JPS62170893A - Lining facility for fast breeder reactor - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to lining equipment for fast breeder reactors that is applied to the floor or insulation board surface of a concrete building housing sodium piping for guiding liquid metal sodium.

[Technical background of the invention and its problems]

Metallic sodium, which is generally used as a coolant for fast breeder reactors, is a chemically very active substance that reacts violently with oxygen and moisture. Therefore, in the event of a large-scale sodium leak, the sodium in the dog reacts with oxygen and hydrogen in the atmosphere, releasing a large amount of heat. Also, if sodium leaks directly into concrete walls forming a room housing pipes or equipment, sodium-concrete
1 ~ Generate hydrogen by reaction. Furthermore, the concrete is heated by the reaction heat and water is generated from the concrete, and the water reacts with sodium, which also generates hydrogen. In this case, there is a risk that the structural strength of the concrete will deteriorate due to hydrogen accumulation and dewatering.

This will be further explained in detail using the case of the prototype reactor "Monjiyu" of a fast breeder reactor (hereinafter referred to as FBR) shown in FIGS. 3 to 5 as an example. As shown in FIG. 3, the power generation system includes a reactor vessel 3 housed in a reactor containment vessel 2 surrounded by an outer concrete wall 1, and a reactor vessel 3 that cools the inside of the reactor vessel. It is piped so that primary sodium 4 circulates inside it, and this -primary sodium 4
is provided so as to be able to exchange heat with the secondary sodium 6 flowing in the piping installed in the reactor auxiliary building 5. The secondary sodium 6 undergoes heat exchange in a superheater 7 J5 and an evaporator 8 to generate superheated steam that drives a steam turbine 9. This superheated steam is guided to the steam turbine 9 through the steam pipe 10,
It does work here to drive the power generation 1a11. The steam expanded by doing work in the steam turbine 9 is sent to the condenser 12, where it is condensed and becomes condensed water. This condensate is sent to the evaporator 8 by the water supply pump 13.

On the other hand, the secondary sodium 6 cooled by heat exchange with the feed water in the evaporator 8 is sent to the heat exchange system with the primary sodium via the secondary main circulation pump 14. In this way, a power generation cycle in a fast breeder reactor power plant is configured, and power is generated by operating this power generation cycle. In addition, the code|symbol 15 is an air cooler provided in the secondary sodium circulation system, and the code|symbol 16 is a circulation pump.

Therefore, the primary sodium 4, which directly transfers the heat of the reactor core, is
Because it is radioactive, leakage countermeasures are particularly strict, not only in the reactor vessel 3 but also in the reactor containment vessel, which is the primary atmosphere where the piping and equipment containing sodium chloride 4 are installed. The inside of the chamber is filled with nitrogen, which is not reactive with sodium, to prevent sodium fires. Additionally, to prevent sodium-concrete reactions, the walls of each room where piping and equipment are installed are entirely lined with steel liners. On the other hand, in the case of secondary sodium 6, it is not radioactive, so the situation is not severe in the case of negative sodium 4, but the reactor auxiliary building where most of the piping and equipment for secondary sodium 6 is installed. Because there is an air atmosphere inside 5, sodium fires are likely to occur.
Preventing this is extremely important for plant safety. In the case of this secondary sodium 6, for example, a superheater 7, an evaporator 8, a secondary main circulation pump 14, an air cooler 1
In rooms where piping and equipment such as No. 5 are installed, No. 4
As shown in the figure, a floor liner 17 is installed, and sodium leaking from each room is drained from the floor liner 17 to the lower room through a communication pipe 18 and stored in a storage tank 19, or is stored in a fire suppression board. Drain into the storage liner 21 with 20 to extinguish the fire by suffocation, and then drain it into the overflow tank 2.
It is accommodated in 2.

Further, as shown in FIG. 5, the sodium pipes 25 of the secondary and secondary sodium circulation systems are supported by clamp portions 24 arranged at appropriate intervals.

This sodium pipe 25 is covered with an interior plate 27 and an exterior plate 28 via an annulus space 26. The interior plate 27 and the exterior plate 28 have a double cylinder structure, and the annulus space thereof is filled with a heat insulating material 29. Thus, when a large amount of sodium leaks from the sodium pipe 25, the leaked sodium A fills the annulus space 26, further fills the heat insulating material 29 from the interior plate 27, and flows downward in the tube axis direction. When this flow of leaked sodium A reaches the clamp part 24, the clamp part 2
4 partitions the annulus space 21, the leaked sodium A accumulates intensively in the part blocked by the clamp part 24, breaks through the heat insulating material 29 and the exterior plate 28, and spouts out to the surroundings. In order to prevent the thorium-concrete reaction that occurs when this leaked sodium A comes into direct contact with the concrete wall 30 forming the room, all parts that may come into contact with the leaked sodium A are made of steel. A liner 31 made of

°The above-mentioned sodium leakage measures prevent sodium fires and suppress sodium-concrete reactions, ensuring the strength of building concrete and greatly contributing to the safety of power plants. However, with this conventional installation, all walls, floors, and ceilings of the room that could come into contact with leaked sodium must be covered with a steel liner 31. Furthermore, when the steel liner 31 is employed, it is necessary to form a shape that takes thermal expansion due to leaked sodium into consideration, and a large amount of cost is required for designing the liner shape and manufacturing the liner.

In addition, when applying the liner 31 to the concrete wall or floor surface of the structural material concrete 30 as shown in FIG.
During on-site welding to attach the anchor 34, a heat insulating material 35, etc. must be interposed, making the attachment work difficult.

Therefore, due to the desire to reduce costs, other fire prevention technologies to replace steel liners have become important.
Currently, there is a demand for rationalization of lining equipment from the viewpoint of economy.

[Purpose of the invention]

The present invention has been made in consideration of the above-mentioned circumstances, and is a high-speed, high-speed liner that can perform the same function as a steel liner in terms of safety in power generation plants, and can significantly reduce costs compared to the case of using a steel liner. The purpose is to provide lining equipment for breeder reactors.

[Summary of the invention]

In order to prevent the sodium leaking from the sodium piping etc. from coming into contact with the structural material concrete of the concrete building in a concrete building housing sodium piping etc. that guides liquid metal sodium, a steel plate is installed on the concrete floor surface. This is lining equipment for a fast breeder reactor, which is characterized by providing drainboards and filling the gaps between the steel drainboards with a sodium-resistant and heat-resistant material.

A ceramic material is desirable as a sodium-resistant and heat-resistant material, and AJ! 203.
At least one powder or bulk particle selected from 1vlO, ZrO2, etc. is used.

According to this invention, construction is easy and insulation properties can be improved.

[Embodiments of the invention]

EMBODIMENT OF THE INVENTION Hereinafter, one embodiment of the lining equipment for a fast breeder reactor according to the present invention will be described with reference to FIGS. 1 and 2.

Note that the overall configuration of the fast breeder reactor is substantially the same as that shown in FIGS. 3 and 4, so a description thereof will be omitted.

In FIG. 1, reference numeral 40 indicates structural concrete used in the concrete building of the fast breeder reactor, and this structural concrete 40 corresponds to the concrete wall 30 shown in FIG. 18-5 and FIG. 6 described above. It is something. On or above the floor surface of the structural concrete 40, sodium piping and equipment for guiding liquid metal sodium inside are installed.

A grid-shaped steel grating 42 is laid on the concrete floor surface 41 of the structural concrete 40, and a powdered or bulk sodium-resistant and heat-resistant material, preferably ceramic, is placed in the gaps between the gratings 42. Material 43 is filled. The steel grates 42 may be provided on a heat insulating board (not shown) laid on the concrete floor surface 41.

Floor surface 41 of concrete 4o, the structural material of the concrete building
Instead of attaching the steel grates 42 thereon, the concrete floor surface 41 may be lined with a ceramic material 43 that is spread or spread in advance, and the steel grates 42 may be laid on the ceramic material 43. In any case, steel grates 42 are provided on the concrete floor surface 41, and
The gaps (lattice holes) of this drainboard 42 are filled with a sodium-resistant and heat-resistant material, preferably a ceramic material 43.

The ceramic material 43 is a sodium-resistant and heat-resistant material, such as alumina (Aj203), magnesia (Mq
O), zirconia (ZrO3), magnesium aluminum oxide (MgA1204), thoria (Tho2), titania (TiO2), silica (Sio2), beryllia
(Bed), Y2O2, and zirconia (Zr02). These ceramic materials 43 have lower free energy of formation than sodium oxide and are chemically stable with respect to sodium. Several experiments have also been conducted to check the compatibility of these ceramic materials with sodium.
3. It has also been experimentally confirmed that it is stable against sodium. The ceramic materials mentioned here, such as alumina, magnesia, and zirconia, are relatively easy to obtain.

Furthermore, these ceramic materials are all high-melting point compounds, and will not deteriorate even when exposed to the heat of leaked high-temperature sodium.

These ceramic materials 43 are then spread on the floor of the structural concrete 40 of the concrete building or on a heat insulating board laid on the floor.

In addition, if the powdered ceramic material 43 is laid in advance for lining, a reinforcing material is used so as not to interfere with work such as maintenance of sodium piping and equipment, and to prevent scattering of the ceramic material 43 during work. Install steel grates 42.

These ceramic materials have high sodium resistance and heat resistance, have a high melting point, and are stable against sodium. Therefore, if hot sodium leaks from the sodium piping, the ceramic material and sodium will not react. In addition, since all of the ceramic materials are materials that do not easily leak sodium, they hardly come into contact with the structural material concrete 40 through gaps between powdery particles.

Therefore, the leaked sodium and the structural concrete 40 will not directly react and the concrete 40 will not deteriorate. In this way, steel grates 42 and ceramic material 4
By using a liner made of 3, there is no need to attach a steel liner to the concrete surface of the building as in the past. Furthermore, it is no longer necessary to design the shape of the steel plate liner in consideration of thermal expansion and the like.

Additionally, the liner made of steel grates 42 and ceramic material 43 is much easier to install than conventional mvil liners.

[Effects of the Invention] According to the present invention, it is possible to provide lining equipment for a fast breeder reactor that has improved heat insulation properties, is easy to construct a liner, and is highly economical.

[Brief explanation of drawings]

Fig. 1 is a partial sectional view showing one embodiment of the lining equipment according to the present invention, and Fig. 2 is a characteristic diagram showing the relationship between the free energy of formation and temperature of a typical ceramic material used in Fig. 1. , Fig. 3 is a schematic diagram to explain the outline of a fast breeder reactor, Fig. 4 is a cutaway perspective view to explain secondary sodium leakage countermeasures, and Fig. 5 is a schematic diagram showing a conventional steel liner. , FIG. 6 is a partial cross-sectional view showing how a conventional steel liner is installed. DESCRIPTION OF SYMBOLS 1... External concrete wall, 2... Reactor containment vessel, 3... Reactor vessel, 4... -order sodium, 5...
... Reactor auxiliary building, 6... Secondary sodium, 7...
・Superheater, 8... Evaporator, 9... Turbine, 11.
... Generator, 12 ... Condenser, 13 ... Water supply pump, 14 ... Secondary main circulation pump, 15 ... Air cooler, 17 ... Floor liner, 18 ... Communication Tube, 19...
Storage tank, 20... Fire suppression plate, 21... Storage liner, 22... Overflow tank, 24... Clamp part, 25... Sodium cooling system piping, 26...
-Annual space, 27...Interior board, 28...Exterior board, A...Leaked sodium, 30...Structural material concrete, 31...Steel liner, 35...Insulation material, 4
0...Structural material concrete, 41...Concrete floor surface, 42...Steel grates, 43...Ceramic material. Figure 6

Claims (1)

[Scope of Claims] 1. In a fast breeder reactor lining facility equipped with a concrete building that houses sodium piping that guides liquid metal sodium and equipment, etc., sodium leaking from the sodium piping, etc. and structural materials of the concrete building Lining equipment for a fast breeder reactor, characterized in that steel grates are provided on the concrete floor surface to prevent contact with concrete, and a sodium-resistant and heat-resistant material is filled in the gaps between the steel grates. 2. The lining equipment for a fast breeder reactor according to claim 1, wherein a heat insulating board is laid on the concrete floor surface, and steel grates are provided on the heat insulating board. 3. High-speed growth according to claim 1 or 2, in which steel grates are attached after laying a sodium-resistant and heat-resistant material on a concrete floor surface or insulation board in a concrete building. Furnace lining equipment. 4. The lining for a fast breeder reactor according to claim 3, wherein the sodium-resistant and heat-resistant material is a ceramic material, and at least one of alumina, magnesia, zirconia, etc. is selectively used as the ceramic material. Facility. 5. The lining equipment for a fast breeder reactor according to claim 3, wherein the ceramic material is a powdered or bulk ceramic.