JP2002347993A - Sheet supply device and processing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sheet supply device capable of securely correcting skewing of the sheet, and to provide an information processing device. SOLUTION: This sheet supply device has a sheet carrying surface 24, to which the sheet is supplied, and at least one skew correcting mechanism for carrying the sheet supplied to the sheet carrying surface by rotating with the correcting member 36 brought in contact with the sheet. The skew correcting member 36 has a range of the rotation angle, in which the correcting member does not contact with the sheet when the correcting mechanism 36 is rotated once, and the skew correcting member 36 makes the sheet abut on an abutment member provided in the downstream side in the sheet carrying direction to correct the skew of the sheet.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sheet feeding apparatus for feeding a sheet while automatically correcting the skew of the sheet, and a processing apparatus having a sheet processing mechanism.

[0002]

2. Description of the Related Art A serial printer includes a print head supported by a carrier, and a platen opposed to the print head. A sheet is transported between the print head and the platen by a pair of sheet transport rollers. Printing is performed on the sheet. The sheet is supplied to the sheet conveying roller automatically or manually.

When a sheet is fed toward a sheet conveying roller, there is a problem that the sheet is skewed. Skew is likely to occur when feeding sheets manually. The skew is a phenomenon in which the upper end of the sheet (the end in the sheet conveying direction) is supplied obliquely to the sheet conveying roller. When the sheet is skewed and supplied to the sheet conveyance roller, the sheet conveyance roller conveys the sheet skewed to the print processing unit by the print head, and printing is not performed at a designated position on the sheet. Therefore, if the sheet is skewed when feeding the sheet, it is desired to correct the skew of the sheet.

[0004] Japanese Patent Application No. 10-07164, which is a prior application of the present application.
No. 4 discloses a sheet feeding device capable of correcting skew of a sheet. The sheet feeding device includes a frame having a sheet conveying surface, a shaft rotatably disposed above the sheet conveying surface, and a shaft spaced apart in an axial direction of the shaft and at different angles in a circumferential direction. And a rotating device for rotating the shaft, the sheet is conveyed by the protrusions along a sheet conveying surface toward a sheet conveying roller in a printer, and the sheet is The skew of the sheet is corrected by abutting the sheet against a conveyance roller.

In this sheet feeding apparatus, when a sheet is fed obliquely, one end of the upper end of the sheet (for example, the left end of the preceding sheet in the conveying direction) is stopped by a sheet conveying roller. Abut When one end of the sheet abuts the sheet transport roller, that edge of the sheet stops, the other portion of the sheet continues to be transported by the protrusion on the shaft, the sheet rotates about the stopped edge, and the sheet is tilted. Rows are corrected. In this case, it is the projection that is engaged with the sheet to convey and rotate the sheet, and the projection does not restrain the sheet like a pair of pinch rollers, so the sheet rotates easily and reliably, The skew of the sheet is corrected. That is, the projection of the shaft as the skew correction member for the sheet intermittently contacts the sheet on the sheet conveyance surface, thereby causing the sheet to contact the sheet conveyance roller to perform skew correction.

[0006]

In the above-described apparatus, the setting position in the sheet width direction is limited to the vicinity of the left end of the apparatus, and the operator has to be careful when handling a sheet having a small width. In order to improve the operability when setting the seat, the position range where the seat can be set is expanded,
It was necessary to further enhance the reliability of the skew correction function.

An object of the present invention is to provide a sheet feeding apparatus and a processing apparatus which can more reliably correct skew of a sheet.

[0008]

According to the present invention, there is provided a sheet feeding apparatus which rotates a sheet feeding surface to which a sheet is fed and a sheet fed to the sheet feeding surface in contact with the sheet. At least one skew correction member that conveys along the sheet conveyance surface, the skew correction member is configured to have a rotation angle range that does not contact the sheet in one rotation thereof, The end of the sheet conveyed by the rotation of the skew feeding correction member on the conveyance direction side abuts against an abutting member provided downstream of the skew feeding correction member in the conveyance direction of the sheet. Skew is corrected.

According to this structure, the skew feeding correcting member rotates and comes into contact with the sheet to convey the sheet toward the abutting member. Move in the free state toward the butting member due to the inertia of the conveying force received from the skew feeding correcting member. As a result, the end of the sheet in the conveyance direction abuts against the abutting member, and the skew of the sheet is corrected.

A processing apparatus according to the present invention conveys a sheet along a sheet conveying surface by rotating the sheet fed to the sheet conveying surface while the sheet is fed in contact with the sheet. At least one skew correction member, a sheet conveyance roller provided downstream of the skew correction member in the sheet conveyance direction, and conveying the sheet, and a sheet conveyance roller downstream of the sheet conveyance roller. And a processing mechanism for performing processing on the sheet conveyed by the sheet conveying roller in opposition to the sheet, wherein the skew feeding correction member rotates in one rotation thereof so as not to contact the sheet. The end of the sheet conveyed by the rotation of the skew feeding correcting member is configured to have an angle range, and the end of the sheet in the conveyance direction is protruded toward the sheet conveyance roller. By striking, in which skew of the sheet is characterized by comprising configured to be corrected.

Also in this configuration, similarly to the above, the skew of the sheet is surely corrected, and then the processing mechanism performs processing on the conveyed sheet. When the processing mechanism is a printer, printing is performed on a sheet.

Preferably, a phase sensor for detecting a rotational position of the skew feeding correcting member is provided, and a rotation position at which the skew feeding correcting member does not contact a sheet on the sheet conveying surface in accordance with an output of the phase sensor. It is configured to stop at. Preferably, the sheet conveying surface is configured such that at least a portion facing the skew feeding correction member does not contact the skew feeding correction member.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. Here, the sheet includes one thin or thick sheet of paper, a bundle of a plurality of sheets such as copy sheets, a passbook, and the like. FIG. 1 shows a sheet feeding device 1.
FIG. 2 is a diagram illustrating a printer (recording device) 50 having 0.
FIG. 2 is a diagram illustrating a place where the sheet feeding apparatus 10 is attached to the printer 50. The printer 50 has a casing 52.
And the casing 52 has front side walls 54, 56. The sheet feeding device 10 is provided with a front side wall 5 of a casing 52.
4 and 56. An operation panel 58 is provided on the front side wall 56 of the casing 52. Further, the casing 52 has a paper guide 59, and a pair of sheet conveying rollers 60 and 62 (FIG. 6) are provided in the casing 52. Sheet conveying rollers 60, 6
One of the two is a driving roller, and the other is a driven roller that rotates in contact with the driving roller.

In FIG. 2, the inner surfaces of the front side walls 54, 56 of the casing 52 have studs 64, 66 as mounting means for the sheet feeding apparatus 10. The inner surfaces of the front side walls 54 and 56 of the casing 52 are formed with recesses (grooves) 6 for mounting a table (not shown) for mounting sheets when the sheet feeding device 10 is not used.
8 and 70 are provided. On the other hand, the sheet feeding apparatus 10 includes a frame 12, and the frame 12 has mounting recesses 14 and 16 at the front end and the bottom of both side walls.

FIG. 3 shows the sheet feeding device 10 connected to a printer 50.
It shows the place to be removed from. As shown in FIG. 3A, the sheet feeding device 10 is attached to the printer 50 by fitting the stud 64 into the attachment recess 14 and the stud 66 into the attachment recess 16. A lock lever 1 is provided on the left and right portions of the device.
9a is attached to prevent upward detachment. In order to remove the sheet feeding device 10 from this state, as shown in FIG. 3B, the front end of the sheet feeding device 10 is lifted with the stud 64 as a fulcrum.
When the stud 66 is moved away from the mounting recess 16 and then the sheet feeding device 10 is pulled out to the front side as shown in FIG. 3C, the stud 64 is moved away from the mounting recess 14. The lock lever 19a is
This is a mechanism for rotating b around a rotation fulcrum, and in the state shown in (A), is locked by a mechanism that applies tension in the direction of 19e by the torsion spring 19d. Conversely, according to the procedure from FIG. 3 (C) to FIG. 3 (A),
The sheet supply device 10 can be attached to the printer 50. Therefore, the sheet feeding device 10 can be detachably attached to the printer 50.

FIGS. 4 and 5 are views showing details of the sheet feeding apparatus 10. FIG. The sheet supply device 10 includes a frame 12
And a cover 18 that covers the tip of the frame 12. The lower end of the vertical wall 20 of the cover 18 is
The cover 18 can be attached to the frame 12 by fitting it into the second slit 22. The upper wall of the frame 12 is substantially flat and forms a sheet conveying surface 24.

A supply shaft 26 is rotatably arranged above the sheet conveying surface 24 and has a vertical support 2 with bearings.
8 support the frame 12. As shown in FIG. 9, a gear 30 is attached to one end of the supply shaft 26, and the gear 30 is connected to a motor gear 34a of a supply motor 34 via a gear train 32 arranged below the sheet conveying surface 24. Is done. The supply motor 34 is supported by the frame 12. Thus, the supply shaft 26 can be rotated by the supply motor 34.

As shown in FIGS. 4 and 5, a plurality of projections (skew correcting members) 36 are spaced apart in the axial direction of the shaft 26 and at different angles in the circumferential direction.
6. These protrusions 36 are formed as protrusions of a profiled roller 38 having a hub held by the supply shaft 26 and at least one protrusion protruding from the hub. In the embodiment, nine profiled rollers 38 are provided on the supply shaft 26, and in each profiled roller 38, two protrusions extend from the hub diametrically opposite the shaft.

FIG. 7 is a side view of the frame 12 viewed from the side to show the protrusion 36 attached to the supply shaft 26. The diametrically opposed projections 36 of the supply shaft 26 are each within an angle range of about 50 degrees, and there are no projections 36 within an angle range of 130 degrees, which is a supplementary angle of 50 degrees. Projection 3 of certain irregularly shaped roller 38 on shaft 26
6, the projection 36 of the next irregular shaped roller 38 is at a position rotated by 50 degrees clockwise, and the projection 36 of the next irregular shaped roller 38 is at a position rotated by 50 degrees counterclockwise. . In FIG. 7, any of the protrusions 36
Also does not contact the sheet on the sheet conveying surface 24, and in this state, the sheet does not receive the conveying force. The supply shaft 26 has an angular range in which none of the protrusions 36 contacts the sheet on the sheet conveying surface 24.

4 and 5, the supply shaft 26
The phase sensor 40 is provided at the end opposite to the end for attaching the gear 30. FIG. 8 is a side view of the frame 12 viewed from the side opposite to that of FIG. The phase sensor 40 is connected to the supply shaft 2
Sensor head 4 of fan-shaped double head attached to 6
0a and an optical detector 40b fixed to the frame 12
Consists of The optical detector 40b includes a light emitting unit and a light receiving unit, and interrupts an optical path each time the sensor lever 40a passes between the light emitting unit and the light receiving unit, and the optical detector 40b generates a signal. .

Although the projection 36 and the phase sensor 40 are shown separately in FIGS. 7 and 8, when the frame 12 is viewed from the lateral direction, actually, as shown in FIG. And the phase sensor 40 are visible at the same time. The projection 36 and the sensor lever 40a of the phase sensor 40 are attached to the supply shaft 26 at substantially the same angular phase. further,
The sheet supply device 10 includes a plurality of supply sensors 4 disposed on a line parallel to the supply shaft 26 at the back of the supply shaft 26.
2 inclusive. Each supply sensor 42 is a reflection type sensor including a light emitting unit and a light receiving unit, and is attached to the cover 18. A portion of the frame 12 located below the supply sensor 42 has a hole 43. When there is no paper, the holes 4 in the frame 12
Because there is 3, there is no response in the light receiving section. When paper is present, the emitted light reflects off the paper and reacts on the light receiving side.

Further, the sheet conveying surface 24 has a depression 44 corresponding to the position of the projection 36. As shown in FIG. 10, the tip of the projection 36 enters the depression 44, and the sheet P supplied to the sheet conveying surface 24 is pushed by the projection 36 and conveyed by the projection 36 while being slightly deformed in the depression 44. Is done. Depending on the thickness of the sheet P, the conveyance force of the protrusion 36 on the sheet P differs. For example, when a thin single sheet is conveyed, the sheet P is easily deformed in the depression 44, and the projection 36 is conveyed with a weak feed force while slightly hitting the sheet P. On the other hand, when conveying a thick single leaf sheet or a slip including a plurality of sheets, the sheet P
4, the sheet 36 is conveyed with a strong feed force while the projection 36 strongly hits the sheet P.

In FIG. 5, since the sheet feeding device 10 can be attached to the printer 50 which has already been shipped, the shaft 2 of the sheet feeding device 10 can be mounted.
Reference numeral 6 is arranged in relation to the sheet conveying roller 60 of the printer 50. Sheet supply apparatus 10 is adapted to be set (random set) the large sheets P _L and smaller sheet P _S to a desired position of the whole area of the sheet conveying surface 24. In the example shown in FIG. 5, a large sheet P _L
Is placed to the left of the position as a normal printer, small sheet P _S is placed in the center position. In the specifications of the sheet feeding apparatus 10, the minimum usable sheet width P
W is set. In FIG. 5, the small sheet P _S
Is shown as the minimum sheet width PW. If the width of the sheet to be used is larger than PW, the sheet is supplied to the printer 50 by the sheet supply device 10, and the skew is automatically corrected during the supply process.

The distance L between the supply sensor 42 in the axial direction of the shaft 26 is equal to or less than PW (L <PW). Therefore, a small sheet P _S of the minimum width be set at the position of the sheet conveyance surface 24 throat, presence or absence of the sheet is detected by at least one feed sensor 42. Also,
The distance M between the protrusions 36 on the shaft 26 of the sheet feeding device 10 in the axial direction of the shaft 26 is equal to or less than 1/2 PW (M <1).
/ 2PW). Therefore, at least two protrusions 36 can be engaged with the sheet, and can abut the sheet conveying rollers 60 and 62 to correct the skew of the sheet.

FIG. 6 is a sectional view showing the printer 50 to which the sheet feeding device 10 is attached. The printer 50
A movable carrier 72, a print head 74 attached to the carrier 72, a platen 76 facing the print head 74, a pair of sheet conveying rollers 60 and 62 arranged on one side of the platen 76, and a platen 76. And a pair of sheet conveying rollers 78 and 80 disposed on the other side of the sheet conveying roller. Further, the printer 50 includes the sheet feeding device 10 described above. In the present application, the sheet feeding device 10
Denotes a pair of sheet conveying rollers 60 and 6 located near the
Related to 2.

The carrier 72 has a sheet guide 86 facing the platen 76. As shown in FIGS. 5 and 11, a pair of sheet upper end sensors 84 (84a, 84a, 8b) are provided.
4b) is attached to the sheet guide 86. The sheet guide 86 has a hole 74a at the center for passing the print pin of the print head 74, and a pair of sheet upper end sensors 84 are provided at equal distances on both sides of the hole 74a. The two sheet upper end sensors 84 and the holes 74a are provided on a line perpendicular to the sheet conveying direction. The two sheet upper end sensors 84 indicate that the upper end of the sheet has reached the position of the print head 74, Skew can be detected.

Next, referring to FIG.
The operation of 0 will be described. The rotatable supply shaft 26 having the plurality of protrusions 36 conveys the sheet P toward (the nip of) the sheet conveying rollers 60 and 62 according to the output of the supply sensor 42. In this case, the sheet P is conveyed only by the frictional force of the protrusion 36 attached to the supply shaft 26.

When the sheet P is supplied obliquely, one side edge of the upper end of the sheet P (for example, the left end of the side of the preceding sheet in the transport direction) is stopped,
Contact 62. One end of the sheet is a sheet conveying roller 6
0, 62, the end of the sheet P stops,
The other portion of the sheet continues to be conveyed by the protrusion 36 of the supply shaft 26, and the sheet P rotates around the stopped end (A), and the skew of the sheet P is corrected (B). In this case, even if the plurality of protrusions 36 are in contact with the sheet P, the action of rotating the sheet P is mainly the protrusion 36 at a position distant from one end of the sheet P in contact with the sheet conveying rollers 60 and 62 (this The projections 36 are indicated by solid lines and the other projections 36 are indicated by chain lines). Since the projections 36 are engaged with the sheet P substantially in point contact, the sheet P is easily and reliably rotated, and the skew of the sheet P is corrected. When the sheet is conveyed by nipping the sheet by a pair of pinch rollers instead of the projection 36 shown by the solid line, the sheet is conveyed while being inclined, and does not rotate as expected.

Next, the operation of the sheet feeding apparatus 10 and the printer 50 will be described with reference to FIGS.
FIG. 13 is a flowchart showing the operation of the sheet feeding apparatus 10, and FIGS. 14 and 15 are flowcharts showing the operation of the printer 50. In FIG. 13, step S
At 1, it is determined whether or not the sheet is set on the sheet conveying surface 24. Since the plurality of supply sensors 42 are arranged at predetermined intervals, the presence / absence of a randomly set sheet is reliably detected. When it is detected that the sheet has been set, in step S2, the sheet detection status is confirmed, and the suction amount is determined. The confirmation of the sheet detection status is to check which supply sensor 42 has detected the presence of the sheet. According to the result, the suction amount is determined, for example, as shown in FIG.

In FIG. 16, one supply sensor 42
If only the presence of a sheet is detected, the number of suction steps is set to N1 as the suction amount. The number of suction steps is the number of operation steps of the motor that drives the shaft 26 of the sheet feeding device 10. When the two supply sensors 42 detect the presence of a sheet, the number of suction steps is set to N2-X.
Set to 1. When the three supply sensors 42 detect the presence of a sheet, the number of suction steps is set to N3-X2. When the four supply sensors 42 detect the presence of a sheet, the number of suction steps is set to N4-X3. In this example, N1 is the maximum, and the number of suction steps decreases sequentially.

Then, in step S3-1, the shaft 26 is driven to perform the suction operation of the sheet feeding device 10. In this suction operation, as described above, the sheet is conveyed toward the sheet conveying rollers 60 and 62 and is brought into contact with the sheet conveying rollers 60 and 62 to correct the skew. N1 has the largest number of suction steps, and N4-X3 has the smallest number of suction steps. This is because when the number of the supply sensors 42 that detect the presence of the sheet is small, that is, when the paper width is small (postcard vertical writing or the like), the conveyance amount of the protrusion 36 of the shaft 26 is small, and it is difficult to correct. Due to the condition of being set obliquely during setting, the number of suction steps is set to be large. Conversely, when the number of supply sensors 42 that detect the presence of a sheet is large, that is, when the sheet width is large, the amount of conveyance of the protrusion 36 of the shaft 26 becomes large and correction is easy, and Due to the conditions that are difficult to set, the number of suction steps is set to be small. Even if the number of suction steps is set to a relatively large value, there is no problem in correcting the skew, but the throughput decreases. In addition, if the number of suction steps is set to a small constant value in order to improve the throughput, the suction will be performed with a skew correction incomplete with a narrow sheet.

After the rotation of the shaft 26 is completed, in step S3-2, the sheet conveying rollers 60 and 6 of the printer 50 are turned on.
2 so that the upper end of the sheet is engaged with the sheet, and the sheet is fixed to the sheet conveying rollers 60 and 62 of the printer 50. In order to confirm the sheet detection status in step 4, the shaft 26 and the conveying rollers 60 and 62 of the sheet conveying apparatus are used. Are simultaneously moved by a predetermined amount.

After the rotation of the shaft 26 and the conveying rollers 60 and 62 is completed, in step S4, the sheet detection status is confirmed again, and the carrier moving position is determined. The carrier movement position is shown, for example, in FIG. Shaft 2
The reason why the sheet detection status is confirmed again after the rotation of No. 6 is completed is that the sheet detection status may be different between when the sheet is set and when the rotation of the shaft 26 is completed.

In FIG. 17, four supply sensors 42
Are assigned PSS1 to PSS4. NO
As in 1, when the four supply sensors 42 are off,
The carrier 72 is set to the position for single-sheet suction (the position for single-sheet suction when the printer is alone). When any one of the supply sensors 42 is ON as in NO2, 3, 5, and 9, the left side (84a) of the upper end sensor 84 of the sheet of the carrier 72 is set at a position on the extension of the supply sensor 42. NO4, 7, 8,
When two or more supply sensors 42 are continuously turned on, such as 13, 15, 16, the carrier 72 is located at a central position on the extension of the supply sensors 42. NO6, 1
Two or more supply sensors 4 such as 0, 11, 12, and 14
When 2 is turned on discontinuously, it is determined that there is an error, and the carrier 72 is moved to the cut-sheet suction position.

Referring to FIG. 14, in step S5, the carrier 72 is moved to a previously set position. For example, in the case of NO2 in FIG. 17, the left side (84a) of the sheet upper end sensor 84 of the carrier 72 (sheet guide 86) in FIG.
Is moved to a position on the extension of the supply sensor 42 on the leftmost side.
That is, in this case, since the small sheet is set at the leftmost position, the carrier 72 is made to correspond to this sheet in advance.

In step S6, the suction operation of the printer is started. In step S7, it is determined whether the upper end of the sheet has been detected. The upper end of the sheet is detected by two sheet upper end sensors 84. Next, in step S8, the skew feeding counter is updated. As shown in FIG.
When one sheet upper end sensor 84 of the two sheet upper end sensors 84 is turned on and the other sheet upper end sensor 84 is turned off, the sheet P has a skew, and the skew judgment counter (C). Counts and updates the difference between the on and off states of the two sheet upper end sensors 84 as the number of steps.

Step S8 will be described in accordance with the flowchart shown in FIG. 26. First, in step S8-1, the sensor 84
The state of a is checked, and if there is no sheet, the state of the sensor 84b is checked in step S8-2, and if there is no sheet, the skew determination counter (C) is reset in step S8-4. In step S8-2, the sensor 8
If the determination in 4b indicates that there is a sheet, the skew determination counter is updated as in step S8-3. Step S8-1
If it is determined in step S8-5 that there is a sheet, step S8-5 is performed.
Check the state of the sensor 84b. Step S8
If the sensor 84b determines that there is no paper at -5, the skew determination counter is updated in step S8-6, as in step S8-3. If it is determined in step S8-5 that there is a sheet, the process proceeds to step S9 without changing the skew determination counter.

In step S9, it is determined whether or not the suction operation has been completed. If the suction operation has not been completed, the process proceeds to step S7. If the suction operation has been completed, the suction operation by the sheet transport rollers 60 and 62 ends in step S10. Next, in step S11 of FIG. 15, it is determined whether or not skewing has been performed. If the determination is yes, the process proceeds to step S12, where the sheet is discharged to the sheet supply device 10 and a retry is performed. That is, the paper transport rollers 60 and 6
2 is rotated in the reverse direction, and then the shaft 2 of the sheet feeding device 10 is rotated.
6 is also rotated in the reverse direction. Thus, the sheet is discharged from the printer 50 to the sheet supply device 10. At this time, the sheet conveying rollers 60 and 62 and the shaft 26 are reversely rotated by an amount plus the number of steps at the time of suction so that the sheet is surely separated from the sheet conveying rollers 60 and 62.

In the retry process, step S13
Then, the retry counter is updated, and it is determined whether or not the retry counter is smaller than a predetermined value W in step S14. If the determination in step S14 is yes, the shaft 26 of the sheet feeding device 10 is further reversely rotated by a certain amount. As a result, the sheet is conveyed further away from the sheet conveying rollers 60 and 62 by the protrusion 36 of the shaft 26, and in this case also, the skew of the sheet is corrected to some extent. In particular, since there is a large gap between the sheet conveying rollers between the portions (a) and correction is difficult, the corresponding position and angular phase of the sheet supply projection 36 are set so that the skew is corrected to some extent during retry discharge. Then, the program proceeds to step S2 in FIG. 13, and repeats sheet supply and skew correction. The phase of the shaft 26 is adjusted each time it stops, and the next time the shaft 26 is driven,
0 and 62 can be synchronized. If the determination in step S14 is NO, the process proceeds to step S15, and an error is determined.

If the determination in step S11 is no,
Proceeding to step S16, it is determined whether the two sheet top sensors 84 have detected the top of the sheet. If the determination in step S16 is YES, the process proceeds to step S20, where it is determined that the sheet has no skewing and the sheet has been sucked, and the printing operation is started. Step S1
If the determination of No. 6 is no, the process proceeds to step S17, and the sheet width detecting operation is performed. Then, the process proceeds to step S18 to determine whether the sheet width is smaller than the set minimum value PW.

If the determination in step S18 is no,
Proceeding to step S21, reverse line feed is performed by the amount from the detection of the upper end of the sheet to the stop of the sheet plus the amount of alpha. In step S22, the carrier 72 is moved so that the carrier 72 comes to the position of the center of the detected sheet width. Then, the program returns to step S6 in FIG. 14, and repeats the detection of the upper end and the detection of the skew. That is, when the sheet width is larger than the set minimum value PW,
Because one of the two sheet top sensors 84 may not be located within the width of the sheet, the carrier 72
To repeat the detection of the upper end and the detection of the skew. If the determination in step S18 is YES, the process proceeds to step S19, and an error is determined because the sheet width is smaller than the set minimum value PW. For the detection of the sheet width in step S17, as shown in the flowchart of FIG.
The carrier movement start position is determined. First, step S
By performing the processing from step 25 to step S33,
The movement target position of the carrier 72 is determined. In the example,
The carrier 72 sets the position on the left of the leftmost supply sensor 42 of the four supply sensors 42 where the signal is on as the movement target position, the movement target position is determined in step S33, and the movement is performed in step S34. Centered to the target position.

For example, if the determination in step S26 is YES, the signal of the leftmost supply sensor 42 is ON, so that the carrier 72 is maintained at the first left end at the movement target position. In the case of YES in step S27, the signal of the leftmost supply sensor 42 is off, the signal of the second supply sensor 42 from the left is on, and step S28.
Then, the carrier 72 is set at the position of the supply sensor 42 at the leftmost position as the movement target position, and is centered at step 34 at the movement target position. This state is shown in FIG.

If the answer is YES in step S29, the third supply sensor 42 from the left is turned on for the first time, and in step S30, the carrier 72 sets the position of the second supply sensor 42 from the left as the movement target position. . Similarly, in the case of YES in step S31, the fourth supply sensor 42 from the left is turned on for the first time, and in step S32, the carrier 72 sets the position of the third supply sensor 42 from the left as the movement target position. Thus, the movement target position of the carrier 86 is determined in step S33, and the carrier 72 is centered at the movement target position in step S34. In the example shown in FIG. 20, each position where the carrier 72 is centered is referred to as a reference position, and the distance between the reference position and the sheet upper end sensor 84 is referred to as a sensor distance. After centering the carrier 72, the sheet width detection is performed as shown in FIG.
As shown in FIGS. 1 and 22, the sheet width can be detected by a simple operation while moving the carrier 72 from left to right.

The sheet width is first detected in step S in FIG.
At 40, a carrier movement target position is set according to the maximum printing digit, and at step S41, the sheet end surface is not determined. The reason is that when the left and right edges of the sheet are detected, it is determined whether or not the left and right edges of the sheet have been detected in order to stop the carrier 72 without reaching the target position (step S57). The end face is left undecided. Next, in step S42, the movement of the carrier 72 from left to right is started. In step S43, it is determined whether the left end has been determined. If the determination in step S43 is NO, in step S44, it is determined whether or not the sheet upper end sensor (S1) 84 on the left side has detected a sheet.

If the determination in step S44 is NO, the left chucker counter is set to 0 in step S49. If the determination in step S44 is yes, the left chucker counter is incremented by 1 in step S45. In step S46, it is determined whether or not the left chucker counter is larger than N1.
If the result is YES, the position of the left end of the sheet is determined in step S47, and it is determined that the left end has been determined in step S48.

Left end position = (reference position of carrier 72−
(Sensor distance-left chatter counter). Carrier 7
2 has been moving since step S42 and the carrier 72
Is the updated value, and the reference position of the carrier 72 used here includes the movement amount until the left sheet upper end sensor 84a moves from the left position of the left end of the sheet to a position crossing the left end of the sheet. In. The reason for subtracting the left chatter counter is that the left sheet upper end sensor 84a is used.
Is to return to the position where the left end of the sheet is first detected.

Then, it is determined whether or not the right end has been determined in step S50 of FIG. If the determination in step S50 is NO, in step S51, it is determined whether or not the upper right sheet sensor 84b detects the sheet. If the determination in step S51 is NO, the right chatter counter is set to 0 in step S56. If the determination in step S51 is YES, the right chatter counter is incremented by 1 in step S52. In step S53, it is determined whether the right chatter counter is greater than N2. If the result is YES, the position of the right end of the sheet is determined in step S54, and it is determined that the right end has been determined in step S55. In this case, the right end position = (reference position of carrier 72 + sensor distance−right chatter counter).

In step S57, it is determined whether or not the left and right ends have been determined. If yes, the movement of the carrier 72 ends in step S58, and the process ends. If “NO” in the step S57, it is determined whether or not the carrier 72 has exceeded the movement target position in a step S59. If the result of step S59 is NO, the process returns to step S43 and continues. If the result of step S59 is yes, step S
Proceeding to 60, the left and right undetermined sides are determined. Step S
At 61, the movement of the carrier 72 is stopped.

The undetermined sides at the left and right ends are described as follows. For example, in the above description of the determination of the left end, it has been described that the left sheet upper end sensor 84a crosses the left end of the sheet. However, if the left sheet upper end sensor 84a is positioned on the sheet from the beginning, the left sheet upper end sensor 84a The sensor 84a does not cross the left edge of the sheet and cannot detect the left edge of the sheet. In such a case, the carrier 7
The minimum value of the reference position 2 in the left direction is the left end position. If the right end is undecided, the right end position is the maximum value in the right direction.

FIG. 23 is a flowchart of control for determining the printing position. In steps S60 and S61, the left and right edges of the sheet determined above are used. In step S62, it is determined whether the position of the left end of the sheet is outside or inside the predetermined area. If the position of the left end of the sheet is outside the predetermined area, the process proceeds to step S63. If the position of the left end of the sheet is inside the predetermined area, the process proceeds to step S64. Similarly, in step S65, it is determined whether the position of the right end of the sheet is outside or inside the predetermined area. If the position of the right end of the sheet is outside the predetermined area, step S65 is executed.
Go to step 66, and if the right end position of the sheet is inside the predetermined area, go to step S67.

FIG. 24 is a diagram for explaining the operation of FIG. (A) shows a case where the width of the sheet is small and the positions of the left and right ends of the sheet are inside a predetermined area.
(B) shows a case where the width of the sheet is large and the positions of the left and right ends of the sheet are outside the predetermined area. In (B), the predetermined area is described as a normal printing area. Here, the normal printing area is the sheet feeding device 1
0 is a print area in the printer 50 when it is not attached. The print head 74 of the carrier 72 can move in an area wider than a normal print area. The normal printing area is defined as an area narrower by N digits on the left side and by M digits on the right side of the moving range of the print head 74.

In steps S64 and S67, as in the case of (A), the positions in consideration of the left and right margins with respect to the actually detected left and right ends are set as the print start position and the print end position. In steps S63 and S66, as in (B), the right and left limit positions where the print head 74 of the carrier 72 can actually move are set as the print start position and print end position. As described above, the width of the carrier 72 is detected by detecting the width of the sheet.
The print head 74 can be moved faster to print over a wider range.

FIG. 25 is a flowchart of line feed control. The supply sensor 42 of the sheet supply device 10 is also used to detect the lower end position of the sheet. Further, as shown in FIG. 6, the printer 50 includes a sheet conveying roller 60,
62 includes a sheet sensor 82 disposed in the vicinity of 62. The sheet sensor 82 detects the lower end position of the sheet when the sheet feeding device 10 is not provided.

In step S80, a line feed phase is switched.
In step S81, it is determined whether the sheet feeding device 10 is attached to the printer 50. Step S8
If the result of step 1 is YES, it is determined in step S82 whether the sheet is supplied from the sheet supply apparatus 10. If the result of step S82 is YES, it is determined in step S83 whether the supply sensor 42 is on. If the result of step S83 is YES, the line feed remaining line counter is set to an initial value in step S84, and if NO, it is determined that the lower end of the sheet has passed the supply sensor 42, and in step S85, the line feed remaining line is counted. Update the counter value. When the plurality of supply sensors 42 are on, it is determined that the lower end of the sheet has passed the supply sensors 42 when all the supply sensors 42 are turned off.

If no in steps S81 and S82, it is determined in step S84 whether the sheet sensor (PE) 82 of the printer 50 is on.
If the result of step S84 is YES, step S84
At 86, the line feed remaining line counter is set to the initial value, and in the case of no, it is determined that the lower end of the sheet has passed the supply sensor 42,
In step S87, the value of the line feed remaining line counter is updated.
Then, in step S87, it is determined whether or not the line feed remaining line counter is greater than 0. If the result is NO, the line feed remaining line counter continues to be updated. In S89, the notification of the PE is performed. The line feed remaining line counter continues until the bottom margin of the sheet reaches a predetermined amount. When the bottom margin of the sheet reaches a predetermined amount, printing is stopped, and a notification of PE (a notification of the end of printing) is sent to, for example, a control device. Then, necessary processing is performed.

The detection of the lower end of the sheet by the supply sensor 42 uses a sensor for detecting the presence or absence of a sheet in the sheet supply device 10, and when all of the plurality of sensors have become empty, it is determined that the lower end of the sheet is present. Determine the print area.
Even if the skew correction has been successful at the end of the skew correction in the sheet feeding apparatus 10, some skew remains, so that when all the sensors are out of sheets, the lower end of the sheet is determined. When one sensor detects the presence of a sheet, it determines that the sheet is at the lower end when one sensor detects the lower end of the sheet.

[0057]

As described above, according to the present invention,
The skew of the sheet can be corrected more reliably.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a printer having a sheet feeding device according to an embodiment of the present invention.

FIG. 2 is a perspective view showing a state where the sheet feeding device is attached to a printer.

FIG. 3 is a diagram illustrating a state where a sheet feeding device is removed from a printer.

FIG. 4 is an exploded perspective view illustrating details of a sheet feeding device.

FIG. 5 is a plan view illustrating a plane of a sheet feeding apparatus.

FIG. 6 is a cross-sectional view illustrating the printer to which the sheet feeding device is attached.

FIG. 7 is a side view of a frame of the sheet feeding apparatus viewed from a lateral direction to show a protrusion attached to a shaft.

FIG. 8 is a side view of a frame of the sheet feeding apparatus viewed from a lateral direction to show a phase sensor.

FIG. 9 is a diagram illustrating a rotation device of a shaft of the sheet feeding device.

FIG. 10 is a cross-sectional view illustrating a shaft having a plurality of protrusions and a sheet conveying path.

FIG. 11 is a diagram showing a carrier having a print head and two sheet upper end sensors.

FIG. 12 is a diagram illustrating the principle of correcting skew of a sheet.

FIG. 13 is a flowchart of control of the sheet feeding device.

FIG. 14 is a continuation of the flowchart of FIG. 13 and is a flowchart of control of the printer.

FIG. 15 is a continuation of the flowchart of FIG. 13 and is a flowchart of control of the printer.

FIG. 16 is a diagram illustrating a relationship between the output of a supply sensor provided in the sheet supply device and the number of drive steps of a shaft.

FIG. 17 is a diagram illustrating a relationship between an output of a supply sensor provided in the sheet supply device and a carrier movement position.

FIG. 18 is a diagram illustrating skew of a sheet.

FIG. 19 is a flowchart illustrating an initial operation of a carrier for detecting a sheet width.

FIG. 20 is a diagram illustrating centering in the initial operation of the carrier.

FIG. 21 is a flowchart of control for detecting a sheet width.

FIG. 22 is a flowchart that follows the control of sheet width detection.

FIG. 23 is a flowchart continued from control for determining a print position.

FIG. 24 is a diagram illustrating how a print position is determined.

FIG. 25 is a flowchart of line feed phase switching including detection of the lower end of a sheet.

FIG. 26 is a flowchart of updating a skew determination counter.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Sheet supply device 12 ... Frame 14 ... Recess 24 ... Sheet conveying surface 26 ... Shaft 34 ... Supply motor 36 ... Protrusion 38 ... Deformed roller 40 ... Phase sensor 42 ... Supply sensor 44 ... Dent 50 ... Printer 52 ... Case 60 62 ... Sheet conveying rollers 64, 66 ... Studs 68, 70 ... Recess 72 ... Carrier 74 ... Print head 76 ... Platen 78, 80 ... Sheet conveying rollers 84 ... Sheet upper end sensor

Continued on the front page (72) Inventor Haruhiko Yashima 1405 Daimaru, Daiji, Inagi-shi, Tokyo Inside Fujitsu A Isotec Co., Ltd. 2C059 AA05 AA32 AA47 3F049 AA02 CA02 CA03 CA16 DA05 DA11 EA10 EA24 EA28 LA07 LB03 3F102 AA01 AB01 BA02 BB04 CA03 CB01 DA08 EA03 FA08

Claims (8)

[Claims] 1. A sheet conveying surface to which a sheet is supplied, and at least one slant which conveys the sheet supplied to the sheet conveying surface along the sheet conveying surface by rotating the sheet in contact with the sheet. A skew correction member, wherein the skew correction member is configured to have a rotation angle range that does not contact the sheet in one rotation, and the skew correction member is conveyed by the rotation of the skew correction member. The sheet is configured such that the skew of the sheet is corrected by the end of the sheet in the conveyance direction abutting against an abutting member provided downstream of the skew correction member in the sheet conveyance direction. A sheet feeding device, comprising: 2. A phase sensor for detecting a rotational position of the skew feeding correcting member, and according to an output of the phase sensor,
The sheet feeding apparatus according to claim 1, wherein the skew feeding correction member is configured to stop at a rotation position where the skew feeding correction member does not contact the sheet. 3. The sheet feeding apparatus according to claim 1, wherein the sheet conveying surface is configured such that at least a portion facing the skew feeding correction member does not contact the skew feeding correction member. 4. A sheet conveying surface to which a sheet is supplied, and at least one inclined member for conveying the sheet supplied to the sheet conveying surface by rotating the sheet in contact with the sheet along the sheet conveying surface. A row correction member, a sheet conveyance roller provided downstream of the skew correction member in the conveyance direction of the sheet, and a sheet conveyance roller for conveying the sheet; and a sheet correction roller provided downstream of the sheet conveyance roller in the conveyance direction of the sheet. A processing mechanism that performs processing on the sheet conveyed by the sheet conveying roller so as to face the sheet, wherein the skew feeding correction member has a rotation angle range that does not contact the sheet in one rotation. When the end of the sheet conveyed by the rotation of the skew feeding correction member on the side in the conveyance direction abuts on the sheet conveyance roller, Processing apparatus skew of the sheet is made is configured to be corrected, it is characterized. 5. A skew feeding correcting member further comprising a plurality of supply sensors disposed between the skew feeding correcting member and the sheet feeding roller at intervals in a width direction of the conveyed sheet. The processing apparatus according to claim 4, wherein the processing apparatus is driven in accordance with an output of the supply sensor. 6. The information processing apparatus according to claim 4, wherein the processing device is a printer, and the processing mechanism is a print head. 7. A phase sensor for detecting a rotational position of the skew feeding correcting member, and according to an output of the phase sensor,
At a rotational position where the skew feeding correction member does not contact the sheet,
5. The processing apparatus according to claim 4, wherein the processing apparatus is configured to stop. 8. The processing apparatus according to claim 4, wherein the sheet conveying surface is configured such that at least a portion facing the skew feeding correction member does not contact the skew feeding correction member.