SK2342000A3 - Protecting device of the nuclear power plants and method of decreasing pressure in adjacent buildings of the nuclear power plant - Google Patents

Abstract

The protective device of the nuclear power plant (4) in the form of the building surrounding the nuclear power plant (4), the inner wall (2) of which consist of thermally resistant material and is fixed on the specialised construction, whilst the inner wall (2) is equipped with the outlets that can be closed with the closing devices (8), for example by clappers, which can be open outwards, particularly under the pressure effect. The outlets on the inner wall (2) made by massive metal plates of the chamber nose (6, 7), placed between outer and inner walls, in which the filtration device (9) for the finest grains with exchangeable fillers for radionuclides filtration is placed and which comes to the annular space between the outer and inner walls (2), which creates the mixing space connected with the outer space by untightnesses of the outer cover (32).

Description

The protective device is a method of reducing pressure in adjacent nuclear power plant buildings.

Technical field

The invention relates to a protective device for atomic power plants in the form of a structure surrounding an atomic power plant when its inner walls consist of a heat-resistant material and are mounted on a support structure, the inner walls being provided with openings with a closing device such as dampers which open against pressure .

BACKGROUND OF THE INVENTION

The invention relates to a protective device combined with a method for reducing the pressure and the amount of gas in the event of a failure of an eastern nuclear power plant with contaminant-free water pressure reactors as in technically old embodiments. The protective device can be made in a massive double-walled version with nuclear power plants running so that, in the event of a failure, escaping gases and vapors of radionuclides can be trapped on the one hand in a very voluminous space of the device and on the other increasing the volume and pressure of the medium, which acts as a means of reducing the pressure and at the same time processing the medium, thereby releasing neutralized gases without radionuclides into the free space.

Technological measures and a special design of the inner wall allow the removal of the failure medium in the chambers at four different places by reducing the pressure and filtering the gases from radionuclides and toxins before they are released into the atmosphere.

Further aspects of the invention envisage that the protective device be made in a low design with optimized technological measures. This is confirmed by the calculations of the Austrian Research Institute A-2444 Seibesdorf, Austrian Research Centers near Vienna, according to Dr. K. Muck June 17, 1999, on page 2: Model calculations can be performed in the event of a nuclear power plant failure for the expected heat sources (pressure, temperature, volume). On the other hand, it is possible to optimize the massive structure for the permissible volume at maximum pressure. The maximum pressure would attempt to lift the building from the ground for a large base area, but this is prevented by the massive interior walls with relatively thick metal plates and metal construction, causing a high ground load. According to technological measures, radioactive fluid can be removed at the deepest point.

It is known that pressure reactors in the event of failure do not explode, as the Russian RBMK Chernobyl reactors. However, even in the event of a failure of the pressure reactor, the pressure in the chambers of the building increases so that its walls can break and radioactive particles can escape. The best known failure occurred in the Western Pressure Reactor at Three - Milé - Island, Harisburg, Pennsylvania, USA in 1979 by partial melting of the core. The inset metal tank above the reactor withstood a rapid increase in pressure and temperature, which later proved to be a critical condition.

A study by Atomwirtschaft, March 1981 by Hennies, Hosemann and Mayinger from Germany entitled The course and consequences of a DWR failure of nuclear melting explains the consequences of a failure of a pressurized reactor of a Western nuclear power plant with a contaminator. See pages 168-175. The graph on page 170, Fig. 1 shows the time course of pressure in the safety tank. The predicted failure time is 4.5 to 12.5 days, while the contaminant pressure has risen to 9 bar, being designed for a pressure of 5 bar. The criterion is a several-day supply of thermal energy, which can last for more than 12.5 days at the next pressure rise. The contaminator breaks when the pressure exceeds 9 bar, probably with similar consequences for man and the environment as the G AU disaster in Chernobyl 1986. To prevent any risk, protection is also anticipated for the disposal of contaminated media.

PCT patent WO 92/02 021 shows a plastic barrier apparatus and methods for absorbing radioactive particles, gases, toxic liquids in a nuclear power plant failure. Above the nuclear power plant are four pumpable independent roofs in the middle upwards and on the sides sealed on the ground. Air filtering systems have gaps between the four roofs. Tent roofs and underground tunnels are also reception facilities. This unstable barrier forms a protective cover but is not a thermally stable measure and is not intended to reduce the pressure of contaminated media at KKW - GAU.

BRD patent 29 21 944 shows the protection of an atomic power plant with receiving rooms where radiation, gases, cooling water that is out of control and small round receiving rooms for receiving equipment and special containers can be received and concentrated by specially trained personnel. This design is foreseen for minor failures, not for nuclear power plant failures without contaminant, and not for accepting large volumes at the degradable site.

With the protection according to AT 405 110, the 150-meter-high version of the inner walls can be fitted with thin metal plates having tensile elements on their outer side to accommodate high bending loads. It is complicated and expensive to fit tension elements on metal beams and slabs on the perimeter of each horizontal row up to the dome. The closed building does not have an overpressure fuse installed, which would allow its removal and cleaning of the medium in case of a long-term increase in pressure and volume.

SUMMARY OF THE INVENTION

The object of the invention is to help in this regard. This is accomplished by the fact that the projected openings in the inner wall formed by the solid metal plates open into a chamber located between the outer and inner walls, which includes a finest grain filtering device for filtering radionuclides with interchangeable inserts which opens into an annular space between the outer and inner walls. it forms a mixing space and is connected to the external space by leakage of the outer cover.

This results in a combined reduction of pressure and gas in this protective device, whereby a special design of the inner wall achieves a massive construction of the structure with thick metal plates. The closure elements may be arranged in pairs diametrically opposite each other at the horizontal level of the cross-section of the building, the closure elements being arranged at the following cross-section levels so as to be offset from one another. These four pairs of displaced chambers are located near the ground and 1/3 of the height of the building, are equipped with shut-off flaps, whereby the weight-loaded flaps mounted on the inner wall can be hinged upwards, and again form a closed and sealed wall. The flaps can be re-opened when internal pressure is applied, or if there is a negative pressure from the outside with the suction device switched on. In each chamber there is a filter device with exchangeable inserts which filters radionuclides and toxic media of the finest particles and grains After passing the GAU medium through the open flap and the upper half of the filter device, neutralized gases emit into the annular space between the inner wall and the outer cover. serves as a mixing space. From this annular space, the cleaned gas passes through the leaks of the outer cover of the protection to the free space.

For the exit of the medium from the interior of the protection, four chambers with wall openings with a closing device and a closing flap are provided so that the closing device can be displaced by 90 ° in the circumferential direction.

It is further envisaged that a ground-mounted and engageable suction device opens into the chamber via a shut-off device and a shut-off suction duct facing outwards, and that another suction duct opens into the space between the outer and inner walls outside the chamber. chamber. It is assumed that the suction device must be switchable to a second connection directly from the interior of the building, the flap and medium being opened under vacuum by the lower half of the filter device, the open shut-off valve and the suction line transporting the cleaned gases into the space.

Furthermore, it is advisable to install a sprinkler or spraying device in a large-volume protection in the form of an annular guide that serves the combined use of technology. This is achieved by installing an annular duct with nozzles in the space enclosed by the inner wall, which is connected to a reservoir of non-combustible liquid, for example water, in the reservoir located in the annular space between the outer and inner walls in the roof area. construction, or the supply consists of water supply.

Preferably, the sprinkler can be installed such that the annular guide is located at 2/3 of the height of the building. The nozzles are directed to the center for intensive spraying on the disturbance medium, with cooling and pressure reduction after initial steam formation.

The liquid tank must always be filled as a reserve and always lowered by the appropriate shut-off valve, even with the spray head in a central position located slightly lower than the annular line. For this purpose, it is necessary to stretch a few meters wide heat-resistant network so that an approximately horizontal path for the spray head mounted on the car is formed between the annular conduit and the ground, and a movable conduit for non-flammable liquid, for example water. Furthermore, it is expedient for the travel path to be formed by a net belt which passes through the inner space to allow free passage of steam.

For the variable placement of the spray head, it is assumed that the ends of the two ropes are attached to the car. which lead from two diametrically opposed positions of the interior space, serving combined technological measures.

For the long-term function of the protective device, it is assumed that the inner wall is provided with a shielding coating which is applied to the inner wall, whereby shielding against the output of radioactive radiation can be guaranteed.

For the control of technological measures, several observation holes on the inner wall fitted with protective glass are required. On these openings it is possible to install TV devices for observation from a central location.

Access to each glass and operator is required from the ground, ensuring the control of all measures by the persons behind the massive inner wall protected.

The protective device is combined for pressure reduction and liquidation, is designed for construction to an atomic power plant and allows for high quality and reliability against radioactive radiation leakage by relieving the escaping pressure of polluted gas after gas purification in the event of an internal failure in the event of a failure. from radioactive particles, through the outer wall, optionally additionally through a filter. People and the environment will receive reliable protection locally and at a greater distance, even in the event of a major failure of the nuclear power plant.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawing shows a protective device according to the invention with a method of pressure reduction and gas removal in three variants:

FIG Protective device according to the invention with a method of pressure reduction and gas removal built to an atomic power plant with side buildings in vertical section.

Fig.2. It shows a horizontal section of FIG. 1 by line a - a.

Fig. 3 shows a partial section along line b - b Fig. 2.

The metal structure is shown schematically in Fig. 1 as a double-walled structure with a dome-shaped roof. The inner wall is massively constructed, with four chambers in pairs displaced by 90 ° in pairs on the ground and at 1/3 of the height of the building, which are opened by overpressure from inside space or underpressure from outside caused by suction device. To control the technology, 2/3 of the building height is fitted with a fine spray nozzle as well as a liquid connection. Below is a spray head on the car coupled to a movable guide which extends through an opening in the inner wall to the downstream water connections. There are two ropes attached to the car, which run through the inner wall and serve for lateral displacement of the spray head.

FIG. 2 also shows schematically a metal structure with an outer cover and an inner duct with nozzles of the spraying device. Centrally beneath this is a narrow permeable support network which serves as a driving path for the spray-headed car, which has an attached hose duct which extends outwardly to the water supply.

Fig. 3 shows opposing chambers on the ground, of which only one is drawn and opened by means of flaps, on which on the one hand the internal pressure is applied and on the other hand the negative pressure externally generated by the suction device. The second pair is located at 1/3 of the height of the building shifted by 90 °. The contaminated medium is cleaned from the radionuclides downstream by the filters with replaceable inserts before the gases are discharged into the mixing space and the free space.

The exhaust device shall be switchable to the exhaust gases from the chamber through the top of the filtering device and to the mixed air of the annular space between the inner and outer walls of the protective device. Each of the four chambers shall be provided with its own exhaust device.

Example

According to FIG. 1, the protective device 1 is a massive inner wall 2 fixed on the base 3 and stands above the nuclear power plant 4 with several secondary structures 5. The inner wall 2 has two opposing chambers 6 near one of the ground, one of which is drawn 90 ° the chambers 7, of which only one is drawn and turned to the level, with their articulated weight flaps 8, the filter device 9 as well as the shut-off valve 10 and the exhaust device U.

At 2/3 of the height of the protective device 1, there is a spraying device on the inner wall 2 with an annular duct 12 and nozzles 13, as well as a side net attached thereto as a lane 14 on which the spray head car 15 can be located and moved. 16 and the hose line 17, as well as the two ropes necessary for changing the position 18. In the dome area, there are two large water-filled tanks 19 with a common connecting line 20. Through the downcomer 21, after opening the shut-off valves 22 and 24, the spraying device can be supplied with filled water tanks 19 in an emergency, the T-piece 23 being foreseen The corner splitter 26 also serves for further water supply to the hose line 17 and the spray head 16 when the shut-off valve 25 is open and guided through the ascending line 27, the open shut-off valve 28 as well as to drive water from the water supply 30 through a rising line 27, open by a closed drive unit. This actuator is, for example, a pump which fits the fittings 25 and 28 as well as 24 to the spray head 16 as well as into the annular line 12 and sprays water through the nozzles on the cooled GAU medium radially into the circle as well as centrally into the interior. The tanks 19 are also still filled through the pump 29.

Fig. 2 shows schematically a metal structure 31 with an outer cover 32 at 2/3 of the height of the building and just above it. Furthermore, a suction device 33 for resting gas exhaust is provided on the ground. An annular duct 13 is mounted on the inner wall 2 as well as a support network as a lane 14 where the carriage 15 with the spray head 16 occupies a central location and can be laterally displaced to the left and right of the two ends of the ropes 18 for spraying. protected position behind the inner wall 2.

Fig. 3 shows the inner wall of the protection 2 and the outer cover 32 with the ground chamber 6, as well as the weight-loaded flap 8 and the filter device 9. The suction device 33 located below can on one side suck the rest media out of the inner space of the wall 2 through the chamber 6, its open flap 8, which is opened by flow, further through the lower half of the filter device 9, the open shut-off fitting 34 and the suction line 35 and, on the other hand, must be switchable to the suction port 36 so as the opening 37 is closed vertically and sealed at the same time by the weight-loaded flap 8 in the unpressurized state on the inner wall 2.

Claims (12)

PATENT CLAIMS 1) Protective device for nuclear power plants to reduce pressure in adjacent buildings »of a nuclear power plant, the inner wall of which consists of a heat-resistant material and is fastened to a professional structure, the inner wall being provided with shut-off openings provided with shut-off devices. outside, in particular against the compressive force, characterized in that chambers (6, 7) are located in openings in the inner wall (2) formed by solid metal plates between the outer and inner walls, in which there is a filter device (9) for the smallest grains with replaceable inserts for filtering radionuclides that open into an annular space between the outer and inner walls, which form a mixing space connected to the outer space by leakage of the outer casing (32). Protective device according to claim 1, characterized in that the shut-off devices (8) are arranged in pairs and one above the other diametrically opposite each other in the horizontal position of the cross-section of the building (1), the shut-off devices (8) being self-shifted. Protection device according to claim 2, characterized in that the closing devices (8) are offset by 90 ° in the circumferential direction. Protective device according to claim 1, characterized in that the chambers (6, 7) open into the space between the outer and inner walls outside the chamber and which can be closed and outwardly guided by means of a shut-off device (8). a suction device (33) which can be connected to a suction device from the chamber (6,7). Protective device according to one of Claims 1 to 4, characterized in that in the space surrounded by the inner wall (2) there are provided nozzles (13) Kj is an annular conduit (12) which is connected to a reservoir of non-combustible liquid, for example water, the reservoir being located in a reservoir (19) located in the annular space between the outer and inner walls in the dome space, or 30). Protective device according to one of Claims 1 to 5, characterized in that the annular guide (12) is located at 2/3 of the height of the building. Protective device according to one of Claims 1 to 6, characterized in that between the annular guide (12) and the ground there is a horizontal path (14) for the spray head (16) fixed to the vehicle (15) to which it opens. a movable conduit (17) for supplying a non-combustible liquid, for example water, which extends upwardly from the interior through an opening in the wall. Protective device according to claim 7, characterized in that the travel path (14) is formed by a net belt (14) which passes through the interior space. Protective device according to claims 7 and 8, characterized in that the ends of the two ropes (18), which extend from two diametrically opposed positions in the interior, are fastened to the car (15). Protective device according to one of Claims 1 to 5, characterized in that the inner wall (2) is provided with a shielding layer which is applied to the cleaned inner wall. Protective device according to one of Claims 1 to 10, characterized in that the inner wall (2) has observation openings closed by a protective glass. Method according to claims 1 to 11, characterized in that in buildings (1) surrounding nuclear power plants (4), in the event of a failure in the interior, the pressure of the polluted gas generated after purification of the radioactive particles is removed via an filter (9). through the outer wall.