This application claims the priority, under 35 U.S.C. § 119, of German Patent Application DE 10 2008 005 632.4, filed Jan. 23, 2008; the prior application is herewith incorporated by reference in its entirety.
The invention relates to a printing press having an assembly and a cam mechanism for moving at least one part of the assembly.
In order to produce movements in printing presses, in particular sheet-fed printing presses, positive mechanisms with a non-uniform transmission ratio such as cam mechanisms, coupler mechanisms or combination of those mechanisms are used at many locations. Non-uniform movements in sheet-fed printing presses are, for example, the front lay or front guide movement and the pull-type lay movement, the swinging movement of the pregripper or the closing movements and opening movement of the gripper systems. The positive mechanisms with a non-uniform transmission ratio are usually coupled fixedly to the uniformly running main drive of the machine. Mechanisms of that type meet the high requirements for accuracy of movement and process speed with high reliability. However, the forces and inertial forces which are introduced during the course of the movement excite frequently disruptive vibrations of the assemblies or of the working elements, for example gripper systems. In that case, the magnitude of the vibration amplitudes which occur depends substantially on the transmission function of the mechanism with a non-uniform transmission ratio which is used, in particular on the configuration of the cam disks in the case of cam mechanisms, and on the operating state of the printing press, in particular on the printing speed of the printing press.
However, the advantages of high movement precision and the realization of a high process speed and process reliability of mechanisms with a non-uniform transmission ratio are seen alongside a low flexibility of the movement which is produced. For example, the transmission behavior of a cam mechanism is fixed by the configuration of the cam, in particular on a cam disk. Flexible adaptation of its transmission function to different operating states of the printing press, in particular for the purpose of reducing the vibrations of the system, is not possible at the same time that the drive of the cam disk is rotating.
In general, there is provision in the construction and configuration of cam mechanisms for the VDI Guideline 2143 to be taken into account. In Guideline 2143 (see VDI-EKV: Guideline 2143, Bewegungsgesetze für Kurvengetriebe [Laws of Motion for Cam Mechanisms], Berlin, Cologne: Beuth Verlag 1980), mathematical principles are described for calculating favorable transmission functions of the 0th to 2nd order for cam mechanisms. The cams can have a plurality of movement regions, that is to say a plurality of sections can exist on the cam with transmission functions which are different from one another or transmission functions which are set against one another in pieces. In that case, the transmission function of the 0th order is the functional relationship between the drive angle (in particular, rotational angle of the cam disk, angle φ1) and the output angle or the output path (in particular, rotational angle of a roller lever, angle ψ1) of a cam mechanism. The transmission functions of the 1st and 2nd orders are the corresponding derivations dψ1/dφ1 and d2ψ1/dφ12. According to the Guideline, expressly only configurations of the output movement of a cam mechanism with a constant transmission function of the 2nd order are recommended as being favorable in vibration terms. According to Guideline 2143, the mathematical description of the corresponding transmission function of the 0th order takes place with the use of suitable polynomial functions or trigonometric functions. In high speed cam mechanisms, as are used in printing presses, corresponding laws of motion frequently lead to a great excitation of vibrations of the mechanical system.
A further prevalent method for configuring favorable transmission functions is harmonic synthesis, that is to say the representation of the transmission function of the 0th order of a cam mechanism as the sum of harmonic proportions (sum of sine and cosine functions). Laws of motion of that type are also denoted HS (High Speed) laws of motion in the literature. In that case, the highest frequency of the harmonic proportions of an HS law of motion lies considerably below the resonant frequencies of the driven mechanical system, for example a cam controlled gripper shaft in a printing press. The corresponding resonant frequencies are therefore excited only to a small extent, with the result that vibrations of the driven system can be reduced effectively in many cases. However, HS laws of motion have the disadvantage, as a result of their principle, that no exact resting phases (phases with a stationary output element of the cam mechanism) can be produced in the course of movement of the output element. However, low vibration movements with resting phases are frequently required in printing presses.
A further possibility for producing low vibration movements is the combination of mechanisms with a non-uniform transmission ratio (cam mechanisms and coupler mechanisms, and combinations thereof) with at least one electronic drive.
For example, in the article “Hybride Antriebssysteme zur Erzeugung Veränderlicher Übertragungs-und Führungsbewegungen” [Hybrid Drive Systems for Producing Variable Transmission and Guiding Movements] by M. Berger and J. Matthes (VDI-Berichte No. 1963, pages 631-642 Düsseldorf, VDI-Verlag 2006), hybrid mechanisms are described for producing movements with a temporally variable movement course of the output movement. Whereas the relationship between the drive variable φ (for example, the angular position of a cam disk which rotates uniformly) and the output variable ψ1 (for example, the angular position of a roller lever which works with the cam disk) is fixed in the case of positive mechanisms with a non-uniform transmission ratio, the corresponding function ψ1(φ1) can be varied within limits in that case. The mechanisms which are described are based in each case on flat five link kinematic chains having the degree of freedom 2, in which the output movement is produced by two drive movements which are independent of one another. Accordingly, the mechanisms have a uniformly rotating main drive and an electronically controlled adjusting drive, by way of which it is possible to influence the output movement of the mechanism within limits in a targeted manner. The number of mechanism elements and joints is also increased by way of the mechanism degree of freedom in comparison with mechanisms having a single drive. As a result thereof, firstly the structural complexity increases and additional compliances and bearing plays are likewise produced in some circumstances, which can have a negative influence on the dynamic behavior of the system.
Various publications also describe mechanisms with a non-uniform transmission ratio (cam mechanisms and coupler mechanisms) which are driven by a single, electronically controlled motor. The following can be mentioned by way of example: Braune, R. “Koppelgetriebe mit Servo-Antrieb in schnellen Verarbeitungsmaschinen” [Coupler Mechanisms having a Servodrive in High Speed Processing Machines] in the congress volume for the congress on processing machines and packaging technology, Technical University Dresden 2006, Callesen, M. and Braune, R. “Kombination von gesteuerten Antrieben mit Koppelgetrieben—Nutzungspotentiale und Konzipierungsaspekte” [Combination of Controlled Drives having Coupler Mechanisms—Potential Uses and Design Aspects] in the congress volume for the VDI/VDE congress on electrical/mechanical drive systems in Fulda 2004, Düsseldorf, VDE-Verlag 2004 and Corves, B., Abel, D., Plesken, W., Harmeling, F., Robertz, D. and Maschuw, J. “Methoden zum Entwurf mechatronischer Bewegungssysteme mit ungleichmaäβig übersetzenden Getrieben” [Methods for Designing Mechatronic Movement Systems with Mechanisms having a Non-Uniform Transmission Ratio] in VDI-Berichte No. 1963, pages 557-573, Düsseldorf, VDI-Verlag 2006. Cam mechanisms or coupler mechanisms usually have uniformly rotating drive motors. The desired output movement with a non-uniform movement course is achieved in the case of cam mechanisms by a corresponding configuration of the cam disks and in the case of coupler mechanisms by the positional dependence of their transmission ratio. The above-mentioned publications eliminate the limitation of a constant angular speed of the drive motor and use controlled or regulated motors to drive cam mechanisms or coupler mechanisms. In particular, the drive motor can also be regulated with the aim of minimizing disruptive vibrations. In that case, the drive motor is operated in a closed regulating loop with corresponding expenditure. When configurations of that type are used in printing presses, it is to be taken into consideration, in particular, that a multiplicity of part functions and movements have to run in that case in a coordinated manner with high process reliability. That is achieved in modern printing presses by the use of a single, central main drive for the part functions (for example, front lay movement and pull-type lay movement, pregripper movement, rotary movement of the cylinders, gripper control). If decentralized drive concepts are used (controlled or regulated individual drives of the part functions), the coordinated movement sequence cannot be achieved with the same reliability in every case. Emergency stop situations (possibly in conjunction with a power failure) can be cited as examples in that case, in which the correct control or regulation of the individual drives which are used is ensured only to a limited extent.
In printing presses, piezoelectric actuators are frequently used as actuators in order to realize as low a vibration movement of the drive element or an assembly as possible. In particular, the following publications are to be cited in this context.
German Published, Non-Prosecuted Patent Application DE 103 35 621 A1 describes a general method for actively influencing vibrations in sheet-fed printing presses with the aid of piezoelectric actuators. In that case, the vibrating component, for example a gripper or a gripper shaft, is provided directly with a piezoelectric actuator. Forces which counteract disruptive vibrations can be superimposed onto the system by suitable actuation of the actuator.
German Published, Non-Prosecuted Patent Application DE 200 11 948, German Published, Non-Prosecuted Patent Application DE 196 52 769 A1, corresponding to U.S. Pat. Nos. 6,156,158 and 6,419,794, International Publication No. WO 03/064763 A1, corresponding to U.S. Pat. Nos. 7,017,483 and 7,040,225, and German Published, Non-Prosecuted Patent Application DE 101 07 135 A1 propose the use of active mountings for influencing vibrations. In that case, the bearings of rotors, for example the bearings of the cylinders of a printing press, are provided with actuators. In that way, the bearings can be moved in each case perpendicularly with respect to the rotational axis of the rotor. Vibrations of the rotor, for example bending vibrations of a printing form cylinder, a blanket cylinder and an impression cylinder, or vibrations of the contact forces between cylinders which roll on one another, can be reduced by suitable actuation of the actuators. Those displacements of the bearing points which are required for that purpose are generally small, with the result that piezoelectric actuators are also proposed in those applications.
German Patent DE 199 63 945 C1, corresponding to U.S. Pat. No. 6,938,515, describes the integration of piezoelectric actuators into the rotating cylinders of printing presses. The cylinders can be deformed in a targeted manner with the aid of the actuators. Disruptive deformations which occur during operation as a result of vibrations are compensated for at least partially by suitable actuation of the actuators.
German Published, Non-Prosecuted Patent Application DE 198 31 976 A1, corresponding to U.S. Pat. No. 6,349,935, describes a drive for a pregripper of a sheet-fed printing press. In that case, the cyclical movement of the pregripper is produced by the superimposition of the movement of a cam mechanism and a controlled actuator, in particular for correcting movement errors. In that case, in particular, the use of piezoelectric actuators is also proposed.
In the case of active vibration reduction, forces which counteract the vibrations of the working element are superimposed onto an oscillatory system in a targeted manner with the aid of suitable actuators. Due to their high dynamics, piezoelectric actuators, in particular, can be used in many cases for producing the corresponding force signals. In corresponding technical configurations, the actuator is operated in a closed regulating loop, in which the vibration which is to be counteracted is measured and converted into a corresponding signal for actuating the actuator. In particular, the vibration reducing effect is canceled completely if the actuator is not actuated.
It is accordingly an object of the invention to provide a printing press, which overcomes the hereinafore-mentioned disadvantages of the heretofore-known devices of this general type and which produces a reduced vibration movement of at least one part of an assembly of a printing press.
With the foregoing and other objects in view there is provided, in accordance with the invention, a printing press, in particular a sheet-fed printing press and/or an offset printing press, comprising an assembly and a cam mechanism for moving at least one part of the assembly. The cam mechanism includes a cam having a movement region and a curvature course with points not being constantly differentiable within the movement region.
In this way, a pronounced reduction or up to a complete elimination of disruptive vibrations can be achieved, in particular with points in the curvature course of the cam disk profile, in which the points are not constantly differentiable and are adapted specifically to the resonant vibration behavior of the assembly.
The movement can be non-uniform, in particular. The movement can be periodic and/or cyclical, in particular. The cam mechanism can be positive and/or have a non-uniform transmission ratio. The curvature course can (preferably) be the second derivation or a higher derivation than the second derivation of the cam course. According to the invention, the curvature course can, in particular, be the curvature or the bump. In other words, the curvature course can have points, at which the curvature of the cam, which curvature is expressed as a function, is not constant or not differentiable in the context of infinitesimal calculus or mathematical analysis of the cam. In particular, the position of the points can be coordinated with or adapted to the resonant vibration behavior of the driven assembly. The cam mechanism can be a cam mechanism in the actual meaning of that expression, or can be a cam mechanism which is combined with further mechanism elements, in particular with a coupler mechanism. The cam mechanism can be part of a drive system, in particular of a drive system for an assembly of a printing press. The assembly can be a working element of an apparatus of the printing press or a component of the printing press.
In accordance with another feature of the invention, in the printing press according to the invention, the points or locations which are not constantly differentiable can be bends or jumps in the curvature course of the cam. However, the bends or jumps in the curvature course are equivalent to corresponding bends or jumps in the transmission function of the 2nd order or in the transmission function which is higher than the 2nd order. In other words, the printing press according to the invention includes a cam mechanism with a transmission function which is not constant or is not differentiable of the 2nd order or higher. As an alternative to a cam disk configuration with jumps in the cam curvature, that is to say jumps in the transmission function of the 2nd order of the cam mechanism (which corresponds to the angular acceleration profile of a roller lever), jumps can also be provided in the transmission functions of a higher order with the aim of a targeted vibration excitation of the driven system (excitation of a compensating vibration of a working element). In particular, jumps in the transmission function of the 2nd order of a cam mechanism correspond to jumps in the curvature course of the corresponding cam disk profile. In the case of jumps in the transmission function of the 3rd order (bump function), cam disk profiles are produced with bends in the curvature course. In other words, if jumps in the transmission function of the 3rd order of the cam mechanism (which corresponds to the bump course of a roller lever) are provided, cam disks are produced with bends in the profile curvature.
In accordance with a further preferred feature of the invention, the cam is the peripheral line of a cam disk or a cam disk contour. In other words, the cam is formed on a cam disk, in particular a closed and/or cyclical and/or periodic cam.
The cam mechanism according to the invention can be used in principle to realize any desired non-uniform movements in the printing press according to the invention. The following application fields are expedient, in particular: front lay or front guide drive, pregripper drive, gripper control, integration of actuators into tooth segments of a turning drum.
In accordance with an added feature of the invention, it is particularly advantageous if, in one embodiment of the printing press, the cam mechanism includes an actuator for the temporal displacement of jolts which are induced by the points, in particular bends and jumps, which are not constantly differentiable, to the at least one part of the assembly. The actuator can, in particular, be controlled, electronically controlled or electronically regulated. The cam mechanism and the actuator together can be called a drive system. In particular, the actuator can be a piezoelectric actuator which is connected to a roller lever that is controlled by the cam. The piezoelectric actuator can be integrated into a coupler of the output train or act on a coupler of the output train. Furthermore or as an alternative thereto, there can be provision for the printing press according to the invention to have a control unit, by way of which the actuator can be actuated as a function of the printing speed. For example, the control unit can be the general machine control device.
In these advantageous embodiments, the movement which is produced can be adapted within certain limits to the operating state of the printing press. A considerable reduction in vibrations can be achieved for all printing speeds. The increased structural expenditure is slight.
As an alternative to piezoelectric actuators, electrodynamic actuators can be used, in particular electric motors and linear electric motors. This use according to the invention requires actuators with high dynamics and a high power density with a comparatively small actuator travel. Piezoelectric actuators meet these requirements in a particularly advantageous way.
Some embodiments of the printing press according to the invention can have a main drive, from which a substantial part of the energy for producing all movement forms is tapped and which also defines synchronous running of the machine cycle. In accordance with an additional feature of the invention, the cam mechanism can also be coupled to the main drive of the printing press. As a result, in particular, process reliability for possible failure of the optionally used actuators or their controllers or regulating devices is achieved in an advantageous way. Even if it has a less favorable vibration behavior, the cam mechanism according to the invention remains functional without a risk of collisions.
In accordance with yet another, particularly preferred feature of the invention, those points of the curvature course which are not constantly differentiable lie on the cam in such a way that vibrations of the part of the assembly are reduced or compensated for in resting phases of the movement of the part. The resting phase is defined as a phase or a time interval with a stationary driven part of the assembly, in particular with a stationary output element or output train of the cam mechanism.
In accordance with yet a further, particularly preferred feature of the invention, as an alternative thereto, two points of the curvature course which are not constantly differentiable lie on the cam at a spacing which is passed through during a multiple of half the vibration duration of the assembly when the cam is sensed by way of a cam follower with a relative movement with respect to the cam at the delivery speed of the cam. For the case of even multiples, in comparison with the situation with odd multiples, there is a jolt with inverted amplitude at the second point which is not constantly differentiable, in order to achieve a comparable situation.
In accordance with yet a concomitant, concrete embodiment of the invention, the printing press is a sheet-fed printing press, in particular a multi-color sheet-fed printing press, and the assembly is a front lay or front guide mechanism for bringing sheets into contact with a first printing unit. A simple three link cam mechanism can advantageously be used as a basic mechanism for the front lay mechanism. In this way, flexibility, compliance or yielding is not increased and an additional bearing play is avoided.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in a printing press, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now to the figures of the drawings in detail and first, particularly, to
In comparison with cam mechanisms and coupler mechanisms with conventional configurations, the drive system or cam mechanism of the printing press 10 according to the invention, which is shown in
A movement of a swinging arm 22 is produced by superimposing the output movement of a cam mechanism and the movement of a controlled actuator 18. It is to be noted at this point that in principle all mechanisms having a degree of freedom 2, in particular five link kinematic chains, can be used to produce this movement. In contrast to combinations of cams and coupler mechanisms on the basis of five link kinematic chains, the exemplary embodiment which is shown having an active roller lever 20, in particular the direct integration which is shown in
The fundamental physical principle and further characterizing properties of the corresponding cam disk profiles and of the actuator 18 will be described in greater detail in the following text with reference to the further figures.
First of all, the basic concept of the embodiment and the working principle of the drive system in the printing press according to the invention will be described in greater detail. The drive system, which is proposed herein (
Without actuation of the actuator 18 (actuator stroke constant) and a conventional cam disk configuration, the results would be first of all undesirable vibrations of the mass m in a resting phase 28 of the cam disk 14 (
The complete freedom from vibrations of the mass m in the resting region is achieved first of all at a defined angular velocity dφ1Auslegung/dt of the cam disk 14. That angular velocity can be freely selected during the mechanism configuration. It is a characteristic of the cam disk configuration that, at this delivery angular velocity, in each case at least two jumps in the curvature course of the cam disk 14 take place, offset by an integral multiple of half the transient duration of the driven mechanical system, in this case by a vibration duration T of the driven mechanical system (vibration duration of the single mass vibrator in
If the angular velocity of the cam disk 14 deviates from the delivery speed ω1Auslegung, the vibrations in the resting region of the output movement cannot be eliminated completely. It is an object of the controlled actuator 18 (
A front lay mechanism of an offset printing press according to the invention will be described in the following text with reference to
Starting from a waiting position, which is shown in
The operation without movement of the linear actuators 44 will first of all be described in greater detail for further explanation.
As a result of this principle, the vibration reducing action of the curvature jumps in the cam disk profile is lost at least partially if the printing speed deviates from the delivery speed of 12,000 prints per hour (
The operation with an actuation of the linear actuators 44 will now be discussed in greater detail for the further more detailed explanation of the operation of the drive system according to the invention of the printing press according to the invention.
In principle, the actuated linear actuators 44 in the roller lever 20 perform identical stroke movements. It should be mentioned at this point that in principle the integration of a single actuator would be sufficient to achieve the kinematic function, but two actuators are used in this advantageous embodiment for concrete structural reasons and in order to avoid undesirable deformations of the roller lever 22. Furthermore, according to the invention, a cam disk is used having jumps in the curvature course (at a delivery speed of 12,000 prints per hour). As a result of the linear movement of the linear actuators 44 with corresponding deformation of the roller lever 22 in the solid body joint 46, an additional amount Δψ is added to the rotational angle ψ (
In order to clarify the improvement which has been achieved,
Number | Date | Country | Kind |
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10 2008 005 632.4 | Jan 2008 | DE | national |