JP2014024638A - Printing unit block alignment device and alignment method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance efficiency and high accuracy of alignment work in a printing unit block alignment device.SOLUTION: The printing unit block alignment device comprises: support means for opening-closing in a support position and a release position for receiving a printing unit block group carried out by transversely feeding from a lower rail group with every row unit block, by dropping the printing unit block group on the orthogonal lower rail group from an upper rail in succession to a primary cutter and a secondary cutter; and an alignment carrying rail for longitudinally feeding at a constant speed by alignment carrying means, by being juxtaposed in the longitudinal direction with every row unit block, by receiving the printing unit block group dropping by a variation to the release position of this support means, and is provided with electric control means for electrically controlling the dropping timing to the alignment carrying rail from the support means, in which this electric control means controls the dropping timing in response to the stage number of a longitudinal row in a different imposition constitution, while setting a carrying speed of transverse feed carrying means to a unified speed regardless of the imposition constitution.

Description

  The present invention is a printing unit in which printing unit blocks with serial numbers such as banknotes and postcards are arranged in order of serial numbers, such as 1 to 100 and 101 to 200. The present invention relates to a block alignment apparatus.

  For example, when unit blocks in which 100 banknotes are stacked are stacked in order of 10 blocks in the stacking process, the process of arranging the unit blocks in order of numbers is required as the preceding process. A conventional unit block aligning apparatus of this type cuts large-sized sheet blocks in which large-sized sheets printed in multiple rows and columns are stacked into row-unit blocks, as represented by Patent Document 1, for example. A plurality of column unit blocks are arranged in a row, and all the columns are sequentially cut from the front end to form a large number of print unit blocks, which are sent out on an alignment line, arranged in numerical order, and supplied to the integration process. The unit block alignment operation is extremely inefficient, which has hindered efficiency improvement in the integration process. In addition, a very large cutting machine is required which arranges a large number of column unit blocks and cuts them at a time.

In order to improve this, the invention of Patent Document 2 by the present applicant has been proposed. According to the present invention, the printing unit block group is longitudinally fed for each serial number group and charged into the upper rail, and the charged printing unit block group is moved down to the serial number group by moving to the release position of the upper rail. Drop on rails.
Next, the printing unit block group dropped on the lower rail is laterally fed to each serial number group and is collectively transported to the supporting means. The printing unit block group is moved to the release position of the supporting means to move the serial number. Each group falls on an alignment conveyance rail, and on the alignment conveyance rail, the printing unit blocks are arranged in the vertical direction in the order of numbers, and are vertically conveyed to the accumulation process and carried out.
As a result, the printing unit block group is processed and aligned in units of columns cut from the large sheet block.

  In addition, the present invention has a two-story structure in which the upper rail and the lower rail group are orthogonal to each other, and the printing unit block group is passed through the upper rail by a conveyor with a pusher provided in parallel with the upper part of the upper rail, and is fed vertically for each number group. The battery is charged, dropped into the lower rail group by moving the upper rail to the release position, and is fed laterally for each number group by a conveyor with a pusher provided parallel to the lower part of each lower rail, and used for the alignment line. As a result, the operation of forming a state in which the printing unit block group is arranged in the vertical direction on the alignment line for each number group and vertically feeding to the next process is appropriately performed in a limited space.

U.S. Pat. No. 4,283,902 Patent Publication No. 7-102519

The configuration of Patent Document 2 has an excellent effect in that it is efficiently and economically aligned in a small space, but there are several difficulties in the process of dropping from the lower rail to the aligned transport rail in this configuration. Admitted.
First, there is no problem as long as printing unit blocks with the same number of columns are dropped from the lower rail group, but when sending printing unit blocks with different number of columns to the alignment conveyance rail, the conveyance speed on the lower rail is There was a problem that had to be changed.

That is, for example, when a large sheet is changed from a sheet with an imposition structure of 5 rows to a sheet with an imposition structure of 10 columns, in the former case, when a space for 5 bundles is created on the alignment conveyance rail, However, in the latter case, the next is supplied after 10 bundles are available.
Because of the restriction of the next process, it is necessary to keep the conveyance speed on the alignment conveyance rail constant, and conventionally, a large-scale operation for exchanging the clutch and gear of the conveyance means for conveying on the lower rail group has been required.
At the same time, in such a change gear system, there is a problem that replacement gears must be provided according to the number of stages for each row unit block, which increases the cost of parts.

The second problem is that the conventional structure uses a shutter structure that opens only in one direction as a support means, and each printing unit block slides down on a shutter plate opened at a certain angle, and is aligned and transported. It is the point that it was the operation which falls to the rail. Since the falling speed of each printing unit block is limited depending on the opening angle of the shutter plate, it causes an operation loss.
Also, the sliding position is irregular because the sliding position is irregular on the surface of the aligned conveying rail, causing a block or paper to be caught in the gap of the apparatus.

  The present invention was created to solve the above-described problems, and an object of the present invention is to realize the efficiency and accuracy of the alignment work in the printing unit block alignment apparatus.

In order to solve the above problems, the present invention provides the following printing unit block alignment apparatus.
In other words, this is a printing unit block aligning device that cuts and aligns a printing unit block from a large-sized sheet printed in multi-sided printing with vertical and horizontal imposition, and then sends it to the next process at a constant speed regardless of the imposition configuration. Primary cutting means for cutting large-sized sheet blocks in which the large-sized sheets are stacked into horizontal row unit blocks, and secondary cutting means for cutting row unit blocks cut by the primary cutting means into printing unit blocks With.

  Then, a vertical feed conveying means for longitudinally feeding the print unit block group charges the print unit block for each column unit block, an upper rail that opens and closes to a release position, and an upper rail that is directly below the upper rail and orthogonal to the upper rail. A lower rail group is provided which receives each unit block of the printing unit block group which is arranged and drops due to the change to the release position of the upper rail for each row unit block and laterally feeds it by the lateral feed conveying means.

  Furthermore, a support unit that opens and closes a printing unit block group that is laterally fed and transported from the lower rail group to a row unit block, and a printing unit that opens and closes to a release position of the support unit. An alignment transport rail is provided that receives the block group and arranges the blocks in a row in the vertical direction, and the alignment transport means vertically feeds at a constant speed.

  In the above configuration, there is provided an electrical control means for electrically controlling the fall timing from the support means to the alignment transport rail, and the transport speed of the laterally transporting transport means is made uniform regardless of the imposition structure. The electrical control means controls the fall timing in accordance with the number of columns in different facet configurations.

  It is preferable that the transport speed of the lateral feed transport means is a transport speed unified under the condition of the minimum number of columns in the corresponding surface-mounted structure of the apparatus.

  The support means may support both sides of the printing unit block at the support position, and simultaneously release the support on both sides at the release position and drop the support onto the alignment transport rail.

  The electric control means may be configured to control a drop timing by causing a certain stop period in the transverse feed driving by controlling a clutch brake provided in the transverse feed conveying means.

The present invention can also provide the following printing unit block alignment method.
In other words, this is a printing unit block alignment method in which a multi-sheet printed large-format sheet having a vertical and horizontal imposition configuration is cut into printing unit blocks and aligned, and then sent to the next process at a constant speed regardless of the imposition configuration. The following steps are included.

(S1) A primary cutting step of cutting the large sheet blocks on which the large sheets are stacked into row unit blocks in a row;
(S2) a secondary cutting step of cutting this column unit block into print unit blocks;
(S3) A longitudinal feed process for longitudinally feeding the print unit block group to charge the print unit block to the upper rail for each row unit block;
(S4) A lateral feed process in which the printing unit block is released from the upper rail, dropped to a lower rail group orthogonal to the upper rail, the unit block of the printing unit block group is received for each row unit block, and is laterally fed.
(S5) The printing unit block group that is laterally fed from the lower rail group is received by the support means for each row unit block, and this support means is released and the alignment transport rail receives the printing unit block group, Alignment transport process that vertically feeds each unit block in the vertical direction.

  The present invention provides an electrical control means for electrically controlling the fall timing from the support means to the alignment transport rail in the above-described alignment transport process, and this electrical control means is used for transport speed in the transverse feed transport process. The drop timing is controlled according to the number of columns in different surface-mounted configurations, while maintaining a uniform speed regardless of the surface-mounted configuration.

  In the printing unit block alignment method, it is preferable that the transport speed in the lateral feed transport process is a transport speed that is unified under the condition of the minimum number of columns in the corresponding imposition structure of the apparatus.

  The electrical control means can control the clutch brake provided in the transverse feed conveying means, thereby controlling the drop timing by causing a certain stop period in the transverse feed drive.

  The support means can support both sides of the printing unit block at the support position, and simultaneously release the support on both sides at the release position and drop it onto the alignment transport rail.

The present invention has the following effects by providing the above configuration.
Since the change gear mechanism for changing the lateral feed conveyance speed of the lower rail can be eliminated, it is possible to easily cope with large sheets having various imposition structures. As a result, the production efficiency can be improved, and at the same time, the number of parts can be reduced, which contributes to cost reduction.

  It is possible to deal with a large sheet having a large number of stages by unifying the lateral feed speed under the condition that the conveying speed is the fastest on the aligned conveying rail, that is, the condition that the number of stages per row unit block is the smallest.

  By changing the open / close shutter, which is the support means for dropping the row unit blocks on the lower rail surface to the alignment transport rail, from the single-open structure to the double-open structure, the fall speed of each print unit block can be maximized and the operating loss is reduced. be able to. At the same time, the drop position is stable, and it is possible to prevent the cause of the defect that the block or paper is caught in the gap of the apparatus.

The perspective view explaining the procedure of the printing unit block alignment apparatus which concerns on this invention. FIG. The front view of the unit block alignment apparatus which forms the said system. The side view of the same unit block alignment apparatus. It is a figure explaining dropping of the printing unit block from the upper rail which forms the unit block alignment device to the lower rail, (A) is a front view showing the closed state of the upper rail, (A) is the opening of the upper rail The front view which shows a state. The top view which shows the lower rail group and the alignment conveyance rail which form the same unit block alignment device. It is a side view explaining operation | movement of a support means, (a) is a general view of a support means, (a) is a figure which shows a support state, (c) is a figure which shows a cancellation | release state. The figure explaining the alignment method in case an imposition structure has 60 imposition. The figure explaining the alignment method in case a surfaced structure is 20 surfaced. The flowchart of the control by an electrical control means.

Hereinafter, embodiments of the present invention will be described based on examples shown in the drawings. The embodiment is not limited to the following.
1 and 2 show a unit block aligning apparatus for aligning, for example, 100 sheet blocks such as banknotes, lotteries, and postcards in numerical order. In the present invention, the order of numbers means the case of stacking from the first rank to the final rank, and is not limited to those in which numbers or the like are specifically entered.

As an example, the large sheet 1 shown in FIGS. 1 to NO. 40 multi-sided printing is performed, and the structure is an imposition with 8 columns in the vertical row and 5 rows in the horizontal row. In this specification, the method of counting the columns and rows of the imposition structure follows this.
100 large sheets 1 are stacked to form a large sheet block 1 '. 1 to NO. Each of the 40 printing surfaces is overlapped on the serial number in the stacking direction. For example, NO. 1 is 1 to 100, NO. 2, 101 to 200, NO. 3 is given a serial number from 201 to 300.

  The large-sized sheet block 1 'is first subjected to unnecessary ear drop in a trimming step (not shown), and then cut by a cutting machine 2 constituting a primary cutting means from the front row to the last row for each row. 3 is formed.

  The cut column unit blocks 3 are arranged in parallel, for example, A column, B column, and C column, and the column unit blocks 3 of A column, B column, and C column are vertically fed and subjected to secondary cutting sequentially from the front end for each printing unit. The printing unit block 5 is formed by cutting with a cutting machine 4 constituting the means.

  The cut printing unit blocks 5 of the A, B, and C rows are bound together by a band 7 using a banding means 6 to form a large number of printing unit blocks 5 in the order of 100 serial numbers. The printing unit block 5 is “vertically fed” to the upper rail 8 and charged to the rail 8 for each row unit block 3.

  Here, in this embodiment, the column unit block 3 has three columns. However, in the embodiment of the present invention, vertical feed can be performed with an arbitrary number of columns.

  As shown in FIG. 3, the upper rail 8 is provided so as to be openable and closable at a support position for supporting the printing unit block group 5 and a position for releasing the support for each of the A, B, and C rows. It has a bottom ruler 8b extending in parallel that allows the group of blocks 5 to fall, and a side ruler 8c that regulates the side surface of the printing unit block 5, and is vertically fed in parallel with the rail 8 above each rail 8. An endless conveyor 9 as means is arranged. As shown in FIG. 4, the endless conveyor 9 is mounted on pulleys 9a and 9b so as to be able to run endlessly, and the endless conveyor 9 presses the rear end face of each printing unit block 5 so that a predetermined interval is provided to the upper rail 8. It has a large number of pushers 9c arranged at regular intervals for carrying in. '

  As the endless conveyor 9 travels intermittently, the transport pusher 9c intermittently puts the printing unit blocks 5 one by one on the bottom ruler 8b of the upper rail 8 as shown in FIG. When a corresponding number of printing unit blocks 5 are charged on each upper rail 8, the upper rail 8 is opened as shown in FIG. 5 (a), that is, the bottom ruler 8b is substantially lowered downward about the axis 8a. The print unit block 5 group for each row unit block 3 is dropped by rotating 90 degrees. This drop is performed almost simultaneously with the A and B rows. The upper rail 8 is opened and closed by, for example, an air cylinder 19 or a cam. The upper rail 8 includes a case where the upper rail 8 is moved back and forth horizontally to open and close the support position and the release position.

  The printing unit block 5 group dropped from the upper rail 8 is received by the lower rail 10 orthogonal to the upper rail 8. In this embodiment, the lower rail 10 is provided with eight stages a to h which are the same as the number of stages (eight stages) of the printing unit block 5 group corresponding to the column unit block 3 in order to simplify the description. In the present invention, the number of stages does not need to match.

Each lower rail 10 has a bottom ruler 10 a extending in parallel with each other and a side ruler 10 b that regulates the side surface of the printing unit block 5. A conveyor 11 is disposed.
The conveyor 11 and the conveyor 9 are arranged orthogonal to each other. The endless conveyor 11 is mounted between the pulleys 11a and 11b shown in FIG. 3 so as to be able to run endlessly. The endless conveyor 11 runs intermittently and prints received from the upper rails 8 of the A, B, and C rows. Each of the unit block groups 5 has a transport pusher 11c that transports the unit blocks 5 along the lower rail 10 in the lateral direction at a predetermined interval. That is, when the endless conveyor 11 runs intermittently, the bottom pusher 10a of the lower rail 10 is maintained while the transport pusher 11c maintains the arrangement relationship of the A, B, and C rows of the printing unit blocks 5 groups in the a to h stages. Are intermittently “transversely fed” along and conveyed to the support means 15.

FIG. 7 is a side view when the support means 15 is viewed from the lateral direction. The same number of support means (15) according to the present invention is arranged on the extension line of the transverse feed conveying means. That is, the printing unit block 5 in each stage (a) to (h) is supported by the shutter units 20 and 20 that can be opened and closed.
First, the a to h-stage printing unit blocks 5 group carried out by the transport pusher 11c are pushed out from the lower rail to the support means 15 at the end of the lower rail 10 while maintaining the arrangement relationship of the A, B, and C rows. The useless pusher 12 provided for each of the lower rails 10a to 11h protrudes from the standby position indicated by the phantom line in FIG. 3 to the position indicated by the solid line, and is thereby fed out from the end of the lower rail 10 onto the support means 15. The group of unit blocks 5 is further pushed and supported at a fixed position on the support means 15. The unit block 5 group pushed out by the support means 15 is brought into contact with the front pad 16 to maintain a fixed position in the shutter unit 20.

  As shown in FIGS. 7A and 7C, each unit block 5 is positioned on the bottom ruler 20b of the shutter unit 20 as a designated position. Thereafter, when the shutter unit 20 is opened on both sides around the axis 20a, the support of the printing unit blocks 5 is released (release position) as is apparent from the figure, and the printing unit blocks 5 group fall down all at once.

  The dropped printing unit block 5 group is received by the alignment transport rail 17 (see FIG. 3) arranged immediately below the shutter unit 20. The alignment transport rail 17 has a bottom ruler 17 a that supports the printing unit block 5 group and a side ruler 17 b that regulates the side surface of the printing unit block 5, and an endless conveyor 18 that is an alignment transport means along the alignment transport rail 17. Deploy. The endless conveyor 18 has pushers 18a for conveying the printing unit blocks 5 received from the support means 15 in the vertical direction along the alignment conveying rails 17 from the dropping position. When the endless conveyor 18 travels intermittently, the pusher 18a of the endless conveyor 18 arranges the printing unit blocks 5 in the numerical order along the bottom ruler 17a of the transport rail 17 and intermittently proceeds to the next process (stacking process). Transport.

  By repeating the above operation, the printing unit blocks 5 groups cut from the large-sized sheet block 1 'printed in multiple rows and columns are conveyed to the next step (stacking step) while being arranged in numerical order, and in this stacking step, For example, NO. 1 in the printing unit block 5 of NO. 2 printing unit blocks are stacked, and NO. No. 2 in the block. 3 blocks are stacked in the same manner as NO. 1 to NO. Ten integrated blocks of ten are formed one after another.

The operation of the printing unit block aligning apparatus according to the present invention is as described above. However, as a conventional problem, there is a limitation on the imposition configuration in the large format sheet block 1.
That is, the large-size sheet block of the above-mentioned embodiment has 40 faces of 8 rows and 5 rows, but when a large-size sheet block with different faces is used, the speed of the lateral feed conveying means is changed. It was necessary to replace the change gear mechanism.

FIG. 8 shows an example using a 60-sheet (30) large-format sheet block having the largest imposition configuration in this embodiment, and FIG. 9 shows an example of 20-sheet (31) having the smallest imposition configuration.
With 60 faces, it has 10 rows and 6 rows, and with 20 faces, it has 5 rows and 4 rows. Note that the printing unit block aligning apparatus used here is different from the above, and is provided with 10 stages of transverse feed conveying means.

  Three steps from the right end of the large sheet with 60 faces are dropped to the lower rail group through the primary cutting process and the secondary cutting process. At this time, in order to carry out from the endless conveyor 11 of the transverse feeding and conveying means to the endless conveyor 18 of the aligned and conveying means, after 10 bundles (32) are dropped on the endless conveyor 18, the next 10 bundles are empty. In addition, the speed of one row of the endless conveyor 11 needs to match.

On the other hand, in the case of a large sheet with 20 sheets, only 5 steps of the lower rail group are used and 5 bundles (33) are dropped from the endless conveyor 11 to the endless conveyor 18.
In the present configuration, unlike the case with 60 sheets, the speed for one row of the endless conveyor 11 needs to match until five bundles of the endless conveyor 18 become empty.

In this way, when the number of columns in the column is different, it is not possible to carry out the alignment conveying means well unless the speed of the endless conveyor 11 is changed.
Therefore, in the present invention, electrical control means (not shown) for electrically controlling the fall timing from the support means 15 to the alignment transport rail 17 is provided, and the transport speed of the endless conveyor 11 is unified regardless of the imposition structure. This electric control means can control the drop timing according to the number of columns in different face-up configurations while maintaining the speed.

FIG. 10 shows a flowchart of control by the electric control means. First, the endless conveyor 11 is driven (S 10), and the shutter unit 20 of the support means 15 is set to the release position (S 11), whereby the first endless conveyor 11 is dropped onto the alignment conveyance rail 17.
Therefore, the electrical control means controls the clutch brake provided on the endless conveyor 11 to temporarily stop the endless conveyor 11 (S12), and waits until there is a space for dropping the next bundle on the alignment transport rail 17. To do.

The temporary stop time may be stopped for a time defined in advance by the number of stages. However, a sensor unit may be provided on the alignment transport rail 17 to stop until an empty space is detected by the sensor.
The endless conveyor 11 is driven again (S14) at the timing (S13) when the desired number of steps are available, and the release operation (S15) of the shutter unit 20 is also performed.
This repetition is repeated until all the printing unit blocks are aligned (S16).

According to the above control, the speed of the endless conveyer 11 is constant, and it is possible to freely cope with the surface-mounted structure having different number of stages only by controlling the driving and stopping thereof.
The speed of the endless conveyor 11 is preferably set to a uniform transport speed under the condition of the minimum number of columns in the corresponding imposition configuration of the apparatus. In the above example, the speed of the endless conveyor 11 is required to be the fastest in the case of five stages. Therefore, in accordance with this, the stop operation is performed in the case of ten stages, and the continuous conveying means is continued. Can be carried out automatically.

Needless to say, the number of columns in the column is not limited to the above number, and can be applied to any number of columns such as 6, 7, 8, and 9.
In the present embodiment, the method of controlling the clutch brake of the endless conveyor 11 is described. However, in the present invention, any method of controlling the fall timing from the support means to the alignment transport rail may be used. For example, a method of directly controlling the drive motor of the endless conveyor, a method of directly controlling the opening / closing timing of the shutter unit 20 of the support means 15, or the like may be used.

DESCRIPTION OF SYMBOLS 1 Large sheet 1 'Large sheet block 2 Cutting device which comprises primary cutting means 3 Row unit block 4 Cutting device which constitutes secondary cutting means 8 Upper rail 10 Lower rail 15 Block base which constitutes support means 17 Alignment conveyance rail

Claims (8)

A printing unit block aligning device that cuts and aligns a printing unit block from a large-sized sheet printed in a multi-sided configuration with vertical and horizontal imposition, and sends it to the next process at a constant speed regardless of the imposition configuration.
Primary cutting means for cutting large sheet blocks on which the large sheets are stacked into row-by-row unit blocks;
Secondary cutting means for cutting the column unit blocks cut by the primary cutting means into printing unit blocks;
An upper rail that opens and closes to a release position and a support position that charges the print unit block for each row unit block by a longitudinal feed conveying means that vertically feeds the print unit block group;
The unit block of the printing unit block group, which is arranged directly below the upper rail and orthogonal to the upper rail and drops due to the change to the release position of the upper rail, is received for each row unit block and is laterally fed by the lateral feed conveying means. A group of rails,
A support means for opening and closing a support position and a release position for receiving the print unit block group which is laterally fed from the lower rail group and is conveyed for each row unit block;
An alignment transport rail that receives the printing unit block group that falls due to the change to the release position of the support means and arranges it in the vertical direction for each row unit block, and the alignment transport means feeds vertically at a constant speed;
In a configuration comprising:
An electrical control means for electrically controlling the fall timing from the support means to the alignment transport rail is provided;
The electrical control means controls the fall timing in accordance with the number of columns in different imposition structures, while making the conveying speed of the transverse feed conveying means uniform regardless of the imposition structure. Printing unit block alignment device. The printing unit block aligning apparatus according to claim 1, wherein the transport speed of the lateral feed transport unit is a transport speed that is unified under the condition of the minimum number of columns in the corresponding surface-mounted configuration of the apparatus. 3. The printing according to claim 1, wherein the electrical control unit controls a clutch brake provided in the lateral feed conveying unit to control a fall timing by causing a certain stop period in the lateral feed drive. 4. Unit block alignment device. 4. The support means supports both side surfaces of the printing unit block at the support position, and simultaneously releases the support on both side surfaces at the release position so as to drop onto the alignment transport rail. The printing unit block alignment apparatus according to any one of the above. A printing unit block alignment method for cutting and aligning a printing unit block from a large-sized sheet printed in a multi-sided configuration with vertical and horizontal imposition, and then sending it to the next process at a constant speed regardless of the imposition configuration,
A primary cutting step of cutting large sheet blocks on which the large sheets are stacked into row unit blocks;
A secondary cutting step of cutting this row unit block into print unit blocks;
A vertical feed process in which the print unit block group is vertically fed and the print unit block is charged to the upper rail for each column unit block.
Release the printing unit block from this upper rail, drop it to the lower rail group orthogonal to the upper rail, receive each unit block of the printing unit block group for each row unit block, and traverse feed process to traverse,
The printing unit block group which is laterally fed out from the lower rail group is received by the supporting means for each column unit block, and this supporting means is released, and the printing unit block group is received by the alignment conveying rail, and the column unit block is received. Alignment conveyance process that arranges vertically in every vertical direction,
Each process,
In the alignment transport process,
Electrical control means for electrically controlling the timing of dropping from the support means to the alignment transport rail is provided, and the electrical control means is used to unify the transport speed in the lateral feed transport process regardless of the imposition structure. A printing unit block alignment method characterized by controlling the fall timing according to the number of columns in different imposition configurations while maintaining speed. The printing unit block alignment method according to claim 5, wherein the transport speed in the lateral feed transport process is a transport speed that is standardized under the condition of the minimum number of columns in the corresponding imposition configuration of the apparatus. 7. The printing according to claim 5, wherein the electrical control unit controls a clutch brake provided in the lateral feed conveyance unit to control a fall timing by causing a constant stop period in the lateral feed drive. 8. Unit block alignment method. 8. The support unit according to claim 5, wherein the support unit supports both sides of the printing unit block at a support position, and simultaneously releases the support on both sides at the release position and drops the support unit on the alignment transport rail. The printing unit block alignment method according to claim 1.

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