Field of the Invention
The invention relates to a delivery for a sheet-processing machine, especially a rotary printing machine, and to a sheet-processing machine equipped with the delivery, especially a rotary printing machine.
In the delivery of a sheet-processing machine, such as especially a rotary printing machine, there is often the necessity to arrange sheet supports between sheet brakes, in order to feed the sheets to a stack without smearing. In this case, during a change from one print job to another, a changeover with regard to the number and placing of the sheet brakes and sheet supports is generally necessary.
In order to reduce the changeover effort which arises in this case, the published German Patent Document DE 198 35 003 A1 proposes to replace a braking element through which a vacuum acts in a sheet brake, for a supporting element through which the vacuum does not act, in order to change a sheet brake into a sheet support. However, this requires the braking element and the supporting element to be compatible, with one and the same geometry. There is therefore a very small amount of freedom for the configuration of the sheet supports. In addition, it may be necessary to adapt the total number of sheet brakes and sheet supports to different requirements of different print jobs.
It is accordingly an object of the invention to provide a delivery for a sheet-processing machine wherein the effort necessary for changing the delivery when changing a job in the sheet-processing machine is virtually eliminated beyond the extent which has already been achieved in the prior art presented hereinbefore.
With the foregoing and other objects in view, there is provided, in accordance with one aspect of the invention, a delivery comprising sheet brakes and sheet supports constructed of modules including respectively identical carrier modules and braking modules with operationally revolving braking elements, the braking modules being selectively connectable to the carrier modules, and support modules selectively connectable to the carrier modules.
In accordance with another feature of the invention, the delivery includes a guide common to the carrier modules.
In accordance with a further feature of the invention, the delivery includes servodrives for moving the carrier modules along the guide.
In accordance with an added feature of the invention, the delivery includes a drive shaft common to the sheet brakes.
In accordance with an additional feature of the invention, a respective sheet brake comprises a gear mechanism for operatively connecting the braking element to the drive shaft, the gear mechanism being constructed so that it can slide in longitudinal direction of the drive shaft.
In accordance with yet another feature of the invention, the gear mechanism is integrated into the braking module.
In accordance with yet a further feature of the invention, the delivery includes a coupling for disengaging the operative connection between the drive shaft and the braking element.
In accordance with yet an added feature of the invention, the coupling is constructed as a claw coupling, and has axially sprung claws.
In accordance with yet an additional feature of the invention, the gear mechanism is integrated into the carrier module.
In accordance with still another feature of the invention, the delivery includes a guide common to the carrier modules, one of the carrier modules being separably composed of a basic module movable along the common guide and a gear mechanism module comprising the gear mechanism, one module of the braking modules and the support modules being selectively detachably connectable to the gear mechanism module.
In accordance with still a further feature of the invention, the delivery includes lockable plug-in connections for assembling respective modules for forming one of the sheet brakes and the sheet supports.
In accordance with still an added feature of the invention, the delivery includes a first suction duct provided in the braking module, and a second suction duct provided in a module for carrying the braking module, the second suction duct being connectable to a suction line, and being closable, the second suction duct communicating with the first suction duct, in a completed state of the sheet brake.
In accordance with another feature of the invention, the delivery includes a suction line detachably connected to the suction duct and to a machine-side blind plug, to which the suction line is pluggable after the connection thereof to the suction duct has been detached.
In accordance with a further feature of the invention, the delivery includes a latch bringable into and out of engagement with the drive shaft and, when engaged therewith, securing it against axial displacement, an end of the drive shaft being exposable when the latch is disengaged from the drive shaft.
In accordance with an added feature of the invention, one of the support modules comprises a tail wheel device.
In accordance with an additional feature of the invention, at least one of the supporting modules serves for applying blast air locally to an underside of a respective sheet.
In accordance with another aspect of the invention, there is provided a sheet-processing machine having a delivery comprising sheet brakes and sheet supports constructed of modules including respectively identical carrier modules and braking modules with operationally revolving braking elements, the braking modules being selectively connectable to the carrier modules, and support modules selectively connectable to the carrier modules.
In accordance with a concomitant aspect of the invention, there is provided a rotary printing machine having a delivery comprising sheet brakes and sheet supports constructed of modules including respectively identical carrier modules and braking modules with operationally revolving braking elements, the braking modules being selectively connectable to the carrier modules, and support modules selectively connectable to the carrier modules.
In order to achieve the objective of the invention, the delivery is thus equipped with sheet brakes and sheet supports which are constructed as modules comprising a carrier model, which is identical in each case, and braking modules and support modules which can optionally be connected to the carrier modules.
This provides, in particular, the possibility of making a sheet brake or a sheet support or both ineffective at the same time, without necessitating complete disassembly thereof, because the associated carrier module or modules can be left in the delivery without requiring a braking module or a supporting module to be connected thereto.
Furthermore, more freedom for the configuration of the sheet supports is provided.
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 delivery for a sheet-processing machine, especially a rotary printing machine, 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.
a is a side elevational view of
a is a side elevational view of
a is a side elevational view of
a is a side elevational view of
Referring now to the drawings and, first, particularly to
The conveyor chains 6 are guided along the paths thereof between the drive sprockets 7, on the one hand, and the deflection sprockets 8, on the other hand, by chain guide rails, which therefore determine the chain paths of the chain strands or runs. In the example at hand, the sheets 3 are transported by the lower chain strand in FIG. 1. The section of the chain path through which the latter runs is followed by a sheet guide surface 17 which faces the section and is constructed on the sheet guide device 10. Between the sheet guide surface 17 and the sheet 3 guided thereover, respectively, a supporting air cushion is preferably formed during operation. For this purpose, the sheet guide device 10 is equipped with blast or blown air nozzles which open into the sheet guide surface 17 and of which
In order to prevent mutual sticking or cohesion of the printed sheets 3 in the pile 14, a dryer 19 and a powdering device 20 are provided on the path of the sheets 3 from the drive sprockets 7 to the sheet brake 11.
In order to avoid excessive heating of the sheet guide surface 17 by the dryer 19, a coolant circuit is integrated into the sheet guide device 10, which is indicated symbolically in
The plan view shown in
The braking module 28 includes a braking element which revolves during operation, in the example shown in the form of a circulating brake band 31, which is provided with suction openings 32, and a suction chamber which is not specifically illustrated here but over which the brake band 31 sweeps and can be connected via a nozzle 132 to a vacuum generator. The mechanical supporting module 29 in the case at hand includes a tail wheel arrangement or rowel 33, and the pneumatic supporting module 30 includes a tube 34 which is connected, in a manner not illustrated, to a blower having outer blower openings 35 which act locally on an underside of a respective sheet 3 with blast or blown air, the tube 34 extending in the processing direction, i.e., in the sheet running or travel direction, in the configuration which is presented. Mechanical and pneumatic supporting modules 29 and 30 can be used alternatively or else together.
The plan view of the carrier module 27 reproduced in
This plug-in connection is implemented as follows. Provided on the braking module 28 and on the supporting modules 29 and 30 is a joint face 36, respectively, and provided on the carrier module 27 is a corresponding joint face 37. Opposite the joint faces 36, respectively, is a bounding face 38 which faces away from the joint faces, is parallel thereto and, respectively, at the same distance therefrom. The respective joint face 36 and the respective bounding face 38 are penetrated by an index hole 39 perpendicular thereto. From the joint face 37 constructed on the carrier module 27, there projects an index pin 40. At a distance which corresponds to that of the boundary faces 38 from the joint faces 36, the index pin has a peripheral groove 41. The braking module 28 and the supporting modules 29 and 30 can be plugged onto a respective carrier module 27 while the index pin 40 engages in the respective index hole 39, and a further securing shaft which cannot be seen here but projects from the joint face 37 of the carrier module 27 engages in a slot 42 parallel to the respective index hole.
The braking module 28 and the supporting modules 29 and 30, respectively, have a sprung latching lug 43 which, when the braking and supporting modules 28, 29, 30 are plugged on, engage in the peripheral groove 41 in the index pin 40, with the joint faces 36 and 37 resting on one another.
The carrier modules 27 can be adjusted by servodrives along a common guide, here in the form of a rack 44. Provided for this purpose on the respective carrier module 27 are a servomotor 51 and a pinion 45 which can be driven by the latter and engages in the rack 44. This permits adjustment, especially automated adjustment, of the sheet brakes 24 and the sheet supports 25, 26.
The rack 44 has a circular cross section which is flattened by the toothing thereof (note
In order to drive a number of sheet brakes 24, a common drive shaft 47 parallel to the rack 44 is provided (note
As depicted in
This provides the option, with a predefined number of carrier modules 27, of forming different numbers of sheet brakes 24 and sheet supports 25, 26, the aforementioned plug-in connection making a further contribution to reducing the changeover effort.
As is apparent from
In the case of the exemplary embodiment discussed to this extent of a first embodiment of the braking and supporting device 11, the gear mechanism 53 is integrated into the braking module 28, which can be detached from the carrier module 27.
In a different configuration, which is not reproduced in the drawing here, the braking element, instead of being represented in the form of a brake band belonging to a band brake and wrapping around a drive roller and at least one deflection roller, is represented in the form of a brake roll, as is disclosed by the published German Patent Document DE 28 11 963 C2, for example.
In a particularly advantageous development, a coupling 58 (explained hereinafter) is provided, by which the operative connection between the drive shaft 47 and the braking element, in the case of the second embodiment, explained hereinbelow, in the form of a brake band 131, can be disengaged. Using a coupling provided in this way and, as explained hereinbefore, corresponding plug-in connections, configurations of a second embodiment of the braking and supporting device 11 are obtained which make it possible to dispense with pulling off a module from the common drive shaft 47, as explained in conjunction with the first embodiment, when a braking module is to be replaced by a supporting module.
In a refinement illustrated in
In a similar way to the carrier modules 27 of the first variant, a respective carrier module 127 is accommodated on a common guide and can be displaced along the latter. However, in the configurations of the second embodiment of the braking and supporting device, the common guide is not simultaneously part of the transport device for displacing a respective sheet brake 124 transversely with respect to the processing direction of the sheets 3, but, by way of example, is constructed in the form of a smooth guide tube 144, while a corresponding transport device, in the case of the second embodiment, comprises, by way of example, a roller chain 56 which is tensioned transversely with respect to the processing direction and a sprocket 57 which engages in the chain and which can be driven in alternating directions of rotation by a servomotor 51 flange-mounted on the carrier module 127.
As can be seen from
The coupling 58 mentioned hereinbefore for the releasable operative connection of the drive shaft 47 to the braking element, here in the form of the brake band 131, is preferably arranged between the output gear 61 of the gear mechanism 153 and a drive roller 59 driving the braking element.
In an analogous way to the braking module 28 of the first embodiment, a braking module 128 of the second embodiment, shown in phantom d chain-dashed in
As can be seen in particular in
In order to implement the lockable plug-in connection, on the terminating plate 66, there is provided an attachment 67 which has a through hole. The latter is essentially perpendicular to the braking run of the brake band 131, which runs at the top in FIG. 9. Fixed to the carrier module 127 is an index pin 68 which is perpendicular in the installed position thereof shown in
Formed on the carrier module 127 is a vertical joint face 70 which, in the finally mounted state, i.e., after the drive roller 59 has been coupled to the output gear 61, is parallel to the terminating plate 66 of the braking module 128 in the installed position of the carrier module 127 and aligned in the processing direction. In order to produce the aforementioned plug-in connection, the braking module 128 is, as can be seen from
In the example at hand, in order to lock the pivoting connection, firstly, on the braking module 128 there is provided a pin 71 which has a conical end, projects beyond the terminating plate 66 and has a peripheral groove 71.1 (note
The coupling mentioned hereinbefore is constructed as a claw coupling, and it has axially sprung claws 58.1. As can be seen in particular in
In the carrier module 127 which, in a completed state of a sheet brake 124, carries the braking module 128, there are provided suction ducts 75 and 76 which can be closed with respect to one another via a rotary valve 74 and of which the suction duct 75 can be connected via a suction line 77 to the vacuum generator mentioned hereinbefore, and the suction duct 76 opens into the joint face 70. In the completed state, a further suction duct 78 which is provided in the braking module 128 and arranged to be aligned with the suction duct 76 communicates with the latter and, ultimately, produces a fluid connection between the vacuum generator and the interior of the suction chamber 64 and a suction opening 79 communicating with the latter in a suction chamber 64 over which the braking run of the brake band 131 sweeps. In this case, the suction duct 78 of the braking module 128 is connected to the suction duct 76 via a sealing ring 80 provided between the joint face 70 and the braking module 128.
To this extent, when the braking module 128 is replaced by a supporting module, the fluid connection between the braking module 128 and the vacuum generator can be disengaged in a particularly simple way without any leakage, to be specific by simply closing the suction duct 75 by the rotary valve 74 and removing the braking module 128 from the carrier module 127.
A supporting module 129 which can be connected to the carrier modules 127 instead of the braking module 128, or to a carrier module 227 which will be explained further hereinbelow, can be seen in FIG. 15 and is illustrated there by way of example in the form of a mechanical configuration with a tail wheel device 129.1. Together with the carrier module 127, the supporting module 129 therefore forms a mechanical sheet support 125 and is analogous to that constructed as disclosed in conjunction with the first embodiment of the braking and supporting device 11, and differs from the latter by a configuration with the effect that, by a plug-in connection provided for the braking module 128, it can be connected to the carrier module 127 or 227 in a manner similar thereto, can be pivoted against the joint face 70 and locked by the leaf spring 72. A face of the supporting module 129 which may rest on the joint face 70 is cut out in the area of the coupling 58.
While in the configuration of the second embodiment of the braking and supporting device 11 which has been discussed to this extent, the gear mechanism 153 and the mutually closable suction ducts 75 and 76 are arranged in the carrier module 127, in a further configuration according to
With regard to moving a sheet brake 224 (note
The detachable and lockable plug-in connection between the basic module 227.1 and the gear mechanism module 227.2 is configured so that the gear mechanism module 227.2 can be coupled to the basic module 227.1 in a direction which is parallel to the aforementioned guide tube 144 and therefore to the common drive shaft 47.
As can be seen from the plan view, reproduced in an exploded illustration in
In the configurations of the second embodiment of the braking and supporting device 11, the suction chamber 64 of the braking module 128 is connected to a vacuum generator, as mentioned hereinbefore, by the suction line 77. The latter can be plugged onto a nozzle forming the suction duct 75 on the carrier module 127 or the gear mechanism module 227.2.
The configuration of the sheet brake 224 or a sheet support conceived in this way and discussed to this extent, wherein the braking module 128 coupled to the gear mechanism module 227.2 is replaced by a supporting module 129 explained further above, can advantageously be dismantled under appropriate conditions down as far as the basic module 227.1, without requiring complicated actions on the braking and supporting device 11. For the purpose of such dismantling, the gear mechanism module 227.2 separated from the basic module 227.1 by detaching the plug-in connection can be stripped off the drive shaft 47 after one end of the latter has been exposed as explained hereinbefore.
In the preferred configuration at hand, the suction line 77 is detachably connected to the nozzle forming the suction duct 75 and, on the machine side, here on the side of the basic module 227 which remains in the machine during the aforementioned disassembly, a blind plug 91 is provided, onto which the suction line 77 pulled off the nozzle 90 in the course of the disassembly can be plugged. In this way, leakage is avoided particularly simply and advantageously even when the gear mechanism module 227.2 is disassembled.
Number | Date | Country | Kind |
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100 14 590 | Mar 2000 | DE | national |
101 03 235 | Jan 2001 | DE | national |
Number | Name | Date | Kind |
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3965767 | Rinio | Jun 1976 | A |
4693462 | Pollich | Sep 1987 | A |
6360739 | Rand et al. | Mar 2002 | B1 |
Number | Date | Country |
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26 27 812 | Dec 1977 | DE |
197 09 083 | Oct 1998 | DE |
198 35 003 | Feb 2000 | DE |
Number | Date | Country | |
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20010026042 A1 | Oct 2001 | US |