This application claims priority of and incorporates by reference German patent application no. 10 2008 020 759.4 filed Apr. 18, 2008.
Rotary tableting presses are sufficiently well known. They usually comprise a rotor having a female mold table with a number of female molds arranged on a circumferential line. An upper ram and a lower ram are assigned to each female mold and are guided by guide cams. A material to be compressed can be added to the female molds through at least one filling device. The upper ram and lower ram are guided over a filling station, a metering station, a prepressure station and a main pressure station.
Rotary tableting presses with which multilayer tablets, e.g., two-layer tablets, can be produced are also known. Two filling stations, two metering stations and two pressure stations are arranged around the circumference of the rotor.
Rotary tableting presses for laboratory operation in particular, which can be retooled from a single-layer operation to a two-layer operation, are also known. These require relatively complex retooling work, namely placement of a second filling spout and adaptation of the first pressure station, the metering unit cams and the filling cams.
An embodiment of the invention provides a rotary tableting press of the generic type, which will be characterized by a simple and variable design.
It is advantageously possible to retool a rotary tableting press rapidly and in a versatile manner because the rotary tableting press has a modular design, with individual modules being arranged so they can be removed and/or converted for retooling of the rotary tableting press from two-layer operation to single-layer operation or vice-versa. The rotary tableting press can thus be used in a variety of ways, in particular as a laboratory press, and may thus be adapted quickly to different desired parameters. This pertains to the replacement of individual components as well as quick retooling from single-layer operation to two-layer operation and/or vice-versa.
In a preferred embodiment of the invention, a first filling device and a second filling device are provided, with the second filling device being removable. This makes it advantageously possible that by removing the second filling device, e.g., by dismantling or by pivoting it into a non-use position, conversion of the
tableting press from a two-layer operation to a single-layer operation can take place very rapidly and in particular also without the use of tools.
Furthermore, in a preferred embodiment of the invention, the first filling device can be equipped with an enlarged filling spout—in single-layer operation with the rotary tableting press. This advantageously makes it possible to operate the rotor at a higher rotational speed during single-layer operation without interfering with reliable filling of the female molds.
In addition, in another preferred embodiment of the invention, a lower pressure roll of a second pressure station in two-layer operation takes on a metering function for filling the female molds in single-layer operation. This advantageously permits effectively support for retooling of the tableting press from two-layer operation to single-layer operation while at the same time allowing multifunctional use of certain components, i.e., for both two-layer operation and single-layer operation.
Furthermore, in a preferred embodiment of the invention, the upper ram guide comprises multiple segments, each at least partially interchangeable with at least one other segment having a different cam characteristic. Owing to this segmentation of the ram guide, retooling from two-layer operation to single-layer operation and/or vice-versa can be implemented easily. Depending on which operating modes are to be implemented in operation, the corresponding segments are used for guiding the upper ram. The longer filling distance may be supported in a single-layer mode in this way.
In another preferred embodiment of the invention, the rotary tableting press comprises drive adapters which are optionally operatively connectable to drive shafts for driving filling devices and/or parts of filling devices. Remodeling of the filling zone from two-layer operation to single-layer operation and/or vice-versa can be supported easily in this way. In particular, no complex assembly work may be conducted. The available drive adapters are optionally either coupled to the corresponding drive shafts or not.
In addition, in a preferred embodiment of the invention, the rotor can be pivoted out of a press interior of the rotary tableting press. It is advantageously possible in this way to either replace the entire rotor or to replace the segments of the ram guides on the rotor itself, for example, and/or to adapt the upper ram and/or lower ram according to the desired parameters of the tablets to be pressed. In addition, maintenance and/or cleaning jobs can easily be performed on the rotor and/or on the interior of the press.
Furthermore, in a preferred embodiment of the invention, the rotor comprises a receptacle for a support arm, whereby the support arm is pivotably arranged with a guide pillar of the rotary tableting press, where a lifting mechanism is preferably integrated into the support arm for lowering and/or raising the rotor. This advantageously permits dismantling and/or installation of the motor without the use of any additional external equipment and/or tools.
The present invention thus relates to a rotary tableting press that can be used universally, in particular a modular design laboratory press equipped for replacement of a complete rotor with only a few manipulations or for retooling the rotor and the necessary peripherals from a two-layer operation to a single-layer operation and vice-versa.
Essential to the invention here is, first of all, the simple and uncomplicated operation of retooling from two-layer operation to single-layer operation. This requires only the removal of the top pressure roll for pressing on the first layer—in two-layer operation—and the cam segments of the upper ram adjacent to the top pressure roll in two-layer operation. These cam segments are replaced for a cam segment having a straight guide for the upper ram. Furthermore, the filling devices for the first layer and the second layer are removed and/or refunctionalized. It is thus possible to easily use the metering unit of the filling station for the first layer in two-layer operation simultaneously with filling of the female molds in single-layer operation. It is thus possible in single-layer operation to lengthen the filling zone easily by lengthening the filling cam in this metering. Replacement of the metering unit is not necessary. The bottom pressure roll for pressing the first layer assumes the function of a metering unit and therefore need not be dismantled or retooled. A longer filling zone for female molds is likewise possible by arranging an additional stirrer blade of a filling spout for single-layer operation, so that there may be an increase in the input speed/working speed of the rotor. Retooling of the laboratory press from two-layer operation to single-layer operation and/or vice-versa can thus be accomplished within the shortest possible amount of time, as needed. Complex breakdown and/or dismantling and assembly jobs are not necessary here. The few coordinated replacement parts can easily be positioned, primarily even without the use of tools.
Another aspect of the present invention is the replaceability of the complete rotor of the rotary tableting press without complex dismantling work. To do so, the rotor is pivoted laterally out of its operating position. This means that the rotor is not raised but instead remains in its elevated position. In this way, pivoting of the pressure rolls and dismantling of the guide cam for the rams and the rams themselves can be omitted. It is necessary only to remove the filling cam because in this area the lower rams engaging therein would stand in the way of pivoting the rotor out laterally.
In its operating position, the rotor is connected in a nonpositive manner to the drive and/or the counter bearing on its drive shaft ends by mechanically acting connecting elements, e.g., connecting elements that are pneumatically or hydraulically operable so that accurate and reproducible positioning of the rotor is possible. For dismantling, the rotor is connected to a support arm and is pivoted outward about a column of the laboratory press fixedly mounted on the frame, as stated, without any change in height. After being pivoted outward, the rotor may then be placed on a rotor wagon or the like by means of a lowering device, e.g., mechanically, hydraulically or pneumatically. Replacement of the rotor, e.g., for repairs and/or maintenance purposes or for cleaning purposes or the like, is thus readily possible in a simple manner.
The basic principle of the invention is illustrated on the basis of the following figures. They show:
It is clear that the second filling device 20 here is removed and/or shifted out of the operative area of the rotor 12. Likewise the upper pressure roll of the first pressure station 18 is removed. The first feed mechanism 16′ is either retained or is equipped with a larger filling spout, as shown here. This permits filling of the female molds on a larger portion of the circumference of the partial circle of the female mold table 14. The lower pressure roll of the first pressure station 18 here takes over the metering function for control of the lower ram for metered feed of a specific quantity into the female mold, in accordance with general practice.
It is clear from the schematic diagrams in
Furthermore, the rotor 12 with the female mold table 14 is visible. The rotor 12 also comprises a lower ram guide 32 and an upper ram guide 34. The lower ram and the upper ram are displaced by guide cams in their position relative to the female mold table in an essentially known manner. The metering, pressing and ejection of tablets can be controlled in this way. The upper ram cam 36 is diagrammed schematically in
All the other components of the tableting press 10 remain unchanged and are functional in both two-layer operation and single-layer operation.
As already explained with reference to the preceding figures, first the female molds are filled upstream from the first pressure station 18, the first layer is prepressed in the pressure station 18, the female molds are filled upstream from the second pressure station 22, the second layer is prepressed in the pressure station 22 and the main pressing takes place in the main pressure station 24. Downstream from the main pressure station 24, the completely pressed tablet is ejected, indicated here with an arrow 64.
In single-layer operation, the top pressure roll 28 of the first pressure station 18 is removed and the segments 40 and 42 of the upper ram guide 60 are replaced by segment 44. The top pressure roll 30 now acts in the function of a metering roll.
These parts are removed by releasing the corresponding quick-snap connections or the like without the use of tools.
Number | Date | Country | Kind |
---|---|---|---|
10 2008 020 759 | Apr 2008 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
2970554 | Haupt | Feb 1961 | A |
3063390 | Frank | Nov 1962 | A |
3460487 | Kibbe | Aug 1969 | A |
3887317 | Plocher et al. | Jun 1975 | A |
5151280 | Arndt et al. | Sep 1992 | A |
5322655 | Ebey | Jun 1994 | A |
5350548 | Hinzpeter et al. | Sep 1994 | A |
6382947 | Bryant | May 2002 | B1 |
6676863 | Christiaens et al. | Jan 2004 | B2 |
6972105 | Boeckx et al. | Dec 2005 | B2 |
20030042639 | Christiaens et al. | Mar 2003 | A1 |
20090142438 | Roemer et al. | Jun 2009 | A1 |
Number | Date | Country |
---|---|---|
967423 | Nov 1957 | DE |
102004040163 | May 2006 | DE |
102005030311 | Nov 2006 | DE |
2065176 | Jun 2009 | EP |
2002301597 | Oct 2002 | JP |
9925545 | May 1999 | WO |
Number | Date | Country | |
---|---|---|---|
20090263532 A1 | Oct 2009 | US |