WO2009071513A1

WO2009071513A1 - Roll press with symmetrical roll centring

Info

Publication number: WO2009071513A1
Application number: PCT/EP2008/066546
Authority: WO
Inventors: Christian Splinter
Original assignee: Khd Humboldt Wedag Gmbh
Priority date: 2007-12-07
Filing date: 2008-12-01
Publication date: 2009-06-11
Also published as: PE20091607A1; DE102007059073A1; CL2008003643A1

Abstract

The invention relates to a roll press for for the compression or compacting of granular products, comprising two detachable rolls separated by a roll gap, driven in opposite directions and mounted in such a way as to rotate in a machine frame by means of a shaft. The shafts of the mobile rolls are received in bearing housings arranged in a mobile manner in the machine frame. According to the invention, the bearing housings of the two shafts are interconnected in a mobile manner by a transmission. In this way, the two rolls move symmetrically in relation to each other, preventing a one-sided movement of one roll in favour of a slower movement of the two rolls, in the event of impacts caused by particles that cannot be ground.

Description

Roller press with symmetrical roller centering

The invention relates to a roller press for pressure treatment or for compacting granular Guts comprising two each rotatably mounted on a shaft in a machine frame and driven in opposite directions, separated by a nip roller bearings, the waves of the Loswalzen are accommodated in the machine frame movably arranged bearing housings.

For pressure treatment or for compacting granular material roll presses are often used with rollers, which have a weight of sometimes well over 50 t. In the roller presses, the material to be treated is passed through a nip between two counter-rotating rollers, whereby the rollers are pressed against each other with pressure systems to maintain the pressure in the nip. To increase the throughput of these roller presses, either larger roller presses are used, which makes the use of even larger rollers required, or the rotational speed of the rollers is increased. In order to absorb the very high forces during pressure treatment, correspondingly large-sized machine frame are necessary, which serve as an abutment for the forces that occur in the nip. In addition to the machine frame, the shafts of the rollers and also the bearings and bearing housings for the shafts must be dimensioned correspondingly large, so that the bearings in addition to the forces from the nip and the loads that are caused by shocks can absorb, without causing damage itself to take.

The large dimensioning of the machine frame, the bearings and the bearing housing makes the logistics of the individual parts and their handling in a necessary and regular change of rolls on and this change is only possible with appropriately sized cranes and removal aids.

In order to be able to reduce the dimensions of the necessary dimensioning of the machine frame, it is proposed in DE 10 2006 006 090 to form both rollers of the roller press as a loose roller, these two loose rollers being connected to one another via the bearings and the bearing housings and via hydraulic drives. The rollers, the bearings, the bearing housings and the hydraulic drives form a closed force system, which relieves the machine frame and thus can be dimensioned to a lesser extent. This arrangement has proven itself in practice.

Nevertheless, it would be desirable if the sizing of the machine frame could be further reduced to reduce not only production costs but also ongoing operation and maintenance.

The object of the invention is therefore to change the roller press so that the dimensions of the necessary dimensioning of the machine frame can be further reduced.

The object of the invention is achieved by a roller press with the features according to claim 1. Further advantageous embodiments of the invention are specified in the Unteransprϋchen.

According to the invention it is proposed to make a roller press with two Loswalzen so that the two Loswalzen are connected to each other via a gear. The gear transmits the horizontal balancing movement of one roller to the other roller so that both rollers face the roller gap with a symmetrical distribution of force. It is possible that both rollers change their hori zontole position in the machine frame, for example, to allow unwanted larger particles to pass through the gap or, to move particles that are inaccessible to pressure reduction through the nip. Both rollers move through the inventive compound of the bearing housing symmetrically about a common center axis, which lies in the nip.

Due to the axisymmetric movement of both rollers, the nip opens, in which both rollers evenly apart from each other axially parallel to each other from the central axis in the nip and the rollers move after the passage of a large or non-comminuted particle again axially parallel to each other.

The symmetrical movement has the advantage that - in contrast to a Loswalzenanordnung without the axisymmetric force distribution - both rollers, which are housed between the bearing housings and the machine frame in the machine frame, with a necessary movement apart for the passage of the above-mentioned unwanted particles evenly and with half each Speed compared to the speed of the roller movement of only one movable Loswalze be driven apart. In a Loswalzenanordnung without symmetrical gear usually moves a roller to the side and another Loswalze remains in place.

Due to the fact that in a roller press without the gear mechanism according to the invention, a roller has to move to the side by the full amount of the width of the particle passing through the roller gap, the duration of the passage being predetermined by the rotational frequency of the rollers, the moving roller exerts its inertia high forces on the entire force system in the roller press. The high and inertial forces wear the bearings and exert wear on the entire system.

Due to the symmetrical movement of the rolls according to the invention, the acceleration of the rolls is only half as high as in the case not coupled by a gearbox, because both rolls are locked by the gear coupling. be driven apart evenly and thus move away evenly and symmetrically from each other. This halves the path of the rollers in the same period of the passage of particles through which the acceleration of the rollers is also halved. Due to the reduced acceleration, the inertia forces also act to a lesser extent, whereby the components of the roller press can be dimensioned smaller, resulting in lower costs in production, but also in operation and maintenance.

To center the symmetrical and positive connection, it may be advantageous to frictionally connect the transmission itself to the machine frame. Although this makes the machine frame part of the force system of the contact force in the nip, but the machine frame then only serve as an abutment for the forces caused by the different friction of the two roller systems. In the worst case, the machine frame must absorb the forces necessary to overcome the static friction of a roller. However, these forces are far lower for a properly maintained roller press than the high forces to maintain pressure in the nip. Namely, this force is generated and absorbed by the pressing system, which presses the two Loswalzen together to build up the pressure for pressure treatment.

In an embodiment of the invention it is provided that the Loswalzen are connected to each other via a linkage in the form of a push rod transmission or via a lever mechanism. In the simplest case, the two rollers are connected to each other via a scissors joint, wherein the actual joint may be fixed to the machine frame or may be floating. This means that the scissors link is connected to the bearing housings exclusively via its scissor arms.

If the two bearing housings are connected to one another on one side of the rollers via a push rod transmission, it is advantageous if the force for the axisymmetric force distribution via a torsion Rod is distributed between the two rollers. For this purpose, it is provided that a bearing housing is connected to a lever which translates the lever action into a torsion via a gearbox fixed to the machine frame. This torsion is transmitted via the torsion bar to a second corresponding gearbox, where the torsion is again translated from a torsion into a leverage. The second bearing of the torsion bar transmission is firmly connected to the machine frame. Moves in this arrangement, a bearing housing for a roller to the outside, the lever is rotated by this bearing housing to its bearing point and this rotation is translated into a twist. At the other end corresponding to the torsion is used for the generation of the leverage force by which the other bearing housing for the second roller in the reverse direction, namely also outwardly moved. The push rod transmission is designed so that the movement of both rollers is axially parallel and axisymmetric. This means that when one roller moves away from the center of the roller, the other roller also moves away from the roller center. If, on the other hand, one roller moves toward the imaginary central axis, then the other roller likewise moves towards the imaginary center line.

In addition to the lever mechanism and the push rod transmission with torsion shaft, it is also possible to transmit the power via a hydraulic system. For this purpose, a first bearing housing can be connected via a first hydraulic cylinder to the machine frame, wherein the first hydraulic cylinder has two working spaces. The two working chambers of the first hydraulic cylinder are cross-connected via a hydraulic line with the two working spaces of an opposite second hydraulic cylinder, which is constructed and arranged corresponding to the first hydraulic cylinder. Due to the crossed connection of the work spaces with each other, the symmetrical movement of both rolls is achieved, in which both rollers move under the action of force in the nip evenly outwards and inwards. By the push rod transmission, the lever mechanism and the hydraulic transmission, the structure of the roller press according to the invention can be kept compact. When using a scissors gear can be achieved depending on the number of scissors and a compact design, but this makes a higher number of bearings for the scissors necessary, which can lead to higher production costs and higher vulnerability.

The invention will be explained in more detail with reference to the following figures.

It shows

Fig. 1 is a schematic side view of a roller press according to the invention in a first embodiment with push / torsion bar gear

Fig. 2 is a schematic side view of a roller press according to the invention in a second embodiment with scissors gear

FIG. 1 shows a schematic view of a first embodiment of the roller press 10 according to the invention, which has two rollers 11 and 12. The two rollers 1 1 and 12 are interconnected via Anpresssysteme 13 and 14 and the Anpresssysteme 13, 14 pull the rollers 1 1 and 12 together, so that in the nip 15, a pressure for the pressure treatment is maintained. The rollers 1 1 and 12 each have a shaft 20 and 21, which are received in each case by a bearing not shown here in the corresponding bearing housings 22 and 23. In order to press the rollers 1 1 and 12 together, the contact pressure systems 13 and 14 engage the bearing housings 22 and 23. In addition to the Anpresssystemen 13 and 14 also engages a push rod and torsion bar gear on the bearing housings 22 and 23, in which a push rod 31 is connected to a first bearing housing 20 and a second push rod 32 with a second bearing housing 32. The push rods 31 and 32 are each with an angle lever 33 and 34 which are rotated about the pivot points A and B by the push rods 31 and 32. The rotation about the point A is transmitted to the torsion shaft 40 through the connecting rods 35 and 36. The torsion shaft 40 rotates about its own axis in the bearings C and C. The angle levers 33 and 34 are connected to the connecting rods 35 and 36, that the rotation of the torsion shaft 40 leads to a symmetrical movement of the two rollers 1 1 and 12 , Due to the symmetrical movement of the two rollers 1 1 and 12 opens and closes the nip 15 by a respective rotation of the torsion shaft 40 in one or the other direction.

In Figure 2, a second embodiment of the roller press 2 according to the invention is shown, which contains the same elements as the roller press 10 in Figure 1. Instead of the push rod and Torsionsstangengetriebes provided in this embodiment that a scissors gear 50 connects the two bearing housing together , By the scissors gear 50 a similar effect is achieved as by the transmission in Figure 1. In order to improve the effect of the transmission on a uniform symmetrical movement of both rollers 1 1 and 12, it is provided that the central joints of the scissors gear 50 in a vertical longitudinal slot , which is connected to the machine frame, are included, so that these longitudinal slots can absorb the radial force components, which are caused by friction.

LIST OF REFERENCE NUMBERS

Roller press 31 Push rod Roller 32 Push rod Roller 33 Angle lever Pressing system 34 Angle lever Pressing system 35 Connecting rod Rolling gap Shaft Shaft 36 Connecting rod Bearing housing 40 Torsion shaft Bearing housing 50 Scissor mechanism

Claims

claims

1. Roll press (10) for pressure treatment or for compacting granular material comprising

two in each case via a shaft (20, 21) rotatably mounted in a machine frame and driven in opposite directions, separated by a roller gap Loswalzen (1 1, 12),

the shafts (21, 22) of the loose rollers (11, 12) being accommodated in bearing housings (22, 23) movably arranged in the machine frame,

characterized in that

the bearing housing (22, 23) of the two Loswalzen () 1 1, 12) via at least one gear (30, 50) for the axisymmetric force distribution of a roller centering arrangement (13, 14) are movably connected to each other.

2. Roller press according to claim 1,

characterized in that

the at least one transmission (30, 50) is a lever or push rod transmission or a scissors gear.

3. Roller press according to claim 2,

characterized in that

in each case a bearing housing (22, 23) of a roll side with the corresponding bearing housing (22, 23) of the second Loswalze (1 1, 12) of the same side via angle lever (33, 34) is connected, in turn via a torsion bar (40) non-positively connected to each other.

4. Roller press according to claim 1,

characterized in that

the at least one transmission (30, 50) is a hydraulic transmission.

5. Roller press according to claim 4,

characterized in that

each one bearing housing (22, 23) of a roll side with the corresponding bearing housing (22, 23) of the second Loswalze (1 1, 12) of the same side is connected to each other via at least one hydraulic cylinder in the hydraulic frictional connection.

6. Roller press according to one of claims 1 to 5

characterized in that the at least one gear (30, 50) is fixedly connected to the machine frame.