KR20000074957A - An Integrated Head Area Design of a Nuclear Reactor - Google Patents

Abstract

PURPOSE: An upper structure of a solid atomic furnace is provided to be capable of lifting the upper structure of the solid furnace at once by designing the upper structure so as to be integrated. CONSTITUTION: An upper structure of a solid atomic furnace comprises a container cover(110) which covers a furnace pressure container. A circular support plate(120) is installed on the furnace container cover(110). A dual cylinder structure(130) is installed on the circular support plate(120), and consists of an outer bulkhead(131) and an inner bulkhead(132) so as to form a cooling air flowing path. A plurality of air intake holes(140) are formed to penetrate the outer bulkhead(131) and the inner bulkhead(132) so that cold air outside the cylinder is flown in the cylinder. A defense plate(150) is installed on the dual cylinder structure(130), and a plurality of cooling fans(160) are installed on the defense plate(150).

Description

An Integrated Head Area Design of a Nuclear Reactor

The present invention relates to a general pressurized PWR reactor, and more specifically, to restructure the structure to reduce the number of structures to be removed or separated for nuclear fuel reloading (replacement and relocation) by integrally designing the PWR reactor upper structure. Related integral reactor superstructures.

LWR nuclear power plants must be shut down on a regular basis to reload nuclear fuel. In other words, in order to reload the fuel, the lid of the reactor vessel is first opened, the old fuel assembly inside the reactor is replaced with a new fuel assembly, and the remaining fuel is rearranged.

In the case of the conventional nuclear power plant for such a task had to go through the following series of steps to open the reactor vessel lid.

① Removal process of missile barriers made of heavy concrete

② Duct removal process for cooling control rod drive device

③ Seismic support rod removal process

④ Power line and signal line separation process of upper part of control rod drive device

⑤ Lifting tripod installation process of reactor upper structure

⑥ Cable installation and cable removal process connected to the work deck or wall at the top of the reactor

⑦ Reactor vessel level measurement measurement line removal process

After the above-described series of work processes are completed, the reactor vessel lid tightening bolts are removed, and the upper structure of the reactor is transferred to a separate storage space and stored. After the fuel has been replaced and reloaded, the assembly of the reactor superstructure is carried out in reverse order of operation.

The series of operations described above are performed in areas with strong radiation emissions, and the time spent on these operations affects the regular maintenance period of a nuclear power plant, so reducing the time spent reloading nuclear fuel is a major challenge for nuclear plant designers. It is becoming.

If the reactor superstructure is designed integrally, the seven-step reactor decomposition process described above can be shortened to four steps as follows.

① Seismic Support Rod Removal Process

② Separation process of power line and signal line of upper part of control rod driving device

③ Cable installation process and cable removal process connected to the work deck or wall in the upper part of the reactor

(4) Reactor vessel water level measurement line removal process can simplify the operation.

As such, if the reactor superstructure is designed integrally, nuclear reactor designers are developing various technologies related to integration.

US Patent No. 5384812, filed in 1995 by Meuschke et al., Proposed a cable mount for connecting cables from the reactor superstructure to the work deck. The pedestal features a cable mount under the deck.

US Patent No. 5715288, filed by Matteson in 1998, proposed an upper structure that partially improved the existing design, such as concrete fly-through barriers, of the previous CE (Combustion Engineering) power plant design.

However, these two designs did not provide a suitable method for removing heat generated from the top of the reactor vessel lid and the control rod drive, and the process was not easy.

In order to improve such a problem, the present invention reduces the reactor superstructure disassembly step that is required to reload the existing nuclear fuel in the pressurized light-water reactor, thus reducing the regular maintenance period of the power plant and reducing the radiation exposure dose of the operator. It is an object of the present invention, more specifically, to provide an integral reactor superstructure designed to lift the reactor superstructure in one lifting operation during the fuel reload period by designing the reactor superstructure as simply and integrally as possible. One of the objects of the invention.

Another object of the present invention is to replace the by-product protection plate made of concrete, such as the existing heavier and bulky with iron plate and integrated with the upper structure of the reactor to more effectively protect the by-products while reloading the nuclear fuel of the upper structure It is to facilitate separation and removal.

Another purpose is to equip the cable mounts so that the power cables and signal transmission wires that enter through the wall between the reactor upper structure and the steam generator can be easily connected to the upper structure of the reactor, and the cable mounts can be lifted when the fuel is reloaded. This allows the fuel reload crane (not shown) to access the reactor.

An additional object is to form a dual air flow path of the outer and inner bulkheads on the reactor vessel cover to remove heat generated from the upper part of the reactor vessel and the control rod drive unit by using a cooling fan. It is to prevent the electrical wiring from heating above the predetermined temperature.

Figure 1 is a perspective view showing the installation state of the present invention integrated reactor upper structure.

Figure 2 is a front view showing the installation state of the present invention integrated reactor upper structure.

3 is a plan view of the present invention integrated reactor upper structure.

Figure 4 is a schematic cross-sectional view showing the internal configuration of the present invention, the integral reactor upper structure.

5 is an operational state diagram of the integrated reactor upper structure cable installation member of the present invention,

(a) is the unfolded state of the cable installation member, (b) is the lifted folded state.

Figure 6 is a front view and a plan view of the installation operation state of the present invention integrated reactor superstructure.

<Explanation of symbols for main parts of drawing>

100 reactor upper structure 110 container cover

111 stud bolt 120 annular support plate

130: double cylinder cylindrical structure 131: outer partition

132: internal partition 133: cooling air flow path

140: air inlet 141: air outlet

150: by-product protection plate 160: cooling fan

170: control rod drive device 180: maintenance door

200: cable installation member 201: cable

210: cable mounting bracket 220: cable mounting hinge

230: cable mounting support support 240: lower support

250: upper support 260: string

270: lifting wire 280: winding machine

300: wall 310: lifting tripod

320: seismic support rod

In order to achieve the above object, the present invention provides a pressurized light-water reactor in a nuclear power plant. A reactor upper structure 100 including a reactor vessel cover fixed to a reactor body by a stud bolt is integrally formed, and a lifting tripod 310 for lifting the reactor upper structure by a crane is a by-product of the reactor upper structure. It is coupled to the upper portion of the protection plate, and also to support a plurality of seismic support rods 320 is installed between the circumference of the reactor upper structure 100 and the wall 300 in order to prevent the reactor upper structure from shaking due to an earthquake. But if necessary detachable, supplying power to the reactor superstructure, It is fixed to the wall to support the signal transmission wires coming from the measuring instrument installed in the furnace, characterized in that it is provided with a cable installation member 200 installed to be lifted toward the wall.

The reactor superstructure includes a reactor vessel lid for closing the pressure vessel; An annular support plate installed on the reactor vessel cover; A double cylindrical structure formed on the annular support plate and having an outer partition and an inner partition to form a cooling air flow path; A plurality of air inlets through the outer partition and the inner partition forming the double cylindrical cylinder structure to allow cold air outside the cylinder to flow into the cylinder; A by-product shield plate installed on an upper portion of the double cylindrical cylinder structure; It is characterized in that the plurality of cooling fans 160 installed on the fly protection plate blows air is formed integrally.

In addition, the cable installation member 200 is installed on the wall 300 by a cable mounting hinge 220, the cable mounting base 210 to the circular motion around the hinge 220; One side is coupled to the lower portion of the cable mount 210 to support the cable mount 210, the other side is a cable mount support rod 230 coupled to the lower support 240 of the wall (300); When the cable mounting bracket 210 is lifted after the lower part of the cable mounting support rod 230 is removed, the cable mounting support 210 is connected between the support rod 210 and the support rod 230 so as to move only within a predetermined range. A string 260; It is installed between the upper end portion of the cable mounting bracket 210 and the upper support 250 to lift or unwind the lifting wire 270 and the lifting wire 270 to lift the cable mounting stand 210, if necessary cable mounting stand ( It is characterized by comprising a winding machine 280 for changing the attitude of the 210.

Exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

1 is a perspective view of a unitary reactor superstructure showing the main components of the present invention, and FIG. 2 is a front view of the reactor vessel cover 110, the annular support plate 120, and the outer partition wall constituting the unitary superstructure 100. 131, the seismic support rod 320, the cable mounting bracket 210, the cooling fan 160, the lifting tripod 310 is shown.

An annular support plate 120 is installed on the hemispherical reactor vessel cover 110, and the annular support plate 120 is a double cylinder in the form of a circular cylinder consisting of an outer partition 131 and an inner partition 132 (see Fig. 4). Cylindrical structure 130 is placed. Since the scattering protection plate 150 is installed above the outer partition 131, the control rod driving device 170 is scattered to prevent damage to the surrounding structure. Parts installed in the control rod driving device 180 and the reactor vessel cover 110 installed in the inner partition 132 during operation or maintenance period by installing the maintenance door 180 in the lower portion of the outer partition 131. And check the signaling system.

The integrated reactor upper structure is equipped with a plurality of seismic support rods 320 to ensure safety even in earthquake conditions. The seismic support rods 320 connect the unitary reactor upper structure 100 and the wall 300 to prevent the reactor upper structure 320 from falling sideways due to its own weight even if the reactor is shaken due to an earthquake or the like.

3 is a plan view of the unitary reactor superstructure 100 and shows the placement of the cooling fan 160 and the lifting tripod 310. Nuclear reactor vessel cover 110 is provided with a plurality of stud bolts 111, the stud bolts 111, seismic support rods 320, and two cable mounts 210 before lifting the reactor upper structure 100 ) Must be separated from the unitary reactor superstructure 100. Here, the cable mounting station 210 is a structure that serves as a bridge for supplying power to the upper structure of the reactor, and connecting the signal transmission wire cable from the instrument installed in the reactor toward the wall (300).

5 shows a detailed configuration of the cable installation member 200. The cable mounting member 200 is a cable mounting bracket 210, the upper support 250, a winding machine 280, the lifting wire 270, cable mounting support rod 230, string 260, cable mounting hinge 220, and It is composed of a lower support 240, the upper support 250, the cable mounting hinge 220, and the lower support 240 is fixed to the wall (300). When lifting the reactor vessel cover 110 in order to reload the nuclear fuel in the reactor, the cable mounting base 210 is left in an elevated state as shown in FIG. After the reloading of the nuclear fuel is completed, the cable mounting stand 210 is almost horizontal as shown in the state where the upper reactor structure 100 is returned to the state as shown in FIG. The posture of the cable installation unit 210 is a structure for winding or releasing the lifting iron wire 270 by using the winding machine 280 installed on the upper support 250 to adjust. When the cable mounting bracket 210 is in a horizontal state, the lower end of the cable mounting support rod 230 and the lower supporter 240 are fixed with pins or bolts.

4 schematically illustrates a cross section of the upper portion of the reactor vessel cover 110 of the unitary superstructure. In the portion of the control rod drive device 170 and the reactor vessel cover 110 inside the upper structure wrapped around the outer partition 132, a lot of heat is generated, it must be released before the electrical device of the control rod drive device 170 Can work properly.

Therefore, the interior of the integrated upper structure 100 is formed with a cooling air flow path 133 for forcibly cooling the heat generated by sucking the cooling air. The arrow in FIG. 4 shows the flow path 133 of cooling air. By the operation of the cooling fan 160 is to blow the air between the outer partition 131 and the inner partition 132 of the upper structure in the direction of the arrow to the outside of the structure, thereby the arrow through the air inlet 140 Cold air flows in the direction. The cold air flowed in the downward direction flows through the cooling air flow path 133 of the control rod drive unit 170, absorbs heat generated by the control rod drive unit 170, and then receives heat generated from the reactor vessel cover 110. After absorbing, it moves upward through the space between the outer partition 131 and the inner partition 132. The air thus moved is forcibly discharged out of the upper structure through the air outlet 141 by the cooling fan 160. The forced cold air flows into the upper structure of the reactor so that the electric coil or the like of the temperature-sensitive control rod driving device 170 is maintained below a predetermined temperature.

FIG. 6 is a front view and a plan view of an installation operation state of the integrated reactor superstructure according to the present invention, showing a state in which a cable 201, which is a signal transmission line from a measuring instrument installed in the reactor, is hypothesized.

Another feature of the present invention is to design the reactor superstructure 100 as integrally as possible so that the removal of the reactor vessel cover 110 for nuclear fuel reassembly can be accomplished in a few simple steps, relatively simple compared to previous complex multi-step processes. The work was done.

As described in detail above, the present invention is a conventional nuclear reactor which has suffered damages such as increased worker radiation exposure and economic loss due to shutdown due to the complicated multi-step process involved in the removal of the upper structure of the reactor during the maintenance period of the nuclear power plant. About the design of the superstructure,

The reactor superstructure is divided into several simple parts to design integrally, so that the reactor superstructure can be quickly removed in a few simple steps, and the cooling air flow path of the cylindrical double bulkhead structure is installed to force cooling air. By circulating furnaces, critical components can be kept below a certain temperature, reducing unnecessary work, reducing downtime and reducing radiation exposure for workers.

Therefore, the present invention is a very useful technique not only for the economical operation of nuclear power plants but also for reducing the radiation exposure dose of workers whose regulations are being strengthened worldwide.

Claims (3)

In pressurized water reactor reactor of nuclear power plant, Located in the upper part of the reactor, a plurality of control rod drive unit 170 is installed therein, the reactor vessel cover 110 is fixed to the reactor body by a plurality of stud bolts 111 to be disassembled and lifted when reloading the fuel. Reactor superstructure 100 formed integrally, including; A lifting tripod (310) coupled to and installed on an upper portion of the protection board (150) of the reactor upper structure to lift the entire structure by a crane; A plurality of seismic support rods 320 disposed between the circumference of the reactor upper structure 100 and the wall 300 to prevent shaking of the reactor upper structure 100; Cable installation member 200 is supplied to the reactor upper structure 100, fixed to the wall 300 to support the signal transmission wires from the instrument installed in the reactor, and installed to be lifted toward the wall 300, if necessary Integral reactor superstructure, characterized in that consisting of. The method of claim 1, The reactor superstructure 100 is A reactor vessel cover 110 for closing the reactor pressure vessel; An annular support plate (120) installed on the reactor vessel cover (110); A double cylindrical cylindrical structure (130) formed on the annular support plate (120) and having an outer partition (131) and an inner partition (132) to form a cooling air flow path (130); A plurality of air inlets 140 penetrating the outer partition 131 and the inner partition 132 forming the double cylindrical cylinder-type structure 130 to allow cold air outside the cylinder to flow into the cylinder; A by-product shield plate 150 installed on an upper portion of the double cylindrical cylinder structure 130; The integrated reactor upper structure, characterized in that the plurality of cooling fan 160 is installed on the fly protection plate 150 to blow air is formed integrally. The method of claim 1, The cable installation member 200 A cable mounting stand 210 installed on the wall 300 by a cable mounting hinge 220 and having a circular motion around the hinge 220; One side is coupled to the lower portion of the cable mount 210 to support the cable mount 210, the other side is a cable mount support rod 230 coupled to the lower support 240 of the wall (300); When the cable mounting bracket 210 is lifted after the lower part of the cable mounting support rod 230 is removed, the cable mounting support 210 is connected between the support rod 210 and the support rod 230 so as to move only within a predetermined range. A string 260; It is installed between the upper end portion of the cable mounting bracket 210 and the upper support 250 to lift or unwind the lifting wire 270 and the lifting wire 270 to lift the cable mounting stand 210, if necessary cable mounting stand ( An integrated reactor superstructure, characterized in that it comprises a winding machine (280) for changing the attitude of the 210.