JP2018006848A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To execute double-side copy processing of a document bundle by an image reading part of a single-side reading type and an image forming part capable of performing double-side printing while avoiding overflow of a built-in storage.SOLUTION: In an image forming apparatus 10, a page organizing part 54 organizes double-side document image data D1 that are obtained by two times of sequential image read processing, into multiple pieces of output page image data D2 that are continued in a preset output page order Dx0. An image forming part 3 is capable of performing double-side print processing. The page organizing part 54 temporarily stores partial data of the double-side document image data D1 in a built-in storage 4, temporarily stores remaining partial data of the double-side document image data D1 through interface parts 6A, 6B and 7 into external storages 60A, 60B and 81x, successively acquires data for one page from multiple storage destinations in accordance with the output page order Dx0, and successively outputs the output page image data D2 corresponding to the acquired data.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an image forming apparatus.

  In general, an image forming apparatus such as a copying machine, a facsimile machine, or a multifunction peripheral includes an ADF (Auto Document Feeder), an image reading unit, and an image forming unit. The ADF conveys a plurality of documents included in a document bundle one by one.

  When the image reading unit is a so-called single-sided reading type, the image reading unit sequentially reads only the images on one side of the plurality of originals while the plurality of originals are conveyed once by the ADF. Outputs document image data.

  The image forming apparatus may include the single-sided reading type image reading unit and the image forming unit capable of double-sided printing processing for forming images on both sides of a sheet. In this case, it is known that the image forming apparatus executes double-sided copy processing of a document bundle (see, for example, Patent Document 1).

  In the double-sided copy processing of the original bundle, the user reverses the original bundle and sets the original bundle twice on the image forming apparatus. Then, the image reading unit executes the image reading process twice for the front side and the back side of the plurality of documents. Further, the image forming unit executes the double-sided printing process based on the double-sided image data of the plurality of documents obtained by the image reading process twice. The image data on both sides of the plurality of documents is temporarily stored in the built-in storage of the image forming apparatus until used for the duplex printing process.

JP 2000-297553 A

  By the way, the image reading unit of the single-sided reading type is often employed in the image forming apparatus that is relatively inexpensive. In such an image forming apparatus, it is not preferable to employ the built-in storage having a large capacity. Therefore, there is a possibility that the internal storage overflows in the double-sided copy processing of the original bundle.

  An object of the present invention is to provide an image forming apparatus capable of executing double-sided copy processing of a document bundle by an image reading unit of a single-sided reading type and an image forming unit capable of duplex printing while avoiding overflow of a built-in storage. is there.

  An image forming apparatus according to an aspect of the present invention includes a document conveying unit, an image reading unit, an order setting unit, a page organization unit, an image forming unit, a built-in storage capable of storing data, and an interface unit. Is provided. The document conveying section can convey a plurality of documents included in a document bundle one by one. The image reading unit can sequentially execute image reading processing for outputting document image data while sequentially reading images on one side of the plurality of documents conveyed by the document conveying unit. The order setting unit sets an output page order that is an output order of images of a plurality of pages in the document bundle. The page organizing unit converts the double-sided document image data, which is the document image data on both sides of the plurality of documents, obtained by the sequential image reading process performed twice in a state where the front and back of the document bundle are different from each other to the output page. It is organized into a plurality of output page image data continuous in order. The image forming unit can perform double-sided printing processing in which images corresponding to the plurality of output page image data obtained from the page organization unit are sequentially formed on both sides of a plurality of sheets. The interface unit relays data transmission between the page organization unit and the external storage. The page organizing unit includes a data accumulation control unit and a page image output unit. The data accumulation control unit temporarily stores a part of the double-sided document image data in the internal storage, and temporarily stores the remaining part of the double-sided document image data in the external storage through the interface unit. Further, information on the storage destination of a part of data corresponding to each of the plurality of page numbers in the double-sided document image data is set in association with each of the plurality of pages in the document bundle. The page image output unit sequentially acquires data for one page in the double-sided document image data from a plurality of storage destinations according to the output page order, and sequentially outputs the output page image data corresponding to the acquired data.

  According to the present invention, it is possible to provide an image forming apparatus capable of executing double-sided copy processing of a document bundle by an image reading unit of a single-sided reading type and an image forming unit capable of double-sided printing while avoiding an overflow of a built-in storage. It becomes possible.

FIG. 1 is a block diagram of an image forming system including an image forming apparatus according to the first embodiment. FIG. 2 is a flowchart illustrating an example of a procedure of data accumulation control in the image forming apparatus according to the first embodiment. FIG. 3 is a flowchart illustrating an example of a procedure of page image output processing in the image forming apparatus according to the first embodiment. FIG. 4 is a diagram illustrating a procedure in which a document bundle is set on the ADF supply tray in the front side pre-reading mode. FIG. 5 is a diagram illustrating a procedure in which a document bundle is set on the ADF supply tray in the back side prefetching mode. FIG. 6 is a diagram illustrating an example of the output page order in the front face look-ahead mode. FIG. 7 is a diagram illustrating an example of the output page order in the back side prefetching mode. FIG. 8 is a diagram schematically illustrating the printing order on a plurality of sheets in the double-sided copy process of the image forming apparatus according to the first embodiment. FIG. 9 is a block diagram of an image forming system including an image forming apparatus according to the second embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In addition, the following embodiment is an example which actualized this invention, Comprising: It does not have the character which limits the technical scope of this invention.

[First Embodiment: Configuration of Image Forming Apparatus 10]
As shown in FIG. 1, an image forming apparatus 10 according to the embodiment includes an ADF 1, an image reading unit 2, an image forming unit 3, a built-in storage 4, a control unit 5, and a first portable storage I / F (Interface) 6A. , A second portable storage I / F 6B, a communication I / F 7, an operation display unit 100, and the like. The operation display unit 100 is a user interface including an operation unit and a display unit.

  The ADF 1 is a device that conveys a plurality of documents 91 included in the document bundle 910 placed on the supply tray 1A one by one from the supply tray 1A to the discharge tray 1B. The ADF 1 includes a document sensor 1C that detects whether or not the document 91 is placed on the supply tray 1A. ADF 1 is an example of a document transport unit.

  The image reading unit 2 is a device that reads an image of the document 91. The image reading unit 2 can also perform processing for outputting document image data while sequentially reading images on one side of a plurality of documents 91 conveyed by the ADF 1. Hereinafter, this process is referred to as a sequential image reading process.

  The image reading unit 2 is a so-called single-sided reading type. Accordingly, while the plurality of documents 91 are conveyed once by the ADF 1, the image reading unit 2 outputs the document image data while sequentially reading only one side image of the plurality of documents 91.

  The image reading unit 2 includes a light source that emits light to the document 91, a line sensor that receives reflected light from the document 91 and outputs the document image data.

  The image forming unit 3 is an apparatus that executes an image forming process for forming an image on the sheet 92 by a predetermined method such as an electrophotographic method or an ink jet method. In the present embodiment, the image forming unit 3 can perform double-sided printing processing.

  The double-sided printing process is a process of sequentially forming images corresponding to a plurality of output page image data D2 on both sides of a plurality of sheets 92. The image forming unit 3 includes a turnback mechanism that reverses the orientation of the sheet 92 during the conveyance when the double-sided printing process is performed.

  As shown in FIG. 8, the image forming unit 3 forms images on both surfaces of the plurality of sheets 92 according to the order of the plurality of pages in the document bundle 910. FIG. 8 shows a printing order on a plurality of sheets 92 in the double-sided copy process, taking as an example a case where the number of originals in the original bundle 910 is three. In FIGS. 5, 6, and 8, G <b> 1 to G <b> 6 are symbols representing images from the first page to the sixth page in the document bundle 910.

  The printing order shown in FIG. 8 is as follows. First, the first page image of the original bundle 910 is formed on the front surface 92X of the first sheet 92, and then the second page image of the original bundle 910 is formed on the back surface 92Y of the first sheet 92. It is formed. Next, the third page image of the original bundle 910 is formed on the front surface 92X of the second sheet 92, and then the fourth page image of the original bundle 910 is formed on the back surface 92Y of the second sheet 92. Formed. Further, the fifth page image of the original bundle 910 is formed on the front surface 92X of the third sheet 92, and finally, the sixth page image of the original bundle 910 is formed on the back surface 92Y of the third sheet 92. It is formed.

  The plurality of output page image data D2 is supplied from the image processing unit 54 of the control unit 5 to the image forming unit 3. For example, when the image forming apparatus 10 executes the double-sided copy process, the ADF 1 and the image reading unit 2 execute the sequential image reading process twice with the front and back sides of the document bundle 910 being different. Thereby, double-sided original image data D1 which is the original image data on both sides of a plurality of originals 91 is obtained.

  Further, in the double-sided copy processing, the image processing unit 54 organizes a plurality of output page image data D2 based on the double-sided document image data D1, and the image forming unit 3 performs the double-sided printing based on the plurality of output page image data D2. Execute the process. The output page order Dx0, which is the output order of images of a plurality of pages in the document bundle 910, is preset by the image processing unit 54.

  In other words, the image processing unit 54 outputs a plurality of continuous double-sided original image data D1 obtained by the sequential sequential image reading processing performed in a state where the front and back sides of the original bundle 910 are different in a preset output page order Dx0. It is organized into output page image data D2.

  In the present embodiment, the double-sided copy process is executed in the front side prefetching mode. As shown in FIG. 4, in the front side pre-reading mode, the original bundle 910 is set on the supply tray 1 </ b> A so that the front side 91 </ b> X of the plurality of originals 91 is read in the first sequential image reading process. This is an operation mode in which the document bundle 910 is set on the supply tray 1A so that the back surfaces 91Y of the plurality of documents 91 are read in the sequential image reading process.

  For example, consider the case where the front side look-ahead mode is employed and the number of originals in the original bundle 910 is three. In this case, as shown in FIG. 6, when the output page order Dx0 is represented by a sequence of numbers arranged in the order of the reading numbers D0 (= 1 to 6) of the six pages in the document bundle 910, the output page order Dx0 is (1 3, 5, 6, 4, 2).

  In other words, in the front side look-ahead mode, the number sequence of the output page order Dx0 corresponding to the reading number D0 is represented by the number of odd pages arranged in ascending order and the number of even pages arranged in descending order.

  In the front side look-ahead mode, only the first reading number D0 in the output page order Dx0 is determined before the number of documents is determined. Further, another odd reading number D0 in the output page order Dx0 is determined each time one page image of the document 91 is read in the first sequential image reading process. Further, all even reading numbers D0 in the output page order Dx0 are determined when the number of documents is determined. The number of originals is determined at least when the first sequential image reading process is completed.

  Note that the back side pre-reading mode is considered as the operation mode different from the front side pre-reading mode. As shown in FIG. 5, in the back side pre-reading mode, the original bundle 910 is set on the supply tray 1A so that the back sides 91Y of the plurality of originals 91 are read in the first sequential image reading process. In this sequential image reading process, the document bundle 910 is set on the supply tray 1A so that the front surface 91X of the plurality of documents 91 is read.

  When the back side prefetching mode is adopted, as shown in FIG. 7, the number sequence of the output page order Dx0 corresponding to the reading number D0 is the number of the even page arranged in descending order, followed by the odd page arranged in ascending order. It is represented by the number. In the back side prefetching mode, all of the output page order Dx0 is determined only after the number of documents is determined.

  However, in both the front side pre-reading mode and the back side pre-reading mode, a part of the double-sided original image data D1 that is output next from the image reading unit 2 is data of odd pages or even numbers in the original bundle 910. It is possible to determine whether the data is a page data.

  For example, the information of the output page order Dx0 is stored in a volatile storage unit such as a RAM (Random Access Memory). The image processing unit 54 is an example of a page organization unit.

  The built-in storage 4 is a computer-readable non-volatile memory. The built-in storage 4 can store various data such as a part of the double-sided document image data D1. For example, a hard disk drive or an SSD (Solid State Drive) is adopted as the internal storage 4.

  The communication I / F 7 is an interface that communicates with another device 10 x in the LAN through a LAN (Local Area Network) 80. In the present embodiment, the other intra-LAN device 10 x is another image forming device 10 within the LAN 80.

  Further, the communication I / F 7 can communicate with the storage server 81 on the Internet 800 through the LAN 80 and the router 801. The storage server 81 is a computer that provides storage services.

  The storage server 81 includes a network storage 81 x that is an example of external storage for the image forming apparatus 10. For example, the network storage 81x may be a hard disk drive.

  The address information of the network storage 81x is set in advance through a setting operation on the operation display unit 100 and stored in the built-in storage 4. The communication I / F 7 executes processing for establishing a communication session with the network storage 81 x using the address information stored in the internal storage 4.

  The communication I / F 7 can record data in the network storage 81x included in the storage server 81 and acquire data from the network storage 81x by communicating with the storage server 81 through the Internet 800. The storage server 81 is an example of another device with which the communication I / F 7 can communicate through a network. The communication I / F 7 is an example of a communication interface unit.

  The image forming apparatus 10 and the storage server 81 that can communicate with each other via the networks 80 and 800 constitute an image forming system.

  The first portable storage I / F 6A is an interface capable of recording data in the first portable storage 60A, which is an external storage detachable from the image forming apparatus 10, and acquiring data from the first portable storage 60A. It is.

  Similarly, the second portable storage I / F 6B records data in the second portable storage 60B, which is an external storage detachable from the image forming apparatus 10, and acquires data from the second portable storage 60B. It is a possible interface.

  The first portable storage I / F 6A and the second portable storage I / F 6B are examples of a portable storage interface unit.

  In the present embodiment, the first portable storage I / F 6A is an interface capable of recording and acquiring data at a higher speed than the second portable storage I / F 6B. For example, the first portable storage I / F 6A may be an interface of an SDXC (Secure Digital eXtended Capacity) memory card, and the second portable storage I / F 6B may be a USB (Universal Serial Bus) interface.

  In the above case, the first portable storage 60A is an SDXC memory card, and the second portable storage 60B is a USB memory.

  In the present embodiment, the first portable storage 60A, the second portable storage 60B, the internal storage 4 of the other apparatus 10x in the LAN, and the network storage 81x of the storage server 81 are examples of external storage.

  Further, the first portable storage I / F 6A, the second portable storage I / F 6B, and the communication I / F 7 transmit data between the image processing unit 54, which is an example of the page organization unit, and the external storage. It is an example of the interface part which relays.

  The control unit 5 executes various calculations, data processing, and various electronic devices included in the image forming apparatus 10. The control unit 5 can exchange data and control signals with the internal storage 4, the first portable storage I / F 6A, the second portable storage I / F 6B, and the communication I / F 7 through the bus.

  The first portable storage 60A and the second portable storage 60B are attached to the image forming apparatus 10 by the user as necessary. For example, it is conceivable that the first portable storage 60A and the second portable storage 60B are the property of the user. The first portable storage 60A and the second portable storage 60B are temporarily used as save destinations for the duplex original image data D1 in the duplex copying process. By the end of the double-sided copy process, the first portable storage 60A and the second portable storage 60B are returned to the state before use.

  The control unit 5 controls the ADF control unit 51 that controls the ADF 1, the image reading control unit 52 that controls the image reading unit 2, the print control unit 53 that controls the image forming unit 3, the image processing unit 54, and the operation display unit 100. A UI (User Interface) control unit 55 and the like.

  For example, the control unit 5 is realized by a processor that executes a program stored in advance in the internal storage 4 or the like.

  Incidentally, the image forming apparatus 10 is a relatively inexpensive apparatus in which the single-sided reading type image reading unit 2 is employed. In such an image forming apparatus 10, it is not preferable to employ the built-in storage 4 having a large capacity. Therefore, in the double-sided copy processing of the original bundle 910, if all the double-sided original image data D1 is temporarily stored in the internal storage 4, the internal storage 4 may overflow.

  However, the image processing unit 54 of the image forming apparatus 10 performs data storage control and page image output processing, which will be described later, when the double-sided copy processing is performed. As a result, the image forming apparatus 10 can execute the double-sided copy processing of the original bundle 910 by the single-sided reading type image reading unit 2 and the double-sided printable image forming unit 3 while avoiding overflow of the internal storage 4. is there.

  In the image forming apparatus 10, the built-in storage 4 is a data recording medium capable of recording data and referencing data at a higher speed than the portable storages 60A and 60B. However, when the portable storages 60A and 60B are mounted on the image forming apparatus 10, the free space of the internal storage 4 is often smaller than the free space of the portable storages 60A and 60B.

  The portable storages 60A and 60B are data recording media capable of recording data and referencing data at a higher speed than the network storage 81x. However, the free capacity of the portable storages 60A and 60B is often smaller than the free capacity of the network storage 81x.

[Image processing unit 54]
The image processing unit 54 includes a data accumulation control unit 541 that executes the data accumulation control, and a page image output unit 542 that executes the page image output process.

  In the data accumulation control, the data accumulation control unit 541 temporarily stores a part of the double-sided document image data D1 in the built-in storage 4, and stores the remaining part of the double-sided document image data D1 in the interface units 6A and 6B. , 7 are temporarily stored in the external storage 60A, 60B, 81x.

  Further, the data accumulation control unit 541 sets storage destination information Dx1 indicating a storage destination of a part of the double-sided document image data D1 corresponding to each of a plurality of pages in the document bundle 910. For example, the data accumulation control unit 541 stores the storage destination information Dx1 in a volatile storage unit such as the RAM.

  On the other hand, the page image output unit 542 sequentially acquires data for one page in the double-sided document image data D1 from a plurality of storage destinations specified by the storage destination information Dx1 according to the output page order Dx0, and outputs corresponding to the acquired data. The page image data D2 is sequentially output. This process is the page image output process. The output page image data D2 is output to the image forming unit 3 through the print control unit 53.

[Data storage control]
Hereinafter, an example of the procedure of the data accumulation control will be described with reference to the flowchart shown in FIG. In the following description, S101, S102,... Represent process identification codes executed by the data accumulation control unit 541.

  In the present embodiment, the data accumulation control unit 541 includes a main control unit 541A, a page capacity assumption unit 541B, a target storage selection unit 541C, a page-by-page accumulation control unit 541D, and an order setting unit 541E. These execute the data accumulation control in the procedure shown in FIG. 2, for example.

  The data storage control unit 541 detects the data storage control when it detects that the double-sided copy processing start operation has been performed on the operation display unit 100 while the document sensor 1C is detecting the document 91. To start. The state in which the document sensor 1C detects the document 91 is a state in which the document 91 is placed on the supply tray 1A of the ADF 1.

  Further, before the first sequential image reading process is started, the page capacity assumption unit 541B sets an initial value of the assumed page capacity Dx2. The assumed page capacity Dx2 is an assumed value of the data capacity necessary for storing data for one page in the double-sided document image data D1.

  For example, it is conceivable that the page capacity assumption unit 541B selects one of a plurality of predetermined candidate values as an initial value of the assumed page capacity Dx2 according to a preset image reading condition. For example, the image reading conditions include image reading resolution, color image and monochrome image distinction, document size, and the like. The image reading condition is set in advance according to an operation on the operation display unit before the double-sided copy process starts. It is also conceivable that the initial value of the assumed page capacity Dx2 is a value set according to a setting operation performed on the operation display unit 100 by the user. The setting of the initial value of the assumed page capacity Dx2 by the page capacity assumption unit 541B is executed before the data accumulation control is started.

<Step S101>
In the data accumulation control, the main control unit 541A of the data accumulation control unit 541 checks the free capacity of each of the plurality of storages 4, 60A, 60B, 81x.

  If the first portable storage 60A is not attached to the image forming apparatus 10, that is, if the first portable storage I / F 6A cannot access the first portable storage 60A, the first portable storage 60A is empty. The capacity is zero. Similarly, when the second portable storage 60B is not attached to the image forming apparatus 10, that is, when the second portable storage I / F 6B cannot access the second portable storage 60B, the second portable storage 60B The empty capacity is zero.

<Step S102>
Further, the main control unit 541A initializes the reading number i. The reading number i is a numerical value that is counted up each time an image for one page of the document 91 is read in the sequential image reading process. In the following description, the data for one page in the double-sided document image data D1 is referred to as document page data D10. The reading number i represents the order in which each of the plurality of document page data D10 is obtained in the two sequential image reading processes.

<Step S103>
Further, the order setting unit 541E sets a part of the output page order Dx0 that can be set at that time. In the first sequential image reading process in the front side pre-reading mode, the order setting unit 541E sets one of the odd output page orders Dx0 based on the reading number i.

  Note that in the second sequential image reading process in the front side pre-reading mode, the order setting unit 541E skips the process of step S103.

<Step S104>
Then, the target storage selection unit 541C selects the i-th target storage. The i-th target storage is a storage for storing the i-th original page data D10. The target storage selection unit 541C selects one of the target storages from among the selection candidates having free capacity equal to or larger than the assumed page capacity Dx2 among the internal storage 4 and the external storages 60A, 60B, 81x.

  For example, when the internal storage 4 is included in the selection candidates, it is conceivable to select the target storage according to the first selection rule shown below. The first selection rule is an external storage as the target storage for temporarily storing the original page data D10 corresponding to the first page of the output page order Dx0 in the double-sided original image data D1 or a plurality of pages set in advance from the top. The rule is that the internal storage 4 is selected with priority over the storages 60A, 60B, 81x.

  By adopting the first selection rule, the time from when the original page data D10 for one page to a plurality of pages from the top of the output page order Dx0 is obtained until the printing process is started is shortened as much as possible. be able to. As a result, the so-called first print time can be shortened as much as possible.

  Further, when one or more of the plurality of external storages 60A, 60B, 81x are included in the selection candidates, it is conceivable to select the target storage according to the second selection rule shown below. The second selection rule is a built-in storage as the target storage for temporarily storing document page data D10 corresponding to pages after a plurality of preset pages from the top of the output page order Dx0 in the double-sided document image data D1. The rule is that the external storages 60A, 60B, 81x are selected with priority over 4.

  For example, the network storage 81x is preferentially selected as the target storage of the document page data D10 corresponding to the pages after 2 pages to 4 pages from the top of the output page order Dx0 in the double-sided document image data D1. I think that.

  By adopting the second selection rule, a process of establishing a communication session with the storage server 81 while the double-sided printing process for two to four pages from the top of the output page order Dx0 is performed. Can be prepared. As a result, it is possible to prevent a waiting time from occurring during the double-sided printing process due to the access time to the network storage 81x becoming a bottleneck.

  Further, when both the portable storages 60A and 60B and the network storage 81x are included in the selection candidates, it is conceivable to select the target storage according to the third selection rule shown below. The third selection rule is a rule that the portable storages 60A and 60B are selected as the target storage in preference to the network storage 81x.

  By adopting the third selection rule, it is possible to reduce the possibility that the access time to the network storage 81x becomes a bottleneck and a waiting time occurs during the double-sided printing process.

  Further, when the portable storages 60A and 60B and the network storage 81x are included in the selection candidates, it is conceivable to select the target storage according to the fourth selection rule shown below. The fourth selection rule selects the portable storages 60A and 60B in preference to the network storage 81x as the target storage of the document page data D10 corresponding to the odd pages in the output page order Dx0, and the output page order Dx0. It is a rule that the network storage 81x is selected with priority over the portable storages 60A and 60B as the target storage of the original page data D10 corresponding to even pages.

  When the two-sided printing is performed in the order shown in FIG. 8, it is usually caused by the turn-back conveyance of the sheet 92 between the end of printing of the odd page and the start of printing of the next even page. A relatively long waiting time is likely to occur. Therefore, by adopting the fourth selection rule, it is possible to perform a preparation process such as a process for establishing a communication session with the storage server 81 while the turnback transfer is being performed. As a result, it is possible to prevent a waiting time from occurring during the double-sided printing process due to the access time to the network storage 81x becoming a bottleneck.

  Further, when the portable storages 60A and 60B and the network storage 81x are included in the selection candidates, it is conceivable to select the target storage according to the fifth selection rule shown below. The fifth selection rule is a rule that the portable storages 60A and 60B are selected as the target storage in preference to the network storage 81x when preset installation area information represents a specific area. The installation area information is information set for a place where the image forming apparatus 10 is used.

  The specific area is an area where the communication environment of the Internet 800 is unstable, and is a predetermined area. By adopting the fifth selection rule, it is possible to prevent a waiting time from occurring during the double-sided printing process due to instability of access to the network storage 81x.

<Step S105>
When the target storage is selected, the target storage selection unit 541C sets information on the selected target storage as storage destination information Dx1 corresponding to the i-th double-sided document image data D1.

<Step S106>
Next, the image reading control unit 52 causes the image reading unit 2 to execute image reading processing for the i-th page. As a result, the i-th original page data D10 is output from the image reading unit 2 to the image processing unit 54.

<Step S107>
Next, the page-by-page accumulation control unit 541D temporarily stores the i-th original page data D10 in the target storage selected in step S104. The page-by-page accumulation control unit 541D continues the process of step S107 until recording of all i-th original page data D10 in the target storage is completed.

  Note that it is possible that the size of the original page data D10 exceeds the free space of the target storage while the page-by-page accumulation control unit 541D is recording the i-th original page data D10 in the target storage. In this case, the main control unit 541A interrupts the data accumulation control and outputs an error notification through the operation display unit 100.

<Step S108>
When the recording of the i-th original page data D10 in the target storage is completed, the page capacity assumption unit 541B executes a process of updating the assumed page capacity Dx2.

  More specifically, each time a single-sided image of a plurality of documents 91 is read, the page capacity assumption unit 541B performs the next operation according to the size of the latest document page data D10 in the duplex document image data D1. The assumed page capacity Dx2 for the page is updated.

  For example, when the latest double-sided document image data D1 is the first page data obtained by the first sequential image reading process, the page capacity assumption unit 541B stores the double-sided document image data D1 of the first page. The assumed page capacity Dx2 for at least the next page is updated according to the size. In this case, the capacity obtained by multiplying the size of the double-sided document image data D1 for the first page by a margin factor larger than 1 is set as the assumed page capacity Dx2 for the second page. It is possible to set.

  Further, when the latest double-sided document image data D1 is the data with the reading number i after the second, the page capacity assumption unit 541B has the margin for the previous assumed page capacity Dx2 and the size of the latest double-sided document image data D1. It is conceivable that the larger one of the capacities obtained by multiplying the coefficients is set as the assumed page capacity Dx2 for the next page.

  On the other hand, the capacity obtained by multiplying the average value of the size of the double-sided document image data D1 from the first page to the latest page by the margin coefficient is assumed as the assumed page capacity Dx2 for the next page. It can be set.

  The page capacity assumption unit 541B sets the capacity obtained by multiplying the size of the first double-sided document image data D1 obtained by the sequential image reading process by the margin coefficient as the assumed page capacity Dx2 for the second and subsequent pages. It is also possible to do. In this case, the assumed page capacity Dx2 is not updated during the sequential image reading process.

<Step S109>
Further, the main control unit 541A updates the free capacity of each of the plurality of storages 4, 60A, 60B, 81x to the latest value.

<Step S110>
Further, the main control unit 541A determines whether or not the next document 91 does not exist in the supply tray 1A according to the detection result of the document sensor 1C.

  If the main control unit 541A determines that the next document 91 exists in the supply tray 1A, the main control unit 541A shifts the process to step S115. As will be described later, after the reading number i is counted up in step S115, the processing from step S103 is repeated.

  On the other hand, when the main control unit 541A determines that the next document 91 does not exist in the supply tray 1A, the main control unit 541A shifts the process to step S111.

<Step S111>
In step S111, the main control unit 541A determines whether or not the first sequential image reading process has been completed. If the main controller 541A determines that the first sequential image reading process has been completed, the process proceeds to step S112.

  On the other hand, when it is determined that the second sequential image reading process has been completed, the main control unit 541A ends the data accumulation control.

<Step S112>
In step S112, the main control unit 541A sets the reading number i at that time as the number of documents. That is, when the first sequential image reading process is completed, the number of originals is determined. Twice the number of originals is the total number of pages in the original bundle 910.

<Step S113>
Further, the order setting unit 541E sets the remaining output page order Dx0 that has not been set yet. That is, when the first sequential image reading process in the front side pre-reading mode is completed, the order setting unit 541E sets all of the even output page orders Dx0 based on the number of documents. The order setting unit 541E shifts the process from step S113 to step S114.

<Step S114>
Further, the main control unit 541A waits until the document sensor 1C detects the document 91, that is, until the document bundle 910 that has been turned upside down is placed on the supply tray 1A. When the document bundle 910 is placed on the supply tray 1A, the main control unit 541A shifts the process to step S115.

<Step S115>
In step S115, the main control unit 541A counts up the reading number i as described above. Thereafter, the main control unit 541A shifts the process to step S103. Accordingly, the second sequential image reading process starts (S106). Further, the remaining half of the double-sided document image data D1 output from the image reading unit 2 is recorded in one or more of the internal storage 4 and the external storages 60A, 60B, 81x (S107).

[Page image output processing]
Hereinafter, an example of the procedure of the page image output process will be described with reference to the flowchart shown in FIG. In the following description, S201, S202,... Represent identification codes of steps executed by the page image output unit 542. The page image output process is executed in parallel with the data accumulation control.

<Step S201>
First, the page image output unit 542 initializes the output number j. The output number j is a numerical value that is counted up each time output page image data D2 corresponding to the document page data D10 is output in accordance with the output page order Dx0. The output number j represents the order in which the page image output unit 542 organizes and outputs each of the plurality of output page image data D2 from the double-sided document image data D1.

<Step S202>
Next, the page image output unit 542 waits until the document page data D10 corresponding to the j-th page in the output page order Dx0 is recorded in any of the plurality of storages 4, 60A, 60B, 81x. At that time, based on the storage destination information Dx1, the page image output unit 542 has document page data D10 corresponding to the jth page in the output page order Dx0 in any one of the plurality of storages 4, 60A, 60B, 81x. It is determined whether or not to do.

  Then, when the page image output unit 542 confirms that the document page data D10 corresponding to the j-th page in the output page order Dx0 exists in any of the plurality of storages 4, 60A, 60B, 81x, the page image output unit 542 proceeds to the next process. The process proceeds to step S203.

<Step S203>
In step S203, the page image output unit 542 acquires document page data D10 corresponding to the j-th page in the output page order Dx0 from any one of the plurality of storages 4, 60A, 60B, and 81x. The acquisition destination storage is specified by the storage destination information Dx1.

  In step S203, the page image output unit 542 deletes the acquired document page data D10 from the acquisition destination storage. For example, when the storage from which the original page data D10 is acquired is the network storage 81x, the page image output unit 542 requests the storage server 81 to delete the acquired original page data D10.

<Step S204>
Further, the page image output unit 542 converts the original page data D10 corresponding to the acquired j-th page in the output page order Dx0 into output page image data D2 for image formation, and the output page image data D2 is printed. The image is output to the image forming unit 3 through the control unit 53.

  The print control unit 53 causes the image forming unit 3 to execute double-sided printing processing based on a plurality of output page image data D2 sequentially output from the page image output unit 542.

<Step S205>
Next, the page image output unit 542 determines whether or not the output number j has reached twice the number of documents. If the page image output unit 542 determines that the output number j has not reached twice the number of documents, the page image output unit 542 shifts the process to step S206. On the other hand, when the page image output unit 542 determines that the output number j has reached twice the number of originals, the page image output unit 542 ends the page image output process.

<Step S206>
In step S206, the page image output unit 542 counts up the output number j, and then shifts the processing to step S202.

  As described above, the page image output unit 542 sequentially acquires one page of document page data D10 in the double-sided document image data D1 from a plurality of storage destinations according to the output page order Dx0 (S203), and acquires the acquired data. Corresponding output page image data D2 is sequentially output (S204).

  If the image forming apparatus 10 is employed, it is possible to execute the duplex copy processing of the bundle of documents 910 by the single-side reading type image reading unit 2 and the image forming unit 3 capable of duplex printing while avoiding the overflow of the internal storage 4. is there.

  Further, the order setting unit 541E of the image processing unit 54 sets the output page order Dx0 according to the number of documents counted when the first sequential image reading process is performed (S112 in FIG. 2). This eliminates the need for the user to grasp and input the number of documents in advance.

  Further, the order setting unit 541E can be set each time an image for one page of the document 91 is read when the first sequential image reading process is performed in the front side pre-reading mode. One of the odd output page orders Dx0 is set (S103).

  In the above case, in the process of step S104 in FIG. 2, a part of the output page order Dx0 that is information useful for selecting the target storage is determined early. As a result, the target storage can be selected more quickly.

  Further, the target storage selection unit 541C selects one target storage from among the selection candidates having a free capacity equal to or larger than the assumed page capacity Dx2 among the plurality of storages 4, 60A, 60B, 81x. Therefore, it is possible to reduce the possibility that the target storage will overflow during the recording of data to the target storage.

  Further, the page capacity assumption unit 541B updates the assumed page capacity Dx2 for the next page according to the size of the original page data D10 obtained each time one single-sided image of the plurality of originals 91 is read.

  By updating the assumed page capacity Dx2 according to the above results, the possibility of overflow of the target storage can be reduced while using the internal storage 4 and the portable storages 60A and 60B that can be accessed at high speed without waste. .

[Second Embodiment]
Next, an image forming apparatus 10A according to the second embodiment will be described with reference to FIG. The image forming apparatus 10A has a configuration in which a FAX modem 70 is added to the image forming apparatus 10 shown in FIG. The FAX modem 70 can communicate with other facsimile apparatuses 82 through the public line network 802.

  The image forming apparatus 10A can execute a duplex FAX transmission process. In the duplex FAX transmission process, the ADF 1 and the image reading unit 2 execute the sequential image reading process twice with the front and back sides of the document bundle 910 being different.

  Further, in the duplex FAX transmission process, the data accumulation control unit 541 of the image processing unit 54 executes the data accumulation control (see FIG. 2). Further, in the duplex FAX transmission process, the page image output unit 542 sequentially outputs a plurality of output page image data D2 as in the page image output process (see FIG. 3). However, the output destination of the plurality of output page image data D2 in the double-sided FAX transmission process is the FAX modem 70.

  The FAX modem 70 sequentially transmits a plurality of output page image data D2 obtained from the page image output unit 542 of the image processing unit 54 to another facsimile apparatus 82 through the public line network 802. The FAX modem 70 is an example of a communication unit.

  If the image forming apparatus 10A is employed, the double-sided FAX transmission processing of the original bundle 910 by the single-sided reading type image reading unit 2 and the FAX modem 70 capable of communicating with other apparatuses while avoiding the overflow of the internal storage 4 is performed. It is feasible.

[Application example]
When the above-described image forming apparatuses 10 and 10A execute the double-sided copy processing, the internal storage 4 of the other intra-LAN apparatus 10x that is not executing a job is stored in the external storage for storing the original page data D10. Use as one is also conceivable.

  Similarly, when the image forming apparatus 10A executes the duplex FAX transmission process, the internal storage 4 of the other apparatus 10x in the LAN that is not executing a job is used as one of external storages for storing the document page data D10. It can also be used.

  In addition, in the image forming apparatuses 10 and 10A, when the start operation of the double-sided copy process is performed on the operation display unit 100, the UI control unit 55 sends a predetermined storage attachment notification to the operation display unit 100. It is also possible to output through The storage attachment notification is a notification that prompts the user to attach at least one of the first portable storage 60A and the second portable storage 60B to the image forming apparatus 10.

  In the image forming apparatuses 10 and 10 </ b> A, the UI control unit 55 may have a function of selecting one of the front side prefetching mode and the back side prefetching mode in accordance with a selection operation on the operation display unit 100.

  As shown in FIG. 7, in the back side prefetching mode, when the original page data D10 of the first page in the second sequential image reading process is obtained, printing on both sides of the first sheet 92 is performed. Processing can be executed. Therefore, when the number of documents is large, the start and end of the duplex printing process can be accelerated.

  In the image forming apparatuses 10 and 10 </ b> A, the turnback mechanism of the image forming unit 3 executes sheet batch processing for forming an image on a new sheet 92 in a state where a plurality of sheets 92 are kept on the turnback path. It may be possible.

  In the sheet batch process, the double-sided printing process may be performed in an order different from the order of the pages in the document bundle 910, so that the efficient double-sided printing process without wasteful waiting time may be possible. . Even in that case, the plurality of sheets 92 constituting the printed matter are discharged onto the sheet discharge tray in a state in which the original bundle 910 is arranged in the page order.

  Therefore, when the duplex printing process is performed in the sheet batch process, the output page order Dx0 may be set to a different order from the page order in the document bundle 910.

  The image forming apparatus according to the present invention can be freely combined with the above-described embodiments and application examples, or can be appropriately modified within the scope of the invention described in each claim. Alternatively, it may be configured by omitting a part.

1: ADF (document feeder)
1A: supply tray 1B: discharge tray 1C: document sensor 2: image reading unit 3: image forming unit 4: built-in storage 5: control unit 6A: first portable storage I / F (interface unit)
6B: Second portable storage I / F (interface section)
7: Communication I / F (interface part)
10, 10A: Image forming apparatus 10x: Other device 51 in LAN: ADF control unit 52: Image reading control unit 53: Print control unit 54: Image processing unit 55: UI control unit 60A: First portable storage 60B: Second Portable storage 70: FAX modem 81: Storage server 81x: Network storage 82: Facsimile device 91: Document 91X: Document front surface 91Y: Document back surface 92: Sheet 92X: Sheet front surface 92Y: Sheet back surface 100 : Operation display unit 541: Data accumulation control unit (page organization unit)
541A: Main control unit 541B: Page capacity assumption unit 541C: Target storage selection unit 541D: Per-page accumulation control unit 541E: Order setting unit 542: Page image output unit (page organization unit)
800: Internet 801: Router 802: Public network 910: Document bundle D0: Reading number D1: Duplex document image data D10: Document page data D2: Output page image data Dx0: Output page order Dx1: Storage destination information Dx2: Assumed page capacity

Claims (10)

A document conveying section capable of conveying a plurality of documents included in a document bundle one by one;
An image reading unit capable of executing a sequential image reading process of outputting document image data while sequentially reading images on one side of the plurality of documents conveyed by the document conveying unit;
An order setting unit for setting an output page order that is an output order of images of a plurality of pages in the document bundle;
The double-sided original image data, which is the original image data on both sides of the plurality of originals obtained by the sequential image reading process performed twice with the front and back sides of the original bundle being different, A page organization section that organizes output page image data;
An image forming unit capable of double-sided printing processing for sequentially forming images corresponding to the plurality of output page image data obtained from the page organization unit on both sides of a plurality of sheets;
Built-in storage that can store data
An interface unit that relays transmission of data between the page organization unit and the external storage,
The page organization part
A part of the double-sided original image data is temporarily stored in the internal storage, and the remaining part of the double-sided original image data is temporarily stored in the external storage through the interface unit. A data accumulation control unit for setting information of a storage destination of a part of the double-sided document image data corresponding to each of a plurality of pages;
A page image output unit that sequentially acquires data for one page in the double-sided document image data from a plurality of storage destinations in accordance with the output page order, and sequentially outputs the output page image data corresponding to the acquired data. Forming equipment.   The image forming apparatus according to claim 1, wherein the order setting unit sets the output page order according to the number of documents counted when the first sequential image reading process is performed. A page capacity assumption unit that sets an assumed page capacity that is an assumed value of the data capacity required to store one page of data in the double-sided document image data;
The data accumulation control unit
Each time a single-sided image on the plurality of originals is read, one target storage is selected from the selection candidates having a free capacity equal to or larger than the assumed page capacity among the internal storage and the external storage. A target storage selector,
The image forming apparatus according to claim 1, further comprising: a page-by-page accumulation control unit that temporarily stores data for one page in the double-sided document image data in the selected target storage.   The page capacity assumption unit sets an initial value of the assumed page capacity before the first sequential image reading process is started, and is obtained by the first sequential image reading process in the double-sided document image data. The image forming apparatus according to claim 3, wherein at least the assumed page capacity for the next page is updated in accordance with a size of data for the first page to be obtained.   The page capacity assumption unit includes the assumed page for the next page in accordance with the size of data for one page in the double-sided original image data obtained each time one single-sided image is read from the plurality of originals. The image forming apparatus according to claim 4, wherein the capacity is updated.   The target storage selection unit temporarily stores a part of data corresponding to a first page of the output page order in the double-sided document image data or a plurality of pages set in advance from the top as the target storage. The image forming apparatus according to claim 3, wherein the internal storage is selected in preference to an external storage.   The target storage selection unit includes the internal storage as the target storage for temporarily storing a part of data corresponding to pages after a plurality of pages set in advance from the top of the output page order in the double-sided document image data. The image forming apparatus according to claim 3, wherein the external storage is selected with priority over storage. The interface unit is
A portable storage interface unit capable of recording data in the portable storage which is the external storage detachable from the image forming apparatus and acquiring data from the portable storage;
A communication interface unit capable of recording data to and acquiring data from the network storage, which is the external storage included in the other device, by communicating with the other device through a network;
The target storage selection unit selects the portable storage in preference to the network storage as the target storage of a part of data corresponding to odd pages in the output page order in the double-sided document image data, and 8. The network storage according to claim 3, wherein the network storage is selected in preference to the portable storage as the target storage of a part of data corresponding to the even pages in the output page order. 9. Image forming apparatus.   The target storage selection unit selects the portable storage as the target storage in preference to the network storage when the installation area information preset for the usage location of the device represents a specific area. Item 9. The image forming apparatus according to Item 8.   The image forming apparatus according to claim 1, further comprising a communication unit that sequentially transmits the plurality of output page image data obtained from the page organization unit to another device.

Images