EP1454685A2 - Method for forming a workpiece and rolling machine - Google Patents

Abstract

The rolling machine has a control circuit (55) connected to adjustment motors (22,23,32,33) geared to the end bearings (16-19) for the rollers (2,3). The bearings can be moved to alter the separation (w) between the rollers. Angled ridges (20,21,30,31) on the outside of the rollers are used for plastic deformation of workpieces. Each of the profiled rollers has stub shafts engaging with the bearings at each end.

Description

The invention relates to a method for forming a workpiece and a rolling machine that is suitable for performing the method.

For forming workpieces from an initial shape into a desired one Intermediate form (semi-finished, preforming) or final form (finished product, Finished molds) are, among many other processes, also rolling processes known, which are counted among the pressure forming processes. When rolling the workpiece (rolling stock) is placed between two rotating rollers and by applying a forming pressure through the rotating rollers changed in shape. Tool profiles are used in the profile rolling process arranged on the circumference of the rollers, which corresponding to the generation Enable profiles in the workpiece. When rolling flat, the cylindrical ones work or conical outer surfaces of the rollers directly on the workpiece.

With regard to the relative movement of the tools or rollers on the one hand and on the other hand, the workpiece is divided into longitudinal rolls, Cross rolls and cross rolls. The workpiece becomes vertical during longitudinal rolling to the axes of rotation of the rollers in a translatory movement and mostly without rotation through the space between the rollers (roller gap) emotional. The workpiece does not move translationally during cross rolling regarding the rollers or their axes of rotation, but only rotates about its own axis, which is usually a major axis of inertia, in particular the axis of symmetry for a rotationally symmetrical workpiece, is. When combining both types of movement in longitudinal rolling and in Cross rolling is referred to as cross rolling. The rollers are in the Usually at an angle to each other and to the workpiece, which is translational and rotational is moved.

Profile cross rolling machines in which two rolls are arranged on the outer circumference wedge-shaped profile tools around mutually parallel axes of rotation Rotating in the same direction is sometimes referred to as cross wedge rolling. The tools have a wedge-shaped or triangular cross-section Geometry can and along the circumference in its axial Increase dimension in one direction and / or at an angle to the axis of rotation of the Rolls run.

These cross wedge rollers or profile cross rollers allow a variety of forming of workpieces with high precision or dimensional accuracy. As a result the pressure force exerted on the workpiece by the wedge-shaped tools the material distribution in the workpiece during the circulation the rollers are changed by a flow process in the workpiece. The wedge-shaped Tools can have circumferential grooves and other tapering in the rotating workpiece. Due to the axial offset in the circumferential direction or the oblique arrangement of the tool wedges relative to The axis of rotation can, for example, change structures axially to the axis of rotation and tapering in the workpiece. By the increase or decrease in the outside diameter of the tool wedges during the course the axis of rotation can be axial in combination with the oblique arrangement running slopes and continuous transitions between two tapers different diameters can be generated in the workpiece. The Wedge shape of the tools allows the production of fine structures through the Wedge outer edges or outer surfaces. Cross wedge rollers are particularly suitable for the production of elongated, rotationally symmetrical workpieces with constrictions or elevations such as cams or ribs.

The forming pressure force and the forming temperature depend on that Material from which the workpiece is made and the requirements the dimensional accuracy and surface quality after forming. In particular in the case of iron or steel materials, the forming is usually carried out carried out during rolling at elevated temperatures in order to form required formability or flowability of the material to reach. These temperatures, particularly those that occur during forging With a so-called cold forming in the range of room temperature, for semi-hot forming between 550 ° C and 750 ° C and at a so-called hot forming are above 900 ° C.

Cross wedge rolling machines (or: profile cross rolling machines) are known in which the workpieces at the beginning of the rolling process by means of a positioning device, which includes two positioning supports (so-called guidelines), in a starting position between the two rollers, which is usually corresponds to the geometric center or the center of the nip, positioned. The position of the rollers and their distance from each other will be fixed in advance. Now the positioning supports of the positioning device withdrawn so that the workpiece is free between the Rolls turns and kneaded into the desired shape between the tools becomes. After this rolling or kneading process and the corresponding completion the workpiece is the workpiece via a recess in the rotating rolling tool detected and ejected.

From DE 1 477 088 C a cross wedge rolling machine is known for the transverse rolling of rotary bodies or flat workpieces with two work rolls rotating in the same direction of rotation, on the roll surfaces of which wedge tools are interchangeably arranged. The wedge tools each have wedge-shaped or triangular-shaped, increasing from the roller shell to a height end position adapted to the workpiece to be manufactured, roughened by knurling or other means, and wedge-shaped smooth shaped surfaces with the same distance from the roller shell with calibration effect. The wedge tools are designed as deformation segments and only run over a partial circumference of the associated roller surface. The surfaces and tools of the two work rolls facing each other move in opposite or opposite directions on the workpiece.

EP 1 256 399 A1 discloses a cross-rolling machine with two modules operated in parallel, each with two rollers rotating in the same direction of rotation, which have half-shell-shaped tools with radially projecting tool wedges on their circumferential surface, the reshaping of a workpiece only rotating around half the circumference of a pair of rollers requires. All four rollers are driven by only one drive motor via an intermediate gear unit and drive shaft.

The invention is based on the object, a new method for Forming workpieces and a new rolling machine with which this Procedure is feasible to specify.

This object is achieved according to the invention with regard to the method the features of claim 1 and with respect to the rolling machine by the Features of claim 17 solved.

a) Umformen des Werkstücks während einer Umformphase (oder: eines Umformschrittes, eines Umformprozesses) zwischen den Oberflächen oder Werkzeugen wenigstens zweier um jeweils eine Drehachse (oder: Rotationsachse) rotierender Walzen,

b) Steuern, Regeln oder Korrigieren der ermittelten relativen Lage (oder: Relativlage, Relativposition) auf wenigstens eine Soll-Relativlage, insbesondere mit Hilfe wenigstens einer Kontrolleinrichtung und wenigstens eines wenigstens einer der Walzen zugeordneten und von der Kontrolleinrichtung angesteuerten Stellantriebes.

The method according to claim 1 for forming a workpiece comprises the following method steps:

a) shaping the workpiece during a shaping phase (or: a shaping step, a shaping process) between the surfaces or tools of at least two rollers each rotating about an axis of rotation (or: axis of rotation),

b) controlling, regulating or correcting the determined relative position (or: relative position, relative position) to at least one target relative position, in particular with the aid of at least one control device and at least one actuator assigned to at least one of the rollers and controlled by the control device.

a) wenigstens zwei um jeweils eine Drehachse rotierbare oder rotierende, insbesondere mit Werkzeugen bestückbare oder bestückte, Walzen (oder: Arbeitswalzen),

b) wenigstens einen Rotationsantrieb zum Rotieren der Walzen während einer Umformphase zum Umformen eines zwischen den Walzen anordenbaren oder angeordneten Werkstücks,

c) wenigstens einen Stellantrieb zum Einstellen der Position(en) der Drehachse(n) einer der Walzen oder beider Walzen und

d) wenigstens eine mit jedem Stellantrieb verbundene (oder: in Wirkverbindung stehende) Kontrolleinrichtung zum Steuern, Regeln oder Korrigieren der relativen Lage der Drehachsen der Walzen auf eine (konstante oder variable) Soll-Relativlage mittels des oder der Stellantriebe(s).

The rolling machine according to claim 17 is suitable for carrying out a method according to one of the preceding claims and preferably also determined and comprises

a) at least two rollers (or: work rollers) which can be rotated or rotated about an axis of rotation, in particular equipped or equipped with tools,

b) at least one rotary drive for rotating the rolls during a forming phase for forming a workpiece that can be arranged or arranged between the rolls,

c) at least one actuator for setting the position (s) of the axis of rotation (s) of one of the rollers or both rollers and

d) at least one control device connected to each actuator (or: in operative connection) for controlling, regulating or correcting the relative position of the axes of rotation of the rolls to a (constant or variable) desired relative position by means of the actuator (s).

The term "reshaping" means any transformation of the form of a Workpiece understood in a different form, as also described at the beginning, including preforms and preforms. The axes of rotation of the Rolls are defined as geometric or mathematical axes in (Euclidean, three-dimensional) space around which the rollers rotate. Power transmission or mechanical axes are used in this application called waves.

The invention is based on the consideration of an automated or automatic (or: automatic) setting of the relative position of the axes of rotation of the Rolling the rolling machine to perform, generally at least an actuator is used. So it becomes particular according to the invention a control, regulation or correction is carried out, the control, Rule or correction variable the relative position of the axes of rotation of the rollers is.

It does not change the rotational position of the rollers or tools around theirs Axes of rotation, which is decisive for the forming of the workpiece, but the spatial position of the rollers or tools that are caused by the Position of the axes of rotation of the rollers or of a stationary or translational variant Spatial point can be defined. The relative location of the Roller rotation axes also determine the position of the rollers or tools relative to the workpiece at given rotational positions of the rollers.

With a pure control (or: open-loop control in English) the relative position according to a given control curve or algorithm controlled without feedback or determination of the relative location, in general based on preset manipulated variable values as setpoints for the Actuator.

In the case of closed-loop control or correction, this is countered feedback is provided, i.e. the relative position is measured and then by reducing the deviation from the target relative position current relative position always kept as close as possible to the setpoint. So far in this application reference values or target values are mentioned, in addition to a constant, it also includes a variable or a command variable understood that during the control, regulation or correction process tracked or according to a predetermined or predeterminable course can or will be changed.

a) Umformen des Werkstücks während einer Umformphase zwischen den Oberflächen oder Werkzeugen wenigstens zweier um jeweils eine Drehachse rotierender Walzen,

b) Ermitteln (oder: Erfassen, Bestimmen), insbesondere Messen, der relativen Lage der Drehachsen der Walzen zueinander,

c) Vergleich der ermittelten relativen Lage (oder: Ist-Relativposition, Istwert der relativen Lage) mit wenigstens einer vorgegebenen konstanten oder variablen Soll-Relativlage (oder: Sollwert(e) der relativen Lage),

d) Kompensation oder Ausgleich einer außerhalb eines Toleranzbereiches liegenden (oder: unzulässigen) Abweichung (oder: Differenz) der ermittelten relativen Lage von der Soll-Relativlage durch Stellen (oder: Korrigieren, Steuern) der relativen (Ist-)Lage der Drehachsen.

In the embodiment of a regulation or correction, the forming method according to the invention can also be characterized alternatively and independently or dependent (here in claim 2) by the following method steps:

a) reshaping the workpiece during a reshaping phase between the surfaces or tools of at least two rolls rotating about an axis of rotation,

b) determining (or: detecting, determining), in particular measuring, the relative position of the axes of rotation of the rolls to one another,

c) comparison of the determined relative position (or: actual relative position, actual value of the relative position) with at least one predetermined constant or variable target relative position (or: target value (s) of the relative position),

d) Compensation or compensation of a (or: inadmissible) deviation (or: difference) of the determined relative position from the target relative position by setting (or: correcting, controlling) the relative (actual) position of the axes of rotation.

The rolling machine accordingly contains a regulation or correction in an independently claimable variant or also in one claim 26 dependent embodiment in addition to the forming rollers, the rotary drive (s) and the at least one Actuator according to claim 17 also at least one device for Determining the relative position of the axes of rotation of the rollers to one another, in particular during the forming phase, and at least one control device, with the device for determining the relative position of the axes of rotation and is connected to each actuator or is operatively connected for correcting the relative position of the axes of rotation to a target relative position by means of the actuator (s). In particular, the control device compares then the determined values or signals for the relative position the axes of rotation with the target relative position and changes when one is determined inadmissible deviation from the target relative position the relative position of the roll axes via the actuator (s) until the deviation is again within a permissible tolerance range.

Advantageous refinements and developments of the method and Rolling machine result from that of claim 1 and claim 17, respectively dependent claims.

In a first advantageous embodiment, the relative position of the Axes of rotation of the rollers determined during the forming phase, preferably at a given angle of rotation position of at least one of the rollers and / or a predetermined force load on the roller (s) or forming force. In particular, a rotation angle sensor device can then be used Determining the roll rotation angle and / or a force sensor device be provided for determining the forming force.

The correction or adjustment of the relative position of the axes of rotation of the rollers can now in real time or directly during the forming phase, in particular in a continuous or in small time intervals regulation. The target relative position corresponds then the desired roll position during the forming.

However, preferably, especially during the forming phase, certain actual position of the relative position of the roll axes of rotation only after or also before forming and / or after ejecting the workpiece the space between the tools or the rollers and / or in a state of the rollers relieved of forming force to a target relative position corrected. The target relative position is then possibly to a target position in the loaded state or adjusted during the forming phase. It can then a change in the relative position during the forming phase the at least one actuator is omitted.

In a typical forming process, several workpieces are made in succession Forming phases in succession between the rolls or Tools of the rolls formed and after the corresponding forming phases ejected from the space between the rollers or the tools. It is now preferably in every or every nth (with a natural Number n greater than 1) forming phase the relative position of the axes of rotation of the rolls determined and after each or every nth forming phase and / or after ejecting the respective workpiece, the correction of the relative Position of the axes of rotation of the rollers performed.

The rollers are generally rotatable in two storage devices or stored rotating.

It can now be used to correct or adjust the relative position of the rollers to each other in a simple embodiment only the position of the axis of rotation one of the rollers is regulated or controlled to a desired position and the position of the axis of rotation of the other roller (s) remains unchanged or remain stationary to the environment, especially to the ground. Here the lower roller in particular can remain stationary and only the upper roller be adjusted.

However, the positions of the axes of rotation of both rollers are preferably Correction or change of the relative position of their axes of rotation adjustable or changeable and can be regulated or corrected to the corresponding target positions. The rollers can now either independently of each other, i.e. without a coupling of their movement, with their own actuators or dependent from each other, i.e. with a control or mechanical Coupling, adjustable or can be set. But it can also Movements and positions of the axes of rotation of both rollers with each other be coupled that the axes of rotation of both rollers simultaneously, preferably even at the same speed, on a between the Reference position lying on the rollers, preferably the central axis, to or are or can be moved away from it. Such a synchronous Movement can be achieved with independent actuators common control or by mechanical coupling with Transmission (s) can be realized.

In a further advantageous embodiment, the relative position of the axes of rotation of the rollers a distance at one point or at least two distances at different points on the axes of rotation two rollers from each other or one or two distances from each axis of rotation determined to a central axis between the two rollers and this (r) determined distance / distances to correct the relative position of the Axes of rotation used to the target relative position. In particular, everyone can determined distance compared with an associated target distance be and in the event of a deviation from the target distance outside a predetermined Tolerance range are corrected to the target distance. It is but also possible, from the individual distances (or positions) a geometric To determine the relative position of the axes of rotation mathematically and to correct.

The central axis (or: geometric center, central position) for recording the space provided between the rollers or the workpiece Tools can in particular be positioned by a positioning device of the workpiece between the rollers, with the central axis within a movement plane or on a movement axis two mutually movable positioning parts of the positioning device to hold the workpiece between the two positioning parts can. This determination of the roll positions or the roll distance Relative to the workpiece has the advantage of being able to be relatively a reliable reference position to the workpiece is justified, which defines the position of the workpiece. The distances the axes of rotation to the central axis are also clearly related to the distances between the axes of rotation.

The determination of the relative position of the axes of rotation to one another can therefore be carried out in only one dimension or projection onto a coordinate direction (spatial direction) or in two or even three dimensions or coordinate directions respectively.

For measuring the position (s) or the distance (s) of the rotary axes the rolling machine generally comprises a measuring device, which in particular at least one non-contact sensor, in particular an ultrasonic sensor and / or an optical sensor and / or an inductive sensor and / or a magnetic sensor, and / or a touching sensor, for example a cable encoder. In particular can the distances between the storage facilities and the Positioning device can be measured, with the sensors on their outer sides can be attached.

To adjust the relative position of the axes of rotation of the rollers to each other are one of the two storage facilities in an advantageous embodiment or both storage devices of at least one roller over at least an actuator moves.

In a preferred embodiment, the adjustable Roller (s) or their storage device (s) for correction or adjustment the relative position to the target relative position or for setting the position (s) their axis of rotation (s) or the distance between the axes of rotation of the rollers linear (or: rectilinear, translational) moved. A linear, purely translational Movement is easy to implement in terms of drive technology. The direction of movement linear movement or displacement of the roller (s) is preferred essentially perpendicular (or: orthogonal) to the axes of rotation of the rollers. Furthermore, the movement can in particular in a vertical Direction, i.e. parallel to the gravitational force. Another one too Movement type for the rollers can be advantageous, especially with asymmetrical ones thermal or mechanical changes in shape or volume in the rolling machine, for example a rotation or tilting movement or one composed of translational and rotary motion or along a given, non-rectilinear trajectory (or: Movement) of the rotary axes. The movement of the The axes of rotation of the rollers can therefore be with one, two or even three degrees of freedom respectively. To fundamentally both linear movements as well as to allow pivoting movements of the axis of rotation (s) becomes one adjusting axis of rotation preferably in two points of attack outside of Roll moves, which can be in particular in storage facilities of the roller.

The axes of rotation of the rolls are generally at least approximate set parallel position to each other and are usually too Main axes of inertia of the rolls, in particular cylinder or central axes with cylindrical rollers. In an advantageous embodiment, the Rollers and their axes of rotation, seen in the direction of gravity, one above the other or arranged vertically to each other. But it is also a horizontal or inclined arrangement of the rollers and their axes of rotation possible.

In a special development of the method and the rolling machine are the target relative position, target position (s) or target distances of the rotary axes the rollers depending on the material and / or shape (or: geometry) of the workpiece to be formed or of the desired shape or the desired dimensions of the workpiece after forming. In particular, the shape of the current workpiece in front of the Forming phase can be measured. However, the parameters of a Workpiece can be entered in advance using a sample.

A first basic, particularly advantageous application of the invention, which is also referred to below as the compensation mode, is based on the knowledge that during the forming process of a workpiece or a process with several successive forming processes in the Machining multiple work pieces expansions or contractions within the rolling machine, especially in the carrier device of the rolls or even within the rollers and tools themselves. Caused these changes in shape and volume are particularly affected by the Forming forces (mechanical expansion or contraction) and by introducing the relative to hot or hot forming high temperature workpiece and the associated temporal and spatial temperature changes leading to thermal expansion or cause contraction. These changes in shape or Volume in the rolling machine are therefore disturbances of the process and disadvantageously change the optimal or preset for the forming process Relative positions of the rollers or tools to each other.

These are now in the compensation mode, especially during the forming phase occurring, thermal and / or mechanical form or Volume changes in the rollers or their tools or others Areas of a rolling machine comprising the rollers, in particular storage facilities for the rollers and carrier devices for the storage devices, by the correction or regulation provided according to the invention the relative position of the axes of rotation of the rollers to the desired relative position essentially compensated or balanced. According to the invention in other words, to be carried out automatically or automatically Compensation (or: for compensation or correction) of the thermal and mechanical shape or volume changes the relative The position of the rolls or tools in space determined (or: determined), in particular measured, and in an adjustment or correction step adjusted if impermissible or intolerable deviations from a target relative position specified or optimal for the forming process of the axes of rotation occur.

A second basic application, also referred to below as the forming mode is referred to and alternatively or in addition to the compensation mode can be provided based on the idea of control or regulation of the relative position of the axes of rotation of the rollers for adjustment the forming and / or the forming pressure on the workpiece.

In the forming mode, the relative position, the position (s) or the distance or distances of the axes of rotation of the rollers during the or at least one forming phase and / or in a forming force Condition of the rollers to the target relative position or the target position (s) or controlled, regulated or corrected the target distance (s). The target relative position or the target position (s) or the target distance or the target distances during the forming phase according to a generally depending on the angular or rotational position the rollers (position-controlled) or time (time-controlled), Course led that a desired, in particular position-dependent or temporal, course of the desired when the workpiece is formed Forming pressure or the forming of the workpiece adjusted is. In particular, in the forming mode due to the variable roll position with the same at least one tool or the same surfaces of the rollers by setting different courses of the target relative position or target position (s) or the target distance or the target distances different transformations of the same in different forming phases or different workpieces are generated, in particular by reducing the distance of the axes of rotation during at least one Part of the forming phase. For example, the increasing radial Expansion of a wedge tool by reducing the roller gap at least partially replicated or replaced. The default The course of the target relative position can be determined in advance and stored.

In addition, deviations in the tool from a given one can also occur Shape, for example due to dimensional tolerances or wear Adjusting the target relative position of the axes of rotation of the rollers at least approximately be balanced.

The forming process carried out with the method and the rolling machine can be a cold forming process, but is preferably a hot forming process or a hot forming process. For hot and hot forming is the correction of the roller positions according to the invention for Compensation or to compensate for thermal changes in particular advantageous.

The material of the workpiece can contain iron, for example iron itself or a steel, or a non-ferrous metallic Be material, for example aluminum or an aluminum alloy.

In a particularly preferred embodiment, the rolling machine is as Profile cross rolling machine or cross wedge rolling machine, whose basic structure was described at the beginning. In particular point the rollers therefore open and rotate corresponding profile or wedge tools in the same direction to each other, whereby the workpiece is only on its own axis rotates and is not transported translationally by the rollers. The tools on the rollers are wedge-shaped or in particular in cross section triangular and take along the circumference in their radial dimension in one direction and / or run obliquely to the axis of rotation of the associated one Roller.

Of course, the invention is except for transverse rolling processes and machines can also be used in longitudinal rolling processes and machines, for example for stretch rolling.

At least one actuator can now be a hydraulic drive. Preferably however, at least one or each actuator is an electric motor Drive, in particular a spindle drive. The accuracy of the actuating movement the actuator is preferably in the range of a few tenths mm or even a few hundredths of a mm, preferably at least 0.1 mm, and / or a thousandth of the adjustment path or stroke. With that, too the tolerance range for the correction or deviation of the relative position the axes of rotation to the desired relative position selected in this order of magnitude become.

In a development of the rolling machine is a fixed one, not with the Rollers with rotating or non-rotating carrier device (or: roll stand, Roller frame) is provided on which the actuator (s) are mounted or is or are worn.

In one configuration of the rolling machine, there are two for each roller End faces of the roller connectable or connected to the roller and with the roller co-rotating or rotating holding devices provided. The connection of the holding devices to the rollers is preferred detachable to allow changing of tools or rollers or to facilitate. There is also a storage device for each holding device, in which the holding device is rotatably provided. The storage devices with the holding devices stored in them at least a roller are connected to the actuator (s) assigned to this roller is coupled or can be coupled and via the actuator (s) movable for changing the position of the axis of rotation of the associated Roller. In particular, each bearing device is each equipped with an actuator connected and the control device controls the actuators of both Bearing devices of a roller according to the desired movement the axis of rotation of the roller. The carrier device has, in particular, guide areas to guide the storage facilities as they move.

The bearing devices can be guided by plain bearings or roller bearings get supported.

In a preferred embodiment, the rollers form with the associated ones Rotary drives each have a unit that is shared by the actuators is adjustable. When moving a roller through the or the associated Actuator (s) thus remains the relative arrangement or position of the Rotary drive assigned to the roller unchanged or translation-invariant. In particular, are on one of the bearing devices of each roller the non-rotating or rotatable parts of the associated rotary drive attached to the rotation of this roller and the co-rotating or co-rotating Drive parts of the rotary drive on or in the storage facility are rotatably mounted.

In a special constructional configuration, the carrier device comprises four support elements, between two of the four support elements one of the bearing devices of a first of the two rollers and one of the Storage facilities of the second of the two rollers and between the other two of the four support elements the other storage device of the first Roller and the other storage device of the second roller arranged and are preferably movably guided.

The actuators for the rollers are generally facing away from one another Sides of the rollers arranged to be between the rollers and laterally leaving space for the workpieces and other machine parts are.

FIG 1

eine Walzmaschine mit zwei Walzen und einer Kontrolleinrichtung zum Überwachen und Korrigieren des Walzenabstandes in einer Prinzipskizze,

FIG 2

eine Walzmaschine mit zwei Walzen mit zugeordneten unabhängigen Rotationsantrieben zum Rotieren der Walzen und Stellantrieben zum Verstellen der Walzen in einem Längsschnitt,

FIG 3

die Walzmaschine gemäß FIG 2 in einer um 90° nach einer Seite gedrehten Seitenansicht,

FIG 4

die Walzmaschine gemäß FIG 2 in einer um 90° nach der anderen Seite gedrehten Seitenansicht und

FIG 5

die Walzmaschine gemäß FIG 2 bis 4 in einer quer zum Längsschnitt gemäß FIG 2 vorgenommenen Schnittdarstellung

jeweils schematisch dargestellt sind. Einander entsprechende Teile und Größen sind in den FIG 1 bis 5 mit denselben Bezugszeichen versehen.The invention is explained in more detail below on the basis of exemplary embodiments. Reference is made to the drawings in which

FIG. 1

a rolling machine with two rolls and a control device for monitoring and correcting the roll spacing in a schematic diagram,

FIG 2

a rolling machine with two rolls with associated independent rotary drives for rotating the rolls and actuators for adjusting the rolls in a longitudinal section,

FIG 3

2 in a side view rotated by 90 ° to one side,

FIG 4

the rolling machine according to FIG 2 in a side view rotated by 90 ° to the other side and

FIG 5

the rolling machine according to FIG 2 to 4 in a cross-section to the longitudinal section shown in FIG 2

are each shown schematically. Corresponding parts and sizes are given the same reference numerals in FIGS. 1 to 5.

The rolling machine shown in Figures 1 to 5 is a cross wedge roller or Cross wedge rolling machine designed and comprises a first work roll 2, the is rotatable or rotating about an axis of rotation A, and a second work roll 3, which is rotatable or rotating about an axis of rotation B. The The direction of rotation of both work rolls 2 and 3 is illustrated with the arrows shown and the same. The axes of rotation A and B are essentially parallel to each other and perpendicular to the direction indicated by the arrow the gravitational or gravitational force (gravitational force) so that the work rolls 2 and 3 are arranged one above the other. The work rolls have a substantially cylindrical outer surface.

The distance W between the two axes of rotation A and B of the work rolls 2 and 3 is referred to below as the roller spacing. The distance between the cylindrical outer surfaces of the two work rolls 2 and 3 clearly linked to the distance W via the roller diameter. A between the two work rolls 2 and 3 parallel to the axes of rotation A and B running central axis defining the geometric center (or: Middle layer) is marked with M. With symmetrical position of the two axes of rotation A and B to the central axis M is the distance between the two axes of rotation A and B to the central axis M is W / 2.

On the outer surface or outer surface of the work rolls 2 and 3 are each cross-sectionally wedge-shaped tools 20 and 21 or 30 and 31 fastened, especially braced or screwed. In the illustrated embodiments 1 to 5, the tools 20 and 21 are the first Work roll 2 and the tools 30 and 31 of the second work roll 3 each at an angle and at an angle to the respective axis of rotation A and B. arranged, the tools 20 and 21 of the work roll 2 with respect the central axis M axially in the substantially same positions are. In the position of the work rolls 2 and 3 shown in FIG. 2 are the tools 20 and 21 or 30 and 31 on the facing each other Inside closer together than on the outside facing away. Preferably take the tools 20 and 21 and 30 and 31 in the circumferential direction also seen in their cross section, with the increase in cross section for tools 20 and 21 in the same direction of rotation or Orientation is and with the tools 30 and 31 of the second work roll 3 opposite or in the opposite direction to that of the tools 20 and 21 the first work roll 2.

Each of the two work rolls 2 and 3 is now on its two end faces Ends each with a shaft extension in two bearing devices 16 and 17 or 18 and 19 rotatably mounted about the respective axis of rotation A or B.

Distance sensors are arranged on the bearing devices, specifically a first distance sensor 51 for measuring the distance w1 essentially between the bearing device 16 and the central axis M (or also one in Area of the central axis M arranged, not shown in FIG 1 positioning device to position the workpiece), a second distance sensor 52 for measuring the distance w2 essentially between the bearing device 17 and the central axis M, a third distance sensor 53 for Measuring the distance w3 essentially between the bearing device 18 and the central axis M and a fourth distance sensor 54 for measuring of the distance w4 essentially between the bearing device 19 and the central axis M. The distance sensors 51 to 54 can in particular be ultrasonic sensors, optical, magnetic or inductive sensors or others known distance sensors.

The bearing devices 16 to 19 are also each in their position or position adjustable, namely the bearing device 16 from an associated one Actuator 22, the bearing device 17 from an associated actuator 23 the bearing device 18 from an associated actuator 32 and the Bearing device 19 from an associated actuator 33. By adjustment the position (s) of the storage device (s) 16 and / or 17 or 18 and / or 19 is now the axis of rotation A or B of the work roll 2 or 3 in adjusted their position. For example, when adjusting the two storage facilities 16 and 17 of the work roll 2 parallel to each other and perpendicular to the axis of rotation A of this work roll 2 by the same adjustment path in the same axis, the axis of rotation A shifted in parallel. The distances w1 and w2 both increase by the same amount. At the same time Adjustment of the bearing devices 18 and 19 of the other work roll 3 in parallel to each other and perpendicular to the axis of rotation B of this work roll 3 um the same adjustment path in the same direction but opposite to each other to the direction of the adjustment of the bearing devices 16 and 17 the axis of rotation B shifted in parallel, the distances w1 to w4 all around increases the same amount and the distance W between the axes of rotation A and B enlarged. When adjusting only the bearing device 16 of the work roll 2 For example, the distance w1 is increased upwards and the distance w2 is kept essentially the same and thus the axis of rotation A of this work roll 2 rotated or pivoted.

A control device 55 is now provided which, preferably electrical, control lines connected to the actuators 22, 23, 32 and 33 is and via, generally electrical, measuring lines for transmission of the measurement signals or measurement values with the distance sensors 51, 52, 53 and 54 connected is. The control device 55 now holds the axes of rotation A and B. the work rolls 2 and 3 in a predetermined relative position to each other, in particular the parallel position at the predetermined distance W, by measuring the measured distances w1 to w4 with predetermined target distances, which are preferably all equal to a common target distance, compares and adjusts to the target distances or corrects them by actuation of the actuators 22, 23, 32 and / or 34. The control device 55 contains preferably at least one digital microprocessor or signal processor and at least one memory with a stored control or Control algorithm for the processor as well as saved or re-storable Setpoints or command values for control or regulation.

2 to 5 show an embodiment of a rolling machine 1 in different Representations. 2 shows a longitudinal section along a the longitudinal direction of the rolling machine and the direction of gravity Cutting plane. 3 and 4 show side views of the rolling machine on the two front or narrow sides. The section of FIG 5 is in FIG 2, 3 and 4 marked with the arrows V-V.

Each work roll 2 and 3 is between two axially to the respective axis of rotation A and B on the end faces arranged holding devices 12A and 12B or 13A and 13B detachably and can be removed from the holding devices 12A and 12B and 13A and 13B are taken out in their unlocked state are used to replace tools 20 and 21 or 30 and 31 or entire work rolls 2 and 3 with the tools 20 and 21 or 30 and 31. There are in each case about pivot bearings, not specified, in particular Rolling bearings, the holding device 12A in the bearing device 16 and the holding device 12B in the bearing device 17 in each case about the axis of rotation A of the first work roll 2 rotatably and the holding device 13A in of the storage device 18 and the holding device 13B in the storage device 19 each rotatably supported about the axis of rotation B of the second work roll 3.

For rotating work rolls 2 and 3 about their respective axes of rotation A and B are a first rotary drive 42 for the first work roll 2 and a second, independently of the first rotary drive 42 43 is provided for the second work roll 3. Each rotary drive 42 and 43 comprises an associated rotary drive motor 44 or 45 and a - not shown - rotary drive gear 46 or 47, for example one, in particular three-stage gear transmission for transmitting the Torque of the rotary drive motor 44 or 45 on the associated Work roll 2 or 3. It is the axis of rotation C of the output shaft of the rotary drive motor 44 of the first rotary drive 42 and the axis of rotation D the output shaft of the rotary drive motor 45 of the second rotary drive 43 orthogonal to the axes of rotation A and B of the respective work rolls 2 and 3 directed.

The holding devices 12A arranged on the left in FIG. 1 for the upper work roll 2 and 13A for the lower work roll 3 each set as Solid shafts (or hollow shafts) axially to the axes of rotation A or B. the associated storage facilities 16 and 18 on and are not - with shown in more detail - rotary drive gear 46 and 47 of the associated Rotational drives 42 and 43 coupled or engaged. An operation of the Rotary drive motors 44 and 45 thus lead to the transmission of a rotational movement via the rotary drive gear 46 or 47 to the holding device 12A or 13A and thus on the work roll 2 or 3 and the co-rotating second holding device 12B and 13B.

The rotary drive motors 44 and 45 are preferably permanent magnet motors, especially so-called torque motors. The high dynamic or spin and the high torque of the torque motor allows a very dynamic control or regulation of the speed the rotating work rolls 2 and 3 in adaptation to the rolling process. Each of the permanent magnet motors 44 and 45 becomes electronic, in particular controlled by a converter.

The rolling machine 1 further comprises a carrier device (or: a roll stand or frame) 6. The carrier device 6 comprises four column-like Carrier elements 6A to 6D arranged in a rectangular arrangement are and on a common base plate 6E, which is supported on the floor 50 is mounted or fastened. The carrier elements 6A to 6D run in a longitudinal direction vertically or vertically, i.e. parallel to the gravitational force G.

In each of the carrier elements 6A to 6D there is an associated tie rod 7A to 7B arranged vertically in the longitudinal direction of the respective carrier element, which is attached to the bottom of the carrier plate 6E and at the top by means of an associated Lock nut not specified, preferably a hydraulic actuated lock nut, is biased. Thereby, under the hydraulic nut preferably placed a split washer segment when the Hydraulic nut is in the pressurized state, and then by relaxing the hydraulic pressure the nut on the washer segment pressed. As a result, the carrier elements 6A to 6D can be below a certain one Tension is set and stiffened. This leads to stiffening of the roll stand of the rolling machine 1.

The bearing device 16 is via a drive spindle (or: adjusting spindle) 26 adjustable in height from a first actuator 22 arranged above along a vertical, i.e. parallel to the direction of gravity G Axis E and the bearing device 17 is via a drive spindle 27 height-adjustable by a second actuator 23 arranged above along a vertical axis F. The bearing device 18 is via a drive spindle 36 from a third actuator 32 arranged below adjustable in height along the vertical axis E and the bearing device 19 is via a drive spindle 37 from a fourth arranged below Actuator 33 adjustable in height along the vertical axis F.

Each actuator 22, 23, 32, 33 comprises a drive motor 24, 25, 34, 35, the one via a drive shaft 28, 29, 38, 39 and an unspecified Worm gear with high reduction the drive spindle 26, 27, 36, 37 and thus drives the bearing device 16, 17, 18, 19. The maximum adjustment ranges or adjustment strokes of the actuators 22, 23, 32, 33 are typically 50 mm to 150 mm, the adjustment accuracy or adjustment steps are typically in adaptation to the thermal expansion in the Rolling machine a few 1/100 mm. The drive motors 24, 25, 34, 35 can Be geared motors and / or three-phase asynchronous motors or synchronous motors and / or permanent magnet motors (e.g. servo motors) an electronic control and are used for high adjustment accuracy when adjusting only current impulses in the millisecond range.

The two bearing devices 16 and 18 are for their adjustment movement via guides 8B of the carrier element 6B and 8C of the carrier element 6C in or guided vertically on the two support elements 6B and 6C. The two other bearing devices 17 and 19 are correspondingly for their adjustment movement via guides 8A of the carrier element 6A and 8D of the carrier element 6D vertically guided in or on the two carrier elements 6A and 6D.

There are thus work units each consisting of a work roll 2 or 3, two Holding devices 12A and 12B or 13A and 13B, two storage devices 16 and 17 or 18 and 19 and a rotary drive 42 or 43, the actuators attached to each of the two support devices 6 22 and 23 or 32 and 33 are suspended adjustable in height and on top of each other to or away from each other and in or on the carrier device 6 are movable.

By adjusting the storage facilities 16 and 17 - and thus the entire Work unit including the associated work roll 2 - by means of Actuators 22 and 23 in the same direction and by the same amount, in other words at the same time up the same stroke or at the same time the same stroke down, the axis of rotation A of the first work roll 2 moved up or down in parallel. Likewise, by adjusting the storage facilities 18 and 19 and associated work unit Work roll 3 via the actuators 32 and 33 in the same direction and the axis of rotation B of the second work roll 3 in parallel by the same amount moved up or down.

Thus, by means of the actuators 22 and 23 and / or the actuators 32 and 33 the roller distance W between the axes of rotation A and B of the two Work rolls 2 and 3 or the tool distance w can be varied.

A distinction is made between at least three process steps in the operation of the rolling machine or process phases. The three process phases form a work cycle. In a series production for the production of several formed Workpieces are usually several such work cycles in a row carried out.

In a first process phase, the workpiece 10 is between the rollers 2 and 3 positioned. The workpiece 10 is for this purpose according to FIG 3 by means of two Guides or positioning parts 61 and 62 of one shown only in FIG 3 Positioning device 60 in a position on the central axis M between brought the work rolls 2 and 3. The two positioning parts 61 and 62 are movable along a positioning axis P perpendicular to the central axis M, as indicated by the double arrows, especially by means of rollers. The positioning parts 61 and 62 can retract in this way in a long guide that the work roll 2 and / or 3 can be changed, without the positioning parts 61 and 62 having to be dismantled.

In a second process phase, the forming phase, the workpiece 10 captured by the tools of the work rolls 2 and 3 and between the rotating tools of the rollers. In this forming phase The distances w1, w2, w3 and w4 are now used as a measure of the distances between the axes of rotation A and B and the central axis M measured.

In a third process phase, the formed workpiece is removed again removed or ejected from the space between the rollers. It the distances w1 and w2 as well as w3 and w4 are now in particular with a common target distance compared, so that a parallel position the axis of rotation A and B is aimed for. If the deviation is too large The distances w1 to w4 from the target distance become the axes of rotation A and B changed its position in the manner described until the deviation eliminated or within a tolerance range.

Alternatively or additionally, the distances w1, w2, w3 and w4 can also during the forming phase in accordance with a predetermined angular position the roll (s) dependent or changing over time, to influence the forming of the workpiece.

LIST OF REFERENCE NUMBERS

1

rolling machine

2.3

Stripper

6A to 6D

support element

6E

baseplate

7A to 7D

tie rods

8A to 8D

guide

10

workpiece

12A, 12B

holder

13A, 13B

holder

16,17,18,19

Storage facility

20, 21

Tool

22, 23

actuator

24, 25

gearmotor

26, 27

adjusting spindle

28, 29

drive shaft

30, 31

Tool

32, 33

actuator

34, 35

gearmotor

36, 37

adjusting spindle

38, 39

drive shaft

42, 43

rotary drive

44, 45

Rotary drive motor

46, 47

Rotary drive gear

50

ground

51, 52

distance sensor

53, 54

distance sensor

55

control device

60

positioning

61, 62

positioning parts

A, B

axis of rotation

C, D

drive axle

E, F

axis

G

gravitational force

M

central axis

V

adjustment axis

P

positioning

w

tool clearance

w1, w2

distance

w3, w4, W

distance

Claims (29)

Process for forming a workpiece a) in which the workpiece (10) is formed during a forming phase between surfaces or tools by at least two rollers (2, 3) rotating about an axis of rotation and b) in which the relative position of the axes of rotation of the rolls relative to one another is controlled, regulated or corrected to a desired relative position, in particular by means of at least one control device (55) and at least one actuator (22, 23) assigned to at least one of the rolls and controlled by the control device , 32, 33). Method according to claim 1, a) the relative position of the axes of rotation of the rollers to one another is determined, b) the determined relative position of the axes of rotation is compared with the target relative position and it is determined whether there is a deviation of the determined relative position of the axes of rotation from the target relative position lying outside a predetermined tolerance range, c) and, if such a deviation of the determined relative position of the axes of rotation from the desired relative position, which is outside the tolerance range, is determined, the relative position of the axes of rotation of the rollers, in particular by means of the at least one actuator, is changed or corrected such that the deviation is again within the tolerance range. The method of claim 2, wherein the relative position of the axes of rotation of the rolls during the forming phase, especially at a given one Angular position of at least one of the rollers and / or at a given force load on the roller (s). Method according to one or more of the preceding claims, in which a) to control, regulate or correct the relative position of the axes of rotation of the rollers b) at least one position of at least one of the axes of rotation of the rollers b1) is controlled, regulated or corrected to an associated constant or variable target position and / or b2) is determined and compared with an associated constant or variable target position and, if there is a deviation from the target position outside of a predetermined tolerance range, corrected to the target position, c) where, where appropriate, the position (s) of the axis of rotation (s) of the other roller (s) remains unchanged or stationary with respect to the surroundings or is or will be or will be assumed. Method according to one or more of claims 1 to 3, in which a) to control, regulate or correct the relative position of the axes of rotation of the rollers b) at least a distance between the axes of rotation of at least two rollers from one another or the axis of rotation of at least one roller from a predetermined central axis in the space provided between the rollers or tools for receiving the workpiece b1) is controlled, regulated or corrected to an associated constant or variable target distance
and or b2) is determined and compared with an associated constant or variable target distance and, if there is a deviation from the target distance outside of a predetermined tolerance range, the target distance is corrected. Method according to Claim 5, in which the control, regulation or Correction of the relative position of the axes of rotation of the rollers at least in each case two distances between the axes of rotation of two rollers or the axis of rotation of at least one roller to the central axis on the one hand and associated target distances are used on the other hand, wherein these distances preferably in the direction of the respective axis of rotation seen, opposite sides of the rollers, are provided or be determined. A method according to claim 5 or claim 6, wherein the central axis within a movement plane or on a movement axis two mutually movable parts of a positioning device for Position the workpiece or define the axis on which the workpiece is positioned. Method according to one or more of the preceding claims, in which one or each control, regulation or correction of the relative Position of the axes of rotation of the rollers to the target relative position before or after the forming phase and / or after ejecting the workpiece the space between the tools or the rollers and / or in a state in which the rollers are relieved of forming force is carried out. Method according to claim 2 or one or more of the claims dependent on claim 2, in which a) several workpieces are successively formed between the surfaces or tools of the rolls in successive forming phases and after the associated forming phase each workpiece is ejected from the space between the rolls or tools and b) the relative position of the axes of rotation of the rolls is determined in each forming phase or in each forming phase following a predetermined number of forming phases, c) after each shaping phase or a predetermined number of shaping phases and / or after ejection of the respective workpiece, the regulation or correction of the determined relative position of the axes of rotation of the rolls to the desired relative position is carried out. Method according to one or more of the preceding claims, in the thermal, in particular occurring during the forming phase and / or mechanical shape or volume changes in one of the rollers or their tools or other areas Rolling machine comprising rolls, in particular storage facilities for the rollers and carrier devices for the storage devices, by correcting the relative position of the axes of rotation of the rollers in the To be largely compensated. Method according to one or more of the preceding claims, where the relative location, position (s) or distance or the Distances of the axes of rotation of the rollers during or at least a forming phase and / or in a state subject to a forming force the rollers to the target relative position or the target position (s) or controlled, regulated or corrected the target distance (s) will or will, where the target relative position or the target position (s) or the target distance or the target distances during the forming phase according to a predetermined, in particular of the angular position or dependent on the rotational position of at least one roller or dependent on the time-dependent course of one desired course of the desired when forming the workpiece Forming pressure or the forming of the workpiece adjusted is. A method according to claim 11, in which at least one with the same Tool or the same surfaces of the rollers by adjusting different courses of the target relative position or target position (s) or the target distance or the target distances in different Forming phases different forming of the same or different workpieces are generated, in particular by Reducing the distance of the axes of rotation during at least one Part of the forming phase, and / or tool deviations from a predetermined shape by adjusting the target relative position of the Axes of rotation of the rollers are at least approximately compensated. Method according to one or more of the preceding claims, in which the rollers are rotatable in two storage devices or are rotating and to adjust the relative position of the Axes of rotation of the rollers to one another of the two bearing devices or both storage devices of at least one roller over at least an actuator can be moved. Method according to one or more of the preceding claims, in which the axis of rotation (s) of the roller (s) or the bearing device (s) the roller (s) to control, regulate or correct the relative Position on the target relative position at least partially in a predetermined Movement direction is or will be linear, the Direction of movement of the linear movement preferably essentially perpendicular to the axes of rotation of the rollers and / or essentially is or will be directed parallel to gravity, and / or at least is partially rotated or tilted. Method according to one or more of the preceding claims, in which the workpiece is hot formed or hot formed and / or from an iron-containing or a non-iron-containing metallic Material exists. Method according to one or more of the preceding claims, at which the target relative position or the target position (s) or the target distance / Target distances of the axes of rotation of the rollers depending on the Material and / or the shape of the workpiece to be formed or of the desired shape or dimensions of the formed workpiece can be set or selected, preferably the shape of the workpiece before the forming phase is measured and the target relative position, target position (s) or the Target distance (s) is set accordingly. Rolling machine, in particular for performing a method according to one of the preceding claims, with a) at least two rollers which can be rotated or rotated about an axis of rotation, in particular equipped or equipped with tools, b) at least one rotary drive for rotating the rolls about their axes of rotation at least during a forming phase for forming a workpiece that can be arranged or arranged between the rolls, c) at least one actuator for adjusting the position (s) of the axis of rotation (s) of one of the rollers or of both rollers, d) a control device which is operatively connected to each actuator for controlling, regulating or correcting the relative position of the axes of rotation of the rollers to a constant or variable target relative position by means of the actuator (s). Rolling machine according to claim 17 with a positioning device two mutually movable positioning parts for positioning the Workpiece in the area of a predetermined central axis between the two rollers. Rolling machine according to claim 17 or claim 18, wherein each Roller at least one associated actuator is assigned to the independent Setting the positions of the axes of rotation of the rollers, the actuators preferably facing away from one another Sides of the rollers are arranged. Rolling machine according to claim 17 or claim 18, in which the rolls a common actuator is assigned, each one Gear can be coupled or coupled to each of the rollers, the Gearboxes are preferably designed so that the axes of rotation of both Rolling at the same time by the common actuator, preferably also at the same speed, on a reference position lying between the rollers, preferably the Central axis, are movable to or away from this. Rolling machine according to one of claims 17 to 20, the a) for each roller two on the end faces of the roller with the roller, preferably detachable, connectable or connected and co-rotating with the roller or co-rotating holding devices and b) for each holding device comprises a bearing device in which the holding device is rotatably mounted, b) wherein the bearing devices are coupled or can be coupled with the holding devices mounted in them with at least one roller to the actuator (s) associated with this roller and via which the actuator (s) can be moved or are moved in order to change the position of the axis of rotation of the associated roller, wherein each bearing device is preferably connected to an associated actuator. Rolling machine according to one or more of claims 17 to 21, in which the axes of rotation of the rollers essentially in the target relative position are directed parallel to one another and / or essentially, in Seen the direction of gravity, are arranged one above the other and / or are arranged substantially perpendicular to the direction of gravity. Rolling machine according to one or more of claims 17 to 22, at least one actuator has at least one electric actuator motor and one with the actuator motor on the one hand and the associated roller, on the other hand, coupling or coupled power transmission device, which in particular has at least one drive spindle and / or a worm gear for transmitting the Driving force or torque of the actuator motor for moving the rollers. Rolling machine according to one or more of claims 17 to 23 with one that does not co-rotate or does not co-rotate with the roller Carrier device, on or of which the actuator (s) are carried or is or are stored, the carrier device preferably Guide areas for guiding the rollers or the bearing devices in their movement. Rolling machine according to claim 24, in which the carrier device four, in particular includes columnar support elements, wherein between two of the four carrier elements one of the bearing devices of a first one of the two rollers and one of the storage devices of the second of the two rollers and between the other two of the four carrier elements the other storage device of the first roller and the other Bearing device of the second roller arranged and preferably are movably guided, the carrier elements in particular by means of Tie rods and, preferably hydraulic, prestressed nuts are. Rolling machine according to one or more of claims 17 to 25 a) a device for determining the relative position of the axes of rotation of the rolls to one another, in particular during the forming phase, b) the control device being operatively connected to the device for determining the relative position of the axes of rotation and b1) compares the relative position of the axes of rotation determined by this device with the desired relative position, b2) determines whether there is a deviation of the determined relative position of the axes of rotation from the desired relative position, which lies outside a predetermined tolerance range, b3) and, if there is such a deviation of the determined relative position of the axes of rotation from the desired relative position, which lies outside the tolerance range, the relative position of the axes of rotation of the rollers, in particular by means of the at least one actuator, changes such that the deviation again within the tolerance range lies. Rolling machine according to one or more of claims 17 to 26, in which the device for determining the relative position of the axes of rotation the rollers to each other at least two distance sensors Measuring the distances of the axes of rotation of the rollers from each other or each to the central axis or the distances between the storage facilities Central axis or to the positioning device as a measure of the position (s) or the distance between the axes of rotation of the rollers. Rolling machine according to one or more of claims 17 to 27, in which the device for determining the relative position of the axes of rotation the rollers to each other at least one non-contact sensor and / or an ultrasonic sensor and / or an optical sensor and / or an inductive sensor and / or a magnetic Sensor includes. Rolling machine according to one or more of claims 17 to 28, which are designed as profile cross rolling machines or cross wedge rolling machines and / or in which the tools on the rollers in cross section have wedge-shaped or triangular profiles or shapes and along the circumference in their radial dimension in one Increase direction and / or at an angle to the axis of rotation of the associated one Roll run.

Images