EP0255653A2 - Device for attaching and stretching printing plates - Google Patents

Abstract

In the case of a device for fastening and tensioning flexible pressure plates, a movable clamping or tensioning bar is held in a hanging or tensioning position by means of magnetic force.

Description

The invention relates to a device for fastening and tensioning flexible pressure plates according to the preamble of claim 1.

Devices of this type have already become known.

DE-OS 19 36 396 shows a plate fastening and tensioning device in which a support block is fastened to the circumference of a plate cylinder in a rectangular pit extending parallel to its axis. The plate fastening and tensioning device consists of two tensioning bars, each of which is pivotably mounted on its axis at its lower end. At their upper end they each have a slot pointing counter to the tensioning direction for receiving bent printing plate ends. Due to the force of compression springs, which are mounted in bores in the walls of the support block and act horizontally on the outer walls of the clamping strips, they are pivoted against each other about their respective axis of rotation from the inner wall of the pit. To tension and hold the tensioning strips, they are pivoted against the force of the compression springs by cam disks attached to the axis and locked to the pit shroud by means of threaded bolts. A disadvantage of the tensioning device described in DE-OS 19 36 396 is that the pressure plate leading edge can only be locked in place using a tool complex way is possible.

Another plate clamping device is shown in DE-GM 72 18 664, in which a plate clamping device is arranged in a trapezoidal pit. The plate clamping device consists of two strips, each of which is pivotally supported at the bottom of the pit with its lower end. At their upper end they have hooks inclined in the tensioning direction, which are hooked into a pre-punched start and end edge of a pressure plate. The plate tension is applied to one bar by a leaf spring which is directed so that it pivots the bar towards the center of the groove. The other bar is loaded with the force of a spiral spring. This is supported horizontally on a support block in the middle of the groove and pivots the tensioning strip in the direction of an inner wall of the pit. The strips are adjusted against the force of the respective springs by rotating a camshaft using a tool. The camshaft, which acts against the force of the spiral spring, is arranged parallel to the groove in a side wall of the plate cylinder, the other camshaft, which counteracts the force of the leaf spring, is mounted in the support block in the middle of the pit.

A plate clamping device with a single clamping shaft is shown in DE-GM 84 13 364. The clamping shaft is arranged in a known manner in an axially parallel pit on the circumference of a plate cylinder. A torsion bar spring is provided to generate a tensioning force, so that a deflection of the tensioning shaft in a clockwise or counterclockwise direction Deflection of the tension shaft in clockwise or counterclockwise direction always takes place against the force of the torsion bar spring. The tensioning shaft has two opposing slots above its axis of rotation, into which an angled start or end of a pressure plate can optionally be hung. In its mouth part, the pit has two mounting edges fixed to the plate cylinder for receiving the beginning or end of the printing plate. For tensioning, the pressure plate is hung with its beginning in the hooking edge pointing in the direction of the plate cylinder rotation. The clamping shaft is then pivoted in the direction of rotation with a tool and the end of the pressure plate is hooked into the accessible slot in the clamping shaft. When the tensioning shaft is released, it swings back into its starting position by the force of the torsion bar spring and tensions the pressure plate. A disadvantage of the tensioning device described in DE-GM 84 13 364 is that no holding device is provided for the tensioning device in the pivoted-out position, so that operating personnel only have one hand free to hang the pressure plate, since the other is required to maintain the holding force to apply.

The invention has for its object to provide a device for fastening and tensioning a printing plate on a plate cylinder, in which no actuating shaft is required.

The object is achieved by the characterizing part of patent claim 1.

The advantages of the invention lie in particular in the easy handling of the device. A first and second embodiment (FIGS. 1 to 4) can be operated manually without tools or other aids. In addition, each of the two strips can be used both as a clamping strip and as a clamping strip, so that the device can be used in both directions of rotation of the plate cylinder. All forces act between the clamping bars and the groove inner walls, so that on a support device between the clamping bars, d. H. can be dispensed with in the middle of the pit. For this reason, the width of the pit can be kept narrow, whereby the non-pressure areas can be kept small. In a third embodiment (Fig. 5) only a single clamping bar is required, so that the width of the pit can be made even narrower.

Three exemplary embodiments are shown in the drawings and are described in more detail below.

• Fig. 1 eine Draufsicht auf eine erste erfindungsgemäße Druckplattenbefestigungs- und Spannvorrichtung,
• Fig. 2 einen Schnitt II - II in Fig. 1 mit aufgespannter Druckplatte,
• Fig. 3 eine zweite Ausführungsform der erfindungsgemäßen Druckplattenbefestigungs- und Spannvorrichtung,
• Fig. 5 Einzelheit Y in Fig. 2,
• Fig. 5 ein drittes Ausführungsbeispiel einer Druckplattenbefestigungs- und Spannvorrichtung mit einer einzigen Spannleiste.

Show it:

• 1 is a plan view of a first printing plate fastening and tensioning device according to the invention,
• 2 shows a section II - II in FIG. 1 with the pressure plate clamped,
• 3 shows a second embodiment of the printing plate fastening and tensioning device according to the invention,
• 5 detail Y in Fig. 2,
• Fig. 5 shows a third embodiment of a printing plate mounting and tensioning device with a single clamping bar.

A plate cylinder 1 is rotatably mounted with its two stub shafts 2 in frames of a rotary printing press. A rectangular groove 3 extends on the circumference of the plate cylinder 1 parallel to its axis. The groove 3 receives a support block 4, which has an axially parallel pit 5 which, in the upper part, in the region of the mouth, has two hanging edges 10; 10.1 has. In these hanging edges 10; 10.1 can a hook-shaped bent front or rear edge 7; 8 of a pressure plate 9 are hung. In the pit 5 there are two strips 12; 12.1 arranged in the head part 14; 14.1 each have a slot 16; 16.1 have, in which the front edge 7 or rear edge 8 can be hung. On each foot 17; 17.1 of the strips 12; 12.1 is a round steel 18; 18.1 welded with which they are on the pit base 19 of the support block 4 in a semicircular groove 21; 21.1 are pivoted freely. In this semicircular groove 21; 21.1 the bar 12; 12.1 held by two clips 20. The clips 20 are fastened to the pit base 19 with hexagon screws 15. These protrude through the clips 20 and the support block 4 and open into a threaded hole 1.1 in the plate cylinder body 1. In bores 22; 22.1 in both side walls 6; 6.1 of the support block 4 are a plurality of horizontal plungers 23 at intervals; 23.1 and several magnets 24; 24.1 alternately arranged. The plunger 23; 23.1 are with the force of the compression springs 26; 26.1 acted upon. The compression springs 26; 26.1 are supported on the inside of the groove 30; 30.1 and move the respective plunger 23; 23.1 horizontally towards the center of the pit. There they lie on the middle parts 25; 25.1 of the clamping strips 12; 12.1 and push it towards the center of the pit. The head part 14; 14.1 of each clamping bar 12; 12.1 has one for clamping a front edge 7 or rear edge 8 of the pressure plate 9 to the side wall 6; 6.1 pointing, low register tab 28; 28.1. The register tab 28; 28.1 represents, in particular when using photopolymer plates which have a plate thickness of approx. 1 mm, a vertical register stop for the front edge 7 of the pressure plate 9, which is designed as a sharp-edged bead 11 with a thickness of approx. 5 mm Defines the circumference register. Of course, with the clamp and tensioning device according to the invention, conventional metal pressure plates can also be clamped and tensioned.

To open the pressure plate clamping and clamping device, the bar is z. B. with the thumb at one end 13; 13.1 pushed away from the side wall 6 in the direction of force of the compression springs 26 and against the attraction of the magnets 24. Here, the strip 12 comes into a position in which the pressure force of the springs 26 is greater than the attraction force of the magnets 24 and the strip 12 presses into the "open" position and finally stops there.

In the gap between the strip 12 and the side wall 6, which is formed after the tensioning strip 13 has been pushed away, the folded or unwound front edge 7 of the pressure plate 9 hooked into the hooking edge 10. When the bar 12 is pivoted against the direction of force of the compression springs 26 and in the direction of the attraction force of the magnets 24, the attraction force of the magnets 24 finally prevails and the front edge 7 of the pressure plate 9 is clamped between the register projection 28 and the side wall 6. In this "clamped" position, the strip 12 is held, since the force of the magnets 24 is greater with a small gap (thickness of the pressure plate) than the force of the pressure springs 26. Here, when using photopolymer plates, the bead 11 with its outer surface Edge 35 in a form-fitting manner on the lower edge 40 of the register projection 28 (see FIG. 4). For tensioning the pressure plate 9, its rear edge 8 is hooked into the slot 16.1 of the head part 14.1 of the second bar 12.1, in this example, which is in a "hanging position" position. Since the holding force of the magnets 24.1 in this position is greater than the counterforce of the compression springs 26.1, the strip 12.1 is held on the side inner wall 6.1. For tensioning, the bar 12.1 with the suspended plate end 8 is then pivoted with the thumb in the direction of force of the compression springs 26.1 and against the direction of the attraction of the magnets 24.1. The bar 12.1 with the pressure plate trailing edge 8 is finally in a position "clamping position" in which the spring force of the compression springs 26.1 predominates significantly, since the gap formed between the magnets 24.1 and the clamping bar 12.1 is too large, and thus the opposite holding force of the magnets 24.1 is negligibly small has become.

An intervention option for manual operation of the strips 12; 12.1 without tools, e.g. B. with the thumb, each offer recessed grips 27 at the two ends of the support block 4, into which the ends 13; 13.1 of the strips 12; 12.1 protrude.

Fig. 3 shows a second embodiment of the invention. The arrangement of the magnets 24 is identical to the first exemplary embodiment; 24.1 and springs 26; 26.1. A difference lies in the storage and guidance of the strips 12; 12.1 which are made thicker for reasons of stability and in the resulting width of the channel 31, which, however, is less deep than the channel 5 in the first embodiment. The strips 12; 12.1 are mounted on a plurality of cylindrical rails 29 independently of one another, horizontally displaceable. The rails 29 are perpendicular to the axis-parallel course of the cylinder pit 5 in bores 32; 32.1 arranged. The holes 32; 32.1 are located in the side walls 6; 6.1 of the support block 4, parallel to the compression springs 26; 26.1 and magnets 24; 24.1 Of course, it is possible in both exemplary embodiments to apply the force-applying tensioning and holding elements, such as magnets 24; 24.1 and springs 26; 26.1 also in the clamping strips 12; 12.1 to integrate.

5 shows a third exemplary embodiment in which the pit 5 for receiving the clamping device is incorporated directly into the plate cylinder 1. The cylinder pit 5 is rectangular in cross section and has two hanging edges 10 in the mouth part; 10.1 on which the folded leading or trailing edge 7; 8 of the pressure plate 9 can be hung. In the middle of the cylinder pit 5 is a narrow clamping bar 33 z. B. 6 mm thick by means of two cylinder bolts 34 pivotally supported at their ends in bearing blocks 36. The two cylinder bolts 34 are each in a horizontal bore 37 in both end faces 38 of the clamping bar 33. The bearing blocks 36 are arranged at the ends of the cylinder pit 5. Sliding the bearing blocks 36 out of the pit 2 prevent two disks 41; 42, which with fastening screws 43; 44 in the area of the hooking edges 10; 10.1 are screwed to the plate cylinder body 1. The disks 41; 42 protrude somewhat into the cylinder pit 5 and each engage in a triangular groove 46; 47 in the top of the pedestals 36. The clamping bar 33 has two triangular recesses 49; 51, into each of which the beveled rear edge 8 of the pressure plate 9 is hung. A bore 53 is provided in an upper side 52 of the clamping bar 33 and serves to receive a lever bolt 54 which can be inserted into the bore 53 through a hole in the pressure plate end. Below the cylinder bolts 34, a longitudinal groove 56 is machined into the clamping bar 33, which extends over the entire length of the clamping bar 33 and reduces the spring stiffness of the lower part 57. In a foot part 55 of the clamping bar 33, several bores 58 are provided at intervals, distributed over the length of the clamping bar 33, in which bar magnets 59 are fastened. These protrude with their two poles 61; 62 beyond the width of the clamping bar 33. The bar magnets 33 are in the region of their poles 61; 62 slightly angular sanded down so that a trapezoidal shape results in the cross section, the longest side being arranged at the top. The angle of inclination of the poles 61; 62 results from the pivoting angle of the clamping bar 33, so that the bar magnets 59 with their poles 61; 62 flat on a ferromagnetic cylinder wall side wall 6; 6.1 concerns.

To fasten the printing plate 9 on the plate cylinder 1, the bent front edge 7 of the printing plate 9 is inserted into the hanging edge 10; 10.1 attached. The clamping bar 11 is in the direction of rotation of the plate cylinder 1 by means of z. B. pivoted a lever pin 54. For this purpose, one end of the lever pin 54 is inserted into the bore 53 of the clamping bar 33 and pivoted by hand in the direction of rotation until the poles 62 of the bar magnet bear against the pit cylinder wall 6.1. In this position, the magnets 59 then hold the clamping bar 33. Now the rear edge 8 of the pressure plate 9 can be hooked into the recess 51 of the clamping bar 33 which is opposite to the direction of rotation of the plate cylinder 1. The pressure plate 9 is tensioned by pivoting the tensioning bar 33 against the direction of rotation of the plate cylinder 1 until the opposite poles 61 of the bar magnet 59 now abut the ferromagnetic side wall 6 of the cylinder pit 5, where they are held there by magnetic force. A spring effect of the tensioning bar 33 is applied here by an elastic deformation of the lower part 57 weakened by the longitudinal groove 56. The clamping bar 33 is now in a "clamping position" position. The pressure plate 9 holds, due to the helix angle Hooking edges 10; 10.1 and recesses 49; 51 independently on the plate cylinder 1 without a clamping device.

In the exemplary embodiments shown, permanent magnets 24; 24.1 used. Of course, it is also possible to replace them with electromagnets. Of course, all parts such as side walls 6; 6.1 or tensioning strips 12; 12.1; 33, the poles of the magnets 24; 24.1; 59 are made of ferromagnetic material or at least coated with it.

Parts list

• 1 plate cylinder
• 1.1 threaded hole
• 2 stub shaft
• 3 groove (1)
• 4 carrier block
• 5 pit
• 6 side wall (4)
• 6.1 sidewall (4)
• 7 leading edge
• 8 rear edge
• 9 pressure plate
• 10 hanging edge
• 10.1 Hook-in edge
• 11 bead
• 12 strips
• 12.1 bar
• 13 end (12)
• 13.1 end (12.1)
• 14 headboard (12)
• 14.1 headboard (12.1)
• 15 screw
• 16 slot (14)
• 16.1 slot (14.1)
• 17 foot section (13)
• 17.1 foot part (12)
• 18 round bars (13)
• 18.1 round steel (12)
• 19 pit base (4)
• 20 clasps
• 21 semicircular groove
• 21.2 semicircular groove
• 22 hole
• 22.1 Hole
• 23 plungers
• 23.1 plunger
• 24 magnet (12)
• 24.1 magnet (12.1)
• 25 middle section (12)
• 25.1 middle section (12.1)
• 26 compression spring
• 26.1 compression spring
• 27 recessed grip (4)
• 28 Register lead
• 28.1 Register lead
• 29 rail
• 30 groove inside
• 31 channel
• 32 hole
• 32.1 hole
• 33 tensioning bar
• 34 cylinder bolts
• 35 edge (11)
• 36 bearing block
• 37 hole
• 38 end face
• 39 -
• 40 bottom edge (28)
• 41 disc
• 42 disc
• 43 fastening screw
• 44 fastening screw
• 45 -
• 46 groove
• 47 groove
• 48 headboard
• 49 recess
• 50 -
• 51 recess
• 52 top (33)
• 53 hole
• 54 lever bolts
• 55 foot section
• 56 longitudinal groove
• 57 lower part
• 58 hole
• 59 bar magnets
• 60 -
• 61 pin
• 62 pin

Claims (10)

1.Device for fastening and tensioning a flexible printing plate on a plate cylinder of a rotary printing press by means of a movable tensioning element arranged in an axially parallel pit with a device for holding the pressure plate end, the tensioning force being applied by means of spring force, characterized in that for holding the tensioning element ( 12; 12.1; 33) in a clamping, clamping or hanging position magnets (24; 24.1; 59) are provided. 2. Device according to claim 1, characterized in that the movable clamping element (12; 12.1; 33) is designed as a clamping bar. 3. Device according to claims 1 and 2, characterized in that the magnets (24; 24.1; 59) are designed as rod-shaped permanent magnets (24; 24.1; 59). 4. Device according to claims 1 to 3, characterized in that a plurality of bar magnets (24; 24.1; 59) in the clamping strips (12; 12.1; 33) is arranged. 5. Device according to claims 1 to 4, characterized in that a plurality of bar magnets (24; 24.1; 59) in the side walls (6; 6.1) is arranged. 6. Device according to claims 1 to 5, characterized in that the bar magnets (24; 24.1; 59) with their respective poles (61; 62) directed to ferromagnetic materials are arranged. 7. Device according to claims 1 to 6, characterized in that the clamping bar (12; 12.1; 33) is arranged pivotably. 8. Device according to claims 1 to 7, characterized in that the clamping bar (12; 12.1) is arranged to be horizontally displaceable. 9. Device according to claims 1 to 8, characterized in that the tensioning strip (12; 12.1) on its head part (14; 14.1) has a register projection (28; 28.1). 10. Device according to claims 1 to 9, characterized in that the clamping bar (33) is provided with a horizontal longitudinal groove (56) to achieve a spring action.

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