placed on the upper end surface of the sodium recovery tank 1 via an O-ring 13 and is fastened and fixed with bolts 15 . In addition, a supply port 16 for methyl alcohol or ethyl alcohol is opened in the center of the cover plate 14, and a pipe line 17 and a third on-off valve 1 are connected to the supply port 16.
8 to an alcohol supply device 19.

Furthermore, a discharge port 20 is opened at the lower end surface of the sodium recovery tank 1 for discharging alcohol in which sodium in the tank is molten to the outside.
It is connected to a waste liquid treatment tank 23 via the first and fourth on-off valves 22.

Next, the operation of the sodium particle melting and recovery apparatus configured as described above will be explained.

First, the pressure reducing pump 9 is operated, and the first and second on-off valves 4
．． Open 8. The third and fourth on-off valves 18 and 22 are closed (. Then, the pipe line 3 is opened from the sodium filling device 5 side.
, an inert gas such as argon gas containing sodium particles is sucked into the sodium recovery tank 1 through the first on-off valve 4 and the suction port 2 .

Sodium particles with a relatively large particle size in the inert gas flowing into the sodium recovery tank 1 are separated by a separation plate 11.
Sodium particles with a small particle size are deposited at the bottom of the tank 1 by the metal fiber body 12 after passing through the through hole 11a, and are attached to the metal wool forming the fibrous body.

In this way, it passes through three stages of metal fiber bodies 12 to 12 (
During the process, all the sodium particles are attached to the fibers and collected.
Only inert gas flows from the discharge port 6 to the pipe line 7 and the second on-off valve 8.
and then moves to the vacuum pump 9. Therefore, the pressure reducing pump 9
Since sodium particles do not enter into the pump, its durability is improved and the volumetric efficiency as a pump can also be maintained appropriately.

If the above-mentioned sodium particle collection operation is repeated, a large amount of sodium particles will adhere to the metal fiber body 12 and the inert gas permeability will decrease.
The sodium particle collection work is stopped, the first, second and fourth on-off valves 4.8°22 are closed, and the third on-off valve 18 is opened, and the pipe line 17 and supply are removed from the alcohol supply device 19. Alcohol is fed into the recovery tank 1 via the port 16. Then, the sodium particles adhering to the metal fiber body 12 are melted by the alcohol and stored at the bottom of the tank 1. This alcohol solution is discharged to the waste liquid treatment tank 23 by opening the fourth on-off valve 22.

In this way, when the sodium particles adhere and the permeability of argon gas decreases, the alcohol melts the sodium particles, so that the efficiency of collecting thorium particles by the collector 12 is always maintained at a high level.

In addition, in the process of melting sodium particles with alcohol, 1
, sodium methylate or sodium ethylate and hydrogen gas are generated, and the hydrogen gas is discharged to the outside from the third on-off valve 18.

Note that the present invention can also be embodied as follows.

(1) Instead of the metal fiber body 12, a ceramic or metal sphere or the like may be used as a sodium collector.

(2) The separation plate 11 may be omitted.

(3) After recovering most of the sodium particles using a cyclone (not shown), inert gas is sucked into the sodium melting and recovery device, etc., and the configuration can be changed as desired within the scope of the claims. You can also do that.

(Effects of the Invention) As detailed above, the invention according to claims 1 and 2 can prevent sodium particles from being released into the atmosphere from a vacuum pump, suppress environmental pollution, and prevent sodium particles from being released into the atmosphere. This has the effect of preventing water from entering the vacuum pump, suppressing a decrease in the performance of the vacuum pump, and improving durability.

In particular, in the inventions described in claims 1 and 2, the sodium particles are melted with alcohol and discharged, thereby eliminating the need to clean or replace the sodium particle collector and maintaining high collection efficiency. effective.

[Brief explanation of the drawing]

FIG. 1 is a vertical cross-sectional view of the central part showing the sodium particle melting and recovery apparatus of the present invention, FIG. 2 is a cross-sectional view taken along line A-A in FIG.
The figure is a perspective view of a sodium collection plate. 1... Sodium recovery tank, 2... Inlet, 3.
7.17.21... Conduit, 4. 8. 18. 22
... First to fourth on-off valves, 5... Sodium filling device, 6... Discharge port, 9... Decompression pump, 10... Locking protrusion, 11... Separation plate, 12... ... Metal fiber body as a sodium particle collector, 14 ... Lid plate, 1
6... Supply port, 19... Alcohol supply device, 20
···Vent.

Claims (1)

[Claims] 1. Inert gas containing sodium particles is sucked into the recovery tank (1) through the suction port (2) provided in the tank (1) by the suction action of the vacuum pump (9). , the sodium particles are attached to the sodium collector (12) in the recovery tank (1) while passing the inert gas through the sodium collector (12), and the inert gas is passed through the sodium collector (12) in the recovery tank (1). The collection body (12) is transferred from the outlet (6) to a vacuum pump.
) after a predetermined amount of sodium adheres to the inlet (2).
and closing the discharge port (6), supplying alcohol into the tank (1) from the supply port (16) provided in the recovery tank (1), dissolving the sodium particles with the alcohol,
A method for melting and recovering sodium particles, which comprises discharging the solution from an outlet (20) provided in a recovery tank (1). 2. An inlet (2) for inhaling inert gas containing metallic sodium particles is opened in the recovery tank (1), and a sodium particle collector (12) is installed inside the recovery tank (1) to which metallic sodium particles are attached. ), and a vacuum pump (
Furthermore, the recovery tank (1) has a supply port (16) for filling the tank with alcohol and an exhaust port for discharging the alcohol in which sodium particles have been dissolved. An apparatus for melting and recovering sodium particles, characterized in that an outlet (20) is opened.