The present invention relates to a printing apparatus and a method of controlling the printing apparatus, and to be specific, the present invention relates to a technique to feed and convey a printing medium by manual feeding.
In manual-feed feeding, a user sets a printing medium to a feeding unit, and feeding to a printing unit is performed from this state. Therefore, depending on how the user sets, the printing medium may be set tilted with respect to a conveyance path of the printing medium.
To deal with this, Japanese Patent Laid-Open No. 2013-129482 describes that a configuration in which a tip of a printing medium is biased to a conveyance roller in a case where the printing medium is set to a feeding unit is provided, and even if the printing medium is set tilted, feeding is performed with the tilt being solved by the biasing force. Specifically, in the printing medium set tilted, bending in accordance with the tilt is formed by the above-described biasing force. Then, with reaction force being caused by the bending, tips of the printing medium are supplied substantially simultaneously in a width direction of the printing medium to a nipping unit of a conveyance roller. Therefore, the tilt of the printing medium is solved in the following conveyance.
However, in the configuration in which the bending is formed on the printing medium to solve the tilt that is disclosed in Japanese Patent Laid-Open No. 2013-129482, for example, if the printing medium is thick paper or the like with high stiffness, there is a possibility that the bending formed on the printing medium is insufficient, and a conveyance malfunction may be caused. That is, because no bending is formed, the entirety of the printing medium in the width direction cannot be aligned and brought into contact with the nipping unit of the conveyance roller. As a result, sufficient conveyance force cannot be obtained, and the conveyance malfunction may be caused.
An object of the present invention is to provide a printing apparatus and a method of controlling the printing apparatus that can perform feeding without causing a conveyance malfunction regardless of a type of a printing medium in manual-feed feeding.
In a first aspect of the present invention, there is provided a printing apparatus having: a first conveyance path on which a printing medium from a manual-feed stacking unit is conveyed to a printing unit in a conveyance direction; a second conveyance path converging with the first conveyance path at a converging section and on which a printing medium from a cassette is conveyed; a first conveyance roller pair provided downstream the converging section in the conveyance direction of the first conveyance path and configured to nip and convey a printing medium; a first detection unit configured to detect a printing medium stacked on the manual-feed stacking unit; a second conveyance roller pair provided on a side downstream the conveyance direction of the first conveyance roller pair on the first conveyance path and configured to nip and convey a printing medium; a second detection unit arranged between the first conveyance roller pair and the second conveyance roller pair and configured to detect a printing medium; and a control unit configured to perform control to start feeding of a printing medium to the printing unit by the first conveyance roller pair in a case where the first detection unit detects the printing medium but the second detection unit does not detect the printing medium.
In a second aspect of the present invention, there is provided a control method of a printing apparatus which has: a first conveyance path on which a printing medium from a manual-feed stacking unit is conveyed to a printing unit in a conveyance direction: a second conveyance path converging with the first conveyance path at a converging section and on which a printing medium from a cassette is conveyed: a first conveyance roller pair provided downstream the converging section in the conveyance direction of the first conveyance path and configured to nip and convey a printing medium; a first detection unit configured to detect a printing medium stacked on the manual-feed stacking unit; a second conveyance roller pair provided on a side downstream the conveyance direction of the first conveyance roller pair on the first conveyance path and configured to nip and convey a printing medium: and a second detection unit arranged between the first conveyance roller pair and the second conveyance roller pair and configured to detect a printing medium, wherein control is performed to start feeding of a printing medium to the printing unit by the first conveyance roller pair in a case where the first detection unit detects the printing medium but the second detection unit does not detect the printing medium.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
An embodiment of the present invention is described below in detail with reference to the appended drawings. Note that, in the appended drawings, the same or similar elements are denoted by the same reference numeral, and a duplicated description may be omitted.
Note that, “printing” indicates not only a case of forming significant information such as a character and a graphic but also a case of forming on a printing medium a wide variety of images, designs, patterns, and the like including something actualized such that a human can perceive with a sense of vision, or a case of processing the printing medium.
Additionally, “printing medium (printing paper)” includes not only common printing paper used in an image formation apparatus but also a wide variety of conveyable printing media such as cloth, plastic film (OHP), metallic plate, glass, ceramics, wooden material, and leather.
A printing apparatus 1 includes a cassette feeding unit 2 and a manual-feed feeding unit 3, a conveyance unit 5, and a discharging unit 8 as a mechanism to convey a printing medium. The cassette feeding unit 2 performs feeding by separating multiple printing media laminated in a cassette 20 one by one. The manual-feed feeding unit 3 performs feeding with the user taking one printing medium and setting to the manual-feed feeding unit 3. The conveyance unit 5 includes a roller and the like provided along a conveyance path of the printing medium and conveys the printing medium. The discharging unit 8 discharges and stacks the printing medium on which printing is performed by a printing unit 7 provided to a part of the conveyance path in the conveyance unit 5.
More specifically, as illustrated in
The manual-feed feeding unit 3 includes a manual-feed stacking unit 31 on which the printing medium is placed to set the printing medium. The printing medium is placed on the manual-feed stacking unit 31 including a feeding port at an end portion while being nipped by an intermediate roller pair 35 (a first conveyance roller pair) by a later-described setting method. A conveyance path formed in the manual-feed stacking unit 31 converges the conveyance path in the conveyance unit 5 upstream the intermediate roller pair 35 in a conveyance direction, and thus the printing medium fed from the manual-feed feeding unit 3 is conveyed by the intermediate roller pair 35 through the conveyance path in the conveyance unit 5.
The conveyance unit 5 includes the intermediate roller pair 35, a conveyance roller 51 and a pinch roller 52 facing the conveyance roller 51, and a discharging roller 53 and a spur 54 facing the discharging roller 53.
To be specific, the intermediate roller pair 35 is formed of an intermediate roller 35b and an association roller 35a, and the printing medium is conveyed with the printing medium nipped by the association roller 35a being pressed onto the intermediate roller 35b while the intermediate roller 35b rotates. In the cassette feeding, the intermediate roller pair 35 functions as an intermediate roller playing a role of a relaying unit that conveys the printing medium in the middle of the conveyance path from the pickup roller 27 of the cassette feeding unit 2 to the conveyance roller 51 and the pinch roller 52 (a second conveyance roller pair). Additionally, in the manual-feed feeding, the intermediate roller pair 35 functions as a feeding roller that conveys the nipped printing medium to the conveyance roller 51 and the pinch roller 52. Thus, since the intermediate roller playing a role of the relaying unit in the cassette feeding is also used as the feeding roller in the manual-feed feeding, there is caused no increase in cost due to an increase in a size of the apparatus and an increase in the number of parts. Additionally, the feeding port provided in the back side makes it possible to start the manual-feed feeding without cumbersome work before the printing, and it is possible to achieve both the feeding of the printing medium with high operability and the feeding with high performance of treating the printing medium.
The discharging unit 8 includes a discharging tray 81 on which the printing medium discharged by the discharging roller 53 is stacked.
The printing medium fed from the cassette feeding unit 2 or the manual-feed feeding unit 3 to the conveyance unit 5 is nipped between the pinch roller 52 and the conveyance roller 51 pivotally held by a pinch roller holder 55. With this, the printing medium is conveyed to the printing unit 7 with the pinch roller 52 applying biasing force to the conveyance roller 51 and also the conveyance roller 51 rotating. According to printing data, ink is ejected from a nozzle of a not-illustrated printing head onto the printing medium conveyed to the printing unit 7, and thus an image and the like are printed. The printing unit 7 can perform the printing in a region in a width direction of the printing medium with the printing head moving in a scanning direction in
Rotational driving force generated by a driving motor (not illustrated) as a driving source is transmitted to the conveyance roller 51, the discharging roller 53, the intermediate roller 35b, and the pickup roller 27 through a gear train 61 and can pivot each roller Note that, a driving direction in which the driving motor rotates the conveyance roller 51 in a direction of conveying the printing medium to a side downstream in the conveyance direction is referred to as a forward direction, and a driving direction in which the driving motor rotates the conveyance roller in a direction of conveying the printing medium to a side upstream in the conveyance direction is referred to as a backward direction.
Between the cassette feeding unit 2 and the conveyance unit 5 in the conveyance direction, the pinch roller holder 55 is arranged on an upper side of
In the cassette stacking unit 21, a pair of right and left cassette side guides (guide members) 24a and 24b that guide side portions of the printing medium in the width direction is provided to align the right and left positions of the sides of the printing medium. The positions of the cassette side guides 24a and 24b can be adjusted in accordance with a width of the printing medium, and the cassette side guides 24a and 24b are formed to face the two side portions of the printing medium, move in conjunction with each other in directions of arrows A1 and B1 to be close to each other, and move in conjunction with each other in directions of arrows A2 and B2 to be away from each other. Thus, the printing medium is arranged such that the center thereof in the width direction (the X direction in
Additionally, in the cassette stacking unit 21, the separation unit 23 that separates the multiple printing media laminated on the cassette stacking unit 21 one by one is arranged on a side downstream a feeding direction of the printing medium (an arrow Y1 side). In the separation unit 23, an inclined surface member 28 and a separation strip 29 are provided. In the inclined surface member 28, an inclined surface forming an obtuse angle with respect to the feeding direction of the printing medium (the arrow Y1 direction) is formed so as to apply predetermined separation resistance force to the printing medium.
In the manual-feed stacking unit 31, a pair of right and left manual-feed side guides (guide members) 32a and 32b that guide the positions of the side portions of the printing medium in the width direction is provided, and the manual-feed side guides 32a and 32b determine the positions of the right and left sides of the printing medium. The positions of the manual-feed side guides 32a and 32b can be adjusted in accordance with a width of the printing medium, and the manual-feed side guides 32a and 32b are formed to face the two side portions of the printing medium, move in conjunction with each other in directions of arrows D1 and E1 to be close to each other, and move in conjunction with each other in directions of arrows D2 and E2 to be away from each other. Thus, the printing medium is arranged such that the center thereof in the width direction (the X direction in
The back side guide 36 forms a U-turn shaped conveyance path guiding the printing medium to the conveyance unit 5 through a converging section during the cassette feeding on the back side of the printing apparatus. Additionally, a top surface of the back side guide 36 forms a part of the conveyance path guiding the printing medium to the conveyance unit 5 during the manual-feed feeding. The back side guide 36 can be attached to and detached from the printing apparatus 1 main body. In a case where the printing medium is jammed during the conveyance, the back side guide 36 can be detached from the printing apparatus 1 and allows the user to access the jammed printing medium. On the conveyance path formed on the top surface of the back side guide 36, a manual-feed detection sensor lever 38 and a manual-feed detection sensor 39 (a first detection unit) are provided to detect the attachment state of the back side guide 36 with respect to the apparatus main body and whether there is the printing medium on the manual-feed stacking unit 31 (first detection). The manual-feed detection sensor lever 38 is pivotally attached, and as described later with reference to
The intermediate roller pair 35 is provided to the conveyance guiding unit 37. The intermediate roller pair 35 includes the intermediate roller 35b to which the driving force is transmitted through a not-illustrated drive transmission mechanism from the driving motor and the association roller 35a pivotally supported by a spring shaft and rotated in association with the rotation of the intermediate roller 35b. Additionally, the conveyance guiding unit 37 forms a part of the conveyance path in the cassette feeding, the manual-feed feeding, and double-sided printing.
The swing arm 311 can pivot about the shaft unit 312 and is biased in the 12 direction in
As the above, with the provision of the driving force interruption mechanism 313 and the swing arm 311 gripping the intermediate roller 35b, it is possible to suppress the resistance force generated in a case of inserting the printing medium between the rollers of the intermediate roller pair 35 put in contact with each other. Thus, without causing an increase in cost due to provision of a mechanism that makes the pair of rollers away from each other and brings them into contact with each other again, it is possible to implement the manual-feed feeding that suppresses the conveyance malfunction and the complication in the apparatus in the configuration of bringing the printing medium into contact with the roller to perform feeding.
An end portion detection sensor lever 57 is provided to the pinch roller holder 55 and detects the printing medium based on whether the end portion detection sensor lever 57 is in a state of blocking or not blocking the light onto an end portion detection sensor 512 (not illustrated in
The printing medium fed to the conveyance roller 51 is conveyed to the printing unit 7 after executing a predetermined skew solving operation as needed, and the printing is performed on the printing medium by the printing head. A publicly-known operation can be used as the skew solving operation, and detailed description thereof is omitted. Along with the printing operation, the printing medium conveyed from the conveyance roller 51 is guided by the platen 58 and a spur base 59 and then reaches the discharging roller 53. During the printing medium printing operation, the conveyance roller 51, the discharging roller 53, or both the conveyance roller 51 and discharging roller 53 perform the conveyance operation, and after the printing operation is completed, the printing medium is discharged by the discharging roller 53 to the discharging tray 81.
In the double-sided printing, the conveyance roller 51 is rotated in the J2 direction (see
The control unit 802 rotates and drives a driving roller of each of the cassette feeding unit 2, the manual-feed feeding unit 3, the conveyance unit 5, and the discharging unit 8 through the driving control by the driving motor 6. Additionally, the control unit 802 performs the driving control of the roller in each of the above-described units particularly based on detection results from the manual-feed detection sensor 39 and the end portion detection sensor 512. Moreover, the control unit 802 controls the ink ejection from the printing head of the printing unit 7 based on the printing data and the like transmitted from an input device 801 and prints an image and the like on the printing medium. Furthermore, positional information on the driving motor 6 from an encoder 813 is also used to control the printing unit 7.
In the above configuration, the user instructs printing and copying through the input device 801 or the operation unit 805 such as a PC or a smartphone. The control unit 802 that receives this instruction stores printing job information according to the instruction and target size information into the storage unit 803.
In a case of the cassette feeding, first, whether the detection state of the manual-feed detection sensor 39 is ON or OFF is determined (S901). If the detection state is OFF, it is determined that the back side guide 36 is not mounted, and error information notifying of the determination result is displayed on the input device 801 or the display unit 806 to prompt the user to mount the back side guide (S902).
On the other hand, if the detection state of the manual-feed detection sensor 39 is ON (no printing medium), whether the detection state of the end portion detection sensor 512 is ON or OFF is determined (S903). If the detection state is OFF, that is, in a case where the end portion detection sensor 512 detects that there is the printing medium, error information notifying that the printing medium is left on the conveyance path (jammed) is displayed on the input device 801 or the display unit 806 (S904). Thus, the user is prompted to take out the printing medium (S904). If the detection state of the end portion detection sensor 512 is ON, it is determined that the back side guide 36 is mounted, and also no printing medium is left in the printing apparatus, in other words, it is a feedable state. Accordingly, the feeding operation (S905) is performed. Additionally, the printing and discharging operation (S906) is performed, and the processing flow ends (S907).
In a case of the manual-feed feeding, once a printing command is received from the user in a manual-feed mode, as illustrated in
On the other hand, if the detection state of the manual-feed detection sensor 39 is ON, it is determined that there is no printing medium in the manual-feed feeding unit 3, and a notification to prompt the user to set the printing medium is displayed (S1003). With this, an instruction to press an “OK” button (not illustrated) displayed on the input device 801 or the display unit 806 after the setting is displayed on the input device 801 or the display unit 806 (S1003). In response to this, once the user sets the printing medium to the manual-feed feeding unit 3 and presses the “OK” button displayed on the display unit 806, the next processing is started (S1004).
As illustrated in
On the other hand, if the detection state of the manual-feed detection sensor 39 is OFF, whether the detection state of the end portion detection sensor 512 is the ON state or the OFF state is determined (S1007). In this process, if the detection state of the end portion detection sensor 512 is OFF, a paper Jam error notifying that the printing medium is inserted too deep is displayed to prompt the user to set the printing medium again (S1008).
If the detection state of the end portion detection sensor 512 is ON, it is possible to determine that the printing medium is properly set on the manual-feed stacking unit 31. In other words, it is determined that the printing medium is nipped by the intermediate roller pair 35 but is not nipped by the conveyance roller 51 and the pinch roller 52 and not put in contact with this pair of rollers. That is, it is determined that it is in the printing medium feedable state, the feeding operation (S1009) and the printing and discharging operation (S1010) are performed, and the processing flow ends (S1011).
With the above conveyance path configuration and control processing, it is possible to detect the attachment state of the back side guide 36 and whether the printing medium is on the manual-feed stacking unit 31 only with the one pair of the manual-feed detection sensor lever 38 and the manual-feed detection sensor 39. Thus, it is possible to determine whether the feeding from the frequently used cassette can be executed and also to determine whether the feeding from the manual-feed feeding can be executed without causing an increase in cost.
In
The printing medium (C) has a printing medium length greater than L1+L2; accordingly, the detection state of the end portion detection sensor 512 is OFF (a state of being nipped by the conveyance roller 51 and the pinch roller 52), and it is determined that the printing medium is inserted too deep. This state corresponds to the detection that the control unit 802 made as OFF in step S1007 in
The printing medium (D) has a printing medium length smaller than L1; accordingly, the detection state of the manual-feed detection sensor 39 is ON (a state of not being nipped by the intermediate roller pair 35), and it is determined that the printing medium is not set on the manual-feed stacking unit 31.
As described above, according to the embodiment of the present invention, in the feeding of the printing medium in a proper size in the manual-feed feeding, for example, it is possible to apply sufficient conveyance force to the printing medium even if it is thick paper, and thus it is possible to suppress the conveyance malfunction in the feeding.
Embodiment(s) of the present invention can also be realized by a computer of a system or apparatus that reads out and executes computer executable instructions (e.g., one or more programs) recorded on a storage medium (which may also be referred to more fully as a ‘non-transitory computer-readable storage medium’) to perform the functions of one or more of the above-described embodiment(s) and/or that includes one or more circuits (e.g., application specific integrated circuit (ASIC)) for performing the functions of one or more of the above-described embodiment(s), and by a method performed by the computer of the system or apparatus by, for example, reading out and executing the computer executable instructions from the storage medium to perform the functions of one or more of the above-described embodiment(s) and/or controlling the one or more circuits to perform the functions of one or more of the above-described embodiment(s). The computer may comprise one or more processors (e.g., central processing unit (CPU), micro processing unit (MPU)) and may include a network of separate computers or separate processors to read out and execute the computer executable instructions. The computer executable instructions may be provided to the computer, for example, from a network or the storage medium. The storage medium may include, for example, one or more of a hard disk, a random-access memory (RAM), a read only memory (ROM), a storage of distributed computing systems, an optical disk (such as a compact disc (CD), digital versatile disc (DVD), or Blu-ray Disc (BD)TM) a flash memory device, a memory card, and the like.
According to the above configuration, it is possible to perform feeding without causing a conveyance malfunction regardless of a type of a printing medium in manual-feed feeding by a printing apparatus.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent mechanisms and functions.
This application claims the benefit of Japanese Patent Application No. 2022-161420 filed Oct. 6, 2022, which is hereby incorporated by reference wherein in its entirety.
Number | Date | Country | Kind |
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2022-161420 | Oct 2022 | JP | national |