Patent Application
20200071100
The present application is based on, and claims priority from JP Application Serial Number 2018-160628, filed Aug. 29, 2018 and JP Application Serial Number 2019-036493, filed Feb. 28, 2019, the disclosures of which are hereby incorporated by reference herein in their entirety.
The present disclosure relates to a medium feeding apparatus that feeds media, an image reading apparatus with the medium feeding apparatus, and a medium feeding method.
Some scanners, which are one example of image reading apparatuses, have sheet feeders that automatically feed and read a plurality of sheets or media. Such sheet feeders are sometimes referred to as auto document feeders (ADFs).
A sheet feeder includes: a sheet tray that has a mounting surface on which a plurality of sheets are to be mounted; and a feed roller and a separation roller disposed in contact with each other. The feed roller rotates in the forward direction while being in contact with the sheets on the sheet tray, thereby feeding them. The separation roller separates one of those sheets from the others.
When separating the sheets, the separation roller rotates in the reverse direction so that the one sheet is fed and the others are returned toward the sheet tray. Such separation rollers can be classified into two types: an active type and an inactive type. A separation roller of the active type rotates by means of a driving torque transmitted from a motor via a torque limiter, whereas a separation roller of the inactive type rotates by means of rotational resistance of a torque limiter. JP-A-2013-184819 discloses one example of medium feeding apparatuses which has separation rollers of active and inactive types. In this document, the separation rollers are called brake rollers.
Image reading apparatuses as described above have some disadvantages. When the front edge of a sheet enters into the nip position between the separation roller and the feed roller, both the separation roller and the feed roller are deformed, because they are each made of an elastic material. Then, when the rear edge of the sheet leaves the nip position, the separation roller and the feed roller return to their original shapes. As this time, the next sheet on the separation roller is pushed back to the upstream side. In other words, a so-called “kickback phenomenon” occurs. If the separation roller is of the active type, this separation roller may rotate in the reverse direction, in which case the rotational force acts on the front edge of the next sheet on the separation roller.
As described above, when the rear edge of a sheet leaves the nip position, both opposite force generated by the above kickback phenomenon and opposite force generated by the reverse rotation of the separation roller are applied at one time to the front edge of the next sheet on the separation roller. As a result, a front portion of this sheet may be curled up and fail to smoothly enter into the nip position. In which case, the sheet may be stuck between the separation roller and the feed roller.
According to an aspect of the present disclosure, a medium feeding apparatus includes a feed roller that feeds a plurality of media. A separation roller nips the media together with the feed roller to separate the media and is rotated in a first rotation direction to feed the media to a downstream side in a feeding direction. A motor applies driving torque to the separation roller in a second rotation direction that is opposite to the first rotation direction. A torque limiter that, when rotation torque applied to the separation roller in the first rotation direction exceeds a preset upper torque limit, causes the separation roller to rotate at idle in the first rotation direction independently of the driving torque. A controller controls the motor. During feeding operations, including an operation of feeding a first medium and a second medium in this order, the controller provides a break period in which the motor is not driven. The break period contains a timing at which a rear edge of the first medium leaves a nip position between the feed roller and the separation roller.
Some aspects of the present disclosure will be described briefly below. According to a first aspect, a medium feeding apparatus includes a feed roller that feeds a plurality of media. A separation roller nips the media together with the feed roller to separate the media and is rotated in a first rotation direction to feed the media to a downstream side in a feeding direction. A motor applies driving torque to the separation roller in a second rotation direction that is opposite to the first rotation direction. A torque limiter, when rotation torque applied to the separation roller in the first rotation direction exceeds a preset upper torque limit, causes the separation roller to rotate at idle in the first rotation direction, independently of the driving torque. The controller controls the motor. During feeding operations, including an operation of feeding a first medium and a second medium in this order, the controller provides a break period in which the motor is not driven. The break period contains a timing at which a rear edge of the first medium leaves a nip position between the feed roller and the separation roller.
If the rear edge of the first medium leaves the nip position between the feed roller and the separation roller of the active type, both opposite force generated by the kickback phenomenon and opposite force generated by the reverse rotation of the separation roller are applied at one time to the front edge of the second medium on the separation roller. As a result, a front portion of the second medium may be curled up.
In the configuration of the first aspect, however, the controller that controls the motor that applies driving torque to the separation roller provides the break period in which the motor is not driven during feeding operations, including an operation of feeding the first medium and the second medium in this order. This break period contains a timing at which a rear edge of the first medium leaves the nip position between the feed roller and the second separation roller. With this configuration, when the rear edge of the first medium leaves the nip position, the opposite force generated by the kickback phenomenon is applied to the front edge of the second medium on the separation roller, but the opposite force generated by the reverse rotation of the separation roller is not applied thereto. As a result, the front portion of the second medium on the separation roller is less likely to be curled up.
According to a second aspect, in addition to the configuration of the first aspect, the medium feeding apparatus may further include a first detector that detects passage of the media. The first detector may be disposed downstream of the nip position in the feeding direction. A transport roller that feeds the media to the downstream side may be disposed downstream of the first detector in the feeding direction. A second detector that detects the passage of the media may be disposed downstream of the transport roller in the feeding direction. The controller may set the break period to a period containing a time interval between when the second detector detects passage of a front edge of the first medium and when the first detector detects passage of the rear edge of the first medium.
In the configuration of the second aspect, the controller may set the break period to a period containing a time interval between when the second detector detects passage of a front edge of the first medium and when the first detector detects the passage of the rear edge of the first medium. This configuration makes it possible to reliably contain the timing at which the rear edge of the first medium leaves the nip position within the break period.
According to a third aspect, in addition to the configuration of the first or second aspect, the feed roller may make contact with a lowermost medium of the media mounted in a medium mount where one or media to be fed are mounted and rotate to feed the lowermost medium. The medium feeding apparatus may further include a plurality of suppression units that suppress front edges of the media from making contact with the separation roller by making contact with the front edges of the media other than at least the lowermost medium. The suppression units may be disposed upstream of the nip position and spaced along a width of the media in a direction intersecting the feeding direction.
When the front edges of the media mounted in the medium mount make contact with the outer circumferential surface of the separation roller, the separation roller presses the feed roller in conjunction with deformation of the outer circumferential surface of the separation roller. As a result, the separation roller may make contact with the feed roller at excessively strong force, thereby causing multi-feeding of the media.
In the configuration of the third aspect, however, the medium feeding apparatus may further include a plurality of suppression units that suppress front edges of the media from making contact with the separation roller by making contact with the front edges of the media other than at least the lowermost medium. The suppression units may be disposed upstream of the nip position and spaced along a width of the media in a direction intersecting the feeding direction. This configuration can reduce the risk of advantages, as described above, caused by the contact between the front edges of the media mounted in the medium mount and the outer circumferential surface of the separation roller.
According to a fourth aspect, in addition to the configuration of the third aspect, the suppression units may be arranged on both sides of the separation roller along the width of the media in the direction intersecting the feeding direction.
In the configuration of the fourth aspect, the suppression units may be arranged on both sides of the separation roller along the width of the media in the direction intersecting the feeding direction. This configuration can reduce the risk of the media angled by the suppression unit.
According to a fifth aspect, in addition to the configuration of the fourth aspect, the suppression units may be displaceable along a thickness of the media. The medium feeding apparatus may further include: an operation unit to be operated by a user; and an operation converter that converts movement of the operation unit into displacement of the suppression units.
In the configuration of the fifth aspect, the suppression units may be displaceable along a thickness of the media. The medium feeding apparatus may further include: an operation unit to be operated by a user; and an operation converter that converts movement of the operation unit into displacement of the suppression unit. This configuration can displace the suppression units in accordance with the total thickness of the media, thereby successfully feeding the media in accordance with their total thickness.
According to a sixth aspect, in addition to the configuration of the fifth aspect, the operation unit may be configured to be switched between a first position, a second position, and a third position. The medium feeding apparatus may further include a switching unit that switches between a first state in which driving power of the motor is transmitted to the separation roller and a second state in which the driving power of the motor is not transmitted to the separation roller. When the operation unit is in the first position, ends of the suppression units may not overlap the feed roller as seen from a side of a feeding route of the media and the switching unit may be in the first state. When the operation unit is in the second position, the ends of the suppression units may overlap the feed roller as seen from the side of the feeding route of the media and the switching unit may be in the first state. When the operation unit is in the third position, the ends of the suppression units may not overlap the feed roller as seen from the side of the feeding route of the media and the switching unit may be in the second state.
The configuration of the sixth aspect can provide various separation conditions to feed the media suitably in accordance with a type of the media.
According to a seventh aspect, in addition to the configuration of the fifth or sixth aspect, the operation unit may be operably disposed on an exterior of a housing.
In the configuration of the seventh aspect, the operation unit may be operably disposed on an exterior of a housing. This configuration enables the operation unit to be operated easily.
According to an eighth aspect, in addition to the configuration of one of the third to seventh aspects, the medium feeding apparatus may further include a nip member that nips the media mounted in the medium mount together with the feed roller. The nip member may be movable toward or away from the feed roller. A presser may press the nip member against the feed roller. The presser may include: a first spring that presses the nip member against the feed roller; and a second spring that presses the nip member against the feed roller. When a total thickness of the media mounted in the medium mount is smaller than a preset thickness, the first spring may exert spring force on the nip member, but the second spring may not exert spring force on the nip member. When the total thickness of the media mounted in the medium mount is equal to or larger than the preset thickness, the first spring may exert the spring force on the nip member, and the second spring may also exert the spring force on the nip member.
When a few media are fed, the nip member may press the media at excessive strong force, depending on a configuration of the medium feeding apparatus and a relationship between force at which the nip member presses the media and the number of media, in which case multi-feeding of the media might occur. When many media are fed, the nip member presses the media at insufficiently strong force, depending on these configuration and relationship, in which case failure to feed the media might occur. In the configuration of the eighth aspect, however, when a total thickness of the media mounted in the medium mount is smaller than a preset thickness, the first spring may exert spring force on the nip member, but the second spring may not exert spring force on the nip member. When the total thickness of the media mounted in the medium mount is equal to or larger than the preset thickness, the first spring may exert the spring force on the nip member, and the second spring may also exert the spring force on the nip member. This configuration can suppress the multi-feeding of the media when a few media are mounted in the medium mount and can also suppress the failure to feed the media when many media are mounted therein.
According to a ninth aspect, in addition to the configuration of one of the third to seventh aspects, the medium feeding apparatus may further include a nip member that nips the media mounted in the medium mount together with the feed roller. This nip member may be movable toward or away from the feed roller. A presser may press the nip member against the feed roller. The presser may have a torsion spring that presses the nip member against the feed roller. The torsion spring may include: a first arm that applies spring force of the torsion spring to the nip member; and a second arm that abuts against a spring abutment unit fixed in place. When the total thickness of the media mounted in the medium mount varies, an angle between the first arm and the second arm, an angle between a direction in which the first arm applies the spring force to the nip member and a distance in which the nip member moves to the feed roller, and a distance between a point at which the first arm applies the spring force to the nip member and a center of the torsion spring may vary.
If the presser is formed of a single compressed spring, for example, when many media are mounted in the medium mount, the presser is kept compressed, thereby applying a strong spring force. When a few media are mounted in the medium mount, the presser is stretched out, thereby applying a weak spring force. In short, the force at which the nip member presses media against the feed roller depends simply on the number of media. This may restrict flexibility of setting the force at which the nip member presses media against the feed roller.
In the configuration of the ninth aspect, however, when the total thickness of the media mounted in the medium mount varies, an angle between the first arm and the second arm, an angle between a direction in which the first arm applies the spring force to the nip member and a distance in which the nip member moves to the feed roller, and a distance between a point at which the first arm applies the spring force to the nip member and a center of the torsion spring may vary. As a result, the force at which the nip member presses media against the feed roller is independent of the number of media. This configuration makes it possible to flexibly set the force at which the nip member presses media against the feed roller, thereby successfully optimizing a condition in which the media are fed.
According to a tenth aspect, a configuration includes a feed roller that makes contact with a plurality of media and rotates to feed the media. A separation roller nips the media together with the feed roller to separate the media. A torque limiter applies preset rotational resistance to the separation roller. The feed roller makes contact with a lowermost medium of the media mounted in a medium mount where one or media to be fed are mounted and rotates to feed the lowermost medium. This configuration further includes a plurality of suppression units that suppress front edges of the media from making contact with the separation roller by making contact with the front edges of the media other than at least the lowermost medium. The suppression units are disposed upstream of the nip position and spaced along a width of the media in a direction intersecting the feeding direction.
When the front edges of media mounted in the medium mount are in contact with the outer circumferential surface of the separation roller, the separation roller presses the feed roller in conjunction with deformation of the outer circumferential surface of the separation roller. As a result, the separation roller may press the feed roller at excessively strong force, thereby causing multi-feeding of the media.
In the configuration of the tenth aspect, however, the suppression units are provided to suppress front edges of the media from making contact with the separation roller by making contact with the front edges of the media other than at least the lowermost medium. The suppression units are disposed upstream of the nip position and spaced along a width of the media in a direction intersecting the feeding direction. This configuration can suppress disadvantages, as described above, caused by the abutment of the front edges of media mounted in the medium mount against the outer circumferential surface of the separation roller.
According to an eleventh aspect, in addition to the configuration of the tenth aspect, the suppression units may be arranged on both sides of the separation roller along the width of the media in the direction intersecting the feeding direction.
The above configuration, in which the suppression units may be arranged on both sides of the separation roller along the width of the media in the direction intersecting the feeding direction, can reduce the risk of the media angled by the suppression units.
According to a twelfth aspect, in addition to the configuration of the tenth or eleventh aspect, the suppression units may be displaceable so as to adjust a size of space in which the media is fed to the nip position between the separation roller and the feed roller, thereby suppressing the number of media entering into the nip position. The configuration may further include: an operation unit to be operated by a user; and an operation converter that converts movement of the operation unit into displacement of the suppression unit.
In the configuration of the twelfth aspect, the suppression units are displaceable so as to adjust a size of space in which the media is fed to the nip position between the separation roller and the feed roller, thereby suppressing the number of media entering into the nip position. The configuration may further include: an operation unit to be operated by a user; and an operation converter that converts movement of the operation unit into displacement of the suppression unit. This configuration can displace the suppression units in accordance with the total thickness of the media, thereby successfully feeding the media in accordance with their total thickness.
According to a thirteenth aspect, an image reading apparatus includes: a reader that reads a medium; and the medium feeding apparatus according to one of the first to twelfth aspects which feeds the medium to the reader.
With the configuration of the thirteenth aspect, the image reading apparatus produces substantially the same effects as the medium feeding apparatus according to any of the first to twelfth aspects.
A description will be given of a medium feeding apparatus, an image reading apparatus, and a medium feeding method according to some embodiments of the present disclosure with reference to the accompanying drawings. In the following embodiments, a document scanner 1A is an example of the image reading apparatus. The document scanner 1A is designed to read an image on at least one surface of a medium, or an original sheet P. Hereinafter, the document scanner 1A is abbreviated as the scanner 1A, and the original sheet P is abbreviated as the sheet P.
The accompanying drawings have an X-Y-Z coordinate system. In this system, the X-axis is parallel to the widths of both the scanner 1A and the sheet P and intersects the feeding direction of the sheet P. The Y-axis is parallel to this feeding direction. The Z-axis, which is perpendicular to the Y-axis, is substantially orthogonal to both the surfaces of the sheet P to be transported. The scanner 1A has six surfaces: front, rear, left, right, upper, and lower surfaces. The front surface faces toward the positive (+) side of the Y-axis; the rear surface faces toward the negative (−) side of the Y-axis; the left surface faces toward the positive (+) side of the X-axis; the right surface faces toward the positive (−) side of the X-axis; the upper surface, which includes some upper parts, faces toward the positive (+) side of the Z-axis; and the lower surface, which includes some lower parts, faces toward the positive (−) side of the Z-axis. Hereinafter, the side to which the sheet P is to be transported, or the positive side of +Y-axis, is referred to as the downstream side, and the side opposite to this downstream side is referred to as the upstream side.
With reference to
The main unit 2 has a sheet mount 11 on its rear surface. The sheet mount 11 is detachably attached to the main unit 2 and has a mounting surface 11a on which a sheet P is to be transported is mounted. The sheet mount 11 is provided with a pair of edge guides: a first edge guide 12A and a second edge guide 12B. Both the first edge guide 12A and the second edge guide 12B guide the side edges of a sheet P. Further, a guide surface U1 of the first edge guide 12A and a guide surface U2 of the second edge guide 12B make contact with and guide the side edges of the sheet P.
The sheet mount 11 has a first paper support 8 and a second paper support 9 that are retractable in the sheet mount 11. By pulling out both the first paper support 8 and the second paper support 9 from the sheet mount 11 as illustrated in
The main unit 2 has an operation panel 7 on the upper surface of upper unit 4. The operation panel 7 is a user interface (UI) and allows the user to perform various settings of a read operation and indicates the set contents. In this embodiment, the operation panel 7 may be a touch panel that can display information and accept input operations. In short, the operation panel 7 serves as both an operation unit that accepts input operations and a display unit that indicates various information. The upper unit 4 has a supply port 6 on its upper surface which leads to the interior of the main unit 2. Via the supply port 6, the sheet P on the sheet mount 11 is transported to a reader 20 in the main unit 2. The lower unit 3 has an ejection tray 5 on its front surface to which the sheet P is to be ejected.
The upper unit 4 has a housing 21 with an operation unit 75a to be operated by the user. The operation unit 75a can have three positions: a first opposition that is a neutral position; a second position in which the operation unit 75a is depressed forward; and a third position which the operation unit 75a is depressed rearward. Details of these positions will be described later. By operating the operation unit 75a, the user can switch sheet feeding conditions. Details of this operation will be described later.
With reference to
Disposed at the upstream end of the sheet feeding route T is the sheet mount 11. Disposed downstream of the sheet mount 11 are the feed rollers 14 and the separation rollers 15. The feed rollers 14 feed sheets P from the mounting surface 11a of the sheet mount 11 to the reader 20. The separation rollers 15 separate one of the sheets P from the others by nipping the sheet P together with the feed rollers 14.
The feed rollers 14 make contact with the lowermost one of the sheets P that have been mounted on the mounting surface 11a of the sheet mount 11. When a plurality of sheets P are mounted on the mounting surface 11a of the sheet mount 11 in the scanner 1A, the feed rollers 14 feed the sheets P one by one to the downstream side in the order from the lowermost sheet P. Disposed upstream of the feed rollers 14 is a mounted sheet detector 33 that detects the presence of a sheet P mounted on the sheet mount 11.
The separation rollers 15 are disposed opposite the feed rollers 14 in order to suppress a plurality of sheets P from being fed at one time between the feed rollers 14 and the separation rollers 15, namely, in order to suppress multi-feeding of the sheets P therebetween. Details of the feed rollers 14 and the separation rollers 15 will be described later.
Arranged downstream of the feed rollers 14 is the transport roller pair 16, the reader 20 that reads an image from a sheet P, and an ejection roller pair 17. The transport roller pair 16 includes a driving transport roller 16a and a driven transport roller 16b; the driving transport roller 16a rotates by means of the driving power from a transport roller motor 46 (see
Disposed downstream of the nip position between the feed rollers 14 and the separation rollers 15 is a first sheet detector 31. The first sheet detector 31, which may be an optical sensor, for example, includes a light emitter 31a and a light receiver 31b disposed opposite each other with the sheet feeding route T therebetween. When the light emitter 31a outputs detection light, this detection light is received by the light receiver 31b. Then, the light receiver 31b outputs an electric signal proportional to the intensity of the received detection light to a controller 40 (see
Disposed downstream of the first sheet detector 31 is multi-feeding detector 30 that detects the multi-feeding of sheets P. The multi-feeding detector 30 includes an ultrasound emitter 30a and an ultrasound receiver 30b disposed opposite each other with the sheet feeding route T therebetween. When the ultrasound emitter 30a outputs an ultrasonic wave, this ultrasonic wave is received by the ultrasound receiver 30b. Then, the ultrasound receiver 30b outputs an electric signal proportional to the intensity of the received ultrasonic wave to the controller 40. If the multi-feeding of sheets P occurs, the level of the electric signal varies. In this way, the controller 40 can sense the multi-feeding of the sheets P.
Disposed downstream of the multi-feeding detector 30, more specifically, the transport roller pair 16 is a second sheet detector 32, which may be a contact sensor with a lever. In response to the passage of the front or rear edge of the sheet P, the lever of the second sheet detector 32 is pivoted, and then the second sheet detector 32 varies an electric signal and sends it to the controller 40. In this way, the controller 40 senses that the front or rear edge of the sheet P has passed near the second sheet detector 32. With the above first sheet detector 31 and second sheet detector 32, the controller 40 can recognize at which position the sheet P is being transported along the sheet feeding route T.
The reader 20, which is disposed downstream of the second sheet detector 32, includes an upper read sensor 20a and a lower read sensor 20b. The upper read sensor 20a is disposed inside the upper unit 4, whereas the lower read sensor 20b is disposed inside the lower unit 3. In this embodiment, each of the upper read sensor 20a and the lower read sensor 20b may be a contact image sensor module (CISM), for example.
After an image on at least one surface of the sheet P has been read by the reader 20, the sheet P is nipped by the ejection roller pair 17 disposed downstream of the reader 20. Then, the sheet P is ejected to the outside of the sheet feeding apparatus 1B through the ejection port 18 disposed on the front surface of the lower unit 3. The ejection roller pair 17 includes a driving ejection roller 17a and a driven ejection roller 17b. The driving ejection roller 17a rotates by means of the driving power from the transport roller motor 46 (see
With reference to
The controller 40 controls the driving sources for the feed rollers 14, the separation rollers 15, the transport roller pair 16, and the ejection roller pair 17 as illustrated in
The controller 40 includes a CPU 41, a ROM 42, and a memory 43. The CPU 41 controls an entire operation of the scanner 1A by performing various calculations in accordance with a program 44 stored in the ROM 42. The memory 43, which is an example of a storage unit, may be a nonvolatile memory from which data can be read or to which data can be written. The memory 43 stores all parameters and data required for the control, which may be updated as appropriate by the controller 40. The scanner 1A is connectable to an external computer 100 so that the controller 40 can receive various information from the external computer 100.
With reference to
The feed roller motor 45 (see
With the one-way clutch 49 disposed on the driving power transmission route between each feed roller 14 and the feed roller motor 45 (see
The separation roller motor 51 (e.g., see
When no or a single sheet P is present between the feed rollers 14 and the separation rollers 15, if the rotation torque that causes the separation rollers 15 to rotate in the forward rotation direction exceeds an upper torque limit of the torque limiter 50, the torque limiter 50 slips on the separation rollers 15. In which case, the separation rollers 15 rotate at idle in the forward rotation direction, independently of the rotation torque from the separation roller motor 51. Hereinafter, the rotation direction in which the separation rollers 15 is rotated in conjunction with the rotation of the feed rollers 14 or the sheet P being fed is referred to as the forward rotation direction (first rotation direction), and the opposite rotation direction is referred to as the reverse rotation direction (second rotation direction). Likewise, the rotation direction in which the separation roller motor 51 rotates to rotate the separation rollers 15 in the forward rotation direction is referred to as the forward rotation direction, and the opposite rotation direction is referred to as the reverse rotation direction. While the sheet P is being fed, the separation roller motor 51 is normally rotating in the reverse rotation direction, thereby generating driving torque to cause the separation rollers 15 to rotate in the reverse rotation direction.
If a first sheet P to be fed and a second sheet P enter together into between the feed rollers 14 and the separation rollers 15, the second sheet P slips on the first sheet P, and then the separation roller motor 51 transmits driving torque to the separation rollers 15 in the reverse rotation direction. The second sheet P is thereby returned to the upstream side. In this way, the multi-feeding is suppressed.
The feed rollers 14 and the separation rollers 15, each of which has an outer circumferential surface made of an elastic material such as elastomer, satisfy the following relationships:
μ1>μ2,
μ1>μ3,
μ1>μ4,
μ2<μ3,
μ2<μ4, and
μ4<μ3,
where μ1 denotes a coefficient of friction between the feed rollers 14 and the separation rollers 15, μ2 denotes a coefficient of friction between sheets P, μ3 denotes a coefficient of friction between the feed rollers 14 and a sheet P, and μ4 denotes a coefficient of friction between the separation rollers 15 and a sheet P.
Next, a description will be given of the driving power transmission route between the separation roller motor 51 and the separation rollers 15. As illustrated in
The power-transmitting pinion 59 is provided with an arm member 56, which is pivotable around a shaft 57. The arm member 56 extends from the shaft 57 in two directions: first and second directions. Further, an end of the arm member 56 which extends in the first direction is provided with the power-transmitting pinion 59, whereas the other end extending in the second direction forms a cam follower unit 56a, which engages with a cam 58 that pivots the cam follower unit 56a, namely, the arm member 56.
The cam 58 is provided in a first end of the shaft 73. A second end of the shaft 73 is provided with an operation member 75, which includes the operation unit 75a that has been described with reference to
The operation member 75 further includes a detected unit 75b and a latched unit 75c. Disposed on the rotation locus of the detected unit 75b drawn by the rotation of the operation member 75 are position sensors 89a and 89b, each of which may be an optical sensor. The controller 40 (
The latched unit 75c is attached to a plate spring 76. As illustrated in
With reference to
With reference to
When the switching unit 55 enters the second state where the driving power of the separation roller motor 51 is not transmitted to the separation rollers 15, the separation rollers 15 does not rotate in the reverse rotation direction and is rotatable freely. In other words, when the switching unit 55 enters the second state, the separation rollers 15 do not separate sheets P. Hereinafter, the feeding of sheets P in this state is referred to below as the “non-separation mode”. The feeding of the sheets P in such a way the separation rollers 15 separate the sheets P is referred to below as the “separation mode”.
Next, a description will be given of a manner in which the switching unit 55 switches pressing forces at which the separation rollers 15 presses the feed rollers 14. The separation rollers 15 are supported by a separation roller holder 65 as illustrated in
Disposed above the separation roller holder 65 is a spring holding member 67, which has two spring holders 67a. Between each spring holder 67a and the separation roller holder 65 is a spring 64 (see
Disposed above the spring holding member 67 is a cam member 69, which is attached to the shaft 73 rotatable by the operation of the operation unit 75a. The cam member 69 has a cam 69a as illustrated in
In short, the operation unit 75a can be switched between the three positions: the first position as illustrated in
Next, a description will be given of suppression units 80a that suppress the front edges of sheets P from making contact with the separation rollers 15. In this embodiment, the lowermost one of the sheets P to be fed is in contact with the feed rollers 14. If the front edge of a sheet P mounted on the sheet mount 11 (see
As illustrated in
As described above, the cam member 69 is attached to the shaft 73 rotatable by the operation of the operation unit 75a. When the shaft 73 rotates, the cam member 69 presses the suppression member 80 downward.
The positional relationship between the operation unit 75a and the suppression units 80a will be described below. When the operation unit 75a is in the first position (see
Table 1 lists the relationships, as described above, between the position of the operation unit 75a and the separation mode
With reference to
To address the above disadvantage, the suppression units 80a are provided. The suppression units 80a are designed to control the number of sheets P in contact with the outer circumferential surfaces of the separation rollers 15. In
Among sheets available from the market, thinner sheets tend to have a greater coefficient of friction therebetween. Sheets P having a smaller thickness, therefore, are more likely to cause multi-feeding. For this reason, if each sheet P has a small thickness, the operation unit 75a (e.g., see
If each sheet P has a large thickness, the operation unit 75a (e.g., see
If many sheets P such as pages of a booklet are transported inside the sheet feeding apparatus 1B, the sheets P may be stuck when separated by the separation rollers 15. In this case, the operation unit 75a (e.g., see
Next, a description will be given of other features of the configuration of the sheet feeding apparatus 1B. As illustrated in
Disposed above and near the front edge of a sheet P mounted in the sheet mount 11 is a pressing member 85, which serves as a nip member. The pressing member 85 is movable toward or away from the feed rollers 14 and urged toward a sheet P by the presser, which will be described later, so as to press a front or surrounding portion of the sheet P mounted in the sheet mount 11. The pressing member 85 nips the sheet P together with the feed rollers 14, as illustrated in
As illustrated in
If a few sheets P are mounted in the sheet mount 11, more specifically, if the total thickness of the sheets P is smaller than a preset thickness, the spring abutment units 79b are not inserted into the spring holders 85a via the apertures 85b, as illustrated in
Effects of the pressing member 85 configured above will be described below. When the sheet feeding apparatus 1B fails to transport sheets P appropriately, the following disadvantages may be arise: some of the sheets P are stuck inside; and some of the sheets P are not ejected to the outside. The multi-feeding of the sheets P may be caused by, for example, a low friction between the separation rollers 15 and the sheets P, a low torque of the separation rollers 15, or a high friction between the sheets P which is attributed to excessively pressing of the pressing member 85. The failure to eject sheets P may be caused by, for example, a low friction between the feed rollers 14 and the lowermost sheet P or a low friction between the sheet mount 11 and the lowermost sheet P. In short, it is necessary to comprehensively consider such factors in order to suppress both the multi-feeding of sheets P and the failure to eject sheets P. Moreover, in this embodiment, the pressing force of the pressing member 85 and the number, or the total thickness, of sheets P mounted are believed to be related to the above disadvantages. More specifically, when a few sheets P are mounted, the pressing member 85 may press the sheet P excessively, thereby causing the multi-feeding of the sheets P. When many sheets P are mounted, the pressing member 85 may press the sheet P insufficiently, thereby causing the failure to eject the sheets P.
To address the above disadvantages, in this embodiment, the pressing member 85 is disposed. When a few sheets P are mounted in the sheet mount 11, only the first pressing spring 90 exerts the spring force on the sheets P. When many sheets P are mounted, not only the first pressing spring 90 but also the second pressing springs 91 exert the spring force to the sheets P. In this way, the pressing member 85 can suppress the multi-feeding of the sheets P when many sheets P are mounted and can also suppress the failure to eject the sheets P when a few sheets P are mounted.
Next, with reference to
As illustrated in
At Step S102, the controller 40 determines whether the first sheet detector 31 has detected the front edge of a first sheet P1. When the first sheet detector 31 has detected the front edge of the first sheet P1 (Yes at Step S102), at Step S103, the controller 40 stops driving the separation rollers 15 (at timing b-1 in
At Step S104, the controller 40 determines whether the second sheet detector 32 has detected the front edge of the first sheet P1. When the second sheet detector 32 has detected the front edge of the first sheet P1 (Yes at Step S104), at Step S105, the controller 40 stops driving the feed rollers 14 (at timing c-1 in
At Step S106, the controller 40 determines whether the first sheet detector 31 has detected the rear edge of the first sheet P1. When the first sheet detector 31 has detected the rear edge of the first sheet P1 (Yes at Step S106), at Step S107, the controller 40 determines whether the next page, or a second sheet P2, is present. When the second sheet P2 is present (Yes at Step S107), the controller 40 repeats the control at the above steps S101 to S107 (at timing d-1 in
The duration of the period between timings c-1 and d-1 may vary depending on the length of the sheets P. This period contains timing e-1 at which the rear edge of the first sheet P1 leaves the nip position between the feed rollers 14 and the separation rollers 15.
Effects of the above control will be described below. If the controller 40 does not perform this control, the separation rollers 15 continue to apply driving torque to the separation rollers 15 in the reverse rotation direction. In this case, when the rear edge of the first sheet P1 leaves the nip position between the separation rollers 15 and the feed rollers 14, the opposite force generated by the kickback phenomenon and the opposite force generated by the reverse rotation of the separation rollers 15 are applied at one time to the front edge of the second sheet P2 on the separation rollers 15. As a result, a front portion of the second sheet P2 may be curled up. With this control, however, a break period in which the separation roller motor 51 stops rotating is reserved during an operation of feeding the first sheet P1 and the second sheet P2 (Step S103 in
Next, a modification of the above control will be described below. The first sheet detector 31, which is disposed downstream of the nip position between the feed rollers 14 and the separation rollers 15, serves as a downstream detector, and an upstream detector is newly disposed upstream of the nip position to detect the passage of a sheet P. As illustrated in
As another modification, the controller 40 may calculate the time interval between when the rotary encoder 94 detects the passage of the rear edge of the sheet P1 and when the rear edge of the sheet P1 leaves the nip position for the downstream side, based on the distance between the driven roller 93 and the nip position and the transport speed of sheets P. After the rotary encoder 94 has detected the passage of the rear edge of the sheet P1, the controller 40 may set the break period to a period containing the calculated time interval. In this way, the controller 40 can also reliably reserve a timing at which the rear edge of the sheet P1 leaves the nip position within the break period.
Next, with reference to
In this embodiment, the presser that presses the pressing member 95 against the feed rollers 14 includes a torsion spring 97 accommodated in a spring holder 98. The torsion spring 97 includes a first arm 97a and a second arm 97b. The first arm 97a applies spring force to the pressing member 95, whereas the second arm 97b abuts against a spring abutment unit 99 fixed in place. Both the first arm 97a and the second arm 97b exert the spring force in directions in which they move away from each other.
In
The first arm 97a of the torsion spring 97 applies the spring force F to a pressed unit 95c of the pressing member 95. When the sheet Pa is mounted, as illustrated in
When the sheet Pb is mounted, as illustrated in
As the total thickness of sheets P increases, the angle α between the first arm 97a and the second arm 97b in the torsion spring 97 decreases, and thus the spring force F that the torsion spring 97 applies to the sheets P increases. This leads to an increase in the component of force Fv contained in the spring force F.
As the total thickness of sheets P increases, the angle β between the direction in which the first arm 97a applies the spring force F to the pressing member 95 and the direction in which the pressing member 95 moves toward the feed rollers 14 increases. In this case, a direction in which the spring force F is applied to the sheets P differs more from a direction in which the pressing member 95 moves toward the feed rollers 14. This leads to a decrease in the component of force Fv.
As the total thickness of sheets P increases, the distance L between the point at which the first arm 97a makes contact with the pressed unit 95c and the center of the torsion spring 97 increases. This leads to a decrease in the component of force Fv.
As described above, when the total thickness of sheets P varies, the angle α between the first arm 97a and the second arm 97b, the angle β between the direction in which the first arm 97a applies the spring force F to the pressing member 95 and the direction in which the pressing member 95 moves toward the feed rollers 14, and the distance L between the point at which the first arm 97a applies the spring force F to the pressing member 95 and the center of the torsion spring 97 vary. In short, the force at which the pressing member 95 presses a sheet P against the feed rollers 14, namely, the component of force Fv does not absolutely depend on the number of sheets P. Consequently, it is possible to flexibly set the force at which the pressing member 95 presses a sheet P against the feed rollers 14, namely, the component of force Fv, thereby successfully optimizing a condition in which sheets P are fed.
By changing the design and position of the torsion spring 97, the relationship between the total thickness of sheets P and the component of force Fv can be adjusted. More specifically, the relationship between the total thickness of the sheets P and the component of force Fv can be adjusted, for example, by changing angles α1, α2, β1, and β2, and the distances L1 and L2, an inclination of the torsion spring 97, the number of times that the torsion spring 97 is twisted, a diameter of the torsion spring 97, and a material and diameter of a wire of the torsion spring 97 and by selecting which of forces generated when the torsion spring 97 is pulled out and pushed down is to be used.
In the foregoing embodiments, a medium feeding apparatus according to the present disclosure is applied to a scanner, which is an example of an image reading apparatus. The medium feeding apparatus is, however, also applicable to a recording apparatus with a recording head, such as a printer, by which information is to be stored in a medium.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2018-160628 | Aug 2018 | JP | national |
| 2019-036493 | Feb 2019 | JP | national |
