1. Field of the Invention
The present invention relates to an image forming apparatus, an image forming system, a controlling method of the image forming apparatus, and a storage medium of storing a program to execute the controlling method.
2. Description of the Related Art
In the related arts, in image forming apparatuses such as a copying apparatus and the like, there has been proposed an image forming apparatus in which by connecting a post-processing apparatus for executing a post-process to a sheet to the image forming apparatus, a bookbinding process such as saddle stitch process for stitching a center portion of the paper or a middle-folding process for folding the center portion of the paper is executed. As for a paper sheaf which was bookbinding-processed, an edge portion is finished by a cutting process for cutting a circumferential blank portion.
In a bookbinding product completed by the bookbinding process, a fact that there are no problems such as misregistration in printing in a printing process, misregistration in bookbinding in the saddle stitch/middle-folding process, misregistration in cutting in the cutting process, and the like has to be confirmed. Ordinarily, in bookbinding inspecting work, an inspector grasps the bookbinding products one by one and confirms by a visual inspection.
However, in the bookbinding inspecting work by the confirmation based on the visual inspection, there is a fear of occurrence of such a problem that an inspecting precision is deteriorated due to a cause of an oversight of the inspector, such a problem that a working burden on the inspector increases because it is necessary to confirm all pages of many bookbinding products one by one every product, and the like.
To solve such problems, according to the technique disclosed in Japanese Patent Application Laid-Open No. 2001-047771, in order to detect missing pages and incorrect collating in the bookbinding product by the visual inspection confirmation, such a mark as to construct a specific figure is added to a top or bottom of the bookbinding product. The inspector confirms whether or not a shape of the mark added to the bookbinding product has correctly been formed, thereby enabling the missing pages to be easily and certainly detected.
However, the mark for inspecting the bookbinding product shown in Japanese Patent Application Laid-Open No. 2001-047771 is added along the outer circumference of the sheet. Therefore, even if the misregistration in cutting occurred at the time of the cutting process, since no mark is left on the sheet after the cutting process, there is such a problem that the user cannot be easily aware of the misregistration in cutting.
The invention is made to solve the foregoing problem and it is an object of the invention to provide such a mechanism that the user can easily detect a misregistration in cutting which occurs at the time of a cutting process.
According to an aspect of the invention, there is provided an image forming apparatus comprising: an obtaining unit configured to obtain image data which is printed onto a sheet; a first setting unit configured to set whether or not a cutting process for cutting the sheet is executed; and a printing unit configured to execute the printing on the basis of the image data in the case where it is set by the first setting unit that the cutting process is executed and print a mark to an outer circumferential side of the sheet on the basis of a cutting position, as a reference, where the cutting process is executed.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Preferred embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
In
When the original passes through the panning reading position on the platen glass 102 from the left toward the right, an image of the original is read by a scanner unit 104 held at a position corresponding to the panning reading position. This reading method is a method which is generally called an original-panning reading. Specifically speaking, when the original passes through the panning reading position, a reading surface of the original is irradiated by light of a lamp 103 in the scanner unit 104. The reflection light from the original is guided to a lens 108 through mirrors 105, 106, and 107. The light which passed through the lens 108 is focused onto an image pickup surface of an image sensor 109.
By carrying the original so as to pass through the panning reading position from the left to the right as mentioned above, an original reading scan in which the direction which perpendicularly crosses the carrying direction of the original is set to the main scanning direction and the carrying direction is set to the sub-scanning direction is performed.
That is, when the original passes through the panning reading position, by carrying the original in the sub-scanning direction while reading the original image every line in the main scanning direction by the image sensor 109, the whole original image is read. The image which was optically read is converted into image data by the image sensor 109 and output. The image data which was output from the image sensor 109 is subjected to a predetermined process by an image signal controlling unit 202, which will be described hereinafter, and subsequently, the image data is input as a video signal to an exposure controlling unit 110 in the printer 300.
It is also possible to construct in such a manner that the original is carried onto the platen glass 102 by the document feeder 100 and stopped at a predetermined position, thereafter, the original is read by scanning the scanner unit 104 from the left side to the right side in this state. This reading method is what is called an original-fixed reading. In the case of reading the original without using the document feeder 100, the user lifts up the document feeder 100 and puts the original onto the platen glass 102. By scanning the scanner unit 104 from the left side to the right side, the original is read. That is, in the case of reading the original without using the document feeder 100, the original-fixed reading is performed.
The exposure controlling unit 110 in the printer 300 modulates a laser beam in accordance with a video signal which was input and outputs. While the laser beam is scanned by a polygon mirror 110a, it is irradiated onto a photosensitive drum 111. An electrostatic latent image according to the scanned laser beam is formed onto the photosensitive drum 111. In the case of the original-fixed reading, the exposure controlling unit 110 emits the laser beam so that a correct image (image instead of a mirror image) is formed.
The electrostatic latent image on the photosensitive drum 111 is visualized as a developer image by a developer which is supplied from a developing unit 113. At the timing synchronized with the start of the irradiation of the laser beam, paper is fed from each cassette 114 or 115, a manual paper feeding unit 125, or a two-sided carrying path 124. The paper is carried between the photosensitive drum 111 and a transferring unit 116.
The developer image formed on the photosensitive drum 111 is transferred onto the paper fed by the transferring unit 116. The paper onto which the developer image has been transferred is carried to a fixing unit 117. The fixing unit 117 heats and presses the paper, thereby fixing the developer image onto the paper. The paper which passed through the fixing unit 117 is ejected from the printer 300 to the outside (finisher 500) through a flapper 121 and an ejecting roller 118.
In the case of ejecting the paper in a (face-down) state where the image forming surface faces down, the paper which passed through the fixing unit 117 is temporarily guided into a reversing path 122 by the switching operation of the flapper 121. After a rear edge of the paper passed through the flapper 121, the paper is switched back and ejected from the printer 300 by the ejecting roller 118.
Such a paper discharge state is called a reversal paper discharge hereinafter. The reversal paper discharge is performed in the case of sequentially forming images from the head page, for example, in the case where the images which were read by using the document feeder 100 are formed, where the images which were output from a computer are formed, or the like, so that the order of the paper derived after the paper discharge becomes the correct page order.
In the case where hard paper such as OHP sheets or the like is fed from the manual paper feeding unit 125 and images are formed onto the paper, the paper is not guided to the reversing path 122 but is ejected by the ejecting roller 118 in a (face-up) state where the image forming surface faces up.
Further, if a two-sided recording mode of forming images onto both surfaces of the paper has been set, the paper is temporarily discharged by the ejecting roller 118 and, thereafter, switched back. Then, the paper is guided to the reversing path 122 by the switching operation of the flapper 121 and, thereafter, carried to the two-sided carrying path 124. Subsequently, such control that the paper guided to the two-sided carrying path 124 is fed again between the photosensitive drum 111 and the transferring unit 116 at the foregoing timing is performed.
The paper ejected from the printer 300 is conveyed to the finisher 500. The finisher 500 executes various kinds of processes such as a stapling process and the like. Further, the trimmer 900 executes the cutting process to an edge portion of the paper to which a saddle stitch, middle-folding, or the like has been performed by the finisher 500.
(System Construction)
In
The CPU circuit unit 150 has therein a CPU 153, a ROM 151, and a RAM 152. The CPU 153 executes a control program stored in the ROM 151, thereby integratedly controlling the respective units 101, 201, 202, 209, 301, 401, and 501. The RAM 152 is used as a work area for an arithmetic operating process accompanied with the control such as a process for temporarily holding control data or the like.
The document feeder controlling unit 101 drives the document feeder 100 in response to an instruction from the CPU circuit unit 150. The image reader controlling unit 201 drives the scanner unit 104, image sensor 109, and the like and transfers the analog image signal which was output from the image sensor 109 to the image signal controlling unit 202.
The image signal controlling unit 202 converts an analog image signal from the image sensor 109 into a digital signal, thereafter, executes various kinds of processes thereto, converts the digital signal into a video signal, and outputs to the printer controlling unit 301. The image signal controlling unit 202 executes various kinds of processes to a digital image signal which was input from the computer 210 through the external I/F 209, converts the digital image signal into a video signal and outputs to the printer controlling unit 301. The processing operation which is executed by the image signal controlling unit 202 is controlled by the CPU circuit unit 150.
The printer controlling unit 301 drives the exposure controlling unit 110 on the basis of the video signal which was input. The finisher controlling unit 501 is mounted in the finisher 500, transmits and receives information to/from the CPU circuit unit 150, and drives the whole finisher.
The trimmer controlling unit 901 is mounted in the trimmer 900, transmits and receives information to/from the finisher controlling unit 501, and drives the whole trimmer.
The operation display controlling unit 401 transmits and receives information to/from the operation display apparatus 400 and the CPU circuit unit 150. The operation display apparatus 400 has a plurality of keys for setting various kinds of functions regarding the image creation, a displaying unit for displaying information showing a setting state, and the like. The operation display controlling unit 401 outputs a key signal corresponding to the operation of each key to the CPU circuit unit 150 and allows the corresponding information to be displayed to the displaying unit in accordance with a signal from the CPU circuit unit 150.
(Operation Display Apparatus)
In
The image forming apparatus of the embodiment has post-processing modes such as non-sorting mode, sorting mode, staple sorting mode (stapling mode), bookbinding mode, and the like. Such a post-processing mode is set by the inputting operation from the operation display apparatus 400. For example, in the case of setting the post-processing mode, if “sorter” serving as a software key is selected on an initial display screen (refer to
(Finisher)
In
In the finisher 500, the paper ejected from the image forming apparatus 10 is fetched into the apparatus by an inlet roller pair 502. The paper fetched into the apparatus is sent toward a buffer roller 505 through a carrying roller pair 503. An inlet sensor 531 is provided on the way of a carrying path between the inlet roller pair 502 and the carrying roller pair 503. A punching unit 550P is provided on the way of a carrying path between the carrying roller pair 503 and the buffer roller 505. The punching unit 550P operates in accordance with the necessity and punches the portion near the rear edge of the carried paper.
The buffer roller 505 is a roller which can laminate a predetermined number of sheets of paper which were sent through the carrying roller pair 503 and wind them around an outer circumference of the buffer roller. Depressing rollers 512, 513, and 514 are provided around the outer circumference of the buffer roller 505. During the rotation of the roller, the paper is wound by each of the depressing rollers 512, 513, and 514. The wound paper is carried in the rotating direction of the buffer roller 505.
A change-over flapper 511 is arranged between the depressing rollers 513 and 514. A change-over flapper 510 is arranged on a downstream side of the depressing roller 514. The change-over flapper 511 is a flapper for peeling off the paper wound around the buffer roller 505 from the buffer roller 505 and guiding to a non-sorting path 521 or a sorting path 522. The change-over flapper 510 is a flapper for peeling off the paper wound around the buffer roller 505 from the buffer roller 505 and guiding to the sorting path 522 or is a flapper for guiding the paper wound around the buffer roller 505 to a buffer path 523 in a wound state.
When the paper wound around the buffer roller 505 is guided to the non-sorting path 521, the change-over flapper 511 operates, the wound paper is peeled off from the buffer roller 505 and guided to the non-sorting path 521. The paper guided to the non-sorting path 521 is discharged onto a sample tray 701 through an ejecting roller pair 509. A paper discharge sensor 533 is provided on the way of the non-sorting path 521 and detects a paper discharge.
When the paper wound around the buffer roller 505 is guided to the buffer path 523, both of the change-over flappers 510 and 511 do not operate, so that the paper is sent to the buffer path 523 in a state where the paper has been wound around the buffer roller 505. A path sensor 532 is provided on the way of the buffer path 523 and detects the paper on the buffer path 523.
When the paper wound around the buffer roller 505 is guided to the sorting path 522, the change-over flapper 511 does not operate but the change-over flapper 510 operates, and the wound paper is peeled off from the buffer roller 505 and guided to the sorting path 522.
A change-over flapper 542 to guide the paper to a sort ejecting path 524 or a bookbinding path 525 is arranged on the downstream of the sorting path 522. The paper guided to the sort ejecting path 524 is stacked onto an intermediate tray (hereinbelow, referred to as a processing tray) 630 through a carrying roller pair 507.
An aligning process by an aligning member 641 provided on each of this side and the interior side, a stapling process, or the like is executed to the paper stacked in a sheaf shape onto the processing tray 630 in accordance with the necessity. After that, the paper is ejected onto a stacking tray 700 by ejecting rollers 680a and 680b.
The ejecting roller 680b is supported to an oscillation guide 650. The oscillation guide 650 oscillates by an oscillation motor (not shown) so that the ejecting roller 680b is come into contact with the top paper on the processing tray 630. When the ejecting roller 680b is in a state where it is in contact with the top paper on the processing tray 630, the ejecting roller 680b can eject the paper sheaf on the processing tray 630 toward the stacking tray 700 in cooperation with the ejecting roller 680a.
The stapling process is executed by a stapler 601. The stapler 601 is constructed so as to be movable along an outer circumference of the processing tray 630 and can staple the paper sheaf stacked on the processing tray 630 at the end position (rear edge) of the paper in the paper carrying direction (the left direction in the diagram).
The paper guided to the bookbinding path 525 is carried to a bookbinding intermediate tray (hereinbelow, referred to as a bookbinding processing tray) 830 through a carrying roller pair 802. A bookbinding inlet sensor 831 is provided on the way of the bookbinding path 525. An intermediate roller 803 and a movable paper positioning member 816 are provided for the bookbinding processing tray 830. An anvil 811 is provided at a position which faces a pair of staplers 810. The staplers 810 and the anvil 811 cooperate and execute the stapling process to the paper sheaf enclosed in the bookbinding processing tray 830.
A folding roller pair 804 is provided on the downstream side of the staplers 810. A bumping member 815 is provided at a position opposite to the folding roller pair 804. By bumping the bumping member 815 toward the paper sheaf enclosed in the bookbinding processing tray 830, the paper sheaf enclosed in a bundle shape in the bookbinding processing tray 830 is pushed out between the folding roller pair 804. Thus, a middle-folding is performed to the center of the paper. In the embodiment, up to three sheets of paper can be middle-folded. The folding roller pair 804 folds the paper sheaf and carries the folded paper sheaf to the downstream.
The folded paper sheaf is sent to the trimmer 900 by the paper discharge roller pair. A paper discharge sensor 832 is provided on the downstream side of the folding roller pair 804.
(Finisher Controlling Unit)
In
(Trimmer)
In
Carrying belt pairs 902 (902a, 902b), 903 (903a, 903b), 904 (904a, 904b), and 905 (905a, 905b) are provided at positions of an equal distance from the center of the carrying path, respectively. The paper is carried to the downstream in a state where it is sandwiched between the pair of upper and lower carrying belts.
A mechanism for cutting an edge portion on the side opposite to a middle-folding edge portion (hereinbelow, referred to as a small-quantity cutting) serving as a downstream side of the paper carrying path is provided between the carrying belts 902 and 903.
The small-quantity stopper 911 can freely sink or exit toward the carrying belts 903 in order to carry the paper without performing the small-quantity cutting or in order to carry the paper after the cutting to the downstream (in
Cut paper chips are enclosed into a small-quantity chip box 915. Generally, the small-quantity cutting upper blade 912a is on standby at the ascending position so as not to obstruct the conveyance of the paper (in
A mechanism for cutting an edge portion which perpendicularly crosses the middle-folding edge portion (hereinbelow, referred to as a vertical cutting) is provided for the carrying belts 905 arranged on the downstream side of the small-quantity cutting portion.
The vertical cutting blades, 921a, 921b, 922a, and 922b are movable in the this-side and interior directions and are moved in accordance with the paper size and the adjustment of the cutting position. The chips cut by the vertical cutting unit are enclosed into a vertical chip box 925. In the case where the vertical cutting is not performed, the paper is carried to the downstream by the carrying belts 905 without being stopped.
The paper which passed through the carrying belts 905 is ejected onto a stacking tray 930. At this time, a large-conveyance roller 931 provided over the stacking tray 930 is driven to move the ejected paper on the stacking tray 930. The paper which has already been stacked on the stacking tray 930 is also moved to the upstream and downstream sides of the tray, thereby preventing the paper from remaining at a paper discharge port of the carrying belts 905.
(Construction of Trimmer Controlling Unit)
Through the communication IC (not shown), the trimmer controlling unit 901 communicates with the finisher controlling unit 501 provided in the finisher 500 and performs a data exchange. In response to an instruction from the finisher controlling unit 501, the trimmer controlling unit 901 executes various kinds of programs stored in the ROM 951 and controls the trimmer 900.
The carrying belts 902a and 902b are connected to the receiving carrying motor M10. The carrying belts 902a and 902b are driven by the receiving carrying motor M10. The carrying belts 903a and 903b are connected to the small-quantity carrying motor M11. The carrying belts 903a and 903b are driven by the small-quantity carrying motor M11. The carrying belts 904a and 904b are connected to the vertical path carrying motor M12. The carrying belts 904a and 904b are driven by the vertical path carrying motor M12. The carrying belts 905a and 905b are connected to the vertical carrying motor M13. The carrying belts 905a and 905b are driven by the vertical carrying motor M13. The motors M10 to M13 are constructed by stepping motors.
The this-side aligning member 910a and the interior aligning member 910b are connected to the receiving aligning motor M14. The this-side aligning member 910a and the interior aligning member 910b are driven by the receiving aligning motor M14, are moved in the center direction by a forward rotation, and are symmetrically moved in the outside direction by a reverse rotation.
The small-quantity cutting upper blade 912a is connected to the small-quantity cutting motor M15. The small-quantity cutting upper blade 912a is elevated up or down by the forward or reverse rotation of the small-quantity cutting motor M15. The small-quantity cutting motor M15 is constructed by a DC motor because a motor load fluctuates by the number of sheets of paper to be cut or a thickness of paper.
The small-quantity stopper 911 is connected to the stopper moving motor M16. A position of the small-quantity stopper 911 is controlled by the stopper moving motor M16 and the stopper 911 is moved in the carrying direction. The stopper moving motor M16 is constructed by a stepping motor. An elevation of the small-quantity stopper 911 is driven by the stopper solenoid SL1.
The vertical cutting upper blade 921a is connected to the vertical cutting motor M17. In a manner similar to the small-quantity cutting upper blade 912a, the vertical cutting upper blade 921a is elevated up or down by the forward or reverse rotation of the vertical cutting motor M17. The vertical cutting motor M17 is constructed by a DC motor.
(Operation in the Bookbinding Mode)
Subsequently, a flow of the paper in the bookbinding mode will be described with reference to
As illustrated in
When the front edge of the paper has reached the paper positioning member and the conveyance has been stopped, the aligning members (not shown) operate in the paper carrying direction and the vertical direction and the paper is aligned. When a predetermined number of sheets of paper have been aligned and enclosed, the stapling process is executed to the center of the paper sheaf (hereinbelow, referred to as a saddle stitch) by the staplers 810 as mentioned above.
As illustrated in
In the case of the bookbinding mode in which the saddle stitch is not performed, in a manner similar to the case of performing the saddle stitch as mentioned above, after the paper was temporarily enclosed at the position where the stapling process is executed to the center of the paper sheaf, the stapling process is not executed but the paper positioning member 816 is descended until the position where the center of the paper reaches the center position of the folding roller pair 804. After that, the bumping member 815 is projected so that the paper sheaf is protruded between the folding roller pair 804. While the paper sheaf is folded by the folding roller pair 804, it is carried to the downstream.
(Operation in the Cutting Mode)
Subsequently, a flow of the paper in the cutting mode will be described with reference to
In the case of performing the small-quantity cutting, the small-quantity stopper is ascended from a standby position shown by a broken line to a position where the stopper is projected to the carrying path as shown by a solid line. Further, the stopper is moved to the position corresponding to the cutting quantity in the carrying direction. After the path sensor 942 detected the front edge of the paper sheaf P which had been carried to the downstream by the carrying belts 902a, 902b, 903a, and 903b, the paper sheaf P is carried by a predetermined distance. Then, the carrying belts 902a, 902b, 903a, and 903b are stopped, the front edge of the paper is come into contact with the small-quantity stopper 911 and enters a state where it is sandwiched between the carrying belts 903a and 903b. At this time, the rear edge of the paper sheaf P is in a state where it came out of the carrying belts 902.
As illustrated in
In the case where the small-quantity cutting is not performed, after the aligning operation was performed by the aligning member 910, a standby state where the small-quantity stopper 911 descended is held and the carrying belts 902, 903, 904, and 905 are rotated in this state, thereby carrying the paper sheaf P to the downstream without being temporarily stopped in the small-quantity cutting unit.
Subsequently, as illustrated in
(Setting of the Bookbinding Mode and the Cutting Mode)
Subsequently, a flow for the setting of the bookbinding mode and the cutting mode will be described with reference to
When “application mode” serving as a software key is selected on an initial display screen illustrated in
When “cutting” is selected and the “OK” key is pressed irrespective of the contents of the setting about the saddle stitch in
The set cutting quantities x and y are sent to the trimmer controlling unit 901 and are used for control of the positions of the small-quantity cutting blades 912a and 912b and the vertical cutting blades 921a, 921b, 922a, and 922b. At this time, in the case of the small-quantity cutting, the small-quantity stopper 911 is used as a reference in the small-quantity cutting and the position of the small-quantity cutting lower blade 912b to the cutting quantity x is unconditionally decided. In the case of the vertical cutting, the positions of the vertical cutting lower blades 921b and 922b are decided to a predetermined interval from the cutting quantity y.
When the “OK” key is pressed after the cutting quantities were input in
Information of the cutting mark which was set here is transmitted to the image signal controlling unit 202 by the CPU circuit unit 150. The digital image signal is converted into the video signal and, thereafter, a print image to which a mark for confirming the inspecting bookbinding product by visual inspection has been added is formed in the printer controlling unit 301.
By this display screen, the user can select a color and a pattern of the mark which is painted in the cutting range. As for the pattern of the mark, besides a solid pattern which is fully painted, another pattern such as dots, lattice, or gradation can be selected. The solid painting is selected unless otherwise the user especially designates it.
Further, the range, color, and pattern of the cutting marker may be set in accordance with a toner residual quantity of the image forming apparatus. Specifically speaking, if the toner residual quantity of the image forming apparatus is small, information of the toner residual quantity is displayed on a setting display screen of
Upon setting of the addition of the cutting mark to the print image illustrated in
Although the cutting mark setting display screen for the three-side cutting setting is illustrated in
It is desirable that such a cutting mark adding setting on a page unit basis is used in accordance with a feature of the pages included in the bookbinding product. For example, a mode in which such a color and a pattern that it can be easily confirmed by visual inspection are selected in accordance with a coloring of the page, a mode in which the cutting mark is not added to the pages such as a blank page or the like in which the detection of misregistration is unnecessary, or the like can be set.
In
To the misregistration in the printing process, when the bookbinding product is spread-opened as illustrated on the left side of
(Bookbinding Inspecting Flow)
Details regarding the bookbinding setting and the cutting setting are as described in
First, in S1100, the CPU 153 discriminates whether or not the user has selected the bookbinding mode by using the operation display apparatus 400. If the CPU 153 determines that the user does not select the bookbinding mode, the bookbinding setting in S1100 is skipped and S1102 follows.
If the CPU 153 determines in S1100 that the bookbinding mode has been selected, the user selects the setting of the paper feed stage or the saddle stitch process as mentioned above.
Subsequently, in S1102, the CPU 153 discriminates whether or not the user has selected the cutting mode by using the operation display apparatus 400. If the CPU 153 determines that the cutting mode is not selected, the cutting setting in S1103 is skipped and S1105 follows.
If the CPU 153 determines in S1102 that the cutting mode has been selected, the user sets the small-quantity cutting or the three-side cutting and, thereafter, sets the cutting quantities as mentioned above. Subsequently, in S1104, the CPU 153 sets the cutting mark addition on the basis of the cutting method and the cutting quantities which were set in S1103. In this instance, the range of the cutting mark, the page to which the cutting mark is added, the color and pattern of the cutting mark, and the like are set.
Subsequently, in S1105, the CPU 153 forms the print data on the basis of the bookbinding processing setting in S1100 to S1104 and executes the printing process. At this time, if the cutting mark adding setting has been made in S1104, the printing process for adding the cutting mark to the print image data is executed.
Subsequently, in S1106, in response to the instruction from the CPU 153, on the basis of the bookbinding setting selected in S1101, the finisher controlling unit 501 executes the bookbinding process to the paper sheaf which was print-processed in S1105.
In S1107, in response to the instruction from the CPU 153, on the basis of the cutting setting selected and set in S1103 and S1104, the CPU of the trimmer controlling unit 901 executes the cutting process to the paper sheaf which was bookbinding-processed in S1106. After the bookbinding product was completed, the present processing routine is finished.
The bookbinding product completed by the above processing flow is sent to the inspecting work by the inspector. Unlike the inspection by the visual inspection confirmation in the related art, since the inspection target is the bookbinding product to which the cutting mark has been added, the inspector can detect the defective bookbinding by confirming by the visible inspection whether or not the cutting mark remains on the bookbinding product.
The second embodiment of the invention will now be described with reference to the drawings.
Since a construction of an image forming system in the embodiment is similar to that of the first embodiment, the same component elements as those in the first embodiment are designated by the same reference numerals and their description is omitted and different operations will be described here.
In the setting display screen of
That is, the user can select the different colors and patterns of the different marks to the two ranges of the range of (x2, y2) on the immediate outside from the cutting position on the UI display screens illustrated in
By adding the marks 1 and 2 of the different colors and patterns on the inside and outside of the cutting position, respectively, the different marks can be set in accordance with a size (level) of the misregistration. Therefore, an inspecting level according to a favor of the user can be set.
For example, by adding the marker of the inconspicuous color to the range where the level of the misregistration is small, the user is allowed to discriminate whether or not such a misregistration can be permitted at the time of inspection. On the other hand, by adding the marker of the conspicuous color to the range where the level of the misregistration is large, the inspector can certainly detect the defective inspection.
Subsequently, the third embodiment will be described with reference to the drawings. The operations different from those in the foregoing embodiments will be also described here.
That is, in the print image to which the cutting mark has been added in
The permission range 1007 to which the cutting mark is not added is a range for permitting an error of the position control of the small-quantity cutting blades 912a and 912b and the vertical cutting blades 921a, 921b, 922a, and 922b to the set cutting quantities. To such permission quantities of the position control of the cutting blades as mentioned above, it is desirable that no marker is added in the detection of the misregistration of the bookbinding inspection. Since such a permission range can be preliminarily used as an inherent value which the image forming apparatus has, by adding a misregistration quantity peculiar to an engine to the range designated by the setting display screen of
As for the cutting mark including a permission range as mentioned above, the user can also designate such a permission range on the cutting mark setting display screen as illustrated in
In
As mentioned above, by adding the cutting mark including the permission range of the misregistration, since the marker is not added to the range where the user can permit in the misregistration of the bookbinding product, the bookbinding product in which only the misregistration out of the permission range can be formed.
As another embodiment of the invention, the setting methods of the cutting mark shown in the embodiments 1 to 3 can be also combined and used. By this method, since the cutting mark according to the engine performance which the image forming apparatus 10 has or the favorite inspecting level of the user can be set, it is more effective for the improvement of the precision of the bookbinding product inspection by the visual inspection confirmation or for the reduction of the load of the inspector.
The invention can be also realized by a method whereby software (application) having the functions of the embodiment mentioned above is implemented into the computer 210, the bookbinding setting including the cutting mark information is transmitted to the image forming apparatus 10 through the external I/F 209, and a similar bookbinding process is executed. At this time, the processes such as creation of the print image and the like based on the various kinds of settings regarding the bookbinding mode and the cutting mode in the operation display apparatus 400 in the foregoing embodiments and the various kinds of settings in the image signal controlling unit 202 is substituted by software on the computer 210.
Aspects of the present invention can also be realized by a computer of a system or apparatus (or devices such as a CPU or MPU) that reads out and executes a program recorded on a memory device to perform the functions of the above-described embodiments, and by a method, the steps of which are performed by a computer of a system or an apparatus by, for example, reading out and executing a program recorded on a memory device to perform the functions of the above-described embodiments. For this purpose, the program is provided to the computer for example via a network or from a recording medium of various types serving as the memory device (e.g., computer-readable medium).
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2011-262270, filed Nov. 30, 2011, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2011-262270 | Nov 2011 | JP | national |