JP6160429B2 - Optical scanning device and image forming apparatus - Google Patents

Description

  The present invention relates to an optical scanning device and an image forming apparatus.

  An image forming apparatus such as a printer or a copier uniformly charges the surface of a photosensitive drum with a charging device, and emits light to the uniformly charged photosensitive drum based on image data from a light source unit. The electrostatic latent image is obtained by irradiating the toner, and a toner image is generated by supplying toner to the electrostatic latent image in the developing unit. The toner image is transferred to the intermediate portion in the transfer unit. It is configured to transfer to a recording sheet through a body or directly.

  In the image forming apparatus as described above, an LED print head using a self-scanning LED array as a light source unit has been proposed (see Patent Document 1). Hereinafter, the LED print head may be referred to as LPH (LED Print Head), and the self-scanning LED may be referred to as SLED (Self-scanning LED).

  Japanese Patent Application Laid-Open No. H10-228707 describes correcting light amount unevenness of each light source by individually controlling the light emission time of the light emitting array.

  Japanese Patent Application Laid-Open No. H10-228561 describes that, during short-time light emission in which the proportional relationship between the light emission time and the light amount is lost, the power supply voltage is finely adjusted to improve the light amount change linearity.

  Furthermore, Patent Document 3 describes that the light amount is adjusted by adjusting the current for a light source array driving circuit other than the SLED.

JP 2003-182143 A JP 2007-105921 A Japanese Patent Laid-Open No. 03-105921

  In consideration of the above facts, the present invention reduces the difference in the light emission time with respect to the light intensity indication value even when the required light intensity is different from the specification designed with the required light intensity specified. It is an object to obtain an optical scanning device and an image forming apparatus capable of achieving the above.

The invention according to claim 1 includes a plurality of light emitting elements arranged along a predetermined scanning direction, and when the light emitting elements are caused to emit light based on a light emission time calculated under an environment of a specific light amount. A plurality of outputs for outputting pulses of light emission times of the light emitting elements for obtaining the target exposure amount in an environment having a plurality of different light amounts, respectively, and an exposure head portion manufactured with specifications for obtaining the target exposure amount A selection unit that selects the output unit based on instruction information of a light amount required at the time of light emission, and an output unit selected by the selection unit in an environment of the light amount required at the time of light emission. based on the pulse of the light emission time, the light-emitting element have a, and scanning control means for sequentially emit light along the scanning direction, wherein the indication information, the average value during light emission of the plurality of light emitting elements, pre Ratio to the defined threshold Characterized in that it is a result information.

  According to a second aspect of the present invention, in the first aspect of the invention, the specific light amount is a maximum light amount required during the light emission.

According to a third aspect of the present invention, in the first or second aspect of the present invention, the plurality of output units vary the driving light for causing the light emitting elements to emit light, thereby the plurality of light amounts. And an output unit that outputs a pulse of the light emission time of the light emitting element for obtaining the target exposure amount under the environment of the specific light amount.

The invention according to claim 4 is the invention according to any one of claims 1 to 3 , wherein the selection unit includes two output units having a relatively large light amount, When the average value exceeds a predetermined threshold value, an output unit having a relatively large light amount is selected. When the average value is equal to or less than the predetermined threshold value, an output having a relatively small light amount is selected. Select the part.

A fifth aspect of the present invention is the invention according to any one of the first to fourth aspects, wherein the light emission time and the exposure amount are related to each of the output units. A correction table between a plurality of light emitting elements is set based on the drawing.

According to a sixth aspect of the present invention, the optical scanning device according to any one of the first to fifth aspects is opposed to the light emitting surface of the optical scanning device, and is relatively moved in a direction intersecting the scanning direction. and image carrier capable, while scanning the emission light of the light emitting device by the optical scanning apparatus, by relatively moving with the optical scanning device and the image carrier, an image for forming an image on the image carrier onto Forming means;
An image forming apparatus having

According to the first aspect of the present invention, the difference between the light emission times with respect to the light amount instruction value is reduced even when the required light amount is different from the specification designed with the required light amount being specified. be able to. In addition, scanning can be performed while maintaining a light emission time with high linearity in accordance with the light emission state of the light emitting element.

  According to the second aspect of the present invention, it is possible to avoid a shortage of light amount even when the required light amount is the maximum.

  According to the third aspect of the present invention, it is possible to maintain the light emission control with the light quantity based on the design specification.

According to the fourth aspect of the present invention, it is possible to perform scanning while maintaining a light emission time having a high linearity with respect to the exposure amount with a simple configuration as compared with the case where the present configuration is not provided.

According to the fifth aspect of the present invention, an optimum correction table can be applied under the required light quantity.

According to the sixth aspect of the present invention, the difference in the light emission time with respect to the light amount indication value is reduced even when the required light amount is different from the specification designed with the required light amount specified. be able to.

1 is a schematic configuration diagram of an engine unit of an image forming apparatus according to an embodiment. It is a block diagram of the control system for image formation in the engine part which concerns on this Embodiment. It is an enlarged view which shows the structure of LPH which concerns on this Embodiment. It is a top view which shows the arrangement structure of SLED concerning this Embodiment. (A) is a control block diagram of the light emission time control unit / drive unit, and (B) is a functional block diagram specialized for buffer selection control provided in the final stage of FIG. 5 (A). It is a light emission control circuit diagram of the SLED chip according to the present embodiment. It is a buffer output impedance with respect to the buffer drive capability based on this Embodiment, and a light quantity characteristic view. It is a light emission time-exposure amount characteristic view according to the present embodiment. It is a flowchart which shows the flow of the buffer selection control of the light emission time control part and the drive part concerning this Embodiment. It is an operation | movement timing chart (1) of the SLED chip | tip of LPH which concerns on this Embodiment. It is an operation | movement timing chart (2) of the SLED chip | tip of LPH which concerns on this Embodiment.

(overall structure)
FIG. 1 is a schematic diagram showing the overall configuration of an engine unit 10 of an image forming apparatus to which the present invention is applied. As shown in FIG. 1, the engine unit 10 includes a photosensitive drum 12 that rotates at a constant speed in the direction of arrow A in FIG.

  Around the photosensitive drum 12, along the rotation direction of the photosensitive drum 12 (clockwise direction indicated by arrow A in FIG. 1), a charger 14, an LED printer head (LPH) 16, a developing device 18, a transfer device A roller 20, a cleaner 22, and an erase lamp 24 are arranged in this order.

  That is, the surface of the photosensitive drum 12 is uniformly charged by the charger 14, and then a light beam is irradiated by the LPH 16 to form a latent image on the photosensitive drum 12. Note that the LPH 16 is connected to the LPH driving unit 26 and is controlled to emit light by the LPH driving unit 26 so as to emit a light beam based on the image data.

  To the latent image formed on the photosensitive drum 12 by the light beam, toner is supplied by the developing unit 18 to form a toner image on the photosensitive drum 12.

  The toner image on the photoconductive drum 12 is transferred by the transfer roller 20 to the paper 28 conveyed from a paper tray (not shown). The toner remaining on the photosensitive drum 12 after the transfer is removed by the cleaner 22, neutralized by the erase lamp 24, charged by the charger 14 again, and the same processing is repeated.

  On the other hand, the paper 28 onto which the toner image has been transferred is conveyed to a fixing device 30 including a pressure roller 30A and a heating roller 30B, and subjected to a fixing process. As a result, the toner image is fixed and a desired image is formed on the paper 28. The paper 28 on which the image is formed is discharged out of the apparatus.

  Further, a density detection circuit 32 is provided around the photosensitive drum 12 and between the developing unit 18 and the transfer roller 20 so as to face the photosensitive drum 12. The density detection circuit 32 detects the density of the toner image on the photosensitive drum 12 when, for example, a density patch pattern (density sample) is formed. The output of the density detection circuit 32 is connected to an exposure control unit 162, the exposure control unit 162 is connected to an LPH drive unit 26 for driving the LPH 16, and the LPH drive unit 26 is connected to the LPH 16.

  As the density patch pattern, a patch pattern having a very small size of about several hundred μm × several hundred μm is used. Since this technique is well known in Japanese Patent Application Laid-Open No. 2003-156929, detailed description thereof is omitted. However, by using this density patch pattern, the density patch pattern is not printed on the paper 28, and the photosensitive drum 12 is not printed. It can be detected by the opposed density detection sensor 32.

  The density detection circuit 32 is attached to a moving mechanism that can move in the main scanning direction, and can detect the density of the density patch pattern in the main scanning direction.

(Engine control system)
FIG. 2 is a block diagram of a control system for image formation in the engine unit 10.

  The main power management unit 150 is connected to a commercial power source (not shown), generates LVPS (low voltage power source) and HVPS (high voltage power source), and supplies power to each unit via a power supply line.

  A user interface 154 is connected to the main controller 152, and an instruction regarding image formation or the like is given by a user's operation, and information on the image formation or the like is notified to the user.

  The main controller 152 is connected to a network line with an external host computer (not shown) so that image data is input.

  When the image data is input, the main controller 152, for example, analyzes the print instruction information included in the image data and the image data, and converts them into a format suitable for the engine unit 10 (for example, bitmap data). The image data is sent to the image forming process control unit 156 that functions as a part of the MCU.

  In the image formation processing control unit 156, based on the input image data, together with the image formation processing control unit 156, the drive system control unit 158, the charge control unit 160, the exposure control unit 162, and the transfer control unit 166 function as MCUs. The fixing control unit 168, the charge removal control unit 170, the cleaner control unit 172, and the development control unit 164 are synchronously controlled to execute image formation.

  The LPH drive unit 26 is controlled by a light emission time control unit / drive unit 162A provided in the exposure control unit 162.

  A state management unit 176 is connected to the image formation processing control unit 156, and determines the operating state of the engine unit 10 (for example, during the processing mode, during the sleep mode, during startup from the sleep mode, during processing, etc.). It is like that. The operating state determined by the state management unit 176 is sent to the main controller 152.

  The main power management unit 150 is connected to a power-on monitoring sensor 178. The power-on monitoring sensor 178 detects when the power is turned on, and the power-on information is sent to the main controller via the state management unit 176. 52 is sent out.

  Further, a temperature sensor 180, a humidity sensor 182 and the like are connected to the main controller 152. The temperature sensor 180 and the humidity sensor 182 detect the environmental temperature and humidity in the engine unit 10.

(Detailed configuration of LPH)
Next, the configuration of the LPH 16 will be described in detail. As shown in FIG. 3, the LPH 16 supports the LED array 50, a printed circuit board 52 on which a circuit for supporting the LED array 50 and supplying various signals for controlling the driving of the LED array 50 is formed. A (registered trademark) lens array (SLA) 54 is provided.

  The printed circuit board 52 is disposed in the housing 56 with the mounting surface of the LED array 50 facing the photosensitive drum 12 and is supported by a plate spring 58.

  As shown in FIG. 4, SLED chips 62 in which a plurality of LEDs 60 are arranged along the axial direction of the photosensitive drum 12 are further arranged in a so-called zigzag pattern. The light beam can be irradiated with a resolution.

(Light emission time control unit / drive unit)
Details of the light emission time control unit / drive unit 162A provided in the exposure control unit 162 will be described.

  The light emission time control unit / drive unit 162A corrects the light emission time of each pixel based on the density unevenness correction data, and generates a control signal for emitting light from the LED 60 of each pixel.

  As shown in FIG. 5A, the light emission time control unit / drive unit 162A includes a presettable digital one-shot multivibrator (PDOMV) 260, a linearity correction unit 262, and an AND circuit 270. The AND circuit 270 receives a trigger signal when the image data is 1 (ON) and does not input a trigger signal when the image data is 0 (OFF).

  The PDOMV 260 receives density unevenness correction data and a reference clock in synchronization with the trigger signal from the AND circuit 270, and generates a light emission pulse signal.

  The linearity correction unit 262 corrects and outputs the light emission pulse signal from the PDOMV 260 in order to correct the variation in the light emission start time of each driver output.

  Specifically, the linearity correction unit 262 includes a plurality of delay circuits 264 (eight in the present embodiment, and the numbers (0 to 7) of the reference numerals 264 identify each delay circuit 264), A delay selection register 266, a delay signal selection unit 265, an AND circuit 267, an OR circuit 268, and a light emission signal selection unit 269 are provided.

  The delay circuit 264 (delay circuit 264-0 to delay circuit 264-7) is connected to the PDOMV 260, and delays the light emission pulse signal from the PDOMV 260 by different times.

  The delay selection register 266 is connected to the delay signal selection unit 265 and the light emission signal selection unit, and the delay selection register 266 stores delay selection data and light emission signal selection data for each driver.

  Delay selection data and light emission signal selection data for each driver are measured in advance and stored in a non-volatile memory such as an EEPROM or a flash ROM (not shown). When stored in the EEPROM, the delay selection data is downloaded to the delay selection register 266 when the machine power is turned on, and when stored in the flash ROM, the flash ROM itself functions as the delay selection register 266.

  The delay signal selection unit 265 is connected to the AND circuit 267 and the OR circuit 268, and is one of outputs from the delay circuits 264-0 to 264-7 based on the delay selection data stored in the delay selection register 266. Select one.

  The AND circuit 267 performs a logical product of the light emission pulse signal from the PDOMV 260 and the delayed light emission pulse signal selected by the delay signal selection unit 265, that is, both the light emission pulse signal before the delay and the light emission pulse signal after the delay are in the light emission state. If there is, output a light emission pulse.

  The OR circuit 268 is a logical sum of the light emission pulse signal from the PDOMV 260 and the delayed light emission pulse signal selected by the delay signal selection unit 265, that is, at least one of the light emission pulse signal before the delay and the light emission pulse signal after the delay is in the light emission state. If so, a light emission pulse is output.

  The light emission signal selection unit 269 selects one of the outputs from the AND circuit 267 or the OR circuit 268 based on the light emission selection data stored in the delay selection register 266.

  The light emission signal selection unit 269 is connected to two types of MOSFETs 272A (buffer (small)) and MOSFET 272B (buffer (large)) via a buffer selection unit 273. The two types of buffers (MOSFET 272A and MOSFET 272B) have different output impedances.

  In this embodiment, when the MOSFET 272A (buffer (small)) and the MOSFET 272B (buffer (large)) are relatively compared, “large and small”, “high and low”, “many and small”, etc. This expression shows a relative comparison between the MOSFET 272A (buffer (small)) and the MOSFET 272B (buffer (large)). In addition, if there is a separate reference value and the comparison is made, the comparison shall be made after clearly specifying the reference value.

  Here, the light emission pulse selected by the light emission signal selection unit 269 is amplified by the MOSFET 272A or the MOSFET 272B selected by the buffer selection unit 273, and is driven as a light emission control signal I (light emission time) by the drive circuit of the SLED chip 62 (FIG. 6).

  Details of the functions of the buffer selection unit 273 and the buffers (MOSFET 272A, MOSFET 272B) will be described later.

(SLED drive circuit)
Next, a circuit configuration inside the SLED chip 62 provided for driving each LED 60 of the SLED chip 62 will be described with reference to FIG.

  In the SLED chip 62, a thyristor 90 is provided for each of a plurality of (for example, 128) LEDs 60 arranged in the SLED 62, and the anode side of each thyristor 90 is connected to the SUB terminal 80. Yes.

  A point P connected to the gate side of the first-stage thyristor 90 (numbers following 1 to 128 / point P indicates the order of the plurality of LEDs 60 arranged) is connected to the ΦS input terminal 88, and the SLED chip 62 As a trigger for causing the LED 60 to emit light, a start signal ΦS (voltage) is applied to the point P (1 to 128).

  Further, the points P (1 to 128) connected to the gate side of the thyristor 90 at each stage are connected in series via a diode 92. Further, the points P (1 to 128) of each stage are connected to a base line 96 connected to the VGA terminal 78 through resistors 94. The base line 96 maintains a predetermined voltage at the first stage and decreases by a predetermined potential (Vf) as it goes to each stage.

  Further, the point P (1 to 128) is connected to the anode side of the LED 60, and the cathode side of the LED 60 is connected via a light emission control signal line 98 that outputs a pulse wave that becomes the light emission control signal (I) of each stage. And connected to the ΦI input terminal 82. When the light emission control signal is at a low level (L), the LED 60 emits light if the thyristor 90 whose gate is the point P (1-128) is ON.

  Further, the cathode side of the odd-numbered thyristor 90 is connected to the first transfer line 100, and the cathode side of the even-numbered thyristor 90 is connected to the second transfer line 102. The transfer signals CK1 and CK2 are supplied respectively. Is done. According to the transfer signals CK1 and CK2, the potential at the point P (1-128) is increased by a predetermined potential (Vf). That is, the potential at the point P reaches the predetermined potential at which the LED 60 can emit light in order from the initial point P1 to the subsequent stage, and the SLED chip 62 can be self-scanned.

(Light emission time control)
Here, the LPH 16 according to the present embodiment is designed to be applicable as a light source for a plurality of types (including model, model, and lot) of image forming units. However, the normal drive current value in the LPH 16 may differ depending on the type. In other words, since the required amount of light is different, the drive current value is basically determined corresponding to the maximum required amount of light.

  The drive current value width of the LED 60 applied to the LPH 16 is, for example, 4 mA to 24 mA.

  When the drive current value is determined, the light emission time is calculated based on the image information (light emission signal) from the relationship of exposure amount = light emission time (pulse width) × light quantity (drive current), and the LED drive to the drive circuit of the SLED chip 62 is performed. It is transmitted as a signal I (light emission control signal).

  At this time, the light emission time-light emission amount characteristic of the LED 60 has a higher linearity (linearity) as the light emission time (pulse width) is longer (long pulse driving), and thus the required light amount is maximized. It is necessary to design a control system (such as a drive circuit for the SLED chip 62) of the LPH 16 so as to drive a long pulse when the type of image forming unit is used.

  As described above, when the LPH16 of the same specification is applied to the type of the image forming unit having the minimum required light amount under the specification designed under the condition that the required light amount is maximum, the light amount is reduced. Inevitably, a short pulse drive is required.

  For this reason, if the same specification is applied to the type of image forming unit with the minimum required amount of light, the linearity becomes lower than the type of long pulse driving. For example, in the short pulse drive, even if the light quantity distribution characteristics of each LED 60 are performed, the light quantity distribution becomes unbalanced due to a slight disturbance, and there is a high possibility that the image quality is deteriorated as compared with the long pulse drive.

  Therefore, in the light emission time control unit / drive unit 162A of the present embodiment, the required light amount is minimized while maintaining the specifications designed based on the type of image forming unit that requires the maximum light amount. Added a function to avoid short pulse drive when applied to various types of image forming units.

  More specifically, in the final stage of the light emission time control unit / drive unit 162A, the buffer selection unit 273 selects the MOSFET 272A or the MOSFET 272B as the drive current adjustment buffer.

  FIG. 5B is a block diagram specialized for buffer selection control after the MOSFET 272A and the MOSFET 272B in FIG.

  As shown in FIG. 5B, each of the MOSFET 272A (small buffer) and the MOSFET 272B (large buffer) uses the light emission pulse signal as an input source, and the processing is executed with each driving capability and is sent to the buffer selection unit 273. It has become so.

  A light emission instruction value comparison unit 275 is connected to the buffer selection unit 273.

  The light emission instruction value comparison unit 275 includes a reception unit 275A that receives the light emission instruction value, a calculation unit 275B that calculates the average value A of the received light emission instruction values, and a threshold value X for comparison with the average value A of the light emission instruction values. 275C, a comparison unit 275D that compares the light emission instruction value with the threshold value X, and a determination unit 275E that makes a determination based on the comparison result.

  Here, the average value A of the light emission instruction values of all the LEDs 60 received by the reception unit 275A is calculated by the calculation unit 275B. Further, the comparison unit 275D compares the average value A with the threshold value X stored in advance in the storage unit 275C.

  In the determination unit 275E, the buffer drive capability is determined based on the comparison result in the comparison unit 275D, and is output to the buffer selection unit 273 as a buffer drive capability selection signal.

  In the present embodiment, the buffer driving capability selection signal is a bit signal (1/0).

  As described above, the light emission signal selection unit 269 shown in FIG. 5A is connected to two types of MOSFETs 272A and 272B (buffers) having different output impedances via the buffer selection unit 273.

  Here, the light emission pulse selected by the light emission signal selection unit 269 is used as the LED drive signal I (light emission control signal) by the MOSFET 272A or MOSFET 272B selected by the buffer selection unit 273 (see FIG. 6). Is output.

  The relationship between the MOSFET 272A and the MOSFET 272B is a difference in output impedance, and the relationship is that the output impedance of the MOSFET 272A (buffer (small))> the output impedance of the MOSFET 272B (buffer (large)).

  The relative difference in output impedance is as follows.

  That is, as shown in FIG. 7, when the output impedance is relatively high, the drive current is small, so the light amount is low. On the other hand, as shown in FIG. 7, when the output impedance is relatively low, the amount of light increases because the drive current is large.

  Further, from the relationship of exposure amount = light emission time × drive current, when the drive current is small, the light emission time is long (pulse width is enlarged), and when the drive current is large, the light emission time is short (pulse width is reduced).

  In this embodiment, one of the two types of MOSFET 272A and MOSFET 272B is selected.

  That is, in the light emission instruction value comparison unit 275, when the average value A> the threshold value X, the MOSFET 272B that is a low output impedance buffer (large) is selected (for example, the bit signal is 1), and the average value ≦ In the case of the threshold value X, the MOSFET 272A which is a buffer (small) having a high output impedance is selected (for example, the bit signal is 0).

  In other words, the light emission time having an average value larger than the threshold value X is as specified in the specification designed under the condition that the required light quantity is relatively large. Accordingly, the buffer (large) MOSFET 272B having a low output impedance is selected.

  On the other hand, the light emission time in which the average value A is smaller than the threshold value X is obtained by reducing the amount of light by reducing the drive current so that the required light amount is relatively small. Minutes, increase the light emission time. Therefore, the buffer (small) MOSFET 272A having a high output impedance is selected.

  Table 1 shows the relative relationship among output impedance, drive current, light amount, and light emission time in the selected buffer.

  Next, when the difference in the light emission time is suppressed, a difference occurs in the absolute light amount when the drive current is reduced. Therefore, it is preferable to prepare a small light amount correction value table and a large light amount correction value table (FIG. 8). reference).

  The operation of this embodiment will be described below.

(Image forming operation)
Around the photosensitive drum 12, an image forming (printing) process for each color by a well-known electrophotographic method is performed as follows.

  First, each of the photosensitive drums 12 is rotationally driven at a predetermined rotational speed.

  As shown in FIG. 1, the surface of the photosensitive drum 12 is brought to a predetermined level by applying a DC voltage having a predetermined charging level (or a voltage obtained by superimposing an AC voltage on the DC voltage) by the charger 14. Uniformly charged.

  Next, the surface of the photosensitive drum 14 having a uniform surface potential is irradiated with a light beam from the LED 60 by the LPH 16 to form an electrostatic latent image corresponding to image information. The light emission control of the LED 60 will be described later.

  Due to the light emission of the LED 60, the surface potential of the exposure portion by the light beam of the photosensitive drum 12 is displaced to a predetermined level.

  The electrostatic latent image formed on the surface of the photosensitive drum 14 is developed by the corresponding developing device 18 and visualized as a toner image on the photosensitive drum 12.

  That is, the developing device 18 takes out the two-component developer from the developing cartridge and causes the toner to fly from the developing roll to adhere to the surface of the photosensitive drum 12 with respect to the electrostatic latent image.

  In the development at this time, the carrier having a role of transporting the toner remains on the developing roll, and only the toner is transferred to the photosensitive drum 12.

  Next, the toner images of the respective colors formed on the respective photosensitive drums 12 are transferred by the transfer roller 20 onto the paper 28 that passes through the paper transport path. After the transfer, the toner image formed on the paper 28 is heated and pressurized and conveyed by the fixing device 30, so that the toner is melted and solidified and fixed on the recording paper P. Further, after fixing, the recording paper P is discharged by a paper discharge roll, and the image forming process ends.

(Light emission control)
"Signal generation"
A trigger signal and image data are input to the AND circuit 270 of the light emission time control unit / drive unit 162A. The AND circuit 270 outputs a trigger signal to the PDOMV 260 only when the image data is on. Density unevenness correction data, a reference clock, and a trigger signal are input to the PDOMV 260. When the image data is on, the PDOMV 260 generates light emission pulses for the number of reference clocks corresponding to the density unevenness correction data.

  The light emission pulse is output to the AND circuit 267 and the OR circuit 268, branched and output to the delay circuit 264-0, delayed by a predetermined time by the delay circuit 264-0, and output to the delay signal selection unit 265. The light emission pulse CKi delayed by the delay circuit 264-0 is also output to the delay circuit 264-1. Thereafter, the light emission pulse CKi from the preceding serial number delay circuit 264 is input to the delay circuits 264-1 to 264-7, and the light emission pulse is delayed for a predetermined time and output to the delay signal selection unit 265. The delayed light emission pulse is also output to the serial number delay circuit 264. However, the delay circuit 264-7 does not output to the delay circuit 264 of the subsequent serial number.

  The delay signal selection unit 265 selects one of the outputs of the light emission pulses CKi output from the delay circuits 264-0 to 264-7 based on the delay selection data stored in advance in the delay selection register 266. . The selected light emission pulse is output to the AND circuit 267 and the OR circuit 268.

  The AND circuit 267 generates a light emission pulse CK1 that is a logical product of the light emission pulse before the delay and the light emission pulse after the delay, and outputs it to the light emission signal selection unit 269.

  In the OR circuit 168, a light emission pulse CK 2 that is a logical sum of the light emission pulse before the delay and the light emission pulse after the delay is generated and output to the light emission signal selection unit 269.

  The light emission signal selection unit 269 selects either the output from the AND circuit 267 or the output from the OR circuit 268 based on the light emission selection data stored in the delay selection register 266 in advance. The selected light emission pulse is output to the LPH 16 via the MOSFET 272A or the MOSFET 272B.

"Buffer selection control"
By the way, in the light emission time control unit / drive unit 162A of the present embodiment, the required amount of light is minimized while maintaining the specifications designed based on the type of image forming unit that requires the maximum amount of light. Added a function to avoid short pulse drive when applied to various types of image forming units.

  That is, in the final stage of the light emission time control unit / drive unit 162A, the buffer selection unit 273 selects the MOSFET 272A or the MOSFET 272B as the drive current adjustment buffer.

  FIG. 9 is a flowchart showing a selection control routine of the MOSFET 272A or the MOSFET 272B in the buffer selection unit 273 and the light emission instruction value comparison unit 275 of the light emission time control unit / drive unit 162A.

  In step 300, it is determined whether or not a light emission instruction value is input to the light emission instruction value comparison unit 275. If a negative determination is made, this routine ends. The light emission instruction value is basically input when the required light quantity is determined at the shipping stage, but the required light quantity may be changed, for example, in inspection or parts replacement. .

  If an affirmative determination is made in step 300, the process proceeds to step 302, the average value A of the light emission instruction values is calculated, and the process proceeds to step 304.

  In step 304, a predetermined threshold value X is read, and then in step 306, the average value A and the threshold value X are compared.

  Note that the threshold value X in the present embodiment is a threshold value for determining whether the required light quantity is the maximum and conforms to the specification of the drive circuit of the LED chip 62.

  If it is determined in step 306 that the average value A> the threshold value X (affirmative determination), it is determined that the required light quantity is in accordance with the design specifications of the drive circuit of the LED chip 62, and the drive current is large. → Based on the condition of large light quantity, in order to maintain the light emission time based on the design specification, the process proceeds to step 308, and a signal for selecting the MOSFET 272B that is the buffer (large) is selected for the buffer selection unit 273 (buffer drive capability selection) Signal), and then the process proceeds to step 310 to select the large light quantity correction table based on FIG. 8, and this routine ends.

  If it is determined in step 306 that the average value A ≦ the threshold value X (negative determination), it is determined that the required light quantity does not conform to the design specifications of the drive circuit of the LED chip 62, and the driving is performed. Based on the condition that the current is small and the light amount is small, in order to make the light emission time longer than the design specification, the process proceeds to step 312 and the buffer selection unit 273 selects a signal (buffer) for selecting the MOSFET 272A as a buffer (small). (Driving ability selection signal) is output, then the routine proceeds to step 314, where the small light quantity correction table is selected based on FIG. 8, and this routine ends.

  In this embodiment, two types of MOSFETs 272A and MOSFET 272B are used, but three or more types may be used. In addition, by applying the feature (buffer selection) of this embodiment, it is not necessary to design as a design specification under the condition that the required light quantity is maximum, and conversely, it is designed under the condition that the required light quantity is minimum. The specification may be used, or when three or more types of buffers are prepared, the specification may be designed so that any of the buffers may meet the specification.

"SLED chip operation control"
Next, the operation of the SLED chip 62 of the LPH 16 will be described with reference to the timing charts of FIGS.

  As shown in FIGS. 10 and 11, by setting the start signal ΦS (CKS) to a high level (H), the potential of the point P1 becomes H, and the potential of the point P2 connected from the point P1 through the diode 92 is , P2 = Φs−Vf (due to the voltage drop of the LED). Similarly, the potential at the point P3 is P3 = P2-Vf, the potential at the point P4 is P4 = P3-Vf,..., And the potential at the point PN is PN = P (N−1) −Vf. However, since it is saturated at the Φga potential, it does not drop below Φga.

  Here, when CK1 becomes L, the thyristor 90 of P1 is turned on. At this time, the potential at the point P1 becomes ΦS → 0V, and the potential at CK1 becomes Φ1 → −Vf. Here, the point P1, which is equivalent to the point P1, that is, the odd-numbered point P is not turned on because the potential drops in units of 2 Vf.

  In this state, when ΦI is changed from H → L, the first LED 60 emits light. Further, by changing ΦI from L → H, the LED 60 at the first stage is turned off, and at this time, the potential of ΦI becomes −Vf.

  Next, by setting CK2 to L, the thyristor 90 of P2 is turned on, and P2 = 0V, P3 = −Vf, and P4 = −2Vf. At this time, since the potential Φ2 of CK2 becomes −Vf, the even-numbered thyristor 90 after P4 is not turned on.

  When the P2 thyristor 90 is turned on, CK1 → H is set to turn off the P1 thyristor 90 so that the first LED 60 does not emit light in the next data signal.

  In this state, by changing ΦI from H → L, the second-stage LED 60 emits light. At this time, the potential of ΦI becomes −Vf. Thereafter, by changing ΦI from L to H, the second-stage LED 60 is turned off (the potential of ΦI is 0 V).

  Hereinafter, CK1 controls ON (light emission) of the odd-numbered thyristor 90 (and the LED 60), CK2 controls ON (light emission) of the even-numbered thyristor 90 (LED 60), and controls each light emission control signal ΦI. The amount of exposure by the LED 60 is made.

DESCRIPTION OF SYMBOLS 10 Engine part 12 Photosensitive drum 14 Charger 16 LED printer head (LPH)
DESCRIPTION OF SYMBOLS 18 Developing device 20 Transfer roller 22 Cleaner 24 Erase lamp 26 LPH drive part 28 Paper 30A Pressure roller 30B Heating roller 30 Fixing device 32 Density detection circuit 50 LED array 52 Printed circuit board 54 SELFOC (registered trademark) lens array (SLA)
56 Housing 58 Leaf spring 60 LED
62 SLED chip ΦS Start signal (voltage)
I light emission control signal 78 VGA terminal 80 SUB terminal 82 ΦI input terminal 88 ΦS input terminal 90 thyristor 92 diode 94 resistance 96 base line 98 light emission control signal line 100 first transfer line 102 second transfer line 150 main power supply management unit 152 Main controller 154 User interface 156 Image formation processing control unit 158 Drive system control unit 160 Charging control unit 162 Exposure control unit 162A Light emission time control unit / drive unit 164 Development control unit 166 Transfer control unit 168 Fixing control unit 170 Static elimination control unit 172 Cleaner Control unit 176 Status management unit 178 Power-on monitoring sensor 180 Temperature sensor 182 Humidity sensor 260 Presettable digital one-shot multivibration Data (PDOMV)
262 Linearity correction unit 264 (264-0 to 264-7) Delay circuit 265 Delay signal selection unit 266 Delay selection register 267 AND circuit 268 OR circuit 269 Light emission signal selection unit 270 AND circuit 272 MOSFET
273 Buffer selection unit 275 Light emission instruction value comparison unit 275A reception unit 275B calculation unit 275C storage unit 275D comparison unit 275E determination unit

Claims (6)

A specification that includes a plurality of light emitting elements arranged along a predetermined scanning direction, and obtains a target exposure amount when the light emitting elements are caused to emit light based on a light emission time calculated in an environment with a specific light amount. A manufactured exposure head, and
A plurality of output units for outputting pulses of the light emission time of the light emitting element for obtaining the target exposure amount under a plurality of different light amount environments, and based on the light amount instruction information required at the time of light emission Selection means for selecting an output unit;
Scanning control means for sequentially emitting the light emitting elements along the scanning direction based on a light emission time pulse output from the output unit selected by the selection means in an environment of a light amount required at the time of light emission; ,
Have a said instruction information, the average value during light emission of the plurality of light emitting elements, an optical scanning device which is the comparison result information with the predetermined threshold value.   The optical scanning device according to claim 1, wherein the specific light amount is a maximum light amount required during the light emission. The plurality of output units set the plurality of light amount environments by changing drive currents for causing the light emitting elements to emit light, respectively, and as one of the output units, under the specific light amount environment The optical scanning device according to claim 1, further comprising an output unit that outputs a pulse of a light emission time of the light emitting element for obtaining the target exposure amount. The selection means includes two output units having a relatively large light amount,
If the average value exceeds a predetermined threshold value, select an output unit with a relatively large amount of light,
4. The optical scanning device according to claim 1, wherein when the average value is equal to or less than a predetermined threshold value, an output unit having a relatively small amount of light is selected . The correction table between a plurality of light emitting elements based on a characteristic diagram showing a relationship between the light emission time and the exposure amount is set for each of the output units. 2. An optical scanning device according to item 1 . The optical scanning device according to any one of claims 1 to 5,
An image carrier that is opposed to the light emitting surface of the optical scanning device and is relatively movable in a direction intersecting the scanning direction;
An image forming unit that forms an image on the image holding member by moving the light scanning device and the image holding member relative to each other while scanning the light emitted from the light emitting element by the optical scanning device;
An image forming apparatus .

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