The invention relates to a method for monitoring the load state of a grinding system and to a grinding system equipped with such a monitoring device.
In order to monitor grinding systems, for example roller mills, it is known to detect the vibration rate of the individual grinding elements and of the entire grinding system by means of sensors and to monitor with respect to predetermined limiting values the effective value of the vibration rate in the frequency range of from 10 to 1000 Hz in accordance with ISO 10816-3, the so-called RMS value (Root-Mean-Square), in the control arrangement of the grinding system.
Investigations and measurements carried out have shown, however, that that known vibration monitoring by means of the RMS value is not entirely reliable since, on the one hand, it sometimes detects critical load states too late or not at all while, on the other hand, it occasionally responds even though a critical load state has not yet been reached.
In order to protect mills against overloading it is also known to pick up electro-acoustically the operating noise generated by the mill and to evaluate the electrical signals so obtained according to frequency and/or intensity (DE 36 21 400 A1). However, nor does that method meet the demands with respect to reliability and sensitivity made on the monitoring of large grinding systems.
The object of the invention is therefore to provide a method and a grinding system which permit an especially reliable and accurate monitoring of the load state of the grinding system.
That object is achieved according to the invention by the features of claims 1 and 11, respectively.
Advantageous forms of the invention are the subject-matter of the subordinate claims.
In the tests on which the invention is based, it was surprisingly established that the first harmonic of the fundamental oscillation of the dynamic forces exerted by the grinding stock on the grinding element is an especially suitable operating parameter for monitoring the load state of the grinding system. For, while the frequency and the magnitude of the fundamental oscillation of the forces exerted on the grinding element are basically determined by the structure of the mill and do not always change significantly even if the load is increased, the magnitude of the first harmonic (that is to say, the first upper harmonic wave) of that fundamental oscillation is found to be an extraordinarily sensitive indicator of a greatly increased or even critical load state. This holds good especially when the magnitude of the first harmonic is placed in relation to the magnitude of the fundamental oscillation.
It is therefore expedient to detect the forces acting on the grinding element in two frequency ranges, namely in a first frequency range which contains the fundamental oscillation of the forces, and in a second frequency range in which the first harmonic of that fundamental oscillation occurs.
Measures for reducing the load state of the grinding system are introduced especially when the first harmonic exceeds a predetermined value in relation to the magnitude of the fundamental oscillation.
In the case of a roller mill, the first frequency range is advantageously from 10 to 30 Hz, preferably from 15 to 25 Hz, and the second frequency range is advantageously from 20 to 60 Hz, preferably from 30 to 50 Hz.
When grinding elements that are driven at an adjustable speed are used, it is possible, according to an advantageous development of the invention, in addition to monitoring the dynamic forces exerted by the grinding stock on the grinding elements, to determine the driving torque from the power and the speed and to alter the load state of the grinding system by changing the speed of the grinding elements.
An embodiment of the invention is illustrated diagrammatically in the drawings in which:
The grinding roller 1 runs on the grinding table (not shown) of a vertical roller mill and can be driven either directly—as in the embodiment shown—by a drive motor 2 by way of a shaft surrounded by an arbor 3, or indirectly by way of the grinding table.
On the side facing the drive motor 2, the shaft is arranged in a stationary bearing 4 and, on the side facing the grinding roller 1, it is arranged in a movable bearing 5 constructed as a force frame.
In operation, dynamic forces are exerted by the grinding stock on the grinding roller 1 in the axial direction (arrow 6), the tangential direction (arrow 7) and the vertical direction (arrow 8).
The forces acting in the axial direction are detected in the stationary bearing 4 by an extension measurement sensor 9 fitted there.
The forces acting in the tangential direction are ascertained in the movable bearing 5 by an extension measurement sensor 10 provided there.
The forces acting in the vertical direction are ascertained in the movable bearing 5 by means of the pressure of a hydraulic system 11 supporting the arbor 3 in the force frame of the movable bearing 5.
In operation, the dynamic forces exerted by the grinding stock on the grinding roller 1 are monitored by measuring the extensions by means of the sensors 9 and 10 and by measuring the pressure in the hydraulic system 11 in the frequency ranges of from 15 to 25 Hz (in accordance with the fundamental oscillation of the dynamic forces) and from 30 to 50 Hz (in accordance with the first harmonic of the dynamic forces) at all of the roller units of the vertical roller mill.
If a level which is at least from three to five times greater than the average level existing in normal operation occurs at least two of the three measuring sites of a roller unit in at least one of the two frequency ranges, this indicates that a critical load state is being approached. In that case, suitable measures for reducing the load state are introduced automatically.
Number | Date | Country | Kind |
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10 2008 046 921.1 | Sep 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP09/61213 | 8/31/2009 | WO | 00 | 1/31/2011 |