The present invention generally relates to a sheet conveying technique in an image forming apparatus, and more particularly, to processing of causing a sheet to wait at a predetermined standby position in a conveyance path on which the sheet is conveyed for reversing the front and back sides of the sheet.
Image forming apparatuses conventionally have allowed double-sided printing in which images are formed on both sides of a sheet. The double-side printing is performed, for example, by forming an image on a first surface of a sheet, turning back the sheet to change the conveying direction thereof in a relay reversal unit placed between a fuser and a discharge port, and then conveying the sheet to a reversal conveyance path to reverse the front and back sides of the sheet to form an image on a second surface thereof.
If the double-sided printing as described above is used to perform double-sided printing operation successively on a plurality of sheets, so-called alternate circulation processing is performed to achieve the double-sided printing. The alternate circulation processing is a processing method for performing the double-sided printing efficiently on a plurality of sheets by forming an image on a first surface of a sheet and then forming an image on another sheet during the reversal of the front and back sides of the former sheet. In the double-sided printing with the alternate circulation processing, however, a sheet present in a reversal conveyance path may prevent the sheet having the image formed on the first surface from being introduced into the reversal conveyance path. In this case, standby processing is performed in which the sheet is caused to wait at a predetermined standby position until it can be introduced into the reversal conveyance path since the sheet in the reversal conveyance path is moved out.
In the standby processing of the sheet, the position of upstream end of the sheet in a conveying direction toward the reversal conveyance path depends on the length of the sheet. For example, a long sheet has an upstream end portion which may protrude from a relay reversal unit and extend into another unit adjacent to the relay reversal unit during the standby state. If sheet obstruction (hereinafter referred to as a jam) occurs in the state as described above in which the sheet spans the relay reversal unit and the unit adjacent to the relay reversal unit, the relay reversal unit must be pulled out of the body of the image forming apparatus to remove the sheet. At this time, the portion of the sheet that extends into the other unit may be snagged on the unit to result in damage to the sheet.
It is an object of the present invention to provide a technique, in an image forming apparatus in which the front and back sides of a sheet are reversed by using a reversal conveyance path, for preventing damage to the sheet when a unit for conveying the sheet to the reversal conveyance path is pulled out for the purpose of clearing a jam or the like.
To solve the abovementioned problem, according to an aspect, the present invention provides an image forming apparatus which turns back a sheet from a first conveying direction toward the outside of the apparatus to a second conveying direction toward the inside of a reversal conveyance path to reverse a front side and a back side of the sheet, the apparatus including an intermediate conveyance unit which is placed upstream from the reversal conveyance path in the second conveying direction and midway in a sheet conveyance path on which the sheet is conveyed during the conveyance involving the turning back, the intermediate conveyance unit being pulled out of the apparatus together with a portion of the sheet conveyance path, a roller which conveys the sheet within the sheet conveyance path in the second conveying direction, and a conveyance control section which controls the roller such that the sheet to be turned back and directed into the reversal conveyance path is caused to wait until the sheet can be conveyed into the reversal conveyance path, the conveyance control section setting, as a standby position of the sheet while the sheet is caused to wait, a position such that an upstream end portion in the second conveying direction of the sheet to be directed into the reversal conveyance path does not extend for a predetermined length or longer into another conveyance unit adjacent to the intermediate conveyance unit upstream from the intermediate conveyance unit in the second conveying direction.
According to another aspect, the present invention provides a sheet conveying method in an image forming apparatus which turns back a sheet from a first conveying direction toward the outside of the apparatus to a second conveying direction toward the inside of a reversal conveyance path to reverse a front side and a back side of the sheet, the apparatus including an intermediate conveyance unit and a roller, the intermediate conveyance unit being placed upstream from the reversal conveyance path in the second conveying direction and midway in a sheet conveyance path on which the sheet is conveyed during the conveyance involving the turning back, the intermediate conveyance unit being pulled out of the apparatus together with a portion of the sheet conveyance path, and the roller conveying the sheet within the sheet conveyance path in the second conveying direction, the method including controlling the roller such that the sheet to be turned back and directed into the reversal conveyance path is caused to wait until the sheet can be conveyed into the reversal conveyance path, and setting, as a standby position of the sheet while the sheet is caused to wait, a position such that an upstream end portion in the second conveying direction of the sheet to be directed into the reversal conveyance path does not extend for a predetermined length or longer into another conveyance unit adjacent to the intermediate conveyance unit upstream from the intermediate conveyance unit in the second conveying direction.
According to another aspect, the present invention provides a sheet conveying program for sheet conveyance in an image forming apparatus which turns back a sheet from a first conveying direction toward the outside of the apparatus to a second conveying direction toward the inside of a reversal conveyance path to reverse a front side and a back side of the sheet, the apparatus including an intermediate conveyance unit and a roller, the intermediate conveyance unit being placed upstream from the reversal conveyance path in the second conveying direction and midway in a sheet conveyance path on which the sheet is conveyed during the conveyance involving the turning back, the intermediate conveyance unit being pulled out of the apparatus together with a portion of the sheet conveyance path, and the roller conveying the sheet within the sheet conveyance path in the second conveying direction, the program including instructions which, when executed by a computer, cause the computer to perform a sheet conveying method including controlling the roller such that the sheet to be turned back and directed into the reversal conveyance path is caused to wait until the sheet can be conveyed into the reversal conveyance path and setting, as a standby position of the sheet while the sheet is caused to wait, a position such that an upstream end portion in the second conveying direction of the sheet to be directed into the reversal conveyance path does not extend for a predetermined length or longer into another conveyance unit adjacent to the intermediate conveyance unit upstream from the intermediate conveyance unit in the second conveying direction.
Preferred embodiments of the present invention will hereinafter be described with reference the accompanying drawings.
The image forming apparatus 1 shown in
The image forming unit 1A includes a relay reversal unit 2 (intermediate conveyance unit) surrounded by a dotted line in
For forming an image on a sheet in the image forming unit 1A, the sheet is first fed by the sheet feed unit 14, and a developer image formed on the intermediate transfer belt 5A is transferred to the sheet by the transfer roller 5 (secondary transfer). The sheet having the developer image transferred thereto is supplied to the fuser 6 which heats and fixes the developer image. The sheet having the image formed thereon is conveyed and ejected through the first discharge port 7 or the second discharge port 8 via the relay reversal unit 2.
On the other hand, for performing so-called double-sided printing in which images are formed on both sides of a sheet, an image is first formed on a first surface of the sheet, then front-back reversal processing is performed in which the side of the sheet opposite to the intermediate transfer belt 5A is chanted to the other side, and then an image is formed on a second surface of the sheet. Specifically, the front-back reversal processing is performed such that the sheet having the developer image heated and fixed thereto by the fuser 6 is turned back to change the conveying direction of the sheet through the use of a conveyance path for reversal retraction in the relay reversal unit 2 and the reversal retraction unit 9 and then the sheet is conveyed to the reversal conveyance path 3. In the conveyance to the path 3, the end of the sheet located at the rear during the formation of the image on the first surface is placed at the front.
In the front-back reversal processing, if the CPU 10 of the image forming apparatus 1 determines, based on the result of detection by a sensor provided for the reversal conveyance path 3 and described later, that the sheet cannot be conveyed to the reversal conveyance path 3 due to the presence of another sheet in the reversal conveyance path 3, then the CPU 10 performs processing of causing the sheet to wait at a predetermined standby position until the sheet can be conveyed. When the sheet can be conveyed to the reversal conveyance path 3, the CPU 10 conveys the sheet to the reversal conveyance path 3, reverses the front and back sides of the sheet, and forms an image on a second surface with the intermediate transfer belt 5A and the fuser 6.
The image forming apparatus 1 of Embodiment 1 is characterized in that, in the standby processing of the sheet, the predetermined standby position is set such that the end portion of the sheet does not extend into the reversal retraction unit 9 as another unit adjacent to the relay reversal unit 2 for a predetermined length which satisfies the following condition or longer. The waiting of the sheet at such a predetermined standby position can prevent damage to the sheet when the relay reversal unit 2 is pulled out of the image forming apparatus 1 for the purpose of clearing a jam of the sheet or the like.
The processing of causing the sheet to wait at the predetermined standby position in order to prevent damage to the portion of the sheet that extends into the reversal retraction unit 9 is required if the end portion of the sheet protrudes from the relay reversal unit 2 and extends into the reversal retraction unit 9 for the predetermined length or longer during the turning back. Thus, the following description will focus on the front-back reversal of the sheet having such a length that one end portion of the sheet protrudes from the relay reversal unit 2 in the front-back reversal and that the turning back cannot be performed unless the sheet extends into the reversal retraction unit 9 for the predetermined length or longer.
Detailed description will hereinafter be made of respective components involved in the front-back reversal processing of the sheet in the image forming apparatus 1 of Embodiment 1 with reference to
The relay reversal unit 2 is a conveyance unit for conveying the sheet having the image formed thereon toward the first discharge port 7 or the second discharge port 8 (in a first conveying direction shown in
The relay reversal unit 2 includes a first conveyance path 2a and a second conveyance path 2b. The first conveyance path 2a includes a discharge conveyance path 2a1 which directs the sheet to the first discharge port 7 and a retraction path 2a2 on which the sheet is conveyed in the turning back of the sheet.
For ejecting the sheet through the first discharge port 7, the sheet is conveyed on the discharge conveyance path 2a1. For conveying the sheet to the reversal conveyance path 3 to perform the front-back reversal of the sheet, the sheet is first conveyed on the retraction path 2a2. For conveying the sheet to the reversal conveyance path 3 after the turning back of the sheet, the sheet is conveyed to the reversal conveyance path 3 via a reversal path 2a3.
The second conveyance path 2b is provided to convey the sheet to the second discharge port 8 for ejecting the sheet through the second discharge port 8.
Conveyance roller pairs 201, 204, 206, 208, and 209 for conveying the sheet are provided on the conveyance paths. A first flapper 202 is provided for switching the sheet between the first conveyance path 2a and the second conveyance path 2b. A second flapper 205 is provided for switching the sheet between the discharge conveyance path 2a1 and the retraction path 2a2. An optical reversal sensor 203 is also provided on the side of the conveyance roller pair 204 closer to the reversal conveyance path 3 to sense the end of the sheet for the turning back. The reversal sensor 203 is placed downstream in the first conveying direction of the first conveyance path 2a from a reversal Mylar® 207 placed above the first flapper 202. The reversal Mylar® 207 has the function of allowing the passage of the end of the sheet conveyed from the fuser 6 through the first conveyance path 2a but preventing the passage of the end of the sheet toward the fuser 6 from the first conveyance path 2a. With the reversal sensor 203 placed downstream from the reversal Mylar® 207 in the first conveying direction as described above, the sheet can be turned back downstream from the reversal Mylar® 207 in the first conveying direction and the turned-back sheet can be conveyed to the reversal path 2a3 reliably.
The operations of the conveyance rollers and the flappers of the relay reversal unit 2 are controlled by the CPU 10.
A discharge roller pair 7A and an output tray 7B are provided close to the first discharge port 7. After the sheet is conveyed on the discharge conveyance path 2a1 of the relay reversal unit 2, the sheet is ejected onto the output tray 7B by the discharge roller pair 7A.
The reversal retraction unit 9 is provided for temporarily retracting the downstream end and its neighboring portion of the sheet in the first conveying direction until the upstream end of the sheet in the first conveying direction passes the reversal sensor 203 and is turned back during the conveyance involving the turning back. In the image forming apparatus 1 of Embodiment 1, the reversal retraction unit 9 is formed integrally with the output tray 7B of the first discharge port 7 in a lower portion of the output tray 7B. The reversal retraction unit 9 includes a reversal retraction path 9A which is connected to the retraction path 2a2 of the relay reversal unit 2 and an optical standby-position sensor 9B which senses the passage of the upstream end of the sheet in the second conveying direction during the turning back.
The standby-position sensor 9B is placed at a position which can cause the sheet to wait at such a predetermined standby position that the upstream end portion of the sheet in the second conveying direction does not extend into the reversal retraction path 9A for the predetermined length or longer in the standby processing performed until the sheet can enter the reversal conveyance path 3 after the turning back of the sheet.
In Embodiment 1, the standby-position sensor 9B is located at the predetermined length L1 in the first conveying direction from the end of the reversal retraction path 9A closer to the relay reversal unit 2 as shown in
The predetermined length refers to the smallest of possible lengths of the portion of the sheet extending into the reversal retraction path 9A that may be damaged if the relay inverse unit 2 is pulled out of the image forming apparatus 1 in the Y-axis direction in
The specific predetermined length depends on the structure of the image forming apparatus 1, but generally falls within the range from more than 0 mm to 20 mm in a typical image forming apparatus. For example, if the predetermined length L1 is 15 mm in the image forming apparatus 1 of Embodiment 1, the sheet is caused to wait at such a position that the length of the portion of the sheet extending into the reversal retraction path 9A is smaller than 15 mm to prevent damage to the sheet when the relay reversal unit 2 is pulled out.
The length of the predetermined length refers to the length from the upstream position to the downstream end position of the edge portion of the sheet in the first conveying direction that abuts on the inner wall of the reversal retraction path 9A when the relay reversal unit 2 is pulled out.
A lower conveyance guide 9C constitutes the bottom surface of the inner wall of the reversal retraction path 9A in the reversal retraction unit 9 and can be opened downward about a rotation axis 9D. The standby-position sensor 9B is preferably placed downstream from the rotation axis 9D in the first conveying direction in the reversal retraction path 9A. With the setting of the position of the standby-position sensor 9B downstream from the rotation axis 9D in the first conveying direction, the standby-position sensor 9B is brought downward integrally with the opening of the lower conveyance guide 9C for clearing a sheet jam or the like. This effectively minimizes damage to the standby-position sensor 9B when the sheet is removed.
The reversal conveyance path 3 is provided for reversing the front and back sides of the turned-back sheet. The reversal conveyance path 3 allows the sheet having the image formed on the first surface to be conveyed therein such that the downstream end in the second conveying direction is located at the leading end. This can reverse the front and back sides of the sheet to form an image on the second surface of the sheet. After the sheet is conveyed in the reversal conveyance path 3 to reverse the front and back sides of the sheet, the sheet is again conveyed to a secondary transfer position 5B to form the image on the second surface. The reversal conveyance path 3 includes conveyance roller pairs 301 to 304, a first sensor 305 of a switch type which senses the entrance of the sheet into the reversal conveyance path 3, and a second sensor 306 of a switch type which senses the conveyance of the sheet near an exit of the reversal conveyance path 3. The CPU 10 determines whether or not the sheet can enter the reversal conveyance path 3 depending on the presence or absence of the sheet sensed by the first sensor 305 and the second sensor 306. If the CPU 10 determines, based on the result of the sensing by the sensors 305 and 306, that the sheet cannot enter the reversal conveyance path 3, then the sheet is caused to wait at the standby position. On the other hand, if the CPU 10 determines that the sheet can enter the path 3, the CPU 10 performs processing of conveying the turned-back sheet or the sheet waiting at the standby position to the reversal conveyance path 3.
Exemplary situations in which the sheet cannot enter the reversal conveyance path 3 include the situation in which the sheet is already present in the reversal conveyance path 3 and the conveyance of the sheet is sensed by both of the first sensor 305 and the second sensor 306 and the situation in which the sheet is present upstream from the reversal conveyance path 3 and is sensed only by the first sensor 305.
On the other hand, exemplary situations in which the sheet can enter the reversal conveyance path 3 include the situation in which no sheet is present in the reversal conveyance path 3 and conveyance of a sheet is not sensed by any of the first sensor 305 and the second sensor 306 and the situation in which the sheet conveyed to the reversal conveyance path is already present but the sheet is short and is sensed only by the second sensor 306 and, if a next sheet is conveyed to the reversal conveyance path 3, the sheet does not interfere with the already conveyed sheet and can be held in the reversal conveyance path 3.
Next, description will be made of the flow of the operation of the front-back reversal processing involving the standby processing of the sheet performed by the image forming apparatus 1 of Embodiment 1 having the abovementioned structure.
First, as described above, the sheet is fed by the sheet feed unit 14, the developer image formed on the intermediate transfer belt 5A is transferred to the sheet, and the developer image is heated and fixed to the sheet by the fuser 6, thereby forming an image on the first surface of the sheet. The sheet having the image formed on the first surface thereof is conveyed from the fuser 6 in the first conveying direction by the conveyance roller pair 201.
For performing the double-sided printing on the sheet, the front-back reversal processing is performed in which the sheet conveyed in the first conveying direction is turned back and conveyed in the second conveying direction to the reversal conveyance path 3.
First, in the front-back reversal processing, the CPU 10 previously performs control to set the first flapper 202 downward as shown by a solid line in
If the reversal sensor 203 senses the passage of the rear end of the sheet during the retraction of the leading end portion of the sheet through the first conveyance path 2a, the retraction path 2a2, and the reversal retraction path 9 of the reversal retraction unit 9 as described above, the CPU 10 starts the turning back of the sheet. Specifically, if the reversal sensor 203 senses the passage of the end of the sheet, the CPU 10 performs control to stop the conveyance in the first conveying direction with the conveyance roller pair 204 to convey the sheet in the second conveying direction. For a sheet S shown in
After the turning back, if another sheet is already present in the reversal conveyance path 3 and thus the CPU determines based on the detection by the sensors 305 and 306 in the reversal conveyance path 3 that the sheet having the image formed on the first surface cannot be conveyed to the reversal conveyance path 3, then the image forming apparatus 1 of Embodiment 1 performs processing of conveying the sheet in the second conveying direction from the turning-back position to the predetermined standby position and causing the sheet to wait at the predetermined standby position.
Specifically, for the sheet S shown in
With the standby processing after the turning back as described above, the image forming apparatus 1 can cause the sheet S to wait in such a state that the end portion of the sheet S does not extend into the reversal retraction path 9A of the reversal retraction unit 9 adjacent to the relay reversal unit 2 for the predetermined length L1 or longer. When a jam or the like occurs in the standby state and the relay reversal unit 2 is pulled out of the image forming apparatus 1, any damage is advantageously prevented to the portion of the sheet S within and closer to the reversal retraction unit 9. This can eliminate waste of the sheet due to damage to the sheet and prevent occurrence of problems in the image forming apparatus 1 that would be caused by any broken portion of the sheet remaining in the image forming apparatus 1.
If the turning-back position is used as the standby position, the sheet is caused to wait with one end portion thereof extending long into the reversal retraction unit 9 adjacent to the relay inverse unit 2 depending on the length of the sheet. When the relay reversal unit 2 is pulled out in this state, the sheet suffers from damage such as a break of the one end portion.
As described above, according to the image forming apparatus 1 of Embodiment 1, if the front and back sides of the long sheet are reversed for the double-sided printing or the like, damage to the sheet can be prevented in pulling out the relay reversal unit 2 to clear a jam.
Although
In some cases, both of a long sheet and a short sheet are present in the image forming apparatus 1. The long sheet needs to wait at the predetermined standby position after turning back since the end portion of the sheet extends into the reversal retraction path 9A for the predetermined length or longer at the time of the turning back. The short sheet does not need to wait at the predetermined standby position 1001b after turning back since the end portion of the sheet does not extend into the reversal retraction path 9A for the predetermined length or longer at the time of the turning back. In this case, the image forming apparatus 1 according to Embodiment 1 can perform the predetermined standby processing described above only in the reversal of the front and back sides of the former long sheet which requires the standby processing.
If the sheet to be turned back is the long sheet as described above, the passage of the end of the sheet is sensed by the two sensors, that is, the standby-position sensor 9B and the reversal sensor 203. Specifically, for the long sheet, the standby-position sensor 9B senses the passage of the downstream end of the sheet in the first conveying direction and then the reversal sensor 203 senses the passage of the upstream end of the sheet in the first conveying direction. When the standby-position sensor 9B and the reversal sensor 203 sense the passage of the ends of the sheet in this manner, the CPU 10 controls the conveyance roller pair 204 to perform the predetermined standby processing described above. As a result, if both of the long sheet requiring the predetermined standby processing and the short sheet requiring no standby processing are present, the predetermined standby processing can be performed only on the long sheet.
The image forming apparatus 1 can be provided with a sensor which detects the length in the conveying direction of the sheet subjected to the front-back reversal processing. The sensor can be used to perform processing of causing the sheet to wait at the predetermined standby position if the length of the sheet is equal to or larger than a predetermined length in accordance with the flow of processing shown in
While the image forming apparatus 1 of Embodiment 1 has been described in conjunction with the reversal retraction unit 9 provided within the output tray 7B, the present invention is not limited thereto. For example, a reversal retraction unit may be provided separately from the first discharge port 7 as required, and the reversal retraction unit may be provided either below or above the first discharge port 7.
While Embodiment 1 has been illustrated with the reversal sensor 203 and the standby-position sensor 9B which are formed of the optical sensors and with the first sensor 305 and the second sensor 306 in the reversal conveyance path 3 which are formed of the switch-type sensors, the present invention is not limited thereto. As long as the passage of the sheet can be sensed, any device can be used. Alternatively, a camera for shooting the sheet being conveyed may be provided and the obtained image may be subjected to image processing, thereby sensing the passage of the sheet and the presence or absence of the sheet, by way of example.
Next, Embodiment 2 of the present invention will be described.
Embodiment 2 of the present invention is a modification of Embodiment 1 of the present invention described above. Embodiment 2 differs from Embodiment 1 in that a stepping motor is used as a unit for stopping a sheet at a predetermined standby position after turning back of the sheet. The stepping motor in Embodiment 2 serves as a unit for driving a conveyance roller pair 204 such that the sheet can be conveyed for an arbitrary distance.
Embodiment 2 of the present invention will hereinafter be described with reference to
The image forming apparatus 1 of Embodiment 2 includes a conveyance roller pair 204A driven by the stepping motor which can control the conveyance distance of a sheet. The conveyance distance is a length previously calculated from a turning-back position to a standby position specified such that the end portion of the sheet does not extend into a reversal retraction path 9A for a predetermined length or longer. Standby processing after turning back of the sheet is performed by conveying the sheet for the conveyance distance with the conveyance roller pair 204A. By way of example, a sheet S shown in
The conveyance distance L2 can be determined, for the sheet S, from the difference between the length of the sheet S in the conveying direction and the distance between a turning-back position 1001a and the standby position 1002b. The length of the sheet in the conveying direction can be previously determined by detecting the size of the sheet in a sheet feed unit 14, for example. The distance between the turning-back position 1001a and the standby position 1002b is determined as a value specific to the image forming apparatus 1 by previously setting the standby position 1002b at an arbitrary position which falls within a predetermined length L1 representing the length of the end portion of the sheet extending into the reversal retraction path 9A. Thus, the distance between the positions 1001a and 1002b is previously stored in a memory 12, and the length of the sheet in the conveying direction is detected in conveying the sheet S, so that the conveyance distance L2 of the sheet S can be determined by the CPU 10 from those values.
Next, description will be made of the flow of processing of causing the sheet S to wait at the predetermined standby position in Embodiment 2.
First, the CPU 10 drives the conveyance roller pair to convey the sheet S in the first conveying direction within the first conveyance path 2a until the passage of the rear end of the sheet S in the first conveying direction is sensed by a reversal sensor 203. When the reversal sensor 203 senses the passage of the rear end in the first conveying direction, the CPU 10 stops the driving of the conveyance roller pair 204A in the first conveying direction. Then, the CPU 10 drives the stepping motor for the conveyance roller pair 204A such that the sheet S is conveyed in the second conveying direction for the conveyance distance L determined previously on the basis of the length of the sheet S and the distance between the points 1001a and 1002b.
Through the flow of the processing, the CPU 10 can cause the sheet S to wait at such a predetermined standby position that the upstream end portion of the sheet in the second conveying direction does not extend into the reversal conveyance path 9A for the predetermined length or longer after the turning back of the sheet S.
Then, if the CPU 10 determines that the sheet S can be conveyed to the reversal conveyance path 3 based on the sensing by sensors 305 and 306 similarly to Embodiment 1, the sheet S is conveyed to the reversal conveyance path 3 to perform front-back reversal of the sheet S. After the front-back reversal of the sheet S, the sheet is again conveyed to a secondary transfer position 5B and a fuser 6 to allow formation of an image on a second surface of the sheet.
As described above, the sheet can be caused to wait at the predetermined standby position in the front-back reversal processing of the sheet in Embodiment 2, as in Embodiment 1. If the relay reversal unit 2 is pulled out of the image forming apparatus 1 due to a jam during the standby of the sheet until it can be conveyed to the reversal conveyance path 3, no damage is caused to a portion of the sheet close to the reversal retraction path 9A.
The program for performing the abovementioned acts in a computer constituting the image forming apparatus can be provided as a sheet conveying program. While Embodiments 1 and 2 illustrate an example in which the program for realizing the functions implementing the present invention is previously recorded on a storage area provided in the apparatus, the present invention is not limited thereto. Such a program may be downloaded from a network to the apparatus, or such a program stored on a computer-readable recording medium may be installed on the apparatus. The recording medium may take any form as long as it can store a program and be read by a computer. Specifically, examples of the recording medium include internal storage implemented in a computer such as a ROM and a RAM, a portable storage medium such as a CD-ROM, a flexible disk, a DVD disk, a magneto-optical disk, and an IC card, a database for holding a computer program, another computer and its database, a transmission medium over a channel, and the like. The functions provided from the previous installation or download may be realized by cooperation with an OS (operating system) in the apparatus or the like.
The program in Embodiments 1 and 2 includes a program in which an executable module is dynamically produced.
While the present invention has been described in detail according to the specific aspects, it is apparent to those skilled in the art that various changes and alterations can be made without departing from the true spirit or scope of the present invention.
As described in detail, the present invention can provide the technique for preventing damage to the sheet when the unit for conveying the sheet to the reversal conveyance path is pulled out for the purpose of clearing a jam or the like in the image forming apparatus in which the front-back reversal processing of the sheet is performed by using the reversal conveyance path.
This application is based upon and claims the benefit of priority from: U.S. provisional application 61/034,395, filed on Mar. 6, 2008, the entire contents of each of which is incorporated herein by reference.
Number | Date | Country | |
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61034395 | Mar 2008 | US |