JP7480616B2 - Image forming apparatus and control method - Google Patents

Description

This disclosure relates to an image forming apparatus and a control method.

In recent years, electrophotographic image forming devices that use toner have become widespread. These image forming devices form a toner image on a photoconductor and transfer the toner image onto a sheet. To form a toner image on the surface of the photoconductor, the image forming device executes a charging process to generate charge on the surface of the photoconductor, an exposure process to irradiate the surface of the photoconductor with light to form an electrostatic latent image, and a development process to attach toner to the surface of the photoconductor.

The above exposure process is performed by the light emission control, which is the control by the light emission control unit to make the light emitting elements emit light. The control unit, which controls the entire image forming apparatus, controls the light emission by sending parameters related to the light emission control to the light emission control unit via serial communication.

Regarding technology for stabilizing light emission control, for example, Japanese Patent Application Laid-Open No. 2019-155807 (Patent Document 1) discloses an image forming apparatus in which "when forming an image on a first sheet S on which an image is formed and a second sheet S on which an image is formed successively from the first sheet S, the control unit changes the target light amount stored in the target light amount register DAC between the first sheet S and the second sheet S, and when serial communication is performed over a period in which the polygon mirror scans the photosensitive drum multiple times to form an image on the first sheet S, the control unit sets the serial communication so that the timing at which the BD signal is output is set as the starting point for the start of the serial communication, and the timing at which APC control is performed and the timing at which the target light amount is rewritten in the target light amount register DAC do not overlap" (see [Abstract]).

JP 2019-155807 A

However, when the control unit and the light-emission control unit communicate serially, the register memories for serial communication built into the light-emission control unit are rewritten all at once, which can cause a large number of flip-flop circuits to operate. As a result, the light-emission control unit temporarily consumes a large amount of power.

When the light-emitting control unit consumes a large amount of power while the light-emitting element is exposing the photoconductor, the light-emitting control unit may malfunction, causing the image printed on the sheet to deteriorate. For this reason, technology is needed to make the light-emitting control more stable.

The present disclosure has been devised in consideration of the above-mentioned circumstances, and its purpose is to provide an image forming apparatus and a control method thereof that prevent deterioration of an image printed on a sheet, even when the light-emitting control unit receives a signal via serial communication while the light-emitting element is exposing the photoconductor.

An image forming apparatus according to an aspect of the present disclosure includes a photoconductor that forms a toner image, at least one light-emitting element that exposes the photoconductor, a light emission control unit that executes light emission control of the light-emitting element, and a control unit that transmits a signal to the light emission control unit to control the light-emitting element. The control unit transmits a signal to the light emission control unit to execute light emission control of adjusted light emission to adjust the light emission control of the light-emitting element, and prohibits the transmission of a signal to the light emission control unit to control the light-emitting element when the light emission control of adjusted light emission of the light-emitting element is started and when the light emission control of adjusted light emission of the light-emitting element is ended.

Preferably, the adjusted light emission includes emitting light from the light-emitting element to obtain a horizontal synchronization signal for exposure timing and emitting light from the light-emitting element to sample the amount of light.

Preferably, the light emission control unit performs light emission control of the light emitting element to adjust the light emission during the process of forming a toner image on the photoconductor.

Preferably, the signal sent by the control unit to the light emission control unit includes a signal for controlling the light emitting element in a mode for adjusting the state of the toner image.

Preferably, the signal sent by the control unit to the light emission control unit includes a signal for controlling the light emitting element in a process for adjusting the state of the photoconductor.

Preferably, the signal sent by the control unit to the light emission control unit includes a signal for controlling the light emitting element in a process for making the potential of the photoconductor uniform.

Preferably, the signal sent by the control unit to the light emission control unit includes a signal for controlling the light emitting element to switch between monochrome printing and color printing.

Preferably, there are multiple light-emitting elements, and the signal sent by the control unit to the light-emission control unit includes a signal for switching which of the multiple light-emitting elements is to be subjected to light-emission control.

Preferably, the control unit transmits the signal for controlling the light emitting element in a plurality of divided parts.
Preferably, the control unit divides a signal for controlling the light emitting element for each function of the light emission control unit and transmits the divided signal.

Preferably, the control unit transmits a signal to the light emission control unit to control the light emitting element after the light emission control of the light element's adjusted light emission is started and before the light emission control of the light emitting element's adjusted light emission is ended.

Preferably, the control unit prohibits the transmission of a signal for controlling the light-emitting element when light emission control of the light-emitting element for adjusting the light emission is being performed.

Preferably, the light emission control unit controls the light emission of the light emitting element so that the light emitting element performs multiple adjusted light emissions at a constant cycle, and the control unit transmits a signal to the light emission control unit to control the light emitting element during successive adjusted light emissions.

Preferably, the control unit prohibits the start and end of transmission of a signal for controlling the light-emitting element to the light-emitting control unit when light-emitting control of the adjusted light-emitting of the light-emitting element is started and when light-emitting control of the adjusted light-emitting of the light-emitting element is ended.

Preferably, the light emission control unit executes control on the light emitting element to emit light in a regular cycle multiple times, and the control unit transmits a signal to the light emission control unit in a cycle in which the timing of the start and end of the light emission control of the adjusted light emission does not overlap with the timing of the start and end of the transmission of the signal to the light emission control unit.

Preferably, the control unit changes the period of sending a signal to the light emission control unit and the start timing of sending a signal to the light emission control unit depending on the light emission mode of the light emitting element.

A control method for an image forming apparatus according to an aspect of the present disclosure is a control method for an image forming apparatus including a photoconductor that forms a toner image, a light-emitting element that exposes the photoconductor, at least one light-emitting control unit that executes light-emitting control of the light-emitting element, and a control unit. The control method includes a step of causing the light-emitting control unit to transmit a signal for controlling the light-emitting element to the control unit, a step of causing the light-emitting control unit to transmit a signal for executing control of adjusted light-emitting to adjust the light-emitting control of the light-emitting element, and a step of prohibiting transmission of a signal to the light-emitting control unit when the light-emitting control of the adjusted light-emitting of the light-emitting element is started and when the control of the adjusted light-emitting of the light-emitting element is ended.

According to the present disclosure, even if the light emission control unit receives a signal via serial communication while the light emitting element is exposing the photosensitive body, the image printed on the sheet is prevented from deteriorating by prohibiting the light emission control unit from sending a signal for controlling the light emitting element when light emission control of the light emitting element's adjusted light emission is started and when light emission control of the light emitting element's adjusted light emission is ended.

1 is a diagram showing an example of an image forming apparatus according to an embodiment of the present invention; FIG. 2 is a schematic diagram showing an example of a part of a control system related to light emission control of the image forming apparatus. 13 is a schematic diagram showing an example of a configuration for controlling a laser diode in a light emission control unit. FIG. FIG. 2 is a side view showing an example of the configuration of a print head unit. FIG. 2 is a top view showing an example of the configuration of a print head unit. 11 is a diagram showing an example of the state of each light emission and signal when the timing of the start of adjusted light emission of a laser diode and serial communication occur simultaneously. FIG. 6 is a diagram showing an example of the state of each light emission and signal when a control unit inhibits serial communication at the timing of starting and ending adjusted light emission in the configuration of FIG. 5 . FIG. 1 is a first schematic diagram showing an example of a print head unit including a plurality of light emission control units. 9 is a diagram showing an example of serial communication during adjusted light emission by a control unit in the configuration of FIG. 8 . FIG. FIG. 2 is a second schematic diagram showing an example of a print head unit including a plurality of light emission control units. 13 is a diagram showing an example of how the period of a serial clock based on an SK signal is set to be the same as the period of adjusted light emission, and the phases are shifted. FIG. 4 is a flowchart showing an example of a print process in the image forming apparatus. 5 is a flowchart illustrating an example of an image stabilization process in the image forming apparatus. FIG. 11 is a diagram showing a list of types of stabilization processing.

Hereinafter, an embodiment of the technical idea according to the present disclosure will be described with reference to the drawings. In the following description, the same components are denoted by the same reference numerals. The names and functions of the components are also the same. Therefore, detailed description thereof will not be repeated.
<A. Overview of Image Forming Apparatus>
1 is a diagram showing an example of an image forming apparatus 1 according to the present embodiment. According to the present embodiment, an image forming apparatus 1 is provided that suppresses communication processing with a light emission control unit when light emission control of the light emitting element for the adjusted light emission is started and when light emission control of the light emitting element for the adjusted light emission is ended. The adjusted light emission will be described later.

The hardware configuration of the image forming device 1 will be outlined with reference to FIG. 1. The image forming device 1 includes a print engine 100, a reading unit 200, and an operation panel 300.

The print engine 100 includes an imaging unit 110, an intermediate transfer belt 120, a fixing unit 130, a paper feed unit 140, a feed roller 150, a transport roller 160, a registration roller 170, a control unit 180, and a power supply unit 190.

The print engine 100 performs printing processing on the sheet in the paper feed section 140. The feed rollers 150 transport the sheet from the paper feed section 140. Furthermore, the transport rollers 160 transport the sheet toward the intermediate transfer belt 120.

The imaging unit 110 includes imaging units 10C, 10M, 10Y, and 10K that form toner images of cyan (C), magenta (M), yellow (Y), and key plate (K), respectively. The imaging units 10C, 10M, 10Y, and 10K each include a charging section (not shown), a developing section (not shown), a cleaning section (not shown), and an intermediate transfer body contact roller (not shown).

Furthermore, imaging unit 10C includes photoreceptor 11C. Imaging unit 10M includes photoreceptor 11M. Imaging unit 10Y includes photoreceptor 11Y. Imaging unit 10K includes photoreceptor 11K. Hereinafter, photoreceptor 11C, photoreceptor 11M, photoreceptor 11Y, and photoreceptor 11K may be collectively referred to simply as photoreceptors.

The exposure section 112 is common to the imaging units 10C, 10M, 10Y, and 10K. In some aspects, each of the imaging units 10C, 10M, 10Y, and 10K may include a separate exposure section 112. In the following description, it is assumed that the exposure section 112 is common to each of the imaging units 10C, 10M, 10Y, and 10K.

The imaging unit 110 and intermediate transfer belt 120 form a toner image that is transferred to a sheet. The charging section uniformly charges the surface of the photoconductor. The exposure section 112 forms an electrostatic latent image on the surface of the photoconductor by exposing the surface of the photoconductor to light according to a specified image pattern, for example by laser writing. The development section develops the electrostatic latent image formed on the photoconductor into a toner image.

The registration rollers 170 adjust the timing of the sheet transport just before the intermediate transfer belt 120. The intermediate transfer belt 120 transfers the toner image onto the sheet. The fixing section 130 fixes the image onto the sheet. Finally, the sheet is discharged onto a discharge tray.

The toner image formed on the surface of the photoconductor is transferred to the intermediate transfer belt 120 by the intermediate transfer contact roller. The toner images are transferred from each photoconductor in sequence onto the intermediate transfer belt 120, resulting in four color toner images being superimposed. The superimposed toner images are then transferred from the intermediate transfer belt 120 to a sheet.

The reading unit 200 reads the sheet and outputs the reading result to the print engine 100 as an input image. The image scanner 210 scans the sheet placed on the platen glass and transmits the generated image data to the control unit 180. The automatic document feeder 220 continuously scans the sheets placed on the paper feed tray 230.

The sheets placed on the paper feed tray 230 are fed one by one by a feed roller (not shown) and scanned sequentially by an image sensor arranged in the image scanner 210 or the automatic document feeder 220. After scanning, the sheets are discharged onto the paper discharge tray 240.

The control unit 180 controls the entire image forming apparatus 1. The power supply unit 190 is connected to an AC power source and supplies power to the image forming apparatus 1. The power supply unit 190 includes a rectifier circuit therein, and can convert the AC supplied from the AC power source to DC and supply DC current to some or all of the circuits in the image forming apparatus 1.

The operation panel 300 includes a display unit (not shown) and an operation unit (not shown). The display unit includes an LCD monitor, an organic EL (Electro Luminescence) monitor, etc. The LCD monitor, the organic EL monitor, etc. include a touch sensor, and can display an operation menu and accept input by touch from the user. The operation unit includes a number of buttons, and can accept input from the user in the same way as a touch panel. The operation panel 300 transmits the accepted input to the control unit 180.

Figure 2 is a schematic diagram showing an example of a part of a control system related to light emission control of the image forming device 1. Each component shown in Figure 2 can be realized by an electric circuit and hardware used in combination with the electric circuit.

The control unit 180 includes an image processing unit 181 and a light emission mode control unit 182. The control unit 180 is also connected to the print head unit 113, the image scanner 210, the operation panel 300, and the humidity sensor 119.

The print head unit 113 includes a light emission control unit 114, a polygon motor 115, a laser diode 116, a light sensor 117, and a dust sensor 118.

The control unit 180 includes a CPU (Central Processing Unit) (not shown), a RAM (Random Access Memory) (not shown), and a ROM (Read Only Memory) (not shown). The CPU executes or references various programs and data loaded into the RAM.

In one aspect, the CPU may be an embedded CPU, an FPGA (Field-Programmable Gate Array), or a combination of these. The CPU can execute programs to realize various functions of the image forming device 1.

The RAM stores programs executed by the CPU and data referenced by the CPU. In some aspects, the RAM may be realized by a dynamic random access memory (DRAM) or a static random access memory (SRAM).

The ROM is a non-volatile memory and may store a program to be executed by the CPU. In this case, the CPU executes the program read from the ROM to the RAM. In some aspects, the ROM may be realized by an EPROM (Erasable Programmable Read Only Memory), an EEPROM (Electrically Erasable Programmable Read-Only Memory), or a flash memory.

The image processing unit 181 transmits an image signal to the light emission control unit 114. The image signal can be generated based on image data read by the image scanner 210, or image data acquired from an external device via a communication unit (not shown) provided in the image forming apparatus 1. The light emission control unit 114 causes the laser diode 116 to form an electrostatic latent image on the surface of the photoconductor based on the image signal.

The light emission mode control unit 182 transmits to the light emission control unit 114 information on synchronous light emission to obtain a SOS (Start of Scan) signal, which is a horizontal synchronization signal for the exposure timing of the laser diode 116, which is a light emitting element, and information on SH (Sample Hold) light emission to adjust the light amount of the laser diode 116. This information includes counter values for defining the generation and end timing of each signal.

The SOS signal can be used to determine the start timing of light emission. The SOS signal is generated when the optical sensor 117 detects a synchronous light emission for obtaining the SOS signal (hereinafter referred to as "SOS light emission").

SH light emission is light emission for adjusting the amount of light irradiated onto the photosensitive member. The optical sensor 117 detects the SH light emission and transmits a signal based on the detection value to the light emission control unit 114 or the control unit 180. The light emission control unit 114 or the control unit 180 can correct the amount of light from the laser diode 116 based on the detection value of the SH light emission.

In one aspect, the image forming device 1 may be provided with an optical sensor (not shown) that is provided separately from the optical sensor 117 that detects the backlight of the laser diode 116.

In this embodiment, the SOS emission and the SH emission are included in the adjusted emission for adjusting the emission control of the laser diode 116. In some aspects, the adjusted emission for adjusting the emission control of the laser diode 116 may include emission other than the SOS emission and the SH emission.

In one aspect, the image processing unit 181 and the light emission mode control unit 182 may be realized as separate hardware included in the control unit 180. In another aspect, the image processing unit 181 and the light emission mode control unit 182 may be realized as a program executed by the CPU of the control unit 180.

The light emission control unit 114 controls each piece of hardware, such as the polygon motor 115 and the laser diode 116 of the print head unit 113. The polygon motor 115 is a motor for driving a polygon mirror that reflects the laser emitted by the laser diode 116.

The laser diode 116 irradiates the photoconductor with a laser to form an electrostatic latent image on its surface. The light emission control unit 114 controls the polygon motor 115 and the laser diode 116 to irradiate the laser to any location on the surface of the photoconductor for each color.

The optical sensor 117 detects the laser light emitted by the laser diode 116. The optical sensor 117 transmits a signal indicating the amount of light detected to the light emission control unit 114. In one aspect, the optical sensor 117 may detect the laser light reflected by the polygon mirror.

The dust sensor 118 detects dust around the print head unit 113. The dust sensor 118 sends a signal indicating the amount of dust detected to the light emission control unit 114. In one aspect, the light emission control unit 114 may output an error to the control unit 180 if the amount of dust is equal to or greater than a certain amount.

The humidity sensor 119 may be installed inside or outside the housing of the image forming apparatus 1. The humidity sensor 119 detects the humidity around the humidity sensor 119. The humidity sensor 119 transmits a signal related to the detected humidity to the control unit 180. The control unit 180 may adjust various parameters of the photoconductor charging process, exposure process, development process, etc. according to the humidity. The various parameters include the charging voltage, the amount of light, the amount of toner, etc.

<B. Light Emission Control and Communication for Light Emission Control>
Fig. 3 is a schematic diagram showing an example of a configuration for controlling the laser diode 116 in the light emission control unit 114. The internal configuration of the light emission control unit 114, the light emission control by the light emission control unit 114, and communication between the control unit 180 and the light emission control unit 114 will be described with reference to Fig. 3.

(B-1. Configuration of the light emission control unit 114)
The light emission control unit 114 includes an OR circuit 401 , a laser diode driving unit 402 , the laser diode 116 , a timing signal generating unit 403 , a light amount correcting unit 406 , a reference clock generating unit 409 , and an error detecting unit 410 .

The timing signal generating unit 403 includes a counter value memory 404 and a counter 405. The light quantity correcting unit 406 includes a correction value memory 407. The control unit 180 and the light emission control unit 114 are connected via the image signal line 302, the serial signal line 303, and the SOS signal line 304.

The OR circuit 401 receives two input signals and outputs one output signal. The first input signal is an image signal output from the image processing unit 181 via the image signal line 302. The second input signal is a timing signal output from the timing signal generating unit 403.

When the OR circuit 401 receives an input of an image signal, it outputs a signal identical to the image signal to the laser diode drive unit 402. When the OR circuit 401 receives an input of a timing signal, it outputs a signal identical to the timing signal to the laser diode drive unit 402.

The laser diode driving unit 402 drives the laser diode 116 based on the signal output from the OR circuit 401. For example, when the laser diode driving unit 402 receives an image signal, it controls the laser diode 116 to form an electrostatic latent image based on the image signal on the surface of the photoconductor.

When the laser diode driving unit 402 receives a timing signal, it controls the laser diode 116 to emit SOS or SH light. The path of the laser light output from the laser diode 116 is adjusted by the polygon mirror 321.

The timing signal generating unit 403 measures the execution timing of the SOS light emission or the SH light emission, and outputs a timing signal to the OR circuit 401 in accordance with the execution timing of the SOS light emission or the SH light emission. The counter value memory 404 holds the counter values of each signal.

For example, the counter value memory 404 holds the matching settings for each signal in the timer, the reset timing of the timer, etc. The counter 405 is a counter for the timer. The timing signal generating unit 403 counts up or down the count value of the counter 405.

The timing signal generating unit 403 compares the count value of the counter 405 with the count values of the matching settings of each signal in the counter value memory 404, and generates a timing signal if they match.

The light emission mode control unit 182 transmits counter values related to SOS light emission or SH light emission to the light emission control unit 114 via the serial signal line 303. In one aspect, these counter values may include matching settings for SOS light emission, matching settings for SH light emission, and timer reset timing. The light emission control unit 114 stores these received counter values in the counter value memory 404.

The control unit 180 uses these counter values to prohibit transmission of a serial signal to the light emission control unit 114 when light emission control of the SOS light emission or SH light emission of the laser diode 116 is started and ended.

The serial signal line 303 may include three signal lines: a serial clock signal line, a data input signal line, and a data output signal line. The serial clock signal line transmits a clock for serial communication. Data for serial communication is transmitted and received at the timing of the clock. In one aspect, the control unit 180 generates a clock to be transmitted to the serial clock signal line.

The data output signal line transmits data from the master control unit 180 to the slave light emission control unit 114. The light emission mode control unit 182 transmits data to the light emission control unit 114 via the data output signal line.

For example, the light emission mode control unit 182 transmits counter values related to SOS light emission and SH light emission to the light emission control unit 114 via the data output signal line.

The data input signal line transmits data from the slave light emission control unit 114 to the master control unit 180. The light emission mode control unit 182 receives data from the light emission control unit 114 via the data input signal line.

For example, the light emission control unit 114 transmits an ACK signal, which indicates that the SOS light emission and the SH light emission have been received, to the control unit 180 via the data output signal line.

The light intensity correction unit 406 transmits a light intensity correction signal to the laser diode driving unit 402. The light intensity correction unit 406 generates the light intensity correction signal based on the correction value memory 407. The light intensity correction unit 406 can store a correction value in the correction value memory 407 based on signals from the light emission mode control unit 182 and the timing signal generating unit 403.

The light emission control unit 114 may rewrite the correction value memory 407 based on the light intensity correction value signal acquired from the control unit 180 via the serial signal line 303.

The reference clock generating unit 409 generates a reference clock for the timer used by the timing signal generating unit 403. The reference clock generating unit 409 can adjust the start or end position of the reference clock based on the SOS signal output by the optical sensor 117 when an SOS emission is detected. The SOS signal is transmitted to the reference clock generating unit 409 and the control unit 180 via the SOS signal line 304.

The error detection unit 410 detects various errors that occur in the print head unit 113. Examples of various errors include an overcurrent to the laser diode 116, a voltage drop in the light emission control unit 114, and a malfunction of the counter 405.

When the error detection unit 410 detects these errors, the corresponding bit in the built-in register changes from 0 to 1. The control unit 180 reads the error information stored in the error detection unit 410 via the serial signal line 303. More specifically, the control unit 180 transmits an error read request to the light emission control unit 114 via the serial signal line 303, and receives the error information from the light emission control unit 114.

(B-2. Timing of each light emission)
Next, a description will be given of the timing at which light is emitted by the laser diode 116. As described above, in the exposure process, the print head unit 113 executes modulated light emission including SOS light emission and SH light emission, and light emission for forming an electrostatic latent image.

The print head unit 113 repeats each of the adjusted light emission including SOS light emission and SH light emission and the light emission that forms the electrostatic latent image multiple times to form one image on the surface of the photoconductor. The print head unit 113 forms a part of the electrostatic latent image on the surface of the photoconductor line by line.

The print head unit 113 repeatedly forms parts of an electrostatic latent image on the surface of the photoconductor in line units, ultimately forming an electrostatic latent image of one image on the surface of the photoconductor. Modulated light emission, including SOS light emission and SH light emission, and light emission that forms the electrostatic latent image occur on a line-by-line basis.

For example, when the print head unit 113 forms a portion of an electrostatic latent image on the surface of the photoconductor in units of lines 1000 times, the adjusted emission including SOS emission and SH emission, and the emission to form the electrostatic latent image also occur 1000 times. The print head unit 113 repeatedly executes each emission in the order of the emission to form the electrostatic latent image, the SOS emission, and the SH emission.

The laser diode 116 emits adjusted light, including SOS and SH light, even during the erase light emission during the end sequence process, which is a post-processing step within a job that makes the potential of the photoconductor uniform.

(B-3. Communications occurring between the control unit 180 and the light emission control unit 114)
The communications related to the light emission control that occur between the above-mentioned control unit 180 and the light emission control unit 114 include at least the following first to fourth communications.

The first communication is a communication of a counter value related to the adjusted light emission including SOS light emission and SH light emission. This communication is performed via the serial signal line 303. The light emission control unit 114 can rewrite the counter value memory 404 of the timing signal generation unit 403 based on the first communication, and count the timing of the adjusted light emission including SOS light emission and SH light emission. The print head unit 113 performs adjusted light emission including SOS light emission and SH light emission before and after the light emission that forms an electrostatic latent image on the surface of the photoconductor.

The second communication is communication of an image signal. The control unit 180 transmits an image signal to the light emission control unit 114 based on the image data and print command acquired. The image signal is a signal for causing the print head unit 113 to form an electrostatic latent image on the surface of the photoconductor. The light emission control unit 114 executes light emission to form an electrostatic latent image on the surface of the photoconductor based on the second communication.

The third communication is communication of the detection value of the optical sensor 117. The optical sensor 117 detects the laser light of the laser diode 116. After detecting the laser light, the optical sensor 117 transmits a detection signal to the reference clock generating unit 409 and the control unit 180 via the SOS signal line 304.

The detection signal transmitted from the optical sensor 117 may include at least an SOS signal. The reference clock generating unit 409 may adjust the reference clock based on the SOS signal when an SOS emission is detected.

The fourth communication is a communication for reading error information. The control unit 180 communicates with the light emission control unit 114 via the serial signal line 303 in order to read the error information of the error detection unit 410. The fourth communication can be performed immediately after the first communication.

When the first or fourth communication (serial communication) occurs among the four types of communication described above, the light emission control unit 114 operates a large number of flip-flop circuits to simultaneously rewrite the built-in register memory for serial communication. As a result, the light emission control unit 114 temporarily consumes a large amount of power.

If serial communication occurs simultaneously with light emission control, it may cause a voltage drop in the light emission control unit 114, which may lead to malfunction of the counter 405. If the counter 405 malfunctions, the electrostatic latent image may not be formed properly on the surface of the photoconductor, and the quality of the printed image may deteriorate.

(B-4. Timing when light emission control and serial communication occur simultaneously)
Next, an example of timing when light emission control and serial communication can occur simultaneously will be described. The first communication occurs in response to the control unit 180 accepting a job. The print head unit 113 receives data related to settings of the job and the like through the first communication.

The first communication occurs before switching to the stabilization mode, which is a mode for adjusting the state of the toner image. The stabilization mode is described in detail below.

The first communication occurs before performing inter-sheet patch processing, which is processing for adjusting the state of the photoconductor. Inter-sheet patch processing is processing for performing test patch processing on the photoconductor between jobs to adjust the wear of the entire photoconductor to a constant level. The image forming device 1 adjusts the state of the photoconductor by inter-sheet patch processing.

The first communication also occurs before switching from monochrome printing to color printing. The first communication also occurs before switching from color printing to monochrome printing. For example, the control unit 180 generates the first communication to operate all imaging units 10C, 10M, 10Y, and 10K from a state in which only imaging unit 10K is operating to form a toner image of the key plate.

In an image forming device 1 with full-color printing capabilities, the print head unit 113 has a light-emitting element (laser diode 116) for each of the colors yellow (Y), magenta (M), cyan (C), and key plate (black) (K). When switching from monochrome printing processing to color printing processing, the image forming device 1 switches the light-emitting element (laser diode 116) for each color.

For example, when switching from monochrome printing to color printing, the image forming device 1 switches from monochrome printing in which only the light-emitting elements corresponding to the key plate (black) (K) are illuminated to color printing in which all light-emitting elements are illuminated. When switching from color printing to monochrome printing, the image forming device 1 switches from a process in which all light-emitting elements are illuminated to a process in which only the light-emitting elements corresponding to the key plate (black) (K) are illuminated.

The image forming device 1 generates a first communication before switching the light-emitting element that controls the light emission. The image forming device 1 may switch the light-emitting element that controls the light emission not only when switching between monochrome and color, but also when, for example, an error is detected in one of the multiple light-emitting elements.

The first communication may also occur before the end sequence process for equalizing the potential of the photoconductor is performed, as a signal to control the laser diode 116 to perform the end sequence process.

After the first communication is completed, the print head unit 113 emits light to form an electrostatic latent image. Also, immediately after the first communication, a fourth communication may occur.

If the first communication overlaps with the start and end of the adjusted light emission, a large amount of power may be consumed in the light emission control unit 114, causing a voltage drop.

Therefore, the image forming device 1 according to this embodiment prevents serial communication that may occur simultaneously when the adjusted light emission starts and when the adjusted light emission ends.

That is, the control unit 180 prohibits the first communication, which is serial communication, from being performed at the start and end of the adjusted light emission. The control unit 180 performs the first communication, which is serial communication, so as not to overlap with the start and end of the adjusted light emission.

More specifically, the light emission mode control unit 182 generates counter values for SOS light emission and SH light emission, and transmits these counter values to the light emission control unit 114. This allows the light emission mode control unit 182 to detect the start and end timing of adjusted light emission based on the transmitted counter values for SOS light emission and SH light emission.

The control unit 180 can prevent the above-mentioned voltage drop by prohibiting serial communication with the light emission control unit 114 when the adjusted light emission starts and ends.

In one aspect, the control unit 180 may prohibit serial communication at the start and end of adjusted light emission by disabling the function of the serial clock port.

In another aspect, the control unit 180 may prohibit serial communication at the start and end timing of regulated light emission by disabling the functions of the serial clock port, the data input port, and the data output port.

The image forming device 1 according to this embodiment disables the serial communication function of the control unit 180 based on various counter values set in the light emission control unit 114. This function allows the image forming device 1 to prevent serial communication from occurring simultaneously with the start and end timing of adjusted light emission. As a result, no voltage drop occurs in the light emission control unit 114, and no malfunction of the counter 405 due to a voltage drop occurs, improving the quality of the printed image.

C. Hardware Configuration of Print Head Unit
Next, the state of reflection of the laser light in the print head unit 113 will be described with reference to Figures 4 and 5. Figure 4 is a side view showing an example of the configuration of the print head unit 113. In the example shown in Figure 4, the laser light reflected by the polygon mirror 321 passes through the fθ lens 322 and enters a reflection mirror for reflecting the laser light onto the photoconductor of each color.

Reflecting mirrors 323Y and 324Y reflect the laser light onto the yellow photoconductor. Reflecting mirrors 323M and 324M reflect the laser light onto the magenta photoconductor. Reflecting mirrors 323C and 324C reflect the laser light onto the cyan photoconductor. Reflecting mirror 323K reflects the laser light onto the key plate (black) photoconductor.

Figure 5 is a top view showing an example of the configuration of the print head unit 113. In an image forming device 1 with full-color printing capabilities, the print head unit 113 has light-emitting elements (laser diodes 116) for each of the colors yellow (Y), magenta (M), cyan (C), and key plate (black) (K).

Each of the laser beams emitted from each light-emitting element is focused by each of the collimator lenses 502Y, 502M, 502C, and 502K. Each of the focused laser beams is collected on the reflecting mirror 504 by each of the reflecting mirrors 503Y, 503M, 503C, and 503K, which are installed with steps. The reflecting mirror 504 guides each of the laser beams to the polygon mirror 321. A portion of the laser beam reflected from the polygon mirror 321 enters the optical sensor 117 via the reflecting mirror 511. When the laser beam enters the optical sensor 117, the control unit 180 detects a synchronization signal including an SOS signal of the laser beam reflected from the polygon mirror 321.

The image forming device 1 of this embodiment further includes a reflecting mirror 512 and an optical sensor 513. When the laser light enters the optical sensor 513, the control unit 180 detects an end signal of the laser light reflected from the polygon mirror 321.

D. Timing of Light Emission and Signals
Next, the timing of light emission from the laser diode 116 and the generation of signals for serial communication will be described with reference to Fig. 6 and Fig. 7. Fig. 6 is a diagram showing an example of the state of each light emission and signal when the timing of the start of regulated light emission from the laser diode 116 and serial communication occur simultaneously.

Communication (SK, DI, DO) refers to the serial clock signal, data input signal, and data output signal.

The light emission control unit 114 executes light emission control of three adjusted lights 601, 602, and 603 at a fixed cycle. In this embodiment, the adjusted lights are composed of SOS lights and SH lights. In some aspects, the adjusted lights may include other lights.

The light emission control unit 114 executes light emission control for forming an electrostatic latent image on the surface of the photoconductor during the light emission control of the successive adjusted light emissions 601, 602, and 603. For example, the light emission control unit 114 may execute light emission control for forming one line of an electrostatic latent image on the surface of the photoconductor during a period 604 between adjusted light emissions 601 and 602. Similarly, the light emission control unit 114 may execute light emission control for forming one line of an electrostatic latent image on the surface of the photoconductor during a period 605 between adjusted light emissions 602 and 603. That is, the second communication occurs during periods 604 and 605.

In the example shown in FIG. 6, serial communication occurs at the start of the SOS light emission, which is the third adjusted light emission 603. As a result, the rewriting process of the communication register inside the light emission control unit 114 and the light emission of the laser diode 116 occur simultaneously, causing a voltage drop in the light emission control unit 114.

At that time, the counter 405 malfunctions, the light emission control unit 114 does not execute the SOS light emission process that it should have executed, and the subsequent formation of an electrostatic latent image on the surface of the photoconductor is also skipped. As a result, the quality of the printed image deteriorates.

Figure 7 is a diagram showing an example of the state of each light emission and signal when the control unit 180 prohibits serial communication at the start and end timing of adjusted light emission in the configuration of Figure 5. The control unit 180 transmits serial communication 701 to execute a job.

As a result, the image forming device 1 is set to the print mode, and image formation processing is performed during period 703. In other words, period 703 is a period during which the light emission control unit 114 performs light emission control. During the print mode, the light emission control unit 114 periodically controls the light emission of the laser diode 116 to perform adjusted light emission, which is SH light emission and SOS light emission. The laser diode 116 emits light to form an electrostatic latent image on the photoconductor during periods between adjusted lights, such as period 706. That is, during period 706, the second communication occurs.

As described above, the control unit 180, which includes the light emission mode control unit 182, can detect the timing of the start and end of the adjusted light emission based on the transmitted counter values related to the SOS light emission and the SH light emission. As a result, the control unit 180 performs serial communication 702 with the light emission control unit 114 during the period 706, thereby preventing the start and end of the adjusted light emission from overlapping with the first communication, which is the serial communication 702.

The control unit 180 transmits serial communication 702 after the SOS light emission end timing 704. The SOS light emission end timing 704 is when the light emission control of the adjusted light emission ends.

The control unit 180 also transmits serial communication 702 before the start timing 705 of the SH light emission. The start timing 705 of the SH light emission is when the light emission control of the adjusted light emission starts.

In other words, the control unit 180 sends serial communications to the light emission control unit 114 to control the laser diode 116 during successive adjusted light emissions.

In the example of FIG. 7, the control unit 180 prohibits serial communication when the laser diode 116 is emitting adjusted light. This more reliably prevents serial communications 701, 702 between the control unit 180 and the light emission control unit 114 from occurring at the same time as the start and end of adjusted light emission. As a result, no voltage drop occurs in the light emission control unit 114, and no deterioration in the quality of the printed image occurs.

The control unit 180 transmits serial communication 702, which is the first communication, to the light emission control unit 114 in order to perform processes such as end sequence processing, paper patch processing, switching between monochrome and color modes, and switching to stabilization mode. That is, after the end of the period 703, the laser diode 116 emits light according to the contents of the serial communication 702.

For example, the control unit 180 controls the stabilization mode and executes inter-paper patch processing, etc., based on information from the dust sensor 118 and humidity sensor 119, or the number of toner rotations, etc. When the control unit 180 executes the stabilization mode and inter-paper patch processing, it generates serial communication 702, which is the first communication.

As shown in FIG. 7, the control unit 180 may transmit serial communication 702 to the light emission control unit 114 in multiple parts. In FIG. 7, the serial communication 702 is divided into four parts. For example, when setting the stabilization mode, the amount of data transmitted by serial communication may increase. Therefore, the control unit 180 transmits the serial communication 702 in parts.

When the control unit 180 performs divided serial communication, it divides the serial communication for each function provided by the light emission control unit 114. Returning to FIG. 3, the function provided by the light emission control unit 114 means functions such as the timing signal generating unit 403 or the light intensity correcting unit 406 provided by the light emission control unit 114.

That is, when switching to the stabilization mode, for example, the control unit 180 transmits data related to the timing signal generating unit 403 in the first serial communication of the serial communication 702, and transmits data related to the light intensity correcting unit 406 in the second serial communication.

This allows the light emission control unit 114 to accept data for each function it has, reducing the risk of partial data loss and preventing unexpected operation.

E. Application to other device configurations
The above disclosure is also applicable to a plurality of light emission control units 114. A method of stopping serial communication of the control unit 180 during light emission control of a plurality of light emission control units 114 will be described with reference to Fig. 8 .

Figure 8 is a first schematic diagram showing an example of a print head unit 113 having multiple light emission control units 114. The example shown in Figure 8 differs from the example shown in Figure 3 in that multiple light emission control units 114A, 114B perform light emission control.

For example, the light emission control unit 114A can execute the formation of electrostatic latent images of yellow (Y) and cyan (C), and the light emission control unit 114B can execute the formation of electrostatic latent images of magenta (M) and key plate (black) (K). In this way, by being equipped with multiple light emission control units 114A and 114B, the print head unit 113 can form electrostatic latent images on the surface of the photoconductor at high speed.

In the example of FIG. 8, the control unit 180 has at least two select ports (not shown) for specifying the communication destination of serial communication. The first select port is connected to the light emission control unit 114A via signal line 801A. The second select port is connected to the light emission control unit 114B via signal line 801B.

The control unit 180 determines the communication destination by setting the output (select signal) of either the first select port or the second select port to HIGH. For example, when the control unit 180 sets the output of the first select port to HIGH, the light emission control unit 114A determines that its own device has been selected as the communication destination, and captures the signal transmitted from the control unit 180.

Conversely, the output of the second select port remains LOW, and the light emission control unit 114B determines that its own device has not been selected as a communication destination, and does not receive the signal sent from the control unit 180.

Based on the counter values of SOS light emission and SH light emission sent to each of the light emission control units 114A, 114B, the control unit 180 does not set the select port of the light emission control unit 114 during light emission control to HIGH, thereby preventing light emission processing and serial communication from occurring simultaneously in each of the light emission control units 114A, 114B.

In one aspect, the control unit 180 may achieve the above functions by using software-based conditional branching, etc. In another aspect, the control unit 180 may rewrite the register of each select port so that the output of each select port cannot be set to HIGH.

Figure 9 is a diagram showing an example of serial communication during regulated light emission by the control unit 180 in the configuration of Figure 8. The SK signal, DI signal, DO signal, and CS signal (SC1 and SC2 signals) are a serial clock signal, a data input signal, a data output signal, and a select signal, respectively.

Serial communication during adjusted light emission means that the control unit 180 transmits a signal to the light emission control unit 114 to control the laser diode 116 from after the light emission control of adjusted light emission starts until before the light emission control of adjusted light emission ends.

Serial communication 902 is communication for performing image formation processing of the laser diode 116. Period 901 is a period during which the light emission control units 114A and 114B execute light emission control in response to serial communication 902.

In other words, period 901 is a period during which image formation processing is being performed. The control unit 180 disables the serial communication function of the control unit 180 at the timing of the start and end of the adjusted light emission. Alternatively, the control unit 180 sets the output of a select port for selecting the light emission control unit 114 that is performing the light emission control to LOW at the timing of the start and end of the adjusted light emission.

In FIG. 7, the control unit 180 prohibits serial communication during adjusted light emission, thereby preventing the start and end timings of adjusted light emission from overlapping with serial communication. In contrast, in FIG. 9, serial communication is performed during the period when adjusted light emission is being emitted, excluding the start and end timings of adjusted light emission. In this way, the control unit 180 prevents the start and end timings of adjusted light emission from overlapping with serial communication.

As a result, no voltage drop occurs in either light emission control unit 114A or 114B, and no deterioration in the quality of the printed image occurs.

Figure 9 shows an example in which the control unit 180 performs serial communication after the start of SOS light emission and before its end, but the control unit 180 may also perform serial communication after the start of SH light emission and before its end.

Figure 10 is a second schematic diagram showing an example of a print head unit 113 having multiple light emission control units 114. The example shown in Figure 10 differs from the above configuration in that multiple light emission control units 114A, 114B perform light emission control, and the control unit 180 disables the serial communication function of the control unit 180 by hardware.

For example, the light emission control unit 114A may execute the formation of electrostatic latent images of yellow (Y) and cyan (C), and the light emission control unit 114B may execute the formation of electrostatic latent images of magenta (M) and key plate (black) (K).

In the example of FIG. 10, signal line 1001 includes a data input signal line and a data output signal line for serial communication. Signal line 1002 is a serial clock communication line.

Signal line 1003A is a signal line connected to a first select port for selecting light emission control unit 114A. Signal line 1003B is a signal line connected to a second select port for selecting light emission control unit 114B.

Signal line 1002 and signal line 1003A are each connected to an input port of AND circuit 1004A. Signal line 1002 and signal line 1003B are each connected to an input port of AND circuit 1004B.

The output signal line of the AND circuit 1004A is connected to the input port of the serial clock signal of the light emission control unit 114A. The output signal line of the AND circuit 1004B is connected to the input port of the serial clock signal of the light emission control unit 114B.

With the above configuration, the signal of the select port for selecting each light emission control unit 114A, 114B can become a signal for controlling the enable and disable of the clock signal.

More specifically, when the control unit 180 sets the output of the first select port to HIGH and the output of the second select port to LOW, when the control unit 180 generates a serial clock, the AND circuit 1004A outputs the serial clock, but the AND circuit 1004B does not output the serial clock.

In this way, in the example of FIG. 10, by using a hardware configuration to block the serial clock to the light-emission control unit 114 that is not selected by the control unit 180, it is possible to more reliably prevent serial communication to the light-emission control unit 114 during light-emission control.

Figure 11 shows an example of how the period of the serial clock generated by the SK signal is set to the same period as the period of the adjusted light emission, and the phase is shifted.

In FIG. 11, when light emission control of the adjusted light emission is started and ended, the control unit 180 prohibits the light emission control unit 114 from starting and ending the transmission of serial communication for controlling the laser diode 116.

The period of the adjusted light emission is shown as period FO in FIG. 11. Period FO indicates, for example, the period from the start timing 1102a of the SOS light emission, which is an adjusted light emission, to the start timing of the next SOS light emission.

As described above, the light emission control unit 114 controls the laser diode 116 to emit adjusted light repeatedly at a constant cycle. Therefore, even after the start timing 1102a of the SOS light emission, the start timing of the SOS light emission occurs at the cycle FO.

Similarly, the timing of the end of SOS light emission occurs with a period FO. The timing of the start and end of SH light emission also occurs with a period FO.

The control unit 180 starts transmitting the SK signal with a cycle FK that is the same cycle as cycle FO. The control unit 180 shifts the phase between cycle FO and cycle FK by shifting the start timing 1101a of the serial clock based on the SK signal from the start timing of the adjusted light emission. This allows the control unit 180 to generate the start and end timing of the serial clock based on the SK signal and the start and end timing of the adjusted light emission with a shift.

In FIG. 11, the start timing of the light emission control of the adjusted light emission is, for example, the start timing 1102a of the SOS light emission and the start timing 1103a of the SH light emission. The end timing of the light emission control of the adjusted light emission is, for example, the end timing 1102b of the SOS light emission and the end timing 1103b of the SH light emission.

The start timing of the transmission of the signal to the light emission control unit 114 is, for example, the start timing 1101a of the serial clock by the SK signal. The end timing of the transmission of the signal to the light emission control unit 114 is, for example, the end timing 1101b of the serial clock by the SK signal.

As a result, no voltage drop occurs in either light emission control unit 114A or 114B, and no deterioration in the quality of the printed image occurs.

The period FO changes according to various conditions. For example, if the sheet being processed by the image forming device 1 is thick paper, the period FO will be longer than when the sheet is a normal sheet. Furthermore, the length of the period FO when performing image formation processing differs from the length of the period FO when performing stabilization mode or inter-paper patch processing. That is, in the image forming device 1, the period FO of the adjusted light emission, in other words, the light emission timing of the adjusted light emission, changes according to the light emission mode, etc.

The control unit 180 changes the period of transmission of the serial clock signal to the light emission control unit 114 and the start timing of transmission of the signal to the light emission control unit 114 according to the light emission mode, etc., to shift the phase.

<F. Internal Processing>
Next, an internal process related to light emission control of image forming apparatus 1 will be described with reference to Figures 12 to 14. In one aspect, the CPU of control unit 180 may load a program for performing the processes of Figures 12 and 13 from the ROM of control unit 180 or another storage medium into the RAM of control unit 180, and execute the program.

In other aspects, some or all of the processing may be implemented as a combination of circuit elements configured to perform the processing.

Figure 12 is a flowchart showing an example of print processing in the image forming device 1. In step S1210, the control unit 180 transmits the SOS light emission start counter value, the SOS light emission end counter value, the SH light emission start counter value, and the SH light emission end counter value to the light emission control unit 114.

The light emission control unit 114 stores each of these counter values in the counter value memory 404. In step S1220, the control unit 180 transmits a light emission control start command to the light emission control unit 114.

In step S1230, the control unit 180 starts the print process. The control unit 180 drives actuators such as the transport roller 160, the imaging unit 110, and the fixing unit 130.

In step S1240, the light emission control unit 114 executes light emission control. The light emission control includes forming an electrostatic latent image on the surface of the photoconductor, SOS light emission, SH light emission, etc.

In step S1250, the control unit 180 determines whether the print process has ended. If the control unit 180 determines that the print process has ended (YES in step S1250), the control unit 180 transfers control to step S1260. If not (NO in step S1250), the control unit 180 transfers control to step S1240.

In step S1260, the control unit 180 determines whether the end sequence processing has ended. If the control unit 180 determines that the end sequence processing has ended (YES in step S1260), the control unit 180 transfers control to step S1270. If not (NO in step S1260), the control unit 180 repeats the processing of step S1260.

In step S1270, the control unit 180 sends a light emission control stop command to the light emission control unit 114.

During control period C1, when light emission control of the adjusted light emission of the laser diode 116 starts, and when light emission control of the adjusted light emission of the laser diode 116 ends, the control unit 180 prohibits the light emission control unit 114 from performing serial communication to control the laser diode 116.

Figure 13 is a flowchart showing an example of image stabilization processing in the image forming device 1. The image forming device 1 performs image stabilization processing during a period when a print process is not being performed, and adjusts the amount of light emitted by the laser diode 116, etc.

The processing in steps S1310 to S1320 and S1360 is the same as the processing in steps S1210 to S1220 and S1270, so the description of these steps will not be repeated.

In step S1330, the control unit 180 starts image stabilization processing. The image stabilization processing includes, for example, forming a test toner patch on the photoconductor and adjusting the exposure amount of the photoconductor and the amount of toner supplied.

In step S1340, IDC (Image Density Control) sensor calibration control is performed. In step S1350, the control unit 180 executes adhesion amount control, laser diode light amount control, registration control, and gamma correction control. Adhesion amount control is a control that adjusts the amount of toner adhesion to the photoconductor.

Laser diode light amount control is a control that adjusts the light amount (output) of the laser diode 116. Registration control is a control that adjusts the position of the sheet. Gamma correction control is a control that corrects the gradation of the image.

During control period C2, when light emission control of the adjusted light emission of the laser diode 116 starts, and when light emission control of the adjusted light emission of the laser diode 116 ends, the control unit 180 prohibits the light emission control unit 114 from performing serial communication to control the laser diode 116.

Figure 14 shows a list of types of stabilization processes. Each stabilization process includes a different sequence. The control unit 180 divides each stabilization process and transmits it when communicating serially with the light emission control unit 114.

<G. Summary >
The image forming apparatus 1 in this embodiment includes a photoconductor for forming a toner image, at least one laser diode 116 for exposing the photoconductor, a light emission control unit 114 for controlling the light emission of the laser diode 116, and a light emission control The control unit 180 transmits a signal to the light emission control unit 114 for controlling the laser diode 116. The control unit 180 controls the light emission control unit 114 to adjust the light emission control of the laser diode 116. A signal for executing light emission control is transmitted to the light emission control unit 114 when the light emission control of the adjusted light emission of the laser diode 116 is started and when the light emission control of the adjusted light emission of the laser diode 116 is ended. 116 is prohibited from transmitting a signal to control the device.

This prevents the image printed on the sheet from deteriorating even if the light emission control unit 114 receives a signal via serial communication while the photoconductor is being exposed by the laser diode 116.

The adjusted light emission also includes light emission from the laser diode 116 to obtain a horizontal synchronization signal for exposure timing and light emission from the laser diode 116 for sampling the amount of light. According to this, the adjusted light emission includes SH light emission and SOS light emission.

Furthermore, the light emission control unit 114 performs light emission control of the laser diode 116 to adjust the light emission during the process of forming a toner image on the photoconductor.

This allows for regulated light emission control during the process of forming a toner image on the photoconductor.

The signal that the control unit 180 sends to the light emission control unit 114 also includes a signal for controlling the laser diode 116 in a mode for adjusting the state of the toner image.

This makes it possible to prevent the serial communication when setting the stabilization mode from overlapping with the start and end of adjusted light emission.

Furthermore, the signal that the control unit 180 sends to the light emission control unit 114 includes a signal for controlling the laser diode 116 in the process of adjusting the state of the photoconductor.

This makes it possible to prevent the serial communication when performing inter-paper patch processing from overlapping with the start and end of adjusted light emission.

The light emission control unit 114 also controls the laser diode 116 to emit adjusted light during the process of making the potential of the photoconductor uniform. This allows the laser diode 116 to emit adjusted light even during the erase light emission in the end sequence.

The signal that the control unit 180 sends to the light emission control unit 114 also includes a signal for controlling the laser diode 116 to switch between monochrome printing and color printing.

This makes it possible to prevent the serial communication that occurs when switching from monochrome printing to color printing, or from color printing to monochrome printing, from overlapping with the start and end of adjusted light emission.

Furthermore, there are multiple laser diodes 116, and the signal that the control unit 180 sends to the light emission control unit 114 includes a signal for switching which of the multiple laser diodes is to perform light emission control.

This makes it possible to prevent the serial communication that occurs when switching from monochrome printing to color printing, or from color printing to monochrome printing, from overlapping with the start and end of adjusted light emission.

The control unit 180 also transmits the signal for controlling the laser diode 116 in multiple parts. This allows the signal to be transmitted in stages, preventing a large amount of data from being overloaded even when the amount of data to be transmitted via serial communication is large.

Furthermore, the control unit 180 divides the signal for controlling the laser diode 116 into signals for each function of the light emission control unit 114 and transmits them.

This allows the light emission control unit 114 to accept data for each function it has, reducing the risk of partial data loss and preventing unexpected operations.

In addition, the control unit 180 transmits a signal to the light emission control unit 114 to control the laser diode 116 after the light emission control of the adjusted light emission of the laser diode 116 is started and before the light emission control of the adjusted light emission of the laser diode 116 is ended.

This allows the control unit 180 to perform serial communication even during adjusted light emission, avoiding the timing of the start and end of adjusted light emission.

Furthermore, the control unit 180 prohibits the transmission of a signal for controlling the laser diode 116 when light emission control of the adjusted light emission of the laser diode 116 is being performed.

This prevents serial communication when the laser diode 116 is emitting light, which more reliably prevents degradation of the image printed on the sheet.

The light emission control unit 114 also controls the light emission of the laser diode 116 so that the laser diode 116 performs multiple adjusted light emissions at a constant period, and the control unit 180 transmits a signal to the light emission control unit 114 for controlling the laser diode 116 during the successive adjusted light emissions.

According to this, the control unit 180 prevents deterioration of the image printed on the sheet by performing serial communication at the timing between multiple adjusted emissions when adjusted emissions are not being emitted.

Furthermore, the control unit 180 prohibits the emission control unit 114 from starting and ending the transmission of a signal for controlling the laser diode 116 when the light emission control of the adjusted light emission of the laser diode 116 starts and when the light emission control of the adjusted light emission of the laser diode 116 ends.

This prevents degradation of the image printed on the sheet by preventing the timing of the serial clock signal transmission and start from overlapping with the timing of the start and end of the light emission control of the adjusted light emission, for example when the period of the serial clock signal is long.

The light emission control unit 114 also controls the laser diode 116 to emit multiple adjusted lights at a constant cycle, and the control unit 180 transmits a signal to the light emission control unit 114 at a cycle in which the timing of the start and end of the light emission control of the adjusted lights does not overlap with the timing of the start and end of the transmission of the signal to the light emission control unit 114.

By making the period of the adjusted light emission and the period of the serial clock generated by the SK signal the same but shifting the phase, the timing of the transmission and start of the serial clock signal does not overlap with the timing of the start and end of the light emission control of the adjusted light emission, preventing degradation of the image printed on the sheet.

Furthermore, the control unit 180 changes the period of transmitting a signal to the light emission control unit 114 and the start timing of transmitting a signal to the light emission control unit 114 depending on the light emission mode of the laser diode 116.

The control unit 180 can change the period of the serial clock generated by the SK signal so that it is the same depending on the period of the adjusted light emission, which changes depending on the light emission mode.

The control method in this embodiment is a control method for an image forming device 1 that includes a photoconductor that forms a toner image, a laser diode 116 that exposes the photoconductor, at least one light emission control unit 114 that controls the light emission of the laser diode 116, and a control unit 180.

The control method includes the steps of causing the light emission control unit 114 to transmit a signal to the control unit 180 for controlling the laser diode 116, causing the light emission control unit 114 to transmit a signal to the control unit 180 for executing control of the adjusted light emission for adjusting the light emission control of the laser diode 116, and prohibiting the transmission of a signal to the light emission control unit 114 when the light emission control of the adjusted light emission of the laser diode 116 is started and when the control of the adjusted light emission of the laser diode 116 is ended.

The embodiments disclosed herein should be considered to be illustrative and not restrictive in all respects. The scope of the present invention is indicated by the claims, not by the above description, and is intended to include all modifications within the meaning and scope of the claims.

1 Image forming apparatus, 11C, 11K, 11M, 11Y Photoconductor, 110 Imaging unit, 100 Print engine, 112 Exposure unit, 113 Print head unit, 114 Light emission control unit, 115 Polygon motor, 116 Laser diode, 117, 513 Light sensor, 118 Dust sensor, 119 Humidity sensor, 120 Intermediate transfer belt, 130 Fixing unit, 140 Paper feed unit, 150 Feed roller, 160 Transport roller, 170 Registration roller, 180 Control unit, 181 Image processing unit, 182 Light emission mode control unit, 190 Power supply unit, 200 Reading unit, 210 Image scanner, 220 Automatic document feeder, 230 Paper feed tray, 240 Paper discharge tray, 300 Operation panel, 302 Image signal line, 303 Serial signal line, 304, 801A, 801B, 1001, 1002, 1003A, 1003B signal line, 321 polygon mirror, 322 fθ lens, 402 laser diode drive unit, 403 timing signal generation unit, 404 counter value memory, 405 counter, 406 light quantity correction unit, 407 correction value memory, 409 reference clock generation unit, 410 error detection unit, 502C, 502K, 502M, 502Y collimator lens, 601, 602, 603 adjusted light emission, 701, 702, 902 serial communication, 1004A, 1004B AND circuit.

Claims (16)

A photoconductor on which a toner image is formed;
At least one light emitting element for exposing the photoreceptor;
a light emission control unit that controls light emission of the light emitting element;
a control unit that transmits a signal to the light emission control unit to control the light emitting element,
The control unit is
Transmitting a signal to the light emission control unit to execute light emission control of adjusted light emission for adjusting light emission control of the light emitting element;
prohibiting the light emission control unit from transmitting a signal for controlling the light emitting element when the light emission control of the adjusted light emission of the light emitting element is started and when the light emission control of the adjusted light emission of the light emitting element is ended ;
The image forming apparatus , wherein the adjusted light emission includes light emission of the light emitting element for obtaining a horizontal synchronization signal for exposure timing and light emission of the light emitting element for sampling a light amount . The image forming apparatus according to claim 1 , wherein the light emission control unit executes light emission control of the adjusted light emission on the light emitting element during a process of forming a toner image on the photoconductor. 3. The image forming apparatus according to claim 1, wherein the signal sent from the control unit to the light emission control unit includes a signal for controlling the light emitting element in a mode for adjusting a state of the toner image. 4. The image forming apparatus according to claim 1 , wherein the signal sent from the control unit to the light emission control unit includes a signal for controlling the light emitting element in a process for adjusting a state of the photoconductor. 5. The image forming apparatus according to claim 1 , wherein the signal sent from the control unit to the light emission control unit includes a signal for controlling the light emitting element in a process for making the potential of the photoconductor uniform. The image forming apparatus according to any one of claims 1 to 5 , wherein the signal sent from the control unit to the light emission control unit includes a signal for controlling the light emitting element to switch between monochrome printing processing and color printing processing. The light-emitting element is a plurality of elements,
The image forming apparatus according to any one of claims 1 to 6 , wherein the signal transmitted from the control unit to the light emission control unit includes a signal for switching which of the plurality of light-emitting elements is to be subjected to light emission control. 8. The image forming apparatus according to claim 4 , wherein the control unit transmits a signal for controlling the light emitting element in a divided manner a plurality of times. The image forming apparatus according to claim 8 , wherein the control unit transmits a signal for controlling the light emitting element by dividing the signal into signals for each function of the light emission control unit. The image forming apparatus according to any one of claims 1 to 9, wherein the control unit transmits a signal to the light emission control unit to control the light-emitting element from after the light emission control of the adjusted light emission of the light-emitting element has started until before the light emission control of the adjusted light emission of the light-emitting element has ended. The image forming apparatus according to any one of claims 1 to 9 , wherein the control unit prohibits transmission of a signal for controlling the light-emitting element when light emission control of the adjusted light emission of the light-emitting element is being executed. the light emission control unit executes light emission control of the light emitting element such that the light emitting element performs the adjusted light emission a plurality of times at a constant cycle;
The image forming apparatus according to claim 11 , wherein the control unit transmits a signal to the light emission control unit to control the light emitting element during the successive adjusted light emissions. The image forming apparatus according to any one of claims 1 to 9, wherein the control unit prohibits the start and end of transmission of a signal for controlling the light-emitting element to the light-emitting control unit when the light-emitting control of the adjusted light-emitting of the light-emitting element is started and when the light-emitting control of the adjusted light-emitting of the light-emitting element is ended. The light emission control unit executes control for the light emitting element to perform the adjusted light emission a plurality of times at a constant cycle,
The image forming apparatus according to claim 13 , wherein the control unit transmits a signal to the light emission control unit in a cycle in which the timing of starting and ending the light emission control of the adjusted light emission does not overlap with the timing of starting and ending the transmission of a signal to the light emission control unit. The image forming apparatus according to claim 14 , wherein the control unit changes a period of transmitting a signal to the light emission control unit and a start timing of transmitting a signal to the light emission control unit according to a light emission mode of the light emitting element. A method for controlling an image forming apparatus including a photoconductor that forms a toner image, a light-emitting element that exposes the photoconductor, at least one light-emitting control unit that controls light emission of the light-emitting element, and a control unit, comprising:
causing the light emission control unit to transmit a signal for controlling the light emitting element to the control unit;
a step of causing the light emission control unit to transmit a signal for executing control of adjusted light emission for adjusting light emission control of the light emitting element to the light emission control unit;
prohibiting transmission of a signal to the light emission control unit when light emission control of the adjusted light emission of the light-emitting element is started and when control of the adjusted light emission of the light-emitting element is ended;
A control method in which the adjusted light emission includes light emission of the light emitting element for obtaining a horizontal synchronization signal for exposure timing and light emission of the light emitting element for sampling the amount of light .

Images