DE2551578A1 - Granulator with rotary stirrer and upright cylindrical vessel - through which drying air flows vertically upwards - Google Patents

Abstract

The coaxially-carried stirrer has two or more blades, and each blade has a run-off surface which is inclined upwards and backwards from the lower leading edge of the blade close to the vessel floor. The run-off maintains a free space behind the rotating blade into which the air, which introduced through the blade, is able to discharge. Used for granulation of pharmaceuticals products, basic materials, explosives and retardants, solid lubricants. Very small vols. of air are required for fluidisation of the bed of granules.

Description

description

Werner Glatt 7851 B i n z e n Granulator The invention relates to a Granulator with an upright, essentially round container, an im Container close to the bottom thereof about a substantially vertical axis, preferably the container axis, rotatable agitator, an air inlet in the lower area and an air outlet in the upper region of the container.

Granules, which for example consist of active pharmaceutical ingredients, raw materials, Disintegrants or sustained release agents and lubricants can consist of either as build-up granulates from liquid starting materials sprayed into a fluidized bed or fluidized bed or as agglomerating granules from moistened powdery starting materials.

From DT-OS 23 17 129 a granulator is the one described above Type known in which an upper part of the container by means of a lifting device can be lifted from the bottom of the container in such a way that between the bottom and the upper part an annular gap is formed through which a stream of air can be blown when it is desirable to produce built-up granules in the fluidized bed or to dry a granulate. On the other hand, there is the possibility of being lowered Upper part in the closed container agglomerating granules by the action of the agitator to create.

The invention is based on the object of creating a granulator, which is capable of even lower air throughput than the known granulator described is to create a fluidized bed and moreover like the known granulator suitable for the production of agglomerating granules and for drying granules is.

The task is with a granulator of the type described at the beginning according to the invention achieved in that the agitator has two or more blades each has a deflecting surface, which from a front in the direction of rotation, just above the container bottom arranged lower edge rises to the rear and when turning the Agitator has an air inlet space connected to the air inlet in the container contains granulated material free.

This ensures that the air introduced into the container is below and / or there is always air inlet spaces behind the deflector surfaces of the wings, through which it can penetrate constantly changing areas of the granulated material. In the direction of rotation in front of the air inlet spaces, the deflector surfaces generate the blades an upward movement of the material to be granulated. As a result, the air, even if you have low overpressure and / or low flow velocity has been introduced into the container, keep the granulated material in suspension and swirl vigorously. It is not of crucial importance which one Place the air is introduced in the lower area of the container, if only for this it is ensured that the air introduced reaches the air inlet spaces, which as a result the design and movement of the deflection surfaces are kept free of granulated material.

It is advantageous if away from the deflecting surface of each wing a rear wall extends downward. With that, at least achieved, that the deflecting surface is supported and therefore even if it is only made of thin Material, in particular thin sheet metal, does not counteract undesirably the bottom of the container can be pressed. Beyond the stiffening effect the rear walls in certain embodiments of the subject matter of the invention still have advantages, the essentials of which are explained in the further description.

It is useful if the rear wall of each wing is inclined backwards is what in the described arrangement means that the rear wall is completely is arranged below the deflection surface, so that the granulated material from the upper edge the deflection surface flows directly and not on the. Remain on the rear wall can.

The subject matter of the invention is preferably designed in such a way that the back wall of at least one wing is perforated and the area between the deflection surface and rear wall is connected to the air inlet.

In addition, at least one of the wings can have a perforated, have radially outer wall.

There are several options for the air intake space each Rejection surface during operation of the granulator according to the invention from the one contained in the container Holds granulated material free to connect to the air inlet: One possibility exists in that the area below each deflecting surface is designed as an air inlet Hollow shaft is connected to which the wings are attached. It can be useful be if the area below the deflection surface of at least one wing thereby It is also delimited that there is a closed one from the lower edge of the deflecting surface Wing base extends to the rear wall. In this case the through the hollow shaft in the area below the deflection surface is forced into the air, exclusively through holes in the rear wall and optionally in the radially outer wall of the relevant Out of the wing.

Another possibility of air guidance is that all Wing bottoms together cover at least half of the container bottom and this is perforated and designed as an air inlet. In this case the air flows directly behind the wing bottoms in the air inlet spaces through the deflection surfaces be kept free of granulated material. It has been found to be useful when the wing bottoms taken together cover the container bottom to 70 to 80%. In this Case, even with a relatively low air flow, there is a guarantee that the the air flowing in through the bottom of the container is that created by the deflection surfaces Air inlet spaces reached without being significantly hindered by the granulated material will.

If wing bottoms are provided, these can be used regardless of which of the two options for air routing described above was selected will rise radially outward, the container bottom then correspondingly funnel-shaped is designed.

If the wings are not with a wing bottom but in the one described above Way are provided with a perforated back wall, there is a third possibility the air duct is that the perforated back wall of each wing through a tight Panel arranged above the container bottom with the lower edge of the deflecting surface of the next wing is connected and the bottom is perforated and designed as an air inlet is. In this case, the air can only be in the area between the deflection surfaces and Scatter the back walls of the individual wings upwards, only to then through the perforated Back walls to get through into the granulated material.

In most cases, granulators according to the invention are like that known granulators of the type described at the beginning with one opening into the container Liquid line equipped for the injection of granulating liquid. The liquid line can be used with granulators according to the invention as well as with that from DT-OS 23 17 129 known granulator end in a nozzle that is in the middle or upper area of the The container is arranged over the granulated material. Instead it can be described at all Embodiments inventive granulators the creation of air inlet spaces through the deflection surfaces also for better distribution the spray liquid in the granulated material can be used in that under the deflection surface at least one wing arranged at least one rearward-facing nozzle in which the liquid line ends. This development of the invention has the advantage that the liquid is introduced into the container together with the Air enters the air inlet space created by the deflecting surface in question and is quickly deposited on the granulated material.

The granulated material acts like a filter, although the air after can flow off at the top, but holds the sprayed liquid.

In contrast, with known granulators it is inevitable that a considerable part of the liquid sprayed in the container together leaves with the exhaust air, which can lead to costly liquid losses and pollution problems arise.

In the following, exemplary embodiments of the invention are illustrated schematically Drawings explained. It shows: FIG. 1 a vertical axial section through a first embodiment of a granulator; 2 shows a cross section along the line II-II in Figure 1; 3 shows a vertical axial partial section along the line III-III in Fig.2; FIG. 4 shows a modification of FIG. 3; 5 shows a vertical axial section by a second embodiment of a granulator; 6 shows a longitudinal cross-section the line VI-VI in Figure 5; 7 shows a cross-section corresponding to FIG. 6 in a third embodiment of a granulator; and FIG. 8 is a vertical partial section along the line VIII-VIII in Fig.7.

The granulator shown in Fig. 1 has a vertical, circular cylindrical Container 10 with a container bottom 12.

An unloading nozzle 14 is arranged directly above the container bottom 12. About halfway up the container 10 has a closable loading opening 16 on. A liquid line also opens into the interior of the container 10 at approximately half the height 18 in a downwardly directed spray nozzle 20.

The container 10 rests on a box 22 in which a supply air fan 24 is arranged. The intake fan 24 is connected to a known one with its suction side and therefore not shown air heater connected and is with its pressure side connected to a vertical hollow shaft 28 via a stationary connecting piece 26, which extends through the container bottom 12 and as an air inlet for the Container 10 is used. The hollow shaft 28 is shown in Figure 3 below the container bottom 12 mounted in roller bearings 30 and drivable by a motor 34 via a belt drive 32.

At the upper end of the hollow shaft 28 is directly above the container bottom 12 an agitator 36 attached. The operating direction of rotation of the hollow shaft 28 and the Agitator 36 is indicated by arrows 38 in FIG. The agitator 32 has in the in Figure 1 to 3 illustrated embodiment, two diametrically opposite one another Wing 40 and with these wings has a diameter which, according to FIG. 2 and FIG 3 is almost as large as the inner diameter of the container 10. The wings 42 are hollow and, as shown in FIG. 1, have a triangular cross-section with one in the direction of rotation front lower edge 42, from which a deflecting surface 44 rises obliquely backwards. The lower edge 42 is arranged directly above the container bottom 12; she has from this a distance of preferably not more than 5 mm, the container bottom but also lightly touch. Essential to that shown in Figs Embodiment is the feature that the area 46 is below at least one deflection surface 44 is in flow connection with the interior of the hollow shaft 28, so that the supply air fan 24 air conveyed into the hollow shaft 28 reaches the area 46 and from there approximately in the direction of arrows 48, that is, with respect to the Direction of rotation 46 of the agitator 36 to the rear, can flow off.

From the rear upper edge of the deflecting surface 44 of each wing 40 can As shown in Fig. 1 to 3, a screen-like or grid-like perforated rear wall 50 extend downward to just above the container bottom 12. The back wall 50 is in the example shown inclined slightly backwards; so its lower edge is arranged in the direction of rotation in front of its upper edge. The lower edge of the rear wall 50 can, as can be seen from Fig. 1 to 3, through a wing bottom 52 with the lower edge 42 of the deflection surface 44 be connected. Each wing 40 thus forms a hollow body, which expediently has a perforated wall 54 at its radially outer end is closed, through which air can also flow out.

According to FIG. 1, a container attachment 56 is arranged above the container 10, which contains an exhaust air filter 58 and has an exhaust air connection 60 above it.

The granulator shown in Figure 1 to 3 can be, for example operate as follows: the container 10 is fed through the loading opening 16 charged with powdery granulation material 62. Then the loading opening 16 tightly closed, the supply air fan 24 is put into operation and the motor 36 switched on. As a result, a supply air flow passes through the connector 26 and the hollow shaft 28 in the area 46 below the deflection surface 44 at least of a wing 40 and flows in the direction of the arrows 48 into an air inlet space 64, which is caused by the deflection surface 44 of the relevant wing 40 as a result of the rotation of the agitator 36 is kept free of material to be granulated 62. The size of the repellent surfaces 44 created air inlet spaces 64 depends on the given condition of the granulated material 62 and with a given delivery rate of the supply air fan 24 from the speed, with which the agitator 36 is driven; this speed is usually about 250 revolutions per minute and can be adapted to the nature of the Adjust the material to be granulated. The speed at which the air leaves the air intakes 64 from the granulated material 62 flows through and whirled around if necessary, depends on the overpressure on the pressure side for the given properties of the granulated material the supply air fan 24 from; this overpressure is preferably of the order of magnitude between 200 and 750mm water column.

The air that has flowed through the material to be granulated 62 passes through the exhaust air filter 58 to the exhaust air connection 60 and can from there in the usual way an air dryer and heater and then fed again to the supply air fan 24 will.

The modified embodiment shown in Figure 4 differs differs from that shown in Fig. 1 to 3 in that instead of a flat container bottom 12 a funnel-shaped container bottom 12 'is provided and the wings 40 are radial have outwardly rising deflection surfaces 44 'and wing bottoms 52', the Deflection surfaces 44 'rise radially outward less strongly than those on the funnel shape of the container bottom 12 'adapted wing bottoms 52'. There is another difference in that according to Figure 4 instead of or in addition to the liquid line shown in Figure 1 18 with spray nozzle 20 is a liquid line arranged coaxially within the hollow shaft 28 18 'is provided, which branches within the agitator 36 and below of the deflection surfaces 44 'each one to the rear, i.e. against the direction of rotation of the agitator, directed spray nozzle 20 'ends.

The embodiment shown in Figure 5 and 6 differs from that shown in Fig.1 to 3 in that the container 10 instead of the closed Container bottom 12 has a sieve-like perforated container bottom 12 "and that on upper end dex hollow shaft 28 instead of the two-blade agitator 36 a four-blade Agitator 36 ″ is arranged, the individual blades 40 of which, however, correspond to those shown in FIGS are similar to those shown. Immediately below the perforated container bottom 12 "is a supply air chamber 68 divided by a parallel partition 66, which through a fan, not shown, separated from the supply air fan 24 via a Valve 70 can be charged with dried and heated supply air if required. Dems supply air fan A valve 72 is also connected upstream. In the container attachment 56 is above of the exhaust air filter 58, a suction fan 74 is arranged.

The granulator shown in Fig.5 and 6 can work in the same way that shown in FIGS. 1 to 3 when the valve 70 is closed and the valve 72 is closed is open. In this case, the supply air fan 24 presses supply air via the connecting piece 26 and the hollow shaft 28 in the wings 40 and through their perforated rear walls 50 in the air inlet spaces formed behind the blades 40 as a result of the rotation of the agitator 36 ″ and further up through the granulated material 62.

The granulator shown in FIGS. 5 and 6 can optionally be used with the closed Valve 72 and open valve 70 exclusively through the supply air chamber 68 and the perforated container bottom 12 ″ are supplied with air. In this case, it arrives the supply air essentially only in the areas between the individual blades 40 into the interior of the container 10, since the remaining areas of the container bottom 12 " are covered by the wing bottoms 52. Also in this mode of operation is a uniform distribution of the supply air in the granulated material 62 promoted in that the Rejection surfaces 44 as a result of the rotation of the agitator 36 "air inlet spaces 64 behind the individual wings 40 form. The decision on whether to use the supply air exclusively through the agitator 36 "or exclusively through the perforated container bottom 12" is introduced into the interior of the container 10, depends on the specifics of the Granulierguts from. Both modes of operation can also be combined with each other, by the valves 70 and 72, as indicated in Figure 5, both at least partially be opened. The two modes of operation can also be mutually exclusive in the course of one Detach the granulation process once or several times.

The embodiment of a granulator shown in FIGS differs from that shown in FIGS through this, that as in Figure 5 and 6 instead of a closed container bottom 12 a sieve-like perforated container bottom 12 "is provided, and further in that the wing bottoms 52 are missing, so the wings 40 are open at the bottom, but the spaces between the individual wings by one each arranged just above the container bottom 12 ″ Aperture 76 are covered. Each of the two apertures 76 extends from the lower one Edge of the perforated rear wall 50 of a wing 40 to the lower edge 42 of the deflection surface 44 of the next wing. Instead of two wings 40, several wings can be provided be, for example four as in the embodiment according to FIGS.

During operation of the granulator shown in FIGS. 7 and 8, the Supply air through the perforated container bottom 12 "first into the hollow wings 40 and then flows through their perforated rear walls 50 in the same way to the outside as based Fig. 1 to 3 described.

In all of the embodiments described, it is possible without the 1 and 5 shown and normally also in the embodiments according to 4 as well as 7 and 8 provided motor 34 manage when the in the wings 40 The incoming air has sufficient overpressure to allow it to flow through the perforated rear wall 50 to generate reaction forces that are able to operate the agitator to turn.

Claims (12)

To claims 1. Granulator with an upright, essentially round container, one in the container just above its bottom by essentially one vertical axis, preferably the container axis, rotatable agitator, a Air inlet in the lower area and an air outlet in the upper area of the container, in that the agitator (36) has two or more blades (40) with. each has a deflection surface (44), which is supported by a front in the direction of rotation, just above the container bottom (12) arranged lower edge (42) rises to the rear and when the agitator rotates, an air inlet space connected to the air inlet (64) from the granulated material (62) contained in the container (10). 2. Granulator according to claim 1, characterized in that g e k e n n z e i c h -n e t that there is a rear wall (50) after the deflection surface (44) of each wing (40) extends below. 3. Granulator according to claim 2, characterized in that g e k e n n z e i c h -n e t that the rear wall (50) of each wing (40) is inclined backwards. 4. Granulator according to claim 2 or 3, characterized in that g e k e n n -z e i c h n e t that the rear wall (50) of at least one wing (40) is perforated and the Area (46) between deflection surface (44) and rear wall (50) connected to the air inlet is. 5. Granulator according to claim 4, characterized in that g e k e n n z e i c h -n e t that at least one of the wings (40) is also perforated, radially outer Has wall (54). 6. Granulator according to claim 4 or 5, characterized in that g e k e n n -z e i c h n e t that the area (46) below each deflection surface (44) with one as an air inlet formed hollow shaft (28) is connected to which the wings (40) are attached. 7. Granulator according to one of claims 2 to 6, characterized in that g e -k e n nz e i c h n e t that from the lower edge (42) of the deflection surface (44) there is a closed Wing base (52) extends to the rear wall (50). 8. Granulator according to claim 7, characterized in that g e k e n n z e i c h -n e t that all wing bottoms (52) taken together the container bottom (12) at least cover halfway and this is perforated and designed as an air inlet. 9. Granulator according to claim 8, characterized in that it is e k e n n z e i c h -n e t that the wing bottoms (52) taken together the container bottom (12) to 70 to 80 % cover. 10. Granulator according to one of claims 7 to 9, characterized g e -k e n n z e i c h n e t that the wing bottoms (52) rise radially outward and the Container bottom (12) is designed in a funnel-shaped manner. 11. Granulator according to one of claims 2 to 6, characterized g e -k e It is noted that the perforated rear wall (50) of each wing (40) by a diaphragm (76) with the lower edge (42) arranged just above the container base (12) the deflection surface (44) of the next wing (40) is connected and the container bottom (12) is perforated and designed as an air inlet. 12. Granulator according to one of claims 1 to 11 with one in the container opening liquid line for spraying in granulating liquid, thereby g It is not noted that under the deflection surface (44) at least one wing (40) at least one rearwardly directed nozzle (20 ') is arranged, in d, he the Liquid line (18 ') ends.