EP0006402A1 - Camless drive for an oscillating front gripper - Google Patents

Abstract

1. A cam-free driving system for the rocking lead edge gripper (16) of a sheet fed rotary printing press, whose driving parts are in all cases joined together by turning joints, characterized in that the driving system is made up of an eight-part linkage (2, 4, 6, 8, 11, 13, 18, 30) in which on a first turnpin (2) with a fixed axis a turning driving crank (10) is placed for driving, by way of a link (5) one arm of a lever (7), which is turningly supported by a second turnpin (8) with a fixed axis, and furthermore the output end of the other arm of the lever (7) is designed for driving, by way of an inbetween link (12), a further lever (14, 15) whose turnpin (30) is turned by a further turning crank (25) round a third turnpin (18) with a fixed axis, the second lever supporting on its other arm (15) the lead edge gripper (16), and the first driving crank (10), controlling the rocking motion of the lead edge gripper (16), and the second driving crank (25), controlling lifting motion of the gripper, are turned at the same speed smoothly about their two axes.

Description

The invention relates to a drive free of cam drives of a vibrating pre-gripper for sheet-fed rotary printing machines, the drive elements of which are connected exclusively by rotary joints.

The purpose of the invention is to grasp the sheet aligned on the feed table with the pre-gripper device and to pass it to the gripper set of the printing cylinder after a short time, in particular the speed states of the gripper in its two important gripper positions, in the sheet transfer with v = 0 and in the sheet transfer with v = impression cylinder speed, exactly:

Only prior art vibrating pre-grippers are known as state of the art, which are either driven by cam drives without articulated drives, but these do not allow lifting when swinging back or vibrating grippers which probably perform a lifting movement when swinging back, but in this case are only driven by cam controls or cam-controlled coupling gear .

For example, German utility model 71 31 281 describes an oscillating pre-gripper that is free of cams and driven by a crank arm. However, since this does not allow a lifting movement when swinging back to the sheet transfer position at the feed table and also the time between the sheet transfer to the printing cylinder and the pivoting back of the gripper is very short, this device requires an extremely wide channel of approximately 200 in the printing cylinder, which in turn increases the length of the maximum format to be processed is severely restricted. That being said, this pre-gripper device has poor transmission conditions due to a small transmission angle.

In the drive of a vibrating pre-gripper disclosed in German Patent Specification 22 20 343, the main disadvantage is that this device is provided with non-positively interacting drive parts. During operation, a lever arm is constantly pressed against a roller via a cam control by means of a spring. The disadvantage of the frictional connection should therefore be compensated for by using a cam control, which inevitably increases the construction effort considerably. In addition, the components involved in the adhesion are inevitably very heavily stressed by the large inertial forces caused by the high angular velocities and accelerations of the pre-gripper.

Furthermore, a printing machine with the type designation "Roland Favorit" from the printing press factory Faber & Schleicher, Offenbach is equipped with a cam-controlled lifting rocking gripper, which does a lifting movement while swinging back into the sheet transfer position, but the drive is very complex via a curve control, which is procedural the difficulties already mentioned. With the required strong deceleration of the pre-gripper from a high speed to the takeover speed v = 0, strong springs must also be provided in order to prevent the roller from lifting off the curve member and thus to ensure a perfect adhesion. In addition, the production of the cams used here is extremely complex and expensive.

Accordingly, the object of the invention is to develop a vibrating pre-gripper for a short cylinder channel to exhaust a large format range, which is driven on the one hand without cam drives and thus excludes the disadvantages of the relatively expensive cam drives described and on the other hand - on the other hand, the swinging back into its sheet take-over position takes place in a path that is more distant from the impression cylinder surface, whereby, among other things, high machine speeds are to be achieved. Particular attention should be paid to good transmission ratios, that is to say transmission angles on the drive members, and the space requirement required should be kept to a minimum.

According to the invention, this problem is solved in that the drive is designed as a seven-link coupling gear, which is driven by two cranks rotating at the same angular speed and the pre-gripper itself is part of the coupling which is connected directly to the one crank.

With a drive of the type mentioned above, the channel of the printing cylinder can be kept extremely short and the circumferential surface available for the sheet support can be increased accordingly, so that larger formats can be processed with the same printing cylinder diameter. In addition, high machine speeds can be achieved thanks to favorable transmission ratios.

An advantageous embodiment of the invention is that an articulation point of the pre-gripper lever is connected via a coupling to the output member of a crank arm, whereby the pre-gripper is given a swinging motion, and that a second articulation point of the pre-gripper lever is eccentrically rotating on a circular path, whereby the pre-gripper experiences a lift against the pressure cylinder when swiveling back. Such an arrangement is simple and inexpensive to manufacture and can be mastered dynamically well, which is why even at high machine speeds and the shortest time intervals of the sheet transfer to the printing cylinder, the exact adherence to the desired speed conditions of the pre-gripper is guaranteed during the sheet transfer at the feed table and sheet transfer to the printing cylinder. A The result is absolutely precise registration when transporting sheets from the feed table to the impression cylinder.

The invention is explained below with reference to the embodiment shown in the drawing.

• Fig. 1 eine schematische Seitenansicht des Vorgreiferantriebes in der Bogenübernahmestellung am Anlegetisch und
• Fig. 2 die gleiche Ansicht wie in Figur 1, jedoch in der Bogenübergabestellung des Vorgreifers an den Druckzylinder.

It shows:

• Fig. 1 is a schematic side view of the pre-gripper drive in the sheet transfer position on the feed table and
• Fig. 2 shows the same view as in Figure 1, but in the sheet transfer position of the pre-gripper to the printing cylinder.

As shown in FIGS. 1 and 2, a first gear wheel 3 is rotatably mounted in the machine frame 1 at frame point 2, centered on the axis of the printing cylinder, and firmly connected to it. This gear 3 can be identical to the drive wheel of the printing cylinder. In gear 3, a coupling 5 is articulated off-center in crank point 4, which is a link via a hinge point 6 to an output member 7 mounted in frame point 8. The driven member 7 mounted in the frame point 8 is designed as a double-armed pivot lever. The crank arm 2, 4, 6, 8 is driven by the crank point 4, which runs through a circular path 9 when the gear 3 rotates, the radius of which is the drive crank 10 for the pivoting movement of the pre-gripper 16.

At the free end of the pivot lever 7, a coupling 12 is articulated in the articulation point 11 and transmits the pivoting movement of the pivot lever 7 to a pre-gripper lever 14 via an articulation point 13. A coupling, the pre-gripper carrier 15, is firmly connected to the pre-gripper lever 14. The pre-grippers 16 are arranged at the free end of the pre-gripper carrier 15. The pre-gripper carrier 15 is rotatably mounted eccentrically at the articulation point 30 of a second gear 17. The gear 17 mounted in the frame point 18 is in engagement with the first gear 3 and rotates at the same angular velocity as this.

• Ein auf einem Bogenanlegetisch 19 aufliegender Bogen 20 wird in der in Figur 1 gezeigten Bogenübernahmestellung 21 von dem Vorgreifer 16 erfaßt. Dabei hat die Greiferauflage des Vorgreifers 16 exakt die Geschwindigkeit v = 0. Durch die Rotationsbewegung des ersten Zahnrades 3 wird nun über die Antriebskurbel 10 dem Koppelgetriebe 2, 4, 6, 8, 11, 13, 30 eine derartige Bewegung erteilt, daß der Vorgreiferträger 15 verschwenkt wird und bereits nach kurzer Zeit in der Bogenübergabestellung 23 die für die Bogenübergabe an den Druckzylinder erforderliche Geschwindigkeit, nämlich genau dessen Zylinderumfangsgeschwindigkeit, erreicht (Figur 2).

The mode of operation of the above-described invention is explained in more detail below:

• A sheet 20 resting on a sheet feed table 19 is gripped by the pre-gripper 16 in the sheet transfer position 21 shown in FIG. The gripper pad of the pre-gripper 16 has exactly the speed v = 0. The rotational movement of the first gear 3 now gives the coupling gear 2, 4, 6, 8, 11, 13, 30 such a movement via the drive crank 10 that the pre-gripper carrier 15 is pivoted and after a short time in the sheet transfer position 23 reaches the speed required for the sheet transfer to the printing cylinder, namely precisely its cylinder peripheral speed (FIG. 2).

The movement of the articulation point 30 of the pre-gripper carrier 15 on a circular path 24 around the frame point 18, which is also the bearing point of the second gear 17, and the movement of the articulation point 13 of the pre-gripper lever 14 give the pre-gripper 16 the required oscillating movement. The radius of the circular path 24 is used as the drive crank 25 for the lifting movement of the pre-gripper 16.

After the sheet has been transferred to the impression cylinder, the pre-gripper carrier 15 continues to oscillate until the gripper support of the pre-gripper 16 has reached the reversal point 26.

During this further swinging of the pre-gripper carrier 15, a through the guidance of the articulation point 30 on the circular path 24 Lifting movement of the pre-gripper 16 is initiated up to a maximum lift 27, so that the gripper support of the pre-gripper 16 is then pivoted back into the sheet transfer position 21 on a path that is higher than the surface of the printing cylinder and only touches the sheet feed path 28 very late, which makes processing very difficult large formats - based on the circumference of the impression cylinder - is possible.

1 and 2, the cam track 29 passing through the sequence of movements of the gripper support of the pre-gripper 16 during one revolution of the printing cylinder or the pre-gripper drum is shown in dashed lines. The dimension of the largest lift 27 of the gripper support from the sheet feed path 28 corresponds to the diameter of the circular path 24, which the articulation point 30 describes during one revolution of the second gear 17.

It goes without saying that deviations with regard to the gear arrangement from the embodiment of the invention shown in the figures and set forth in the description as an example are conceivable, which lie within the framework thereof. For example, it is entirely possible to arrange the frame point 2 for the drive crank 10 taking into account a change in scale of the crank arm 2, 4, 6, 8 according to the changing frame length at any other point, that is to say not on the pressure cylinder.

PARTS LIST

• 1 machine frame
• 2 rack point
• 3 gear
• 4 - crank point
• 5 paddocks
• 6 pivot point
• 7 output link
• 8 rack point
• 9 circular path
• 10 drive crank
• 11 pivot point
• 12 paddocks
• 13 pivot point
• 14 pre-gripper lever
• 15 pre-gripper carriers
• 16 pre-grippers
• 17 gear
• 18 rack point
• 19 sheet feed table
• 20 sheets
• 21 sheet take-over position
• 22
• 23 sheet transfer position
• 24 circular path
• 2 5 drive crank
• 26 reversal point
• 27 excavation
• 28 sheet feed path
• 29 curved track
• 30 pivot point

Claims (2)

1. Curve drive-free drive of a vibrating pre-gripper (16) for sheet-fed rotary printing presses, the drive elements of which are connected exclusively by swivel joints,
characterized,
that the drive is designed as a seven-link coupling gear (2, 4, 6, 8, 11, 13, 30), this being driven by two cranks (10, 25) rotating at the same angular velocity and the pre-gripper (16) itself being part is the coupling (15) which is immediately connected to the one crank (25). 2. cam drive free drive according to claim 1,
characterized,
that a hinge point (13) of the pre-gripper lever (14) is connected via a coupling (12) to the output member (7) of a crank arm (2, 4, 6, 8), whereby the pre-gripper (16) is given an oscillating movement,
and that a second articulation point (30) of the pre-gripper lever (14) is eccentrically circumferentially guided on a circular path (24), whereby the pre-gripper (16) experiences a lift (27) with respect to the pressure cylinder when it is pivoted back.

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