EP3597300A1 - Rolling packets for milling devices, milling devices and method - Google Patents

Abstract

Disclosed are roller packages (10) for grinding devices (70), comprising a first roller (11), which is held by at least one first bearing body (13), and a second roller (12), which is held by at least one second bearing body (14) becomes. A first aspect provides that the first bearing body (13) and the second bearing body (14) are prestressed against one another and have stop bodies (17, 19) with stop surfaces (18, 20), the contact of which comes into contact with the rollers (11, 12 ) counteracts. The rotational position of the first stop body (17) determines the minimum width of the grinding gap. Also disclosed are grinding devices (70), methods for operating a roller package (10) and methods for determining the radial force acting between the rollers (11, 12) of a roller package (10).

Description

The present invention is concerned with roller packs for grinding devices, with grinding devices and with methods for determining the radial force acting between the rolls of a roll packet.

Various types of grinding devices are used for a large number of industrial applications, with which particulate ground material is ground. These include, for example, mill rollers, malt grist mills, feed mills and coffee grinders. Such grinding devices contain one or more roll packs, each with at least two rolls. The rollers can be held by a respective bearing body. A grinding gap is formed between the rollers and can be adjusted in many roller packages, for example in that the bearing bodies are adjustable relative to one another.

The known roller packs are constructed essentially on the same principle: the width of the grinding gap is reduced by moving the movably mounted roller to an operating gap by means of a mechanical, pneumatic or electromechanical drive; H. "indented". The operating gap can then be adjusted further during operation, for example manually or by motor.

In the documents DE 595 934 and DE 597 775 devices for controlling the contact pressure of grinding rollers are disclosed. These devices contain adjustable suspensions, which allow the grinding rollers to avoid the passage of hard foreign bodies.

Roll packages have a certain stiffness, which can be characterized by the dependence of the radial force acting between the rolls and the width of the grinding gap. This stiffness is made up of the stiffness of the rollers, the roller bearings and the remaining components of the roller package. In the engaged state, the positions of the rollers are therefore dependent on the forces prevailing in the grinding gap. Mainly the radial forces widen the grinding gap. As long as the forces are constant, this can be corrected during operation and then has no negative influence.

For regrind that is difficult to pull in between the rollers, the forces in the grinding gap are very variable. If the ground material passes the grinding gap, the rollers are pressed apart. If no regrind is drawn in briefly, the rollers touch. In such a situation, the gap stiffness has a major influence on the behavior and properties of the regrind.

It is a first object of the invention to overcome the disadvantages of the known roll packages. In particular, roll packages are to be provided in which the width of the grinding gap remains as constant as possible in order to be able to produce regrind with properties that are as homogeneous as possible.

These and further objects are achieved in a first aspect of the invention by a roller package for a grinding device, which contains a first roller, which is held by at least one first bearing body, and a second roller, which is held by at least a second bearing body. The first bearing body and the second bearing body are adjustable relative to one another in such a way that a grinding gap formed between the first roller and the second roller is adjustable. For example, the second bearing body can be pivotally supported on the first bearing body. The first bearing body and the second bearing body can be preloaded against one another by means of a tensioning device such that the first roller and the second roller to be pressed towards each other.

According to the invention, it is provided that the first bearing body has at least one first stop body with a first stop surface and the second bearing body has at least one second stop body with a second stop surface, the stop surfaces being designed and arranged or arranged on the bearing bodies such that contact of the stop surfaces counteracts contact of the rollers. Counteracting here and below does not necessarily mean that contact of the rollers is completely prevented; Such a contact is also permitted within the scope of the present invention with very small predetermined grinding gap widths.

Furthermore, the first stop body is rotatable about a first axis of rotation. The first stop surface is formed by a peripheral surface of the first stop body that is eccentric with respect to the first axis of rotation, in such a way that the rotational position of the first stop body determines the minimum width of the grinding gap. The peripheral surface of the first stop body is referred to here and below as eccentric if it is not rotationally symmetrical with respect to the first axis of rotation, i.e. if it is rotated by at least an angle greater than 0 ° and less than by rotating the first stop body about the first axis of rotation Is 360 °, is not transformed into itself.

If the force prevailing in the grinding gap varies in the case of a roller package according to the invention, only the pretensioning force between the bearing bodies changes, but not their relative position. The only flexibility regarding the grinding gap results from the rollers and bearings. By turning the first stop body, the properties of the ground material can be precisely adjusted, such as starch damage, water absorption and, above all, the particle size distribution of flour (especially if the gap occupancy and thus the splitting force varies due to a fluctuation in the mass flow fed to the grinding device).

In order to prevent the stop bodies from coming out of contact and thus the width of the grinding gap from becoming too large, the prestressing force prevailing between the stop bodies from the tensioning device should be greater than the maximum expected force between the stop bodies, which results from the forces prevailing in the grinding gap.

The tensioning device can be part of the roll package. However, it is preferred if the clamping device is part of a machine stand of the grinding device and the roller package has a coupling device for detachable coupling to the clamping device. This facilitates the assembly and disassembly of the roller package. By means of this coupling, the clamping device of the machine stand can effect the preloading of the bearing bodies of the roll package. The coupling device can be arranged on one of the bearing bodies.

The peripheral surface of the first stop body can be cylindrical with respect to the first axis of rotation. In the circumferential direction with respect to the first axis of rotation, the circumferential surface can have the shape of a spiral, for example at least in sections. A spiral is understood to mean that the distance of the peripheral surface from the first axis of rotation becomes larger or smaller depending on the angle. The spiral is preferably an Archimedean spiral in which the distance depends linearly on the angle.

It is advantageous if the second stop body can be rotated about a second axis of rotation parallel to the first axis of rotation and the second stop surface by means of one with respect to the second Axis of rotation rotationally symmetrical peripheral surface of the second stop body is formed. Because when the first stop body is rotated to adjust the width of the grinding gap, the peripheral surfaces of the two stop bodies can roll against each other, which results in a significantly lower friction and consequently the adjustment is facilitated. This is important in the context of the present invention, since the stop bodies are preferably pressed against one another with a high prestress.

Furthermore, it is expedient if the first axis of rotation of the first stop body and / or the second axis of rotation of the second stop body is arranged to be displaceable, in particular in a direction perpendicular to the first axis of rotation. While rotating the first stop body causes a fine adjustment of the grinding gap, a rough adjustment of the grinding gap can be achieved by moving at least one of the stop bodies.

The fine adjustment is further facilitated if the roller package has a handwheel which can be rotated about a handwheel axis of rotation and which is coupled to the first stop body via a handwheel gear such that turning the handwheel causes the first stop body to turn. In a manner known per se, a gear can be selected such that a comparatively small torque on the handwheel is translated into a large torque on the first stop body. The handwheel gear should preferably have the highest possible efficiency. A small gear backlash is also advantageous in order to enable the position indicator on the handwheel to be as accurate as possible and the position of the first stop body to be as precise as possible. All this is important in the context of the present invention, since the stop bodies are preferably pressed against one another with a high prestress. In addition, it is preferred if the handwheel transmission has a plurality of transmission inputs, in particular a first transmission input for the Handwheel and a second gear input for motor adjustment.

The invention also includes a method for operating a roll package as described above. The method includes a step in which the first bearing body and the second bearing body are preloaded against one another by means of the tensioning device in such a way that the first roller and the second roller are pressed towards one another.

In order to set the minimum width of the grinding gap, the method can include a further step in which the first stop body is rotated about a first axis of rotation in order to set the minimum width of the grinding gap.

Furthermore, it makes sense if the roller package has a force measuring device that contains a first sensor for determining a first force with which the first bearing body and the second bearing body are preloaded against one another, and a second sensor for determining a second force that lies between the acts first stop body and the second stop body. One or both sensors can be force sensors for the direct determination of the forces. Alternatively, however, at least one of the two sensors can also be designed for indirect determination of the forces, for example as a pressure sensor with which a pressure prevailing in a cylinder (in particular in a bellows cylinder explained below) can be determined, from which the associated force can then be determined can. The force acting between the rollers can be calculated from the two forces determined directly or indirectly by the sensors.

The first sensor can be integrated in the tensioning device, for example. The second sensor can, for example, be arranged on the second stop body.

The invention also includes a method for determining the radial force acting between the rollers of such a roller package. The method includes a step in which the force acting between the rollers is calculated from the forces determined by the sensors.

In order to indicate the position of a handwheel as already mentioned above in the simplest possible way (without electronic elements such as gap sensors or encoders), position indicators are used in the prior art. If the operating gap is set as desired, the position of the handwheel is referenced by turning the position indicator. This means that if the grinding gap needs to be adjusted, the basic state can be easily found. The position indicator is picked up in the handwheel and, in the state of the art, clamped by a radial adjusting screw and thus secured against twisting or slipping out. Another variant is axial clamping to the rear. However, the vibrations that occur during grinding operation can significantly impair the position display.

Oil-filled position indicators are more robust in this regard; however, the clamping of the position indicator is even more critical: too weakly tensioned, the position indicator loosens, too tightly it can break. Attempts have already been made to solve this problem with special screws. However, such a special screw can be lost. If it is replaced by an ordinary screw, it can leak. Another disadvantage is that a tool is required for referencing and that the screws are small and often difficult to access.

Another object of the present invention is to overcome these drawbacks and in particular to provide a roll package with a position indicator which corresponds to that during grinding can withstand vibrations and can be easily adjusted.

To achieve this object, the second aspect of the invention proposes a roller package for a grinding device, which contains a first roller and a second roller and a handwheel that can be rotated about a handwheel axis of rotation, by means of which a grinding gap formed between the first roller and the second roller can be set. For example, it can be a roll package as described above. According to the invention, it is provided that the roller package has a position indicator for indicating a position of the handwheel and the position indicator contains a position indicator housing and a display element which is movable along the handwheel axis of rotation relative to the position indicator housing and which is biased or pretensionable against the position indicator housing in the direction of the handwheel axis of rotation. that it is secured against rotation about the handwheel axis of rotation by contact with the position indicator housing in a holding position and can only be rotated about the handwheel axis of rotation if the preload caused by the position indicator spring is overcome.

To be able to turn the display element when referencing, it only has to be pressed by hand against the pretension and can then be turned. This eliminates the screws and tools mentioned above. In addition, the disruptive effects of vibrations during grinding can be effectively prevented.

In one possible embodiment, the display element and the position display housing have contact surfaces which allow a form fit in the holding position. In this way, the disruptive influences of vibrations during grinding operation can be suppressed particularly effectively. alternative or in addition to the positive connection, there may also be a frictional connection in the holding position.

For example, for revision purposes, it is sometimes necessary to replace one or more rollers of a grinding device. For this purpose, the roller package can have an integrated roller device with at least one roller, which is arranged or can be arranged on the roller package in such a way that the roller package with the at least one roller can be placed on and moved on a horizontal base.

The storage of the rollers in rolling bearings of the bearing bodies requires the use of lubricants, the uncontrolled escape of which should be prevented. There are sealing systems that are robust against over-lubrication or against rough installation conditions, but which cannot completely prevent the lubricants from escaping.

In order to enable the lubricants to escape in a controlled manner, a bearing cover of the roller bearing supporting the roller stub can have on its inside a guide groove for lubricants that runs around the roller stub and is connected to an outlet opening through which lubricant can escape from the guide groove. A collecting device for collecting the lubricant, for example a collecting container, can be arranged below the outlet opening. The targeted collection of the leaked lubricant allows a robust seal structure that is inexpensive and easy to install, does not pose a risk of over-lubrication and at the same time enables the grinding device to be operated hygienically.

In order to achieve homogeneous grinding over the entire length of the rolls, the rolls are often cambered. If it is still not possible to achieve uniform grinding work over the entire length of the roller, the crowning can be adjusted. By setting the rollers, i.e. tilting the roller axes, In addition to the gap adjustment, there is a manipulated variable in order to influence the grinding over the roll length and to achieve a more uniform grinding. For this purpose it can be provided that the first roller is held by two first bearing bodies, the second roller is held by two second bearing bodies and the first bearing bodies are adjustable independently of one another and / or the second bearing bodies are adjustable independently of one another.

In one possible embodiment, this can be achieved in that the second bearing body is pivotally supported on the first bearing body via a pivot pin and the pivot pin is adjustable relative to the first bearing body, for example in the vertical direction. This can be accomplished, for example, in that the first bearing body has a wedge which is designed and arranged such that a displacement of the wedge in a first direction relative to the first bearing body causes a displacement of the pivot pin in a second direction different from the first direction relative to the causes first bearing body. Alternatively, the second bearing body can also be adjustable relative to the first bearing body with the aid of an eccentric.

The roller packages according to the invention are particularly advantageous in connection with one as in the international patent application PCT / EP2018 / 061793 Disclosed transmissions, the disclosure of which regarding this transmission is incorporated by reference into the present application. In particular, the present invention thus encompasses the fact that the roller package further contains a transmission which comprises a bearing housing in which an input shaft, a first output shaft and a second output shaft are accommodated, the input shaft and the first output shaft are perpendicular to one another and the first output shaft and the second output shaft are arranged parallel to one another, the input shaft and the first output shaft are operatively connected to one another via a bevel gear pair, the first output shaft and the second output shaft are operatively connected to one another via a torque transmission arrangement, the first output shaft is coupled to the first roller and the second output shaft is coupled to the second roller.

Another aspect of the invention is a grinding device, for example a milling roller mill, a malt grist mill, a feed mill or a coffee grinder. The grinding device contains a machine stand and at least one roll package as described above, which is designed according to one of the preceding claims and is inserted or can be used in the machine stand. This results in the advantages already explained above for the roller package for the grinding device.

As has already been explained above, it is expedient if the machine stand has a tensioning device and the roller package has a coupling device for releasable coupling to the tensioning device. This facilitates the assembly and disassembly of the roller package.

To generate the preload, the tensioning device can have a cylinder, which is preferably designed as a bellows cylinder. It is particularly preferred if the bellows cylinder is coupled to a vent valve. In the event of an overload (for example when a foreign body penetrates into the grinding gap), this can be relieved by reducing the pressure prevailing in the bellows cylinder by opening the ventilation valve. The vent valve should be dimensioned accordingly for quick relief.

In order to enlarge the widening of the grinding gap in the event of an overload, the tensioning device can furthermore have at least one prestressed spring, which is connected in series with the cylinder in particular. The pretensioned spring can be, for example, a disk spring assembly known per se.

The tensioning device can contain a tie rod, a tie bush pivotally mounted on a first end of the tie rod, a tie rod partially received in the tie bush and pretensioned by means of a spring, and the cylinder which is coupled to a second end of the tie rod. The pull rod can be coupled to a coupling device of the roller package arranged on the second bearing body. In the assembled state of the roller package, the tie rod can be supported in a support point on the bearing body located between its ends. By activating the cylinder, the second end of the tie rod can be pressed against and supported on the first bearing body, as a result of which the total torque acting on the roller package can be reduced. The tie rod can be swiveled around the support point and thus pull the pull bushing and the pull rod. In this way, the first bearing body and the second bearing body can be preloaded against one another in such a way that the first roller and the second roller are pressed towards one another.

It has already been mentioned that, for example for revision purposes, one or more rollers of a grinding device have to be replaced. The rollers can be removed one after the other, or the entire package can be removed. The rollers can be held on the grinding surfaces, on the bearing bodies or on the roller stubs. In the first variant, it is lifted by hydraulic lifting tables and then rolled out. When mounting on the bearing bodies, rollers are first mounted, and then the roller package is raised by lowering the rollers and then rolled out on the rollers. To hang them on the roller stubs, they can be lifted with chain hoists and the chain hoists can then be moved in rails. A horizontal mounting on the roller stubs is also possible by attaching rollers to them and moving them in rails. The document EP 1 201 308 A1 disclosed furthermore a roller package with integrated rollers, which can be put down by means of an eccentric, in order to be able to lift the roller package.

However, all of these methods have disadvantages. For example, in order to roll it out in a preparatory step, the rolls first have to be mounted or at least adjusted. In addition, the lifting of the roller package is in accordance with EP 1 201 308 A1 quite difficult.

In a further aspect of the invention, these disadvantages are eliminated by a grinding device, in particular a milling roller mill, which contains a machine stand and at least one roll package with a first roll and a second roll, which is inserted or can be used in the machine stand. In particular, the roller package can be one as described above. The roller package has an integrated roller device with at least one roller, which is arranged or can be arranged on the roller package in such a way that the roller package with the at least one roller can be placed on a horizontal base and moved thereon. Furthermore, the machine stand has at least one rail on which the at least one roller of the roller package can be moved during the assembly and / or disassembly of the roller package. Furthermore, the roll package has at least one contact surface, and the machine stand has at least one counter-contact surface. The contact surface and the counter-contact surface are matched to one another and to the at least one rail in such a way that the at least one roller of the roller package does not rest on the rail in an assembly position of the roller package due to a positive fit between the contact surface and the counter-contact surface.

As a result of this design according to the invention, the package is not raised during dismantling but is lowered onto the rollers. In addition, the rollers of the roller package do not lie on the rail in the assembly position, which protects the rollers.

Figur 1:

ein erfindungsgemässes Walzenpaket in einer ausgerückten Stellung mit einem Teil einer Spanneinrichtung;

Figur 2:

das erfindungsgemässe Walzenpaket in einer eingerückten Stellung mit dem Teil der Spanneinrichtung;

Figur 3a:

einen erfindungsgemässen Müllereiwalzenstuhl mit zwei erfindungsgemässen Walzenpaketen in einer perspektivischen Ansicht;

Figur 3b:

den erfindungsgemässen Müllereiwalzenstuhl in einer Seitenansicht;

Figur 3c:

den erfindungsgemässen Müllereiwalzenstuhl in einer Draufsicht;

Figur 4:

einen erfindungsgemässen Müllereiwalzenstuhl mit einem erfindungsgemässen Walzenpaket in einer Seitenansicht;

Figur 5:

eine Detailansicht eines Handrads und eines Handradgetriebes zur Feineinstellung der Spaltbreite;

Figur 6:

eine Detailansicht einer Positionsanzeige zum Anzeigen einer Position des Handrads;

Figur 7:

eine Detailansicht zweier Kraftsensoren zur Bestimmung der zwischen den Walzen wirkenden Kraft;

Figur 8:

eine Detailansicht des Walzenpakets zur Verstellung der Lagerkörper;

Figur 9:

eine Schnittansicht durch ein Wälzlager des Walzenpakets;

Figur 10:

eine perspektivische Ansicht des Walzenpakets mit einer Auffangwanne für Schmiermittel;

Figur 11:

eine Detailansicht einer Rolleinrichtung des Walzenpakets mit Rollen und Kontaktflächen;

Figur 12:

eine Detailansicht des Maschinenständers mit Schienen und Gegenkontaktflächen.

The invention is explained below using an exemplary embodiment and several drawings. Show

Figure 1:

an inventive roller package in a disengaged position with part of a tensioning device;

Figure 2:

the roller package according to the invention in an engaged position with the part of the tensioning device;

Figure 3a:

a milling roller mill according to the invention with two roller packages according to the invention in a perspective view;

Figure 3b:

the mill roller mill according to the invention in a side view;

Figure 3c:

the mill roller mill according to the invention in a plan view;

Figure 4:

a milling roller mill according to the invention with a roller package according to the invention in a side view;

Figure 5:

a detailed view of a handwheel and a handwheel gear for fine adjustment of the gap width;

Figure 6:

a detailed view of a position indicator for displaying a position of the handwheel;

Figure 7:

a detailed view of two force sensors for determining the force acting between the rollers;

Figure 8:

a detailed view of the roller package for adjusting the bearing body;

Figure 9:

a sectional view through a roller bearing of the roll set;

Figure 10:

a perspective view of the roll package with a drip pan for lubricants;

Figure 11:

a detailed view of a roller device of the roller package with rollers and contact surfaces;

Figure 12:

a detailed view of the machine stand with rails and mating contact surfaces.

The Figures 1 and 2 show a roller package 10 for a milling roller mill in a side view. The roller package 10 contains a first roller 11, which is held by two first bearing bodies 13, and a second roller 12, which is held by two second bearing bodies 14. The second bearing bodies 14 are pivotally supported on the first bearing bodies 13 via pivot bolts 57.

The one in the Figures 3a to 3c Milling roller mill 70 shown has a machine stand 71 and two roller packages 10 arranged one above the other and thus saving space. Each roller package 10 can be driven by means of a gear 43 which comprises a bearing housing 44 in which an input shaft (not recognizable here), a first output shaft 46 and a second one Output shaft 47 are added. The input shaft and the first output shaft 46 are perpendicular to one another and the first output shaft 46 and the second output shaft 47 are arranged parallel to one another. The input shaft and the first output shaft 46 are operatively connected to one another via a bevel gear pair that cannot be seen here, and the first output shaft 46 and the second output shaft 47 are connected via a torque transmission arrangement that is also not visible in active connection with each other. The first output shaft is coupled to the first roller 11, and the second output shaft 47 to the second roller 12. For a detailed description of the gear 43, reference is made to the already mentioned international patent application PCT / EP2018 / 061793 directed. The gear 43 permits the movable mounting of the second roller 12.

The first bearing body 13 also has a first stop body 17 rotatable about a first axis of rotation A1 with a first stop surface 18. This is formed by a peripheral surface 18 of the first stop body 17 which is eccentric with respect to the first axis of rotation A1. The second bearing body 14 has a second stop body 19 which can be rotated about a second axis of rotation A2 parallel to the first axis of rotation A1 and has a second stop surface 20. This is formed by a circumferential surface 20 of the second stop body 19 which is rotationally symmetrical with respect to the second axis of rotation A2. The two stop surfaces 18, 20 are designed and arranged on the bearing bodies 13, 14 in such a way that contact of the stop surfaces 18, 20 counteracts a contact of the rollers 11, 12, as will be explained below.

In Figure 1 a disengaged position of the roller set 10 is shown, in which the stop surfaces 18, 20 are not in contact with one another. The first bearing body 13 and the second bearing body 14 can be adjusted relative to one another by means of a clamping device 16, which is part of the machine stand 71 and is only partially shown here, such that a grinding gap formed between the first roller 11 and the second roller 12 can be adjusted. The tensioning device 16 contains a tie rod 51, a tie bush 55 which is pivotally mounted on an upper end 67 of the tie rod 51 via a joint 54, a tie rod 52 which is partially received in the tie bush 55 and preloaded by means of a plate spring assembly 41, and a bellows cylinder 40 which is connected to a lower one Late 68's Tie rod 51 is coupled and only in Figure 4 is shown. The pull rod 52 is coupled to the second bearing body 14 by a coupling direction 66 arranged on the second bearing body 14. The tie rod 51 is supported in a support point 75 on the first bearing body 13 as long as the roller package 10 is installed.

Figure 4 shows a side view of a milling roller mill 70 with the roller package 10. By activating the bellows cylinder 40, the lower end 68 of the tie rod 51 is pressed against and supported on the first bearing body 13, whereby the total torque acting on the roller package 10 is reduced. The tie rod 51 is pivoted about the support point 75 and thus pulls on the pull bushing 55 and on the pull rod 52 and thus via the coupling device 66 on the second bearing body 14. In this way, the first bearing body 13 and the second bearing body 14 are preloaded against one another in this way, that the first roller 11 and the second roller 12 are pressed towards each other.

The storage over the bellows cylinder 40 causes an overload protection. In order to enable immediate relief in the event of an overload (for example, when a foreign body enters the grinding gap), the bellows cylinder is coupled to a vent valve of sufficient size so that the pressure in the bellows cylinder can be quickly relieved by opening the vent valve. Without opening the vent valve, there would also be an increase in force, which would be much smaller than if only one spring assembly were present.

In the Figure 2 The indented position of the roller package 10 shown is achieved when the stop surfaces 18, 20 come into contact with one another. If the force prevailing in the grinding gap varies, then only the preload force between the bearing bodies 13, 14 changes, but not their relative position. The rotational position of the first stop body 17 determines the minimum width of the grinding gap.

In order to be able to roughly adjust the width of the grinding gap, the first axis of rotation A1 of the first stop body 17 and the second axis of rotation A2 of the second stop body 19 are arranged displaceably, in a direction perpendicular to the axes of rotation A1, A2.

The roller package 10 also has a handwheel 21 which can be rotated about a handwheel axis of rotation H for fine adjustment of the width of the grinding gap. The handwheel 21 is in a Figure 5 Handwheel gear 22 shown coupled to the first stop body 17. It is such that turning the handwheel 21 causes the first stop body 17 to turn. As a result, a comparatively small torque on the handwheel 21 can be translated into a large torque on the first stop body 17. The handwheel gear 22 has a high efficiency and a small gear play for the purposes mentioned above.

The roller package 10 also has a detail in Figure 6 Position indicator 26 shown for displaying a position of the handwheel 21. The position indicator 26 contains a position indicator housing 27 and a display element 28 which is movable along the handwheel rotation axis H relative to the position display housing 27 27 is biased or biased that it can only be rotated about the handwheel axis of rotation H when the preload caused by the position indicator spring 29 is overcome. This is done by positive locking elements 53 on the display element 28 and on the position indicator housing 27.

To determine the radial forces between the rollers 11, 12, the roller package 10 comprises a force measuring device, which contains a first force sensor 24 and a second force sensor 25. The first force sensor 24 is integrated in the tensioning device 16, namely in the region of the joint 54 formed between the tie rod 51 and the tie rod 52; the second force sensor 25 is located on the second stop body 19 (see Figure 7 ). As a result, the first sensor 24 can be used to determine a first force with which the first bearing body 13 and the second bearing body 14 are preloaded against one another, and the second sensor 25 can be used to determine a second force which is between the first stop body 17 and the second Stop body 19 acts. From these forces, the force acting between the rollers 11, 12 can be calculated.

In Figure 8 is shown in detail how the second bearing bodies 14 are pivotally supported on the first bearing bodies 13 via pivot bolts 57. The first bearing bodies 13 each contain a wedge 39 through which an adjusting screw 56 is guided. Turning the adjusting screw 56 causes the wedge 39 to be displaced in a horizontal first direction R1 and thus to move the pivot pin 57 and the second bearing body 14 in a second direction R2 vertical to the first direction R1. In this way, the second bearing bodies 14 are individually adjustable relative to the first bearing bodies 13, which enables the roll axes to be tilted.

The Figures 9 and 10 show in detail a rolling bearing 58 and its seal. A roller stub 33 of the second roller 12 is supported by an inner ring 59, a plurality of rolling elements 60 and an outer ring 61. In the axial direction thereof there are an inner bearing cover 62 and an outer bearing cover 63, which on their inner sides 34 have grooves 64 which surround the roller stub 33 for seals and guide grooves 35 for lubricants, not shown here. Furthermore, paragraphs 65 are present which prevent the lubricant from being thrown away support. The guide groove 35 of the outer bearing cover 63 is connected to an outlet opening 36, through which lubricant can escape from the guide groove 35 of the outer bearing cover 63. Below the outlet opening 36 there is a collecting device 37 for collecting the lubricant, which is designed in the form of a trough 37. There is a connection hole, not shown, between the interior and the guide groove 35 to prevent over-greasing and thus excess grease can escape through this connection hole. As a result, the mill roller mill 70 can be operated hygienically.

How Figure 11 shows, the roller package 10 has an integrated roller device 30 with rollers 31. The rollers 31 are arranged on the roller package 10 such that the roller package 10 with the rollers 31 can be placed on a horizontal base (not shown here) and moved thereon. The machine stand 71 of the mill roller mill 70 points in accordance with Figure 12 Rails 72 on which the rollers 31 of the roller package 10 can be moved during the assembly and / or disassembly of the roller package 10. The roller package 10 also has front contact surfaces 76 (see Figure 8 ) and rear contact surfaces 42, and the machine stand 71 has corresponding counter-contact surfaces 73. The contact surfaces 42, 76 and the counter-contact surface 73 are matched to one another and to the rails 72 in such a way that the rollers 31 in an assembly position of the roller package 10 due to a positive fit between them the contact surface 42, 76 and the counter-contact surface 73 do not rest on the rail 72.

Claims (10)

Roller package (10) for a grinding device (70), comprising a first roller (11) and a second roller (12) and a handwheel (21) rotatable about a handwheel axis of rotation (H), by means of which a handwheel between the first roller (11) and the grinding gap formed in the second roller (12) is adjustable,
characterized in that
the roller package (10) has a position indicator (26) for indicating a position of the handwheel (21) and the position indicator (26) has a position indicator housing (27) and a display element (28) movable along the handwheel axis of rotation (H) relative to the position indicator housing (27) contains, which is biased or can be pretensioned in the direction of the handwheel axis of rotation (H) against the position indicator housing (27) by means of a position indicator spring (29) such that it can only be rotated about the handwheel axis of rotation (H) when the preload caused by the position indicator spring (29) is overcome , Roll package (10) according to claim 1,
The roller package (10) has an integrated roller device (30) with at least one roller (31), which is arranged or can be arranged on the roller package (10) in such a way that the roller package (10) with the at least one roller (31) is aligned on a horizontal one Pad can be placed and moved on it. Roll package (10) according to one of the preceding claims,
wherein at least one of the bearing bodies (13, 14) has a roller bearing (58) which supports a roller stub (33) of one of the rollers (11, 12), a bearing cover (63) of the roller bearing (58) on its inside (34) one the Roller stub (33) has circumferential guide channel (35) for lubricant, which is connected to an outlet opening (36) through which lubricant can exit from the guide channel (35). Roll package (10) according to one of the preceding claims,
the first roller (11) being held by two first bearing bodies (13), the second roller (12) being held by two second bearing bodies (14) and the first bearing bodies (13) being adjustable independently of one another and / or the second bearing bodies ( 14) are independently adjustable. Grinding device (70), in particular milling roller mill (70), comprising a machine stand (71) and at least one roll package (10) according to one of the preceding claims, which is inserted or can be used in the machine stand (71). Grinding device (70) according to claim 5,
wherein the machine stand (71) has a clamping device (16) and the roller package (10) has a coupling device (66), in particular arranged on the second bearing body (14), for releasably coupling the roller package (10) to the clamping device (16). Grinding device (70) according to one of claims 5 and 6,
the tensioning device (16) having a cylinder (40), in particular a bellows cylinder (40). Grinding device (70) according to one of claims 5 to 7,
wherein the tensioning device (16) has at least one prestressed spring (41) connected in particular with the cylinder (40). Method for operating a roller package (10) according to one of claims 1 to 4, comprising a step in which the first bearing body (13) and the second bearing body (14) are biased against each other by means of a tensioning device (16) such that the first roller (11) and the second roller (12) are pressed towards each other. Method according to claim 9,
the method comprising a further step in which the handwheel (21) is rotated, preferably about an axis of rotation of the handwheel (H), and thereby a first stop body (17) coupled to the handwheel (21) via a handwheel gear (22) a first axis of rotation (A1) is rotated in order to set a minimum width of the grinding gap.

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