JPH0780614B2 - Seat storage device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a sheet storage device having first and second sheet storage means each having a plurality of storage portions for storing a sheet on which an image is recorded.

2. Description of the Related Art Conventionally, there is known a device having a plurality of bins and moving pins to sort the sheets discharged from a recording device such as a copying machine into the plurality of bins.

However, it was not possible to sort a large number of sheets with one such device. Therefore, in order to cope with this, it is conceivable that one of the bins of such a device is used as a transport path to the device on the downstream side so that multi-stage connection is possible.

In the case of such a configuration, each time a sheet is stored in the bin, the bin is moved to sequentially store the sheets in order from the first bin of the upstream side device, and then the transport path can be transported to the downstream side device. And the sheets are sequentially stored from the first bin of the apparatus on the downstream side.

However, if the first sheet in which the second original is copied is stored in the bin of the downstream apparatus and then the first sheet in which the second original is copied is stored in the first bin of the upstream apparatus, that position is not reached. Productivity is reduced because it takes time to move the bin of the upstream device.

The present invention has been made in view of the above points, and provides a sheet storage device in which a plurality of storage means for moving a plurality of storage portions to store a sheet in each storage portion are connected, and the productivity is improved. An object is to provide an improved sheet storage device.

Embodiments Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a block diagram showing a connection state of a copying machine, an automatic document feeder, and a bin moving type sheet sorting apparatus (hereinafter referred to as a sorter), and FIG.
The figure shows the timing chart of each part of the apparatus, and Fig. 5 shows the state of the sorter in the sorting mode. Figs. 6-1 to 6-
FIG. 3 is a flow chart for executing the sort mode and the reverse sort mode.

As shown in FIG. 1, an automatic document feeder 18 is attached to the copying machine 17.
There are bin movable sorters 19 and 20 connected to the discharge side of the copying machine. The sorters 19 and 20 each have 25 sheet storage bins.

The operation mode of the bin-movable sorter is a tray mode in which the sheets discharged from the copying apparatus 17 are stored in the bin 100, and a predetermined number of sheets carried out from the copying apparatus 17 (in this embodiment, 50 sheets for A4 size or smaller are used. Group tray mode for storing 25 sheets of B4 size sheets or more), a series of sheets related to one job, for example, a collate mode for storing sheets copied from the same original document in one bin and shifting each original exchange, There are a sort mode in which a series of sheets related to one job is stored in separate bins one by one, and a reverse sort mode in which sheets are stored in the sort mode in the reverse order of the sort mode.

Further, various kinds of data are communicated by performing serial communication between the copying machine 17 and the sorters 19 and 20. For example, when communication is performed between the copying apparatus 17 and the sorter 19, when the request signal REQ is output from the copying apparatus 17, the acknowledge signal ACK from the sorter 19 is sent to the copying apparatus 17.
And the data is sent from the copying apparatus 17 by the signal TXD.

When this data is received by the sorter 19, the data is sent from the sorter 19 to the copying machine 17 by the signal RXD. Also, 19
Similar data communication is also performed between the and the sorter 20. The data sent by this communication are shown in Tables 1 and 2.

Table 1 Communication data (1) Copying device → Sorter 1 Sorter 1 → Sorter 2 SST Sorter operation signal HON Paper delivery side discharge signal BCR Sorter home position movement signal BSFT Sorter 1 bin shift signal REQ Sorter storage number request signal Operation mode / sorting Mode ・ Collate mode ・ Tray mode ・ Pre-rotation mode JAM Reset signal Size data Paper size Number of sheets Data Estimated number of sheets to be discharged Internal RAM address data Table 2 Communication data (2) Sorter 1 → Copying device Sorter 2 → Sorter 1 STBY Sorter standby signal SJAM Sorter JAM signal ALARM Sorter door switch open signal OSRT Old original sorting signal RSRT Reverse sorting signal Total bin number data Sorter completed number data Internal RAM data For S-CNCT, copy machine 17 and sorter 19 must be connected. , S-ON is a power supply to the sorter 19. Signal for controlling the supply, S ₂ -CNCT the signal indicating that the sorter 19 and the sorter 20 are connected, S ₁ -CNCT is a signal for controlling the power supply to the sorter 20.

Next, when the number of originals is 2, the number of set sheets is 30, and sorting is performed in the sort mode and the reverse sort mode.
The operation will be described with reference to the flow chart of FIG.

When the copy key of the copying machine is pressed, the copy set number data (30 sheets) and the sort mode are sent from the copying machine to the sorter 19 via communication, and then the BCR / SST signal is sent. B
Depending on the CR signal, the sorter 19 can exceed 25 sheets that can be sorted. 5
The number of sheets data is sent to the sorter 20, and then the BCR / SST signal is sent to the sorter 20 (see FIG. 3). Receiving the BCR signal, the sorters 19 and 20 move the bins to the home position (first bin) for sorting (see FIG. 5). When the bin movement of the sorter 20 is completed, the STBY signal is sent to the sorter 19. Sorter
19th Sorter 19 bin move is completed, STBY from Sorter 20
When receiving the signal, it sends a STBY signal to the copying machine 17. (Third
See figure). When the copying machine 17 receives the STBY signal from the sorter 19, it turns off the BCR signal and starts the copy operation.
Since the BCR signal is turned off, the conveyor motor 2 of the sorter is activated. The first sheet is the paper ejection sensor of the copying machine 17.
While passing through 16, a paper discharge signal HON is sent to the sorter 19. Sorter 1
9 operates the JAM timer from the time when this HON signal changes from ON to OFF, and monitors the arrival at the sort paper sensor 22. Until the sort paper sensor 22 reaches 25 sheets,
Every time a sheet passes through the sort paper sensor 22, the bin motor 5 is operated to raise it by one bin (FIG. 5).

After storing 25 sheets in the sorter 19, the sorter 19 is the 26th bin of the bridge 10.
BCR signal to the sorter 20 while moving to
By doing so, the 26th sheet from the copying machine that operates the transport motor of the sorter 20 is sent to the sorter 20 via this bridge. At this time, at the same time, by sending a paper ejection signal HON of the sorter 19 to the sorter 20,
JAM between the sorter 20 and the sorter 20 is performed (Fig. 5-).

The sorter 20 moves up by one bin every time the 26th sheet to the 29th sheet passes through the sort sensor 15. Sorter 20 to 30
When the first sheet passes, the number data of 5 sent from the sorter 19 and the number of 5 sorted by the sorter 20 coincide with each other, so that the raising of one bin is prohibited. When the copy device 17 has finished copying the set number of sheets and ejected the sheet, the automatic document feeder 18 sets the next document at the exposure position of the copy device 17, and similarly sets the number data and sort mode. Sorter 19
Then send the BCR / SST signal. At the same time as the STBY signal is turned off, the sorter 19 sends the OSRT signal to the copying apparatus 17 until the copied sheet of the previous document is completely stored in the sorter 19 or the sorter 20. At this time, when the last copied sheet of the previous document passes through the sorter 19, the BCR / SST signal is sent to the sorter 20 after sending the classification surplus sheet number data and the sort mode. Since the sorter 19 is the number data exceeding the number of sheets that can be classified, the previous number data (30 sheets) and the number data match,
Since the bin position is at the 26th bin and the SST signal is continuous, the operation mode is set to the mode in which the sorting surplus number of sheets are sent to the sorter 20 and then reverse sorted.

Sorter 20 will continue until the last sheet of the previous document is stored.
The STBY signal is turned off and the OSRT signal is sent to the sorter 19. When the last sheet is stored, the bin position (fifth bin) of the sorter 20, the number data 5 of the next original, and the number of stored previous documents (5) match, and the SST signal is Since it is continuous, the operation mode is set to the reverse sort mode and the OS
The RT signal is turned off, and the STBY signal and RSRT signal are sent to the sorter 19.

When the sorter 19 receives the STBY signal from the sorter 20, if the reverse sort mode of the sorter 19 is confirmed, the sorter 19 proceeds to the copying apparatus 17.
Send STBY and RSRT signals. The copying apparatus 17 starts the copying operation on the sheet previously fed from the cassette or the like, and first starts the sorting from the sorter 20. Sorter
When 20 stores the first sheet, it goes down every bin, contrary to the sort mode (Fig. 5-). Copying device
When 17 finishes the copy operation of the surplus number of sheets (5 sheets), the sheets pass through the bridge 10 and are stored in the sorter 20, and the time when the sorter 19 moves from 26 bins to 25 bins, The copy operation is temporarily stopped, and the sheet (5
Completely send the second sheet) to sorter 19. When the sorter 19 sends the fifth sheet to the bridge 10, the sorter 20 simulates BC
Send R / SST signal.

When receiving the BCR signal, the sorter 20 turns on the OSRT signal and turns off the STBY signal until the sheet on the bridge is stored (see FIG. 4). Since the sorter 20 is in the reverse sort mode, when the BCR signal is received, the mode is switched to the sort mode and the sheet (fifth sheet) is stored because the bin position is in the first bin which is the home position of sorting. Then, the OSRT signal is reset and the STBY signal is sent to the sorter 19. Also, at this time, until the BCR signal turns off, the sorter 20
The transport motor of is stopped. Sorter 19 is pseudo BCR / SST
After sending the signal, BIN movement is prohibited until the OSRT signal from the sorter 20 turns off. When the OSRT signal is turned off, the sorter 19 moves to the 25th bin and sorts the bins every time the 6th to 30th sheets are stored in the sorter 19 while descending the bin (Fig. 5-).

Next, the operation of sorting in the collate mode will be described with reference to FIGS. 7-1 and 7-2. The number of originals is 2, the set number is 50, and the selected sheet size is
The description will be given assuming that it is A3.

When the copy key of the copying machine is pressed, the copy setting number (50
Data) and collate mode from copy device to sorter 19
To the BCR / SST signal. The BCR signal causes the sorter 19 to send the copy set number (50 sheets) data and the collate mode to the sorter 20, and then the BC
Send R / SST signal. As a result, the sorters 19 and 20 move to the first bin, which is the collate home position.

When each of the sorters 19 and 20 completes its movement, the sorter 19 sends a STBY signal to the copying machine to inform that the sorters 19 and 20 can collate. The copying machine starts feeding and copying the A3 sheet and turns off the BCR signal. At this time, the copying apparatus transmits the paper size data to the sorter 19 in advance.

When the BCR signal is turned off, the sorter 19 determines the number of sheets to be loaded per bin according to the paper size, the small size such as A4 size is 50, and the other large sizes are 25. Whenever the A3 sheet is stored in the bin from the copying machine, the stacking number counter is decremented by one, and the number of stored bins is increased by one, and thus 25 sheets of the A3 are stored in one bin in this way. The number-of-loaded-sheets counter becomes 0, the bin 1 moves up, and the number-of-loaded sheets counter is set again according to the paper size. The remaining 25 sheets are stored in the second bin. When a total of 50 sheets are stored in the first bin and the second bin of the sorter 19, both the collate copy set number data and the bin storage number data are the same, so the stacking number counter may be 0. No, it does not rise by 1 bottle.

When the copying apparatus finishes copying the first original of 50 sheets, it sets the next original and, at the same time, transmits a collate bin shift signal BSFT to the sorter 19. As a result, the sorter 19 moves up by 1 bin when the sheet of the previous document is completely delivered, and sets the stacking number counter again according to the sheet size,
By setting the number of sheets stored in the bin to 0 and performing the above-described operation, the first original sheet is 25 sheets in each of the first bin and the second bin of the sorter 19, a total of 50 sheets, and the second original sheet is 3 sheets. A total of 50 sheets will be sorted into the 4th and 4th bins.

Although the copying machine and the sorter are combined in this embodiment,
The present invention is not limited to this, and is also applicable to a case where a sorter is combined with a printer or the like that records data output from a computer or the like.

As described above, according to the present invention, the first and second sheet storage means each having a plurality of storage portions for storing the sheets fed from the recording apparatus, and the first sheet storage A conveyance path that is provided integrally with the storage section of the recording means and that conveys the sheet fed from the recording device to the second sheet storage means, and a plurality of storage sections and the conveyance paths of the first sheet storage means that form the first conveyance path. Direction and a first moving means for moving in a second direction opposite to the first direction, and a first moving means for moving a plurality of storage portions of the second sheet storage means in the first direction and the second direction. The second moving means and the first moving means for storing the sheet in the respective storing portions of the first sheet storing means each time the sheet on which the first image is recorded is fed. Move the storage part of the means and the transport path in the first direction so that the transport path is When the sheet is moved to a position where it can be conveyed to the second storing means, the operation of the first moving means is prohibited, and each time the sheet on which the first image is recorded is fed, the second sheet storing means respectively. The second moving unit moves the storage unit of the second sheet storage unit in the first direction to store the sheet in the storage unit of the second storage unit, and the last sheet on which the first image is recorded is the second storage unit. After being fed to the second sheet storing means, the operation of the first moving means is prohibited every time the sheet on which the second image is recorded is fed to store the sheet in each of the storing portions of the second sheet storing means. When the storage unit of the second sheet storage unit is moved in the second direction by the second moving unit as it is, and a predetermined number of sheets on which the second image is recorded are fed to the second sheet storage unit. A first moving hand for storing the sheets in the respective storage portions of the first sheet storage means. Since there is control means for releasing the prohibition of the step operation and moving the storage portion and the conveyance path of the first sheet storage means in the second direction by the first moving means, the plurality of storage portions are moved to move the sheet. It is possible to provide a sheet storage device in which a plurality of storage means for storing in each storage portion are connected, and a sheet storage device with improved productivity can be provided.

[Brief description of drawings]

FIG. 1 is a diagram showing a connection relationship between a copying machine having an automatic document feeder and a sorter, FIG. 2 is a block diagram showing a control unit of the sorter, and FIGS. 3 and 4 are devices in sort mode and reverse sort mode. Timing chart showing the operation timing of each part, FIG. 5 is a view showing the operation of the sorter in the sort mode and the reverse sort mode, FIG. 6-1 is the main flow chart, and FIGS. 6-2 and 6-3 are sorts. FIG. 7A and FIG. 7B are flow charts of a control program for executing the mode and reverse sort mode, and FIGS. 7-1 and 7-2 are flow charts of the control program for executing the collate mode. In the figure, 17 is a copying machine, 18 is an automatic document feeder, 1
9 and 20 are sorters.

Claims (1)

[Claims] 1. A first and a second sheet storage means each having a plurality of storage portions for storing sheets fed from a recording apparatus, and integrally provided with the storage portion of the first sheet storage means. The
A conveyance path for conveying the sheet fed from the recording device to the second sheet storage means, a plurality of storage portions of the first sheet storage means and the conveyance path in the first direction and the first direction. The second opposite to the direction
A first moving means for moving the plurality of storage portions of the second sheet storage means in the first direction and the second direction, Each time the sheet on which the image is recorded is fed, the first moving means stores the sheets in the respective storage portions of the first sheet storage means, and the storage portion of the first sheet storage means and the storage portion of the first sheet storage means. When the conveying path is moved in the first direction and the conveying path is moved to a position where the sheet can be conveyed to the second storing means, the operation of the first moving means is prohibited and the first image is displayed. Each time the recorded sheet is fed, the second moving means moves the storage portion of the second sheet storage means to store the sheet in each storage portion of the second sheet storage means. The first image is recorded. After the last sheet is fed to the second storing means, every time the sheet on which the second image is recorded is fed, the sheet is stored in each storing portion of the second sheet storing means. Therefore, while the operation of the first moving means is prohibited, the second moving means causes the second
When the storage portion of the sheet storage means is moved in the second direction and a predetermined number of sheets on which the second image is recorded are fed to the second sheet storage means, the first sheet storage means In order to store the sheets in the respective storage portions of the means, the operation prohibition of the first moving means is released, and the storage portion of the first sheet storage means and the conveyance path are moved to the second by the first moving means. And a control means for moving the sheet storage device in the direction of.