This application is the U.S. national phase of the International Patent Application No. PCT/FR2013/051841 filed Jul. 30, 2013, which claims the benefit of French Application No. 12 57424 filed Jul. 31, 2012, the entire content of which is incorporated herein by reference.
The invention relates to sealing a crack in a pool wall in a nuclear facility.
Such cracks can occur in pool walls, particularly at the welding seams in the lining which is usually made of steel. For example, the inner walls of such pools may be covered with sheets of stainless steel and the edges of the sheets are welded to each other. Said cracks often occur at these welds.
In such cases, an adhesive tape made of an adhesive polymer (for example an elastomer and/or silicones or other, with selected additives) is used to cover welds at these cracks when such cracks occur, as described in particular in document FR 2874020.
The adhesive has a protective coating, for example in the form of a film of stainless steel, usually similar to the pool walls. For example, the tape may be applied along the seam between two sheets of a wall, to cover a crack that has formed in the weld between sheets (due to wear, corrosion, etc.). This step is often conducted while the pool is full of water that may be contaminated by radiation from the spent nuclear fuel it contains. It is undesirable to involve a diver in sealing the crack. A robot could be used to apply an adhesive tape of the aforementioned type to the crack, after a prior phase of locating and detecting defects or cracks.
It could be arranged, for example, to have a mobile robot at the bottom of the pool, supporting an articulated arm for reaching cracks high on the vertical walls of the pool. Such pools are deep, however, typically reaching depths of around 14 meters. An angular misalignment, however small, is likely to generate unacceptable positioning errors when placing the tape over a crack. In particular, a very small positioning error tolerance is desired. The tape is about 40 mm wide and the weld, where the crack to be covered is likely to be, can be up to about 6 mm wide. Furthermore, a positioning error tolerance for the tape is required that corresponds to at least 15 mm of adhesive beyond the weld, leaving a positioning error tolerance of 2 mm allowed between the center of the tape and the center of the weld. The positioning error tolerance is therefore 2 mm with an articulated arm 14 meters long. The required angular precision is 0.008 degrees, which is difficult if not impossible to achieve in practice (particularly because of the intrinsic mechanical flexibility of the arm).
The invention improves the situation.
For this purpose, it proposes a method for sealing a seam in a wall of pool of a nuclear facility (this seam may or may not have a crack). In particular, this method makes use of a mobile robot carrying a dispenser of adhesive tape coated with a protective material (for example stainless steel). In the method, at least the following are provided:
Thus, said plurality of suction systems allows retaining the robot assembly on a vertical wall of the pool, for example by the suction of suction cups, and the first suction system to which the dispenser is attached can move relative to the other suction cups in order to adjust the position of the dispenser, and thus of the tape, relative to the crack or more generally to the seam to be sealed.
It thus becomes possible to unwind the tape continuously and along a great length. It is then possible to cover an entire seam, for example at the weld between two sheets (typically for the entire aforementioned 14 meters), as this seam is likely to exhibit cracks, but without worrying about the actual existence and exact location of these cracks.
Moreover, the defect detection/location phase is no longer necessary. This detection is usually conducted manually (which raises the problem of protecting the operator from radiation). In addition, it remains imprecise and limited. Through-cracks creating an opening of less than 90 μm are not detected. The term “through-crack” here is understood to mean that the crack forms an opening to the other side of the sheets, which are no longer fluid-tight.
This detection phase requires several days of intervention, in an outage schedule that is already usually very tight.
In addition, the formation of a crack is part of a fatigue process that is not dependent on the local dose. Therefore one cannot predict the location or number of through-crack defects.
The invention overcomes these constraints by sealing all accessible welds, rendering the detection-location phase optional.
The above controlling steps can be performed remotely from a control station which, for example, receives images from cameras mounted on the robot.
In one embodiment, a frame is provided comprising one or more suction systems, as well as a crosspiece movably mounted in the frame and supporting the first suction system and the dispenser.
In this embodiment, the crosspiece may be movable in translation along a first direction of the frame.
In this embodiment, the crosspiece may support an arm mechanically integral with the dispenser and this arm can be mounted to move in translation relative to the crosspiece in at least a second direction that is different from the first direction. Such an embodiment ensures, for example, a movement in a plane parallel to the wall to be sealed, said two directions defining this plane. Of course, this arm may also support a vertical shaft for adjusting the height of the dispenser head, and thus apply the tape it carries against the seam to be sealed.
In one embodiment, the dispenser can be placed outside the frame, which allows better dispenser accessibility in tight areas (areas cluttered with filtration/lighting/ladder equipment) or, more generally, over uneven contours, for example if plates were fillet-welded. For this purpose, the very structure of a tape having a flexibility suitable for such placement and comprising an elastomer coated with a stainless steel film is advantageous in itself.
In one general embodiment, the first suction system may be mounted to rotate relative to the other suction systems, which allows changing the movement direction of the robot, or for example precisely adjusting the path over a wall seam.
In one embodiment, to move the dispenser relative to a wall of the pool, alternating steps are ordered which comprise at least the following:
In one embodiment, the suction systems comprise suction cups with backflow of fluid, for example remotely controlled. Such an embodiment allows, for example, ordering a rapid movement of the dispenser relative to a pool wall.
In one embodiment, as the dispenser comprises a head that presses the tape against the wall, said head may be equipped with a servomotor. Such an embodiment allows, for example, guaranteeing optimal contact during tape application. An alternative is to wrap the tape around a roller divided, for example, into at least two parts and mounted on two springs at the head end of the dispenser, as discussed below with reference to
The invention also concerns a robot comprising means for implementing the invention presented above, and more particularly a mobile robot for sealing cracks in a wall of a spent fuel pool, carrying an adhesive tape dispenser and comprising:
It should be noted that the robot can also adapt to and operate in an air environment for all seam repair (between any liners), thus avoiding not only the detection-location phases but also the erection of scaffolding (for example for maintenance operations on internal metal liners sealing the concrete wall of the reactor building for example).
The invention also relates to a facility comprising such a robot and means for remotely controlling the suction systems and motor means comprised in the robot.
It will be understood that the robot, by its system for movement over the vertical walls of a pool by means of said suction systems, enables it to be autonomous on site, although remotely controlled by a control station of a facility in the sense of the invention. However, the movement of the robot can be controlled very precisely and in general allows extreme accuracy in positioning the head of the dispenser relative to the crack, or more generally to the seam, to be sealed. Furthermore, in an advantageous embodiment, to avoid drift due to long application lengths, the robot may be equipped with a system for realignment during application without damaging the tape. This realignment is made possible by the accurate positioning of the robot, as the increment of the positioning motors is preferably 0.01° in rotation and 0.25 mm in translation.
Other features and advantages of the invention will become apparent upon reading the exemplary non-limiting embodiments described below, and upon examining the accompanying drawings in which:
We first refer to
It has generally been observed that as the sheets age, if a crack appears it starts at this weld. Usually, the crack is covered by an adhesive tape BS in the form of a strip, often continuous, as shown in
Referring to
Additionally or in a sophisticated variant, the head of the dispenser can be equipped with a servomotor that changes the height of the head based on the resistance encountered relative to a particular contour.
It is understood that the head of the dispenser DIS can fit into tight areas of the pool, for example under pipes conveying fluids or ladder rungs, or other areas.
Particularly in the context of the present invention, the adhesive tape is particularly thin (a few millimeters) and therefore flexible. It is thus possible to apply the tape under the above conditions (tight areas, sharp edges, etc.) and to do so over long distances.
In addition, as the robot can be moved over a vertical wall of the pool, and this can be done with very precise positioning of the dispenser head relative to a given point on the wall, it is possible to lay the tape along a very long weld. Such an embodiment advantageously shortens repair operations on spent fuel pools by eliminating the conventional phase of detecting defects, including through-cracks. Currently, spent fuel pool repairs require a prior detection phase. It is only once the defects are detected that they are sealed. In general, defects are detected by an ACFM (Alternative Current Field Measurement) method: an electric current is injected by probe along the weld, then analysis of the generated magnetic field translates the dimensions and location of through-cracks (cracks extending through the thickness of a sheet). The embodiment illustrated in
Advantageously, a front camera C1 and a rear camera C2 are mounted on the dispenser DIS, for controlling its movement from a remote control station (denoted PC in
Referring to
We now refer to
We now refer to
In a first step S1, the first system of suction cups is lowered by downward translation along shaft Tz′1. Simultaneously, in step S2, the first system of suction cups V21 to V24 is activated then the second system of suction cups V11 to V14 is deactivated. Suction cups V21 to V24 then adhere to the surface of the wall (for example vertical) of the pool, while the second system of suction cups V11 to V14 disengages from said surface. In step S3, translation along axis Ty, longitudinally, is ordered so as to “advance” the system of suction cups V11 to V14 relative to the first system of suction cups V21 to V24, and also relative to the wall of the pool, since the first system is fixed relative to the wall. Then, in step S4, the reverse mechanism of steps S1 and S2 is executed: the second system of suction cups V11 to V14 is lowered in step S4, and suction cups V11 to V14 are activated while the first system of suction cups V21 to V24 is deactivated. It will be understood that, in general, the robot device is advanced by the translation along axis Ty performed in step S3; it only remains to bring, in step S6, the first system of suction cups V21 to V24 to an initial position that will offer the highest possible amplitude for a future translation performed in a subsequent iteration of step S3.
The movement of the mobile robot can be controlled remotely to approach a seam, using the cameras carried by the robot (test T7). The movement of the robot continues (arrow KO exiting test T7) until it arrives at a suitable distance from the seam (arrow OK exiting test T7). When the robot is sufficiently close, in step S8 the angular position of the dispenser DIS is adjusted by rotation Rz, and the precise position of the dispenser DIS within the plane of the pool wall is precisely adjusted by translations along axes Tx and Ty, to place the dispenser exactly within the axis of the seam. Then, in step S9, once the dispenser head has been adjusted to be above the seam, the dispenser can be lowered in translation along axis Tz to start forcibly applying the tape against the seam. Next, the robot can move (translations along Ty) and the dispenser can be moved angularly Rz and within the plane Tx, Ty of the pool wall (and if necessary also heightwise Tz), as described above in the succession of steps S1 to S6.
Moreover, the suction cups of the robot's suction systems can be implemented for example in the form of a piston mounted on a cylinder and capable of discharging water from one or more successive cavities, allowing precisely adjustable adhesion of the suction cup. As indicated above, a degree of heightwise translation Tz for each suction cup can advantageously provide stability of the robot within a plane, in case of pronounced unevenness in the wall.
It is thus possible to initially apply the robot to a side edge of the pool (typically near the surface of the liquid it contains), and then to steer it towards the seam, with the robot adhering to the wall and moving relative to the wall until it reaches the seam.
We have, of course, described an example in this embodiment where the dispenser DIS is integral to the shaft Tz1′ supporting the first system of suction cups V21 to V24. Other embodiments are possible. For example, the dispenser may not be integral to this shaft, but rather to a shaft parallel to the axis of lateral translation Tx (representation according to
More generally, the invention is of course not limited to the exemplary embodiments described above; it extends to other variants.
It is therefore understood that in a very simple embodiment, the general system for moving the robot can be based on a minimum of two suction devices. Indeed, it is sufficient for one suction device to move in translation relative to the other to cause a mobile robot in the sense of the invention to move.
Number | Date | Country | Kind |
---|---|---|---|
12 57424 | Jul 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FR2013/051841 | 7/30/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/020280 | 2/6/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4345658 | Danel | Aug 1982 | A |
20100192368 | Kramer | Aug 2010 | A1 |
Number | Date | Country |
---|---|---|
298 22 221 | Aug 1999 | DE |
0 010 034 | Apr 1980 | EP |
2 874 020 | Feb 2006 | FR |
2874020 | Feb 2006 | FR |
62-111544 | Jul 1987 | JP |
04-309890 | Nov 1992 | JP |
06-201896 | Jul 1994 | JP |
11-079019 | Mar 1999 | JP |
2004-323621 | Nov 2004 | JP |
Entry |
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Machine translation of FR 2874020. |
English language translation of Office Action issued in related application JP 2015-524836, dated Dec. 21, 2015, 6 pages. |
Office Action issued in related application CA 2,879,919, dated Feb. 3, 2017, 4 pages. |
Number | Date | Country | |
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20150200026 A1 | Jul 2015 | US |