The present invention relates generally to a collating machine and, more particularly, to a dual accumulator in the collating machine for collating serially fed sheets of document into stacks.
Collating machines are frequently used in line with other paper handling equipment as a means for assembling a plurality of sheets of document into a stack. The stack is transferred to a folding stage for folding, if necessary, and then to an insertion stage where the stack is inserted in an envelope. Some collating machines have a dual accumulator which uses two accumulator bays from which completed accumulations are discharged back into a single transport path.
Thus, it is advantageous and desirable to provide a method and apparatus for keeping each of the released collations, whether it is released from the upper bay or the lower bay, under a positive control when the collation is in the merging region.
The present invention uses a collation control mechanism located in the merging region of a dual accumulator to provide positive control of the collations released from the upper and lower bays. The apparatus has a drum rotatable in a clockwise direction to transfer a collation from the upper bay to the exit nip, and in a counter clockwise direction to transfer a collation from the lower bay to the exit nip.
Accordingly, the first aspect of the present invention is a method for use in a dual accumulator having a first bay end and a second bay end. The method comprises:
providing a rotatable drum between an exit nip and the dual accumulator;
causing the rotatable drum to rotate in a clockwise direction for transferring a collation from the first bay end to the exit nip, or to rotate in a counter-clockwise direction for transferring a collation from the second bay end to the exit nip;
engaging a first roller with the rotatable drum for causing the first roller to rotate in the counter-clockwise direction when the rotatable drum rotates in the clockwise direction for forming a first nip for transferring the collation from the first bay end; and
engaging a second roller with the rotatable drum for causing the second roller to rotate in the clockwise direction when the rotatable drum rotates in the counter-clockwise direction for forming a second nip for transferring the collation from the second bay end.
If one driving mechanism is used to drive both the collation control mechanism and the exit nip formed by a first exit roller and a second exit roller, it is possible to mechanically couple one or both of the exit rollers with the rotatable drum, directly or indirectly, such that the second exit roller is caused to rotate in the clockwise direction when the rotatable drum rotates in the clockwise or the counter-clockwise direction.
The second aspect of the present invention is an apparatus for control of the collations in the merging region between a dual accumulator and an exit nip of a collation machine. The apparatus comprises:
a rotatable drum positioned between the exit nip and the dual accumulator, the rotatable drum is adapted to rotate in a clockwise direction for transferring a collation from a first bay of the dual accumulator to the exit nip, or in a counter-clockwise direction for transferring a collation from a different second bay of the dual accumulator to the exit nip;
a first roller, located adjacent to the rotatable drum, for forming a first nip with the rotatable drum, wherein when the rotatable drum rotates in the clockwise direction, the first roller is caused to rotate in the counter-clockwise direction for transferring the collation from the first bay through the first nip; and
a second roller, located adjacent to the rotatable drum and spaced from the first roller, for forming a second nip with the rotatable drum, wherein when the rotatable drum rotates in the counter-clockwise direction, the second roller is caused to rotate in the clockwise direction for transferring the collation from the second bay through the second nip.
The rotatable drum can be directly or indirectly linked to a driving mechanism so that the rotatable drum is caused to rotate in the clockwise or counter-clockwise direction.
According to one embodiment of the present invention:
the first roller is fixedly attached to a first roller shaft for rotation,
the second roller is fixedly attached to a second roller shaft for rotation, and
the rotatable drum is fixedly attached to a drum shaft for rotation, wherein
the first roller shaft comprises a first roller gear fixedly attached to the first roller shaft,
the second roller shaft comprises a second roller gear fixedly attached to the second roller shaft; and
the drum shaft comprises a drum shaft gear fixedly attached to the drum shaft, the drum shaft gear separately engaged with the first roller gear and the second roller gear. The apparatus further comprises:
a driving mechanism, operatively engaged with one of the first roller shaft, the second roller shaft and the drum shaft for driving the first roller shaft, the second roller shaft and the drum shaft.
According to the present invention, the exit nip has a first exit roller and a second exit roller, wherein the first exit roller and the first exit roller are adapted to rotate in opposite directions, and a coupling mechanism is used for engaging at least one of the first and second rollers to the driving mechanism for rotation.
According to one embodiment of the present invention:
the driving mechanism is engaged with the second roller shaft for driving the first roller shaft, the second roller shaft and the drum shaft,
the first exit roller is adapted to rotate in the counter-clockwise direction, and
the second exit roller is adapted to rotate in the clockwise direction, wherein the coupling mechanism comprises:
a first set of one-way clutches for mechanically engaging the second exit roller to the second shaft for causing the second exit roller to rotate in the clockwise direction, and
a second set of one-way clutches for mechanically engaging the second exit roller to the second shaft through a transfer axis for causing the second exit roller to rotate in the clockwise direction.
According to another embodiment of the present invention:
the coupling mechanism comprises:
a first set of one-way clutches for mechanically engaging the first exit roller to the second shaft for causing the first exit roller to rotate in the counter clockwise direction, and
a second set of one-way clutches for mechanically engaging the second exit roller to the second shaft for causing the second exit roller to rotate in the clockwise direction.
According to the present invention, the first exit roller and the second exit roller can be engaged with the second draft through a transfer axis.
The third aspect of the present invention is a sheet collator. The sheet collator comprises:
an exit nip; and
a dual accumulator, wherein the dual accumulator comprising
a first bay for collating sheets received in the first bay into a collation, the first bay having a first bay end for releasing the collation to the exit nip, and
a second bay, located adjacent to the first bay, for collating sheets received in the second bay into a collation, the second bay having a second bay end for releasing the collation to the exit nip;
a rotatable drum positioned between the exit nip and the dual accumulator; wherein the rotatable drum is adapted for rotating in a clockwise direction for transferring the collation from the first bay end to the exit nip, or in a counter-clockwise direction for transferring a collation from the second bay end to the exit nip;
a first roller, located adjacent to the rotatable drum, for forming a first nip with the rotatable drum, wherein when the rotatable drum rotates in the clockwise direction, the first roller is caused to rotate in the counter-clockwise direction for transferring the collation from the first bay through the first nip; and
a second roller, located adjacent to the rotatable drum and spaced from the first roller, for forming a second nip with the rotatable drum, wherein when the rotatable drum rotates in the counter-clockwise direction, the second roller is caused to rotate in the clockwise direction for transferring the collation from the second bay through the second nip.
The present invention will become apparent upon reading the description taken in conjunction with
The present invention provides a method and a mechanism for positive control of the collations released from the upper or the lower bay end to a merging region of a dual-accumulator. Because of the short and narrow space in the merging region between the bay ends and the exit nip, adding two more sets of roller nips is impractical or even infeasible. In particular, it would be very difficult to fit the drives and bearings for driving the two more sets of roller nips in the merging region.
The present invention uses a single drum or roller to form two nips with two pulleys. A schematic representation of a collation control mechanism, according to the present invention, is shown in
It should be noted that, when the upper nip 122 is used to transport a collation from the upper bay end 22 to the exit nip 40, the drum rotates in a clockwise direction and the upper roller 80 rotates in a counter-clockwise direction, as shown in
It is possible, however, to use a single driving mechanism to drive both the control mechanism 110 and the exit rollers 50 and 60. The arrangement of the various components in the control mechanism 110, the exit rollers 50, 60 and the driving mechanism is shown in
It should be noted that, when only one driving mechanism, such as a motor, is used to drive the control mechanism 110 and the exit rollers 50 and 60, it is possible to engage the exit rollers 50, 60 differently than the linkage as depicted in
The method for controlling a collation in the merging region between a dual accumulator and an exit nip is illustrated in the flowchart of
Thus, although the present invention has been described with respect to one or more embodiments thereof, it will be understood by those skilled in the art that the foregoing and various other changes, omissions and deviations in the form and detail thereof may be made without departing from the scope of this invention.
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Number | Date | Country | |
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20080272533 A1 | Nov 2008 | US |