The invention relates to a mixing device with a rotating drive shaft that supports a pulverizing tool that is formed as a rotor and has pulverizing edges on the outside in the radial direction and can be moved in a rotating manner relative to a stationary stator that is supported, in particular, by a shaft tube and has, on its side, pulverizing edges turned toward the rotor, wherein the pulverizing edges of the rotor and the pulverizing edges of the stator apply a force to, process, or pulverize a medium located between these edges and solids located in the medium and feed it out from the region of the rotor as the rotor rotates.
Such a mixing device is known from DE 10 2004 009 708 B3 and has proven effective. The pulverizing edges of the rotor and stator adjacent to each other in the radial direction cause the desired mixing of a medium fed or suctioned into the rotor region due to the high rotational speed of the rotor and the small distance between these pulverizing edges.
Here, however, the possibility of pulverization is limited, that is, the size of the resulting parts or particles of the mixing process could still not be small enough in some cases.
Therefore, there is the objective of creating a mixing device of the type defined above with which additional processing of the particles is possible with additional pulverization, without an additional stage made from the rotor and stator being required, but this would also be possible.
For achieving this objective, the mixing device defined above is characterized in that the pulverizing edges of the stator define grooves or slots closed in the radial direction and oriented in the axial direction, that the rotor has a pumping or feeding effect from its axial inlet region in the axial direction, and that behind the mixing region formed from the rotor and stator in the axial feed direction, there is at least one rolling bearing through which the medium can be fed and behind which an outlet is arranged for the processed medium.
In this way, a material to be pulverized or a mixture can be pulverized initially in the conventional way in a mixing region between a rotor and a stator. This pulverized material is then forced through at least one rolling bearing in which it is acted upon by the rolling bodies and even further pulverized accordingly. A correspondingly small particle size or a correspondingly intense mixing result can be achieved just with a single-stage mixing device. Analogously, however, such additional pulverization could also be provided in at least one rolling bearing in a two-stage mixing device. The rolling bearing or bearings themselves could be viewed as additional pulverization stages of the mixing device. Here, the rolling bearing has a double function, because, on one hand, it supports the drive shaft for the rotor and, on the other hand, it causes or supports the pulverization and mixing of the medium and particles located therein.
While in the mixing device according to DE 10 2004 009 708 B3 the pulverizing edges of the rotor and stator are each arranged on an imaginary cylinder, a construction of the invention can provide that the envelope surface enclosing the pulverizing edges of the rotor and/or the envelope surface enclosing the pulverizing edges of the stator have a decreasing cross section or diameter in the approximately axial feed direction. Therefore, the rate of flow in the feed direction can be increased and the feed flow that receives an approximately ring-shaped cross section can be targeted and limited, so that it is led with increasingly high pressure to the rolling bearing or bearings.
Here it is further preferred if the radial distance of the pulverizing edges of the rotor to the pulverizing edges of the stator decreases in the direction of flow or feed. This also contributes to improving the mixing result and accelerating the feed flow or to feeding it with correspondingly high pressure to the rolling bearing or bearings.
One especially preferred and advantageous construction of the mixing device according to the invention can provide that the rotor is formed by inclined vanes projecting in the radial direction on the drive shaft and whose ends oriented in the feed direction are directed toward the rolling bearing. These vanes thus have a double function in that, on one hand, they support the pulverizing edges on their border lying on the outside in the radial direction and, on the other hand, they exert a feeding and pumping effect from the inlet into the mixing device to the rolling bearing or bearings due to their corresponding inclined position.
The outlet from the mixing region formed by rotor and stator can form a ring surface that coincides at least partially with the ring surface or is adjacent to this in the axial direction, wherein this ring surface borders the ring region with the rolling bodies of the rolling bearing, and the slots of the stator and the intermediate spaces between the pulverizing edges of the rotor can open into this ring region. Thus it is guaranteed that the feed flow of the medium processed by the rotor and stator is led to the rolling bodies of the rolling bearing and can enter into the rolling bearing in the axial direction. The vanes of the rotor could be arranged inclined relative to an axial direction and the center axis of the drive shaft—as already mentioned—such that they have a feeding effect in the axial direction from the inlet into the mixing region to the inlet into the rolling bearing or bearings.
As was already indicated, optionally also more than one rolling bearing could be provided, in order to cause an even stronger pulverization of particles. Here it could be preferred if at least one additional rolling bearing is arranged behind the rolling bearing in the feed direction, wherein these rolling bearings can preferably abut each other directly, so that the feed flow can be realized directly from one rolling bearing to the other.
The rolling bearing or bearings essential for the mixing device according to the invention could have different constructions. For example, it is possible that the rolling bearing or bearings is or are formed by rolling bodies guided in a housing between the rotor and stator or have inner and/or outer rings for holding the rolling bodies. Above all, such conventional rolling bearings provided with inner rings and outer rings simplify the assembly.
It is also possible that at least one of the rolling bearings is a ball bearing or barrel-shaped bearing and the balls or barrels are fixed in the axial direction especially on their outside in a circular channel and held without a cage, wherein this channel could be machined directly into the retaining housing, if space is to be saved in the radial direction. However, the outer ring of such an especially conventional rolling bearing could also have the circular channel, in order to avoid a cage for the rolling bodies, wherein this cage could obstruct the entry of medium into the bearing.
For the pulverizing effect, it is favorable if the rolling bodies can be pressed by centrifugal force during their rotation onto the stationary outer side or the outer ring of the rolling bearing and can roll there practically without play and when the bearing play during use is arranged on the side of the rolling bodies lying on the inside in the radial direction. Through these measures, the fact can be taken advantage of that the rolling bodies are subjected to a centrifugal force especially at a high rotational speed and thus can revolve without play on the outer side and can simultaneously free up a pulverizing gap on their side lying on the inside in the radial direction.
For an especially space-saving arrangement, the rolling bearing or bearings could be needle bearings.
Furthermore, space could be saved—as already indicated—in the radial direction such that the shaft tube or housing carrying the stator itself forms the outer ring of the rolling bearing or bearings and/or that the drive shaft contains a circular guide channel for guiding the side of the rolling bodies lying on the inside in the radial direction or carries the inner ring of the rolling bearing.
A long service life and effectiveness can be achieved if the rolling bodies and/or their bearing rings are made from hard ceramic.
Rotors, stators, and/or pumping or feeding devices could also be made from hard ceramic or heat-treated, especially in order to be able to easily withstand abrasive media.
Another advantageous construction increasing the effectiveness of the mixing device according to the invention can provide that, behind the rolling bearing or bearings in the direction of flow, another pumping or feeding device or pump vane unit and in their effective region or behind in the axial direction of flow, at least one radial outlet from the shaft tube or housing of the mixing device is provided. In this case, the medium can then be moved both from the rotor exerting a pumping effect in the direction of flow in front of the rolling bearing or bearings and also by such an additional pump vane unit effectively by the entire mixing device and processed accordingly.
Tests have shown that, above all, such a flow emerging through an additional pump vane unit in the radial direction out from the shaft tube or housing is so strong that a vortex formed by the rotational effect of the mixing device in a stirring vessel is destroyed or prevented by this radial flow. In this way, the risk is also avoided or overcome that the rotor runs with the pulverizing edges completely or partially in the air and then would have no effect.
Primarily from the combination of individual or several of the features and measures described above, an effective mixing device is produced in which the rolling bearing or bearings used for the support of the rotor can be included in the pulverization process. Here, ceramic bearings could also be used that require no lubrication and could even run dry, in order to cause this additional pulverizing effect. Here, the known high temperature resistance of ceramic bearings in an application in a mixing device is also advantageous, because the very high rotational speeds in mixing processes generate a correspondingly high amount of heat; it is often also necessary to process the product for its pulverization under a large amount of heat that is well tolerated by such ceramic bearings.
Below, an embodiment of the invention will be described in detail with reference to the drawings. Shown in partially schematic representation are:
A mixing device designated overall with 1, also called “device 1” below, has a drive shaft 2 rotating during use according to
On the lower end in the mixing region 5, the drive shaft 2 supports a pulverizing tool 6 that is formed as a rotor and has pulverizing edges 7 on the outside in the radial direction and can be moved in a rotating manner relative to a stationary stator 8 carried in the shaft tube 3 or in the housing 4 held by this tube. The stator 8 that can be seen especially well in
With reference to
The medium is thus acted upon and processed initially by the pulverizing edges 7 and the pulverizing edges 9 of rotor 6 and stator 8 and then by the rolling bodies 14 of the rolling bearing 12. Therefore, a more thorough pulverization can be achieved than with the help of only rotor 6 and stator 8.
The—optionally several—rolling bearings 12 are here used simultaneously as a radial and axial bearing point and for pulverization.
According to
The entire mixing region 5 thus actually has two mixing stages, namely the first stage formed by rotor 6 and stator 8 and the second stage formed by the rolling bearing 12. Accordingly, fine particles can leave the entire mixing region 5.
In a way not shown in more detail, behind the rolling bearing 12 in the feed direction there could be at least one additional such rolling bearing if a better support and even stronger pulverization is desired.
In the embodiment, an essentially conventional ball bearing is provided as a rolling bearing 2 whose rolling bodies 14 are thus balls. Here, the rolling bearing 12 has an inner ring and an outer ring and the channels on these rings guide the balls, so that no cage that could obstruct the flow through the rolling bearing 12 is necessary for these balls. It would also be possible, however, to provide these channels for the rolling bodies directly on the inside of the housing 4 and/or on the drive shaft 2.
The use of the rolling bearing 12 for additional pulverization could be utilized here in that the rolling bodies or balls 14 are pressed outward by centrifugal force during rotation, that is, revolve on the outside without play and thus free up on the inside a gap corresponding to the bearing play for further pulverization.
It is especially favorable when the rolling bearing 12 is a ceramic bearing that requires no special lubrication and can receive high thermal loading.
In
The formation of the individual components of the mixing device is more clearly shown in
The mixing device 1 has a rotor 6 that has pulverizing edges 7 and interacts with pulverizing edges 9 of a stator 8, wherein the rotor 6 simultaneously exerts a feeding effect in the axial direction with the help of pump vanes and the stator is closed outward in the radial direction. Behind the rotor 6 in the feed direction, there is at least one rolling bearing 12 whose roller body 14 causes further pulverization of products processed in the mixing device 1. Preferably, behind the rolling bearing 12 in the feed direction, another pump vane unit 15 can improve the flow of the medium, especially through the rolling bearing 12, and can feed the processed medium preferably in the radial direction out from the device 1.
Number | Date | Country | Kind |
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102008062570.1 | Dec 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP09/08721 | 12/7/2009 | WO | 00 | 5/20/2011 |