The invention deals with a device for stopping a container provided with a neck, and a container equipped with such a device. The invention also deals with a batch of such containers and with a method for closing such a batch.
In the field of containers for medicines, it is known to use a glass bottle to retain an active principle in freeze-dried, powder or liquid solution form. Such a bottle must be sealed in a leakproof manner in order to maintain its content in a satisfactory state of conservation, until its usage date. To hermetically close a bottle, it is known to use a stopping device which comprises an elastomer stopper, the function of which is to ensure a totally gas-, liquid- and bacteria-tight seal. This device also comprises a capsule which, as mentioned in U.S. Pat. No. 5,314,084, can be made of plastic and is intended to be immobilized around the stopper to insulate it from the outside.
When the content of a container is freeze-dried, a drying procedure is applied to remove the water from the product by sublimation.
When a part of a cap has to be displaced to be locked around the neck of a container, friction occurs, the intensity of which varies according to the manufacturing tolerances of the constituent parts of the cap and the prepositioning of these parts when they are installed on the neck of the container. Thus, when a pressure plate is used to lock the caps of a large number of containers, given the manufacturing tolerances of the constituent parts of these caps and the operating plays of the pressure plate, some caps may not be locked correctly. Similarly, the dimensional variations of the containers themselves and of the stoppers used have a negative influence on the closure of a batch of containers. Given these difficulties, until now it has not been the practice to seal containers in batches inside a freeze-dryer, which imposes complex and therefore costly handling procedures when packaging freeze-dried products.
It is these drawbacks that the invention more particularly seeks to remedy by proposing a stopping device thanks to which a locking force for a bottle top can be effectively transmitted, including taking into account the manufacturing tolerances of the bottles, of the stoppers, of the constituent parts of a bottle top, and of the mechanical members for applying a force.
To this end, the invention relates to a device for stopping a container provided with a neck, this device comprising an elastomer stopper and a cap made of plastic, able to cover both the neck and the stopper in position in the neck, the cap comprising a ring, able to surround the stopper and the neck in the fitted configuration and provided with means for locking it onto the neck, and an operating member able to be fitted on the ring and provided with first means of transmitting a thrust force to the ring and second means of activating the ring locking means. This device is characterized in that the operating member is equipped with at least one deformable element for transmitting a thrust force, parallel to a central axis of the ring, between two parts of said member or between an external appliance and this member, and in that the force transmission element is deformable between a first configuration in which its length parallel to the central axis has a first value and a second configuration in which its length parallel to this axis has a second value less than the first value. Thanks to the invention, the thrust force exerted, for example, by a pressure plate is transmitted by the force transmission element or elements so as to allow for the bottle top to be effectively locked around the stopper, it being understood that, when this force has been effectively transmitted, the force transmission element can be deformed, from its first to its second configuration, so that it does not hamper the transmission of the force in stopping devices fitted on neighboring containers. Thus, it is possible to close containers belonging to a batch of containers thanks to a common force applied by means of a single pressure plate, even when there are dimensional variations between these containers, their stoppers and the associated caps, and even when the pressure plate may not be strictly flat.
According to advantageous but non-mandatory aspects of the invention, such a device can incorporate one or more of the following characteristics:
The invention also relates to a container equipped with a stopping device as described above. A container of this type is easier to stop than those of the prior art.
In a batch of containers of this type, provision is advantageously made for, after the force transmission elements have changed to their second configuration and the thrust force has been eliminated, the caps to be able, through elasticity, to assume one and the same configuration, which facilitates the subsequent inspection operations.
The invention finally relates to a method for closing a batch of containers as mentioned hereinabove, this method comprising steps consisting in:
Advantageously, in the step b), the value of the thrust force is gradually increased.
The invention will be better understood and other benefits of it will become more clearly apparent in light of the description below, given with reference to the appended drawings in which:
In
When a predetermined quantity of product P has been introduced into the bottle 1, the pipette is removed and a stopping device 500 is fitted on the neck 12. The device 500 comprises an elastomer stopper 501 of a shape suitable to be partially introduced into the throat 11, while resting on the face 13A of the collar 13 opposite to the bottom 14 of the bottle 1. In position in the neck 12, the stopper 501 insulates the content of the bottle 1 from the outside. The device 500 also comprises a cap 502 designed to cover and insulate the stopper and the neck 12 in the closed configuration of the stopping device.
As emerges more particularly from
The cap 502 also comprises an operating member 504 consisting of an annular part 505 made of plastic, that is referred to as a “key” hereinafter, and a cover 506, also made of plastic, attached reversibly to the key 505. The key 505 has an annular part 505A in the center of which is defined an opening 505B and which is extended by a skirt 505J. The portions 505A and 505J are centered on an axis X505 which is a central axis of the key 505.
The cover 506 bears a first lip 506A designed to be fixed on the edge 505B1 of the opening 505B and centered on a central axis X506 of the stopper 506.
The cover 506 is also provided with a second annular lip 506B which is engaged in the opening 505B, to bear against the top surface of the stopper 501, when the elements 505 and 506 are joined to form the member 504.
The key 505 is provided with a set of three elastic tongues 505C provided by the creation of three openings 505Q in the skirt 505J. 505D denotes the annular edge of the skirt 505J which is opposite to the part 505A.
Each tongue 505C is provided with an external rib or nose 505E which projects radially relative to the skirt 505J. Thus, each tongue 505C forms an elastic hook.
The distance, taken parallel to the axis X505, between the ribs 505E and the edge 505D, is denoted d1.
Moreover, the key 505 is provided with a peripheral collar 505R which projects radially relative to the skirt 505J and which extends continuously between two openings 505Q. The distance taken parallel to the axis X505, between the free edge 505R1 of the collar 505 and the edge 505D, is denoted d2. The value d2 is greater than the value d1.
The collar has an overall tapered form about the axis X505 and divergent moving away from the edge 505D.
As for the ring 503, it includes a peripheral annular skirt 503A, a first edge of which is denoted 503B. Inside the skirt 503A and opposite the edge 503B, an annular part 503C is provided that is overall perpendicular to a central axis X503 of the ring 503 and of the skirt 503A. The part 503C is extended, at the level of five angular segments distributed around the axis X503, by five connecting straps 503D which are connected to the internal surface of the skirt 503A in the vicinity of the edge 503B. The connecting straps 503D extend away from the internal surface of the skirt 503A, so that they define five individual elongate recesses 503E into which the skirt 505J of the key 505 can be inserted via the side of the ring 503 that bears the part 503C and that is visible in
In the angular segments where the part 503C is not prolonged by connecting straps 503D, five openings 503F are provided in each of which the skirt 505J can also be introduced when said skirt is introduced into the recesses 503E.
Facing each opening 503F, a locking tab or tongue 503G is provided which extends, from the internal face of the skirt 503A, radially toward the axis X503. The free edge of each tab 503G is denoted 503J. The ends of the connecting straps 503D and of the tabs 503G are positioned alternately, inside the skirt 503A and in the vicinity of the edge 503B.
The device 500 is assembled by fitting the cover 106 on the key 105, then by aligning the axes X505 and X506, already combined, with the axis X503 and by engaging the skirt 505J in an annular volume 503V defined between the skirt 503A, the connecting straps 503D and the locking tabs 503G. Given the annular nature of the edge 505D and of the volume 503V, the member 504 can be fitted on the ring 503 with no particular precautions as to its angular orientation about the axis X503. This facilitates the fitting of the cap 502 because this orientation does not need to be checked.
The internal face of the skirt 503A is provided with a peripheral groove 503L provided in the vicinity of the edge 503M of the skirt 503A opposite the edge 503B and adjacent to the part 503C. The groove 503L is configured to receive the ribs 503E of the tongues 505C when the member 504 is fitted on the ring 503. More specifically, when fitting the member 504 on the ring 503, the skirt 505J penetrates into the volume 503V through the openings 503F and the entry openings of the recesses 503E. The skirt 505 then advances toward the edge 503B until the ribs 505E of the tongues 505C are engaged in the groove 503L, which makes it possible to keep the member 504 at a distance from the part 503C, in the position represented in
It is then possible to partially introduce the stopper 501 to the neck 12, then to place the cap 502 on this stopper. In this configuration, the stopper 501 does not completely block the throat 11 since this stopper is provided with a lateral cut 501A providing an interstice 200 level with a part of the top face 13A of the throat 13.
The bottle 1 equipped with the device 500 can then be introduced into a freeze-dryer 300, within a batch of bottles 1. In
Inside the freeze-dryer 300, it is then possible, as represented in
When a force F′2 is exerted on the stopper 506 of a member 504, this force is transmitted by the cover 506 to the key 505 and the ribs 505E of the tongues 505C1 transmit this force to the ring 503 via the interaction between these ribs 505E and the groove 503L. The tongues 505C then act as thrusters, inasmuch as they make it possible to displace or thrust the ring 503 toward the bottom 14 of the bottle 1, under the effect of the force F′2, which makes it possible to achieve the configuration of
When the locking tabs 503G have passed the collar 13 and reached the position of
In the configuration of
Thus, the final placement of the cap 502 takes place in two steps. In the first step, the stopper 501 is put in place and the tabs 503G are folded back toward the skirt 503A to extend beyond the collar 13. In the second step, the tabs 503G are locked in position by the edge 505D.
Inasmuch as a number of bottles 1 are placed on one and the same shelf 303 inside the freeze-dryer 300, the individual force F′2 applied by the plate 301 to each cover 506 can vary given the dimensional tolerances of the constituent elements of the caps 500, the tolerances in the device for guiding and driving the plate 301 and the flatness of this plate. In order to avoid having some of the caps 502 remain in an intermediate position between the
More specifically, each stopper 506 is equipped with six tongues 506C which are made as a single piece with the rest of the stopper 506, evenly distributed about the axis X506 and extending from a face 506D of this cover which normally faces toward the part 505A of the key 505. Each tongue 506D has an elongate form in a direction parallel to the axis X506, with an overall parallelepipedal and constant section along its length. L506 denotes the length of a tongue 506C taken parallel to the axis X506 in its stress-free configuration of
When the cap 502 of a device with which one of the bottles 1 placed on a shelf 303 is equipped reaches the configuration of
As long as the edge 505D of the key 505 has not reached the position where it folds back the tongues 503G toward the neck 12, the individual reaction force r′2 exerted on each tongue 506C is of a relatively low intensity given the current displacement of the ring 505.
While the key 505 is being displaced inside the ring 503, between the configurations of
On the other hand, from the instant when the key 505 reaches the configuration of
When the force F′2, and consequently the individual forces f′2, exceed a predetermined value which depends on the geometry of the tongues 506C, these tongues buckle to successively reach the configurations represented in
In practice, each tongue 506C can be modeled like a beam of rectangular section having a free end 506C1 and an embedded end 506C2. This beam can withstand a buckling force until the latter exceeds a critical value f′0, the intensity of which is equal to
where E is the Young's modulus of the constituent material of the beam, I its quadratic modulus, L506 the length of the beam and K a coefficient at the limit conditions.
In the case in point, when a critical value f′0 is reached for the buckling force undergone by the different tongues 506C, each tongue 506C is deformed by buckling.
The thrust force f″2 then transmitted by each tongue 506C to the key 505 is of very low intensity, substantially lower than the force f′2, because the tongue is very flexible parallel to its thickness. The reaction force r″2 then exerted on the end face 506C1 of each tongue 506C is also of very low intensity, so that the resultant of the reaction forces of the key on the cover does not hamper the motion of the plate 301 toward the shelf 303.
The cover 506 is thus partially deformed toward the bottom 14 of the bottle 1, as represented in
Because of its collapse through buckling each tongue 506C can then slide over the part 505A to reach the configuration of
In practice, the forces f″2 and r″2 are negligible relative, respectively, to the forces f′2 and r′2. For clarity in the drawing, the representation of the forces f″2 and r″2 is enlarged in
L′506 and L″506 respectively denote the axial length of a tongue 506C in the configuration of
Because of the excess travel obtained by displacement of the external radial portion 506E of the stopper 506 between the configurations of
Thus, even if different forces may be needed to lock the different caps 502 onto the stoppers 501, notably because of the manufacturing tolerances and the plays in the driving of the plate 301, the transmission of the thrust forces F′2 between the different covers 506 and the different keys 505 by means of the tongues 506C makes it possible, thanks to their buckling, to ensure that all the caps 502 are effectively locked on completion of the travel of the plate 301.
Each cover 506 comprises a relatively bulky central portion 506F from which extend the lips 506A and 506B. This portion is linked by a flexible annular portion 506G to a rigid crown 506H, from which extend the tongues 506C. The crown 506H is rigidly linked to the external radial portion 506E of the cover 506 which is edged by the external peripheral edge 506M of the cover. Thanks to its deformable nature, the portion 506G enables the portions 506E, 506H and 506J to accompany the crushing motion of the tongues 506C after they have been buckled.
To allow for a good distribution of the force F2, taking into account the different positions that the bottles 1 can occupy on the shelf 303, the face 301A of the plate 301 facing toward this shelf is flat. Given the starting geometry of the stopper 506, a hollow volume V1 is provided between the portion 506F and the surface 301A, this hollow volume extending radially above the portions 506F, 506G and 506H, to the internal edge of the portion 506E.
Upon the collapse of the tongues 506C and the deformation of the portion 506G, the volume V1 is reduced. To prevent the cover 506 from adhering to the wall 301A by suction effect, grooves 506K are provided on the face 506L of the stopper opposite the face 506D, there being four of these grooves extending radially over the width of the portion 506E, so that they link the volume V1 to the edge 506M.
As can be seen in
Obviously, the number and the distribution of the grooves 506K can be modified within the framework of the present invention. In the first embodiment, the grooves 506K extend in directions that are radial relative to the axis X506. However, as represented in
On completion of the travel of the plate 301, all the caps 502 are effectively locked onto the corresponding bottles 1, the covers 506 being in the configuration of
Since all the stopping operations take place in a medium that is isolated from the outside, the stoppers 501 are kept sterile.
According to a variant of the invention which is % not represented, tongues similar to the tongues 506C can be provided on the top face of the annular part 505A of the key 505, in which case there is no need to provide tongues on the cover 506.
According to another variant partially represented in
As previously, these tongues 506C are deformed by buckling, under the effect of the force exerted by the pressure plate, when the key associated with the cover 506 has reached its position in which it locks the corresponding cap onto the bottle fitted with this cap.
When the content of the bottle 1 is to be used, the cover 506 is removed, as represented by the arrow F3 in
The materials used for the parts 503, 505 and 506, which are single-piece, are designed to retain their mechanical property over a range of temperatures between −80 and +120° C. It may be, for example, polyoxymethylene (POM) or polybutylene terephthalate (PBT).
The invention has been described in the case of use for a bottle whose content is freeze-dried. It can also be applied to the case where the content of the bottle is not freeze-dried. In this case, the stopper 501 can be put in place on the bottle 1 in a step immediately after it has been filled then the cap 502 can be put in place immediately after, within a sterile chamber that is not represented, and by an axial force, which also makes it possible to achieve a sealed configuration similar to that of
Number | Date | Country | Kind |
---|---|---|---|
07 00939 | Feb 2007 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR2008/000154 | 2/8/2008 | WO | 00 | 10/22/2009 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2008/129144 | 10/30/2008 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3926341 | Lhoest | Dec 1975 | A |
5314084 | Folta et al. | May 1994 | A |
5555988 | Koch et al. | Sep 1996 | A |
Number | Date | Country |
---|---|---|
WO 2005000703 | Jan 2005 | WO |
Number | Date | Country | |
---|---|---|---|
20100050575 A1 | Mar 2010 | US |