This patent application is based on and claims priority pursuant to 35 U.S.C. § 119(a) to Japanese Patent Application No. 2022-184956, filed on Nov. 18, 2022, in the Japan Patent Office, the entire disclosure of which is hereby incorporated by reference herein.
Embodiments of the present disclosure relate to a sheet feeder.
A sheet feeder is known that floats a sheet by air and sucks and conveys the sheet by a suction belt. In such a sheet feeder, desirably, clearances between restricting members to support stacked sheets in the width direction of the sheets and lateral sides of the sheets are adequate to stabilize feeding and conveyance of the sheets. In such a sheet feeder, a technology is employed that detects the time needed for a sheet to float to determine whether clearances between restricting members to support stacked sheets in the width direction of the sheets and the lateral sides of the sheets are adequate.
In an embodiment of the present disclosure, a sheet feeder according to a first aspect includes a lift table on which sheets are stacked, a first sheet-side restricting member, a second sheet-side restricting member, a suction conveyor, a rear-end restricting member, an upper distance-measuring sensor, a lower distance-measuring sensor, and processing circuitry. The lift table is movable in a vertical direction. The first sheet-side restricting member restricts first ends of the sheets stacked on the lift table in a width direction of the sheets. The second sheet-side restricting member restricts second ends of the sheets opposite to the first ends of the sheets in the width direction of the sheets. The suction conveyor sucks and conveys a sheet floated from the lift table after the lift table is lifted. The rear-end restricting member is disposed at a center portion of the sheets in the width direction of the sheets, to restrict the sheets stacked on the lift table from moving in a longitudinal direction of the sheets. The upper distance-measuring sensor is disposed at an upper portion of the rear-end restricting member, to measure a first distance to the first sheet-side restricting member or the second sheet-side restricting member. The lower distance-measuring sensor is disposed at a lower portion of the rear-end restricting member, to measure a second distance to the first sheet-side restricting member or the second sheet-side restricting member. The processing circuitry compares a measurement result of the first distance with a measurement result of the second distance to determine whether a distance between the first sheet-side restricting member and the second sheet-side restricting member is adequate.
A more complete appreciation of the disclosure and many of the attendant advantages and features thereof can be readily obtained and understood from the following detailed description with reference to the accompanying drawings, wherein:
The accompanying drawings are intended to depict embodiments of the present disclosure and should not be interpreted to limit the scope thereof. The accompanying drawings are not to be considered as drawn to scale unless explicitly noted. Also, identical or similar reference numerals designate identical or similar components throughout the several views.
In describing embodiments illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the disclosure of this specification is not intended to be limited to the specific terminology so selected and it is to be understood that each specific element includes all technical equivalents that have a similar function, operate in a similar manner, and achieve a similar result.
Referring now to the drawings, embodiments of the present disclosure are described below. As used herein, the singular forms “a,” “an,” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise.
A sheet feeder according to embodiments of the present disclosure is described in detail with reference to the accompanying drawings in the following description.
As illustrated in
The image forming system 200 sends a recording medium 8 such as a sheet of paper conveyed from the sheet feeder 210 to the pretreatment-liquid application apparatus 220. The pretreatment-liquid application apparatus 220 applies a pretreatment liquid to the recording medium 8 to enhance image quality such as for prevention of ink bleeding and assistance of ink permeation. The pretreatment-liquid application apparatus 220 applies the pretreatment liquid to the front side, the back side, or both sides of the recording medium 8.
The sheet feeder 210 supplies the recording medium 8 such as a cut sheet to the pretreatment-liquid application apparatus 220 disposed downstream from the sheet feeder 210 in a conveyance path of the recording medium 8. As described below, the pretreatment-liquid application apparatus 220 applies the pretreatment liquid, which prevents, for example, bleeding and bleed-through of inkjet ink printed on the recording medium 8, to the recording medium 8. The pretreatment-liquid application apparatus 220 includes a reverse path. In the case of duplex printing, after the pretreatment-liquid application apparatus 220 has applied the pretreatment liquid to the front side of the recording medium 8, the pretreatment-liquid application apparatus 220 reverses the recording medium 8 and applies the pretreatment liquid to the back side of the recording medium 8.
The inkjet printer 230 discharges ink droplets to the front side of the recording medium 8 to which the pretreatment liquid has been applied by the pretreatment-liquid application apparatus 220 to form a desired image. The drier 240 includes a drying device and dries the image on the front side of the recording medium 8, formed by the inkjet printer 230. When printing is performed on the front and back sides of the recording medium 8, the recording medium 8 is reversed along a path on which the recording medium 8 returns from the drier 240 back to the inkjet printer 230. Then, the inkjet printer 230 discharges ink droplets onto the front side, which is the back side of the recording medium 8 before the recording medium 8 is reversed, of the recording medium 8 to form a desired image. Subsequently, the drier 240 dries the image on the front side, which is the back side of the recording medium 8 before the recording medium 8 is reversed, of the recording medium 8. Then, the recording medium 8 is ejected to the sheet ejector 250.
The sheet tray 100 provided for the sheet feeder 210 includes a lift table 5 movable in a vertical direction in
The recording media 8 are stacked such that downstream ends of the recording media 8 in the longitudinal direction of the recording media 8 contact a front-side plate 11. Upstream ends of the recording media 8 in the longitudinal direction of the recording media 8 are pressed against a rear-end restricting member 4 to be aligned along the rear-end restricting member 4. In other words, the rear-end restricting member 4 serves as a rear-end restricting member that restricts the recording media 8, which are stacked on the lift table 5, from moving in the longitudinal direction. The rear-end restricting member 4 is disposed at a center portion of the recording medium 8 in the width direction. The rear-end restricting member 4 is coupled to a guide rail 16. The guide rail 16 is fixed to a guide frame 2. The rear-end restricting member 4 is movable in the longitudinal direction of the recording medium 8 and is fixed with the upstream ends of the recording media 8 in the longitudinal direction of the recording medium 8 pressed against the front-side plate 11. The amount of movement of the rear-end restricting member 4 corresponds to the size of the recording media 8 in the longitudinal direction, which is the size of the sheets of paper in the longitudinal direction, stacked on the sheet tray 100. The range of the amount of movement of the rear-end restricting member 4 is set in accordance with the size of the recording media 8 in the longitudinal direction.
When a printing operation is started in the image forming system 200, the sheet feeder 210 blows air from an air nozzle 30 attached to the front-side plate 11 to cause an uppermost recording medium 8 to float up to the vicinity of a pickup belt 6 to a position upstream in the longitudinal direction of the recording media 8. Multiple holes are formed in the pickup belt 6, and air is sucked into the multiple holes by a fan.
Accordingly, the recording medium 8 floated by the air blown out from the air nozzle 30 is attracted to the pickup belt 6 and is ejected in a direction toward a guide plate 7 with the movement of the pickup belt 6. In other words, the pickup belt 6 and the air nozzle 30 serve as a suction conveyor that conveys the recording medium 8 floated from the lift table 5 after the lift table 5 has been lifted.
When the recording medium 8, which floats from downstream to upstream in the conveyance path of the recording medium 8 by the air blown from the air nozzle 30, is excessively floated by air, the recording medium 8 may be folded and wrinkled. For this reason, multiple sheet-pressing guides 1 are attached to the guide frame 2 in the longitudinal direction of the recording medium 8.
In the present embodiment, the sheet tray 100 of the sheet feeder 210 has a box-shaped structure formed with a left-side plate 13 and a right-side plate 12 attached to the bottom plate 10. In the box-shaped structure, for example, the lift table 5 and the rear-end restricting member 4 are disposed.
The guide frame 2 is attached to the right-side plate 12 via a hinge 15 to rotate about the hinge 15. The multiple sheet-pressing guides 1 are attached to the guide frame 2 and are fixed at given positions in accordance with the width of the recording media 8. A right sheet-side restricting member 33a and a left sheet-side restricting member 33b are attached to the right side and left side, respectively, of the lift table 5. The positions of the right sheet-side restricting member 33a and the left sheet-side restricting member 33b are moved in accordance with the recording media 8 set on the lift table 5.
The right sheet-side restricting member 33a and the left sheet-side restricting member 33b are moved in conjunction with each other by a coupler 35. Specifically, the right sheet-side restricting member 33a serves as a first sheet-side restricting member that restricts ends of the recording media 8 on one side in the width direction, which are stacked on the lift table 5. Those ends of the recording media 8 on one side are examples of the first ends of recording media. The left sheet-side restricting member 33b serves as a second sheet-side restricting member that restricts the other ends of the recording media 8 on the other side, which are stacked on the lift table 5. Those other ends of the recording media 8 on the other side are examples of the second ends of the recording media. The right sheet-side restricting member 33a and left sheet-side restricting member 33b are disposed to be movable in conjunction with each other in the width direction of the recording media 8. The multiple bottom-surface supports 51 placed on the lift table 5 are removably attached to the lift table 5 in accordance with the width of the recording medium 8 and slidable in the width direction of the recording media 8. The right sheet-side restricting member 33a and the left sheet-side restricting member 33b include multiple air nozzles 32 and 31, respectively. When the image forming system 200 starts a printing operation, air is blown out from the air nozzles 31 and 32. Accordingly, in the printing operation of the image forming system 200, several upper sheets of the recording media 8 may float as a whole, and the floated sheets of the recording media 8 are restricted by the sheet-pressing guides 1 and held at a constant height.
Specifically,
When the inclination of the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is large, the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 may be narrower than the size of the recording media 8 in the width direction after the lift table 5 is lifted to the vicinity of the pickup belt 6. Accordingly, the right sheet-side restricting member 33a and the left sheet-side restricting member 33b may be pressed against the lateral sides of the recording media 8. In particular, when sheets of thick paper each having a large basis weight, which is an example of the recording media 8, are employed and the lift table 5 is lifted, the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of recording media 8 may become narrow. In such cases, the friction between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 may increase when the recording media 8 is floated and sucked and conveyed, which may cause a sheet feeding failure. In a method in which whether the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 are adequate is determined after lifting of the recording media 8 is started, the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 are readjusted after the operation of the image forming system 200 which is in operation is stopped. Accordingly, the time to start over the operation is long.
In the present embodiment, the sheet feeder 210 includes a lower distance-measuring sensor 40a and an upper distance-measuring sensor 40b at a lower portion and an upper portion, respectively, of the rear-end restricting member 4 disposed at the center of the lift table 5 in the width direction of the recording media 8. The lower distance-measuring sensor 40a and the upper distance-measuring sensor 40b measure distances to the right sheet-side restricting member 33a and the left sheet-side restricting member 33b.
Specifically, the upper distance-measuring sensor 40b is disposed at the upper portion of the rear-end restricting member 4 and serves as an upper distance-measuring sensor that measures a first-measurement value that is an example of a first distance, which is the distance to the right sheet-side restricting member 33a or to the left sheet-side restricting member 33b. The lower distance-measuring sensor 40a is disposed at the lower portion of the rear-end restricting member 4 and serves as a lower distance-measuring sensor to measure a second-measurement value that is an example of a second distance, which is the distance to the right sheet-side restricting member 33a or the left sheet-side restricting member 33b. In the present embodiment, desirably, the upper distance-measuring sensor 40b is disposed at a height similar to the height at which the pickup belt 6 is disposed. The lower distance-measuring sensor 40a is disposed at a height in the vicinity of the upper surface of the lift table 5 when the lift table 5 is lowered to the lowest position.
After the recording media 8 are stacked and the positions of the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the rear-end restricting member 4 are adjusted, the sheet feeder 210 compares the measured values of the upper distance-measuring sensor 40b and the lower distance-measuring sensor 40a before lifting operation of the lift table 5 is started. When the first-measurement value measured by the upper distance-measuring sensor 40b is smaller than the second-measurement value measured by the lower distance-measuring sensor 40a, the sheet feeder 210 determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b in the vicinity of the pickup belt 6 is narrower than the size of the recording media 8 in the width direction. In this case, the sheet feeder 210 displays an alert to request readjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b such that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is widened.
Whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b in the vicinity of the pickup belt 6 is adequate may be determined using the sheet width of the recording media 8 set in advance by an operator, which is referred to as sheet-width size in the following description, in addition to the measured values measured by the upper distance-measuring sensor 40b and the lower distance-measuring sensor 40a. More specifically, even when the first-measurement value measured by the upper distance-measuring sensor 40b is smaller than the second-measurement value measured by the lower distance-measuring sensor 40a, the sheet feeder 210 may not display the alert to request readjustment to widen the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b when the first-measurement value measured by the upper distance-measuring sensor 40b is greater than the sheet-width size set in advance.
As a result, the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b at a position at which the recording media 8 are sucked and conveyed is adequately secured. Accordingly, the recording media 8 can be fed and conveyed in a stable manner. Whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate can be determined before the lift table 5 is lifted. Accordingly, the time to start over the operation can be minimized when the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is readjusted.
Specifically,
The lower distance-measuring sensor 40a and the upper distance-measuring sensor 40b are attached to lower and upper portions, respectively, of the rear-end restricting member 4 in the sheet tray 100, to measure distances to the right sheet-side restricting member 33a and the left sheet-side restricting member 33b. The control panel 601 receives input of setting information of sheet data, for example, a sheet-width size, and displays the alert to request readjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b. The lifting motor 40 lifts or lower the lift table 5. The lower distance-measuring sensor 40a and the upper distance-measuring sensor 40b, the control panel 601, and the lifting motor 40 are electrically connected to the controller 602 and controlled by the controller 602.
The controller 602 includes, for example, an input and output (I/O) port 602a, a central processing unit (CPU) 602b, and a read-only memory (ROM) 602c. The CPU 602b of the controller 602 determines whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate based on, for example, the measurement values of the lower distance-measuring sensor 40a and the upper distance-measuring sensor 40b, sheet data displayed on the control panel 601, sheet-size data and the allowable range of distance data stored in the ROM 602c. Subsequently, based on the above-described determination result, the CPU 602b causes the control panel 601 to display the alert to request readjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and outputs an instruction to start lifting the lift table 5 to the lifting motor 40.
Specifically, the CPU 602b serves as or functions as a determiner that compares the first-measurement value, i.e., the measurement result of the first distance, with the second-measurement value, i.e., the measurement result of the second distance, to determine whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. Specifically, when the first-measurement value is equal to or greater than the second-measurement value, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. Accordingly, in the sheet feeder 210 that feeds the recording media 8 after the lift table 5 is lifted and the recording media 8 are moved to the vicinity of the suction conveyor, the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 in the vicinity of the suction conveyor can be adequately secured, even if the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 are adjusted when the recording media 8 are stacked. At the same time, unnecessary friction between the left sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 can be prevented from being generated, and the time to start over the operation can be reduced.
In the present embodiment, the CPU 602b determines whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate before the lift table 5 is lifted. Accordingly, the CPU 602b determines whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate before the lift table 5 is lifted. By so doing, the occurrence of downtime can be prevented and the operation time to readjust the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b can be minimized.
In the present embodiment, when the positions of the right sheet-side restricting member 33a, the left sheet-side restricting member 33b, and the rear-end restricting member 4 are adjusted in accordance with the recording media 8 such as stacked sheets of paper stacked on the sheet tray 100 and the sheet tray 100 is set (step S701), the CPU 602b starts processing to determine whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. In the present embodiment, it is assumed that the right sheet-side restricting member 33a and the left sheet-side restricting member 33b contact against the lateral sides of the stacked recording media 8 to adjust the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b.
First, the CPU 602b acquires the first-measurement value measured by the upper distance-measuring sensor 40b (step S702). The CPU 602b acquires the second-measurement value measured by the lower distance-measuring sensor 40a (step S703). Subsequently, the CPU 602b determines whether the first-measurement value measured by the upper distance-measuring sensor 40b is equal to or greater than the second-measurement value measured by the lower distance-measuring sensor 40a. In other words, the CPU 602b determines whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b at upper sides of the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is greater than the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b at lower sides of the right sheet-side restricting member 33a and the left sheet-side restricting member 33b (step S704).
When the first-measurement value is equal to or greater than the second-measurement value (YES in step S704), the CPU 602b determines that the friction between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 does not increase when the recording media 8 are floated and sucked and conveyed even after the lift table 5 has been lifted. In such cases, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. Alternatively, when the first-measurement value is smaller than the second-measurement value (NO in step S704), the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is inadequate. Then, the CPU 602b displays an alert on the control panel 601 to request readjustment of the positions of the right sheet-side restricting member 33a and the left sheet-side restricting member 33b (step S705).
When the positions of a right sheet-side restricting member and a left sheet-side restricting member and a rear-end restricting member are adjusted and a sheet tray is set, the sheet feeder in the related art lifts a lift table by a lifting motor (step S801) and stops the lifting motor when the lift table reaches a position at which recording media are fed (step S802).
Subsequently, the sheet feeder in the related art determines whether the distance between the right sheet-side restricting member and the left sheet-side restricting member is adequate (step S803). When the distance between the right sheet-side restricting member and the left sheet-side restricting member is adequate (YES in step S803), the sheet feeder in the related art starts feeding the recording media. Alternatively, when the distance between the right sheet-side restricting member and the left sheet-side restricting member is inadequate (NO in step S803), the sheet feeder in the related art lowers the lift table by the lifting motor (step S804) and stops the lifting motor when the lift table reaches a lower-limit position (step S805).
When the positions of the right sheet-side restricting member 33a, the left sheet-side restricting member 33b, and the rear-end restricting member 4 are adjusted and the sheet tray 100 is set, the CPU 602b determines whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate by the above-described determination processing (step S901). When the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is inadequate (NO in step S901), the CPU 602b waits until the positions of the right sheet-side restricting member 33a, the left sheet-side restricting member 33b, and the rear-end restricting member 4 are adjusted and the sheet tray 100 is set.
Alternatively, when the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate (YES in step S901), the CPU 602b lifts the lift table 5 by the lifting motor 40 (step S902). When the lift table 5 reaches a position at which the recording medium 8 is fed, the CPU 602b stops the lifting motor 40 (step S903). Subsequently, the CPU 602b starts feeding the recording medium 8.
When the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate, there is no difference between the time in driving the lift table of the sheet feeder in the related art and the time in driving the lift table 5 of the sheet feeder 210 of the present embodiment. However, when it is determined that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is inadequate, in the sheet feeder in the related art, an extra operation time is needed for lifting and lowering the lift table. By contrast, in the sheet feeder 210 according to the present embodiment, it is determined whether the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate before the lift table 5 is driven. Accordingly, the occurrence of downtime can be prevented and the operation time for readjusting the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b can be minimized.
As described above, the sheet feeder 210 of the image forming system 200 according to the first embodiment feeds the recording medium 8 after the lift table 5 is lifted to move the recording media 8 to the vicinity of the suction conveyor. Such a configuration as described above allows the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 in the vicinity of the suction conveyor to be adequately secured, even if the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 are adjusted at the time at which the recording media 8 are stacked. As a result, unnecessary friction between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 can be prevented from being generated and the time to start over the operation can be reduced.
In a second embodiment of the present disclosure, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate even when the first-measurement value is smaller than the second-measurement value, if the first-measurement value is greater than the sheet-width size set in advance by an operator. In the following description, the description of configurations of the second embodiment similar to the configurations of the first embodiment are omitted.
In the present embodiment, if the first-measurement value is greater than the sheet-width size even when the first-measurement value is smaller than the second-measurement value, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. Accordingly, if the first-measurement value of the upper distance-measuring sensor 40b is greater than the preset sheet-width size even when the first-measurement value of the upper distance-measuring sensor 40b is smaller than the second-measurement value of the lower distance-measuring sensor 40a, an option in which the adjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is allowed can be selected. In so doing, an unnecessary operation to readjust the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b can be avoided.
In the following description, the description of processing similar to the processing illustrated in
When the first-measurement value is smaller than the second-measurement value (NO in step S704), the CPU 602b acquires sheet-size data indicating the sheet-width size set in advance by the operator (step S1001). Subsequently, the CPU 602b determines whether the first-measurement value is equal to or greater than the sheet-width size indicated by the sheet-size data (step S1002).
When the first-measurement value is equal to or greater than the sheet width size (YES in step S1002), the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is greater than the set sheet-width size, i.e., the sheet width of the stacked recording media 8 and that the friction between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 does not increase when the recording media 8 are floated and sucked and conveyed even after the lift table 5 is lifted. For this reason, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. Alternatively, when the first-measurement value is smaller than the sheet-width size (NO in step S1002), the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is inadequate and displays the alert to request readjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b on the control panel 601 (step S705).
As described above, in the sheet feeder 210 of the image forming system 200 according to the second embodiment, if the first-measurement value of the upper distance-measuring sensor 40b is greater than the sheet-width size set in advance even when the first-measurement value of the upper distance-measuring sensor 40b is smaller than the second-measurement value of the lower distance-measuring sensor 40a, an option in which the adjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is allowed can be selected. In so doing, an unnecessary operation to readjust the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b can be avoided.
In a third embodiment of the present disclosure, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate when the first-measurement value is equal to or greater than the second-measurement value and the difference between the first-measurement value and the second-measurement value falls within the allowable range or when the difference between the first-measurement value and the sheet-width size set in advance falls within the allowable range. In the following description, the description of configurations of the third embodiment similar to the configuration of the above-described embodiments is omitted.
In the present embodiment, the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate when the first-measurement value is equal to or greater than the second-measurement value and the difference between the first-measurement value and the second-measurement value falls within the allowable range or when the difference between the first-measurement value and a sheet-width size set in advance falls within the allowable range, which is, for example, greater than 0 mm and equal to or smaller than 2 mm which is an example of a predetermined value. Accordingly, a disadvantage related to the recording media 8, for example, the occurrence of skew of the recording media 8, which is caused when the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of recording media 8 are excessively large, can be prevented.
In the following description, the description of processing similar to the processing illustrated in
The CPU 602b determines whether a difference obtained by subtracting the second-measurement value from the first-measurement value is greater than 0 mm and equal to or smaller than a predetermined value, for example, 2 mm, in other words, whether the first-measurement value is equal to or greater than the second-measurement value and the above-described difference is greater than 0 mm and equal to or smaller than the predetermined value (step S1101). When the difference obtained by subtracting the second-measurement value from the first-measurement value is greater than 0 mm and equal to or smaller than the predetermined value (YES in step S1101), the friction between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of the recording media 8 does not increase when the recording media 8 are floated and sucked and conveyed even after the lift table 5 is lifted. In such a case, the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b falls within a certain range, i.e., the allowable range. Accordingly, the CPU 602b determines that the skew of the recording media 8 does not occur and the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate.
Alternatively, when the difference obtained by subtracting the second-measurement value from the first-measurement value is not in the range of greater than 0 mm and equal to or smaller than the predetermined value (NO in step S1101), the CPU 602b acquires the sheet-size data indicating the sheet-width size set in advance by the operator (step S1102). Subsequently, the CPU 602b determines whether a difference obtained by subtracting the sheet-width size from the first-measurement value is greater than 0 mm and equal to or smaller than the predetermined value (step S1103). When the CPU 602b determines that the difference obtained by subtracting the sheet-width size from the first-measurement value is greater than 0 mm and equal to or smaller than the predetermined value (YES in step S1103), the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is adequate. Alternatively, when the CPU 602b determines that the above-described difference is not in the range of greater than 0 mm and equal to or smaller than the predetermined value (NO in step S1103), the CPU 602b determines that the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b is inadequate and displays the alert to request readjustment of the distance between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b on the control panel 601 (step S705).
As described above, in the sheet feeder 210 of the image forming system 200 according to the third embodiment, a disadvantage related to the recording media 8, for example, the occurrence of skew of the recording media 8, caused when the clearances between the right sheet-side restricting member 33a and the left sheet-side restricting member 33b and the lateral sides of recording media 8 are excessively large, can be prevented. Aspects of the present disclosure are, for example, as follows.
First Aspect
A sheet feeder according to a first aspect includes a lift table on which sheets are stacked, a first sheet-side restricting member, a second sheet-side restricting member, a suction conveyor, a rear-end restricting member, an upper distance-measuring sensor, a lower distance-measuring sensor, and a determiner.
The lift table is movable in a vertical direction. The first sheet-side restricting member restricts first ends of the sheets stacked on the lift table in a width direction of the sheets. The second sheet-side restricting member restricts second ends of the sheets opposite to the first ends of the sheets in the width direction of the sheets. The suction conveyor sucks and conveys a sheet floated from the lift table after the lift table is lifted. The rear-end restricting member is disposed at a center portion of the sheets in the width direction of the sheets, to restrict the sheets stacked on the lift table from moving in a longitudinal direction of the sheets. The upper distance-measuring sensor is disposed at an upper portion of the rear-end restricting member, to measure a first distance to the first sheet-side restricting member or the second sheet-side restricting member. The lower distance-measuring sensor is disposed at a lower portion of the rear-end restricting member, to measure a second distance to the first sheet-side restricting member or the second sheet-side restricting member. The determiner compares a measurement result of the first distance with a measurement result of the second distance to determine whether a distance between the first sheet-side restricting member and the second sheet-side restricting member is adequate.
Second Aspect
In the sheet feeder according to the first aspect, the determiner determines that the distance between the first sheet-side restricting member and the second sheet-side restricting member is adequate when the first distance is equal to or greater than the second distance.
Third Aspect
In the sheet feeder according to the first aspect or the second aspect, the determiner determines that the distance between the first sheet-side restricting member and the second sheet-side restricting member is adequate when the first distance is smaller than the second distance and the first distance is greater than a sheet-width size set in advance by an operator.
Fourth Aspect
In the sheet feeder according to any one of the first to third aspects, the determiner determines whether the distance between the first sheet-side restricting member and the second sheet-side restricting member is adequate before the lift table is lifted.
Fifth Aspect
In the sheet feeder according to the first aspect or the fourth aspect, the determiner determines that the distance between the first sheet-side restricting member and the second sheet-side restricting member is adequate when the first distance is equal to or greater than the second distance and a difference between the first distance and the second distance falls within an allowable range or when a difference between the first distance and a sheet-width size set in advance by an operator falls within an allowable range.
Sixth Aspect
In the sheet feeder according to any one of the first to fifth aspects, the first sheet-side restricting member and the second sheet-side restricting member move in conjunction with each other in the width direction of the sheets.
The above-described embodiments are illustrative and do not limit the present disclosure. Thus, numerous additional modifications and variations are possible in light of the above teachings. For example, elements and/or features of different illustrative embodiments may be combined with each other and/or substituted for each other within the scope of the present disclosure.
Any one of the above-described operations may be performed in various other ways, for example, in an order different from the one described above.
Each of the functions of the described embodiments may be implemented by one or more processing circuits or circuitry. Processing circuitry includes a programmed processor, as a processor includes circuitry. A processing circuit also includes devices such as an application specific integrated circuit (ASIC), digital signal processor (DSP), field programmable gate array (FPGA), and conventional circuit components arranged to perform the recited functions.
Number | Date | Country | Kind |
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2022-184956 | Nov 2022 | JP | national |