EP1877195A1

EP1877195A1 - Multi-stage coating device for moulded bodies

Info

Publication number: EP1877195A1
Application number: EP06742531A
Authority: EP
Inventors: Günter KÖRBLEIN
Original assignee: Uhde GmbH
Current assignee: ThyssenKrupp Industrial Solutions AG
Priority date: 2005-05-03
Filing date: 2006-04-01
Publication date: 2008-01-16
Also published as: DE102005020992B3; MX2007013820A; US20090220676A1; WO2006117046A1; CN101193710A; JP2008540072A

Abstract

The invention relates to a quasi-continuously operating coating device for the coating of moulded bodies, in particular for pharmaceutical products, such as tablets, drops, pressed moldings and granulates. The coating device comprises a rotating coating drum, divided into several drum longitudinal sections by a transport element, whereby the introduction of the process medium for all segments occurs individually and depending on the appropriate stage of the coating process. The moulded bodies are conveyed through the drum in an axial direction by means of said transport element. In an ideal embodiment the transport element is in the form of a cylindrical screw.

Description

MULTI-STAGE COATING DEVICE FOR MOLDING BODY

The invention relates to a device according to the preamble of claim 1. It is a quasi-continuous coating device for coating moldings, especially for pharmaceutical products, such as tablets, dragees, pellets and granules. In this case, the coating device comprises a rotating coating drum, which is subdivided by a transport element into several segments, wherein the supply of process media for all segments can be done individually and depending on the stage of the coating process and the molded body by means of this transport element in the axial direction through the Drum be transported. In an ideal embodiment, this transport element is shaped as a spindle. The invention also relates to an associated method or the use of the device.

In the prior art devices for coating tablets, dragees and granules are known. In the case of food, the coating of products usually serves to visually improve the product, but also to optimize the mechanical properties during storage or consumption and to protect against atmospheric moisture after opening the packaging.

For pharmaceuticals such coatings or coatings in addition to the optical and mechanical stabilizing effect, usually also physiological significance, namely to improve the sensory perception in the mouth to facilitate swallowing, to ensure a slowed or defined drug release or the tablet conserve until, for example, the intended site of action in the gastrointestinal tract is reached. There are usually three treatment steps go through: Dusting and warming, spraying and subsequent drying of the moldings. These treatment stages are usually carried out serially one after the other in the same apparatus.

The coating layer is thus adjusted very precisely in pharmaceuticals, often not several different coating layers are required to meet all the above requirements. Furthermore, due to regulatory requirements, the concentrations and masses of all substances per single tablet must be kept within very narrow tolerances, so that previously continuous processes were hardly realized. Essentially, two systems are described in the prior art, both of which work batchwise.

The first system is a kind of rotating pan or kettle with a generally central opening through which the moldings are filled. The heap of moldings is formed by the rotation of the pan in a continuous flow and roll held and over nozzles with a coating medium, usually a liquid, evenly sprayed. During the coating process, the axis of rotation of the boiler is oriented at an angle of approx. 30-50 ° to the horizontal, so that the boiler opening points diagonally upwards. At the same time or following the wetting with a fluid, volatile constituents are filtered off with suction and then the coated and moist shaped bodies are dried. EP 0 088 317 A1 discloses such a system in which the shaped bodies are sprayed with coating medium via nozzles which are attached to a fixed pipe, the pipe projecting through the free opening into the interior of the boiler. The suction and drying is realized by a grating, which is mounted inside the boiler and is covered as far as possible by the debris in the filled state even during the rotation.

The suction line of the device according to EP 0 088 317 A1, is also guided by the aforementioned boiler opening to the outside. A comparable device is also disclosed in DE 27 31 351 A1, FR 2 222 957 A1 or in DE 24 23 933 A1. In this first system, the fully coated charge is discharged from the supply lines through the one boiler opening after decoupling.

In the second coating system, which is substantially identical to the first, the uncoated molded bodies are filled on one side or through a wall opening of a coating drum or container. The coating drum rotates during the coating process about a substantially horizontal axis. EP 0 198 929 A1, DE 44 45 618 A1 or FR 2,053,554 A5 disclose such coating devices for shaped bodies.

[0009] Another prior art coating apparatus provides multiple directions of movement of the drum and drum internals to hold the moldings in suspension. DE 31 49 421 A1 in conjunction with DE-2218729 A discloses such a device. The built in the drum mixing, stirring and conveying devices improve the mixing throughout the drum interior, but do not allow continuous production operation. A disadvantage of the known in the prior art devices for coating of pharmaceutical moldings is that these are all devices for batch processes that do not allow continuous or quasi-continuous operation and sometimes required multiple Umfüllvorgängen are consuming, delay the Process and require expensive suction or encapsulation devices. Thus, it is an object of the invention to provide an apparatus and a method which, even in a multistage coating process, improves the flow rate of the product without degrading product safety as provided by batchwise treatment in the prior art. This object is achieved with the device according to the present invention having the features of claim 1 and 9, respectively. Advantageous developments of the method and the device are evident from the dependent claims.

Coating apparatus for coating moldings, comprising a perforated drum accommodated in a housing, a mold body conduit for guiding the moldings into the interior of the drum, at least one fluid conduit and nozzles for spraying fluids inside the drum, wherein, in operation, the drum rotates about its horizontal axis to move the body heap. Furthermore, the coating device comprises at least one gas suction line to remove moisture and dust from the housing and drum interior of the coating device. The drum has several so-called. Segments (drum longitudinal sections), wherein the segments are formed by a transport element, and leads to at least one segment at least one fluid line, are arranged at which nozzles to spray the moldings within the segment. The number of segments is arbitrary and limited only by the mechanical requirements of the drum or the transport element and the other internals.

The movement of the transport element takes place independently of the rotation of the drum, wherein the moldings are conveyed by the movement of the transport element in the axial direction in the subsequent segment or from the coating device out. In an optimized embodiment, the coating device according to the invention comprises as a transport element, a cylindrical spiral or helix.

Ideally, the cylindrical spiral is rotatably mounted and the segments and the pitch of the cylindrical spiral are dimensioned such that by the rotation of the cylindrical spiral by a maximum of one revolution, the molded body of a segment completely moved into the respective subsequent segment or from the coating device be transported out. The radius of the cylindrical spiral is ideally chosen such that a small gap remains between the inner side of the drum and the outer edge of the cylindrical spiral, which gap is less than or equal to half the smallest diameter of the shaped bodies to be coated. way smaller than one-fifth of this diameter is. In an embodiment variant of the device according to the invention, the separating element is arranged in a grinding manner in the drum.

Advantageously, the rotation of the drum and the cylindrical spiral with respect to rotational direction and speed of each other completely independent.

In an improved embodiment of the coating apparatus, the segments in the interior of the drum in the region of the axis of rotation are connected to each other by a through opening.

[0020] Ideally, each individual segment can be supplied with one or more process media independently of the adjacent segment.

An improved embodiment of the invention is that in at least one segment, one or more mixer elements are arranged, which are mounted so movable that they can be immersed in the bed of the moldings and lifted out of this bed. In the immersed position, these mixing elements produce a transverse mixing in the heap of shaped bodies moved by the rotation of the drum.

In a further improved embodiment variant of the device, the mixing element is fastened to the transport element, wherein it is shaped such that during the movement of the transport element and the associated transport of the shaped body in the axial direction, no shaped body is lifted out of the total drive ,

Thus, a particular advantage of the invention is the fact that not a single molding can leave the respective segment via a short circuit flow before the end of a coating stage, which is very essential for pharmaceutical products. Thus, the individual stages within the coating process are just as sharply demarcated as in a known in the art batch device.

The transition of the moldings in the next treatment stage or the discharge can be done with moving or stationary drum, wherein the cylindrical spiral is rotated by half a maximum or a full rotation, depending on the dimensioning of the segments. Advantageously, by this in itself very closed and simplified transport process, a use in clean rooms greatly facilitated because no additional e-missions occur in the transfer of the moldings from one treatment stage in the subsequent. [0026] The invention further includes a process for coating spherical particles, in which the coating device according to the invention and described above is used.

From the invention is further included to use the coating device according to the invention or the coating process for coating moldings, for manufacturing processes of pharmaceutical products or food.

The coating device according to the invention can thus be directly connected to the tablet press and the subsequent primary packaging plant, such as a blister machine. This avoids intermediate storage with all the disadvantages of the break and the additional residence times. In particular, for highly effective substances such a closed process from granules to finished packaging can be realized.

At the same time, the disadvantages of a true continuous production are avoided since there are always defined partial charges, with which precise spray quantities and defined times can be realized.

The subject invention is described in more detail by way of example in the drawing with reference to an embodiment. In the drawing, Fig. 1 shows the coating device 1 according to the invention, consisting of an outer housing 2 in which a rotatably mounted perforated drum 3 is arranged. In the drum 3, an open cylindrical spiral 4 is further provided, which divides the drum interior into three segments A to C. The molded bodies 6 to be coated are introduced into the segment A via the molded body conduit 7 and, after complete treatment, leave the coating apparatus via the conduit 8 in all segments.

FIG. 1 also shows an exhaust element 5 in the form of a shell, which faces a partial surface of the drum 3 with a very small gap width. This exhaust air element 5 is connected via the Gasabsaugleitung 9 with a vacuum pump, not shown, and sucks the moisture and dust from the interior of the housing 2 and especially the bed of moldings 6 on the perforated wall of the drum 3 to the outside. In operation of the coating device 1, the moldings 6 are raised by the rotation of the drum 3 at the foot of the bed and rolls due to gravity, especially on the Haufwerksoberfläche down, the lowest point of the drum 3 from. The exhaust air element 5 is shaped in such a way that it mainly covers completely the drum surface covered by the molded bodies 6 in operation from the rear side. In the central near-axis space 12 of the drum 3, in which the walls of the cylindrical spiral 4 do not protrude, nozzles 10 are arranged, which are supplied via a line 11 with fluid, wherein the line 11 in the example shown as an attachment for the nozzles 10 acts.

The nozzles are arranged in the segments A and B, in which the coating liquid is applied to the moldings 6. In the segment C, the drying and cooling of the coated moldings 6, wherein in the example shown via a gas pressure line 14 and a gas outlet 13 targeted a suitable gas is passed into the segment C in order to optimize the drying and cooling process.

LIST OF REFERENCE NUMBERS

1 coating device

2 housings

3 drum

4 spiral

5 exhaust air element

6 shaped body / fill

7 molded body pipe

8 molded body pipe

9 Gas suction line

10 nozzles

11 fluid line

12 near-axis space

13 gas outlet

14 Gas pressure line A - C Segments of the drum

Claims

1) Coating apparatus for coating moldings, comprising a perforated drum housed in a housing, a mold body conduit for guiding the moldings into the interior of the drum, at least one fluid conduit and nozzles for spraying fluids inside the drum and at least one Gasabsaugleitung, wherein the drum rotates in operation about its horizontal axis, wherein the housing and drum interior is sucked through the Gasabsaugleitung,

characterized in that

Is divided ^■ the drum of a device for transport of the molded body into a plurality of segments (drum longitudinal sections),

^Leading to at least one segment at least one fluid line to which nozzles are arranged, with which the moldings are sprayed in the segment, wherein

^■ the drum is rotatable independently of the movement of the device for transporting the moldings, and

^■ the shaped bodies by the movement of the transport device in the direction of the drum axis in the subsequent segment are respectively transported from the coating device out.

2) Coating device according to claim 1, characterized in that the device for transporting the shaped body is designed as a cylindrical spiral.

3) Coating device according to claim 2, characterized in that the cylindrical spiral is rotatably mounted and the shaped body of a segment by the rotation of the cylindrical spiral by a maximum of one revolution in the respective next segment shifted or transported out of the coating device out.

4) Coating device according to one of claims 2 or 3, characterized in that the rotation of the drum and that of the cylindrical spiral with respect to rotational direction and rotational speed can be independent of each other. 5) Coating device according to one of claims 1 to 4, characterized in that the device for transporting the moldings is arranged to be abrasive in the drum.

6) Coating device according to one of claims 2 to 4, characterized in that between the drum inner side and the outer edge of the cylindrical spiral, a gap remains, which is less than or equal to half the smallest diameter of the molded body to be coated and ideally less than one fifth of this diameter ,

7) Coating device according to one of claims 1 to 6, characterized in that each individual segment, regardless of the adjacent segment, can be supplied with one or more process media.

8) Coating device according to one of claims 1 to 7, characterized in that in at least one segment, one or more mixer elements are arranged, which are mounted so movable that they can be immersed in the bed of the moldings and lifted out.

9) A method for coating shaped bodies such as dragees, tablets, lozenges or the like, wherein a coating apparatus is used according to any one of the preceding claims, and in a first step, the moldings are filled in the first segment, in a second step, the moldings corresponding to the respective Be wetted with fluid, in the third step, the device for transporting the moldings is rotated a maximum of one revolution, whereby the first segment is emptied and the moldings are moved in the second segment in the direction of the axis, in the fourth step, the first segment according to the the first step is refilled, while in the second segment, the moldings wetted or cooled or heated according to the respective requirements again with fluid, wherein air or a gas passed directly into the segment or sucked through the perforation of the drum wall and passed over the moldings w In the fifth step, the device for transporting the moldings is again rotated by a maximum of one complete revolution, whereby the moldings of the second segment are rotated into the third and the moldings of the first segment into the second mold. and the first to fourth steps are repeated as often as desired, the moldings being led out of the drum in the last segment of the coating apparatus, and during the process the drum is rotated and the inside of the coating apparatus and the inside of the drum are sucked out via the gas suction duct.

10) Use of the coating device according to one of claims 1 to 8, characterized in that the coating device is used for manufacturing processes of pharmaceutical products.

11) Use of the coating device according to one of claims 1 to 8, characterized in that the coating device is used for manufacturing processes of food.