RU2727616C1 - Shipping packaging set for transportation and storage of liquid spent nuclear fuel - Google Patents

Abstract

FIELD: nuclear industry.SUBSTANCE: invention relates to nuclear industry, in particular, to transportation of spent nuclear fuel of nuclear reactors for processing. Transport package for transportation and storage of liquid spent nuclear fuel (LSNF) comprises a container having a housing in which a container for radioactive material is installed, an inner and an outer cover with fastening and sealing means, damper installed on outer side of container. Container body is made thickened from corrosion-resistant steel, the container is made in the form of a cup from corrosion-resistant steel, equipped with fuel and gas nozzles, and fixed in the container against movement by an inner cover and a pin on the side surface of the container entering the groove of the inner surface of the body, the damper is made of two attached compartments and is installed along the entire lateral and end surface of the container.EFFECT: invention makes it possible to ensure safety requirements of personnel when performing work on loading (unloading) of LSNF in shipping packaging set.13 cl, 6 dwg

Description

The invention relates to the field of the nuclear industry, in particular, to the transportation of spent nuclear fuel (SNF) of nuclear reactors for reprocessing, namely, to the design of transport-packaging sets (TUK) for the transportation of liquid SNF (LFSF).

The experience of transporting LSNF of the IIN-3M research reactor operated by the Foton joint-stock company from the Republic of Uzbekistan to the Russian Federation is known (“The first experience in the development of technology for the transportation and processing of liquid spent nuclear fuel” from the collection of reports of the X International Forum “Safety of Nuclear Technologies: Transportation of Radioactive Materials - "Atomtrans-2015", St. Petersburg, October 5-9, 2015). LSFC in the amount of 23 liters was reloaded with the help of special equipment from temporary storage tanks into transport canisters, then canisters with LSFC were loaded into SKODA VPVR / M TUK. For transportation by road, this TUK with LSF was placed in an ISO container.

The SKODA VPVR / M container is a structure that allows loading it from below and unloading it from above, for which the container has a system of two upper and two lower lids. The container body is made of cast iron. The inner walls of the container are aluminum coated. The standard case installed in the container is made of sheets of boron-containing steel and has cells for placing canisters with spent nuclear fuel. A central suspension running through the center of the boot is used to raise or lower the boot. To ensure tightness, special metal gaskets are used.

The use of TUK SKODA VPVR / M for transportation of LSF has the following disadvantages:

- The TUK is designed for the transportation of spent nuclear fuel in the form of spent fuel assemblies (SFA) of high activity and its use for the specific transportation of canisters with LSNF to the processing plant is one-off;

- the overall and mass characteristics of the TUK do not allow it to be rationally used for the transportation and long-term storage of canisters with LSF in it, as follows: the overall dimensions of the canister depend on the dimensions of the TUK cover cells, while damping assemblies are installed in the cells not filled with canisters; the filling of the canisters of LSFS is carried out at special posts where it is impossible to place the TUK, after which special equipment is used to load the canisters with the LSFS of the TUK, which ensures the required level of safety of the work.

Known transport packaging for the transportation and storage of radioactive materials for patent RU 71803 U1, publ. 20.03.2008 Bul. No. 8. The known device is intended for transportation and storage of spent nuclear fuel in the form of a nuclear-radiation-hazardous bulk cargo and contains a container body, inner and outer covers mounted on the body with fastening and sealing means, a cover and dampers, the inner cavity of the cover is divided, at least , into two parts by a vertically installed neutron trap in the form of a hollow dividing wall, and the bottom of each part is made in the form of a sash with the possibility of opening, wooden dampers are lined with stainless steel, installed at the ends of the container and pulled together by pins.

This TUK is taken as a prototype, as the closest in technical essence to the claimed technical solution.

This TUK has the following disadvantages:

- loading of the cover installed in the container body with radioactive material is carried out under water. After loading, the inner lid is installed and the container cavity is dried. This method of loading radioactive material excludes the possibility of loading LFSF into the case;

- the presence of dampers only on the end surfaces of the container does not exclude the possibility of damage to the container in an emergency, leading to a violation of the tightness of its cavity.

The technical result is the creation of a TUK for the transportation and long-term storage of LSF of increased activity with the provision of personnel safety requirements when performing work on loading (unloading) of LSF in the TUK.

The technical result is achieved by the fact that in a transport packaging set for transportation and storage of liquid spent nuclear fuel, containing a container having a housing in which a container for radioactive material is installed, an inner and outer cover with fastening and sealing means, a damper installed on the outside of the container, a housing the container is made thickened of corrosion-resistant steel, the container is made in the form of a glass of corrosion-resistant steel, equipped with fuel and gas fittings, and is fixed in the container against movement by an inner lid and a pin on the side surface of the container that goes into a groove on the inner surface of the body, a damper made of two fastened compartments and installed along the entire side and end surface of the container.

In TUK versions:

- a cover with fastening and sealing means is installed in the upper part of the container glass;

- biological protection is installed in the upper part of the tank;

- the biological protection is made of a composite, one part of which is the neck, and the other is an insert made of high density material, for example, lead;

- each damper compartment is made in the form of a cylinder with a bottom, fastened to each other in the equatorial region of the container and having cavities in which blocks of wood are located, pasted over with a special fabric, for example, MBOR, on the outer surface of the cylinder there are longitudinal ribs with holes for lifting the TUK, on the inner surface of the bottom there is a gasket made of elastic material, for example, rubber;

- the cylindrical surface of the container body cavity has a groove in which a neutron-absorbing insert is installed;

- neutron absorbing insert is made of cadmium;

- the outer and inner covers have two concentrically located sealing elements on the end surface mating with the container body;

- two channels are made in the container body to check for tightness of cavities between the sealing elements of the inner and outer covers, plugs are installed in the channels;

- the inner cover has a channel for testing the cavity under the cover for tightness, a plug is installed in the channel;

- on the end surface of the outer cover there are threaded holes for installing lifting equipment, for example, eye bolts;

- there are holes filled with compound on the inner cylindrical and end surfaces of the metal lining of the damper compartments;

- the thickness of the walls of the container and the container are selected on the basis of the conditions for ensuring nuclear and radiation safety during transportation and storage of TUK with LSF, as well as the safety of work by the service personnel after filling the canister of LSF in the container body with a total activity of up to 915Ci.

Placement in the cavity of the container of a container for LSFL, as well as the presence of a groove on the inner cylindrical surface of the container body for the pin of the canister allows the canister to be installed in a given angular position relative to the container body. Implementation of the container in the form of a glass of corrosion-resistant steel, equipped with fuel and gas fittings, the presence of a composite biological shield in the upper part of the container, one part of which is the neck, and the other - an insert made of high-density material, for example, lead, as well as a lid with fastening and sealing means allow to fill the LFSF tank in compliance with work safety requirements.

The presence of two sealing elements in each lid increases the reliability of sealing the internal cavities of the container, while the tightness of the cavities is monitored through the existing channels in the container body and the inner lid.

The damper is made of two compartments fastened together in the equatorial region of the container, each of which is made in the form of a cylinder with a bottom, having cavities in which blocks of wood are located, pasted over with a special fabric, for example, MBOR, as well as the presence of gaskets on the inner end surfaces of elastic material, and on the outer surface of the cylinder of the longitudinal ribs, allows to ensure the integrity and tightness of the container, with the container with LSFF placed in it, in emergency situations, for example, fire or fall during transportation and lifting.

The presence of holes filled with a compound on the inner cylindrical and end surfaces of the metal lining of the damper makes it possible to preserve the integrity of the metal lining when the TUK enters a fire when exposed to increased pressure of the environment that occurs when the damper is heated in cavities where blocks of wood are located, while the compound is removed from the holes medium pressure.

The presence of a neutron-absorbing insert in the groove of the cylindrical surface of the cavity of the container body ensures nuclear safety in the case of a dense arrangement of a large number of TCs with LSF.

FIG. 1 shows a general view of the TUK in section; in fig. 2 is a top view of the TUK, view A in FIG. 1; in fig. 3 - sealing of the inner and outer covers, element B in FIG. 1; in fig. 4 - channels for checking the tightness, section B-B in Fig. 3; in fig. 5 - section Г-Г in Fig. 4; in fig. 6 - element D in Fig. 1.

TUK consists of:

- container 1, including:

a) body 2, which has channels "a" and "b" to check the tightness. Plugs 3 are installed in the channels. On the inner cylindrical surface of the body cavity there is a groove "c" and a groove in which a neutron-absorbing insert 4 of cadmium is installed;

b) inner cover 5 with channel "d" for tightness test. A plug 6 is installed in the channel. The cover has sealing elements 7 and 8. The cover is fixed to the body 2 with fasteners 9;

d) outer cover 10. The cover has sealing elements 11 and 12, as well as threaded holes intended both for lifting it and for lifting the container 1. The cover is fixed to the body 2 by fasteners 13;

- tanks 14 for SNF, made in the form of a glass 15 made of corrosion-resistant steel, having:

a) pin 16, which fits into the groove "c" of the body 2;

b) a gas nozzle 17 with a plug 18 and a fuel nozzle 19 with a plug 20;

c) biological protection 21, consisting of a neck 22 and an insert 23;

d) cover 24, with a sealing element 25. The cover is fixed in the upper part of the cup 15 by means of fasteners 26;

- damper 27, consisting of a compartment of the lower 28 and a compartment of the upper 29, docked with each other by fasteners 30 and 31. Compartments 28 and 29 have blocks 32 and 33 of wood, covered with a special fabric 34, and located in the cavities of the lining 35 of corrosion-resistant steel ... On the outer cylindrical surface of the cladding 35 there are longitudinal ribs 36 with holes for lifting the TUK. On the inner surface of the bottoms of the compartments 28 and 29 there is a gasket 37 of elastic material. On the inner cylindrical and end surface of the lining 35 there are holes filled with the compound 38.

The intended use of the TUK is carried out as follows:

- TUK is installed on a flat horizontal surface, while for its lifting holes are used in the ribs 36 of the compartment of the upper 29 of the damper 27;

- remove the fastening elements 30 and 31 from the damper 27 and raise the upper compartment 29 with its subsequent installation on a flat horizontal surface;

- into the threaded holes of the outer cover 10 of the container 1, the eye-bolts are screwed, for which the container 1 is lifted, transferred and installed at the filling station of the TUK LFSF, where the following works are carried out:

a) remove the outer cover 10 from the container 1, then the inner cover 5;

b) remove the cover 24 from the glass 15 of the container 14;

c) remove the plug 18 from the gas fitting 17, and the plug 20 from the fuel fitting 19;

d) connect to the gas nozzle 17 a pipeline of the evacuation system, to the fuel nozzle 19 - a pipeline of the liquid fuel supply system coming from the tanks for the temporary storage of the liquid fuel, located in a special room;

e) service personnel leave the filling station;

f) remotely switch on the evacuation system and create a vacuum in the cavity of the glass 15;

g) remotely switch on the LSNF supply system. LSFC is supplied in a predetermined volume from temporary storage tanks through a pipeline into the cavity of the nozzle 15;

h) after filling the canister with LSNF, a predetermined volume of decontamination solution is supplied to the cavity of the nozzle 15 remotely from the decontamination system via the LSNF supply pipeline. After passing the decontamination solution, the service personnel enter the room;

i) the pipeline of the evacuation system is undocked from the gas nozzle 17 and the sealing plug 18 is installed;

j) the liquid SNF supply pipeline is undocked from the fuel nozzle 19 and a sealing plug 20 is installed;

l) install the cover 24 on the glass 15 and fix it with fasteners 26;

m) install the inner cover 5 on the container body 2 and secure it with fasteners 9, while the gap between the cover and the open end surface of the glass 15 is minimal, which limits the vertical movement of the container 14 during transportation. Install the pipeline of the leakage control system into the channel "d" of the cover 5 and check the tightness of the cavity under the cover. After checking the tightness, plug 6 is installed in channel "d";

m) install the outer cover 10 on the body 2 of the container 1 and secure it with fasteners 13;

- lift the container 1 by the eye-bolts, move it and install it in the lower compartment 28 of the damper 27;

- in the channels "a" and "b" of the container 1 sequentially install the pipeline of the leakage control system and check the tightness of the cavities between the sealing elements 7, 8, 11 and 12. After checking the tightness, plugs 3 are installed in the channels "a" and "b";

- raise the upper compartment 29 of the damper 27 and install it on the lower compartment 28. The compartments 28 and 29 are fastened together with fasteners 30 and 31.

Then the TUK is ready for transportation.

The overall and mass characteristics of the TUK prototype and its main components for the transportation of LSNF are:

- according to TUK: diameter -1050 mm, height - no more than 1150 mm, weight - no more than 1900 kg with LSF;

- by container: diameter - 510 mm, height - no more than 800 mm, weight - about 1100 kg;

- on a pencil case: diameter - 185 mm, height - 540 mm, weight - about 60 kg, volume of the inner cavity - 6.1 dm ³ ;

- the volume of the transported liquid fuel-5.1 dm ³ ;

- volume of decontamination solution - 0.5 dm ³ .

Strength, radiation-nuclear, thermal calculations and calculation of radioactive content leaks have shown that TUK allows:

- load LSF with activity up to 915Ci, coming from temporary storage tanks, into a case located in the container body;

- to carry out transportation of TUK with LSF by road, rail and water transport;

- to reload the TUK with LSF from one type of transport to another using lifting equipment;

- to ensure the protection of radioactive contents from external mechanical, thermal and other influences under normal and normal conditions of transportation and storage;

- to ensure radiation safety of service personnel, population and environment;

- to exclude the release of radioactive contents into the environment above the established limits in accordance with the rules of NP-053-16 and IAEA SSR-6;

- to ensure nuclear and radiation safety during normal operation, violations of normal operation, including design basis accidents.

Claims (13)

1. A transport packaging kit for the transportation and storage of liquid spent nuclear fuel (LFSF), containing a container with a housing in which a container for radioactive material is installed, an inner and outer cover with fastening and sealing means, a damper installed on the outside of the container, which is different in that the container body is made of thickened corrosion-resistant steel, the container is made in the form of a glass of corrosion-resistant steel, equipped with fuel and gas fittings, and is fixed in the container against movement by an inner cover and a pin on the side surface of the container, which goes into the groove of the inner surface housing, the damper is made of two bonded compartments and is installed along the entire side and end surface of the container. 2. A transport packaging set according to claim 1, characterized in that a lid with fastening and sealing means is installed in the upper part of the container glass. 3. A transport packaging set according to claim 1, characterized in that a biological shield is installed in the upper part of the container. 4. A transport packaging set according to claim 3, characterized in that the biological shielding is made of a composite, one part of which is the neck, and the other is an insert made of a high density material, for example lead. 5. The transport packaging set according to claim 1, characterized in that each damper compartment is made in the form of a cylinder with a bottom, fastened to each other in the equatorial region of the container and having cavities in which blocks of wood are located, pasted over with a special fabric, for example MBOR, on the outer surface of the cylinder has longitudinal ribs with holes for lifting the TUK, on the inner surface of the bottom there is a gasket made of an elastic material, such as rubber. 6. A transport packaging set according to claim 1, characterized in that the cylindrical surface of the cavity of the container body has a groove into which a neutron-absorbing insert is installed. 7. A transport packaging set according to claim 6, characterized in that the neutron-absorbing insert is made of cadmium. 8. A transport packaging set according to claim 1, characterized in that the outer and inner lids have two concentrically arranged sealing elements on the end surface mating with the container body. 9. The transport packaging set according to claim 1, characterized in that two channels are made in the container body to test for tightness of cavities between the sealing elements of the inner and outer covers, and plugs are installed in the channels. 10. A transport packaging set according to claim 1, characterized in that the inner cover has a channel for testing the cavity under the cover for leaks, and a plug is installed in the channel. 11. A transport packaging set according to claim 1, characterized in that there are threaded holes on the end surface of the outer cover for installing lifting equipment, for example, eye bolts. 12. A transport packaging set according to claim 1, characterized in that there are holes filled with a compound on the inner cylindrical and end surfaces of the metal lining of the damper compartments. 13. A transport packaging set according to claim 1, characterized in that the thickness of the walls of the container and the container are selected from the conditions for ensuring nuclear and radiation safety during the transportation and storage of the fuel oil and gas fuel complex with LFSF, as well as the safety of work by the service personnel after filling the LFSF canister in the container body total activity up to 915 Ci.

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