In a typical nuclear reactor, the reactor core generally includes a number of fuel assemblies, each of which is made up of an array of fuel rods. Each fuel rod includes a tubular cladding sealed by upper and lower end caps or plugs. The nuclear reactor core is made up of an array of such fuel assemblies.
Generally, the present disclosure provides an end cap for a nuclear fuel rod and methods of welding the end cap to a cladding tube of a fuel rod to yield a weld joint between the end cap and the cladding tube. The end cap includes an angled recess in the end that abuts the cladding tube.
One particular implementation described herein is an end cap for a nuclear fuel rod. The end cap has a tip end, an opposite abutment end for attaching to a cladding tube, and an outer surface. The abutment end has an angled recess therein and an annular shoulder defined by the outer surface of the end cap and by an outer wall of the recess. The outer wall of the angled recess forms an angle no less than 5 degrees with respect to the outer surface.
Another particular implementation described herein is another end cap for a nuclear fuel rod. The end cap has an abutment end for attaching to a cladding tube. The abutment end has an annular shoulder and an angled recess having an outer wall. The outer wall forms an angle no less than 95 degrees with respect to the annular shoulder.
Yet another particular implementation described herein is a fuel rod, comprising a cladding tube and an end cap. The end cap has an outer surface, an abutment end with an angled recess therein and an annular shoulder defined by the outer surface and an outer wall of the recess. The annular shoulder may be at least 0.05 mm wider than a wall thickness of the cladding tube.
Yet another particular implementation described herein is a method of forming a fuel rod from an end cap and a cladding tube. The method includes providing an end cap having an angled recess in an end, and attaching an end cap electrode to the end cap, and providing a cladding tube and attaching a cladding electrode thereto. The end cap and cladding tube are abutted, and a current is applied from the end cap electrode to the cladding electrode while applying a compressive force to the end cap and the cladding tube. A portion of the end cap and/or the cladding tube plastically deforms to form a weld joint.
The disclosure also generally provides methods of welding that include monitoring one or more weld parameters of the welding operation. The one or more weld parameters can include weld current, weld force, cladding tube extension and weld duration. Classifying the weld joint as satisfying a weld quality condition can be done if the welding operation is performed with one or more of the weld parameters satisfying a predetermined weld parameter condition.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. These and various other features and advantages will be apparent from a reading of the following detailed description.
The described technology is best understood from the following Detailed Description describing various implementations read in connection with the accompanying drawings.
One particular type of nuclear reactor, traveling wave reactors (TWR), may include a sodium-cooled fast reactor designed for breed and burn equilibrium with a long fuel cycle without refueling. A TWR fuel assembly can be based on metallic fuel in stainless steel cladding, for example HT9 (Fe-12Cr-1MoV). Manufacturing of these fuel rods can include welding end caps to the top and bottom of the cladding tube, such as, for example, by resistance pressure welding (RPW), also referred to a pressure resistance welding (PRW).
The RPW process is capable of producing acceptable welds over wide parameter ranges for a variety of materials, including HT9. The RPW process can produce welds that are stronger than the cladding wall and that be used successfully for HT9 cladding tube closure welds in fuel rod fabrication, including to HT9 end caps.
As indicated above, provided herein is an end cap for a nuclear fuel rod and methods of welding the end cap to a cladding tube, particularly an HT9 end cap to an HT9 cladding tube. Also provided herein are welding techniques and techniques for classifying fuel rod cladding tube welds.
In the following description, reference is made to the accompanying drawing that forms a part hereof and in which are shown by way of illustration at least one specific implementation. The following description provides additional specific implementations. It is to be understood that other implementations are contemplated and may be made without departing from the scope or spirit of the present disclosure. The following detailed description, therefore, is not to be taken in a limiting sense. While the present disclosure is not so limited, an appreciation of various aspects of the disclosure will be gained through a discussion of the examples provided below.
A nuclear reactor core 100, diagrammatically shown in
A single fuel rod 104 is also diagrammatically shown in
The end caps 110, 112 can be girth or butt welded to the opposite ends of the cladding tube 106, for example by fusion welding or solid state welding. Resistance welding, e.g., resistance pressure welding (RPW) or pressure resistance welding (PRW), of the end caps, butted against the tube, can also be done to seal the rod 104. In this approach, a high current is passed through the cladding 106 and the end cap 110 or 112, as they are held under a compressive load. Resistance at the interface between the end cap 110, 112 and the cladding tube 106 generates localized heating resulting in melting of a portion of the material forming the end cap 110, 112 and/or the cladding tube 106, and hence forming a bond.
While resistance welding has many desirable attributes, including a weld bond line that is stronger than the cladding tube itself, the process has some shortcomings. For example, non-destructive weld examination is generally not feasible. Bond quality can also be susceptible to some contaminants, in some cases, with no means of detection. Weld upset, or flash, typically must be mechanically removed or suppressed in a post-weld process that complicates the processing.
However, disclosed herein are weld parameters developed to provide a range of weld parameters, including currents, over which cladding tubes 106 could be successfully and consistently joined with the end caps 110, 112. The resulting resistance welds meet non-destructive and destructive examination requirements.
In this particular implementation, the cladding tube 210 has a cylindrical wall 212 with a thickness T and a terminal end 214. The end 214 has a surface area based on the thickness T of the wall 212 and the inner diameter and the outer diameter of the wall 212.
Particular examples suitable for the cladding tube 210 have the dimensions provided in Table 1.
The end cap 220, which in this implementation is generally conical with a cylindrical base extension, has a tip end 222 and a circular base 223 with an end surface 224 configured to abut the wall 212 of the cladding tube 210. The base 223 has an exterior surface with an outer diameter essentially the same as the outer diameter of the wall 212 of the cladding tube 210.
Inward from the exterior surface of the base 223, present in the abutment end surface 224, is a recess, particularly an annular channel or groove 225 that forms an angled undercut. As seen in
The angled annular groove 225 also has a radial width or thickness between the outer wall 227 and the inner wall 229, when measured at the end surface 224, of at least 0.5 mm. In some implementations, the angled annular groove 225 has a width of 0.5-4 mm, in other implementations 1-2 mm. One exemplary width is 1.37 mm.
Referring now to
In accordance with the paragraph above and as described further below, the invention presented here includes an end cap having an angled recess, such as an angled groove, the outer wall angle defined by the outer wall of the recess being no less than 5 degrees in respect to the outer wall of the end cap proximate the abutment end of the end cap, and/or the outer wall of the recess being no less than 95 degrees in respect to the abutment end of the end cap. Although angles of less than 5 degrees and/or 95 degrees may be disclosed and enabled herein, Applicant specifically disclaims rights to an end cap that has both an angled recess with an outer wall having an angle less than 5 degrees with respect to the exterior wall and an outer wall having an angle less than 95 degrees with respect to the abutment end.
As seen in
Depending on the technology used to create the angled groove 225 in the end cap 220, the groove 225 may have a rounded terminal end; the portion of the depth of the groove 225, without the rounded terminal end, is depth D, seen in
In another implementation, shown in
The inner wall 229 of the angled annular groove 225 may be parallel to the outer wall 227 or may be angled in either direction.
As seen in
An alternate implementation of an end cap is illustrated in
The end cap 420 has a tip end 422 and a base 423 with an end surface 424 configured to abut the wall of a cladding tube. Inward from the outer surface of the base 423, present in the abutment end surface 424, is a recess 425 formed by an angled or sloped wall 427 that forms an angled undercut. An annular shoulder area 428 is present on, in, or otherwise is the abutment end surface 424 between the exterior surface of the cap 420 and the angled wall 427 forming the angled recess 425.
The various dimensions and features of the end cap 420 are similar to the dimensions and features discussed above in respect to the end cap 220.
It is noted that although the end caps 220, 420 are illustrated as generically conical with a cylindrical base and a rounded tip at the conical portion, the end caps 220, 420 may have any shape or structure, such as a domed end, a flat end, entire tapered, or entire conical, or an intricate design.
During welding (e.g., PRW or RPW), an electrode is placed on each of the cladding tube and the end cap. The cladding tube and the end cap are held in abutting engagement and a high current is passed across the parts. Resistance, due to the material (e.g., HT9), generates localized heating resulting in a bond between the two parts.
In
To better control the upset and obtain consistency across multiple fuel rods, an end cap as described above in
By including an annular shoulder (e.g., annular shoulder 228, 428), the current during the welding process is localized in a smaller annular area and thus within a smaller volume of material. When no annular shoulder is present, in some implementations, much higher current is needed to obtain an acceptable weld joint. A higher current used with no annular shoulder can result in localized melting of the material and/or undesirable metal expulsion from the weld area. Having the annular shoulder decreases and limits the amount of material from the end cap that must be heated and deformed in order to create a good joint with the cladding tube.
Additionally, the undercut area adjacent to the annular shoulder (e.g., the angled groove 225 or the angled recess 425) accommodates any undesired metal expulsion from the weld area by providing a volume into which the material can flow. The sloped or angled wall that forms the annular shoulder (e.g., outer wall 227 of the angled groove 225, or wall 427 of the angled recess 425) may direct the flow of any excess material away from the weld joint. In other words, an angled or sloped wall could facilitate the flow of molten material away from the weld area.
In operation 602 an end cap is provided; the end cap includes an angled annular groove formed by a sloped or angled outer wall. In an alternate operation, an end cap having an angled center recess is provided. In either operation, the end cap has an annular shoulder and may be formed from HT9. An electrode is attached to the end cap in operation 603. In operation 604 a cladding tube is provided, and in operation 605 an electrode is attached to the cladding tube. The cladding tube may be formed from HT9.
In operation 606 the end cap and cladding tube are abutted. A weld current is applied across the end cap and the cladding tube for a predetermined time, via the electrodes, in operation 608 while simultaneously applying a compressive weld force. A portion of either or both the end cap and the cladding tube plastically deforms to form a weld joint in operation 610.
If one or more of the weld parameters such as weld current, weld force, cladding tube extension and weld duration are within a predetermined parameter condition, the weld joint satisfies a weld quality condition
Returning to
Various welding parameters affect the weld joint between a cladding tube and an end cap, particularly when both the cladding tube and end cap are HT9. Several resistance welding parameters, including current, tube wall thickness and/or area, cladding tube extension distance, weld force of the end cap electrode, weld current, and weld duration were developed over which cladding tubes could be successfully and consistently joined with an end cap.
Resistance pressure welding of HT9 samples typically results in a quality weld joint between the end cap and the cladding tube. If the weld current or weld force is too low, the end cap may not properly bond to the cladding tube. If too much weld force or too high of a weld current is used, then fusion of the joint would occur with significant expulsion of metal (upset), and localized melting may occur.
After welding, room temperature burst testing may be performed to test the weld durability and determine the failure location of a sample. Room temperature burst testing is a metric for determining weld quality. If rupture of the sample occurs in the cladding wall, the sample is a successful burst test. If rupture of the sample occurs in the weld joint or heat affected zone, then the sample fails burst testing.
Table 2 shows four different weld input parameters for RPW, their corresponding effects on measured outputs, and examples of destructive test results used to examine weld quality.
Of the four input parameters in Table 2, weld quality is most sensitive to the weld current. Performing a current sweep establishes the relationship between current, displacement, and room temperature burst test performance. Current ranges may be selected based on visual appearance and burst test performance. The process extremes may be evaluated during the current sweep. Minimum current samples are expected to fail room temperature burst tests, as the current is insufficient to provide for adequate bonding. High current samples may exhibit melting, metal expulsion, and other potentially detrimental conditions. While high current samples typically produce a thick bond line, the amount of metal expulsion (upset) may produce a significantly larger outer diameter, and therefore may not be desirable for the weld conditions.
Ten samples were prepared by RPW for each of the four cladding tube samples (made from HT9) from Table 1 for a current sweep test. The cladding tubes were welded to an end cap (made from HT9) as illustrated in
Samples that pass burst testing had a thick weld joint between the cladding and the end cap.
Weld displacement is a measure of the change in position of the end cap electrode before and after welding; this is shown schematically in
The results for the current sweep in the weld development produced a trend that can be used for predictive purposes of weld performance.
First, changing cladding tube dimensions will result in a different cross section area that will subsequently require a different set of weld parameters for successful joining of the end cap to the cladding tube. Based on the minimum current required for a successful burst test for each of the cladding designations, a correlation was developed for current as a function of the weld cross section area; see
Second, rather than performing destructive or non-destructive analyses to verify weld quality, examination of the post-weld conditions is a quick and easy check to determine the quality of a weld.
The results of the testing showed that weld current and weld displacement are the primary parameters affecting weld quality. A linear relationship exists between weld current and weld displacement, with weld current a defined input parameter and weld displacement a measured output value based on the weld conditions. Burst test performance can be accurately predicted based on weld current and weld displacement.
Various implementations, such as fuel rod end caps, methods of welding, and methods of analyzing welds, have been described above.
Each and any of the end caps described above and claimed below can be welded, such as by resistance pressure welding or pressure resistance welding, to a cladding tube to form a fuel rod.
For example, described above is a method comprising resistance pressure welding a Fe-12Cr-1MoV (HT9) end cap of a nuclear fuel rod to a Fe-12Cr-1MoV (HT9) cladding tube of the nuclear fuel rod to yield a weld joint between the end cap and the cladding tube. The method may include monitoring one or more weld parameters of the resistance pressure welding operation, the one or more weld parameters including at least one of weld current, weld force, cladding tube extension and weld duration; and classifying the weld joint as satisfying a weld quality condition if the resistance pressure welding operation is performed with one or more of the weld parameters satisfying a predetermined weld parameter condition. Additionally or alternately, the method may include monitoring at least four weld parameters including weld current, weld force, tube extension and weld duration; and classifying the weld joint as satisfying a weld quality condition if the resistance pressure welding operation is performed with each of monitored weld parameters satisfying an individual predetermined weld parameter condition. The weld current can be monitored by measuring the weld current, the weld force can be monitored by measuring the weld displacement, the tube extension can be monitored by measuring the upset dimension, and/or the weld duration can be monitored by visual appearance.
As another example, described above is a resistance pressure welding system comprising an end cap electrode coupled to a weld transformer and configured to secure to an end cap of a nuclear fuel rod, the end cap being formed of Fe-12Cr-1MoV (HT9) material, and a cladding electrode coupled to the weld transformer and configured to secure to a cladding tube of the nuclear fuel rod, the cladding tube being formed of Fe-12Cr-1MoV (HT9) material, the end cap electrode and cladding electrode being further configured to resistance pressure weld the end cap to the cladding tube with an electrical current provided by a power supply through the weld transformer.
The above specification provides a complete description of the structure and use of exemplary implementations of the invention. The above description provides specific implementations. Features and/or elements may be interchanged among the various implementations. It is to be understood that other implementations are contemplated and may be made without departing from the scope or spirit of the present disclosure. The above detailed description, therefore, is not to be taken in a limiting sense. While the present disclosure is not so limited, an appreciation of various aspects of the disclosure will be gained through a discussion of the examples provided.
Unless otherwise indicated, all numbers expressing feature sizes, amounts, and physical properties are to be understood as being modified by the term “about.” Accordingly, unless indicated to the contrary, any numerical parameters set forth are approximations that can vary depending upon the desired properties sought to be obtained by those skilled in the art utilizing the teachings disclosed herein.
As used herein, the singular forms “a”, “an”, and “the” encompass implementations having plural referents, unless the content clearly dictates otherwise. As used in this specification and the appended claims, the term “or” is generally employed in its sense including “and/or” unless the content clearly dictates otherwise.
Spatially related terms, including but not limited to, “bottom,” “lower”, “top”, “upper”, “beneath”, “below”, “above”, “on top”, “on,” etc., if used herein, are utilized for ease of description to describe spatial relationships of an element(s) to another. Such spatially related terms encompass different orientations of the device in addition to the particular orientations depicted in the figures and described herein. For example, if a structure depicted in the figures is turned over or flipped over, portions previously described as below or beneath other elements would then be above or over those other elements.
Since many implementations of the invention can be made without departing from the spirit and scope of the invention, the invention resides in the claims hereinafter appended. Furthermore, structural features of the different implementations may be combined in yet another implementation without departing from the recited claims.
This application is a continuation-in-part application of U.S. application Ser. No. 15/205,944 filed Jul. 8, 2016 titled “End Cap for Nuclear Fuel Rod and Welding Thereof,” which claims priority under 35 U.S.C. 119(e) to U.S. provisional application 62/281,149 filed Jan. 20, 2016 titled “Resistance Pressure Welding of Cladding Tubes,” and this application claims priority under 35 U.S.C. 119(e) to U.S. provisional application 62/281,149 filed Jan. 20, 2016 titled “Resistance Pressure Welding of Cladding Tubes,” the entire disclosures of all of which are incorporated herein by reference for all purposes.
Number | Date | Country | |
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62281149 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 15205944 | Jul 2016 | US |
Child | 15277869 | US |