EP0386520A2 - Material bed roller mill - Google Patents

Abstract

The invention relates to a material bed roller mill for comminuting brittle regrind in the roller gap (4) between two driven rollers (1, 2) pressed against one another with high grinding force, via which a filling shaft (5) is provided for supplying regrind. The width of the regrind stream supplied to the roll gap (4) can be changed with the aid of vertical guide walls (7a, 7b) which are adjustable transversely to the vertical central plane (8) of the roll mill while maintaining their vertical position. The millbase column, which is aligned vertically above the rollers (1, 2), brings the pressure created by it completely into the material bed size reduction and can be adjusted across the rollers if necessary.

Description

The invention relates to a material bed roller mill according to the preamble of claim 1.

A material bed roller mill of the type required is known for example from DE-OS 35 35 406. Here, at a certain height above the nip and at the lower end of a filling shaft, two opposing, slide-like covers are provided, which can be shifted in a straight line against each other in their chosen inclined position, thereby regulating the material feed width and / or the height of the material column on the rollers to be able to.

The invention has for its object to improve a material bed roller mill of the type required in the preamble of claim 1 in such a way that, with a relatively simple structural design, the pressure which is established by the column of grinding material above the rollers can be used as far as possible for material bed reduction even with fluctuating supply of grinding material .

This object is achieved according to the invention by the characterizing features of claim 1.

Particularly expedient refinements and developments of the invention are the subject of the dependent claims.

In this embodiment of the filling shaft in accordance with the invention, the regrind to be fed to the roll gap is limited laterally in guide walls which can be adjusted transversely to the vertical central plane of the material bed roller mill, that is to say in the transverse direction to the roller axes, so that a minimum height is obtained both with smaller amounts of regrind and with larger amounts of regrind the column of ground material that forms can be maintained. It is also essential that the adjustable guide walls of the filling shaft maintain their vertical position even when they are adjusted transversely. In this way, the regrind pressure, which is formed by the regrind column above the rollers, can be practically fully utilized for comminution in the area of the nip. With this design of the guide walls, the incoming regrind or the regrind located in the regrind column always has a reliable vertical lateral guidance even if the vertical guide walls of the filling shaft are adjusted in the transverse direction to the vertical central plane in accordance with the respective incoming regrind quantity.

For the two vertical guide walls it can be expedient if these can be adjusted jointly in the transverse direction to the vertical central plane or individually and independently of one another in this transverse direction. The millbase column laterally delimited by the vertical guide walls can thus be aligned symmetrically to the vertical center plane of the mill-bed roll mill if the two drive motors of the two mill rolls have the same power consumption in accordance with the millbase composition.

If the regrind to be fed is of different origin and / or has very different grain sizes (if, for example, uncrushed fresh material and recycled semolina are fed together to the hopper), then it can happen that the two grinding rollers are loaded to different extents when the regrind column is fed symmetrically to the nip and whose drive motors thus show different power consumption. In this case, for example by transverse adjustment of only one guide wall, the millbase column above the nip asymmetrical to the vertical center plane of the whale zenmühle be adjusted so that the power consumption of the drive motors of both rollers is balanced again.

The invention is explained in more detail below with reference to the drawing. In this drawing, FIGS. 1, 2 and 3 each show schematically held, largely similar cross-sectional views through a material bed roller mill according to the invention, in which three figures of the drawing. only vertical guide walls of the hopper each occupy different positions.

The general structure of this material bed roller mill is first explained with reference to FIG. 1, but all parts of this material bed roller mill in all the figures. are the same, so that they are all provided with the same reference numerals.

The material bed roller mill contains two rollers 1, 2 which are arranged next to one another and are pressed against one another with high grinding force, of which roller 1 is designed as a fixed roller and roller 2 as a loose roller. The loose roller 2 is movably mounted in the direction of the double arrow 3 and thus in the direction of the fixed roller 1, as is known per se. Both rollers 1, 2 are preferably driven against each other by a separate drive motor, which is not illustrated in detail here.

Between the two rolls 1, 2 there is a roll gap (grinding gap) 4, above which a filling shaft 5 is arranged for feeding regrind to the roll gap 4.

So that the clear width B of the regrind stream fed from the filling chute 5 to the nip 4, that is to say the regrind column 6 formed thereby, can be changed in the desired manner in each case, in the lower region of the filling chute 5 there are two which are opposite one another vertical guide walls 7a and 7b are provided adjustable while maintaining their vertical position transverse to the vertical central plane 8 of the material bed roller mill. These two vertical guide walls 7a, 7b thus limit the regrind flow (regrind column 6) to be fed to the roll nip 4 in the lateral direction, ie in the transverse direction to the roll axes 1a and 2a.

The two vertical guide walls 7a and 7b opposite each other on both sides of the vertical center plane 8 extend parallel to the roller axes 1a, 2a and essentially over the entire axial length (perpendicular to the plane of the drawing of FIGS. 1-3) of the rollers 1 and 2. Both guide walls 7a, 7b can be adjusted jointly or individually and independently of one another in the transverse direction to the vertical central plane 8, ie in the direction of the double arrows 9a, 9b, depending on requirements and design. In this way, a more or less wide symmetrical regrind column 6 or 6a (FIGS. 1 and 2) or asymmetrical regrind column 6b (FIG. 1) can be positioned above the nip 4 or above the two rollers 1, 2 with respect to the vertical central plane 8 of the material bed roller mill 3) are formed and maintained or adjusted, which generally depends primarily on the power consumption of the two drive motors for the rollers 1 and 2 and thus on the respective workload of these two rollers 1, 2. In any case, the millbase column 6, 6a, 6b is always laterally delimited by vertically running guide walls 7a, 7b, in order thereby to utilize the full pressure generated by the millbase column above the rollers 1, 2 for comminution of the material bed. The height H (FIG. 1) of the material column 6, 6a or 6b, which is above the rolls 1, 2 or the roll nip 4 and which becomes effective in this regard, can be adjusted by the transverse adjustability (arrows 9a, 9b) of the guide walls 7a, 7b and thus can be kept or adjusted at their most favorable height by the adjustability of the width B of the material bed column.

This means that the lateral transverse adjustment of the vertical guide walls 7a, 7b allows a reduction in the quantity of regrind to be fed without the regrind pressure on the part of the regrind column being reduced in the direction of the nip 4. Each of the two vertical guide walls 7a, 7b is arranged directly above an associated roller 1 or 2. Here, the lower longitudinal edge 7a 'or 7b' of each guide wall 7a or 7b has a substantially constant minimum distance a to the outer peripheral side 1b, 2b of the associated roller.

In the example illustrated in the drawing, the filling chute 5 has a chute base body 10, which in the lower, vertical chute section 5a has two stationary chute walls 11a, 11b, which are spaced apart on both sides of the vertical central plane 8 and run parallel to the roller axes 1a, 2a , between which the two vertical guide walls 7a, 7b are arranged so as to be transverse (arrows 9a, 9b). These two stationary shaft walls 11a, 11b also end at a short distance (approximately distance a in FIG. 1) above the outer circumferential side 1b or 2b of the associated roller 1 or 2. The transverse distance between these two stationary shaft walls 11a, 11b is so great dimensioned such that the guide walls 7a, 7b, which can move transversely between them, can be adjusted to a maximum width B of the millbase column (approximately millbase column 6 in FIG. 1).

The shaft base body 10 also has in the region of the upper ends 7a˝, 7b˝ of the vertical guide walls 7a, 7b - viewed in cross section of the roller mill (cf. representations in FIGS. 1-3) - a funnel-shaped extension, which is preferably preferably by two the same size, symmetrical to the vertical center plane 8 downward (converging) inclined walls 12a and 12b is formed. These two inclined walls 12a, 12b connect approximately to the upper ends of the stationary shaft walls 11a, 11b. Above the funnel-shaped extension formed in this way, the manhole base body 10 can also have a container-like upper part 10 'with essentially straight side walls in the manner of a storage container.

With the upper end 7a˝ or 7b˝ of each vertical guide wall 7a, 7b, a substantially flat slide wall 13a or 13b is fixed, preferably rigidly connected, which is assigned to one of the inclined walls 12a or 12b of the shaft base body 10. Each of these essentially flat slide walls 13a, 13b is inclined in the same way as the inclined walls 12a, 12b, and each slide wall 13a or 13b is guided and adjustable in the same direction as the double arrows 14a, 14b in or on the associated inclined wall 12a or 12b . This adjustability in the direction of the arrows 14a, 14b of the two slide walls 13a, 13b is provided in such a way that the vertical guide walls 7a and 7b connected to these slide walls 13a, 13b are adjusted transversely to the vertical central plane 8 in the direction of the double arrows 9a and 9b can be. It goes without saying that each slide wall 13a, 13b can be assigned a suitable adjusting device, not illustrated in more detail, which can be designed for slides in a manner known per se in order to adjust the necessary or desired adjustment options of the vertical guide walls 7a, 7b ( jointly or individually and independently of each other).

The slide walls 13a, 13b explained have the advantage that they can extend the inclined walls 12a, 12b of the shaft base body 10 in the direction of the vertical central plane 8 (as an additional inclined funnel guide for the material flow to be supplied).

It goes without saying that, if necessary, suitable additional adjustment means can also be provided on the lower end sections of the vertical guide walls 7a, 7b, which, in particular with relatively large height dimensions of the vertical guide walls 7a, 7b, for maintaining the vertical position of these guide walls 7a, 7b also worry in this lower section. These additional adjustment means could expediently be coupled to the adjustment devices for the slide walls 13a, 13b. It is also understood that other suitable means for transverse adjustment of the vertical guide walls 7a, 7b can also be provided.

If one looks at the representations in FIGS. 1, 2 and 3, only different setting positions of the vertical guide walls 7a and 7b can be seen there in each case. For example, FIG. 1 shows the greatest clear width B of the ground material column 6 with the vertical guide walls 7a and 7b practically completely adjusted outwards. 1, this results in a millbase column 6 with maximum width B that is symmetrical with respect to the vertical center plane 8 of the material bed roller mill or that is symmetrical with respect to the roller gap 4.

2, the two vertical guide walls 7a and 7b are adjusted by an equal amount against the vertical center plane 8, so that here again a regrind column 6a symmetrical with respect to the vertical center plane 8, but of relatively small width B 1 results.

As shown in Fig. 3, only the right vertical guide wall 7b is almost completely adjusted against the vertical center plane 8 of the material bed roller mill, while the left vertical guide wall 7a remains set in its outermost position near the shaft wall 8a (as in Fig. 1). This way a with respect to the vertical center plane 8 and the nip 4 asymmetrical adjustment of the ground column 6b formed with a corresponding width B₂.

The comparison between FIGS. 1, 2 and 3 reveals that any settings and orientations of the mill column to be fed to the roll nip 4 are possible. The asymmetrical supply of the regrind to the nip 4 is selected to a correspondingly large extent if the power consumption of the drive motor from one roller is higher than that of the other roller, so that this asymmetrical setting of the regrind stream is more pronounced on the outer circumferential side of the one Roller can be steered that the power consumption of the drive motors is the same for both rollers.

Finally, it should also be mentioned that the highest throughput of this material bed roller mill is achieved with the always vertical guide walls 7a, 7b of the filling shaft 5 when the clear shaft width B (and thus the width B of the column of ground material), the ground material height H and the diameter of the rollers 1, 2 are coordinated in a suitable relationship.

For the sake of completeness, it should also be mentioned that in the area of the end faces of the filling shaft 5, d. H. In the region of the axial ends of the pair of rollers 1, 2, of course, in any suitable manner, implemented and attached, known end walls can be provided, which limit the column of ground material there.

Claims (7)

1. Gutbettwalzenmühle, containing
a) two driven rollers (1, 2) which are arranged side by side to form a roller gap (4) and are pressed against one another with high grinding force, of which at least one roller is movably mounted in the direction of the other roller,
b) a filling chute (5) arranged above the roll gap (4) for feeding the ground material to the roll gap,
c) devices for changing the width of the regrind stream fed from the filling shaft (5) to the roller gap (4),
characterized,
that vertical guide walls (7a, 7b), which laterally limit the flow of regrind (6, 6a, 6b) supplied to the roll gap (4) in the lower region of the filling shaft (5), while maintaining their vertical position transverse to the vertical central plane (8) of the material bed roller mill are adjustable. 2. Gutbettwalzenmühle according to claim 1, characterized in that the vertical guide walls (7a, 7b) extend parallel to the roller axes (1a, 2a) and substantially over the entire axial length of the rollers (1, 2). 3. Gutbettwalzenmühle according to claim 1, characterized in that the two vertical guide walls (7a, 7b) together in the transverse direction (9a, 9b) to the vertical central plane (8) are adjustable. 4. Gutbettwalzenmühle according to claim 1, characterized in that the two vertical guide walls (7a, 7b) individually and independently of each other in the transverse direction (9a, 9b) to the vertical central plane (8) are adjustable. 5. Gutbettwalzenmühle according to claim 1, characterized in that each vertical guide wall (7a, 7b) is assigned to a roller (1, 2) and their under longitudinal edge (7a ', 7b') a substantially constant minimum distance (a) to the outer circumferential side (1b, 2b) of the associated roller. 6. Gutbettwalzenmühle according to claim 1, characterized in that the filling shaft (5) has a shaft base body (10) with two opposite, parallel to the roller axes (1a, 2a), fixed shaft walls (11a, 11b), between which the two Guide walls (7a, 7b) are arranged so as to be transverse. 7. Gutbettwalzenmühle according to claim 6, characterized in that the shaft base body (10) in the region of the upper ends (7a˝, 7b˝) of the vertical guide walls 7a, 7b) - viewed in cross section of the roller mill - a funnel-shaped extension with two preferably the same size , symmetrically to the vertical central plane (8) downward inclined walls (12a, 12b), in each of which a similarly inclined, substantially flat slide wall (13a, 13b) is slidably guided, which with the upper end (7a˝, 7b˝ ) one of the vertical guide walls (7a, 7b) is connected, a sliding movement of the slide walls displacing these guide walls in the transverse direction (9a, 9b).

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