Paper feeder and image forming device

Abstract

A paper feeder includes a sheet container including a platen member on which sheet-like recording media is placed, the platen member having one end portion on an upstream side of a paper feed direction rotatably supported to a spindle, such that the other end portion on a downstream side of the paper feed direction is lifted, and a paper feed member which draws and feeds the sheet-like recording media, and the sheet container includes a stepped portion which presses down the downstream side of the paper feed direction of the platen member when inserting the sheet container in the direction opposite to the paper feed direction, and a sliding portion which maintains the pressing down.

Description

PRIORITY CLAIM

The present application is based on and claims priority from Japanese Patent Application No. 2008-229894, filed on Sep. 8, 2008, the disclosure of which is hereby incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a paper feeder which draws a sheet-like recording medium such as paper from a paper feed tray, and feeds the sheet-like recording medium, and to an image forming device such as a copier, a printer, a facsimile each having the paper feeder, or a device having two of these functions.

2. Description of the Related Art

A conventional paper feeder including a unit which contains a stack of sheet-like recording media such as paper (hereinafter, recording paper) has a rotatable platen which biases the recording paper stack by means of a pressing unit such as a spring such that the top sheet of the recording paper stack has contact with a paper feed roller. In such a paper feeder, the top sheet of recording paper stack is fed by the paper feed roller, and the recording paper stack is separated sheet by sheet by a separator such as a friction pad.

FIG. 3 is a structural view of a conventional paper feeder, which illustrates a relationship between a feed part of recording paper P and a separator. Referring to FIG. 3, a paper feed roller 48 is disposed in the paper feeder on the downstream side of the paper feed direction of a paper feed tray, and a friction pad 49 which separates the recording paper P is disposed in the paper feed tray on the downstream side of the paper feed direction. The friction pad 49 is made of a material which generates dynamic friction resistance larger than that between recording paper, and generates predefined dynamic friction resistance by predetermined pressure applied from a spring 52 via a retaining member 51. When two sheets of the recording paper P are fed on top of one another, the sheet which has contact with the paper feed roller 48 is separated from the sheet which has contact with the friction pad 49 because the dynamic friction between the recording paper is smaller than the dynamic friction between the recording paper P and the friction pad 49.

The paper feed tray provided with the friction pad 49, the retaining member 51 and the spring 52 includes a platen 53 having a top face to which the recording paper P is placed. The end portion of the platen 53 on the paper feed roller 48 side is elastically biased upward by the spring 52, and is always biased in the direction of the paper feed roller 48 regardless of the carrying capacity of the recording paper.

If a paper feed operation is performed without placing the recording paper stack in an appropriate position, i.e., a large number of sheets exceed the friction pad 49 by inertia force or the like in the operation of the paper feed tray, the sheets are not separated. For this reason, the sheets are fed on top of one another. If the paper feed operation is performed without placing the recording paper stack in an appropriate position, i.e., more than the expected amount of recording sheets are disposed between the paper feed face and the paper feed roller, the paper feed roller becomes overloaded, resulting in the inability to rotate, which stops the feeding. Moreover, due to such an overload, the recording paper becomes damaged, and the paper feeder becomes overloaded, thereby causing problems relating to paper insertion and drawing operations of the paper feed tray.

In order to place the recording paper stack in an appropriate position, a paper feeder including mechanism capable of locking a platen in a lower position and releasing the lock when the paper feed tray is housed in the paper feeder is provided. When a user places the recording paper, the user locks the platen in this paper feeder.

FIG. 4 is a view illustrating the end portion of the platen on the paper feed roller side when the platen is locked in a lower position. In addition, reference number 41 denotes a paper feed tray. In this case, a user pushes down the platen 53 when placing the recording paper P, so as to lock the platen 53 in a defined position. Then, the user houses the paper feed tray 41 in the paper feeder, so that the paper feed operation is started while maintaining the recording paper in an appropriate position.

However, the paper feed tray may be inserted in the paper feeder without locking the platen 53 by an operation error of a user. FIG. 5 is a view illustrating a condition in which the platen is not locked in a lower position. Since a member which controls the recording paper P is not provided in the platen 53 on the downstream side of the paper feed direction, the recording paper P is placed in an inappropriate position by inserting and drawing the paper feed tray 41.

If the paper feed tray is housed in the paper feeder in this condition, the recording paper P is placed as illustrated in FIG. 6. FIG. 6 is a view illustrating the platen set in the paper feeder without being locked in a lower position. As illustrated in FIG. 6, a large number of sheets enter into a position exceeding the end portion of the friction pad 49 on the upstream side of the paper feed direction, so that the sheets are fed on top of one another upon the start of the paper feed operation. The paper feed roller 48 is thereby overloaded according to the amount of recording paper P that enters that position, resulting in the inability of the paper feed operation and damage to the recording paper. If the paper feed tray is overloaded, the inserting and drawing operation of the tray may not be able to be performed. Accordingly, the above problems depend on a user's operation as to whether performing the locking operation of the platen or not. A method of placing recording paper stack in an appropriate position by lowering a platen in response to the housing operation of a paper feed tray in the paper feeder is proposed. With this method, however, depending on the housing operation of the paper feed tray, inertia force relative to the recording paper is generated, so that the recording paper stack may not be placed in an appropriate position.

JP H05-97255A describes that a position of an end face is changed according to a position of recording paper when the recording paper is placed in an inappropriate position in a paper feed cassette, so as to prevent the recording paper from being damaged when the recording paper is placed in an inappropriate position. Moreover, JP2003-246480A describes that a control member which projects downwardly is provided in a part of an image forming device, so as to prevent a feeding error of a sheet by the running of the leading end of the sheet over a separation inclination face, which shifts the sheet in an inappropriate position.

The techniques described above are aimed to prevent sheets from being fed on top of one another. Such feeding, however, can not be completely prevented by the above techniques.

SUMMARY OF THE INVENTION

It is, therefore, an object of the present invention to provide a paper feeder which prevents a paper feeding error and an operation error by guiding recording paper to an appropriate position.

A first aspect of the present invention relates to a paper feeder, comprising: a sheet container including a platen member on which sheet-like recording media is placed, the platen member having one end portion on an upstream side of a paper feed direction rotatably supported by a spindle, such that the other end portion on a downstream side of the paper feed direction is lifted; and a paper feed member which draws and feeds the sheet-like recording media, the sheet container including a stepped portion which presses down the downstream side of the paper feed direction of the platen member when inserting the sheet container in the direction opposite to the paper feed direction, and a sliding portion which maintains the pressing down.

Preferably, the stepped portion and the sliding portion are pressed to a locking member by a biasing member which elastically supports the platen member.

Preferably, the stepped portion and the sliding portion are integrally provided in the platen member.

Preferably, the stepped portion is provided above a straight line connecting the spindle of the platen member and a leading end of the platen member.

Preferably, a relationship of Ls/L>f/F is satisfied where a biasing force of the platen member to the paper feed member is F, a sliding load in the platen member and the sliding portion is f, a distance from the spindle of the platen member to a biasing position is Ls, and a distance from the spindle to the stepped portion is L.

Preferably, the sheet container includes a control member which controls a top sheet of the sheet-like recording media, and a relationship of Lt/L>Y/y is satisfied where a height from a surface from which the sheet-like recording media is fed in the platen member to the control member is Y, a height of the stepped portion y, a distance from the spindle of the platen member to a leading end position of the platen member is Lt, and a distance from the spindle to the stepped portion is L.

Preferably, the stepped portion is formed in a circular shape and the circular stepped portion is concentric with the spindle of the platen member.

A second aspect of the present invention relates to an image forming device including the above paper feeder.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings are included to provide further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate an embodiment of the invention and, together with the specification, serve to explain the principle of the invention.

FIG. 1 is a view illustrating a schematic structure of an image forming device according to one embodiment of the present invention.

FIG. 2 is a view illustrating a structure of a paper feed tray in a paper feeder and a part of the image forming device near the paper feed tray.

FIG. 3 is a view illustrating a structure of a conventional paper feeder.

FIG. 4 is a view illustrating an end portion of a conventional platen on a paper feed roller side when the platen is locked in a lower position.

FIG. 5 is a view illustrating a conventional platen when the platen is not locked.

FIG. 6 is a view when the conventional platen is set in a main body of an image forming device without being locked in a lower position.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 1 illustrating a schematic structure of an image forming device according to one embodiment of the present invention, the image forming device is a tandem color image forming device of an indirect transfer system as a printer in which four color image forming units, cyan (C), magenta (M), yellow (Y) and black (K), each having one development station on an outer circumferential surface of an image carrier are arranged. In FIG. 1, the development station and the image carrier unit are mounted on the main body of the image forming device.

In FIG. 1, the color image forming device includes an optical writing station 2, an image forming station 3, a paper feed station 4, a fusing station 5, a paper discharging station 6, and a transport station 7.

The details of the optical writing station 2 are not illustrated in the figure. In the optical writing station 2, an LD unit as a light source emits laser light of respective colors, the respective emitted laser light is irradiated on photoreceptor drums 31C, 31M, 31Y, 31K, which are image carriers of the image forming units 30C, 30M, 30Y, 30K of the image forming station 3, via a polygon mirror and a plurality of reflection mirrors, so as to perform laser writing. The laser writing is conducted by irradiating laser light modulated by modulation signals obtained according to writing data, so that latent images are formed on the surfaces of the photoreceptor drums 31C, 31M, 31Y, 31K, respectively.

The image forming station 3 is disposed in the central portion of the main body of the image forming device 1, and includes the image forming units of respective colors 30C, 30M, 30Y, 30K, an intermediate transfer belt 38 as an image carrier, and a secondary transfer roller 39. The image forming units 30C, 30M, 30Y, 30K include the photoreceptor drums 31C, 31M, 31Y, 31K, respectively. Electrophotography forming elements are disposed along the outer circumference of each photoreceptor drum 31C, 31M, 31Y, 31K. In this embodiment, since the same structure is applied for each color, a reference sign for black (K) is only applied, and reference signs for other colors (C, M, Y) will be omitted. The image forming units each having the same structure are arranged in series along the moving direction of the intermediate transfer belt 38. Moreover, when generally describing each element, the reference signs indicating colors C, M, Y, K will be omitted.

The photoreceptor drum 31K includes, as the image formation elements, in the outer circumference thereof in the clockwise direction a charging roller 32K which charges the surface of the photoreceptor drum 31K, a development units 33K which houses developer including toner and develops a latent image on the photoreceptor drum 31K as a toner image, a primary transfer roller 34K which transfers the toner image on the photoreceptor drum 31K onto the intermediate transfer belt 38, a cleaning unit 35K having a cleaning blade which scrapes residual toner after the primary transfer, and an electricity removal unit (not shown) which removes electric charge remaining on the photoreceptor drum 31K after the primary transfer. The laser light 21K performs optical writing from an exposure unit 36K placed between the charging roller 32K and the development unit 33K. The image forming units 30C, 30M, 30Y, 30K are arranged in order along the movement direction (arrow A direction) of the intermediate transfer belt 38. The primary transfer roller 34K is disposed in a position which faces the photoreceptor drum 31K while sandwiching the intermediate transfer belt 38 therebetween. Reference number 37 is a collection unit which collects waste toner.

The secondary transfer roller 39 is provided on the upstream side of the paper feed direction of the intermediate transfer belt 38 of the image forming unit 30C while sandwiching a recording paper transport path 42 from the paper feed station 4 therebetween. The secondary transfer roller 39 transfers the toner image on the intermediate transfer belt 38 onto recording paper P (sheet-like recording media). In addition, the residual toner after the transfer of the secondary transfer roller 39 is cleaned by an intermediate transfer belt cleaning unit 38a provided on the upstream side of the image forming unit 30C which is the downstream side of the paper feed direction of the intermediate transfer belt 38 of the secondary transfer roller 39, and is sent to the image forming unit on the downstream side.

Negative bias voltage in which alternate current and direct current from a not shown bias power source are superimposed is applied to a core of the development roller 33a (33aK in FIG. 1) of each development unit 33. Direct negative voltage is applied to each charging roller 32 from another bias power source.

The cleaning blade of the cleaning unit 35 cleans toner remaining on the outer circumferential surface of the photoreceptor drum 31. The charging roller 32 uniformly charges the outer circumferential surface of the cleaned photoreceptor drum 31 to a high potential, so that the charged charging roller 32 is initialized. Then, the laser beam 21 is irradiated on the photoreceptor drum 31 of the image forming unit 30 of each color, and the outer circumferential surface of the photoreceptor drum 31 of each color, which is uniformly charged to high potential is selectively exposed by laser light modulated according to the image data. By this exposure, an electrostatic latent image having a low potential part in which the electric potential is attenuated by the exposure and a high potential part by the initialization is formed. The development unit 33 transfers the toner to the low potential part (or high potential part) of the electrostatic latent image so as to form (develop) the toner image. The photoreceptor drum 31 transfers the toner image to the intermediate transfer belt 38 while rotating and carrying the toner image.

The operation of image forming units 30K, 30Y, 30M, 30C is timely performed such that the four-color (CMYK) toner images formed on the outer circumferential surfaces of the photoreceptor drums 31K, 31Y, 31M, 31C, respectively, are timely transferred onto the same position of the intermediate transfer belt 38 to be overlapped, and a full color toner image is thereby formed.

The full color toner image on the intermediate transfer belt 38 is transferred onto the recording paper P transported along the transport path 42 from the paper feed station 4 by the secondary transfer roller 39, is fused by heat and pressure in the fusing station 5, and then is discharged onto the discharging tray 6b by the discharging roller 6a of the paper discharging station 6. Here, in a paper feed tray 41 (sheet container) of the paper feed station 4, which houses a recording paper stack, the recording paper P is separated sheet by sheet by a paper feed roller 48 (paper feed member) and a friction pad 49, the separated sheet is transported to the resist roller 46, and the leading end of the separated sheet of the recording paper P has contact with a nip of the resist roller 46 such that the leading end is aligned. The resist roller 46 temporarily stops the transport of the recoding paper P, and timely starts rotating such that the toner image of the intermediate transfer belt 38 and the leading end of the recording paper P are located in a predetermined position.

When forming an image on both faces of the recording paper P, an image is transferred onto the first face of the recording paper P by the secondary transfer roller 39. Then, the rotation direction of the paper discharging roller 6a is reversed when the back end of the recording paper P fused by the fusing station 5 is passed a switching point 71, and the leading end and the back end of the recording paper P are switched, and then the recording paper is transported to the transport path 72. The recording paper P is again transported to the resist roller 46 via a re-feeding path 74, and is sent to the secondary transfer roller 39 side by the resist roller 46 at the toner image's timing, which is formed on the intermediate transfer belt 38. Then, the toner image is transferred onto the second face of the recording paper P. The recording paper P having an image on the second face is fused by the fusing station 5, and discharged onto the discharging tray 6b from the paper discharging roller 6a. In addition, a filler 73 which detects paper is provided near the upstream side of the paper feed direction of the switching point 71. In addition, reference number 44 is a filler which detects the passage of the paper supplied from the paper feed tray 41 or the paper fed via the re-feeding path 74.

The paper feed station 4 includes the paper feed tray 41 which houses unused recording paper P. This paper feed tray 41 is disposed to be drawable in the right direction in FIG. 1 together with the friction pad 49 and the installation position of the re-feeding path 74 while leaving the paper feed roller 48, a sensor 45 which detects recording paper, and the like in the main body of the image forming device.

FIG. 2 is a view illustrating the structure of the paper feed tray in the paper feeder and the structure of a part of the image forming device near the paper feed tray. The paper feed tray 41 includes inside thereof a platen 53 (platen member). The platen 53 includes on both side portions thereof side walls 61 which extend in the paper feed direction. Since a spindle 62 (rotation axis) having both ends attached to the main body of the paper feeder penetrates the end portions of the side walls 61 on the upstream side of the paper feed direction, the platen 53 is rotatable about the spindle 62. A spring (biasing member) 54 is disposed in the back face of the platen 53 on the downstream side of the paper feed direction. The platen 53 is elastically biased upward by the spring 54, and is supported such that the end portion has elastic contact with the paper feed roller 48.

The side wall 61 of the platen 53 extends near the end portion of the platen 53 on the downstream side of the paper feed direction. The upper end portion of the side wall 61 includes a sliding face (sliding portion) 63 which substantially extends in the horizontal direction and has contact with a lower face of a rib (locking member) 64 provided in the main body of the image forming device. Since the sliding face 63 is formed in the upper end portion of the side wall 61, the sliding face 63 and the platen 53 move together. The height of the sliding face 63 is set such that the sliding face does not have contact with the rib 64 when the platen 53 is locked in a lower position as illustrated in FIG. 4. The sliding face 63 includes a circular stepped portion 63a which has contact with the rib 64 provided in the main body of the image forming device when the platen 53 is inserted into the main body of the image forming device without being locked in a lower position. The height of the sliding face 63 is also set such that the platen 53 is pushed down to the locking position by the rib 64 after passing through the stepped portion 63a when the platen 53 is set in the main body of the image forming device without being locked. In addition, reference number 65 is a control member which controls the top of the recording paper P stack, and is provided in the side wall of the paper feed tray 41.

The stepped portion 63a is provided above the straight line connecting the spindle 62 and the leading end of the platen 53. Accordingly, inertia force is applied to the recording paper P and sliding load of the recording paper P and the control member 65 is reduced by performing an operation lowering the platen 53; thus, the moving amount of the recording paper P by the inertial force can be improved. More particularly, if the paper feed tray 41 is inserted into the main body of the image forming device without locking the platen 53, the stepped portion 63a hits the rib 64, and then if the paper feed tray 41 is further pushed to the main body of the image forming device, the stepped portion 63a is guided by the rib 64, and the platen 53 is lowered. Therefore, the recording paper P can be placed in an appropriate position by the inertial force of the recording paper P in the inserting direction of the paper feed tray 41 when the stepped portion 63a hits the rib 64, and the upward inertial force of the recording paper P when the platen 53 is lowered. In addition, even if the paper feed tray 41 is inserted into the main body of the image forming device without locking the platen 53, the load by the contact and sliding between the recording paper P and the control member 65 can be reduced because the platen 53 is lowered. Since the stepped portion 63a has a circular form and is concentric with the spindle 62 which is the rotation axis of the platen 53, the reaction force in the stepped portion 63a can be constantly maintained regardless of an angle of the platen 53.

If a relationship of Ls/L>f/F is satisfied where biasing force of the platen 53 to the paper feed roller 48 is F, sliding load in the paper feed tray 41 and a sliding portion of the main body of the device is f, a distance from the spindle 62 of the platen 53 to a biased position is Ls, and a distance from the spindle 62 to the stepped portion 63a is L, the reaction force in the stepped portion which is necessary for moving the recording paper P to a regular position can be obtained while using the biasing force of the platen 53.

Since the paper feed tray 41 includes the control member 65 which controls the top of the recording paper P stack, if a relationship of Lt/L>Y/y is satisfied where a height from a surface from which the recording paper in the paper feed tray 41 is fed to the control member 65 is Y, a height of the stepped portion 63a is y, a distance from the spindle 62 to the position of the leading end of the platen 53 is Lt, and a distance from the spindle 62 to the stepped portion 63a is L, the recording paper P can be positioned in a regular position by lowering the top face of the recording paper P stack when inserting the paper feed tray 41 into the main body of the image forming device than the paper feed face.

As described above, when inserting the paper feed tray into the main body of the image forming device, the platen 53 slides with the rib 64 provided in the main body of the image forming device. The stepped portion 63a is provided on the sliding face 63 of the platen 53. When inserting the paper feed tray 41 into the main body of the image forming device with the platen 53 being locked in a lower position, the sliding portion 63 and the stepped portion 63a do not have contact with the rib 64; however, the stepped portion 63a has contact with the rib 64 when inserting the paper feed tray 41 into the main body of the image forming device without locking the platen 53 in a lower position, so that reaction force is generated in the platen 53. By this reaction force, inertial force is applied to the recording paper P, so that the recording paper P moves in the inserting direction of the paper feed tray 41 (position which controls the back end of the recording paper P. For this reason, the recording paper P can be moved to an appropriate position even when inserting the paper feed tray 41 without locking the platen 53; thus, the problems can be prevented. If the stepped portion 63a has contact with the rib 64, the platen 53 rotates in the direction lowering the platen 53, so that the sliding load of the control member 65 on the upper end of a sheet and the recording paper is reduced, and loss to the inertial force can be controlled. Therefore, the moving amount of the recording paper can be sufficiently ensured.

According to the embodiment of the present invention, when inserting the paper feed tray (sheet container) into the main body of the image forming device, the operational ability when inserting is increased, so that the inertial force is generated in the sheet-like recording paper which is not placed in an appropriate position. Therefore, the recording paper can be guided to an appropriate position, and the feeding error and operation error can be thereby prevented.

Although the embodiments of the present invention have been described above, the present invention is not limited thereto. It should be appreciated that variations may be made in the embodiments described by persons skilled in the art without departing from the scope of the present invention.

Claims

1. A paper feeder, comprising:

a sheet container including a platen member on which sheet-like recording media is placed, the platen member having one end portion on an upstream side of a paper feed direction rotatably supported to a spindle, such that the other end portion on a downstream side of the paper feed direction is lifted; and

a paper feed member which draws and feeds the sheet-like recording media,

the sheet container including a stepped portion which presses down the downstream side of the paper feed direction of the platen member when inserting the sheet container in the direction opposite to the paper feed direction, and a sliding portion which maintains the pressing down.

2. The paper feeder according to claim 1, wherein the stepped portion and the sliding portion are pressed to a locking member by a biasing member which elastically supports the platen member.

3. The paper feeder according to claim 1, wherein the stepped portion and the sliding portion are integrally provided in the platen member.

4. The paper feeder according to claim 2, wherein the stepped portion and the sliding portion are integrally provided in the platen member.

5. The paper feeder according to claim 1, wherein the stepped portion is provided above a straight line connecting the spindle of the platen member and a leading end of the platen member.

6. The paper feeder according to claim 1, wherein a relationship of Ls/L>f/F is satisfied where a biasing force of the platen member to the paper feed member is F, a sliding load in the platen member and the sliding portion is f, a distance from the spindle of the platen member to a biasing position is Ls, and a distance from the spindle to the stepped portion is L.

7. The paper feeder according to claim 1, wherein the sheet container includes a control member which controls a top sheet of the sheet-like recording media, and a relationship of Lt/L>Y/y is satisfied where a height from a surface from which the sheet-like recording media is fed in the platen member to the control member is Y, a height of the stepped portion y, a distance from the spindle of the platen member to a leading end position of the platen member is Lt, and a distance from the spindle to the stepped portion is L.

8. The paper feeder according to claim 1, wherein the stepped portion is formed in a circular shape and the circular stepped portion is concentric with the spindle of the platen member.

9. An image forming device comprising the paper feeder set forth in claim 1.