DE4143597C2 - Electromotor for driving rotating cylinders of printing machines - Google Patents

Abstract

An arrangement for an electromotor for driving a rotating body, especially a print cylinder of a printing machine, rotatably mounted on a wall. The body is adjustably movable along its axis of rotation and also at an angle to it and diagonally to it. The rotating body can be used in all printing machines, especially offset printers. The machine includes several printing cylinders (D1-D4). These are disposed so that they are rotatable in relation to the diagonal, side and circumferential register and are also adjustable in relation to each other (R,S,T,U,W) to form a paper feed. Each cylinder (D1-D4) is connected to an electromotor (F,G) to form a direct drive (E).

Description

The invention relates to a printing press with at least one electromotive driven, axially adjustable cylinder or other rotating body according to the preamble of claim 1.

In the printing press, the several pose for printing interacting cylinders that are rotatable with respect to the Diagonal, side and circumferential registers adjustable as well adjustable to form a paper feed are stored, represent the relevant rotating body.  

A generic printing press is known from published patent application DE 38 25 600 A1 known. Inside are the axes of cylinders that are on their outsides interchangeable sleeves with printed images on their side panels ster setting axially slidably mounted. This also applies to rubber sleeves cylinders carrying the outer surface. The axial displacement takes place via the rolling of helical gears or other, in the state of Technology known means. The pressure cylinder is driven in such a way Printing machines in general from a common main drive, the its drive power via a mechanical longitudinal shaft on the individual units distributed to the printing press. The printing units are mechanical through this Longitudinal shaft connected and coupled in such a way that on their Syn chronological to each other is ensured. For practical implementation, however a complex mechanical system with a multitude of different compos nents such as B. gears, couplings, spindles, slides, etc. necessary. The resulting weaknesses such as transmission errors due to after yields of mechanical transmission elements, backlash and friction reversal tension, elasticities, additional large masses of inertia as well as numerous, low natural frequencies affect the print quality and the Re register accuracy of such conventional printing units.

From the published patent application DE 34 32 572 A1 a rotary printing press is included a print carrying a continuous web of material to be printed cylinder, a plate cylinder for one color and one attached to it employed ink roller known. The drive shafts of these rotating elements are partly indirectly via a toothed belt, some directly with the rotor of one each associated electric drive motor connected, this drive motor be managed by a higher-level controller. However, in particular for the plate and directly connected to the rotors of the electric motors Ink cylinder opens no possibility for side register adjustment.  

Although it is known (cf. Offenlegungsschrift DE 30 22 516 A1), with Reibschei benantrieben the shaft or the rotor of the electric drive motor on strong roller bearings axially displaceable to la gladly. The use of compressed air or an electromagnet is used for the displacement with excitation winding in a magnetic body and one against spring pressure baren magnetic disk proposed. Such arrangements for axial displacement However, are especially for the use in printing machines in view of the unsuitable for page register setting and not intended for it at all.

The invention has for its object a printing machine with Seitenregi ster adjustment of the pressure cylinder or other rotating body in a constructive easy way to create with a direct drive. The solution is in Claim 1 marked printing machine proposed. More, before partial configurations result from the subclaims.

Due to the invention, the use of the air gap between the stator and Rotor for side register adjustment possible by the with the printing press Rotator directly connected rotor is linearly adjustable along the air gap. In Connection to the electric direct drive for every cylinder, for every pressure factory roller or other rotating body is at the same time a backlash-free, inertial mer and mechanically rigid drive train. This gives one  high control dynamics, so that exact Web guidance, constant web tension and constant Coloring over the thus made possible, highly precise Allow register control and pressure adjustment to be achieved. The relevant rotating body (e.g. plate and Blanket cylinders in a printing unit) according to the invention directly driven so that used Have control systems drastically simplified: The too moving masses are to the exclusion of elasticities, Compliance and play directly with the rotor of the driving electric motor rigid and firmly connected. Here According to the invention, the stator of the electric motor is also included a stationary wall, for example the Printing machine wall, free of elasticity and play connected.  

To a stationary, rigid support of a stator that can be moved in the axial direction on the Reaching wall is in further training Invention provided a locking device with which Stator is fixable relative to the wall.

For axial linear displacement of the rotor according to the rotating body / rotor Adjustment movements it is advisable to use one or more to provide separate movement devices: e.g. one Linear drive, which on axially displaceably mounted rotor attacks.  

More details, features and benefits based on the invention result from the following Description of a preferred embodiment of the Invention and with reference to the drawings. These show with each schematic representation in

Fig. 1 is a front view of radial cylinder printing unit,

Fig. 2 is a plan view of the printing unit cylinder according to the direction II in Fig. 1,

Fig. 3 in the axial or longitudinal section of the attachment of the electric motor of the printing unit cylinder and the wall,

Fig. 4 is a directional arrow IV in Fig. 3 ent speaking front view and

Fig. 5 is a direction arrow V in Fig. 3 ent speaking front view.

In Figs. 1 and 2, the position of the cylinders D1- D4 is an offset printing press to each other both in front and the front view (Fig. 1) as well as in top view (Fig. 2) partially overlapping each other recognizable. The plate cylinders D1, D4 and blanket cylinders D2, D3 mounted in the printing unit wall H are provided with the following degrees of freedom: In order to be able to influence the position of the printed image transversely to the direction of travel of the paper P, the plate cylinders D1, D4 are primarily in the longitudinal direction U, that is to say parallel to its central axis, adjustable. This change of direction is called "adjustment of the side register" in printing technology. In order to be able to rotate the position of the printed image about an axis perpendicular to the cylinder center / longitudinal axis, the plate cylinders D1, D4 are each adjusted in the transverse direction R at their ends. This type of movement is called "adjusting the diagonal register".

Before the actual printing process, the paper P to be printed must first be drawn between the blanket cylinders D2, D3. For this purpose, it is passed between the blanket cylinders D2, D3 in the direction of paper travel. These cylinders are initially separated from each other in this paper feeding process, so that they limit a common feed gap. If the offset machine is ready for operation, the blanket cylinders D2, D3 are each given an adjusting movement W (see FIGS . 4 and 5), so that they are moved together and press against each other. In the course of the adjusting movement W, the blanket cylinders D 2, D 3 are also pressed against the plate cylinders D1, D4. This position is shown in Fig. 2 and is referred to in printing technology as "pressure on".

Referring to FIG. 3-5 is on the drive shaft E of the four above-mentioned cylinder D1, D2, D3, D4, the rotor sleeve Z of the rotor core F of an electric drive motor immediately fixed and stationary. The rotor sleeve Z together with the rotor package F forms the rotor of the electric motor. The drive shaft E, directly surrounded by a ball bearing 21 , is rotatably mounted in the wall H. The ball bearing 21 is directly surrounded by an eccentric bushing A, which is connected to the printing unit wall H via a further ball bearing 22 . As a result, the drive shaft E can rotate relative to both the printing unit wall H and the eccentric bushing A about its axis of rotation Y. If the eccentric bushing A is rotated via a rotary drive (not shown because it is known per se), for example a lever linkage or a toothing, a force IW or IR acting tangentially on the eccentric bushing A is produced. This force is converted via the first, inner ball bearing 21 into a radially deflected, eccentric orbit W or R of the axis of rotation Y of the drive shaft E of the respective cylinder D1, D2, D3 or D4. This is based on the fact that the eccentric bushing A is fixedly connected on its inside to the outer ring of the first, inner ball bearing 21 and on its outside to the inner ring of the second, outer ball bearing 22 . The inner ring of the first ball bearing 21 is fixed on the drive shaft E, while the outer ring of the second ball bearing 22 is immovably fixed to the wall H. With this eccentric bush bearing arrangement 21 , 22 , A, the tangential force IW or IR generated by the rotary drive can be transmitted from the eccentric bush A to the rubber blanket cylinders D2, D3 or the plate cylinders D1, D4: the axis of rotation Y of the respective cylinder then describes the approach movement path W (for the blanket cylinders D2, D3) or the diagonal register adjustment path R (for the plate cylinders D1, D4). These radial-eccentric deflections W / R of the drive shaft E are illustrated in the view in FIG. 4.

Referring to FIG. 3 of the wall H in the region of its recess for the drive shaft E, the eccentric bushing A and the two bearings 21, 22, two bridge projections K are each attached firmly with L-like profile on the outside, such that the respective shorter L-legs face each other in alignment. The outer ring of a further, third ball bearing 23 is clamped in place from its opposite sides. Its inner ring also comprises a second eccentric bushing B, the annular inner side of which is placed on the stator sleeve N and fixed thereon in a rigid manner. Thus, this arrangement and mounting of the stator core G enclosed by the stator sleeve corresponds approximately to that of the rotor core F or the stationary drive shaft E, albeit with the exception that the stator G, N of the electric motor relative to the wall H or its bridge extension K , but is not rotatable relative to the second eccentric bushing B. As a result, there is the possibility illustrated in FIG. 9 of tracking the stator G, N of any adjustment movements W or diagonal register adjustment movements R of the respective cylinder D1-D4. Since the two eccentric bushings A, B overlap in their outer diameters at a certain angular position and their respective outer ball bearings 22 , 23 are formed and arranged in circular ring profiles, which are also congruent with one another, according to FIG. 5, the stator G, N is even one with the movements W / R of the rotor F, Z completely overlapping or matching tracking is possible if the same tangential force IW or IR is exerted on the second eccentric bushing B by means of the mentioned or another rotary drive (toothing or lever linkage). If, according to FIG. 3, the two eccentric bushes A, B are rigidly coupled to one another by means of a mechanically releasable connecting device Q in the rotational position in which they overlap axially with their outer diameters (see above), no further rotating device is specifically required for the eccentric bushing B. .

After the stator G, N has traced the cylinder / rotor movements W / R, its stationary and rigid support with respect to the wall H or its bridge extension K is necessary. For this purpose, blocking blocks C are arranged around the stator eccentric bushing B, preferably diametrically opposite one another. Their (inner) sides facing the eccentric bushing B are concavely curved in the manner of brake shoes in such a way that they encompass the eccentric bushing B from the outside in a form-fitting manner and thus block their rotation in the bearing 23 about the Y axis. The blocking or blocking of the eccentric bushing B is actuated or given by the blocking blocks C being given a displacement movement M radially inwards (locking the stator E against the wall H) or outwards (releasing this locking).

Finally, the side register adjustment movement U for the respective cylinder D1-D4, together with rotor F, Z rigidly attached to it, is indicated in FIG. 3, but the associated linear guide, possibly with a linear drive, is not shown for the sake of clarity. Within the scope of the invention, it would also be conceivable to adjust the stator G of the side register adjustment movement U by means of a linear guide.

A stator tracking the movement of each Cylinder D1-D4 is particularly appropriate when the Adjustment movement W one of the blanket cylinders D2, D3 or the diagonal register adjustment R one of the Plate cylinder D1, D4 is too big for another Compensation via the air gap L between rotor package F and Stator package G would be possible.  

In the print-on position, the stator G is supported free of play and elasticity against the printing unit wall H, whereas the rotor F is connected to the printing unit wall with play and elasticity by the two inner and outer ball bearings 21 , 22 . All tolerances due to bearing play of the two ball bearings 21 , 22 as well as elastic deformations and displacements due to the still existing contact force IW can be compensated for by the air gap of the electric motor when the stator G is firmly locked. This effect is further promoted by the fact that the electric motor does not have its own bearing directly between the stator and rotor. An axial and radial displacement from stator to rotor is therefore not hindered, but is in principle possible to a limited extent. The possibility of axial displacement along the air gap L can advantageously be used for the side register adjustment U.

After all, due to the invention for Lateral register adjustments U of cylinders D1-D4 the principle of direct, rigid  Connection of the rotor to the cylinder and the stator to the Printing unit wall can be realized. The still necessary Mobility or mobility tolerances can be Compensate axially and / or radially via the engine air gap.

Within the scope of the invention are electric drive motors the version with cylindrical rotor and thus with radial field and the version with disc rotor and thus with Axial field can be used.

For more details in particular becomes the offset printing machine mentioned above in addition to the parent patent 41 38 479 ver grasslands. This also applies to the eccentric Tracking.

Claims (6)

1. Printing machine with at least one electromotive Zy cylinder (D1, D2, D3, D4) or other rotating body, which is guided with respect to its axis of rotation (Y) in a wall (H) axially longitudinally adjustable (U), characterized in that the rotor (F) of the electric motor (F, G) is rigidly and directly connected to the rotary body for its direct drive, and the stator (G) of the electric motor (F, G) is axially invariably supported on the wall (H). 2. Printing machine according to claim 1, characterized in that the tub dung (H) a fixed, preferably bridge-like and / or L-shaped extension (K) on which the stator (G) is attached is. 3. Printing machine according to claim 1 or 2, characterized in that the Rotary body / rotor assembly (D1, D2, D3, D4; F) with one of the longitudinal ver adjustment movement (U) corresponding linear drive is provided. 4. Printing machine according to one of the preceding claims, characterized ge indicates that in the electric motor (F, G) the rotor (F) has no La is arranged opposite the stator (G). 5. Printing machine according to one of the preceding claims, characterized ge indicates that the stator (G) on the wall (H) in the axial direction is changeable and ascertainable. 6. Printing machine according to claim 5, characterized by a locking device direction (C) for locking and / or for rigid connection of the stator (G) with respect to the wall (H) and / or its approach (K).