The present invention relates generally to printing presses and more particularly to printing presses with conveyors altering the pitch of printed products printed in the printing press.
U.S. Pat. No. 6,176,485, hereby incorporated by reference herein, discloses a diverting device for a continuous sequence of flat products traveling in a product travel plane. A first product exit path and a second product exit path emerge both from said product travel plane.
U.S. Pat. No. 6,405,850 discloses an apparatus for advancing and/or slowing signatures in a printing press. The apparatus and method includes a series of two or more belt drives, where each belt drive includes at least a pair of opposed belts. The belts are preferably timing or toothed belts driven by sprockets.
U.S. Pat. No. 6,561,507 discloses a folder apparatus that includes a conveyor and knock-down wheel assembly to receive signatures from, for example, a tape system output. The conveyor and knock-down wheel assembly slow down the signatures from the tape system and create a shingled output stream of signatures.
The present invention provides a printing press including:
a print unit printing a stream of printed products, the printed products having a first pitch; and
a pitch changing device including;
The present invention also provides a method for changing the velocity of printed products in a product stream including the steps of:
moving printed products at a first velocity and a first pitch;
rotating a nip of two rollers at the first velocity;
receiving the printed products at the nip; and
changing the first velocity of the nip and printed products to a second velocity that is different from the first velocity using an electronic cam velocity profile so as to alter the first pitch.
A preferred embodiment of the present invention will be elucidated with reference to the drawings, in which:
A motor 60 drives a roller 36 and motor 60 is connected to a controller 80. Roller 36 drives rollers 30, 32 and 34 via belt 50. Roller 34 rotates in the clockwise direction, thus rotating axle 62 in the clockwise direction. Due to the arrangement of belt 50, roller 32 rotates in the counter-clockwise direction, thus rotating axle 64 in the counter-clockwise direction. Nips 40, 42 receive printed products 102, 104 and transport printed products 102, 104 in a direction X through nips 40, 42. Printed products 102′, 104′ correspond to printed products 102, 104 at a point in time after products 102, 104 have passed through electronic pitch changing apparatus 10.
The “pitch” or distance between the head of printed products may be varied by increasing or decreasing the velocity of printed products 102, 104, while printed products 102, 104, are transported through nips 40, 42. Distance (d) traveled by a printed product is equal to the product of the velocity (v) of the product and the time of travel (t), d=v*t. A direct relationship exists between the velocity of a printed product and the distance traveled by the printed product. Accordingly, decreasing the velocity decreases the distance traveled by the product.
Motor 60 has an electronic cam velocity profile designed to increase or decrease pitch of printed products 102, 104 by increasing or decreasing the velocity of the printed products 102, 104, respectively. The linear velocities of products 102, 104 and nips 40, 42 when products 102, 104 first come into contact with nips 40, 42 are the same, initial velocity V1. The initial velocity V1 is changed in accordance with the electronic cam velocity profile in motor 60. An initial pitch P1 exists between products 102 and 104 before entering nips 40, 42. As shown in
As shown in
Motor 60, following cam velocity profile 200, reduces the initial velocity V1, 2750 FPM of product 104 to final velocity V2, 1700 FPM, upon exit of product 104′ from apparatus 10. Motor 60 slows the initial velocity V1 of nips 40, 42 and product 104 to 1700 FPM in 0.018 seconds, indicated by point 206 on cam velocity profile 200. At point 206, product 104′ exits apparatus 10.
From 0.018 seconds to 0.036 seconds, no products may be transported through nips 40, 42. Following cam velocity profile 200, motor 60 brings the velocity of nips 40, 42 up to 2750 FPM in 0.018 seconds, as indicated by point 204. At this point, nips 40, 42 are ready to receive a subsequent product 102. Product 102 is slowed down in the same manner as product 104. The decrease in initial velocity V1 to final velocity V2 of products 102 and 104 results in a smaller final pitch P2 between products 102′ and 104′ as compared to the initial pitch P1 between products 102 and 104 as shown in
As shown in
In arrangement 108, there is more time between products 104, 99 and 102, 98 entering nips 40, 42 and 140, 142, respectively, because a void is left between products when single product stream 103 is split into two product streams A, B. Thus, an initial pitch P3 between products 104 and 99 and an initial pitch P5 between products 102 and 98 is greater than the initial pitch P1 between products 104 and 102 in
The increased pitch and subsequent increase in time between products entering nips allows for changes in the cam velocity profile.
Motor 160 following cam velocity profile 300 reduces the initial velocity V1, 2750 FPM, of product 102 to final velocity V2, 1500 FPM, upon exit of product 102′ from apparatus 110. Motor 160 slows the initial velocity V3 of nips 140, 142 and product 102 to 1500 FPM in 0.018 seconds, indicated by point 306 on cam velocity profile 300. At point 306, product 102′ exits apparatus 110.
From 0.018 seconds to 0.072 seconds, no products may be transported through nips 140, 142. Following cam profile 300, motor 160 brings the velocity of nips 140, 142 up to 2750 FPM in 0.054 seconds, as indicated by point 304. At this point, nips 140, 142 are ready to receive a subsequent product 98. Product 98 is slowed down in the same manner as product 102. The decrease in initial velocity V3 to final velocity V4 of products 102 and 98 results in a smaller final pitch P6 between products 102′ and 98′. Sensor 72 detects final pitch P6 between products 102′ and 98′. Controller 80 may adjust the velocity profile of motor 160 to obtain a desired final pitch P6.
Motor 160 has 0.054 seconds to bring the linear velocity of nips 140, 142 up to the initial velocity V3 of 2750 FPM. This may be advantageous by reducing the amount of RMS torque required by motor 160. Thus, it may be easier for motors 60, 160 to work on separated streams A, B as shown in
Alternatively, as shown in
Referring back to
Electronic pitch changing apparatus 400 works similarly to electronic pitch changing apparatus 10 in
The continuous nips advantageously may be used on all folder cutoff lengths since the length of the nips does not need to be resized. Continuous nips also advantageously provide flexibility since as little or as much of the nip surface may be used as desired.
The cam profile may be sinusoidal, symmetric or asymmetric. Cam profiles of individual motors do not have to be identical when a diverter or stream separator is used.
In the preceding specification, the invention has been described with reference to specific exemplary embodiments and examples thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of invention as set forth in the claims that follow. The specification and drawings are accordingly to be regarded in an illustrative manner rather than a restrictive sense.
This is a continuation of U.S. application Ser. No. 12/072,947 filed on Feb. 29, 2008, the entire disclosure of which is hereby incorporated by reference herein.
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Number | Date | Country | |
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Parent | 12072947 | Feb 2008 | US |
Child | 14721845 | US |