METHOD FOR ASSEMBLING A CONTAINER-MIXER COMPRISING A TELESCOPIC TREE

专利摘要:
A method of assembling a mixing vessel (1) for receiving a biopharmaceutical fluid (C), wherein: - a container (2) is provided the container (2) comprising: ○ a mixing device (7) ) having at least one shaft (8) having an adjustable length, ○ at least one first bearing (11) attached to the wall (3), the shaft (8) extending at least in the interior space (4) since the first bearing (11), - there is a rigid external device of contention (18) of the container (2), - one has a drive motor (9) located outside the container (2). the first bearing (11) of the container (2) spaced apart from the motor (9) is adjusted; the length of the shaft (8) is adjusted along the main axis (XX) by arranging the shaft (8); ) facing the motor (9) to allow the motor (9) to drive the shaft (8) in rotation.
公开号:FR3039776A1
申请号:FR1557500
申请日:2015-08-03
公开日:2017-02-10
发明作者:Sebastien Chaussin；Jeremy Gibelin；Stefan Zeuch；Michael Bates
申请人:Sartorius Stedim FMT SAS；
IPC主号:

专利说明:

The invention relates to the field of mixing vessels.
It relates more particularly to a method of assembling a mixing container for receiving a biopharmaceutical fluid for mixing, and such a mixing container.
"Biopharmaceutical fluid" means a product derived from biotechnology (culture media, cell cultures, buffer solutions, artificial nutrition liquids, blood products and derivatives of blood products) or a pharmaceutical product or, more generally, a product intended to be used in the medical field. The invention also applies to other products but subject to similar requirements as regards their packaging.
Container-mixers are known for mixing biopharmaceutical fluid. Such mixing containers comprise a rigid external restraining device forming a housing for receiving a disposable sterile container. The container includes a flexible wall defining an interior space to be filled with the biopharmaceutical fluid. The container also includes a mixing member attached to a downward shaft. The shaft is attached to the container at a level of a first bearing and a second bearing. The shaft of the container comprises at the level of the first bearing a disc having magnets that can be placed opposite a similar disk connected to a motor thus allowing the magnetic drive in rotation of the shaft under the effect of the engine. The shaft can rotate to allow mixing of the biopharmaceutical fluid.
Such magnetic training requires precise alignment and positioning of the magnetic disk of the shaft and the magnetic disk of the motor to ensure optimum training.
However, problems of geometric tolerances due to the dimensional variability inherent in the manufacture of the elements forming the mixing container, can lead to a bad positioning of the magnetic disks of the shaft and the engine facing each other during the installation of the container in the rigid external device of contention. Furthermore, during the mixing and heating of the biopharmaceutical fluid, for example from temperatures of the order of 30-40 degrees Celsius, an expansion of the plastic parts forming the mixing vessel may occur. This alters the arrangement and position of the first bearing of the shaft relative to the motor, leading to a malfunction of the mixing vessel. It is then necessary to be able to adjust the positioning of the first bearing relative to the engine.
It is thus known to use a motor whose position is adjustable in height. However, setting such an engine can be difficult. If the motor is positioned too low, the arrangement of the first bearing with the motor puts a stress on the shaft, which can cause a deflection or even breakage of the shaft. In addition, a set of axial flapping, of the order of 2 millimeters, is required between the first bearing and the magnetic disk of the motor to allow satisfactory operation of the container-mixer. A motor set too low does not allow the presence of this play of flapping, which generates abrasion at the level of the first bearing during the operation of the container-mixer,
On the contrary, if the motor is positioned too high, the wall of the container is under tension stress so that the motor and the first bearing can be positioned with each other. These stresses can degrade the wall of the container, or even lead to a tear resulting in a loss of the biopharmaceutical fluid.
Thus, the adjustment and the positioning of the motor can prove to be long and complicated to implement to obtain a satisfactory installation of the container in the rigid device of contention.
There are also known containers including trees of variable length, in particular to be able to fold the container by shortening the length of the tree and facilitate the storage of the container. By way of example, WO 2015/039034 discloses bioreactor support structures comprising a telescopic shaft that can be used with containers of various sizes and shapes.
US8951785 discloses an agitator for a bioreactor having a plurality of arms articulated together and pivotable about a transverse axis of rotation. The shaft can thus have an adjustable height by folding the articulated arms.
WO 2009/143925 discloses a container having two adjacent tree members having between them a hollow body in which one of the two elements of the shaft can slide. An elastic member is located between the hollow body and the filler body to allow transmission of rotational movement between the two members. An opening is formed in the wall of the hollow body to balance the pressure included in the hollow body and in the rest of the container. A gas-permeable hydrophobic membrane is placed in front of the opening to prevent container fluid from being introduced into the hollow body.
However, such a shaft is difficult to implement since it is necessary to provide a hydrophobic membrane on the opening of the hollow body. In addition, in the case of a circular shaft, the elastic element only transmits low rotational torque, preventing effective mixing of the fluid filling the container. The invention aims to solve the disadvantages described above and, more particularly, aims to optimize the placement of the container in the rigid external restraint device to allow a satisfactory mixing of the biopharmaceutical fluid. For this purpose, according to a first aspect, the invention relates to a method of assembling a mixing container intended to receive a biopharmaceutical fluid for the purpose of mixing it, in which: a container having a flexible wall is provided; defining an interior space capable of being filled with biopharmaceutical fluid, the container comprising: a mixing device comprising at least one shaft having an adjustable length along a main axis, at least one first bearing fixed to the wall, the shaft extending at least into the interior space from the first landing, - there is a rigid external device for restraining the container, - there is a drive motor located outside the container, the engine being adapted in order to rotate the shaft of the mixing device, the container is placed in the external rigid support device, the external rigid restraint device taking a bottom wall and a peripheral wall delimiting a housing adapted to receive the container, the flexible wall of the container being disposed on the bottom wall of the rigid external device of contention, and - the length of the shaft is adjusted according to the main axis by arranging the shaft opposite the motor to allow the motor to drive the shaft in rotation.
In various embodiments according to the present invention, one or more of the following arrangements, taken separately or in combination, may also be used, in which: the container is in a disassembled state; empty of biopharmaceutical fluid when it is placed in the rigid external device of contention; - The length of the shaft is adjustable on a stroke corresponding substantially to the axial size of the motor; - the shaft is located entirely in the interior space and in which the length of the shaft is adjusted along the main axis by positioning the first bearing facing the motor to allow the motor to drive the rotating shaft ; and the container also comprises a second bearing fixed to the wall and the second bearing is connected to the external rigid support device after having placed the container in the rigid external restraint device.
According to a second aspect, the invention relates to a mixing vessel intended to be assembled by the assembly method according to the invention, comprising: a container comprising a flexible wall delimiting an interior space capable of being filled with biopharmaceutical fluid, the container comprising: a mixing device comprising at least one shaft having an adjustable length along a main axis, at least one first bearing, the shaft extending at least in the interior space from the first bearing, an engine driving device located outside the container, the motor being adapted to rotate the shaft of the mixing device, and - a rigid external restraint device comprising a bottom wall and a peripheral wall defining a housing adapted to receive the container.
In various embodiments according to the present invention, one or more of the following arrangements, taken separately or in combination, may be used in addition, according to which: the motor is fixed relative to the device; rigid external restraint; - The motor is adapted to allow the magnetic drive of the shaft and comprises a rotary disk driving located outside the container, the rotating rotary disc cooperating functionally with a driven rotating disk fixed to the shaft; - The first bearing comprises a flange, the flange comprising an outer annular collar, the motor being connected with the collar of the flange; and - a bioreaction is carried out, the mixing vessel being a bioreactor.
According to a third aspect, the invention relates to a container intended to be assembled to a motor according to the assembly method in order to form a mixing container according to the invention.
In various embodiments according to the present invention, one or more of the following arrangements, taken separately or in combination, may be used in addition, depending on which: - the whole tree is situated in the interior space; - the shaft is crossing at the first level; the shaft supports and drives at least one mixing member capable of mixing the biopharmaceutical fluid located in the interior space; the shaft supports and drives a plurality of mixing members located at a plurality of axial locations on the shaft; the container has a capacity of between 50 liters and 200 liters; and - the container is for single use.
According to a fourth aspect, the invention relates to a mixing device comprising a shaft of adjustable length extending between a first bearing and a second bearing, each of the first bearing and the second bearing being fixed to the flexible wall of a container according to the invention. 'invention.
In various embodiments according to the present invention, it may further be possible to use one and / or the other of the following provisions, taken separately or in combination, according to which: the tree comprises at least a first part and a second part movable in translation relative to each other along the main axis; the first part comprises an element adapted to slide in a rectilinear slot of the second part of the shaft; - the slit crosses on both sides the second part of the tree; - The slot has a length of between 1 and 10 centimeters, even equal to 5 centimeters; and the first part and the second part of the shaft are integral in rotation.
Several embodiments of the invention will now be described with the aid of the drawings, in which:
Figure 1 is a perspective view of a possible embodiment of a container-mixer according to the invention showing the rigid external device contention;
Figure 2 is another perspective view of the rigid outer container device of the mixing container of Figure 1;
Figure 3 is a side view of a container to be placed in the rigid outer restraining device of Figures 1 and 2;
Figure 4 is a sectional view along the plane IV-IV of the container of Figure 3, positioned relative to a motor;
Figures 5A and 5B are enlarged views of the shaft of the mixing device at the first bearing of Figure 4 in two different arrangements; and
Figure 6 is a schematic sectional view of the container placed in the outer rigid device of contention of the container-mixer in operating condition, in particular in an assembled state filled.
A mixing vessel 1 according to the invention is intended to receive a biopharmaceutical fluid C, for the purpose of mixing it or, if appropriate, for a chemical and / or biological reaction (or bioreaction), the mixing vessel 1 being then a bioreactor.
The biopharmaceutical fluid C comprises one or at least one liquid phase. Where appropriate, the biopharmaceutical fluid C is made from several components of which at least one is in the liquid phase and one or more of which may be in the solid phase, such as powder.
The mixing vessel 1 has a main axis XX, vertical. The mixer-container 1 comprises, on the one hand, a container 2 and, on the other hand, an external rigid support device 18.
As represented in FIG. 3, the container 2 is formed by a wall 3, advantageously made of plastic material, flexible and leakproof to the biopharmaceutical fluid C. The wall 3 of the container 2 may comprise a lower part 3a, a lateral part 3b and a part upper 3c, for example formed by one or more sections joined together, welded, with each other. The container 2 thus delimits an interior space 4, advantageously sterile, capable of receiving a certain quantity of the biopharmaceutical fluid C. The wall 3 may be totally or partially transparent or translucent in order to be able to visualize from the outside the biopharmaceutical fluid C in the interior space 4.
In one embodiment, the container 2 is disposable.
The container 2 can have a capacity of up to 5,000 liters, depending on the needs and applications. The container 2, however, preferably has a capacity of between 10 and 500 liters, or even between 50 and 200 liters.
The words "vertical", "horizontal", "upper", "lower" refer to the situation in which the mixing vessel 1, and in particular the container 2, is in a position suitable for its operation. However, it is understood that the mixing container 1 and the container 2 may occupy other positions or have other states, for example because they are not in operation. The word "vertical" should not be understood in a narrow sense, but in the sense meaning from the highest to the lowest and vice versa. On the other hand, the words "inside" and "outside" refer respectively to what is in the interior space 4 and outside the container 2.
Finally, the words "axial" on the one hand, "radial" and "transverse" on the other hand, refer to what extends in or parallel to or substantially parallel to the main axis XX on the one hand, and perpendicularly or orthogonally or substantially perpendicularly or orthogonally to the main axis XX on the other hand.
The mixer-container 1 may comprise one or more through-ports for introduction into the container 2 of the biopharmaceutical fluid C, or components of the biopharmaceutical fluid C, cooperating with one or more introduction orifices provided in the container 2.
The mixer-container 1 may also comprise at least one through-port 6 for emptying the biopharmaceutical fluid C from the container 2, cooperating with at least one emptying orifice formed in the container 2. The emptying port 6 is able to be closed at each when necessary and on the contrary open for emptying.
"Port" means a means of connection or physical connection. Such a port is through when it is a question of ensuring a function of communication between the interior space 4 and the outside of the container 2, for example for the introduction or the emptying of what must be placed or is placed in the container 2. Such a port can also be non-traversing when it comes to ensuring a function of maintaining an organ of the container-mixer.
Pipes, pockets, tanks, where appropriate flexible, may be associated with the introduction port 5, in fluid communication and with a sealed connection and optionally removable. Similarly, ducts, pockets, tanks, where appropriate flexible may be associated with the drain port 6, in fluid communication and with a waterproof connection and if necessary removable.
In the embodiment shown in FIGS. 3 and 4, the introduction port 5 is situated in the upper part 3c of the wall 3, while the emptying port 6 is situated in the lower part 3a of the container 2, in particular in the lowest position of the container-mixer 1. However, this embodiment is not limiting and one or more ports of introduction 5 may be located in the lower part 3a or in the lateral part 3b of the container 2.
The mixing vessel 1 may also comprise a ventilation device 13 capable of delivering a certain quantity of aeration gas to the biopharmaceutical fluid C. This device 13 thus allows the aeration of what is in the interior space 4 of the container 2, whether the biopharmaceutical fluid C, or a part of its components.
The ventilation device 13 may comprise a ventilation gas supply device 14 having at least one tubular element 14a extending with fluid communication from the outside of the container 2. At the aeration device 13 which has just may be described may be functionally associated with at least one ventilation gas discharge port 36 formed in the upper part 3c of the wall 3 of the container 2. Such a venting air outlet port 36 allows the evacuation of container 2, to the outside, the gas which has not been mixed with the biopharmaceutical fluid C of the container 2.
In some embodiments, the mixer-container 1 may also include other ports known per se, for example for mounting a functional means, capable of ensuring the maintenance of an organ such as typically the collection or measurement of data. , or taking samples for analysis.
The mixer-container 1 also comprises a device 7 for mixing the biopharmaceutical fluid C with the container 2. This mixing device 7 allows the mixing of what is in the interior space 4 of the container 2, whether it is the biopharmaceutical fluid C, or a part of its components.
The mixing device 7 comprises at least one descending shaft 8, able to be driven, in particular magnetically, in rotation by a motor 9 and to rotate at least one mixing member 10. The mixing member (s) 10 are substantially spaced apart of the lower part 3a and of the lateral part 3b of the wall 3 of the container 2. As shown in FIGS. 3, 4 and 6, the mixing member 10 may be in the form of a propeller having a supporting hub several blades. The shaft 8 according to the invention is adjustable in length. According to the embodiment shown in the figures, the shaft 8 is thus formed of two parts 24, 25. A first portion 24 extends between the lower end 8a to an intermediate connection zone 26, while the second part 24 25 extends from the connecting zone 26 to the upper end 8b.
As shown in more detail in FIGS. 5A and 5B, the first portion 24 of the shaft 8 at the connection zone 26 comprises an element 27, such as a key, housed in a slot 28 of the second portion 25. of the shaft 8. The slot 28 extends in particular in a rectilinear manner along the main axis XX. The slot 28 crosses in particular on both sides the second portion 25 of the shaft 8. The element 27 then has a particular flattened shape, including square, to pass through the slot 28 through the second part 25 of the tree 8.
The first part 24, in particular the element 27, is adapted to slide in the second part 25 of the shaft 8 along the main axis XX. As shown in Figures 5A and 5B, the slot 28 has a length lf, for example between 1 and 10 centimeters, preferably equal to about 5 centimeters. In particular, the length lf can be adapted according to the size of the container 2. Thus, the shaft 8 is adjustable in length between a fully extended position and a fully retracted position. In the fully retracted position, as shown in FIG. 5B, the shaft 8 has a minimum height, the first part 24, in particular the element 27, abutting with the second part 25 of the shaft 8. element 27 is adapted to slide continuously in the slot 28. The shaft 8 may have a continuously adjustable length and non-discrete, for example in case of expansion of certain elements of the mixing vessel 1 during mixing.
In addition, because the element 27 protrudes into the slot 28, the first portion 24 and the second portion 25 of the shaft 8 are integral in rotation, especially when they are subjected to high torque.
In addition, because the shaft 8 has an adjustable length, the motor 9 can be fixed relative to the external compression device 18, and it is not necessary that it has an adjustable positioning, especially in height so to place the shaft 8 facing the motor 9 to allow the rotation of the shaft 8 as will be described below.
The container 2 also comprises at least a first bearing 11, adjacent to the upper part 3c of the wall 3, with which the upper part 8b of the shaft 8 cooperates.
The first bearing 11 comprises a rigid flange 16. The term "flange" here means a rigid piece generally shaped solid wall, at least substantially flat, placed flat, and intended for maintenance. This flange 16 is fixed rigidly and tightly to the upper part 3c of the wall 3 of the container 2.
More specifically, the flange 16 is formed of a substantially rigid material, preferably a rigid plastic material in the form of a wall or wafer connected to the container 2, in the center of the upper part 3c. This flange 16 may be connected to the wall 3 of the container 2 in any appropriate manner so as to form a rigid and hermetic seal between the respective rigid and flexible materials of the flange 16 and the wall 3.
According to a first embodiment, the shaft 8 of the mixing device 7 is located entirely in the interior space 4. Thus, the shaft 8 extends rectilinearly between a lower end 8a and an upper end 8b. When the mixer-container 1 is in a position suitable for its operation, the shaft 8 extends vertically along the main axis XX, the lower end 8a being located towards the lower part 3a of the container 2 while the 8b upper end is located towards the upper part 3c of container 2, in particular connected to the first bearing 11. The first bearing 11 is then adapted to be positioned relative to the engine 9 located outside the container 2.
According to the first embodiment shown for example in FIGS. 5A and 5B, the drive motor 9 allows the magnetic drive in rotation of the shaft 8. For this purpose, the motor 9 comprises a rotary drive disk 30 located at the outside of the container 2. The shaft 8 then comprises a driven rotating disk 15 intended to functionally cooperate, in particular magnetically, with the driving rotary disk 30 of the engine 9. More particularly, the driven rotary disk 15 comprises a plurality of magnets 17, which are integrated by any fixing or construction means, in order to allow the rotation of the shaft 8 during the rotation of the rotary disk driving the motor 9.
The driven rotary disk 15 is integral, in particular in rotation, with the shaft 8, in particular the second portion 25 of the shaft 8. For example, the driven rotary disk 15 is fixed to the upper end 8b of the 8 by screwing a threaded end of the shaft 8 into a threaded opening within the driven rotating disk 15. Other means, such as adhesive elements, fasteners, quick fasteners, locks, welding, and the like As well as the formation of the rotating disc driven directly by molding with the shaft 8 during its manufacture, can be used to secure the driven rotary disc 15 to the shaft 8, without limitation.
In addition, the driven rotary disk 15 is connected to the first bearing 11, in particular to the flange 16, so as to allow the motor 9 to act on the magnets 17 of the driven rotating disk 15. Thus, the flange 16 is connected to the 8 in the interior space 4 of the container 2 via the driven rotating disc 15. In particular, the shaft 8 and the driven rotating disc 15 are mounted to rotate about the main axis XX relative to the first bearing 11, so that the driven rotary disc 15 can rotate relatively freely relative to the flange 16. For this purpose, it can be provided to include ball bearing or roller elements between the driven rotating disc 15 and the first bearing 11.
In the operating state, the first bearing 11 is positioned, in particular assembled, with respect to the motor 9. The rotating rotary disk 30 of the motor 9 and the driven rotating disk 15 are then arranged opposite one another, each side of the first bearing 11. It can be provided a flapping game between the rotary drive disc 30 and the first bearing 11, for example of the order of 2 millimeters, to facilitate the rotation of the first bearing 11 relative to the engine 9.
The first bearing 11, in particular the flange 16, comprises for example an outer annular flange 16a having a radial radial bead extending laterally outwardly and limiting inwardly a cavity 16b of the flange 16. The motor 9 can be positioned relative to the flange 16 and in particular with the collar 16a fixedly in translation. In particular, the rotating rotary disc 30 of the motor 9 is intended to be disposed in the cavity 16b of the flange 16 as shown in FIGS. 5A and 5B.
As shown in FIG. 6, a clamp 22 acting as a flange makes it possible to connect the flange 16 with the motor 9. Such a gripper conventionally comprises a handcuff and is known as a "tri-clamp" gripper. The clamp 22 is adapted and intended to be clamped on the motor 9 and the flange 16a of the flange 16 while holding them in translation to prevent their inadvertent disassembly. However, the motor 9 remains rotatable relative to the first bearing 11 around the main axis XX. Thus, the rotating driving disc 30 of the motor 9 can rotate the driven rotating disc 15.
According to a second embodiment not shown in the figures, the shaft 8 may be partially located outside the container 2. According to this embodiment, the shaft 8 passes through the container 2, in particular at the first level 11 tightly. The driven rotating disk 15 of the shaft is then located outside the container 2 and is intended to functionally cooperate, in particular magnetically, with the rotating rotary disk 30 of the engine 9.
According to this embodiment, the connection zone 26 of the shaft 8 can be located outside the container 2. The length of the shaft 8 can thus be easily adjusted from the outside of the container 2 by the user of the mixer-container 1, which makes it possible to obtain a container 2 that is simple to use and economical to produce. In addition, the connection zone 26 is then easier to access, which facilitates its sterilization before use of the container 2.
The mixing vessel 1 may also comprise, because of the flexible nature of the container 2, a rigid, possibly semi-rigid, external containment device 18 of the container 2 filled with its biopharmaceutical fluid C during filling, mixing and emptying .
The rigid external contention device 18 comprises a bottom wall 19 and a peripheral wall 20 delimiting a housing in which the container 2 is removably placed. The bottom wall 19 has for example a rounded crown shape, for example hemispherical or pseudo hemispherical, However, the external rigid contention device 18 may have any other shape, such as cylindrical, parallelepiped or other.
The lower part 3a of the wall 3 of the container 2 rests on the bottom wall 19, while the lateral part 3b of the wall 3 of the container 2 is applied, when the container 2 is filled with biopharmaceutical fluid C, against the peripheral wall 20. The rigid external contention device 18 is generally of geometry, shape and / or dimension identical to the container 2, in order to reduce the stresses or the mechanical stresses on the wall 3 of the container 2.
The rigid external contention device 18 may comprise an access opening 21 in order to allow the introduction and the removal of the container 2. Where appropriate, the rigid external contention device 18 comprises a closure means, such as doors, in order to alternatively allow the opening or closing of the access opening 21.
According to one embodiment, the external rigid contention device 18 comprises other openings for introducing the biopharmaceutical fluid C or the components of the biopharmaceutical fluid C and draining the biopharmaceutical fluid C, or to access the different elements of the container 2 which must be accessible for use.
The motor 9 is advantageously placed above the rigid external contention device 18, in a fixed manner. As shown more particularly in FIGS. 1 and 2, the motor 9 may in particular be fixed to a holding arm 23 comprising a transverse part 23a. Due to this transverse portion 23a of the holding arm 23, the motor 9 is more particularly centered above the rigid external contention device 18 along the main axis XX.
According to one embodiment, the external rigid contention device 18 also comprises a heating and / or cooling device for heating and / or cooling the biopharmaceutical fluid C of the container 2. In this case, the rigid external restraint device 18 and or the container 2 are made of a material having a certain thermal conductivity, so that the implementation of the heating device and / or cooling allows the heating and / or cooling of the biopharmaceutical fluid C. In this case, and if necessary, there is also provided a device for controlling the temperature of the contents in the container 2 and a device for controlling the heating and / or cooling device. Such a temperature control device can be carried by one or more ports provided for this purpose.
The container 2 may comprise a single first bearing 11, to be positioned relative to the motor 9. However, in a variant, the container 2 may further comprise a second bearing 12, adjacent to the lower part 3a of the wall 3, with which cooperates the lower part 8a of the shaft 8. In the same way as the first bearing 11, the second bearing 12 is connected to the wall 3 of the container 2 to form a rigid and sealed seal with the lower part 3a of the wall 3 For this purpose, the second bearing 12 comprises a flange (this term to be understood as above) fixed rigidly and tightly to the lower part 3a of the wall 3 of the container 2.
The container 2 is then connected at the level of the second bearing 12 to the external compression device 18. According to the first embodiment described above in which the shaft 8 of the mixing device 7 is located entirely in the interior space 4 it is thus possible to adjust the size of the container 2 by adjusting the length of the shaft 8 which extends between the first bearing 11 and the second bearing 12.
The container 2 can be in three distinct states in relation to the rigid external contention device 18: an empty disassembled state, in which the container 2 is disassembled from the external rigid support device 18 and is not positioned relative to the In this state, the container 2, which is flexible as a whole, while empty of the biopharmaceutical fluid C, can be arranged flattened on itself. This state is particularly useful for storage or transport; an empty assembled state, in which the container 2 is assembled to the external rigid contention device 18, the container 2 being empty of the biopharmaceutical fluid C. In this state, the container 2 is disposed in the housing of the compression device 18 while resting on the bottom wall 19. In particular, the term "assembly" means that the container 2 functionally interacts with the engine 9. However, such an assembly is not limited to a direct contact between the container 2 and the engine 9. these elements can be assembled according to the invention while being spaced apart from each other, for example in the context of a magnetic drive; and - and finally, a partially or completely filled assembled state, in which the container 2 is assembled to the external rigid contention device 18 and positioned relative to the motor 9, the container 2 being filled with biopharmaceutical fluid C. In this state, the mixing vessel 1 is operable to allow mixing of the biopharmaceutical fluid C.
The method of assembly of a mixing vessel 1 according to the first embodiment is described below, in particular to pass between the different states of the container 2 described above.
It starts from a mixing container 1 whose container 2 is in a disassembled state of the external rigid support device 18, as well as empty of biopharmaceutical fluid C and arranged more or less flattened on itself.
The container 2 is placed in the housing to the external rigid support device, resting on its bottom wall 19.
The second bearing 12 of the container 2 is connected with the external rigid support device 18, for example with an opening 29 located in the center of the bottom wall 19.
The first bearing 11 of the container 2 is then positioned with respect to the motor 9. The bag 3 of the container 2 is thus brought to the level of the motor 9. The shaft 8 is then in an at least partially retracted position. Because the shaft 8 is adjustable in length, it is possible firstly to place the upper end 8b, in particular the first bearing 11, away from the motor 9. The first bearing 11 may in particular be placed in the immediate vicinity of the motor 9, for example at a distance from the motor 9 less than the length lf of the slot 28. The driven rotary disc 15 is then located opposite the motor 9. The length of the shaft 8 is then increased so that the first bearing 11 is positioned opposite the engine 9, in particular connected without friction and with a flapping game between the rotary drive disc 30 of the motor 9 and the first bearing 11, so that the motor 9 can rotate easily.
In order to adjust the length of the shaft 8, the sliding of the two parts 24, 25 of the shaft 8 between them can be performed manually or with any other tool allowing such sliding. Thus, it is not necessary when connecting the first bearing 11 with the motor 9, to vary the position of the motor 9. The container 2 is thus assembled more easily and optimally with the external rigid support device 18.
The motor 9 is connected with the flange 16a of the flange 16 integrally in translation through the clamp 22 (handcuff tri-clamp) acting as a flange. Thus arranged, the rotary disk driving the motor 9 is able to drive in rotation the driven rotating disk 15, and therefore the shaft 8 of the mixing device 7. FIG. 6 represents in particular the container 2 thus arranged with the rigid external device of FIG. contention 18 and the engine 9.
Alternatively, it is possible to connect the first bearing 11 of the container 2 with the motor 9 before connecting the second bearing 12 with the rigid external contention device 18.
The biopharmaceutical fluid C is introduced into the container 2, in particular through the introduction port 5.
Finally, the mixing device 7 is used to stir the biopharmaceutical fluid C of the container 2 in the interior space 4. Where appropriate, the length of the shaft can be adjusted to ensure optimal relative positioning of the motor. 9 and the first landing 11.
Moreover, in the context of a bioreaction process, the ventilation device 13 is used to deliver a certain amount of aeration gas to the contents of the container 2 in the interior space 4. Stirring and aeration are performed at least partially simultaneously, if necessary, completely simultaneously.
Following the mixing of the biopharmaceutical fluid C and its emptying, in particular through the emptying port 6, the container 2 is disassembled from the external rigid contention device 18. The container 2 is then discarded, the latter being disposable.
The process described above can be carried out partially, the steps described above being able to be carried out independently of one another. In particular, the container 2 can be placed in the rigid external contention device 18 while it is already filled with biopharmaceutical fluid C.
Of course, the invention is not limited to the embodiments described above and provided solely by way of example. It encompasses various modifications, alternative forms and other variants that may be considered by those skilled in the art in the context of the present invention and in particular any combination of the different modes of operation described above, which can be taken separately or in combination.

权利要求:
Claims (21)
[1" id="c-fr-0001]
A method of assembling a mixing vessel (1) for receiving a biopharmaceutical fluid (C) for mixing, wherein: - a container (2) having a flexible wall (3) is provided defining an interior space (4) capable of being filled with biopharmaceutical fluid (C), the container (2) comprising: o a mixing device (7) comprising at least one shaft (8) having an adjustable length along a main axis ( XX), o at least a first bearing (11) fixed to the wall (3), the shaft (8) extending at least in the interior space (4) from the first bearing (11), - there is a rigid external device for restraining (18) the container (2), - a driving motor (9) is located outside the container (2), the motor (9) being adapted to drive in rotation the shaft (8) of the mixing device (7), the container (2) is placed in the external rigid support device (18), the device rigid outer contention container (18) comprising a bottom wall (19) and a peripheral wall (20) delimiting a housing adapted to receive the container (2), the flexible wall (3) of the container (2) being disposed on the bottom wall (19) of the rigid external contention device (18), and - the length of the shaft (8) is adjusted along the main axis (XX) by placing the shaft (8) facing the motor ( 9) to allow the motor (9) to drive the shaft (8) in rotation.
[2" id="c-fr-0002]
2. Method according to the preceding claim, wherein the container (2) is in an empty disassembled state of biopharmaceutical fluid (C) when it is placed in the rigid external device of contention (18).
[3" id="c-fr-0003]
3. Method according to claim 1 or 2, wherein the length of the shaft (8) is adjustable over a stroke corresponding substantially to the axial size of the motor (9).
[4" id="c-fr-0004]
4. Method according to any one of claims 1 to 3, wherein the shaft (8) is located entirely in the interior space (4) and the length of the shaft (8) is adjusted along the axis main (XX) by positioning the first bearing (11) facing the motor (9) to allow the motor (9) to drive the shaft (8) in rotation.
[5" id="c-fr-0005]
5. A method according to any one of the preceding claims, wherein the container (2) also comprises a second bearing (12) fixed to the wall (3) and the second bearing (12) is connected to the rigid external compression device ( 18) after placing the container (2) in the rigid outer contention device (18).
[6" id="c-fr-0006]
6. Mixing container (1) intended to be assembled by the assembly method according to any one of the preceding claims, comprising: - a container (2) comprising a flexible wall (3) delimiting an interior space (4) capable of to be filled with biopharmaceutical fluid (C), the container (2) comprising: o a mixing device (7) comprising at least one shaft (8) having an adjustable length along a main axis (XX), o at least a first bearing (11), the shaft (8) extending at least in the interior space (4) from the first bearing (11), - a drive motor (9) located outside the container (2) ), the motor (9) being adapted to rotate the shaft (8) of the mixing device (7), and - a rigid external restraining device (18) comprising a bottom wall (19) and a peripheral wall (20) delimiting a housing adapted to receive the container (2).
[7" id="c-fr-0007]
7. The mixing vessel (1) according to claim 6, wherein the motor (9) is fixed relative to the rigid external contention device (18).
[8" id="c-fr-0008]
The mixing vessel (1) according to any one of claims 6 to 7, wherein the motor (9) is adapted to allow the magnetic drive of the shaft (8) and comprises a rotary drive disk (30). located outside the container (2), the rotating rotary disk (30) cooperating functionally with a driven rotating disk (15) fixed to the shaft (8).
[9" id="c-fr-0009]
Mixer-container (1) according to any one of claims 6 to 8, wherein the first bearing (11) comprises a flange (16), the flange (16) comprising an outer annular flange (16a), the motor (9) being connected with the flange (16a) of the flange (16).
[10" id="c-fr-0010]
Container (2) having a flexible wall (3) delimiting an interior space (4) capable of being filled with biopharmaceutical fluid (C), the container (2) comprising: - a mixing device (7) comprising at least one shaft (8) having an adjustable length along a main axis (XX),. - at least a first bearing (11) fixed to the wall (3), the shaft (8) extending at least in the interior space (4) from the first bearing (11), the container (2) being intended to be assembled with a motor (9) according to the method of assembly of claims 1 to 5 to form a mixing vessel (1) according to one of claims 6 to 9.
[11" id="c-fr-0011]
11. Container (2) according to claim 10, wherein the shaft (8) is located entirely in the interior space (4).
[12" id="c-fr-0012]
12. Container (2) according to claim 10, wherein the shaft is bent through at the first bearing (11).
[13" id="c-fr-0013]
13. Container (2) according to any one of claims 10 or 12, wherein the shaft (8) supports and drives at least one mixing member (10) capable of mixing the biopharmaceutical fluid (C) located in the interior space (4).
[14" id="c-fr-0014]
14. Container (2) according to any one of claims 10 to 13, wherein the shaft (8) supports and drives a plurality of mixing members (10) located in a plurality of axial locations on the shaft (8).
[15" id="c-fr-0015]
15. Container (2) according to any one of claims 10 to 14, having a capacity of between 50 liters and 200 liters.
[16" id="c-fr-0016]
Mixing device (7) comprising a shaft (8) of adjustable length extending at least between a first bearing (11) and a second bearing (12), each of the first bearing (11) and the second bearing (12). being attached to the flexible wall (3) of a container (2) according to any one of claims 10 to 15. "
[17" id="c-fr-0017]
17. Device (7) according to claim 16, comprising at least a first portion (24) and a second portion (25) movable in translation relative to each other along the main axis (XX) of the tree (8).
[18" id="c-fr-0018]
18. Device (7) according to claim 17, wherein the first portion (24) comprises a member (27) adapted to slide in a straight slot (28) of the second portion (25) of the shaft (8).
[19" id="c-fr-0019]
19. Device (7) according to claim 18, wherein the slot (28) passes through both sides of the second portion (25) of the shaft (8).
[20" id="c-fr-0020]
20. Device (7) according to claim 18 or 19, wherein the slot (28) has a length (lf) of between 1 and 10 centimeters, or even equal to 5 centimeters.
[21" id="c-fr-0021]
21. Device (7) according to any one of claims 17 to 20, wherein the first portion (24) and the second portion (25) of the shaft (8) are integral in rotation.

类似技术:

---

公开号 | 公开日 | 专利标题

---

WO2017021653A1|2017-02-09|Mixer-container and method for assembling a mixer-container including a telescopic shaft

---

EP2254687B1|2012-05-09|Mixing vessel

---

EP0553190B1|1994-10-05|Mixing bowl for a planetary centrifugal mixer and mixer receiving such bowls

---

WO2010106282A1|2010-09-23|Mixing container comprising a shaft bearing in the upper part

---

EP2146904B1|2011-07-06|Package for food product taken out with a measuring device

---

EP2259980B1|2012-02-08|Large liquid container forbiopharmaceutical applications

---

EP2800806B1|2016-05-25|Container for biopharmaceutical content

---

EP0328590B1|1991-10-09|Auxiliary work bowl for kitchen mixer

---

US20180304216A1|2018-10-25|Post/Pedestal-Mounted IBC Mixing/Blending Machine

---

EP1868901A1|2007-12-26|Multiple pivoting flask

---

EP2588591B1|2015-03-18|Device for sensing a parameter related to an electrical phenomenon of a biopharmaceutical content and biopharmaceutical container comprising such a sensing device

---

EP3651889B1|2021-07-28|Fluid agitating device and lid equipped with such an agitating device

---

EP1011333B1|2001-10-24|Machine for making and storing natural liquid leaven

---

EP1050335B1|2003-11-26|Spherical mixer

---

EP2179787A1|2010-04-28|Device with mixing vessel

---

EP2179648B1|2014-12-03|Assembly for the preparation of organs to be transplanted

---

EP1571103A1|2005-09-07|Dispensing device

---

EP3890678A1|2021-10-13|Biopharmaceutical liquid reservoir with mechanical member including rotating and stationary sets of parts

---

FR3057251A1|2018-04-13|PACKAGING CONTAINER WITH IMPROVED DISCHARGE SPEED OF CAPSULE-LIKE CONTENT

同族专利:

---

公开号 | 公开日

---

CN107921387B|2021-02-09|

---

US20180221838A1|2018-08-09|

---

WO2017021653A1|2017-02-09|

---

EP3331637A1|2018-06-13|

---

FR3039776B1|2017-08-25|

---

US10456761B2|2019-10-29|

---

US10702838B2|2020-07-07|

---

US20190329197A1|2019-10-31|

---

CN107921387A|2018-04-17|

---

CN112844138A|2021-05-28|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

DE202007005868U1|2006-05-10|2007-07-19|Sartorius Ag|One-way bioreactor for cultivating cells, includes flexible walls, side wall, bottom part and cover part limiting the reactor interior, in which rotation mixer comprising mixing element and mixer shank arranged at the cover part is arranged|

---

DE202009005407U1|2008-04-17|2009-09-17|Sartorius Stedim Biotech Gmbh|Flexible bag with a mixing device|

---

DE102008058338A1|2008-11-20|2010-05-27|Sartorius Stedim Biotech Gmbh|Stirrer for bioreactor|CN113509875A|2021-05-10|2021-10-19|清华大学|Electric drive magnetic force rotating stirring device|DE2017472A1|1970-04-11|1971-11-04|Roehm Gmbh|Magnetic agitator for small vessels|

---

US7153021B2|2003-03-28|2006-12-26|Hyclone Laboratories, Inc.|Container systems for mixing fluids with a magnetic stir bar|

---

SE531572C2|2006-04-05|2009-05-26|Millipore Ab|Disposable unit for process products|

---

FR2921905B1|2007-10-04|2012-09-28|Sartorius Stedim Biotech|CONTAINER FOR PROCESSING AND / OR CONTROLLING PRODUCTS COMPRISING A CHAMBER FOR PROTECTING MEANS OF PROCESSING AND / OR CONTROLLING THESE PRODUCTS, AND CONTAINER COMPRISING SUCH A CONTAINER|

---

US7832922B2|2007-11-30|2010-11-16|Levitronix Gmbh|Mixing apparatus and container for such|

---

DE102007060291B4|2007-12-12|2011-04-28|Sartorius Stedim Biotech Gmbh|Container arrangement with a container with flexible wall|

---

DE102007061664B4|2007-12-18|2009-11-19|Sartorius Stedim Biotech Gmbh|Container with flexible wall|

---

WO2009122310A2|2008-03-19|2009-10-08|Sartorius Stedim Biotech Gmbh|Disposable mixing vessel|

---

FR2929253B1|2008-03-28|2013-09-13|Sartorius Stedim Biotech Sa|RIGID FRAME FOR 3D CONTAINER CONTAINING AT LEAST PARTIALLY DEFORMABLE|

---

FR2933881B1|2008-07-16|2011-05-27|Sartorius Stedim Biotech Sa|MIXING IN A CONTAINER OF A CONTENT HAVING A BASE COMPONENT AND A MIXING COMPONENT|

---

US8851785B1|2009-11-17|2014-10-07|Trw Automotive U.S. Llc|Ball joint|

---

US8960486B2|2010-06-16|2015-02-24|Life Technologies Corporation|Fluid mixing system with hangers|

---

FR2962224B1|2010-07-02|2013-05-10|Sartorius Stedim Biotech Sa|SENSOR DEVICE OF A PARAMETER RELATED TO AN ELECTRIC PHENOMENON OF A BIOPHARMACEUTICAL CONTENT AND A BIOPHARMACEUTICAL CONTAINER HAVING SUCH A SENSOR DEVICE.|

---

FR2969506B1|2010-12-22|2013-02-15|Sartorius Stedim Biotech Sa|MIXING THE CONTENTS OF A FLEXIBLE CONTAINER FOR BIOPHARMACEUTICAL USE.|

---

EP3922712A3|2011-10-25|2022-03-09|Life Technologies Corporation|Fluid mixing systems with adjustable mixing element|

---

FR2985518B1|2012-01-05|2014-02-07|Sartorius Stedim Biotech Sa|CONTAINER FOR BIOPHARMACEUTICAL CONTENT.|

---

US9700857B1|2012-03-23|2017-07-11|Life Technologies Corporation|Fluid mixing system with drive shaft steady support|

---

US9839886B2|2012-04-06|2017-12-12|Life Tehnologies Corporation|Fluid mixing system with flexible drive line and foldable impeller|

---

WO2014116165A1|2013-01-23|2014-07-31|Ge Healthcare Bio-Sciences Ab|Magnetic agitator mixing system and an agitator mixing stand|

---

DE102013002091B3|2013-02-05|2014-05-28|Sartorius Stedim Biotech Gmbh|Container, transport device, use and method|

---

DE102013106680B3|2013-06-26|2014-08-14|Sartorius Stedim Biotech Gmbh|container|

---

EP3046644A4|2013-09-16|2017-08-09|F.Hoffmann-La Roche Ag|Bioreactors with multiple or adjustable -position agitator designs|

---

CN106232220B|2014-03-22|2019-08-20|生命科技股份有限公司|Impeller sub-assembly for fluid handling system|

---

FR3039776B1|2015-08-03|2017-08-25|Sartorius Stedim Fmt Sas|METHOD FOR ASSEMBLING A CONTAINER-MIXER COMPRISING A TELESCOPIC TREE|

---

DE102016003136A1|2016-03-15|2017-09-21|Sartorius Stedim Biotech Gmbh|Apparatus and method for receiving a disposable container|

---

EP3241608B1|2016-05-02|2020-04-08|Levitronix GmbH|Mixing device and disposable device for such a mixing device|FR3039776B1|2015-08-03|2017-08-25|Sartorius Stedim Fmt Sas|METHOD FOR ASSEMBLING A CONTAINER-MIXER COMPRISING A TELESCOPIC TREE|

---

EP3405404A4|2016-01-19|2020-01-22|Furman, Ehud|Internal shield system for fluids and solids processing devices and uses thereof|

---

CN106823927B|2017-03-24|2019-06-11|武汉华星光电技术有限公司|A kind of agitating device and photoresist bucket of processing photoresist deposition|

法律状态:
2016-07-12| PLFP| Fee payment|Year of fee payment: 2 |

---

2017-02-10| PLSC| Publication of the preliminary search report|Effective date: 20170210 |

---

2017-06-28| PLFP| Fee payment|Year of fee payment: 3 |

---

2018-06-12| PLFP| Fee payment|Year of fee payment: 4 |

---

2019-06-19| PLFP| Fee payment|Year of fee payment: 5 |

---

2020-08-27| PLFP| Fee payment|Year of fee payment: 6 |

---

2021-08-18| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

---

申请号 | 申请日 | 专利标题

---

FR1557500A|FR3039776B1|2015-08-03|2015-08-03|METHOD FOR ASSEMBLING A CONTAINER-MIXER COMPRISING A TELESCOPIC TREE|FR1557500A| FR3039776B1|2015-08-03|2015-08-03|METHOD FOR ASSEMBLING A CONTAINER-MIXER COMPRISING A TELESCOPIC TREE|

---

US15/750,048| US10456761B2|2015-08-03|2016-08-02|Mixer-container and method for assembling a mixer-container including a telescopic shaft|

---

CN201680047799.7A| CN107921387B|2015-08-03|2016-08-02|Blender container and method of assembling a blender container including a telescoping shaft|

---

CN202110035430.7A| CN112844138A|2015-08-03|2016-08-02|Blender container and method of assembling a blender container including a telescoping shaft|

---

PCT/FR2016/052017| WO2017021653A1|2015-08-03|2016-08-02|Mixer-container and method for assembling a mixer-container including a telescopic shaft|

---

EP16757705.5A| EP3331637A1|2015-08-03|2016-08-02|Mixer-container and method for assembling a mixer-container including a telescopic shaft|

---

US16/504,612| US10702838B2|2015-08-03|2019-07-08|Mixer-container and method for assembling a mixer-container including a telescopic shaft|