JP2010081475A - Image reader and image-forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make uniform the image quality of the data of an image formed on the front surface of a document and the quality of image data of an image formed on the rear surface of the document, and to accelerate document reading speed, in an image reader. <P>SOLUTION: An image reader comprises: a first feed means 23 for feeding a document placed in a placing tray 20, while turning a feeding path H toward an eject tray 21, in such a way that a front side of the document is opposed to a reading area R; a first feed and housing means 24 for feeding and housing the document passed through the read area R by the first feed means 23, while turning the feed path H toward the eject tray 21, without flipping the document; a second feed and housing means 25 for feeding and housing the document housed in the first feed and housing means 24, while flipping the document and turning the feed path H toward the ejection tray 21; a second feed means 26 for feeding the document housed in the second feed and housing means 25, while turning the feed path H toward the ejection tray 21, in such a way that a rear side of the document is opposed to the reading area R; and a third feed means 27 for ejecting the document that has passed through the reading area R by the second feeding means 26 into the ejection tray 21. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image reading apparatus and an image forming apparatus.

An image forming apparatus such as a multifunction peripheral includes an image reading apparatus for reading an image formed on a document as image data.
In such an image reading apparatus, in order to enable reading of images formed on both sides of a document, a configuration including two sensors and a configuration for switching back a document are provided as disclosed in Patent Document 1. Yes.

  In the case of adopting a configuration including two sensors, the sensor includes two sensors, a sensor facing the front surface of the transported document and a sensor facing the back surface of the transported document. By acquiring image data, images formed on both sides of the original are read.

On the other hand, when adopting a configuration in which a document is switched back, an image formed on the front surface of the document and an image formed on the back surface of the document are sequentially read by one sensor.
Specifically, the document is first transported so that the surface of the document faces the sensor, the image formed on the surface is read, and then the document is switched back to reverse the front and back so as to face the sensor again. Transport to. Thus, when the original again faces the sensor, the image formed on the back side of the original is read because the back side of the original faces the sensor.
JP 2005-142669 A

In recent years, in image forming apparatuses, both higher image quality and faster image formation have been demanded.
However, when the configuration including the above-described two sensors is adopted, the quality of the image data of the image formed on the front surface of the document and the image data of the image formed on the back surface of the document are determined based on individual differences between the sensors. There is a difference in quality, and image quality deterioration such as a difference in color occurs when the image formed on the front side of the document is copied and when the image formed on the back side of the document is copied.
Also, when switching back an original, the original is transported along the same transport path when reading the image formed on the front side and when reading the image formed on the back side. The next original cannot be taken into the image reading apparatus until both the front side image and the back side image of the original are read. For this reason, it is difficult to increase the speed of image formation when images of a plurality of documents are continuously read.

  The present invention has been made in view of the above-described problems. In the image reading apparatus, the quality of image data of an image formed on the front surface of a document and the quality of image data of an image formed on the back surface of the document are uniform. It is an object of the present invention to improve the image quality in the image forming apparatus by increasing the speed of image formation in the image forming apparatus by improving the reading speed of a document in the image reading apparatus.

  The present invention adopts the following configuration as means for solving the above-described problems.

  According to a first aspect of the present invention, there is provided an image reading method for reading an image formed on the original as image data while conveying a conveyance path formed by drawing an original placed on the placement tray from the placement tray to the discharge tray. An image reading sensor that reads the image facing the reading area arranged in the middle of the transport path as the image data, and the document placed on the placing tray is opposed to the reading area. First conveying means for conveying the conveying path toward the discharge tray, and the conveying path toward the discharge tray without turning over the original that has passed through the reading area by the first conveying means. A first conveying and storing unit configured to convey and store, and a second conveying unit configured to convey and store the conveying path toward the discharge tray while turning over the document stored in the first conveying and storing unit. A storage unit; a second transport unit configured to transport the document stored in the second transport storage unit toward the discharge tray so that the back surface faces the reading region; and the second transport unit. And controlling the third conveying means for discharging the document that has passed through the reading area to the discharge tray, the first to third conveying means, the first conveying and accommodating means, and the second conveying and accommodating means. A configuration including a control means is employed.

  According to a second aspect of the present invention, in the first aspect, when the images formed on both sides of the original document stacked on the placing tray are continuously read, the control unit includes the second conveying and storing unit. When the document is not stored, the first transport unit, the first transport storing unit, and the second transport storing unit are configured to transport the document by the first transport unit, the first transport storing unit, and the second transport storing unit. 2 transporting and storing means is driven, and when the original is stored in the first transporting and storing means and the second transporting and storing means, the driving of the first transporting means is stopped and the 2 transporting and storing means and the above The second conveying and storing means and the second conveying means are driven so that the original is conveyed by the second conveying means, the original is not accommodated in the first conveying and accommodating means, and the second conveying is performed. The above-mentioned original Is stopped, the second conveying and storing means and the second conveying means are stopped, and the original is conveyed by the first conveying means and the first conveying and storing means. A configuration is adopted in which one transport means and the first transport housing means are driven.

  According to a third aspect, in the first aspect, the supply destination of the document that has passed through the reading area by the first transport unit can be switched between the first transport storage unit and the third transport unit. A configuration that includes a simple switching unit is employed.

  According to a fourth invention, in any one of the first to third inventions, the image reading sensor is a CCD sensor.

  According to a fifth aspect of the present invention, there is provided an image forming apparatus for acquiring image data by an image reading apparatus and forming an image on a recording medium based on the image data. A configuration in which such an invention is used is adopted.

According to the present invention, the document placed on the placement tray is transported by the first transport unit so that the image formed on the surface of the document is read, and transported by the first transport storage unit and the second transport storage unit. Turned over in the process. Further, the document that has been turned over is conveyed by the second conveying unit so that the image formed on the back side of the document can be read.
According to the present invention, the image formed on the front surface of the document and the image formed on the back surface of the document are read by the same image reading sensor. Therefore, it is possible to make the quality of the image data of the image formed on the front side of the original and the quality of the image data of the image formed on the back side of the original uniform, and further improve the image quality in the image formation. Is possible.

  According to the present invention, the document is always transported toward the discharge tray through the transport path formed by being routed from the placement tray to the discharge tray without being switched back. Further, the original can be accommodated in the first conveyance accommodating means and the second conveyance accommodating means. For this reason, the image formed on the surface of the subsequent original can be read by the image reading sensor while the previous original is turned over in the process of being conveyed by the first and second conveying and accommodating means. It becomes. Therefore, it is possible to improve the document reading speed in the image reading apparatus, and it is possible to increase the speed of image formation.

  Therefore, according to the present invention, in the image forming apparatus, the quality of the image data of the image formed on the front surface of the document and the quality of the image data of the image formed on the back surface of the document are made uniform in the image reading apparatus. In addition to improving the image quality, it is possible to increase the speed of image formation in the image forming apparatus by increasing the document reading speed in the image reading apparatus.

  Hereinafter, an embodiment of an image forming apparatus according to the present invention will be described with reference to the drawings. In the following description, a multifunction peripheral will be described as an image forming apparatus including an image reading apparatus.

  FIG. 1 is a block diagram illustrating a functional configuration of the multifunction peripheral A according to the present embodiment. As shown in this figure, the multi-function device A of this embodiment includes a CPU (Central Processing Unit) 1, a ROM (Read Only Memory) 2, a RAM (Random Access Memory) 3, various sensor groups 4, and a printing paper transport unit 5. An image data storage unit 6, an image forming unit 7, a communication I / F unit 8, an operation display unit 9, and an image reading device 10.

  The CPU 1 is a control program stored in the ROM 2, detection signals input from the various sensor groups 4, image data stored in the image data storage unit 6, a personal computer or the like via the communication I / F unit 8. The overall operation of the multifunction peripheral A is controlled based on a print instruction signal received from an external device, image data for printing, an operation signal input from the operation display unit 9, and the like.

The ROM 2 is a non-volatile memory that stores a control program executed by the CPU 1 and other data.
The RAM 3 is a working memory used as a temporary storage destination of data when the CPU 1 executes a control program and performs various operations.
The various sensor groups 4 are various sensors necessary for the image forming operation such as a paper out detection sensor, a paper position detection sensor, a temperature sensor, and the like, and output various information detected by each to the CPU 1 as detection signals.

The printing paper transport unit 5 transports printing paper stored in a printing paper tray (not shown) to the image forming unit 7, a motor for driving the printing paper transport roller, and printing paper after image forming processing. It comprises a transport roller for transporting to a printing paper discharge tray (not shown), a motor for driving the transport roller, and the like.
The image data storage unit 6 is, for example, a flash memory, and stores image data of a document in response to a request from the CPU 1 and outputs image data of a predetermined document to the CPU 1.

The image forming unit 7 is controlled by the CPU 1 based on the image data of the original document stored in the image data storage unit 6 and the image data for printing received from an external device such as a personal computer. An image is formed on the printing paper by transferring the toner onto the conveyed printing paper and performing a fixing process on the toner.
The communication I / F unit 8 is an interface for performing communication between the multifunction peripheral A and an external device such as a personal computer, and is connected to the external device via a network such as a LAN (Local Area Network).

  The operation display unit 9 includes a start key, a stop key, a power key, a numeric keypad (numerical value input key), a touch panel, a clear key, and other various operation keys, and outputs an operation instruction for each key to the CPU 1. Under the control of the CPU 1, various screens are displayed on the touch panel.

Next, the image reading apparatus 10 will be described in detail with reference to FIG. FIG. 2 is a schematic configuration diagram illustrating a configuration of the image reading apparatus 10 of the multifunction peripheral A according to the present embodiment.
As shown in FIG. 2, the image reading device 10 includes an automatic document feeder 11, a flat bed type reading device 12, and an image reading circuit 13 (control means).

The automatic document transport device 11 is a device that automatically transports a document one by one from a bundle of documents placed on the placement tray 20, and passes a transport path H formed by routing from the placement tray 20 to the discharge tray 21. Has inside.
Note that a reading region R on a contact glass 12e of the flatbed reader 12 described later is disposed in the middle of the transport path R. In the reading region R, a platen roller 28 that is in contact with the contact glass 12e and is rotatable is provided.

  The automatic document feeder 11 includes a first transport unit 23 (first transport unit), a first transport storage unit 24 (first transport storage unit), and a second transport storage unit 25 (second transport storage unit). And a second transport unit 26 (second transport unit) and a third transport unit 27 (third transport unit).

  The first transport unit 23 transports the document placed on the placement tray 20 toward the discharge tray 21 so that the surface faces the reading region R, and includes a pickup roller 23a, A pair of conveying rollers 23b and 23c and a guide 23d are provided. Further, the platen roller 28 serves as a part of the function of the first transport unit 23, and transports the original so that the surface thereof faces the reading region R when rotated counterclockwise with respect to the paper surface of FIG. 1.

  The first transport storage unit 24 transports and stores the document that has passed through the reading region R in the first transport unit 23 by turning the transport path R toward the discharge tray 21 without turning it over. 24a and 24b are provided. Note that the first transport accommodating unit 24 can store a document between the transport roller pair 24a and the transport roller 24b. The pair of transport rollers 24 b plays a part of the function of the second transport housing unit 25 and discharges the document stored in the first transport housing unit 24 toward the discharge tray 21.

  The second transport housing unit 25 transports and stores the document stored in the first transport housing unit 24 toward the discharge tray 21 while turning it over, and includes a guide 25a and a transport roller pair 25b. , 25c. The second transport accommodating unit 25 can store a document between the transport roller pair 25b and the transport roller 25c. The pair of transport rollers 25 c serves as a part of the function of the second transport unit 26 and discharges the document stored in the second transport storage unit 25 toward the discharge tray 21.

The second transport unit 26 transports the document stored in the second transport storage unit 25 toward the discharge tray 21 so that the back surface faces the reading region R, and the movable guide 26a. It has. Further, the platen roller 28 serves as a part of the function of the second transport unit 26, and transports the document so that the back surface faces the reading region R by being rotated clockwise with respect to the paper surface of FIG. 1.
The movable guide 26a serves as a switching unit for switching the supply destination of the document that has passed through the reading region R in the first transport unit 23 to either the first transport accommodating unit 24 or the third transport unit 27. Function. Specifically, the movable guide 26a is rotatable between an angle at which the document discharged from the platen roller 28 is picked up and an angle at which the document passes below. When the movable guide 26a is at an angle at which the document discharged from the platen roller 28 passes below (the angle shown in FIG. 1), the document is supplied to the first conveyance housing unit 24. When the movable guide 26a is at an angle at which the document discharged from the platen roller 28 is picked up (an angle shown in FIG. 9), the document is supplied to the third transport unit 27. For example, a solenoid can be used as a power source for the movable guide 26a.

  The third transport unit 27 discharges the document that has passed the reading region R by the second transport unit 26 or the document that has passed the reading region R by the first transport unit 23 to the discharge tray 21. A guide 27a and conveying roller pairs 27b and 27c are provided.

As shown in FIG. 2, the automatic document feeder 11 includes a detection sensor 29 for detecting the presence of a document in the first transport container 24. A signal indicating the detection result of the detection sensor 29 is input to the image reading circuit 13.
Further, the automatic document feeder 11 includes a detection sensor 30 for detecting the presence of a document in the second transport housing unit 25. A signal indicating the detection result of the detection sensor 30 is input to the image reading circuit 13.
In addition, the automatic document feeder 11 includes a detection sensor 31 for detecting the presence of a document on the loading tray 20. A signal indicating the detection result of the detection sensor 31 is input to the image reading circuit 13.

  The flat bed type reading device 12 is fitted with a contact glass 12e serving as a document placement table on its upper surface, and reads an image of a document placed on the contact glass along the document transport path. The flat bed reader 12 includes a lamp 12a and a mirror 12b. , A condenser lens 12c and a CCD (Charge Coupled Devices) 12d.

  The lamp 12a irradiates the surface of the document on the contact glass with illumination light (white light) having a constant intensity in a scanning manner, and the mirror 12b reflects the reflected light from the surface of the document toward the condenser lens 12c. To do.

  The condensing lens 12c condenses the reflected light of the surface of the document reflected by the mirror 12b on the light receiving surface of the CCD 12d.

  The CCD 12 d (image reading sensor) converts the reflected light of the surface of the original collected by the condenser lens 12 c into image data (analog signal) and outputs the image data to the image reading circuit 13.

  The image reading circuit 13 will be described in detail with reference to FIG. FIG. 3 is a functional block diagram showing a functional configuration of the image reading circuit 13. In FIG. 3, thick arrows indicate input / output of image data, and thin arrows indicate input / output of control signals.

  The image reading circuit 13 controls the automatic document feeder 11 and the flat bed type reading device 12, and generates image data by converting data input from the CCD 12d into a digital signal and performing predetermined processing. is there.

  The image reading circuit 13 includes an A / D converter 13a, an image processing circuit 13c, an image memory circuit 13d, an image reading RAM 13e, an image reading ROM 13f, and an image reading CPU 13g.

  The A / D converter 13a converts data (analog signal) input from the CCD 12d of the flatbed reader 12 into a digital signal under the control of the image reading CPU 13g, and the digital signal is sent to the image processing circuit 13c. Output.

The image processing circuit 13c generates image data from data input from the A / D conversion unit 13a under the control of the image reading CPU 13g.
Then, the image processing circuit 13c outputs the image data generated as described above to the image memory circuit 13d.

  The image memory circuit 13d stores image data input from the image processing circuit 13c under the control of the image reading CPU 13g.

  The image reading RAM 13e is a working memory used as a temporary data storage destination when the image reading CPU 13g executes a control program to perform various operations.

The image reading ROM 13f is a non-volatile memory that stores a control program executed by the image reading CPU 13g and other data.
In the present embodiment, the image reading ROM 13f is a program for executing a double-sided reading mode for reading images formed on both sides of the original in the image reading apparatus 10, and a single side for reading only an image formed on one side of the original. A program or the like for executing the reading mode is stored.

The image reading CPU 13g controls the overall operation of the image reading apparatus 10 based on a control program stored in the image reading ROM 13f.
The function of the image processing circuit 13c can be assigned to the image reading CPU 13g.

  In the MFP A of the present embodiment having such a configuration, an image based on the image data generated by the image reading device 10 in the image forming unit 7 is printed on the printing paper under the control of the CPU 1. The image data is transmitted via the communication I / F unit 8.

Next, operations of the image reading apparatus 10 in a double-sided reading mode for reading an image formed on both sides of a document and a single-sided reading mode for reading only an image formed on one side of a document will be described. In the following description of the operation, a case will be described in which the double-sided reading mode and the single-sided reading mode are performed from a state where a plurality of documents are stacked on the loading tray 20.
Further, the duplex scanning mode and the duplex scanning mode are switched by, for example, an instruction from the operation display unit 9 of the multifunction peripheral A or an external instruction input via the communication I / F unit 8.

FIG. 4 is a flowchart showing processing performed by the image reading circuit 13 in the duplex reading mode.
As shown in this figure, in the double-sided reading mode, the image reading circuit 13 detects whether or not a document is stored in the second transport storage unit 25 (step S1), and the document exists in step S1. If the original is present in step S1, and the step of driving the first transport unit 23, the first transport storage unit 24, and the second transport storage unit 25 (step S2). A step (step S3) for detecting whether or not a document is contained, and when a document is present in step S3, the driving of the first conveyance unit 23 is stopped and the second conveyance accommodation unit 25 and the second conveyance unit 26 are stopped. In step S4, and when the document does not exist in step S4, the driving of the second transport accommodating unit 25 and the second transport unit 26 is stopped and the first transport is performed. 23 and the first conveyor housing portion 24 executes the process (step S5) to be driven. Then, when step S2, step S4, or step S5 ends, the image reading circuit 13 performs step S1 again.
When the image reading circuit 13 detects that there is no document on the loading tray 20, the image reading circuit 13 and the second transport accommodating unit 25 until the document in the automatic document transport device 11 is discharged to the discharge tray 21. The driving of the second transport unit 26 is repeated, and then the duplex reading mode is ended.

  In other words, in the image reading apparatus 10, when no document is stored in the second transport storage unit 25, the document is transported by the first transport unit 23, the first transport storage unit 24, and the second transport storage unit 25. As described above, the first transport unit 23, the first transport storage unit 24, and the second transport storage unit 25 are driven, and when the original is stored in the first transport storage unit 24 and the second transport storage unit 25, the first transport is performed. The drive of the unit 23 is stopped, and the second transport housing unit 25 and the second transport unit 26 are driven so that the original is transported by the second transport housing unit 25 and the second transport unit 26, and the first transport housing unit When no document is stored in 24 and a document is stored in the second transport storage unit 25, the driving of the second transport storage unit 25 and the second transport unit 26 is stopped and the first transport unit 23 and Documents are conveyed in the first conveyance container 24. Driving the first conveyor 23 and the first conveyor housing portion 24.

  When the above processing is executed by the image reading circuit 13, first, since there is no document in the first transport container 24 and the second transport container 25, the process proceeds from step S1 to step S2 and the first transport is performed. The unit 23, the first transport housing unit 24, and the second transport housing unit 25 are driven. As a result, the first document placed on the placement tray 20 is transported by the first transport unit 23 so that the surface thereof faces the reading region R as shown in FIG. For this reason, the image on the surface of the first original is read. The first original discharged from the reading area R is transported and stored in the first transport storage unit 25. It should be noted that the document is not transported by driving the second transport housing unit 25 because the document is not stored in the first transport housing unit 25 before the first document.

  Subsequently, step S1 is executed again. In this case as well, since there is no document in the second conveyance housing unit 25, the process proceeds from step S1 to step S2, and the first conveyance unit 23, the first conveyance accommodation unit 24, and the like. The 2nd conveyance accommodating part 25 is driven. As a result, as shown in FIG. 6, the first original document stored in the first transport storage unit 24 is transported and stored in the second transport storage unit 25. On the other hand, the second sheet of the document placed on the placement tray 20 is transported by the first transport unit 23 so that the surface faces the reading region R. For this reason, the image on the surface of the second original is read. Then, the second original discharged from the reading region R is transported and stored in the first transport storage unit 24.

  Subsequently, when step S1 is executed again, the second original is present in the first transport accommodating portion 24 and the first original is present in the second transport accommodating portion 25. In step S4, the driving of the first transport unit 23 is stopped and the second transport accommodating unit 25 and the second transport unit 26 are driven. As a result, as shown in FIG. 7, the first document stored in the second transport storage unit 25 is transported by the second transport unit 26 so that the back surface faces the reading region R. For this reason, the image on the back side of the first original is read. Note that the first document whose back side is read is discharged to the discharge tray 21 by the third transport unit 27. On the other hand, the second original document stored in the first transport storage unit 24 is transported and stored in the second transport storage unit 25.

  Subsequently, when step S1 is executed again, there is no document in the first transport housing unit 24, and a second document exists only in the second transport housing unit 25, so steps S1 to S5 are performed. Then, the driving of the second transport housing unit 25 and the second transport unit 26 is stopped, and the first transport unit 23 and the first transport housing unit 24 are driven. As a result, as shown in FIG. 8, the third sheet of the document placed on the placement tray 20 is transported by the first transport unit 23 so that the surface faces the reading region R. For this reason, the image on the surface of the third original is read. Then, the third original document discharged from the reading area R is conveyed to and stored in the first conveyance storage unit 24.

  Thereafter, there is a state in which a document exists in the first transport accommodation unit 24 and the second transport storage unit 25, and a state in which no document exists in the first transport storage unit 24 and a document exists in the second transport storage unit 25. Are repeated, and images formed on both sides of a plurality of documents are successively read.

  In the single-sided reading mode, as shown in FIG. 9, the image reading circuit 13 controls the movable guide 26a so that the original discharged from the platen roller 28 is picked up. As a result, the document ejected from the reading region R by the first transport unit 23 is supplied to the third transport unit 27. For this reason, only the image on the surface of the document is read.

According to the image reading apparatus 10 included in the multifunction peripheral A of the present embodiment, the document placed on the placement tray 21 is transported so that the image formed on the surface of the document can be read by the first transport unit 23, In the course of being transported by the first transport housing unit 24 and the second transport housing unit 25, it is reversed. Further, the document that has been turned over is transported by the second transport unit 26 so that an image formed on the back surface of the document can be read.
Then, according to the image reading apparatus 10 provided in the multifunction peripheral A of the present embodiment, the image formed on the front surface of the document and the image formed on the back surface of the document are read by the same CCD 12d. Therefore, it is possible to make the quality of the image data of the image formed on the front side of the original and the quality of the image data of the image formed on the back side of the original uniform, and further improve the image quality in the image formation. Is possible.

  In addition, according to the image reading apparatus 10 provided in the multifunction peripheral A of the present embodiment, the document is not switched back, and the discharge tray always keeps the conveyance path H formed by drawing from the placement tray 20 to the discharge tray 21. It is conveyed toward. Further, the first transport container 24 and the second transport container 25 can store the original. Therefore, the image formed on the surface of the subsequent document can be read by the CCD 12d while the previous document is turned over in the process of being transported by the first transport housing unit 24 and the second transport housing unit 25. It becomes. Therefore, it is possible to improve the document reading speed in the image reading apparatus 10, and it is possible to increase the speed of image formation.

  Therefore, according to the multifunction peripheral A of the present embodiment and the image reading device 10 included in the multifunction peripheral A, the image data quality of the image formed on the front surface of the document and the back surface of the document are formed on the image reading device 10. The image quality of the multifunction device A is improved by making the quality of the image data of the image uniform, and the speed of image formation in the multifunction device A is increased by improving the document reading speed in the image reading apparatus 10. Is possible.

Further, in the image reading apparatus 10 provided in the multifunction peripheral A of the present embodiment, the supply destination of the document that has passed the reading region R by the first transport unit 23 is set as the first transport accommodation unit 24 and the third transport unit 27. The movable guide 26a for switching to any of the above is provided.
For this reason, it is possible to easily switch between the double-sided reading mode and the single-sided reading mode.

Further, in the image reading apparatus 10 provided in the multifunction machine A of the present embodiment, the CCD 12d is used as the image reading sensor of the present invention.
Therefore, the quality of the image data can be further improved as compared with the case where a CIS (Contact Image Sensor) is used as the image reading sensor.
Note that the image reading apparatus 10 provided in the multifunction peripheral A of the present embodiment employs a configuration including only the CCD 12d as an image reading sensor. However, in the present invention, as the image reading sensor, a configuration including CIS or both CCD and CIS can be adopted.

  Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to the above-described embodiments, and design changes and the like can be made without departing from the scope of the present invention. .

For example, in the above-described embodiment, the configuration in which the image reading apparatus 10 and the operation display unit 9 are mounted on the multifunction peripheral A has been described.
However, the present invention is not limited to this, and can be used for an image forming apparatus such as a copying machine, a facsimile apparatus, or a scanner apparatus.

1 is a functional block diagram of a multi-function peripheral including an image reading apparatus according to an embodiment of the present invention. 1 is a schematic configuration diagram of an image reading apparatus according to an embodiment of the present invention. 1 is a functional block diagram of an image reading apparatus according to an embodiment of the present invention. 6 is a flowchart for explaining a double-sided reading mode in the image reading apparatus according to the embodiment of the present invention. It is explanatory drawing for demonstrating the double-sided reading mode in the image reading apparatus which is one Embodiment of this invention. It is explanatory drawing for demonstrating the double-sided reading mode in the image reading apparatus which is one Embodiment of this invention. It is explanatory drawing for demonstrating the double-sided reading mode in the image reading apparatus which is one Embodiment of this invention. It is explanatory drawing for demonstrating the double-sided reading mode in the image reading apparatus which is one Embodiment of this invention. It is explanatory drawing for demonstrating the single-sided reading mode in the image reading apparatus which is one Embodiment of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Image reading device, 20 ... Loading tray, 21 ... Discharge tray, 23 ... 1st conveyance part (1st conveyance means), 24 ... 1st conveyance accommodation part (1st conveyance accommodation means) , 25... 2nd transport accommodating section (second transport accommodating means), 26... 2nd transport section (second transport means), 26 a... Movable guide (switching section), 27. 3 transport means), 12d... CCD (image reading sensor), 13... Image reading circuit (control means), A.

Claims (5)

An image reading apparatus that reads an image formed on the original as image data while conveying a conveyance path formed by drawing the original placed on the placement tray from the placement tray to the discharge tray.
An image reading sensor that reads, as the image data, the image that faces a reading region arranged in the middle of the conveyance path;
First conveying means for conveying the document placed on the placing tray toward the discharge tray so that the surface faces the reading area;
First transport accommodation means for transporting and storing the transport path toward the discharge tray without turning over the document that has passed through the reading area by the first transport means;
Second conveying and storing means for transferring and storing the conveying path toward the discharge tray while turning over the document stored in the first conveying and storing means;
Second conveying means for conveying the document accommodated in the second conveying and accommodating means toward the discharge tray so that the back surface thereof faces the reading area;
Third conveying means for discharging the original that has passed through the reading area by the second conveying means to the discharge tray;
An image reading apparatus comprising: control means for controlling the first to third conveyance means, the first conveyance accommodation means, and the second conveyance accommodation means. When continuously reading images formed on both sides of the original document stacked on the placing tray,
The control means includes
The first transport unit, the first transport unit, the first transport unit, and the second transport unit when the second transport unit does not store the document. Driving one conveying and storing means and the second conveying and storing means;
When the document is stored in the first transport and storing means and the second transport and storing means, the driving of the first transport means is stopped and the document is moved by the second transport and storing means and the second transport means. Driving the second transport accommodating means and the second transport means so that the
When the original is not stored in the first transport and storage unit and the document is stored in the second transport and storage unit, the driving of the second transport and storage unit and the second transport unit is stopped. The image reading apparatus according to claim 1, wherein the first conveyance unit and the first conveyance accommodation unit are driven so that the original is conveyed by the first conveyance unit and the first conveyance accommodation unit. apparatus.   2. The apparatus according to claim 1, further comprising a switching unit capable of switching a supply destination of the document that has passed through the reading area by the first conveying unit between the first conveying unit and the third conveying unit. The image reading apparatus described.   The image reading apparatus according to claim 1, wherein the image reading sensor is a CCD sensor. An image forming apparatus that acquires image data with an image reading apparatus and forms an image on a recording medium based on the image data,
An image forming apparatus using the image reading apparatus according to claim 1 as the image reading apparatus.

Images