KR20020050331A - Low and intermediate-level waste treatment system - Google Patents

Abstract

PURPOSE: A low and intermediate level radioactive waste treatment system is provided to achieve an improved operation of the system by efficiently controlling vitrification and discharge of radioactive waste. CONSTITUTION: A treatment system comprises a supply unit(20) for supplying low and intermediate level radioactive waste and material to be vitrified; a crucible melter(30) having a melting chamber(32) for providing glass melt so as to vitrify the low and intermediate level radioactive waste and material to be vitrified; a heating and pyrolysis unit(50) installed in the melting chamber of the crucible melter, and which heats, burns and thermally decomposes the low and intermediate level radioactive waste and material to be vitrified; an inductor(60) installed outside the crucible melter, and which melts the material to be vitrified by applying an induction current to the material; a heating and discharge unit(70) for heating the vitrified material such that the material has a reduced viscosity so as to be discharged from the melting chamber of the crucible melter; a cooling unit(80) for controlling discharge of vitrified material; and an air supply unit(90) for bubbling the glass melt by supplying air to the melting chamber of the crucible melter.

Description

LOW AND INTERMEDIATE-LEVEL WASTE TREATMENT SYSTEM}

The present invention relates to a treatment system for radioactive waste, and more particularly, to a treatment system for medium and low level radioactive waste for vitrification of medium and low level radioactive waste.

Radioactive wastes generated by nuclear power plants or radioisotopes should be safely disposed of. Radioactive wastes are classified into low and intermediate level wastes and high-level wastes according to their radioactivity intensity. Most low-level radioactive wastes are wastes generated during the operation of nuclear power plants, such as filter media, ion exchange resins, waste residues from waste evaporators, and other collectibles such as work clothes, tools, and toilet paper used by radiation workers.

Such low and low level radioactive waste is mixed with solidified materials, such as cement or paraffin, and then encapsulated in a waste drum and then solidified or compressed and encapsulated in a waste drum and stored in a safe place such as a waste management facility. In addition to the considerable manpower and cost required for installation and maintenance, the social evasion phenomenon is accompanied by a lot of difficulties in the installation, which is a serious social problem.

On the other hand, as a treatment technology for low and medium-level radioactive waste, the waste is incinerated (Combustion), pyrolysis (Pyrolysis) and then treated with a glass solidified by a vitrification technology that the high temperature melting with glass. This vitrification technology for low and medium level radioactive waste not only can dramatically reduce the amount of waste, but also permanently block radioactive leakage.

Referring to the conventional low and low level radioactive waste treatment system for vitrifying and treating the low and low level radioactive waste in accordance with FIG. At the lower side of 12, a flat plate cooling device 16 having a cooling water passage 14 capable of cooling the periphery of the discharge pipe 12 with the cooling water is provided.

In the low and low level radioactive waste treatment system having such a configuration, in order to discharge the glass in the melting furnace 10, the bottom of the melting furnace 10 is cooled by the cooling water of the cooling device 14, and then the cooling is blocked. The glass compact is discharged through the discharge pipe 12 of the melting furnace 10.

However, in the conventional low and low level radioactive waste treatment system, in order to discharge the glass cargo from the melting furnace 10, the glass solidified in the discharge pipe 12 by the cooling of the cooling apparatus 14 and the glass cargo in the melting furnace 10 Since it is necessary to reach the thermal equilibrium temperature, it takes a long time until the actual discharge of the glass, there is a problem that the treatment efficiency is greatly reduced.

In addition, due to the contact with air, vitreous having a very high viscosity tends to stick to the inner surface of the discharge pipe 12 and harden. Therefore, while the discharge pipe 12 of the melting furnace 10 is blocked by the vitrified material, it is difficult to discharge the vitrified material, thereby reducing the processing efficiency.

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention is to provide a low and low level radioactive waste treatment system that can be discharged quickly and smoothly through the discharge port. .

Another object of the present invention is to provide a low and low level radioactive waste treatment system that can prevent the clogging of the discharge passage by lowering the viscosity of the free cargo by heating, thereby significantly improving the treatment efficiency and operability.

Features of the present invention for achieving the above object, the supply device for supplying low and medium-level radioactive waste and glass raw material; A closed cylindrical melting furnace having a melting chamber for providing a glass molten metal capable of vitrifying a low to medium level radioactive waste and a glass raw material supplied from an injection device; Heat pyrolysis means installed in the melting chamber of the melting furnace to heat, incinerate and pyrolyze the medium and low level radioactive waste and the glass raw material; An inductor installed outside the melting furnace and melting by applying an induction current to the glass raw material; Heating and discharging means for heating to lower the viscosity of the vitrified product from the melting chamber of the melting furnace and discharge it; A cooling device for controlling the discharge of the glass cargo through the heating discharge means; There is a low and low level radioactive waste treatment system including an air supply device for supplying air to the melting chamber of the melting furnace to bubble the molten glass.

In addition, the heat pyrolysis means is composed of a resistance heating element composed of SiC or MoSi ₂ , the heat discharge means is a hopper type bottom heating plate having a slope guide path to guide the glass material to the center and downward in the center of the bottom heating plate. It consists of an exhaust heating tube mounted vertically in communication with each other, and the bottom heating plate and the exhaust heating tube are made of Inconel. And an exhaust body treatment apparatus for purifying the exhaust body exhausted from the melting chamber of the melting furnace.

1 is a cross-sectional view showing a conventional low and low level radioactive waste treatment system;

Figure 2 is a cross-sectional view showing a treatment system for low and medium level radioactive waste in accordance with the present invention,

Figure 3 is a cross-sectional view partially showing a treatment system for low and medium level radioactive waste according to the present invention.

♣ Explanation of symbols for the main parts of the drawing ♣

20: feeder 30: melting furnace

32: melting chamber 38: observation glass window

40: exhaust gas treatment device 50: heat pyrolysis means

52, 54: resistance heating element 60: inductor

70: heating discharge means 74: bottom heating plate

76: exhaust heating tube 80: cooling device

90: air supply device 100: thermometer

110: waste drum 120: conveying device

Hereinafter, a preferred embodiment of the treatment system for low and medium level radioactive waste according to the present invention will be described in detail with reference to the accompanying drawings.

2 and 3 is a view showing for explaining the treatment system of the medium and low level radioactive waste according to the present invention.

First, referring to Figure 2, the treatment system of the present invention, the supply device 20 for supplying low and low level radioactive waste and glass raw material, and the low and medium level radioactive waste and glass raw material supplied from the supply device 20 at high temperature It is provided with a closed cylindrical melting furnace 30 to produce a vitrified. The melting furnace 30 is arrange | positioned downstream of the injection apparatus 20, and the supply pipe 22 of the supply apparatus 20 is obliquely connected to the melting chamber 32 of the melting furnace 30. As shown in FIG. The melting furnace 30 is made of stainless steel with excellent corrosiveness.

The bottom of the melting furnace 30 is composed of a hopper-type bottom body 36 having a central hole 34 so as to guide the vitreous to the center, and an observation glass window at the top so that the melting chamber 32 can be visually observed. (38) is mounted. In this embodiment, a glass melt (G) is provided in the melting chamber 32 of the melting furnace 30.

In addition, the melting chamber 32 of the melting furnace 30 communicates with the exhaust body processing apparatus 40 and the exhaust pipe 42. The exhaust pipe 42 of the exhaust gas treatment device 40 exhausts the exhaust gas generated in the melting chamber 32 of the melting furnace 30 by the incineration and pyrolysis of waste and glass raw materials to the exhaust gas treatment device 40. The exhaust body treatment apparatus 40 purifies the exhaust body.

On the upper side of the melting chamber 32 of the melting furnace 30, a pair of thermal pyrolysis means 50 for incineration and pyrolysis by heating the medium and low level radioactive waste and the glass raw material is vertically installed. The heat pyrolysis means 50 is composed of resistance heating elements 52 and 54, and the resistance heating elements 52 and 54 are made of silicon carbide (SiC) or molybdenum silicide (MoSi ₂ ). An inductor 60 is installed outside the smelting furnace 30 to apply an induction current to the glass raw material for melting.

2 and 3, a heating discharge means 70 is installed in the central hole 34 of the hopper-shaped bottom body 36 to heat the discharge of the glass by lowering the viscosity of the vitreous. The heating and discharging means 70 is composed of a hopper type bottom heating plate 74 having an inclined guide path 72 and a discharge heating tube 76 mounted in vertical communication with the center of the bottom heating plate 74 downwardly. It is. The inclined guide path 72 of the bottom heating plate 74 is inclined at about 4 to 8 degrees with respect to the horizontal plane to smoothly guide the flow of the glass cargo to the discharge heating tube 76. In the present embodiment, the bottom heating plate 74 and the discharge heating tube 76 of the heating and discharging means 70 are chromium (Cr), nickel (Ni), iron (Fe) having excellent characteristics in heat resistance, acid resistance, and high temperature strength. It is composed of Inconel, an alloy.

In addition, an annular water-cooled cooling device 80 is provided to surround the discharge heating tube 76 of the heating and discharging means 70. By discharging the discharge heating tube 76 by the cooling water flowing in the cooling water passage 82 of the cooling device 80, the discharge of the free cargo through the discharge heating tube 76 is controlled.

Referring back to FIG. 2, the treatment system of the present invention provides a plurality of air supply devices for supplying air to bubble the glass molten metal G provided in the melting chamber 32 of the melting furnace 30. 90 is provided. The air supply device 90 has an upper air supply pipe 92 for supplying air from the upper side of the melting furnace 30, and a lower air supply pipe 94 for supplying air from the lower side of the melting furnace 30. Although the figure shows that the upper air supply pipe 92 and the lower air supply pipe 94 of the air supply device 90 are provided in one place, these can be installed in multiple places, for example, four places. And the upper part of the melting furnace 30 is provided with the thermometer 100 which can detect the temperature of the melting chamber 32. As shown in FIG.

On the other hand, the glass cargo discharged through the discharge heating tube 76 of the heating discharge means 70 is contained in the waste drum 110, the glass cargo contained in the waste drum 110 is solidified into a glass solid. The waste drum 110 is transported and stored in a safe place such as a waste management facility by the transport device 120.

The following describes the operation of the treatment system for low and medium level radioactive waste according to the present invention having such a configuration.

Referring to FIG. 2, first, the glass raw material supplied through the injection path 22 of the injection device 20 is melted in the melting chamber 32 of the melting furnace 30 by the induction current generated by the inductor 50. Glass molten metal G is prepared. The molten glass 32 of the melting chamber 32 is bubbled by the air supplied from the upper air supply pipe 92 and the lower air supply pipe 94 of the air supply device 90. The temperature of the melting chamber 32 is detected and controlled by the thermometer 100, the vitrification process or the state of the molten glass (G) can be easily observed with the naked eye through the observation glass window (38).

On the other hand, the low and medium-level radioactive waste and glass raw material supplied to the melting chamber 32 of the melting furnace 30 through the injection passage 22 of the injection device 20 to the resistance heating elements 52 and 54 of the thermal pyrolysis means 50. By incineration and pyrolysis process is heated to about 1150 ℃. In addition, the harmful inorganic substances produced by the incineration and pyrolysis process are vitrified with vitrified, that is, trapped in the glass structure of the glass molten glass (G) which is bubbled, and the exhaust body is exhausted through the exhaust pipe 42. It is exhausted to 40 and it is purified. At this time, the viscosity of the harmful inorganic substances is maintained in the range of about 20 to 100 poise (Poise) at about 1150 ℃.

Next, when the bottom heating plate 74 and the discharge heating tube 76 of the heating and discharging means 70 are operated to maintain the viscosity of the vitreous to 100 poise or less, the vitreous is melted in the melting chamber 32 of the melting furnace 30. Is discharged through the discharge heating pipe (76). At this time, the bottom heating plate 74 and the discharge heating tube 76 is operated by applying a current of about 0.78 amperes per unit area, and the temperature of the discharge heating tube 76 side is detected and properly controlled by a thermometer (not shown). can do.

As such, the viscosity of the vitreous is lowered by the heating of the heating and discharging means 70, so that the vitreous can be smoothly discharged through the discharge heating tube 76, and the discharge heating tube due to the solidification of the vitreous is obtained. The blockage of 76 can be effectively prevented. As a result, it is possible to greatly improve the treatment efficiency of low and medium level radioactive waste. The inclined guide path 72 of the bottom body 36 of the melting furnace 30 and the bottom heating plate 74 guides the vitreous to the discharge heating tube 76 to more smoothly maintain the discharge of the vitreous.

Finally, the glass cargo discharged through the discharge heating tube 76 of the heating discharge means 70 is solidified into a glass solid after being introduced into the waste drum 110. The waste drum 110 is transported by the transport device 120 and stored in a safe place such as a waste management facility.

On the other hand, when the operation of the treatment system of the present invention is stopped and the cooling water is supplied to the cooling water passage 82 of the cooling device 80, the discharge heating tube 76 of the heating and discharging means 70 is cooled, and the vitreous solidifies. . Therefore, while the discharge heating tube 76 is blocked by the glass solid, the glass cargo is not discharged.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and the scope of application of the present invention is not limited to these, and may be appropriately changed within the scope of the same idea. For example, the shape and structure of each component specifically shown in the embodiment of the present invention can be modified.

As described above, according to the treatment system of the low and medium level radioactive waste according to the present invention, the low and low level radioactive waste is vitrified by heat pyrolysis means in the melting furnace, and the viscosity of the vitrified material by the heat discharging means constituting the discharge passage of the vitrified product. By lowering the discharge, the glass can be discharged quickly and smoothly through the discharge port, it is possible to prevent the blockage of the discharge passage due to the solidification of the glass can improve the treatment efficiency significantly. As a result, it is possible to efficiently control the vitrification and discharge of the medium and low level radioactive waste, thereby improving the operability.

Claims (6)

A supply device for supplying low and medium level radioactive waste and glass raw materials; A closed cylindrical melting furnace having a melting chamber for providing a glass molten metal so as to vitrify the low and medium-level radioactive waste and the glass raw material supplied from the injection device; Heat pyrolysis means installed in a melting chamber of the melting furnace and heating and incineration and pyrolysis of medium and low level radioactive waste and glass raw materials; An inductor installed outside the melting furnace and melting by applying an induction current to the glass raw material; Heating and discharging means for heating to lower the viscosity of the vitrified product from the melting chamber of the melting furnace and discharge it; A cooling device for controlling the discharge of the glass cargo through the heating discharge means; And an air supply apparatus for supplying air to the melting chamber of the melting furnace to bubble the molten glass. The treatment system of claim 1, wherein the bottom of the melting furnace is composed of a hopper-type bottom having a center hole to guide the vitreous to the center. The low and medium level radioactive waste treatment system of claim 1, wherein the heat pyrolysis means is a resistance heating element composed of SiC or MoSi ₂ . 2. The heating and discharging means according to claim 1, wherein the heating and discharging means has a hopper type bottom heating plate having an inclined guide path capable of guiding the vitreous material to the center, and a discharge heating tube mounted vertically in communication with the center of the bottom heating plate. The bottom heating plate and the discharge heating pipe is composed of Inconel, characterized in that the low and low level radioactive waste treatment system. According to claim 1, wherein the air supply device is an upper air supply pipe for supplying air from above the melting furnace, and the lower air supply pipe for supplying air from the lower side of the melting furnace characterized in that the treatment system for low and medium level radioactive waste . The low and middle level radioactive waste treatment system according to claim 1, further comprising an exhaust body treatment device for purifying the exhaust body exhausted from the melting chamber of the melting furnace.