IMAGE FORMING APPARATUS

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2016-173800, filed on Sep. 6, 2016, the entire contents of which are incorporated herein by reference.

FIELD

An embodiment to be described here generally relates to an image forming apparatus.

BACKGROUND

Sheets with wireless tags (RF (Radio Frequency) tags) are known. An apparatus that forms an image on a sheet with a wireless tag by using an electrophotographic method, writes information in the wireless tag, and reads information from the wireless tag, is known.

A wireless tag may sometimes be broken since, in the electrophotographic method, a fixing unit for fixing a toner image heats and presses the wireless tag. A sheet with the broken wireless tag is discharged to a dedicated tray for sheets with broken wireless tags. Accordingly, when images of a plurality of pages are formed on a plurality of sheets, a page is skipped in the sheets discharged to a normal tray if a wireless tag is broken.

Further, when an image, which is formed on the sheet with the broken wireless tag, is formed again on a new sheet and the new sheet is discharged to the normal tray, the page sequence of the sheets discharged to the normal tray is disordered. For example, it is assumed that the image of the 2nd page is formed on a sheet, the wireless tag of this sheet is broken, the image of the 3rd page is formed on a sheet, the wireless tag of this sheet is unbroken, and this sheet with the unbroken wireless tag is discharged to the normal tray. Then, since the wireless tag of the sheet, on which the image of the 2nd page is formed, is broken, the image of the 2nd page is formed again on a new sheet, and the new sheet is discharged. As a result, the sheet on which the image of the 1st page is formed, the sheet on which the image of the 3rd page is formed, and the sheet on which the image of the 2nd page is formed are stacked in this order on the normal tray.

As described above, in the prior art, a page is skipped in the sheets discharged to a normal tray, and the page sequence is disordered.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view showing an image forming apparatus of an embodiment.

FIG. 2 is a block diagram showing the image forming apparatus of the embodiment.

FIG. 3 is a flowchart showing the printing process of the image forming apparatus of the embodiment.

FIG. 4 is a flowchart showing the sequence-nonguaranteed high-speed process of the image forming apparatus of the embodiment.

FIG. 5 is a flowchart showing the process executed by the wireless tag unit of the embodiment.

FIG. 6 is a diagram showing a memory map of the image forming apparatus of the embodiment.

FIG. 7 is a flowchart showing the image data decompressing process of the image forming apparatus of the embodiment.

FIG. 8 is a flowchart showing the sequence-guaranteed low-speed process of the image forming apparatus of the embodiment.

FIG. 9 is a flowchart showing the process executed by the wireless tag unit of the embodiment.

FIG. 10 is a flowchart showing the sequence-guaranteed high-speed process of the image forming apparatus of the embodiment.

FIG. 11 is a flowchart showing the re-printing process of the image forming apparatus of the embodiment.

DETAILED DESCRIPTION

According to an embodiment, an image forming apparatus includes an image forming unit, a writing unit, and a processor. The image forming unit forms images on sheets conveyed in sequence. The writing unit writes information in a wireless tag of a sheet, on which an image is formed by the image forming unit. The processor controls image-formation by the image forming unit to form a first image on a first sheet. The processor suspends image-formation of a second image, the second image being next to the first image, until the processor recognizes whether the writing unit succeeds in or does not succeed in writing the information in the wireless tag of the first sheet, on which the first image is formed. The processor forms the first image again on a second sheet, when the processor recognizes that the writing unit does not succeed in writing the information in the wireless tag of the first sheet, on which the first image is formed. The processor starts image-formation of the second image to form the second image on the second sheet, when the processor recognizes that the writing unit succeeds in writing the information in the wireless tag of the first sheet, on which the first image is formed.

According to the embodiment, it is possible to provide an image forming apparatus, with which no page is skipped in discharged sheets and the page sequence is not disordered. Hereinafter, an image forming apparatus of an embodiment will be described with reference to the drawings. In the drawings, the same reference symbols indicate the same or similar hardware/software.

FIG. 1 is a side view showing the image forming apparatus 10 of the embodiment.

As shown in FIG. 1, the image forming apparatus 10 includes the control panel 13, the wireless tag unit 200, and the printer 18. The printer 18 includes the processor 51, the paper cassettes 16a, 16b, and the like. The processor 51 controls the control panel 13, the wireless tag unit 200, and the printer 18. The processor 51 controls conveyance of sheets in the printer 18. In the present embodiment, a wireless tag is, for example, an RF (Radio Frequency) tag.

The control panel 13 includes input keys and a display. For example, the input keys accept input from a user. For example, the display is a touch panel-type display. The display accepts input from a user, and displays information for the user.

The paper cassette 16a accommodates sheets with wireless tags (hereinafter referred to as “wireless tag sheet”.). The paper cassette 16b accommodates normal sheets without wireless tags (hereinafter referred to as “normal sheet”.). Each of the paper cassettes 16a, 16b includes, for example, a cassette that accommodates sheets, and a paper-feeding mechanism. The paper-feeding mechanism feeds sheets of paper one by one from the cassette, and conveys the fed sheets to the conveying path 33a.

The printer 18 forms an image. For example, the printer forms an image on the basis of image data. In the following description, to form image is also referred to as printing. The printer 18 includes the intermediate transfer belt 21. The driven roller 41, the backup roller 40, and the like of the printer 18 support the intermediate transfer belt 21. The printer 18 rotates the intermediate transfer belt 21 in the direction of the arrow “m”.

The printer 18 includes the four image forming stations 22Y, 22M, 22C, and 22K. The image forming stations 22Y, 22M, 22C, and 22K form images of Y (yellow), M (magenta), C (cyan), and K (black), respectively. The image forming stations 22Y, 22M, 22C, and 22K are arrayed side by side in the rotation direction of the intermediate transfer belt 21 below the intermediate transfer belt 21.

Hereinafter, for an example, the image forming station 22Y for Y (yellow) will be described out of the image forming stations 22Y, 22M, 22C, and 22K. Note that the structure of each of the image forming stations 22M, 22C, and 22K is similar to the structure of the image forming station 22Y, and therefore will not be described in detail.

The image forming station 22Y includes the electrostatic charger 26, the exposure scanning head 27, the developing device 28, and the photosensitive cleaner 29. The electrostatic charger 26, the exposure scanning head 27, the developing device 28, and the photosensitive cleaner 29 are arranged around the photosensitive drum 24, which rotates in the direction of the arrow “n”.

The image forming station 22Y includes the primary transfer roller 30. The primary transfer roller 30 faces the photosensitive drum 24, the intermediate transfer belt 21 being therebetween.

In the image forming station 22Y, the electrostatic charger 26 electrostatically-charges the photosensitive drum 24, and then the exposure scanning head 27 exposes the photosensitive drum 24 to light. In the image forming station 22Y, an electrostatic latent image is formed on the photosensitive drum 24. The developing device 28 develops the electrostatic latent image on the photosensitive drum 24 with two-component developer including toner and carrier to thereby form a toner image on the photosensitive drum 24.

The primary transfer roller 30 primarily transfers the toner image formed on the photosensitive drum 24 to the intermediate transfer belt 21. In the image forming stations 22Y, 22M, 22C, and 22K, the primary transfer rollers 30 form a color toner image on the intermediate transfer belt 21. The color toner image is formed by overlaying a Y (yellow) toner image, a M (magenta) toner image, a C (cyan) toner image, and a K (black) toner image in sequence. After the primary transfer, the photosensitive cleaner 29 removes the remaining toner from the photosensitive drum 24.

The printer 18 includes the secondary transfer roller 32. The secondary transfer roller 32 faces the backup roller 40, the intermediate transfer belt 21 being therebetween. The secondary transfer roller 32 secondarily transfers the full-color toner image on the intermediate transfer belt 21 to a sheet. In other words, the image forming unit including the image forming stations 22Y, 22M, 22C, and 22K, the primary transfer roller 30, the intermediate transfer belt 21, and the secondary transfer roller 32 forms the image on the sheet.

The printer 18 includes the plurality of conveying paths 33a, 33b, and 33c. The conveying path 33a is a conveying path from the junction point 44a to the branch-off point 44b. The conveying path 33b is a conveying path passing through the duplex printer device 38, i.e., a conveying path from the branch-off point 44b to the junction point 44a. The conveying path 33c is a conveying path from the branch-off point 44b to the switcher unit 202 of the wireless tag unit 200. Each of the conveying paths 33a to 33c includes, for example, guide members that guide a sheet, a conveying roller that conveys the sheet, and a motor that drives a conveying roller.

The processor 51 controls conveyance of a sheet via the conveying paths 33a to 33c and conveyance of a sheet from the above-mentioned paper cassettes 16a, 16b. For example, the processor 51 conveys a sheet fed from the paper cassette 16a or 16b to the conveying path 33a, and controls the fixer device 34 to fix a toner image to thereby fix an image on a sheet. The processor 51 conveys the sheet, on which the image is formed, to the conveying path 33c to thereby discharge the sheet.

When the printer 18 executes duplex printing, the processor 51 conveys a sheet, an image being formed on its front face, to the conveying path 33c. After the whole sheet passes through the branch-off point 44b, the processor 51 conveys the sheet to the conveying path 33b (switchback). After that, the processor 51 conveys the sheet to the junction point 44a via the conveying path in the duplex printer device 38, and conveys the sheet to the conveying path 33a. Then the processor 51 controls the fixer device 34 to fix a toner image to thereby form an image on the back face of the sheet. The processor 51 conveys the sheet, the image being formed on its back face, to the conveying path 33c to thereby discharge the sheet.

In the present example, the conveying path 33b is also used as a conveying path for evacuating a sheet. Specifically, the processor 51 firstly conveys a sheet, an image being formed on its front face, to the conveying path 33c. After the whole sheet passes through the branch-off point 44b, the processor 51 conveys the sheet to the conveying path 33b (switchback), and conveys the sheet until the whole sheet passes through the branch-off point 44b. As a result, the sheet is evacuated from the conveying path 33a, and the processor 51 is thus capable of conveying another sheet from the conveying path 33a to the conveying path 33c. When discharging the evacuated sheet, different from the way of duplex printing, the processor 51 conveys the sheet to the branch-off point 44b, and then conveys the sheet straight to the conveying path 33c to thereby discharge the sheet. In the following description, “normal conveyance” means to convey a sheet, on which an image is formed, from the conveying path 33a to the conveying path 33c without evacuating the sheet. Further, “evacuation conveyance” means to convey a sheet, on which an image is formed, for evacuating the sheet.

The wireless tag unit 200 includes the control unit 201, the switcher unit 202, the reading unit 203, and the writing unit 204. In the present example, the wireless tag unit 200 is detachable from the printer 18.

The control unit 201 includes a processing unit (processor unit) and a memory unit. The control unit 201 controls the reading unit 203 and the writing unit 204. Further, the control unit 201 controls the switcher unit 202 under control of the processor 51 that conveys a sheet. Further, the control unit 201 is capable of communicating with the processor 51. The control unit 201 is capable of detecting that a sheet is conveyed to the wireless tag unit 200.

The writing unit 204 writes information (hereinafter also referred to as “tag data”) in a wireless tag of a wireless tag sheet on which an image is formed. The reading unit 203 reads the tag data from the wireless tag. The control unit 201 determines whether the writing unit 204 succeeds in or does not succeed in writing tag data on the basis of the tag data read from the wireless tag by the reading unit 203. When the control unit 201 determines that the writing unit 204 succeeds in writing tag data in a tag of a sheet, the switcher unit 202 discharges the sheet to the OK tray 20a. When the control unit 201 determines that the writing unit 204 does not succeed in writing tag data in a tag of a sheet, the switcher unit 202 discharges the sheet to the NG tray 20b. Note that all the normal sheets are discharged to the OK tray 20a after printing.

The above-mentioned image forming apparatus 10 is not limited to the so-called tandem type image forming unit. For example, the image forming unit may form toner images of respective colors on one photosensitive drum, and the toner images may be transferred directly from the photosensitive drum 24 to a sheet. Further, the number of the developing devices 28 of the image forming unit is not limited.

FIG. 2 is a functional block diagram showing the image forming apparatus 10. The image forming apparatus 10 includes the controller 100, the control panel 13, the printer 18, and the wireless tag unit 200. The controller 100 includes the processor 51 and the memory device 52. The processor 51 executes an image processing program stored in the memory device 52 to thereby control the control panel 13 and the wireless tag unit 200. Further, the processor 51 controls conveyance of sheets from the paper cassettes and conveyance of sheets via the conveying paths 33a, 33b, and 33c depending on processing modes (described later). Further, the processor 51 controls the control unit 201 to thereby control the switcher unit 202 to discharge sheets.

The processor 51 is a computer device. The processor 51 includes, for example, a CPU (Central Processing Unit), an ASIC (Application Specific Integrated Circuit), and the like. The memory device 52 includes a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The processor 51 loads a control program, which is stored in a ROM, in a RAM and executes the control program to thereby operate as the data receiving unit 53 and the image data decompressing unit 54. The data receiving unit 53 receives data (for example, data described in page description language, etc.) indicating an image to be printed from a host such as a PC (Personal Computer), and stores the received data in the memory device 52. The image data decompressing unit 54, for example, decides a print profile on the basis of the data stored in the memory device 52 by the data receiving unit 53. The image data decompressing unit 54 decompresses the data stored in the memory device 52 on the basis of the decided print profile and the like to thereby obtain data (for example, rasterized data, etc.) printable by the printer 18, and stores the printable data in the memory device 52.

As described above, the printer 18 includes the fixer device 34, the secondary transfer roller 32, and the developing device 28. The printer 18 forms an image on a sheet on the basis of the data stored in the memory device 52 by the image data decompressing unit 54. Note that all or part of the functions of the image forming apparatus 10 may be realized by using hardware such as an ASIC, a PLD (Programmable Logic Device), and an FPGA (Field-Programmable Gate Array). The image processing program may be stored in a non-transitory computer readable recording medium. Examples of the non-transitory computer readable recording medium include memory devices such as a flexible disk, a magneto-optical disk, a ROM, a mobile medium such as a CD-ROM, and a hard disk built in a computer system. The image processing program may be sent via electronic communication lines.

In the present example, the image forming apparatus 10 (the processor 51) executes four processing modes of image forming process. According to one of the four processing modes, i.e., the normal printing mode, an image is formed on a normal sheet, or an image is formed on a wireless tag sheet but no tag data is written in a wireless tag. According to the other three processing modes, i.e., the sequence-nonguaranteed high-speed mode, the sequence-guaranteed low-speed mode, and the sequence-guaranteed high-speed mode, an image is formed on a wireless tag sheet and tag data is written in a wireless tag.

According to the sequence-nonguaranteed high-speed mode, even if the printer fails to write tag data in a wireless tag, re-printing (described later) is not executed. Therefore, for example, if the printer 18 prints images of 10 pages on sheets and fails to write tag data in a wireless tag on the 5th-page sheet, the sheets, on which images of 1st to 4th and 6th to 10th pages are printed, are stacked on the OK tray 20a.

As described above, according to the sequence-nonguaranteed high-speed mode, sequence of pages are nonguaranteed, but printing can be executed at a high speed since sequence-guaranteed page control is not executed.

According to the sequence-guaranteed low-speed mode and the sequence-guaranteed high-speed mode, sequence of pages are guaranteed but the printing speed is different. The above-mentioned four processing modes are selected by using the control panel 13 or the like. The processor 51 stores the selected processing mode in the memory device 52. Hereinafter, the image forming process of the present example will be described with reference to the flowcharts.

FIG. 3 is a flowchart showing the image forming process of the image forming apparatus 10. In FIG. 3, when the processor 51 starts the image forming process, the processor 51 determines whether selected processing mode is the normal printing mode or not with reference to the memory device 52 (ACT101). When the processing mode is the normal printing mode (ACT101: YES), the processor 51 executes the normal printing process (ACT102), and finishes this process. Since the normal printing process is a conventional process, description thereof will be omitted.

When the processing mode is not the normal printing mode (ACT101: NO), the processor 51 determines whether the selected processing mode is the sequence-nonguaranteed high-speed mode or not (ACT103). When the processing mode is the sequence-nonguaranteed high-speed mode (ACT102: YES), the processor 51 executes the sequence-nonguaranteed high-speed process (ACT104), and finishes this process. The sequence-nonguaranteed high-speed process will be described later in detail.

When the processing mode is not the sequence-nonguaranteed high-speed mode (ACT103: NO), the processor 51 determines whether the selected processing mode is the sequence-guaranteed low-speed mode or not (ACT105). When the processing mode is the sequence-guaranteed low-speed mode (ACT105: YES), the processor 51 executes the sequence-guaranteed low-speed process (ACT106), and finishes this process. The sequence-guaranteed low-speed process will be described later in detail.

When the processing mode is not the sequence-guaranteed low-speed mode (ACT105: NO), the processor 51 executes the sequence-guaranteed high-speed process (ACT107), and finishes this process. The sequence-guaranteed high-speed process will be described later in detail.

FIG. 4 is a flowchart showing the flow of the sequence-nonguaranteed high-speed process. In FIG. 4, the processor 51 initializes the counter “k” for counting the page number, i.e., sets “1” (ACT201). The processor 51 starts to form an image of the “k”th page (“k”th image) (ACT202). When the processor 51 finishes forming the image of the “k”th page (ACT203: YES), the processor 51 conveys the sheet, on which the image is formed, in the normal way (ACT204).

The processor 51 notifies the wireless tag unit 200 of tag data to be written in the wireless tag of the “k”th-page sheet (ACT205). The processor 51 increments the counter “k” (ACT206). The processor 51 determines whether there is image data of the “k”th page or not (ACT207). When there is image data of the “k”th page (ACT207: YES), the processor 51 returns to ACT202. When there is no image data of the “k”th page (ACT207: NO), the processor 51 finishes this process.

In this way, according to the sequence-nonguaranteed high-speed mode, printing can be executed at a high speed since sequence-guaranteed page control is not executed.

FIG. 5 is a flowchart showing the flow of the tag unit process executed by the wireless tag unit 200 in the sequence-nonguaranteed high-speed process. In FIG. 5, when the control unit 201 is notified of tag data (ACT301: YES), the control unit 201 stores the notified tag data in the memory unit (ACT302).

When the control unit 201 detects that a sheet is conveyed to the wireless tag unit 200 (ACT303: YES), the control unit 201 controls the writing unit 204 to write the stored tag data in the wireless tag (ACT304). The control unit 201 controls the reading unit 203 to read the tag data (ACT305).

The control unit 201 determines whether the writing unit 204 succeeds in or does not succeed in writing the tag data (ACT306). The control unit 201 determines that the writing unit 204 succeeds in writing the tag data when the tag data read by the reading unit 203 is the same as the stored tag data.

When the writing unit 204 succeeds in writing the tag data (ACT306: YES), the control unit 201 controls the switcher unit 202 to discharge the sheet to the OK tray 20a (ACT307), and finishes this process. When the writing unit 204 does not succeed in writing the tag data (ACT306: NO), the control unit 201 controls the switcher unit 202 to discharge the sheet to the NG tray 20b (ACT308), and finishes this process.

Next, the sequence-guaranteed low-speed process will be described. In the present embodiment, the memory device 52 (for example, RAM) includes a plurality of memory areas that store image data for executing the sequence-guaranteed low-speed process. FIG. 6 is a diagram showing part of a memory map of a RAM. The RAM includes the received-data memory area 52a, the first area 52b, and the second area 52c. The received-data memory area 52a is an area in which data received by the processor 51 (the data receiving unit 53) is stored. Each of the first area 52b and the second area 52c is an area in which image data decompressed by the processor 51 (the image data decompressing unit 54) is stored. Further, the memory volume of each of the first area 52b and the second area 52c is a volume for storing image data of 1 page.

In the present embodiment, image data of an odd page is stored in the first area 52b, and image data of an even page is stored in the second area 52c. Specifically, firstly, the processor 51 stores the image data of the 1st page in the first area 52b, and stores the image data of the 2nd page in the second area 52c. When the writing unit 204 succeeds in writing tag data in the tag of a sheet, on which the image data of the 1st page is formed, the processor 51 then stores the image data of the 3rd page in the first area 52b. In this way, image data is stored in the memory area 52b or 52c until it is determined whether the writing unit 204 succeeds in or does not succeed in writing tag data. Then, new image data is overwritten in the area storing the image data of the image formed on the sheet, which has the wireless tag in which the writing unit 204 succeeds in writing the tag data.

FIG. 7 is a flowchart showing the flow of the image data decompressing process. The image data decompressing process is executed in parallel with the sequence-guaranteed low-speed process. Further, it is assumed that data received by the data receiving unit 53 is stored in the received-data memory area 52a.

In FIG. 7, the processor 51 stores the image data of the 1st page in the first area 52b (ACT801). The processor 51 determines whether the total page number is only 1 page or not (ACT802). When the total page number is only 1 page (ACT802: YES), the processor 51 finishes this process. When the total page number is more than 1 page (ACT802: NO), the processor 51 of the controller 100 stores the image data of the 2nd page in the second area 52c (ACT803).

The processor 51 initializes the counter “j” for counting the page number, i.e., sets “2” (ACT804). The processor 51 determines whether the processor 51 receives an OK signal or not (ACT805). The OK signal is a signal sent from the wireless tag unit 200, the OK signal indicating that the writing unit 204 succeeds in writing tag data in a wireless tag of a sheet. Note that, in the tag unit process (described later), the OK signal is a signal indicating that the writing unit 204 succeeds in writing tag data in a wireless tag of the “k”th-page sheet. The “k”th page of the tag unit process corresponds to the “j−1”th page of the image data decompressing process. This is because the sheet next to the printed sheet corresponds to the “j”th page in the image data decompressing process.

When the processor 51 receives the OK signal (ACT805: YES), the processor 51 determines whether there is image data of the “j+1”th page or not (ACT806). When there is no image data of the “j+1”th page (ACT806: NO), the processor 51 finishes this process. When there is image data of the “j+1”th page (ACT806: YES), the processor 51 increments the counter “j” (ACT807).

The processor 51 determines whether j % 2 is 1 or not (ACT808). “%” is a remainder operator. In other words, j % 2 indicates the remainder when “j” is divided by 2. Therefore j %2=1 when “j” is odd, and j %2=0 when “j” is even. When j % 2 is 1 (ACT808: YES), the processor 51 stores the image data of the “j”th page (“j”th image data) in the first area 52b (ACT809), and returns to ACT805. When j % 2 is not 1 (ACT808: NO), the processor 51 of the controller 100 stores the image data of the “j”th page in the second area 52c (ACT810), and returns to ACT805.

As described in ACT803, ACT 809, and ACT 810, the processor 51 stores the image data, which is used to form the image of the “j”th page on a sheet, in the memory area 52b or 52c regardless of determining whether the writing unit 204 succeeds in or does not succeed in writing tag data in the tag of the “j−1”th-page sheet or not. Specifically, in ACT803, the processor 51 stores the image data, which is used to form the image of the 2nd page on a sheet, in the second area 52c regardless of determining whether the writing unit 204 succeeds in or does not succeed in writing tag data in the tag of the 1st-page sheet or not.

In this way, the image data, which is used to form the image of the “j”th page on a sheet, is stored in the memory area 52b or 52c. Therefore, when the writing unit 204 succeeds in writing tag data in the tag of the “j−1”th-page sheet, it is possible to start the image forming operation immediately. Therefore it is possible to resume printing more promptly than the case when the image data, which is used to form the image of the “j”th page on a sheet, is not stored in the memory area.

FIG. 8 is a flowchart showing the flow of the sequence-guaranteed low-speed process. The sequence-guaranteed low-speed process is executed in parallel with the image data decompressing process after ACT801 of the image data decompressing process.

In FIG. 8, the processor 51 initializes the counter “k” for counting the page number, i.e., sets “1” (ACT401). The processor 51 determines whether k % 2 is 1 or not (ACT402). When k % 2 is 1 (ACT402: YES), the processor 51 treats the image data stored in the first area 52b as data-to-be-printed (ACT403). When k % 2 is not 1 (ACT402: NO), the processor 51 treats the image data stored in the second area 52c as data-to-be-printed (ACT404).

The processor 51 starts to form an image of the “k”th page (ACT405). When the processor 51 finishes forming the image of the “k”th page (ACT406: YES), the processor 51 suspends the image forming operation (ACT407), and conveys the sheet, on which the image is formed, in the normal way (ACT408).

The processor 51 notifies the control unit 201 of tag data to be written in the wireless tag of the “k”th-page sheet (ACT409). At this time, the processor 51 notifies the control unit 201 that the tag data is the “k”th page, in addition to the tag data.

The processor 51 determines whether the processor 51 receives the OK signal (signal indicating that the writing unit 204 succeeds in writing tag data) for the “k”th-page sheet from the control unit 201 or not (ACT410). When the writing unit 204 succeeds in writing the tag data, the control unit 201 supplies the OK signal to the processor 51. When the writing unit 204 fails to write the tag data, the control unit 201 supplies an NG signal (signal indicating that the writing unit 204 fails to write tag data) to the processor 51.

When the processor 51 receives the NG signal from the control unit 201 (ACT406: NO), the processor 51 recognizes that the writing unit 204 does not succeed in writing the tag data, returns to ACT405, and starts to form an image of the “k”th page again (ACT405). When the processor 51 receives the OK signal from the control unit 201 (ACT410: YES), the processor 51 recognizes that the writing unit 204 succeeds in writing the tag data, and increments the counter “k” (ACT411).

The processor 51 determines whether there is image data of the “k”th page or not (ACT412). When there is image data of the “k”th page (ACT412: YES), the processor 51 returns to ACT402. When there is no image data of the “k”th page (ACT412: NO), the processor 51 finishes this process.

In this way, according to the sequence-guaranteed low-speed mode, when the control unit 201 determines that the writing unit 204 succeeds in writing tag data in a wireless tag of a sheet, on which a first image (image of “k”th page) is formed, a second image (image of “k+1”th page) is formed on a sheet.

The processor 51 executes the following process, when the control unit 201 determines that the writing unit 204 does not succeed in writing the tag data in the wireless tag of the sheet, on which the first image (image of “k”th page) is formed. In short, the processor 51 controls the printer 18 to form the first image (image of “k”th page) again on a new sheet (ACT405).

Only after the writing unit 204 succeeds in writing the tag data in the wireless tag of the sheet, on which the first image (image of “k”th page) is formed, the second image (image of “k+1”th page) is formed. Therefore the “k”th-page sheet is always discharged prior to the “k+1”th-page sheet. Therefore, according to the sequence-guaranteed low-speed mode, the sequence of the discharged sheets can be guaranteed, thus no page is skipped, and the page sequence is not disordered.

In the above-mentioned ACT407, the processor 51 suspends the image forming operation of the printer 18 until the processor 51 determines whether the writing unit 204 succeeds in or does not succeed in writing the tag data in ACT410. In the present embodiment, the suspended image forming operation is the operation of exposing the photosensitive drum 24 to light. While the exposure operation is suspended, rotation of the photosensitive drum 24, electrostatically-charging by the electrostatic charger 26, application of a developing bias to a developing roller by the developing device, and rotation of the developing roller are continued. Therefore the processor 51 only has to start the exposure operation when starts printing, and thus can resume printing promptly.

FIG. 9 is a flowchart showing the flow of the tag unit process executed by the wireless tag unit 200 in the sequence-guaranteed low-speed process. Note that the tag unit process of FIG. 9 is the same as the tag unit process executed by the wireless tag unit 200 in the sequence-guaranteed high-speed process (described later). Therefore, in FIG. 9, the sequence-guaranteed low-speed process and the sequence-guaranteed high-speed process will collectively be referred to as sequence-guaranteed process.

In FIG. 9, when the control unit 201 is notified of tag data (ACT501: YES), the control unit 201 stores the notified tag data in the memory unit (ACT502). Note that, as described above with reference to FIG. 6, the processor 51 notifies the control unit 201 that the tag data is the “k”th page, in addition to the tag data. So the control unit 201 stores the information indicating that the tag data is the “k”th page in the memory unit.

When the control unit 201 detects that a sheet is conveyed to the wireless tag unit 200 (ACT503: YES), the control unit 201 controls the writing unit 204 to write the stored tag data in the wireless tag (ACT504). The control unit 201 controls the reading unit 203 to read the tag data (ACT505).

The control unit 201 determines whether the writing unit 204 succeeds in or does not succeed in writing the tag data (ACT506). When the writing unit 204 succeeds in writing the tag data (ACT506: YES), the control unit 201 sends the OK signal to the processor 51. In other words, the control unit 201 notifies the processor 51 that the writing unit 204 succeeds in writing the tag data (ACT507). At this time, the control unit 201 notifies the processor 51 that the tag data, which the writing unit 204 succeeds in writing, is the “k”th page, in addition to the tag data. The control unit 201 controls the switcher unit 202 to discharge the sheet to the OK tray 20a (ACT508), and finishes this process.

When the writing unit 204 does not succeed in writing the tag data (ACT506: NO), the control unit 201 sends the NG signal to the processor 51. In other words, the control unit 201 notifies the processor 51 that the writing unit 204 does not succeed in writing the tag data (ACT509). At this time, the control unit 201 notifies the processor 51 that the tag data, which the writing unit 204 does not succeed in writing, is the “k”th page, in addition to the tag data. The control unit 201 controls the switcher unit 202 to discharge the sheet to the NG tray 20b (ACT510), and finishes this process.

FIG. 10 is a flowchart showing the flow of the sequence-guaranteed high-speed process. In FIG. 10, the processor 51 initializes the counter “k” for counting the page number, i.e., sets “1” (ACT601). The processor 51 starts to form an image of the “k”th page (ACT602). When the processor 51 finishes forming the image of the “k”th page (ACT603: YES), the processor 51 determines whether or not k is 2 or more (ACT604).

When k is less than 2 (ACT604: NO), the processor 51 proceeds to ACT606. When k is 2 or more (ACT604: YES), the processor 51 determines whether the processor 51 receives the OK signal for the “k−1”th page or not (ACT605). When the processor 51 receives the NG signal for the “k−1”th page (ACT605: NO), the processor 51 recognizes that the writing unit 204 does not succeed in writing the tag data, executes the re-printing process (described later) (ACT607), and proceeds to ACT608.

When the processor 51 receives the OK signal for the “k−1”th page (ACT605: YES), the processor 51 recognizes that the writing unit 204 succeeds in writing the tag data, and conveys the sheet, on which the image is formed, in the normal way (ACT606). The processor 51 notifies the control unit 201 of tag data to be written in the wireless tag of the “k”th-page sheet (ACT608). At this time, the processor 51 notifies the control unit 201 that the tag data is the “k”th page, in addition to the tag data.

The processor 51 increments the counter “k” (ACT609). The processor 51 determines whether there is image data of the “k”th page or not (ACT610). When there is image data of the “k”th page (ACT610: YES), the processor 51 returns to ACT602. When there is no image data of the “k”th page (ACT610: NO), the processor 51 finishes this process.

FIG. 11 is a flowchart showing the flow of the re-printing process. In FIG. 11, the processor 51 conveys the sheet, on which the image of the “k”th page is formed, for evacuation (ACT701). The processor 51 starts to form an image of the “k−1”th page (ACT702). When the processor 51 finishes forming the image of the “k−1”th page (ACT703: YES), the processor 51 conveys the sheet, on which the image is formed, in the normal way (ACT704). Since the sheet, on which the image of the “k”th page is formed, is conveyed for evacuation, the sheet, on which the image of the “k−1”th page is formed, can be conveyed to the wireless tag unit 200.

The processor 51 notifies the control unit 201 of tag data to be written in the wireless tag of the “k−1”th-page sheet (ACT705). At this time, the processor 51 notifies the control unit 201 that the tag data is the “k−1”th page, in addition to the tag data.

The processor 51 determines whether the processor 51 receives the OK signal for the “k−1”th page or not (ACT706). When the processor 51 receives the NG signal for the “k−1”th page (ACT706: NO), the processor 51 recognizes that the writing unit 204 does not succeed in writing the tag data, and returns to ACT702. When the processor 51 receives the OK signal for the “k−1”th page (ACT706: YES), the processor 51 recognizes that the writing unit 204 succeeds in writing the tag data, and conveys the evacuated sheet, on which the image of the “k”th page is formed, to the wireless tag unit 200 (ACT707).

In this manner, according to the sequence-guaranteed high-speed mode, before the control unit 201 determines whether the writing unit 204 succeeds in or does not succeed in writing tag data in the wireless tag of the sheet, on which the first image (image of “k−1”th page) is formed, the second image (image of “k”th page) is formed on a sheet in ACT602.

Then, when the control unit 201 determines that the writing unit 204 does not succeed in writing tag data in the wireless tag of the sheet, on which the first image (image of “k−1”th page) is formed, the following process is executed. In short, the processor 51 evacuates the sheet, on which the second image (image of “k”th page) is formed, from the conveying paths 33a and 33c for conveying the sheet from the printer 18 to the writing unit 204, to stay in the other conveying path 33b (ACT701).

When the control unit 201 determines that the writing unit 204 does not succeed in writing tag data in a tag of a sheet, then the processor 51 controls the printer 18 to form the first image (image of “k−1”th page), which is formed on the sheet, again on a new sheet (ACT702). The processor 51 conveys the sheet, on which the first image (image of “k−1”th page) is formed, in the normal way (ACT704). Only after the writing unit 204 succeeds in writing the tag data in the wireless tag of the thus-conveyed sheet, on which the first image (image of “k−1”th page) is formed, the evacuated sheet, on which the second image (image of “k”th page) is formed, is released. When the writing unit 204 succeeds in writing the tag data in the wireless tag of the sheet, on which the first image (image of “k−1”th page) is formed, the sheet, on which the second image (image of “k”th page) is formed, is conveyed to the wireless tag unit 200 (ACT707). Therefore the “k−1”th-page sheet is always discharged prior to the “k”th-page sheet.

Therefore, according to the sequence-guaranteed high-speed mode, the sequence of the discharged sheets can be guaranteed, thus no page is skipped, and the page sequence is not disordered. Further, according to the sequence-guaranteed high-speed mode, before the control unit 201 determines whether the writing unit 204 succeeds in or does not succeed in writing tag data in the wireless tag of the sheet, on which the first image (image of “k−1”th page) is formed, the second image (image of “k”th page) is formed on a sheet in ACT602. Therefore, the printing speed of the sequence-guaranteed high-speed mode is higher than the printing speed of the sequence-guaranteed low-speed mode.

In the above-mentioned embodiment, an ink-jet device may be provided in the wireless tag unit, and may print “NG”, a slash, or the like on a sheet with a wireless tag, in which the writing unit 204 fails to write information (tag data), before discharging the sheet. In this case, the tray to which the sheet is discharged may be the same as the tray to which a sheet with a wireless tag, in which the writing unit 204 succeeds in writing information, is discharged.

Data can be read from/written in some types of wireless tags from several meters away. Therefore it is not necessary to provide a reading unit and a writing unit close to a sheet as described in the present example. For example, a reading unit and a writing unit may be provided several meters away. Further, the writing unit writes information (tag data) in a wireless tag of a sheet, on which an image is formed, the reading unit reads the information from the wireless tag, and the control unit determines whether the writing unit succeeds in or does not succeed in writing the information in the wireless tag. The control unit may send the result of the determination to the switcher unit via wireless communication.

In the above-mentioned embodiment, the RAM of the memory device 52 has the two areas 52b and 52c to store two image data items. Alternatively, for example, one image data may be stored in the RAM, and the other image data may be stored in a memory device such as an HDD and an SSD. Further, in the above-mentioned embodiment, the two areas of the RAM are preassigned to the RAM. Alternatively, the two areas of the RAM may be assigned dynamically. Further, image data may be stored not in the two memory areas but in three or more memory areas.

According to the image forming apparatus of the above-mentioned embodiment, it is possible to provide an image forming apparatus, with which no page is skipped and the page sequence is not disordered.

A computer may realize the functions of the image forming apparatus of the above-mentioned embodiment. In this case, a non-transitory computer readable recording medium may store a program for realizing those functions, and a computer system may read the program stored in the recording medium and execute the program to thereby realize those functions. Note that, herein, the “computer system” includes an OS and hardware such as peripheral devices. Further, the “non-transitory computer readable recording medium” means a flexible disk, a magneto-optical disk, a ROM, a mobile medium such as a CD-ROM, a memory device such as a hard disk built in the computer system. Further, the “non-transitory computer readable recording medium” may also mean a recording medium that stores the program instantly and dynamically, such as a communication line, when the program is sent via a network such as the Internet or a communication line such as a telephone line. In this case, the “non-transitory computer readable recording medium” may also mean a recording medium that stores the program for a predetermined time period, such as a volatile memory in a computer system such as a server or a client. Further, the above-mentioned program may realize part of the above-mentioned functions, and may realize the above-mentioned functions on the basis of combination with a program already recorded in the computer system.

While certain the embodiments have been described, these the embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel the embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.

IMAGE FORMING APPARATUS

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