This application claims the benefit of the German patent application No. 10 2015 012 588.5 filed on Sep. 29, 2015, the entire disclosures of which are incorporated herein by way of reference.
The invention relates to a rotor for a device for disintegrating feedstock, comprising a drive shaft, a plurality of rotor disks which sit on the drive shaft and disintegration tools which are arranged in the region of the outer circumference of the rotor disks; the invention additionally relates to a device for disintegrating feedstock.
Rotors are used in devices for disintegrating feedstock for the coarse or fine disintegration or deagglomeration of the feedstock as a result of beating forces, shear forces or impact forces. Disintegration tools such as blades, hammers or beating bars are arranged for this purpose in the outer circumferential region of the rotor disks, which are arranged as hubs on at least one drive shaft, on or between the rotor disks. The feedstock, for example scrap metal, textiles or granular feedstock, which is fed in the majority of cases radially to the rotating rotor, is grasped and disintegrated by the disintegrating tools of the rotor, often interacting with elements such as baffle plates (stator) which are arranged statically in the housing of the device. Thus, for instance, impact hammer mills are used in the course of cement production for preparing (disintegrating and simultaneous drying) the raw meal. Along with embodiments with beating bars, hammers, which are arranged on axial rods so as to oscillate, i.e., so as to be pivotable, are frequently provided in this case as disintegration tools which exert beating forces or impact forces on particles of the feedstock. Embodiments of impact hammer mills are taught, for example, in documents DE 24 16 499 C3 and DE 10 2006 033 300 A1.
The transmission of torque, relevant to the disintegration devices which are based on the rotor principle, from the driven shaft to the disintegration tools is effected via the rotor disks. Particular significance for effective and fault-free operation of the rotor and therefore of the disintegration device is consequently given to the connection between the rotor disks and the drive shaft. Frequently, the shaft-hub connection is realized by a feather key connection, that is to say, a transmission of torque by means of a feather key inserted into a groove, as, for example, taught in document DE 39 38 725 A1. In the normal case, the rotor disks, in this case, are pushed loosely onto the shaft and are secured at the sides against displacement, e.g., by way of stops, so that, in particular, as simple and rapid an assembly or disassembly of individual worn disks is possible. In particular, in the case of high torques that are typical to impact hammer mills and of forces that do not occur just radially due to the impact on the feedstock particles, however, there is a risk of the rotor disks deflecting out of their provided equilibrium position or operating position on account of the given play in the connection between the disks and the shaft, which can result in damage to the disks culminating in the shaft breaking. The disks creeping sideways cannot be ruled out either.
Similar difficulties can arise in the case of the rotor disclosed in document EP 2 098 297 B1 for disintegrating feedstock, including, in particular, a drive shaft, rotor disks and disintegration tools. Here, not all the rotor disks are fixedly connected to the shaft. Rather, a transmission of force takes places between the rotor disks, only the outer rotor disks being connected to the shaft by means of frictional locking. Deflection of the middle rotor disks in the case of particularly high torque and force loads can only be ruled out by particularly sturdy, expensive force connections between the disks. Over and above this, the proposed, complex clamping sets for producing the frictional locking of the outer disks have to enable a certain amount of slippage between shaft and rotor disks in the case of stresses occurring in a peak-like manner on account of the transmission of force between the disks themselves, which can also result in the disks leaving their provided operating position in a disadvantageous manner.
It is consequently an object of the invention to provide a rotor for a device for disintegrating feedstock, where the risk of the rotor disks deflecting and the rotor disks creeping out sideways is reduced.
According to the invention, it is therefore provided that in the case of the rotor, at least one retaining flange is provided for each rotor disk for connecting the rotor disk to the drive shaft, wherein the at least one retaining flange is connected non-detachably to the drive shaft and is connected detachably to the rotor disk. A departure is consequently made from the known forms of connection between drive shaft and rotor disks, such as the use of feather keys, on the one hand, in favor of the use of flanges which are fixedly connected to the shaft, as connecting parts between the shaft and the hubs held by the flanges, i.e., the rotor disks. In a particularly preferred embodiment of the invention, the retaining flanges are connected non-detachably to the shaft by means of weld connection. According to the invention, it is provided, on the other hand, that each rotor disk of the rotor is connected detachably to, in each case, at least one retaining flange. The transmission of torque from the drive shaft to the rotor disk takes place by means of the connection. The detachability of the connection here allows for the rapid, separate replacement of individual rotor disks which are exposed to heavy wear in operation, in particular on account of the repeated impact of particles of feedstock. As a result of the connection between every individual rotor disk and at least one retaining flange, each individual rotor disk is protected against sideways creeping. The expert will choose the strength of the connection corresponding to the forces and torques occurring during typical operation of the rotor in the disintegration device. Sideways creeping of the rotor disks as a result of the effect of non-radial forces, such as, for example, as typical in impact hammer mills on account of the flight paths of the feedstock, is prevented in this way in a more effective manner than when rotor disks are pushed loosely onto the shaft with stops provided at the sides.
In a preferred embodiment of the invention, the rotor disks are connected to the respective retaining flanges by means of a screw connection. This can occur by means of screws as a result of screw-connecting the rotor disk to the at least one retaining flange in a direct manner A connection which is to be preferred and is also sturdier, in particular against shear forces, as well as simpler to assemble, however, is producible by using one or multiple connecting parts which are designed as disks, brackets, plates or similar elements, overlap the shaft/hub connection of rotor disk and retaining flange at the side and are screw-connected in each case to the retaining flange and to the rotor disk. Retaining flanges and rotor disks are then sufficiently solid with one another but are connected detachably in an indirect manner. As a result of the connection according to the invention between every individual disk and at least one retaining flange, for example realized by means of screw connection, there are no loose rotor disks present in the rotor. As a result of the fixed, play-free connection between rotor disk and retaining flange, which acts as part of the shaft, the risk of the rotor disks moving out of their provided equilibrium position, that is to say of the rotor disks deflecting, is largely prevented. On account of the typically beating stress of the rotor in the case of impact hammer mills, this is extremely advantageous precisely for this type of disintegration device.
In one design of the invention, it is provided that the retaining flanges are realized in a circular manner about the shaft and each rotor disk is retained by precisely one retaining flange. The rotor disk, in this case, comprises a circular hub bore for the connection to the retaining flange. When viewed from the rotational axis of the shaft, each rotor disk comprises, as a result, a radial inner side, that is to say, an inner delimiting surface located toward the shaft—in the geometrically idealized case of a circular ring cylinder, the inner lateral surface. It is provided that in the shaft/hub system, the rotor disk rests by way of its radial inner side or inner surface on the radial outer side or outer surface of the associated retaining flange. For increased stability of the connection, the surfaces rest on one another as mating surfaces and therefore act as centering surfaces (for the positioning of the disks). The fit between shaft (retaining flange) and hub (rotor hub) can be a clearance fit with little play in the case of disintegration devices where only small forces and torques occur. In the normal case, in particular in the case of impact hammer mills, however, play-free connections in the form of transition fits are to be preferred, for reasons of the deflecting of the rotor disks which is to be avoided. An interference fit is only to be realized in exceptional cases of particularly large forces and torques; the disadvantage of the press fit thereof, in particular, is a costly assembly/disassembly of the rotor disks. The actual non-positive connection between the rotor disks and each of the corresponding retaining flanges is produced in the design of the invention by means of a screw connection, where the rotor disk and retaining flange are each fixedly screw-connected with one and the same connecting element. This can be, in particular, a plate which is arranged at the side and covers both rotor disk and the associated retaining flange in the region of the mating surfaces which rest one on top of another. A connecting plate in the form of a circular ring disk arranged concentrically to the rotor disk on one side of the rotor disk is, for example, suitable, the plate, for the purposes of simpler mountability, comprising multiple separate parts, for example of two semicircular ring disks. It seems reasonable to use a further multi-part connecting plate in an analogous manner on the other side of the disk or flange for further securing the screw connection and to tighten the nuts.
In a further design of the embodiment of the invention described above, arrangements are made which enable a relatively simple and rapid assembly of the rotor disks. During assembly, the rotor disks are pushed with the retaining flanges in the axial direction, i.e., longitudinally of the shaft, over the drive shaft. For this reason, each retaining flange comprises recesses (flange recesses) which are distributed over its outer circumference and are open radially outward and toward the side surfaces similarly as in the case of tuning forks or toothed wheels. Web-like parts of the retaining flange, designated as flange webs, remain between every two adjacent recesses in the outer circumferential region of the retaining flange. In an analogous manner, the rotor disk assigned to the respective retaining flange comprises recesses (disk recesses) and disk webs which are distributed over its inner circumference. In this case, flange recesses and flange webs correspond with the disk recesses and disk webs such that in the completely assembled rotor, that is to say in the operating state, the radial outer sides of the flange webs and the radial sides (located inward toward the shaft) of the corresponding disk webs rest one on top of another as centering surfaces with the already described fit. Accordingly, in this case, the recesses of rotor disk and retaining flange also adjoin one another and form common recesses. For a simplified assembly of the rotor disk on the associated retaining flange, the extents of the flange recesses provided along the circumference are dimensioned such that in at least one position of the rotor disk, rotated in relation to the assembled state, with respect to the retaining flange, each flange recess has situated opposite thereto a disk web with a smaller extent provided along the circumference. It follows that the corresponding disk recesses are also dimensioned such that each disk recess has located opposite thereto a flange web with a smaller extent provided along the circumference. For mounting, the rotor disk is therefore rotated in relation to the retaining flange such that the recesses of the disk can be guided above the webs of the flange and the recesses of the flange can be guided under the webs of the disk without blocking caused by friction during axial displacement. After being pushed-on in this way, the rotor disk is then rotated with respect to the retaining flange into the end position, where the outer surfaces of the corresponding webs rest on top of one another with fit as centering surfaces. In an advantageous manner, only a small depth of recess is required here for the screw connection.
In the typical case, the rotor disks and retaining flanges are each of the same design such that they match in form and size, i.e., are in each case congruent with one another. In an advantageous special realization of the afore-described design of the invention, the flange recesses are congruent with one another and the disk recesses are congruent with one another. In addition, to promote uniform material stress on the retaining flanges and on the rotor disks, the flange recesses, therefore also the disk recesses and the flange webs and the disk webs, are distributed uniformly on the circumference of every retaining flange or of every rotor disk. With reference to the distribution, there is therefore rotational symmetry or radial symmetry. For example, the recesses are arranged offset to one another at an angle of 60° with regard to rotation about the rotational axis of the shaft. For the simplification, provided as a result of play, of the assembly step of pushing a rotor disk over the retaining flange longitudinally of the drive shaft, it is sufficient and advantageous to the stability of the connection which is provided by centering surfaces that are as large as possible, when the flange recesses in (all dimensions of) their planar extent along the outer radial circumference are only a little larger than the (planar) extent of a flange web provided along the outer circumference. The same applies therefore to recesses and webs of the rotor disks and to the corresponding ratio of the corresponding portions of disks and flanges with respect to one another. In a preferred manner, the longitudinal extent of the recesses of the flanges or disks (with reference to the minimum dimension) is consequently to be chosen as between approximately 0.5% and a maximum of 10% greater than the extent of the webs (with reference to the maximum dimension thereof).
Such a dimension of webs and recesses is also possible where, in an alternative arrangement, the webs are pushed into the recesses in the manner of a plug-in connection. As a result of such interlocking, a connection, which is additionally also positive locking, is certainly produced between disks and flanges, but the production of the screw connection is made difficult.
The rotor according to the invention is suitable for all types of devices for disintegrating feedstock, the disintegration operation thereof is based on the rotation of a rotor fitted with disintegration tools, frequently in combination with a stator which is provided correspondingly in the housing or as the housing of the device. As a result of using a rotor in one of the embodiments according to the invention inside the disintegration unit of disintegration devices which are known per se and operate with the rotor principle, the invention also includes devices for the disintegration of feedstock which comprise a rotor according to the invention in one of the described embodiments.
As the rotor according to the invention is advantageous, in particular for use in impact hammer mills on account of the play-free connection between the rotor disks and the drive shaft, an advantageous design of the invention provides that the disintegration tools are present in the form of hammers. As known from generic hammer mills and impact hammer mills, the hammers, in this case, are arranged on axial rods so as to be pivotable, which axial rods penetrate the rotor disks, usually parallel to the drive shaft.
An important design of the device for disintegrating feedstock, which includes a rotor according to the invention, provides that the disintegration tools of the rotor are realized as hammers, beating bars or similar known striking tools and that the rotor has assigned thereto an impact hammer mill stator. The rotor according to the invention is therefore part of an impact hammer mill, the disintegration unit thereof also includes a stator which is typical to impact hammer mills, along with the rotor. For example, the stator comprises impact elements, such as, for example, beating bars, which are arranged fixedly in an additional impact chamber and by which the feedstock particles caught by the hammers of the rotor are centrifuged and as a result are (preliminarily) disintegrated.
The invention is explained in more detail by way of the following figures, in which:
In
The position shown in
In contrast to the assembly position from
An important design of a device 20 for disintegrating feedstock, which includes a rotor 1 according to the invention, provides that the disintegration tools 16 of the rotor are realized as hammers, beating bars or similar known striking tools and that the rotor has assigned thereto an impact hammer mill stator 22. The rotor 1 according to the invention is therefore part of an impact hammer mill 20, the disintegration unit thereof also includes a stator which is typical to impact hammer mills, along with the rotor. For example, the stator 22 comprises impact elements 24, such as, for example, beating bars, which are arranged fixedly in an additional impact chamber and by which the feedstock particles caught by the hammers 16 of the rotor 1 are centrifuged and as a result are (preliminarily) disintegrated.
As is apparent from the foregoing specification, the invention is susceptible of being embodied with various alterations and modifications which may differ particularly from those that have been described in the preceding specification and description. It should be understood that I wish to embody within the scope of the patent warranted hereon all such modifications as reasonably and properly come within the scope of my contribution to the art.
Number | Date | Country | Kind |
---|---|---|---|
10 2015 012 588 | Sep 2015 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2016/073140 | 9/28/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/055365 | 4/6/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3235189 | Rogers | Feb 1966 | A |
3533565 | Weiner | Oct 1970 | A |
3724767 | Scarbrough | Apr 1973 | A |
3779470 | Smits | Dec 1973 | A |
6527210 | Mecklenfeld | Mar 2003 | B1 |
20050051651 | Enderle | Mar 2005 | A1 |
20090224089 | Pallmann | Sep 2009 | A1 |
20140166795 | Mogan | Jun 2014 | A1 |
Number | Date | Country |
---|---|---|
2145868 | Mar 1973 | DE |
2416499 | Oct 1975 | DE |
3938725 | May 1991 | DE |
19848866 | Apr 2000 | DE |
102006033300 | Jan 2008 | DE |
2098297 | Sep 2009 | EP |
159925 | Mar 1921 | GB |
336776 | Oct 1930 | GB |
Entry |
---|
International Search Report, dated Dec. 5, 2016, priority document. |
Number | Date | Country | |
---|---|---|---|
20180280985 A1 | Oct 2018 | US |