METHOD TO PRESSURIZE SIC FUEL CLADDING TUBE BEFORE END PLUG SEALING BY PRESSURIZATION PUSHING SPRING LOADED END PLUG

Abstract

An apparatus and method for pressurizing SiC clad rods of a nuclear core component. A lower end of the rod is sealed with a lower end plug and an upper end of the rod is sealed between the cladding and an external piece of an upper end plug that has a through opening through which a separate internal piece of the upper end plug extends. The internal piece of the upper end plug is initially moveable within the through opening between an upper position that forms a gas tight seal and a lower position that forms a gaseous path through the through opening. The rod is placed in a pressure chamber pressurized to a desired pressure. When the pressure is reduced within the pressure chamber the internal pressure in the rod biases the internal piece of the upper end plug in the upper sealed position.

Claims

1.-10. (canceled)

11. The method of claim 1 including the step of mechanically attaching the upper end plug external piece to the cladding.

12. A nuclear core component having a tubular cladding with an upper and lower end respectively sealed by an upper end plug and a lower end plug, a lower portion of an interior of the cladding housing an active element with a spring extending between the upper end plug and the active element to bias the active element toward the lower end plug, the upper end plug comprising: an upper end plug external piece and an upper end plug internal piece, the upper end plug internal piece configured to slide within a through opening in the upper end plug external piece and have a lower end that biases the spring towards the active element when the upper end plug forms a gas tight seal at an interface of the cladding and the upper end plug, at least partially closing off the upper end of the cladding, the through opening and the upper end plug internal piece configured so an upper portion of the upper end plug internal piece fits within the through opening but cannot pass through and out of an upper portion of the through opening and the spring is configured to support the upper end plug internal piece within the through opening, the upper end plug internal piece and the through opening forming a substantially gas tight seal at an upper limit of travel of the upper end plug internal piece through the through opening and a gas communication path at a point below the upper limit of travel, the upper end plug internal piece being structured to be permanently sealed to the upper end plug external piece after an interior of the cladding is pressurized.

13. The nuclear core component of claim 12 wherein the nuclear core component is a fuel rod.

14. The nuclear core component of claim 12 wherein the nuclear core component is a control rod.

15. The nuclear core component of claim 12 wherein the upper end plug external piece through opening has a frustoconical wall and an interfacing wall of the upper end plug internal piece has a frustoconical contour with a smallest diameter of the frustoconical contour larger than a smallest diameter of the frustoconical wall.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] A further understanding of the invention can be gained from the following description of the preferred embodiments when read in conjunction with the accompanying drawings in which:

[0012] FIG. 1 is a longitudinal sectional view of a prior art fuel rod containing a stack of fuel pellets, a holding spring and end caps;

[0013] FIG. 2 is a longitudinal sectional view of an upper section of a nuclear fuel element formed in accordance with this invention, showing the upper most fuel pellet, the plenum spring and an upper end plug comprising an external piece with a through opening closed off by an internal piece; and

[0014] FIG. 3 is a longitudinal sectional view of a fuel element formed in accordance with this invention as shown in FIG. 2, with the end plugs sealed to the cladding with a clamp.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0015] In many conventional reactors the standard fuel cladding is made of various zirconium alloys that act as the fission product barrier and prevent release of radioactive materials to the environment. Though zirconium alloys have desirable neutronic properties and, in the past, adequate strength and oxidation resistance in coolant at normal operating conditions, these types of cladding rapidly oxidize at beyond design basis temperatures above 1,200 degree C. Because the zirconium steam reaction is exothermic and rapid, and hydrogen is produced during this reaction, which can be explosive, new materials such as silicon carbide (SiC) have been proposed and experimentally tested to replace the zirconium alloy cladding. The SiC materials have much better oxidation resistance than zirconium alloys at temperatures above 1,200 degree C. Advanced SiC-based materials are no longer in the complete experimental stage and can vastly improve the fuel failure temperature by >600 degrees C., compared to zirconium alloy cladding—which in itself is extremely beneficial for safe reactor operation. This application describes a method and apparatus for pressurizing such a ceramic cladding with ceramic end caps. Though the preferred embodiment will be described with an application to a nuclear fuel rod, it should be appreciated that the method and apparatus disclosed herein and claimed hereafter are equally applicable to control rods.

[0016] For the purpose of comparison, FIG. 1 shows a longitudinal cross-section of a conventional fuel rod. As shown in FIG. 1, the fuel rod cladding 12 is typically in the shape of an elongated tube having a cavity formed therein and two opposing open ends. The thickness of the tube wall can vary. In certain embodiments, the tube wall thickness is typically from about 500 to about 1,000 microns. The cavity has fuel pellets 10 contained therein and typically a hold-down device, such as a spring 14, to maintain the configuration, e.g., a stack, of the fuel pellets. A sealing mechanism, such as the end caps 16, is typically positioned at or in each open end of the cladding 12 to provide a seal and prevent the coolant circulating in the core from entering the cavity of fuel rod cladding. Typically, the plenum area 18 occupied by the spring 14 is pressurized with a thermally conductive gas such as helium to 400 to 500 psi.

[0017] FIG. 2 shows a longitudinal cross-section of the upper portion of a fuel rod, modified in accordance with this invention, showing a ceramic cladding 12, such as SiC, housing an upper most fuel pellet 10, and plenum spring 14, with the cladding 12 closed at an upper end by an upper end plug 20. Typically, to seal the SiC cladding to the end plug one of a number of processes can be employed such as a high temperature polymer infiltration pyrolysis (PIP) process, chemical vapor infiltration (CVI), chemical vapor deposition (CVD), hot isostatic press (HIP) or spark plasma sintering (SPS). These processes are typically performed above 1,000° C. and conducted in a vacuum with an exception of HIP, which may permit a helium and/or an inert gas environment. In order to pressurize the SiC clad rods with a high thermal conductivity gas, such as helium, a specially designed end plug is used to seal off the upper portion of the cladding. The upper end plug 20 is comprised of two separable parts, an upper end plug external piece 22 that around its periphery forms the seal with the cladding 12 and an upper end plug internal piece 24, which rides within a through opening 26 in the upper end plug external piece 22. In addition to chemically bonding the external piece 22 to the cladding 12, the external piece 22 can also be mechanically joined to the cladding 12 with a bolt/screw type of coupling as schematically shown in FIG. 2 by reference character 32. The term “through opening” means that the opening extends completely through the upper end plug external piece 22 exposing the plenum to the external environment. In one embodiment, the interior wall of the through opening has a frustoconical profile and the opposing exterior wall of the upper end plug internal piece has a matching frustoconical contour with the corresponding diameters of the profile and contour being substantially equal or the contours corresponding diameters being slightly larger than those of the profile. It should be appreciated that other interfacing profiles and contours can also be used so long as the interfacing walls of the through opening 26 and the upper end plug internal piece 24 prevent the upper end plug internal piece from traveling completely through and out of the through opening; at a limit of upward travel of the upper end plug internal piece 24 in the through opening 26, the interface of the profile and contour forms a gas tight seal; and at a point below the limit of upward travel the interface of the profile and contour forms a gaseous pathway through the through opening, exposing the internal plenum to the environment outside the upper end plug 20. It is perfectly acceptable for the upper end plug internal piece 24 to protrude partially through the through opening 26 to extend beyond the upper end plug external piece 22.

[0018] To pressurize the rods, the SiC fuel rods are prepared in a way similar to the current zirconium fuel rods. The SiC lower end plug is held against the cladding, the fuel pellets 10 are loaded, the spring 14 and the upper end plug internal piece 24 are inserted into the plenum and the upper end plug external piece 22 is pressed over the upper end of the cladding to form a gas tight seal. The spring 14 supports the upper end plug internal piece 24 in the through opening 26 and the spring 14 is, preferably, attached to the underside of the upper end plug internal piece 24. The upper and lower end plugs can either be pressed in place to form the gas tight seal by mechanical means such as a hydraulic or mechanical clamp, such as the clamp 28 shown in FIG. 3 or they can be permanently sealed using a chemical process such as PIP, CVI, CVD, and/or SPS.

[0019] The fully assembled rod is placed or the end plug segment is placed within a pressure chamber 30 and a thermally conductive gas, such as helium is introduced into the chamber and the pressure is increased to a level in the order of 500 psi. A vacuum may be applied to the interior of the cladding before pressurization. The pressure of the gas in the pressure chamber acts upon the upper end plug internal piece 24 compressing the spring 14 and filling the plenum. Alternately, the internal piece 24 can be pushed by an external force to open up the gap between the external piece 22 and the internal piece 24. The inside of the cladding will automatically be filled with the gas at the same pressure as the pressure chamber. The pressure in the pressure chamber is then reduced to approximately atmospheric pressure after a selected period of time and the pressure inside the cladding is maintained at the level it was raised to by the mechanical seal between the upper end plug external piece 24 and the through opening 26. The higher pressure in the plenum forces the contour of the wall of the upper end plug internal piece 24 against the contour of the through opening 26 to maintain that seal. Preferably, a binding agent such as SiC paste or graphite is inserted at the interface of the through opening and the upper end plug internal piece during the assembly of the rod to improve the seal. After the pressurization is complete the pressurized rod can be removed to a vacuum chamber where the interface of the upper end plug internal piece and the through opening, and the end plugs if not previously permanently sealed, can be permanently sealed.

[0020] While specific embodiments of the invention have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular embodiments disclosed are meant to be illustrative only and not limiting as to the scope of the invention which is to be given the full breadth of the appended claims and any and all equivalents thereof.