1. Field of the Invention
The present invention generally relates to a sheet processing apparatus. More particularly, the present invention relates to a sheet processing apparatus capable of cutting a sheet.
2. Description of the Related Art
With a conventional image forming apparatus, such as a copying machine, a printer, a facsimile, and a multifunction peripheral including functions of such apparatuses, a booklet-like sheet stack can be obtained in the following manner. After sheets output from an image forming apparatus body are stacked, the sheet stack is bound with a stapler at one or two positions. Then, the bound sheet stack is folded at the stapled positions to produce a booklet.
In recent years, post-processing of a print product is performed in various different ways as in the case of, for example, producing a booklet to be inserted into an envelope. For example, in outputting a small size bound sheet stack, it may be desirable to cut a large regular-size sheet into a number of small size sheets. In this regard, Japanese Utility Model Registration No. 3012298 discusses a paper cutting apparatus configured to cut a large size sheet into small size sheets.
In cutting a large regular-size sheet into small size sheets, waste cut-off sheets may be generated due to the difference between the size of the large regular-size sheet and the size of the small size sheet. In this regard, however, a conventional paper cutting apparatus merely cuts a sheet into a desired size sheet and does not support bookbinding processing after cutting a sheet stack. Accordingly, the conventional paper cutting apparatus cannot calculate a sheet size according to which an amount of waste cut-off sheets generated during a cutting operation is minimized or decreased. Thus, to minimize or decrease an amount of waste cut-off sheets, a relatively complex computation is required to be manually performed by a user to select or determine an optimal sheet size to be cut with the conventional paper cutting apparatus.
Furthermore, in producing a small size bound sheet stack with a conventional paper cutting apparatus, the number of times of folding a large size sheet is limited to one. Thus, only a small number of pages can be obtained from one large size sheet. Accordingly, when a desired sheet size is smaller than the size of a sheet obtained by folding a large size sheet once, an excessive amount of waste cut-off sheets can be generated.
An embodiment of the present invention is directed to a sheet processing apparatus capable of utilizing a sheet such that an amount of waste cut-off sheets generated during a cutting operation is minimized or reduced.
According to an aspect of the present invention, a sheet processing apparatus includes a cutting unit configured to cut an edge portion of a sheet, and a calculation unit configured to calculate a sheet utilization efficiency based on an area of the sheet before cutting and an area of a sheet obtained by cutting the edge portion by the cutting unit.
According to another aspect of the present invention, a sheet processing apparatus includes a cutting unit configured to cut an edge portion of the sheet, and a sheet size selection unit configured to select a size of sheet to be processed based on an area of the sheet before cutting and an area of a sheet obtained by cutting the edge portion by the cutting unit.
According to an exemplary embodiment of the present invention, sheets can be efficiently used without generating an excessive amount of waste cut-off sheets.
Further features and aspects of the present invention will become apparent from the following detailed description of exemplary embodiments with reference to the attached drawings.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments, features, and aspects of the invention and, together with the description, serve to explain the principle of the invention.
Various exemplary embodiments, features and aspects of the present invention will now herein be described in detail with reference to the drawings. It is to be noted that the relative arrangement of the components, the numerical expressions, and numerical values set forth in these embodiments are not intended to limit the scope of the present invention unless it is specifically stated otherwise.
The image forming apparatus 1000 includes an image forming apparatus body 1100, a folding machine 400, a finisher 500, and a cutting unit 2000. The image forming apparatus body 1100 includes a document feeder 100, an image reader 200, and a printer 300. The document feeder 100 and the image reader 200 are not always necessary. The image forming apparatus body 1100 can form an image based on an external signal with the printer 300.
The document feeder 100 conveys documents D that are set thereon sheet by sheet from the first page from left to right in
When a document passes the scanner unit 104, light emitted from a lamp 103 of the scanner unit 104 illuminates the document, and light reflected from the document is guided to an image sensor 109 via mirrors 105, 106, and 107 and a lens 108. When the user sets a document on the platen glass 102 without using the document feeder 100, the image reader 200 can read the set document while moving from left to right in
The image of the document read with the image sensor 109 is subjected to image processing, and the processed image is then sent to an exposure control unit 110. The exposure control unit 110 outputs a laser beam according to an image signal. The laser beam is irradiated onto the surface of a photosensitive drum 111, which is an image forming member, to form an electrostatic latent image on the surface of the photosensitive drum 111. The electrostatic latent image formed on the surface of the photosensitive drum 111 is developed with toner by a development device 113 to form a toner image. The toner image formed on the photosensitive drum 111 is transferred by a transfer unit 116 onto a sheet fed from any one of cassettes 114 and 115, a manual feed unit 125, and a two-sided conveyance path 124.
The user can enter a type of sheet to be fed from the manual feed unit 125 or the cassettes 114 and 115, such as, for example, a thick paper or an overhead projector (OHP) sheet, via an operation unit 1 (
The toner image transferred onto the sheet is fixed by a fixing unit 117. The sheet that has passed the fixing unit 117 is temporarily guided to a path 122 by a flapper 121. Then, after a trailing edge of the sheet passes through the flapper 121, the sheet is guided to a discharge roller 118 by the flapper 121. Thus, the sheet is switched back to be conveyed. The sheet is conveyed with a side having the toner image formed thereon facing down and is discharged from the printer 300 by the discharge roller 118.
The sheet discharged from the discharge roller 118 is conveyed into the folding machine 400. The folding machine 400, which is also referred to herein as a folding unit, can fold the sheet in three-folded sections in a Z-like shape or fold the sheet in a single-fold configuration (also referred to herein as “once-folding”). In a case where an A3 size or B4 size sheet is designated to be subjected to Z-like shape folding processing or where the sheet is designated to be cut into smaller size sheets and a double-fold configuration (also referred to herein as “twice-folding”) is requested, the folding machine 400 performs the requested folding processing on the sheet. It is noted that sheets can be conveyed into the finisher 500 without being folded by the folding machine 400.
The finisher 500 includes an inlet roller pair 502 that guides the sheet discharged from the printer 300 via the folding machine 400. On the downstream side of the inlet roller pair 502, a switching flapper 551 that guides the sheet into a finisher path 552 or a first bookbinding path 553 is disposed.
The sheet conveyed from the first bookbinding path 553 is stacked onto a bookbinding processing tray 820 via a first conveyance roller pair 813 and a second conveyance roller pair 817. The sheet is further conveyed by a third conveyance roller 822 until the leading edge of the sheet contacts a movable sheet positioning member 823. Two pairs of staplers 829, which serve as a binding unit, are disposed on the downstream side of the second conveyance roller pair 817 in the conveyance direction. The staplers 829 operate in cooperation with an anvil 830 disposed at a position opposite to the staplers 829 to bind a sheet stack at a center portion thereof with staples. The staplers 829 can move in a direction orthogonal to the sheet conveyance direction and can freely change a staple position according to a booklet configuration to be produced.
A folding roller pair 826 is disposed on the downstream side of the staplers 829. The folding roller pair 826 pinches a sheet stack that is extruded by an extrusion member 827. Then, the folding roller pair 826 conveys and folds the sheet stack to feed the sheet stack to the cutting unit 2000. The folding roller pair 826 and the extrusion member 827 constitute a sheet stack folding apparatus 828, which is a folding unit.
In the cutting unit 2000, a cutter 2001 cuts off a trailing edge portion (upstream edge portion) of the sheet stack. Thus, a pouched portion on the trailing edge of a sheet twice-folded by the folding machine 400 and the sheet stack folding apparatus 828 is cut off in a method described later below, thus forming pages that can be turned over. Then, a cutter 2002 cuts off the side edge portions of the sheet stack and cuts the sheet stack along a direction parallel to the sheet conveyance direction to divide the sheet stack into two. Thus, the cutting unit 2000 cuts the sheet stack into a designated size.
In addition, the image forming apparatus 1000 can stack a sheet stack onto an intermediate tray 630, bind the sheet stack at its edge portion by using a stapler 601, and discharge the bound sheet stack onto a tray 700 or a tray 701.
The sheet feeder control unit 101 controls the document feeder 100. The image reader control unit 201 controls the image reader 200. The image forming control unit 301 controls the printer 300. The folding machine control unit 401 controls the folding machine 400. The finisher control unit 501 controls the finisher 500. The finisher control unit 501 also controls a cutting unit control unit 2100. The cutting unit control unit 2100 controls the cutting unit 2000.
A random access memory (RAM) 152 is used as a temporary storage area for temporarily storing control data and a work area for calculation performed during control. The external I/F 209, which is an interface with a computer 210, rasterizes print data into image data and outputs the image data to the image signal control unit 202. Image data read with the image sensor 109 is output from the image reader control unit 201 to the image signal control unit 202. Image data output from the image signal control unit 202 to the image forming control unit 301 is supplied to the exposure control unit 110.
Referring to
If, in the processing for determining the number of times of folding in step S300, it is determined that the number of times of folding is 2, it is necessary to fold the sheet twice. That is, the folding machine 400 folds the sheet once and the finisher 500 further folds the folded sheet once. On the other hand, if, in the processing for determining the number of times of folding in step S300, it is determined that the number of times of folding is 1, the sheet is folded only once by the finisher 500, while the folding machine 400 does not perform folding. The sheet that is once-folded is doubled in the thickness direction. The sheet that is twice-folded is quadruplicated in the thickness direction.
If it is determined in step S102 that the number of times of folding is 2, then in step S103, the image forming circuit 150 allows the folding machine 400 to perform first folding processing via the folding machine control unit 401 to fold the sheet as illustrated in
The sheet conveyed to the finisher 500 is stacked onto the bookbinding processing tray 820. If it is determined in step S102 that the number of times of folding is 1, the folding machine control unit 401 does not operate the folding machine 400 according to a command from the image forming circuit 150. In this case, the sheet passes through the folding machine 400 without being processed and is stacked onto the bookbinding processing tray 820 of the finisher 500. Sheets stacked onto the bookbinding processing tray 820 are received by the sheet positioning member 823 with their lower edge portions aligned.
In step S104, after the sheets are stacked onto the bookbinding processing tray 820, the finisher control unit 501 checks if the current stacked sheet is the last sheet of the sheet stack. If it is determined in step S104 that the current stacked sheet is not the last sheet of the sheet stack (NO in step S104), then the image forming circuit 150 performs the processing described above on a subsequent sheet. On the other hand, if it is determined in step S104 that the current stacked sheet is the last sheet of the sheet stack (YES in step S104), then in step S105, the image forming circuit 150 operates the staplers 829 to staple the sheet stack received by the sheet positioning member 823.
In step S106, the finisher control unit 501 moves the sheet positioning member 823 downward to allow the bound portion of the sheet stack to face the extrusion member 827, and performs second folding processing to fold the sheet stack with the extrusion member 827 and the folding roller pair 826. In this case, the sheet stack that has been subjected to the first folding processing is folded once more. The sheet stack folded twice is quadruplicated in the thickness direction in a state where a pouched portion is formed at the trailing edge thereof, as illustrated in
In step S107, the finisher control unit 501 conveys the folded sheet stack to the cutting unit 2000 to perform cutting processing on the folded sheet stack with the cutting unit 2000. In the cutting processing, as illustrated in
Then, as illustrated in
Referring to
The user enters, via the operation unit 1, values of the length of a feeding sheet in the conveyance direction (Y), a cutting margin (A), and a distance (M) between the back and the fore edge of a booklet. The feeding sheet is a sheet that is to be folded and is stored in either of the cassettes 114 and 115 and the manual feed unit 125.
In step S301, the CPU 153 calculates a numerical value for determining the number of times a sheet is to be folded according to the following expression:
((Y(length of the feeding sheet in the conveyance direction)/2)−A(cutting margin))/M(distance between the back and the fore edge).
If it is determined that the numerical value for determining the number of times of folding is less than 1, then in step S302, the CPU 153 determines that the feeding sheet has an unusable size, with which a booklet cannot be produced. If it is determined that the numerical value for determining the number of times of folding is equal to or greater than 1 and less than 4, then in step S303, the CPU 153 determines that the feeding sheet has a once-folding size, with which the feeding sheet can be folded once (the number of times of folding being 1). If it is determined that the numerical value for determining the number of times of folding is equal to or greater than 4, then in step S304, the CPU 153 determines that the feeding sheet has a twice-folding size, with which the feeding sheet can be folded twice (the number of times of folding being 2). As illustrated in
In step S400, the image forming circuit 150 determines the number of divisions. The processing of “division” refers to division of a sheet stack by cutting the sheet stack on the line along the conveyance direction. The user enters, via the operation unit 1, numerical values of the length of the feeding sheet in a direction orthogonal to the sheet conveyance direction (X) and the length of the back (L).
In step S401, the CPU 153 calculates a numerical value for determining the number of divisions for a booklet according to the following expression:
(X(length of the feeding sheet in the direction orthogonal to the sheet conveyance direction)−A(cutting margin)×2)/L(length of the back).
If the numerical value for determining the number of divisions for a booklet is less than 1, then in step S402, the CPU 153 determines that the feeding sheet has an unusable size, with which a booklet cannot be produced. If it is determined that the numerical value for determining the number of divisions for a booklet is equal to or greater than 1 and less than 2, then in step S403, the CPU 153 determines that the feeding sheet has an undivided size, with which the feeding sheet cannot be divided (that the number of divisions being 1). If it is determined that the numerical value for determining the number of divisions for a booklet is equal to or greater than 2, then in step S404, the CPU 153 determines that the feeding sheet has a two-division size, with which the feeding sheet can be divided into two (the number of divisions being 2). As illustrated in
The value “A” (cutting margin) is an assumed minimum value, and is not necessarily equivalent to the actual amount of cutting of the sheet stack. That is, supposing that a utilization efficiency illustrated in
In step S500, the CPU 153 calculates an area of the booklet (utilization area) according to the following expression:
L×M×number of divisions×number of times of folding×2.
In step S600, the CPU 153 calculates a utilization efficiency according to the following expression:
Utilization area/regular size area.
The CPU 153 performs the above-described processing on each regular size sheet or each arbitrary size sheet stacked in the paper feed cassettes to determine a sheet utilization efficiency for each sheet size.
The image forming circuit 150 displays a result of calculation performed during the utilization efficiency determination processing on the operation unit 1 (
In addition, the ratio of cut-off wastes (the amount of waste cut-off sheets) or the area of cut-off wastes can be displayed instead of the utilization efficiency. In this case, the area of cut-off wastes=100%−utilization efficiency (%). For example, in a case where the utilization efficiency is 64%, the area of cut-off wastes is 56%. In this case, the image forming circuit 150 can select a sheet having the highest utilization efficiency to automatically feed the sheet having the highest utilization efficiency from the cassette 114 or 115.
The user can select a feeding sheet size by selecting one of “select” buttons 1A through 1E, which are disposed to the right of the portions indicating the paper sizes to be selected. In addition, the user can select an “auto setting” button 1F to automatically select an optimum feeding sheet size.
In the above-described example, the user enters and sets the size that can be obtained after bookbinding. However, the size that can be obtained after bookbinding can be automatically set by the CPU 153.
A case where an optimum booklet size (the size of a sheet stack after bookbinding) is calculated and displayed based on the size of a designated feeding sheet will now be described below.
The CPU 153 calculates the length of the back (L) according to the following expression:
(X(length of the feeding sheet in the direction orthogonal to the conveyance direction)−2×A(minimum cutting margin))/number of divisions.
In addition, the CPU 153 calculates the distance between the back and the fore edge (M) according to the following expression:
(Y(length of the feeding sheet in the conveyance direction)−number of times of folding×2×A)/(number of times of folding×2).
In an embodiment, the CPU 153 performs the above-described calculation under four different conditions ((1) the number of times of folding is 1 and the number of divisions is 1, (2) the number of times of folding is 1 and the number of divisions is 2, (3) the number of times of folding is 2 and the number of divisions is 1, and (4) the number of times of folding is 2 and the number of divisions is 2) to determine the optimum size for a booklet. The CPU 153 then displays the optimum size and the utilization efficiency for each condition, as illustrated in
The user can select a booklet size by selecting one of “select” buttons 1H through 1M disposed to the right of the field indicating the sizes to be selected. The user can enter a feeding sheet size by selecting a “paper size” button 1G illustrated in
It may be necessary to alter an image orientation and a page allocation depending on the case of once-folding performed only with the finisher 500 (where the number of times of folding is 1) and the case of twice-folding performed with the finisher 500 and the folding machine 400 (where the number of times of folding is 2) and depending on the direction of opening a booklet. The opening direction includes “open to right”, with which a page in a booklet is turned over with its back positioned on the right of the booklet, “open to left”, with which a page in a booklet is turned over with its back positioned on the left of the booklet, and “open to top”, with which a page in a booklet is turned over with its back positioned on the top of the booklet.
In the case of dividing a sheet, the same images can be formed on the sheet to be juxtaposed along the direction orthogonal to the conveyance direction. The number of times of folding can be calculated according to the utilization efficiency determination flow S200 in
An orientation of images in the case of once-folding (where the number of times of folding is 1) will now be described below with reference to
The page allocation in the case of “open to left” or “open to top” in once-folding (where the number of times of folding is 1) will now be described below with reference to
The CPU 153 first calculates the number of sheets on which images are to be formed (K). The number of sheets on which images are to be formed (K) is indicated by a value obtained by an expression “the number of documents/4”, while rounding fractional figures (K=roundup (the number of documents/4)).
Then, the CPU 153 performs allocation on each sheet on which images are to be formed considering which page is allocated to each image position of the sheet on which images are formed at four positions (A, B, C, and D). A print page for each image position can be calculated according to the following expressions (1) through (4). However, if the calculated value exceeds the number of documents, no image is formed at the image position:
The image position A: 2×(K+N) (1)
The image position B: 2×(K−N)+1 (2)
The image position C: 2×(K−N)+2 (3)
The image position D: 2×(K+N)−1 (4)
where “N” denotes the order of discharge of a sheet from the image forming apparatus body 1100 (the first sheet, the second sheet, . . . and the N-th sheet), and “K” denotes the number of sheets on which images are to be formed.
For example, when the number of documents is 9, a resulting value of round-up of 9/4 is 3, and thus the number of sheets on which images are to be formed is 3. With respect to the page allocation, as illustrated in
The page allocation in the case of “open to right” in once-folding (where the number of times of folding is 1) will now be described below with reference to
The CPU 153 calculates the number of sheets on which images are to be formed (K). The number of sheets on which images are to be formed (K) is indicated by a value obtained by an expression “the number of documents/4”, while rounding fractional figures (K=roundup (the number of documents/4)).
Then, the CPU 153 performs allocation on each sheet on which images are to be formed considering which page is allocated to each image position of the sheet on which images are formed at four positions.
A print page for each image position can be calculated according to the following expressions (5) through (8). However, if the calculated value exceeds the number of documents, no image is formed at the image position:
The image position A: 2×(K−N)+1 (5)
The image position B: 2×(K+N) (6)
The image position C: 2×(K+N)−1 (7)
The image position D: 2×(K−N)+2 (8)
where “N” denotes the order of discharge of a sheet from the image forming apparatus body 1100 (the first sheet, the second sheet, . . . and the N-th sheet), and “K” denotes the number of sheets on which images are to be formed.
For example, when the number of documents is 9, a resulting value of round-up of 9/4 is 3, and thus the number of sheets on which images are to be formed is 3. With respect to the page allocation, as illustrated in
An orientation of images in the case of twice-folding (where the number of times of folding is 2) will now be described below with reference to
The page allocation in the case of “open to left” or “open to top” in twice-folding (where the number of times of folding is 2) will now be described below with reference to
The CPU 153 first calculates the number of sheets on which images are to be formed (K). The number of sheets on which images are to be formed (K) is indicated by a value obtained by an expression “the number of documents/8”, while rounding fractional figures (K=roundup (the number of documents/8)).
Then, the CPU 153 performs allocation on each sheet on which images are to be formed considering which page is allocated to each image position of the sheet on which images are formed at eight positions (A, B, C, D, E, F, G, and H).
A print page for each image position can be calculated according to the following expressions (9) through (16). However, if the calculated value exceeds the number of documents, no image is formed at the image position:
The image position A: 4×(K−N)+2 (9)
The image position B: 4×(K+N)−1 (10)
The image position C: 4×(K+N)−2 (11)
The image position D: 4×(K−N)+3 (12)
The image position E: 4×(K−N)+4 (13)
The image position F: 4×(K+N)−3 (14)
The image position G: 4×(K+N) (15)
The image position H: 4×(K−N)+1 (16)
where “N” denotes the order of discharge of a sheet from the image forming apparatus body 1100 (the first sheet, the second sheet, . . . and the N-th sheet), and “K” denotes the number of sheets on which images are to be formed.
For example, when the number of documents is 15, a resulting value of round-up of 15/8 is 2, and thus the number of sheets on which images are to be formed is 2. With respect to the page allocation, as illustrated in
The page allocation in the case of “open to right” in twice-folding (where the number of times of folding is 2) will now be described below with reference to
The CPU 153 first calculates the number of sheet on which images are to be formed (K). The number of sheets on which images are to be formed (K) is indicated by a value obtained by an expression “the number of documents/8”, while rounding fractional figures (K=roundup (the number of documents/8)).
Then, the CPU 153 performs allocation on each sheet on which images are to be formed considering which page is allocated to each image position of the sheet on which images are formed at eight positions (A, B, C, D, E, F, G, and H).
A print page for each image position can be calculated according to the following expressions (17) through (24). However, if the calculated value exceeds the number of documents, no image is formed at the image position:
The image position A: 4×(K+N)−1 (17)
The image position B: 4×(K−N)+2 (18)
The image position C: 4×(K−N)+3 (19)
The image position D: 4×(K+N)−2 (20)
The image position E: 4×(K+N)−3 (21)
The image position F: 4×(K−N)+4 (22)
The image position G: 4×(K−N)+1 (23)
The image position H: 4×(K+N) (24)
Where “N” denotes the order of discharge of a sheet from the image forming apparatus body 1100 (the first sheet, the second sheet, . . . and the N-th sheet), and “K” denotes the number of sheets on which images are to be formed.
For example, when the number of documents is 15, a resulting value of round-up of 15/8 is 2, and thus the number of sheets on which images are to be formed is 2. With respect to the page allocation, as illustrated in
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 modifications, equivalent structures, and functions.
This application claims priority from Japanese Patent Application No. 2006-161535 filed Jun. 9, 2006, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2006-161535 | Jun 2006 | JP | national |