DE461426C - Device for lifting and changing paper rolls in printing machines, in particular rotary printing machines - Google Patents

Description

Device for lifting and changing paper rolls in printing machines, in particular rotary printing machines. The additional patent 457.?.? i concerns a Device for lifting and changing paper rolls in printing machines, in particular Rotary printing machines in which the paper roll transferred to the lifting bearing is lifted the bearing comes into contact with a drive belt and is in contact with it for so long remains and is rotated by him until their support axis reaches auxiliary bearings.

The invention relates to a further training according to the invention the additional patent, through which a significant simplification of the device is achieved will.

The subject matter of the invention is illustrated in the drawing, and although they show: Fig. i a side view of the device, Fig. 2 a front view, Fig.3 is a view of the lever bearing in section through the screw spindle, the Bevel gear nut is shown partially in view, Fig. D. a cut after the Line A-B in Fig. 3, Fig. 5 a section along the line C-D in Fig. 3 and Fig. 6 a top view of the lever bearing with the roller spindle.

The paper roll a is mounted on a shaft b. The wave b can be designed as a continuous shaft on which the roller can be adjusted in the usual way held or wedged. On this wave b and with it the role should a be movable up and down between vertical columns of the machine frame, as is also described in the additional patent. Two pairs of bearings are provided, a vertically movable pair of bearings c and a horizontally movable pair of bearings d. The lever bearings c are movable up and down on a vertical spindle e 'while the auxiliary bearings d on the uprights e in the already described in the additional patent Way to avoid the lifting roller shaft b in its horizontal plane and the roller shaft b can allow passage to itself, after the passage of the To push shaft b back into the rest position illustrated in Fig. I; in this they have the task of when the vertically movable lever bearing c the to lift out the expired roll a with its shaft b from the bearings c and hold it back.

The paper roll a is driven by the endless belt f, which is itself driven by the printing machine at machine speed. It is z. B. the lower pulley f1 is the driving pulley, while the belt f is guided in the upper part over a tensioning pulley f =. The contact of the belt f with the paper roll a can be as strong as desired, because the lever bearings c are vertically adjustable.

The lever bearings c are designed as gear boxes, while the roller spindle b is provided at both ends with wide gears b1 with which it can engage in a drive wheel ia of each gear box c, adjustable in its longitudinal direction in the bearing c. With the paper roll a rotating, these wide gear wheels b1 at the ends of the roll spindle b are supposed to transmit the movement by self-locking worm drive to bevel gears i (Fig. 3), which are designed as threaded nuts and run on the vertical screw spindles e1 in the stands e. The vertical spindles e1 are driven by a self-locking worm gear g by a motor da , which in the exemplary embodiment according to Fig.

A contact lever l is installed above the horizontally displaceable auxiliary bearing d , which can close or interrupt the circuit to the motor h. The contact lever L is connected by a push rod h to a contact lever l 'attached to the foot of the stator e, while the lever bearings c' above and below in the path of this contact lever l and l 'have stops 12, which the contact lever, depending on the bearings c arrive in one or the other end position, adjust and thereby start or stop the motor h.

There are switches for switching on and off at a convenient height of the engine lz provided.

The gear boxes c are equipped with a self-locking worm gear, so that the drive by the roller spindle b is completely independent of the motor drive through the spindles e1. The gear boxes c, which take up the roller shaft b as a lever bearing are to be arranged so that they are attached to the auxiliary bearings d on the insides the stand are attached. They consist, like Fig. 3 to 6 illustrate, essentially from the housing cl, which under mediation the nut i held by the spindle e1 and on the uprights or guide rails e, as can be seen in particular from Fig. 5, is performed. The stand e are on the side surfaces at e 'and can be placed in corresponding recesses of the Engage housing cl. There is a corresponding guide in the housing for the spindle e1 c = provided, which is arranged opposite the uprights. Get the lever bearings c so at a greater height, as Fig. 3 shows, a reliable and wide guide. Towards the front, the housing cl has a recess c3 at the top, in which the roller shaft b is embedded. The roller shaft protrudes with its gear b1 the main part of the bearing c to the outside; bearing c has a at this point Housing extension c4, in which a gear n is rotatably mounted, which with the pinion b1 of the roller shaft b comes into engagement. With this gear n is on the same axis continuously a gear o of smaller diameter firmly connected that its rotation can be transferred to an adjacent gear q. - The gear q is through its shaft q1 in connection with a worm p, which drives a worm wheel p1, which transmits its movement to a bevel gear r seated on the same shaft as it. This is in engagement with the nut, which is designed as a bevel gear in the lower part i, which sits on the spindle e1 and from the housing c, as illustrated in fig is separated by a ball bearing; that has the task of rotating the Nut i to reduce the friction as much as possible. So the bevel gear nut i is at the same time the carrier of the lever bearing c. The shaft b also rests on ball bearings, to reduce friction. By turning the spindle b, the conical raco nut becomes i set in rotation so that they the wheel base c, which is also the paper roll carrier is moving upwards.

The vertical threaded spindle e1 is also activated by means of the motor h set in rotation, the gear case in the exemplary embodiment is c and thus the bevel gear nut i carrying the paper roll d independently of the drive of the spindle b moves up or down.

As can be seen in particular from Figure 6, an exact axial adjustment of the spindle b can be carried out by means of an auxiliary device which is also mounted in the gear case c. The spindle b has a circumferential groove b5, while a toothed rail u is mounted in the gear case with a cam t which can engage in this circumferential groove b3. The cam t sits under spring pressure in a recess u1 of the rail u.If it is not opposite the groove, it can be pushed back by the inserted shaft b into the recess u1 until the shaft b with the groove b3 joins the cam t opposite. A plurality of such grooves b3 can be provided next to one another. The rail u carries a toothing u ', in which the worm v1 of a worm shaft v engages, which can be turned by a handwheel. It can readily be seen that by rotating the worm shaft v, the toothed rail u can move the shaft b with the paper roll a axially with the aid of the cam t and thus adjust the paper edge. The worm shaft v and its bearings are covered by a cover c ° '(Fig. 3).

The mode of operation results from the description.

The bevel gear nuts i wind the bearings c according to the decrease in diameter the roll of paper a high, so that the angle of tension of the belt f is always the same remain.

The horizontally displaceable auxiliary bearings d are pushed under the influence of springs into the path of the temporary paper roll shaft b, which engages the motor h through the lever 1 and winds the lever bearings c back down again through the now oppositely rotating spindles e1. During this time, the machine runs with the rest of the rolls in the auxiliary store without interruption. The new paper roll is provided with an adhesive strip. If the paper roll in the auxiliary store d has run out so far that the new roll can be glued on, the spindles e1 are turned by switching on the pushbutton to "upwards" and the new roll against the belt f or the unwinding paper web pressed; the resulting friction on the circumference of the new roller causes it to rotate. As soon as the glue point comes together with the running paper web, the running paper web is torn off; the new role thus takes the place of the expired role. The paper roll is changed when the machine is running at a reduced speed.

In order to stretch the paper web more or less in the machine by means of push buttons the lever bearing c independently of the lifting of the bearing c the rotating paper roll a moves up and down so that the roll is more or is spanned less by the belt f.

Claims (5)

PATLNTt1NSPRÜCIIL: i. Device for lifting and changing the paper rolls for printing machines, especially rotary printing machines, according to additional patent 457 421, characterized in that the paper roll spindle (b) is on a lever bearing (c) rests on the vertical screw spindle (e1) by the drive of a Motor (h) or by rotating the paper spindle (b) up and down. 2. Apparatus according to claim i, characterized in that the roller spindle (b) load-bearing lever bearings (c) by means of a bevel gear designed as a threaded nut (i) is held on the vertical spindles (e1). 3. Apparatus according to claim i and 2, characterized in that the roller spindle (b) with a gear (b1) at both ends in a toothed gear of the lever bearing designed as a gear box (c) engages and its rotation by self-locking worm gear on the as Threaded nut trained bevel gear (a) transmits. . 4. Apparatus according to claim i to 3, characterized in that the motor (1L), the vertical one, the lever bearing (c) supporting spindles (e1) drives, either by hand or in the end positions of the Lever bearing (c) can be switched on and off by these. 5. Apparatus according to claim i to q., characterized. that the roller spindle (b) and thus the edge of the paper axially precisely adjusted with the aid of an adjusting device seated in the lever bearing (c) can be.