FI71030C - KAERNREAKTORSCHAKT - Google Patents

Description

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(51) Kv.lk. «/ Lnt.CI.« G 21 C 11/08 (21) Patent application - Patentansöknlng 791969 (22) Filing date - Ansökningsdag 20.06.79 (H) (23) Starting date - Glltighetsdag 20.06.79 (41) ) Become public - Blivit offentllg 2 ^ * .12.79

National Board of Patents and Registration / 44) Date of insertion and hearing glare— l8.O7.86

Patent- oeh registerstyrelsen '' Ansökan utlagd och utl.skriften publlcerad (86) Kv. application - Int. ansökan (32) (33) (31) Privilege claimed - Begärd priorltet 23.06.78 ussr (su) 2625001 (71) Moskovsky I nzhenerno-Stroitel ny Institut Imeni V.V. Kuibysheva, Shjuzovaya Naberezhnaya, 8, Moscow, Opytno-Konstruktorskoe Bjuro "Gidropress", ulitsa Ordzhnikidze, 21, Podolsk, USSR (SU) (72) Georgy Ivanovich Zholdak, Moscow, Vladimir Nikolaevich Ivanov, Moscow, Vitaly Borisov Petrovich Kaloshin, Moscow,

Jury Vasilievich Vikhorev, Podolsk, Nikolai Arsentievich Cyrillic, Podolsk, Larisa Evgenievna Shebanova, Podolsk, Mikhail Andreevich Lukyanov, Podolsk, Vladimir Iosifovich Tsofin, Podolsk, Vladimir Alexeevich Dorokhin, Moscow, Sergei Georgievich Golovska, Vor Nikolaevich Rukhmanov, Moskovskaya oblast, USSR (SU) (7 * 0 Oy Kolster Ab (5 * 0 Nuclear Reactor Gap - KSrnreaktorschakt

The invention relates to the production of nuclear energy and in particular to the shaft of a nuclear reactor.

The invention is most preferably used in the construction of nuclear reactor shafts under both normal and seismic conditions.

The nuclear radiation in the reactor is attenuated by biological protective layers made of concrete. Radiation leaks cause changes in the properties of conventional concrete, so to protect it, a radiation and heat shield is made between the concrete and the reactor, for example made of cast iron, steel or special concrete. It is known that reactor performance can be estimated based on the amount of neutron flux. The amount of neutron flux is measured from the radiation and heat shield using ionization chambers. To this end, each chamber is placed from the movable inside the tube and the tube is placed inside a radiation and heat shield. Several such tubes form an annular row. The shield material contains a considerable amount of hydrogen to increase the flow of thermal neutrons due to the deceleration of the fast neutron portion 2,71030, thereby improving the reliability of recording the start of the nuclear process in the reactor during start-up and other transient conditions.

The known protection structure against ionizing radiation from a nuclear reactor comprises a concrete shaft for receiving the reactor jacket and a radiation and heat shield in place in the form of a cast reinforced concrete cylinder, the steel cladding being arranged in the space between the shaft and the reactor walls. The cylinder is mounted on a support ring at the bottom of the reactor jacket and has an ultrasonic device for detecting cracks in the metal jacket of the reactor (West German Patent 2,226,574, G 21C 13/02, G21C 17/00, published December 30, 1976).

This structure is deficient because it does not have access to the outer surface of the reactor jacket for repair, refurbishment and prevention work, and the attachment of a thermal and radiation shield to the actual reactor results in reduced seismic stability of the reactor.

These disadvantages have been eliminated in the shaft of a nuclear power reactor, in which the radiation and heat shield in the form of a cast-in-place reinforced concrete cylinder is arranged to stand freely in the annular cavity of the shaft. This cavity or recess is bounded at the top by the cantilever supports of the reactor jacket and at the bottom by a protrusion supporting the cover.

The shield has a metal jacket with holes and tubes for the ionization chambers and thermal insulation on the reactor side. The space between the reactor jacket and the thermal insulation is sufficient to carry the ultrasonic detector for the jacket cracks and to carry out repair, rehabilitation and prevention work. When the plant is operating, this space is not cooled. This results in a decrease in the temperature gradient in the reactor jacket wall, which improves its reliability. In addition, the cooled spaces between the thermal insulation, the radiation and heat shield and the cantilever supports and the shaft wall reliably biologically protect the concrete layer and the ionization chambers from heating. Spaces are also necessary to allow free deformation of the cover.

The disadvantage of this structure is the long construction time of the shaft, which is 60-80 days longer due to the thermosetting (drying) of the concrete of the radiation and heat shield. In addition, it is not permitted to place the cover freely in a recess in earthquake areas.

3,71030

The object of the present invention is to eliminate the above-mentioned drawbacks.

The object of the invention is to provide a shaft for a nuclear reactor in which the structure of the radiation and heat shield is such that the shaft can be used in both normal and seismic conditions.

This object is solved in that in a nuclear reactor shaft comprising a cantilevered reinforced concrete cylinder, thermal insulation and a reinforced concrete shield with channels for ionization chambers and a cooling system, this shield is placed concentrically inside the cylinder at a distance from the , which are attached to the inner wall of the cylinder by leaving an air space between the different elements.

The nuclear reactor shaft according to the invention makes it possible to significantly reduce the construction time (by 60-80 days) due to the use of the modular arrangement and simplification of the assembly.

The mass of the individual elements is negligible compared to the mass of the in-situ cast cylinder. There are no difficulties in installing the prefabricated elements and fixing the shaft to the walls. This is because each prefabricated element, which together form an annular row, is installed independently of the others without any connecting members, with the exception of an air space of up to 15 mm wide between them.

The provision of air spaces between the reinforced concrete elements of the cover allows the use of such a gap in seismic conditions, i.e. in earthquake areas.

The intermediate spaces of the prefabricated elements increase the surface area available for cooling and reduce heating during continuous use. In addition, the provision of air spaces between the prefabricated elements allows the removal of stresses caused by radiation and thermal deformation, so that the protective strength of the prefabricated elements can be increased to 2-5 x 10 neutrons / cm, which is better - in terms of reliable life - subjection to repair and refurbishment.

The radiation dose capacity (possible amount of radiation dose) of neutron and gamma radiation behind the cover according to the invention is 4,71030 only 6.5 times compared to the cast structure of the cover. Such a local increase in radiation flux does not result in the presence of a substantial source of heat release in the materials of the shelter and therefore in any local overheating of the concrete of the actual biological protection system, which has been experimentally proven.

According to one embodiment of the invention, the prefabricated reinforced concrete elements of the cover are refractory concrete. This gives the shield increased radiation stability and raises its operating temperature limit.

In another embodiment, the air spaces between the reinforced concrete elements of the cover are arranged radially.

The radial spaces between the prefabricated elements result in an increase in the cooling surface area of up to 40% and a decrease in the heating temperature during continuous use by 10-15%. In addition, in an emergency, the radial air spaces cause the prefabricated elements to wedge as they move toward the center of the shaft as the fasteners and reactor jacket are destroyed, while as they move outwardly, the elements rest against the cylindrical inner wall of the concrete shaft.

Other objects and advantages of the invention will become apparent from the following detailed description of the preferred embodiments thereof with reference to the accompanying drawings, in which Figure 1 is an overview of a nuclear reactor shaft according to the invention; Fig. 2 is a sectional view taken along line II-II of Fig. 1; Fig. 3 is a sectional view taken along line III-III of Fig. 1; and Figure 4 shows the distribution curves of velocity neutron flux density behind a shield made of prefabricated elements and a mold cast in situ.

Figures 1, 2 and 3 show a shaft 1 for receiving a reactor jacket 2 and consisting of a reinforced concrete cylinder 3 with cantilever supports 4. The reactor jacket 2 is surrounded by a layer of thermal insulation 5. Between this layer 5 and the inner wall of the shaft 1 there are a concentric radiation and heat shield 6 having through passages 7 for receiving ionization chamber tubes (not shown in the drawings). The cover 6 consists of several prefabricated refractory concrete elements 8. The elements 8 are fixed to the wall of the shaft 1 and provided with a metal cladding 9. The space 10 between the prefabricated elements 8 and the wall of the reactor shaft 1 communicates with the radial air spaces 11 10 and 11 through.

Curve 12 in Figure 4 shows the flux density behavior of fast neutrons behind a prefabricated radiation and heat shield, and curve 13 shows the same in place behind a molded shield. The values of the flux density of fast neutrons in relative units are plotted on the ordinates and the abscissa represents the distance in centimeters symmetrically with respect to the axis of the airspace 11.

The division of the cover 6 into prefabricated elements 8 results in a reduced seismic load. This reduction in load is determined by the ratio of the mass of the annular cover 6 to the mass of the individual prefabricated elements 8 and is 2-10. The radial air spaces 11 between the prefabricated elements 8 result in an increase in the cooling surface area of up to 40% and a decrease in the heating temperature of the concrete by 5-10%. The provision of free surfaces of the prefabricated elements 8 for cooling in the air spaces 11 between them reduces the pressure difference in the emergency discharge of vapors from the reactor jacket 2. Thus, the conditions necessary for the operation of the ionization chambers are maintained. The design allows overheating as the radiation flux increases due to reactor capacity.

The separate prefabricated elements 8 are manufactured in a factory where they are dried by heating to 110 ° C. This results in dehydration of the entire volume of the prefabricated element 8, which reduces the release of gas by 25% during irradiation. The dried prefabricated elements 8 are sent to the construction site and installed by conventional methods in the shaft 1 of the reactor 2 together with the thermal insulator in 1-2 days, and the assembly of the production unit can then be done without wasting time due to concrete hardening and concrete preparation.

When the power plant is in operation, the mixed flux of neutron and gamma radiation passes through the shield 6. The radiation dose capacity of the neutron and gamma radiation behind the prefabricated shield 6 is only 6.5 times higher compared to the cast structure on site. This local increase in ionizing radiation flux does not cause an increased release of heat in the shielding material and therefore no local overheating of the concrete cylinder forming the shaft 1 of the reactor 2, as has been experimentally proven.

The fabrication of the shield 6 from the prefabricated elements 8 allows the fabrication of the nuclear reactor 60-75 days earlier than using conventional methods.

The concrete shaft 1 is manufactured up to the level of the cantilever supports 4 of the reactor jacket 2, the prefabricated elements 8 are mounted in an annular row, each element being fixed separately to the wall of the shaft 1, and then the elements of the reactor jacket 2 cantilever support 4 are mounted. The joints of the support 4 are filled with concrete and at the same time the reactor shaft is covered on the inside with an insulating layer, after which the assembly of the reactor jacket begins.

During manufacture, drying, installation and use, all prefabricated elements 8 are remotely controllable for their main function, i. its ability to slow the flow of fast neutrons.