JP2011051777A - Device and method for processing document - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a document processor capable of continuously conveying a plurality of documents and slips of different sizes by shortening an interval between slips according to slip sizes. <P>SOLUTION: In the case that a rear edge of a slip going ahead is detected among slips which are conveyed continuously, speed for supplying a following slip to an image reading device is reduced, and after a predetermined number of steps are counted (a predetermined time passed), the control for re-accelerating the slip supply speed from the state of decelerating is continuously carried out for each slip. BY this, an interval between the slips is shortened according to the slip sizes, and the image reading section can accurately read the image formed in the slip at a high speed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a document processing apparatus and a document processing method for transporting various documents, forms, and the like along a transport path.

  Currently, a wide variety of documents and forms are used in all types of business, and the need to reliably process them in a short time is increasing. For example, a large hospital needs to process a large number of receipts (medical fee bills), and a large-scale retail store, mail-order dealer, carrier, etc. Since logistics is progressing, it is indispensable to efficiently process a large amount of documents, slips and forms. For this reason, in each industry, in order to enable high-speed processing, a processing device corresponding to the type of document or the like is used. For example, in the apparatus described in Patent Document 1, when a document placed on a hopper device is separated for each spell, sent to a recognition unit at a predetermined speed, and passed through the recognition unit at a predetermined speed, the surface of the document Alternatively, the image on the back side is read and necessary image analysis processing is performed. Such a processing apparatus includes, for example, a feeder mechanism / conveying mechanism including a belt that is rotationally driven at a predetermined speed because it is necessary to reliably process a wide variety of forms in a short time.

JP 2003-54812 A

  In the above document processing apparatus, for example, in order to read the information described in the document at a high speed and reliably in the recognition unit of the document, for example, the document to be processed is taken out from the hopper after the conveyance is completed. In this case, when the documents and the like are continuously conveyed to the recognition unit, it is necessary to convey the individual documents so as to have an interval that can secure the processing time in the recognition unit. In the conventional document processing apparatus, the interval between the preceding document and the subsequent document is simply created based on the speed difference between the transport speed in the feeder section and the transport speed in the recognition section that is faster than that. The intervals between the documents are based on the minimum length in the transport direction, and the transport speeds of the feeder unit and the recognition unit are fixed at a predetermined constant speed.

  In such a document processing apparatus, when documents of different sizes are conveyed together, the interval between documents of the same size is kept constant according to the difference in the conveyance speed between the feeder unit and the recognition unit. When a document having a size longer than the reference size follows, the following problem occurs. In other words, since the transport speed is fixed and set based on the document with the minimum length in the transport direction, a long size document is preceded according to the difference between the reference size and the long size document. The interval between documents becomes unnecessarily long. Such a long interval between the conveyed documents causes a problem that an unnecessary blank time is generated in the image recognition processing or the like in the recognition unit, and a business processing amount (throughput) per unit time of document processing is reduced. Arise.

  The present invention has been made in view of such problems, and the object of the present invention is to provide an interval between forms on a conveyance path even when a plurality of documents or forms having different sizes are continuously conveyed. It is to provide a document processing apparatus that can reduce the size according to the form size. It is another object of the present invention to provide a document processing apparatus that can easily correct a tilt even if a slip or the like is tilted during conveyance.

In order to achieve the above object, the present invention is a document processing apparatus capable of transporting a document from the upstream side to the downstream side of the transport path, wherein the paper feed means supplies the document to the transport path at a first paper feed speed. And means for conveying the document at a predetermined conveyance speed according to the conveyance path; means for detecting a trailing edge of the document conveyed on the conveyance path at a predetermined position of the conveyance path; and the trailing edge detected In this case, the sheet feeding speed of the subsequent document is decelerated from the first sheet feeding speed to the second sheet feeding speed for a predetermined time, and the second feeding after the deceleration after the predetermined time has elapsed. Means for reaccelerating the paper speed to the first paper feed speed, the first paper feed speed is set slower than the transport speed, and a plurality of documents continuously transported through the transport path A predetermined interval corresponding to the deceleration and re-acceleration of the paper feed speed is provided. That.
For example, the first paper feeding speed is set to be 10 to 20% slower than the transport speed, and the image reading unit disposed in the transport path is continuously transported by the image reading unit for the predetermined time. Is determined in accordance with the minimum document interval that can be reliably read. Further, for example, the re-acceleration of the paper feed speed is continued for at least a time corresponding to a time required for a document having a minimum length in the transport direction to pass through the paper feed unit among a plurality of documents to be transported. It is characterized by that.
Further, for example, an upper roller and a lower roller for sandwiching a document to be conveyed, a driving means for rotating one of the upper roller and the lower roller in the document conveying direction, the upper roller and the lower roller And a means for detecting the presence or absence of double conveyance of the document passing between the upper roller and the lower roller based on the difference in rotational speed between the upper roller and the lower roller. In addition, for example, the paper feeding unit includes a first conveying unit that conveys a document in a downstream direction of the conveying path, a first driving unit that rotationally drives the first conveying unit, and the first A second conveying means that is arranged in parallel with the conveying means, conveys the document in the downstream direction of the conveying path, a second driving means that rotationally drives the second conveying means, and the conveying path Detecting means for detecting the inclination of the document before reaching the position, and control means for individually controlling the rotation speeds of the first driving means and the second driving means in accordance with the direction of the inclination, the control means The rotational speed of the first driving means is set to be higher than the rotational speed of the second driving means or the rotational speed of the second driving means is set to the first speed according to the tilt direction of the document. By making it faster than the rotation speed of the drive means, the document conveyance speed can be increased. And integer, and correcting the inclination of the document.

  In order to achieve the above object, the present invention provides a document processing method for conveying a document from an upstream side to a downstream side of a conveyance path, wherein the document is supplied to the conveyance path at a first paper feed speed, and the conveyance path If the trailing edge of the document conveyed on the conveyance path is detected by the detection means arranged at a predetermined position on the conveyance path, the sheet feeding speed for the subsequent document is set. The first paper feed speed is decelerated from the first paper feed speed to the second paper feed speed for a predetermined time, and after the predetermined time has elapsed, the second paper feed speed after the deceleration is returned to the first paper feed speed. By performing the acceleration process continuously for each document, a predetermined interval corresponding to the deceleration and re-acceleration of the paper feed speed is provided between a plurality of documents continuously conveyed on the conveyance path. It is characterized by.

  According to the present invention, when a document or a document of a different size is continuously conveyed and processed, the interval between the continuously conveyed documents can be shortened according to the document size on the conveyance path. Thereby, the business processing amount (throughput) in the conveyance process and the reading process of the form and the like is improved.

1 is an external view showing an overall configuration of a document processing apparatus according to an embodiment of the present invention. It is a figure which shows the external appearance structure of the feeder apparatus of the document processing apparatus which concerns on the example of an embodiment, an image reading apparatus. It is a block diagram which shows the structure of the principal part of the document processing apparatus which concerns on the example of an embodiment. It is a flowchart which shows the conveyance control procedures, such as a form, in the document processing apparatus which concerns on embodiment. It is a figure which shows typically the conveyance state of the form etc. in each of the feeder apparatus of the document processing apparatus which concerns on embodiment, and an image reading apparatus. It is a partially broken figure which shows the detailed structure of the feeder part of the document processing apparatus which concerns on the embodiment.

  Embodiments according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is an external view showing the overall configuration of a document processing apparatus according to this embodiment. A document processing apparatus 100 shown in FIG. 1 includes a feeder apparatus 10, an image reading apparatus (also referred to as a reading apparatus) 20, a determination apparatus 30, and a stacker apparatus 60. The feeder device 10 is a device for separating and transporting documents, forms, and the like placed on the hopper part by moving the paddle part, which will be described later. For example, the feeder apparatus 10 is not limited to forms of different sizes or single-bound forms. The forms having various thicknesses and the binding method are indefinite are separated for each binding, and are fed into the conveyance path of the reading device 20.

  The image reading device 20 reads image information of the entire surface such as a form conveyed along the conveyance path from the feeder device 10 and performs predetermined image analysis processing. Specifically, a scanner (image reader) 50 electronically captures image information on the front or back side of a conveyed form or the like as an image, and analyzes an image of a character or the like described in a predetermined area of the form or the like. To extract the description. Then, the stacker device 60 is controlled according to the extracted contents.

  The determination device 30 is located on the downstream side of the reading device 20, and determines the type of form sent from the reading device 20, the overlapping state of the forms, and the like. A stacker device 60 is disposed at the subsequent stage of the determination device 30 and functions as a document storage unit that separates and places the conveyed forms and the like in pockets according to instructions from the reading device 20. A plurality of light emitting elements are embedded in a row in the conveying surface of the discriminating device 30 so as to be orthogonal to the conveying direction. A light receiving element is arranged. The light emitted from the light emitting elements arranged in a row in the vertical upper direction through the holes provided in the transport surface is detected by the light receiving element. Here, based on the light detection result by the light receiving element, the state of the form passing between the light emitting element and the light receiving element is determined.

  The document processing apparatus 100 further includes an operation unit and a display for an operator to input various operation information, to display an operation state of the apparatus, or to visually display an image read by the image reader 50. The monitor unit 40 functions as a unit. It should be noted that the description of the specific contents of the image reading process from the document, the determination method of the form type, and the document storing process is omitted here.

  Next, a feeder mechanism and a transport mechanism for documents and the like in the document processing apparatus according to the present embodiment will be described. FIG. 2 is a perspective view showing an external configuration of the feeder device 10 and the image reading device 20 of the document processing apparatus 100. In the mechanism shown in FIG. 2, the hopper unit 201 separates documents of various thicknesses and documents having different binding methods for each binding, and each separated document is sent at a predetermined speed via the sending unit 202. Is sent to the reading device 20. The hopper unit 201 is provided with a picker unit 103 and a conveyor belt unit 101. A part of the conveyor belt unit 101 moves not only the document as described later but also the paddle unit 102 itself, It has a function of transporting a document placed on the hopper unit 201 to the picker unit 103.

  Of the belts constituting the conveyor belt unit 101, two belts arranged on the front side of the apparatus (side on which the operator of the apparatus stands) are tooth-shaped slits arranged on the surface at regular intervals (the belt moving direction and the belt direction). The protrusion and the groove that run in the vertical direction have a structure that is continuous at a constant interval. Part of the bottom of the paddle part 102 is engaged with this groove, and the paddle part 102 itself moves to the picker part 103 side as the groove part moves due to the movement of the conveyor belt part 101. For this reason, the conveyance belt unit 101 is driven almost in synchronization with the bundle of documents and forms (not shown in FIG. 2) placed in front of the paddle unit 102 gradually decreasing by conveyance. Control is performed.

  The picker unit 103 is provided with a sensor unit 104 that detects the position of the pickup roller 131 based on the thickness of the document positioned below the pickup roller 131 in order to operate the above-described conveyance belt 101. Further, in order to align the front edge of the documents loaded on the feeder device 10, a document guide portion 107 that runs in parallel with the front side of the conveying belt portion 101 is provided.

  The sending unit 202 is provided with a feeder unit 130 as a document separation / feeding mechanism. As shown in FIG. 2, the feeder unit 130 is covered with a safety cover. As will be described later, the feeder unit 130 separates documents and forms by two conveyor belts that rotate in opposite directions while being in contact with each other. And carry. On the other hand, a plurality of conveying belts 207 are arranged in the conveying unit 203 of the image reading apparatus 20 in order to convey a document or the like along the conveying surface 205. These conveyance belts 207 maintain a positional relationship of being adjacent to each other in parallel with a certain distance. The conveyor belt 207 is rotationally driven by a drive motor (not shown) and moves in the same direction at the same speed in synchronization with each other. Further, a gap sensor 209 for detecting an end of a document or a form is arranged at a location upstream of the conveyance surface 205 and in the vicinity of the sending unit 202. A scanner 50 for reading image information as an image from a conveyed form or the like is arranged.

  Next, a conveyance process of a form or the like in the document processing apparatus according to the present embodiment will be described in detail. FIG. 3 is a block diagram showing a configuration of a main part of the document processing apparatus according to the present embodiment, and FIG. 4 is a flowchart showing a conveyance control procedure for a form or the like in the document processing apparatus. FIG. 5 schematically shows the state of conveyance of forms and the like in each of the feeder device and the image reading device of the document processing apparatus.

  In FIG. 3, the central control unit 401 is composed of, for example, a microprocessor, and controls the feeder unit 130. The memory 407 stores control programs, control data, control parameters, and the like required by the central control unit 401. As will be described later, the central control unit 401 receives a detection signal corresponding to an edge portion of a conveyed form or the like from the gap sensor 209, and based on the detection signal, a driving motor A (403) and a driving motor B for the conveying belts 301 and 303. (405) is controlled. The gap sensor 209 is a sensor for detecting an edge of a conveyed form or the like. For example, the gap sensor 209 has a configuration in which a light emitting element is embedded in the conveying surface 205 and a light receiving element is arranged at a predetermined distance above the vertical surface. Have. The gap sensor 209 detects the passing state of the form or the like based on whether or not light reaching the light receiving element from the light emitting element is blocked by the form or the like passing between the light emitting element and the light receiving element.

  When the conveyance of a form or the like is started in the document processing apparatus, the central control unit 401 initializes variables (parameters) for controlling the conveyance speed of the form, the I / O pin state, etc. in step S1 of FIG. In the next step S3, a predetermined communication process is performed. In step S5, the image reading apparatus 20 waits for an operation start signal from the scanner control unit 315 that controls the entire scanner. When the operation start signal is received, the central control unit 401 applies a predetermined drive voltage to the motors that drive the conveyor belts disposed in the feeder device 10 and the image reading device 20 in step S7, thereby exciting the motors. To start. Here, the conveyance belt of the feeder apparatus 10 is operated at the conveyance speed Vf and the conveyance belt of the image reading apparatus 20 is operated at the conveyance speed Vr by excitation of the drive motor. At this time, Vf <Vr, for example, Vf is 10-20% slower than Vr so as to have a speed ratio of Vf: Vr = 80: 100 or 90: 100.

  In the document processing apparatus according to the present embodiment, for example, the forms A, B, C, and D are placed on the hopper unit 201 of the feeder apparatus 10, and the forms A, B, and D have the same size, and the form C Is assumed to be larger in size than the other forms and sent out from the feeder unit 130 to the conveying belt 207 side of the image reading device 20 in the order of forms A → B → C → D. When the operation of the document processing apparatus is started, the feeder unit 130 starts the conveyance operation by excitation of the drive motor, so that the form A is first transferred onto the conveyance belt of the feeder unit 130 as shown in FIG. Is sent downstream at a speed Vf. Since the transport belt 207 is driven at the transport speed Vr, the form A sent from the feeder unit 130 toward the transport belt 207 is also transported downstream at the speed Vr. When the form A passes through the lower part of the gap sensor 209 disposed in the vicinity of the upstream end of the conveyor belt 207 as shown in FIG. 5B, the trailing edge (trailing) of the form A is formed by the gap sensor 209.・ Edge) is detected.

  When the central control unit 401 receives the trailing edge detection signal TE of the form A from the gap sensor 209 in step S9, the central control unit 401 sets the flag corresponding to the gap sensor to “true” in subsequent step S11, and then performs processing. Proceed to S15. In this step S15, the feed control motor deceleration process, that is, the excitation state of the drive motors A and B that actuate the conveyor belt of the feeder unit 130 is changed, and the conveyance speed in the feeder unit 130 is decelerated from Vf to Vf ′. . In the next step S17, it is determined whether or not the number of steps for continuing the excitation state for deceleration has reached a predetermined number. Then, the deceleration processing of the drive motors A and B is continued until the number of deceleration steps has expired. In FIG. 5B, the form B following the form A is in a decelerating state on the transport belt of the feeder unit 130.

  If it is determined in step S17 that the number of deceleration steps has expired, the central control unit 401 sets the sensor flag to “false” in step S19, and then in step S21, re-acceleration processing of the feed control motor, that is, feeder. The drive motors A and B are re-excited to shift the feeder unit 130 of the apparatus 10 from the deceleration state to the acceleration state. FIG. 5C shows a state when the conveyor belt of the feeder unit 130 of the feeder apparatus 10 is accelerated from the speed Vf ′ to Vf. Specifically, the form A that has already been sent onto the conveyance belt 207 (here, the form conveyed first is also referred to as “preceding form” and the subsequent form is also referred to as “following form”). The upper side is conveyed at the speed Vr, and the form B, which is a subsequent form, is sent to the conveyor belt 207 side at the speed Vf by the reacceleration process. Then, the subsequent form B is sent out to the conveyor belt 207 side at the speed Vf until the predetermined number of acceleration steps expires (step S23). Note that the number of acceleration steps is determined in accordance with, for example, the time until a form having the smallest length in the carrying direction passes through the feeder unit 130 out of various sizes of forms to be carried. .

  FIG. 5D shows a state in which the form B is sent onto the conveyor belt 207 of the image reading apparatus 20 by the reacceleration process and is conveyed downstream at the speed Vr together with the preceding form A. As a result of performing the deceleration process and the reacceleration process as described above, the speed Vf during the deceleration process corresponding to the number of deceleration steps is between the preceding form A and the following form B as shown in FIG. An interval G defined by the difference between 'and Vr can be provided. After the acceleration step number has expired, the trailing edge of the subsequent form is detected by the gap sensor 209 in step S25. In the example shown in FIG. 5D, the trailing edge of the form B is detected, and the detection signal TE is sent to the central control unit 401. In subsequent step S27, the flag corresponding to the gap sensor is set to “true”.

  In step S29, it is determined whether there is a subsequent form or the like. Here, since there is a form C to be processed next to the form B, the central control unit 401 returns the process to step S15. Since the sensor flag is “true” when the gap sensor 209 detects the trailing edge of the form B as described above, the central control unit 401 continues the form B following the form B until the number of deceleration steps has expired. Deceleration processing is performed on C (steps S15 and S17). When the number of deceleration steps expires and the drive motors A and B of the feeder unit 130 of the feeder apparatus 10 shift to the reacceleration state due to reexcitation of the feed control motor (step S21), the central control unit 401 performs predetermined acceleration. Until the number of steps expires, the form C is sent to the image reading apparatus side at the conveyance speed Vf (step S23). FIG. 5E shows a state where the form C is being re-accelerated.

  Since the form C is larger in size than the other forms A, B, etc., which are the reference for the number of acceleration steps (the length in the transport direction is long), even after the number of acceleration steps has expired in step S23, the form C Sending from the feeder unit 130 to the image reading device 20 side is not completed. Therefore, in the state of FIG. 5E, the rear edge of the form C is not detected by the gap sensor 209. In other words, if the number of acceleration steps expires and the trailing edge of the following form is detected, the following form is a predetermined minimum size form, but even after the number of acceleration steps has expired, If the trailing edge of the succeeding form is still not detected, the succeeding form is a form having a length in the transport direction longer than the predetermined minimum size. In this case, the central control unit 401 continues the acceleration processing of the feed control motors A and B, and the detection processing of the trailing edge portion of the subsequent form (form C in this case) is executed in step S25.

  FIG. 5F shows a state when the form C is sent to the image reading apparatus 20 side by the above acceleration processing. During the deceleration process and the acceleration process for the form C, the preceding forms A and B are both conveyed by the conveyance belt 207 at the speed Vr. As a result, as shown in FIG. 5F, a gap G ′ defined by the difference between the speeds Vf ′ and Vr during the deceleration process of the form C is provided between the preceding form B and the succeeding form C. .

  Thus, after the reacceleration process, when the form C is sent to the conveying belt 207 side of the image reading device 20, the number of acceleration steps in step S23 has already expired, so in step S25, the form C is detected by the gap sensor 209. The trailing edge is detected. When the trailing edge of the form C is detected, the gap sensor 209 sends the trailing edge detection signal TE of the form C to the central control unit 401, and the flag corresponding to the gap sensor becomes “true” in step S27. Here, since there is a form D to be processed next (NO in step S29), as shown in FIG. 5F, a drive motor for feed control is performed on the form D following the form C in step S15. Excitation for deceleration processing is performed on A and B. Thereafter, the re-acceleration process similar to the above is performed on the form D (see FIG. 5G), and the preceding form C and the subsequent form C, which are conveyed on the conveyance belt 207 together with the forms A and B, and the subsequent form. An interval G is provided between the form D and the form D. The state of the form at that time is shown in FIG. If there is no form to be processed next (YES in step S29), in step S31, the application of the drive voltage to the motor that drives the conveying belt of the feeder device 10 and the image reading device 20 is stopped, and the motor Stop excitation.

  Note that the number of deceleration steps and the transport speed Vf ′ after the deceleration can be reliably read by the scanner 50, for example, information described in a form or the like that is continuously transported to the image reading device 20. Determine according to the minimum form interval. The number of deceleration steps and the deceleration speed Vf ′ are stored in the memory 407 as variable parameters so that optimum values can be selected as appropriate according to the type of form or the like handled by the document processing apparatus.

  Next, a feeder unit that separates and sends out documents in the document processing apparatus according to the present embodiment will be described. FIG. 6 is a partially broken view showing a detailed configuration of the feeder unit. The feeder unit 130 drives the form 500 sent from the picker unit 103 to the downstream image reading device 20. Therefore, two sets of belt conveyance mechanisms 301 and 303 arranged in parallel with each other and a multifeed detection mechanism 350 positioned on the downstream side of the belt conveyance mechanisms 301 and 303 are provided. The double feed detection mechanism 350 is for detecting double conveyance (simultaneous conveyance) of a document or the like, and is composed of drive wheels 351 and 353 and slave wheels 352 and 354 that rotate while being in contact with the drive wheels 351 and 353. Become.

  Of the belt transport mechanisms 301 and 303, the belt transport mechanism 301 is wound between a drive roller 311 driven by a transport motor (drive motor A) and a roller 312 which is coaxial with the drive roller 313 but rotates freely. The upper conveyor belt 305 is driven to rotate in the direction of the arrow a in the drawing according to the rotation of the driving roller 311 and is positioned below the upper conveyor belt 305, while being in surface contact with the upper conveyor belt 305 or slightly A reverse belt 321 (also referred to as a separator belt or a reverse belt) that is rotationally driven by a motor (not shown) in the opposite direction (in the direction of arrow b in the figure) while maintaining a gap. Similarly, the belt conveying mechanism 303 is wound between a driving roller 313 driven by a driving motor B and a roller 314 that is coaxial with the driving roller 311 but rotates freely. Similar to the upper conveyor belt 305, the upper conveyor belt 307 that is rotationally driven in the direction of the arrow, and the lower conveyor belt 307 is in surface contact with the upper conveyor belt 307 (or while maintaining a slight gap). The reverse belt 323 is rotationally driven by a motor (not shown) in the opposite direction to the upper conveyor belt 307.

  When the upper conveyance belts 305 and 307 are rotationally driven, when the document or the like is sent to the feeder unit 130 through the lower part of the pickup roller 131, the uppermost document is transferred to the upper conveyance belts 305 and 307. Is conveyed to the feeder unit 130 side. On the other hand, since the reverse belts 321 and 323 are rotating at a low speed in the opposite direction to the upper conveying belts 305 and 307, the lower document that is not at the uppermost portion has a force to send it back in the opposite direction to the feeder unit 130. . As a result, only the uppermost document is taken in the direction of the feeder unit 130 (downstream direction). The horizontal position of the contact surface between the upper conveyor belts 305 and 307 and the reverse belts 321 and 323 is the position of the conveyance surface such as a form in the feeder device 10 or the like.

  As shown in FIG. 6, the drive rollers 311 and 313 of the belt conveyance mechanisms 301 and 303 are connected to the independently provided drive motors A and B, so that the belt conveyance mechanisms 301 and 303 are also independent of each other. Behave. That is, these belt conveyance mechanisms 301 and 303 can rotate at different speeds and convey documents and the like by changing the drive speeds (speed parameters) of the drive motors A and B in accordance with conditions described later. Is possible. On the other hand, the drive motor C (435) controlled in synchronization with the drive motors A and B by the central control unit 401 rotates the drive (drive) wheels 351 and 353, whereby the clutches connected to the slave wheels 352 and 354 are connected. The mechanism unit 361 operates corresponding to the above-described conditions. Since both wheels of the drive wheels (drive wheels) 351 and 353 are simultaneously driven to rotate by the drive motor C, when the slave wheels 352 and 354 are also in contact with the drive wheels 351 and 353, the drive wheels 351 and 353 are driven. Rotating at the same speed as those receiving the rotational driving force. In addition, a clutch mechanism 361 is connected to the shafts of the slave wheels 352 and 354 via a coupling joint 370.

  The clutch mechanism portion 361 functions as a so-called one-way clutch (one-way clutch), receives the rotational torque of the follower wheels 352 and 354, rotates in a certain direction, and “slides” between the drive wheels 351 and 353 and the follower wheels 352 and 354. Operates according to the difference in rotational speed. Therefore, the operations in a normal case where the conveyed forms do not overlap each other and a case where, for some reason, two or more forms pass between the drive wheels 351, 353 and the sub wheels 352, 354 will be described. .

  In a normal state in which the forms do not overlap, when the drive wheels 351 and 353 rotate at a constant speed, the rotational force is transmitted to the follower wheels 352 and 354 through the forms as they are. Therefore, the slave wheels 352 and 354 also rotate at the same speed as the drive wheels 351 and 353. In this case, since the follower wheels 352 and 354 are rotating at a predetermined constant speed, the clutch mechanism 361 as a one-way clutch receives torque due to the rotation of the follower wheels 352 and 354 and receives the torque from the follower wheels 352 and 354. It rotates with no load (free rotation). Therefore, in the normal state, the aforementioned “slip” does not occur between the drive wheels 351 and 353 and the slave wheels 352 and 354.

  However, when the forms are sent in a state of being overlapped, a conveyance force is imparted to the forms directly contacting the drive wheels 351 and 353 from the drive wheels 351 and 353 to the conveyance downstream side (direction of the reading device 20). However, the conveyance force of the drive wheels 351 and 353 does not directly act on the form below the uppermost form. Therefore, the driven wheels 352 and 354 rotate at a speed different from that of the drive wheels 351 and 353, and a difference (slip) occurs between the rotation speeds of both wheels. Specifically, since the rotation torque beyond a certain level does not act on the slave wheels 352 and 354 due to “slip”, the rotation speed of the slave wheels is slower than that of the drive wheels. In some cases, the rotation stops. The clutch mechanism 361 functions as a one-way clutch and functions to apply a certain load to the slave wheels 352 and 354.

  As described above, the slave wheels 352 and 354 to which a constant load is applied by the clutch mechanism 361 acts to lower the conveyance speed of the lower form among the overlapping forms. As a result, only the uppermost form is preceded by the lower form, and is conveyed downstream by the drive wheels 351 and 353, and the lower form is sent to the downstream side with a slight delay. The double feed detection mechanism 350 monitors the rotational speeds of the follower wheels 352 and 354 and the drive wheels 351 and 353, and if there is a speed difference between them, the conveyance state of the form is in the double feed state. Detect.

  The drive wheels 351 and 353 are connected to the clutch mechanism 361 in the state where the rotation speeds of the drive (drive) wheels 351 and 353 are rotated by receiving the drive of the drive motor C (435) synchronized with the drive motors A and B. If there is a speed difference between the rotational speeds of the slave wheels 352 and 354 rotating in contact with each other, it means that the form is in a double feed state. Further, in the feeder unit 130 of the feeder device according to the present embodiment, an operation corresponding to the “slip” state is performed by the clutch mechanism unit 361 that rotates via the joint 370. In other words, the feeder device performs an appropriate operation by the clutch mechanism unit 361 during double conveyance of a form (simultaneous conveyance of two or more forms).

  On the other hand, the document processing apparatus according to the present embodiment includes an inclination determination device (not shown) on the upstream side of the image reading apparatus 20, and when the conveyed form is inclined with respect to a regular position, The inclination information value is immediately fed back to the central control unit 401. The central control unit 401 functions to control the drive motors A and B based on this determination information, correct the inclination of the form, and return it to a regular feed with no inclination.

  Specifically, the central control unit 401 drives the upper transport belt 305 constituting the belt transport mechanism by the drive motor A (403) according to the inclination of the form or the like, and drives the upper transport belt 307 by the drive motor B (405). To drive individually. For example, when the form on the transport surface on the downstream side of the feeder device is inclined with respect to the transport direction, the form that is passing between the light emitting element (not shown) and the light receiving element arranged on the transport surface is These optical elements (sensors) are not covered uniformly. Specifically, the light blocking state in which only the sensor on the back side of the transport surface is covered with the form indicates that the form to be transported tends to be “right tilted”, and the front side of the transport surface. The light blocking state in which only the sensor on the side is covered determines that the form tends to be “left tilted”. In this case, the time difference value of each sensor is notified to the central control unit 401 as inclination information.

  When a form or the like is sent with an inclination to the right, the central control unit 401 controls the drive motors A and B independently to control the rotation speed N1 of the upper conveyance belt 305 constituting the belt conveyance mechanism 301 to the belt conveyance. The rotational speed N2 of the upper conveyance belt 307 of the mechanism 303 is made faster (N1> N2). As a result, the form that has been inclined to the right is corrected in position (inclination correction) to a normal form. On the other hand, when the form or the like sent to the feeder device is tilted to the left, control is performed to make the rotational speed N2 of the upper transport belt 307 faster than the rotational speed N1 of the upper transport belt 305 (N1 <N2). As a result, the inclination of the form that has been inclined to the left is corrected, and the form returns to the normal form. When the feeder apparatus determines that no inclination is generated in the conveyed form or the like, the drive motors A and B are synchronously driven to control the upper transport belts 305 and 307 at the same speed (N1 = N2). ) To rotate.

  As described above, according to the present embodiment, in the document processing apparatus, after the trailing edge of the preceding form is detected among the continuously conveyed forms, the subsequent form is read. Control for reducing the supply speed (sending speed) to the apparatus side and re-acceleration of the supply speed of the form after the predetermined number of deceleration steps is completed is continuously performed for all the forms to be conveyed. In this way, even when forms of different sizes are continuously conveyed, the number of deceleration steps and the conveyance speed on the image reading device side are defined between the preceding and succeeding forms on the conveyance path. A predetermined interval can be provided. As a result, the interval between forms can be shortened according to the form size, and even when the supply speed of forms is increased to approach the conveyance speed on the conveyance path, unnecessary blank time occurs for image recognition processing in the image reading unit, etc. Therefore, the amount of business processing (throughput) per unit time of document processing can be greatly improved, and it is easy to reduce congestion of forms and the like on the conveyance path and to synchronize with the reading speed of image information in the reading apparatus. Furthermore, by parameterizing the form supply speed so that it can be varied, the speed of the drive motor can be freely changed according to the type of document to be conveyed, etc., enabling efficient conveyance of forms and the like. .

  In addition, by providing a one-way clutch mechanism including a drive wheel and a slave wheel in the feeder unit of the document processing apparatus, even if a form or the like is supplied in an overlapping manner, double conveyance of the form or the like in the feeder apparatus can be prevented. Furthermore, by detecting the inclination state of the forms on the conveyance path and independently controlling the drive motor according to whether it is right inclination or left inclination, the rotational speed of the two parallel conveyance belts can be adjusted individually. The tilt correction for returning the tilted form to the normal position can be performed, and the adverse effect on the image reading process caused by the tilt of the form can be eliminated.

DESCRIPTION OF SYMBOLS 10 Feeder apparatus 20 Reading apparatus 30 Discriminating apparatus 40 Monitor part 50 Imaging apparatus (image reader)
60 Stacker Device 101 Conveying Belt Unit 102 Paddle Unit 103 Picker Unit 130 Feeder Unit 131 Picker Roller 201 Hopper Unit 202 Sending Unit 203 Conveying Unit 207 Conveying Belt 209 Gap Sensor 301, 303 Belt Conveying Mechanism 305, 307 Upper Conveying Belt 315 Scanner Control 321, 323 Reverse belt 350 Double feed detection mechanism 351, 353 Drive wheel 352, 354 Slave wheel 361 Clutch mechanism part 380 Double feed detection unit 401 Central control unit 407 Memory 500 Form

Claims (6)

A document processing apparatus capable of transporting documents from the upstream side to the downstream side of the transport path,
Paper feeding means for feeding documents to the transport path at a first paper feeding speed;
Means for conveying a document at a predetermined conveyance speed according to the conveyance path;
Means for detecting a trailing edge of a document conveyed on the conveyance path at a predetermined position of the conveyance path;
Means for decelerating the feeding speed of subsequent documents from the first feeding speed to the second feeding speed for a predetermined time when the trailing edge is detected;
Means for re-acceleration of the second feeding speed after the deceleration to the first feeding speed after the predetermined time has elapsed,
The first paper feed speed is set slower than the transport speed, and a predetermined interval corresponding to the deceleration and re-acceleration of the paper feed speed is provided between a plurality of documents continuously transported on the transport path. Document processing device characterized by. The first paper feed speed is set to 10 to 20% slower than the transport speed, and the image reading means arranged in the transport path ensures the images on the continuously transported document for the predetermined time. 2. The document processing apparatus according to claim 1, wherein the document processing apparatus is determined in accordance with a minimum document interval that can be read. At least the refeeding of the paper feeding speed is continued for a time corresponding to a time required for a document having a minimum length in the transporting direction to pass through the paper feeding unit among a plurality of papers to be transported. The document processing apparatus according to claim 1. An upper roller and a lower roller for holding the conveyed document;
Drive means for rotationally driving one of the upper roller and the lower roller in the document conveying direction;
2. The apparatus according to claim 1, further comprising means for detecting the presence or absence of double conveyance of a document passing between the upper roller and the lower roller based on a difference in rotational speed between the upper roller and the lower roller. Document processing equipment. The paper feeding means is
First transport means for transporting documents toward the downstream direction of the transport path;
First driving means for rotationally driving the first conveying means;
A second conveying means arranged in parallel with the first conveying means and conveying a document in a downstream direction of the conveying path;
Second driving means for rotationally driving the second transport means;
Detecting means for detecting the inclination of the document before reaching the conveyance path;
Control means for individually controlling the rotational speeds of the first drive means and the second drive means according to the direction of the inclination,
The control means makes the rotation speed of the first drive means faster than the rotation speed of the second drive means, or sets the rotation speed of the second drive means to the rotation speed according to the direction of document inclination. 2. The document processing apparatus according to claim 1, wherein the document conveying speed is adjusted by adjusting the rotation speed of the first drive means to correct the inclination of the document. A document processing method for conveying a document from an upstream side to a downstream side of a conveyance path,
A document is supplied to the transport path at a first paper feed speed, the document is transported at a predetermined transport speed according to the transport path, and the transport path is transported by detection means arranged at a predetermined position of the transport path. When the trailing edge of the document is detected, the feeding speed for the subsequent document is reduced from the first feeding speed to the second feeding speed for a predetermined time, and after the predetermined time has elapsed, By performing the process of accelerating the second paper feeding speed after the deceleration to the first paper feeding speed continuously for each document, a plurality of documents continuously conveyed on the conveyance path A document processing method characterized in that a predetermined interval is provided in accordance with deceleration and reacceleration of the paper feed speed.

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