PRINTING PRESS FOLDER WITH PARALLEL PROCESS TRANSPORT TAPES

[0001] The present invention relates generally to folders for web printing presses.

BACKGROUND OF THE INVENTION

[0002] Many folders used in web printing presses use driven belts or tapes to transport signatures from the cut cylinder to the next operation, such as signature deceleration or folding. These tapes contact the web or ribbons before the signature is created and have a velocity higher than that of the ribbon. The velocity difference causes relative motion (scrubbing) between the ribbons and tapes.

[0003] After a signature is created by the cut cylinder, the signature is accelerated by the tapes from ribbon or web speed, which generally matches the surface speed of the cut cylinder as well, to tape speed. The rate of signature acceleration depends on the mass of the signatures and on the normal force and coefficient of friction between the tapes and signatures. Variations in these factors cause position variations in the signatures when they reach the next device, such as a fan or jaw cylinder. Position variations include: signature-to-signature variation at a given press speed, variations due to press speed changes, and variations over time due to, for example, tape wear. Position variations cause the following problems: reduced maximum allowable press speed, increased need for manual phase adjustments, machine damage, and press downtime due to jammed signatures. Such problems are worse in variable cutoff applications and become worse as press speeds increase.

[0004] U.S. Patent No. 4,919,027 shows a sheet diverting system and U.S. Patent No. 6,612,213 shows a belt diverter. Both are hereby incorporated by reference herein.

SUMMARY OF THE INVENTION

[0005] The present invention provides a folder for a web printing press comprising: a cut cylinder cutting a web into signatures; a first transport belt having a first raised section; and a second transport belt having a second raised section, the signatures being received from the cut

cylinder so as to be located between the first and second raised sections; and at least one variable speed motor driving the first and second transport belts so as to accelerate the signatures.

[0006] By providing raised belt sections and acceleration, head-to-tail spacing can be created while the signatures remain under positive control.

[0007] The present invention also provides a method for delivering signatures cut from a web comprising: receiving the signatures at a ribbon speed under positive control between two belts; and accelerating the two belts to create a spacing between the signatures.

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] One embodiment of the present invention is shown with respect to the drawings in which:

[0009] Fig. 1 shows a folder section including cut cylinders, a transport system, and slowdown fans;

[0010] Fig. 2 shows an enlarged view of the transport system; and

[0011] Figs. 3 A and 3B are plots of belt pad velocity as a function of time.

DETAILED DESCRIPTION

[0012] Fig. 1 describes a folder section 10 according to the present invention, having an incoming web or ribbon 12, nip rollers 14, a first cut cylinder 16 interacting with a first anvil cylinder, a second cut cylinder 18 interacting with a second anvil cylinder, a transport system 20, and slowdown fans 22, 24. Transport system 20 includes tapes 26, 28 driven by a motor 30, and positive control transport belts 32, 34 driven by motors 36, 38. First cut cylinder 16 creates first perforations in ribbon 12, and second cut cylinder 18 creates signatures by cutting between the perforations. Transport system 20 delivers the signatures to slowdown fans 22, 24.

[0013] Fig. 2 shows transport system 20 schematically in more detail. Perforated ribbon 12 enters transport system 20 traveling at velocity Vl. The lead edge of ribbon 12 is guided loosely by belts 26, 28 traveling at a higher velocity V2, but is not positively gripped by the belts 26, 28.

[0014] Ribbon 12 then is contacted by belt pads 40, 42. Belt pads 40, 42 are driven by motor 48 and, when belt pads first close on ribbon 12, belt pads 40, 42 are also traveling at velocity Vl . Cut cylinder 18 then cuts a signature from ribbon 12 with a knife blade 50. Motor 48 then accelerates the signature and pads 40, 42 to velocity V2 of tapes 26, 28. The signature is then transported from pads 40, 42 to tapes 26, 28 for continued transportation to fans 22, 24. Alternately, rather than being delivered to fans 22, 24, signatures could be delivered to a jaw cylinder, for example.

[0015] When a signature is first created by cut cylinder 18, a trailing edge 52 of the new signature is contacting a leading edge 54 of ribbon 12. By accelerating each signature in transport system 20 from Vl to V2, a head-to-tail distance L between consecutive signatures is advantageously created for delivery of the signatures to fans 22, 24.

[0016] Pads 40, 42 have positive control over the signature to prevent slipping between pads 40, 42 and the signature. Positive control advantageously minimizes position variations in signatures at the exit of transport system 20.

[0017] Transport belts 32, 34 may contain two sets of pads 40, 42 and 44, 46. Each set of pads 40, 42 and 44, 46 contacts every other signature and each belt 32, 34 can be driven by separate motors 48, 56. The spacing of the pads is such that the pads 40, 42 do not influence the signature contacted by the pads 44, 46 (and visa versa).

[0018] After releasing a signature and prior to contacting a subsequent signature, each set of pads 40, 42 and 44, 46 is decelerated on return paths 58, 60 to velocity Vl by variable speed motors 48, 56. Then pads 40, 42 and 44, 46 contact ribbon 12 again, and the process is repeated.

[0019] Figs. 3 A and 3B contain plots of velocity versus time for belt pads 40, 42 and belt pads 44, 46, respectively, during the creation of two consecutive signatures. In these figures, belt pads 40, 42 contact and accelerate the first signature, and belt pads 44, 46 contact and accelerate the second signature. The first signature is created by cut cylinder 18 at time tl and the second is created by cut cylinder 18 at time t3.

[0020] Variable speed motors, such as servo motors available from Siemens Corporation, can be used to provide such velocity variation.

[0021] As shown in both Figs. 3 A and 3B, the velocity of belt pads 40, 42 and 44, 46 oscillates between ribbon velocity Vl and tape velocity V2. In Fig. 3 A, at time tl, the velocity of belt pads 40, 42 equals ribbon velocity Vl. Belt pads 40, 42 then accelerate the first signature and reach tape velocity V2 at time t2. Belt pads 40, 42 and signature A (SA) remain at velocity V2 until time t3 when belt pads 40, 42 deliver the first signature to tapes 26, 28 and begin to decelerate. Belt pads 40, 42 reach ribbon velocity Vl at time t4 and remain at velocity Vl until time t5 when a new signature is created and the process repeats.

[0022] As shown in Fig. 3B, the velocity of belt pads 40, 42 is the mirror image of the velocity of belt pads 44, 46. At time tl, belt pads 44, 46 deliver a preceding signature to tapes 26, 28 at velocity V2 and begin to decelerate. Belt pads 44, 46 reach velocity Vl at time t2. When the second signature is created at time t3, belt pads 44, 46 accelerate the second signature and reach velocity V2 at time t4. Belt pads 44, 46 and signature B (SB) remain at velocity V2 until the second signature is delivered at time t5.

[0023] Belt pad velocity profiles are not limited to those shown in Figs. 3A and 3B. Alternately, these velocity profiles could be sinusoidal or piece-wise linear, for example. Varying the velocity profiles can set the spacing between signatures.

[0024] A single variable motor and gearing could also be used for the belts 32, 34.