The present invention relates to a mixer with a mixing container and a tool shaft arranged at least partly in the mixing container, the tool shaft having a working end to which a working tool is fastened or can be fastened and a drive end which is mounted by means of two mutually set-apart tool bearings, and a drive motor being provided with a motor shaft for driving the tool shaft.
A mixer of this type is for example known from DE 35 20 409. The embodiment disclosed therein comprises a pressure-resistant mixer with a filling opening, a rotating mixing container having an emptying means, with mixing tools arranged eccentrically to the mixing container axis inside the mixing container.
The mixer known in the art is represented schematically in
The working tools 6 are fastened to a tool shaft 8 which has a drive end on which the V-belt 9 acts and a working end to which the working tools 6, which are embodied as the mixing tool, are fastened. The tool shaft 8 is in the embodiment shown formed in two parts, wherein the two parts can be joined together or separated from each other via the flange connection 10. This flange connection 10 is provided inter alia to exchange the working tool 6 for another working tool 6, such as for example a star vortexer for a pin vortexer. In addition, the working tool can, when it displays phenomena of wear, be exchanged for a new one. As both the mixing container 3 and the tool shaft 8 rotate, considerable transverse forces can act on the tool shaft 8, the transverse forces being caused by the flow of material through the rotating mixing container 3, especially as the tool shaft is held in the housing cover 5 only at one side. The magnitude of the transverse force depends inter alia on the nature of the material to be mixed and of course on the rotational speed of both the mixing container 3 and the working tool 6.
Two tool bearings 11, 12, which each mount the shaft having a diameter D, are therefore provided at the drive end for holding the tool shaft 8. In order to absorb the forces, the tool bearings 11, 12 are screwed to the mixer housing 2 or the housing cover 5 via a flange 13.
The V-belt 9 then acts on the drive end of the tool shaft 8. The drive motor 7 has a motor shaft 20 which is also held via two motor bearings 14, 15. It may be seen that the diameter d′ of the motor shaft 20 is much smaller than the diameter D of the tool shaft 8.
In the prior art, the drive motor is mainly in the form of three-phase asynchronous motors or hydraulic motors with V-belt or toothed belt transmission, and also geared motors.
All these types of drive have in common the fact that a large number of elements are required for generating torque and for converting torque and also for accommodating the load. In the simplest case of the asynchronous motor with a corresponding bearing arrangement, at least four bearings are required—two bearings for the motor shaft and two bearings for the tool shaft—which have to accommodate, as well as the weight forces, in addition also the high forces from the working tool and also the considerable belt forces.
If a geared motor or a separate gear mechanism is used, at least two further bearings have to be provided for each further reduction stage.
In addition to the complex and yet failure-prone bearings, the belt transmission, consisting generally of a set of a plurality of V-belts or toothed belts, is a high-maintenance machine element. These components have to be checked at regular intervals for correct stress and the stress must, if appropriate, be adapted. Likewise, both V-belts and toothed belts are prone to wear and must therefore be exchanged at regular intervals.
Against the background of the described prior art, it is therefore the object of the present invention to provide a mixer which is simple and economical to manufacture and has torque which is as high as possible in a broad rotational speed range and a minimum number of wear-prone components for driving the working tool.
According to the invention, this object is achieved in that the motor shaft is mounted by at least one of the two mutually set-apart tool bearings.
In other words, one of the bearings, which is provided for mounting the tool shaft, is used at the same time for mounting the motor shaft. The motor shaft and tool shaft are therefore directly connected to each other. This measure allows at least one bearing to be avoided.
Particularly preferred is an embodiment in which the motor is arranged between the two tool bearings and the motor shaft is mounted preferably by means of the two tool bearings. This embodiment allows two bearings to be dispensed with, as the bearings for the tool shaft serve at the same time as bearings for the motor shaft. Basically, in this embodiment, it is no longer possible to distinguish between the motor shaft and tool shaft, as one portion of the shaft functions as the motor shaft and another portion of the same shaft functions as the tool shaft.
The motor used is in these cases preferably a direct drive and particularly preferably a three-phase synchronous motor (servo motor, torque motor, reluctance motor).
In a further preferred embodiment, the bearing of the motor shaft that faces the tool shaft is suitable for accommodating particularly high radial and axial forces. The bearing is designed preferably as a combined radial axial bearing (radiax bearing), for example as a self-aligning roller bearing or self-aligning ball bearing and particularly preferably a twin-row self-aligning roller bearing.
It has been found that, in particular, a twin-row self-aligning roller bearing can best accommodate the transverse forces occurring during operation.
A further preferred embodiment makes provision for the diameter of the motor shaft to differ on the two tool bearings, preferably the diameter of the motor shaft d″ on the tool bearing remote from the tool shaft being smaller, preferably at least 30%, particularly preferably at least 50% smaller, than the diameter of the motor shaft D on the other tool bearing.
It has been found that merely the bearing facing the mixing container must have a large diameter. On suitable designing of the bearings, the bearing remote from the mixing container can be made much smaller and thus more economical.
The motor is expediently arranged in a motor housing, both tool bearings being arranged on or in the motor housing. In this case, the motor housing can have a first outer flange by which the motor housing, and thus the motor, is fastened to the mixer housing. Furthermore, in a particularly preferred embodiment, the motor housing can have a second outer flange which is also fastened to the mixer housing, the second outer flange having preferably a larger average diameter than the first outer flange.
The motor housing could have, for example, a circular cross section, the outer flange then expediently also having a circular cross section. However, in principle, other cross sections, for example square or rectangular cross sections, are also conceivable. The fact that the second outer flange has a larger average diameter means that the motor can easily be fastened to the mixer housing. For example, the mixer housing can have a stepped through-opening with a first portion having a smaller average diameter and a second portion having a larger average diameter, the second portion having an average diameter which is larger than the average diameter of the first outer flange and smaller than the average diameter of the second outer flange. In a preferred embodiment, the smallest average diameter of the stepped through-opening in the mixer housing is larger than the largest external diameter of the working tool. This measure allows the entire working tool, including the motor, to be removed via the stepped through-opening.
Typically, both flanges have holes for fastening the flanges to the mixer housing. In this case, the larger flange can have additional openings which are preferably larger than the holes for fastening and are provided to allow a tool to access the holes or fastening means in the smaller flange through the opening. This facilitates the fastening of the motor housing to the mixer housing.
In a further preferred embodiment, the tool shaft consists of two parts which are detachably fastened to each other, one part being integrally connected to the motor shaft, while the other part carries the working tool. In this case, the detachable connection can be carried out via a flange connection.
Alternatively thereto, the tool shaft can also be formed in one piece with the motor shaft.
Further advantages, features and possible applications of the present invention will become clear from the following description of preferred embodiments and also from the associated figures, in which:
If required, the motor can thus easily be detached from the housing cover and removed.
A situation of this type is shown in
The integration of the motor into a robust bearing unit for accommodating the forces and moments of the working tool produces a unit having minimal maintenance costs and the highest possible reliability. Only one shaft is guided in two bearings. This shaft takes over both the forces of the motor (for example weight forces, magnetic residual forces) and the forces of the working tool (vortexer, kneader, etc.). Any necessary variation of the rotational speed may be facilitated by the use of a frequency converter.
Number | Date | Country | Kind |
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10 2008 054 842 | Dec 2008 | DE | national |
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PCT/EP2009/066458 | 12/4/2009 | WO | 00 | 6/17/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/076120 | 7/8/2010 | WO | A |
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