EP2817100A2

EP2817100A2 - Vertical roller mill and method for operating a vertical roller mill

Info

Publication number: EP2817100A2
Application number: EP13701064.1A
Authority: EP
Inventors: Markus Berger
Original assignee: ThyssenKrupp Industrial Solutions AG
Current assignee: ThyssenKrupp Industrial Solutions AG
Priority date: 2012-02-24
Filing date: 2013-01-22
Publication date: 2014-12-31
Anticipated expiration: 2033-01-22
Also published as: CN104220172A; US9643188B2; JP2015508021A; CN104220172B; WO2013124106A2; DE102012101489B4; JP6196243B2; DE102012101489A1; DK2817100T3; EP2817100B1; WO2013124106A3; US20150014455A1

Abstract

The invention relates to a vertical roller mill and a method for operating a vertical roller mill, wherein the grinding assemblies thereof, consisting of a grinding table and at least one grinding roller, interact such that material to be ground is comminuted in the grinding bed between the grinding table and the at least one grinding roller, wherein at least one grinding assembly is driven and at least one grinding assembly is pulled, and the pulled grinding assembly is braked in order to increase the flow of energy through the grinding bed between the grinding table and the at least one grinding roller.

Description

Vertical mill and method of operating a vertical mill

The invention relates to a VertikalroUenmühle and a method for operating a VertikalroUenmühle whose Mahlaggregate consisting of a grinding table and at least one grinding roller, cooperate such that grinding material between the grinding plate and the at least one Mahlroller is comminuted, at least one grinding unit driven and at least one grinding unit is being towed.

For the production of powdery materials for the binder industry, there are increasingly used vertical roller mills which are superior to other milling systems, e.g. Tube mills, allow a significant energy savings.

From DE 10 2007 033 256 AI a VertikalroUenmühle with driven grinding table is known, wherein the grinding table on the grinding bed drives the grinding rollers. However, this leads to strong power fluctuations and thus to high loads on the drive train, which requires correspondingly high safety factors in the drive train. On the other hand is the power consumption and also the

Comminution also subject to strong fluctuations and controllable only conditionally over the material bed.

From DE 35 20 937 AI further a roller mill with a rotatably mounted about a vertical axis table is known, which is provided with an annular groove in its upper side and cooperates with convex grinding rollers, being between the spherical peripheral part of the grinding rollers and the annular groove Gap formed in the ground material is crushed and crushed.

It has therefore been proposed in DE 197 02 854 Al to drive the grinding rollers. There it was also pointed out that the individual grinding rollers on the one hand on the grinding table and the grinding stock or Mahlgutbett are rotationally coupled together and on the other hand can have very different power consumption, for example different rolling diameters on the grinding plate (rolling point / diameter), different effective diameters of the individual grinding rollers (eg due to wear) and due to a different intake behavior of the ground material in interaction on grinding plate and grinding roller are due.

Even small changes in speed between individual grinding rollers cause relatively high power fluctuations in the individual drives. This can cause the grinding rollers to be partially accelerated and decelerated, so that the individually driven grinding rollers work against each other, which leads to a significantly increased power or energy consumption during the crushing operation.

In DE 197 02 854 AI has therefore been proposed that the operating fluctuations between the individual rotary actuators of all driven grinding rollers are compensated by a common power compensation control.

However, the achievable with vertical mills finest portion of the material to be ground is lower than in other grinding systems, such. Tube mills is what may adversely affect the binder properties in the production of binders.

The present invention is therefore based on the object to improve the vertical roller mill and the method for operating the vertical roller mill to the effect that the fines per Mahlwerkzeugkontakt (crushing progress during the stress in the grinding bed between the grinding roller and grinding plate) is increased.

According to the invention, this object is solved by the features of claims 1 and 10.

In the method according to the invention for operating a vertical roller mill, its grinding units, consisting of a grinding plate and at least one grinding roller, cooperate in such a way that the material to be ground in the grinding bed is between the grinding plate and the at least one grinding roller is comminuted, wherein at least one grinding unit is driven and at least one grinding unit is towed, and the towed grinding unit is braked to increase the flow of energy through the grinding bed between the grinding table and the at least one grinding roller.

The vertical roller mill according to the invention has at least one driven and at least one towed grinding unit, wherein the grinding units are formed by a grinding table and at least one grinding roller, which cooperate in such a way that ground material is comminuted in the grinding bed between the grinding table and the at least one grinding roller. The towed grinding aggregate also acts to increase the flow of energy through the grinding bed between the grinding table and the at least one grinding roller with a braking device for braking the towed grinding aggregate.

The towed grinding unit is not driven by a drive, but only rotated about the material to be ground in rotation.

The increase in the energy flow through the grinding bed results in an increase in the slip between the grinding table and the at least one grinding roller, which is explained in more detail below with reference to FIGS. 1 to 3. There, a grinding table 1, a grinding roller 2 and the grinding bed 3 are shown schematically. The force application point of the grinding roller 2 on the grinding bed 3 is indicated by the reference numeral 4. The slip is defined by the differential speed Avs between the peripheral speed of the grinding roller 2 in the force application point 4 and the peripheral speed of the grinding table 1 in the force application point (radius RK) projected vertically downwards onto the grinding table 1.

2 shows an example with driven grinding roller 2 and dragged grinding plate 1 in the region of the force application point 4. It is clearly evident that the upper layer coming into contact with the grinding roller 2 of the grinding bed 3 has a higher speed than the one with the drag plate 1 having in contact lower layer. The difference between the highest and the lowest speed is called slip Avsi. In Fig. 3, the towed grinding table 1 is additionally braked. While the speed of the uppermost layer of the grinding bed 3 remains substantially unchanged, the speed of the lower layer in contact with the grinding table 1 is reduced. Accordingly, the slip Avs ₂ in FIG. 3 is greater than the slip Avsi in the situation according to FIG. 2. If, however, the grinding disc speed is influenced by a control (eg constant speed), the speed of the one contacting the grinding roller 2 increases Layer.

The self-adjusting slip Avsi of FIG. 2 essentially depends on the normal force exerted on the grinding bed via the grinding roller, the grinding bed 3 of the geometry of grinding rollers and grinding table and the transmitted moment. The controlled braking of a grinding unit (energy flow increase through the grinding bed), here the braking of the grinding table 1 in Fig. 3, increases with the same normal force of the slip Avs ₂ , resulting in an increased shear stress in the grinding bed 3. This in turn has an immediate effect on a higher fines content per run.

Further embodiments of the invention are the subject of the dependent claims.

The increase in the energy flow through the grinding bed can be realized in various ways. For example, a grinding roller can be driven and the grinding table can be braked, or at least the grinding table can be driven and at least one grinding roller can be braked. According to a preferred embodiment of the invention, energy is generated during braking of a grinding unit, which is used to drive the other grinding unit. As a result of the regeneration of the braking energy, the energy consumption of the entire system increases only slightly, whereas the grinding efficiency increases significantly with a desired target fineness.

Furthermore, it can be provided that, in order to regulate the energy flow through the grinding bed, the slip between the grinding plate and the at least one grinding roller is regulated within a predetermined range. For this purpose, in particular the rotational speed of the braked grinding unit can be determined and for Regulation can be used. Furthermore, it is conceivable that the slip between the grinding plate and at least one grinding roller is regulated as a function of the fines content of the comminuted material to be ground.

In the experiments on which the invention is based, it has been shown that the braked grinding unit is advantageously braked relative to the driven grinding unit in such a way that the slip between the grinding plate and the at least one grinding roller is controlled within a range of 3-10%. Furthermore, the braked unit with respect to the driven grinding unit can be braked so that the slip between the grinding table and the at least one grinding roller relative to an unrestrained and merely towed grinding unit increased by 15-100%.

In the physical configuration of the vertical roller mill, the at least one driven grinding unit can be formed by at least one grinding roller, which cooperates with a Mahlrollenantrieb and the at least one trailed grinding unit can be formed by the grinding table, which cooperates with a braking device. But it would also be conceivable that the at least one driven grinding unit is formed by the grinding table, which cooperates with a Mahltellerantrieb and the at least one towed grinding unit is formed by at least one grinding roller, which cooperates with the braking device. The braking action can be formed in particular by a generator.

Further advantages and embodiments of the invention will be explained in more detail below with reference to the following description and the drawing.

In the drawing show

1 is a schematic detail view of the vertical roller mill for explaining the force application point, 2 is a schematic representation of the slip with driven grinding roller and dragged grinding plate,

3 is a schematic representation of the slip with driven grinding roller and braked grinding plate,

4 is a schematic representation of a vertical roller mill with driven grinding rollers and braked grinding plate,

5 is a schematic representation of a vertical roller mill with driven grinding table and a driven and a braked grinding roller,

Fig. 6 is a schematic representation of the slip when driven

Grinding table and trailed grinding roller,

Fig. 7 is a schematic representation of the slip when driven

Grinding table and braked grinding roller,

Fig. 8 is a schematic representation of a vertical roller mill with driven grinding table and a braked and a towed grinding roller and

Fig. 9 is a schematic representation of a vertical roller mill with braked

Grinder and a braked and a driven grinding roller.

In the embodiment according to FIG. 4, two grinding rollers 2, 5 are driven via associated grinding roller drives 6, 7. The grinding table 1 is towed over the grinding bed 3 and is connected to a braking device 8 for controlling the slip between the grinding table 1 and the grinding rollers 2, 5 in operative connection. Furthermore, a control device 9 is provided, which is in communication with the Mahlrollenantrieben 6, 7 and the braking device 8. The actual slip can, for example, via sensors, in particular sensors for detecting the Revolution speeds of grinding plate 1 and possibly the grinding rollers 2, 5, are determined.

The braking device 8 is designed here as a generator to generate energy when braking the grinding plate 1, which can be used for the Mahlrollenantriebe 6 and / or 7 via a common intermediate energy storage device 14.

If the grinding table 1 according to FIG. 4 is not additionally braked, a slip Avsi according to FIG. 2 would occur. If the grinding table 1 is additionally braked via the braking device 8, the slip on Avs ₂ increases according to FIG. As a result, an increased shear stress is generated within the grinding bed 3, since the differential speed increases within the grinding bed. The additional shear load causes a higher fines content per run. It is therefore possible to imagine a control of the slip also as a function of the fines content of the comminuted regrind. For this purpose, one would determine the fines in the crushed millbase and use it for control.

In the embodiment of FIG. 5, the grinding table 1 is driven via a grinding table drive 1 1. Furthermore, the grinding roller 2 is driven via the Mahlrollenantrieb 6. A grinding roller 12, however, is braked by a braking device 10. Again, the resulting braking energy for driving the grinding roller 2 and / or the grinding table 1 can be used. The slip between the grinding roller 12 and the grinding table 1 can be controlled again via the control device 9 in a predetermined range. The variant according to FIG. 5 has the advantage of greater flexibility of the mill, wherein in particular a higher proportion of fines can be realized with an increased throughput.

FIG. 6 and FIG. 7 show the situation of slippage between a merely dragged or braked grinding roller and a driven grinding plate, wherein the grinding roller 13 in FIG. 6 is merely towed and the grinding roller 12 is additionally braked in FIG. Again, it can be seen that by the additional braking of the grinding roller 12, the slip between the grinding roller 12 and Grinding plate 1 and the shear stress within the grinding bed 3 in turn increased

In FIG. 8, a grinding table 1 driven by a grinding table drive 11 is combined with a grinding roller 12 braked by a braking device 10 and a grinding roller 13 only towed. The adjustment of the slip between the braked grinding roller 12 and the grinding table 1 is again via the control device 9. The energy obtained during the braking process can be used to drive the grinding table 1. The resulting slip in the area of the grinding rollers 12 and 13 can also be seen from FIGS. 6 and 7.

In Fig. 9, finally, an embodiment is shown, where a braked grinding plate 1 is combined with a driven grinding roller 2 and a braked grinding roller 12.

Appropriately Mahltellerantrieb 11 and braking device 10 of the grinding table are realized by an aggregate, which can optionally drives or brakes. The Mahlrollenantriebe 6 and 7 and the braking device 12 may be formed by an aggregate, which can realize both tasks.

Of course, in all variants shown, more than two grinding rollers can be provided, wherein each of the additional grinding rollers can either be driven, braked or merely towed.

In the experiments on which the invention is based, it has been found that a slippage between a driven and a braked grinding aggregate is expediently to be regulated in a range of 3-10%, on the one hand to markedly increase the microfine content and, on the other hand, to increase the energy requirement within a reasonable range hold. This means that the speed of the grinding bed in the contact area of the driven grinding unit is 3-10% higher than the speed of the grinding bed in the contact area of the braked grinding unit.

Claims

claims

1. A method for operating a vertical roller mill whose grinding units, consisting of a grinding table (1) and at least one grinding roller (2, 5, 12, 13), cooperate in such a way that the ground material in the grinding bed between the grinding table (1) and the at least one grinding roller (2, 5, 12, 13) is comminuted, wherein at least one grinding unit is driven and at least one grinding unit is towed, characterized in that the towed grinding unit to increase the energy flow through the grinding bed between the grinding table and the at least one grinding roller is braked.

2. The method according to claim 1, characterized in that at least one grinding roller (2, 5) driven and the grinding table (1) is braked.

3. The method according to claim 1, characterized in that at least the grinding table (1) is driven and at least one grinding roller (12) is braked.

4. The method according to claim 1, characterized in that when braking of a grinding unit energy is generated, which is used to drive the other grinding unit.

5. The method according to claim 1, characterized in that the energy flow through the grinding bed via a between the grinding table (1) and the at least one grinding roller (2, 5, 12) adjusting slip (Avs ₂ , Avs ₄ ) in a predetermined range is regulated.

6. The method according to claim 5, characterized in that for controlling the slip (Avs ₂ , Avs ₄ ) between the grinding table (1) and the at least one grinding roller (2, 5, 12), the rotational speed of the braked grinding unit is determined.

7. The method according to claim 5, characterized in that the braked grinding unit is braked relative to the driven grinding unit such that the slip (Avs ₂ , Avs ₄ ) between the grinding table (1) and the at least one grinding roller (2, 5, 12). is regulated in a range of 3 to 10%.

8. The method according to claim 5, characterized in that the slip (Avs ₂ ;

Avs ₄ ) between the grinding table (1) and the at least one grinding roller (2, 5, 12) is regulated as a function of the fines content of the comminuted material to be ground.

9. The method according to claim 5, characterized in that the braked grinding unit is braked relative to the driven grinding unit in such a way that the slip (Avs ₂ , Avs ₄ ) between the grinding table (1) and the at least one grinding roller (2, 5, 12 ) increased by 15 to 100% compared to an unrestrained and only towed grinding unit.

10. Vertical roller mill with at least one driven and at least one towed grinding units, which are formed by a grinding table (1) and at least one grinding roller (2, 5, 12, 13) which cooperate in such a way that ground material in the grinding bed between the grinding table and the at least a grinding roller (2, 5, 12, 13) is comminuted, characterized in that the towed grinding unit to increase the energy flow through the grinding bed between the grinding table (1) and the at least one grinding roller (2, 5, 12) with a braking device ( 8, 10) for braking the towed grinding aggregate.

11. Vertical roller mill according to claim 10, characterized in that the at least one driven grinding unit by at least one grinding roller (2, 5) is formed, which cooperates with a Mahlrollenantrieb (6, 7) and the at least one towed grinding aggregate through the grinding table (1). is formed, which cooperates with the braking device (8).

12. Vertical roller mill according to claim 10, characterized in that the at least one driven grinding unit through the grinding plate (1) is formed, which cooperates with a grinding table drive (11) and the at least one towed grinding unit is formed by at least one grinding roller (12) with the braking device (10) cooperates.

13. Vertical roller mill according to claim 10, characterized in that the braking device (8, 10) is formed by a generator.

14. Vertical roller mill according to claim 10, characterized in that a control device (9) for controlling a slip between the grinding plate and the at least one grinding roller (2, 5, 12) is provided in a predetermined range.