This patent application is based on and claims priority pursuant to 35 U.S.C. § 119(a) to Japanese Patent Application No. 2015-233836, filed on Nov. 30, 2015 in the Japan Patent Office, the entire disclosure of which is hereby incorporated by reference herein.
Technical Field
The present disclosure relates to an image forming apparatus.
Description of the Related Art
The image forming apparatuses are known which include both a rolled sheet feeder and a manually-inserted cut sheet feeder. Such image forming apparatuses are also equipped with a conveyance path and a sheet feeding roller exclusively used for manually-inserted cut sheets.
In one example of the above-described image forming apparatuses, a cut sheet is manually inserted until the leading edge of the cut sheet strikes against a switching member held in a striking position and is automatically conveyed thereafter.
This image forming apparatus has a drawback that a time-wasting complicated operation is required to transfer the switching member to the striking position, when the sheet is set at a wrong position due to the occurrence of skew, etc., and needs to be reset at a proper position.
In accordance with some embodiments of the present invention, an image forming apparatus is provided. The image forming apparatus includes a feeder, an image former, an ejector, a conveyance path, a manual feeder, a manual conveyance path, a conveyer, a drive source, a switching member, a drive force transmitter, a slip rotator, a clutch, a set position detector, and a first controller. The feeder feeds a recording medium. The image former forms an image on the recording medium. The ejector ejects the recording medium having the image thereon. The conveyance path guides the recording medium fed from the feeder to the image former. The manual feeder feeds a manually-inserted recording medium from the ejector to the manual conveyance path. The manual conveyance path guides the manually-inserted recording medium fed from the manual feeder, to the image former via a downstream side of the conveyance path in an ejection direction. The conveyer conveys the recording medium fed from the feeder to the image former via the conveyance path and conveys the manually-inserted recording medium fed from the manual feeder to the image former via the manual conveyance path. The conveyer is rotatable either normally or reversely. The drive source drives the conveyer to rotate either normally or reversely. The switching member is a claw-like member disposed on a shaft. The switching member is swingable between an evacuation position and a striking position as the shaft rotates. The switching member in the evacuation position is evacuated from the manual conveyance path to allow the manually-inserted recording medium to advance. The switching member in the striking position is entered into the manual conveyance path to allow a leading edge of the manually-inserted recording medium to strike against the switching member. The switching member is configured to switch from the striking position to the evacuation position as the conveyer reversely rotates. The drive force transmitter transmits a drive force from the drive source to both the conveyer and the shaft. The slip rotator gives a rotational load to the shaft. The clutch is coupled to the drive force transmitter. The clutch is configured to transmit the drive force to the shaft when being connected, and to hold the switching member at the striking position or the evacuation position when being disconnected owing to the rotational load from the slip rotator. The set position detector detects whether a trailing edge of the manually-inserted recording medium is positioned at a set position or not relative to the image former. The first controller controls the drive source and the clutch such that the conveyer normally rotates to convey the manually-inserted recording medium from the manual conveyance path to the ejector and that the switching member swings from the evacuation position to the striking position, based on a signal indicating that the set position is wrong, transmitted from the set position detector.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will he readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
The accompanying drawings are intended to depict example embodiments of the present invention 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.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present invention. 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. It will be further understood that the terms “includes” and/or “including”, when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.
Embodiments of the present invention are described in detail below with reference to accompanying drawings. In describing embodiments illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the disclosure of this patent 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 operate in a similar manner and achieve a similar result.
For the sake of simplicity, the same reference number will he given to identical constituent elements such as parts and materials having the same functions and redundant descriptions thereof omitted unless otherwise stated.
In accordance with some embodiments of the present invention, an image forming apparatus is provided which is easy to reset the position of a manually-inserted recording medium.
A first embodiment of the present invention is described below with reference to
An image forming apparatus 1 illustrated in
Referring to
The image forming apparatus 1 is a compact apparatus which requires no large installation space. The image forming apparatus 1 is capable of feeding manually-inserted cut sheets or long sheets (a long sheet refers to a part of a rolled sheet) without causing skew or paper jam. The image forming apparatus 1 is configured such that long sheets easily insertable. Moreover, the image forming apparatus 1 is configured such that a registration roller and a pressure roller are contactable with and separable from each other by a manual operation. Compared to high-end image forming apparatuses in which the registration roller and the pressure roller are automatically contactable with and separable from each other, or in which the pressing force is variable in accordance with the sheet size, the image forming apparatus 1 includes a lesser number of components with a lower cost.
Referring to
The image former 2 forms an image on a recording medium by means of inkjet recording. The recording medium may be either a long sheet 10 or a cut sheet. The image forming apparatus 1 is a serial type inkjet recording apparatus.
Referring to
The ejector 4 further includes a front cover 12 that is openable and closable, to allow a user to manually insert a recording medium or to remove paper jam. The front cover 12 is swingable about a hinge disposed on an upper part of the front side F of the apparatus body 1A, so that the lower part of the front cover 12 is openable and closable. A front cover open sensor 13 is disposed on the apparatus body 1A in proximity to the hinge of the front cover 12. The front cover open sensor 13 detects whether the front cover 12 is in an open state or a closed state. The front cover open sensor 13 is turned on when the front cover 12 is opened by a user.
The feeder 3 is capable of feeding the sheet 10, in the form of a long sheet, drawn from a sheet roll 10a or 10b stored in the spool bearing stand 101a or 101b, respectively. The spool bearing stands 101a and 101b are aligned in the upside-downside (vertical) direction Z of the apparatus body 1A. The spool beating stands 101a and 101b store the sheet rolls 10a and 10b, respectively, so that the sheet 10 is drawable from the sheet roll 10a or 10b.
The sheet roll 10a on the upper side (hereinafter “upper sheet roll 10a”) and the sheet roll 10b on the lower side (hereinafter “lower sheet roll 10b”) are rotatabiy supported by the spool bearing stands 101a and 101b, respectively. The sheet 10 is selectively drawable from the upper sheet roll 10a or the lower sheet roll 101b. Referring to
The upper sheet roll 10a and the lower sheet roll 10b are stored at a lower end part and a front surface side of the apparatus body 1A. A front surface 1F of the apparatus body 1A has openings 7 and 8 through which the upper sheet roll 10a and the lower sheet roll 10b, respectively, are replaceable.
At the periphery of the spool bearing stands 101a and 101b, a drive motor and a drive force transmitter are provided, capable of drawing out the sheet 10 from the upper sheet roll 10a or the lower sheet roll 10b, conveying the sheet 10, and rewinding the conveyed sheet 10.
In place of the above-described spool bearing stands 101a and 101b, flange hearing stands may support the sheet rolls 10a and 10b so that the sheet 10, in the form of a long sheet, is drawable therefrom.
The image former 2 includes a guide rod 18 and a guide rail 19 each supported by side plates disposed on the left and right sides of the apparatus body 1A in the width direction Y. The guide rod 18 and the guide rail 19 moveably hold a carriage 20 in the main scanning direction Y.
The carriage 20 includes liquid recording heads 15 for discharging black, yellow, magenta, and cyan ink droplets, respectively. Each liquid recording head 15 integrally includes a sub tank for retaining an ink to be supplied thereto.
A main scanning mechanism that moves the carriage 20 in the main scanning direction Y includes a drive motor 21, a drive pulley 22, a driven pulley 23, and a belt 24. The drive motor 21 is disposed on one side (left side in
The driven pulley 23 is pulled by a tension spring in a direction away from the drive pulley 22.
As illustrated in
As illustrated in
As illustrated in
A sheet conveying device is described below with reference to
Referring to
The registration roller 34 and each of the pressure rollers 35 form a pair of holding-conveying members contactable with and separable from each other, serving as a conveyer. The registration roller 34 is a drive roller rotary-driven by the drive motor 38. The pressure rollers 35 are driven rollers driven by the registration roller 34. The registration roller 34 and the pressure rollers 35 are supported by inner side plates so as to be rotatable either normally or reversely.
A motor pulley 38a is disposed on the output shaft of the drive motor 38. A registration large-diameter pulley 52 is secured to one end of the registration roller 34. A timing belt 43 is wound around the motor pulley 38a and the registration large-diameter pulley 52. A rotation or drive force of the drive motor 38 is transmitted to the registration roller 34 via the timing belt 43. Each of the motor pulley 38a and the registration large-diameter pulley 52, as well as the later-described other pulleys wound around another timing belt, is a toothed pulley (timing pulley).
The drive motor 38 may include a DC motor. The drive motor 38 serves as a single drive source for driving the conveyer to rotate either normally or reversely. The drive motor 38 is secured to an inner side plate fixed to the apparatus body 1A.
The pressure rollers 35 are rotatably supported by a common shaft disposed at an end of at arm-like pressure roller bracket 53. The pressure rollers 35 are divided and skewered rollers. Each pressure roller bracket 53 supports two pressure rollers 35. The pressure roller bracket 53 includes a wire spring for applying a pressing force (biasing force) in a direction in which the pressure rollers 35 is pressed against the registration roller 34.
As illustrated in
As illustrated in
The pressure releasing lever 54 may be replaced with another pressure releaser, such as a pressure releasing mechanism and a link mechanism having an operation lever.
The encoder sheet 37 is a disk-like member disposed coaxially with the registration roller 34. The encoder sensor 36 includes a transmissive photosensor having a light emitting part and a light receiving part. The encoder sensor 36 is secured to an inner side plate so as to grip the outer peripheral edge of the encoder sheet 37.
On one end side (right side in
A cutter 27 is disposed in the vicinity of the ejection port 4a of the ejector 4 in the image former 2. The cutter 27 cuts the sheet 10 into a piece having a predetermined length. The cutter 27 is secured to a wire or timing belt wound around multiple pulleys, one of which being coupled to a cutter drive motor. As the cutter drive motor moves in the main scanning direction Y, the cutter 27 cuts the sheet 10 into a piece having a predetermined length.
A sheet feeding and conveying operations and an image forming operation when the feeder 3 feeds the sheet 10 are described below with reference to
The conveyance path 5 is formed of sheet conveyance guide members 201 and 202. The sheet 10 passes through the conveyance path 5 to reach the image former 2. In the image former 2, the liquid recording heads 15 discharge colored liquid droplets onto the sheet 10 to form an image on the sheet 10 in accordance with image data. A pre-registration sensor 49 is disposed in the vicinity of the conveyance path 5, to be described in detail later with reference to
While the image former 2 is performing an image forming operation, the sheet 10 is intermittently conveyed in a direction indicated by arrow Xa (hereinafter “ejection direction Xa”) along the sub-scanning direction (i.e., the front-back direction X). The sub-scanning direction X is perpendicular to the main scanning direction Y along which the carriage 20 moves. The amount of conveyance is controlled by a controller 110 based on information obtained by the encoder sensor 36 by reading the encoder sheet 37 coaxially disposed with the registration roller 34.
A manual feeder and a manual conveyance path are described below with reference to
As illustrated in
As illustrated in
The conveyance path 5 and the manual conveyance path 11 join together on a downstream side of the conveyance path 5, thereby forming a joined conveyance path 14. The joined conveyance pad 14 extends from the joined position of the conveyance path 5 with the manual conveyance path 11 to the ejection port 4a of the ejector 4.
As described above, the conveyer, including the registration roller 34 and the pressure rollers 35, has a function of conveying the sheet 10 fed from the feeder 3 to the image former 2 via the conveyance path 5. At the same time, the conveyer has another function of conveying the cut sheet 50 manually inserted from the manual feeder 6 to the image former 2 via the manual conveyance path 11, while being rotatable either normally or reversely.
As illustrated in
In particular, multiple switching members 40 are disposed on the shaft 41 in a longitudinal direction in a cyclic manner within a region where the cut sheet 50 passes within the manual conveyance path 11. When the switching member 40 is in the striking position, as illustrated in
A manual sensor 47 is disposed downstream from the switching member 40 on the manual conveyance path 11 relative to the ejection direction Xa. The manual sensor 47 detects presence of the manually-inserted cut sheet 50. The manual sensor 47 includes a reflective photosensor.
A conveyance operation is described below with reference to
First, a conveyance operation for conveying the sheet 10 drawn from the sheet roll 10a or 10b (hereinafter simply “the sheet roll”) is described with reference to
A manual insertion-feeding operation for cut sheets is described with reference to
During the manual insertion-feeding operation, the sheet 10 drawn from the sheet roll should be temporarily evacuated from the joined position of the conveyance path 5 with the manual conveyance path 11 to an upstream side thereof. Thus, the registration roller 34 is reversely rotated and the sheet roll is wound back, to evacuate a leading edge 10A of the sheet 10 to a position near the pre-registration sensor 49.
Next, the front cover 12 is opened, as illustrated in
Whether or not the leading edge 50a of the cut sheet 50 has struck against the switching member 40 is detected by the manual sensor 47. It is preferable that the inserted cut sheet 50 is prevented from shifting until the pressure rollers 35 are switched to the pressurizing state, as illustrated in
Next, after the pressure releasing lever 54 is operated such that the pressure rollers 35 are pressed against the registration roller 34, the registration roller 34 is reversely rotated in a direction indicated by arrow in
When the gear ratio is set such that the rotation speed of the switching member 40 is slower than the sheet conveyance speed, the cut sheet 50 will be pressed against the switching member 40 and damaged or bent thereby. To prevent this phenomenon, the gear ratio is set such that the circumferential speed of the switching member 40 at the position where the leading edge 50a of the cut sheet 50 strikes thereon is faster than the sheet conveyance speed of the registration roller 34. In this case, the switching member 40 can be moved to the evacuation position without the cut sheet 50 being pressed against the switching member 40, and the cut sheet 50 can be normally conveyed.
As illustrated in
A driver for driving the conveyer is described below with reference to
Referring to
A drive force transmitter, for transmitting a drive force of the drive motor 38 to the conveyer (i.e., the registration roller 34 and the pressure rollers 35) and to the shaft 41 of the switching member 40, is described below with reference to
On one end of the registration large-diameter pulley 52 of the registration roller 34, the registration small-diameter pulley 55 is coaxially disposed. The transmission shaft 62 is rotatably supported by inner side plates 46a and 46b. The transmission shaft pulley 63 is secured to one end of the transmission shaft 62. The timing belt 44 is wound around the registration small-diameter pulley 55 and the transmission shaft pulley 63. Thus, the registration roller 34 and the transmission shaft 62 rotate in the same direction.
The clutch gear 45 is disposed on the transmission shaft 62 via the electromagnetic clutch 42. When the electromagnetic clutch 42 is connected, a drive force of the drive motor 38 is transmitted to the transmission shaft 62. When the electromagnetic clutch 42 is disconnected, the switching member 40 is held at the striking position or the evacuation position owing to a rotational load from a slip rotator, to be described in detail later.
The gear 51 is engaged with the gear 67. The gear 51 is rotatably supported by a shaft 51a inserted into the gear 51, The shaft 51a is secured to the inner side plate 46a. The spring 66 is disposed between the inner side plate 46a and the disc member 91. The disc member 91 is disposed between the spring 66 and the gear 51. The gear 51 is loaded with a pressure from the spring 66. Thus, even when the electromagnetic clutch 42 is disconnected, the switching member 40 can keep its position.
The shaft 41 of the switching member 40 is supported by the inner side plate 46a and another inner side plate disposed on a left side in
The disc member 87 has a convex engagement part that is engaged with a groove formed on the shaft 41 in a longitudinal direction. The disc member 87 is slidable in a longitudinal direction of the shaft 41 and rotatable along with rotation the shaft 41 in the same direction. This configuration makes it possible to transmit a rotational drive force and torque of the gear 67 to the shaft 41.
The gear 67, the spring 60, and the disc member 87 form a slip rotator. The slip rotator automatically blocks transmission of torque to the shaft 41 when an excessively large load is applied to the gear 67, by making the gear 67 slip relative to the shaft 41.
Referring to
As the electromagnetic clutch 42 is connected and the registration roller 34 is rotary-driven, a drove force is transmitted through the timing belt 44, the clutch gear 45, and the gear 67 to rotate the shaft 41 and to switch the position of the switching member 40. At this time, the gear 51 is also rotated. The drive force transmitter makes the registration roller 34 and the shaft 41 rotate in the opposite directions.
Referring to
In the slip rotator, the gear 67 is loaded by the disc member 87 and the spring 60 relative to the filler 64. As a torque above a certain value acts on the gear 67, a slip is caused between the disc member 87 and the filler 64. Thus, the peripheral components never get broken even when the registration roller 34 is excessively rotated. Since the number of rotations of the registration roller 34 is accurately measurable by the encoder sensor 36, the rotational position (rotational angle) of the switching member 40 is controllable.
The screw pins 89 and 90, serving as second rotation regulators, are each secured to the inner side plate 46a with a screw so as to protrude toward the conveyer 32 side in a direction perpendicular to the inner side plate 46a. (The screw pin 90 is illustrated in
The spring pin 88, serving as a first rotation regulator, is secured to the shaft 41 at right angle. The spring pin 88 is extended in the space between the screw pins 89 and 90. As the registration roller 34 normally rotates in a direction indicated by arrow NR (corresponding to the ejection direction Xa) in
On the other hand, as the registration roller 34 reversely rotates in a direction indicated by arrow RR in
As a drive force is transmitted to the gear 67 after the spring pin 88 has been brought into contact with the screw pins 89 or 90, an excessively large load is applied to the gear 67 and a slip is caused between the disc member 87 and the filler 64, thereby blocking transmission of torque to the shaft 41.
As described above, the rotational position (e.g., striking position, switching position, evacuation position) of the switching member 40 can be detected by the position detection sensor 65 by detecting the rotational position of the filler 64 secured to the shaft 41.
A configuration of the controller 110 of the image forming apparatus 1 is described below with reference to
The controller 110 illustrated in
The RAM 113 temporarily stores various data, such as calculation results of the CPU 111. The ROM 12 previously stores necessary control programs (to be described later referring to
To the CPU 111, each of the front cover open sensor 13, the encoder sensor 29, the sheet end detection sensor 30, the encoder sensor 36, the manual sensor 47, the pre-registration sensor 49, and the position detection sensor 65 is electrically connected via an input port. In addition, to the CPU 111, a head driving circuit 71 for driving the liquid recording head 15, the drive motor 21, the drive motor 38, and the electromagnetic clutch 42 is electrically connected via an output port. Further, an operation display 70 is electrically connected to the CPU 111 via an input port and an output port.
A set position detector, for detecting whether or not a trailing edge of a manually-inserted cut sheet is set at a proper set position relative to the image former 2, is described below. The set position detector includes the sheet end detection sensor 30 as a major component and the encoder sensors 29 and 36 as sub components.
In the state illustrated in
(1) Detection of Skew
The sheet end detection sensor 30 mounted on the carriage 20 detects the right end of the cut sheet 50 (or the sheet 10) while the carriage 20 is scanning in the main scanning direction Y (“first detection”). After tile cut sheet 50 (or the sheet 10) is conveyed in the ejection direction Xa for a predetermined amount, the sheet end detection sensor 30 detects the right end of the cut sheet 50 (or the sheet 10) again (“second detection”). The difference in detected position between the first and second detections represents a skew. When the skew is in excess of a specified value, the set position is determined to be wrong.
(2) Detection of Size of Cut Sheet
The sheet end detection sensor 30 detects the right end of the cut sheet 50 (or the sheet 10) while the carriage 20 is scanning in the main scanning direction Y. The carriage 20 keeps on scanning to detect the left end of the cut sheet 50 (or the sheet 10). The difference in detected position between the right and left ends represents the width (size) of the sheet. When the detected size of the cut sheet 50 (or the sheet 10) is out of a specified range, the set position is determined to be wrong.
(3) Detection of Right End of Sheet
The sheet end detection sensor 30 detects the right end of the cut sheet 50 (or the sheet 10) while the carriage 20 is scanning in the main scanning direction Y. When the detected value is out of a specified range, the set position is determined to be wrong.
The operation display 70 includes: a touch panel, switches, and keys, for instructing each part of the image forming apparatus 1 to perform each operation; a liquid crystal display for visually checking the operation; and a sound generator. The liquid crystal display and the sound generator each serve as an informer. Examples of the sound generator include a voice generator and a buzzer that generates a warning sound.
In the first embodiment, the CPU 111 serves as a first controller. Specifically, the CPU 111 serving as the first controller controls the drive motor 38 and the electromagnetic clutch 42 such that the registration roller 34 normally rotates to convey the cut sheet 50 from the manual conveyance path 11 to the ejector 4 and that the switching member 40 swings from the evacuation position to the striking position, based on a signal indicating that the set potion of the cut sheet 50 is wrong, transmitted from the set position detector (including the sheet end detection sensor 30).
In addition, the CPU 111 has an interlock function that stops operations of the head driving circuit 71 of the liquid recording head 15, the drive motor 21, the drive motor 38, and the electromagnetic clutch 42, based on a signal indicating that the cover is open, transmitted from the front cover open sensor 13.
Moreover, the CPU 111 has a function that causes the liquid crystal display and the sound generator in the operation display 70 inform the user of the status of each part, such as the electromagnetic clutch 42, drive motors 21 and 38, etc., based on a signal from each sensor.
Now, a manual feeding preparation operation for a manually-inserted cut sheet (simply referred to as “sheet” in
In step S21 in
Whether or not the leading edge 50a of the cut sheet 50 has struck against the switching member 40 is detected by the manual sensor 47. In step S24, the user operates the pressure releasing lever 54 in the direction indicated by arrow in
In step S26, the cut sheet 50 having struck against the switching member 40 is then automatically conveyed in the conveyance direction Xc, as illustrated in
As the trailing edge 50b of the cut sheet 50 reaches an immediately upstream position of the print start position in the conveyance direction Xc, the set position of the trailing edge 50b of the cut sheet 50 is detected by the set position detector (including the sheet end detection sensor 30) mounted on the carriage 20.
The set position detector then performs detection of (1) skew, (2) the size of the cut sheet, and (3) the right end of the cut sheet. In step S27, the CPU 111 refers to fixed data or a data table stored in the ROM 112 to determine whether the set position is good or wrong.
When the set position is determined to be good, in step S28, the trailing edge 50b of the cut sheet 50 is conveyed to a writing position where the liquid recording heads 15 are capable of writing an image on the cut sheet 50, by the registration roller 34 normally rotated and the pressure rollers 35, as illustrated in
In this operation according to the first embodiment, the above-described steps S21 to S28 are the same as steps S1 to S8, respectively, in a related-art operation illustrated in
In step S29, the CPU 111 serving as the first controller automatically performs an operation that causes the cut sheet to be automatically ejected and causes the switching member 40 to automatically transfer to the striking position. Specifically, the CPU 111 controls the drive motor 38 and the electromagnetic clutch 42 such that the registration roller 34 normally rotates to convey the cut sheet 50 from the manual conveyance path 11 to the ejector 4 and that the switching member 40 swings from the evacuation position to the striking position.
In step S30, information indicating completion of ejection of the cut sheet is displayed on the liquid crystal display of the operation display 70. Thus, the user recognizes that a sheet re-setting operation is needed and performs the sheet re-setting operation (i.e., step S21 and subsequent steps).
Now for the comparative purposes, the related-art manual feeding preparation operation for a manually-inserted cut sheet (simply referred to as “sheet” in
As described below, the image for apparatus according to the related art only controls the drive motor 38 and the electromagnetic clutch 42 such that the switching member 40 is switched from the striking position to the evacuation position when the registration roller 34 is reversely rotated and the trailing edge of the cut sheet 50 occupies the set position. In addition, the image forming apparatus according to the related art causes the liquid crystal display and the sound generator in the operation display 70 inform the user, only based on a signal indicating that the set potion of the cut sheet 50 is wrong, transmitted from the set position detector (including the sheet end detection sensor 30).
Referring back to
In step S12, the user removes the cut sheet, determined to be in a wrong set position, from the positions of the pressure rollers 35 separated from the registration roller 34. The user then operates the pressure releasing lever 54 to a pressurizing state in step S13 in the same manner as in step S4, and closes the front cover in step S14 in the same manner as in step S5.
In step S15, an initial operation; including a carriage forming operation and a switching operation for transferring the switching member 40 to the striking position, is automatically performed. Since the front cover 12 was opened in the prior step, the carriage needs to check whether or not foreign substances present on the print surface by slowly scanning the whole area in the main scanning direction. Such a scanning operation causes a waste of time. To omit the time spent for the scanning operation, the initial operation is automatically performed in step S15.
As the switching member 40 has switched to the striking position through steps S10 to S15, the cut sheet gets ready for being reset. The user then performs a series of steps S1 to S5 to reset the cut sheet.
In the related-art image forming apparatus, as described above, the switching member 40 is not in the striking position when reset of the cut sheet is required, and therefore a series of complicated operations is needed. Specifically, the series of complicated operations includes manual operations (e.g., opening the front cover, operating the pressure releasing lever to the depressurizing state, removing the cut sheet, operating the pressure releasing lever to the pressurizing state, closing the front cover) and the initial operation (e.g., the carriage forming operation and the switching operation for switching the switching member 40 to the striking position). The series of complicated operation takes a long time.
Further, when the front cover is opened, the CPU stops an operation of the drive motor 38, etc., based on a signal indicating that the cover is open, transmitted from the front cover open sensor 13. By this interlock function of the CPU, the drive motor 38 cannot be put into operation.
In contrary, according to the first embodiment of the present invention, when the set position is determined to be wrong, the cut sheet can be properly reset without complicated operation, because the cut sheet is ejected without being touched by the user and the switching member 40 is automatically transferred to the striking position at the same time.
Since no complicated operation is required, a waste of time can be minimized.
Modification 1
A first modification is described below with reference to
The first modification is different from the first embodiment in the following two aspects. With respect to the first aspect, step S29 in the first embodiment is modified such that conveyance of the manually-inserted cut sheet 50 to the ejector 4 is completed while the cut sheet 50 is being sandwiched by the registration roller 34 and the pressure rollers 35, as illustrated in
With respect to the second aspect, the CPU 111 serves as a second controller in addition to serving as the first controller. The CPU 111 serving as the second controller controls the electromagnetic clutch 42 and the drive motor 38 such that the electromagnetic clutch 42 gets connected and the switching member 40 swings to the striking position at the time when the manual sensor 47 detects absence of the manually-inserted cut sheet 50, to transfer the switching member 40 to the striking position while the manually-inserted cut sheet 50 is being ejected.
According to the first aspect, when the set position is determined to be wrong, the cut sheet 50 is conveyed toward the ejector 4 (while the switching member 40 is in the striking position), and the conveyance is stopped while the cut sheet 50 is being sandwiched by the registration roller 34 and the pressure rollers 35, as illustrated in
A stop position of the trailing edge of the cut sheet 50 (corresponding to the leading edge 50a of the manually-inserted cut sheet 50) is between a position within the manual conveyance path 11 (formed of the manual sheet conveyance guide plates 251 and 252) and the nip position of the registration roller 34.
The amount of conveyance of the cut sheet 50 is controllable by the accumulated normal/reverse rotation pulse number of the registration roller 34, detected by the encoder sensor 36, which may be a constant value regardless of the length of the cut sheet 50.
Thus, the cut sheet 50 is prevented from falling and being soiled or bent.
According to the second aspect, when the set position is determined to be wrong, the cut sheet 50 is conveyed toward the ejector 4 in the ejection direction Xa, as illustrated in
Modification 2
A second modification is described below with reference to
The second modification is different from the first modification in that the CPU 111 serves as a third controller in addition to serving as the second controller. The CPU 111 serving as the third controller controls the sound generator in the operation display 70 to inform that the manually-inserted cut sheet 50 is set at the set position based on a signal indicating that the manually-inserted cut sheet 50 has struck against the switching member 40 in the striking position, transmitted from the manual sensor 47.
The operation according to the second modification illustrated in
In other words, when the leading edge 50a of the cut sheet 50 is properly set within the manual conveyance path 11 by striking against the switching member 40 in the striking position, a sheet set alarm is sounded as the manual sensor 47 detects presence of the cut sheet.
In a case in which the cut sheet 50 is manually inserted as illustrated in
To avoid such a phenomenon, the image forming apparatus according to the second modification can inform the user of proper set of the cut sheet by means of a sheet set alarm, etc., optionally together with a display. When the cut sheet has not properly set, the image forming apparatus informs the user of wrong set of the cut sheet to prompt the user to reset the cut sheet. Wrong set of the cut sheet may be displayed on the liquid crystal display of the operation display 70 and/or alarmed by a buzzer sound, to reliably prompt the user to reset the cut sheet.
Modification 3
A third modification is described below with reference to
The third modification is different from the first embodiment in the following two aspects. Firstly, the installation position of the switching member 40 is changed to an upstream side of the joined conveyance path 14 relative to the insertion direction Xb. Secondly, the switching member 40 is made switchable among the striking position illustrated in
The third modification may be applied to the second modification. In the third modification, to make the switching member 40 swingable among the striking position, evacuation position, and separation position, the driver 33 (illustrated in
In the first embodiment, when the cut sheet 50 is manually inserted and set, the cut sheet 50 may enter into or strike against the conveyance path 5, exclusively used for the rolled sheet without entering into the manual conveyance path 11, depending on the degree of curl of the leading edge 50a of the cut sheet 50. The third modification has solved such a problem.
The image forming apparatus according to some embodiments of the present inventions is not limited to an inkjet recording apparatus. The image forming apparatus according to some embodiments of the present invention may be an electrophotographic copier or printer which forms images on either a long sheet drawn from a sheet roll or a cut sheet manually inserted. Specific examples of the long sheet include, but are not limited to, various recording media such as normal sheet, recording sheet, gloss sheet, and coated sheet. Specific examples of the cut sheet used for manual insertion include, but are not limited to, various recording media such as normal sheet, recording sheet, gloss sheet, coated sheet, thick sheet, envelope, thin sheet, and film (e.g., OHP sheet), and a cut piece of the long sheet. The long sheet and the cut sheet may be made of paper, fiber, or plastic.
The liquid discharge head of the inkjet recording apparatus includes an energy generation source. Specific examples of the energy generation source include, but are not limited to, a piezoelectric actuator (e.g., a laminated piezoelectric element, a thin-film piezoelectric element), a thermal actuator using a thermoelectric conversion element such as a heat element, and an electrostatic actuator including a vibration plate and a counter electrode.
Numerous additional modifications and variations are possible in light of the above teachings. It is therefore to be understood that, within the scope of the above teachings, the present disclosure may be practiced otherwise than as specifically described herein. With some embodiments having thus been described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the scope of the present disclosure and appended claims, and all such modifications are intended to be included within the scope of the present disclosure and appended claims.
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