RU2092917C1 - Nuclear reactor fuel assembly check-up device - Google Patents

Abstract

FIELD: nuclear power engineering. SUBSTANCE: device has facilities for fuel assembly mounting and holding it in position and facilities for vertical displacement of carriage with check-up instruments along fuel assembly, all placed in cooling pond and made in the form of separate modules with supporting pads provided in adjacent slotted floors of pond with supporting pads installed on metal structures of mentioned floors. Fuel assembly mounting and holding module has fuel assembly mounting and turning unit placed on supporting pad and uprising and downtake posts with fuel assembly holding units. Carriage vertical displacement module has supporting pad mounting two downtake guides and carriage both installed in slotted floor plane. Fuel assembly mounting and turning unit is made in the form of shell mounted for rotation about its longitudinal axis whose top end has conical drilling to receive fuel-assembly hanger displacer cone. Shell is turned by means of worm gear fixed on shell and engaging two kinematically linked together and with common drive by means of bevel gear transmission. EFFECT: improved design. 7 cl, 8 dwg

Description

 The invention relates to nuclear energy and can be used at nuclear power plants with a RBM-K type reactor, on which two-beam fuel assemblies are used.

 Known fuel assembly, consisting of two bundles of fuel rods strung on a bearing rod and fixed on the rod using the upper and lower shanks. A suspension is attached to the upper shank, consisting of a rod on which biological protection, a displacer and a sealing plug are installed in series with each other. Using the suspension, the fuel assembly is removed from the reactor and transferred to the holding pool, inserted into narrow slots formed by parallel-running metal structures forming the shutter pool overlap, and suspended from them / 1 /.

 As the operating experience of two-beam fuel assemblies showed, in most cases during operation one of the single fuel rod bundles is damaged, and in 90 cases one of the outer fuel rods is damaged. For this reason, a large number of fuel assemblies have accumulated in the holding pools of nuclear power plants with RBM-K reactors that can be returned to the fuel cycle if the damaged fuel element is removed (replaced).

 Previously, it was proposed a device for monitoring the fuel assembly of a nuclear reactor / 2 /. The device contains a vertical stationary rack, on one side of which the upper and lower nodes are mounted to hold the fuel assembly in a vertical position on the same side of the rack. The lower carriage with the drive is located on the same side of the rack as the above nodes, is connected to the rack by the type of bracket and can be moved vertically along the fuel assembly. A device is installed on the carriage for measuring the envelope of the fuel assembly and when it stops at the required elevation.

 The proposed device has a narrow focus.

 A device for measuring cassettes with fuel elements / 3 / is also known. The device is designed to control the external geometry of cartridges with fuel elements and fuel elements by measuring the outer surface along the entire cross section and its entire length. The device is located in a holding pool containing borated water. A vibration-independent and wear-free device for measuring the external geometry of an object is provided. To do this, a support is made on the measuring support, on which there are contactless sensors of linear size. As sensors can be used, for example, inductive eddy current sensors. When the caliper guide is made from the side of the device toward the measurement object, it is possible to maintain a very small distance from the measurement plane, so that vibrations, for example, due to extraneous influence of the caliper drive, do not transform in a positive direction, distorting the measurement results.

 This device in comparison with the previously given has a certain advantage, which consists in the fact that in addition to controlling the external geometry of the cartridge, the device allows you to control the external geometry of the fuel elements. However, like the first device, it has a narrow focus.

 The closest in their technical essence to the claimed one is a device for monitoring the fuel assembly of a nuclear reactor, containing installed in the holding pool means of vertical movement along the controlled fuel assembly of the carriage with control devices / 4 /.

 In the known device, the mechanism for moving the control means is formed by the first carriage moving along the deck; a column rigidly connected to the first carriage; the console moving along the column and the second carriage moving along the console in the transverse direction, and the control means are fixed on the second carriage. On the same floor there is a means of placing and fixing the fuel assembly.

This device has large dimensions, for its installation in the pool of exposure it is necessary to allocate a special place. Therefore, such a device cannot be used to control fuel assemblies of RBM-K reactors with their design of holding pools. In addition, this device is designed to control square in cross-section of fuel assemblies. In the control process of such an assembly, control is carried out from one side of the fuel assembly. Then the assembly must be unlocked, raised using a gripping device, for example, a shutter pool crane, rotated by 90 ^o , locked and again checked from the second side of the fuel assembly. With this control method, the control tool must make many movements in the control process, which is associated with a large expenditure of time. In addition, such a device has a complex structure.

 The aim of the invention is to simplify the installation and dismantling of the control device, as well as simplifying its maintenance.

 The basis of the invention was the task of developing a device for monitoring fuel assemblies of a RBM-K type nuclear reactor, which can be placed in holding pools existing on these reactors without additional work on adapting holding pools to control devices, and to carry out quick and easy installation and dismantling of the device for control.

 This problem is solved in that in a device for monitoring the fuel assembly of a nuclear reactor containing means for positioning and securing the fuel assembly and means for vertically moving the carriage with the monitoring devices installed in the holding pool, according to the invention, both means are made in the form of modules with support sites located in adjacent slit ceilings of the exposure pool and installed by supporting sites on the metal structures of these slotted floors, while the module of the assembly and mounting means of the fuel assembly comprises a assembly for locating and turning the fuel assembly and upward and downward struts with mounting assemblies of the fuel assembly, the assembly and turning assembly of the fuel assembly, its upper mounting assembly and the supporting platform are provided with vertical through slots for the suspension rod of the fuel assembly, coinciding in direction with the slit overlap of the holding pool, and the module of the means for vertical movement of the carriage contains mounted on op the platform and two guiding carriages extending downward with control devices, the guides and the carriage being placed in the same plane.

 It is advisable to place and rotate the fuel assembly in the form of a cup mounted on a rotatable axis around its longitudinal axis, on the upper end of which a conical bore is made under the cone of the propellant suspension of the fuel assembly.

 It is possible to fix the worm wheel on the cup coaxially with its longitudinal axis and engage it with two worms kinematically connected to each other and with a rotation drive through a bevel gear pair, in this case, the rollers in contact with the supporting platform should be placed on the lower end of the cup, and on the worm wheel to make a slot equivalent to the slot of the glass.

 The lower mounting assembly of the fuel assembly is preferably made in the form of a spring-loaded socket under the lower tail of the fuel assembly, mounted for rotation and vertical movement relative to the rack.

 It is advisable that the upper assembly of the fuel assembly is made in the form of a fork mounted on the upper end of the upper strut and means for overlapping the cuts of the fork located on the same strut.

 Preferably, the means for overlapping the slots of the fork are made in the form of a lever pivotally mounted on the upper strut connected to the mechanism of its rotation.

 It makes sense to turn the lever mechanism of the fork overlap means in the form of an electromagnet, the spring-loaded core of which is pivotally connected to the lever of the fork overlap means.

 In contrast to the prototype, in which the device for monitoring fuel assemblies is made in the form of a single unit and for installation of which it is necessary to allocate a special place in the holding pool, in the claimed invention the device for monitoring is made in the form of two modules: a module for locating and fixing the fuel assembly and a module assembly control tools. Both modules are located in adjacent slit ceilings of the exposure pool. Their installation in the pool of exposure can be carried out only at the moment when control tests are required. After such tests, the modules can be easily removed from the exposure pool.

 In addition, the design of the device for monitoring the fuel assembly is such that in order to install the fuel assembly in the placement and mounting module for the maintenance personnel of the holding pool, it is necessary to perform almost the same steps as when installing the spent fuel assembly in the holding pool when hanging it on the slotted metal structures pool exposure.

 Figure 1 shows the proposed device, a General view; figure 2 is a view along arrow A in figure 1; figure 3 view along arrow B in figure 1; figure 4 section BB in figure 1; in Fig.5 node 1 in Fig.1; in Fig.6 node 2 in Fig.1; in Fig.7 section along G-G in Fig.2; on Fig section along DD in Fig.7.

 Subject to control (Fig. 1,2), the fuel assembly 1 consists of two bundles of fuel rods 2 strung on a supporting rod and fixed to the rod using the upper 3 and lower 4 shanks (Fig. 6). A suspension 5 is attached to the upper shank, consisting of a rod 6 on which biological protection 7, a displacer 8 and a sealing plug 9 are installed in series with each other. Using the suspension 5, the fuel assembly is removed from the reactor, transferred to the holding pool for temporary storage, and started into narrow slots formed by parallel-running metal structures forming the shutter pool overlap, and suspended on them. The width of the slots is 110 mm.

 A device for monitoring 10 (Fig.1,2,3) of the fuel assembly 1 of a nuclear reactor contains a module 11 of the means for placement and fastening of the fuel assembly and module 12 of its control means. Both modules 11,12 contain supporting platforms 13,14 installed on the metalwork of 15 adjacent slotted floors 16,17 of the holding pool 18. The module 11 of the means for locating and securing the fuel assembly comprises an upright strut 21 with a fork 22 mounted on the supporting platform 13. the supporting platform 13 is placed with the possibility of rotation around its longitudinal axis of the glass 23 (Fig.7). On the upper end of the glass 23, a conical bore 24 is made under the propellant cone 8 with a diameter of 80 mm of the suspension 5 of the fuel assembly 1. Along the generatrix of the glass, a slot 25 is made under the rod 6 of the suspension of the fuel assembly 1. On the bracket 20 (Fig.6), the housing 26 is aligned with the glass 23 in the cylindrical bore of which, with the possibility of vertical movement under the action of the compression spring 27, a slider 28 is installed. On the slider 28 on the thrust bearing 29, a socket 30 is installed under the lower shank 4 of the fuel assembly 1. The socket 30 is fixed in a known manner polzushke but in such a way that it can move in the vertical direction together with polzushkoy 28 relative to the column 21 and simultaneously rotate relative to the column 21.

 On the plug 22 (Fig. 4), a slot 31 is made of a width of 45 mm under the rod 6 of the suspension assembly of the fuel assembly. The direction of the slot 31 coincides with the direction of the slit overlap 16 of the holding pool 18 and is equivalent to the slot 25 of the glass 23. On the rack 21 there is a means for overlapping the plug 22. The means for overlapping the plug are made in the form of a lever 32 pivotally mounted on the upright vertical rack 21 connected to the mechanism 33 ( Fig.5.5) of its reversal. The mechanism 33 is an electromagnet 34, a spring-loaded core 35 of which is pivotally connected to the intermediate lever 36, which in turn is pivotally connected to the lever 32. The electromagnet 34 is fixedly mounted on the rack 21.

 On the cup 23 (Fig. 7.8), a worm wheel 37 is fixed coaxially with its longitudinal axis, coupled to two worms 38 kinematically connected to each other and with a rotation drive 39 through a bevel gear pair 40. A slot 41 is made on the worm wheel 37, equivalent to coinciding with the slot 25 of the machine 23. At the lower end of the glass 23, a disk 42 is fixed, in which a slot 43 is also made, which is equivalent and coinciding with the slot 25 of the glass 23. On the disk 42 evenly around the circumference with a step exceeding the width of the slot 44 of the supporting platform 13 (direction and widths the slit 44 coincides with the slit nozzle 25), fitted with at least four bearings 45 rolling in contact with the support plate 13.

 The assembly control module 12 (Fig. 1,2) comprises two guides 46 connected to each other by means of a plate 47 located at the lower end of the guides 46. The upper ends of the guides 46 are fixed in a known manner on the supporting platform 14. A table 48 is located on the guides 46 on which the device can be installed and fixed in any known manner (any control devices 49. Table 48, using a metal tape 50 wound around the drive drum 51, moves along the guides 46. The guides and the table are placed in one plane bones, which allows you to freely bring the module 12 into the slit overlap of the exposure pool.

 The operation of the device for monitoring is as follows.

 Modules 12 and 11 are successively inserted into slotted floors 16 and 17, respectively, using the shut-off pool crane (not shown) and installed by supporting platforms 13 and 14 on the corresponding metal structures 15 of the shut-off pool ceilings 18. Modules 11.12 are verified against each other and fixed on the metal structures 15. Then, the fuel assembly 1 to be monitored is inserted into the slotted overlap 16 and into the module 11 through slots 25,31,41 and 44 using the shut-off pool crane (not shown), and sections of the suspension rod 6 are included in these slots 5 of the fuel assembly 1, the diameter of which is 45 mm. Then the fuel assembly is lowered, while its lower tail 4 comes into contact with the socket 30, which together with the creeper 28 will move down until the cone of the displacer 8 with a diameter of 80 mm comes into contact with the conical bore 24 of the glass 23. Then turning off the electromagnet 34. The core 35 rises under the action of a spring and, using the intermediate lever 36, turns the lever 32, blocking the slot 31 of the plug 22. The fuel assembly to be monitored is installed and fixed in module 11.

 On the table 48 in a known manner install and fix the control device 49, which is necessary to perform the corresponding control operation. The drive 51 is turned on and by moving the table 48 along the guides 46, a control operation is carried out along the generatrix of both bundles of fuel rods 2. Then, table 48 is lowered down, and the fuel assembly is rotated by a certain angle. To do this, turn on the drive 39 of turning the cup 23. The movement from the drive through the bevel gear is transmitted to both worms 38 and the worm wheel 37 and the cup 23 connected to them. Worms 38 most of the turn per one turn of the worm wheel are simultaneously engaged. When the slot 41 of the worm wheel approaches one of the worms, the engagement between this worm and the worm wheel will be broken, but the worm wheel will rotate due to its engagement with the second worm. The first worm with the same angular velocity will continue to rotate and will smoothly engage with the worm wheel when the slot 41 is rotated by a certain angle.

 At least three rolling bearings 45 will always be in constant contact with the support platform 13 and will perceive axial load from the weight of the fuel assembly and transfer it through the support platform 13 to the metal structure 15 of the slit overlap of the holding pool.

 Thus, the proposed design of a device for monitoring the fuel assembly of a nuclear reactor allows it to be installed in any desired location in the holding pool without adapting this holding pool to the placement of the control device. In addition, the exposure pool operators perform operations during the installation of this equipment that are not much different when they perform regular operations when installing fuel assemblies in the exposure pool. Thus, the proposed design allows to achieve the purpose of the invention.

Claims (7)

 1. A device for monitoring the fuel assembly of a nuclear reactor, comprising means for positioning and securing the fuel assembly installed in the holding pool and means for vertically moving along the fuel assembly of the carriage with control devices, characterized in that both means are made in the form of modules with supporting platforms placed in adjacent slotted floors of the holding pool and installed supporting platforms on the metal structures of these slotted floors, the module of the placement means and The fuel assembly replica comprises a fuel assembly placement and rotation unit mounted on a support platform and racks with fastening assemblies of the fuel assembly extending up and down, wherein the fuel assembly placement and rotation assembly, its upper mounting assembly and support platform are provided with vertical through slots for the fuel assembly suspension rod coinciding in direction with the slit overlap of the holding pool, and the module of the means for vertical movement of the carriage contains those installed on the supporting platform and extending into bottom two guides for the carriage with the control device, and the guides and the carriage are placed in the same plane.  2. The device according to claim 1, characterized in that the assembly and rotation unit of the fuel assembly is made in the form of a cup mounted with the possibility of rotation from the drive around its longitudinal axis, on the upper end of which a conical bore is made under the cone of the propellant of the suspension of the fuel assembly.  3. The device according to claim 2, characterized in that the worm wheel is fixed on the cup coaxially with its longitudinal axis, coupled to two worms kinematically connected to each other and with a rotation drive through a bevel gear pair, with rollers placed on the lower end of the cup, in contact with the support platform, and a slot is made on the worm wheel, equivalent to the slot of the glass.  4. The device according to claim 1, characterized in that the lower mounting assembly of the fuel assembly is made in the form of a spring-loaded socket under the lower tail of the fuel assembly, mounted for rotation and vertical movement relative to the rack.  5. The device according to claim 1, characterized in that the upper mounting assembly of the fuel assembly is made in the form of a fork mounted on the upper end of the upper rack, and means for overlapping the cuts of the fork located on the same rack.  6. The device according to p. 5, characterized in that the means for closing the slot of the plug is made in the form of a lever pivotally mounted on the upper strut connected to the mechanism of its rotation.  7. The device according to claim 6, characterized in that the mechanism for turning the lever of the fork closing means is made in the form of an electromagnet, the spring-loaded core of which is pivotally connected to the intermediate lever, pivotally connected to the fork closing lever.

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