JP2009143653A - Sheet conveying device and its control method, and image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sheet conveying device having excellent energy saving property and durability, and capable of rapidly detecting the transverse deviation of sheets. <P>SOLUTION: If all sensors 104A-104C detect a sheet S or detect no sheet when the sheet S reaches a transverse deviation detection sensor unit 104, the sensor (104A or 104C) closest to a side end of the sheet S is selected. On the other hand, if at least one of the sensors 104A-104C detects the sheet S, any one of the sensor which is closest to the side end of the sheet S and detects the sheet S and the other sensor which is closest to the side end of the sheet S and does not detect the sheet S is selected. A CPU 401 performs the control that the selected sensor is energized, and the unselected sensor is not energized. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a sheet conveying apparatus that conveys an image-formed sheet, a control method therefor, and an image forming apparatus.

  Some recent image forming apparatuses are connected to a plurality of sheet processing apparatuses that perform large-capacity stackers, stapling, punching, saddle stitching, and the like to constitute an image forming system. In such a large-scale image forming system, an attachment error occurs at a connection portion between the image forming apparatus and the sheet processing apparatus or between the sheet processing apparatuses, or the conveyance path becomes long. As a result, during sheet conveyance, the sheet misalignment (hereinafter referred to as “lateral deviation”) in the direction orthogonal to the sheet conveyance direction (hereinafter referred to as “width direction”) is larger than that in the prior art. Tend to be. In particular, in the sheet processing apparatus disposed on the downstream side in the sheet conveyance direction, the lateral shift becomes large.

  Since the lateral shift becomes a factor that reduces the positional accuracy of stapling and punching in the sheet processing apparatus, the lateral shift is corrected in the sheet processing apparatus. In order to correct the lateral deviation at high speed, there is a method of correcting the lateral deviation by detecting the lateral deviation amount in advance and moving the sheet in the width direction while conveying the sheet. In this method, the sheet is moved in the width direction in a state where the movement distance of the sheet necessary for correcting the lateral deviation is grasped. Therefore, the sheet can be moved at an optimum speed according to the moving distance, and the lateral shift can be corrected at a high speed.

  As a typical lateral deviation detection method, an optical transmission sensor is moved in the width direction, and a lateral deviation amount is detected from a movement distance from the start of movement to detection of the lateral edge of the sheet (Patent Document 1). And a method of detecting a lateral deviation amount using a line sensor. Although the latter method can detect at high speed, the circuit for controlling the line sensor is very expensive, and the former method is adopted in many products.

  In the former method, the sensor waits so that the detection point of the sensor is located at the sheet end in a state where there is no lateral shift. If the sensor is ON at the start of detection (sheet is detected), the sensor is moved in the direction in which the sensor is OFF. On the other hand, when the sensor is OFF (no sheet is detected), the sensor is moved in the direction in which the sensor is ON. For example, when there is a lateral displacement of 15 mm with the sensor detecting the sheet, the lateral displacement amount can be detected by moving the sensor by 15 mm in a direction in which the sensor no longer detects the sheet.

  However, in the former method, the longer the amount of lateral displacement, the longer it takes to detect. When the sheet is conveyed at a high speed in order to increase the number of images formed per unit time (high productivity), there is a possibility that the amount of lateral deviation cannot be detected while the sheet passes through the sensor. Thus, in order to detect the amount of lateral deviation even during high-speed conveyance, a method of arranging a plurality of transmission sensors in the width direction and reducing the movement distance can be considered. For example, if there is a lateral displacement of 15 mm as in the above example, if the three sensors are arranged at intervals of 10 mm in the width direction, the lateral displacement amount can be detected only by moving the sensors by 5 mm.

On the other hand, in a system composed of an image forming device and a sheet processing device, in addition to realizing high productivity and reducing the unit price, it also reduces the maintenance cost (running cost) of the device due to energy saving and longer life. Is also strongly sought after.
2005-156578

  However, when the number of sensors is increased in order to increase the speed as described above, there is a problem that the current consumption increases accordingly. Moreover, if the usage time of the sensor becomes long, the sensor will reach the end of its life quickly. For example, since the light output of an LED used in an optical sensor is reduced by long-term use, it is necessary to shorten the lighting time of the LED during operation in order to extend the life.

  The present invention has been made in view of the above problems, and its object is to provide a sheet conveying apparatus that is excellent in energy saving and durability, and capable of detecting a lateral deviation amount of a sheet at high speed with an inexpensive configuration, and its A control method and an image forming apparatus are provided.

  In order to achieve the above object, a sheet conveying apparatus according to claim 1 is provided along a width direction perpendicular to a sheet conveying direction in order to detect a sheet conveyed by the conveying unit and a sheet conveyed by the conveying unit. A sheet conveying device comprising: a sheet detecting unit having a plurality of sensors arranged; and a moving unit that moves the sheet detecting unit in the width direction, wherein the sheet is detected when the sheet reaches the sheet detecting unit. If all of the plurality of sensors detect or do not detect the sheet, the sensor closest to the side edge of the sheet is selected, while if at least one of the plurality of sensors detects the sheet, Either one of the sensor that detects the sheet closest to the side edge and the other sensor that does not detect the sheet closest to the side edge of the sheet is selected. And a control unit that energizes the sensor selected by the selection unit and does not energize the unselected sensor when detecting the side edge of the sheet while moving the sheet detection unit by the selection unit and the moving unit. And a control means for performing the above.

  In order to achieve the above object, a sheet conveying apparatus according to claim 2 is provided along a width direction orthogonal to a sheet conveying direction in order to detect a sheet conveyed by the conveying means and a sheet conveyed by the conveying means. A sheet conveying device including a sheet detecting unit having a plurality of sensors arranged and a moving unit that moves the sheet detecting unit in the width direction, each counting the number of energizations to the plurality of sensors. When detecting the side edge of the sheet while moving the sheet detecting means by the moving means, the selecting means for selecting the sensor with the smallest number of energized times among the plurality of sensors, The sensor selected by the selection means is energized, and the sensor not selected is not energized.

  In order to achieve the above object, a control method for a sheet conveying apparatus according to claim 5 includes a conveying unit that conveys a sheet, and a width orthogonal to a sheet conveying direction to detect the sheet conveyed by the conveying unit. A sheet conveying apparatus control method comprising: a sheet detecting unit having a plurality of sensors arranged along a direction; and a moving unit that moves the sheet detecting unit in the width direction. A first control step that energizes the sensor closest to the side edge of the sheet and does not energize other sensors when all of the plurality of sensors at the time of reaching the sheet have detected or have not detected the sheet And when at least one of the plurality of sensors when the sheet reaches the sheet detecting means detects the sheet, the sheet closest to the side edge of the sheet is detected. A second control step of energizing either one of the sensor and the other sensor not detecting the side edge of the sheet closest to the side edge of the sheet and not energizing the other sensor. Features.

  According to the present invention, the power required for a plurality of sensors can be reduced by turning off the power to the sensors that are not used when detecting the amount of lateral deviation of the sheet by the plurality of sensors. Moreover, the lighting time of LED used for a sensor can also be reduced and the lifetime of a sensor can also be extended.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a longitudinal sectional view illustrating a schematic structure of an image forming system including a sheet processing apparatus including a sheet conveying apparatus according to an embodiment of the present invention and an image forming apparatus.

  The image forming system 1 includes a black-and-white / color copying machine main body (hereinafter referred to as “copying machine main body”) 300 and a sheet processing apparatus 100 connected to the copying machine main body 300.

  The copying machine main body 300 includes an automatic document feeder 500, yellow, magenta, cyan, and black photosensitive drums 914a to 914d as image forming units, a fixing device 904, and cassettes 909a to 909d that store sheets. Prepare. Further, a control device 950 that controls the entire copying machine is provided. On the sheets fed from the cassettes 909a to 909d, toner images of four colors are transferred by the photosensitive drums 914a to 914d, etc., conveyed to the fixing device 904, and the toner images are fixed, and then discharged outside the apparatus. The copying machine main body 300 includes constituent elements necessary for the copying machine other than those shown in the drawing, but the description thereof is omitted.

  Sheets discharged from the copying machine main body 300 to the sheet processing apparatus 100 are subjected to stapling and folding processing online in the sheet processing apparatus 100. The sheet processing apparatus 100 may be used as an option. Therefore, the copying machine main body 300 can be used alone. The sheet processing apparatus 100 and the copying machine main body 300 may be integrated.

  Next, the sheet processing apparatus 100 will be described with reference to FIG.

  FIG. 2 is a longitudinal sectional view showing a detailed structure of the sheet processing apparatus 100 of FIG.

  The sheet discharged from the copying machine main body 300 is transferred to the inlet roller pair 102 in the sheet processing apparatus 100. At this time, the sheet delivery timing is detected by the entrance sensor 101.

  The sheet conveyed by the pair of entrance rollers 102 is detected by the lateral deviation detection sensor unit 104 while passing through the conveyance path 103 and the edge (side edge) of the sheet. As a result, it is detected how much lateral deviation has occurred with respect to the center (center) position of the sheet processing apparatus 100.

  After the lateral shift is detected, the sheet is conveyed by the shift roller pair 105, 106 (conveying means), and the shift unit 108 is moved by the amount of lateral deviation from the front to the back in FIG. A shift operation is performed. Thereafter, the sheet is conveyed to the buffer rollers 2 to 115 by the conveying roller 110 and the separation roller 111. When the paper is discharged to the upper tray 136, the upper path switching flapper 118 is switched to a broken line state in the drawing by a driving means (not shown) such as a solenoid. Then, after being guided to the upper path conveyance path 117 by the two pairs of buffer rollers 115, it is discharged to the upper tray 136 by the upper discharge roller 120.

  On the other hand, when the sheet is not discharged to the upper tray 136, the sheet conveyed by the buffer rollers 2 to 115 is guided to the bundle conveyance path 121 by the upper path switching flapper 118. Thereafter, the sheet sequentially passes through the conveyance path by the buffer roller 3 pair 122 and the bundle conveyance roller pair 124.

  When saddle (saddle stitching) processing is performed on a sheet, the saddle path switching flapper 125 is switched to a broken line state in the drawing by a driving means (not shown) such as a solenoid, whereby the sheet is conveyed to the saddle path 133. Then, the saddle entrance roller pair 134 guides the saddle unit 135 to perform saddle processing (saddle stitching). The saddle process is a general process and will not be described in detail.

  When the sheet is discharged to the lower tray 137, the sheet conveyed to the bundle conveying roller pair 124 is conveyed to the lower path 126 by the saddle switching flapper 125. Thereafter, the sheet is discharged to the intermediate processing tray 138 by the lower discharge roller pair 128, and a predetermined number of sheets are aligned on the intermediate processing tray 138 by return means such as a paddle 131 or a knurled belt (not shown). Then, after a binding process is performed by the stapler 132 as necessary, the sheet is discharged onto the lower tray 137 by the bundle discharge roller pair 130.

  FIG. 3 is an external perspective view of the shift unit 108 in FIG. 4 is a view of the shift unit 108 shown in FIG. 3 and 4, the upper end side of the drawing is the back side of the sheet processing apparatus 100, and the lower end side is the front side.

  The frame 108A is supported by slide bushes 205a, 205b, 205c, and 205d that are movable on slide rails 246 and 247 fixed to the sheet processing apparatus 100. Therefore, the frame 108A can reciprocate in the direction of arrow J in the drawing along the slide rails 246 and 247. The arrow J direction is a direction orthogonal to the sheet conveying direction, that is, the sheet width direction.

  The frame 108A is provided with a shift conveyance motor 208 and shift roller pairs 105 and 106. The shift conveyance motor 208 rotates the shift roller pair 105 via the drive belt 209 (FIG. 4). Further, the shift roller pair 105 rotates the shift roller pair 106 via the drive belt 213.

  On the sheet processing apparatus 100 side, a lateral deviation detection sensor unit 104 (FIG. 4) and a shift motor 210 are provided. When the shift motor 210 receives a signal for moving the frame 108 </ b> A from a sheet processing apparatus control unit 501 described later, the shift motor 210 drives the drive belt 211. The drive belt 211 is connected to the frame 108A by a connecting member 212. For this reason, the frame 108 </ b> A is moved in the direction of arrow J by the circulating drive belt 211. The movement of the frame 108A in the direction of arrow J is performed when the shift roller pair 106, 107 holds the sheet S. The lateral deviation detection sensor unit 104 detects the side edge of the sheet S and moves in the arrow E direction by a pulse motor 104M (moving means).

  FIG. 5 is a block diagram showing the configuration of the control unit 950 in the copying machine main body 300 and the control unit in the sheet processing apparatus 100 of FIG.

  The control device 950 in the copying machine main body 300 includes a CPU circuit unit 305 connected to the sheet processing device control unit 501 in the sheet processing device 100. The CPU circuit unit 305 includes a CPU (not shown), a ROM 306 and a RAM 307 as storage means. In the CPU circuit unit 305, the CPU reads and executes the control program stored in the ROM 306. As a result, the document feeder control unit 301, the image reader control unit 302, the image signal control unit 303, the printer control unit 304, the operation unit 308, and the sheet processing device control unit 501 connected to the CPU circuit unit 305 are integrated. Controlled. The RAM 307 temporarily stores control data and holds data as a work area for arithmetic processing associated with control.

  The document feeder control unit 301 is a control unit for driving and controlling the automatic document feeder 500 based on an instruction from the CPU circuit unit 305. The image reader control unit 302 performs drive control on a light source, a lens system, and the like of an image reading unit (not shown), and transfers RGB analog image signals output from the lens system to the image signal control unit 303. The image signal control unit 303 converts each RGB analog image signal from the lens system into a digital signal, performs each process, converts the digital signal into a video signal, and outputs the video signal to the printer control unit 304. The processing operation by the image signal control unit 303 is controlled by the CPU circuit unit 305. The printer control unit 304 is the above-described image forming unit based on the received video signal.

  The operation unit 308 includes a plurality of keys for performing various settings relating to image formation, a display unit for displaying information indicating the setting state, and the like. The key signal corresponding to the key operation on the operation unit 308 is supplied to the CPU circuit unit 305 that functions as a calculation unit and an input unit. In the operation unit 308, information based on a signal from the CPU circuit unit 305 is displayed on the display unit.

  The sheet processing apparatus control unit 501 is mounted on the sheet processing apparatus 100 and performs drive control of the entire sheet processing apparatus 100 by communicating information data with the CPU circuit unit 305 via a communication IC (IPC) (not shown). It is configured to be possible.

  The sheet processing apparatus control unit 501 includes a CPU 401, a ROM 402, and a RAM 403. The sheet processing apparatus control unit 501 controls various actuators and various sensors based on a control program stored in the ROM 402. For example, the sheet processing apparatus control unit 501 controls the inlet sensor 101, the lateral deviation detection sensor unit 104, the shift motor 210, the shift conveyance motor 208, the pulse motor 104M for moving the lateral deviation detection sensor unit 104, and the like. The RAM 403 temporarily stores control data and is used as a work area for arithmetic processing associated with control.

  The lateral deviation detection sensor unit 104 includes a plurality of sensors 104A, 104B, and 104C that detect side edge portions of the sheet S in order to detect the lateral deviation amount in the width direction of the sheet S being conveyed. Further, the lateral deviation detection sensor unit 104 is disposed upstream of the shift unit 108 in order to detect the lateral deviation amount.

  FIG. 6 is a diagram illustrating a schematic configuration of the sensors 104A, 104B, and 104C.

  Each of the sensors 104A, 104B, and 104C includes an LED (Light Emitting Diode) 161, a phototransistor 162, and a prism 163 disposed at a position facing the LED 161 and the phototransistor 162. The sensors 104A, 104B, and 104C are configured such that light emitted from the LED 161 is reflected by the prism 163 disposed at the opposing position and enters the phototransistor 162.

  When the sheet exists between the prism 163 and the LED 161 and the phototransistor 162, the light emitted from the LED 161 is blocked and the light does not enter the phototransistor 162. On the other hand, when the sheet does not exist between the prism 163 and the LED 161 and the phototransistor 162, the light emitted from the LED 161 is reflected by the prism 163 and enters the phototransistor 162. As described above, the sensors 104A, 104B, and 104C detect the presence / absence of the conveyed sheet based on the presence / absence of light entering each phototransistor 162.

  FIG. 7 is a diagram illustrating a lateral shift that occurs in the sheet S being conveyed in the shift unit 108.

  As shown in FIG. 7, the sheet S may be conveyed through the sheet processing apparatus in a state where the sheet S is shifted in the width direction by a distance X from the reference position of the sheet when there is no lateral shift. This distance X is the lateral displacement amount X. In the present embodiment, the lateral deviation amount X is detected by moving the lateral deviation detection sensor unit 104 in the sheet width direction and detecting the side edge of the sheet S.

  FIG. 8 is a diagram showing the arrangement of the sensors 104A, 104B, and 104C in the lateral deviation detection sensor unit 104. As shown in FIG.

  In the lateral deviation detection sensor unit 104, sensors 104A, 104B, and 104C are arranged at equal intervals (L / 2) as shown in the figure. The lateral deviation detection sensor unit 104 can be moved in the width direction of the sheet S by a pulse motor 104M. The lateral deviation detection sensor unit 104 moves in the illustrated sensor unit moving direction, and detects the edge (side edge) of the sheet S on which the sensors 104A, 104B, 104B have been conveyed.

  Each of the sensors 104A, 104B, and 104C is ON when a sheet is detected, and is OFF when no sheet is detected. The sheet processing apparatus control unit 501 is configured to be able to turn on / off the power supply to each sensor 104A, 104B, 104C.

  FIG. 9 is a diagram illustrating the positions of the reference position P and HP of the lateral deviation detection sensor unit 104.

  The lateral deviation detection sensor unit 104 stands by at the home position (HP) when the sheet is not being conveyed. HP is located on the most front side, and is managed as a reference for the position in the width direction of the lateral deviation detection sensor unit 104 (for example, the reference positions Pa, Pb, Pc of the lateral deviation detection sensor unit 104). Therefore, HP is always detected by an HP detection sensor (not shown). Note that the front side and the back side refer to the state viewed from the paper surface side (front side of the image forming apparatus) in FIG.

  When sheet conveyance is started, the lateral deviation detection sensor unit 104 moves to the reference position P by the pulse motor 104M and waits until the sheet S is conveyed. In the drawing, the reference positions P of the lateral deviation detection sensor unit 104 when sheets Sa, Sb, and Sc having different sheet sizes are conveyed are Pa, Pb, and Pc. The reference positions Pa, Pb, and Pc are determined according to the sheet size and the conveying direction of the sheet S, and are determined based on the sheet information sent from the copying machine main body 300 (image forming apparatus) before starting the sheet conveyance.

  As shown in FIG. 9, the reference position P approaches the HP side from the center position as the sheet width in the direction (width direction) orthogonal to the sheet conveyance direction increases. For the movement of the lateral deviation detection sensor unit 104 from the HP to the reference position P, the CPU 401 in the sheet processing apparatus control unit 501 calculates the distance from the HP to the reference position P, and drives the pulse motor 104M based on the calculated distance. Is done.

  Next, a method for detecting a lateral deviation amount using three sensors will be described.

  When the user presses the start button on the operation unit 308 and the job is started, the lateral deviation detection sensor unit 104 is moved to the reference position P by the pulse motor 104M before the detection is started. As described above, the reference position P is determined by the sheet size and the direction in which the sheet is conveyed. In the present embodiment, the reference position P is any one of Pa to Pc.

  FIG. 10 is a diagram illustrating the relationship between the lateral shift detection sensor unit 104 and the reference positions Pa to Pc.

  The lateral deviation detection sensor unit 104 moves so that the sensor 104B arranged at the center of the three sensors 104A, 104B, and 104C is positioned at the reference position Pa. For example, when the reference position P is Pa, the lateral deviation detection sensor unit 104 is moved so that the sensor 104B is positioned at the reference position Pa, and waits until the sheet S is conveyed. Similarly, when the reference position P is Pb or Pc, the lateral deviation detection sensor unit 104 is moved so that the sensor 104B is positioned at the reference position Pb or Pc.

  In the present embodiment, L is the maximum (allowable value) of the lateral shift amount of the sheet S in the width direction. Therefore, by aligning the sensor 104B with the reference position P, the sheet edge can be detected by moving the lateral deviation detection sensor unit 104 by L / 2 even when the lateral deviation amount is L. By arranging three sensors in parallel in this way, the movement distance to the sheet edge detection can be halved and the detection time of the lateral deviation amount can be shortened as compared with the case of one sensor.

  Next, when the conveyed sheet S reaches the lateral deviation detection sensor unit 104, the lateral deviation detection sensor unit 104 is moved in the width direction by the pulse motor 104M so that the lateral deviation detection sensor unit 104 detects the sheet edge. When the lateral edge detection sensor unit 104 detects the sheet edge, the lateral displacement amount X of the sheet S is calculated from the movement distance from the reference position P.

  The lateral deviation amount X of the sheet S can be obtained from the following equation based on the advance amount Β of the lateral deviation detection sensor unit 104 per pulse of the pulse motor 104M and the number of pulses p from the reference position P until the sheet edge is detected. it can.

Side shift amount X = advance amount B per pulse × number of pulses p (Expression 1)
Then, the sheet position is corrected by the shift unit 108 based on the lateral deviation amount calculated by the above equation. The lateral deviation detection sensor unit 104 moves to the reference position P again after the detection of the sheet edge and waits until the next sheet arrives.

  Next, a sheet edge detection method by the lateral deviation detection sensor unit 104 will be described with reference to FIG.

  FIG. 11 is a diagram illustrating a lateral shift pattern of the sheet S that is assumed.

  First, when it is determined that the leading edge (upper end) of the sheet S has reached the lateral deviation detection sensor unit 104, detection of the sheet edge is started. At this time, it is assumed that power (electric power) is supplied to the sensors 104A, 104B, and 104C so that the sheet edge can be detected.

  If none of the sensors 104A, 104B, and 104C detect the sheet S as shown in the pattern 1 in the figure, the power supply to the sensors 104A and 104B is cut off (not energized), and the power is supplied only to the sensor 104C. Supply (energize). Then, the lateral deviation detection sensor unit 104 is moved to the back side in the figure so that the sensor 104C is turned on.

  On the other hand, as in pattern 2, when the sensors 104A and 104C do not detect the sheet S and the sensor 104C detects the sheet S, the power supply to the sensors 104A and 104C is cut off and the power is supplied only to the sensor 104B. To do. Then, the lateral deviation detection sensor unit 104 is moved to the illustrated back side so that the sensor 104B is turned on. Note that power may be supplied only to the sensor 104C, and the lateral deviation detection sensor unit 104 may be moved to the front side in the drawing so that the sensor 104C is turned off.

  If the sensor 104A does not detect the sheet S and the sensors 104B and 104C detect the sheet S as in the pattern 3, the power supply to the sensors 104A and 104C is cut off and the power is supplied to the sensor 104B. . Then, the lateral deviation detection sensor unit 104 is moved to the front side in the figure so that the sensor 104B is turned off. Note that power may be supplied only to the sensor 104A, and the lateral deviation detection sensor unit 104 may be moved to the back side in the drawing so that the sensor 104A is turned on.

  When all of the sensors 104A, 104B, and 104C detect the sheet S as in the pattern 4, the power supply to the sensors 104B and 104C is cut off, and the power is supplied to the sensor 104A. Then, the lateral deviation detection sensor unit 104 is moved to the back side so that the sensor 104A is turned off.

  In the patterns 1 to 4 described above, the power supply to the sensor is stopped when the end of the sheet S is detected, and the power supply is stopped until the next sheet lateral shift detection is started.

  As described above, according to the detection status of each sensor, the power supply to the sensor and the moving direction of the lateral deviation detection sensor unit are changed to detect the sheet edge. Thus, power can be reduced by supplying power only to the sensor used for detecting the sheet edge. Moreover, the lifetime of the light emitting element (LED) which comprises a sensor can be made long.

  As described above, the lateral deviation amount of the sheet S is calculated by the movement amount of the lateral deviation detection sensor unit 104 from the reference position P until the sheet edge is detected. When the lateral deviation detection sensor unit 104 detects the lateral deviation amount of the sheet S, the lateral deviation detection sensor unit 104 moves from the reference position P by an inter-sensor distance L / 2 that is the maximum movement distance. Since the maximum lateral deviation amount of the sheet S is the distance L from the sensor 104B, the sheet edge is detected during that time. Therefore, the movement amount of the lateral deviation detection sensor unit 104 is always constant at the inter-sensor distance L / 2.

  The lateral deviation detection sensor unit 104 moves by an inter-sensor distance L / 2, stops, returns to the reference position P, and waits until the next sheet is conveyed. Thereafter, when the job is finished, the lateral deviation detection sensor unit 104 returns to the home position HP and waits until the next job is started. Note that the movement of the lateral deviation detection sensor unit 104 may be stopped and returned to the reference position P when the sensor supplied with the power changes from ON to OFF or from OFF to ON.

  Next, the lateral deviation amount detection process will be described with reference to the flowchart of FIG.

  FIG. 12 is a flowchart of the lateral shift amount detection process. The processing in this flowchart is executed by the CPU 401 based on a control program stored in the ROM 402 of the sheet processing apparatus control unit 501. The lateral deviation amount detection processing is executed by the CPU 401 (lateral deviation amount detection means) of the sheet processing apparatus control unit 501 when a start button (not shown) of the operation unit 308 is pressed and a job is started.

  First, the CPU 401 determines whether or not the image forming system is in the long life mode (step S10). The long life mode is a mode in which the life of the apparatus is given priority over productivity. When the long life mode is selected, the sheet conveyance speed in the image forming system is set slower than in the case other than the long life mode. The long life mode can be set on the operation unit 308. The long life mode setting information is sent from the CPU circuit unit 305 to the sheet processing apparatus control unit 501 through a communication line (not shown).

  If the CPU 401 determines in step S10 that the mode is not the long life mode, the lateral deviation detection sensor unit 104 is moved by the pulse motor 104M so that the sensor 104B matches the reference position P (step S11). The reference position P is determined by the size information of the sheet S sent from the CPU circuit unit 305 when the job starts. In the present embodiment, it is assumed that one of the reference positions Pa to Pc shown in FIG.

  Next, the CPU 401 supplies power to all the sensors of the lateral deviation detection sensor unit 104 (step S12). Subsequently, in step S <b> 13, the CPU 401 waits for the leading edge of the sheet to reach the lateral deviation detection sensor unit 104. The CPU 401 determines that the leading edge of the sheet has reached the lateral deviation detection sensor unit 104 when the sheet conveyance distance after the entrance sensor 101 is turned on matches the distance from the entrance sensor 101 to the sensor. If the CPU 401 determines in step S13 that the sheet leading edge has reached the lateral deviation detection sensor unit 104, the CPU 401 executes a first sheet edge detection process (step S14). Details of the first sheet edge detection process will be described later.

  After the first sheet edge detection process is executed, the CPU 401 determines whether or not the job is finished (step S15). If it is determined that the job has not ended, the process returns to step S11, and the CPU 401 moves the lateral deviation detection sensor unit 104 by the pulse motor 104M so that the sensor 104B is positioned at the reference position P. On the other hand, when determining that the job is completed, the CPU 401 moves the lateral deviation detection sensor unit 104 to the home position HP by the pulse motor 104M in step S16, and ends the lateral deviation detection process.

  In step S <b> 10, when the CPU 401 determines that the long life mode is in effect, the second sheet edge detection process is executed. The second sheet edge detection process is as follows.

  First, among the sensors 104A, 104B, and 104C, the power source of the sensor with the smallest number of uses (the number of energizations) is turned on (step S41) (third control step). The number of use times of each sensor is determined from a use number counter (energization number counting means) for each sensor provided on the RAM 403 in the sheet processing apparatus control unit 501. This use number counter is incremented by one each time each sensor is energized or each sensor is kept in an energized state in step S41 and steps S22, S27, S31, and S34 in the sheet edge detection process described later. Note that since the power to the RAM 403 is supplied from a battery (not shown), the information in the RAM 403 is retained even when the apparatus is turned off.

  Next, in step S41, the CPU 401 moves the lateral deviation detection sensor unit by the pulse motor 104M so that the sensor supplied with power is positioned at the reference position P (step S42). Next, in step S43, the CPU 401 waits for the leading edge of the sheet to reach the lateral deviation detection sensor unit 104.

  In step S43, when the CPU 401 determines that the leading edge of the sheet has reached the lateral deviation detection sensor unit 104, the CPU 401 determines whether or not the sensor supplied with power in step S41 is turned on (step S44). As a result, when it is determined that the sensor is turned on, the CPU 401 moves the lateral deviation detection sensor unit 104 to the near side (see FIG. 11) by one pulse by the pulse motor 104M (step S45).

  Next, the CPU 401 determines whether or not the sensor is turned off (step S46). As a result, when it is determined in step S46 that the sensor is not OFF, the process returns to step S45. On the other hand, if it is determined in step S46 that the sensor is ON, the CPU 401 calculates the lateral deviation amount using the above-described equation 1 from the movement amount (movement distance) of the lateral deviation detection sensor unit 104 until the sheet edge detection. (Step S47). The amount of movement of the lateral deviation detection sensor unit 104 until sheet edge detection is obtained from a movement amount counter provided on the RAM 403 in the sheet processing apparatus control unit 501. This movement amount counter is incremented by 1 every time the pulse motor 104M for moving the lateral deviation detection sensor unit 104 moves by one pulse in step S45 or step S49, and is cleared when the calculation of the lateral deviation amount is completed in step S47. .

  On the other hand, if it is determined in step S44 that the sensor is not ON, the CPU 401 moves the lateral deviation detection sensor unit 104 to the far side (see FIG. 11) by one pulse by the pulse motor 104M (step S49). Next, the CPU 401 determines whether or not the sensor is ON (step S50). As a result, when it is determined in step S50 that the sensor is not ON, the process returns to step S49. On the other hand, if it is determined in step S50 that the sensor is ON, the CPU 401 uses the above-described equation 1 to calculate the lateral deviation amount from the movement amount (movement distance) of the lateral deviation detection sensor unit 104 until the sheet edge is detected. Calculate (step S47). The above is the details of the second sheet edge detection process.

  When step S47 ends, the CPU 401 determines whether or not the job has ended (step S48). If the job has not ended, the process returns to step S41. On the other hand, when the job is finished, the above-described step S16 is executed, and the lateral deviation amount detection process is finished.

  Next, details of the first sheet edge detection processing in step S14 of FIG. 12 will be described with reference to FIG.

  FIG. 13 is a flowchart showing details of the first sheet edge detection process in step S14 of FIG.

  First, the CPU 401 determines whether or not the sensor 104C is OFF (step S21). When determining that the sensor 104C is OFF, the CPU 401 turns off the power of the sensors 104A and 104B in step S22 (power OFF). Next, the CPU 401 uses the pulse motor 104M to move the lateral deviation detection sensor unit 104 to the far side by one pulse (step S23).

  Next, the CPU 401 determines whether or not the sensor 104C is ON (step S24). If it is determined in step S24 that the sensor 104C is not ON, the process returns to step S23. On the other hand, if the sensor 104C is determined to be ON, the CPU 401 calculates the lateral deviation amount using the above-described equation 1 from the movement amount (movement distance) of the lateral deviation detection sensor unit 104 until the sheet edge detection (step S25). Return. As described above, the movement amount of the lateral deviation detection sensor unit 104 until the sheet edge detection is obtained from a movement amount counter provided on the RAM 403 in the sheet processing apparatus control unit 501. This movement amount counter is incremented by 1 every time the pulse motor 104M for moving the lateral deviation detection sensor unit 104 moves by one pulse, and is cleared when the lateral deviation amount calculation is completed.

  The processing in steps S21 to S24 corresponds to the pattern 1 in FIG. As described above, when all of the plurality of sensors 104 </ b> A to 104 </ b> C do not detect the sheet S, the sensor 104 </ b> C closest to the end portion of the sheet S is selected as a sensor for detecting the amount of lateral deviation. Then, the CPU 401 performs control to energize the selected sensor 104C and not energize the unselected sensors 104A and 104B (first control step).

  When determining in step S21 that the sensor 104C is not OFF, the CPU 401 determines whether or not the sensor 104B is OFF (step S26). When it is determined in step S26 that the sensor 104B is OFF, the CPU 401 turns off the power of the sensors 104A and 104C in step S27 (power OFF). Next, the CPU 401 uses the pulse motor 104M to move the lateral deviation detection sensor unit 104 to the far side by one pulse (step S28).

  Next, the CPU 401 determines whether or not the sensor 104B is ON (step S29). If it is determined in step S29 that the sensor 104B is not ON, the process returns to step S28. On the other hand, if the sensor 104B is determined to be ON, the CPU 401 calculates the lateral deviation amount using the above-described equation 1 from the movement amount (movement distance) of the lateral deviation detection sensor unit 104 until the sheet edge detection (step S25). Return.

  The processing in steps S26 to S29 corresponds to the above-described pattern 2 in FIG. Thus, it is assumed that the sensor 104C among the sensors 104A to 104C detects the sheet S. At that time, the sensor 104B, which is one of the closest sensors between the sensor 104C that detects the sheet S and the sensor 104B that does not detect the sheet S, is selected as a sensor that detects the amount of lateral deviation. Then, the CPU 401 performs control to energize the selected sensor 104B and not energize the unselected sensors 104A and 104C (second control step).

  The sensor 104C may be selected as the closest sensor between the sensor 104C that detects the sheet S and the sensor 104B that does not detect the sheet S. In this case, control is performed so that the unselected sensors 104A and 104B are not energized, and the movement direction of the lateral deviation detection sensor unit 104 is the front side shown in FIG.

  When determining in step S26 that the sensor 104B is not OFF, the CPU 401 determines whether or not the sensor 104A is OFF (step S30). When determining that the sensor 104A is OFF in step S30, the CPU 401 turns off the power of the sensors 104A and 104C in step S31 (power OFF). Next, the CPU 401 moves the lateral deviation detection sensor unit 104 forward by one pulse by the pulse motor 104M (step S32).

  Next, the CPU 401 determines whether or not the sensor 104B is OFF (step S33). If it is determined in step S33 that the sensor 104B is not OFF, the process returns to step S32. On the other hand, when determining that the sensor 104B is OFF, the CPU 401 calculates the lateral deviation amount using the above-described equation 1 from the movement amount (movement distance) of the lateral deviation detection sensor unit 104 until the sheet edge detection (step S25). Return.

  The processing in steps S30 to S33 corresponds to the above-described pattern 3 in FIG. Thus, it is assumed that the sensors 104B and 104C among the sensors 104A to 104C detect the sheet S. At that time, the sensor 104B, which is one of the closest sensors between the sensors 104B and 104C that detect the sheet S and the sensor 104A that does not detect the sheet S, is selected as a sensor that detects the lateral deviation amount. Then, the CPU 401 performs control to energize the selected sensor 104B and not energize the unselected sensors 104A and 104C (second control step).

  Note that the sensor 104A may be selected as the closest sensor between the sensors 104B and 104C that detect the sheet S and the sensor 104A that does not detect the sheet S. In this case, control is performed so that the unselected sensors 104B and 104C are not energized, and the movement direction of the lateral deviation detection sensor unit 104 is the back side shown in FIG.

  When determining in step S30 that the sensor 104A is not OFF, the CPU 401 turns off the power of the sensors 104B and 104C in step S34 (power OFF). Next, the CPU 401 moves the lateral deviation detection sensor unit 104 forward by one pulse by the pulse motor 104M (step S35).

  Next, the CPU 401 determines whether or not the sensor 104A is OFF (step S36). If it is determined in step S36 that the sensor 104A is not OFF, the process returns to step S35. On the other hand, if it is determined that the sensor 104A is OFF, the CPU 401 calculates the amount of lateral deviation using the above-described equation 1 from the amount of movement (movement distance) of the lateral deviation detection sensor unit 104 until sheet edge detection (step S25). Return.

  The processing in steps S34 to S36 corresponds to the pattern 4 in FIG. As described above, when all of the plurality of sensors 104A to 104C detect the sheet S, the sensor 104A closest to the end portion of the sheet S is selected as a sensor for detecting the lateral deviation amount. Then, the CPU 401 performs control to energize the selected sensor 104A and not energize the unselected sensors 104B and 104C (first control step).

  According to the above embodiment, when all of the sensors 104A to 104C when the sheet S reaches the lateral deviation detection sensor unit 104 detects or does not detect the sheet S, the sensor closest to the side edge of the sheet S. Is selected. On the other hand, when at least one of the sensors 104A to 104C detects the sheet S, the sensor that detects the sheet S closest to the side edge of the sheet S and the sheet S that is not closest to the side edge of the sheet S are detected. One of the sensors is selected. Then, the CPU 401 performs control to energize only selected sensors and not energize unselected sensors. That is, the CPU 401 functions as a selection unit that selects a sensor to be used for detecting the side edge of the sheet from the sensors 104a, 104b, and 104c, and a function as a control unit that controls energization of the selected sensor. Have.

  Thereby, when detecting the amount of lateral deviation of the sheet with a plurality of sensors, the power required for the plurality of sensors can be reduced by turning off the power to the sensors that are not used. Moreover, the lighting time of LED used for a sensor can also be reduced and the lifetime of a sensor can also be extended. As a result, it is excellent in energy saving and durability, and the lateral displacement amount of the sheet can be detected at high speed.

  In the above embodiment, the number of sensors of the lateral deviation detection sensor unit 104 is three. However, the number of sensors is not limited to three, and two or four or more sensors can be arranged. The more sensors are arranged, the smaller the amount of movement until the sheet edge is detected, so the sheet edge detection time can be shortened.

  The sensor used for the lateral deviation detection sensor unit 104 may be any sensor that can detect the sheet edge. For example, a configuration may be adopted in which a plurality of transmissive or reflective sensors that do not use a prism are arranged and the sheet edge is detected based on the transmissive / reflective state. Moreover, it is not limited to an optical sensor, The mechanical sensor which mechanically detects the side edge part of a sheet | seat may be sufficient.

  In the above-described embodiment, the embodiment when applied to the sheet processing apparatus has been described, but it goes without saying that the embodiment may be applied to the image forming apparatus alone.

  The object of the present invention is achieved by executing the following processing. That is, a storage medium that records a program code of software that realizes the functions of the above-described embodiments is supplied to a system or apparatus, and a computer (or CPU, MPU, etc.) of the system or apparatus is stored in the storage medium. This is the process of reading the code. In this case, the program code itself read from the storage medium realizes the functions of the above-described embodiments, and the program code and the storage medium storing the program code constitute the present invention.

  Moreover, the following can be used as a storage medium for supplying the program code. For example, floppy (registered trademark) disk, hard disk, magneto-optical disk, CD-ROM, CD-R, CD-RW, DVD-ROM, DVD-RAM, DVD-RW, DVD + RW, magnetic tape, nonvolatile memory card, ROM or the like. Alternatively, the program code may be downloaded via a network.

  Further, the present invention includes a case where the function of the above-described embodiment is realized by executing the program code read by the computer. In addition, an OS (operating system) running on the computer performs part or all of the actual processing based on an instruction of the program code, and the functions of the above-described embodiments are realized by the processing. Is also included.

  Furthermore, a case where the functions of the above-described embodiment are realized by the following processing is also included in the present invention. That is, the program code read from the storage medium is written in a memory provided in a function expansion board inserted into the computer or a function expansion unit connected to the computer. Thereafter, based on the instruction of the program code, the CPU or the like provided in the function expansion board or function expansion unit performs part or all of the actual processing.

1 is a longitudinal sectional view illustrating a schematic structure of an image forming system including a sheet processing apparatus including a sheet conveying apparatus according to an embodiment of the present invention and an image forming apparatus. FIG. 2 is a longitudinal sectional view showing a detailed structure of the sheet processing apparatus 100 in FIG. 1. It is an external appearance perspective view of the shift unit 108 in FIG. FIG. 4 is a view of the shift unit shown in FIG. FIG. 2 is a block diagram illustrating configurations of a control device 950 in the copying machine main body 300 and a control unit in the sheet processing apparatus 100 in FIG. 1. It is a figure which shows schematic structure of sensor 104A, 104B, 104C. FIG. 10 is a diagram illustrating a lateral shift that occurs in a sheet S being conveyed in the shift unit. It is a figure which shows arrangement | positioning of sensor 104A, 104B, 104C in the lateral deviation detection sensor unit 104. FIG. It is a figure which shows the reference position of HP and the position of HP of a lateral shift detection sensor unit. It is a figure which shows the relationship between the lateral deviation detection sensor unit 104 and each reference position Pa-Pc. FIG. 6 is a diagram illustrating a pattern of a lateral shift of a sheet S that is assumed. It is a flowchart of a lateral deviation amount detection process. 13 is a flowchart showing details of sheet edge detection processing in step S14 of FIG.

Explanation of symbols

100 sheet processing apparatus 104 lateral deviation detection sensor unit 104A, 104B, 104C sensor 104M pulse motor 105, 106 shift roller pair 108 shift unit 161 LED
162 Phototransistor 163 Prism 300 Copier body 305 CPU circuit unit 401 CPU
501 Sheet processing apparatus control unit 950 control apparatus

Claims (9)

A sheet detecting unit having a plurality of sensors arranged along a width direction orthogonal to a sheet conveying direction in order to detect a sheet conveyed by the conveying unit; A sheet conveying apparatus comprising a moving means for moving the sheet in the width direction,
When all of the plurality of sensors when the sheet arrives at the sheet detection means detects or does not detect the sheet, the sensor closest to the side edge of the sheet is selected, while the plurality of sensors If at least one sheet is detected, select one of the sensor that detects the sheet closest to the side edge of the sheet and the other sensor that does not detect the sheet closest to the side edge of the sheet Selection means to
Control means for controlling to energize the sensor selected by the selection means and not to energize the unselected sensor when detecting the side edge of the sheet while moving the sheet detection means by the movement means. A sheet conveying apparatus comprising: A sheet detecting unit having a plurality of sensors arranged along a width direction orthogonal to a sheet conveying direction in order to detect a sheet conveyed by the conveying unit; A sheet conveying apparatus comprising a moving means for moving the sheet in the width direction,
Energization frequency counting means for counting the energization frequency of each of the plurality of sensors;
Selecting means for selecting a sensor having the smallest number of energizations among the plurality of sensors;
When detecting the side edge of the sheet while moving the sheet detecting unit by the moving unit, the sensor selected by the selecting unit is energized, and the sensor not selected is not energized. Sheet conveying device. The moving means moves the sheet detecting means to a reference position before the sheet reaches the sheet detecting means, and then moves the sheet when the sensor selected by the selecting means detects the sheet. While moving the sheet detection means in a direction to stop detection, if the selected sensor does not detect the sheet, move the sheet detection means in a direction to detect the sheet,
The control means includes the reference position and a distance from the start of movement of the selected sensor from the reference position to detection of a sheet, or from the start of movement from the reference position to detection of a sheet. 3. The sheet conveying apparatus according to claim 1, further comprising a deviation amount detection unit configured to detect a deviation amount of the sheet in the width direction based on the distance between the plurality of sensors and the distance between the plurality of sensors.   4. The sheet conveying apparatus according to claim 1, wherein the plurality of sensors are arranged at equal intervals in the width direction. 5. A sheet detecting unit having a plurality of sensors arranged along a width direction orthogonal to a sheet conveying direction in order to detect a sheet conveyed by the conveying unit; A sheet conveying apparatus comprising a moving means for moving the sheet in the width direction,
When all of the plurality of sensors when the sheet arrives at the sheet detecting means detects or does not detect the sheet, the sensor closest to the side edge of the sheet is energized and the other sensors are energized. A first control step that does not,
When at least one of the plurality of sensors when the sheet reaches the sheet detecting unit detects the sheet, the sensor that detects the sheet closest to the side edge of the sheet and the side edge of the sheet are closest. A control method for a sheet conveying apparatus, comprising: a second control step of energizing any one of the other sensors not detecting the side edge of the sheet and not energizing the other sensors. The sheet conveying device further includes energization frequency counting means for counting the energization frequency of the plurality of sensors,
When detecting the side edge of the sheet while moving the sheet detecting means by the moving means, the sensor having the smallest energization frequency among the plurality of sensors is energized, and the unselected sensor is not energized. 6. The control method for a sheet conveying apparatus according to claim 5, further comprising a control step (3).   An image forming apparatus comprising the sheet conveying device according to claim 1.   A sheet processing apparatus comprising the sheet conveying apparatus according to claim 1 and connected to an image forming apparatus.   A computer-readable program for causing a computer to execute the control method according to claim 5 or 6.

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