DE3323418A1 - Apparatus for fluidised bed process and process which can be carried out using it - Google Patents

Abstract

An apparatus for a fluidised bed process has sensors for detecting the flow velocity, especially in a treatment zone divided into a plurality of adjacent regions and having riser tubes or gas stream nozzles or the like arranged there, each sensor being assigned to a respective region. These sensors are fitted, protected, outside and especially below the treatment zone. Both operating states and malfunctions can be detected by means of these sensors and a monitoring device connected to them.

Description

Device for fluidized bed processes and what can be carried out with it Process The invention relates to an apparatus for fluidized bed processes, such as e.g. granulation processes, drying processes, etc., in particular for coating Shaped bodies, e.g. tablets or the like, wherein the device comprises a container, that of an adjustable, the tablets or the like. Through a treatment zone conveying gas flow is flowed through. In the case of fluidized bed processes, the Device container provided a treatment zone within which the tablets od. Like. Items to be treated z. B. coated, dried and the like. Treated.

In particular in the case of spray treatments and the like, it can occur within the treatment zone under certain conditions to glue the item to be treated and thus to a Disturbance of the production process come. The container can be used to observe the Treatment method may be provided control window through which, inter alia. such Incidents can be detected. However, such a permanent visual inspection is too expensive and also in view of the very irregular occurrence of the incident also awkward.

In fluidized bed systems with several side by side in the direction of flow lying treatment zones, the monitoring of each of these zones becomes largely confusing, so that possibly also initially unnoticed disturbances occur, through which the end product can be adversely affected.

The object of the present invention is to provide a device of the initially mentioned to create the type mentioned, in which a safe monitoring of malfunctions, in particular from a decrease in product movement within the treatment zone is possible. It should also be used in spite of the often sticky spray coating agents high operational reliability and, if necessary, selective recording of certain Areas of the treatment zone.

To solve this problem, it is proposed according to the invention in particular that that for detecting the flow velocity of the gas stream in its inflow area a monitoring device is provided in the treatment zone.

The flow velocity of the gas flow can thus cause disturbances, in particular in a decreasing flow of the material to be treated and thus make a decrease in the flow through the gas flow noticeable, can be recorded immediately and further processed if necessary.

It is particularly advantageous that the monitoring device has a or has several sensors arranged in the gas flow, the outside and in particular are arranged below the treatment zone. This arrangement makes a direct one Avoid contact with the item to be treated or with a spray or the like, which contributes significantly to the operational safety of the monitoring device.

In the case of a fluidized bed device with one in the direction of flow in treatment zone divided into several adjacent areas, whereby in the individual areas at least spray nozzles, possibly multi-fluid nozzles and the like. Like. Are arranged, a sensor is advantageously assigned to each area. This also enables selective monitoring of each individual area.

In this arrangement it is advantageously provided that the individual areas of the treatment zone each flow guides with in their Sensors arranged in the area for detecting the respective area assigned Gas flow portion are provided. Within these flow guides is the dem Gas flow proportion assigned to the respective area can be measured particularly well, with changes the permeability of the respective area can be clearly recorded.

The monitoring device expediently has at least one Control connection to spray nozzle valves, possibly also to others, the fluidized bed influencing facilities, e.g. B. od to a floor plate.

like. on.

This can result in malfunctions during the procedure already recorded in the initial stage and, if necessary, through corresponding tax measures, such as B. Change in the gas flow rate, the spray amount and the like. Can be corrected.

According to one embodiment, the sensor or sensors is in each case through preferably a vane anemometer, a measuring orifice, possibly a pitot tube or the like. Formed.

A vane anemometer has a high measurement sensitivity and is therefore also suitable for small flow velocities or even small changes in flow velocity. A measuring orifice is particularly robust in structure and also largely insensitive Against pollution.

According to a further development of the invention, there are gas flow feeds for the individual treatment zone areas or the like. Provided, in particular for feeding an additional, optionally changeable gas flow. Thereby the individual Areas can also be flowed through differently, or the individual flow through can be different operating situations can be adapted.

The invention also relates to a method for monitoring the production process in fluidized bed processes, in particular those involving a fluidized gas circulation formed fluidized bed zone. This method is particularly in accordance with the invention characterized in that the flow rate of the inflowing gas is detected and used at least for signal output. The flow rate can be measured particularly well on the inflow side and leave the corresponding Conclusions about the treatment process.

Additional refinements of the invention are set out in the further subclaims listed.

The following is the invention in its essential details explained in more detail with reference to the drawing.

It shows partly more schematically: FIG. 1 a side view in section of a container section in the area of a treatment zone, FIG. 2 a Top view of a container section with several riser pipes arranged therein, 3 shows a view roughly comparable to FIG. 1, but here only with a riser pipe, Fig. 4 several, shown in sections, side by side arranged Container sections with a common gas flow feed, FIG. 5 corresponds approximately to FIG View, but here with additional gas flow feeds, FIG. 6 is a plan view of the container section shown in Fig. 5 with a ring line and gas flow feeds and FIG. 7 shows a side view of a modified embodiment of a container section with multiple treatment zone areas.

A shown in Fig. 1 portion of a container 1 is part of a Fluidized bed system, inside which is coated, granulated and also dried can. In particular, z. B. tablet cores with an outer coating provided and then dried. The container 1 is here in the area the treatment zone, which is delimited on the underside by a floor 2.

The item to be treated, e.g. B. Tablets 3, are within the treatment zone conveyed around according to the arrows Pf 1. The container is responsible for this whirling motion 1 interspersed with a gas flow from below (arrow Pf 2).

The embodiment shows a fluidized bed system in which the Treatment zone is divided into several adjacent areas 14. In the exemplary embodiments according to FIGS. 1 to 6 are a riser pipe in each sub-area 4 provided, which are each arranged at a distance from the bottom 2, being coaxial to the riser pipes 4 are located in the floor area spray nozzles 5.

During a fluidized bed treatment, the underside of the Container 1 ago a gas stream (arrow Pf 2) supplied to the extent that the through the arrows Pf 1 indicated vortex movement sets. The item to be treated is thereby by the riser pipes 4 or the like. Conveyed through and reaches the upper end laterally back into the inflow area of these riser pipes. In the inflow area of each riser pipe 4 flow guides 6 are now arranged through which at least a large part of the each provided for a riser 4 gas flow portion flows through. Within Each flow guide 6 are sensors 7 for detecting the flow rate arranged within these flow guides. This is a monitoring the proper gas flow through each riser pipe 4 is possible. For example, as indicated in the case of the right riser pipe 4 in FIG. 1, the material to be treated is more in it or less, it would reduce the flow rate result within the associated flow guide 6. One possible countermeasure could now consist in the fact that the spray nozzle 5 arranged there is switched off, in order to avoid further sticking of the items to be treated. The single ones Sensors 7 are therefore, as indicated in FIG. 2, with a monitoring device 8 in connection. The measurement signal evaluated there can, as already mentioned, for Control of the spray nozzle valves, but also of others, the fluidized bed influencing facilities are used. For example, next to the spray nozzle valves the conveying device for the gas flow, one optionally arranged in the floor area Base plate or the like. Called.

The flow guides 6 are in particular by approximately coaxial to the respective riser pipe 4 or the like. Arranged pipe sections 9 formed into which the Sensors 7 protrude. Depending on the application, the sensors 7 can be equipped with vane anemometers, Orifice plates, possibly also pitot tubes, can be formed. Prefer to come here Vane anemometers because of their good measuring sensitivity in question. The use of i.a. also against environmental influences (pollution, etc.) sensitive vane anemometers is possible in particular because the sensors are arranged outside and in particular below the treatment zone. they are coming therefore practically no contact with the material to be treated or with the spray. In the case of more difficult environmental conditions, especially with regard to pollution Orifice plates can also be used as sensors 7.

As already mentioned above, the measurement results of the sensors 7 for Control of a device influencing the fluidized bed zone can be used. When arranging a fluidized bed system with several riser pipes 4 od.

Like. It is useful if each of the individual areas with respect to the gas flow is monitored and, if necessary, individually influenced accordingly will. This is then also possible in particular by means of the respectively assigned spray nozzle. If necessary, this influence can also be combined with other variables, z. a. the individual gas throughput, as will be described with reference to FIGS. 5 and 6 will be changed.

Instead of the control of the fluidized bed zone influencing Facilities, in a simpler embodiment, devices for a signal output in the event of a malfunction can be provided. For example this could be be acoustic and / or optical devices, by means of which preferably also the area in which the fault has occurred is signaled.

There is also the possibility of the total flow to determine the individual measurement results of the sensors 7, so that the total climbing height of the material to be treated indirectly detected via the flow and possibly also can be kept at a certain value. Even if the gas pressure is too low reinforced the malfunction shown in Fig. 1 occur in which the material to be treated because of insufficient flow through the riser pipe or pipes 4 exceeds. The monitoring device 8 with the sensors 7 can thus except for pure fault reporting also for the controlled influencing of the fluidized bed zone can be used. With a corresponding design of the monitoring device 8 can simultaneously monitor the entire gas flow (arrow Pf 1) as selective monitoring of the individual areas or riser pipes 4 associated gas flow components (arrow Pf 3).

In addition to the arrangement shown in FIGS. 1 and 2, the monitoring a Direction with sensors in a fluidized bed system with one in several areas divided treatment zone, kann.die device according to the invention also in fluidized bed systems with only one riser pipe 4, as shown in Fig. 3, can be used. Also the use in the case of several separate fluidized bed systems, as shown in Fig. 4, is possible. It is also easy to see here that the individual fluidized bed systems have a common gas flow feed 10. The individual fluidized bed systems can optionally also be equipped with several riser pipes 4 here.

The sensors, optionally with their pipe sections, are expedient 9 attached to the working container 1 so as to be adjustable in height or removable. By a provided height or side adjustability is an adaptation to the respective Flow conditions or

the treatment conditions possible. With a designated detachability the sensors can be withdrawn accordingly if z. B. the product container should be removed.

Figures 5 and 6 show an expanded embodiment a fluidized bed system in which over individual gas flow feeds 11 gas can be fed to the individual areas 14. The gas flow feeds are here connected to the pipe sections 9 and on the other hand open into a Ring line 12. In the connection area to this ring line 12 there are throttle valves 13 or

Like. Installed, by means of which the supply air to the individual areas can be changed. This makes it possible to use the individual areas 14 to act differently with gas or air. In addition to influencing the actual treatment of the tablets od.

Like. You also have the option of increased gas pressurization of a single area, through which then also disturbances or blockages, such as this is indicated in Fig. 5 for the right riser pipe 4, eliminated by "blowing through" can be. The aforementioned training is particularly important for larger systems an advantage because both the possibility of compensating for differences in flow between the individual areas as well as to protect against malfunction during of the treatment process are given.

In addition to the supply of gas through the gas flow inlets targeted to the individual treatment areas 14 takes place, as indicated by the arrows Pf 2 in Fig. 5 indicated, in addition, the supply of a further gas stream in the entire treatment area.

Fig. 7 shows another embodiment in which by the training of the bottom 2 and also built up by the arrangement of the nozzles 5 a flow conditions can be comparable to those when using a riser pipe 4 are. Corresponding to the exemplary embodiments according to FIGS. 1 to 6 can also here the above-described arrangements of monitoring devices 8 with sensors 7 or the gas flow feeds described with reference to FIGS. 5 and 6 are provided be. The spray nozzles 5 a are designed here as multi-substance nozzles, whereby here the right area 14 with a two-substance nozzle for supplying a liquid (Pf 3) and air (arrow Pf 4) is formed, while the multi-substance nozzle 5 a also has an air jacket 15.

All shown in the description, the claims and the drawing Features can be essential to the invention both individually and in any combination with one another be.

- Summary -

Claims (14)

Device for fluidized bed processes and what can be carried out with it Process Claims device for fluidized bed processes, such as granulation processes, Dry processes and the like, in particular for coating molded articles, e.g. tablets or the like., wherein the device has a container which is of an adjustable, the tablets od. The like. Flows through a gas stream conveying a treatment zone is, d u r c h e k e n n -z e i c h n e t, that for detecting the flow velocity a monitoring device of the gas flow in its inflow area into the treatment zone is provided. 2. Apparatus according to claim 1, characterized in that the monitoring device one or more, arranged in the gas flow sensors ('I), the outside and in particular are arranged below the treatment zone. 3. Apparatus according to claim 1 or 2, with one in the direction of flow treatment zone divided into several adjacent areas, whereby in the individual areas at least spray nozzles, possibly multi-fluid nozzles and the like. Like. Are arranged, characterized in that at least a number of areas a flow sensor (7) is assigned. 4. Apparatus according to claim 1 to 3, characterized in that flow guides in each case in the individual areas (14) of the treatment zone (6) with sensors (7) arranged in their area for detecting the one in each case Area (14) assigned gas flow portion is provided. 5. Apparatus according to claim 1 to 4, wherein the individual areas the treatment zone have riser pipes through which there is longitudinal flow, characterized in that that the flow guides (6) with sensors (7) arranged in their area Distance to the lower ends of the riser pipes (4) are arranged. 6. Device according to one of claims 1 to 5, characterized in that that the flow guides (6) through in particular approximately coaxial to the respective Riser pipe (4) or the respective treatment zone area (14) or the like Pipe sections (9) are formed into which the sensors (7) protrude. 7. Device according to one of claims 1 to 6, characterized in that that the monitoring device has at least one control connection to the spray nozzles, possibly also to other facilities influencing the fluidized bed, z. B. od to a base plate. Like. Has. 8. Device according to one of claims 1 to 7, characterized in that that the sensor or sensors (7) are each preferably provided by a vane anemometer, a measuring orifice, if necessary a pitot tube or the like. is formed. 9. Device according to one of claims 1 to 8, characterized in that that the sensor (s) (7) the monitoring device (8) preferably with their flow guides (6) at least adjustable in height or removable on the Working container (1) or the like. Are attached. 10. Device according to one of claims 1 to 9, characterized in that that gas flow feeds (11) for the individual treatment zone areas (14) od. Like. Are provided, in particular for supplying an additional, optionally variable gas flow. 11. The device according to claim 10, characterized in that the individual gas flow guides (11) or the like. Connected to a common ring line (12) are and that they are preferably independently operable throttle valves (13) or the like. 12. Process for monitoring the production process in fluidized bed processes, in particular the fluidized bed zone formed with the help of a fluidized gas circulation by means of the device according to one or more of claims 1 to 11, characterized characterized in that the flow rate of the inflowing gas is detected and is used at least for signal output. 13.- The method according to claim 12, characterized in that the flow measured variable used to control at least one spray device and / or the gas flow will. 14. The method according to claim 12 or 13, characterized in that in fluidized bed systems with a treatment zone divided into several areas, each of these areas is monitored and, if necessary, with regard to the gas flow is individually influenced accordingly. - Description -