DE4025487C2 - - Google Patents

Description

The invention relates to a filling and dosing device for the matrices of a rotary tablet machine according to the Preamble of claim 1.

A filling and dosing device of the generic type is from the DE-GM 75 35 875 known. The filling and dosing device includes one Endless belt that is between a lower plate and a upper protective cover moves. Arranged on the inside of the belt cam-like projections engage in corresponding Cutouts from pulleys. By the on the outside of the belt formed wing-like blades  that through an inlet opening into that of the lid and the Plate formed chamber introduced powder in the direction of a first exhaust port moves. The first outlet is located above the matrices to be loaded. The Excess powder on the matrices is perpendicular to the stripped edges of two drop openings and through the blades formed on the belt are removed. The Belt blades cannot fulfill the stripping function because the lower plate is arranged between them and the matrices is.

In a further known filling device according to the DE 26 39 090 B2 is a gear housing on a base plate arranged in which a filling wheel with radially aligned Wings rotated clockwise. Spread the wings in the working position of the filling device the individual matrices and fill tablet powder into the matrices. Behind the Filling wheel is a metering wheel, the angled wing that rotate counterclockwise. By means of the The metering wheel becomes excess powder over the individual Matrices of the matrix table stripped and into the work area of the filling wheel.

The known filling and dosing devices have no filling area or skimming area in which Collect stripped excess powder and remove from the powder can be returned to the filling process. The in the known filling and dosing devices designed for powder transport Wings don't have the job of making the excess Stripping powder from the matrices without loss and into the Filling process. It can therefore in the known Filler come in that powder material, for. B. toxic powder material emerges from the filling device and the operating personnel are endangered.

The invention is therefore based on the object Filling and dosing device of the generic type  develop that for even filling of the matrices a sufficient amount of powder is regularly available, with an almost lossless pull and immediate Return of the excess powder in the filling housing. To belongs to a regulated filling of the interior of the filling housing.

The solution to this problem results from the Features of claim 1. A device for controlled feeding of the powder into the filling housing itself known.

Due to the bulge forming the filling area curve the inner wall of the in a known manner with the end faces lying tightly on the surface of the die table, housing frame open at the bottom is connected with the rear deflection slope of each metering scoop achieved that for filling the dies of the die table regularly a sufficient amount of powder material Is available that accumulates in the filling area curve, so that a good degree of filling of the matrices is achieved. The Powder jam in the filling area curve arises as a result of Speed difference between the movement of the die table and the movement of the timing belt with the cams. The accumulated powder is accumulated through the rear Deflection bevel pushed towards the matrices. Likewise, the flat projections (chicanes) Powder material directed from the opposite direction to the center of the die. In the Fill range curve is filled in the pitch circle of the Matrices with powder material lowered lower stamps. The outer areas, i.e. H. the Tips of the cams describe a path that the Circle of the matrix table which has matrices is tangent. The Excess powder material is removed in the direction of rotation the dosing scoops at the front are conveyed further and passes the following flat projections (chicanes)  and the space extension in between and reaches the in Direction of rotation behind the filling area curve area curve. In the area of the skimming area curve are the Lower stamp already raised to such an extent that excess powder material from the matrices. This is in the intersection between the skimming curve and stripped the pitch circle and by means of the metering vanes Cams conveyed in the direction of rotation of the cams.

Further advantageous embodiments of the invention result itself from the further subclaims.

The invention is based on one in the drawings illustrated embodiment of a filling and Dosing device for the matrices of a rotary tablet machine explained in more detail. Show it:

Fig. 1 is a plan view of the the die table of a rotary tabletting machine partially overlapping filling and metering unit,

Fig. 2 is a vertical section along the line AA in Fig. 1,

Fig. 3 is a longitudinal section along the line BB in Fig. 1,

Fig. 4 is a plan view of the housing frame made of plastic with removed intermediate plate and the housing cover removed,

Fig. 5 shows a detail cross section along the line DD in Fig. 4 and

Fig. 6 shows a further detailed cross-section along the line EE in Fig 1..

The filling and dosing device 1 for the matrices of a die table 3 of a rotary tableting machine rotating on the pitch circle 2 partially covers the die table 3 over a circumferential angle of approximately 100 °. The filling and dosing device 1 is used to fill the matrices of the die table 3 with powder material and to remove the excess powder material after the lower punches have been lifted, a loss-free supply and discharge of the powder material to be achieved.

The filling and dosing device 1 first comprises a housing frame 4 made of plastic, in particular polyamide, which rests tightly on the die table 3 , so that no powder material can escape between the housing frame 4 and the die table 3 . The shape of the housing frame 4 and its interior 5 result in particular from FIG. 4. The housing frame 4 and its interior 5 are covered by an intermediate plate 6 made of aluminum. A housing cover 7 made of aluminum is placed on the intermediate plate 6 and screwed to the housing frame 4 by means of threaded screws 8 such that the intermediate plate 6 made of aluminum is firmly clamped. Within the housing cover 7 are two as toothed belt pulley 9 , 10 trained planet wheels which are arranged in the interior 5 of the housing frame 4 . The toothed belt pulley 9 shown on the right in FIG. 3 is firmly connected to a drive shaft 11 which is rotatably supported by roller bearings 12 mounted in the housing cover 7 and is driven in rotation in a manner not shown. The toothed belt pulley 10 shown on the left in FIG. 3 is rotatably supported on an axle 13 which is firmly inserted in the housing cover 7 via roller bearings 14 . Both toothed belt pulleys 9 , 10 are provided in the cross-sectional plane of the intermediate plate 6 made of aluminum with cover plates 15 made of plastic, in particular polyamide, which are screwed by thread 16 to the toothed belt pulleys 9 , 10 . Between the two toothed pulleys 9, 10 of the body frame 4 is in the inner space 5, an intermediate rail 17 made of plastic, in particular polyamide stored, which according to FIG. 4 includes the located between the toothed pulleys 9, 10 between the space tight. The shape of the intermediate rail 17 results in particular from FIG. 4. Around both toothed belt pulleys 9 , 10 , an endless belt designed as a toothed belt 18 is placed inside the interior 5 of the housing frame 4, which belt is provided on the outside with a plurality of cams 19 which together with the toothed belt 18 and driven by the drive axis 11 of the toothed belt pulley 9 in a clockwise direction. Each cam 19 comprises in the direction of rotation of the toothed belt 18 on the front of a metering scoop 20 and on the back a deflection 21st The outer straight surfaces 22 of the cams 19 form the outer cam track, to which the interior 5 of the housing frame 4 is closely adapted outside the area in which the housing frame 4 covers the die table 3 . Only in the area above the die table 3 is the interior 5 of the housing frame 4 with its inner wall arranged at a greater distance from the outer cam track. The interior 5 of the housing frame 4 forms, in addition to the toothed belt pulley 10 shown on the left in FIG. 4, a filling area curve 23 and, in addition to the toothed belt pulley 9 shown in FIG. 4, a wiping area curve 24 , between which two flat projections (chicanes) 25 projecting close to the outer cam track are arranged are, which end in the region of the pitch circle 2 and between which a space extension 9 is formed. The powder material located in the interior 5 of the housing frame 4 is taken along by means of the cams 19 rotating in the clockwise direction together with the toothed belt 18 and pressed into the filling area curve 23 . As a result of the speed difference between the movement of the die table 3 and the movement of the toothed belt 18 with the cams 19 , a powder jam occurs in the filling area curve 23 . The accumulated powder is pushed upwards in the direction of the dies by running over the rear deflection slope 21 . Likewise, 25 powder material is led to the center of the die via the flat projections (chicanes). In the filling area curve 23 , the matrices located in the pitch circle 2 of the die table 3 are filled with powder material with the lower punches lowered. The excess powder material is conveyed further by means of the metering blades 20 located at the front in the direction of rotation of the cams 19 and passes the subsequent flat projections (baffles) 25 and the space extension 26 in between and reaches the stripping area curve 24 located behind the filling area curve 23 in the direction of rotation. In the area of the stripping area curve 24 , the lower punches have already been raised to such an extent that excess powder material is obtained from the dies. This is subtracted in the cutting area between the stripping area curve 24 and the pitch circle 2 and conveyed further in the direction of rotation of the cams 19 by means of the metering vanes 20 of the cams 19 .

The powder material is supplied to the interior 5 of the housing frame 4 via a feed opening 30 formed in the housing cover 7 and a feed device 31 placed thereon for the powder material. The feed device 31 comprises a housing 32 screwed onto the housing cover 7 with a first housing opening 33 , in which a tubular feed funnel 34 is mounted directly above the feed opening 30 of the housing cover 7, which has an external toothing 35 at its lower end and an inner toothing in its interior fixed inclined plate 36 is provided. Through the inclined plate 36 , a slot-shaped outlet opening 37 of the feed hopper 34 is shown in the plan view in FIG. 1, which is located directly above the path of movement of the cams 19 of the toothed belt 18 at a maximum amount of powder material, as shown in Fig. 1. By rotating the feed funnel 34 , the outlet opening 37 can be brought above the area of the cover plate 15 covering the toothed belt pulley 10 , so that the outlet opening 37 can be partially or completely closed. The rotation of the feed funnel 34 takes place via a gear 38 meshing with the external toothing 35 of the feed funnel 34 , which is mounted with the axis 39 via roller bearings 40 , 41 both in the housing cover 7 for the housing frame 4 and in the housing 32 of the feed device 31 and via which the outlet opening 37 of the feed funnel 34 is set. The setting of the position of the outlet opening 37 relative to the cover disk 15 of the toothed belt pulley 10 located underneath takes place on the one hand depending on the degree of filling of the interior 5 of the filling and metering device 1 or of the housing frame 4 . For this purpose, a measuring and control device is attached to the filling and dosing device 1 in a manner not shown in detail. Thus, a float can be attached to the powder material in the interior 5 , which is raised by the powder material and thus determines the degree of filling of the interior 5 . A capacitive transmitter with a certain switching distance can also be fitted in the interior 5 , which responds to a certain powder material height. Strain gauges or piezo elements can also be provided in the interior 5 to determine the dynamic pressure. Finally, the power or the torque can be measured via the motor current for the drive axis 11 of the toothed belt 19 , it being true that a larger amount of powder material in the interior requires more drive power and thus a higher torque. The filling and dosing device can thus be regulated on the one hand via the speed of the die table 3 and on the other hand via the degree of filling of the interior 5 in its speed.

Claims (7)

1. Filling and dosing device for filling the matrices of the die table of a rotary tableting machine with powder material, with a filling housing that covers the part circle of the die table facing the matrices over an angle of approx. 100 °, with one by two in the filling housing stored revolving wheels, on the outside provided with cams endless belts and with a housing frame enclosing the outer track of the cams, characterized in that the inner wall of the table lying closely on the surface of the dies, open at the bottom and with its end face sliding on the die surface Housing frame ( 4 ) has a filling area curve ( 23 ) and a wiping area curve ( 24 ) which are formed from bulges of the housing frame ( 4 ) covering the part circle ( 2 ) of the matrices, that between the two curves ( 23 , 24 ) at least one to the outer path of the cams ( 19 ) led flä chiger projection ( 25 ) is arranged and that the cams ( 19 ) in the direction of rotation (arrow 42 ) of the endless belt ( 18 ) on the front metering vanes ( 20 ) and on the back have deflection bevels ( 21 ) for the powder material and that a device ( 31 ) for the controlled feeding of the powder into the filling housing. 2. Filling and dosing device according to claim 1, characterized in that between the two planet gears ( 9 , 10 ) a gap closing the gap and to the thickness of the gears ( 9 , 10 ) adapted intermediate rail ( 17 ) is arranged made of plastic. 3. Filling and dosing device according to one of claims 1 to 2, characterized in that the filling housing is formed from the housing frame ( 4 ) made of plastic and from an upwardly sealing metallic intermediate plate ( 6 ) and from a metallic housing cover ( 7 ) . 4. Filling and dosing device according to claims 1 and 3, characterized in that the housing cover 7 has a feed opening ( 30 ) and the associated controllable feed device ( 31 ) for the powder material. 5. Filling and dosing device according to claim 4, characterized in that the controllable feed device ( 31 ) from a rotatably mounted in a housing ( 32 ) tubular feed hopper ( 34 ), a fixed inclined plate ( 36 ) and a drive and Control device is formed. 6. Filling and dosing device according to claim 5, characterized in that the drive and control device for the feed hopper ( 34 ) from an external toothing formed on this ( 35 ), an engaging gear ( 38 ) and a drive this drive controllable drive motor is formed. 7. Filling and dosing device according to claim 6, characterized in that the control of the controllable drive motor takes place in dependence on the speed of the die table ( 3 ) and in dependence on the amount of powder material in the interior ( 5) of the housing frame ( 4 ).