The present disclosure relates to a copying machine and a printer each of which is configured to form a color image on a recording material using an electrophotographic system.
For an electrophotographic image forming apparatus, it has been desired to shorten a first print time required after printing is instructed until outputting is performed and a first copy time required after a copy key is pressed until a copy is output.
In an electrophotographic color image forming apparatus, toner images of respective colors of yellow, magenta, cyan, and black (hereinafter referred to as “Y”, “M”, “C”, and “K”) are formed on photosensitive drums of the respective colors, and the images are transferred from the photosensitive drums onto an intermediate transfer belt. There has been widely known a method of superimposing the toner images of the respective colors on each other when the images are transferred onto the intermediate transfer belt, and after that, transferring the images from the intermediate transfer belt onto a sheet or other such transfer material.
In the color image forming apparatus, a specific photosensitive drum may not be used depending on a mode of color to be used. For example, in a monochrome mode for forming a monochrome image, the photosensitive drums of the respective colors of Y, M, and C are not used, and only the photosensitive drum of K is used. Meanwhile, in a full-color mode, all the photosensitive drums of Y, M, C, and K are used.
In Japanese Patent Application Laid-Open No. 2005-156776, there is proposed a configuration in which, in the monochrome mode, primary transfer rollers of the respective colors of Y, M, and C are moved so as to separate the photosensitive drums and the intermediate transfer belt from each other. By separating the photosensitive drums and the primary transfer rollers from each other so as to prevent the intermediate transfer belt from being brought into contact with the photosensitive drum, the photosensitive drums of the respective colors of Y, M, and C are inhibited from being used, to thereby produce an advantage that life of an intermediate transfer belt, the photosensitive drums of the respective colors of Y, M, and C, and other such member is extended.
In the technology described in Japanese Patent Application Laid-Open No. 2005-156776, it is required to switch a separated position of the primary transfer roller between a time of color image formation (full-color mode) and a time of monochrome image formation (monochrome mode) when the toner image is transferred onto the intermediate transfer belt. The separated position of the primary transfer roller refers to a position of the primary transfer roller in a state in which at least one primary transfer roller is separated from the photosensitive drum.
In this case, before starting the image formation on the photosensitive drum, it is required to match the position of the primary transfer roller and the mode for performing the image formation. That is, in the respective colors of Y, M, and C, it is required to bring the respective photosensitive drums and the intermediate transfer belt into a contact state in the full-color mode, and bring those components into a separated state in the monochrome mode.
When the mode of color to be used for performing the image formation and the position of the primary transfer roller do not match, an operation for the abutment and an operation for the separation are required, which causes downtime.
Therefore, it is desired to prevent an occurrence of such downtime or shorten the downtime even when the mode for performing the image formation and the position of, for example, the primary transfer roller do not match.
An image forming apparatus according to the present disclosure has an image forming mode in which an image is formed and a standby mode in which an image is not formed as states of the image forming apparatus, and has a color mode for forming a color image and a monochrome mode for forming a monochrome image as modes to be employed in a case where an image is formed in the image forming mode, the image forming apparatus includes: a first image bearing member configured to bear a toner image; a second image bearing member configured to bear a toner image; a belt member onto which the toner images borne on the first image bearing member and the second image bearing member are to be transferred; a first transfer member configured to transfer the toner image borne on the first image bearing member onto the belt member; a second transfer member configured to transfer the toner image borne on the second image bearing member onto the belt member; a first moving unit configured to move the first transfer member; and a controller configured to control the first moving unit to move the first transfer member such that: in the monochrome mode, the belt member is located at a first position at which the belt member is separated from the first image bearing member; in the color mode, the belt member is located at a second position at which the belt member is in contact with the first image bearing member; and in the standby mode, the first transfer member is located at a predetermined position between the first position and the second position, wherein the belt member is in contact with the second image bearing member in the image forming mode and the standby mode.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
Now, an embodiment of the present disclosure is described in detail with reference to the accompanying drawings. An image forming apparatus described below has, as states thereof, an image forming mode in which an image is formed and a standby mode in which an image is not formed. The image forming apparatus also has, as modes of color, a color mode for forming a color image and a monochrome mode for forming a monochrome image when an image is formed in the image forming mode. In the following embodiments, as an example of “color mode”, full-color mode, in which the colors of yellow, magenta, cyan, and black are used, is described. A position of a primary transfer roller (as primary transfer member) exhibited when the image forming apparatus is in the standby mode in which an image is not formed is referred to as “standby position”, and a position of the primary transfer roller exhibited when a monochrome image is formed in the monochrome mode is referred to as “monochrome position”. In the same manner, a position of the primary transfer roller exhibited when a color image is formed in the full-color mode is referred to as “fully abutted position”. In addition, a position of all the primary transfer rollers that have been separated from photosensitive drums is referred to as “fully separated position”.
<Schematic Configuration of Image Forming Apparatus>
The scanner section includes an original table 152, an original presence-or-absence sensor 151, an original conveying roller 112, a glass table 55, and an image sensor 233. An original is placed on the original table 152. The original presence-or-absence sensor 151 detects the presence or absence of the original on the original table 152. The original conveying roller 112 conveys originals placed on the original table 152 to a reading position one by one. The image sensor 233 optically reads the original conveyed to the reading position to generate an image signal. On the glass table 55, the user directly places an original without using the original table 152. The image sensor 233 can also optically read the original placed on the glass table 55 to generate an image signal.
The printer section includes an image forming unit 120, a laser scanner unit 103, an intermediate transfer unit 140, a secondary transfer roller 118 (as a secondary transfer member), a fixing device 170, and different kinds of rollers configured to convey a sheet on which an image is to be formed.
The image forming unit 120 includes photosensitive drums 101y, 101m, 101c, and 101k, which serve as image bearing members, and charge rollers 102y, 102m, 102c, and 102k. The image forming unit 120 also includes developing devices 104y, 104m, 104c, and 104k and drum cleaners 107y, 107m, 107c, and 107k.
The suffixes “y”, “m”, “c”, and “k” of the respective reference symbols represent parts corresponding to the colors of yellow, magenta, cyan, and black, respectively. For example, the image forming units 120(y, m, c, k) indicate the image forming unit 120y of yellow, the image forming unit 120m of magenta, the image forming unit 120c of cyan, and the image forming unit 120k of black. In the following description, unless each part is required to be particularly distinguished from other parts, the image forming units 120(y, m, c, k) may be referred to simply as “image forming unit 120”. The same applies to the photosensitive drums 101(y, m, c, k) and the other components.
The charge rollers 102(y, m, c, k) charge surfaces of the photosensitive drums 101(y, m, c, k). The developing devices 104(y, m, c, k) develop electrostatic latent images by causing toners to adhere to the photosensitive drums 101(y, m, c, k) corresponding thereto, respectively. A yellow toner image is formed and borne on the photosensitive drum 101y, and a magenta toner image is formed and borne on the photosensitive drum 101m. A cyan toner image is formed and borne on the photosensitive drum 101c, and a black toner image is formed and borne on the photosensitive drum 101k. The drum cleaner 107 removes the toner remaining on the photosensitive drum 101 corresponding thereto after the transferring onto an intermediate transfer belt 130.
The laser scanner units 103(y, m, c, k) emit light based on video signals obtained by digitally converting an image signal generated by the scanner section. The laser scanner units 103(y, m, c, k) include the laser scanner 103y, the laser scanner 103m, the laser scanner 103c, and the laser scanner 103k. The laser scanner 103y to the laser scanner 103k apply laser light corresponding to the video signals of yellow, magenta, cyan, and black to the corresponding photosensitive drum 101y to photosensitive drum 101k, respectively.
The intermediate transfer unit 140 includes the intermediate transfer belt 130, which is a belt member, and the primary transfer rollers 105(y, m, c, k). The primary transfer rollers 105(y, m, c, k) are provided so as to sandwich the intermediate transfer belt 130 between the primary transfer rollers 105(y, m, c, k) and the corresponding photosensitive drums 101(y, m, c, k), respectively. The primary transfer rollers 105(y, m, c, k) transfer the toner images of the corresponding colors formed on the corresponding photosensitive drums 101(y, m, c, k), respectively, to the intermediate transfer belt 130. The toner images of the respective colors are transferred onto the intermediate transfer belt 130 so as to be superimposed on each other, to thereby form a full-color toner image.
The secondary transfer roller 118 transfers the toner image, which has been transferred onto the intermediate transfer belt 130, onto a sheet. The sheet is conveyed to the secondary transfer roller 118 from a sheet feeding cassette 111 by a sheet feeding pickup roller 113, sheet feeding rollers 114, and registration rollers 116.
The fixing device 170 heats and pressurizes the sheet onto which the toner image has been transferred by the secondary transfer roller 118, to thereby fix the toner image on the sheet. This brings the image formation on the sheet to an end. The sheet on which the image has been formed is delivered from the fixing device 170 onto a delivery tray 132 by delivery rollers 139.
The UI 330 includes a key button, a display, and a touch panel to be operated by the user.
[Schematic Configuration of Image Forming Apparatus]
The CPU 301 is a CPU configured to perform system control on the image forming apparatus. The CPU 301 is connected to the ROM 302 to which a control program is written and the RAM 303 configured to store a variable to be used for control and image data read by the image sensor 233. In this example, the CPU 301 is connected to, for example, the ROM 302 through an address bus and a data bus. The CPU 301 is also connected to the timer 291 capable of counting time. The CPU 301 sets a time count value of the timer 291 and acquires a timer measurement value. The CPU 301 performs different kinds of processing by reading computer programs from the ROM 302 and using the RAM 303 as a work area to execute the computer programs.
The CPU 301 causes an original feeder controller 480 to drive the original conveying roller 112 in the image forming apparatus of
At a time of a copying operation of the image forming apparatus, the image signal controller 281 converts the analog image signal received from the image sensor 233 into a digital image signal, then performs each kind of processing thereon, converts the digital image signal into a video signal, and outputs the video signal to a printer controller 285. At a time of a printing operation, the image signal controller 281 performs different kinds of processing on the digital image signal input from a computer or other such external device 283 through an external I/F 282. Then, the image signal controller 281 converts the digital image signal into a video signal, and outputs the video signal to the printer controller 285.
The printer controller 285 instructs an image former 271 to form an image based on an instruction given by the CPU 301. The image former 271 drives the image forming unit 120 based on the input video signal. The printer controller 285 also causes a sheet conveyor 270 to feed a sheet and control conveyance thereof based on an instruction given by the CPU 301.
The UI 330 corresponds to the operating section illustrated in
[Basic Image Forming Operation of Image Forming Apparatus]
Next, with reference to
The CPU 301 controls the position of the primary transfer rollers 105 in the intermediate transfer unit 140 in accordance with the mode determined by the image signal controller 281, and also causes the image former 271 to control the image forming unit 120 for start preparation of the image forming operation.
The image forming units 120(y, m, c, k) include the photosensitive drums 101(y, m, c, k), the developing devices 104(y, m, c, k), the charge rollers 102(y, m, c, k), and the drum cleaners 107(y, m, c, k). The position control of the intermediate transfer unit 140 is described later in detail.
When the switching of an abutted state of the intermediate transfer unit 140 and the preparation for the image forming units 120(y, m, c, k) are completed, the CPU 301 causes the image former 271 to control each of the image forming units 120(y, m, c, k). With this control, the CPU 301 starts the image forming operation for the image data stored in the RAM 303. In each of the image forming units 120(y, m, c, k), after the surface of the photosensitive drum 101 is charged, the latent image is formed on the photosensitive drum 101 with laser light emitted from the laser scanner unit 103.
The latent image that has been formed is developed on the photosensitive drum 101 with the toner contained in the developing device. After that, a primary transfer voltage is applied to the toner image developed on the photosensitive drum 101 in each of the monochrome primary transfer roller 105k and the color primary transfer rollers 105(y, m, c), and the toner image is transferred onto the intermediate transfer belt 130. The toner image transferred onto the intermediate transfer belt 130 reaches the secondary transfer roller 118 in accordance with the rotation of the intermediate transfer belt 130.
The CPU 301 causes the sheet conveyor 270 to drive a conveyance motor (not shown) so as to have a sheet reach the secondary transfer roller 118 in time for a timing at which the toner image reaches the secondary transfer roller 118. The conveyance motor is a drive source for the sheet feeding pickup roller 113, the sheet feeding rollers 114, the registration rollers 116, and the delivery rollers 139. In response thereto, the sheet feeding pickup roller 113 is driven to rotate, and sheets are fed and conveyed from the sheet feeding cassette 111 one by one. In the above-mentioned manner, a secondary transfer voltage is applied to the sheet and the toner image that have reached the secondary transfer roller 118, to thereby transfer the toner image onto the sheet.
The sheet onto which the toner image has been transferred is conveyed to the fixing device 170. As described above, in the fixing device 170, the toner image on the sheet is heated to be fixed to the sheet. After that, the CPU 301 delivers the sheet onto the delivery tray 132 using the delivery rollers 139 controlled by a sheet feeder/conveyor. When the printing operation is completed, the CPU 301 switches an abutted/separated state of the intermediate transfer unit 140 to the abutted state during standby. The abutted state during standby is described later in detail.
The above-mentioned basic image forming operation is merely an example, and the present disclosure is not limited to the above-mentioned configuration.
[Description of Abutment and Separation for Primary Transfer]
Next, a description is given of a mechanism for controlling the abutment and separation of the intermediate transfer belt 130 and the photosensitive drum 101 (hereinafter referred to as “abutment/separation mechanism”) in this embodiment.
The photosensitive drums 101(y, m, c, k) are driven by drum motors of yellow, magenta, cyan, and black (not shown), respectively.
As illustrated in
The primary transfer rollers 105(y, m, c) are separated from the photosensitive drums 101(y, m, c), and thus a drum motor Y, a drum motor M, and a drum motor C that are configured to drive those components are also brought to a stop.
In
Referring back to
In this embodiment, the distance between the primary transfer rollers 105(y, m, c) and the photosensitive drums 101(y, m, c) at the standby position is set as the standby separation distance DAcs for each of the colors y, m, c, as shown in
However, other methods may be used to measure the distance between the primary transfer roller 105 and the photosensitive drum 101. For example, the distance between the primary transfer roller 105m and the photosensitive drum 101m for magenta or between the primary transfer roller 105c and the photosensitive drum 101c for cyan may be measured.
This embodiment is further configured to move the positions of the primary transfer rollers 105(y, m, c, k) without changing the positions of the photosensitive drums 101(y, m, c, k). However, it is also possible to change the positions of the photosensitive drums 101(y, m, c, k) without changing the positions of the primary transfer rollers 105(y, m, c, k). In another case, the positions of both the primary transfer rollers 105(y, m, c, k) and the photosensitive drums 101(y, m, c, k) may be changed to set relative positions therebetween so as to achieve DAcs and Dbk described above.
(Description of Abutment and Separation Configuration for Primary Transfer)
Next, with reference to
First, with reference to
The slider 402, the arm bearings 403(y, m, c, k), and the lift arms 404(y, m, c, k) are all capable of moving in the horizontal direction in
Meanwhile, the positions of slider arm support portions 405(y, m, c, k) illustrated in
When the slider 402 moves in the rightward direction from the state of
Meanwhile, even when the slider 402 moves in parallel in the horizontal direction, the arm bearing 403k does not move until the arm bearing 403k is brought into contact with an end portion of the slit 406, and hence the lift arm 404k does not rotate as well.
In
Next, a description is given of an operation for rotating the cam gear 502. The gear shaft 501 illustrated in
When the bearings 210(y, m, c) are raised, the primary transfer rollers 105(y, m, c) of yellow, magenta, and cyan are pushed upward. This situation corresponds to the standby position described with reference to
In this manner, the abutment/separation motor 504 and the slider 402 operate as a moving unit configured to move the primary transfer rollers 105(y, m, c) and the primary transfer roller 105k. Therefore, in the first embodiment, the primary transfer rollers 105(y, m, c) and the primary transfer roller 105k are moved by one moving unit. However, there may be employed other configurations of using separate moving units to move the primary transfer rollers 105(y, m, c) and the primary transfer roller 105k.
Therefore, in the state of
Meanwhile, when the abutment/separation motor is driven to rotate reversely, the cam gear 502 is caused to rotate in a direction reverse to the direction C. That is, when the abutment/separation motor is driven to rotate reversely from the state of
The image forming apparatus includes a sensor 325 configured to detect that the primary transfer roller 105 is located at the standby position. The sensor 325 includes a light emitter 326 and a light receiver 327 configured to receive a light beam from the light emitter 326. The sensor 325 is provided so that, when the cam gear 502 rotates to be located at a position corresponding to the standby position of
Therefore, in
The configuration for moving the primary transfer rollers 105(y, m, c, k) up and down and the configuration for detecting the standby position described above are merely examples, and freely-selected methods can be used to perform the moving up and down and the detection.
Next, with reference to
As described with reference to
In
C2 corresponds to the rotation angle of the cam gear 502 at the standby position illustrated in
In
As described with reference to
In this case, angular velocity in the rotation in the direction C based on the above-mentioned driving of the abutment/separation motor is constant, and hence the moving speed of the slide lever 401 in the direction A gradually increases as the cam gear 502 rotates from C1 to C2. As shown in
In addition, as shown in
In the example of
When the instruction to start the printing operation is input to the image forming apparatus, the CPU 301 switches the positions of the primary transfer rollers 105(y, m, c, k) depending on the mode to perform a preparation operation of image formation for the image forming units 120(y, m, c, k).
The CPU 301 starts the image forming operation after both the switching of the position of the primary transfer roller 105 and the preparation operation are completed. In this embodiment, the time T2 required until the cam gear 502 has rotated from C2 to C3 is set equal to the preparation operation time Tstartup for the image forming units 120(y, m, c, k). To that end, the standby position C2 is adjusted so as to satisfy T2=Tstartup.
Therefore, when the primary transfer rollers 105(y, m, c, k) are at the standby position, regarding a print job for a monochrome image, the time T2 for switching from the standby position to the monochrome position is equal to the preparation operation time Tstartup, which causes no downtime.
When the primary transfer rollers 105(y, m, c, k) are at the standby position, regarding a full-color print job, the time T1 for switching from the standby position to the fully abutted position is longer than the preparation operation time Tstartup. Therefore, in this case, there occurs downtime Tdown=T1−Tstartup. However, as described with reference to
Note that, in this embodiment, the standby position C2 is set so as to satisfy T1>T2, but relationship in magnitude of T1 and T2 may be reversed as T1<T2. In another case, T1=T2 may be set.
In this embodiment, T3=T1+T2>Tstartup is established, and hence it is not possible to simultaneously satisfy Tstartup≥T1 and Tstartup≥T2. However, when a print job for a color image is more often received by the image forming apparatus than a print job for a monochrome image, T1 may be set equal to or smaller than a preparation operation period (T1≤Tstartup) to cause downtime at a time of color image formation to become 0. In this case, downtime (T2−Tstartup) occurs at the time of the monochrome image formation, but the monochrome image formation is requested less often, and hence an occurrence frequency of the downtime can be suppressed to a low level.
In the same manner, when the print job for a monochrome image is more often received by the image forming apparatus than the print job for a color image, T2≤Tstartup may be set to cause downtime at the time of the monochrome image formation to become 0. In this case, downtime (T1−Tstartup) occurs at the time of the color image formation, but the color image formation is requested less often, and hence the occurrence frequency of the downtime can be suppressed to a low level.
In particular, the CPU 301 can achieve such a configuration as described above by including a function of calculating the occurrence frequencies of the monochrome mode and the full-color mode. In this case, the CPU 301 determines whether to set T1≤Tstartup or T2≤Tstartup depending on the detected occurrence frequency.
It is also possible to set both T1 and T2 smaller than Tstartup by, for example, raising a rotation speed of the abutment/separation motor to decrease T3. In this case, the downtime Tdown due to the switching of the positions of the primary transfer rollers 105(y, m, c, k) can be set to 0 irrespective of the mode. The above-mentioned times T1, T2, and Tstartup are merely examples, and the present disclosure is not limited to the above-mentioned configuration.
In this embodiment, in the operation of the image forming apparatus, the primary transfer rollers 105(y, m, c, k) are moved to the standby position after the image formation is completed in both the full-color mode and the monochrome mode. When the image formation is performed in the full-color mode after the image forming apparatus receives a print job and the mode is determined, the abutment/separation motor is driven in the reverse direction before the image formation is started. With this driving, the primary transfer rollers 105(y, m, c, k) are moved from the standby position to the fully abutted position. Meanwhile, when the image formation is performed in the monochrome mode, the abutment/separation motor is driven in the forward direction before the image formation is started. With this driving, the primary transfer rollers 105(y, m, c, k) are moved from the standby position to the monochrome position.
In the related art, there is a case in which, when the image forming apparatus is in a state of being in the standby mode, the primary transfer rollers 105(y, m, c, k) are located at the fully abutted position for forming a color image. When the image forming apparatus receives a print job for forming a monochrome image in this state, the positions of the primary transfer rollers 105(y, m, c, k) are required to be switched from the fully abutted position to the monochrome position. In the same manner, there is a case in which, when the image forming apparatus is in the state of being in the standby mode, the primary transfer rollers 105(y, m, c, k) may be located at the monochrome position for forming a monochrome image. When the image forming apparatus receives a print job for forming a color image in this state, the positions of the primary transfer rollers 105(y, m, c, k) are required to be switched from the monochrome position to the fully abutted position. In any one of the cases, the switching of the positions of the primary transfer rollers 105(y, m, c, k) requires a long time equivalent to T3 of
Meanwhile, as described with reference to
(Description of Flow of Execution)
When the image forming apparatus is powered on (or has recovered from a power-saving state), the CPU 301 moves the positions of the primary transfer rollers 105(y, m, c, k) from the fully separated position to the standby position (Step S1201). On this occasion, as described with reference to
After the primary transfer rollers 105(y, m, c, k) have moved to the standby position, the CPU 301 clears the timer 291 illustrated in
Next, the CPU 301 determines whether or not the primary transfer rollers 105(y, m, c, k) are at the fully separated position (Step S1203). When the primary transfer rollers 105(y, m, c, k) are not at the fully separated position (N in Step S1203), the CPU 301 determines whether or not a timeout has been achieved, that is, whether or not the timer value is equal to or larger than the value of a timeout tout (Step S1204). When the determination results in N (N in Step S1204), the CPU 301 executes Step S1206 described later. When the determination results in Y (Y in Step S1204), the CPU 301 moves the primary transfer rollers 105(y, m, c, k) to the fully separated position (Step S1205), and executes Step S1203 again. In this embodiment, 8 hours is set as the timeout tout to shift to primary-transfer full separation. The value of the timeout tout to shift to the primary-transfer full separation is merely an exemplary value, and any value can be freely set.
When the primary transfer rollers 105(y, m, c, k) are at the fully separated position (Y in Step S1203), the CPU 301 determines whether or not the image forming apparatus has received a print job (referred to simply as “job” in
When the mode has not been determined (N in Step S1207), the CPU 301 executes Step S1207 again. When the mode has been determined (Y in Step S1207), the CPU 301 determines whether or not the mode is the full-color mode (Step S1208). When the mode is the full-color mode (Y in Step S1208), the CPU 301 starts the preparation operation for the image forming units 120(y, m, c, k) (Step S1209). For example, the drum motor y (not shown), the drum motor m (not shown), the drum motor c (not shown), and a drum motor k (not shown) are started to be driven at a target speed for image formation.
When the preparation operation for the image forming units 120(y, m, c, k) is started or after the preparation operation is started, the CPU 301 moves the primary transfer rollers 105(y, m, c, k) to the fully abutted position corresponding to the full-color mode (Step S1210). After that, the CPU 301 executes Step S1213 described later.
The image forming apparatus according to this embodiment has two modes, namely, the full-color mode and the monochrome mode. Therefore, when it is determined in Step S1208 that the mode is not the full-color mode (N in Step S1208), the CPU 301 determines that the mode is the monochrome mode. After that, the CPU 301 starts the preparation operation for the image forming unit 120k (Step S1211), moves the primary transfer rollers 105(y, m, c, k) to the monochrome position (Step S1212), and executes Step S1213 described later.
In this manner, after performing the preparation operation for the image forming units 120(y, m, c, k) and moving the primary transfer rollers 105(y, m, c, k) to the positions corresponding to the mode, the CPU 301 executes the print job to execute the image forming processing (Step S1213). The CPU 301 determines whether or not the print job has been finished (Step S1214), and when the print job has not been finished (N in Step S1214), the CPU 301 executes Step S1213. When the print job has been finished, the CPU 301 stops driving the image forming units 120(y, m, c, k) (Step S1215), and determines whether or not a power-off command or a command for a shift to the power-saving mode has been input (Step S1216).
When the command has not been input (N in Step S1216), the CPU 301 executes Step S1201 again. When the command has been input (Y in Step S1216), the CPU 301 moves the primary transfer rollers 105(y, m, c, k) to the fully separated position to bring the processing to an end.
As described above, according to this embodiment, during a predetermined period required after the image forming processing is executed until the subsequent image forming processing is executed, the positions of the primary transfer rollers 105(y, m, c, k) are set to the standby position. At this standby position, at least a part of the primary transfer rollers 105(y, m, c, k) is located between the position in the monochrome mode and the position in the full-color mode.
With this configuration, it is possible to eliminate or shorten the downtime for moving the positions of the primary transfer rollers 105(y, m, c, k) to the position corresponding to the print job at the time of the execution of the print job. Accordingly, it is possible to reduce a time required for moving the positions of the primary transfer rollers 105(y, m, c, k) to the positions corresponding to the mode before starting the image formation, to be able to shorten a first copy time.
As has been described above, according to this embodiment, it is possible to inhibit an occurrence of the downtime or shorten the downtime even when the position of, for example, the primary transfer roller does not match the mode for performing the image formation.
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 structures and functions.
This application claims the benefit of Japanese Patent Application No. 2018-045231, filed Mar. 13, 2018, which is hereby incorporated by reference herein in its entirety.
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