This application is a national phase of International Application No. PCT/EP2006/063689 entitled “Device to Monitor the Postiion of An Assembly Containing Nuclear Fuel in a Storage Basket Housing”, which was filed on Jun. 29, 2006, which was not published in English, and which claims priority of French Patent Application No. 05 51847, filed Jun. 30, 2005.
1. Field of the Invention
The present invention relates generally to a device to monitor the position of an assembly containing nuclear fuel, in a storage basket housing.
It particularly applies to the monitoring of the position of nuclear fuel assemblies or fuel rod boxes in their respective housings, said fuel rod boxes corresponding generally to metal boxes wherein nuclear fuel rods are packaged, intended for the production of fuel assemblies.
The invention also relates to a locking system of an assembly containing nuclear fuel in a storage basket housing, the system ensuring axial and lateral locking of the assembly in the housing, and being equipped with such a monitoring device.
2. State of the Related Art
During the transport of fresh nuclear fuel, for example of the “MOX” type, the containers used are arranged in the prone position, i.e. positioned horizontally, such that the nuclear fuel assemblies arranged inside the basket housings rest gravitationally on the side wall of their respective housings.
More specifically, if the assemblies are nuclear fuel assemblies of a parallelepipedic rectangle shape, they are therefore two adjacent lateral surfaces of each assembly resting respectively on two surfaces of the side wall of the housing in question. This particular arrangement is essentially adopted in order to maintain the integrity of the fuel during transport.
In the prior art, it has been proposed to reinforce the locking of these assemblies by providing a locking system fitted at the upper end of each housing. In this way, this locking system makes it possible not only to press the two lateral surfaces of the assembly flat against the side wall of the associated housing, but also makes it possible to carry out axial tightening of said assembly in its housing.
Such a system is particularly disclosed in the document FR-A-2 833 401. As an indication, it is noted that this type of tightening system cooperates in a manner with the assembly such that the latter is displaced axially towards the top of the housing during the tightening operation, which implies that this assembly is no longer in contact with the bottom of the housing during transport, but in surface contact with the locking system. The gap between the bottom of the housing and the lower tip of the assembly advantageously allows a risk-free differential expansion between these two components.
Therefore, while the addition of this locking system makes it possible to reinforce the locking of the nuclear fuel assembly in its associated housing, and reduce as a result the risks of damage of the fuel assemblies during transport, it is however noted that visual and manual access inside the housing becomes extremely restricted once the blocking system is positioned on the open end of the housing.
In this way, it remains very difficult for an operator to determine the actual position of the assembly inside its housing rapidly, this drawback being all the more restricting as the exposure time of an operator in a nuclear environment must naturally be reduced to a minimum.
As an indication, it is possible to mention various situations wherein the operator should, even if it proves to be impossible due to the presence of the station locking system above the housing to be able to monitor the position of the assembly easily and quickly.
This consists first of all naturally of the case wherein the operations for the loading of the assembly in its housing and tightening of the locking system have just been completed. In fact, the operator should be able to ensure that the assembly occupies a good position in its housing, i.e. a position enabling the transport of the container. As indicated by the above, it would be necessary to be able to monitor the satisfactory position of each of the two adjacent lateral faces of the assembly intended to be in contact with the side wall of the housing, and the position of the upper tip intended to be in surface contact with the locking system.
Another situation wherein the operator would benefit from being rapidly and easily informed of the actual position of the assembly in its housing relates to the time following the release of the locking system. In fact, after the transport of the container and before removing the locking system, the operator should be able to ensure that the fuel assembly occupies a position enabling the unloading thereof from the housing, i.e. a position that can be qualified as “unlocked” and conveying, on one hand, the fact that the locking system has been sufficiently unlocked to be able to be removed from the housing without any risk of damage to the assembly, and, on the other, the fact that the latter has returned to rest in the bottom of the housing, or in a position very close to said bottom.
As indicated by the above, given that the release of the locking system results, in some types of embodiment, in an axial movement of the assembly to the bottom of the housing to the point of unloading said assembly in the bottom of the housing, it would be sufficient in this case to be able to monitor the axial positioning of said assembly.
Therefore, the aim of the invention is to propose a device to monitor the position of an assembly containing nuclear fuel in a storage basket housing, and a locking system of an assembly incorporating such a monitoring device, so as to remedy at least partially the drawbacks mentioned above relating to embodiments according to the prior art.
To this end, the invention relates to a device to monitor the position of an assembly containing nuclear fuel in a storage basket housing, comprising at least one mobile stop device and a position indicator suitable for being held at a stop by the mobile stop device in a first position indicating that the assembly occupies a first position, said mobile stop device being arranged so as to be able to be placed, by means of contact with the assembly located in a second position in its housing, in a position enabling it to release the position indicator devised to move automatically from the first position to a second position indicating that the assembly occupies the second position.
Advantageously, said monitoring device of a simple and clever design makes it possible to inform the operator rapidly and clearly on the position of the assembly in its housing, without it being necessary to have visual or manual access to the inside of said housing. In fact, the position indicator may easily be mounted outside the housing in question, such as the storage basket, or preferentially on the locking system fitted in the upper part of said housing. In this case, this indicator is produced so as to generate clear information for the operator, such as digital type information.
It is also noted that the result of the presence of such a device for each basket housing is that the exposure time of the operator in the nuclear environment during the loading and unloading of the assemblies may advantageously be substantially reduced.
Preferentially, the device is designed such that said first position of the assembly corresponds to a position prohibiting transport, and designed such that the second position of the assembly corresponds to a position enabling transport and such that the second position of the indicator corresponds to a position indication position enabling transport.
In such a case, it is therefore necessary to understand that the monitoring device makes it possible to indicate generally to the operator, following the loading of the assembly in housing and after the tightening of the locking system, whether the assembly occupies a satisfactory position in its housing, i.e. a satisfactory position with a view to subsequent secure transport of the container. As detailed hereinafter, it is noted that the position enabling transport is obtained when the assembly has made all the required contacts with the housing and the locking system, when such a system has been provided.
It is also possible to envisage that the position indicator is also suitable for being held at a stop by at least one mobile stop device in the position indication position enabling transport, said mobile stop device being arranged so as to be able to be placed, by means of contact with the assembly located in a position enabling the unloading thereof from the housing, in a position enabling it to release the indicator designed to move automatically from the position indication position enabling transport, to a position indication position enabling the unloading of the assembly.
In this way, in this configuration enabling the monitoring device to indicate a third position, the operator may then be informed, before unloading the assembly and after the release of the locking system, whether the assembly occupies a position or not enabling a risk-free extraction of the locking system, this extraction needing necessarily to be performed before the unloading of the assembly. As detailed hereinafter, it is possible to envisage that the position enabling the unloading of the assembly is obtained when the assembly was replaced in the bottom of the housing or returned in the vicinity thereof, following the release of the locking system.
In addition, it is preferentially envisaged that the indicator is held at a stop in the position indication position enabling transport by a single mobile stop device, preferentially any of those already used to maintain said indicator in the position indication position prohibiting transport.
Alternatively, the monitoring device may be designed such that the first position of the assembly corresponds to a position prohibiting the unloading of the assembly and such that the first position of the indicator corresponds to a position indication position prohibiting the unloading of the assembly, and designed such that the second position of the assembly corresponds to a position enabling the unloading thereof from the housing and such that the second indicator position corresponds to a position indication position enabling the unloading of the assembly.
Therefore, in this case where the device is not intended to provide information on the position of the assembly before the transport of the container, but only generally devised to monitor the unloading of assembly at the bottom on the housing after the release of the locking system, therefore, it is possible to envisage only monitoring the axial position of the assembly with this device, for example using a single mobile stop device, such as an axial thruster. As an indication, it is noted that the change of the assembly from the position prohibiting unloading to the position enabling unloading is identical or similar to the abovementioned change from the position enabling transport to the position enabling unloading, as in both cases, the assembly changes from a state wherein it is at a distance from the bottom of the housing to a state wherein it is in contact with said bottom or very close thereto.
Preferentially, the device comprises a plurality of mobile stop devices, each suitable for holding the position indicator at a stop in the first position. In addition, as mentioned above, it is also possible to envisage that at least one of these devices is suitable for holding the indicator in at least one other position among those specified above.
In this case, the device comprises a first mobile stop device arranged to move in translation in a first direction, said first device preferentially taking the form of a thruster provided with a throat cooperating with a groove produced in the position indicator.
According to a first preferred embodiment of the present invention, the device also comprises a second mobile stop device and a third mobile stop device respectively arranged to pivot around a second direction and a third direction, the first, second and third directions being orthogonal with respect to each other.
In this way, the three devices proposed make it possible to monitor the position of three orthogonal surfaces of the assembly, by means of contact therewith, this solution being evidently sought in order to monitor the position of rectangle parallelepipedic shaped assemblies, such as that observed on nuclear fuel rod assemblies and fuel rod boxes. Naturally, the invention also applies to the monitoring of the position of assemblies displaying a different shape, the number and design of the mobile stop devices then being selected as a function of the number and layout of the surfaces of the assembly to be monitored.
Preferentially, the first, second and third mobile stop devices are equipped with elastic return means, which preferentially all tend to return their associated mobile device to a position wherein the latter forms a stop for the indicator.
According to a second preferred embodiment of the present invention, the monitoring device no longer incorporates the second and third abovementioned devices, but comprises a fourth mobile stop device arranged to move in translation along a first direction, said fourth mobile stop device having one contact end of a tapered shape, of an axis parallel with the first direction.
In this way, said contact end of tapered shape makes it possible to monitor the position of two surfaces of the assembly orthogonal with each other and parallel with the first direction, whereas the first device makes it possible to monitor the position of a third surface of said assembly, orthogonal with the two others. The second preferred embodiment, wherein the fourth mobile stop device is equipped with elastic return means, is therefore also particularly suitable for monitoring the positioning of assemblies of rectangle parallelepipedic shape, but could naturally find an application for assemblies having other shapes.
Moreover, the position indicator takes the form of a flap equipped with elastic return means enabling the automatic movements thereof from the first position to the second position.
Finally, the invention also relates to a locking system of an assembly containing nuclear fuel in a storage basket housing, said system providing axial and lateral support of the assembly in its housing, and being equipped with a monitoring device such as that described above and also according to the present invention. As described above, the lateral support is preferentially performed by pressing at least two surfaces of the assembly against the associated housing, and preferentially two surface orthogonal with each other.
Other advantages and characteristics of the invention will emerge in the non-limitative detailed description below.
This description with be made with reference to the appended figures wherein;
a shows a partial sectional view showing more specifically the first mobile stop device of the device shown in
b shows a similar view to that of
a shows a partial sectional view showing more specifically the second mobile stop device shown in
b shows a similar view to that in
a shows a partial sectional view of the monitoring device shown in
b shows a similar view to that in
c shows a similar view to that in
With reference to
Each housing 1 is designed to receive only one assembly 4. To this end, the inner dimensions of the housing 1 are slightly greater than those of the assembly 4, as can be seen clearly in
Housing 1 is equipped on the upper open part thereof with a locking system 6 according to the present invention, shown only schematically and in a tightening configuration wherein it locks the assembly 4 in its housing 1, which was previously inserted therein.
The tightening performed by means of the system 6 makes it possible to lock the assembly 4 along the axial direction 8 of the housing 1, by means of surface contact, preferentially plane, between an upper tip 11 of the assembly and said blocking system, and more preferentially between the horizontal upper surface 9 of the upper tip 11 and the locking system. In a manner known to those skilled in the art, the tightening operation results in the detachment of the lower tip 10 of the assembly from the bottom 12 of the housing 1, as can be seen in
In addition, in the general case wherein the assembly 4 has a square cross section, the tightening being performed on the upper tip 11 of the assembly 4 also results in causing the pressing of two adjacent lateral faces 14a, 14b of said assembly 4 against two adjacent lateral surfaces 16a, 16b respectively of the lateral wall of the housing 1, as can be seen schematically in
The design of the locking system 6, and more specifically that of its means making it possible to carry out the three lockings described above, corresponds to a design known to those skilled in the art, and will therefore not be described further. As an indication, said locking system 6 designed to limit the movements of the assembly 4 during transport as much as possible may take any of the forms described in the document FR-A-2 833 401, which is incorporated herein by reference. In these various forms, the system essentially comprises an attachment device designed to produce a rigid connection between the upper tip of the assembly, and the open end of the housing.
As will now be described, the specificity of this system 6 lies in the fact that it incorporates a position monitoring device of the assembly in the housing in question.
Firstly with reference to
In this
As an indication,
As will be explained hereinafter, the monitoring device 20 is preferentially designed to monitor the axial position of the assembly, and its lateral position in two separate directions, which are in this case orthogonal due to the orthogonal nature between the two lateral surfaces 14a, 14b wherein the contact with the wall of the housing 1 is to be monitored.
For this purpose, it comprises two mobile stop devices 24, 26, 28, which, when the assembly 4 occupies a position prohibiting transport in its housing, each hold via a stop a position indicator 30 in a position indication position prohibiting transport.
Said position indicator 30 may be made in any manner known to those skilled in the art, by combining it with marking made on a support of the indicator which in this case is the plate 22, said marking possibly for example taking the form of a graduation, and more generally any form enabling the operator to be able to determine visually the position of the indicator, and therefore that of the assembly in the housing. For example, in the first preferred embodiment represented in the figures, the indicator takes the form of a flap 30 mounted externally in a hinged manner on the main plate 22 serving as a support, along a pivot 31 parallel with the axial direction 8. In this position indication position prohibiting transport, its angular position with respect to the plate 22 is such that it reveals a first zone 34 of a marking, said zone 34 being produced on the upper surface of said plate 22 and created so as to indicate clearly and accurately to the operator that the assembly 4 is incorrectly positioned in the housing 1 to which it no longer has visual access. This first zone 34 may for example adopt a specific colour, belonging to a colour code known to the operator.
More specifically with reference to the
At this stage, the locking system 6 has only been positioned on the upper part of the housing 1 with which it is in contact, but it has not yet been tightened. This is the reason for which the assembly 4 occupies an axial position prohibiting transport, which is conveyed by the absence of contact between the upper surface 9 of the tip 11 and a lower horizontal surface 36 of the plate 22, these two surfaces 9, 36 being oriented perpendicular with the direction 8.
Therefore, the axial thruster 24 is in the lowest position provided by elastic return means preferentially taking the form of a compression spring 40 inserted between the plate 22 and the lower end 38, and by a shoulder 42 limiting the stroke of said thruster 24 downwards by pressing against a seat 44 produced in an upper portion of the plate 22. In this position, the lower end 38 and the upper end 9 are preferentially spaced by a clearance 46. Moreover, an upper end 50 of said thruster 24 is housed in a through orifice 52 of the flap 30, the orifice 52 and the end 50 having a substantially identical diameter.
Therefore, the stop between these two components 50 and 52 makes it possible to maintain the flap 30 in the position indication position prohibiting transport shown in
With reference now to
During this tightening, the upward movement of the assembly 4 in the housing 1 results in the surface 9 and the lower end 38 of the thruster 24 coming into contact. As a result, the tip 11 applies an action on the thruster 24 which is then moved upwards compressing the spring 40, until the surfaces 9 and 36 come to a stop, as is represented in
The diameter of said throat 56 is substantially identical to the width of a groove 58 (visible in
With reference now to
At this stage, the locking system 6 has only been positioned on the upper part of the housing 1 with which it is in contact, but it has not yet been tightened. This is the reason for which the assembly 4 occupies a lateral position prohibiting transport, which is conveyed by the absence of contact between the lateral surface 14a of the assembly and the lateral surface 16a of the housing.
Therefore, the arm 26 is in a position wherein its lower end projects more inside the housing 1, via the surface 16a, this position being held by default by means of elastic return means such as a torsion spring 68 only represented schematically and being arranged around the pivot 64, therefore in the second direction 62. In this case, the spring 68 has one end attached to the arm 26, and another end attached to the plate 22. In this way, as is also the case for the spring 40 associated with the thruster 24, the spring 68 holds the arm 26 in a stop position for the flap 30.
Therefore, in this state held by the stop between the surface 36 of the plate 22 and the lower end 66 of the arm 26, this arm 26 rests in a substantially tilted position wherein it deviates upwards from the housing.
Moreover, an upper end 72 of said arm 26, also referred to as the stop end, is housed in a straight groove 74 of the flap 30, said groove 74 opening radially to the outside of said flap 30 and being created on a lower surface thereof. More specifically, the groove 74 is created in the same plane as the plane of movement of the arm 26, i.e. in a plane parallel with the direction 8 and orthogonal with the direction 62.
Therefore, here again, the stop between these two components 72, 74 makes it possible to hold the flap 30 in the position indication position prohibiting transport shown in
With reference now to
During this tightening, the lateral movement of the assembly 4 in the housing 1, in the direction of the surface 16a, results in the surface 14a and the lower end 66 of the arm 26 coming into contact. As a result, the surface 14a exerts an action on the arm 26 which pivots around the pivot 64 in the second direction 62 by compressing the spring 68, until the surfaces 14a, 16a come to a stop, as represented in
In this way, in this state, the arm 26 no longer holds the flap 30 at a stop, as a pivoting thereof along the axis 60 would result in a relative movement between the gap 78 and the end 72 located therein.
With reference again to
At the end of the tightening of the locking system 6, the three mobile stop devices 24, 26, 28 are normally positioned simultaneously in the states shown in
Jointly with reference to
In this position indication position enabling transport, the angular position of the flap 30 with respect to the plate 22 is such that it covers the first marking zone 34, which indicates clearly and precisely to the operator that the assembly 4 is positioned correctly in the housing 1 to which he no longer has visual access. In this preferred example of marking, it was indeed envisaged that during the occupation by the flap 30 of the position indication position enabling transport, none of the zones of the marking are displayed.
The device 20 is also devised, in this first preferred embodiment, such that the flap 30 can occupy a third position referred to as the position indication position enabling unloading of the assembly. In fact, in this third position, the operator can then be informed, before the unloading of the assembly 4 and after the release of the locking system 6, whether said assembly occupies a position or not enabling a safe extraction of the locking system 6. It can then be preferentially envisaged that the position enabling unloading of the assembly is obtained when the assembly 4 has been unloaded in the bottom of the housing or returned in the vicinity thereof, following the release of the locking system 6.
In fact, during this release, the assembly 4 is returned to the bottom of the housing 4, and, therefore, the thruster 24 forming the only mobile stop device to still hold the flap 30 follows the movement of said assembly, under the effect of the compression spring 40 undergoing decompression. As a result, said thruster 24 is lowered progressively to the position shown in
As a result, the flap 30 may then automatically reach the position indication position enabling unloading of the assembly as shown in
As an indication, it is noted that, to prevent static indetermination problems, the automatic transition between the second and the third position of the flap 30 is performed preferentially not at the end of release, but just before the end of said release of the system 6. As a result, after the abovementioned transition of the flap 30 from the second to the third position, the operator is obliged to complete the release to finish unloading the assembly in the bottom of the housing 1, the lowering induced only however being very slight and corresponding substantially to the clearance 46 shown in
Once these operations have been performed, the operator can then remove the locking system 6 and extract the assembly 4 from its housing 1. In addition, the monitoring device 20 may then be reset manually with a view to a future assembly transport in the housing in question.
With reference now to
Moreover, this device will be described as being only capable of detecting two separate positions of the assembly in its housing, i.e. that prohibiting transport and that enabling the transport of said assembly. Nevertheless, it is clear that it could be adapted by those skilled in the art, in view of the first preferred embodiment described above, to also detect a third position corresponding to the position enabling unloading of the assembly.
Overall, said second embodiment differs from the first in that the two lateral arms 26 and 28 are replaced by a fourth mobile stop device taking the form of a thruster suitable for monitoring the lateral position of the assembly in the housing.
More specifically, as can be seen in
As will be explained hereinafter, the monitoring device 20 is preferentially designed to monitor the axial position of the assembly, and its lateral position in a plane orthogonal to the axial direction 8. In this way, the monitoring of the lateral position performed, comparable to lateral monitoring in two directions, for example orthogonal with each other as was the case in the first preferred embodiment, is clearly associated with both lateral surfaces 14a, 14b of the assembly 4 wherein the contact with the wall of the housing to be monitored. As a result, said device 20 is very suitable to monitoring the contact of three orthogonal surfaces of the assembly 4, respectively with the tightening system 6 and the lateral wall of the housing.
For this purpose, it comprises a first mobile stop device 124 and a fourth mobile stop device 90, which, when the assembly 4 occupies a position prohibiting transport in its housing, hold by a stop the flap 30 in the position indication position prohibiting transport, said flap 30 being in this case also hinged around the pivot 31 of the axis 60 parallel with the direction 8. In this position indication position prohibiting transport, the angular position of the flap 30 with respect to the plate 22 is such that it reveals is the first marking zone 34 created so as to indicate clearly and precisely to the operator that the assembly 4 is incorrectly positioned in the housing.
With reference to
Therefore, the axial thruster 124 is in the lowest position provided by elastic return means preferentially taking the form of a compression spring 140 inserted between a hollow body 92 of the device 20 and the lower end 138, the components 124, 140 and 92 being concentric. Moreover, the lowest position is retained by means of a stop between a shoulder 142 of the thruster 124, possibly being formed by a ring, and an upper end 94 of the hollow body 92 attached to the plate 22, said stop actually limiting the downward stroke of the thruster 124. In this position, the lower end 138 and the upper surface 9 are spaced by a clearance 46. In addition, an upper end 150 of said thruster 124 is housed in a through orifice 52 of the flap 30, the orifice 52 and the end 150 having a substantially identical diameter.
Therefore, the stop between said two components 150 and 52 makes it possible to hold the flap 30 in the position indication position prohibiting transport shown in
With reference now to
During this tightening, the upward movement of the assembly 4 in the housing 1 results in the surface 9 and the lower end 138 of the thruster 124 coming into contact. As a result, the tip 11 exerts an action on the thruster 124 which then moves upwards compressing the spring 140, until the surfaces 9 and 36 are at a stop, as represented in
The diameter of said throat 156 is substantially identical to the width of the groove 58 (visible in
Again with reference to
At this stage where the locking system 6 has not yet been tightened, the assembly 4 occupies a lateral position prohibiting transport, which is conveyed by the absence of contact between the lateral surface 14a of the assembly and the lateral surface 16a of the housing, and between the lateral surface 14b of the assembly and the lateral surface 16b of said housing (the surfaces 14b and 16b not being visible in
The thruster 90 is in this case in the lowest position provided by elastic return means preferentially taking the form of a compression spring 102 inserted between the hollow body 92 and a brace 104 pressing against an upper portion of a rod 106 passing orthogonally through the thruster 90. Moreover, the lowest position is retained by means of a stop between both ends of said rod 106 and the bottom of two slots 110 created in lateral faces of the hollow body 92, therefore, said stop limiting the downward stroke of the thruster 90. In this position, the lower end 96 and the upper end 9 are for example in contact with each other, or very close, which implies that the end 96 projects slightly from the end 138, downwards. Moreover, an upper end 112 of said thruster 90 projects upwards from the upper end 150 of the thruster 124.
With reference to
Therefore, the stop between these two components 112, 113 makes it possible to hold the flap 30 in the position indication position prohibiting transport shown in
With reference now to
During this tightening, the lateral movement of the assembly 4 in the housing 1, in the direction of the surfaces 16a and 16b, results in the orifice 98 of the tip 11 being centred with respect to the contact end 96 of tapered shape. Once this is performed, the action of the compression spring 102 on the thruster 90 induces an automatic downward movement thereof, enabled by an entry of the end 96 in the orifice 98, as can be seen in
In this position, it can be seen that the end 112 has been moved sufficiently downwards to be fully extracted from the orifice 113. In fact, the upper end 112 is now housed in the end 150 of the thruster 124, and therefore arranged in the recess 116 of the plate 114. In this way, in this state, the thruster 90 no longer holds the flap 30 at a stop.
At the end of the tightening of the locking system 6, both mobile stop devices 124, 90 alone making it possible to monitor the contact of three orthogonal surfaces of the assembly 4 are normally positioned in the state shown in
In
In this position indication position enabling transport, the angular position of the flap 30 with respect to the plate 22 is such that it covers the first marking zone 34 while revealing another zone 119, the latter also being created on the upper surface of said plate 22 and produced so as to indicate clearly and precisely to the operator that the assembly 4 is correctly positioned in the housing 1. Naturally, this zone 119 preferentially adopts a different colour to that of the first zone 34.
Naturally, various changes may be made by those skilled in the art to the tightening system and the monitoring devices described above, only as non-limitative examples.
In particular, while both preferred embodiments have been described with reference to a nuclear fuel assembly, it should be understood that the invention also applies to any assembly containing nuclear fuel designed to be positioned in a storage box housing, such as for example a fuel rod housing, and preferentially displaying a polygonal cross section, such as a square.
In addition, it is noted that the monitoring device may not only be incorporated in a locking system designed to be fitted in a given storage basket housing but could alternatively be mounted directly thereon.
Finally, it is noted that while the two preferred embodiments described above are devised such that they make it possible to indicate to an operator that the assembly is either in a position prohibiting transport (after the loading of the assembly, and conveying one or more non-satisfactory contacts), or in a position enabling transport (after the tightening of the locking device, and conveying satisfactory contacts), or possibly in a position enabling its unloading (after the transport and release of the locking system, and conveying the unloading of the assembly in the bottom of the housing), the invention also applies to devices designed to only indicate a position prohibiting the unloading and a position enabling the unloading of the assembly. In the latter case, the device of a similar design to any of those described above is produced such that the transition of the assembly from the position prohibiting unloading to the position enabling unloading is identical to the transition described above from the position enabling transport to the position enabling unloading, as in both cases, the assembly changes from a state wherein it is at a distance from the bottom of the housing to a state wherein it is in contact with said bottom or very close thereto.
Number | Date | Country | Kind |
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05 51847 | Jun 2005 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/063689 | 6/29/2006 | WO | 00 | 2/18/2009 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2007/003575 | 1/11/2007 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4077840 | Aubert | Mar 1978 | A |
4678620 | Marshall et al. | Jul 1987 | A |
5064606 | Go | Nov 1991 | A |
5461647 | Clark et al. | Oct 1995 | A |
6134290 | Yoshizawa et al. | Oct 2000 | A |
Number | Date | Country |
---|---|---|
18 16 856 | Jul 1970 | DE |
0 506 512 | Sep 1992 | EP |
2 833 401 | Jun 2003 | FR |
Number | Date | Country | |
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20090172961 A1 | Jul 2009 | US |