KR20070018530A - Image forming apparatus including parts for the scanning module detouring - Google Patents

Abstract

The present invention provides a scanning module and a scanning module bypass portion for scanning an image recorded on an original while being slid, and are arranged in parallel with the first flat glass in contact with the original conveyed by the automatic paper feeder and the first flat glass. A second flat glass contacting the stopped original, a scanning module slidably installed on the rear surface of the first or second flat glass, and scanning an image recorded on the original; A guide module having a structure, a structure disposed at a boundary between the first and second plate glass, and the scanning module when the scanning module passes through a boundary between the first and second plate glass. An image forming apparatus having a bypass portion spaced apart from the object is provided.

Scanning module, guide module, bypass unit, image forming apparatus

Description

Image forming apparatus including parts for the scanning module detouring}

1 is a perspective view of an image forming apparatus according to a first embodiment of the present invention.

FIG. 2 is a side cross-sectional view illustrating a main part of a scanning module bypass unit in the image forming apparatus of FIG. 1.

FIG. 3 is a partially enlarged side cross-sectional view illustrating stepwise operations of a scanning module bypass unit included in the image forming apparatus of FIG. 1.

4 is a side cross-sectional view of the image forming apparatus according to the second embodiment of the present invention, corresponding to FIG. 2 of the first embodiment.

FIG. 5 is a side cross-sectional view of the scanning module and the guide module of FIG. 4 viewed from the A direction. FIG.

<Description of the symbols for the main parts of the drawings>

201 and 301: main body frame 201a and 301a: main body frame groove

210, 310: Automatic Document Feeder (ADF) 220, 320: Tray

230, 330: discharge stand 240: display panel

250, 350: first flat glass 251, 351: second flat glass

260, 270, 360, 370: ADF Bezel 270a, 370a: Document Guide Section

       270b, 370b: ADF bezel interferer 280, 380: guide module

281, 381: guide shaft 282, 382: guide shaft holder

283, 383: guide shaft springs 290, 390: scanning module

291 and 391: scanning module main body 292 and 392: scanning module interference part

393: scanning module spring 394: scanning module roller holder

395: scanning module roller

The present invention relates to an image forming apparatus, and more particularly, to an image forming apparatus including a scanning module and a scanning module bypass unit for scanning an image recorded on an original while sliding.

Background Art [0002] Image forming apparatuses, such as printers, scanners, copiers, facsimiles, and the like, which print text or pictures on a recording medium, have recently been used in the form of a multifunction machine that performs various functions in combination. The scanner includes a scanning module that reads an image recorded on an original as an optical signal and converts the image into an electrical signal.

In general, the scanning module scans an image on one axis of the original, and in order to scan the original on two axes, the scanning module needs to be moved or the original needs to be moved. The scanner to which the scanning module is moved is commonly referred to as a flat bed type scanner. A distinctive concept is a sheet feed type scanner in which a document is moved. In addition, a flatbed scanner includes an automatic document feeder (ADF), which also serves as a sheet-feed scanner.

As such, the image forming apparatus including the flatbed and sheet-feed scanners may be formed integrally with the ADF section glass and the stationary document section glass, or may be formed separately. The problem is as follows.

First, when both of the flat glass portions are formed integrally, the document guides are coupled to the boundary portions that partition the flat glass portions. In this case, when a contact image sensor (CIS) is used for the scanning module, since the depth of focus decreases, the gap between the scanning module and the flat glass should be kept narrow. In addition, the document to be discharged into the discharge bin may be jammed by the front end is caught in the coupling portion between the platen glass and the document guide. In order to prevent such jams and to take into account the low depth of focus of the contact image sensor, a thin transparent sheet through which light passes can be placed on the flat glass of the ADF section so as to cover the original guide so that the original is transferred onto the transparent sheet. . However, in this case, the depth of focus of the CIS sensor may not be correct due to the arrangement of the transparent sheet having the thickness tolerance, or the original may pass through the transparent sheet, causing scratches on the transparent sheet, thereby degrading the quality of the scanned image or There was a problem that requires frequent replacement.

On the other hand, when the ADF plate glass and the stationary platen glass plate is separated separately, it is possible to prevent the jam of the original by inserting the document guide between each end of the separated plate glass without interposing the transparent sheet, In order to prevent such a collision with the document guide, the scanning module is arranged spaced apart from the document guide by a predetermined interval. In this case, there is a problem that the scanning module is spaced apart from the original by a considerable distance so that the depth of focus of the CIS sensor does not match, and thus the quality of the scanned image is deteriorated.

An object of the present invention is to provide an image forming apparatus which allows a scanning module to pass between the separated ends of the flat plate glass of the ADF section and the flat platen of the stationary document section without abrasion or transfer shock. .

Still another object of the present invention is to provide an image forming apparatus capable of adjusting the depth of focus by narrowing the distance between the flat glass and the scanning module.

According to the present invention, there is provided a first flat glass contacting an original conveyed by an automatic sheet feeder, a second flat glass arranged in parallel with the first flat glass, and in contact with a stopped original, and the first or second flat panel. A scanning module slidably mounted on the rear surface of the glass and scanning an image recorded on the document, a guide module for guiding the transfer of the scanning module and having a vertical flow structure, and a boundary portion between the first and second flat glass plates And a bypass portion that separates the scanning module from the structure when the scanning module passes through a boundary between the first and second flat glasses.

According to an embodiment of the present invention, the structure disposed at the boundary between the first and second flat glass is to hold the first flat glass and the front end portion of the original conveyed by the automatic sheet feeder as the paper is discharged. It is preferably a guiding ADF bezel.

According to another embodiment of the present invention, the bypass portion, an ADF bezel interference portion formed in the ADF bezel disposed on the boundary between the first and second flat glass, the ADF bezel interference portion formed in the scanning module A scanning module interference part, a guide shaft provided in the guide module, and a guide shaft spring connected to the guide shaft to cause vertical flow of the guide shaft and the scanning module, wherein the scanning module interference part interferes with the ADF bezel. It is preferable that the scanning module is bypassed by the elastic force of the guide shaft spring when in contact with the part.

According to a preferred embodiment of the present invention, the scanning module is further provided with a scanning module spring for promoting the vertical flow of the scanning module, one end of the scanning module spring is fixed to the scanning module body and the other end of the scanning module roller Is preferably connected.

According to another embodiment of the present invention, the scanning module includes a contact image sensor (CIS) or a charge coupled device (CIS) that converts an optical signal obtained by scanning the document into an electrical signal. It is desirable.

Hereinafter, an image forming apparatus according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an image forming apparatus according to a first embodiment of the present invention, FIG. 2 is a side cross-sectional view showing a main part of a scanning module bypass unit in the image forming apparatus of FIG. 1, and FIG. 3 is an image forming apparatus of FIG. 1. A partially enlarged side cross-sectional view showing step by step the action of the scanning module bypass provided in the apparatus.

1 and 2, the image forming apparatus 200 according to the first exemplary embodiment may include a first flat glass 250 to which an original conveyed by an automatic document feeder (ADF) 210 is in contact. And a second flat glass 251 in contact with the stationary document. Here, the first flat glass 250 and the second flat glass 251 are separated from each other.

In addition, the display panel 240 displays the operation and status of the image forming apparatus 200 and includes various operation keys.

In addition, the document loaded on the tray 220 is transferred to the first flat glass 250 by the automatic sheet feeder 210. Next, the scanning module 290 stationary on the rear surface of the first flat glass 250 scans the image recorded on the document. Thereafter, the scanned document is discharged to the discharge tray 230.

In addition, an ADF bezel 270 is disposed at the boundary between the first and second flat glasses 250 and 251. Details thereof will be described later.

On the other hand, the document fed in a sheet, not by the automatic sheet feeder (ADF) 210, is placed on the upper surface of the second flat glass 251. Next, the scanning module 290 is transported in the scanning direction on the rear surface of the second flat glass 251 and scans the image of the stopped original.

The initial position of the scanning module 290 is the rear surface of the first flat glass 250 when scanning the document fed to the automatic document feeder 210, and the second flat glass 251 when scanning the stopped document. It is the back side.

The image sensor included in the scanning module 290 may be a contact image sensor (CIS) or a charge coupled device (CIS) that converts an optical signal obtained by scanning an original into an electrical signal. Do. However, the rod lens array employed in the CIS has a low depth of focus. Therefore, in the case of using the CIS, a good image quality may be obtained by closely attaching the scanning module 290 to the rear surface of the first or second flat glass 250 or 251. In addition, a charge coupled device (CCD) having a relatively large depth of focus may be used as an image sensor.

Hereinafter, referring to FIG. 2, when the scanning module 290 provided in the image forming apparatus 200 according to the first embodiment is transferred from the second flat glass 251 to the first flat glass 250, Or the bypass portion that separates the scanning module 290 from the ADF bezel 270 when conveyed in the opposite direction will be described in detail.

The ADF bezel 270 is provided at the boundary between the first flat glass 250 and the second flat glass 251. Here, the ADF bezel 270 serves to hold the first flat glass 250 together with another ADF bezel 260 disposed on the opposite side of the first flat glass 250. In addition, the ADF bezel 270 includes a document guide portion 270a having an inclined surface at the upper end of the automatic document feeder 210 side, and an ADF bezel interference portion 270b at the lower end of the automatic document feeder 210.

The document guide part 270a serves to guide the leading end of the document passing through the first platen glass 250 to the discharge table 230, and the ADF bezel interference part 270b is a scanning module interference part 292, which will be described later. ) To bypass the scanning module 290 from the structure disposed at the boundary between the first and second flat glasses 250 and 251, that is, the ADF bezel 270.

The scanning module 290 is provided below the first or second flat glass 250 or 251. Here, the scanning module interference part 292 is formed on the upper end of the scanning module 290 is in close contact with the first or second flat glass (250, 251).

Here, the scanning module interference part 292 is formed to be inclined at both upper ends in the axial direction. That is, when the scanning module interference part 292 contacts the ADF bezel interference part 270b, the force caused by the interference does not correspond to the scanning module interference part 292 and the feeding direction of the scanning module 290 is not parallel. It is preferably formed to be inclined to act in the direction of. In more detail, when the force caused by the above-described interference acts in the direction parallel to the conveying direction of the scanning module 290, the force is eventually perpendicular to the guide shaft spring 283 of the guide module 280 described later. It acts in one direction, and in this case, the guide shaft spring 283 described later does not contract or extend. On the other hand, when the force caused by the above-described interference acts in a direction that is not parallel to the conveying direction of the scanning module 290, the guide shaft spring 283, which will be described later, is contracted by the component force of the force and the force is removed. The guide shaft spring 283 is extended by the elastic force and restored to its original state.

In addition, it is preferable that the side surface of the scanning module interference part 292 is formed in a ladder shape, as shown in FIG. 2. In this way, even when the scanning module 290 is transferred from the first flat glass 250 side to the second flat glass 251, the above-described scanning module 290 is removed from the second flat glass 251 side. The same effect as in the case of being conveyed toward the one flat glass 250 can be obtained. However, the present invention is not limited thereto, and the scanning module interference unit 292 may be formed in various other forms as long as the same purpose can be achieved.

On the other hand, the scanning module interference unit 292 is responsible for the function of separating the scanning module 290 from the first or second flat glass 250, 251 by a predetermined interval. That is, since the height h of the scanning module interference part 292 means a distance between the main body of the scanning module 291 and the first or second flat glass 250, 251, the image is adjusted by adjusting the height h. The center of focus of the sensor can be properly adjusted.

In addition, although two scanning module interference parts 292 are illustrated in the accompanying drawings, the present invention is not limited thereto, and one or three or more scanning module interference parts may be formed.

In addition, the scanning module 290 is guided by the guide module 280 consisting of a guide shaft 281, the specific configuration of the guide module 280 is as follows.

That is, a guide hole (not shown) is formed in the scanning module 290, and a guide shaft 281 is inserted into the guide hole to guide the scanning module 290. Here, both ends of the guide shaft 281 are supported by the guide shaft holder 282, respectively, and one end of the guide shaft holder 282 which is not in contact with the guide shaft 281 is a guide shaft spring 283. Connected. In addition, the guide shaft holder 282 and the guide shaft spring 283 are disposed in the body frame groove 201a formed in the body frame 201 so as to secure a space capable of vertical flow. Here, one end of the guide shaft spring 283, which is not connected to the guide shaft holder 282, is fixed to the body frame 201 at a predetermined position.

That is, the bypass portion of the scanning module 290 is connected to the ADF bezel interference portion 270b, the scanning module interference portion 292, and the guide shaft 281, so that the upper and lower portions of the guide shaft 281 and the scanning module 290 are separated. A guide shaft spring 283 causing a flow. In addition, the bypass portion of the scanning module 290 may further include a guide shaft holder 282 for interconnecting the guide shaft 281 and the guide shaft spring 283.

Hereinafter, a process of bypassing the scanning module 290 by the bypass unit in the image forming apparatus 200 having the above configuration will be described in detail with reference to FIG. 3.

First, in the initial state, the scanning module 290 is in contact with the rear surface of the second flat glass 251 in the manual feeding mode (step 1).

Thereafter, when the ADF paper feed mode is switched, the scanning module 290 is transferred toward the first flat glass 250 in the direction of the arrow (step 2). In this process, the scanning module interference part 292 is brought into contact with the ADF bezel interference part 270b.

Then, since the scanning module 290 is in contact with the ADF bezel interfering unit 270b, the feeding is hindered, and thus the scanning module 290 is not horizontally fed and is fed obliquely along the direction of the arrow in the direction parallel to the inclined surface of the scanning module interfering unit 292 < Step 3>. That is, when the scanning module interferer 292 exerts a force on the inclined surface of the scanning module interferer 292 by contacting the ADF bezel interferer 270b, the guide shaft spring 283 shown in FIG. Due to the component force, it contracts, which has the effect of flowing the guide shaft 281 downward. Accordingly, the scanning module 290 guided by the guide shaft 281 is also moved downward so that it is eventually fed obliquely along the direction of the arrow as described above.

Then, when the transfer is in progress and the scanning module interferer 292 is completely in contact with the lower surface of the ADF bezel interferer 270b, the scanning module 290 again starts to move horizontally along the direction of the arrow. .

Then, when the transfer is further progressed so that the scanning module interferer 292 is spaced apart from the ADF bezel interferer 270b, the guide shaft spring 283 of FIG. 2 is restored to its original state according to the opposite principle of step 3 above. The scanning module 290 is in contact with the rear surface of the first flat glass 250 to be horizontally moved in the direction of the arrow (step 5).

As a result, the scanning module 290 can be smoothly transferred from the second flat glass 251 to the first flat glass 250 without any transfer shock or wear.

In addition, by doing so, the scanning module 290 is spaced apart from the first and second flat glass plates 250 and 251 by a considerable distance so that the scanning module 290 does not naturally contact the ADF bezel interference part 270b. It is possible to solve the problems with the prior art to prevent the transfer shock or wear as described above. That is, the prior art as described above has a problem in that the separation distance between the document and the image sensor is considerably increased so that the focal center of the image sensor such as the CIS is not aligned so that the quality of the scanned image is deteriorated.

3 illustrates an example in which the scanning module 290 is transferred from the second flat glass 251 to the first flat glass 250, but the scanning module 290 is the first flat glass 250. The same principle applies when conveying from the side to the second flat glass 251. Therefore, detailed description of this case will be omitted here.

4 is a side cross-sectional view of the image forming apparatus according to the second embodiment of the present invention, corresponding to FIG. 2 of the first embodiment, and FIG. 5 is a side cross-sectional view of the scanning module and the guide module of FIG. to be.

Referring to FIG. 4, the image forming apparatus 300 according to the second exemplary embodiment may include an automatic document feeder (ADF) 310, a tray 320, a first flat glass 350, and a second flat plate. A glass 251, ADF bezels 360 and 370, a scanning module 390 and a guide module 380 are provided.

Here, the first flat glass 350 and the second flat glass 351 are separated from each other, and the ADF bezel 370 is disposed at the boundary between the flat glass 350 and 351. Another ADF bezel 360 is disposed at the end of the first flat glass 350 located opposite the boundary. In addition, the ADF bezel 370 includes an original guide portion 370a and an ADF bezel interference portion 370b.

In addition, a scanning module interferer 392 is formed at an upper end of the scanning module 390. Here, the height h of the scanning module interference part 392 means a distance between the scanning module main body 391 and the first or second flat glass 350, 351.

In addition, the scanning module 390 is guided by the guide module 380. Here, the guide module 380 is a guide hole (not shown) formed in the scanning module 390, the guide shaft 381, the guide shaft holder 382, the guide shaft spring 383 and the guide shaft holder 382 And a body frame groove 301a which is a space in which the guide shaft spring 383 is installed. Here, one end of the guide shaft spring 383, which is not connected to the guide shaft holder 382, is fixed to the body frame 301 at a predetermined position.

The second embodiment differs from the first embodiment in that, instead of the scanning module 290 of the first embodiment, the scanning module 390 of the second embodiment includes a scanning module body 391 and a scanning module interference unit 392. In addition to the scanning module spring 393 and the scanning module roller 395 is further provided. Here, the scanning module spring 393 is disposed in the scanning module groove 391a so that one end thereof is fixed to the scanning module main body 391, and the scanning module spring 393 and the scanning module roller 395 have a scanning module roller holder ( 394). In addition, one end of the scanning module roller 395 which is not connected to the scanning module roller holder 394 may be in contact with the main body frame 301 at a predetermined position and slide over the main body frame 301.

By adding the scanning module spring 393 to the scanning module 390 as described above, the scanning module interference portion 392 is in contact with the ADF bezel interference portion 370b and perpendicular to the inclined plane of the scanning module interference portion 392. When the force is applied to, the scanning module spring 393 is primarily contracted by the force component of the force so that the scanning module 390 flows downward. In addition, when only the contraction of the spring 393 does not completely bypass the ADF bezel 370b, when the scanning module 390 does not completely bypass the ADF bezel 370b, the guide shaft spring 383 is additionally contracted to further reduce the scanning module 390 downward. Will flow.

In addition, the scanning module roller 395 serves to distribute the load of the scanning module 390. That is, the load of the scanning module 390 is distributed to the scanning module roller 395 and the guide shaft 381.

To this end, as shown in FIG. 5, when the scanning module 390 and the guide module 380 of FIG. 4 are viewed in the A direction, the guide module 380 is disposed at one side of the scanning module 390. The scanning module roller 395 may be disposed at the other side of the scanning module 390. Accordingly, the scanning module groove 391a, the scanning module spring 393 and the scanning module roller holder 394 are also arranged on the same line as the scanning module roller 395 in a predetermined direction.

According to the present invention, there can be provided an image forming apparatus that allows the scanning module to pass between the separated ends of the flat plate glass of the ADF section and the flat platen of the stationary document section without wear or transfer shock.

In addition, according to the present invention, an image forming apparatus capable of adjusting the depth of focus by narrowing the distance between the platen glass and the scanning module can be provided.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

Claims (5)

A first flat glass in contact with the document conveyed by the automatic document feeder; A second flat glass arranged in parallel with the first flat glass and in contact with the stopped original; A scanning module slidably installed on the rear surface of the first or second flat glass and scanning an image recorded on an original; A guide module for guiding the transfer of the scanning module and having a vertical flow structure; A structure disposed at a boundary between the first and second plate glass; And And a bypass portion that separates the scanning module from the structure when the scanning module passes through a boundary between the first and second flat glasses. The method of claim 1, The structure disposed at the boundary between the first and second flat glass is an ADF bezel holding the first flat glass and guiding the document leading end conveyed by the automatic sheet feeder as a discharge medium. Image forming apparatus. The method of claim 1, The bypass portion, An ADF bezel interference portion formed in the ADF bezel disposed at a boundary between the first and second plate glass; A scanning module interference part in contact with the ADF bezel interference part and formed in the scanning module; And A guide shaft provided in the guide module and a guide shaft spring connected to the guide shaft to cause a vertical flow of the guide shaft and the scanning module, And the scanning module interferes with the scanning module by an elastic force of the guide shaft spring when the scanning module interference portion comes in contact with the ADF bezel interference portion. The method of claim 3, wherein The scanning module is further provided with a scanning module spring for promoting the vertical flow of the scanning module, one end of the scanning module spring is fixed to the main body of the scanning module, the other end of the image forming apparatus characterized in that the scanning module roller is connected . The method according to any one of claims 1 to 4, And the scanning module includes a contact image sensor (CIS) or a charge coupled device (CSI) for converting an optical signal obtained by scanning the document into an electrical signal.

Images