1. Field of the Invention
The invention relates to a mixing container and a mixing system.
2. Description of the Related Art
The pharmaceutical industry has a need for a low cost single-use mixing technology that operates over a large scale range of container volume, for example for containers from 3 liters volume to 3000 liters volume. The mixing technology should be capable to mix two or more liquids or at least one solid with at least one liquid. Because disposable containers are preferred in various applications the mixing container should be easy and inexpensive to manufacture and should perform a reliable mixing operation. Additionally, because the material to be mixed has high purity requirements, the mixing technology should be ultraclean, i.e. should not generate particulates or create a risk of leakage of fluid through seals.
One aspect of the invention relates to a mixing container comprising a wall enclosing a mixing volume, an anchor fixed at the wall of the mixing container inside the mixing volume, and at least one mixing plate movably mounted to the anchor to allow a relative movement of the at least one mixing plate along a stir direction having a component perpendicular to the extension of the mixing plate. Each of the at least one mixing plate is provided with at least one magnetic device.
Herein “at least one mixing plate movably mounted to the anchor” is synonymous with a connection between the mixing plate and the anchor that allows a movement of the mixing plate relative to the anchor, including, but not limited to a hinge, flexure material, a mechanical linkage or by pivotally mounting the mixing plate to the anchor.
The mixing volume may be substantially identical to the volume of the container.
Alternatively, the container may be partially filled with a gas, i.e. may contain a headspace, to provide a wider range of working volumes or to provide stabilization of the liquid material (e.g. with an inert gas such as nitrogen).
The anchor can be mounted from the inside of the mixing container to the wall. The anchor is not able to move laterally and/or rotatably relative to the part of the wall surrounding the anchor. Thus, the anchor is not a movable element.
One or more mixing plates are movably, preferably pivotally, mounted to the anchor. The mounting may be provided by means of a hinge or a flexible region of the mixing plate and/or the anchor allowing a relative movement of each mixing plate along a stir direction perpendicular to the extension of the mixing plate. The mixing plate has generally a lateral extension along two dimensions which is much larger than the thickness of the mixing plate. The thickness direction is generally identical to the stir direction.
The mixing or stirring of a liquid and/or solid in the mixing container is performed by vibrating the mixing plates. In order to actuate the at least one mixing plate, each mixing plate is provided with at least one magnetic device, such as a piece of ferromagnetic material (for example steel), a permanent magnet, a superconducting magnet or an electromagnet. Thus, the mixing plate can be actuated by applying a variant external magnetic field to the mixing container, preferably near the mixing plate. In case the external magnetic field is time variant, the magnetic device and thus the mixing plate can be induced to perform a vibrating motion, which is beneficial for performing the mixing operation.
Optionally, each of the at least one mixing plates is mounted to the anchor by means of a flexure hinge. The anchor and the at least one mixing plate may be made of the same material and/or made as one piece. As example, the anchor and the at least one mixing plate can be made of thermoplastic resin, preferably by injection molding. In this case anchor, mixing plate and the connecting flexure hinge can be easily formed.
As a further option, each of the at least one mixing plates comprises a proximal end movably, preferably pivotally, mounted to the anchor and a distal end comprising the at least one magnetic device. The flexure hinge may be located at the proximal end of the at least one mixing plate.
In an alternative embodiment, each of the at least one mixing plates comprises a proximal end movably, preferably pivotally, mounted to the anchor, a distal end and a magnetic device, wherein the magnetic device is located in a part of the mixing plate between the proximal end and the distal end. Preferably, the magnetic device is located in the middle part of the mixing plate between the proximal end and the distal end.
These embodiments offer the advantage that the magnetic actuator positioned outside of the container and containing the magnets of the drive unit (which interact with the corresponding magnets of the magnetic devices of the mixing plates inside the container) can have a smaller, more space-saving size than a larger magnetic actuator adapted to interact with magnetic devices which are placed at the distal ends of the mixing plates.
Optionally, the at least one magnetic device is located at a side or a surface of the mixing plate directed to the wall of the mixing container. In other words the side or surface of the mixing plate comprising the magnetic device is directed away from the center of the mixing volume or to the outside of the container.
According to another embodiment of the invention, the magnetic device is embedded in the interior of the mixing plate, in case the magnetic device is made of a material which is not compatible with the contents to be mixed in the mixing container.
In all of the aforementioned embodiments, the gap between the mixing plate, respectively the magnetic device, and the wall of the container should be minimized in order to maximize the coupling between the at least one magnetic device of the mixing plate and a corresponding magnetic device outside the container. However, an undersized gap undesirably limits the travel distance of the mixing plate, hence a gap in the range of 5 mm to 10 mm is preferred.
In an embodiment of the invention, the anchor is fixed and the mixing plates are set in vibrating motion by application of an external driving magnetic field. However, it is also possible for an internal magnetic field in the mixing plates (e.g. by an electromagnet disposed in each mixing plate and a fixed permanent magnet disposed outside the container) to create an internal driving magnetic field.
As an option the wall of the mixing container comprises a flexible material. Generally the wall can be formed as a flexible bag, particularly when used as a disposable bioreactor, e.g. for mixing and for culturing organisms. As a further option the wall can be formed as a rigid container. In both cases the wall can be at least partially made of at least one of plastic, metal such as (stainless) steel, and glass. The wall can be made of a gamma-ray sterilizable polymer, particularly when used as a bioreactor.
Anchor and wall are assembled in a fluid (liquid and/or gas) tight manner. As an option the anchor is welded to the wall of the mixing container. Particularly, in case the anchor and the wall are made of the same or different thermoplastic polymers the welding of anchor and wall is a convenient way to mount both together in a fluid tight manner.
Optionally, the mixing container comprises a plurality of mixing plates and the magnetic devices of neighbouring mixing plates are of opposite orientation. For example, two, three, four, five, six, seven, eight or more mixing plates may be connected to the anchor. The mixing plates can be identical or different from each other.
Each mixing plate can comprise one or more mixing orifices, i.e. holes through the mixing plate in order to allow a fluid flow from one side of the mixing plate to the other. Optionally, each mixing orifice is a tapered orifice through which a net fluid flow can be generated when the orifice moves up and down during the vibrating motion of the mixing plate which leads to a better mixing result. The flow of fluid is a net fluid flow caused by flow in one direction being higher than flow in the opposite direction. The facilities provided in the mixing-plate openings can be tapered upwards or downwards, although a combination is possible. In other words all tapered orifices can be oriented in one direction or the tapered orifices may be partially directed in one direction and partially in the opposite direction. The orifices can have other geometries, such as orifices with round entrances or ellipse entrances or diffuser nozzles. In order to perform the mixing each of the mixing plates is moved periodically along and against the stir direction, which extend substantially perpendicular to the areal extension of the mixing plate. In other words, the mixing plates perform longitudinal vibrations along the stir direction.
The invention also relates to a mixing system comprising the above-described mixing container, a container receptacle adapted to at least partially receive the mixing container, and a magnetic actuator comprising at least one magnetic device adapted to induce a time-variant magnetic field which actuates the at least one magnetic device of the mixing container in order to move the corresponding mixing plate along the stir direction.
Optionally, the magnetic actuator comprises a turntable to which the at least one magnetic device is mounted. Particularly, the arrangement pattern of the magnetic devices mounted to the turntable can be congruent or identical to the pattern of the magnetic devices of the mixing plates mounted to the anchor. As an option, the turntable comprises a plurality of magnetic devices wherein neighbouring magnetic devices are of opposite orientation. Optionally, the stir direction is substantially parallel to the axis of rotation of the turntable.
In a particularly preferred embodiment the magnetic devices of neighboring mixing plates have opposite polarity, i.e. N, S, N, S, N, etc., whereas the turntable comprises a plurality of magnetic devices wherein neighboring magnetic devices are of the same orientation, i.e. N, N, N, N, N, etc. or S, S, S, S, S, etc. In other words, the magnetic devices of the turntable have all the same polarity. By means of this embodiment half of the mixing plates are moving in one direction (for example upward movement), while the other half of the mixing plates are moving in the opposite direction (for example downward movement). This arrangement pattern of the magnetic devices of the mixing plates and of the turntable creates a balanced movement of the mixing plates which avoids potentially damaging reaction forces which may be caused by a unbalanced movement of the mixing plates wherein all mixing plates move in the same direction simultaneously.
The invention further relates to a mixing container comprising a wall enclosing a mixing volume, an anchor fixed at the wall of the mixing container inside the mixing volume, and at least one mixing plate movably mounted to the anchor to allow a relative movement of the at least one mixing plate along a stir direction perpendicular to the extension of the mixing plate. Each of the at least one mixing plates is provided with at least one mixing orifice and wherein each of the at least one mixing plates is provided with at least one magnetic device.
Further features and advantages are described with references to the figures.
The mixing container 1 may be a single use container. The anchor 3 is attached to the wall 7 of the mixing container 1 via a welding flange 9 of the anchor 3 which is welded to a welding zone 11 of the wall 7. One or more (not shown) mixing plates 13 are movably, preferably pivotally connected to the anchor 3 via a flexure hinge 15 (shown in
Each mixing plate 13 is formed as a planar plate comprising one or more mixing orifices 17, which can have a tapered shape, for example a cone shape, as shown for example in the figures. This allows the generation of a net fluid flow through the mixing orifices 17 leading to an improved mixing result.
The mixing plate 13 contains one or more embedded magnetic devices or magnets 19, which can be for example formed of a NdFeB disc made of an alloy of neodynium, iron and boron and which are used as drivers. A ferromagnetic material such as ferritic stainless steel could be substituted for the permanent magnet 19 to reduce costs. However, the driving force would be reduced by approximately the half. The magnets 19 may also be mounted to the surface of the mixing plate 13. Alternatively, the magnets 19 can be embedded in the interior of the mixing plate 13.
The mixing plate can be actuated by applying an external magnetic field to the mixing container 1, preferably near one or more magnets 19 of the one or more mixing plates 13. By varying the external magnetic field over the time the magnets 19 and thus the mixing plates 13 are induced to perform a vibration motion along a stir direction S. A magnetic actuator comprising at least one magnetic device or magnet 21 can be located near the mixing container 1 in order to induce a time-variant magnetic field which actuates the at least one magnet 19 of the mixing plate 13, and thus, cause a vibration of the mixing plate 13 along the stir direction S.
The transient actuation of the magnets 19 can be obtained by using a magnet 21 providing a variable magnetic field, such as an electromagnet, or by moving the position of magnet 21.
The orifices 17 located in the mixing plate 13 need not be of circular shape, but they may also have the shape of a slot or any other convenient shape. Each mixing plate 13 may be connected to the anchor 3 at one or more locations via linkages or hinges 15. These linkages may be rigid, thereby creating a bending cantilever beam, or flexible, such as a living hinge. The motion of the mixing plate 13 is determined by the geometry, material properties, fluid properties, and the temporal variation of the external magnetic field. The anchor 3 and the at least one mixing plate 13 may be formed integrally, e.g. by injection molding, from a polymeric material suitable for product contact, and thus, forming a mixing head 2. The mixing head 2 is ideally contoured such that the top surface is smooth and does not have any sharp edges that could potentially damage the opposite interior wall 7 of the mixing container 1 when the mixing container 1 is collapsed.
The drive unit 5 includes a magnetic actuator 27 comprising at least one magnet 21 adapted to induce a time-variant magnetic field which actuates the at least one magnet 19 of the mixing container 1 in order to move the corresponding mixing plate 13 along the stir direction S.
The magnetic drive unit 5 is external to the mixing container 1 and generates a variable magnetic field for example by motion of a permanent magnet 21 or by variable current through a fixed electromagnet (not shown). The preferred solution is to move one or more permanent magnets 21 in a circular path C that coincides with the position of the permanent magnets 19 embedded in the mixing plates 13. The permanent magnets 21 may be mounted to a turntable 29 and are rotated by means of a conventional rotating motor 31, such as a brushless DC motor 31, powered via a power cord 33. The turntable 29 can be coupled to the motor 31 via a gear 35 and a driving shaft 37.
The permanent magnets 21 can be arranged on the turntable in a way so that neighbouring magnets 21 are of opposite orientation. In other words the magnetic poles of adjacent magnets 21 are opposite—e.g. N, S, N, S, so that the rotation of the motor 31 generates alternating attraction and repulsion forces at each mixing plate 13 as the permanent magnet 21 in the drive unit 5 approaches the permanent magnet 19 embedded in the mixing plate 13. In a preferred embodiment the magnets 19 of neighboring mixing plates 13 have opposite polarity—e.g. N, S, N, S, whereas the magnets 21 of the drive unit 5 all have the same polarity, i.e. N, N, N, N or S, S, S, S, so that a balanced motion of the mixing plates 13 is created, wherein one half of the mixing plates 13 moves upward and the other half of the mixing plates 13 performs a downward motion or vice versa.
As shown in
The motion of each orifice 17 (as shown in
There are several parameters which may be adjusted in design or in operation to achieve a target performance. The number, size, spacing, and polarity of the magnets 19, 21 in the mixing plates 13 and the drive unit 5 may be adjusted to change the driving power. The power, speed, and gear ratio of the motor 31 may be adjusted to change the mixing power. It may be advantageous to operate near the resonant frequency of the mixing plate 13 to maximize the amplitude of response of the mixing plate 13.
The geometry of the mixing orifices 17 (e.g. diameter, angle, depth) may also be optimized to maximize mixing performance.
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Number | Date | Country | |
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20150265985 A1 | Sep 2015 | US |