JP2008228210A - Image reader and image scanner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To attain high speed reading, while maintaining the reading image quality in a large capacity image scanner. <P>SOLUTION: Documents on a document tray are transferred sheet by sheet (S101) and when the height of upper surface (upper surface height) lowers to turn a height sensor off, different control is performed depending on the reading speed (S103). At the time of low speed reading, the document tray is further raised at once to a height higher by a predetermined distance after the height sensor is turned on at an inter-transferring timing after completing transferring of a document before starting transferring of a next document (S104-S107). At the time of high speed reading, the document tray is raised gradually at the inter-transferring timing every time when a sheet of document is transferred until the height sensor is turned on (S108-110). After the height sensor is turned on, the document tray is raised gradually, each time when a sheet of document is transferred until the upper surface height rises by a predetermined target distance, while taking account of decrement in upper surface height due to transferring of document. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a configuration of an image reading apparatus suitable for setting and reading a large amount of originals at a time.

Japanese Patent Application Laid-Open No. 2004-228561 discloses a copying machine that can set a plurality of documents on a document tray (document feeding tray) and includes an upper limit position detection sensor that detects a top document. In the copying machine disclosed in Patent Document 1, when the number of originals decreases as the originals on the original tray are fed, the control device controls the tray driving mechanism according to the detection result of the upper limit position detection sensor. The upper document is always positioned at the same position with respect to the pickup roller. As a result, the document located at the top is always positioned at a document feedable position.
JP 2006-16093 A

  In an image reading apparatus for a large capacity such as that disclosed in Patent Document 1, with a growing need for copying a large amount of documents in a short time, there is a strong demand for high-speed reading while maintaining read image quality.

  In this regard, Patent Document 1 does not mention the timing of raising and lowering the document tray by controlling the tray driving mechanism. Therefore, in Patent Document 1, if the document tray is raised during document reading, the document being conveyed may move as the document tray is raised, and the read image quality may deteriorate.

  The present invention has been made in the above circumstances, and an object of the present invention is to prevent document image quality from being lowered and to realize document tray lifting control suitable for high-speed reading.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above. Next, means for solving the problems and the effects thereof will be described.

  According to an aspect of the present invention, an image reading apparatus having the following configuration is provided. That is, a document tray on which a plurality of documents can be stacked and set, an image reading unit that reads the document, a feeding unit that feeds documents on the document tray one by one toward the image reading unit, and the document A lifting device that lifts and lowers the tray; a height detection sensor that detects a height of an upper surface of the document stacked on the document tray; and a control unit that controls the lifting device. When the height detection sensor detects that the upper surface height has fallen below a predetermined height due to the feeding of the document in the feeding unit, the control unit reads the document when the document reading speed is low. From the height at which the height detection sensor detects that the height of the upper surface has become equal to or higher than a predetermined height at the inter-feed timing after the completion of the transfer of the document and before starting the transfer of the next document. The document tray is raised to a height that is higher by a predetermined distance. When the document reading speed is high, each time a document is fed, the timing between feedings until the height detection sensor detects that the upper surface height is equal to or higher than a predetermined height. Raise the document tray by a predetermined pitch. When the height detection sensor detects that the upper surface height is equal to or higher than a predetermined height, the transfer is performed each time a document is fed until the upper surface height is further increased by a predetermined target lift distance. The document tray is raised by a predetermined pitch at a certain timing. In determining whether the upper surface height has increased by the target increase distance, the determination is made taking into account the decrease in the upper surface height due to the feeding of the document.

  As a result, when the document reading speed is low or when the document reading speed is high, the document tray is raised between the feeding of one document. Therefore, it is ensured that the document tray is stationary at the time of image reading by the image reading unit, and deterioration of the read image quality due to document conveyance blur is prevented. Further, when the document reading speed is high, the document tray is not raised at a time but is raised by a relatively short predetermined pitch (in small increments), so that the document feeding is not interrupted and is short. The document tray can be raised without difficulty using the inter-feed timing. Further, in determining whether the upper surface height has increased by the target ascent distance, a reduction in the upper surface height due to the feeding of the document is taken into account, so the document tray is raised in small increments each time the document is fed. However, the uppermost layer of the document can be substantially raised to an appropriate height.

  The image reading apparatus preferably has the following configuration. That is, when the reading speed of the document is high and the height detection sensor detects that the upper surface height is equal to or higher than a predetermined height, the control unit sets a predetermined additional rising distance. At the same time, each time a document is fed, the document tray is raised by a predetermined pitch at every feeding time until the document tray is raised by the additional raising distance. Each time a document is fed, a predetermined distance is added to the additional ascent distance to reset it.

  As a result, every time a document is fed, the additional rising distance of the document tray is added so as to compensate for the decrease in the height of the top surface of the document. Accordingly, the uppermost layer of the document can be substantially raised to an appropriate height while taking into account the reduction in the height of the upper surface due to the feeding of the document with simple control.

  In the image reading apparatus, it is preferable that the predetermined pitch is determined so as to become shorter as the reading speed of the original increases.

  As a result, even if the document reading speed is increased and the inter-feed timing is shortened, the predetermined pitch is also shortened accordingly, so that the document tray can be raised in small increments between the feeds. Can do.

  In the image reading apparatus, it is preferable that a driving source of the elevating device is the same as a driving source of an original conveying apparatus for conveying the original to the image reading unit.

  Thereby, the configuration can be simplified, and the cost reduction, weight reduction, and compactness of the image scanner device can be realized. In addition, since the document tray is raised at the timing between feeding, by switching the power transmission destination of one drive source between when the document is fed and when the document tray is raised, the conveyance of the document and the document tray It is possible to properly balance the rise of

  According to another aspect of the present invention, an image scanner device as the image reading device is provided.

  Next, embodiments of the invention will be described. FIG. 1 is a side sectional view showing the overall configuration of an image scanner device according to an embodiment of the present invention, and FIG. 2 is a block diagram showing a part of the electrical configuration of the image scanner device. FIG. 3 is an enlarged side cross-sectional view showing a state in which the feeding unit is driven and one uppermost document is fed into the document conveyance path. FIG. 4 is an enlarged side cross-sectional view showing a state in which the pickup roller is lifted and retracted immediately before completion of feeding the uppermost document. FIG. 5 is an enlarged side cross-sectional view showing a state where the feeding is completed and the pickup roller is lowered again. FIG. 6 is an enlarged side cross-sectional view showing how the document tray is raised. FIG. 7 is a flowchart showing the document tray lifting control.

  As shown in FIG. 1, an image scanner device 10 as an image reading device of the present embodiment includes a large-capacity document tray 11 for setting a document 14 at the lower part of the main body, and discharges the document 14 after reading. A tray 20 is provided at the top of the main body.

  The image scanner device 10 also supplies a document supply port 41 for supplying the document 14 on the document tray 11 to the inside of the main body, and discharges the document 14 after the image is read inside the main body to the discharge tray 20. Document discharge port 42.

  A curved document conveyance path 21 that connects the document supply port 41 and the document discharge port 42 is formed inside the main body of the image scanner apparatus 10, and a plurality of conveyance rollers 25, 26, 27 are formed along the document conveyance path 21. , 28, 29 are installed. In addition, two image sensors 51 and 52 are arranged in the middle of the document conveyance path 21 so as to correspond to the front and back sides of the document, and the front and back surfaces of the document 14 passing through the document conveyance path 21 are read by the image sensors 51 and 52. It is configured as follows. An operation panel 50 is provided at the upper part of the main body of the image scanner device 10 to control the document reading mode (high resolution mode / low resolution mode), the document reading speed, start / stop of image reading, and the like. It can be instructed.

  The image scanner device 10 includes an image reading unit 46 that reads the document 14 and a document transport device 47 that transports the document 14. The document conveying device 47 includes conveying rollers 25, 26, 27, 28, and 29 and an electric motor (drive source) (not shown) for driving them. The document transport device 47 transports the document 14 on the document tray 11 from the document supply port 41 to the image reading unit 46, and the document 14 after passing through the image reading unit 46 from the document discharge port 42 to the discharge tray 20. It is configured to discharge toward

  The image scanner device 10 includes the document tray 11 and a feeding unit 48 that feeds the document 14 and separates it one by one and transports it from the document supply port 41. The feeding unit 48 contacts the upper surface of the uppermost layer of the document 14 stacked on the document tray 11 and feeds it to the document supply port 41, and is disposed downstream of the pickup roller 22 in the document transport direction. And a retard roller 24 disposed to face the separation roller 23.

  A guide rail (not shown) is installed in a vertical direction at an appropriate position of the image scanner device 10, and an elevating frame 35 is provided along the guide rail so as to be movable up and down. The document tray 11 is attached to the lift frame 35. Accordingly, the document tray 11 can move in the vertical direction together with the lifting frame 35.

  The lower limit position (position shown in FIG. 1) of the lifting stroke of the document tray 11 is a document setting position for setting the document on the document tray 11. On the other hand, the position above the original setting position where the uppermost layer of the original 14 can come into contact with the pickup roller 22 (the position shown in FIG. 3) is separated by the feeding section 48 one by one. The separation position can be supplied toward the document conveyance path 21.

  As shown in FIG. 1 and the like, the document conveying device 47 includes a lifting device 49 that can lift and lower the document tray 11. The elevating device 49 includes a tray elevating motor (driving means) 15 that is an electric motor, a pinion (gear) 13 that is driven by the tray elevating motor 15, and a rack 12 that meshes with the pinion 13. The tray lifting / lowering motor 15 is configured as a stepping motor.

  The rack 12 is fixed to the lifting frame 35 and is configured to move in the vertical direction together with the lifting frame 35 and the document tray 11.

  The pickup roller 22 is provided at a position facing the document tray 11 above and is supported so as to be movable up and down. The pickup roller 22 is biased downward by a spring (not shown) so that the pickup roller 22 can be pressed against the upper surface of the document 14.

  Further, the feeding portion 48 is provided with a height detection sensor 31 for detecting the height of the pickup roller 22. With this configuration, the height of the pickup roller 22 is detected by the height detection sensor 31 in a state in which the pickup roller 22 is in contact with the uppermost layer of the stacked documents 14, thereby increasing the height of the upper surface of the stacked documents 14. The height (upper surface height) can be detected.

  The height detection sensor 31 is composed of, for example, a photo sensor, and is turned on when the height of the pickup roller 22 (the height of the upper surface of the document 14) is equal to or higher than a predetermined height, and is turned off when the height is lower than the predetermined height. ing. This predetermined height is set to a height when the pickup roller 22 is lifted by a small amount by the upper surface of the document 14. As shown in FIG. 2, the height detection sensor 31 is electrically connected to a control unit 60 described later, and can transmit an ON / OFF state signal to the control unit 60.

  Further, as shown in FIG. 1, a retraction solenoid 33 is connected to the pickup roller 22 so that the pickup roller 22 can be lifted and retreated at an appropriate timing to forcibly separate the pickup roller 22 from the upper surface of the document. It is configured. As shown in FIG. 2, the retracting solenoid 33 is connected to the control unit 60.

  Further, the pickup roller 22, the separation roller 23, and the retard roller 24 are connected to an electric motor as a drive source of the document conveying device 47 via an electromagnetic clutch 34. The electromagnetic clutch 34 is electrically connected to the control unit 60.

  As shown in FIG. 1, a document passage detection sensor 32 composed of, for example, a photosensor is installed at a position downstream of the separation roller 23 in the document conveyance direction. This document passage detection sensor 32 is configured to detect the document immediately after passing through the nip position between the separation roller 23 and the retard roller 24 and to turn it on otherwise. As shown in FIG. 2, the document passage detection sensor 32 is electrically connected to the control unit 60.

  The image scanner device 10 includes a microcomputer-type control unit 60, and the control unit 60 is electrically connected to the tray lifting / lowering motor 15 and the operation panel 50 as shown in FIG. 2.

  With this configuration, when the operator places the document tray 11 on the document setting position, the operator sets the document 14 as shown in FIG. 1 and instructs the operation panel 50 (or a higher-order personal computer) to start reading. A reading start signal is transmitted to the control unit 60.

  Upon receiving this signal, the control unit 60 turns off the retracting solenoid 33 to lower the pickup roller 22 and then starts to drive the tray lifting / lowering motor 15. As a result, the tray lifting / lowering motor 15 is driven to rotate the pinion 13, and a lifting force acts on the rack 12 that meshes with the pinion 13. As a result, the document tray 11 rises along the guide rail from the document setting position.

  The control unit 60 monitors the state of the height detection sensor 31 while the tray lifting / lowering motor 15 is being driven. Then, the controller 60 causes the tray lifting / lowering motor 15 to move until the upper surface of the document 14 rising together with the document tray 11 comes into contact with the pickup roller 22 and the pickup roller 22 to be lifted reaches a predetermined height and the height detection sensor 31 is turned on. A driving pulse is transmitted to raise the document tray 11. Even after the height detection sensor 31 is turned on, the control unit 60 drives the tray lifting / lowering motor 15 until the document tray 11 further rises by a predetermined height. The raising control of the predetermined height is realized by the control unit 60 transmitting a predetermined number of driving pulses to the tray lifting / lowering motor 15 as a stepping motor.

  After raising the document tray 11 to the separation position shown in FIG. 3, the tray lifting / lowering motor 15 is stopped and the driving of the feeding unit 48 is started immediately. Specifically, the control unit 60 connects the electromagnetic clutch 34 (FIG. 2) to start driving the pickup roller 22, the separation roller 23, and the retard roller 24. As shown in FIG. The original 14 is fed and supplied to the original transport path 21 through the original supply port 41 while being separated one by one by the separation roller 23 and the retard roller 24.

  At the time of document supply, the control unit 60 monitors the state of the document passage detection sensor 32. Then, when the document passage detection sensor 32 detects the uppermost document 14 sent downstream by the separation roller 23 and the retard roller 24, the control unit 60 turns on the retract solenoid 33 and picks up as shown in FIG. The roller 22 is retracted upward. As a result, it is possible to prevent the next original 14 from being irregularly transferred continuously to the previous original 14.

  The document 14 is transported on the document transport path 21 by transport rollers 25 to 29 (FIG. 1), and the front and back surfaces of the document are scanned by the image sensors 51 and 52. Data obtained by this scanning is subjected to appropriate conversion processing, and transmitted to a personal computer or the like as a host device connected to the image scanner device 10 via a communication cable (not shown). The scanned document 14 is sent out to the discharge tray 20 along the document transport path 21.

  The controller 60 measures the elapsed time using a timer circuit (not shown) from when the document passage detection sensor 32 detects the document 14 and is turned on. When a predetermined time elapses, the document 14 passes through the nip portion between the separation roller 23 and the retard roller 24, and the document 14 can be regarded as being held by the downstream conveying roller 25 or the like. The controller 60 releases the connection of the electromagnetic clutch 34 and stops driving the pickup roller 22, the separation roller 23, and the retard roller 24 as shown in FIG. Immediately thereafter, the retracting solenoid 33 is turned off, and the pickup roller 22 is lowered and brought into contact with the uppermost layer of the document 14 again.

  Thereafter, the control unit 60 monitors the state of the document passage detection sensor 32. Then, when a predetermined time has elapsed from the time when the fed document 14 passes through the document passage detection sensor 32 and the document passage detection sensor 32 is turned off, the control unit 60 turns the electromagnetic clutch 34 again as shown in FIG. Then, the next document 14 is fed by the pickup roller 22. By repeating the above operation (FIGS. 3 to 5), the document 14 is supplied to the document conveyance path 21 one by one until the document 14 disappears while ensuring a certain distance between the document 14 and the document 14 that follows. Then, it can be read by the image reading unit 46.

  Note that when the document 14 on the document tray 11 is successively fed out by the feeding unit 48 as described above, the remaining amount of the document 14 gradually decreases, and accordingly, the height of the upper surface of the document 14 decreases. Will go. In this regard, in the present embodiment, by performing tray raising control as described below, the state in which the document 14 can be fed by the pickup roller 22 is maintained regardless of the remaining amount of the document 14, and a large amount The document 14 can be conveyed one after another until the set document 14 disappears.

  Next, the raising control of the document tray 11 will be described in detail with reference to FIG. As shown in the flowchart of FIG. 7, when reading of a document is started, the document tray 11 is raised to the separation position as described above, and one document 14 is fed (S101). This transfer operation is as described with reference to FIGS. Each time one sheet is fed, the timing of completing the feeding of the original and before starting the feeding of the next original (hereinafter referred to as “inter-feeding timing”) is high in the state of FIG. The state of the height detection sensor 31 is checked (S102 in FIG. 7). If the height detection sensor 31 is ON, the height of the upper surface of the document 14 is not so low, so the process returns to S101 and repeats the feeding of the document 14 one by one.

  If the height detection sensor 31 is OFF, the reading speed instructed to the image scanner device 10 is checked in S103. This reading speed is determined corresponding to the reading mode instructed on the operation panel 50 or the like, and is determined to be low in the high resolution mode and high in the low resolution mode.

  When the mode is the high resolution mode (when the reading speed is low), the tray lifting / lowering motor 15 is immediately driven from the state of FIG. 5 to start raising the document tray 11 (S104 in FIG. 7). Then, the document tray 11 is raised until the height detection sensor 31 in the OFF state is turned on (S105), and even after the height detection sensor 31 is turned on, as shown in FIG. The document tray 11 is raised until it becomes higher by (a predetermined number of pulses) (S106 in FIG. 7). When the document tray 11 reaches the above height, the tray lifting / lowering motor 15 is stopped to stop the document tray 11 (S107), and the process returns to S101 to start feeding the next document 14.

  That is, in the high-resolution mode with a low reading speed, a certain amount of time can be secured after feeding of the document 14 is finished and before feeding the subsequent document 14. As a result, the control unit 60 performs control to raise the document tray 11 to a required height all at once in one inter-feed timing in the control of S104 to S107.

  On the other hand, in the case of the low resolution mode (when the reading speed is high) as determined in S103, the tray lifting / lowering motor 15 is driven immediately from the state shown in FIG. Regardless, the distance is equal to the predetermined number of pulses of the tray lifting / lowering motor 15 (S108). Hereinafter, this ascent distance is referred to as “rising pitch”.

  This rising pitch is determined to be smaller than the distance raised at a time by the control described in S104 to S107, but larger than the thickness of one document 14. Further, the rising pitch is set to be short when high-speed reading is instructed in the low-resolution mode, and relatively long otherwise.

  After the document tray 11 is raised by the rising pitch in step S108 and stopped, one document is fed by the feeding unit 48 in step S109. Note that since the ascending amount of the document tray 11 in S108 is only the ascending pitch, the document can be fed even at a short inter-feed timing from when the document 14 is fed in until high-speed reading until the subsequent document 14 is fed. The tray 11 can be reliably raised and stopped. Accordingly, the succeeding document 14 can be fed while the document tray 11 is completely stopped (S109), so that it is possible to avoid conveyance blur during scanning of the document 14 and to prevent deterioration of the read image quality.

  After feeding one document 14 in S109, the state of the height detection sensor 31 is checked (S110). When the height detection sensor 31 is OFF, the process returns to S108, and the raising of the document tray 11 by the rising pitch and the feeding of the document are repeated (S108, S109).

  As described above, when the original 14 is transferred once (S108 to S110), the stacking height of the original 14 is reduced by the thickness of one original, but the original tray 11 is increased by the above-mentioned rising pitch. To rise. Therefore, when the feeding of the document 14 is repeated, the upper surface height of the document 14 gradually increases eventually. Then, when the pickup roller 22 rises and the height detection sensor 31 is turned on in accordance with the above, the process goes through the loop of S108 to S110 and shifts to the processing after S111.

  In S111, a distance (additional lift distance) at which the document tray 11 should be additionally lifted from the time when the height detection sensor 31 is turned on is first set, and this additional lift distance is stored in a memory (storage means). deep. Note that the initial set value of the additional rising distance is equal to the distance (target rising distance) at which the upper surface height of the document 14 should be raised. Further, this additional ascent distance is set equal to the predetermined distance for raising the document tray 11 by the control of S106 at the time of low speed reading.

  Next, the tray lifting / lowering motor 15 is driven to raise the document tray 11 by the rising pitch and stop (S112). As in S108, the document tray 11 is raised and stopped at a short inter-feeding timing from when the original 14 is transferred to when the subsequent original 14 is further transferred during high-speed reading. Further, this rising pitch is the same distance as described in S108 above.

  Then, the total distance by which the document tray 11 is raised from the time of S111 is calculated, and it is checked whether or not the obtained total distance has reached the additional rising distance (S113). If the additional ascent distance has not been reached, the subsequent document 14 is fed one sheet (S114). Then, a distance corresponding to the thickness of one sheet of the document 14 is added to the additional rising distance and stored again in the memory (S115), and the process returns to S112.

  By the loop of S112 to S115, the document tray 11 is raised by the rising pitch every time the document 14 is fed, and the additional rising distance is added by the thickness of one document. This is equivalent to recalculating the additional rising distance of the document tray 11 in consideration of the decrease in the upper surface height due to the feeding of the document 14. In this way, it is determined whether the total ascent distance of the document tray 11 has reached the additional ascent distance while recalculating the additional ascent distance each time the document is fed and the document tray is elevated (S113). If it is determined in S113 that the total ascent distance has reached the additional ascent distance, the top surface height of the document 14 can be substantially increased by the target ascent distance. Returning to the process, the original 14 is fed again with the original tray 11 stopped.

  As described above, the image scanner device 10 according to the present embodiment includes a document tray 11 on which a plurality of documents 14 can be set in an overlapping manner, an image reading unit 46 that reads the documents 14, and a document 14 on the document tray 11. Are fed one by one toward the image reading unit 46, a lifting device 49 for raising and lowering the document tray 11, and the height of the upper surface of the document 14 stacked on the document tray 11. The height detection sensor 31 and the control part 60 which controls the said raising / lowering apparatus 49 are provided.

  When the height of the upper surface of the document 14 is lowered by the feeding of the document 14 by the feeding unit 48 and the height detection sensor 31 is turned off, the control unit 60 reads the document 14 at a reading speed ( Different processing is performed depending on whether the transfer speed of the transfer section 48 is low or high (S103). Specifically, at the time of reading the document 14 at a low speed (high resolution mode), the height detection sensor at the inter-feeding timing after completing the feeding of the document 14 and before starting the feeding of the next document 14. The document tray 11 is raised at a time from a height at which 31 is turned ON to a height higher by a predetermined distance (S104 to S107). On the other hand, at the time of high-speed reading of the document 14 (low resolution mode), every time the document 14 is fed one sheet until the height detection sensor 31 is turned on, the document tray 11 is moved to a predetermined timing at the timing between feeding. The pitch is raised by the rising pitch (S108 to S110). When the height detection sensor 31 is turned on, the document tray is fed at the timing between feeding each time the document 14 is fed until the upper surface height is further raised by a predetermined distance (target rising distance). 11 is raised by the rising pitch (S112). In determining whether or not the document tray 11 should be lifted by the rising pitch (S113), it is not simply determined whether or not the document tray 11 has been raised by the target lift distance. In consideration of the decrease in the upper surface height due to the insertion (S115), it is determined whether or not the upper surface height has substantially increased by the target increase distance.

  As a result, when the document reading speed is low or when the document reading speed is high, the document tray 11 is raised between the feeding of the documents 14 one by one. Therefore, it is ensured that the document tray 11 is stationary at the time of image reading by the image reading unit 46, and the reading image quality is prevented from being deteriorated due to the conveyance blur of the document 14. Further, when the document reading speed is high, the document tray 11 is not raised at a time but is raised by a relatively short predetermined ascending pitch (in small increments), so that the document feeding is interrupted. The document tray 11 can be raised without difficulty using a short inter-feed timing. In determining whether or not the upper surface height of the document 14 has increased by the target ascent distance, a reduction in the upper surface height due to the document transfer is taken into account, so that the document tray 11 is loaded every time the document 14 is transferred. Even if it is raised in small increments, the uppermost layer of the document 14 can be substantially raised to an appropriate height, and the document 14 can be smoothly fed by the pickup roller 22.

  In the present embodiment, in the processing after S111 in FIG. 7, a predetermined additional rising distance is set (S111), and each time the original 14 is fed until the original tray 11 is raised by the additional rising distance. Then, the document tray 11 is raised by a predetermined rising pitch at the timing between feeding (S112, S113). Each time a document is fed, a predetermined distance is added to the additional rising distance and the setting is reset (S114, S115).

  As a result, every time the document 14 is fed, the additional rising distance of the document tray 11 is added so as to compensate for the decrease in the upper surface height of the document 14. As a result, the uppermost layer of the document 14 can be substantially raised to an appropriate height while taking into account the reduction in the height of the upper surface due to the feeding of the document with simple control.

  Further, in the processes of S108 and S112, the rising pitch of the document tray 11 is determined so as to decrease as the reading speed of the document 14 increases.

  As a result, even if the reading speed of the document 14 is increased and the inter-feed timing is shortened, the rising pitch is also shortened accordingly, so that the document tray 11 can be lifted in small increments.

  In this embodiment, the tray lifting / lowering motor 15 that is a driving source of the lifting / lowering device 49 is provided separately from the driving source of the document conveying device 47. However, the tray lifting / lowering motor may be configured in common with the electric motor of the driving source of the document conveying device 47. As this configuration, for example, it is conceivable that the electric motor of the document conveying device 47 and the pinion 13 are connected by a known clutch means (for example, an electromagnetic clutch).

  In this case, the configuration can be simplified, and the cost reduction, weight reduction, and compactness of the image scanner device can be realized. Since the document tray 11 is raised at the timing between feeding, the power transmission destination of one electric motor is switched between when the document 14 is fed and when the document tray 11 is raised. The conveyance and the raising of the document tray 11 can be appropriately made compatible.

  Although the preferred embodiment of the present invention and the modification thereof have been described above, the above-described configuration can be changed as follows, for example.

  In the above embodiment, in the process of S115 in the flowchart (FIG. 7), the distance corresponding to the thickness of one document is added to the additional rising distance and reset, but instead, one document is processed. Each time the sheet is retracted, a distance corresponding to the thickness of one document may be subtracted from the total ascent distance of the document tray 11.

  The height detection sensor 31 is not limited to a sensor that is turned on when the pickup roller 22 is equal to or higher than a predetermined height, but can be changed to a configuration that is turned off when the height is higher than a predetermined height.

  The height detection sensor 31 is configured to directly detect the top surface height of the document 14 instead of indirectly detecting the top surface height of the document 14 by detecting the height of the pickup roller 22. Can be changed.

  The tray lifting / lowering motor 15 is not limited to a stepping motor, and can be configured as a servo motor, for example.

  The configuration for raising the document tray is not limited to the image scanner device in which the document conveyance path 21 is formed in a curved shape (C-shape) as shown in FIG. 1. For example, the document tray has a horizontal document conveyance path. The present invention can be applied to an image scanner apparatus that supplies a document from one side and discharges it to the opposite side. The present invention is not limited to an image scanner device, and can be applied to, for example, an auto document feeder type copying machine having a large capacity document tray.

1 is a side sectional view showing an overall configuration of an image scanner device according to an embodiment of the present invention. FIG. 3 is a block diagram showing a part of the electrical configuration of the image scanner device. FIG. 3 is an enlarged side cross-sectional view illustrating a state where a feeding unit is driven and one uppermost document is fed into a document conveyance path. FIG. 4 is an enlarged side cross-sectional view showing a state where the pickup roller is lifted and retracted immediately before completion of feeding the uppermost document. FIG. 4 is an enlarged side cross-sectional view illustrating a state where the feeding is completed and the pickup roller is lowered again. FIG. 6 is an enlarged side cross-sectional view showing a state where the document tray is raised. The flowchart figure which shows the raising control of a document tray.

Explanation of symbols

11 Document tray 14 Document 15 Tray lift motor (driving device drive source)
Reference Signs List 31 Height detection sensor 46 Image reading unit 47 Document conveying device 48 Feeding unit 49 Lifting device 60 Control unit

Claims (5)

A document tray that can stack multiple documents,
An image reading unit for reading the document;
A feeding unit that feeds documents on the document tray one by one toward the image reading unit;
A lifting device that lifts and lowers the document tray;
A height detection sensor for detecting the height of the upper surface of the document stacked on the document tray;
A control unit for controlling the lifting device;
With
When the height detection sensor detects that the upper surface height has fallen below a predetermined height due to the feeding of the document in the feeding unit, the control unit
When the document reading speed is low, it is determined that the upper surface height has become equal to or higher than the predetermined height at the inter-feed timing after the completion of the document transfer and before the start of the next document transfer. Raise the document tray from the height detected by the height detection sensor to a height higher by a predetermined distance,
If the document scanning speed is high,
Every time one document is fed, the document tray is raised by a predetermined pitch at the timing between feeding until the height detection sensor detects that the upper surface height is equal to or higher than a predetermined height.
When the height detection sensor detects that the upper surface height is equal to or higher than a predetermined height, the transfer is performed each time a document is fed until the upper surface height is further increased by a predetermined target lift distance. The document tray is raised by a predetermined pitch at a certain timing,
The image reading apparatus according to claim 1, wherein the determination as to whether or not the upper surface height has increased by the target increase distance takes into account a decrease in the upper surface height due to feeding of the document. The image reading apparatus according to claim 1,
When the document reading speed is high and the height detection sensor detects that the upper surface height is equal to or higher than a predetermined height, the control unit sets a predetermined additional ascent distance. The document tray is raised by a predetermined pitch at the timing between feeding each time a document is fed until the document tray is lifted by the additional raising distance,
An image reading apparatus according to claim 1, wherein each time a document is fed, a predetermined distance is added to the additional rising distance and the setting is reset. The image reading apparatus according to claim 1, wherein
2. The image reading apparatus according to claim 1, wherein the predetermined pitch is determined so as to decrease as the reading speed of the document increases. The image reading apparatus according to any one of claims 1 to 3,
The image reading apparatus according to claim 1, wherein a driving source of the elevating device is common to a driving source of a document conveying device for conveying the document to the image reading unit.   An image scanner device as an image reading device according to any one of claims 1 to 4.

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