1. Field of the Invention
The present invention relates to a sheet punching apparatus for punching a sheet and a control method thereof.
2. Description of the Related Art
The sheet punching apparatus is classified into a press punch type for punching conveyed recording sheets one sheet by one sheet while temporarily stopping sheet conveyance and a rotary type for punching recording sheets without stopping sheet conveyance. The press punch type is generally more accurate in punched hole position and smaller in variation in punched hole position than in the rotary type.
To make the apparatus compact in size and reduced in cost, a punch drive motor comprised of a DC motor is used in the sheet punching apparatus. However, the DC motor is lower in stop accuracy as compared to a pulse motor and hence produces a large variation in stop position from a target stop position.
In order to suppress a variation in stop position, a punching apparatus described in U.S. Pat. No. 7,172,185 is configured to start, immediately after start of a punch motor, a time measurement in which pulses are counted by an encoder attached to the punch motor, and applies brake to the motor upon lapse of a predetermined time from the start of the motor.
The punching apparatus described in the U.S. patent causes the punch motor to restart so as to bring a punch blade close to a desired position, if a punch blade position detected at the time of or prior to a motor stop deviates from the desired position, thereby improving the accuracy of motor stop position.
Although the punching apparatus described in the U.S. patent is suitable for correction of a variation (individual difference) of the apparatus (punch motor), operation of the apparatus is liable to vary even if the apparatus operates at the same load. Thus, even when a timing at which brake is started to be applied to the punch motor is kept the same, the punch motor (a movable part of the apparatus) does not always stop at the same position, and therefore the accuracy of movement distance of the movable part is not high.
With the punching apparatus described in the U.S. patent that restarts the punch motor (DC brush motor) to correct a deviation of the stop position of the punch blade, the motor is repeatedly started and stopped, and therefore the service life of the motor is shortened, posing a problem that component parts of the apparatus must frequently be replaced and the maintenance cost of the apparatus increases.
The present invention provides a sheet punching apparatus and a control method thereof, which are capable of improving the accuracy of movement distance of a movable member of the apparatus and maintaining the durability of a drive unit of the apparatus.
According to a first aspect of this invention, there is provided a sheet punching apparatus for punching a sheet, which comprises a punch configured to punch a sheet by being moved, a movable member configured to move in a predetermined direction to thereby move the punch, a drive unit configured to move the movable member in the predetermined direction, a position detection unit configured to detect that the movable member is at a predetermined position, a stop control unit configured, in response to the position detection unit detecting that the movable member reaches the predetermined position after movement of the movable member is started by the drive unit, to stop an operation of the drive unit to thereby stop the movement of the movable member, and a timing decision unit configured to decide a next start timing of movement of the movable member based on a position where the movable member is stopped by the stop control unit.
According to a second aspect of this invention, there is provided a control method of the sheet punching apparatus described in the first aspect.
With this invention, a start timing of next movement of the movable member is decided based on a stop position of the movable member, e.g., a difference between a first movement amount of the movable member from the start of movement of the movable member until the movable member reaches the predetermined position and a second movement amount of the movable member from the start of movement of the movable member until the movable member is stopped. By changing the next start timing (i.e., distance) of movement of the movable member according to the stop position of the movable member, it is possible to improve the accuracy of movement distance of the movable member and shorten a substantial drive time of the drive unit. It is therefore possible to improve the accuracy of movement distance of the movable member and the durability of the drive unit even by using the drive unit comprised of a DC motor.
Further features of the present invention will become apparent from the following description of an exemplary embodiment with reference to the attached drawings.
The present invention will now be described in detail below with reference to the drawings showing a preferred embodiment thereof.
The post-processing apparatus 100 is coupled to the image forming apparatus 300 and includes a saddle-stitching unit (saddle unit) 135 and a side-stitching unit (as a sheet stacking unit). The post-processing apparatus 100 and the image forming apparatus 300 can be configured integrally with each other.
The image forming apparatus 300 includes cassettes 909a to 909d, an image forming unit having photosensitive drums 914a to 914d for yellow, magenta, cyan, and black, and an operation unit 308. Toner images of four colors formed on the photosensitive drums 914a to 914d are transferred to a sheet supplied from any of the cassettes 909a to 909d. The sheet is conveyed to a fixing unit 904 where the toner images are fixed to the sheet, and is then conveyed to the post-processing apparatus 100.
To correct the lateral shift, the sheet is moved in a front-to-rear direction by a shift unit 108 while being conveyed by pairs of shift rollers 105, 106. A predetermined number of holes can be punched at an edge portion of the sheet by a punch unit 250 (punching apparatus), as needed. The sheet is then conveyed by a conveyance roller 110, a separation roller 111, and a pair of buffer rollers 115, and further conveyed to an upper conveyance path 117 or to a bundle conveyance path 121.
To guide the sheet to the upper conveyance path 117, an upper path changeover flapper 118 is switched by a solenoid (not shown) to a position (not shown). Thereafter, the sheet is conveyed through the upper conveyance path 117 by an upper sheet discharge roller 120 to an upper tray 136.
On the other hand, to guide the sheet to the bundle conveyance path 121, the upper path changeover flapper 118 is switched to the position shown in
Subsequently, to perform saddle processing on the sheet, a saddle path changeover flapper 125 is switched to a position (not shown) by a solenoid (not shown). Then, the sheet is conveyed to a saddle path 133 and guided by a pair of saddle inlet rollers 134 to the saddle unit 135 where it is subjected to the saddle processing. Since the saddle processing is ordinary processing and does not relate to the gist of this invention, a description thereof is omitted.
On the other hand, to discharge the sheet to a lower tray 137, the saddle path changeover flapper 125 is switched to the position shown in
Next, a description will be given of the construction and operation of the punch unit 250 as the punching apparatus.
The punch unit 250 includes a slider 260, punches 273 movable in a punching direction, a punch motor 221, a punch home position 1 sensor (hereinafter, referred to as the first HP sensor) 271, and a punch home position 2 sensor (hereinafter, referred to as the second HP sensor) 272. The first and second HP sensors 271, 272 each comprised of a transmittive photointerrupter are for determining a position of the slider 260 (movable member). If both the HP sensors 271, 272 are light-intercepted by the slider 260 as shown in
If none of the HP sensors 271, 272 are light-intercepted as shown in
The slider 260 is driven by the punch motor 221 so as to be reciprocated in directions c and d in
As shown in
An encoder 280 is fixed to a rear end of an output shaft of the punch motor 221. With rotation of the punch motor 221, a punch motor clock sensor 276, which is comprised of a transmittive photointerrupter, generates a punch motor clock pulse (hereinafter, referred to as the clock pulse) each time one slit of a slit pattern of the encoder 280 has passed the sensor 276. By counting the clock pulses, an amount of rotation of the punch motor 221, i.e., an amount of movement of the slider 260, is detected. While the slider 260 is moved by a predetermined distance, one punching operation is carried out. In this embodiment, a sheet is punched when the slider 260 is moved from the front side to the rear side. After the next sheet is set in the punch unit, this sheet is punched when the slider 260 is moved from the rear side to the front side.
The original feeding apparatus controller 301 drives and controls the automatic original feeding apparatus 500 (see,
The post-processing apparatus controller 501 is mounted on the post-processing apparatus 100 and performs data communication with the image forming apparatus controller 305 via a communication IC (not shown) to control the operation of the post-processing apparatus 100. The post-processing apparatus controller 501 includes a CPU 401, ROM 402, and RAM 403.
The CPU 401 executes a control program stored in the ROM 402 to control various actuators and sensors (for example, the inlet sensor 101, and a conveyance motor 208 for driving the inlet roller pair 102 and the shift roller pairs 105, 106). A punch motor driver 279, conveyance motor driver 278, first HP sensor 271, second HP sensor 272, and punch motor clock sensor 276 are connected to the post-processing apparatus controller 501. The punch motor driver 279 drives the punch motor 221. The conveyance motor driver 278 drives the conveyance motor 208. The RAM 403 temporarily stores control data and is used as a work area for arithmetic processing for the control.
Next, a description will be given of an initial operation and a punching operation of the punch unit 250.
When a user selects execution of punching operation and instructs copy start, the post-processing apparatus controller 501 performs the initial operation of the punch unit 250, including checking whether the punch unit 250 normally operates. In the initial operation, the post-processing apparatus controller 501 starts the punch motor 221 to rotate the motor output shaft clockwise in order to move the slider 260 from the position shown in
With movement of the slider 260 caused by the rotation of the punch motor 221, the light interception member of the slider 260 gets out of the first HP sensor 271 and therefore the sensor 271 is turned off (low level). With further movement of the slider 260, the light interception member of the slider 260 gets out of the second HP sensor 272, and the sensor 272 is turned off. At that time, the post-processing apparatus controller 501 stops driving the punch motor 221.
During the initial operation, the CPU 401 counts pulses supplied from the punch motor clock sensor 276 to measure the time period ΔT0. In other words, the CPU 401 and the clock sensor 276 function as a movement amount detection unit.
It should be noted that the above description is applied not only to the initial operation, but also to a punching operation in which the slider 260 is moved in the direction shown by arrow h.
After completion of the initial operation, the conveyance motor 208 is driven (see,
In a punching operation of a press punch type punching apparatus, the punch motor 221 is usually started after the conveyance motor 208 is stopped, as shown by chain lines in
As compared to a case where the punch motor 221 is started after the stop of the conveyance motor 208, the punch motor 221 is started at a timing earlier by the time period ΔT0, as shown by leftward arrows in
After the start of the punch motor 221, the second HP sensor 272 is turned on by the movement of the slider 260 caused by the motor rotation and then the first HP sensor 271 is turned on. In response to the sensor 271 being turned on, the post-processing apparatus controller 501 stops the punch motor 221 (see,
In the next punching operation (i.e., in the punching operation on the next sheet), the post-processing apparatus controller 501 starts the punch motor 221 at a timing earlier by the time period ΔT1 than the stop timing of the conveyance motor 208. In this way, the start timing of each punching operation (i.e., the start timing of the punching operation on each sheet) is properly determined in advance based on the amount of overrun determined in the preceding punching operation (i.e., in the punching operation on the preceding sheet). In other words, the time period ΔT1 is used as a correction value for the start timing of the punch motor 221.
First, the CPU 401 determines whether the first HP sensor 271 is ON, i.e., whether the slider 260 is stopped at the position shown in
If the first HP sensor 271 is ON, the CPU 401 performs the initial operation shown in
Next, the CPU 401 waits for the punch motor 221 to completely stop, so that the punch motor clock pulse is no longer output (step S6). When determining that the punch motor clock pulse is no longer output, the CPU 401 computes a time period ΔT0 (see,
On the other hand, if it is determined in step S1 that the first HP sensor 271 is not ON, i.e., if the slider 260 is stopped at the position shown in
Next, the CPU 401 determines whether the first HP sensor 271 is turned ON (step S10). If the sensor 271 is turned ON, i.e., if the slider 260 is moved to reach the position shown in
Then, the CPU 401 waits for the punch motor 221 to completely stop, so that the punch motor clock pulse is no longer output (step S12). When determining that the punch motor clock pulse is no longer output, the CPU 401 computes a time period ΔT0′ (see,
First, the CPU 401 determines whether a rear end of a sheet has passed the inlet sensor 101 (step S21). If the answer to step S21 is NO, the CPU 401 repeats the determination in step S21. On the other hand, if the sheet rear end has passed the inlet sensor 101, the CPU 401 outputs, at a timing earlier by a time period t0 than a stop timing of the conveyance motor 208, a punch motor start signal that causes the punch motor 221 to rotate anticlockwise (step S22). Next, the CPU 401 starts inputting clock pulses from the punch motor clock sensor 276 (step S23), and stops the conveyance motor 208 (step S24).
It should be noted that in a case where the punching operation is performed not for the first time after power-on of the image forming apparatus, the time period t0 is computed based on the amount of overrun in the preceding punching operation. On the other hand, if the punching operation is performed for the first time after the power on of the apparatus, the time period t0 (equal to the time period ΔT0 shown in
Next, the CPU 401 determines whether the first HP sensor 271 is ON, i.e., whether the slider 260 is at the position shown in
When determining that the clock pulse is no longer output, the CPU 401 computes the time period t1 based on the number of clock pulses (amount of overrun) from when the first HP sensor 271 was turned ON to when the motor completely stops (step S28). Then, the CPU 401 outputs a conveyance motor start signal to restart the conveyance motor 208 (step S29), whereby the punched sheet is conveyed toward the downstream of the punch unit 250.
Next, the CPU 401 determines whether the punching operation is to be continued (step S30). If the punching operation is not to be continued, the CPU 401 completes the present process. On the other hand, if the punching operation is to be continued, the CPU 401 causes the next sheet to be conveyed into the post-processing apparatus 100 (step S31).
After the next sheet is conveyed into the post-processing apparatus 100, the CPU 401 waits for the sheet rear end to pass through the inlet sensor 101 (step S32). When determining that the sheet rear end has passed the inlet sensor 101, the CPU 401 outputs, at a timing earlier by a time period t1 than a stop timing of the conveyance motor 208, a punch motor start signal that causes the punch motor 221 to rotate clockwise (step S33). Thus, the CPU 401 functions as a timing decision unit to decide a start timing of the punch motor 221. Next, the CPU 401 starts inputting clock pulses from the punch motor clock sensor 276 (step S34), and stops the conveyance motor 208 (step S35). It should be noted that the time period t1 corresponds to the amount of overrun in the preceding punching operation, and is updated each time the punching operation is completed.
Next, the CPU 401 determines whether the second HP sensor 272 is turned OFF (step S36). If the second HP sensor 272 is turned OFF, the CPU 401 outputs a punch motor stop signal to stop the punch motor 221 (step S37). Then, the CPU 401 determines whether the punch motor 221 completely stops, so that the punch motor clock pulse is no longer output (step S38). When determining that the clock pulse is still output, the CPU 401 repeats the determination in step S38. On the other hand, when determining that the punch motor clock pulse is no longer output, the CPU 401 computes an overrun time period from when the second HP sensor 272 was turned OFF to when the motor completely stops (step S39). Subsequently, the CPU 401 outputs a conveyance motor start signal to restart the conveyance motor 208 (step S40), whereby the punched sheet is conveyed toward the downstream of the punch unit 250.
Then, the CPU 401 determines whether the punching operation is to be continued (step S41). If the punching operation is not to be continued, the CPU 401 completes the present process. On the other hand, if the punching operation is to be continued, the CPU 401 causes the next sheet to be conveyed into the post-processing apparatus 100 (step S42), and returns to step S21. The CPU 401 executes the above-described operation procedures until completion of the punching operation.
First, the CPU 401 determines whether a rear end of a sheet has passed the inlet sensor 101 (step S51). If the answer to step S51 is NO, the CPU 401 repeats the determination in step S51. On the other hand, if the sheet rear end has passed the inlet sensor 101, the CPU 401 outputs, at a timing earlier by a time period t0 than a stop timing of the conveyance motor 208, a punch motor start signal that causes the punch motor 221 to rotate clockwise (step S52). Next, the CPU 401 starts inputting clock pulses from the punch motor clock sensor 276 (step S53), and stops the conveyance motor 208 (step S54).
It should be noted that in a case where the punching operation is performed not for the first time after power-on of the image forming apparatus, the time period t0 is computed based on the amount of overrun in the preceding punching operation. On the other hand, if the punching operation is performed for the first time after power-on of the apparatus, the time period t0 (equal to the time period ΔT0′ shown in
Next, the CPU 401 determines whether the second HP sensor 272 is OFF, i.e., whether the slider 260 is at the position shown in
When determining that the clock pulse is no longer output, the CPU 401 computes the time period t1 based on the number of clock pulses (amount of overrun) from when the second HP sensor 272 was turned OFF to when the motor completely stops (step S58). Then, the CPU 401 outputs a conveyance motor start signal to restart the conveyance motor 208 (step S59), whereby the punched sheet is conveyed toward the downstream of the punch unit 250.
Next, the CPU 401 determines whether the punching operation is to be continued (step S60). If the punching operation is not to be continued, the CPU 401 completes the present process. On the other hand, if the punching operation is to be continued, the CPU 401 causes the next sheet to be conveyed into the post-processing apparatus 100 (step S61).
After the next sheet is conveyed into the post-processing apparatus 100, the CPU 401 waits for the sheet rear end to pass through the inlet sensor 101 (step S62). When determining that the sheet rear end has passed the inlet sensor 101, the CPU 401 outputs, at a timing earlier by a time period t1 than a stop timing of the conveyance motor 208, a punch motor start signal that causes the punch motor 221 to rotate anticlockwise (step S63). Next, the CPU 401 starts inputting clock pulses from the punch motor clock sensor 276 (step S64), and stops the conveyance motor 208 (step S65). It should be noted that the time period t1 corresponds to the amount of overrun in the preceding punching operation, and is updated each time the punching operation is completed.
Next, the CPU 401 determines whether the first HP sensor 271 is turned ON (step S66). If the first HP sensor 271 is turned ON, the CPU 401 outputs a punch motor stop signal to stop the punch motor 221 (step S67).
Then, the CPU 401 determines whether the punch motor 221 completely stops, so that the punch motor clock pulse is no longer output (step S68). When determining that the punch motor clock pulse is still output, the CPU 401 repeats the determination in step S68. On the other hand, when determining that the punch motor clock pulse is no longer output, the CPU 401 computes an overrun time period from when the first HP sensor 271 was turned ON to when the motor completely stops (step S69). Subsequently, the CPU 401 outputs a conveyance motor start signal to restart the conveyance motor 208 (step S70), whereby the punched sheet is conveyed toward the downstream of the punch unit 250.
Then, the CPU 401 determines whether the punching operation is to be continued (step S71). If the punching operation is not to be continued, the CPU 401 completes the present process. On the other hand, if the punching operation is to be continued, the CPU 401 causes the next sheet to be conveyed into the post-processing apparatus 100 (step S72), and returns to the processing of step S51. The CPU 401 executes the above-described operation procedures until completion of the punching operation.
The sheet punching apparatus of this embodiment computes an actual stop position of the slider 260, and changes a start timing (i.e., distance) of the next movement of the slider 260 according to the computed stop position, thereby improving the accuracy of movement distance of the slider 260. As a result, a motor drive time from the start of the punch motor until the motor reaches a stop position can be minimized, and the durability of the punch motor can be improved. In addition, the productivity in sheet punching can be made higher than in a case where the punch motor is started after completion of sheet conveyance. Even when the punch motor comprised of a DC motor is used, the accuracy of movement distance of the motor and the durability of the motor can be improved.
In the initial operation, it is possible to decide a start timing of movement of the slider (movement start timing) while checking whether the sheet punching apparatus normally operates, whereby an immediate shift to the sheet punching operation can be realized.
Since the start timing is updated each time a sheet is punched, a highly accurate movement distance of the slider 260 can be maintained, irrespective of a state of the motor. In this embodiment, a sheet can be punched by simply moving the slider 260 in a predetermined direction.
It should be noted that this invention is not limited to the above-described embodiment. For example, as image forming apparatuses to which the sheet punching apparatus of this invention is applied, there may be mentioned a printing apparatus, a facsimile machine having a printing function, and a multi-function peripheral having a printing function, copy function, scanner function, and the like.
In the above-described embodiment, the image forming apparatus using an electrophotographic printing method has been described by way of example, however, this invention is also applicable to image forming apparatuses using various printing methods such as an ink jet method, thermal transfer method, thermography method, electrostatic method, and discharge breakdown method.
Shapes and relative positions of component parts described in the above embodiment are not limitative, and can be modified according to the construction of an apparatus to which this invention is applied and according to various conditions.
A sheet to be punched is not limited in material and in shape, and may be paper medium, OHP sheet, heavy sheet, tab sheet, etc.
While the present invention has been described with reference to an exemplary embodiment, it is to be understood that the invention is not limited to the disclosed exemplary embodiment. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2009-257180, filed Nov. 10, 2009, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2009-257180 | Nov 2009 | JP | national |
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Number | Date | Country | |
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20110107886 A1 | May 2011 | US |