DE102008039275A1 - sheet feeder - Google Patents

Abstract

Image target media (P) stacked in a tray (12) are bent in a width direction orthogonal to a transmission direction, so that rigidity of the imaging target media (P) in the transfer direction becomes higher than the rigidity before bending. Accordingly, even when a separation imaging target medium (Ps) is bound to a transport imaging target medium (Pc) by using a link, the separation imaging target medium (Ps) is transferred to a imaging unit (28) by transport rollers (20) together with the transport imaging target medium (Pc), without bending in the transfer direction. Superimposed transfer of the imaging target media (P) is detected by sensors (22), and rotation of the transfer roller (14) is stopped. Due to this, the superimposed transfer of the imaging target media (P) is stopped just before the imaging unit (28).

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The The present invention relates to a sheet feeding apparatus, which sheet-like imaging target media transports to imaging units, which are provided in an image scanner or an image copier.

2. Description of the Related Art

A Sheet feeding device, in other words a so-called automatic document feeder (ADF), it is suggested which originals (sheet-like imaging target media) in succession transported to imaging units in an image scanner or a picture copier are provided.

In such a sheet feeder become under the originals, which are stacked in a tray, transport origins, which touch a transfer roller due to a Transfer the transfer roller in turn to the imaging units. When a separation master is stacked on the transport original, touches a separation unit of a separation roller, etc., the separation original and separates the separation master from the transport originals by Separating original in a direction opposite to the transport originals which transmit through the transfer roller in a transfer direction become. Due to this, the originals successively become the imaging units transported.

If the transport original and the separation original by a link such as a stapler at a forward end of the transfer direction are tied together and if the transport original and the separation original due to a rotational force of the transfer roller together transferred to the imaging units, recognizes Torque sensor current fluctuations of a DC (DC) motor, in other words detects load torque fluctuations of the DC motor, which rotatably drives the transfer roller. Thus, will a mass transfer or superimposed transfer the originals detected and is a rotary drive of the transfer roller stopped. Due to this, a transport of the originals is through the transfer roller interrupted.

However, when the transport original and the separation original through the link such as a stapler at a rear end of the transfer direction are tied together, the transport original through the transfer roller transported to the imaging units while the separation original by the separation unit of the separation roller, etc., from the transport original is disconnected. Because of this, the separation master is subjected to bending, so that ultimately a binding component of the link between the transport original and the separation original rips and a Jam of originals occurs.

Around to fix such a problem before the binding component between the transport original and the Trennoriginal rips and the Jam of originals occurs, it is necessary the rotary actuator stop the transfer roller and transport the To interrupt originals.

In the sheet feeding device, which in the Japanese Patent No. 3197029 is disclosed when the transport original and the separation original are bound together by the link such as a stapler at the rear end of the transfer direction and when the separation original which is separated by the separation roller from the transport original transported to the imaging unit is subjected to bending , the rotation of the transfer roller is stopped.

however must be in the above-disclosed sheet feeding device Dedicated sensor which detects a bend of the separation original, be provided. In this way, an electrical configuration complicate the device and cost of the device rise.

SUMMARY OF THE INVENTION

It It is an object of the present invention to solve the problems in the art at least partially solve conventional technology.

According to one aspect of the present invention, a sheet feeding apparatus includes: a tray in which sheet-like imaging target media are stacked; a transfer roller that rotates and, upon touching a single imaging target medium to be transported among the stacked imaging target media, transfers the contacted transport imaging target medium to an imaging unit; a separation unit that among the stacked imaging target media contacts a separation imaging target medium that is not to be transported, separating the separation imaging target medium by moving the separation image target medium in a direction opposite to the transport imaging target medium transferred to the imaging unit by the transfer roller, and transmitting the separation imaging target medium prevents the imaging unit; a rotatable drive unit which rotatively drives the transfer roller; a transport whale which rotates and which, upon contact of the transport imaging target medium transferred by the transfer roller, transports the contacted transport imaging target medium to an imaging position of the imaging target medium formed by the imaging unit; a detection sensor, which is provided between the transfer roller and the transport roller and which detects whether the imaging target media, which are transmitted by the transfer roller, only the transport imaging target media; and a control unit that, upon determining that the detected imaging target media includes the imaging media other than the transport imaging target media, stops rotation of at least the transfer roller via the rotary drive unit, wherein the tray includes a bending unit that transfers the stacked imaging target media from a rear to a front end a transmission direction in a direction which intersects the transmission direction of the imaging target media by the transfer roller, and reduces a degree of bending of the imaging target media from the rear end to the front end of the transfer direction.

The above and other tasks, features and advantages and a technical and industrial significance of this invention will be better understood By now, the following detailed description will be more preferred Embodiments of the invention is read when they considered in conjunction with the accompanying drawings becomes.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 10 is a sectional view of a sketch of a paper feeding apparatus according to a first embodiment of the present invention;

2 Fig. 15 is a perspective view of a bending unit of a tray of the sheet feeding apparatus;

3 Fig. 15 is a perspective view of a relation between the bending unit and an imaging target medium placed in the bending unit;

4 Fig. 15 is a perspective view of a relation between the bending unit and a plurality of imaging target media stacked in the bending unit;

5A and 5B Figures are perspective views of a sketch of detection sensors;

6 Fig. 10 is a flowchart of operations of an image scanner in which the sheet feeding apparatus according to the first embodiment is applied;

7A and 7B Fig. 15 is perspective views of a bending unit of a tray of a sheet feeding apparatus according to a second embodiment of the present invention;

8th Fig. 15 is a perspective view of a bending unit of a tray of a sheet feeding apparatus according to a third embodiment of the present invention;

9 Fig. 15 is a perspective view of a relation between a pressing member and a bending unit of a tray of a sheet feeding apparatus according to a fourth embodiment of the present invention;

10 Fig. 10 is a side view of a modification example of the pressure member;

11 Fig. 12 is a perspective view of a status when a thick imaging target medium is placed in the tray;

12 Fig. 10 is a side view of a printing member of a sheet feeding apparatus according to a fifth embodiment of the present invention; and

13 Fig. 10 is a side view of a printing member of a sheet feeding apparatus according to a sixth embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

exemplary Embodiments of the sheet feeding device according to the present invention will be hereinafter with reference to the accompanying drawings. However, the present invention is not limited to those described below To limit embodiments. Even if the sheet feeding apparatus according to the present invention Invention is provided in an image scanner, the sheet feeding device for example, be provided in an image copier, etc.

A sheet feeding apparatus according to a first embodiment of the present invention will be described below. 1 Fig. 10 is a typical sectional view of a sketch of the sheet feeding apparatus according to the first embodiment.

A sheet feeding device 10 includes a tray 12 , a transfer roller 14 , a separating roller 16 as a separation unit, an engine 18 as a rotatable drive unit, a pair of transport rollers 20 , a pair of detection sensors 22 and a control circuit 24 as a control unit.

Foliar imaging target media P are in the bin 12 stacked. As in 2 shown includes the tray 12 a bending unit 26 ,

As in 3 except for bending the imaging target medium P which is in the tray 12 is stacked, from a rear end to a front end of a transfer direction of the imaging target medium P by the transfer roller 14 , reduces the bending unit 26 in a direction intersecting the transmission direction, also a bending degree of the imaging target medium P from the rear end to the front end of the transmission direction. As in 2 shown includes the bending unit 26 in the first embodiment, a foundation member 26a representing the imaging target medium P stored in the tray 12 is stacked, facing, and a pair of bending links 26b , which on the foundation member 26a are provided at both edges of a width direction which is orthogonal to the transmission direction.

The foundation member 26a has the shape of a rectangular plate.

Furthermore, each bender is 26b on the foundation member 26a positioned and a bottom of each flexure 26b is in the foundation member 26a integrated. However, every bender can 26b detachable on the foundation member 26a be positioned to attach and disconnect each flexure 26b to and from the foundation member 26a to enable. Furthermore, the bending members 26b designed as a three-sided pillar and a length of the bending member 26b in the transmission direction is provided larger than a length of the bending member 26b in the width direction. A cross-sectional surface of each flexure 26b along the width direction propagates at the bottom with respect to a side surface of the bending unit 26 out. One side of the bender 26b at an edge of the width direction is perpendicular to the foundation member 26a , which forms a right-angled triangle along the transmission direction. Furthermore, the cross-sectional surface along the width direction is equal to the right-angled triangle along the transfer direction, and a surface area of the cross-sectional surface is reduced along the width direction. In other words, the bending members stand 26b from both edges of the bending unit 26 in a stacking direction of the imaging target media P, and a protrusion amount along the transfer direction becomes progressively smaller.

In addition, each bending member comprises 26b according to the first embodiment, a guide unit 27 , The leadership units 27 Regulate a movement of the imaging target media P, which are transmitted by the transfer roller, in the width direction. Every leadership unit 27 is in both sides of the width direction in the bending member 26b integrated. The leadership units 27 have the shape of rectangular plates and are on the bending members 26b provided with a plate thickness in the width direction. A tip of every leadership unit 27 along the stacking direction of the imaging target media P occupies the same position as that of a tip of each flexure member 26b at the rear end of the transfer direction. Because of this, in a section of the tray 12 in which the imaging target media P are stacked, from the rear end to the front end of the transfer direction, a portion of the flexures 26b which opposes the imaging target media P with an enlargement in an area of the guide units 27 , which faces the imaging target media P, progressively smaller. Accordingly, the opposing guide units regulate 27 the movement of the imaging target media P transmitted through the transfer roller in the width direction.

The transfer roller 14 transmits the imaging target media P which is in the tray 12 are stacked, to imaging units 28 , As in 4 shown touches the transfer roller 14 a transport imaging target medium Pc among the imaging target media P stored in the tray 12 are stacked. The motor 18 turns the transfer roller 14 , and the transfer roller 14 transmits the touched transport imaging target medium Pc to the imaging units 28 ,

Among the imaging target media P, which in the tray 12 Stacked, prevents the separation roller 16 a transfer of the separation image target medium Ps, which does not belong to the imaging units 28 to be transported. The separation roller 16 touches the separation imaging target medium Ps, which is not to be transported, among the imaging target media P stored in the tray 12 are stacked. Furthermore, the separation roller separates 16 the touched separation imaging target medium Ps from the transport imaging target medium Pc by moving the separation imaging target medium Ps in a direction opposite to the transport imaging target medium Pc passing through the transfer roller 14 to the imaging units 28 whereby transfer of the separation image-targeting medium Ps to the imaging units 28 is prevented. To further explain, the transfer roller is 14 opposite the separation roller 16 positioned. A torque limiter (not shown) is attached to a rotation shaft of the separation roller 16 attached. When the imaging target media P passes through the transfer roller 14 to the imaging units 28 be transferred, the separation roller rotates 16 at a slower rotational speed than the rotational speed of the transfer roller 14 , As a result, the separation roller moves 16 the separation image target dium Ps in the direction opposite to the transport imaging target medium Pc, and prevents transmission of the separation imaging target medium Ps to the imaging units 28 ,

The motor 18 drives the transfer roller 14 turning on. The motor 18 , which with the rotating shaft of the transfer roller 14 is coupled, receives a power supply from the control circuit 24 and turns the transfer roller 14 ,

The transport rollers 20 transport the transport imaging target medium Pc to an imaging position of the imaging target medium P through the imaging units 28 is formed. The transport rollers 20 are with a motor 29 coupled with the control circuit 24 connected is. The transport rollers 20 rotate due to a driving force of the motor 29 that of the control circuit 24 Power is applied to touch the transport imaging target medium Pc, which passes through the transfer roller 14 is transferred, and transport the touched transport imaging target medium Pc to the imaging position of the imaging target medium P, which is detected by the imaging units 28 is formed.

The detection sensors 22 recognize whether the imaging target media P passing through the transfer roller 14 are transmitted, only the transport mapping target media Pc. The detection sensors 22 are between the transfer roller 14 and the transport rollers 20 intended. As in the 5A and 5B shown are the detection sensors 22 for example, ultrasonic sensors. In the first embodiment, a pair of the detection sensors 22 arranged so that a transport path is located between them, which is a moving location of the imaging target medium P, and are the detection sensors 22 along a thickness direction of the imaging target medium P passing through the transfer roller 14 is transferred, placed opposite each other. Furthermore, the detection sensors judge 22 In the first embodiment, ultrasonic waves are incident on the imaging target medium P and detect a variation amount of the ultrasonic waves subjected to variation as they pass through the imaging target medium P.

The control circuit 24 controls a rotation of the transfer roller 14 over the engine 18 , The control circuit 24 is with the engine 18 connected. If the detection sensors 22 recognizing that the imaging target media P is not only the transport imaging target media Pc stops the control circuit 24 the power supply of the engine 18 and stops a rotation of the transfer roller 14 over the engine 18 , In the first embodiment, a threshold value of an output level of the detection sensors becomes 22 between the output level of the detection sensors 22 if the detection sensors 22 only recognize an imaging target medium P, and the output level of the detection sensors 22 set when the detection sensors 22 recognize more than two imaging target media P When the output level of the detection sensors 22 is lower than the threshold, determines the control circuit 24 in that the imaging target media P generated by the detection sensors 22 not only the transport mapping target media Pc are. In other words, if the output level of the detection sensors 22 is less than the threshold, determines the control circuit 24 in that the imaging target media P generated by the detection sensors 22 be recognized, more than two are. Furthermore, when it is determined that the imaging target media P generated by the detection sensors 22 If more than two are detected, the control circuit stops 24 the power supply of the engine 18 and stops a rotation of the transfer roller 14 ,

When an instruction to start scanning the imaging target media P is input through a scan switch (not shown), the control circuit feeds 24 Energy both in the engine 18 as well as in the engine 29 and turns the transfer roller 14 or the transport rollers 20 , Further, when an instruction to stop scanning the imaging target media P is inputted by a scan stop switch (not shown), the control circuit stops 24 at least the power supply of the engine 18 and stops at least one rotation of the transfer roller 14 , In the first embodiment, when the command is input to stop scanning the imaging target media P, the control circuit stops 24 the power supply of the engine 18 and the engine 29 and stops a rotation of the transfer roller 14 which by the engine 18 is driven, and also stops a rotation of the transport rollers 20 which by the engine 29 are driven.

As in 1 shown is a pair of discharge rollers 30 in the transfer direction of the imaging target media P downstream, in front of the imaging units 28 , and are the output rollers 30 arranged opposite to each other so that the transport path lies between them, which is the moving location of the imaging target medium P.

Leaves, Overhead Projector (OHP) transparencies etc. may act as the imaging target media P mentioned above can be used.

The following are operations of the sheet feeding apparatus 10 explained according to the first embodiment of the present invention.

6 Fig. 10 is a flowchart of the operations of the sheet feeding apparatus.

When the imaging target media P in the tray of the sheet feeder 10 is stacked, and when the scan switch (not shown) of the image scanner is pressed, the command to start scanning the imaging target media P becomes the control circuit 24 entered, and energy gets into the engine 18 and the engine 29 from the control circuit 24 fed (Yes in step S100). Because of this, the transfer roller 14 and the transport rollers 20 rotated (step S102). This starts the image scanner in which the sheet feeding device 10 is applied, a process of scanning the imaging target media P. Next, the bending unit bends 26 the filing 12 the imaging target media P, which in the tray 12 are stacked, in the direction which the transmission direction of the imaging target media P by the transfer roller 14 cuts, that is, the bending unit 26 Bends the imaging target media P in the width direction, which is orthogonal to the transfer direction.

Among the imaging target media P, which in the tray 12 When a single transport imaging target medium Pc is not bound to the separation imaging target medium Ps by using the link such as a stapler, the transport imaging target medium Pc contacts the transferring roller 14 , which is a rotatable driving force of the motor 18 receives, and the transport imaging target medium Pc due to the rotational force of the transfer roller 14 to the imaging units 28 transported. On the other hand, when the separation imaging target medium Ps is the separation roller 16 touches, a frictional force between the separation image target medium Ps and the separation roller 16 generated. Due to this, the separation imaging target medium Ps is separated from the transport imaging target medium Pc by moving the separation imaging target medium Ps in the direction opposite to the transport imaging target medium Pc passing through the transfer roller 14 to the imaging units 28 and transfer of the separation image-targeting medium Ps to the imaging units 28 will be prevented. As a result, only the transfer imaging target medium Pc to be transferred is passed through the transfer roller 14 transfer.

Alternatively, when the separation imaging target medium Ps does not pass through the separation roller 16 is separated from the transport imaging target medium Pc passing through the transfer roller 14 to the imaging units 28 or when the separation imaging target medium Ps and the transport imaging target medium Pc passing through the transfer roller 14 to the imaging units 28 are transferred at the front end of the transfer direction by using the link such as a stapler, the transfer imaging target medium Pc and the separation imaging target medium Ps become due to the rotational force of the transfer roller 14 indicating the rotational driving force of the motor 18 receives, together to the imaging units 28 transfer. For example, even if the separation imaging target medium Ps and the transport imaging target medium Pc passing through the transfer roller 14 to the imaging units 28 is transferred at the end of which the transfer direction is tied together by using the link such as a stapler, the separation imaging target medium Ps is formed together with the transfer imaging target medium Pc by the bending unit 26 bent along the width direction to strengthen a rigidity in the transfer direction as described above. In particular, since the rigidity in the transfer direction is increased from the rigidity before bending, the release image target medium Ps bends when it is the separation roller 16 touched, not in the transmission direction. As a result, the separation imaging target medium Ps, which is connected to the transport imaging target medium Pc through the transfer roller 14 to the imaging units 28 is transferred at the rear end of the transferring direction by using the link such as a stapler, together with the transfer imaging target medium Pc due to the rotational force of the transfer roller 14 to the imaging units 28 transported. In other words, when a plurality of imaging target media P, which are bound together at the rear end of the transfer direction by using the link, are passed through the transfer roller 14 which transmits the rotational drive force of the motor 18 receives, a plurality of imaging target media P together to the imaging units 28 transported.

Subsequently, the imaging target medium P passing through the transfer roller 14 is transmitted to the imaging position by the imaging units 28 is formed by the detection sensors 22 detected (step S104). Specifically, ultrasonic waves are directed to the imaging target medium P, and the amount of variation of the ultrasonic waves that are subjected to variation as they pass through the imaging target medium P is detected by the detection sensors 22 recognized.

When the output level of the detection sensors 22 is greater than the threshold, determines the control circuit 24 in that only the transport imaging target medium Pc in a recognition position of the imaging target medium P in the recognition sensors 22 is positioned. When the control circuit 24 determines only the transport imaging target medium Pc in the detection position of the imaging target medium P in the detection sensors 22 is positioned, in other words, when the imaging target medium P, which by the detection sensors 22 is detected, only the transport imaging target medium Pc is, the transport imaging target medium Pc by the transport rollers 20 transported to the imaging position, which by the imaging units 28 is formed (Yes in step S104), images of the transport image target medium Pc are made by the imaging units 28 is made (step S106), and image data corresponding to the transport image target medium Pc is generated by using an image data generating circuit (not shown) of the image scanner (step S108). When the scan stop switch (not shown) of the image scanner is depressed, the command to terminate scanning of the imaging target media P is input to the control circuit 24 is input (Yes in step S110) and becomes the power supply of the motor 18 and the engine 29 from the control circuit 24 stopped. Due to this, rotation of the transfer roller becomes 14 and the transport rollers 20 stops, and stops the image scanner, in which the sheet feeding device 10 is applied, the process of scanning the imaging target media P (step S112). When the command to terminate scanning of the imaging target media P does not enter the control circuit 24 is input (No in step S110) while the control circuit 24 determines whether the imaging target medium P detected by the detection sensors 22 is detected, only the transport imaging target medium Pc, images of the transport imaging target medium Pc are processed by the imaging units 28 and the image data corresponding to the transport image target medium Pc is recreated.

On the other hand, if the output level of the detection sensors 22 is lower than the threshold, determines the control circuit 24 in that the imaging target media P generated by the detection sensors 22 not only the transport imaging targets are in PC, in other words the control circuit recognizes 24 a so-called mass transfer in which more than two imaging target media P are transmitted. When the control circuit 24 the mass transfer of the imaging target media P determines, in other words, when it is recognized that a plurality of imaging target media P are to the transport rollers 20 is transmitted, the power supply of the engine 18 and the engine 29 from the control circuit 24 stopped (No in step S104). As a result, rotation of the transfer roller becomes 14 and the transport rollers 20 stopped. Due to this, transfer of the transport-image target media Pc through the transfer roller becomes 14 and transporting the transport imaging target media Pc through the transport rollers 20 stopped. Therefore, a plurality of imaging media P will not pass through the transport rollers 20 transported to the imaging position, which by the imaging units 28 is formed, however, a transport of the imaging target media P just before the transport rollers 20 stopped, and interrupts the image scanner, in which the sheet feeding device 10 is applied, the process of scanning the imaging target media P (step S114). Subsequently, by using an informing unit such as a display screen or an indicator lamp (not shown) informing the user of a non-normal condition of the image scanner, a user is informed that the scanning process is interrupted.

As mentioned above, although no dedicated sensor is provided which detects bending of the separation imaging target medium Ps, and even if a plurality of sheet-like imaging target media P are bound together at a rear end of the transfer direction by using the link, transport of the imaging target media P may tied to the imaging position, which by the imaging units 28 is formed, be suppressed. In other words, the mass transport of a plurality of sheet-like imaging target media P to the imaging position provided by the imaging units 28 is formed, be suppressed.

In the sheet feeder 10 of the first embodiment can, by a simple structure of the bending unit 26 is used, which is the foundation member 26a and a pair of flexures 26b includes the rigidity of the imaging target media P stored in the tray 12 stacked are increased in the transmission direction.

In the bending unit 26 can, since the degree of bending of the imaging target media P, which in the tray 12 are stacked, decreases from the rear end to the front end of the transfer direction, the imaging target media P easily to the transfer roller 14 and the separation roller 16 be transferred.

If the imaging target media P which is in the tray 12 are stacked to the transfer roller 14 and the separation roller 16 is transferred, the movement of the imaging target media P in the width direction by the guide units 27 the bending unit 26 regulated. Accordingly, a displacement of the imaging target media P by the bending unit 26 be bent in the width direction are prevented.

As mentioned previously, a plurality of sheet-like imaging target media P which are bound together at the rear end of the transfer direction are due to the rotational force of the transfer roller 14 transferred directly from the shelf. Therefore, rippling of the imaging target media P due to the binding component of the imaging media P which are bound together by using the link and jamming of the imaging target media between the transfer roller 14 and the separation roller 16 occurs, be suppressed.

In the first embodiment, when the imaging target media P generated by the detection sensors 22 Not only are the transport mapping target media Pc detected, the control circuit stops 24 the power supply of the engine 18 and the engine 29 and stops a rotation of the transfer roller 14 and the transport rollers 20 , However, the present invention is not limited thereto. In the present invention, the sheet feeding device may be structured such that when the imaging target media P generated by the detection sensors 22 not only the transport imaging target media Pc, a rotatable drive unit is rotation of at least the transfer roller 14 stops, for example, stops the control circuit 24 the power supply of the engine 18 and stops a rotation of the transfer roller 14 ,

In the first embodiment, although the separation roller 16 As a separation unit, the present invention is not limited thereto. For example, in the present invention, a partition plate may be used as a separation unit and may be opposite to the transfer roller 14 be arranged. When the partition plate contacts the separation image target medium Ps, a frictional force in a direction opposite to the transfer direction can be exerted on the separation image target medium Ps, and the separation image target medium Ps can be separated from the transport image target medium Pc by moving the separation image target medium Ps in the direction opposite to the transport image target medium Pc ,

A sheet feeding apparatus according to a second embodiment of the present invention will be explained below. 7A and 7B Fig. 15 are perspective views of a bending unit of a tray of the sheet feeding apparatus according to the second embodiment. Structural components that are the same as the first embodiment described above have identical reference numerals, and a redundant explanation thereof will be omitted.

As in 7A shown has the filing 12 in the second embodiment, a rectangular shape. Filing 12 is from the foundation member 26a which is disposed in a middle portion of the width direction, and a pair of the bending members 26b shaped, which are arranged at both edges of the width direction.

A surface of the foundation member 26a which faces the imaging target medium P is an isosceles trapezoidal plate having a broad base along the transmission direction. Alternatively, the surface of the foundation member 26a which faces the imaging target medium P, be an isosceles triangular plate having a broad base along the transmission direction.

A surface of each bender 26b which faces the imaging target medium P is a rectangular triangular plate, and a dimension of each flexure 26b in the width direction becomes progressively smaller along the transmission direction. Each bending member 26b is on the foundation member 26a fastened by using joints. As in 7B shown is each bender 26b on both edges of the foundation member 26a supported in the width direction by the joints such that each flexure 26b over the foundation member 26a can be raised. If over the foundation member 26a lifted, stands every bender 26b in a stacking direction of the imaging target media P, and a protrusion amount along the transmission direction becomes progressively smaller.

In the sheet feeder 10 According to the second embodiment, a pair of the bending members 26b supported by the joints such that each flexure 26b over the foundation member 26a can be raised. Due to this, the user can select whether the imaging target media P stored in the tray 12 stacked, to be bent. The remaining structural components in the second embodiment are the same as mentioned in the first embodiment.

A sheet feeding apparatus according to a third embodiment of the present invention will be explained below. 8th FIG. 15 is a perspective view of a bending unit of a tray of the sheet feeding apparatus according to the third embodiment. FIG. The structural components that are the same as the first and second embodiments described above bear identical reference numerals, and a redundant explanation thereof will be omitted.

In the third embodiment, at least one of the two bending members 26b the bend unit 26 , which is described in the first embodiment, stored such that the bending member 26b over the foundation member 26a is displaceable along the width direction. In particular, as in 8th shown are both bending members 26b stored such that the bending members 26b along the width direction over the foundation member 26a can slide.

To further explain each bending member 26b comprises a rectangular plate-shaped sliding unit in addition to the guide unit 27 which will be described in the first embodiment. Each sliding unit is thick in the stacking direction of the imaging target medium P and is slidably mounted on rail members (not shown) extending along the width direction on the foundation member 26a are attached. Due to this, each slide unit is slidable along the rail members in the width direction, whereby the bending members 26b along the width direction over the foundation member 26a can be moved. In the third embodiment set both bending members 26b a center line in the width direction of the foundation member 26a as a center ahead and slide along the width direction in conjunction with each other via the foundation member 26a , If only one of the two benders 26b slidable on the foundation member 26a is stored, one of the two bending members 26b on the foundation member 26a be fixed while the other may be stored such that the other bending member 26b can slide along the rail members, which on the foundation member 26a are fixed along the width direction.

In the sheet feeder 10 According to the third embodiment, at least one of the two bending members 26b or are both of the bending members 26b supported such that the bending members along the rail members in the width direction via the foundation member 26a can slide. Due to this, a distance between the bending members 26b be adjusted according to a size of the imaging target medium P in the width direction. As a result, the imaging target medium P can be bent in accordance with the size. The remaining structural components in the present embodiment are the same as those mentioned in the first embodiment.

A sheet feeding apparatus according to a fourth embodiment of the present invention will be explained below. 9 FIG. 15 is a perspective view of a bending unit of a tray of the sheet feeding apparatus according to the fourth embodiment. FIG. The sheet feeding device 10 According to the fourth embodiment, in addition to each of the first to third embodiments, a pressing member 34 The picture target media P working in the bin 12 stacked, towards the filing 12 press and the imaging target media P bends. The structural components that are the same as the first, second, and third embodiments described above bear identical reference numerals, and a redundant explanation thereof will be omitted.

The sheet feeding device 10 According to the fourth embodiment, the pressure member comprises 34 , which opposite the filing 12 is placed and a pressure and bending unit 34a and a carrier unit 34b includes.

The printing and bending unit 34a pushes the imaging target media P stacked in the tray toward the tray 12 and bends the imaging target media P according to a shape of the bending unit 26 , The printing and bending unit 34a has a spherical shape. Alternatively, the pressure and bending unit 34a be shaped as a log, as in 10 shown.

The carrier unit 34b that the printing and bending unit 34a carries at the front end, has the shape of a long staff. In such a carrier unit 34b is a proximal portion of the carrier unit 34b on an opposite side of the printing and bending unit 34a fixed to a housing of the image scanner, in which the sheet feeding device 10 is applied.

As in 11 shown when a thick imaging target medium P in the tray 12 in other words, when the imaging target medium P, which has a higher rigidity than a thin imaging target medium P, in the tray 12 is stacked, bending of the imaging target medium P is suppressed. However, as in 9 shown in the sheet feeder 10 according to the fourth embodiment, by pushing the imaging target medium P toward the tray 12 , wherein the pressure and bending unit 34a of the pressure member 34 is used, the imaging target medium P according to the shape of the bending unit 26 bent. As a result, the rigidity of the imaging target medium P in the transfer direction can be further increased.

In the fourth embodiment, when the proximal portion of the carrier unit 34b on the opposite side of the printing and bending unit 34a is fixed, the carrier unit 34b be structured so as to bend approximately in the stacking direction of the imaging target medium P.

A sheet feeding apparatus according to a fifth embodiment of the present invention will be explained below. 12 Fig. 10 is a typical sectional view of a sketch of the sheet feeding apparatus according to the fifth embodiment. In the sheet feeder 10 According to the fifth embodiment, the proximal portion of the carrier unit 34b on the opposite side of the printing and bending unit 34a as a center, and the pressure member 34 which is described in the fourth embodiment can oscillate around the center. Furthermore, structural components that are the same as the fourth embodiment described above carry identical reference numerals, and a redundant explanation thereof will be omitted.

Depending on a bearing force due to a compressive force, which by the pressure and bending unit 34a is applied to the imaging target medium P, the printing and bending unit 34a of the pressure member 34 According to the fifth embodiment, approximately in the stacking direction of the imaging target medium P is oscillated around the center, that is, the proximal portion of the support unit 34b , In the carrier unit 34b to the printing and bending unit 34a towards the filing 12 To pretension, the proximal portion on the opposite side of the pressure and bending unit 34a be biased by a biasing member such. B. a leaf spring is used.

In the sheet feeder 10 according to the fifth embodiment, depending on the bearing force due to the pressing force, which by the pressure and bending unit 34a is applied to the imaging target medium P, the pressure member oscillates 34 around the center, that is the proximal portion of the carrier unit 34b on the opposite side of the printing and bending unit 34a , Due to this, a load may be generated by the pressure and bending unit 34a is applied to the imaging target medium P, as compared to the load which is transmitted through the pressure member 34 is exercised, wherein the proximal portion of the carrier unit 34b on the opposite side of the printing and bending unit 34a not oscillated (the pressure member 34 according to the fourth embodiment described above).

A sheet feeding apparatus according to a sixth embodiment of the present invention will be explained below. 13 Fig. 10 is a typical sectional view of a sketch of the sheet feeding apparatus according to the sixth embodiment. In the sheet feeder 10 according to the sixth embodiment has the pressure and bending unit 34a of the pressure member 34 according to the fourth embodiment, the shape of a sliding roller, and the frictional force between the pressure and bending unit 34a and the imaging medium P is reduced. Further, structural components that are the same as the fourth embodiment described above carry identical reference numerals, and a redundant explanation thereof will be omitted.

In the sheet feeder 10 according to the sixth embodiment has the pressure and bending unit 34a of the pressure member 34 the shape of the sliding roller, which passes through the carrier unit 34b what is a free rotation of the printing and bending unit 34a allowed. The sliding roller according to the sixth embodiment slides by rotating with respect to the pressed imaging target medium P together with the movement of the pressed imaging target medium P in the transmission direction.

In the sheet feeder 10 according to the sixth embodiment, when the imaging target medium P, formed by the printing and bending unit 34a of the pressure member 34 is pressed, moved along the transfer direction, slides the pressure and bending unit 34a by rotating with respect to the imaging target medium P. This may increase the frictional force between the pressure and flexure units 34a and the imaging target medium P, can be suppressed without reducing the pressing force exerted by the printing and bending unit 34a of the bending member 34 is applied to the imaging target medium P.

According to an embodiment of the present invention, imaging target media stacked in a tray by using a tray bending unit is bent in a direction crossing a transmission direction of the imaging target media by a transfer roller, for example, in a width direction orthogonal to the transfer direction is. A rigidity of the imaging target media stacked in the tray is increased along the transfer direction against the rigidity of the imaging target media before bending. Accordingly, when a transport imaging target medium and a separation imaging target medium are bound together by using a link such as a stapler, and when the transport imaging target medium is transferred to the imaging units by the imaging roller, the separation imaging target medium is transferred to the imaging units, along with the transport imaging target medium without getting lost to bend in the transfer direction. In other words, when a plurality of imaging target media, which are bound together by the link, are transmitted through the transfer roller, a plurality of imaging target media are transferred together to the imaging units. Further, recognition sensors recognize that the imaging target media being transferred to transport rollers are not only the transport imaging target media, in other words, the recognition sensors recognize that a plurality of images are displayed tion target media are transmitted to the transport rollers, and a control unit stops rotation of at least the transfer roller. As a result, a plurality of imaging target media are not transported by the transport rollers to an imaging position formed by the imaging units, and transportation is stopped just in front of the transport roller. Thus, even if no dedicated sensor is provided which detects bending of the separation imaging target media when a plurality of imaging target media are bound by the link, transport of a plurality of imaging target media bound together to the imaging position formed by the imaging units to be suppressed.

According to one Embodiment of the present invention reduced a degree of bending of the imaging target media stored in the tray are stacked, from a rear end to a front end of the transfer direction. Therefore, the imaging target media can easily be transferred to the transfer roller and a separation unit.

According to one Embodiment of the present invention comprises the bending unit comprises a foundation member and a pair of bending members. by virtue of such a simple structure of the bending unit can be a rigidity of the imaging target media stacked in the tray, in FIG the transmission direction can be increased.

According to one Embodiment of the present invention is a Pair of bending members mounted so that the bending members on the foundation member can be raised. Therefore, a Users choose whether the imaging target media is bent should be.

According to one Embodiment of the present invention is at least one of the two bending members mounted such that the bending member via the foundation member can slide along the width direction. Therefore may be a distance between the two bending members corresponding to one Size of the imaging target media in the width direction be adjusted. Due to this, the imaging target media can be bent according to the size.

According to one Embodiment of the present invention, when the Imaging target media stacked in the tray to the transfer roller and the separation unit are transferred, the movement of the Imaging target medium along the width direction regulated by Guide units are used. Consequently, a Displacement of the imaging target media, which by the bending unit be bent in the width direction are prevented.

According to one Embodiment of the present invention, when thick Imaging target media are stacked in the tray, in other words if the imaging target media, the higher rigidity own as a thin picture target media, in the clipboard stacking, bending of the imaging target media is suppressed. However, since the imaging target media are through the printing and bending unit bend the bender in the direction of the tray are the imaging target media according to a form of Bending unit bent. As a result, the rigidity of the imaging target media be further increased in the transmission direction.

According to one Embodiment of the present invention, depending from a bearing force due to a compressive force, which by the Pressing and bending unit applied to the imaging target media is, the pressure member oscillates when a proximal portion of the Carrier unit is considered as a center. by virtue of its may be a load passing through the pressure and bending unit is added to the imaging target media with the bending member, wherein the proximal portion of the support member not oscillated, be reduced.

According to one Embodiment of the present invention, when the imaging target media formed by the printing and bending unit of the Bending member are pressed along the transmission direction move, the printing and bending unit slides with respect to the imaging target media. Therefore can be an increase in a frictional force, which between the printing and bending unit and the imaging target medium occur, be suppressed without the pressure force on the imaging target media which was exerted by the pressure and bending unit becomes.

Even though the invention for a complete and clear Disclosure with respect to specific embodiments should be described, the appended claims should not be limited to it but should be interpreted Be that they have all the modifications and alternative constructions embody what a professional can come up with and which fall entirely into the basic teaching set forth herein.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - JP 3197029 [0007]

Claims (8)

A sheet feeding device ( 10 ), comprising: a file ( 12 ) in which sheet-like imaging target media (P) are stacked; a transfer roller ( 14 ) which rotates and when touching a single imaging target medium (P) to be transported among the stacked imaging target media (P), the contacted transport imaging target medium (Pc) to an imaging unit (FIG. 28 ) transmits; a separation unit ( 16 ) touching, among the stacked imaging target media (P), a separation image target medium (Ps) that is not to be transported, separating the separation image target medium (Ps) by moving the separation image target medium (Ps) in a direction opposite to the transport image target medium (Pc) through the transfer roller ( 14 ) to the imaging unit ( 28 ), and transmission of the separation image-targeting medium (Ps) to the imaging unit (FIG. 28 ) prevented; a rotatable drive unit ( 18 ), which the transfer roller ( 14 ) rotates; a transport roller ( 20 ) which rotates and which upon contact of the transport imaging target medium (Pc) passing through the transfer roller (FIG. 14 ), the transported transport imaging target medium (Pc) is transported to an imaging position of the imaging target medium (P) which is detected by the imaging unit (P). 28 ) is formed; a recognition sensor ( 22 ), which between the transfer roller ( 14 ) and the transport roller ( 20 ) is provided and which detects whether the imaging target media (P), which by the transfer roller ( 14 ), only the transport mapping target media (Pc) are; and a control unit ( 24 ), which, upon determining that the detected imaging target media (P) comprises the imaging media other than the transport imaging target media (Pc), rotates at least the transfer roller (16) 14 ) via the rotatable drive unit ( 18 ) stops, wherein the tray ( 12 ) a bending unit ( 26 ) which bends the stacked imaging target media (P) from a back to a front end of a transfer direction in a direction which controls the transfer direction of the imaging target media (P) through the transfer roller (12). 14 ) and reduces a degree of bending of the imaging target media (P) from the rear end to the forward end of the transfer direction. The sheet feeding device ( 10 ) according to claim 1, wherein the bending unit ( 26 ) a foundation member ( 26a ) facing the stacked imaging target media (P) and a pair of flexures (FIG. 26b ), which on the foundation member ( 26a ) are mounted on both edges of a width direction that is orthogonal to the transmission direction, and the bending members ( 26b ) protrude in a stacking direction of the imaging target media (P) and a protrusion amount along the transfer direction decreases. The sheet feeding device ( 10 ) according to claim 2, wherein the bending members ( 26b ) at both edges of the width direction of the foundation member ( 26a ) are mounted such that the bending members ( 26b ) over the foundation member ( 26a ), and the bending members ( 26b ) when lifting lateral surfaces of the foundation member ( 26a ) protrude in a stacking direction of the imaging target media (P) and the protrusion amount decreases along the transfer direction. The sheet feeding device ( 10 ) according to claim 2, wherein at least one of the two bending members ( 26b ) is mounted such that the bending member ( 26b ) over the foundation member ( 26a ) can slide along the width direction. The sheet feeding device ( 10 ) according to claim 2 or 4, wherein the bending members ( 26b ) opposite guide unit ( 27 comprising a movement of the imaging target media (P) passing through the transfer roller ( 14 ) in the width direction. The sheet feeding device ( 10 ) according to one of claims 1 to 5, further comprising: a pressure member ( 34 ), which the filing ( 12 ) is arranged opposite and which a bending and compression member ( 34a ) comprising the imaging target media (P) stored in the repository ( 12 ) are stacked in the direction of the tray ( 12 ) and the imaging target media (P) corresponding to a shape of the bending unit ( 26 ), and a carrier unit ( 34b ) comprising the bending and pressing unit ( 34a ) at the front end. The sheet feeding device ( 10 ) according to claim 6, wherein, depending on a bearing force due to a compressive force, by the pressure and bending unit ( 34a ) is applied to the imaging target media (P), the printing and bending unit ( 34a ) of the pressure member ( 34 ) in a direction away from the tray ( 12 ) can oscillate with a proximal portion of the carrier unit ( 34b ) as a center. The sheet feeding device ( 10 ) according to claim 6 or 7, wherein the pressure and bending unit ( 34a ) a sliding roller ( 34a ) provided by the carrier unit ( 34b ), which allows a free rotation, and the pressure and bending unit ( 34a ) with respect to the depressed imaging target media (P) together with a movement of the depressed imaging target media (P) in the transfer direction.