KR20250001113A - Duplex Document Scanning apparatus - Google Patents

Abstract

The present invention relates to a double-sided document scanning device. A scan case includes a document supply port for receiving documents to be scanned into the interior, a document discharge port for discharging scanned documents to the exterior, a first scan transparent plate arranged on the inside near the document discharge port, a second scan transparent plate arranged on the inside near the document supply port, and a transport path section for transporting a document supplied from the document supply port through the second scan transparent plate, reversing the document, and guiding the document through the first scan transparent plate to the document discharge port, but such that the transport distance between the first scan transparent plate and the second scan transparent plate is longer than the length of the document. A light source section irradiates light to the first scan transparent plate and the second scan transparent plate. A first optical system transmits light reflected from one side of the document through the first scan transparent plate to an image sensor. A second optical system transmits light reflected from the other side of the document through the second scan transparent plate to the image sensor.

Description

{Duplex Document Scanning apparatus}

The present invention relates to a double-sided document scanning device, and more particularly, to a double-sided document scanning device that sequentially scans images contained on both sides of a document.

In general, a double-sided document scanning device is a device that feeds a document containing images on both sides and automatically reads the images contained on both sides, and is widely applied to various products such as scanners, copiers, fax machines, and multi-function printers that capture and process document images.

As an example of such a double-sided document scanning device, there is a technology disclosed in U.S. Patent Publication No. US 5,430,536. According to the disclosed technology, when a scan operation is started, a single document is picked up from a feeder and fed into a transport path. Then, the document passes through an image reader, and the image of one side is read. The document with one side read is delivered to the output tray by the output roller.

In the case of duplex scanning, before the rear end of the document has completely passed through the output roller, the output roller reverses and re-introduces the document from the rear end toward the image capture unit. When the document passes through the image capture unit again, the opposite side of the previously captured side faces the image capture unit, so the opposite side is read. The document whose opposite side has been captured is discharged to the output tray through a branched transport path. As a result, the images contained on both sides of the document can be captured sequentially.

However, if the duplex scanning process described above is performed, the transport path through the image capture unit for each document must be repeated twice before the next document can be fed. In addition, even after duplex scanning, if the document is reversed to match the stacking order of the documents loaded on the tray, the document must go through the transport process once more before the next document can be fed, so there is a problem that it takes a considerable amount of time to output a single document by scanning both sides.

Meanwhile, there is an example of configuring two image acquisition units placed above and below the document to scan both sides with one document discharge, but the cost of adding an image acquisition unit may be burdensome. If a CCD (Charged Coupled Device) image sensor constitutes the image acquisition unit, the CCD image sensor has a complex configuration, a large configuration space, and is expensive, so it is not suitable for the aforementioned method.

U.S. Patent Publication No. US 5,430,536 (registered on July 4, 1995)

The object of the present invention is to provide a double-sided document scanning device capable of significantly shortening double-sided scanning time and reducing manufacturing costs.

In order to achieve the above object, a double-sided document scanning device according to the present invention includes a scan case, a document transport mechanism, an image sensor, a light source unit, a first optical system, and a second optical system. The scan case includes a document supply port for receiving documents to be scanned into the interior, a document discharge port for discharging scanned documents to the exterior, a first scan transparent plate arranged on the inside near the document discharge port, a second scan transparent plate arranged on the inside near the document supply port, and a transport path unit for transporting a document supplied from the document supply port through the second scan transparent plate, and then reversing the document and guiding it to the document discharge port through the first scan transparent plate, but such that the transport distance between the first scan transparent plate and the second scan transparent plate is longer than the length of the document. The document transport mechanism is mounted on the inside of the scan case to transport the document from the document supply port to the document discharge port. The image sensor is mounted on the inside of the scan case. The light source unit irradiates light onto the first scan transparent plate and the second scan transparent plate. The first optical system transmits light reflected from one side of the document through the first scan transparent plate to the image sensor. The second optical system transmits light reflected from the other side of the document through the second scan transparent plate to the image sensor.

According to the double-sided document scanning device of the present invention, since both sides can be scanned by discharging a document once, the double-sided scanning time can be significantly shortened compared to an example in which both sides are scanned while discharging a document multiple times.

According to the double-sided document scanning device of the present invention, since both sides are scanned using one image sensor, a multi-function printer, etc. can be configured at a lower cost than an example in which both sides are scanned using two image sensors. In addition, according to the double-sided document scanning device of the present invention, since a CCD image sensor can be used as the image sensor, excellent scan image quality can be provided.

FIG. 1 is a configuration diagram of a double-sided document scanning device according to one embodiment of the present invention.
Figures 2 to 4 are drawings showing an example of operation of the double-sided document scanning device illustrated in Figure 1.

The present invention will be described in detail with reference to the attached drawings as follows. Here, the same reference numerals are used for the same components, and repetitive descriptions and detailed descriptions of well-known functions and components that may unnecessarily obscure the gist of the present invention are omitted.

The embodiments of the present invention are provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for a clearer explanation.

FIG. 1 is a configuration diagram of a double-sided document scanning device according to one embodiment of the present invention. FIGS. 2 to 4 are drawings showing an example of operation of the double-sided document scanning device illustrated in FIG. 1.

Referring to FIGS. 1 to 4, a double-sided document scanning device (100) according to one embodiment of the present invention includes a scan case (110), a document transport mechanism (120), an image sensor (130), a light source unit (141, 142), a first optical system (150), and a second optical system (160).

The scan case (110) includes a document supply port (111), a document discharge port (112), a first scan transparent plate (113), a second scan transparent plate (114), and a transport path (115). The document supply port (111) receives a document (1) to be scanned into the interior. For example, the document supply port (111) may be arranged on one side of the upper portion of the scan case (110).

The document discharge port (112) discharges the scanned document (1) to the outside. For example, the document discharge port (112) may be arranged on the lower side of the scan case (110). If the document supply port (111) is arranged on the left side of the scan case (110), the document discharge port (112) may also be arranged on the left side of the scan case (110). If the document supply port (111) is arranged on the right side of the scan case (110), the document discharge port (112) may also be arranged on the right side of the scan case (110).

The first scan transparent plate (113) is placed on the inner side close to the document discharge port (112). The first scan transparent plate (113) can be placed horizontally on the transport path section (115) to support the document (1) from the lower side. The first scan transparent plate (113) can transmit light irradiated from the first light source (141) to the document (1). When the document (1) is reversed while being transported along the transport path section (115), the first scan transparent plate (113) allows light to be irradiated on the reversed upper surface of the document (1).

The second scan transparent plate (114) is arranged on the inner side close to the document supply port (111). The second scan transparent plate (114) can be arranged horizontally on the transport path section (115) to support the document (1) from the lower side. The second scan transparent plate (114) can transmit light irradiated from the second light source (142) to the document (1). When the document (1) is transported along the transport path section (115), the second scan transparent plate (114) allows light to be irradiated to the lower surface of the document (1). The second scan transparent plate (114) can be arranged to be horizontally misaligned with respect to the first scan transparent plate (113).

The transport path section (115) transports a document (1) supplied from the document supply port (111) through the second scan transparent plate (114), then reverses the document (1) and guides it through the first scan transparent plate (113) to the document discharge port (112). The transport path section (115) is formed in a form in which it extends to one side from the document supply port (111) and then changes direction to extend to the document discharge port (112).

For example, when the document supply port (111) and the document discharge port (112) are arranged vertically, the transport path section (115) may extend from the document supply port (111) through the second scan transparent plate (114), then bend downward, and then extend through the first scan transparent plate (113) to the document discharge port (112). The middle section of the transport path section (115) between the first scan transparent plate (113) and the second scan transparent plate (114) may be formed in a curved shape like a U shape to facilitate the direction change of the document (1).

The transport path section (115) guides the document (1) in a form where the transport distance between the first scan transparent plate (113) and the second scan transparent plate (114) is longer than the length of the document (1). Here, the length of the document (1) is the front-back length along the transport direction. This transport path section (115) prevents the front end of the document (1) from reaching the first scan transparent plate (113) until the rear end of the document (1) completely passes through the second scan transparent plate (114), thereby allowing the lower surface of the document (1) to be scanned on the second scan transparent plate (114).

The document transport mechanism (120) is mounted on the inside of the scan case (110) to transport the document (1) from the document supply port (111) to the document discharge port (112). The document transport mechanism (120) may be driven and controlled by a device controller that generally controls the double-sided document scanning device (100). For example, the document transport mechanism (120) may include a pickup roller (121), a separation roller (122), a transport roller (123), and a discharge roller (124).

The pickup roller (121) picks up documents (1) loaded in multiple sheets on the feeder (120a) through the document feed port. The separation roller (122) separates the documents (1) picked up by the pickup roller (121) one by one. An auxiliary separation roller (122a) is installed on the opposite surface of the separation roller (122) to separate the documents (1). Although not shown, as another example, a friction pad may be installed adjacent to the opposite surface of the separation roller (122) to provide frictional force when separating the documents (1).

The conveying rollers (123) convey the documents (1) separated by the separating rollers (122) along the conveying path (115). An auxiliary conveying roller (123a) is installed on the opposite surface of each conveying roller (123) to guide the conveying of the documents (1). The discharge roller (124) discharges the documents (1) conveyed by the conveying rollers (123) through the document discharge port (112) to the discharge tray (120b). An auxiliary discharge roller (124a) is installed on the opposite surface of the discharge roller (124) to guide the discharge of the documents (1).

The image sensor (130) is mounted on the inside of the scan case (110). The image sensor (130) receives an optical image of a subject and converts it into an electrical signal. The image sensor (130) can perform line scanning along the width direction of the document (1) being transported. The image sensor (130) can be either a CMOS (Complementary Metal Oxide Semiconductor) image sensor or a CCD (Charged Coupled Device) image sensor.

The image sensor (130) may be placed adjacent to the first optical system (150). The image sensor (130) may be driven and controlled by a device controller. The image sensor (130) may be driven and controlled according to position information of the document (1).

The light source unit (141, 142) irradiates light to the first scan transparent plate (113) and the second scan transparent plate (114). The light source unit (141, 142) may include a first light source (141) that irradiates light to one side of the document (1) through the first scan transparent plate (113), and a second light source (142) that irradiates light to the other side of the document (1) through the second scan transparent plate (114).

The first light source (141) is driven when scanning the inverted upper surface of the document (1) transferred to the first scan transparent plate (113). The first light source (141) can be driven only while the document (1) passes through the first scan transparent plate (113). The first light source (141) can be driven and controlled by a device controller. The first light source (141) can be driven and controlled according to the position information of the document (1).

The first light source (141) can be configured in a form in which light-emitting elements such as LEDs are mounted in a row on a substrate. The first light source (141) can be mounted on the inside of the scan case (110) so that the light-emitting elements are arranged along the scan line of the document (1) and can irradiate light onto the first scan transparent plate (113).

The second light source (142) is driven when scanning the lower surface of the document (1) transferred to the second scan transparent plate (114). The second light source (142) can be driven only while the document (1) passes through the second scan transparent plate (114). The second light source (142) can be driven and controlled by a device controller. The second light source (142) can be driven and controlled according to the position information of the document (1). The second light source (142) can be configured in the same manner as the first light source (141). When the first light source (141) irradiates light to the second scan transparent plate (114) through the second optical system (160), the second light source (142) may be omitted.

The first optical system (150) transmits light reflected from one side of the document (1) through the first scan transparent plate (113) to the image sensor (130). For example, the first optical system (150) may include a first reflector (151) that receives light reflected from one side of the document (1) and reflects it to the sensing unit of the image sensor (130).

When the first scan transparent plate (113) is horizontally arranged on the lower side of the document (1) being transferred, the first reflector (151) may be arranged on the lower side of the first scan transparent plate (113). The first reflector (151) may be formed in a form that is extended to a length corresponding to the scan line length of the first scan transparent plate (113). The reflective surface (151a) of the first reflector (151) may be inclined at 45 degrees with respect to the horizontal plane.

The reflective surface (151a) of the first reflector (151) is positioned so as to face the lower surface of the first scan transparent plate (113). Accordingly, the first reflector (151) can reflect light reflected from the inverted upper surface of the document (1) and traveling vertically downward by 90 degrees so as to travel horizontally. The sensing unit of the image sensor (130) is positioned to receive light reflected from the first reflector (151) and traveling horizontally, thereby enabling scanning of the inverted upper surface of the document (1).

The second optical system (160) transmits light reflected from the other side of the document (1) through the second scan transparent plate (114) to the image sensor (130). For example, the second optical system (160) may include a second reflector (161) and a third reflector (162). The second reflector (161) receives and reflects light reflected from the other side of the document (1). When the second scan transparent plate (114) is horizontally arranged below the document (1) being transported, the second reflector (161) may be arranged below the second scan transparent plate (114).

The second reflector (161) may be formed in an extended form with a length corresponding to the scan line length of the second scan transparent plate (114). The reflective surface (161a) of the second reflector (161) may be inclined at 45 degrees with respect to the horizontal plane. The second reflector (161) may be configured in the same manner as the first reflector (151).

The reflective surface (161a) of the second reflector (161) is arranged to face the lower surface of the second scan transparent plate (114). Therefore, the second reflector (161) can reflect light reflected from the lower surface of the document (1) and traveling downward vertically by 90 degrees so as to travel horizontally. Here, the second reflector (161) can be arranged in a left-right reversed position with respect to the first reflector (151). Therefore, the second reflector (161) can travel light to the third reflector (162) arranged directly above the first reflector (151).

The third reflector (162) receives the light reflected from the second reflector (161) and reflects it onto the first reflector (151), so that the reflected light is transmitted to the sensing unit of the image sensor (130) by the first reflector (151). The third reflector (162) may be formed in an extended form with a length corresponding to the scan line length of the second scan transparent plate (114). The reflective surface (162a) of the third reflector (162) may be inclined at 45 degrees with respect to the horizontal plane. The third reflector (162) may be configured in the same manner as the second reflector (161).

The third reflector (162) can be arranged at the same height as the second reflector (161) directly above the first reflector (151). The third reflector (162) can be arranged in an upside-down position with respect to the first reflector (151). The reflective surface (162a) of the third reflector (162) can be parallel to the reflective surface (161a) of the second reflector (161) and be vertically symmetrical with the reflective surface (151a) of the first reflector (151).

Accordingly, the third reflector (162) can receive light traveling horizontally from the second reflector (161), reflect it downward vertically at 90 degrees, and transmit it to the first reflector (151). Then, the first reflector (151) can reflect the light received from the third reflector (162) horizontally at 90 degrees and transmit it to the sensing unit of the image sensor (130).

In this way, when the first and second optical systems (150, 160) are used including the first, second and third reflectors (151, 161, 162), they can be configured regardless of the focal length, and can be easily applied without changing the size even when mounted on a complex machine. The first, second and third reflectors (151, 161, 162) are exemplified as triangular mirrors, but may also be configured as flat mirrors, etc.

An example of the operation of the above-described double-sided document scanning device (100) will be described below with reference to FIGS. 2 to 4.

As shown in Fig. 2, when the duplex scan mode is set and the scanning operation is started, the document (1) loaded on the feeder (120a) enters the transport path section (115) from the document supply port (111) by the document transport mechanism (120). When the document (1) reaches the second scan transparent plate (114), the second light source (142) is driven to irradiate light to the lower surface of the document (1) through the second scan transparent plate (114).

Then, the light reflected from the bottom of the document (1) passes through the second reflector (161) and the third reflector (162) in sequence and then to the first scan transparent plate (113). Then, the light passes through the first scan transparent plate (113) and is reflected by the first reflector (151) and transmitted to the image sensor (130).

While the document (1) passes through the second scan transparent plate (114), the light reflected from the lower surface of the document (1) is transmitted to the image sensor (130) through the aforementioned process, thereby scanning the entire lower surface of the document (1). Thereafter, the second light source (142) is turned off.

Next, as shown in Fig. 3, the document (1) is reversed while changing direction along the transport path section (113) after passing through the second scan transparent plate (114). Accordingly, the upper surface of the document (1) is reversed and faces downward.

Next, as illustrated in FIG. 4, when the document (1) reaches the first scan transparent plate (113), the first light source (141) is driven to irradiate light onto the inverted upper surface of the document (1) through the first scan transparent plate (113). Then, the light reflected from the inverted upper surface of the document (1) is reflected by the first reflector (151) and transmitted to the image sensor (130).

While the document (1) passes through the first scan transparent plate (113), the light reflected from the inverted upper surface of the document (1) is transmitted to the image sensor (130) through the aforementioned process, so that the entire inverted upper surface of the document (1) is scanned. Accordingly, after both sides of the document (1) are scanned, the document is discharged to the discharge tray (120b) through the document discharge port (1202).

In this way, according to the double-sided document scanning device (100) of the present embodiment, since both sides can be scanned by discharging a document (1) once, the double-sided scanning time can be significantly shortened compared to an example in which both sides are scanned while discharging a document multiple times.

According to the double-sided document scanning device (100) of the present embodiment, since both sides are scanned using one image sensor (130), a multi-function printer, etc. can be configured at a lower cost than an example in which both sides are scanned using two image sensors. In addition, according to the double-sided document scanning device (100) of the present embodiment, since a CCD image sensor can be used as the image sensor (130), excellent scan image quality can be provided.

Although the present invention has been described with reference to the embodiments illustrated in the attached drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

1..Document 100..Double-sided document scanning device
110..Scan Case 111..Document Feed Port
112..Document outlet 113..1st scan transparent plate
114..2nd scan transparent plate 115..Transport path section
120..Document transport device 120a..Feeder
120b..badge 121..pickup roller
122..Separation roller 122a..Auxiliary separation roller
123..Transport roller 123a..Auxiliary transport roller
124.. Badge roller 124a.. Auxiliary badge roller
130..Image sensor 141, 142..Light source
150..1st optical system 151..1st reflector
151a..Reflective surface of the first reflector 160..Second optical system
161..2nd reflector 161a..Reflective surface of the second reflector
162..3rd reflector 162a..Reflective surface of the 3rd reflector

Claims (5)

A scan case comprising a document supply port for receiving documents to be scanned into the interior, a document discharge port for discharging scanned documents to the exterior, a first scan transparent plate arranged on the inside near the document discharge port, a second scan transparent plate arranged on the inside near the document supply port, and a transport path section for transporting a document supplied from the document supply port through the second scan transparent plate, reversing the document, and guiding the document to the document discharge port through the first scan transparent plate, wherein the transport distance between the first scan transparent plate and the second scan transparent plate is longer than the length of the document;
A document transport mechanism mounted on the inside of the scan case to transport documents from the document supply port to the document discharge port;
An image sensor mounted on the inside of the above scan case;
A light source unit that irradiates light onto the first scan transparent plate and the second scan transparent plate;
A first optical system that transmits light reflected from one side of a document through the first scan transparent plate to the image sensor; and
A second optical system that transmits light reflected from the other side of the document through the second scan transparent plate to the image sensor;
A duplex document scanning device including:
In the first paragraph,
The above first optical system includes a first reflector that receives light reflected from one side of the document and reflects it to the sensing unit of the image sensor;
A double-sided document scanning device, characterized in that the second optical system includes a second reflector that receives and reflects light reflected from the other side of the document, and a third reflector that receives light reflected from the second reflector and reflects it to the first reflector, so that the reflected light is transmitted to the sensing unit of the image sensor by the first reflector.
In the first paragraph,
A double-sided document scanning device, characterized in that the image sensor is either a CMOS (Complementary Metal Oxide Semiconductor) image sensor or a CCD (Charged Coupled Device) image sensor.
In the first paragraph,
The above light source part,
A first light source that irradiates light to one side of the document through the first scan transparent plate, and
A double-sided document scanning device characterized by including a second light source that irradiates light to the other side of the document through the second scan transparent plate.
In the first paragraph,
The above document transfer mechanism is,
A duplex document scanning device comprising: a pickup roller for picking up documents loaded in multiple sheets on a tray through the document feed port; a separation roller for separating the documents picked up by the pickup rollers one by one; transport rollers for transporting the documents separated by the separation rollers along the transport path; and a discharge roller for discharging the documents transported by the transport rollers to the discharge tray through the document discharge port.

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