EP2823958A2 - Tablet press and method for producing a tablet - Google Patents

Abstract

With the present invention, a station-by-rotation rotary press and a corresponding method for producing a tablet is to be improved so that the error and susceptibility to interference is reduced just during the compression of sticky contents. This object is achieved by a tablet press (1) and a method for producing a tablet, wherein the lower punch (31) in the female mold (23) of the rotary unit (5) is arranged and rotates with the rotary unit (5).

Description

The present invention relates to a tablet press according to the preamble of claim 1 and to a method of manufacturing a tablet according to the preamble of claim 10.

From the WO 2011/038058 A1 a station-wise rotary tablet press of this type is known with a filling station, a pressing station and an ejection station. A tabletop table rotates indexed from the filling station through the grout station to the ejection station when producing a tablet. In the ejection station, the lower die is moved out of the die mold containing a pressed tablet, and the pressed tablet is pushed out from above through the die mold onto a passing conveyor belt from an ejector pin. However, the known tablet press tends to contaminate or stick together during the pressing of filling material with sticky natural products, which can result in malfunctions in the operation.

The invention is based on the object of developing a simple structure, reliable and easy-to-use station-wise working rotary tablet press and a corresponding method for producing a tablet, wherein the reliability should also be ensured during processing of contents with sticky natural products.

This object is achieved with a device according to the independent device claim or a method according to the independent method claim.

In the case of the tablet press described in the independent device claim, in which the lower punch with the rotary unit is arranged rotatingly in the die form, a reliable interaction of the lower punch and the female mold is ensured in all processing positions of the tablet press. Surprisingly, it has been found that the permanent positioning of the lower punch in the die mold keeps the soiling of the female mold and the lower punch, ie the permanent adhesion of filling material to the lower punch and / or the die mold, even during the processing of sticky contents low.

In an advantageous embodiment of the invention, a control plate for a curve control of the lower punch position may be provided. This allows accurate positioning of the lower punch in the die form in and between the individual processing positions of the tablet press.

In a particularly advantageous embodiment of the invention, a loading device can press the lower punch against the control plate. This increases the position accuracy of the lower punch in the die form, since the connection between the control plate and lower punch is always ensured.

Conveniently, the loading device can be arranged within the rotary unit. This increases the reliability of the loading device, since its protected position within the rotary unit a reduced risk of contamination by contents or contaminants from the environment.

In a further embodiment of the invention, the lower punch can be lowered in its position immediately after the pressing in comparison to its final position during pressing. This creates a gap between the lower punch and the pressed tablet, thereby preventing further impact of the pressed tablet on the lower punch. In some embodiments, this facilitates rotation of the rotary unit.

In an advantageous embodiment of the invention, the lower punch can be designed as an ejector for a pressed tablet. As a result, the lower punch reliably conveys the pressed tablet from the mold. In addition, the mold is cleaned by the lower punch during ejection

In a further embodiment of the invention, a coupling unit can be provided, which can couple the drive unit with the rotary unit and decouple from it. The transmission of a drive movement from the drive unit to the turntable can thereby be suspended so that the turntable stands still. The coupling unit also makes it possible to pass only certain drive movements from the drive unit to the turntable, which extends the range of usable drive systems. If necessary, decoupling also makes it possible to move the rotary unit by hand with little effort without moving the drive unit at the same time.

In a particularly advantageous embodiment of the invention, the coupling unit can decouple the drive unit from the rotary unit in a processing position. The rotary unit thus stands still in the processing position and a processing step for producing the tablet can be carried out.

In a preferred embodiment of the invention, the drive unit may comprise a linear actuator. It has been shown that a reliable and indexed rotation of the Turntable in addition to the standard rotating drive systems can also be effected with a linear actuator.

In a particularly advantageous manner, the drive unit may have a first and a second linear actuator, wherein the two linear actuators work in opposite directions. It has been shown that by two mutually oppositely operating linear actuators, the rotary unit, if desired, can be rotated in both directions without having to use more complex rotating drive systems. The use of two oppositely operating linear actuators also makes it possible to perform the linear actuators single acting.

Conveniently, an indexing unit can be provided, which locks the rotary unit in a processing position. The rotary unit is thereby accurately positioned in the machining position and secured against unintentional movement in the machining position, whereby the reliability of the manufacturing process is increased.

In one embodiment of the invention, a filling channel may be provided, in which the filling material is supplied to the female mold. As a result, a reliable supply of the filling material is ensured for Matrizenform.

In a particularly advantageous embodiment of the invention, the filling channel can cover a region of a movement path of the female mold. This improves the degree of filling and the filling state of the female mold, in particular in the case of sticky filling material, since the filling material receives more time during the rotation of the female mold into the female mold.

In a particularly advantageous manner, the rotary unit and the filling channel can be biased against each other. As a result, a secure contact between the rotary unit and the filling channel is achieved, which increases the reliability of the supply of filling material to the female mold.

In a preferred embodiment of the invention, a pressing force generating unit may be arranged below the rotary unit. This arrangement improves accessibility to the tablet press in the area above the rotary unit.

In a particularly advantageous embodiment of the invention, the pressing force generating unit can pull an upper punch in the direction against the lower punch during pressing. The drawing of the upper punch allows an advantageous arrangement of upper punch, lower punch and pressing force generating unit in a line of action.

Conveniently, the pressing force generating unit comprise a pressure cylinder and at least one further pressure cylinder, wherein the one pressure cylinder pulls the upper punch during pressing from a starting position in the direction against the lower punch and the at least one further pressure cylinder moves back the upper punch after pressing into its initial position. It is also conceivable that the pressing force generating unit only one of the printing cylinder, ie the printing cylinder, which pulls the upper punch during pressing from a starting position in the direction against the lower punch or the at least one pressure cylinder, which moves back the upper punch after pressing into its initial position. The use of a pressure cylinder for pressing allows the most constant and thus gentle pressing force generation for forming the tablet, which specifically reduces the release of sticky substances when pressing natural substances. The use of a pressure cylinder to move back the upper punch allows the upper punch to be moved back with little resistance.

In a further embodiment, the at least one pressure cylinder, which moves the upper punch back to its starting position after pressing, may be made smaller than the pressure cylinder which pulls the upper punch in the direction against the lower punch. Since the at least one pressure cylinder for moving back the upper punch in its working volume is smaller than the working volume of the printing cylinder for pressing, the response time of the smaller printing cylinder compared to that of the larger printing cylinder can be reduced, which is the duration for moving back of the upper punch and thus the total duration shortened to produce a tablet.

In a preferred embodiment of the invention, the filling volume of the female mold may be variable. This allows producing different tablet sizes or tablet densities with the same template shape.

In a further embodiment of the invention, the filling volume of the female mold may be variable via the position of the lower punch. By raising or lowering the position of the lower punch in the female mold, thus, the tablet size and / or tablet density can be set reliably and accurately.

In a particularly advantageous embodiment of the invention, the filling volume of the mold may be variable during rotation of the rotary unit. This allows a time-saving and easy adjustment of the filling quantity or the tablet size and / or the tablet density.

In a further embodiment of the invention, the tablet press may be pneumatically driven. The use of air as a fuel reduces the risk of dust explosions compared to electrical drives and contamination of the tablet by the fuel compared to hydraulic drives.

In the method described in the independent method claim, in which a lower punch is arranged in the matrix mold and rotates with the rotary unit, a reliable interaction of the lower punch and the female mold results in all method steps. Surprisingly, it has been shown that the permanent positioning of the lower punch in the die mold during rotation of the rotary unit, the contamination of the female mold and the lower punch, so the permanent adhesion of filling material to the lower punch and / or the die shape, even when processing sticky contents is reduced ,

In an advantageous embodiment of the invention, the lower punch can be lowered immediately after the pressing compared to its final position during pressing. This creates a gap between the lower punch and the pressed tablet, thereby preventing further impact of the pressed tablet on the lower punch. In some embodiments, this facilitates rotation of the rotary unit.

In a further advantageous embodiment of the invention, the tablet can be ejected from the lower punch. As a result, the pressed tablet is reliably transported from the lower mold from the Matrizenform. In addition, the mold is cleaned by the lower punch during ejection

In a particular embodiment of the invention, the rotary unit and a drive unit can be decoupled from one another in a processing position. The transmission of a drive movement of the drive unit to the rotary unit can be suspended, so that the rotary unit is stationary and a processing step can take place.

In a further advantageous embodiment of the method, the mold is filled along a filling channel. This improves the degree of filling and the filling state of the female mold since the filling material receives more time during the rotation of the female mold along the filling channel to get into the female mold.

In a further variant of the method according to the invention, an upper punch is pulled in the direction against the lower punch during pressing. The pulling of the upper punch allows an advantageous arrangement of upper punch, lower punch and a pressing force generating unit in a line of action.

In a particularly advantageous embodiment of the invention, the rotary unit rotates, wherein at the same time the filling volume of the female mold is variable. This allows a time-saving and easy adjustment of the filling quantity or the tablet size and / or the tablet density.

Figur 1

eine perspektivische Darstellung der erfindungsgemäßen Tablettenpresse in einer Vorderansicht von schräg oben,

Figur 2

eine perspektivische Darstellung der Tablettenpresse aus Figur 1, in einer Rückansicht von schräg oben,

Figur 3

eine perspektivische Ansicht der Dreheinheit von schräg oben,

Figur 4

Die Dreheinheit aus Figur 3, wobei zu Darstellungszwecken einzelne Bauteile nicht oder nur transparent dargestellt sind,

Figur 5

eine perspektivische Ansicht der Steuerplatte mit der darunter liegenden Antriebseinheit von schräg oben,

Figur 6

eine perspektivische Ansicht der Kupplungseinheit sowie weiterer Bauteile von schräg oben,

Figur 7

eine perspektivische Ansicht der Kupplungseinheit, der Antriebseinheit und weiterer Bauteile von schräg oben,

Figur 8

eine perspektivische Ansicht eines Füllvolumeneinstellmechanismus von schräg oben,

Figur 9

eine perspektivische Ansicht der Presskrafterzeugungseinheit und weiterer Bauteile von schräg oben, und

Figur 10

eine Querschnittsansicht der Presskrafterzeugungseinheit aus Figur 9, geschnitten in der Ebene I - I wie in Figur 9 angedeutet.

In the following, a possible embodiment of the invention will be explained in more detail with reference to the following drawings. Showing:

FIG. 1

a perspective view of the tablet press according to the invention in a front view obliquely from above,

FIG. 2

a perspective view of the tablet press FIG. 1 in a back view diagonally from above,

FIG. 3

a perspective view of the turntable from obliquely above,

FIG. 4

The turntable off FIG. 3 , where for illustration purposes individual components are not shown or only transparent,

FIG. 5

a perspective view of the control plate with the underlying drive unit obliquely from above,

FIG. 6

a perspective view of the coupling unit and other components obliquely from above,

FIG. 7

a perspective view of the coupling unit, the drive unit and other components obliquely from above,

FIG. 8

a perspective view of a Füllvolumeneinstellmechanismus obliquely from above

FIG. 9

a perspective view of the pressing force generating unit and other components obliquely from above, and

FIG. 10

a cross-sectional view of the pressing force generating unit FIG. 9 , cut in the plane I - I as in FIG. 9 indicated.

FIGS. 1 and 2 show a tablet press according to the invention 1. For better illustration, the structure of the tablet press along a rotation axis A of a rotary unit 5 of the tablet press is described.

FIG. 1 shows a Füllgutzuführungseinrichtung 2, which comprises a container 84 for the contents, a housing 3 and a linear actuator 85 designed as a compressed air cylinder. The housing 3 accommodates two, not shown, different sized conveyor wheels and a not shown gear. The axes of rotation of the two conveyor wheels are parallel to each other and to the axis of rotation A and their planes of rotation are offset in the direction of the axis of rotation A to each other. The housing 3 lies with one side partly on a guide plate 4 lying orthogonal to the axis of rotation A.

On the guide plate 4 is followed by the drum-like rotary unit 5, which rests flush on the guide plate 4.

At the end of the guide plate 4 opposite side of the rotary unit 5, there is an indexing 6th

Next in the axial direction follows after the turntable 5, a control plate 7, which lies in a plane orthogonal to the axis of rotation A and is in contact with the rotary unit 5.

In the axial direction after the control plate 7 is followed by a drive unit 8, which lies in a plane orthogonal to the axis of rotation A and rests against the control plate 7. In the plane of the drive unit 8 are a first linear actuator 10 and a second linear actuator 11, which are both attached to the same side of the drive unit 8.

In the axial direction after the drive unit 8, a coupling unit 12, a Füllvolumeneinstellmechanismus 15 and a pressing force generating unit 17 follow successively. From the pressing force generating unit 17, two parallel tie rods 18, 19 extend parallel to the axis of rotation A to above the guide plate 4. The tie rods thereby pierce through holes in the Füllvolumeneinstellmechanismus 15, the drive unit 8 and the control plate 7 and are connected to each other via a yoke 20 at its upper end. The yoke 20 carries at its center the upper punch 21, which forms the top of the tablet.

FIG. 3 shows the drum-like rotary unit 5 with its axis of rotation A. The rotary unit 5 sometimes includes a die plate 22, a main body 25, a locking ring 27 and a loading device 32, not shown here.

As seen in the axial direction, the die plate 22 lies on one side of the rotary unit in a plane orthogonal to the rotation axis A. The circular die plate 22 has five die forms 23. In the center of the die plate 22 is a circular passage opening 24th

The female molds 23 are formed as through holes orthogonal in the female plate 22 and constant in axial direction in their cross section. The cross section is rectangular with rounded corners. All die forms 23 have the same distance to the central axis of rotation A and the same distance to their two direct neighbors.

In the axial direction of the die plate 22 is the cylindrical main body 25. The main body 25 has in its center also has a circular passage opening 26 and is fixedly connected to the overlying die plate 22.

On the lateral outer peripheral surface of the main body 25, the circular lock ring 27 is fixedly connected to the main body 25 at one end. The locking ring 27 has on its lateral outer peripheral surface rectangular recesses 28 which correspond in number to the number of female molds 23 and are distributed uniformly on the peripheral surface. The rotation axes of the lock ring 27, the main body 25 and the die plate 22 coincide. A recess 28 is located with the closest her coming female mold 23 and the axis of rotation A in a plane.

On the side facing away from the die plate 22 side of the main body 25, a coupling ring 29 is arranged concentrically to the main body 25 and the die plate 22. The coupling ring 29 has on its underside five star-shaped arranged to the rotation axis A engagement openings 30.

The intended direction of rotation of the rotary unit 5 is, looking in the axial direction of the die plate 22, in a clockwise direction and is indicated by a curved arrow 86.

In FIG. 4 the die plate 22 and the main body 25 are shown transparent. The locking ring 27 is not shown. For reasons of clarity, only one of five lower punches 31 and only one associated loading device 32, a holding plate 34 and a sliding pin 33 is shown.

The lower punch 31 corresponds in its cross section orthogonal to the axis of rotation A almost the cross section of the female mold 23, extending in the axial direction A along the female mold 23 and is guided in its movement in the axial direction of the female mold 23.

In the axial direction on the side facing away from the female mold 23 of the lower punch 31 is the holding plate 34 which is fixedly connected to the lower punch 31. The holding plate 34 is rotationally symmetrical and has a part 35 with a smaller diameter and a part 36 with a larger diameter. The part 35 is firmly connected to the lower punch 31. The part 36 touches on its side facing away from the part 35 an end face of the cylindrical sliding bolt 33 which projects from the side facing away from the die plate 22 side of the main body 25 and is guided in the main body.

In this embodiment, the slide pin 33 via the holding plate 34 is an extension of the lower punch 31 in the axial direction. The lower punch 31, the holding plate 34 and the slide pin 33 may, however, also be formed in one piece, for example.

On two opposite sides of the holding plate 34 rotationally symmetrical, in cross section along the axis of rotation A T-shaped and loaded by a respective spring 38 load stamp 37 are arranged. The head of the loading punch 37 presses because of the overlying spring 38, which is supported on the main body 25 facing side of the die plate 22 against a lying orthogonal to the axis of rotation A surface of the part 36. Since the lower punch 31 and the holding plate 34 firmly connected are, the two springs 38 press the lower punch 31 and the sliding pin 33 down. The two load stamp 37 and the holding plate 34 are guided at their lateral peripheral surfaces of corresponding recesses in the main body 25 in the axial direction. In the exemplary embodiment shown, the loading device 32 comprises the two loading punches 37 and the two springs 38.

FIG. 5 shows the control plate 7 with its rotating unit 5 facing top 39. The control plate 7 widened over its length constantly in a horizontal direction. The control plate has in this embodiment on its upper side 39 a groove 40, a centrally located to the rotation axis A, circular passage opening 41, two located at the edge through openings 46 for the tie rods 18, 19, a recess 45 and a through hole 44 for a Auswerfstange 56 ,

As the rotary unit 5 rotates, the sliding pins 33, with their end faces remote from the rotary unit 5, slide on the upper side 39 of the control plate and in the region of the groove 40 completely on the orthogonal axis of rotation A The groove 40 has a region 42 having a first depth, for example 1 mm, and a region 43 having a second depth which is greater than the first depth, for example 1.5 mm. The second-depth region 43 has the through-hole 44 at its end, as seen in the direction of rotation 86. In area 42, the corresponding lower punch 31 of the rotary unit is in the processing position of the pressing. In the region of the through hole 44, the associated lower punch 31 is in the processing position of the ejection.

The partial arc-like recess 45 connects to the groove 40 in the direction of rotation 86. Here, if necessary, one or more inserts with different height profiles can be introduced. It is conceivable, for example, to lift the lower punch 31 after ejection to such an extent that automatic brushing of the lower punch upper side is carried out in an additional processing position and / or during movement of the rotary unit. The shape of the guide plate 4 would then be adjusted accordingly.

The area in which the filling of the female mold 23 takes place is positioned on the circular path of the groove 40 in the direction of rotation 86 in front of the area 42 and has the original height of the control plate top 39. The two through openings 46 are located at the two opposite corners of the wide end the control plate 7.

Also in FIG. 5 and also in FIG. 7 to see the drive unit is 8. In FIG. 7 In addition, the arrangement between the drive unit 8, coupling unit 12, column 48 and guide plate 4 is shown.

The drive unit comprises in this embodiment sometimes the two linear actuators 10, 11 and two racks 49, 50th

The drive unit 9 is plate-shaped in a plane orthogonal to the axis of rotation A and widens constantly in the same direction as the control plate 7. The two racks 49, 50 are parallel to each other and in a plane orthogonal to the axis of rotation A, facing their tooth flanks. Each rack 49, 50 is in effect with one of the two linear actuators 10, 11 and is guided in an elongated recess 51, 52 in the drive unit 8. The two racks 49, 50 are engaged with a ring gear 47 between them, as in FIG FIG. 7 good to see. The two linear actuators 10, 11 are designed as single-acting pneumatic cylinders, the cylinder 10 being stronger than the cylinder 11.

The drive unit 8 further has a circular passage opening 53 which corresponds in its dimensions in approximately the passage opening 41 in the control plate 7 and is arranged coaxially to the axis of rotation A. The two through holes 54 for the tie rods 18, 19 are located in the two opposite corners at the wide end of the drive unit 8. The drive unit 8 further has a through hole 55 for the Auswerfstange 56 in the vicinity of the edge on the side of the stronger cylinder 10.

FIG. 6 shows the approximately circular surface formed guide plate 4 with the filling channel 57, a press opening 58 and a circular segment-like recess 59th

The filling channel 57 is formed as a passage opening in the guide plate 4 and extends in a certain length, partially arc-like and parallel along the trajectory of the guide plate 4 flush vorbeirotierenden female molds 23. The cross-sectional opening of the filling channel 57 orthogonal to the axis of rotation A is over its entire length in Axial direction A constant. The guide plate 4 is fixed and does not rotate with the rotary unit 5. The width of the filling channel 57, measured in the radial direction of the axis of rotation A, is constant except for the two rounded ends of the filling channel 57. This width of the filling channel 57 is usually at least as wide as the corresponding measured width of the female mold 23rd

The press opening 58 has the shape of a through hole for the upper punch 21. The press opening 58 is slightly larger in horizontal dimensions than the horizontal dimensions of the upper punch 21. When a female mold 23 is in the processing position of pressing, the press opening 58 is aligned with this female mold 23rd

In the area of the machining position of the ejection, the guide plate 4 has the recess 59. The recess 59 is located on the guide plate approximately opposite the filling channel 57. The guide plate 4 is fixedly connected to the coaxial with the axis of rotation A extending column 48. This column 48 is fixedly connected to the Füllvolumeneinstellmechanismus 15.

The coupling unit 12, as in FIG. 6 shown, in this embodiment, sometimes includes a housing 13, the ring gear 47, pneumatically driven coupling pins 62, and the in Figures 3 and 4 shown coupling ring 29th

The housing 13 is substantially cylindrical and has in its center a circular through hole through which the column 48 extends.

Orthogonal to the rotary unit 5 facing side of the housing 13 protrude through the ring gear 64 five of the movable in the axial direction of the coupling pins 62 in the direction of the rotary unit 5. The coupling pins 62 are arranged in a star shape and on a circular path rotating about the column 48. The ring gear 47 is also rotatably disposed about the column 48 in a plane orthogonal to the axis of rotation A. The ring gear 47 has lateral passage openings 63 corresponding to the coupling pins 62. The coupling pins 62 are guided in the corresponding through holes 63. In her position shown in FIG. 6 the coupling pins 62 protrude out of the side surface 64 of the ring gear 47 facing the rotary unit 5. In this position they engage in the corresponding engagement openings 30 of the coupling ring 29 and form a positive connection with this. In a second position

The coupling pins 62 do not protrude out of the side surface 64. Above the side surface 64 disc springs 65 are mounted concentrically around the column 48.

The disc springs 65 are mounted separately from the ring gear 47 and are supported on a part of the housing 13, not shown. The housing 13 further has three triangularly arranged and disposed on a circular path, vertical through holes 66 for actuators 67 Füllvolumeneinstellmechanismus, as well as a through hole 68 for the Auswerfstange 56 on.

FIG. 8 FIG. 12 shows the filling volume adjusting mechanism 15. In this embodiment, the filling volume adjusting mechanism 15 sometimes includes a housing plate 14, three large gears 69, a small gear 70, three actuators 67, a shaft 71, and a setting wheel 72.

The housing plate 14 is shown transparent for ease of illustration and lies in a plane orthogonal to the axis of rotation A. The three large gears 69 and the small gear 70 are located inside the housing plate 69 and lie in one plane. The large gears 69 are arranged like a planet around the small gear 70. Of the small gear 70 orthogonal to the housing plate 14 extends a rotatable shaft 71 which has a thumbwheel 72 at its end. This setting wheel 72 is located in the tablet press 1 easily accessible on the side facing away from the rotary unit 5 side of the guide plate 4. The shaft 71 is surrounded and guided by the housing 48 to the guide plate 4 of the column 48 coaxial. The axis of rotation of the shaft 71 coincides with the axis of rotation A of the rotary unit. Each of the spindle mechanisms 67 has a cylindrical body 73 having a shoulder 74. The shoulders 74 of all three spindle mechanisms 67 are orthogonal to the axis of rotation A in the same plane and are in the tablet press 1 in abutment with the drive unit 8. The housing plate 14 further has a through hole 76 for the Auswerfstange 56 on.

In FIG. 9 For the most part, the pressing force generating unit 17 is shown. FIG. 10 shows a cross-sectional view along the section plane II in FIG. 9 , The sectional plane II extends slightly offset from the center of the two tie rods 18, 19 in the direction of the also indicated axis of rotation A of the rotary unit 5, so that the upper punch 21 is not cut anymore.

The pressing force generating unit 17 in this embodiment sometimes includes a large pneumatic cylinder 77, two small pneumatic cylinders 78, and a top plate 16. The large cylinder 77 is essentially formed from a large, circular, and plate-like piston 79, a piston ring 79 laterally enclosing cylinder ring 80 and the piston 79 facing side of the top plate 16. Compressed air connections 81 on the side facing away from the piston 79 of the top plate 16 and corresponding channels in the interior of the top plate allow compressed air to the upper plate 16 facing side of the large piston 79th

In the axial direction below the large cylinder 77 are the two small cylinders 78. A small cylinder 78 consists of a smaller, circular piston 82 and a corresponding cylinder housing 83. The two small cylinders 78 are in the same plane orthogonal to the axis of rotation A and are spaced from each other , The large piston 79 rests on the two small pistons 82.

In each case from the center of the two small pistons 82 extends in the axial direction upward one of the two columnar tie rods 18, 19. The small piston 82 are fixedly connected to the respective tie rods 18, 19.

In FIG. 9 Furthermore, the Auswerfstange 56 can be seen, which extends parallel to the axis of rotation A from the interior of the top plate 16 in the direction of the rotary unit 5. The Auswerfstange 56 sits on a movable piston of a pneumatic Auswerfzylinders, which is not shown here. The Auswerfstange 56 is guided in the associated through holes of Füllvolumeneinstellmechanismus 15, the clutch unit 12, the drive unit 8 and the control plate 7.

In the following, the function and mode of action of the embodiment of the tablet press shown in the drawings and the method according to the invention for producing a tablet will be described in more detail.

The Füllgutzuführungseinrichtung 2 continuously transports contents from the container 84 by means of the two conveyor wheels and the influence of gravity from above into the filling channel 57, so that this contains a large part of its length filling. When the individual female molds 23 are at their respective machining positions, two of the female molds 23 opaque with their upper openings below the lower opening portion of the filling channel 57, so that, when the rotary unit 5 is in the resting or arresting position, contents simultaneously two matrix forms can be promoted. The one of the two female molds, which is close to empty at this time, lies below the beginning of the filling channel 57 viewed in the direction of rotation, and the second female mold, which is almost completely filled, lies below the end of the filling channel 57.

Now the female mold 23, which is located at the beginning of the filling channel 57, is moved towards the next processing position at the end of the filling channel 57 and thereby completely filled with filling material. The die plate 22 presses at this and any other time biased by the plate springs 65 against the fixed guide plate 4 and the filling channel 57. The lower punch 31 is always arranged in this, as well as in all other steps in the female mold 23 and rotates with the rotary unit 5 with ,

Subsequently, the filled mold die 23 is moved to the subsequent processing position of the pressing. In this movement, the edge of the filling channel 57 facing the rotary unit 5 and its inner wall brushes off excess contents above the female mold 23 and retains this excess in the filling channel. At this time, the tablet forming side of the upper punch 21 is still above the die plate 22. Accordingly, the large piston 79 is in a first position in a plane orthogonal to the rotation axis A, as in FIG FIG. 10 shown.

When the filled die mold 23 has arrived in the processing position of compression, compressed air is applied to the upper side of the large piston 79 via the compressed air ports 81, so that the piston 79 presses against the small pistons 82. The small cylinders 78 are deaerated at the same time. Under the force of the large piston 79, the small pistons 82 pull the upper punch 21 toward the lower punch 31 via the tie rods 18, 19 and the yoke 20, thereby pressing the tablet in the female mold 23. The end position of the upper punch 21 during pressing is determined by a stop between the rotary unit 5 opposite sides of the small piston 82 and the cylinder housings 83. The large piston 79 is now in its second position in a plane orthogonal to the axis of rotation A, wherein the second position is offset in the axial direction down to the first position.

The lower punch 31 is not moved during the pressing process and forms the bottom of the tablet. During the pressing of the lower punch 31 associated sliding pin 33 is on the first depth of the control plate 42.

After the upper punch 21 has reached its end position, pressure is applied to the small piston 82 and at the same time the large cylinder 77 is vented. As a result, the large piston 79 is returned to its first position and thus the upper punch 21 is moved back to its original position. The pressing force generating unit 17 is now available for a further pressing operation.

After completion of the pressing operation, the female mold 23 is rotated with the pressed tablet to the subsequent ejection position. In this case, the lower punch 31 is lowered immediately after leaving the pressing position by the second depth 43 of the control plate, so that the pressed tablet can exert no more force on the lower punch 31 and the holding plate 34 on the slide pin 33 and thus the control plate 7.

Subsequently, the female mold 23 with the pressed tablet is in the machining position for ejection. At the beginning of the Auswerfzyklus is the free end of Auswerfstange 56 in a position offset from the end face of the sliding pin 33 which is in contact with the control plate. Subsequently, the ejection pneumatic cylinder pushes the ejection rod 56 against the grinding pin 33, whereby the lower punch 31 conveys the pressed tablet out of the female mold 23. The tablet now located on the upper side of the die plate 22 can subsequently be carried away from the rotary unit 5, for example by a rake and a chute.

The rotary unit described in this embodiment has a plurality of female molds 23. A filling, pressing and ejecting takes place here at the same time in several mold forms in the individual processing positions of the tablet press 1.

The drive unit 8 rotates the rotary unit 5 stationwise or indexed between the individual processing positions. The strong air cylinder 10 thereby rotates the rotary unit 5 exclusively in the direction of the processing order, i. in the direction of rotation 86. In this case, the strong air cylinder 10 moves its rack 49 away from itself, whereby the ring gear 47 rotates. The coupling pins 62 are pneumatically charged at this time and in engagement with the engaging holes 30 of the coupling ring 29 and thus give the rotation of the ring gear 47 to the rotary unit 5 on. If the rotary unit 5 is finally in the desired processing position, the indexing unit 6 performs an engagement with the corresponding recess 28 on the locking ring 27 with the aid of a pneumatically extendable latching element and thereby locks the rotary unit 5. The coupling pins 62 are then pneumatically lowered so that they engage no longer protrude from the side surface 64 of the ring gear. The form fit between the ring gear 47 and rotary unit 5 is no longer given. Now, the weaker air cylinder 11 moves its rack 50 away from itself and thus moves via the ring gear 47 and the rack 49, the stronger air cylinder 10 in its original position.

Subsequently, the rotary unit can be driven again by the stronger air cylinder 10 in the intended direction of rotation.

If the filling volume of the female mold 23 or the tablet size and / or tablet density is to be changed at any time, then the setting wheel 72 of the filling volume setting mechanism 15 is rotated. Rotation of the thumbwheel 72 causes raising or lowering of the shoulders 74, the drive unit 8, the control plate 7, the slide pin 33, the holding plate 34 and the lower punch 31, which results in increasing or decreasing the filling volume in the female mold 23 ,

1. 1. Tablettenpresse (1), mit einer Dreheinheit (5), die mindestens eine Matrizenform (23) zum Formen der Tablette aufweist, einer Antriebseinheit (8), welche die Dreheinheit (5) stationsweise zwischen einzelnen Bearbeitungspositionen rotieren lässt, und mindestens einem Unterstempel (31),
   dadurch gekennzeichnet,
   dass der Unterstempel (31) mit der Dreheinheit (5) rotierend in der Matrizenform (23) angeordnet ist.
2. 2. Tablettenpresse nach Ausführungsform 1,
   dadurch gekennzeichnet,
   dass eine Steuerplatte (7) für eine Kurvensteuerung der Unterstempelposition vorgesehen ist.
3. 3. Tablettenpresse nach Ausführungsform 2,
   dadurch gekennzeichnet,
   dass eine Belastungsvorrichtung (32) den Unterstempel (31) gegen die Steuerplatte (7) drückt.
4. 4. Tablettenpresse nach Ausführungsform 3,
   dadurch gekennzeichnet,
   dass die Belastungsvorrichtung (32) innerhalb der Dreheinheit (5) angeordnet ist.
5. 5. Tablettenpresse nach einer der vorherigen Ausführungsformen,
   dadurch gekennzeichnet,
   dass der Unterstempel (31) in seiner Position unmittelbar nach dem Verpressen im Vergleich zu seiner Endposition beim Verpressen abgesenkt ist.
6. 6. Tablettenpresse nach einer der vorherigen Ausführungsformen,
   dadurch gekennzeichnet,
   dass der Unterstempel (31) als Auswerfer für eine gepresste Tablette ausgebildet ist.
7. 7. Tablettenpresse nach einer der vorherigen Ausführungsformen,
   gekennzeichnet durch
   eine Kupplungseinheit (12), welche die Antriebseinheit (8) mit der Dreheinheit (5) koppeln und von ihr entkoppeln kann.
8. 8. Tablettenpresse nach Ausführungsform 7,
   dadurch gekennzeichnet,
   dass die Kupplungseinheit (12) in einer Bearbeitungsposition die Antriebseinheit (8) von der Dreheinheit (5) entkoppelt.
9. 9. Tablettenpresse nach einer der vorherigen Ausführungsformen,
   dadurch gekennzeichnet,
   dass die Antriebseinheit (8) einen Linearaktuator (10, 11) aufweist.
10. 10. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    dadurch gekennzeichnet,
    dass die Antriebseinheit (8) einen ersten und einen zweiten Linearaktuator (10, 11) aufweist, wobei die beiden Linearaktuatoren (10, 11) einander entgegengesetzt arbeiten.
11. 11. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    dadurch gekennzeichnet,
    dass eine Indexiereinheit (6) vorgesehen ist, welche die Dreheinheit (5) in einer Bearbeitungsposition arretiert.
12. 12. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    gekennzeichnet durch
    einen Füllkanal (57), in welchem das Füllgut der Matrizenform (23) zugeführt wird.
13. 13. Tablettenpresse nach Ausführungsform 12,
    dadurch gekennzeichnet,
    dass der Füllkanal (57) einen Bereich einer Bewegungsbahn der Matrizenform (23) überdeckt.
14. 14. Tablettenpresse nach einer der Ausführungsformen 12 oder 13,
    dadurch gekennzeichnet,
    dass die Dreheinheit (5) und der Füllkanal (57) vorgespannt gegeneinander drücken.
15. 15. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    gekennzeichnet durch
    eine Presskrafterzeugungseinheit (17), welche unterhalb der Dreheinheit (5) angeordnet ist.
16. 16. Tablettenpresse nach Ausführungsform 15,
    dadurch gekennzeichnet,
    dass die Presskrafterzeugungseinheit (17) beim Verpressen einen Oberstempel (21) in Richtung gegen den Unterstempel (31) zieht.
17. 17. Tablettenpresse nach einer der Ausführungsformen 15 und 16,
    dadurch gekennzeichnet,
    dass die Presskrafterzeugungseinheit (17) einen Druckzylinder (77) und mindestens einen weiteren Druckzylinder (78) aufweist, wobei der eine Druckzylinder (77) den Oberstempel beim Verpressen von einer Ausgangslage in Richtung gegen den Unterstempel zieht und der mindestens eine weitere Druckzylinder (78) den Oberstempel nach dem Verpressen in seine Ausgangslage zurückbewegt.
18. 18. Tablettenpresse nach Ausführungsform 17,
    dadurch gekennzeichnet,
    dass der mindestens eine weitere Druckzylinder (78), der den Oberstempel nach dem Verpressen in seine Ausgangslage zurückbewegt, kleiner ist als der Druckzylinder, der den Oberstempel in Richtung gegen den Unterstempel zieht.
19. 19. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    dadurch gekennzeichnet,
    dass das Füllvolumen der Matrizenform (23) veränderbar ist.
20. 20. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    dadurch gekennzeichnet,
    dass das Füllvolumen der Matrizenform (23) über die Position des Unterstempels (31) veränderbar ist.
21. 21. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    dadurch gekennzeichnet,
    dass das Füllvolumen der Matrizenform (23) während der Rotation der Dreheinheit (5) veränderbar ist.
22. 22. Tablettenpresse nach einer der vorherigen Ausführungsformen,
    dadurch gekennzeichnet,
    dass die Tablettenpresse pneumatisch angetrieben ist.
23. 23. Verfahren zum Herstellen einer Tablette, wobei eine Dreheinheit (5) mindestens eine Matrizenform (23) zum Formen der Tablette aufweist und stationsweise zwischen einzelnen Bearbeitungspositionen rotiert,
    dadurch gekennzeichnet,
    dass ein Unterstempel (31) in der Matrizenform (23) angeordnet ist und mit der Dreheinheit (5) rotiert.
24. 24. Verfahren nach Ausführungsform 23,
    dadurch gekennzeichnet, dass der Unterstempel (31) unmittelbar nach dem Verpressen abgesenkt wird im Vergleich zu seiner Endposition beim Verpressen.
25. 25. Verfahren nach einer der Ausführungsformen 23 und 24,
    dadurch gekennzeichnet,
    dass die gepresste Tablette vom Unterstempel (31) ausgeworfen wird.
26. 26. Verfahren nach einer der Ausführungsformen 23 bis 25,
    dadurch gekennzeichnet,
    dass in einer Bearbeitungsposition die Dreheinheit (5) und eine Antriebseinheit (8) voneinander entkoppelt werden.
27. 27. Verfahren nach einer der Ausführungsformen 23 bis 26,
    dadurch gekennzeichnet,
    dass die Matrizenform (23) entlang eines Füllkanals (57) befüllt wird.
28. 28. Verfahren nach einer der Ausführungsformen 23 bis 27,
    dadurch gekennzeichnet,
    dass beim Verpressen ein Oberstempel (21) in Richtung gegen den Unterstempel (31) gezogen wird.
29. 29. Verfahren nach einer der Ausführungsformen 23 bis 28,
    dadurch gekennzeichnet,
    dass die Dreheinheit (5) rotiert und gleichzeitig das Füllvolumen der Matrizenform (23) veränderbar ist.

Further possible embodiments of the invention are:

1. A tablet press (1) comprising a rotary unit (5) having at least one female mold (23) for molding the tablet, a drive unit (8) which rotates the rotary unit (5) station by station between individual processing positions, and at least one lower punch (31)
   characterized,
   that the lower punch (31) with the rotary unit (5) is arranged to rotate in the die form (23).
2. 2. tablet press according to embodiment 1,
   characterized,
   in that a control plate (7) is provided for a curve control of the lower punch position.
3. 3. tablet press according to embodiment 2,
   characterized,
   a loading device (32) presses the lower punch (31) against the control plate (7).
4. 4. tablet press according to embodiment 3,
   characterized,
   in that the loading device (32) is arranged inside the rotary unit (5).
5. 5. tablet press according to one of the previous embodiments,
   characterized,
   that the lower punch (31) is lowered in its position immediately after the pressing compared to its final position during pressing.
6. 6. tablet press according to one of the previous embodiments,
   characterized,
   that the lower punch (31) is designed as ejector for a pressed tablet.
7. 7. tablet press according to one of the previous embodiments,
   marked by
   a coupling unit (12) which can couple the drive unit (8) with the rotary unit (5) and decouple from it.
8. 8. tablet press according to embodiment 7,
   characterized,
   the coupling unit (12) decouples the drive unit (8) from the rotary unit (5) in a processing position.
9. 9. tablet press according to one of the previous embodiments,
   characterized,
   the drive unit (8) has a linear actuator (10, 11).
10. 10. tablet press according to one of the previous embodiments,
    characterized,
    in that the drive unit (8) has a first and a second linear actuator (10, 11), wherein the two linear actuators (10, 11) operate opposite to one another.
11. 11. tablet press according to one of the previous embodiments,
    characterized,
    an indexing unit (6) is provided which locks the rotary unit (5) in a processing position.
12. 12. tablet press according to one of the previous embodiments,
    marked by
    a filling channel (57), in which the filling material of the female mold (23) is supplied.
13. 13. tablet press according to embodiment 12,
    characterized,
    the filling channel (57) covers a region of a movement path of the female mold (23).
14. 14. tablet press according to any one of embodiments 12 or 13,
    characterized,
    that the rotary unit (5) and the filling channel (57) bias against each other press.
15. 15. tablet press according to one of the previous embodiments,
    marked by
    a pressing force generating unit (17) disposed below the rotary unit (5).
16. 16. tablet press according to embodiment 15,
    characterized,
    in that the pressing force generating unit (17) pulls an upper punch (21) towards the lower punch (31) during pressing.
17. 17. tablet press according to any one of embodiments 15 and 16,
    characterized,
    in that the press force generating unit (17) has a pressure cylinder (77) and at least one further pressure cylinder (78), wherein the one pressure cylinder (77) pulls the upper punch during pressing from a starting position in the direction against the lower punch and the at least one further pressure cylinder (78) the upper punch after pressing back into its original position.
18. 18. tablet press according to embodiment 17,
    characterized,
    that the at least one further pressure cylinder (78), which moves the upper punch back to its starting position after pressing, is smaller than the pressure cylinder, which pulls the upper punch in the direction against the lower punch.
19. 19. tablet press according to one of the previous embodiments,
    characterized,
    that the filling volume of the female mold (23) is variable.
20. 20. tablet press according to one of the previous embodiments,
    characterized,
    the filling volume of the female mold (23) can be changed via the position of the lower punch (31).
21. 21. tablet press according to one of the previous embodiments,
    characterized,
    the filling volume of the female mold (23) is variable during the rotation of the rotary unit (5).
22. 22. tablet press according to one of the previous embodiments,
    characterized,
    that the tablet press is pneumatically driven.
23. 23. A method for manufacturing a tablet, wherein a rotary unit (5) has at least one mold form (23) for forming the tablet and rotates stationwise between individual processing positions,
    characterized,
    a lower punch (31) is arranged in the female mold (23) and rotates with the rotary unit (5).
24. 24. Method according to embodiment 23,
    characterized in that the lower punch (31) is lowered immediately after the pressing compared to its final position during pressing.
25. 25. Method according to one of the embodiments 23 and 24,
    characterized,
    that the pressed tablet is ejected from the lower punch (31).
26. 26. Method according to one of the embodiments 23 to 25,
    characterized,
    that in a processing position, the rotary unit (5) and a drive unit (8) are decoupled from each other.
27. 27. Method according to one of the embodiments 23 to 26,
    characterized,
    the mold (23) is filled along a filling channel (57).
28. 28. Method according to one of the embodiments 23 to 27,
    characterized,
    that during pressing a top punch (21) is pulled in the direction against the lower punch (31).
29. 29. Method according to one of the embodiments 23 to 28,
    characterized,
    that the rotary unit (5) rotates and at the same time the filling volume of the female mold (23) is variable.

Claims (15)

A tablet press (1) comprising a rotary unit (5) having at least one female mold (23) for forming the tablet, a drive unit (8) which rotates the rotary unit (5) station by station between individual processing positions, and at least one lower punch (31 )
characterized,
that the lower punch (31) with the rotary unit (5) is arranged to rotate in the die form (23). Tablet press according to claim 1,
marked by
a pressing force generating unit (17) disposed below the rotary unit (5), wherein preferably the pressing force generating unit (17) pulls an upper punch (21) towards the lower punch (31) during pressing. Tablet press according to claim 2,
characterized,
in that the press force generating unit (17) has a pressure cylinder (77) and at least one further pressure cylinder (78), wherein the one pressure cylinder (77) pulls the upper punch during pressing from a starting position in the direction against the lower punch and the at least one further pressure cylinder (78) the upper punch after pressing back into its original position, wherein preferably the tablet press is driven pneumatically, and in particular the at least one further pressure cylinder (78), which moves the upper punch after pressing back to its original position, smaller than the impression cylinder, the upper punch in Direction against the lower punch pulls. Tablet press according to one of the preceding claims,
characterized,
in that a control plate (7) is provided for curve control of the lower punch position, wherein preferably a loading device (32) presses the lower punch (31) against the control plate (7), and in particular the loading device (32) is arranged inside the rotary unit (5). Tablet press according to one of the preceding claims,
characterized,
that the lower punch (31) is lowered in its position immediately after the pressing compared to its final position during pressing, and / or that the lower punch (31) is designed as ejector for a pressed tablet. Tablet press according to one of the preceding claims,
marked by
a coupling unit (12) which can couple the drive unit (8) with the rotary unit (5) and decouple from it, wherein preferably in a processing position the coupling unit (12) decouples the drive unit (8) from the rotary unit (5). Tablet press according to one of the preceding claims,
characterized,
in that the drive unit (8) comprises a linear actuator (10, 11), preferably a first and a second linear actuator (10, 11), the two linear actuators (10, 11) operating in opposite directions; and / or that an indexing unit (6) is provided, which locks the rotary unit (5) in a processing position. Tablet press according to one of the preceding claims,
marked by
a filling channel (57) in which the filling material is fed to the female mold (23), wherein preferably the filling channel (57) covers a region of a movement path of the female mold (23); and / or in that the rotary unit (5) and the filling channel (57) press biased against each other. Tablet press according to one of the preceding claims,
characterized,
that the filling volume of the female mold (23) is variable, preferably, the filling volume of the female mold (23) on the position of the lower punch (31) is variable; and / or that the filling volume of the female mold (23) during the rotation of the rotary unit (5) is variable. Method for producing a tablet, wherein a rotary unit (5) has at least one die mold (23) for forming the tablet and rotates stationwise between individual processing positions,
characterized,
that a lower punch (31) into the female mold (23) and rotates with the rotating unit (5). Method according to claim 10,
characterized,
that during pressing a top punch (21) is pulled in the direction against the lower punch (31). Method according to claim 10 or 11,
characterized in that the lower punch (31) is lowered immediately after the pressing compared to its final position during pressing, and / or that the pressed tablet is ejected from the lower punch (31). Method according to one of claims 10 to 12,
characterized,
that in a processing position, the rotary unit (5) and a drive unit (8) are decoupled from each other. Method according to one of claims 10 to 13,
characterized,
that the female mold (23) along a feed channel (57) is filled. Method according to one of claims 10 to 14,
characterized,
that the rotary unit (5) rotates and at the same time the filling volume of the female mold (23) is variable.

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