JP4436912B2 - Tandem continuous paper printer - Google Patents

Description

  The present invention relates to a continuous paper printer having a tandem configuration.

  As a continuous paper printer having a tandem configuration, there is a continuous paper printer having a double-sided printing function.

  In the present invention, two continuous paper printers (first printer engine and second printer engine) are connected in tandem to realize double-sided printing.

In the present invention, the following plural printing modes are realized by a system in which two continuous paper printers (first printer engine and second printer engine) are connected in tandem.
Two-sided printing mode Two-sided one-sided printing mode One-sided one-sided printing mode Here, consider a case where folding paper is used as the paper and is installed in the paper feeding unit of the first printer engine for printing.

  When printing in the duplex printing mode, paper output from the first printer engine must be taken out without being stored in the stacker unit of the first printer engine.

  On the other hand, when printing in the two-sided single-sided printing mode, the paper output from the first printer engine needs to be stored in the stacker unit of the first printer engine.

  The conventional continuous paper printing apparatus realizes double-sided printing. In the double-sided printing mode, the first printer engine exits the paper discharge path without passing through the stacker unit. There is no control for storing paper output from one printer engine in the stacker section of the first printer engine.

  Therefore, it is necessary for the operator to instruct from the printer controller each time whether or not to output to the stacker unit as the discharge path of the first printer engine according to the print mode, which is troublesome.

  An object of the present invention is to automatically control the determination that the operator outputs to the stacker unit as the paper discharge path of the first printer each time corresponding to the print mode.

In order to solve the above problems, the present invention provides a tandem continuous paper printer comprising a first printer engine, a second printer engine, and a printer controller, wherein the first printer engine has a stacker control unit and a stacker unit, The controller has a print mode setting unit for the operator to set the print mode. When the print mode set by the operator is “double-sided print mode”, the stacker unit of the first printer engine is set to the unused mode. And output to the outside of the first printer engine without passing through the stacker unit as a paper discharge path. In the “two-sided single-sided printing mode”, the stacker unit of the first printer engine is set to the use mode, Depending on the set print mode so that it is stored in the stacker unit as a paper discharge path, Characterized by automatically controlling the paper discharge path of the first printer engine.

In the control of the paper discharge path of the first printer engine according to the print mode, the stacker control unit controls a use mode of the stacker unit .

  According to the present invention, it is not necessary for the operator to instruct each time whether or not to output to the stacker unit as the discharge path of the first printer engine in correspondence with the print mode.

  Examples of the present invention will be described below. First, the overall configuration of the tandem continuous paper printer of the present invention will be described with reference to FIG.

  The tandem continuous paper printer 100 includes a first printer engine 110, a second printer engine 120, and a printer controller 200.

  The first printer engine 110 includes a paper feeding unit 111, an electrophotographic process 112, a stacker control unit 113, and a stacker unit 114.

Folded paper is set in the paper feeding unit 111. The electrophotographic process 112 performs processing such as printing, transfer, and fixing, and performs printing processing on the paper supplied from the paper feeding unit 111.
The stacker control unit 113 controls the operation of the stacker according to whether the stacker is used or not. Specifically, when the presence of the stacker is specified, the stacker control unit 113 can store the stacker unit 114 in the stacker unit as a use mode, that is, an operable mode and a paper discharge path.

  On the other hand, when “no use” is specified as the stacker use, the stacker control unit 113 sets the stacker unit to the unused mode, that is, the stop mode, and does not pass the stacker unit as a paper discharge path.

  The second printer engine 120 includes a paper feeding unit 121, an electrophotographic process 122, a stacker control unit 123, and a stacker unit 124. The functions of the respective parts 121 to 124 are the same as those of the first printer engine 110.

The printer controller 200 receives print data from the host computer device, performs drawing processing, and then outputs image data to the first printer engine and the second printer engine. The printer controller 200 Keru set the print mode setting unit 2610. The contents will be described later with reference to FIG.

In the duplex printing mode, a sheet reversing unit 150 and a sheet winding unit 160 are added to realize duplex printing using the first printer engine 110 and the second printer engine 120.
The paper reversing unit 150 reverses the paper printed on the first surface of the paper by the first printer engine 110 and outputs the paper to the second printer engine 120. The paper winding unit 160 winds up the paper supplied to the second printer engine 120 via the paper reversing unit 150 and supplies the paper to the electrophotographic process 122 of the second printer engine 120.

  By using the paper reversing unit 150 and the paper winding unit 160 described above, the second printer engine performs printing on the opposite surface of the paper, thereby realizing double-sided printing.

  The sheet printed by the second printer engine 120 is output to the stacker unit 124 or the post-processing device 170 in accordance with an operator instruction.

Next, the configuration and processing contents of the printer controller 200 will be described with reference to FIG.
As shown in FIG. 2, the printer controller 200 includes, as processing units, an upper interface unit 2100, a drawing unit 2300, a print control unit 2500, a user interface control unit 2600, a first engine control unit 2551, and a second engine control unit 2552. Have The printer controller 200 has a page buffer memory unit 2400 and a print mode 2710 for storing various data.

  First, the upper interface unit 2100 will be described.

  The upper interface unit 2100 receives print data from the upper computer apparatus using various interfaces such as a network and a local interface. The physical I / F of the network 400 includes Ethernet (registered trademark), Token-Ring, FDDI (Fiber Distributed Data Interface), ATM (Asynchronous Transfer Mode), ISDN (Integrated Services Digital Network), ADSL, wireless LAN (IEEE802. 11a, IEEE802.11b, IEEE802.11g, etc.), Bluetooth, etc. are used.

  As the local interface, Centronics, SCSI, fiber channel, IEEE1394, USB, RS-232C, RS-422 / 423, etc. are used.

  The drawing unit 2300 receives the print data from the upper interface unit 2100, draws, that is, expands each of the character elements, graphic elements, and image elements constituting the print data into a dot image format in the page buffer memory unit 2400. Write and output. The page buffer memory unit 2400 is configured to store dot image data for a plurality of pages.

  The print control unit 2500 reads the dot image data for a certain page in the page buffer memory unit 2400 and outputs it to the first printer engine 110 or the second printer engine 120. The engine control unit 2552 is instructed. In accordance with this instruction, the first engine control unit 2551 reads the dot image format data for the page in the page buffer memory unit 2400 and outputs it to the first printer engine 110. As a result, printing by the first printer engine 110 is performed.

  The second engine control unit 2552 reads the dot image format data for the page in the page buffer memory unit 2400 and outputs it to the second printer engine 120. As a result, printing by the second printer engine 120 is performed.

  The user interface control unit 2600 accepts an input from the operator from the input unit 420, displays the state in the printer controller 200, and the like. The user interface control unit 2600 is provided with a print mode setting unit 2610. As the print mode 2710 of the tandem continuous paper printer 100, the operator can select either the double-sided print mode, the two-sided single-sided printing mode, the single-sided single-sided printing mode, or the like by the print mode setting unit 2610.

  In accordance with the selected print mode 2710, the used / unused mode of the stacker unit 113 is automatically switched. The discharge path of the first printer engine 110 is controlled by switching between the used / unused mode. Specifically, when the printing mode 2710 is the double-sided printing mode, the stacker unit 114 of the first printer engine 110 is set to an unused mode so that it can go out without passing through the stacker unit 114 as a paper discharge path.

  On the other hand, when the printing mode 2710 is the two-sided single-sided printing mode, the stacker unit 114 of the first printer engine 110 is set to the use mode and stored in the stacker unit 114 as a paper discharge path.

This control is realized by controlling the stacker control unit 113 of the first printer engine 110 from the first engine control unit 2551 using the print mode 2710 as an input.

  This eliminates the need for the operator to instruct whether or not to output to the stacker unit 114 as the paper discharge path of the first printer engine corresponding to the print mode 2710 as in the prior art.

  Next, the hardware configuration of the printer controller 200 will be described with reference to FIG.

  The printer controller 200 includes an MPU 400, a system bus 401, a ROM memory 410, a RAM memory 411, an input unit 420, a display unit 440, a disk controller 431, a secondary storage device 432, a network controller 450, a local I / F adapter 480, a first This is an apparatus comprising an engine I / F adapter 481 and a second engine I / F adapter 482.

  The system bus 401 includes various input / output signals (address signals, data signals, and other control signals) of the MPU 400.

  The MPU 400 performs input / output to / from peripheral devices such as the secondary storage device 432, the input unit 420, the display unit 440, and the network 451, and memories such as the ROM memory 410 and the RAM memory 411 via the system bus 401.

  The secondary storage device 432 is connected to the system bus 401 via the disk controller 431. The system bus 401 of this apparatus is connected to a network 451 such as a LAN or WAN via a network controller 450.

  The physical I / F of the network 451 is Ethernet (registered trademark), Token-Ring, FDDI (Fiber Distributed Data Interface), ATM (Asynchronous Transfer Mode), ISDN (Integrated Services Digital Network), etc. Depending on the type of F, an appropriate hardware logic of the network controller 450 is mounted.

  The local I / F adapter 480 is an adapter for directly connecting the printer controller 200 to a computer. In this case, Centronics, SCSI, fiber channel, IEEE1394, USB, RS-232C, RS-422 / 423, etc. are used as an interface with the computer, and connection is made using a printer local I / F adapter.

  The first engine I / F adapter 481 is an adapter for interfacing with the first printer engine 110. In this case, a video interface is used as an interface with the first printer engine 110. The second engine I / F adapter 482 is an adapter for interfacing with the second printer engine 120. In this case, a video interface is used as an interface with the second printer engine 120.

  The ROM memory 410 stores an initialization startup program (also called an IPL (Initial Program Loading) program) of the printer controller 200 and a part of a character font.

  The RAM memory 411 stores (a) a printer controller control program, (b) remaining character fonts, (c) various buffer memories, (d) various management tables, and the like. Of these, (a) and (b) are stored by being loaded from the secondary storage device 432 by the IPL program. Further, (a) and (b) may not be stored in the RAM memory 711 but may be stored in the ROM memory 410 in advance. Conversely, the ROM memory 410 may store all character fonts in the RAM memory 411 without storing them at all.

  The input unit 420 is used for an operator to input to the printer controller 200. As an input means, a keyboard, a mouse, a switch, a touch panel, or the like can be used.

  The display unit 440 is used to display the printer controller status and setting values. As the display means, a panel such as a liquid crystal or CRT, an LED, or the like can be used.

  The first engine I / F adapter 481 performs input / output processing with the first printer engine 110 in accordance with an instruction from the MPU 400. The second engine I / F adapter 482 performs input / output processing with the second printer engine 120 in accordance with an instruction from the MPU 400.

  The first engine I / F adapter 481 performs processing for reading the contents of the page buffer memory unit 2400 to the first printer engine 110. The second engine I / F adapter 482 performs processing for reading the contents of the page buffer memory unit 2400 to the second printer engine 120. The reading process is performed using a DMA (Direct Memory Access) function built in the first engine I / F adapter 481 and the second engine I / F adapter 482.

  The first engine I / F adapter 481 sends an interrupt signal (for MPU 400) to the MPU 400 when the dot image data for one page of the page has been read for a certain page in the page buffer memory unit 2400. (Part of the bus signal) is asserted to cause the MPU 400 to start the read end interrupt processing of the page buffer memory unit 2400.

  Similarly, the second engine I / F adapter 482 sends an interrupt signal to the MPU 400 when reading of the dot image data for one page of the page buffer page 2400 is completed. (Part of the bus signal for the MPU 400) is asserted to cause the MPU 400 to start reading end interrupt processing of the page buffer memory unit 2400.

  In the above read end interrupt process, the fact that the page that has been read is empty and can be used for drawing the next page is set in the management table related to the page buffer memory unit 2400 and the page buffer memory unit 2400 A task such as the drawing unit 2300 that is waiting for a free page is released from the free state.

  The first engine I / F adapter 481 and the second engine I / F adapter 482 convert the read dot image data into a serial format by using the image transfer signal to and from the printer engine. The data is output to the printer engine 110 or the second printer engine 120. The image transfer signal may be transferred in the parallel format without performing parallel-serial conversion. In addition, before performing the parallel-serial conversion, the compressed format may be converted to an uncompressed format if necessary.

  The first engine I / F adapter 481 and the second engine I / F adapter 482 further use a signal for command transmission and status reception between the corresponding first printer engine 110 and the second printer engine 120 to perform the first operation. Commands for inquiries and instructions to the printer engine 110 and the second printer engine 120 are transmitted, and response statuses are received from the first printer engine 110 and the second printer engine 120.

  The first engine I / F adapter 481 and the second engine I / F adapter 482 can be mounted by mounting a dedicated sub MPU on the adapter or by causing the MPU 400 to perform necessary control processing without mounting. There are two methods, and either can be used.

  The present invention can be applied to a continuous paper printer having a tandem configuration, in which paper discharge from a printer arranged in the preceding stage may or may not be output to a subsequent printer.

1 is a diagram for explaining the overall configuration of a tandem continuous paper printer according to the present invention. FIG. FIG. 3 is a diagram for explaining a configuration of a printer controller according to the present invention. FIG. 2 is a hardware configuration diagram of a printer controller according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Tandem continuous paper printer 110 1st printer engine 120 2nd printer engine 200 Printer controller 113 Stacker control part 114 Stacker control part 2100 High-order interface part 2300 Drawing part 2500 Print control part 2600 User interface control part 2610 Print mode

Claims (2)

First printer engine, the second printer engine, in a tandem continuous paper printer ing from a printer controller,
The first printer engine has a stacker control unit and a stacker unit, and the printer controller has a print mode setting unit for an operator to set a print mode,
When the printing mode set by the operator is the “double-sided printing mode”, the stacker unit of the first printer engine is set to an unused mode, and the sheet discharge path is not passed through the stacker unit outside the first printer engine. In the case of the “two-sided single-sided printing mode”, the set printing mode is set so that the stacker unit of the first printer engine is set to the use mode and is stored in the stacker unit as a paper discharge path. tandem continuous paper printer, characterized by automatically controlling the paper discharge path of the first printer engine in accordance with the. 2. The tandem continuous paper printer according to claim 1, wherein the stacker control unit controls a use mode of the stacker unit in controlling a discharge path of the first printer engine according to a print mode.

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