EP0973612A1

EP0973612A1 - Crushing gap adjustment device

Info

Publication number: EP0973612A1
Application number: EP98928196A
Authority: EP
Inventors: Harald Gratzer
Original assignee: Anton Steinecker Maschinenfabrik GmbH
Current assignee: Anton Steinecker Maschinenfabrik GmbH
Priority date: 1997-04-11
Filing date: 1998-04-08
Publication date: 2000-01-26
Also published as: AU8013398A; WO1998046354A1; DE19715210A1; CN1255878A; CN1110370C; JP2000510388A; DE19715210C2; JP3420772B2

Abstract

The invention relates to a crushing gap adjustment device for a crushing machine comprising at least two cylinders (1, 2) between which malt is ground in a gap (22). The inventive machine is particularly suitable for wet malt mills comprising a continuous, tool-less adjustment device for the crushing gap (22) using an eccentric bearing (3) of at least the first (1) of two cylinders (1, 2).

Description

Grinding gap adjustment

The invention relates to a grinding gap adjustment device for a grinder with at least two rollers, between which ground material is ground, and a wet grinding mill with at least two rollers.

When crushing good, e.g. To prepare the mash for beer production, the material to be crushed is ground between two counter-rotating rollers. Several such double-roller arrangements can follow one another in order to obtain a corresponding degree of crushing or to increase the service life of the grinding rollers. The rollers and their axles or stub shafts are supported in appropriate bearing shells, which enable smooth operation. Such a double roller arrangement is e.g. described in German utility model 296 20 133.2.

When preparing the mash in a beer production process, e.g. the diameter of the grinding rollers is typically about 40 cm, while the grinding gap is of the order of 0.4 mm. In order to obtain an optimal grinding result, an exact adjustment of the grinding gap or the roller spacing is necessary.

In order to achieve adjustability of the grinding gap, one of the two rollers has already been mounted on a lever device in dry grinding mills, which, when a lever is adjusted, adjusts or removes a roller from the second roller so that the grinding gap can be adjusted. However, this solution is structurally complex and expensive. In addition, the adjusting lever and the adjusting drive have to absorb the forces resulting from the grinding process and are heavily loaded. In addition, such an arrangement can not be used for wet shot mills, since there the rollers move in the wet environment of the wet shot. Accordingly, an expensive sealing of the movable bearing lever would be necessary.

With wet grinding mills, gap adjustment has so far only been possible with tools and can only be carried out by dismantling housing parts during inspection or maintenance work. An adjustment in the company to the individual needs, depending on the regrind, is therefore not possible. In practice, it is therefore the case that larger breweries keep several mills, the grinding gaps of which are adjusted to the different regrinds to be processed. It is therefore an object of the present invention to provide a wet grinding mill which enables the grinding gap to be adjusted continuously, preferably without tools, and to propose a grinding gap adjustment device which is also particularly suitable for a wet grinding mill and which enables the grinding gap to be set continuously, preferably without tools.

This object is achieved with a grinding gap adjustment device with the properties of claim 1 and a wet shot mill with the properties of claim 12. Advantageous further developments are the subject of the subclaims.

The grinding gap adjustment device according to the invention has an adjusting device for the grinding gap, which can be adjusted continuously and without tools, an eccentric bearing of at least one of the first two rollers being used.

With these features, an adjustment device is created which enables the grinding gap to be adjusted for various grinding materials in operation. The mill operator can specify the roll gap suitable for a particular type of ground material, in which case the rolls can be adjusted accordingly. The eccentric mounting of at least one of the two rollers enables the grinding gap to be set very precisely by turning without the bearings being excessively loaded. The grinding forces can thus be easily derived into the wall in which the bearing is preferably implemented. Depending on how the degree of eccentricity is chosen, a very fine, essentially continuously variable adjustment can be achieved. If the claim is infinitely variable, it should also include an adjustment that takes place in very small steps, such as occurs, for example, when using a stepper motor. The term "tool-free" is intended to indicate that an adjustment is easily possible from the outside without parts of the mill having to be dismantled and the rollers uncovered. Ideally, the operator of the mill can e.g. specify a desired roll gap by assigning recipe-dependent setpoints to a process control system, which is then set.

Advantageously, a first eccentric ring with an inner bore is provided for the eccentric mounting, the center of which is offset from the center of the outer circumference of the ring, the inner bore supporting the at least one roller.

Furthermore, it is advantageous if a rotating device is provided which engages the first eccentric ring in order to rotate it about the center of its outer circumference. The first eccentric ring is rotatably mounted in a plain bearing. This enables a structurally simple structure for rotating the eccentric ring.

According to one embodiment, this rotating device comprises a lever which is in engagement with an adjusting device. This adjusting device can simply comprise a pneumatic cylinder or a hydraulic system.

According to other embodiments, the rotating device comprises an electrical lifting spindle drive or a stepper motor, which enable direct control of the eccentric ring.

The eccentric ring is advantageously held in a bearing cover by a clamping ring. Such a clamping ring enables a precise setting of the force that is to be applied when the eccentric ring is rotated.

It is particularly advantageous if the eccentricity is chosen to be so small that the first eccentric ring with sliding bearings is self-locking in its mounting. In this way, forces on the adjusting device of the eccentric ring can be reduced or avoided during grinding operation.

According to a particularly advantageous embodiment, for the initial setting of the grinding gap, the second roller is held in a second eccentric ring, in which the center point of the inner bore is offset from the center point of the outer circumference, the eccentricity that occurs being greater than that of the first eccentric ring. Such an arrangement enables the grinding gap to be set for the first time, especially after regrinding due to wear. The fine adjustment with the help of the first eccentric ring then enables the fine adjustment or adjustment for different regrinds.

A wet grinding mill according to the invention with at least two rollers has an adjustment device for the width of the grinding gap that can be adjusted continuously and without tools.

Such a stepless adjustment device, which can be operated without the use of tools, enables simple, individual adaptation of the wet grist mill to various regrinds. The wet grinding mill according to the invention advantageously comprises a grinding gap adjustment device according to the invention, as described in claims 1 to 11.

The invention will now be explained in more detail with reference to the accompanying drawings.

It is

1 is a plan view of a storage area of the two rollers of a device according to the invention,

Fig. 2 is a side sectional view taken approximately along the plane A-A of Figs. 1 and

Fig. 3 is a schematic overall view of a wet shot mill.

Fig. 3 shows schematically a wet grist mill for crushing malt in beer production. Reference numerals 1 and 2 designate two rollers of the grinder. They are surrounded by a housing 30, in the bottom area of which an outlet 32 with a pump 32a is arranged. A soft container 40 and a feed metering device 41 are located above the grinder. A second feed metering device 42 connects the soft container 40 to a scrap container 44. A water inlet 43 is provided in this area.

Fig. 1 shows in detail in plan view the area of the storage of the two rollers 1, 2 according to the invention.

The rollers 1, 2, the diameter of which is typically, for example, 40 cm, have stub shafts 5, 6 which are mounted in spherical roller bearings 11, 12 in eccentric rings 3, 4. The shaft ends 5, 6 are sealed with the aid of seals 23a, 23b. The eccentric rings 3, 4 are arranged in circular recesses (bores) in the bearing cap 10. More precisely, the bearing cover 10 has a circular recess (bore) for receiving the first eccentric ring 3, which is adapted to the outer circumference of the first eccentric ring 3 in such a way that the eccentric ring is accommodated without play but rotatably. There is also a circular recess in the region of the second roller 2, which is correspondingly adapted to the outer diameter of the second eccentric ring 4. In the example shown, the eccentricity of the first eccentric ring 3 is designated by e- _t , but is so small that it cannot be shown to scale in the drawing. In practice, it is preferably between 0.5 and 1 mm. The eccentricity of the eccentric ring 4 of the second roller 6 is designated by the letter e ₂ and is significantly larger than

The first eccentric ring 3 is held axially fixed by a retaining ring 7 with screws 8 in the bearing cap 10. The second eccentric ring 4 is fastened with a retaining ring 21 and retaining screws 9. The screws 8 and the retaining screws 9 are screwed into the bearing cover 10.

With 13 in Fig. 1, the drive for the second roller 2 is designated. The first roller is also driven by this drive via transmission means, not shown, in such a way that the rollers run in opposite directions and synchronously.

The grinding gap 22 is formed between the rollers 1, 2.

In Fig. 2, the inlet opening for the material to be crushed is designated 14. Reference numeral 17 denotes the bearing cover of the bearing for the second stub shaft 6. The bearing cover 17 is fastened to the second eccentric ring 4 with screws 15.

On the first eccentric ring 3, a ring 18 is fastened with screws 16, which ring is provided with a protruding arm 19, on which an electrical lifting spindle drive engages with position feedback 20, if necessary.

The functioning of the grinder is explained below.

Each time the roll is changed and the grinder is started up for the first time, the grinding gap 22 is set exactly to the smallest required grinding gap width, for example by appropriate adjustment of the eccentric ring 4. For this purpose, the eccentric 4 is inserted into a corresponding position in its receiving opening in the bearing housing and then this position is fixed by tightening the screws 9. The eccentric 3 for the first roller is also in the set starting position, so that the desired gap width of the gap 22 is obtained. Before the grinding process, the desired grinding gap is set by turning the eccentric 3. Now the mill can be put into operation for the regrind for which the set gap distance is suitable. The regrind fails the inlet opening 14 into the area of the grinding gap is squeezed there and reaches the mash tun (not shown) via the pump 32a and line 32 (cf. FIG. 3). Water can be supplied through the feed line 43 for wet grinding.

If the brewer now wants to process a different regrind mixture, for example to produce a different type of beer, he can adjust the grinding gap 22 by giving appropriate signals to the electric lifting spindle drive 20, which then rotates the eccentric 3 accordingly. These signals can e.g. can be given electrically to the electric lifting spindle drive via an external terminal. However, a corresponding, e.g. mechanical adjusting device can be attached to the outside of the mill housing or the like.

Depending on the direction of rotation, the gap then increases or decreases as desired due to the eccentricity of the mounting of the first roller 1. The adjustment paths are adapted so that essentially a continuous adjustment of the grinding gap can be achieved. An adjustment of the grinding gap between 0.3 and 1.2 mm should preferably be possible for the area of the beer breweries.

The force that is applied by the drive 20 is essentially converted into a rotary movement. Since the eccentricity is only very low, there is a very simple changeover option and it is also achieved that the low eccentricity results in a self-locking bearing. Instead of the electrical lifting spindle drive 20, a hydraulic or pneumatic positioning cylinder or a manual spindle drive can also effect the same adjustment.

With the invention it is therefore possible to adjust the roller gap to the regrind to be processed practically infinitely in operation, in each case individually adapted, without major conversion, disassembly or adjustment work having to be carried out. In particular, the adjustment can also be carried out for wet shot mills, since sealing is easily possible with this type of storage. The forces are introduced via the eccentric into the bearing housing and thus into the roller housing, so that they can be easily controlled.

If the rollers show signs of wear after prolonged operation, the rollers can be reground and the resulting, usually larger, removal can be compensated for by appropriate remounting of the eccentric 4. The grinding gap adjustment device according to the invention can be used in dry shot mills, but also has its advantages in particular when used in wet shot mills.

The grinding gap adjustment device according to the invention has a simple, inexpensive structure and nevertheless enables the grinding gap to be set very precisely. It is suitable for both dry and wet grinding processes.

Claims

claims

1. Grinding gap adjustment device for a grinder with at least two rollers (1, 2), between which grinding material is ground in a grinding gap (22), particularly suitable for a wet grinding mill, with an infinitely adjustable tooling device for the grinding gap (22) using a eccentric bearing (3) at least a first (1) of the two rollers (1, 2).

2. grinding gap adjustment device according to claim 1, characterized by a first eccentric ring (3) with an inner bore, the center of which is offset from the center of the outer circumference of the first eccentric ring (3), the inner bore holding the first roller (1).

3. grinding gap adjustment device according to claim 2, characterized by a rotating device (18, 19) with an adjusting device (20), wherein the eccentric ring is slidably mounted and the rotating device engages the eccentric ring (3) to rotate it about the center of its outer circumference.

4. grinding gap adjustment device according to claim 3, characterized in that the

Rotating device comprises a lever (19).

5. grinding gap adjustment device according to claim 3, characterized in that the adjusting device (20) comprises a pneumatic cylinder.

6. grinding gap adjusting device according to claim 3, characterized in that the adjusting device (20) comprises a hydraulic system.

7. grinding gap adjustment device according to claim 3, characterized in that the adjusting device (20) comprises an electric lifting spindle drive.

8. grinding gap adjustment device according to claim 3, characterized in that the rotating device comprises a stepper motor.

9. grinding gap adjustment device according to one of claims 2 to 8, characterized in that the first eccentric ring (3) is held by a retaining ring (7) in a bearing cover (10).

10. grinding gap adjustment device according to one of claims 2 to 9, characterized in that the first eccentric ring (3) is mounted self-locking.

11. grinding gap adjustment device according to one of claims 2 to 10, characterized in that for the coarse adjustment of the grinding gap (22), the second roller is held in a second eccentric ring (4), in which the center of the inner bore is offset from the center of the outer circumference, wherein the resulting eccentricity (e ₂ ) is greater than that (e-ι) of the first eccentric ring (3).

12. Wet grist mill with at least two rollers (1, 2), characterized in that it is provided with a practically infinitely variable and tool-free adjustment device for the width of the grinding gap (22).

13. wet shot mill according to claim 12, characterized by a grinding gap adjustment device according to one of claims 1 to 11.

14. Method for continuously adjusting the grinding gap (22) of a grinder with two rollers (1, 2) by rotating an eccentric bearing of the axis (5) of at least one roller (1).