KR20120082831A - Method for removal of pressure tubes and calandria tubes from a nuclear reactor - Google Patents

Abstract

PURPOSE: A method for removing pressure tubes and calandria tubes from a nuclear reactor is provided to eliminate a main calandria tube portion along with a main pressuring tube portion received inside a main calandria tube. CONSTITUTION: A pressuring tube, which is inside each first and second bell-shaped end portions in a calandria tube, is cut(102). A second end coupling portion is removed along with a cut second pressuring tube end portion combined with other end shielding portion of a calandria(106). The calandria tube, which is inside the second bell-shaped end portion and outside the main pressuring tube portion, is cut. The calandria tube located within the main calandria tube portion is cut from the main pressuring tube portion(114). The main calandria tube portion is removed from one end shield portion of the calandria along with the main pressuring tube portion. A cut end portion of the calandria tube is removed from other end shield portion of the calandria(122).

Description

How to remove calandria tubes and pressurized tubes from a reactor {METHOD FOR REMOVAL OF PRESSURE TUBES AND CALANDRIA TUBES FROM A NUCLEAR REACTOR}

The present invention relates to a method for removing irradiated components from a reactor. In particular, the method relates to removing the main calandria tube portion together with the main pressurized tube portion contained within the calandria tube.

Candu ^TM type reactors typically require retrofit after approximately 30 years of operation. This retrofit can multiply the lifetime of the reactor and typically involves retubing the calandria. This tube replacement process involves the removal of the end fasteners and their associated components, the removal of the press tube and the removal of the calandria tube and some of its related components around the press tube. Spacers necessary to maintain the gap between horizontal and coaxially extending pressurized tubes and calandria tubes are also removed. Since these portions are radioactive, the removed portions are typically placed in shielded flasks located in containment vaults. It is also known to reduce the volume of large parts by means of a chipper located in the reactor containment bolt.

The removal process for these fuel channel components from Calandria includes forming first cuts to separate end fasteners from outside the pressurized tube of the Calandria core in the grating tube. These first cuts are typically formed from the interior of the fuel channel through the pressure tube at an internal position of the engagement portion of the pressure tube and the end fastener so that no part of the end fastener is cut off. Alternatively, the cuts may be formed at both the pressure tube and the end fastener at the position of the joint of the pressure tube relative to the somewhat external or end fastener of this joint. However, in all examples, the cut is formed in the grating tube of Calandria and outside of the end shield inner tube sheet bores. Following these cuts, the end fasteners are removed from the calandria with or without press tube stub portions depending on where the cut is formed. The pressurized tube is then removed from the calandria tube, typically through one of the calandria's end shield grating tubes. When the pressurized tube is removed, it is highly irradiated and must be placed in a shielded flask. The stopper is then moved through the calandria tube to remove any remaining garter springs into the flask.

The next step is to remove the calandria tube. The calandria tube has opposing bell shaped end portions extending slightly from the calandria core into the opposing end shields of the calandria. The outer edges of the bell shaped end portions of the Calandria tube extend a portion of the path into the inner tube sheet bore. These bell shaped end portions are held in place by the Calandria tube inserts. The calandria tube insert is a ring member inserted inside the calandria tube at each of the bell-shaped end portions, and rolls outwardly to provide an interference fit between the bell-shaped end portions of the calandria tube and the corresponding tube seat bore. A) is formed. The calandria tube insert is removed by inserting a heating coil through the lattice tube sheet bore adjacent to the insert and then shock heating the insert. When the insert is cooled after heating, it may shrink to a diameter smaller than its outwardly rolled diameter and be removed out of the tube sheet bore and out through the grid tube. Once both Calandria tube inserts are free, the Calandria tube can be free from the tube sheet bores and pulled / pulled out through one grating tube in one of the end shields. Can be.

This process involves separate removal steps for pressurized tube, calandria tube, calandria tube inserts and garter springs, which takes time for the tube replacement process. In addition, these separate removal steps require separate collection / containment of pressurized tubes from the calandria tubes. In addition, the callan passing through the same tube sheet bore in one of the end shields of the calandria to maintain within acceptable limits the risk of damaging the inner and outer tube sheets, the tube sheet bore and the gland tube of calandria Care must be taken to remove both bell shaped end portions of the dry tube.

The present invention relates to a method for removing irradiated components from a reactor. In particular, the method relates to the removal of the main calandria tube part together with the main pressurized tube part housed inside the calandria tube.

The advantage is obtained by removing the main pressurized tube part together with the main callandria tube part in one operation, because it takes less time to remove both of these components together instead of removing each component one at a time. to be.

Another advantage associated with removing the main calandria tube portion with the main press tube portion is that the garter springs or spacers located between the press tube and the calandria tube are removed at the same time. This eliminates the step of moving the plug along the calandria tube to remove the spaces. In addition, any FROBs (flow regulating outlet bundles) placed in the pressurized tube during defueling prior to tube replacement are removed by removal of the main pressurized tube portion.

Another advantage associated with the removal of the main calandria tube portion with the main press tube is that the outer wall of the main calandria tube portion is typically very clean, thus minimizing the spread of contamination by acting as a sleeve covering the contaminated press tube. Is that. In addition, during the volume reduction, softer Calandria tubes help to accommodate the more brittle members of the pressurized tube that are typically subdivided during the volume reduction.

According to the invention, for removing first and second end fasteners opposingly coupled to calandria tubes, generally pressurized tubes coaxially within the calandria tubes and end portions of the pressurized tubes, from the calandria of the reactor. A method is provided. This method

a) the first and the first of the calandria tube to form a main pressurized tube portion between the first cut pressurized tube portion and the second cut pressurized tube portion still coupled to each one of the first and second end fasteners, respectively. Cutting the press tube inside each of the two bell shaped end portions,

b) removing the first end fastener with the first cut pressure tube end portion joined from one end shield of the calandria, and with the second cut pressure tube end portion joined from the other end shield of calandria. Removing the two end fasteners,

c) cutting the calandria tube inside the second bell-shaped end portion and the outside of the main pressurized tube portion to form a cut off Calandria tube end portion with the main Calandria tube portion, wherein the main pressurized tube portion comprises the main callan Cutting the calandria tube, located within the dry tube portion,

d) removing the main calandria tube portion together with the main pressurized tube portion from one end shield of the calandria, and removing the calandria tube end portion cut away from the other end shield of the calandria.

During removal step b), the end fasteners can be removed in separate steps performed in any order. Also, in step d), removal of the calandria main tube portion and the cut calandria tube end portion can be removed in separate steps performed in any order.

Another advantage is found in the process of the invention by steps c) and d). Step c) forms the main calandria tube portion and the cut calandria tube end portion. This step, together with the removal of the main calandria tube portion from the one end shield of the calandria and the cut calandria tube end portion from the other end shield of the calandria, is followed by the bell shape of the calandria tube path. Compared to previous processes where both the end portions pass through the same tube seat bore of the same end shield, the bell shaped end portions of the callandia have the advantage that they are removed through different tube seat bores of the various end shields of the callandaria. . Removing only one of the bell shaped end portions of the Calandria tube through the tube sheet bore reduces the risk of damage to the grid tube and tube sheet bore associated with the tube sheet bore.

After removal step b), the method may further comprise inserting temporary protective sleeves and shielding plugs in the callandria from which the first and second end fasteners are removed therefrom. These protective sleeves protect the grating tubes from being damaged upon removal of parts from the calandria. The method may further comprise removing the protective sleeves from the calandria after the main calandria tube portion and the cut calandria tube end portion are removed. These shielding stoppers still act to close the grating tube between the steps of the removal process to shield the irradiated components to be removed from the calandria.

Method step b) further comprises the step of removing from the calandria a first calandria tube insert which generally holds the first bell shaped end portion of the calandria tube together with the calandria, and the method step d) comprises The method may further include removing from the calandria a second calandria tube insert that generally retains the second bell shaped end portion of the calandria tube along with the drea. These two removal steps may include respectively freeing or separating the first and second Calandria tube inserts from their respective first and second bell shaped end portions of the Calandria tube. . The first Calandria tube insert can then be removed with or separately from the removal of the main pressurized tube portion and the main Calandria tube portion. In addition, the second calandria tube insert can be removed with or separately from the truncated calandria tube end portion once it has been separated or freed from the second bell shaped end portion of the calandria tube. .

For a better understanding of the features and objects of the present invention, reference is made to the accompanying schematic drawings, for example.
1 is a schematic diagram of a reactor assembly in which the method of the present invention may be performed.
FIG. 2 is an enlarged cross-sectional view of one of the refueling channels shown in FIG. 1.
3 is an enlarged cross-sectional view of the refueling channel of FIG. 2 with some fuel channel components removed.
4 is a flow chart that outlines a detailed process for the removal of components of one of the fuel channels shown in the callandria of FIG. 1.

The present invention relates to a method for removing irradiated components from a reactor. In particular, the method relates to removing the main calandria tube portion along with the main pressurized tube portion housed inside the calandria tube during shutdown, where fuel and heavy water are removed from the calandria environment.

Referring to FIG. 1, a reactor assembly 8 of the Candu ^™ type is shown schematically. Reactor 8 includes a calandria 10 having first and second end shields 12, 14 (FIG. 2). Although only one end shield 12 is shown in FIG. 1, the other end shield 14 is located on the opposite face for the calandria 10 to the end shield 12 and the end shields It should be understood that both (12, 14) are shown in FIGS. 2 and 3. Each of the end shields 12, 14 includes inner and outer tube sheets 16, 18, respectively. Each of the end shields 12, 14 has a corresponding series of grating tubes 22, 24 extending between the inner tube sheet bore 16 and the outer tube sheet bore 18. Corresponding ones of the grating tubes 22, 24 are aligned (FIG. 2). It should be understood that in Calandria 10, there may be as many as 480 tubes in each of the end shields 12, 14. Between the inner and outer tube sheet walls 16, 18 there is a shielding material shown in the figure in the form of steel balls 20.

The calandria tubes 26 extend horizontally across the core 28 of the calandria 10 between the end shields 12, 14. The calandria tubes 26 are axially aligned with the corresponding one of the first and second grating tubes 22, 24 of the end shields 12, 14, respectively.

As shown in FIGS. 2 and 3, the calandria tube 26 has opposing first and second bell shapes having an outer diameter configured to fit into the tube sheet bores 22a, 24a of the inner tube sheet 16. End portions 40, 42. The tube sheet bores 22a, 24a are connected with the grating tubes 22, 24. The outer diameter of the bell shaped end portions 40, 42 is slightly smaller than the inner diameter of the tube sheet bores 22a, 24a. The bell shaped end portions 40, 42 are positioned to extend into the tube sheet bores 22a, 24a adjacent the inner tube sheets 16. The calandria tube inserts 44 have the tube sheet bores 22a, 24a to retain the bell shaped end portions 40, 42 in tight fit with the inner walls of the tube sheet bores 24a, 26a. Is located within. The Calandria tube insert 44 is rolled outward to form an interference fit between the respective tube sheet bores 22a and 24a and the bell shaped end portions 40 and 42, and the bell shaped portions ( A ring inserted into the end of 40, 42).

The pressurization tube 30 is coaxially located in each of the Calandria tubes 26. Spacers or garter springs 32 are located in the annular space 34 between the inner wall of the calandria tube 26 and the outer wall of the pressure tube 30.

Pressurized tube 30 has first and second outer end portions within tube sheet bores 22a and 24a and which extend outwardly slightly beyond bell shaped end portions 40 and 42, respectively. 46, 48). It should be understood that the outside means closer to the outside of the calandria 10 than to the inner center of the calandria 10. Likewise, the interior means closer to the inner center of the calandria 10 than the outside of the calandria 10.

Outside of these first and second end portions 46, 48 of the press tube 30, first and second end fasteners 50, 52 are located. The end fasteners 50, 52 have inner end portions 36 superimposed on and joined to the outer end portions 46, 48 of the pressure tubes 30 by rolled couplings 54.

Each of the end fasteners 50, 52 extends beyond the outer tube wall 18 of the end shields 12, 14 through the grating tubes 22, 24 and outwardly of the calandria 10 in a direction away therefrom. Extend. End fasteners 50, 52 pass through fuel bundles (not shown) located in pressurized tube 30 within Calandria core 28 during normal reactor operation, through the pressurized tube 30 and the end fasteners. Attached to the feeder ducts 56 to allow the coolant to flow. In each of the end fasteners 50, 52 a shielding plug 58 and a closing plug 60 are inserted into them. Journal bearings 62 are located in the grating tubes 22, 24 to allow the end fasteners 50, 52 to be moved into the grating tubes. End fasteners 50, 52 are positioned relative to the outer tube sheet 18 of the end shields 12, 14 by a channel locking and unlocking mechanism 64. In addition, the bellows 66 surround each of the end fasteners 50, 52 adjacent to the outer tube sheet 18 and are attached to the outer tube sheet 18. The weld 68 is formed between each of the end shields 50, 52 and the bellows 66. In this way, the end fasteners 50, 52 are engaged with the calandria 10.

Referring to FIG. 4, a detailed flow chart of the process of the present invention for removal of end fasteners 50, 52, pressurized tube 30, and calandria tube 26 is shown. While these steps are described in a particular order, it should be understood that changing the order of specific steps may also achieve the same result of the present invention. In addition, the steps of the present invention may involve the removal of a set of end fasteners 50, 52, an associated pressurized tube 30 and a calandria tube 26 of one fuel channel, but in fact a number of Or all end fasteners 50 and the plurality or all of the second end fasteners 52 are removed from the calandria 10 before the removal of any of the calandria tubes 26 and the pressurized tubes 30. Can be removed from. Thus, each step of the method may be made for each of the fuel channels prior to performing the next method step on the fuel channel.

The first stage of the process 100 includes a closure plug 60, a shielding plug 58, a channel locking / unlocking mechanism 64 (FIG. 2) and associated end fasteners including the feeder tubes and tubing 56. It is about the removal of the components.

In step 102, the pressure tube 30 is cut inside each of the first and second bell shaped end portions 40, 42. These locations are shown at 70 generally in FIG. 2, which are also inside of the inner tube sheets 16. It should be understood that the cuts formed for the pressure tube may be at locations 70 that may be at the same distance or at different distances from each of their ends into the pressure tube 30. The cut is formed internally by cutting an internal cutting tool through the wall of the press tube 30. The tool may enter from one side of the calandria to form both cuts, or two tools entering from each side of the calandria may be used to form the cuts. A roll cutting tool is used to cut the pressurized tube 30. Alternatively, milling tools can be used. After these cuts have been made, the pressurized tube 30 is cut into first and second end portions 74, 76 and the main portion (12) positioned adjacent to the first and second end shields 12, 14. 72).

In step 104, the weld 68 securing the bellows 66 with each of the first and second end fasteners 50, 52 is cut. It should be understood that step 104 may precede step 102 or, alternatively, form part of step 100.

In step 106, the end fasteners 50, 52 are removed from their respective grating tubes 22, 24 together with their still joined cut pressure tube end portions 74, 76.

In step 108, the protective sleeves 92 and the shielding caps 98 (FIG. 3) are inserted into and fixed inside the tube sheet bores 22, 24. Shielding plugs 98 are inserted to shield the outside of the calandria from the irradiated components left inside the calandria, which will still be removed from the calandria in subsequent steps. By way of example, it is contemplated that all end fasteners 50, 52 may be removed prior to the removal of any other components. Thus, the shielding plug is inserted to cover each exposed opening after removal of the end fastener to cover this opening while the other end fasteners are removed.

In step 110, the shielding cap 98 is removed from one of the first grating tubes 22 and the heating coil is adjacent to the first grating tube insert 44 and the first grating tube bore 22a. (22) is inserted into. The heating coil performs a thermal shocking treatment of the calandria tube insert 44. The calandria tube insert 44 allows for cooling, at which time it is retracted to a diameter smaller than its outwardly rolled diameter so that the first bell shape of the first tube sheet bore 22a and the calandria tube 26 is reduced. Allow the insert 44 to be detached from the end portion 40 or to be free. While thermal shock is disclosed to bring the insert 44 free, it should be understood that any other suitable method may be used, such as, for example, internal cutting of the insert 44. However, thermal shock is a good method because it is considered a faster operation than cutting or machining. In addition, heat shocking is a cleaner process because it does not produce any chips or debris that can be caused by machining.

In step 112, the shielding plug 98 removed in step 110 is reinserted into the grating tube 22, since a significant time may elapse before further steps are performed in this grating tube.

In step 114, both shielding caps 98 in the grating tubes 22, 24 are removed. The cutting tool inserted through the second grating tube 24 is then moved into the calandria tube 26 inside the second bell shaped end portion 42. This position is shown entirely in FIG. 3 at 82 and is located outside the position 96 of the main pressurizing tube portion 72. 3 also shows a calandria tube cutting position 82 that is outside of the position 70 at which the pressure tube is cut at step 102. The calandria tube 26 is cut at position 82. After the calandria tube 26 is cut, the calandria tube 26 forms a cut calandria tube end portion 84, which is the second bell shaped end portion 42 and the main Calandria tube portion 86. And the main calandria tube portion 86 comprises a first bell-shaped end portion 40 and a majority of the length of the calandria tube 26 extending out of the second bell-shaped end portion 42. do. In addition, any FROBs in the main pressurizing tube portion 72, garter springs 32 and the main pressurizing tube portion 72 are housed in the main callandria tube portion 86.

In step 116, for example, a tool (not shown), such as an internal gripper tool, is passed through the first grating tube 22 inside of the first bell-shaped end portion 40 in the position shown at 88 in FIG. 3. It is moved in the first direction. The gripping tool extends to position 88 to contact the inner wall of the calandria tube, allowing the wall to expand. However, this wall does not expand larger than the outer diameter of the first bell shaped end portion 40. The gripper tool is then moved backwards out of the first grating tube 22, thereby bringing both the main calandria tube portion 86 together with the insert 44 and the press tube main portion 72 in the free state. Tow together. Garter springs 32 follow the removal of the main Calandria tube portion. In addition, any FROBs located in the main pressurizing tube portion 72 are removed together with the main pressurizing tube portion 72. This gripping position 88 is shown to be inside of the main pressurizing tube portion 72 and outside of the first bell shaped end portion 40. The ends of the main Calandria tube portion 86 may then be plugged or covered to receive the main tube portion 72. The removed components are placed in a shielding flask for removal from the bolt. After these components have been removed from the grating tube 22, the shielding plugs 98 are again inserted into each of the grating tubes 22, 24.

In addition, another tool may extend through the second tube sheet bore 24 to facilitate removal of the main Calandria tube portion 86 and the pressurized tube portion 72, and the first tube sheet bore 22a. It is to be understood that the primary Calandria tube portion 86 can be pushed outward. This propulsion tool may also help support the main callandria tube portion 86 when pulled or pushed out of the tube seat bore 22a with the main pressurizing tube portion 72. Even when the first Calandria tube insert 44 is in the free state, very large force is required to release the first bell shaped end portion 40 out of the interference fit with the first tube seat bore 22a. Should be understood. However, once the interference fit is free, the pressing tube main portion 72 and the main callandia tube portion 86 are moved out of the first lattice tube 22 through the first tube sheet bore 22a. The force required for this is significantly reduced.

In an alternative method, it should be understood that the insert 44 in the free state can be removed after being free from the first bell shaped end portion 40 prior to the removing step 116.

In step 118, the shielding cap 98 is removed from the second grating tube 24. Next, the calandria tube insert 44 forcing an interference fit between the second tube seat bore 24 and the second bell shaped end portion 42 of the cut calandria tube end portion 84 is in a free state. Or are separated. The calandria tube insert 44 is removed in a manner similar to that described above, in which a heating coil is inserted into the inner tube seat bore 24a and the second tube seat bore 24 in the vicinity of the calandria tube insert 44. . The calandria tube insert 44 is subjected to a shock heating process. After the Calandria tube insert 44 is heated, cooling is allowed, thereby reducing the diameter to a diameter less than its outwardly rolled diameter.

In step 120, the shielding plug removed in step 118 is reinserted into the second grating tube 24 because enough time may elapse before additional steps are performed on this grating tube.

In step 122, the same or another gripping tool (not shown) is formed at 90 degrees in its entirety in FIG. 3 and cut off of the cut calandria tube end portion 84 outside of the calandria tube cutting position 82. It is inserted through the second grating tube 24 to a position outside of the two bell shaped end portions 42. The tool extends to grip the Clandria tube end portion 84 cut to a diameter less than the outer diameter of the first bell shaped end portion 42. The gripper tool is moved outwardly of the second tube seat bore 24 to remove the cut calandria tube end portion 84 and its associated free state calandria tube insert 44 from the calandria 10. do. Removal forces similar to those described for removal of the first Calandria tube insert are used.

Alternatively, it should be understood that the Calandria tube insert 44 in the grating tube 24 may be removed immediately after being freed from the Calandria tube in step 118.

Next, at step 124, the shielding plug 98 is reinserted into the grating tube 24.

It should be understood that upon removal of all of these portions from the calandria, these portions are placed in the shielding flasks and volume reduced as part of the tube replacement / remodeling process.

Although the method is not concerned with the removal and replacement of the journal bearings 62 in the grating tubes 22, 24, if these bearings need to be replaced, the bearings are at any suitable stage of the method of the invention. It should be understood that it can be removed.

It is also believed that the positions 70 for cutting of the pressure tube 30 provide sufficient space for the remaining steps of the method to be completed, but if these cutting positions do not provide enough space, then the main press The tube portion 72 is adapted to facilitate cutting of the Calandria tube and to promote thermal shock of the Calandria tube insert 44 at the first bell-shaped end portion 40. It is contemplated that it can be moved axially in each direction within.

While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention may be practiced with variations within the spirit and scope of the invention as described below.

Claims (11)

A method for removing calandria tubes, generally coaxially located within the calandria tube, and first and second end fasteners coupled to opposing end portions of the pressurization tube from the calandria of the reactor,
a) each first of the calandria tube to form a main pressurizing tube portion between the first and second cut pressurizing tube end portions still engaged with respective end fasteners of the first and second end fasteners, respectively; And cutting said press tube inside of second bell shaped end portions;
b) removing the first end fastener with the first cut pressure tube end portion joined from one end shield of the calandria, and the second cut pressure tube end portion joined from the other end shield of the calandria And removing the second end fastener,
c) cutting said Calandria tube inside of said second bell-shaped end portion and outside of said main pressurizing tube portion to form a main Calandria tube portion and a truncated Calandria tube end portion, said main pressurizing tube portion Cutting the calandria tube, located within the main calandria tube portion,
d) removing the main calandria tube portion together with the main pressurized tube portion from one end shield of the calandria and removing the calandria tube end portion clipped from the other end shield of the calandria How to. The method of claim 1, wherein step a) comprises cutting the press tube in two separate cutting steps, and step b) removing the first and second end fasteners in two separate removal steps. Removing, wherein step d) comprises removing the main calandria tube portion and the cut calandria tube portion in separate steps. The method of claim 1, wherein after removal b), the method further comprises inserting removable shielding plugs and temporary protective sleeves into the callandria from which the first and second end fasteners are removed. 4. The method of claim 3, further comprising removing the protective sleeves from the calandria after the main calandria tube portion and the cut calandria tube end portion are removed. 5. The first bell-shaped end of claim 1, wherein step b) is with the main pressurizing tube part and the main callandria tube part, generally with the callandria. Removing the first tube insert bearing the portion from the calandria, wherein step d), together with the cut calandria tube end portion, generally with the calandria, Removing from the calandria a second calandria tube insert having a second bell shaped end portion. 6. The method of claim 5, wherein prior to steps b) and d), each of said first and second calandria tube inserts are respectively separated from said first and second bell shaped end portions of said calandria tube. Way. 2. The method of claim 1, further comprising removing from the calandria a first calandria tube insert bearing the first bell-shaped end portion of the calandria tube generally with the calandria prior to step d). Further comprising, prior to step d) removing from the calandria a second calandria tube insert that generally retains the second bell shaped end portion of the calandria tube together with the calandria. How to include more. 8. The method of claim 7, wherein each of said first and second Calandria tube inserts are respectively from said first and second bell shaped end portions of said Calandria tube prior to steps e) and f), respectively. Way to be separated. The method of claim 1, wherein the cuts formed for cutting the pressure tube to form the first and second cut pressure tube end portions and the main pressure tube portion are formed by an internal roll cutting tool. The method of claim 1, wherein the cutting of the calandria tube of step c) is made by an internal roll cutting tool. The method according to claim 1, wherein step d) is attached to inner wall of each of the callandria tube main part and the callandia tube cutting part respectively of the first and second bell shaped end parts, and the first and second Performed by an inflatable gripping tool that extends the inner walls to a diameter smaller than that of the bell shaped end portions.

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