JP6287028B2 - Paper transport device, double feed detection method, and image forming system - Google Patents

Description

The present invention relates to a paper transport device that detects double feed of paper in a paper transport unit, a multi-feed detection method, and an image forming system .

In an image forming system that forms an image on a sheet while conveying the sheet, the sheet may be overlapped on the conveyance path without being smoothly conveyed in the middle of conveyance (hereinafter referred to as multi-feed). When double feed occurs, an overload is generated in the motor that drives the transport rollers provided in the paper transport unit, and the SC (serviceman call) stops or transports unnecessarily until a jam is detected and transport stops. The problem of continuing will occur.
For this reason, conventionally, a method has been adopted in which a double feed detection unit is provided at an appropriate position in the middle of the transport path, and the transport state is well controlled by quickly detecting double feed.
For example, in Patent Document 1, double feeding of paper is detected by receiving ultrasonic waves that irradiate the paper side with ultrasonic waves and pass through the paper.
Further, in Patent Document 2, double feeding of paper is detected by a double feed detection unit that receives transmitted light of light emitted toward the paper.

JP 2009-292549 A JP 2003-137457 A

However, in the conventional double feed detection, one double feed detection unit performs detection in one format, and when passing an envelope or special paper, ultrasonic waves and transmitted light are reliably detected. It is not possible to detect double feeds. For this reason, it is necessary to turn off the double feed detection in the conveyance of envelopes or special paper, and double feed cannot be detected. For this reason, it is impossible to carry out conveyance control while detecting double feed for a part of paper, and the above-described problems occur when double feed actually occurs.
Although it is possible to provide another double feed detection means for an envelope or special paper to perform double feed detection, there is a problem that the apparatus cost increases.

The present invention has been made against the background of the above circumstances, and provides a paper transport device, a multi-feed detection method, and an image forming system that can accurately detect multi-feed regardless of the type of paper. Objective.

That is, among the sheet conveying apparatuses of the present invention, the first aspect of the present invention is a sheet conveying apparatus provided with a detection system for detecting double feeding of sheets fed and conveyed from a sheet feeding unit,
A paper detection sensor for detecting paper,
First detection means for detecting whether or not double feeding based on information on the thickness direction of the paper obtained by the paper detection sensor;
Second detection means for detecting whether or not double feeding based on information on the length of the paper in the conveyance direction obtained by the paper detection sensor;
It is characterized by comprising switching means for switching between the first detection means and the second detection means based on the information on the paper to be fed and conveyed .

The second sheet conveying apparatus of the present invention, in the first invention, the information of the paper, the paper type of the paper, wherein the paper size is at least one of the basis weight.

The third sheet conveying apparatus of the present invention, in the first or second invention, the information of the sheet is characterized in that it is one that is set to the tray the paper is fed.

According to a fourth aspect of the present invention, there is provided the sheet conveying apparatus according to any one of the first to third aspects of the present invention, wherein the sheet information is set by a user .

The sheet conveying apparatus according to a fifth aspect of the present invention is the paper conveying apparatus according to any one of the first to fourth aspects of the present invention, wherein the switching means detects the double feeding and the first detecting means and the second detecting means. And a method using only the second detection means .

According to a sixth aspect of the present invention, there is provided the sheet conveying device according to any one of the first to fifth aspects, wherein the sheet detecting sensor uses an ultrasonic wave .

A double feed detection method according to a seventh aspect of the present invention is a double feed detection method for detecting double feed of paper fed and conveyed from a paper feed unit using a paper detection sensor for detecting paper,
A first detection method for detecting whether or not double feeding is performed based on information on the thickness direction of the paper obtained by the paper detection sensor, and whether double feeding is performed based on information on the length of the paper in the conveyance direction obtained by the paper detection sensor. It is characterized in that the second detection method for detecting whether or not is switched based on the information of the paper to be fed and conveyed .

Multifeed detection method of the present eighth aspect of the present invention of the seventh, information of the paper, the paper type of the paper, wherein the paper size is at least one of the basis weight.

Multifeed detection method of the present ninth aspect of the present invention of the seventh or eighth, information of the sheet is characterized in that the paper is set to the tray to be fed.

According to a tenth aspect of the present invention , there is provided the double feed detection method according to any one of the seventh to ninth aspects, wherein the information on the sheet is set by a user .

A multifeed detection method according to an eleventh aspect of the present invention is a method of using the first detection method and the second detection method in combination when detecting multifeed in any of the seventh to tenth aspects of the present invention. And a method using only the second detection method .

In a twelfth feed detection method according to a twelfth aspect of the present invention, in any one of the seventh to eleventh aspects of the present invention, the sheet detection sensor uses an ultrasonic wave .

13th image forming system of the present invention is characterized by comprising a sheet conveying apparatus according to any one of the first to sixth invention.

  That is, according to the present invention, even for paper that cannot be detected by double feed detection in a normal double feed determination, it is possible to detect double feed and stop transport as soon as possible to prevent wasteful paper transport. It is possible to prevent SC (Service Man Call) stoppage due to overloading and recover. When the SC is stopped, the power must be turned off / on, and the production efficiency decreases.

1 is a schematic configuration diagram of an image forming system of the present invention. Similarly, it is a control block diagram. Similarly, it is a figure which shows the outline of a paper conveyance path | route. Similarly, it is a figure which shows a paper type setting screen. Similarly, it is a flowchart showing a procedure of double feed detection switching determination processing. Similarly, it is a flowchart which shows the procedure of double feed detection judgment processing.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.
The image forming system 1 of this embodiment includes a large-capacity paper feeding device 30, a color image forming device 10 connected downstream of the large-capacity paper feeding device 30 in the paper transport direction, and the paper transport direction of the image forming apparatus 10. The post-processing device 20 is connected to the downstream side.

  However, the configuration of the image forming system of the present invention is not limited to the above, and the image forming system may be configured only by the image forming device. The image forming system may be configured by a combination with a processing device or the like, or another device may be connected to the configuration of the present embodiment.

The large-capacity paper feeder 30 has PFU units in three stages and two rows, and the conveyance path connected to the PFU tray provided in each unit is connected to the conveyance path of the image forming apparatus 10. The PFU unit corresponds to the paper feed tray of the present invention. In the present invention, the number of paper feed trays in the large-capacity paper feeder 30 is not particularly limited, and as described above, it may not have a PFU tray.
The conveyance path of the large-capacity sheet feeding device 30 constitutes a part of the sheet conveyance unit of the present invention together with a conveyance roller and a drive unit.

The image forming apparatus 10 is provided with a scanner unit 13 on the upper side of the image forming apparatus main body 10A, and an image of a document can be read through a platen glass 13A and an ADF document reading slit glass 13B.
In addition, an operation unit 14 including a touch panel is provided at a position where the platen glass 13A is not located on the upper side of the image forming apparatus main body 10A, so that an operator can perform operations and display information. In this embodiment, the operation unit 14 constitutes an operation unit with a touch panel and also serves as a display unit. In the present invention, the operation unit and the display unit can be configured separately.

  The image forming unit 11 has four image forming units in a tandem configuration for each color (cyan, magenta, yellow, black, etc.). Each of the image forming units has a photoconductor prepared for each, and a charger, a writing unit including an LD, and a developing unit are arranged on a peripheral portion of each photoconductor.

  The surface of the photosensitive member charged by the charger is subjected to image exposure by the writing unit based on the image information of the document recorded in the image memory or the like, and a latent image is formed on the surface of the photosensitive member. The latent image is developed by a developing unit to become a toner image. The toner image is transferred to the intermediate transfer belt 11D, and is transferred from the intermediate transfer belt 11D to a sheet conveyed through the conveyance path 15 by the secondary transfer roller 11E. The transferred paper is heated and fixed by the fixing device 16 and discharged to the post-processing device 20.

Further, in the image forming unit 11, corresponding to each photoconductor, the residual toner is brought into contact with each photoconductor on the rotation direction side with respect to the intermediate transfer belt 11 </ b> D and on the rotation direction opposite side with respect to the charger. A cleaning unit to be removed is arranged. Further, a cleaning unit for removing residual toner on the intermediate transfer belt 11D is disposed on the rotation direction side of the intermediate transfer belt 11D with respect to the sheet transfer position and on the rotation direction opposite side of the transfer position with each photoconductor.
Each of the photosensitive members 11 is rotated by a drive motor (not shown), and the intermediate transfer belt 11D is also driven by a drive motor (not shown).

  In the image forming apparatus 10, a paper feed tray 12 that stores paper is disposed below the image forming unit 11. In the present embodiment, the image forming apparatus 10 is provided with three stages of paper feed trays. In the present invention, the number of paper feed trays is not limited.

Each paper feed tray 12 is connected to a paper feed transport path 12 A, and the paper feed transport path 12 A joins the transport path 15. The conveyance path 15 reaches the image forming unit 11, and is further connected to the conveyance path of the post-processing device 20 from the image forming unit 11.
The transport path 15 and the paper feed transport path 12A constitute a part of the sheet transport section of the present invention together with transport rollers, a drive unit, and the like.

In addition, a pair of registration rollers 15 </ b> B that abuts the sheet and corrects the inclination on the upstream side in the sheet conveyance direction of the image forming unit 11 are disposed in the conveyance path 15.
The registration roller 15B temporarily stops the paper in order to transfer the toner image formed on the intermediate transfer belt 11D to the fed paper with high positional accuracy, and transfers the toner image onto the paper at a timing with the toner image. It is what

In the transport path 15, the paper stored in the paper feed tray 12 is fed via the paper feed transport path 12 </ b> A, and is transported to the secondary transfer roller 11 </ b> E via the registration roller 15 </ b> B. The secondary transfer roller 11E transfers a color image or a monochrome image on the intermediate transfer belt 11D onto a sheet. The sheet on which the image is transferred is fixed with the toner image on the sheet by applying heat and pressure by the fixing device 16.
Further, in the transport path 15, when a sheet is introduced from the large capacity sheet feeder 30, the sheet is received from the large capacity sheet feeder 30 and used for image formation as described above.

  Further, the image forming apparatus 10 is provided with a sheet reversing conveyance path 15A. The fixed sheet is guided from the fixing device 16 to the sheet reversing conveyance path 15A, the front and back are reversed, and the sheet is discharged face-down outside the image forming apparatus main body 10A. Alternatively, it is possible to form an image on both sides of the paper in the duplex mode. The sheet reverse conveyance path 15A merges with the conveyance path 15 on the upstream side of the registration roller 15B. In the double-side mode, the sheet can be circulated to form an image on the back side of the sheet.

FIG. 2 shows a circuit block of the image forming system 1, and is an overall block diagram of the image forming system. The contents will be described in detail below.
The image forming system is mainly composed of an operation panel control unit 140, a system control unit 100, an engine control unit 110, and a post-processing control unit 160. The system control unit 100 manages the system and controls the entire system, and the engine control unit 110 is responsible for actual operation such as sheet conveyance control and toner image formation control.

The system control unit 100 is provided in the image forming apparatus main body 10A, and includes a CPU, a program for operating the CPU, a RAM serving as a work area, a ROM storing a program, a flash memory storing operation parameters, and the like. The The system control unit 100 performs control according to operation parameters stored in the flash memory and setting contents through the operation panel control unit 140. The system control unit 100 functions as a control unit of the present invention.
An operation panel control unit 140 is connected to the system control unit 100. The operation panel control unit 140 is provided in the image forming apparatus main body 10 </ b> A and controls the operation panel 14 according to a command from the system control unit 100.

  The operation panel control unit 140 includes a tray selection / setting unit 141 and a paper setting unit 142. The tray selection / setting unit 141 and the paper setting unit 142 can be operated and input with tray selection / setting and paper setting on the operation unit 14 by the operation panel control unit 140 controlling the operation unit 14 according to a command from the system control unit 100. To. The tray selection / setting unit 141 can perform settings such as selection of a paper feed tray and selection of paper in the paper feed tray. The paper setting unit 142 can set the paper type and the amount of paper for each paper type.

An engine control unit 110 provided in the image forming apparatus main body 10A is connected to the system control unit 100. The engine control unit 110 controls an image forming operation, a conveying operation, a post-processing operation and the like in the image forming system 1 and includes a CPU and a program for operating the CPU.
The large-capacity paper feeding device 30 is an optional mechanism that can be separated, but the engine control unit 110 performs conveyance and other control of the large-capacity paper feeding device 30 itself.

  A post-processing control unit 160 provided in the post-processing device 20 is controllably connected to the engine control unit 110, and the post-processing control unit 160 performs post-processing from the system control unit 100 via the engine control unit 110. The post-processing side is controlled according to the instruction content. Further, a post-processing control I / F processing unit 150 is connected to the engine control unit 110 in a controllable manner to enable communication with the post-processing device.

  To the engine control unit 110, an image forming processing unit 120 provided in the image forming apparatus main body 10A is connected in a controllable manner. The image forming processing unit 120 performs data processing on the writing unit based on the image data and creates an image in the image forming unit 11.

  The engine control unit 110 is connected to a controllable sheet conveyance control unit (main body) 130 that is provided in the image forming apparatus 10 and controls sheet conveyance. A double feed detection unit 131 is controllably connected to the paper transport control unit (main body) 130, and the detection result of the double feed detection unit 131 is transmitted via the paper transport control unit (main body) 130 and the engine control unit 110. To the system control unit 100.

  In addition, a paper conveyance control unit (PFU) 230 that controls paper conveyance in the large-capacity paper feeding device 30 is connected to the engine control unit 110 in a controllable manner. A double feed detection unit 231 is controllably connected to the paper transport control unit (PFU) 230, and the detection result of the double feed detection unit 231 passes through the paper transport control unit (PFU) 230 and the engine control unit 110. To the system control unit 100.

The double feed detection units 131 and 231 irradiate the paper conveyed through the conveyance path with ultrasonic waves from a set position, receive the ultrasonic waves that have passed through the paper, and determine the double feed of the paper according to the received waves. is there. The system control unit 100 that receives the detection results of the multi-feed detection units 131 and 141 performs multi-feed determination by two methods, that is, a method of detecting the overlap of paper and a method of detecting the length of the paper passing direction. Is possible. The double feed detection units 131 and 231 can perform double feed detection by two methods by irradiating a certain amount of ultrasonic waves.
Note that the configuration of the double feed detection unit is not limited to the above, and a configuration using light transmission or the like is also possible. Further, some of the double feed detection units may include those that do not use the two methods.

Next, the configuration of the transport path will be described based on the schematic diagram of FIG.
The large-capacity paper feeder 30 has the PFU trays 1, 2, and 3 in the left column shown in FIG. 1 and the PFU trays 4, 5, and 6 in the right column shown in FIG. A transport path 32 is connected to the PFU trays 1, 2, and 3, and the transport path 32 is connected to the transport path 15 of the image forming apparatus 10. A transport path 31 is connected to the PFU trays 4, 5, 6, and the transport path 31 joins the transport path 32. Thus, the sheets on the PFU trays 1, 2, and 3 can be conveyed to the conveyance path 15 of the image forming apparatus 10 through the conveyance path 32, and the sheets on the PFU trays 4, 5, and 6 are conveyed on the conveyance path 31 and the conveyance path 31. The sheet can be conveyed to the conveyance path 15 of the image forming apparatus 10 through the path 32.

In the large-capacity paper feeding device 30, a multi-feed detection sensor 231A, which is one of the multi-feed detection units 231, is provided in the transport path 31 where the transport paths of the PFU trays 4, 5, and 6 merge. 31 detects the double feed of the paper transported. Further, the transport path 32 is provided with a double feed detection sensor 231B, which is one of the double feed detection units 231, in the transport path 32 where the transport paths of the PFU trays 1, 2, and 3 merge. 32, the double feed of the paper conveyed is detected.
In the image forming apparatus 10, a double feed detection sensor 131 </ b> A that is one of the double feed detection units 131 is provided in a paper feed conveyance path 12 </ b> A where the conveyance paths from the paper feed trays 12 of the respective stages merge. A double feed of a sheet conveyed on the conveyance path 12A is detected.

  In the present embodiment, a double feed detection sensor is provided after the merging point of each paper feed tray. As a result, the number of double feed detection units can be reduced. Note that the number of sensors installed may be reduced in consideration of the fact that a sensor is provided for each tray in accordance with the machine configuration or that detection of double feed is delayed as detection is performed on the downstream side.

  The paper fed from each tray is subjected to double feed detection by the corresponding double feed detection sensor unit, and if it is not double fed, it continues to be conveyed and reaches the registration unit 15B of the image forming apparatus 10 And make an image. The imaged paper is heated and pressed by the fixing roller 16A of the fixing device 16 to fix the image, and is discharged to the post-processing device 20.

The system control unit 100 has two double feed detection methods for each sensor for detection by the double feed detection sensors 131A, 231A, and 231B. The first detection method is a method of performing double feed detection based on a difference in normal ultrasonic amount, and the second detection method is for a paper (envelope or special paper) that is detected as double feed in the normal detection method. When the amount of ultrasonic waves that can be determined to be double feed is detected, it is determined that there is a sheet, and otherwise, it is determined that there is no sheet. If the trailing edge is later than the expected timing, it can be determined that the paper is detected longer than the specified size by double feeding.
For the double feed detection method, for example, the usage method can be set based on paper information such as paper type, paper size, and basis weight.

FIG. 4 shows a paper type setting screen 1400 displayed on the operation unit 14.
In the paper type setting screen 1400, a paper setting screen is provided for each paper feed tray, and the paper type can be selected and set by a paper type button 1401 as shown in the figure. In this embodiment, five types of settings are provided as paper types: plain paper, high-quality paper, color paper, envelope, and coated paper (can be set according to the basis weight). A desired paper type can be selected from the paper type list displayed on the paper type button 1401.

Depending on the paper type, you can set whether one or both of the detection methods are used, and the detection method can be determined when the paper type is determined. Good. Settings corresponding to the type of paper can be stored, for example, in a flash memory of the system control unit 100. This setting may be changed, deleted, newly installed by the user through the operation unit 14. The detection method can be stored in a flash memory or the like as setting contents in the sheet feeding tray, and the setting contents can be read out and used for double feed detection when the sheet feeding tray to be used is used.
In addition to the above settings, the user may be able to set a method that is arbitrarily used for each paper feed tray. Only one of the settings based on printing conditions such as paper information and user settings may be possible, but if both are set, it is desirable to prioritize user settings. . As a result, even if the paper used by the user is special, it is possible to pass the paper using the optimum double feed detection method at the user's discretion.

Also, on the paper type setting screen 1400, it is possible to set whether or not to detect double feed for each paper feed tray, and with the double feed detection button 1402 it is possible to select between detection and non-detection.
Even if “plain paper” is used, the user can set whether or not to detect double feed for each tray in consideration of the case where the user uses special paper partially duplicated. If special paper is used even if it is plain paper, control is performed by the second detection method by selecting “not detected”.

  As described above, according to the paper type setting of the paper, it can be determined whether the double feed detection is performed by the first method, the second method, or a combination of both. The detection method determination procedure selected according to the paper type will be described with reference to the flowchart of FIG. The following procedure is executed under the control of the system control unit 100.

In the double feed detection switching determination process, a paper feed instruction is awaited (step s1, No), and if there is a paper feed instruction (step s1, Yes), it is determined whether the paper type is other than an envelope (step s2). If the paper type is other than envelope (step s2, Yes), it is determined whether the paper feed tray is set to detect double feed (step s3). If the paper type is an envelope (No at step s2), the double feed detection method is set to the second detection method, and the procedure ends.
If it is determined in step s3 that there is a double feed detection (step s3, Yes), the double feed detection method is set to use the first detection method or the first and second detection methods in combination (step s4). .
If it is determined in step s3 that no multi-feed detection is set in the paper feed tray (step s3, No), the multi-feed detection method is set to the second detection method (step s5), and the process ends.

As described above, when “envelope” is selected as the paper type, the first detection method cannot be performed as described above, so the second detection method is always selected. (In the paper type setting screen 1400, “detected” is grayed out or the like, and is displayed so that the user cannot select it). If double feed detection is possible with the first detection method, the second detection method may be used in combination.
As described above, the double feed determination is performed according to the detection method determined by the switching detection means of the first detection method and the second detection method.

Next, the procedure of the double feed detection determination process will be described with reference to the flowchart of FIG. The following procedure is executed under the control of the system control unit 100.
First, it is determined whether the first detection method is used (step s10). When the first detection method is used (step s10, Yes), it is determined whether it is the detection start timing (step s11). The detection start timing is determined based on whether the leading edge of the paper is detected by the sensor. If it is not the detection start timing, it waits until the detection start (step s11, No).

  Whether or not it is the arrival timing of the leading edge of the target paper to the double feed detection sensor that starts double feed detection control may be detected from the threshold value of the double feed detection sensor. There is a possibility that the detection accuracy is inferior to that of the reflective sensor used in the control. When a reflection type sensor for paper conveyance control is provided one upstream from the paper conveyance direction, the arrival timing may be determined by obtaining the arrival time from the paper conveyance start time from the reflection type sensor.

If it is the detection start timing (step s11, Yes), the paper leading edge arrival time is recorded (step s12), and it is determined whether the detection completion timing is reached (step s13). The completion of detection is determined at the timing when the trailing edge of the sheet is completed.
If the detection completion timing has not been reached (No at step s13), it is determined whether double feed is detected after a delay of 100 msec (step s15).

In the first detection method, the double feed detection sensor value is detected at a cycle of 100 msec from the timing when the leading edge of the target paper reaches the double feed detection sensor, and it is determined whether or not the threshold value can be determined as double feed.
If double feed detection has not been performed (No in step s15), the process returns to step s13 to continue the processing. If double feed detection has been performed (Yes in step s15), the conveyance is performed assuming that double feed JAM has occurred. Stop (step s16) and end the process. The detection is repeated until the trailing edge of the paper reaches the double feed detection sensor as described above. In addition, the numerical value in the delay can be set to an appropriate numerical value in consideration of the detection capability of the sensor and the control burden.

  In step s13, if the detection completion timing has been reached (step s13, Yes), it is determined whether the first and second detection are used together (step s17), and if the first and second detection are not used together (step s17, No). ), No double feed (normal operation; step s21), and the process is terminated.

When the first and second detections are used together in step s17 (step s17, Yes), it is determined whether the rear end Xmm has passed (step s18) and waits until the rear end Xmm has passed (step s18, No).
In the second detection method, double feed is detected by detecting the sheet trailing edge removal timing from the double feed detection sensor. The trailing edge removal time is calculated according to the paper passing direction size, and a margin of X mm is provided.

  When the trailing end Xmm has elapsed (step s18, Yes), it is determined whether there is a sheet (double feed detection state) (step s19). If there is a sheet (step s19, Yes), double feed JAM is stopped as double feed detection (step s20), and the procedure is terminated. If there is no sheet (No in step s19), the procedure is ended as no double feed (normal operation; step s21).

In the above description, even if the time including the margin elapses, if there is still a sheet (double feed detection), it is determined that a double feed has occurred. At this time, the threshold of the ultrasonic detection amount for determining that there is paper may be set to a different threshold from that of the first detection method in order to prevent erroneous detection. In this case, since the sheet is originally detected as a double feed, it is possible to switch to the threshold value on the side that is determined to be a double feed.
Further, the margin Xmm at this time may be provided with a margin larger than usual in consideration of the case where the accuracy is inferior to that of detecting the trailing edge of the paper with a reflective sensor.

If the first detection method is not used in step s10 (step s10, No), the second method is used, and the sensor arrives at the leading edge of the target paper (step s22, No).
The timing at which the leading edge of the target paper reaches the double feed detection sensor, which is the start of double feed detection control, may be detected from the threshold of the double feed detection sensor, as in step s11. There is a possibility that the detection accuracy is inferior to that of the reflective sensor used in the paper conveyance control. When a reflection type sensor for paper conveyance control is provided one upstream from the sheet conveyance direction, arrival may be determined by obtaining an arrival time from a sheet conveyance start time from the reflection type sensor.

If the paper front end sensor has been reached (step s22, Yes), the paper front end arrival time is recorded (step s23), and it is determined whether it is the detection completion timing (step s24).
When the detection completion timing is reached (step s24, Yes), the trailing edge removal time is calculated according to the sheet passing direction size, a margin is provided by Xmm, and it is determined whether the trailing edge Xmm has passed (step s25). .

It waits for X mm to elapse at the rear end (step s25, No), and after Xmm has elapsed (step s25, Yes), it is determined whether paper is present (double feed detection state) (step s26).
Even if the time including the margin elapses, if there is still a sheet (double feed detection) state, it can be determined that double feed has occurred.
If there is paper (step s26, Yes), the double feed JAM is stopped as the double feed detection (step s27), and the procedure is terminated. If there is no sheet (No in step s26), the procedure is ended as no double feed (normal operation; step s28).

  The threshold value of the ultrasonic detection amount for determining that there is a sheet at this time may be a threshold value different from that of the first detection method in order to prevent erroneous detection. In this case, since the sheet is originally detected as a double feed, it is possible to switch to the threshold value on the side that is determined to be a double feed. In addition, the margin Xmm at this time can be provided with a margin larger than usual in consideration of a case where the accuracy is inferior to that of detecting a trailing edge omission of the paper with a reflective sensor.

  As described above, the present invention has been described based on the above embodiment, but appropriate modifications can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Image forming system 10 Image forming apparatus 11 Image forming part 12 Paper feed tray 12A Paper feed conveyance path 14 Operation part 15 Transport path 15A Reverse conveyance path 20 Post-processing device 30 Large capacity paper feeder 31 Transport path 32 Transport path 100 System control Unit 110 Engine control unit 131 Double feed detection unit 131A Double feed detection sensor 231 Double feed detection unit 231A Double feed detection sensor 231B Double feed detection sensor

Claims (13)

A paper transport device having a detection system for detecting double feeding of paper fed from a paper feed unit,
A paper detection sensor for detecting paper,
First detection means for detecting whether or not double feeding based on information on the thickness direction of the paper obtained by the paper detection sensor;
Second detection means for detecting whether or not double feeding based on information on the length of the paper in the conveyance direction obtained by the paper detection sensor;
A sheet conveying apparatus comprising: a switching unit that switches between a first detection unit and a second detection unit based on information on a sheet to be fed and conveyed. The paper transport apparatus according to claim 1 , wherein the paper information is at least one of a paper type, a paper size, and a basis weight of the paper . 3. The paper conveying apparatus according to claim 1, wherein the paper information is set for a tray to which paper is fed . The paper conveying apparatus according to claim 1, wherein the paper information is set by a user. 2. The switching unit according to claim 1, wherein when detecting double feed, the switching unit switches between a method using both the first detection unit and the second detection unit and a method using only the second detection unit. The paper conveying apparatus of any one of -4. The paper conveyance device according to claim 1, wherein the paper detection sensor uses ultrasonic waves. A double feed detection method for detecting double feed of paper fed from a paper feed unit using a paper detection sensor for detecting paper,
A first detection method for detecting whether or not double feeding is performed based on information on the thickness direction of the paper obtained by the paper detection sensor, and whether double feeding is performed based on information on the length of the paper in the conveyance direction obtained by the paper detection sensor. A double feed detection method, characterized in that the second detection method for detecting whether or not is switched based on information on a sheet to be fed and conveyed. The multifeed detection method according to claim 7, wherein the paper information is at least one of a paper type, a paper size, and a basis weight of the paper. The multifeed detection method according to claim 7 or 8, wherein the paper information is set for a tray to which paper is fed. The multi-feed detection method according to claim 7, wherein the paper information is set by a user. The method according to any one of claims 7 to 10, wherein when detecting double feed, the method is switched to a method using both the first detection method and the second detection method and a method using only the second detection method. The double feed detection method according to Item 1. The multi-feed detection method according to claim 7, wherein the paper detection sensor uses ultrasonic waves. An image forming system comprising the sheet conveying device according to claim 1 .

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