This application is based upon and claims the benefit of priority from the corresponding Japanese Patent Application No. 2018-008666 filed Jan. 23, 2018, the entire contents of which are hereby incorporated by reference.
The present disclosure relates to a sheet processing device that performs stapling processing on a bundle of sheets, and an image forming apparatus.
Conventionally, there is a sheet processing device that performs stapling processing on a bundle of sheets. The conventional sheet processing device performs a process of cutting excess parts of staples as one process in the stapling processing. The cut excess parts of staples are stored in a container.
In addition, the conventional sheet processing device counts the number of performing times of the stapling processing so as to detect that the container is full when the count value exceeds a predetermined value. Further, the conventional sheet processing device displays a warning message when the container becomes full.
A sheet processing device according to a first aspect of the present disclosure includes a stapling unit, a container, a pair of electrodes, and a control unit. The stapling unit performs stapling processing in which a staple is driven into a bundle of sheets at a predetermined normal processing position, excess parts of the staple are cut off, and the staple from which the excess parts are cut off is bent. The container has an upper end portion with an opening formed that receives the excess parts. The container is disposed below the stapling unit so that the opening faces the stapling unit. The container stores the excess parts that are cut off by the stapling unit and drop from the stapling unit. The pair of electrodes is disposed at a portion of a side wall of the upper end portion, the portion corresponding to the normal processing position, the pair of electrodes being exposed to inside the container. The control unit detects whether or not the pair of electrodes is short-circuited, so as to detect that the excess parts deposited inside the container have reached the upper end portion when the pair of electrodes is short-circuited.
An image forming apparatus according to a second aspect of the present disclosure includes the sheet processing device described above.
<Overall structure of Multifunction Peripheral>
As illustrated in
The printing portion 1 conveys a sheet S such as plain paper along a sheet conveying path (shown by broken lines in
The image reading portion 2 optically reads a document so as to generate image data of the document. The image reading portion 2 includes a light source and an image sensor. The light source irradiates the document with light. The image sensor receives reflection light reflected by the document and performs photoelectric conversion.
In addition, the multifunction peripheral 100 includes an operation panel 3. The operation panel 3 is provided with a touch screen and hardware buttons. The touch screen display software buttons and messages, and it receives various settings from a user. For instance, when performing a print job with stapling processing in which an end portion of a bundle of sheets is stapled, the operation panel 3 receives setting of a stapling position designated by the user.
Further, a post-processing device 200 is attached to the multifunction peripheral 100. The post-processing device 200 corresponds to a “sheet processing device”. The multifunction peripheral 100 equipped with the post-processing device 200 conveys the printed sheet S to the post-processing device 200 when performing the print job. The post-processing device 200 performs post-processing such as punching processing or stapling processing on the printed sheet S.
As illustrated in
In addition, the post-processing device 200 is provided with a punching unit 10 and a stapling unit 20. The punching unit 10 performs punching processing on the sheet S. The stapling unit 20 performs stapling processing on a bundle of sheets placed on a processing tray 205 (a bundle of the sheets S). The stapling unit 20 performs the stapling processing generally in a state where a center position of the bundle of sheets in a width direction (perpendicular to the sheet conveying direction) matches a predetermined reference position (e.g. a center position in a width direction of the processing tray 205).
As illustrated in
When performing the stapling processing, the stapling unit 20 first drives the staple SN into the bundle of sheets (see the first and second parts from the top in
Next, the stapling unit 20 moves the cutting member 21 so as to cut off excess parts SP of the staple SN (see the second and third parts in
After cutting off the excess parts SP of the staple SN, the stapling unit 20 moves the clinching member 22 to bend the staple SN from which the excess parts SP are cut off (see the third and fourth parts in
As illustrated in
The stapling unit 20 waits at a predetermined initial position on the guide rail GR until the print job with stapling processing is started. Further, when the print job with stapling processing is started, the stapling unit 20 moves to one of predetermined normal processing positions PP (PP1, PP2, PP3 and PP4) as a position for performing the stapling processing. Note that one of the normal processing positions PP may be the initial position.
For instance, if a position P1 shown in
Further, as illustrated in
A storage container 30 is disposed below the stapling unit 20 so as to store the excess parts SP dropped from the stapling unit 20. The storage container 30 corresponds to a “container”. The storage container 30 is disposed in a manner attachable to and detachable from the post-processing device 200. When the storage container 30 is detached from the post-processing device 200, the excess parts SP stored in the storage container 30 can be discarded.
As illustrated in
Further, the post-processing device 200 includes a detection board 40 that detects an internal state of the storage container 30 (a deposited state of the excess parts SP). The detection board 40 corresponds to a “circuit board”. The detection board 40 is disposed outside a side wall of the duct portion 31 of the storage container 30, i.e. in a vicinity of the opening 300 of the storage container 30. In a state where the storage container 30 is attached to the post-processing device 200, a mount surface of the detection board 40 contacts with an outer surface of the side wall of the duct portion 31.
As illustrated in
For instance, as illustrated in
Further, the pair of electrodes 41 is disposed at each of the plurality of portions corresponding to the plurality of drop predicted positions FP. In other words, the pair of electrodes 41 is disposed at each of the plurality of portions corresponding to the plurality of normal processing positions PP. Each of the plurality of pairs of electrodes 41 is disposed so that its position in a container width direction perpendicular to the up and down direction of the storage container 30 matches the corresponding normal processing position PP (drop predicted position FP).
In addition, a hole 31a penetrating the side wall of the duct portion 31 of the storage container 30 in a thickness direction is formed at each of the plurality of portions (at which the pair of electrodes 41 is disposed) facing the plurality of pairs of electrodes 41. Thus, each of the plurality of pairs of electrodes 41 is exposed to inside of the storage container 30 through the hole 31a of the duct portion 31.
With reference to
The discharging outlet 202 side of the processing tray 205 is provided with a discharge roller pair 241 (an upper roller 241a and a lower roller 241b) for discharging the sheet S through the discharging outlet 202. The upper roller 241a is connected to one end of an arm 242, and the other end of the arm 242 is connected to a rotation shaft 243. When the one end of the arm 242 is rotated upward about the rotation shaft 243, the upper roller 241a is moved upward. In this case, the upper roller 241a is separated from the lower roller 241b. When the one end of the arm 242 is rotated downward about the rotation shaft 243, the upper roller 241a moves downward. In this case, the upper roller 241a approaches to the lower roller 241b.
In order to place the sheet S on the processing tray 205, the upper roller 241a is separated from the lower roller 241b to allow the front end of the sheet S to enter between the upper roller 241a and the lower roller 241b. After that, for example, a paddle (not shown) shifts the sheet S in a diagonally downward direction along the processing tray 205 (or the sheet S is shifted by its weight).
When discharging the sheet S placed on the processing tray 205 (including a bundle of sheets bound by the staple SN), the upper roller 241a is made to approach the lower roller 241b so that the sheet S is sandwiched between the upper roller 241a and the lower roller 241b, and the upper roller 241a and the lower roller 241b are rotated. In this way, the sheet S placed on the processing tray 205 is discharged onto the discharge tray 206 through the discharging outlet 202.
In addition, as illustrated in
The main control unit 110 is connected to the printing portion 1 and the image reading portion 2 so as to control the printing portion 1 to perform printing operation and the image reading portion 2 to perform reading operation. In addition, the main control unit 110 is connected to the operation panel 3. Further, the main control unit 110 controls the operation panel 3 to perform display operation and detects an operation made to the operation panel 3.
The post-processing device 200 includes a post-processing control unit 210. The post-processing control unit 210 corresponds to a “control unit”. The post-processing control unit 210 includes a post-processing CPU 211 and a post-processing memory 212. The post-processing control unit 210 is connected to the main control unit 110 in a communicable manner. The post-processing control unit 210 receives an instruction from the main control unit 110 and controls the post-processing device 200 to perform the post-processing operation based on a control program and control data. Note that the main control unit 110 may control the post-processing device 200 to perform the post-processing operation. In this case, the main control unit 110 functions as the “control unit”.
The post-processing control unit 210 is connected to the punching unit 10 so as to control the punching unit 10 to perform operation. In addition, the post-processing control unit 210 is connected to the stapling unit 20 so as to control the stapling unit 20.
As to the print job with stapling processing, the main control unit 110 notifies the post-processing control unit 20 about the stapling position designated by the user when performing the job. When receiving the notice, the post-processing control unit 210 moves the stapling unit 20 to the normal processing position PP corresponding to the stapling position designated by the user among the plurality of normal processing positions PP, as one process in a preparation process for the print job with stapling processing. The post-processing control unit 210 is connected to a unit motor UM and control the unit motor UM, so as to move the stapling unit 20 along the guide rail GR.
In addition, the post-processing control unit 210 is connected to a conveying motor M1, a discharging motor M2, and a shift motor M3. The post-processing control unit 210 controls the conveying motor M1, the discharging motor M2, and the shift motor M3.
The post-processing control unit 210 controls the conveying motor M1 so that the conveying roller pair 203 is appropriately rotated. In addition, the post-processing control unit 210 controls the discharging motor M2 so that the discharge roller pair 241 is appropriately rotated. In addition, the post-processing control unit 210 controls the shift motor M3 so that the shift guide 205a of the processing tray 205 is appropriately moved in the width direction.
In addition, the post-processing control unit 210 performs a state detection process to detect an internal state of the storage container 30 using the detection board 40. For instance, the first connection terminal 40a of the detection board 40 (see
<State Detection Process and State Notification Process>
As illustrated in
If a deposition height (from the bottom of the storage container 30) of the excess parts SP in the storage container 30 becomes higher than a predetermined allowable height, it may cause the excess parts SP to overflow from the opening 300 of the storage container 30 resulting in a malfunction. In addition, if a work of detaching the storage container 30 is performed in the state where the deposition height of the excess parts SP in the storage container 30 is higher than the allowable height, it may cause the excess parts SP to scatter inside the apparatus resulting in a malfunction.
Therefore, the post-processing control unit 210 performs the state detection process using the detection board 40. The post-processing control unit 210 performs the state detection process using the detection board 40, and thereby detects whether or not the excess parts SP deposited inside the storage container 30 have reached a vicinity of the opening 300 (whether or not the deposition height of the excess parts SP in the storage container 30 has reached the allowable height). In order to make the post-processing control unit 210 perform the detection, a distance in the up and down direction between the bottom of the storage container 30 and the position of the plurality of pairs of electrodes 41 is set to a value corresponding to the allowable height (see
For instance, when the state illustrated in
In this case, the post-processing control unit 210 detects that one of the pairs of electrodes 41 is short-circuited. When this detection result is obtained, the post-processing control unit 210 detects that the excess parts SP have reached a vicinity of the opening 300 of the storage container 30 (the deposition height of the excess parts SP in the storage container 30 has reached the allowable height). When the post-processing control unit 210 detects that the excess parts SP have reached a vicinity of the opening 300 of the storage container 30, it performs the state notification process to notify the fact to the user.
With reference to the flowchart shown in
Further, the excess parts SP to be stored in the storage container 30 are produced when performing the print job with stapling processing (including the print job with both stapling processing and punching processing). In other words, the state inside the storage container 30 is not changed when performing a job other than the print job with stapling processing (e.g. when performing a print job with only punching processing). For this reason, the flowchart shown in
In Step S1, the post-processing control unit 210 determines whether or not one of the pairs of electrodes 41 is short-circuited (whether or not there is a short-circuited pair of electrodes 41 among the plurality of pairs of electrodes 41). As a result, if the post-processing control unit 210 determines that one of the pairs of electrodes 41 is short-circuited, the process proceeds to Step S2.
In Step S2, the post-processing control unit 210 transmits to the main control unit 110 a warning notice indicating that there is a short-circuited pair of electrodes 41 among the plurality of pairs of electrodes 41. When receiving the warning notice, the main control unit 110 controls the operation panel 3 to display a warning message. For instance, the operation panel 3 displays a message informing that the storage container 30 will be full soon (a message informing a current state of the storage container 30) or a message urging to discard the excess parts SP in the storage container 30, as the warning message.
Note that the main control unit 110 continues the print job even when receiving the warning notice from the post-processing control unit 210. However, it may be possible to stop the print job when the warning notice is transmitted to the main control unit 110 from the post-processing control unit 210.
In Step S3, the post-processing control unit 210 determines whether or not the short-circuited state is canceled. As a result, if the post-processing control unit 210 determines that the short-circuited state is canceled, the process proceeds to Step S4. For instance, after one of the pairs of electrodes 41 becomes short-circuited, e.g. a vibration generated when the print job is executed may collapse the deposition of the excess parts SP so that the deposition is leveled (the excess parts SP contacting with one of the pairs of electrodes 41 may drop from the position of the pair of electrodes 41). In this case, the short-circuited state is canceled.
In Step S4, the post-processing control unit 210 transmits to the main control unit 110 a cancellation notice indicating that the short-circuited state is canceled. When receiving the cancellation notice, the main control unit 110 stops the display of the warning message on the operation panel 3. After that, the process proceeds to Step S5. Note that, if the post-processing control unit 210 determines that the short-circuited state is not canceled in Step S3, the process proceeds to Step S5 without performing Step S4 (the operation panel 3 continues to display the warning message).
In Step S5, the post-processing control unit 210 determines whether or not the print job is completed. As a result, if the post-processing control unit 210 determines that the print job is completed, this flow is finished. On the contrary, if the post-processing control unit 210 determines that the print job is not completed, the process proceeds to Step S1. The post-processing control unit 210 determines whether or not the print job is completed on the basis of whether or not it has received a completion notice transmitted from the main control unit 110 when the print job is completed.
In Step S1, if the post-processing control unit 210 determines that there is no short-circuited pair of electrodes 41, the process proceeds to Step S5.
If the print job is completed without the short-circuited state is canceled, the post-processing control unit 210 continues the state detection process also after the print job is completed. In addition, the main control unit 110 controls the operation panel 3 to continue the display of the warning message also after the print job is completed.
After the print job is completed without the short-circuited state is canceled, the user who notices the warning message will detach the storage container 30 from the post-processing device 200 in order to discard the excess parts SP in the storage container 30. In this case, the deposition of the excess parts SP in the storage container 30 is collapsed, and hence the short-circuited state is canceled, which is detected by the post-processing control unit 210. When detecting that the short-circuited state is canceled, the post-processing control unit 210 transmits the cancellation notice to the main control unit 110. Therefore, after the print job is completed without cancellation of the short-circuited state (while the warning message is displayed on the operation panel 3), when the user detaches the storage container 30 from the post-processing device 200, the display of the warning message on the operation panel 3 is stopped.
In the structure of this embodiment, as described above, the deposition of the excess parts SP deposited in a protruding shape in the storage container 30 is not leveled, and the excess parts SP are continuously deposited. When the excess parts SP reach a vicinity of the opening 300 of the storage container, the excess parts SP contact with the pair of electrodes 41 disposed at the duct portion 31 of the storage container 30 (at which the opening 300 is formed). In other words, the pair of electrodes 41 becomes short-circuited. Further, the post-processing control unit 210 detects whether or not the pair of electrodes 41 has become short-circuited. In this way, when the excess parts SP deposited inside the storage container 30 reach a vicinity of the opening 300, the post-processing control unit 210 can securely detect that the excess parts SP has reached a vicinity of the opening 300 of the storage container 30.
In addition, as described above, in this embodiment, the pair of electrodes 41 is disposed in each of the plurality of portions corresponding to the plurality of normal processing positions PP on the side wall of the duct portion 31 of the storage container 30. In this structure, even if there are plurality of positions in the storage container 30 at with the excess parts SP can be deposited in a protruding shape (i.e. even if there are a plurality of normal processing positions PP), when the excess parts SP deposited at one of the positions reaches a vicinity of the opening 300 of the storage container 30, this can be detected by the post-processing control unit 210.
In addition, as described above, in this embodiment, the distance between the pair electrodes 41 is wider than the maximum length of the excess parts SP of the staples SN. In this structure, for example, it is possible to prevent the excess part SP from being caught by the pair of electrodes 41. In this way, it is possible to prevent occurrence of an improper state in which the pair of electrodes 41 becomes short-circuited although a summit of the protruding deposition of the excess parts SP has not reached a vicinity of the opening 300 of the storage container 30 (it is possible to prevent misdetection).
In addition, as described above, in this embodiment, the pair of electrodes 41 is formed on the detection board 40 disposed outside of the side wall of the duct portion 31 of the storage container 30, and is exposed to inside of the storage container 30 through the hole 31a formed in the side wall of the duct portion 31. In this structure, although the detection board 40 is disposed outside of the storage container 30, when the excess parts SP reaches a vicinity of the opening 300 of the storage container 30, this can be detected by the post-processing control unit 210.
<Stapling Processing at Position Shifted from Normal Processing Position>
In a structure in which the stapling processing is performed only at the normal processing position PP, a protruding deposition (a deposition mountain generated when the excess parts SP are locally deposited) is likely formed in the storage container 30. In other words, the state illustrated in
The stapling unit 20 can perform the stapling processing also at a position shifted from the normal processing position PP. In this way, occurrence of the above-mentioned improper state can be prevented. Although not particularly limited, the stapling unit 20 can perform the stapling processing at positions on one side and the other side of the normal processing position PP shifted by a few mm each in the width direction.
For instance, after the stapling processing (on one bundle of sheets) at the normal processing position PP is finished, when performing the next stapling processing, the stapling unit 20 moves to a position shifted from the normal processing position PP. Then, the stapling unit 20 performs the stapling processing at the position shifted from the normal processing position PP. In other words, if the previous stapling processing is performed at the normal processing position PP, the stapling unit 20 performs the stapling processing of this time at the position shifted from the normal processing position PP. In this structure, if the stapling processing is sequentially performed on a plurality of bundles of sheets in one print job, the stapling unit 20 moves to change its position every time when the stapling processing on the bundle of sheets is finished (the stapling processing is not performed successively at the same position).
Alternatively, after the print job with stapling processing at the normal processing position PP is finished, when performing the next stapling processing, the stapling unit 20 moves to a position shifted from the normal processing position PP. Then, the stapling unit 20 performs the stapling processing at the position shifted from the normal processing position PP. In other words, if the stapling processing is performed at the normal processing position PP in the previous print job, the stapling unit 20 performs the stapling processing at the position shifted from the normal processing position PP in the print job of this time. In this structure, the stapling unit 20 moves to change its position every time when the print job with stapling processing is finished (the stapling processing in the print job of this time is not performed at the same position as the stapling processing in the previous print job).
Note that when the post-processing control unit 210 controls the stapling unit 20 to perform the stapling processing at a position shifted from the normal processing position PP, it moves the shift guide 205a of the processing tray 205 so that the center position in the width direction of the bundle of sheets placed on the processing tray 205 is shifted from the reference position (the bundle of sheets is shifted in the width direction).
For instance, if the stapling positions designated by the user are two positions in the middle of the end portion of the bundle of sheets, the stapling unit 20 moves to a position shifted from the normal processing position PP2 on one side (or the other side) in the width direction by a predetermined amount, and performs the stapling processing. After that, the stapling unit 20 moves a position shifted from the normal processing position PP3 on one side (or the other side) in the width direction by a predetermined amount, and performs the stapling processing.
In this case, when the stapling unit 20 performs the stapling processing, the post-processing control unit 210 shifts the bundle of sheets placed on the processing tray 205 to one side (or the other side) in the width direction by the same amount as the predetermined amount. In other words, the post-processing control unit 210 shifts the center position in the width direction of the bundle of sheets from the reference position. Then, in this state, the post-processing control unit 210 control the stapling unit 20 to perform the stapling processing. In this way, the bundle of sheets are bound by the staples SN at the stapling positions designated by the user (the two positions in the middle of the end portion of the bundle of sheets).
After the stapling processing (on a bundle of sheets) at the position shifted from the normal processing position PP is finished, when performing the next stapling processing, the stapling unit 20 moves to the normal processing position PP. Then, the stapling unit 20 performs the stapling processing at the normal processing position PP. Alternatively, after the print job with stapling processing at the position shifted from the normal processing position PP is finished, when performing the next stapling processing, the stapling unit 20 moves to the normal processing position PP. Then, the stapling unit 20 performs the stapling processing at the normal processing position PP.
In this structure, the stapling unit 20 does not perform the stapling processing repeatedly at the same position. In other words, drop positions of the excess parts SP dropping into the storage container 30 are dispersed. In this way, it is possible that the protruding deposition (a deposition mountain having a deposition height reaching the allowable height) is hardly generated in the storage container 30.
The embodiment described above is merely an example in every aspect and should not be understood as a limitation. The scope of the present disclosure is defined not by the above description of the embodiment but by the claims, and should be understood to include all modifications within the meaning and scope equivalent to the claims.
Number | Date | Country | Kind |
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2018-008666 | Jan 2018 | JP | national |