JP5135878B2 - Image forming apparatus and exposure apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus and an exposure apparatus.

Japanese Patent Application Laid-Open No. H10-228561 describes an exposure apparatus used in an image forming apparatus using an electrophotographic system, which uses a light emitting element array in which a plurality of light emitting elements such as LEDs are arranged in a line.
Patent Document 2 describes a self-scanning LED that employs a thyristor as a switch element for selectively turning on / off a light emitting element as a light emitting element array.

JP 2006-21533 A JP-A-2-263668

Here, in general, in an exposure apparatus using a plurality of light emitting elements, when the light emitting elements are not normally turned on / off, there is a problem that an image defect occurs.
An object of the present invention is to suppress the occurrence of image defects in an image forming apparatus equipped with an exposure apparatus using a plurality of light emitting elements.

According to a first aspect of the present invention, an image carrier, a plurality of light emitting elements arranged in a row are turned on based on image data, and the exposure unit that exposes the image carrier, and the plurality of light sources based on the image data. A signal generation unit configured to generate a signal for sequentially lighting each light emitting element along the array; and a detection unit configured to detect occurrence of a state where the plurality of light emitting elements are not sequentially turned on, the signal generation unit including the detection unit When the state is detected by the above , the lighting in the adjacent light emitting element adjacent to the one light emitting element along the array from the end of the lighting period assigned to turn on the one light emitting element set by the signal is an image forming apparatus, characterized in that in place of the first time interval defined the time interval previously set to second time interval longer than the first time interval until the start of the period

According to a second aspect of the present invention, in the image forming apparatus according to the first aspect , the signal generating unit is set with a plurality of different time intervals as the second time interval.
The invention according to claim 3, in the image forming apparatus according to claim 1, wherein the image data to obtain the, further comprising a changing means for changing the acquired image resolution of the image data, wherein the changing means, wherein When the signal generating unit sets the second time interval, the image resolution in the sub-scanning direction of the acquired image data is changed to be lower than when the signal generating unit sets the first time interval. The signal generating means generates the signal corresponding to the image data whose image resolution in the sub-scanning direction has been changed to be low by the changing means when the second time interval is set. To do.

The invention according to claim 4, in the image forming apparatus according to claim 1, a first moving speed which is set when said signal generating means sets the first time interval, the said signal generating means the second Ru is set when setting the time interval, it is configured to move in one of the said first slower than the moving speed of the one or more second moving speed, the signal generating means Is characterized in that, when the second time interval is set, the signal corresponding to the state in which the moving speed of the image carrier is set to the second moving speed is generated.
According to a fifth aspect of the present invention, in the image forming apparatus according to the first aspect, the signal generating unit sets an upper limit value of a lighting time of the light emitting element.
According to a sixth aspect of the present invention, in the image forming apparatus according to the first aspect, a test pattern image forming unit that forms a predetermined test pattern image in the main scanning direction of the exposure unit on the image carrier, Image density detecting means for detecting the image density of the test pattern image formed by the test pattern image forming means in the main scanning direction of the exposure means, and the signal generating means includes the image density detecting means. The second time interval is set instead of the first time interval based on the image density of the test pattern image detected in step ( 1 ).

The invention according to claim 7, a plurality of light emitting elements arranged in rows, and signal generating means for generating a signal to turn on in sequence along said plurality of light emitting elements each array on the basis of the image data, wherein Detecting means for detecting occurrence of a state in which a plurality of light emitting elements are not sequentially turned on, and the signal generating means is configured to detect one light emitting element set by the signal when the state is detected by the detecting means. The time interval between the end of the lighting period assigned for lighting and the start of the lighting period in the adjacent light emitting element adjacent to the one light emitting element along the array is replaced with a predetermined time interval. An exposure apparatus is characterized in that a time interval longer than a predetermined time interval is set .

According to an eighth aspect of the present invention, in the exposure apparatus according to the seventh aspect , the storage unit stores a plurality of different time intervals as time intervals longer than the predetermined time interval set by the signal generation unit. Is further provided.
The invention according to claim 9 is the exposure apparatus according to claim 7 , wherein the signal generating means sets an upper limit value of a lighting time of the light emitting element.

According to the first aspect of the present invention, compared with the case where the present invention is not adopted, in the image forming apparatus equipped with the exposure apparatus using the self-scanning LED, the occurrence of the image defect due to the transfer defect is suppressed. Can do.
According to the second aspect of the present invention, as compared with the case where the present invention is not adopted, a different drive signal is generated according to the occurrence state of the image defect, so that the LED lighting time is set as long as possible to emit light. It is possible to suppress a decrease in the light amount of the element.
According to the third aspect of the present invention, the effect of suppressing the occurrence of image defects can be enhanced as compared with the case where the present invention is not adopted.
According to the fourth aspect of the present invention, the effect of suppressing the occurrence of image defects can be enhanced as compared with the case where the present invention is not adopted.

According to claim 5 of the present invention, by providing an upper limit of the lighting time of the light emitting element having a correction width, it is possible to suppress an increase in the light amount variation of the light emitting element as compared with the case where the present invention is not adopted. it can.
According to claim 6 of the present invention, when an image defect actually occurs, a drive signal that is less likely to cause an image defect than a drive signal that drives an LED set during a normal image forming operation is generated. The state in which the light amount of the light emitting element is reduced is prevented from being set unnecessarily, and a high-quality image can be provided when no image defect occurs.

According to the seventh aspect of the present invention, in comparison with the case where the present invention is not adopted, in the exposure apparatus using the self-scanning LED, when the image forming apparatus is mounted on the image forming apparatus, the occurrence of the image defect due to the transfer defect is generated. Can be suppressed.
According to the eighth aspect of the present invention, compared to the case where the present invention is not adopted, the process of generating a drive signal that is less likely to cause image defects than the drive signal for driving the LED set during the normal image forming operation. Can be done quickly.
According to claim 9 of the present invention, by providing an upper limit of the lighting time of the light emitting element having a correction width, it is possible to suppress an increase in the light amount variation of the light emitting element compared to the case where the present invention is not adopted. it can.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 is a diagram illustrating an example of the overall configuration of an image forming apparatus 1 to which the exemplary embodiment is applied. An image forming apparatus 1 shown in FIG. 1 is a multi-function machine having a copying function, a facsimile function, and a printing function in combination. For example, printing of image data generated by a personal computer (PC) 3 or the like, Print image data received by facsimile, copy image, etc. Specifically, the image forming apparatus 1 according to the present embodiment illustrated in FIG. 1 includes an image forming process unit 10 that forms an image corresponding to image data of each color, and a control unit that controls the operation of the entire image forming apparatus 1. 30, an image reading unit 35 configured by a scanner, a facsimile (FAX) function unit 36 that transmits and receives an image through a public line, an image reading unit 35, image data received from an external device such as a PC 3, and the like. An image processing unit 37 that performs image processing and a main power supply 70 that supplies power to each unit are provided.

The image forming process unit 10 includes four image forming units 11Y, 11M, 11C, and 11K (hereinafter, simply referred to as “image forming unit 11”) that are arranged in parallel at regular intervals. Yes. Each of the image forming units 11 is a photosensitive drum 12 as an example of an image carrier that forms an electrostatic latent image and holds a toner image, and a charger 13 that uniformly charges the surface of the photosensitive drum 12 with a predetermined potential. An LED print head (LPH) 14 as an example of an exposure means (exposure device) that exposes the photosensitive drum 12 charged by the charger 13 based on image data, and an electrostatic latent image formed on the photosensitive drum 12. A developing unit 15 for developing an image and a drum cleaner 16 for cleaning the surface of the photosensitive drum 12 after transfer are provided.
Each image forming unit 11 is configured in substantially the same manner except for the toner stored in the developing device 15. The image forming units 11Y, 11M, 11C, and 11K form yellow (Y), magenta (M), cyan (C), and black (K) toner images, respectively.

Further, the image forming process unit 10 includes an intermediate transfer belt 20 onto which the color toner images formed on the photosensitive drums 12 of the image forming units 11 are transferred, and the color toner images of the image forming units 11 to the intermediate transfer belt. A primary transfer roll 21 that sequentially transfers (primary transfer) to 20 and a secondary transfer roll 22 that collectively transfers (secondary transfer) the toner image transferred onto the intermediate transfer belt 20 onto a sheet P that is a recording material (recording paper). And a fixing device 50 for fixing the second-transferred toner image on the paper P.
Further, the image density of each color test pattern (see the subsequent stage) that is primarily transferred to the intermediate transfer belt 20 at a position downstream of the image forming unit 11K in the conveyance direction of the intermediate transfer belt 20 and upstream of the secondary transfer portion T2. A concentration detection sensor 55 for detecting the above is provided.

  In the image forming apparatus 1 according to the present embodiment, image data input from the PC 3 or the image reading unit 35 is subjected to predetermined image processing by the image processing unit 37, and each image forming unit of the image forming process unit 10 is processed. 11 is supplied. The image data received by the FAX function unit 36 is also supplied to each image forming unit 11 of the image forming process unit 10. Then, each image forming unit 11 forms each color toner image based on each color image data. For example, in the black (K) image forming unit 11K, the photosensitive drum 12 is uniformly charged at a predetermined potential by the charger 13 while rotating in the direction of arrow A. The photosensitive drum 12 is exposed by the LPH 14 that is turned on based on the black (K) image data from the image processing unit 37. Thereby, an electrostatic latent image related to a black (K) color image is formed on the photosensitive drum 12. The electrostatic latent image formed on the photosensitive drum 12 is developed by the developing device 15, and a black (K) toner image is formed on the photosensitive drum 12. Similarly, in the image forming units 11Y, 11M, and 11C, yellow (Y), magenta (M), and cyan (C) color toner images are formed, respectively.

  Each color toner image formed by each image forming unit 11 is sequentially electrostatically transferred (primary transfer) onto the intermediate transfer belt 20 that circulates in the direction of arrow B in the primary transfer portion T1 where the primary transfer roll 21 is disposed. The As a result, a composite toner image in which the toners of the respective colors are superimposed is formed on the intermediate transfer belt 20. The synthetic toner image on the intermediate transfer belt 20 is conveyed to the secondary transfer portion T2 where the secondary transfer roll 22 is disposed as the intermediate transfer belt 20 moves. Further, the paper P is transported from the paper holding unit 40 to the secondary transfer unit T2 in accordance with the timing at which the toner image is transported to the secondary transfer unit T2. Then, in the secondary transfer portion T <b> 2, the composite toner image is collectively electrostatically transferred onto the paper P by the transfer electric field formed by the secondary transfer roll 22.

The sheet P on which the composite toner image has been electrostatically transferred is peeled off from the intermediate transfer belt 20, guided to the conveyance guide 23, and conveyed to the fixing device 50. In the fixing device 50, the synthetic toner image is fixed by receiving a fixing process using heat and pressure. Then, the fixed sheet P is conveyed to a paper discharge stacking unit 45 provided in a discharge unit of the image forming apparatus 1.
Further, the toner (primary transfer residual toner) adhering to the photosensitive drum 12 after the primary transfer is removed by the drum cleaner 16. Further, toner (secondary transfer residual toner) adhering to the intermediate transfer belt 20 after the secondary transfer is removed by the belt cleaner 25. Then, it is prepared for the next image forming cycle.
In the image forming apparatus 1, such an image forming cycle is repeatedly executed by the number of prints.

  Next, FIG. 2 is a cross-sectional configuration diagram of the LED print head (LPH) 14. 2, the LPH 14 includes an LED circuit board 62 on which a housing 61 as a support, a self-scanning LED array (SLED) 63, a signal generation circuit 100 (see FIG. 3 at a later stage) for driving the SLED 63 and the SLED 63, and the like are mounted. A rod lens array 64 that forms an image of light emitted from the SLED 63 on the surface of the photosensitive drum 12, a holder 65 that supports the rod lens array 64 and shields the SLED 63 from the outside, and a plate that pressurizes the housing 61 toward the rod lens array 64 A spring 66 is provided.

The housing 61 is formed of a metal block such as aluminum or SUS or a sheet metal, and supports the LED circuit board 62. The holder 65 supports the housing 61 and the rod lens array 64, and is set so that the SLED 63 and the rod lens array 64 maintain a predetermined optical positional relationship. Furthermore, the holder 65 is configured to seal the SLED 63. This prevents dust from adhering to the SLED 63 from the outside. On the other hand, the leaf spring 66 presses the LED circuit board 62 in the direction of the rod lens array 64 via the housing 61 so as to maintain the optical positional relationship between the SLED 63 and the rod lens array 64.
The LPH 14 configured in this manner is configured to be movable in the optical axis direction of the rod lens array 64 by an adjustment screw (not shown), and the imaging position (focal plane) of the rod lens array 64 is the surface of the photosensitive drum 12. It is adjusted so that it is located above.

As shown in FIG. 3 (plan view of the LED circuit board 62), the LED circuit board 62 includes, for example, SLEDs 63 composed of 58 SLED chips (CHIP1 to CHIP58) in parallel with the axial direction of the photosensitive drum 12. Are arranged in a line with high accuracy. In this case, each LED array is arranged continuously at the connection portion between the SLED chips at the end boundary of the arrangement (LED array) of the light emitting elements (LEDs) arranged in each SLED chip (CHIP1 to CHIP58). In addition, the SLED chips are alternately arranged in a staggered pattern.
Further, the LED circuit board 62 stores a signal generation circuit 100 and a level shift circuit 104 that generate a signal (drive signal) for driving the SLED 63, a three-terminal regulator 101 that outputs a predetermined voltage, light amount correction data of the SLED 63, and the like. A harness 103 that receives signals from the EEPROM 102, the control unit 30, and the image processing unit 37 and receives power from the main power source 70 is provided.

Next, the SLED 63 provided on the LED circuit board 62 will be described. FIG. 4 is a diagram for explaining an example of the circuit configuration of the SLED 63. The SLED 63 shown in FIG. 4 shows an SLED chip for an image resolution of 1200 dpi (dots per inch) as an example, and 256 light emitting points (LEDs) are arranged per SLED chip.
The SLED 63 of the present embodiment is connected to the signal generation circuit 100 via the level shift circuit 104. The level shift circuit 104 has a configuration in which a resistor R1B and a capacitor C1, and a resistor R2B and a capacitor C2 are arranged in parallel, one end of which is connected to the input terminal of the SLED 63, and the other end of the signal generation circuit 100. Connected to the output terminal. The transfer signal CK1 and the transfer signal CK2 are output to the SLED 63 based on the transfer signals CK1R and CK1C and the transfer signals CK2R and CK2C output from the signal generation circuit 100.
In the SLED 63 of the present embodiment, 58 SLED chips are arranged in series, but FIG. 4 shows only one SLED chip and a signal line connected thereto. In the description of FIG. 4, the SLED chip is referred to as SLED 63 for convenience.

The SLED 63 of the present embodiment shown in FIG. 4 includes 256 thyristors S1 to S256 (hereinafter also simply referred to as “thyristor S”) as an example of a switch element, and 256 LEDs L1 as an example of a light emitting element. ˜L256, 256 diodes D1 to D256, 256 resistors R1 to R256, and transfer current limiting resistors R1A and R2A for preventing excessive current from flowing through the signal lines φ1 and φ2.
In the SLED 63 shown in FIG. 4, the anode terminals (input terminals) A1 to A256 of the thyristors S1 to S256 and the anode terminals AL1 to AL256 of the LEDs L1 to L256 are connected to the power supply line 105. The power supply line 105 is supplied with a voltage VDD (VDD = + 3.3 V) output from the three-terminal regulator 101.
.., S255, the transfer signal CK1 from the signal generation circuit 100 and the level shift circuit 104 is transferred to the cathode terminals (output terminals) K1, K3,... K255 of the odd-numbered thyristors S1, S3,. Supplied from the signal line φ1.
In addition, the transfer signal CK2 from the signal generation circuit 100 and the level shift circuit 104 is transferred to the cathode terminals (output terminals) K2, K4,..., K256 of the even-numbered thyristors S2, S4,. Is supplied from the signal line φ2.

On the other hand, the gate terminals (control terminals) G1 to G256 of the thyristors S1 to S256 are connected to the gate terminals of the LEDs L1 to L256 provided corresponding to the thyristors S1 to S256, respectively.
Further, the cathode terminals of the diodes D1 to D256 are connected to the gate terminals G1 to G256 of the thyristors S1 to S256. The gate terminals G1 to G255 of the thyristors S1 to S255 are connected to the anode terminals of the next-stage diodes D2 to D256, respectively. That is, the diodes D1 to D256 are connected in series with the gate terminals G1 to G255 interposed therebetween.
The anode terminal of the diode D1 is connected to the signal generation circuit 100 via the transfer current limiting resistor R2A and the level shift circuit 104, and the transfer signal CK2 is transmitted. Further, the cathode terminals of the LEDs L1 to L256 are connected to the signal generation circuit 100, and the lighting signal ΦI is transmitted.

Next, the signal generation circuit 100 provided on the LED circuit board 62 will be described.
FIG. 5 is a block diagram illustrating a configuration of the signal generation circuit 100. The signal generation circuit 100 includes an image data development unit 110, a density unevenness correction data unit 112, a timing signal generation unit 114, a reference clock generation unit 116, and a lighting time control / drive unit 118 (118-1 to 118-58). Yes.
The image data development unit 110 converts the image data serially transmitted from the image processing unit 37 into each SLED chip (CHIP1 to CHIP1 to 256th dot, 257th to 512th dot,..., 14593 to 14848th dot). A process of dividing the image data to be transmitted for each CHIP 58) is performed. The divided image data is output to the lighting time control / drive units 118-1 to 118-58.

The density unevenness correction data unit 112 acquires light amount correction data for each LED from the EEPROM 102 in which the light amount correction data for each LED is stored. Then, based on the light amount correction data for each LED, density unevenness correction data Corr for correcting image density unevenness caused by variations in the light amount for each LED in the SLED 63 is generated. The density unevenness correction data Corr is output to the lighting time control / drive units 118-1 to 118-58 in synchronization with the data read signal from the density unevenness correction data unit 112. The density unevenness correction data Corr is data set for each LED, and is formed, for example, as 8-bit (0 to 255) data.
The reference clock generation unit 116 outputs a reference clock signal corresponding to the light amount adjustment data transmitted from the control unit 30 to the timing signal generation unit 114 and the lighting time control / drive units 118-1 to 118-58. The light amount adjustment data is a light amount instruction value that uniformly sets the light amount of each LED arranged in the SLED 63. In the image forming apparatus 1, for example, fluctuations in sensitivity of the photosensitive drum 12, fluctuations in the latent image potential (dark part potential V _H or bright part potential V _L ), and fluctuations in the developer amount in the developing device 15 are factors. As a result, the toner image density varies. For this reason, for example, the light quantity of the LEDs arranged in the LPH 14 is uniformly adjusted by the light quantity adjustment data formed as 10-bit (0 to 1023) data to suppress the fluctuation of the toner image density.

The timing signal generator 114 generates the transfer signals CK1R and CK1C and the transfer signals CK2R and CK2C in synchronization with the horizontal synchronization signal (Lsync) from the control unit 30 based on the reference clock signal from the reference clock generator 116. . The transfer signals CK1R and CK1C and the transfer signals CK2R and CK2C are transferred to the SLED 63 through the level shift circuit 104 as the transfer signal CK1 and the transfer signal CK2. In FIG. 5, the timing signal generator 114 is described to output one set of transfer signals CK1R and CK1C and transfer signals CK2R and CK2C. Transfer signals CK1R and CK1C and transfer signals CK2R and CK2C are output.
Further, the timing signal generator 114 reads image data corresponding to each pixel from the image data developing unit 110 in synchronization with the Lsync signal from the controller 30 based on the reference clock signal from the reference clock generator 116. And a data read signal for reading out density unevenness correction data corresponding to each pixel (each LED) from the density unevenness correction data unit 112. Further, the timing signal generation unit 114 is also connected to the lighting time control / drive units 118-1 to 118-58, and based on the reference clock signal from the reference clock generation unit 116, the trigger signal TRG for starting the lighting of the SLED 63. Is output.

The lighting time control / drive units 118-1 to 118-58 correct the lighting time (lighting pulse width) of each pixel (each LED) based on density unevenness correction data and the like, and light each pixel of the SLED 63. The lighting signal ΦI (ΦI1 to ΦI58) is generated.
In addition, a three-terminal regulator 101 is connected to the SLED 63, and an output voltage VDD = + 3.3V from the three-terminal regulator 101 is supplied to drive the SLED 63.

The signal generation circuit 100 configured in this way is connected to the SLED 63 via the level shift circuit 104 by wiring formed on the LED circuit board 62. Then, a signal (driving signal) for driving the SLED 63 such as the generated lighting signal ΦI (ΦI1 to ΦI58), the transfer signals CK1R and CK1C, the transfer signals CK2R and CK2C, the transfer signal CK1 and the transfer signal CK2 is output.
FIG. 6 is a diagram showing wiring between the signal generation circuit 100 and the level shift circuit 104 and the SLED 63 on the LED circuit board 62. As shown in FIG. 6, on the LED circuit board 62, from the power supply line 105 that supplies the output voltage from the three-terminal regulator 101 to each SLED chip, the grounded (GND) power supply line 106, and the signal generation circuit 100. A signal line 107 (107_1 to 107_58) that transmits a lighting signal ΦI (ΦI1 to ΦI58) to each SLED chip, and a signal line that transmits a transfer signal CK1 (CK1_1 to 1_6) from the level shift circuit 104 to each SLED chip. 108 (108_1 to 108_6) and a signal line 109 (109_1 to 109_6) for transmitting the transfer signal CK2 (CK2_1 to 2_6) are wired. At that time, six sets of transfer signals CK1 (CK1_1 to CK1_6) and CK2 (CK2_1 to CK2_6) are connected to 9 to 10 SLED chips for each set of transfer signals CK1 and CK2.

FIG. 7 is a timing chart for explaining the output timing of the drive signals output from the signal generation circuit 100 and the level shift circuit 104. In the timing chart shown in FIG. 7, the case where all LEDs perform optical writing (lights up) is described.
(1) First, when a reset signal is input from the control unit 30 to the signal generation circuit 100, the transfer signal CK1C is at a high level (hereinafter referred to as “H”) in the timing signal generation unit 114 of the signal generation circuit 100. The transfer signal CK1R is set to “H”, and the transfer signal CK1 is set to “H”. Further, the transfer signal CK2C is set to a low level (hereinafter referred to as “L”), the transfer signal CK2R is set to “L”, and the transfer signal CK2 is set to “L”. Thereby, all the thyristors S1 to S256 of the SLED 63 are set to an off state (FIG. 7A).
(2) Following the reset signal, the horizontal synchronization signal Lsync output from the control unit 30 becomes “H” (FIG. 7A), and the operation of the SLED 63 is started. Then, in synchronization with the horizontal synchronization signal Lsync, as shown in FIGS. 7E, 7F, and 7G, the transfer signal CK2C and the transfer signal CK2R are set to “H”, and the transfer signal CK2 is set to “H”. (FIG. 7B).

  (3) Next, as shown in FIG. 7C, the transfer signal CK1R is set to “L” (FIG. 7C). FIG. 8 is a diagram for explaining a current flow in the level shift circuit 104 when the transfer signal CK1R is set to “L” from the initial state. As shown in FIG. 8, by setting the transfer signal CK1R to “L”, in the level shift circuit 104, a current flows in the direction of the dashed arrow, and the potential of the transfer signal CK1 eventually becomes GND. On the other hand, since the potential of the transfer signal CK1C is 3.3V (“H”), the potential across the capacitor C1 is 3.3V (= VDD).

  (4) Subsequently, as shown in FIG. 7B, the transfer signal CK1C is set to “L” (FIG. 7D). FIG. 9 is a diagram illustrating the flow of current immediately after the transfer signal CK1C is set from “H” to “L”. In FIG. 9, the thyristor S1 is represented by a transistor Tr1 and a transistor Tr2. As shown in FIG. 9, since the electric charge is accumulated in the capacitor C1 (see FIG. 8), the potential of the transfer signal CK1 is about −3.3V by sufficiently taking the period of FIG. 7 (c). It becomes. The potential of the transfer signal CK1 at this time is referred to as a “level shift voltage”. In this case, since the transfer signal CK2 in FIG. 7G is “H” (see FIG. 7D), the gate G1 potential is CK2 potential−Vf = about 1.8V. Here, Vf is a forward voltage of the diode D1, and is about 1.5V. Thereby, φ1 potential = G1 potential−Vf ′ = about 0.3V. Vf ′ is a forward voltage (between the emitter and the base) of the transistor Tr2, which is about 1.5V. For this reason, a potential difference of about 3.6 V is generated between the signal line φ1 and the transfer signal CK1.

Thereby, in the state where the level shift voltage of −3.3V is generated, the gate current of the thyristor S1 flows through the route (broken arrow) of the gate G1 → the signal line φ1 → the transfer signal CK1, as shown in FIG. start. At that time, the tri-state buffer B1R (see FIG. 4) of the signal generation circuit 100 is set to high impedance (HiZ), thereby preventing current backflow.
Thereafter, Tr2 is turned on by the gate G1 current of thyristor S1, whereby the base current of Tr1 (the collector current of Tr2) flows, and thyristor S1 begins to turn on in the order that Tr1 is turned on (turn on).
Along with this, the gate G1 current gradually increases, and the current flows into the capacitor C1 of the level shift circuit 104 (broken arrow). Thereby, as shown in FIG. 7D, the potential of the transfer signal CK1 also gradually increases.

(5) After a predetermined time (time when the transfer signal CK1 potential becomes close to GND) elapses, the tristate buffer B1R of the signal generation circuit 100 is set to “L” (FIG. 7E). As a result, the potential of the signal line φ1 and the potential of the transfer signal CK1 rise due to the rise of the gate G1 potential, and accordingly, current starts to flow to the resistor R1B side of the level shift circuit 104. On the other hand, the current flowing into the capacitor C1 of the level shift circuit 104 gradually decreases as the potential of the transfer signal CK1 increases. Then, the thyristor S1 is completely turned on. When the thyristor S1 is in a steady state, a current for holding the thyristor S1 in the on state flows to the resistor R1B of the level shift circuit 104, but does not flow to the capacitor C1.
At this time, as shown in FIG. 7B, the tristate buffer B1C of the signal generation circuit 100 is set to high impedance (Hiz) (FIG. 7E).

  (6) With the thyristor S1 completely turned on, the lighting signal ΦI is set to “L” as shown in FIG. 7H (FIG. 7F). At this time, the gate G2 potential = the gate G1 potential−Vf = about 0.3 V, and the gate G1 potential> the gate G2 potential. Therefore, the LED L1 having a thyristor structure is turned on earlier and is lit. As the LED L1 is turned on, the potential of the signal line φ1 rises, so that the LEDs after the LED L2 are not turned on. That is, for the LEDs L1, L2, L3, L4,..., Only the LED L1 having the highest gate G1 potential is turned on (lit).

(7) Next, as shown in FIG. 7 (F), when the transfer signal CK2R is set to “L” (FIG. 7 (g)), a current flows as in FIG. A voltage of about −3.3V is generated across the capacitor C2 104.
(8) As shown in FIG. 7E, when the transfer signal CK2C is set to “L” in this state (FIG. 7H), the thyristor S2 is turned on.
(9) Then, as shown in FIGS. 7B and 7C, when the transfer signals CK1C and CK1R are simultaneously set to “H” (FIG. 7I), the thyristor S1 is turned off and passes through the resistor R1. As a result of the discharge, the potential of the gate G1 gradually decreases. Thereafter, the thyristor S2 is completely turned on. Then, by setting the lighting signal ΦI to “L” in synchronization with the thyristor S2 being turned on, the LED L2 can be turned on. In this case, since the potential of the gate G1 is already lower than the potential of the gate G2, the LED L1 is not turned on.
Here, the period from when one thyristor S (here thyristor S2) is turned on until the preceding thyristor S (here thyristor S1) is turned off is Ta, and the preceding thyristor S (here thyristor S1) is turned off. The time interval from when the current thyristor S (here thyristor S2) is completely turned on is Tb, and the time interval set by Ta + Tb is referred to as “transfer time”. This transfer time is the time from when the thyristor S is turned on until it is completely turned on. During this transfer time, both the preceding thyristor (here thyristor S1) and the succeeding thyristor (here thyristor S2) cannot be turned on. Therefore, the period (lighting period) allocated for lighting one LED is set before and after the transfer time, and the lighting pulse width of the lighting signal ΦI is set within the lighting period (see FIG. 7H). ).
(10) Such an operation is sequentially performed, and the LEDs L1 to L256 are sequentially turned on.

As described above, in the signal generation circuit 100 of the present embodiment, the timing signal generator 114 outputs the transfer signals CK1C and CK1R and the transfer signals CK2C and CK2R from “H” to “L” and “L” at predetermined timings, respectively. To “H”. Accordingly, the odd-numbered thyristors S1, S3,..., S255 are sequentially turned off by repeatedly setting the potential of the transfer signal CK1 from the level shift circuit 104 from “H” to “L” and from “L” to “H”. → Operate from on to off. Further, by alternately setting the potential of the transfer signal CK2 from the level shift circuit 104 from “H” to “L” and from “L” to “H” alternately with the transfer signal CK1, the even-numbered thyristor S2, S4,..., S256 are sequentially operated from OFF to ON to OFF. Accordingly, the thyristors S1 to S256 are sequentially turned off, on, and off in the order of S1, S2,..., S255, and S256, and are synchronized with the lighting time control / drive units 118-1 to 118-. The lighting signals ΦI1 to ΦI58 are output from the LED 58 so that the LEDs L1 to L256 are sequentially lit.
In the LPH 14 according to the present embodiment, since the SLED 63 is driven by three drive signals of the lighting signal ΦI, the transfer signal CK1, and the transfer signal CK2, the wiring is simplified, the LPH 14 is downsized, and the LPH 14 is mounted. The image forming apparatus 1 can be downsized.

  Incidentally, at the stage shown in FIG. 7D, the transfer signal CK1C is set from “H” to “L”, and the potential of the transfer signal CK1 is set to about −3.3 V (level shift voltage) (FIG. 7). 9). However, the level shift voltage becomes about −3.3 V because the period of FIG. 7C, that is, the time for setting the transfer signal CK1R to “L” and the transfer signal CK1C to “H” is set sufficiently long. (For example, about 200 nsec), the capacitor C1 is fully charged to the rated capacity. If the period shown in FIG. 7C is set to a time long enough for the capacitor C1 to be fully charged to the rated capacity, high-speed data transfer can be performed when a high-resolution SLED 63 such as 1200 dpi is used. It becomes difficult. Therefore, normally, the period of FIG. 7C is set shorter than the time during which the capacitor C1 is charged to the rated capacity. Therefore, the level shift voltage actually set in FIG. 7D is used with a negative voltage value whose absolute value is smaller than −3.3V. The same applies to the capacitor C2 charged in the period of FIG.

On the other hand, the capacitances of the capacitors C1 and C2 generally vary due to the influence of temperature. For example, when the temperature rises, the capacitances of the capacitors C1 and C2 decrease. When the capacitances of the capacitors C1 and C2 are reduced, the amount of charge charged in the capacitors C1 and C2 is reduced within the period of FIGS. 7C and 7G. In particular, as described above, when the period of FIGS. 7C and 7G is set shorter than the time during which the capacitors C1 and C2 are charged to the rated capacity, the capacitors C1 and C2 are charged. The amount of charge is greatly affected. For example, FIG. 10 shows the charging time and charge amount (charge charge amount) when the rated capacitance of the capacitors C1 and C2 is 560 pF and when the capacitance is lowered to 400 pF due to temperature rise. FIG. As shown in FIG. 10, in the signal generation circuit 100 of the present embodiment, when 20 nsec is set as the period of FIGS. 7C and 7G, the amount of accumulated charge is reduced by about 15%. .
Therefore, in the gate current of the thyristor S in the route (broken arrow) of the gate G1 → the signal line φ1 → the transfer signal CK1 as shown in FIG. Thereby, the time from when the thyristor S starts to turn on in the order that the Tr2 is turned on and then the Tr1 is turned on until the thyristor S is completely turned on is compared with the time before the capacitances of the capacitors C1 and C2 are reduced. As a result, the phenomenon of becoming longer occurs. Therefore, in the state where the capacitances of the capacitors C1 and C2 are reduced, the thyristor S may not be completely turned on during the transfer time initially set as the time from when the thyristor S1 starts to turn on until it is completely turned on. Arise. In that case, a so-called “transfer failure” occurs in the SLED chips (CHIP1 to CHIP58) in which the thyristor S is not completely turned on, and a white-out image failure occurs.
Therefore, the signal generation circuit 100 according to the present embodiment is configured so that the set value of the transfer time (time interval set by Ta + Tb) can be changed as necessary.

Here, FIG. 11 is a block diagram showing a configuration of the timing signal generation unit 114 arranged in the signal generation circuit 100 of the present embodiment. As shown in FIG. 11, the timing signal generation unit 114 includes a signal generation unit 41 and a transfer time setting register 42 as an example of a storage unit.
The transfer time setting register 42 stores a transfer time setting value Tck for setting the transfer time in the SLED 63. Then, the transfer time setting value Tck corresponding to the transfer time instruction signal transmitted from the control unit 30 is output to the signal generation unit 41. For example, the transfer time setting register 42 of the present embodiment has a transfer time set value Tck0 (first time interval) set at the time of normal image formation and more than that at the time of normal image formation when a transfer failure occurs. A transfer time setting value Tck1 (second time interval) for setting a long transfer time is stored. In this case, a plurality (for example, three) of transfer time set values Tck1 (second time intervals) selected in correspondence with information on the image density of each color test pattern from the density detection sensor 55 described later. The transfer time setting values Tck1_1, Tck1_2, and Tck1_3 may be stored. The transfer time setting values Tck1_1, Tck1_2, and Tck1_3 here set different transfer times that are longer than those during normal image formation.
The signal generation unit 41 obtains a horizontal synchronization signal (Lsync) from the control unit 30, a reference clock signal (Mclk) from the reference clock generation unit 116, and a transfer time setting value Tck from the transfer time setting register 42. Then, transfer signals CK1C and CK1R and transfer signals CK2C and CK2R corresponding to the transfer time set value Tck are generated. That is, the signal generation unit 41 generates transfer signals CK1C and CK1R and transfer signals CK2C and CK2R in which transfer times having different lengths are set according to the transfer time setting value Tck, and sends them to the SLED 63 via the level shift circuit 104. Output.

Next, the transfer time instruction signal output from the control unit 30 will be described.
As described above, when the capacitance of one or both of the capacitor C1 and the capacitor C2 arranged in the level shift circuit 104 fluctuates due to a temperature change or the like in the surrounding environment, the SLED chips (CHIP1 to CHIP1) constituting the SLED 63 are used. A transfer failure may occur in one or more of the CHIPs 58). In that case, a white-out image defect based on a transfer defect occurs.
When an image defect based on such a transfer defect occurs, for example, when image data from a PC 3 or the like is printed or when an original document is copied using the image reading unit 35, a user is usually used. Is in the vicinity of the image forming apparatus 1, so there is a high possibility that an abnormality will be immediately noticed. Therefore, in such a case, it is easy to take measures such as obtaining a normal image by performing printing or copying again.
However, when a facsimile reception is performed by the facsimile (FAX) function unit 36 in a situation where there is a high possibility that no one is in the vicinity of the image forming apparatus 1 such as an office at night, for example, the above transfer failure occurs. May occur. In that case, an important business part may overlap with a white part, and it may become unreadable. In that case, a request for another facsimile transmission or the like is necessary, and the inconvenience becomes large.

  Therefore, in the image forming apparatus 1 of the present embodiment, for example, when facsimile reception is performed by the FAX function unit 36, in each of the image forming units 11Y, 11M, 11C, and 11K as an example of a test pattern image forming unit. Each color test pattern in the form of a solid image over the entire width direction (main scanning direction) of the LPH 14 is formed. Then, it is transferred onto the intermediate transfer belt 20, and the image density of each color test pattern is detected over the entire region in the width direction by the density detection sensor 55 as an example of the image density detection means. The density detection sensor 55 sends information related to the detected image density of each color test pattern to the control unit 30. The control unit 30 determines whether or not a transfer failure has occurred based on information on the image density of each color test pattern from the density detection sensor 55. If it is determined that a transfer failure has occurred, a transfer time instruction signal for setting the transfer time longer than that during normal image formation is transmitted to the LPH 14 of the image forming unit 11 in which the transfer failure has occurred. To do.

Here, the density detection sensor 55 is, for example, an illumination system that illuminates the intermediate transfer belt 20, a light receiving element such as a CCD line sensor, and imaging optics that forms an image of reflected light from the intermediate transfer belt 20 on the light receiving element. System. Then, the image density for each color test pattern is detected over the entire region in the width direction at a position downstream of the intermediate transfer belt 20 in the conveyance direction of the image forming unit 11K and upstream of the secondary transfer portion T2. Information regarding the image density is transmitted to the control unit 30.
The density detection sensor 55 may be arranged along the axial direction of the photosensitive drum 12 in each image forming unit 11 so as to detect the image density on the photosensitive drum 12.

Subsequently, processing from the determination of the occurrence of a transfer failure performed by the control unit 30 to the output of the transfer time instruction signal will be described. FIG. 12 is a flowchart for explaining an example of processing from determination of whether or not a transfer failure has occurred to output of a transfer time instruction signal.
As shown in FIG. 12, when the FAX function unit 36 receives a facsimile (S101), the control unit 30 instructs each image forming unit 11 to form each color test pattern (S102). . Each image forming unit 11 forms each color test pattern (S103), and the density detection sensor 55 detects the image density of each color test pattern conveyed in order across the entire width direction (S104).
Here, FIG. 13 is a diagram showing an example of each color test pattern transferred onto the intermediate transfer belt 20 and the density detection sensor 55. As shown in FIG. 13, on the intermediate transfer belt 20, a yellow (Y) color test pattern Test_Y, a magenta (M) color test pattern Test_M, and a cyan (C) color test pattern formed by each image forming unit 11. Test_C and black (K) color test pattern Test_K are successively conveyed. The density detection sensor 55 detects the image density of each color test pattern that is successively conveyed in order across the entire width direction. FIG. 13 shows a state in which white spots have occurred in the M color test pattern Test_M.

The density detection sensor 55 sends information related to the image density over the entire width direction of each detected color test pattern to the control unit 30.
The control unit 30 acquires information on the image density of each color test pattern from the density detection sensor 55 (S105). Then, based on the acquired information regarding the image density in each color test pattern, it is determined whether or not a transfer failure has occurred in any of the image forming units 11 (S106). For example, in the example shown in FIG. 13, white spots have occurred in the M color test pattern Test_M. For this reason, the information regarding the image density of the M color test pattern Test_M detected by the density detection sensor 55 includes an image density portion equivalent to the white background (white background level). Therefore, the control unit 30 determines that a transfer failure has occurred when the image density information from the density detection sensor 55 includes a white background level image density portion. In the example of FIG. 13, it is determined that a transfer failure has occurred in the LPH 14 of the M color image forming unit 11.
In particular, when a white spot due to a transfer failure occurs, an area illuminated by image data that is not transferred due to a transfer failure is formed as a high image density portion upstream of the white spot portion in the main scanning direction. Therefore, a high image density portion and a white background level image density portion are continuously detected from upstream to downstream in the main scanning direction. Therefore, when the information on the image density from the density detection sensor 55 includes the high image density part and the image density part of the white background level continuously, it may be determined that a transfer failure has occurred.

When it is determined that a transfer failure has occurred in any of the image forming units 11 (S107), the control unit 30 transfers the transfer time to the LPH 14 of the image forming unit 11 in which the transfer failure has occurred. A transfer time instruction signal for designating a transfer time set value Tck1 for setting a longer time is output. Further, a transfer time instruction signal designating a transfer time setting value Tck0 set during normal image formation is output to the LPH 14 of the image forming unit 11 in which no transfer failure has occurred (S108).
When the control unit 30 outputs the transfer time instruction signal for specifying the transfer time setting value Tck1, the control unit 30 includes a plurality of ranks of transfer time instruction signals in accordance with the number of image density portions at the white background level. Either may be selected and output. In that case, a plurality of different transfer times are set in the transfer time setting register 42 of the timing signal generator 114 in correspondence with the transfer time instruction signals of a plurality of ranks. For example, transfer time setting values Tck1_1, Tck1_2, Tck1_3 Remember. Then, in the signal generation unit 41 of the timing signal generation unit 114, the one corresponding to the rank of the acquired transfer time instruction signal is selected from the plurality of transfer time setting values Tck1_1, Tck1_2, and Tck1_3.

When the transfer time instruction signal is output in step 108, the LPH 14 that has acquired the transfer time instruction signal specifying the transfer time setting value Tck1 uses the transfer time instruction signal in the transfer time setting register 42 of the timing signal generation unit 114. The corresponding transfer time set value Tck1 is selected and output to the signal generator 41. The signal generation unit 41 corresponds to the transfer time instruction signal based on the horizontal synchronization signal (Lsync) from the control unit 30, the reference clock signal (Mclk) from the reference clock generation unit 116, and the transfer time set value Tck1. The transfer signals CK1C and CK1R and the transfer signals CK2C and CK2R to be generated are generated and output to the SLED 63 via the level shift circuit 104.
Further, in the LPH 14 that has acquired the transfer time instruction signal designating the transfer time setting value Tck0, the transfer time setting value Tck0 corresponding to the transfer time instruction signal is selected in the transfer time setting register 42 of the timing signal generator 114, and the signal generation is performed. Is output to the unit 41. The signal generation unit 41 corresponds to the transfer time instruction signal based on the horizontal synchronization signal (Lsync) from the control unit 30, the reference clock signal (Mclk) from the reference clock generation unit 116, and the transfer time set value Tck0. The transfer signals CK1C and CK1R and the transfer signals CK2C and CK2R to be generated are generated and output to the SLED 63 via the level shift circuit 104.

On the other hand, when it is determined that no transfer failure has occurred in any of the image forming units 11 (S107), the control unit 30 sets the LPH 14 of each image forming unit 11 during normal image formation. The transfer time instruction signal designating the transfer time set value Tck0 to be output is output (S109). In this case, in the LPH 14 of each image forming unit 11, the transfer time setting value Tck 0 corresponding to the transfer time instruction signal is selected in the transfer time setting register 42 of the timing signal generator 114 and output to the signal generator 41. . The signal generation unit 41 corresponds to the transfer time instruction signal based on the horizontal synchronization signal (Lsync) from the control unit 30, the reference clock signal (Mclk) from the reference clock generation unit 116, and the transfer time set value Tck0. The transfer signals CK1C and CK1R and the transfer signals CK2C and CK2R to be generated are generated and output to the SLED 63 via the level shift circuit 104.
In this way, when a transfer failure occurs in any of the image forming units 11, the transfer time in the SLED 63 is set longer than the transfer time set during normal image formation. Thereby, the SLED 63 is recovered from the transfer failure to the normal state.

By the way, if the transfer time is set to be longer than that at the time of normal image formation, as shown in FIG. 7H, each of the LEDs L1 to L256 is within the period in which each thyristor S1 to S256 is on. The time allocated for lighting is reduced.
In the lighting time control / drive units 118-1 to 118-58 of this embodiment, the lighting pulse width (lighting time) of each LED is a reference pulse width BASE for setting a reference lighting pulse width and density unevenness correction data. For example, the following equation (1) is set by Corr.
Lighting pulse width = BASE · (1 + Corr / 128) (1)
Since the density unevenness correction data Corr of this embodiment is composed of 8-bit data (0 to 255), when the setting of the expression (1) is used, the lighting pulse width is 1 · BASE to 3 ·. Adjustment is made within the range of BASE.
However, when the transfer time is set to be longer than that during normal image formation as described above and the time allotted to the lighting of the LEDs L1 to L256 is reduced, the lighting of each LED set by the equation (1) is performed. The pulse width may not be within the time allotted for lighting. For example, the lighting pulse width may not be set to 3 · BASE, which is the maximum lighting pulse width.
Therefore, in the image forming apparatus 1 of the present embodiment, when the transfer time is set longer than that during normal image formation, an upper limit value is set for the lighting pulse width set for each LED. In this case, the upper limit value of the lighting pulse width is set in a range in which the sum of the set transfer time and the upper limit value of the lighting pulse width does not exceed the period in which the thyristor is in the on state.

  Further, in the image forming apparatus 1 of the present embodiment, when a transfer failure occurs, the transfer time is set longer than that during normal image formation. At the same time, the image resolution in the sub-scanning direction is set lower. Also good. For example, the SLED 63 of the present embodiment has an image resolution of 1200 dpi as an example. However, when a transfer failure occurs, the image resolution in the sub-scanning direction may be changed to, for example, 600 dpi. In that case, based on an instruction from the control unit 30, in the signal generation circuit 100 of each LPH 14, the timing signal generation unit 114 generates a data read signal and a trigger signal TRG corresponding to the sub-scanning direction 600 dpi. Then, the data is output to the image data development unit 110, the density unevenness correction data unit 112, and the lighting time control / drive units 118-1 to 118-58. Further, the control unit 30 controls the image processing unit 37 as an example of a changing unit to perform processing for changing to image data corresponding to the sub-scanning direction 600 dpi. Thereby, the transfer time is set longer.

  Further, when a transfer failure occurs, the transfer time may be set longer than that during normal image formation and the process speed may be set low. For example, when the image forming apparatus 1 of the present embodiment has a process speed (first moving speed) of 100 mm / sec as an example, if a transfer failure occurs, the process speed is set to 80 mm / sec, for example. The setting may be changed to (second moving speed). In that case, based on an instruction from the control unit 30, in the signal generation circuit 100 of each LPH 14, the reference clock generation unit 116 generates a reference clock signal corresponding to a process speed of 80 mm / sec. And it outputs to the timing signal generation part 114 and the lighting time control and drive part 118-1 to 118-58. Further, in the signal generation circuit 100 of each LPH 14, the timing signal generator 114 generates a data read signal and a trigger signal TRG corresponding to a process speed of 80 mm / sec. Then, the data is output to the image data development unit 110, the density unevenness correction data unit 112, and the lighting time control / drive units 118-1 to 118-58. Thereby, the transfer time is set longer.

  As described above, in the image forming apparatus 1 according to the present embodiment, the time (transfer time) set for turning on / off the thyristor that is a switch element that sets each LED arranged in the LPH 14 to the lighting enabled state. ) Can be changed. Then, when a transfer failure of the thyristor occurs, the transfer time is changed to suppress the occurrence of an image failure.

1 is a diagram illustrating an example of the overall configuration of an image forming apparatus of the present invention. It is a section lineblock diagram of a LED print head (LPH). It is a top view of a LED circuit board. It is a figure explaining an example of the circuit structure of SLED. It is a block diagram which shows the structure of a signal generation circuit. It is the figure which showed the wiring between the signal generation circuit on a LED circuit board, a level shift circuit, and SLED. 6 is a timing chart for explaining the output timing of drive signals output from a signal generation circuit and a level shift circuit. It is a figure explaining the flow of an electric current in a level shift circuit when transfer signal CK1R is made "L" from the initial state. It is a figure explaining the flow of an electric current immediately after setting transfer signal CK1C from "H" to "L". It is the figure which showed the relationship between the charge time in capacitor | condenser C1, C2, and the charge amount (charge charge amount) charged. It is the block diagram which showed the structure of the timing signal generation part. It is a flowchart explaining an example of a process from determination of the presence or absence of generation | occurrence | production of transfer failure to the output of a transfer time instruction signal. FIG. 4 is a diagram illustrating an example of each color test pattern transferred onto an intermediate transfer belt and a density detection sensor.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Image forming apparatus, 10 ... Image forming process part, 11 (11Y, 11M, 11C, 11K) ... Image forming unit, 12 ... Photosensitive drum, 14 ... LED print head (LPH), 30 ... Control part, 36 ... Facsimile (FAX) function unit 37... Image processing unit 41... Signal generation unit 42... Transfer time setting register 62 62 LED circuit board 63 63 self-scanning LED array (SLED) 100. DESCRIPTION OF SYMBOLS ... Level shift circuit, 110 ... Image data development part, 112 ... Density unevenness correction data part, 114 ... Timing signal generation part, 116 ... Reference clock generation part, 118 (118-1 to 118-58) ... Lighting time control / drive Part

Claims (9)

An image carrier,
Exposure means for lighting a plurality of light emitting elements arranged in a row based on image data, and exposing the image carrier;
Signal generating means for generating a signal for sequentially lighting each of the plurality of light emitting elements along an array based on the image data ;
Detecting means for detecting occurrence of a state in which the plurality of light emitting elements are not sequentially turned on,
When the state is detected by the detecting means , the signal generating means follows the arrangement of the one light emitting element from the end of the lighting period assigned to turn on the one light emitting element set by the signal. The time interval between the adjacent light emitting elements until the start of the lighting period is set to a second time interval longer than the first time interval instead of the predetermined first time interval. An image forming apparatus. It said signal generating means, the image forming apparatus according to claim 1, wherein said plurality of time intervals different from the second time interval is set. The image processing apparatus further includes a changing unit that acquires the image data and changes the image resolution of the acquired image data.
When the signal generating unit sets the second time interval, the changing unit sets the image resolution in the sub-scanning direction of the acquired image data, and the signal generating unit sets the first time interval. Change lower than the case ,
The signal generating unit generates the signal corresponding to the image data in which the image resolution in the sub-scanning direction is changed to be low by the changing unit when the second time interval is set. The image forming apparatus according to claim 1 . The image carrier includes a first moving speed which the signal generating means is set when setting the first time interval, is set when the signal generating means sets the second time interval that is configured to move in one of the said first slower than the moving speed of the one or more second moving speed,
The signal generating means generates the signal corresponding to a state in which the moving speed of the image carrier is set to the second moving speed when the second time interval is set. The image forming apparatus according to claim 1 .   The image forming apparatus according to claim 1, wherein the signal generating unit sets an upper limit value of a lighting time of the light emitting element. A test pattern image forming unit that forms a predetermined test pattern image in the main scanning direction of the exposure unit on the image carrier, and an image density of the test pattern image formed by the test pattern image forming unit Image density detecting means for detecting over the main scanning direction of the exposure means,
The signal generation means sets the second time interval instead of the first time interval based on the image density of the test pattern image detected by the image density detection means. Item 2. The image forming apparatus according to Item 1. A plurality of light emitting elements arranged in a row,
Signal generating means for generating a signal for sequentially lighting each of the plurality of light emitting elements along an array based on image data ;
Detecting means for detecting occurrence of a state in which the plurality of light emitting elements are not sequentially turned on,
When the state is detected by the detecting means , the signal generating means follows the arrangement of the one light emitting element from the end of the lighting period assigned to turn on the one light emitting element set by the signal. An exposure apparatus characterized in that a time interval between the adjacent adjacent light emitting elements until the start of the lighting period is set to a time interval longer than the predetermined time interval instead of the predetermined time interval. . 8. The exposure apparatus according to claim 7 , further comprising storage means for storing a plurality of different time intervals as time intervals longer than the predetermined time interval set by the signal generating means. The exposure apparatus according to claim 7 , wherein the signal generation unit sets an upper limit value of a lighting time of the light emitting element.

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