Printing substrate transport device and printing machine

Abstract

A transport device for transporting printing substrates includes a conveyor belt that is supported on its inner side by revolving profiles. Each profile has grooves, at least one of which has a first bore and a second bore. A vacuum is applied to the first bore and the second bore is in air-conducting connection with a longitudinal groove in a slide so that suction air flows out of the longitudinal groove, through the at least one groove and into the first bore. A printing machine is also provided.

Claims

1. A transport device for transporting printing substrates, the transport device comprising: a conveyor belt having an inner side; revolving profiles supporting said inner side of said conveyor belt, each of said profiles having grooves and at least one of said grooves having a first bore and a second bore; a slide having a longitudinal groove; said first bore having a vacuum applied thereto and said second bore being in air-conducting connection with said longitudinal groove causing suction air to flow out of said longitudinal groove through said at least one groove and into said first bore; a groove cam for pushing said slide in an adjustment direction when said slide passes; and a cam roller fixed to said slide, said cam roller contacting said groove cam upon a format change.

2. The transport device according to claim 1, wherein said grooves extend in a direction parallel to a direction of revolution of said profiles.

3. The transport device according to claim 1, wherein said first bore of said at least one groove and said first bores of adjacent grooves form a first row and branch off a common longitudinal channel.

4. The transport device according to claim 3, wherein said grooves of said first row are located within a smallest format of the printing substrate able to be processed with the transport device.

5. The transport device according to claim 4, wherein said second bore of said at least one groove and said second bores of adjacent grooves form a second row extending so as to cover said longitudinal groove.

6. The transport device according to claim 5, wherein said grooves of said second row adjacent said at least one groove are outside of the smallest format of the printing substrate.

7. The transport device according to claim 1, wherein said groove cam has flanks, and said cam roller and said flanks are spaced apart from each other when said cam roller passes through said groove cam during normal machine operation.

8. The transport device according to claim 7, wherein said groove cam has a first section and a second section, and said flanks converge in said first section and are parallel to one another in said second section.

9. A printing machine, comprising: a transport device according to claim 1; and at least one print head for inkjet printing, said at least one print head being oriented towards said transport device for printing on said printing substrate located on said transport device.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

(1) FIG. 1 is a diagrammatic, side-elevational view of a printing machine with a printing substrate transport device;

(2) FIG. 2 is a fragmentary, top-plan view of revolving profiles of the transport device;

(3) FIG. 3 is an enlarged, fragmentary, top-plan view of a section of one of the revolving profiles;

(4) FIG. 4 is a sectional view taken along the line IV-IV of FIG. 3, in the direction of the arrows;

(5) FIG. 5 is a sectional view taken along the line V-V of FIG. 2, in the direction of the arrows; and

(6) FIG. 6 is a sectional view taken along the line VI-VI of FIG. 2, in the direction of the arrows.

DETAILED DESCRIPTION OF THE INVENTION

(7) Referring now to the figures of the drawings in detail and first, particularly, to FIG. 1 thereof, there is seen a printing machine 1 with a transport device 2 for transporting printing substrates 3 in the form of a web or, preferably, in the form of sheets. The transport device 2 includes an endless conveyor belt 4 for transporting the printing substrate 3 in a direction of transport 7 and past one or more printing heads 5 for inkjet printing and, if applicable, past one or more dryers 6, for instance for so-called UV pinning. Beam-shaped profiles 8 are disposed within a path of revolution of the conveyor belt 4. The profiles 8 are connected to one another to form an endless chain. The profiles 8 run in a direction of revolution 11 on rolls 9 on a ring-shaped guide 10. The conveyor belt 4 is a so-called vacuum belt. It has a non-illustrated perforation through which the profiles 8 hold the printing substrate 3 on the conveyor belt 4 by suction.

(8) FIG. 2 illustrates a section of the chain of profiles 8. The conveyor belt 4, which actually covers the profiles 8, is not shown. The length of the profiles 8 and the width of the conveyor belt 4 are to be measured in a direction perpendicular to the plane of the image of FIG. 1 and in a direction horizontal in the plane of the image of FIG. 2. They are at least as big as the width of the printing substrate 3, which is to be measured in the same direction. FIG. 2 is a view of the surface of the profile 8 that faces the inner side of the conveyor belt 4. Grooves 12 that run parallel to the direction of revolution 11 are formed in this surface. The grooves are equidistantly spaced apart from one another and disposed in a row along the profile 8. A vacuum is applied to the grooves 12 from the inside of the profile 8. Thus, with the open side facing the conveyor belt 4, the grooves 12 suck the conveyor belt 4 against the chain of profiles 8. This increases the frictional connection between the conveyor belt 4 and the profiles 8. This feature is advantageous in terms of a frictional driving connection between the conveyor belt 4 and the profiles 8. Moreover, the grooves 12 aspirate the printing material 3 through the aforementioned perforation of the conveyor belt 4.

(9) Two slides 13 are integrated into the respective profiles 8. The slides 13 are disposed in such a way as to be movable towards and away from one another along the row of grooves 12. The slides 13 are disposed in a linear guide 14, which is only shown in FIGS. 4 to 6. The slides 13 adjust the effective suction width of the profile 8 to accommodate the respective format of the printing material 3. FIG. 4 illustrates an adjustment direction of the slide 13 when it is adjusted to accommodate a larger format. Every groove 12 that is located within a minimum format 16 of the printing substrate 3 has a first bore 17 in its base. The first bores 17 form a row and branch off a longitudinal channel 18. Every groove 12 located outside the minimum format 16 has a second bore 19 in its base. The second bores form a row along the linear guide 14. At least one groove 12 has both a first bore 17 and a second bore 19. In the exemplary embodiment shown in FIG. 3, there are two grooves 12 that have a first bore 17 and a second bore 19 each. This information of course only refers to one profile end and one slide 13. FIG. 2 shows that at the other profile end, there are also two grooves 12, each one having two bores 17, 19 that cooperate with the slide 13 there.

(10) In every slide 13 there is a longitudinal groove 20 that covers more or fewer second bores 19 as a function of the format setting of the slide 13. FIGS. 3 and 4 show that the longitudinal groove 20 covers eleven second bores 19 but does not cover the two outermost second bores 19. The grooves 12 with the bores 19 that are covered by the longitudinal groove 20 are connected to the vacuum by the longitudinal groove 20, which is in air-conducting connection with the covered second bores 19. At the illustrated format settings, which accommodate a format that is larger than the minimum format 16, they are active grooves 12. The second bores that are not covered by the longitudinal groove 20 belong to grooves 12 that are outside the set width of the format of the printing substrate 3 to be processed. These grooves 12, which amount to two at every end of the profile in the illustrated exemplary embodiment, are not connected to the vacuum in the longitudinal groove 20 and are thus deactivated.

(11) The way in which a vacuum is applied to the active grooves 12 will be described below: In the straight upper section of the ring-shaped guide 10, every profile 8 moves along a rail 21 with a vacuum groove 22 that extends in the direction of revolution 11. A connector 23 connects the vacuum groove 22 to a vacuum generator, which is not shown in the drawing. FIG. 6 shows that the upper side of the profile has the grooves 12 and the underside of the profile 8 is in contact with the rail 21 while the profile 8 runs along the rail 21. There is an air-conducting connection between a connecting channel 24 in the profile 8 and the open side of the vacuum groove 22, allowing suction air to flow out of the longitudinal channel 18 into the vacuum groove 22 through the connecting channel 24. The connecting channel 24 terminates in the longitudinal channel 18 on one end and in the base of the profile 8 on the other end.

(12) The suction air flows from the grooves 12 located within the minimum format 16 through the first bores 17 thereof and into the longitudinal channel 18. At every groove 12 that has the two bores 17, 19, suction air flows out of the second bore 19 through the groove 12 and into the first bore 17. Thus, the longitudinal groove 20 and the longitudinal channel 18 are in a suction-air-conducting connection with one another through every groove 12 that has both bores 17, 19. Suction air flows from the active grooves 12 that are located outside the minimum format 16 into the longitudinal groove 20 of the slide 13 through the respective single second bore 19. This means that these active grooves 12, too, are in a suction-air-conducting connection with the vacuum groove 22.

(13) FIGS. 5 and 6 show that the linear guide 14 is a type of T-groove guide that engages beyond the slide 13 from below. The slide 13 has a journal 25 that protrudes from the base of the profile 8. A cam roller 26, which may be embodied as a rolling bearing, sits on the end of the journal 25. There is a groove cam 27 per every slide 13 of the profile 8 on a fixed point along the path of revolution of the chain of profiles 8. The two groove cams 27 are moved away from one another when an adjustment is made to accommodate a larger printing substrate format and they are moved towards one another when an adjustment is made to accommodate a smaller printing substrate format. The two groove cams 27 may, for instance, sit on a common threaded spindle, with one groove cam 27 connected to the common threaded spindle by a left-hand thread and the other groove cam 27 connected to the common threaded spindle by a right-hand thread.

(14) The inside of every groove cam 27 has a right-hand flank 28 and a left-hand flank 29 in terms of the direction of revolution 11. Starting from the entry side of the groove cam 27, where the cam roller 26 enters the groove cam 27 (at the bottom in FIG. 3), the groove cam 27 has a first section 30 followed in the direction of revolution 11 by a second section 31. In the first section, the flanks 28, 29 converge towards the second section 31 to center the cam roller 26 as it enters. In the second section 31, the flanks 28, 29 are parallel to one another and spaced apart from one another by a distance A that is greater than a diameter D of the cam roller 26. The second section 31 may be followed by a third section in which the flanks 28, 29 diverge. When it passes through the groove cam 27, the cam roller 26 hits one of the flanks 28, 29 in the first section 30 and is thus moved into the adjustment direction 15. The slide 13, which is connected to the cam roller 26, is moved together with the cam roller 26.

(15) If a format adjustment is made in which the difference between the previous format width and the format width that is to be set is very big, multiple steps may be necessary to adjust every profile 8. In a first revolution of the profile 8, the two slides 13 of the respective profile 8 are adjusted towards or away from one another by a specified amount and in a following second revolution of the profile, they are moved by a specified further amount and in the same adjustment direction as in the first revolution. Between the two revolutions, the groove cam 27 is adjusted by a specified amount in the required adjustment direction. Due to the step-by-step adjustment, the groove cam 27 may be of comparatively compact construction in which the opening side of the first section 30 and the angle between the flanks 28, 29 in the first section 30 may be kept small. The adjustment amounts are selected so as to avoid any danger of the cam roller 26 hitting the groove cam 27 next to the groove cam opening between the flanks 28, 29.

(16) A last step of a format adjustment is a fine-adjustment of the groove cam 27 with respect to the cam roller 26 to center the groove cam 27 relative to the cam roller 26 so that there is adequate space both between the right-hand flank 28 and the cam roller 26 and between the left-hand flank 29 and the cam roller 26. This centering fine-adjustment effectively prevents contact between the cam roller 26 and the groove cam 27 during normal operation of the machine, for instance during printing, because contact would lead to friction, wear, and start-up shocks.

(17) The following is a summary list of reference numerals and the corresponding structure used in the above description of the invention: 1 printing machine 2 transport device 3 printing substrate 4 conveyor belt 5 print head 6 dryer 7 direction of transport 8 profile 9 roll 10 guide 11 direction of revolution 12 groove 13 slide 14 linear guide 15 adjustment direction 16 minimum format 17 first bore 18 longitudinal channel 19 second bore 20 longitudinal groove 21 rail 22 vacuum groove 23 connector 24 connecting channel 25 journal 26 cam roller 27 groove cam 28 right-hand flank 29 left-hand flank 30 first section 31 second section A distance D diameter