Field of the Invention
The present invention relates to an image forming apparatus, such as a copying machine and a printer, which is configured to perform image formation on a recording material through an electrophotographic method, and more particularly, to a print preparation operation of the image forming apparatus.
Description of the Related Art
In a color image forming apparatus employing an electrophotographic method, a toner image formed on a photosensitive drum is transferred onto an intermediate transfer belt by a primary transfer roller arranged opposed to the photosensitive drum, and this process is repeated for each of a plurality of toner colors. With this, a full color toner image is formed on the intermediate transfer belt. A color image forming apparatus of a so-called tandem type has become the mainstream. In the image forming apparatus of the tandem type, four photosensitive drums, which are configured to form toner images of yellow, magenta, cyan, and black, respectively, are arranged in a rotating direction of the intermediate transfer belt, and the toner images formed on the photosensitive drums are sequentially transferred onto the intermediate transfer belt. The color image forming apparatus have been demanded to shorten a first print output time (hereinafter also referred to as “FPOT”) and a first copy output time (hereinafter also referred to as “FCOT”). The FPOT is a period of time from input of a print instruction to output of a first recording material. The FCOT is a period of time from pressing of a copy key to output of a first recording material as a copy of an original. As a method of shortening the time, there has been widely used a technology of performing a print preparation operation before input of an instruction to start printing or an instruction to start copying.
In U.S. Pat. No. 5,107,279, there is proposed a print preparation method. In the proposed print preparation method, when an operation from which a print instruction is predicted, such as an operation to an operation unit of an image forming apparatus or placement of an original to an original reading device, is detected, rotation of a scanner motor is started prior to the print instruction. In general, the scanner motor, which is configured to drive a rotary polygon mirror of an optical scanning device, requires longer time from the start of rotation to stabilization of the rotational speed as compared to other motors necessary for image formation such as a drive motor configured to drive the photosensitive drum. Thus, rotation of the scanner motor is started before the print instruction is received. Such a configuration is advantageous in that printing can be started without a standby time from the input of the print instruction to the stabilization of the rotation of the scanner motor.
In the color image forming apparatus, selection can be made from two color modes including a full color mode of performing image formation with a full color image and a monochromatic mode of performing image formation with a black and white image. In the related art, a print preparation operation control is not switched in accordance with the color mode setting, with the result that the print preparation operation control is not optimum. In view of this, the print preparation operation control can be optimized through switching of the print preparation operation control in accordance with color mode setting which is set through the operation unit. However, for example, there is a problem that, when color toner is used up, and only the monochromatic printing can be performed, the print preparation operation performed in accordance with the color mode setting of the full color mode may disadvantageously cause an unnecessary print preparation operation control to be performed.
The present invention which has been made under such a circumstance has an object to perform a print preparation operation control in accordance with a state of an image forming portion.
In order to solve the above-mentioned problem, according to one embodiment of the present invention, there is provided an image forming apparatus, including: an image forming unit including a plurality of image forming stations configured to respectively perform image formation of different colors, the image forming unit being configured to perform image formation to a recording sheet in any one of a first mode, in which image formation is performed through use of the plurality of image forming stations, and a second mode, in which image formation is performed through use of a predetermined image forming station among the plurality of image forming stations; an operation unit configured to allow input of color mode information for setting to perform image formation in the first mode or to perform image formation in the second mode; and a controller configured to: i) control the image forming unit to perform a preparation operation for image formation in accordance with the color mode information before image formation when detecting an operation from which a start instruction of image formation is predicted; ii) set a restricted operation state in which the controller prohibits the image formation in the first mode and permits the image formation in the second mode when any one image forming station, except for the predetermined image forming station, among the plurality of image forming stations is incapable of performing image formation, and the predetermined image forming station is capable of performing image formation; and iii) prevent the image forming unit from performing the preparation operation when a performing the image formation in the first mode is set as the color mode information, and the restricted operation state is set.
According to the present invention, the print preparation operation control in accordance with the state of the image forming portion can be performed.
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 invention is described in detail with reference to the drawings.
<Schematic Configuration of Image Forming System>
[Schematic Configuration of Image Forming Apparatus]
A control portion 300 illustrated in
During a copy operation, the image signal control portion 281 performs various processes after the analog image signal input from the image sensor 233 is converted into a digital image signal. After converting the digital image signal that has been subjected to the various processes into a video signal, the image signal control portion 281 outputs the video signal to a printer control portion 285. In the copy operation, an operation of reading the original with the image sensor 233 and performing a print operation based on the read data is performed. Further, during the print operation performed in response to an instruction from outside, the image signal control portion 281 first performs the various processes on the digital image signal that has been input from an external computer 283 through an external interface (I/F) 282. Then, the image signal control portion 281 converts the digital image signal that has been subjected to the various processes into the video signal, and outputs the video signal to the printer control portion 285.
In accordance with an instruction from the CPU 301, the printer control portion 285 controls image formation by the image forming portion 271, and controls feed and conveyance of a sheet being a recording material by a sheet conveying portion 270. The image forming portion 271 includes an image forming unit 120, an intermediate transfer belt unit 140, a laser scanner unit 103, and a fixing device 170, which are illustrated in
An operation unit 330 is used to input color mode information for image formation (full color mode (first instruction information), monochromatic mode (second instruction information), and automatic (third instruction information)), display a state of the image forming apparatus, and input an instruction such as an instruction to start copying. The selected color mode information is stored in the RAM 303.
[Basic Image Forming Operation of Image Forming Apparatus]
With reference to
Next, when receiving the instruction to start the print operation from the operating portion 330, the CPU 301 starts an operation of reading an image of the original via the original feeder control portion 480. The CPU 301 drives the original conveying roller 112 to convey the original from the original table 152 onto a platen glass plate, and irradiates toward the platen glass plate with light of a lamp (not shown). Reflected light from the original is guided to the image sensor 233 through a mirror. Image data of the original that is read by the image sensor 233 is output to the image signal control portion 281. The reading of the original is continued until the reading of the original on the original pressure plate glass plate 55 is completed or until reading of an image of a final original detected by the original presence sensor 151 is completed.
After the switching of the abutment state of the intermediate transfer belt unit 140 is completed, the CPU 301 controls the image forming unit 120 through the image forming portion 271 and starts an image forming operation for image data stored in the RAM 303. The image forming unit 120 includes, for respective colors of toner, an image forming station 120y for yellow, an image forming station 120m for magenta, an image forming station 120c for cyan, and an image forming station 120k for black. The suffixes y, m, c, and k representing colors of toner are hereinafter omitted unless otherwise needed. Each laser scanner unit 103 includes a laser light source 131 configured to emit laser light, a rotary polygon mirror 133 configured to deflect the laser light emitted from the laser light source 131, and the scanner motor 274 being a drive portion configured to control rotation of the rotary polygon mirror 133. Further, each laser scanner unit 103 includes a mirror (not shown) configured to reflect the laser light, which is deflected by the rotary polygon mirror 133, to the photosensitive drum 101. The laser light source 131 emits the laser light in accordance with a video signal. In
The image forming unit 120 includes photosensitive drums 101 respectively being a photosensitive member, developing devices 104, charging rollers 102, and photosensitive drum cleaners 107. In the image forming unit 120, surfaces of the photosensitive drums 101 respectively rotated in a direction indicated by the arrow in
The CPU 301 drives the conveyance motor 272 through the sheet conveying portion 270 so as to match a timing of arrival of the toner image on the intermediate transfer belt 130 to the secondary transfer portion 118. The conveyance motor 272 drives a sheet feeding pickup roller 113, sheet feeding rollers 114, registration rollers 116, and delivery rollers 139. With this, the sheet feeding pickup roller 113 is driven to rotate so that sheets are fed and conveyed from the sheet feeding cassette 111 one after another. Then, through application of a secondary transfer voltage at the secondary transfer portion 118, the toner image on the intermediate transfer belt 130 is transferred onto the conveyed sheet. The image forming apparatus of
The sheet onto which the toner image has been transferred in the secondary transfer portion 118 is conveyed to the fixing device 170. In the fixing device 170, the unfixed toner image on the sheet is heated and pressurized so as to be fixed onto the sheet. Thereafter, the CPU 301 delivers the sheet to a delivery tray 132 by the delivery rollers 139 that are controlled by the sheet conveying portion 270. The above-mentioned image forming operation is an example, and the present invention is not limited to the above-mentioned configuration. In this embodiment, the laser scanner unit 103 is provided for each photosensitive drum 101. That is, one laser scanner unit 103 is provided for one photosensitive drum 101. For example, one laser scanner unit 103 may perform light exposure for two photosensitive drums 101 or four photosensitive drums 101.
[Full Color Print Restricted Operation]
With reference to
In S1202, the CPU 301 determines whether or not the color drums have reached the lifetime limit. The color drums correspond to the photosensitive drum 101y of the image forming station 120y for yellow, the photosensitive drum 101m of the image forming station 120m for magenta, and the photosensitive drum 101c of the image forming station 120c for cyan. When any one of the photosensitive drums 101y, 101m, and 101c has reached the lifetime limit, the CPU 301 determines that the color drum has reached the lifetime limit, and proceeds the processing to S1207. When no color drum has reached the lifetime limit, the CPU 301 proceeds the processing to S1203. The CPU 301 stores, in the RAM 303, information related to the amounts of use of the photosensitive drums 101y, 101m, 101c, and 101k from the start of use to a current time. A cumulative rotation time (amount of rotation) of the photosensitive drum is used as the amount of use. Based on this information, the CPU 301 determines whether or not the amount of use of the color drum has reached a predetermined amount to reach the lifetime limit. The lifetime limit of the photosensitive drum may be determined through another method. For example, the CPU 301 may determine the lifetime limit when a current flowing to the photosensitive drum, which is measured by a current detection circuit of the image forming portion, is equal to or less than a predetermined value.
In S1203, the CPU 301 determines whether or not the color laser scanner units have a failure. The color laser scanner units correspond to the layer scanner unit 103y configured to irradiate laser light to the photosensitive drum 101y of the image forming station 120y for yellow, the laser scanner unit 103m configured to irradiate laser light to the photosensitive drum 101m of the image forming station 120m for magenta, and the laser scanner unit 103c configured to irradiate laser light to the photosensitive drum 101c of the image forming station 120c for cyan. When there is a laser scanner unit 103 having a failure in the laser scanner units 103y, 103m, and 103c, the CPU 301 determines that the color laser scanner unit has a failure, and proceeds the processing to S1207. On the contrary, when no laser scanner unit 103 has a failure, the CPU 301 determines that no color laser scanner unit has a failure, and proceeds the processing to S1204. When the motor does not rotate at the time of driving, the scanner motor 274 outputs a lock signal. The CPU 301 detects a failure in the color laser scanner units based on whether or not each the scanner motor for the laser scanner units 103y, 103m, 103c, and 103k outputs the lock signals.
In S1204, the CPU 301 determines whether or not the color high-voltage units have a failure. The color high-voltage units correspond to high-voltage units (for yellow, magenta, and cyan) 275 configured to apply the primary transfer voltages to the primary transfer roller 105y of the image forming station 120y for yellow, the primary transfer roller 105m of the image forming station 120m for magenta, and the primary transfer roller 105c of the image forming station 120c for cyan, respectively. When there is a high-voltage unit having a failure in the high-voltage units (for yellow, magenta, and cyan) 275, the CPU 301 determines that the high-voltage unit has a failure, and proceeds the processing to S1207. On the contrary, when no high-voltage unit has a failure, the CPU 301 determines that no high-voltage unit has a failure, and proceeds the processing to S1205. The CPU 301 detects a failure in each color high-voltage unit based on current value detected at the time of application of the primary transfer voltage by a detecting portion configured to detect a current flowing to each primary transfer roller 105.
In S1205, the CPU 301 determines whether or not the color drum motors have a failure. The color drum motors correspond to the drum motor y configured to drive the photosensitive drum 101y of the image forming station 120y for yellow, the drum motor m configured to drive the photosensitive drum 101m of the image forming station 120m for magenta, and the drum motor c configured to drive the photosensitive drum 101c of the image forming station 120c for cyan. When there is a drum motor having a failure in the drum motors y, m, and c, the CPU 301 determines that the color drum motor has a failure, and proceeds the processing to S1207. On the contrary, when no drum motor has a failure, the CPU 301 determines that no color drum motor has a failure, and proceeds the processing to S1206.
In S1206, the CPU 301 stores, in the RAM 303, information indicating that the print restricted operation is not necessary, and terminates the processing. In S1207, the CPU 301 stores, in the RAM 303, information indicating that the print restricted operation is necessary, and terminates the processing. The components subjected to the above-mentioned print restricted operation are examples, and the present invention is not limited to the configuration described above.
<Control for Image Forming Apparatus in accordance with Color Mode>
[Setting of Color Mode]
Setting can be performed through the “FULL COLOR” key 321 and the “AUTOMATIC” key 323 even under the print restricted operation state in which the print operation cannot be performed in the full color mode. This is because, when the setting of the color mode is not permitted during the print restricted operation, processing of reading a color original cannot be performed in a case where the original scanning operation is to be performed through an original reading device (reader) being an input unit.
The CPU 301 can obtain a set value which is set through the operation unit 330, and the set value is stored in the RAM 303. Further, when the operation to the operation unit 330 is detected, or when the placement of an original on the original table 152 is detected by the original presence sensor 151, the CPU 301 performs the print preparation operation control in accordance with color mode setting stored in the RAM 303. Further, also when completion of initialization processing, which is performed at the time of power-on or restoration from the power saving mode, is detected, the CPU 301 performs the print preparation operation control in accordance with the color mode setting stored in the RAM 303. In this embodiment, the color mode is set through operation to the color mode setting keys through the operation unit 330. However, for example, the color mode setting may be input from the external computer 283 through the external I/F 282.
In this embodiment, as the print preparation operation, the temperature of the fixing device 170 is shifted to a predetermined temperature in accordance with the color mode setting, and the abutment and separation states of the intermediate transfer belt unit 140 are switched in accordance with the color mode setting. Details thereof are described later.
[Switching Control for Abutment and Separation Mechanism in Accordance with Color Mode]
Description is made of the abutment and separation mechanism of this embodiment being a switching unit, which is configured to switch the abutment and separation states of the intermediate transfer belt 130 and the photosensitive drum 101 in the full color mode and the monochromatic mode.
(Description of Configurations of Photosensitive Drum and Intermediate Transfer Belt)
When the monochromatic mode is set as the color mode, image formation using only the black toner is performed. Thus, the photosensitive drum 101k for black and the primary transfer roller 105k opposed thereto are brought into abutment against each other through intermediation of the intermediate transfer belt 130. Other primary transfer rollers 105y, 105m, and 105c are separated from the intermediate transfer belt 130 and the opposed photosensitive drums 101y, 101m, and 101c. The drum motors, which are configured to drive the photosensitive drums 101y, 101m, and 101c being separated, are stopped. As illustrated in
(Configuration of Abutment and Separation Switching Mechanism and Control Therefor)
Next, with reference to
The abutment and separation mechanism 400 is described with reference to
Description is made of an operation which is performed when an abutment and separation motor (not shown) configured to drive the abutment and separation mechanism 400 is driven. Through driving of the abutment and separation motor (not shown), the shaft 501 illustrated in
When the abutment and separation motor is driven from the state of
When the color mode is in the monochromatic mode, the abutment and separation mechanism 400 is set to the separation mode, thereby being capable of reducing abrasion of the surfaces of the photosensitive drums 101y, 101m, and 101c due to friction with the intermediate transfer belt 130. With this, as compared to the case of not being separated, the lifetime limit of the photosensitive drums 101y, 101m, and 101c can be extended. Further, along with the separation, the drum motors (not shown) configured to drive the photosensitive drums 101y, 101m, and 101c can also be stopped, thereby being capable of achieving power saving.
At the time of print standby, the image forming apparatus according to this embodiment is set to standby under a state in which the intermediate transfer belt unit 140 is separated (state in the separation mode). Thus, when the image formation is completed, or when the print preparation operation is performed but timeout occurs due to no input of a job for a predetermined period of time, the state is shifted to the state of the separation mode. Therefore, when the image formation is to be performed in the full color mode, it is necessary to shift the intermediate transfer belt unit 140 to the state of the abutment mode before starting the image formation. In this embodiment, the intermediate transfer belt unit 140 is shifted to the abutment mode or to the separation mode during the print preparation operation prior to the print operation. With this, the time for switching of the abutment and separation modes before the start of the image formation is reduced, thereby being capable of shortening the first copy output time.
Even when the abutment and separation state at the time of print standby is any one of the state in the separation mode or the state of retaining the state in the abutment mode for the image formation, time for switching the abutment and separation modes is required before the print operation is to be performed in a different mode. In this embodiment, the abutment and separation modes are switched prior to the print operation, and it is not limited to the abutment and separation states at the time of print standby.
[Adjustment Control for Temperature of Fixing Device]
Description is made of an adjustment control for a fixing temperature of the fixing device 170 in the full color mode and in the monochromatic mode in this embodiment.
(Configuration of Fixing Device)
The fixing film 6 forms a fixing nip portion with the pressure roller 9. The heater 1 is arranged to heat the recording material P which passes through the fixing nip portion. The heater 1 receives supply of power at both ends thereof in the longitudinal direction (direction perpendicular to the drawing sheet of
(Fixing Temperature Adjustment Control During Print Preparation Operation)
A temperature adjustment control for the fixing device 170 during the print preparation operation is described with reference to
With reference to
Description is made of the temperature adjustment for the fixing device 170 in the case where the color mode set through the operation unit 330 is the full color mode. At the time T1 of starting the print preparation operation, the CPU 301 performs supply of power of 1,000 W to the heater 1 until the detected temperature of the heater 1 by the thermistor 5 reaches 80° C. being the print preparation temperature in the case of the full color mode. Then, at the time T2, when the detected temperature by the thermistor 5 becomes equal to or higher than 80° C. being the print preparation temperature, the CPU 301 switches the supply of power to the heater 1 from 1,000 W to 300 W so that the detected temperature by the thermistor 5 is maintained at 80° C. being the print preparation temperature. The time T2 at which the detected temperature by the thermistor 5 becomes equal to or higher than 80° C. being the print preparation temperature is changed in accordance with the detected temperature by the thermistor 5 at the time T1.
Next, from the time T3 of starting the print operation, the CPU 301 performs the supply of power of 1,000 W to the heater 1 until the detected temperature of the heater 1 by the thermistor 5 reaches 150° C. being the print temperature of fixing the unfixed toner image on the recording material P. At the time T4 at which the detected temperature by the thermistor 5 reaches 150° C. being the print temperature, and the recording material P having the unfixed toner image formed thereon arrives at the fixing device 170, the CPU 301 switches the supply of power to the heater 1 from 1,000 W to 600 W. That is, the CPU 301 switches the supply of power to the heater 1 from 1,000 W to 600 W so that the detected temperature by the thermistor 5 is maintained at 150° C. being the print temperature, thereby fixing the unfixed toner image T on the recording material P.
Description is made of the temperature adjustment for the fixing device 170 in the case where the color mode is the monochromatic mode, or in the case where the color mode is an automatic determination mode of setting the full color mode or the monochromatic mode based on whether or not an image of an original read by the image sensor 233 is a monochromatic image (based on property of an image). From the time T1 of starting the print preparation operation, the CPU 301 performs supply of power of 1,000 W to the heater 1 until the detected temperature of the heater 1 by the thermistor 5 reaches 120° C. being the print preparation temperature for the case of the monochromatic mode. Then, at the time T2m, when the detected temperature by the thermistor 5 is equal to or higher than 120° C. being the print preparation temperature, the CPU 301 switches the supply of power to the heater 1 from 1,000 W to 400 W so that the detected temperature by the thermistor 5 is maintained at 120° C. being the print preparation temperature. The time T2m at which the detected temperature by the thermistor 5 becomes equal to or higher than 120° C. being the print preparation temperature is changed in accordance with the detected temperature by the thermistor 5 at the time t1.
Next, at the time T3 of starting the print operation, the CPU 301 performs supply of power of 1,000 W to the heater 1 until the detected temperature of the heater by the thermistor 5 reaches 150° C. being the print temperature of fixing the unfixed toner image on the recording material P. At the time T4m at which the detected temperature by the thermistor 5 reaches 150° C. being the print temperature and at which the recording material P having the unfixed toner image formed thereon arrives at the fixing device 170, the CPU 301 switches the supply of power to the heater 1 from 1,000 W to 600 W. That is, the CPU 301 switches the supply of power to the heater 1 from 1,000 W to 600 W so that the detected temperature by the thermistor 5 is maintained at 150° C. being the print temperature, thereby fixing the unfixed toner image T on the recording material P.
In order to fix the unfixed toner image T on the recording material P, the print preparation temperature is set so that the detected temperature of the heater 1 by the thermistor 5 becomes equal to or higher than 150° C. at the time T4 at which the recording material P arrives at the fixing device 170. As the print preparation temperature is set higher, the temperature of the heater 1 can reach 150° C. being the print temperature earlier after the start of the print operation. However, as the print preparation temperature is set higher, more power needs to be supplied to maintain the heater 1 at the print preparation temperature, which is not efficient in terms of power saving. Therefore, in this embodiment, in accordance with the color mode set through the operation unit 330, the setting of the print preparation temperature is different between the case where the color mode is the full color mode and the case where the color mode is the monochromatic mode. With this, the temperature of the fixing device 170 reaches 150° C. being the print temperature at the time T4 (or time T4m), thereby being capable of shortening the first copy output time, which is the time required to output a first copy, and achieving power saving.
Description is made of a difference in setting of the print preparation temperature between the case where the color mode is the full color mode and the case where the color mode is the monochromatic mode.
Therefore, a time period of supplying power to the heater 1 from the start of the image formation by the image forming unit 120 to the arrival of the recording material P at the fixing device 170 is longer in the full color mode than the monochromatic mode. The print temperature of the fixing device 170 is equal in the monochromatic mode and the full color mode. Therefore, the print preparation temperature being the temperature of the fixing device 170 at the time of starting the print operation can be set lower in the case of the full color mode than the case of the monochromatic mode. As compared to the case of not switching the print preparation temperature in accordance with the color mode, in this embodiment, the print preparation temperature can be set lower in the case where the color mode is the full color mode. With this, the supply of power for maintaining the print preparation temperature can be set smaller, thereby being effective in terms of power saving. The print preparation temperature and the supply of power are set to fixed values in this embodiment, but may be changed in accordance with, for example, an environmental temperature or a power supply voltage.
(Control for Abutment and Separation Mechanism During Print Preparation Operation)
Description is made of a control for the abutment and separation mechanism 400 during the print preparation operation. In this embodiment, the state of the abutment and separation mechanism 400 is switched during the print preparation operation in accordance with the color mode setting which is set through the operation unit 330. At this time, when the full color mode is set as the color mode, the print preparation operation is performed so as to bring the abutment and separation mechanism 400 into the state of the abutment mode. When the automatic determination mode (third mode) is set, the print preparation operation is performed so as to bring the abutment and separation mechanism 400 into the separation mode. In the automatic determination mode, any one of the full color mode and the monochromatic mode is automatically set as the color mode based on a property of an input image. When the automatic determination mode is set, the same print preparation operation as the monochromatic mode is performed. Such a configuration is employed because of the following reason. In the case of the automatic determination mode, the color mode is not determined until printing is started. Thus, it is necessary to perform the print preparation operation with prediction of the color mode. Accordingly, improvement in the first copy output time can be expected when the print preparation operation is performed in the monochromatic mode which is frequently used.
(Control Sequence for Print Preparation Operation)
Now, a comparative embodiment is described with reference to
In S1001, the CPU 301 resets and starts a timer 291 to monitor whether or not a print operation start instruction is given within a predetermined time period. The timer 291 adds a timer value every 1 millisecond (ms), and the CPU 301 refers to the timer value of the timer 291 to determine an elapsed time from the start of the timer 291 in S1001. In S1002, the CPU 301 reads the color mode setting stored in the RAM 303 to determine whether or not the set color mode is the full color mode. When it is determined that the set color mode is the full color mode, the CPU 301 proceeds the processing to S1003. When it is determined that the set color mode is not the full color mode, that is, the set color mode is the monochromatic mode or the automatic determination mode, the CPU 301 proceeds the processing to S1007.
In S1003, in order to determine whether or not the full color print restricted operation is necessary, the CPU 301 starts the processing of determining the necessity of the full color print restricted operation described with reference to
In S1005, the CPU 301 sets the color mode of the print preparation operation to the full color mode. In S1006, the CPU 301 sets the print preparation temperature of the fixing device 170 to 80° C. being the print preparation temperature for the full color mode (print preparation temperature=full color print preparation temperature), performs supply of power to the heater 1 of the fixing device 170, and proceeds the processing to S1009.
In the case of NO in S1002, the color mode set through the operation unit 330 is the monochromatic mode or the automatic determination mode. Thus, in S1007, the CPU 301 sets the color mode for the print preparation operation to the monochromatic mode. Further, when the print restricted operation is to be performed (NO in S1004), the CPU 301 sets the color mode for the print preparation operation to the monochromatic mode irrespective of the color mode setting which is set through the operation unit 330. In S1008, the CPU 301 sets the print preparation temperature of the fixing device 170 to 120° C. being the print preparation temperature for the monochromatic mode (print preparation temperature=monochromatic print preparation temperature), performs supply of power to the heater 1 of the fixing device 170, and proceeds the processing to S1009.
In S1009, the CPU 301 performs the control for the abutment and separation mechanism 400 in accordance with the color mode setting for the print preparation operation. The control for the abutment and separation mechanism 400 is executed in the subroutine, and details thereof are described later.
In S1010, the CPU 301 determines whether or not the print operation start instruction from the operation unit 330 is detected (in
In S1013, the CPU 301 refers to the timer value of the timer 291 to determine whether or not 15 seconds or more have elapsed. When it is determined that 15 seconds or more have elapsed, the CPU 301 proceeds the processing to S1014. When the elapsed time is less than 15 seconds, the CPU 301 proceeds the processing to S1016. The time of 15 seconds is an example of a waiting time from the print prediction operation, from which the print operation start instruction is predicted, to detection of the print operation start instruction, and the time is not limited to 15 seconds. In S1014, the CPU 301 stops the supply of power to the heater 1 of the fixing device 170. In S1015, the CPU 301 controls the abutment and separation mechanism 400 to the state of the separation mode, and terminates the processing.
In S1016, the CPU 301 determines whether or not an operation of pressing a key or other operation is performed to the operation unit 330. When the operation is performed, the CPU 301 returns the processing to S1001. When the operation is not performed, the CPU 301 returns the processing to S1010.
When the print operation start instruction is detected, the CPU 301 terminates the print preparation operation and starts the print operation. Before the print operation is started, the CPU 301 checks whether or not the state of the abutment and separation mechanism 400 matches with the color mode setting given at the time of the print start instruction. Then, when the state is unmatched with the color mode setting, the CPU 301 performs the control to achieve the state in which the abutment and separation mechanism 400 matches with the color mode. Such a configuration is employed because of the following reason. In the case of the automatic determination mode, the abutment and separation mechanism 400 is in the state of separation to perform the print preparation operation in the monochromatic mode. Thus, when a print job of the full color mode is executed, the full color print operation cannot be performed in such a state.
In the comparative embodiment, when the print start instruction of the full color mode is received during the print restricted operation, the following processing is performed to notify that the full color printing cannot be performed. That is, the CPU 301 controls the display portion 311 (notification unit) of the operation unit 330 to display a message to confirm whether or not to perform the monochromatic printing (see
(Control Sequence for Abutment and Separation Mechanism)
In S1101, the CPU 301 reads the color mode setting for the print preparation operation to determine whether or not the set color mode is the full color mode. When it is determined that the set color mode is the full color mode, the CPU 301 proceeds the processing to S1102. When it is determined that the set color mode is not the full color mode, that is, the set color mode is the monochromatic mode, the CPU 301 proceeds the processing to S1104. In S1102, the CPU 301 determines whether or not the state of the abutment and separation mechanism 400 is the separation state (separation mode). When it is determined that the state of the abutment and separation mechanism 400 is the separation state, the CPU 301 proceeds the processing to S1103. When it is determined that the state of the abutment and separation mechanism 400 is not the separation state or is the abutment state, the CPU 301 terminates the processing without changing the state of the abutment and separation mechanism 400. In S1103, the CPU 301 shifts the state of the abutment and separation mechanism 400 to the abutment state (abutment mode), and terminates the processing.
In S1104, the CPU 301 determines whether or not the state of the abutment and separation mechanism 400 is the abutment state (abutment mode). When it is determined that the state of the abutment and separation mechanism 400 is the abutment state, the CPU 301 proceeds the processing to S1105. When it is determined that the state of the abutment and separation mechanism 400 is not the abutment state or is the separation state, the CPU 301 terminates the processing without changing the state of the abutment and separation mechanism 400. In S1105, the CPU 301 shifts the state of the abutment and separation mechanism 400 to the separation state (separation mode), and terminates the processing.
In the comparative embodiment, the print preparation operation control is switched in accordance with the color mode setting, thereby being capable of shortening the first copy output time. Further, when the color toner is used up, or during the print restricted operation in which only the monochromatic print operation can be performed due to a failure in a component which is used only for the full color print operation, the full color print preparation operation control is not performed, and the monochromatic print preparation operation is performed. With this, the print preparation operation can optimally be performed. As a result, an unnecessary operation is not performed during the print preparation operation, thereby being capable of achieving power saving for drive power. Further, the abrasion of the photosensitive drum due to the friction with the intermediate transfer belt is prevented, thereby being capable of extending the lifetime limit of the photosensitive drum.
In the comparative embodiment, the print preparation operation in the monochromatic mode is performed during the print restricted operation. However, in the case of the comparative embodiment, when only a scanning operation is performed under a state in which a user sets the color mode to the full color mode through the operation unit 330 during the print restricted operation, an unnecessary print preparation operation is performed. In order to avoid such a circumstance, in this embodiment, the print preparation operation is not performed during the print restricted operation when the instruction of the print preparation operation in the full color mode is received.
(Control Sequence for Print Preparation Operation)
In
In S1309, the CPU 301 performs the following processing to indicate that the print preparation operation in the full color mode (S1305 and S1306) or the print preparation operation in the monochromatic mode (S1307 and S1308) is performed. That is, the CPU 301 turns on a print preparation operation performance flag (hereinafter referred to as “performance flag”), stores the performance flag in the RAM 303, and proceeds the processing to S1311. Meanwhile, in S1310, in order to indicate that the print preparation operation is not performed, the CPU 301 turns off the performance flag, stores the performance flag in the RAM 303, and proceeds the processing to S1312.
The processing of S1311 is the same as the processing of S1009 of
When the print operation start instruction is detected, the CPU 301 terminates the print preparation operation. Also in this embodiment, similarly to the comparative embodiment, the CPU 301 checks, before starting the print operation, whether or not the state of the abutment and separation mechanism 400 matches with the color mode of the print start instruction, that is, the state of the abutment and separation mechanism 400 matches with the color mode set in the RAM 303. When the state of the abutment and separation mechanism 400 is unmatched with the color mode, the CPU 301 brings the abutment and separation mechanism 400 into the state of matching with the color mode setting. Such a configuration is employed because of the following reason. In the case of the automatic determination mode, the abutment and separation mechanism 400 is in the separation state to perform the print preparation operation in the monochromatic mode. Thus, when a print job of the full color mode is executed, the full color print operation cannot be performed in such a state.
In this embodiment, when the print start instruction of the full color is received during the print restricted operation under the state in which the color mode setting is set to the full color mode, neither the full color printing nor the monochromatic printing can be performed. Therefore, the CPU 301 controls the display portion 311 of the operation unit 330 to display a message to confirm whether or not to perform the monochromatic printing (see
In this case, the print preparation operation is not performed during the print restricted operation irrespective of the set color mode. Thus, the power is not supplied to the fixing device 170. Therefore, as compared to the comparative embodiment in which the print preparation operation in the monochromatic mode is performed in advance, the first copy output time becomes longer. When the scanning operation is performed under a state in which the user sets the color mode setting to the full color mode, the print preparation operation in the monochromatic mode is not performed in this embodiment, unlike the comparative embodiment. Therefore, the abrasion of the photosensitive drum 101k for black is prevented, thereby being capable of extending the lifetime limit of the photosensitive drum 101k.
In this embodiment, when the opening and closing of the original pressure plate, the placement of an original on the original table 152, or the operation to the operation unit 330 is detected, the CPU 301 performs the control for the print preparation operation. Operations from which printing is expected include, for example, a mounting and removing operation of the sheet feeding cassette 111, placement of a sheet on the multi tray 117, print condition setting input from the external computer 283 through the external I/F 282, or detection of an approach or a contact by a person through a human sensor. Therefore, those conditions may be added to the determination conditions in S1317 of
As described above, according to this embodiment, the print preparation operation control can be performed in accordance with the state of the image forming unit.
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. 2016-064112, filed Mar. 28, 2016, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2016-064112 | Mar 2016 | JP | national |