RU2170961C2 - Fuel-element inspection and rejection line - Google Patents

Abstract

FIELD: nuclear power engineering. SUBSTANCE: line designed for use by manufacturers of fuel elements for VVER-1000 and VVER-440 reactors is provided, in addition, with at least three tilted platforms; inspection transducers are mounted on each platform in front cutters parallel to axis of piece-by-piece cutters for feeding fuel elements and under fuel element conveying facilities after each inspection facility in parallel with conveying facility axis; mounted between each pair of inspection transducers for start and finish of fuel element of reactor VVER-1000 are intermediate fuel-element start inspection transducers for reactor VVER- 440 at distance from inspection transducer to start of fuel element equal to difference in lengths of fuel elements of reactors VVER-1000 and VVER-440; both fuel-element start inspection facilities 0f VVER-1000 and VVER-440 reactors are provided with power switches. Head tilted platform is of inverted-V form in height with upper platform tilted from fuel-element output mechanism and lower one inclined to conveying facility (rolling conveyer); tilted platform for inspecting and rejecting fuel elements has same curvature and diameter as head platform; final tilted platform mounts acceptance mechanism for inspected fuel elements. EFFECT: enlarged functional capabilities of line; enlarged area of fuel-element storages. 4 cl, 6 dwg

Description

 The invention relates to nuclear energy and may find application in enterprises manufacturing fuel elements (TVEL) for nuclear water-cooled power reactors.

 It is known that fuel elements (TVELS) are the most responsible and most stressed structures of the active zone of a modern nuclear power reactor, therefore the most stringent requirements are imposed on their manufacture and control.

 It is known that the rod fuel rod of a thermal neutron reactor consists of a cylindrical metal zirconium alloy with 1% niobium shell, inside which nuclear fuel is placed in the form of dioxide enriched in 235 uranium, end parts necessary for sealing the shell, a retainer that ensures the placement of nuclear fuel in tablets in the required position (see Development, production and operation of fuel elements of power reactors. Book 1, F.G. Reshetnikov, Yu.K. Bibilashvili, I.S. Golovnin. M .: Energoatomizdat, 1995, p. 45) For water of the VVER-1000 coke reactor, the length of the rod fuel rod is 3837 mm and a diameter of 9.1 mm, while for VVER-440 the length is ≈ 2500 mm and a diameter of 9.1 mm. Due to different lengths, these fuel elements differ in the length of the fuel column, the length of the compensation volume from the tablet to the plug and cannot be controlled on one line, for example, VVER-440 fuel elements on the VVER-1000 line and vice versa without constructive restructuring of the line, i.e. one line was required for VVER-440 fuel elements, and another line for VVER-1000 fuel elements.

 The closest in technical essence and the achieved effect is a line for monitoring and sorting out fuel elements, containing a fuel rod delivery mechanism, consisting of two inclined platforms with a bias towards the means of conducting fuel elements for control operations in the form of a live roll, cut-off devices for piece-wise delivery of fuel elements to the live rolls placed along the live roll inclined platforms of storage containers with input windows of defective fuel elements, a control system and a coaxial roller table located in the technological sequences between inclined platforms of means for detecting defects in fuel tablets, column length of fuel tablets, the presence of clamps, total gaps between fuel tablets with a gamma radiation source and photosensors, placed after the second inclined platform of means for measuring a fuel element in diameter and curvature, scaffolds and ejectors fuel elements interlocked with the sensor of the corresponding measuring instrument (see USSR author's certificate N 1117088 according to the application 3502508 \ 28-12 (161085) of 10.22.82, Mkl B 07 C 5/04).

 The disadvantage of the line is that the control and sorting of fuel elements on it can be carried out either for the VVER-1000 reactor or for the VVER-440 reactor, i.e. it was required to have two lines, otherwise, due to the different lengths of the fuel rods, they would not be conducted through the cutoffs along the inclined platform.

 One of the conditions for posting a fuel rod on an inclined platform is that each actuation of the block-by-piece output cutoffs is preceded by the mandatory presence of a fuel rod above two sensors of the beginning and end of the fuel rod, which give a signal to trigger the cutter. For this reason, the fuel rods of the VVER-440 reactor, because of its length shorter than the length of the fuel rods of the VVER-1000 reactor, will not be routed through the shut-off blockers on the control line of the VVER-1000 fuel rods. The line is not provided with drives in the form of inclined platforms for carrying out production and technical control, control of quality control and picking a batch.

 An object of the invention is to expand the technological capabilities of the line, which allows for the monitoring and sorting of both fuel elements of the VVER-1000 reactor and fuel elements of the VVER-440 reactor, as well as the expansion of the area of the drives.

 This technical problem is solved in that in the line for monitoring and sorting out the fuel elements, comprising a mechanism for issuing fuel elements, consisting of two inclined platforms with a slope towards the means for conducting the fuel elements for monitoring and sorting operations in the form of a rolling table, cut-off devices for the piece-wise delivery of fuel elements to the roller table located along inclined platforms, storage containers with entry windows for defective fuel elements, the control system and the means for detecting internal defects of fuel pellets, the column length of fuel pellets, the presence of clamps, the total gaps between the fuel pellets with a gamma radiation source and photosensors in the technological sequence between the inclined platforms and after the second inclined platform of the means for controlling the fuel element in diameter and curvature , distributors and dumpers of fuel elements interlocked with control sensors of the corresponding measuring and control means According to the invention, the line is equipped with at least three additional inclined platforms, control sensors are placed on each inclined platform in front of the cut-off devices parallel to the axis of the cut-off devices for the fuel elements and under the means of the fuel element wiring after each control parallel to the wiring axis, between each pair of start control sensors and the end of the fuel element for a nuclear reactor VVER-1000 at a distance from the sensor control the beginning of the fuel element for nuclear about the VVER-1000 reactor, equal to the difference between the length of the VVER-1000 fuel element and the length of the fuel element for the VVER-440 nuclear reactor, intermediate sensors for controlling the beginning of the fuel element for the VVER-440 nuclear reactor are placed, both sensors for controlling the beginning of the fuel element for the nuclear reactor VVER-1000 and the beginning of the fuel element for the VVER-440 nuclear reactor are equipped with circuit breakers.

 Other differences are the execution of the head inclined platform gable, in height with the direction of the slope of the upper platform from the mechanism for issuing fuel elements, and the lower one with a slope, on the contrary, to the wiring means - the roller table.

 The execution of the inclined site for sorting the fuel elements in diameter and curvature is similar to the head platform, i.e. gable and the placement of the receiving mechanism of the controlled fuel elements on the final inclined site.

 Such a design of a line for monitoring and sorting out fuel elements will allow expanding the technological capabilities of the line and expanding the storage area by supplying the line with an additional three inclined platforms for running the gable head platform and placing it on all platforms between each pair of sensor sensors at a distance from the control sensor for the end of the VVER-1000 fuel element equal to the difference in the lengths of the fuel elements of the VVER-1000 and VVER-440 and supplying them with switches from the electric network, allowing When the intermediate sensor is turned off, control the VVER-1000 fuel elements, and when the end sensor of the VVER-1000 fuel element is disconnected, control the VVER-440 fuel elements.

The drawings show the line of control and sorting of fuel elements, where:
in FIG. 1 - general view of the line;
in FIG. 2 - view from the side of the head platform;
in FIG. 3 is a view from the side of an inclined platform for sorting out internal defects;
in FIG. 4 is a view from the side of an inclined site for sorting a fuel rod in diameter and curvature;
in FIG. 5 is a side view of the end inclined platform;
in FIG. 6 is a diagram of sensor switches.

 The line for monitoring and sorting out the fuel elements, contains a mechanism for issuing 1 fuel elements 2 and consists of inclined platforms 3, 4 with a slope towards the wiring means 5 of the fuel elements 2 for monitoring and sorting in the form of a rolling table, cut-offs 6 of the piece-wise delivery of fuel elements 2 to the roller table 5, placed along inclined platforms 3, 4 of storage containers 7 with windows 8 for introducing defective fuel elements 2, a control system and coaxial to the rolling table 5, placed in the process between the inclined platforms of the means 9 for detecting defects in fuel pellets, the presence of fixatives, the total gaps between the fuel tablets with a gamma radiation source and photosensors (not shown), placed after the second inclined platform 4 of the means 10 for monitoring the fuel element 2 in diameter and curvature, reamers 11 and ejectors 12 of the fuel element 2, interlocked with sensors 13 control the beginning and sensors 14 of the end of the fuel element 2 of the corresponding measuring means and to ontrol.

The line is equipped with at least three additional inclined platforms 15, 16, 17, control sensors 13, 14 are placed on each inclined platform 3, 4, 15, 16, 17 in front of the cut-off devices 6 parallel to the axis of the cut-off devices for the piece of fuel elements 2 and under the means 5 of the wiring of the fuel element 2 after each control means parallel to the axis of the wiring, between each pair of sensors 13, 14 of the end and the beginning of the fuel element for the VVER-1000 nuclear reactor at a distance from the sensor 14 for controlling the beginning of the fuel element for the nuclei of a VVER-1000 reactor equal to the difference ΔL = LL ₁ between the long L of the VVER-1000 fuel element and the L ₁ length _{of the} fuel element for the VVER-440 nuclear reactor, intermediate sensors 18 for controlling the start of the fuel element for the VVER-440 nuclear reactor are placed, both of which the control sensor 14, 18 of the beginning of the fuel element for the VVER-1000 nuclear reactor and the beginning of the fuel element for the VVER-440 nuclear reactor are equipped with switches 19, 20 for disconnecting the sensors 14, 18 from the electric network.

 The head platform 3 is gable, where the upper platform 3 has a bias from the mechanism 1 for issuing fuel elements, and the lower platform 21 has a bias towards the roller table 5.

 Similarly made inclined platform 15, i.e. gable with a lower inclined platform 22. The final inclined platform 17 is equipped with a mechanism for receiving controlled fuel elements 2 and is made similar to mechanism 1 with the platform inclined towards the receiving mechanism.

 The line of control and sorting of fuel elements works as follows.

 The fuel elements 2 from the dispensing mechanism 1 slide onto an inclined platform 3 to the cutoffs 6, where they undergo production and technical control in appearance, i.e. nicks, scratches, abrasions, etc. are detected, and are separated from the main stream. When monitoring the fuel elements 2 of the VVER-1000 with the switch 20, the sensor 18 is disconnected from the electric network, and the sensors 13, 14 are connected to the electric network when working with the fuel elements 2 of the VVER-440; the sensor 14 is disconnected from the electric network by the switch 19, and in operation connected to the electric network are sensors 13, 18. When the fuel element 2 enters the range of two sensors, i.e. when a fuel element (fuel element) is located above a pair of sensors, a signal is sent from the latter to trigger the cut-off device 6 for the single-piece delivery of fuel elements 2 and the fuel element 2 rolls down to the lower inclined platform 21 to the cut-off devices 6 located on the lower platform, where two sensors 13 , 14 for VVER-1000 fuel elements, or 13, 18 sensors for TVEL-440 from the sensors, a signal is sent to trigger the cut-off element for the fuel elements separately. After the cut-off device for the single-piece delivery of fuel elements by means of wiring - the live table 5 is transferred to the control means 9, where, moving the live table 5, the defects of the fuel pellets inside the fuel rod 2 are checked, the length of the stack of fuel pellets, the presence of clamps, and the total gap between the fuel pellets are determined. After the control of the fuel rod 2, the roller table 5 moves over the sensors, similarly placed, as on the inclined platform 3, i.e. when monitoring the VVER-1000 fuel rod, sensors 13, 14 are turned on and the sensor 18 is turned off, and when monitoring the VVER-440 fuel rod, the sensors 13, 18 are turned on and the sensor 14 is turned off. If a defect is detected in the control means 9, a signal is received from the sensors to remove the defective fuel rod from the total flow and to the operation of the reamers 11, which dump the defective fuel elements through the window 8 into the storage container 7 of the defective fuel elements 2, and the suitable fuel element 2 with the help of the ejector 12 raises the fuel element 2 to the inclined platform 4 to the cutoffs 6 and to the live roll 5, along which the fuel element 2 moves through the facility 10 control diameter and curvature. If the fuel rod 2 is found to be defective in diameter or curvature, the last one with the reamer 11 discards the fuel rod 2 through the window into the container 7, and the suitable fuel rod 2 with the roller table 5 with the ejector 12 is dumped onto the inclined platform 15 to the cutters 6, from where it is piece by piece to the lower inclined platform 22 to the cutters 6 and piece by piece on the roller table 5, which transports the fuel rod 2 to the inclined platform 16, where a batch is formed and the quality control department is checked for the appearance of the fuel rod. The formed batch of TVEL 2 is conveyed by the live roll 2 to the final inclined platform 17, where the VVER-1000 or VVER-440 TVEL batches are formed using sensors 13, 14 or 13, 18 and loaded into a receiving mechanism made similar to mechanism 1 (transport cassette).

 Due to the presence of a sufficient number of drives, the line can operate according to a given program in automatic mode, and the proposed placement of sensors will allow monitoring of fuel rods for both VVER-1000 and VVER-440 on one line instead of the required two.

Claims (4)

 1. The line of control and sorting of fuel elements, containing a mechanism for issuing fuel elements, consisting of two inclined platforms with a slope towards the means of posting fuel elements for operations of control and sorting in the form of a rolling table, cut-off devices for the piece of fuel elements on the rolling table placed along inclined platforms, storage containers with entry windows for defective fuel elements, a control system and a coaxial roller conveyor placed in a technological sequence between the inclined platforms of the means for detecting internal defects of the fuel tablets, the length of the column of fuel tablets, the presence of clamps, the total gaps between the fuel tablets with a gamma radiation source and photosensors and after the second inclined platform of the means for controlling the fuel element in diameter and curvature, strippers and ejectors fuel elements interlocked with control sensors of the corresponding measuring and control means, characterized in that the line is equipped with at least measure, in addition to three inclined platforms, control sensors are placed on each inclined platform in front of the cutters parallel to the axis of the cut-off units for the fuel elements and under the means of wiring the fuel element after each control parallel to the wiring axis between each pair of sensors for controlling the beginning and end of the fuel element for a nuclear reactor VVER-1000 at a distance from the sensor for monitoring the start of a fuel element for a VVER-1000 nuclear reactor equal to the difference between of another VVER-1000 fuel element and the length of the fuel element for the VVER-440 nuclear reactor, intermediate sensors for controlling the start of the fuel element for the VVER-440 nuclear reactor are placed, both sensors for controlling the start of the fuel element for the VVER-1000 nuclear reactor and the start of the fuel element for the nuclear VVER-440 reactors are equipped with circuit breakers.  2. The line according to claim 1, characterized in that the head inclined platform is gable in height with the direction of the slope of the upper platform from the mechanism for issuing fuel elements, and the lower inclined platform with a slope, on the contrary, to the wiring-rolling table.  3. The line according to claims 1 and 2, characterized in that the inclined platform for monitoring and sorting the fuel elements in diameter and curvature is made similar to the head inclined platform.  4. The line according to claim 1, characterized in that on the final inclined platform there is a mechanism for receiving controlled fuel elements.

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