Sheet processing apparatus and method, as well as controlling apparatus

A sheet processing apparatus which is capable of completing a bound document containing appropriately Z-folded sheets when performing folding together with edge cutting and binding. The sheet processing apparatus controls a Z-folding process, a cutting process, and a binding process for a sheet. A first folding position from a free end of the sheet coincides with a position corresponding to half a width of the sheet excluding a cut width of the sheet a binding margin, when the Z-folding process, the cutting process, and the binding process are executed.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a sheet processing apparatus equipped with a sheet processing unit which performs sheet processing, including folding, cutting, and binding, on sheets and to a sheet processing method, as well as a controlling apparatus.

2. Description of the Related Art

Recent printing systems and the like intended for the POD (print-on-demand) market are configured by connecting a printer directly with various sheet processing apparatuses (by in-line connection) and adapted to perform folding, cutting, and binding such as stapling or case binding on the printed sheets.

If such printing systems and the like perform folding and cutting in combination, a portion around a fold line produced by the folding could be cut off. Furthermore, when the folding and the binding are performed in combination, the portion around the fold line produced by the folding could be bound by staples or the like.

Therefore, in the printing systems and the like, operations on a control panel are limited so as to disable the cutting after the folding. Also, operations on the control panel are limited so as to disable the combined use of a specific folding (e.g., Z-folding) and a specific cutting (e.g., edge cutting).

Thus, in relation to the conventional printing systems and the like, a technique has been proposed in order to prevent the fold lines from being cut off. The technique involves, for example, placing two fold lines on the inner side of the respective sheet edges during Z-folding to thereby displace the fold lines so as to avoid portions around the fold lines from being cut off. Also, in relation to conventional sheet processing apparatus and the like, a technique has been proposed of determining whether or not sheets include any part to be eventually cut off and changing fold line positions based on the determination result (see Japanese Laid-Open Patent Publication (Kokai) No. 2001-163514, for example).

Also, with the conventional sheet processing apparatus and the like, if a cutting position of a sheet is affected by folding, printing of the sheet to be folded is interrupted. For the conventional sheet processing apparatus and the like, a technique has been proposed of changing fold line positions by prompting a user to enter an input for folding position adjustment again (see Japanese Laid-Open Patent Publication (Kokai) No. 2010-002859, for example).

Furthermore, some conventional sheet processing apparatuses and the like are designed to be able to extract and subsequently cut only sheets to be not subjected to folding. In relation to these conventional sheet processing apparatuses and the like, when there is a mixture of sheets which require folding and sheets which require no folding, it is proposed to sort the sheets into a type of sheet requiring folding and a type of sheet requiring no folding and then output the two types of sheet separately (see Japanese Laid-Open Patent Publication (Kokai) No. 10-186959, for example).

In relation to some conventional sheet processing apparatuses and the like, a folding position adjustment technique for a plurality of folding manners including Z-folding has been proposed (see Japanese Laid-Open Patent Publication (Kokai) No. 2006-193288, for example).

However, the use of the conventional techniques described above involve problems described below.

For example, when a specific folding such as Z-folding and a specific cutting such as edge cutting are combined, it is conceivable to use measures described in Japanese Laid-Open Patent Publication (Kokai) No. 2001-163514 and Japanese Laid-Open Patent Publication (Kokai) No. 2010-002859. In so doing, if the first folding position from a base end of the sheet is adjusted automatically, only a single folding position can be adjusted automatically. Consequently, when these measures are used, a distance between the first folding position and the second folding position from the base end of the sheet becomes fixed. This results in a Z-fold of undesirable style in which the distance of the second folding position from the base end of the sheet is longer than half the sheet.

If binding is done in addition to folding and edge cutting, only the first folding position from the base end of the sheet can be adjusted automatically as is the case with the techniques described in Japanese Laid-Open Patent Publication (Kokai) No. 2001-163514 and Japanese Laid-Open Patent Publication (Kokai) No. 2010-002859. Consequently, if the sheet marked for folding is wide, requiring a large cut width, the second folding position from the base end of the sheet will overlap the binding position, resulting in an unexpected output.

SUMMARY OF THE INVENTION

The present invention provides a sheet processing apparatus and method, as well as a controlling apparatus, which are capable of completing a bound document containing appropriately Z-folded sheets when performing folding together with edge cutting and binding.

According to as aspect of the invention, there is provided a sheet processing apparatus controlling a Z-folding process, a cutting process, and a binding process for a sheet, comprising: a cut width acquisition unit configured to acquire a cut width of the sheet for the cutting process; a binding margin acquisition unit configured to acquire a binding margin for the binding process; and a control unit configured to take control such that a first folding position from a free end of the sheet coincides with a position corresponding to half a width of the sheet excluding the cut width acquired by said cut width acquisition unit and the binding margin acquired by said binding margin acquisition unit, when the Z-folding process, the cutting process, and the binding process are executed.

With this arrangement, it is possible to complete a bound document containing an appropriately Z-folded sheet by adjusting a first folding position and a second folding position of the Z-folded sheet when performing folding together with edge cutting and binding.

Further features and advantages of the present invention will become apparent from the following detailed description of exemplary embodiments with reference to the attached drawings.

DETAILED DESCRIPTION OF THE EMBODIMENTS

FIG. 1is a view schematically showing a construction of a printing system equipped with a sheet processing apparatus according to an embodiment of the present invention.

InFIG. 1, a client computer (PC)102and a printing system103are interconnected via a network101. The client computer (PC)102transmits image data as well as a command of specifying post-processing to the printing system103via the network101. The printing system103includes a printing apparatus104and a post-processing apparatus105.

Next, a description will be made of an internal construction of the printing apparatus104inFIG. 1with reference to a block diagram ofFIG. 2.

InFIG. 2, the printing apparatus104of the printing system103is a multi function peripheral (MFP) which has multiple functions including copier functions and printer functions.

The printing apparatus104may be comprised of a single-function printing apparatus (printer) provided with, for example, only copier functions or printer functions.

The printing apparatus104includes various units other than the post-processing apparatus105. Furthermore, the printing apparatus104is adapted to be connectable with the post-processing apparatus105comprised of an arbitrary number of units.

The post-processing apparatus105connected to the printing apparatus104is configured to perform post-processing on sheets printed by the printing apparatus104. It should be noted that the printing system103may be comprised of only the printing apparatus104without the post-processing apparatus105connected to the printing apparatus104.

The post-processing apparatus105is adapted to communicate with the printing apparatus104to thereby perform post-processing (described later) on instructions from the printing apparatus104.

A description will now be made of individual components of the printing apparatus104with reference to a block diagram ofFIG. 2.

The printing apparatus104includes an input image processing unit201, an NIC unit/RIP unit202, an operation unit203, a memory unit207, an output image processing unit205, and a control unit204connected therewith. Besides, the printing apparatus104includes a printer unit206connected to the output image processing unit205. To the printer unit206is connected a post-processing apparatus105.

The input image processing unit201reads images from a source document, converts the images into image data, and transfers the image data to the other units.

The NIC unit/RIP unit202exchanges data with the other units connected to the network101, interprets received PDL (Page Description Language) data, converts the PDL data into raster data, and transfers the raster data to other units.

The output image processing unit205performs image processing suitable for the printer unit206on inputted image data. The printer unit206prints images on sheets based on the image data subjected to output image processing.

The operation unit203includes a hard key input unit (key input unit)302and a touch panel unit301and accepts commands from the user therethrough. Also, the operation unit203produces various displays on the touch panel unit301.

The control unit204exerts overall control over processes and operations of various units in the printing system103. That is, the control unit204also controls operations of the printing apparatus104and the post-processing apparatus105connected to the printing apparatus104.

The memory unit207, which is connected to the control unit204, stores various computer programs to be executed by the control unit204, image data which has been processed by the input image processing unit201, and image data which has been processed by the NIC unit/RIP unit202. Specifically, the memory unit207stores, for example, a program which causes the control unit204to perform various processes shown in a flowchart (described later) and a display control program needed to display various settings screen (described later).

Also, the memory unit207stores a program used by the NIC unit/RIP unit202to translate PDL (Page Description Language) data received from the client computer (PC)102into raster image data. Furthermore, the memory unit207stores a boot sequence, font information, and the like.

A description will now be further made of the internal construction of the printing apparatus104inFIG. 1with reference toFIG. 3.

InFIG. 3, the printing apparatus104mainly includes the input image processing unit201which reads source image data and the printer unit206which outputs source images to recording sheets.

The printing apparatus104is adapted to carry out operations due to the user's operation of the operation unit203of entering a copy mode command or the like. Furthermore, the printing apparatus104is adapted to display various settings and current job status of the printing apparatus on the touch panel unit301of the operation unit203in response to the user actions. The printing apparatus104is adapted to display a “call service person” message on the touch panel unit301in case of trouble in the printing apparatus and display the position of a recording sheet stuck in the apparatus on the touch panel unit301in case of a jam.

The printing apparatus104has paper feed trays34,35,36, and37in the printer unit206to store recording sheets into which the recording sheets are sorted according to paper size and paper type as desired by the user. Also, the printer unit206can be externally connected with a large-capacity paper deck15.

In the printing apparatus104, the recording sheets stored in the paper feed trays34,35,36, and37and a paper deck15are conveyed to an image forming unit by paper feed/conveyance rollers38,39,40,41, and42driven by a motor (not shown).

The printing apparatus104has the input image processing unit201installed on a top portion thereof. In the input image processing unit201, a light source21adapted to move right and left inFIG. 3emits light onto a source document placed on a document glass plate on a top face of the input image processing unit201, and an optical image produced by the light reflected off the source document is focused onto a CCD26through mirrors22,23, and24and a lens25. The CCD26converts the focused optical image into an electrical signal as digital image data, which is subjected to an image conversion process such as scaling at the request of the user, and the data resulting from the image conversion process is stored in the memory unit207.

In the printing apparatus104, at the time of image output, the printer unit206calls up the image data stored in the memory unit207and reconverts the digital signal into an analog signal. The printer unit206converts the analog signal into an optical signal of a laser beam using an optical irradiation unit27, and irradiates a photosensitive drum31via a scanner28, lens29, and a mirror30to thereby scan the photosensitive drum31.

The photosensitive drum31, having a photoconductive layer comprised of organic photoconductive material on an surface thereof, is rotationally driven at a fixed speed during a copy job, which causes an electrostatic latent image corresponding to the image data to be formed on the surface of the photosensitive drum31.

Onto the surface of the photosensitive drum31having the electrostatic latent image formed thereon is adhered toner transferred from a developing device33filled with toner (not shown), thereby enabling a visible image to be formed.

On the other hand, recording sheets are conveyed from the paper feed tray34,35,36, or37through paper conveyance paths and rolling-contact to the photosensitive drum31at a bottom thereof, in synchronization with the visible image. Then, the visible image on the photosensitive drum31is transferred to the recording sheet by a transfer charger48.

The recording sheet carrying the visible toner image (not-yet fixed image) is introduced into between a fixing roller32and a pressure roller43of a fixing device and heated under pressure there, and consequently the visible toner image is fixed to the recording sheets. The image-formed recording sheet with the toner fixed is discharged onto the post-processing apparatus105outside the printing apparatus104.

A description will next be made of the internal construction of the post-processing apparatus105inFIG. 1with reference toFIG. 4.

InFIG. 4, the post-processing apparatus105is adapted to link any number of units of any type as long as sheets with images formed thereon by the printing apparatus104can be conveyed from upstream units to downstream units.

In the post-processing apparatus105ofFIG. 4, a paper folding machine400, a saddle stitch binding machine410, and a cutting machine420are linked in the order named with respect to the distance from the printing apparatus104. The various units of the post-processing apparatus105are designed to be selected and used freely in the printing system103. Also, each unit of the post-processing apparatus105is equipped with a discharge unit, allowing the user to take the post-processed sheets out of the discharge unit.

For example, the sheets discharged from the fixing device of the printing apparatus104enter the post-processing apparatus105. The post-processing apparatus105is equipped with paper output trays413,415as paper output destinations. The discharged sheets are stacked on the paper output trays413,415selectively according to the type of job, the number of sheets discharged, and desires of the user.

Also, the paper folding machine400and the saddle stitch binding machine410are placed on the transport path leading to the paper output trays413,415. The paper folding machine400includes a multi-function folding unit of which functions include a Z-folding function (described later). The multi-function folding unit folds the sheet twice into the shape of a letter Z as viewed from the long side of the sheet using so-called Z-folding. The sheet folded by the paper folding machine400is sent to the saddle stitch binding machine410.

The saddle stitch binding machine410is equipped with a saddle stitcher418. The saddle stitcher418binds a central part of the sheets at two locations, inserts the midsection of the sheets under a roller, thereby folding the bundle of sheets in the middle, and creates a booklet such as a magazine or pamphlet. The sheets book-bound by the saddle stitcher418are discharged onto a booklet tray419and then conveyed to a cutting machine connected to the booklet tray419.

The saddle stitch binding machine410is equipped with a puncher414and is capable of punching holes in the sheets. The saddle stitch binding machine410is equipped with a double-stapling unit417and is capable of applying double-stapling to an end of the sheet. The saddle stitch binding machine410is equipped with an inserter411and is capable of performing saddle stitch binding, double-stapling, and punching by supplying sheets from an insert tray412.

After being thus subjected to saddle stitch binding by the saddle stitcher418or subjected to punching and double-stapling, the bundle of sheets is transported to the cutting machine420via the booklet tray419.

The cutting machine420trims an edge of the book-bound bundle of sheets neatly by a cutter unit421cutting off the edge by a predetermined length. After going through cutting, the bundle of sheets is stored in a booklet holding unit422. In addition to the cutter unit421, the cutting machine420has cutter units (not shown) respectively placed both on the near side and far side in the conveyance direction of the bundle of sheets to enable three-sided cutting as well as edge cutting.

Next, a description will be made of a concrete operation of the paper folding machine400with reference toFIG. 5A. Incidentally, technical details of the paper folding machine400are described in Japanese Laid-Open Patent Publication (Kokai) No. 2006-193288.

InFIG. 5A, the sheet discharged through the fixing device of the printing apparatus104is carried into the paper folding machine400through a conveyance path501. The sheet carried into the paper folding machine400is conveyed on a conveyance path502and caused to hit a first stopper407. Subsequently, the sheet continues to be conveyed to thereby form the first loop. The looped portion of the sheet is thrust into a nip405by folding rollers402,403, and then conveyed by the folding rollers402,403under pressure and hence folded in half.

The paper folding machine400adjusts vertical position of the stopper407to thereby vary the distance between the stopper407and the nip405and to thereby adjust a distance505of a Z-folded portion shown inFIG. 5B. That is, adjusting the vertical position of the stopper407causes the paper folding machine400to form a “first fold of Z-folding” which is the first fold from a free end of the sheet (second fold from a base end of the sheet).

Furthermore, the paper folding machine400continues to convey the sheet folded in half upward, hits the sheet against a second stopper401, continues conveyance after the hit to thereby cause the sheet to form a loop. The second loop of the sheet thus formed is thrust into a second nip406by folding rollers403,404, and then conveyed under pressure by the folding rollers403,404to thereby form a second fold line.

The paper folding machine400moves the second stopper401vertically to thereby vary the distance between the second stopper401and the second nip406, and to thereby adjust a Z-folded width506shown inFIG. 5B. That is, adjusting the vertical position of the second stopper401causes the paper folding machine400to form a “second fold of Z-folding” which is the second fold from the free end of the sheet (first fold from the base end of the sheet).

In the paper folding machine400, the sheet which has been Z-folded is conveyed via a sheet conveyance path503to the post-processing apparatus downstream of a conveyance path504.

A descriptions will now be made of control details and operation of the control unit of the printing system ofFIG. 1.

In the printing system, the control unit204causes the printer unit206to print based on print data contained in a print request (print job) issued at the direction of the user. At the same time, the control unit204analyzes print control information similarly contained in the print request (print job) and subsequently determines what type of post-processing is needed.

Then, the control unit204conveys the print-processed sheet to a unit of the post-processing apparatus105in order for the post-processing apparatus105to perform specified post-processing.

A description will now be made of an example of a print job for the printing system with reference toFIGS. 6A to 6C, assuming that the print job uses four A4-size sheets for print data and includes a process performed when double-stapling is specified in print control information.

In the printing system, when executing the print job which includes a process performed with double-stapling specified, the control unit204causes the printer unit206to perform printing based on the print data. Consequently, the printer unit206outputs printed sheets601,602,603, and604as shown in FIG.6A.

Next, as shown inFIG. 6B, the control unit204transports the printed sheets601to604to the saddle stitching machine410via the paper folding machine400and causes the double-stapling unit417to perform a double-stapling process.

Finally, the control unit204takes control to cause a stapled bundle of sheets (reference) such as shown inFIG. 6Cto be discharged onto the booklet tray419and loaded onto the booklet holding unit422via the cutting machine420. This completes the print job which includes a process performed with double-stapling specified.

A description will now be made of another example of a print job for the printing system with reference toFIGS. 8A to 8D, assuming that the print job uses a mixture of A4 plus sheets and a A3 plus sheet for print data and includes a process performed with a binding margin and a cut width for double-stapling are specified. It should be noted that although in the present embodiment, a position of cutting is specified by the distance from an end of the sheet, the position of cutting may be specified by finished size resulting from the cutting.

When starting the print job, the user specifies a binding margin701and a cut width702using the operation unit203or a driver (not shown) on the client PC102, as shown inFIG. 7by way of example.

As shown inFIG. 8Aby way of example, it is assumed that the first sheet801, the second sheet802, and the fourth sheet804are of A4 plus size and the third sheet803is of A3 plus size.

The printing system Z-folds the A3 plus sized sheet803under the control of the control unit204. Then, the printing system stacks the first sheet801, the second sheet802, the third sheet803, and the fourth sheet804in order.

Next, under the control of the control unit204, the printing system performs a double stapling process on the outer side of the sheet's binding margin specified by the user, as shown inFIG. 8B.

Next, under the control of the control unit204, the printing system performs a cutting process as shown inFIG. 8Cand outputs a bound document such as shown inFIG. 8Dresulting from the cutting.

A description will now be made of details of Z-folding performed by the printing system to produce a good-looking bound document with reference toFIGS. 9A and 9B, taking as an example a mixture of A4 plus sheets and an A3 plus sheet such as described above.

Specifically, a “good-looking bound document” means a bound document folded such that the second folding position will coincide with a position corresponding to approximately half the sheet width excluding any cut width and binding margin as shown inFIGS. 9A and 9B.

The A4 plus size is a size slightly larger than the A4 size (210 mm wide by 297 mm long). Although there are no fixed values, it is assumed here that the A4 plus size measures 220 mm wide by 307 mm long. Also, the A3 plus size is a size slightly larger than the A3 size (420 mm wide by 297 mm long). Although there are no fixed values, it is assumed here that the A3 plus size measures 450 mm wide by 307 mm long. On the other hand, it is assumed that the cut width is 10 mm as specified by the user.

Also, as shown inFIG. 7, the binding margin701entered and specified by the user and acquired by a binding margin acquisition unit adapted to acquire the binding margin is 10 mm. Also, the cut width702acquired by a cut width acquisition unit adapted to acquire the cut width is 10 mm.

In the example shown inFIGS. 9A and 9B, to perform ideal ¼ Z-folding for a good-looking bound document, it is necessary to fold the sheet at the position corresponding to half the size obtained by subtracting the binding margin and the cut width from the A4 plus size.

Specifically, the distance506corresponding to the folding width is given by (220−10−10)/2=100 mm which is equal to half the value obtained by subtracting the cut width of 10 mm and binding margin of 10 mm from the A4 plus size of 220 mm.

Next, to determine the distance505from the end shown inFIGS. 9A and 9B, the cut width702is added to the Z-folded width506. That is, the distance505from the end is given by 100 mm+10 mm=110 mm.

The control unit204takes control to perform Z-folding by adjusting the positions of the second stopper401and the first stopper407in the paper folding machine400shown inFIG. 5using the distance505from the end determined as described above.

In this way, the printing system inFIG. 2can perform ideal Z-folding without cutting a fold during cutting work or binding a portion around the fold during binding work and without specifying complex folding positions.

It should be noted that although an example of using an A4 plus size and an A3 plus size has been described in relation to the print job including a process performed with double-stapling specified, the present invention is not limited to this.

The printing system inFIG. 1can apply the present method to any size as long as the size is supported by the printing system. In this case, in determining folding positions based on the cut width and the binding margin specified by the user and on paper size, the control unit204of the printing system103uses generalized calculation formulae described below. The distances or widths used are as shown inFIGS. 9A and 9B.
Z-folded width 506=(sheet width 901−cut width 702−binding margin 701)/2  Calculation formula (1)
Distance 505 from the end=Z-folded width 506+cut width 702  Calculation formula (2)

The sheet width represents the paper size.

In short, the control unit204performs Z-folding in such a way that the first fold line from the free end of the sheet will fall on the position corresponding to the size of half the value obtained by subtracting the cut width702and the binding margin701specified by the user from the sheet width901. Thus, the size resulting from addition of the cut width to the size of half the value obtained by subtracting the cut width702and the binding margin701specified by the user from the sheet width901is set to correspond to the distance of the first fold line from the free end of the sheet before cutting.

That is, as can be seen from the above calculation formulae, once the cut width702and the binding margin701are determined, an ideal folding position can be determined automatically based on the sheet width901representing the paper size.

A description will now be made of the print job processing performed by the printing apparatus104shown inFIG. 2with reference to a flowchart ofFIG. 11.

A processing program used to control the print job processing is stored in the memory unit207and executed by the control unit204.

InFIG. 11, first print control information of a print job which specifies printing is acquired (step S1102).

Next, the print control information acquired in step S1102is scanned to determine whether or not folding is specified for the print job (step S1103).

As a result of the determination of the step S1103, when there is a sheet specified to be folded, the program proceeds to step S1104.

Next, the print control information acquired in step S1102is scanned to determine whether or not cutting is specified for the print job, i.e., whether or not the print job is subjected to cutting (step S1104).

As a result of the determination of the step S1104, when the cutting is specified for the print job (YES to the step S1104), the program proceeds to step S1105.

Next, the print control information acquired in step S1102is scanned to determine whether or not binding or a binding margin is specified for the print job (step S1105).

Moreover, the order of steps S1103, S1104, and S1105above is arbitrary.

As a result of the determination of the step S1105, when there is no sheet for which a binding margin is specified, the binding margin is set to “0” (step S1108) and subsequently the folding position is calculated (step S1106), to perform a normal printing process.

Subsequently, a printing process is performed based on the print data and print control information contained in the print job, followed by the program terminating (step S1110).

On the other hand, if it is determined in the step S1105that a binding margin has been specified, (YES to the step S1105), the control unit204calculates the folding position using the calculation formulae described above (step S1106).

Next, a printing process is performed based on the folding position calculated in the step S1106as well as on the binding margin and the cut width (step S1110), followed by the program terminating.

If it is determined in the step S1104that the print job is not subjected to cutting (NO to the step S1104), a standard folding position is set (step S1109), and subsequently a printing process is performed based on the standard folding position (step S1110), followed by the program terminating.

As described above, according to the printing system ofFIG. 1, it is possible to avoid inadvertently cutting or binding a bundle of sheets containing the folded sheet. Also, according to the printing system ofFIG. 1, it is possible to perform ideal ¼ Z-folding without specifying complex folding positions and easily provide high-value products in the form of good-looking bound documents by preventing errors. Also, according to the printing system ofFIG. 1, it is possible to perform ¼ Z-folding in relation to finished size even if sheets have undergone binding, cutting, and folding. Furthermore, according to the printing system of the present embodiment, it is possible to avoid a situation in which a sheet which has undergone Z-folding is bound inadvertently even if folding positions are adjusted so as to avoid cutting.

Also, according to the printing system ofFIG. 1, it is possible to obtain a bound document folded such that the second folding position will coincide with a position corresponding to half the sheet width excluding any cut width and binding margin by calculating the folding position using the calculation formulae described above.

Next, another configuration example of the printing system ofFIG. 1will be described with reference toFIGS. 10A and 10B, wherein a folding margin is provided to avoid cutting a fold due to the problem of mechanical accuracy of the folding position and cutting position.

As shown inFIG. 10A, when a folding margin1001of approximately 5 mm is provided, a Z-folded width1002and the distance505from the end can be found using the calculation formulae described above.

The distance1002of binding is calculated as (220 mm−10 mm−10 mm)/2=100 mm while the distance505from the end is calculated as 100 mm+10 mm=110 mm

By taking into consideration the folding margin1001of 5 mm, the control unit204exercises control so as to perform Z-folding by adjusting the positions of the second stopper401and the first stopper407in the paper folding machine400shown inFIG. 5. That is, by setting the distance between the second stopper401and the second nip406of the paper folding machine400to 100 mm−5 mm=95 mm, the control unit204can prevent a portion around a fold from being cut off due to the problem of mechanical accuracy.

In this case, the calculation formulae shown below are used.
Z-folded width 506=(sheet width 901−cut width 702−binding margin 701)/2−folding margin 1001  Calculation formula (3)
Distance 505 from the end=Z-folded width 506+cut width 702  Calculation formula (4)

That is, once the cut width702, the binding margin701, and the folding margin1001are determined, the printing system can automatically determine an ideal folding position from the sheet width901(paper size).

The processing functions shown in the processing ofFIG. 11can also be implemented by means of software (program) acquired via a network or any of various storage media and executed on a processing unit (CPU or processor) of a computer.

This application claims the benefit of Japanese Applications No. 2010-279276, filed Dec. 15, 2010, which is hereby incorporated by reference herein in its entirety.