This application is a 35 USC 371 application of PCT/EP 2007/055800 filed on Jun. 13, 2007.
1. Field of the Invention
The present invention relates to an apparatus for homogenizing powder, in which the powder is then dispensed into a container, such as a capsule or a package.
2. Description of the Prior Art
An apparatus for homogenizing powder is known from the prior art, such that an agitator mechanism, for instance, is provided, having a rotating agitator that plunges into the powder and is rotated. By means of the rotating agitator, the attempt is made to break up so-called powder bridges. However, especially with very fine-grained powder such as medications or the like, it is still possible for the powder to stick together and clump. Moreover, agitator mechanisms require a relatively large amount of space.
The apparatus for homogenizing powder according to the invention has the advantage over the prior art that while having a simple construction and being economical to manufacture, it enables reliable homogenization of a powder. In particular, unwanted powder concentrations can be broken up with a high degree of process safety. In particular, homogenization can be done in a way that makes for very gentle product handling, as is necessary particularly for medications or the like. Moreover, the power can be adapted flexibly to different powdered products. This is attained according to the invention in that the apparatus for homogenizing powder includes a drive device and a homogenization unit. The drive device moves the homogenization unit back and forth at least in a horizontal direction. The homogenization unit includes many rod-shaped elements, which plunge at least partway into a powder that is to be homogenized. Thus by means of the driven homogenization unit, the rod-shaped elements are moved back and forth in a horizontal direction, so that the rod-shaped elements are moved through the powder in the lateral direction. The rod-shaped elements are disposed essentially in the vertical direction.
The rod-shaped elements preferably have a circular outer cross section. Alternatively, it would also be possible for the cross section of the rod-shaped elements to be oval or polygonal, such as hexagonal or octagonal.
Also preferably, the drive device includes an electromagnet and a vibration plate, with a pole element of a ferromagnetic material. The vibration plate is movably supported, and the pole element is disposed relative to the electromagnet such that between them, a vertical gap is formed, in order upon an actuation of the electromagnet to attract the pole element by means of magnetic force and to excite the vibration plate to vibrate. The homogenization unit is connected to the vibration plate and is moved back and forth in the horizontal direction by the excited vibration plate.
The vibration plate is preferably vibratably supported by means of at least one leaf spring. A plurality of leaf springs are advantageously provided here, in particular four leaf springs, one on each corner of the vibration plate.
In an alternative embodiment of the invention, the drive device includes a piezoelectric actuator or pneumatic actuator for moving the homogenization unit.
Preferably, the rod-shaped elements are embodied as small tubes and communicate with a pressure region that contains compressed air. It is thus possible to feed compressed air directly into the powder through the small tubes. This mixing in of compressed air has the advantage in particular that the flowability of the powder is improved significantly. The compressed air should preferably be dry. Moreover, the pressure of the compressed air should not be too high, to prevent blowing the powder away.
Also preferably, the homogenization unit includes a pressure chamber, in which a throttle restriction is disposed. The throttle restriction furnishes a uniform distribution of the compressed air among the small tubes disposed adjacent to one another.
In a further preferred feature of the invention, the throttle restriction is a block of a microporous, air-permeable material.
To enable fast and simple replacement of the homogenization unit by another homogenization unit, an adapter is preferably disposed between the drive device and the homogenization unit. The homogenization unit is secured to and released from the adapter. A fast replacement of the apparatus for homogenizing powder, for example for a different powdered product, can thus be performed. The adapter furthermore preferably has a compressed air connection.
In a further preferred embodiment of the invention, the rod-shaped elements embodied as small tubes have many openings on their free end, that is, on the end that has plunged into the powder. The openings may be provided in the form of pointlike openings and/or as slits. The slits can be embodied as straight slits and/or as curved slits. By the provision of the openings on the end of the small tubes that is plunged into the powder, improved and more-uniform introduction of air into the powder is achieved.
If the openings are embodied as slits, the slits preferably have a length that is equivalent to approximately ⅓ the circumference of the small tubes. The slits are especially preferably offset from one another along the circumference, at different heights and oriented in different directions.
Especially good homogenization of the powder can be achieved if a spacing of adjacent rod-shaped elements is uniform.
Also preferably, the rod-shaped elements have different lengths. In particular, the lengths of rod-shaped elements which are disposed on the edge of the vibration plate are shorter than rod-shaped elements farther toward the middle. As a result, an adaptation of the homogenization unit, for instance to a tapering container, such as a funnel-shaped container, in which the powder is stored can be achieved.
The present invention is used especially preferably in conjunction with a metering device for metering powder into vessels, such as capsules or the like. The powder may for instance be a medication, or a food, such as flour, coffee, cocoa, and so forth. Hence the invention is used especially preferably in bottling machines.
Preferred exemplary embodiments of the invention will be described in detail below in conjunction with the drawings. In the drawings:
a-4c show various views of a rod-shaped element of the homogenization unit;
Below, an apparatus 1 for homogenizing powder will be described in detail in terms of a first exemplary embodiment of the invention, in conjunction with
The homogenization unit 2 further includes a housing 7, in which a pressure chamber 5 is disposed. In the pressure chamber 5, there is a throttle restriction 6, which is made from a microporous, air-permeable material. The throttle restriction 6 is disposed directly upstream, in the flow direction, of the rod-shaped elements 4 (see
The drive device 3, which is shown in the lower part of
An adapter 15 with a compressed air connection 16 is also disposed on the drive device 3. The adapter 15 is connected to the vibration plate 11, and in its upper region it has an opening 18 that is provided with a thread. By means of this opening, the homogenization unit 2 can be secured to the adapter 15 by means of a screw element 8. The screw element 8 has a large engagement region, so that securing and releasing the homogenization unit 2 to and from the drive device 3 can be done by hand. With the aid of the adapter 15, a drive device 3 can therefore be used for many different homogenization units, which can be replaced simply and quickly.
To enable metering that is as fast and precise as possible, the powder 20 must be present as homogeneously as possible in the supply chamber 22. This is attained by means of the apparatus 1 of the invention. The rod-shaped elements 4 of the homogenization unit 2 are plunged partway into the powder 20 located in the supply chamber 22. The drive device 3 moves the homogenization unit 2 back and forth horizontally in the direction of the double arrow A. By means of the rod-shaped elements 4, which all have a circular outer cross section and are embodied as small tubes, product concentrations, which can occur particularly at the surface of the powder in the supply chamber 22, are broken up. At the same time, compressed air is also fed through the rod-shaped elements 4, embodied as small tubes, into the powder 20 through the exposed end of the passage 4b and through the slits 4c. As a result of this mixing in of compressed air, the flowability of the powder 20 is improved significantly. As a result, the homogenization of the powder 20 is done in a way that is especially gentle to the product.
By means of the homogenization apparatus 1 according to the invention, the most uniform possible introduction of vibrational energy into the powder 20 can thus be attained. This further reinforces the breaking up of unwanted powder concentrations, especially at the surface.
Below, in conjunction with
As shown in
As can be seen from
It should be noted that the drive device 3, for all the exemplary embodiments described, can also be embodied such that the homogenization unit 2 is moved back and forth in two different directions. The devices then are especially preferably perpendicular to one another. In this respect it is possible for the motion in two different directions to be executed successively, or for the two directions of motion to overlap, resulting in a circular or oval motion.
The foregoing relates to the preferred exemplary embodiments of the invention, it being understood that other variants and embodiments thereof are possible within the spirit and scope of the invention, the latter being defined by the appended claims.
Number | Date | Country | Kind |
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10 2006 035 051 | Jul 2006 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/055800 | 6/13/2007 | WO | 00 | 12/19/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/012139 | 1/31/2008 | WO | A |
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Number | Date | Country | |
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20100157721 A1 | Jun 2010 | US |