JP3596970B2 - Light beam scanning device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a light beam scanning device used for an image forming device (including a color image forming device) such as a copying machine, a facsimile, a printer, a printing machine, and more particularly to a light beam scanning device having a plurality of rotating polygon mirrors. It relates to the control of the rotation phase between the respective rotating polygon mirrors.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as a light beam scanning device used in an image forming apparatus such as a copying machine, a facsimile, a printer, a printing machine, etc., a light beam generating means, and a rotating polygonal surface which deflects and scans an image carrier with a light beam generated by the light beam generating means. A mirror, driving means for rotating the rotating polygon mirror, rotating position detecting means for detecting a rotating position of the rotating polygon mirror, and the rotating polygon mirror based on a rotation reference signal and an output signal of the rotating position detecting means. A plurality of sets of rotation drive control means for controlling the drive means so as to rotate at a constant speed, and a rotation reference signal generating means for generating the rotation reference signal corresponding to each of the rotary polygon mirrors It has been known.
[0003]
In the light beam scanning device having the above configuration, based on each rotation reference signal generated by the rotation reference signal generation unit and the output signal of each rotation position detection unit, each driving unit is controlled so that each rotating polygon mirror rotates at a constant speed. Control. In the image forming apparatus equipped with the light beam scanning device, an independent latent image is formed on the corresponding image carrier by the light beam deflected and scanned by each rotating polygon mirror, and the latent image is developed. Each image is superimposed and transferred on a recording medium. Here, in order to superimpose each image on an accurate position on a recording medium, the main scanning direction (light beam scanning direction) and the sub-scanning direction (moving direction of the image carrier surface) of each image on the image carrier are required. ) Must be accurately adjusted.
[0004]
For the main scanning direction, for example, a light beam is detected at a predetermined position on a scanning path, and the writing timing of each scanning line of an image is adjusted based on the detection result. Even if the initial mounting angle of the mirror to the image carrier, that is, the surface phase of each rotary polygon mirror does not completely coincide with each other, it is possible to prevent the occurrence of image shift in the main scanning direction.
[0005]
On the other hand, in the sub-scanning direction, for example, when a plurality of image carriers are provided corresponding to a plurality of rotating polygon mirrors, the interval (pitch) between the image carriers is set to an integral multiple of the scanning pitch, and The writing start timing is adjusted in units of time required for one light beam scanning, and the image is written by rotating the polygon mirror based on the rotation reference signal of the same frequency, thereby performing one scanning over the entire image. It is possible to prevent the occurrence of an image shift in the sub-scanning direction larger than the pitch.
[0006]
However, even when the image writing start timing is adjusted in the unit of time required for the one light beam scanning, if the surface phases between the rotating polygon mirrors do not completely match each other, the scanning pitch is equal to or less than one scanning pitch. There is a problem that an image shift in the sub-scanning direction occurs (84.67 μm or less at an image resolution of 300 dpi). This image shift causes a problem of color shift when a color image is formed.
[0007]
Therefore, conventionally, in order to prevent the image shift in the sub-scanning direction of one scanning pitch or less, a method of controlling the rotation phase between the rotating polygon mirrors as follows is known.
[0008]
For example, in Japanese Patent Application Laid-Open No. 64-73369, a reference frequency as the rotation reference signal generating means for generating a reference frequency signal as the rotation reference signal is provided to each of the PLL control means as the rotation drive control means. The signal generation means and the horizontal synchronization signal output timing difference output from each of the synchronization sensors remaining in synchronization with the output of the horizontal synchronization signal as the output signal output from one synchronization sensor as the light beam detection means, Timing measuring means for measuring based on the reference frequency signal, and phase adjusting means for adjusting the phase of the reference frequency signal to be supplied to the PLL control means based on the difference between each horizontal synchronization signal output timing measured by the timing measuring means An apparatus comprising:
[0009]
According to this device, one PLL control unit starts the rotation speed control of the rotating polyhedron (rotating polygon mirror) based on the reference frequency signal generated by the reference frequency signal generating unit. When the synchronous sensor generates a horizontal synchronizing signal after receiving the laser beam deflected by the rotating polyhedron rotating at a constant speed, the timing measuring means remains in synchronization with the output of the horizontal synchronizing signal output from one synchronous sensor. A horizontal synchronization signal output timing difference output from each synchronization sensor is measured based on the reference frequency signal. Then, based on the measured horizontal synchronization signal output timing differences, the phase adjustment unit adjusts the phase of the reference frequency signal supplied to the PLL control unit. Thus, the phase shift can be finely adjusted within the pixel unit distance, and the top scan line shift of each laser beam on each photosensitive drum (image carrier) can be set to the minimum.
[0010]
In addition, for example, in Japanese Patent Application Laid-Open No. 2-170110, detecting means for receiving each light beam deflected by each rotating polygon mirror and detecting a phase difference between the beams, and detecting the phase difference detected by the detecting means The rotation phase angle of the driving means for rotating each rotating polygon mirror at a constant speed depends on the one rotating polygon mirror so as to cancel a phase angle difference between at least one rotating polygon mirror and each of the remaining rotating polygon mirrors. A light beam scanning device having phase control means for individually controlling the light beam is disclosed.
[0011]
According to this device, when each rotating polygon mirror is started by each driving means and reaches a constant speed rotation, the detecting means receives each light beam deflected by each rotating polygon mirror and detects a phase difference of each light beam. And the phase difference information is sent to the phase control means. The phase control means individually sets the rotation phase angle of each drive means and one rotation polygon so that the phase difference between at least one rotation polygon mirror and each of the remaining rotation polygon mirrors is canceled based on the detected phase difference. By controlling the mirrors to be dependent on each other, it is possible to match the write start positions of the respective light beams which are deflected and scanned from each rotary polygon mirror to the image carrier.
[0012]
Also, the above-mentioned Japanese Patent Application Laid-Open No. 2-170110 discloses an embodiment of the following two-beam system. The rotation phase synchronization control device, which also serves as the detection means and the phase control means, comprises: a first beam detect pulse signal which is an output signal from a first laser beam detector as the light beam detection means; When a second beam detect pulse signal, which is an output signal from the second laser beam detector as a means, is transmitted with a phase difference, the phase difference is measured by a time measuring means such as an internal counter circuit, and the rotation is measured. Of the plurality of reference signals output from the reference signal generator as the reference signal generating means, a reference signal for generating a phase close to the measured phase difference is selected by a selection switch and the second rotary polygon mirror is selected. The signal is sent to a second phase synchronization control unit as a rotation drive control unit for controlling the rotation drive. Accordingly, the first and second motors as the driving unit control the rotation drive of the second phase synchronization control unit and the first rotary polygon mirror using the reference signal for generating the measured phase difference. The phase synchronization control is performed by the first phase synchronization control unit. The phases of the subsequent first and second beam detection pulse signals are substantially the same, and the beam reflection surfaces of the first and second rotary polygon mirrors are in the same phase. It becomes. Therefore, the image writing positions by the respective light beams that are deflected and scanned from the first and second rotary polygon mirrors to the photosensitive drum as the image carrier become coincident.
[0013]
For example, in Japanese Patent Application Laid-Open No. Hei 5-227383, a reference write start position detection signal from a scanner motor serving as a driving means of a rotary polygon mirror serving as a reference and a write start position detection signal from a scanner motor of the remaining rotary polygon mirror are determined. It takes in the microprocessor as means, judges the time lag of the other writing position detection signal with respect to the reference writing position detection signal, and based on the judgment result, the scanner motor of the remaining rotary polygon mirror, the motor of the motor is used. One that supplies a phase control signal that increases or decreases the rotation speed is disclosed. With this configuration, the write start position by the remaining rotary polygon mirror is made coincident with the write start position by the reference rotary polygon mirror to correct the positional deviation in the sub-scanning direction.
[0014]
[Problems to be solved by the invention]
However, in the rotary polygon mirror used in the conventional apparatus that performs the phase control for controlling the rotation phase of each of the rotary polygon mirrors, the rotation unevenness is slightly generated due to the drive unevenness of the driving unit. This uneven rotation tends to increase due to a rise in temperature and deterioration over time in the driving means and the rotation driving control means for controlling the driving means. Further, the length in the rotation direction of the light reflecting surface formed on the rotary polygon mirror also varies slightly. If there is such a rotation unevenness of the rotating polygon mirror or a variation in the length of the light reflecting surface, the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror and the output signal of the light beam detecting means corresponding to the remaining rotating polygon mirror will be reduced. It is considered that the time difference from the output signal also varies.
[0015]
Further, in the phase control of the above-described conventional apparatus, based on a light beam detection signal corresponding to a reference rotary polygon among a plurality of rotary polygons, an optical writing position is controlled so as to control an image writing position of each of the remaining rotary polygons. By controlling the beam generating means, phase control is performed so that the image writing position of each of the remaining rotary polygon mirrors coincides with the image writing position of the reference rotary polygon mirror. For example, when an output signal from the light beam detection signal corresponding to the reference rotary polygon mirror is detected a predetermined number of times, the light beam generating means is controlled so as to start image writing by the remaining rotary polygon mirror. Therefore, if the time difference between the output signals of the light beam detecting means varies as described above during the period in which the phase control is not performed, such as the image writing operation period, the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is changed. After receiving, the time until receiving the output signal of the light beam detecting means corresponding to the remaining rotary polygon mirror suddenly changes by a time close to the cycle of this output signal, and the image in the sub-scanning direction close to one scanning pitch The displacement may occur suddenly.
[0016]
The image shift in the sub-scanning direction will be described with reference to a specific example of a time chart of the output signal of the light beam detecting means before and after the phase control shown in FIGS. 17A and 17B. In this specific example, two sets of laser scanning units including a laser as a light beam generating means and a rotating polygon mirror are provided, and the laser is turned on and the rotating polygon mirror is rotated at a constant speed. As described above, output signals (referred to as a write start position detection signal, a horizontal synchronization signal, or a detector pulse signal in the above-described conventional example) are output from the light beam detection means corresponding to each rotary polygon mirror. . Here, the time difference (timing difference) of another output signal DP2 with respect to the output signal DP1 is measured with reference to the output signal DP1. Assuming that the time difference fluctuates by twice the value of T4 as shown by, the measured time difference is defined as T1 as shown in FIG. When the conventional phase control based on the time difference T1 is performed under such a condition, a time chart of each output signal is as shown in FIG. After this phase control, the time difference between the other output signal DP2 and the reference output signal DP1 is twice as long as T4. For example, if the output signal DP2 is located at the position b, two sets of laser scanning are performed. The direction (surface phase) of the light reflecting surface of the rotary polygon mirror of the unit is matched, and an image without image shift can be obtained. Further, when the output signal DP2 changes to the position c, the time difference between the reference output signal DP1 and the other output signal DP2 is shifted by T4, and an image shift occurs by that amount. When the output signal DP2 changes to the position a, the direction (surface phase) of the light reflecting surface of the rotary polygon mirror is shifted only by T4 as in the case of shifting to the position c above. It changes by the amount of time close to the signal period, and an image shift close to one scanning pitch (color shift when a color image is formed) suddenly occurs. More precisely, an image shift (color shift) occurs by (one line writing time-T4).
[0017]
The present invention has been made in view of the above problems, and an object of the present invention is to provide a light beam scanning device that performs phase control at a predetermined timing to adjust the rotational phases of respective rotary polygon mirrors so as to substantially match each other. In addition, while minimizing the amount of image shift due to the rotational phase difference between the rotary polygon mirrors, it is possible to prevent sudden occurrence of image shift in the sub-scanning direction due to uneven rotation of the rotary polygon mirror during the period when the phase control is not performed. It is to provide a light beam scanning device that can perform the scanning.
[0018]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 includes a light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on an image carrier, and rotating the rotating polygon mirror. A driving unit for driving, a rotation position detection unit for detecting a rotation position of the rotary polygon mirror, a rotation drive control unit for controlling the driving unit based on a rotation reference signal and an output signal of the rotation position detection unit, A plurality of sets of light beam detecting means for detecting a light beam deflected and scanned by the rotating polygon mirror at a predetermined position on a scanning path, and generating a rotation reference signal for generating the rotation reference signal corresponding to each of the rotating polygon mirrors Means, and a time difference between an output signal of the light beam detecting means corresponding to the reference rotating polygon mirror among the plurality of rotating polygon mirrors and an output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors. Phase control means for controlling the rotation reference signal generating means so that the rotation phases of the remaining rotary polygon mirrors substantially match the reference rotary polygon mirror based on the time difference, and each of the light beams The light beam scanning in each main scanning direction is started based on the output signal of the detecting means, and the deflection scanning is performed by each of the remaining rotating polygon mirrors based on the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror. Light beam generating control means for controlling the light beam generating means, so as to start image writing in the sub-scanning direction by the light beam to be performed,A plurality of time differences from when the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors immediately after the output signal are output are plural. Times, and based on the minimum time difference that is the minimum value of the plurality of time differences,With respect to the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, the rotation signal is output such that the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors is output simultaneously or always with a delay. It is characterized by controlling the reference signal generating means.
[0020]
Claim2The invention of claim1In the light beam scanning device, when an output signal of the light beam detecting means corresponding to the reference rotating polygon is output during standby for image writing, light beam detection corresponding to each of the remaining rotating polygons immediately after the output signal is performed. A time difference until an output signal of the means is output is calculated in a certain cycle, and when the time difference becomes larger than a predetermined time difference, phase control based on the time difference at that time is performed. is there.
[0021]
Claim3The invention ofA light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position, a rotation reference signal generating means for generating the rotation reference signal corresponding to each of the rotary polygon mirrors, and a reference rotation polygon mirror among the plurality of rotation polygon mirrors The time difference between the output signal of the light beam detecting means corresponding to the above and the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors is calculated, and based on the time difference, the reference rotation time is calculated. Phase control means for controlling the rotation reference signal generation means so that the rotation phases of the remaining rotary polygon mirrors substantially coincide with the mirror; and each main scanning direction based on the output signal of each light beam detection means. At the same time, and based on the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, write the image in the sub-scanning direction with the light beam deflected and scanned by each of the remaining rotating polygon mirrors. Light beam generation control means for controlling the light beam generation means to startIn the light beam scanning device, after the output signal of the light beam detection means corresponding to the reference rotary polygon mirror is output, the output signal of the light beam detection means corresponding to each of the remaining rotary polygon mirrors immediately thereafter is output. Calculate the time difference until a plurality of times, obtain a variation range from the plurality of time differences, based on a subtraction value obtained by subtracting the variation range from any one of the plurality of time differences,For the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, so that the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors is output simultaneously or always with a delay,The rotation reference signal generating means is controlled.
[0022]
Claim4The invention ofA light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position, a rotation reference signal generating means for generating the rotation reference signal corresponding to each of the rotary polygon mirrors, and a reference rotation polygon mirror among the plurality of rotation polygon mirrors The time difference between the output signal of the light beam detecting means corresponding to the above and the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors is calculated, and based on the time difference, the reference rotation time is calculated. Phase control means for controlling the rotation reference signal generation means so that the rotation phases of the remaining rotary polygon mirrors substantially coincide with the mirror; and each main scanning direction based on the output signal of each light beam detection means. At the same time, and based on the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, write the image in the sub-scanning direction with the light beam deflected and scanned by each of the remaining rotating polygon mirrors. Light beam generation control means for controlling the light beam generation means to startIn the light beam scanning device, after the output signal of the light beam detection means corresponding to the reference rotary polygon mirror is output, the output signal of the light beam detection means corresponding to each of the remaining rotary polygon mirrors immediately thereafter is output. Is calculated based on a subtraction value obtained by subtracting a fluctuation range of the time difference measured and stored in advance from the time difference,For the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, so that the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors is output simultaneously or always with a delay,The rotation reference signal generating means is controlled.
[0023]
Claim5The invention of claim3Or4Light beam scanning deviceAfter the power is turned on, the control of the rotation reference signal generating means based on the subtraction value is performed.There is a time difference from when the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors immediately after the output signal is output. Calculated multiple times in a cycle, and one of the multiple time differencesWhen the time difference becomes larger than a predetermined time difference or when the fluctuation width obtained from the plurality of time differences becomes larger than the fluctuation width used for the previous phase control, unless the image is being written, the time difference at that time is used. Based on the subtraction value obtained by subtracting the fluctuation range, the output signal of the light beam detecting means corresponding to each of the remaining rotating polygons is simultaneously or simultaneously output with respect to the output signal of the light beam detecting means corresponding to the reference rotating polygon. The rotation reference signal generating means is controlled so that the output is always delayed.It is characterized by performing phase control.
[0024]
Claim6The invention of claim3Wherein the maximum value of the plurality of time differences is used as the time difference used for the phase control.
[0025]
Claim7The invention ofA light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position, a rotation reference signal generating means for generating the rotation reference signal corresponding to each of the rotary polygon mirrors, and a reference rotation polygon mirror among the plurality of rotation polygon mirrors The time difference between the output signal of the light beam detecting means corresponding to the above and the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors is calculated, and based on the time difference, the reference rotation time is calculated. Phase control means for controlling the rotation reference signal generation means so that the rotation phases of the remaining rotary polygon mirrors substantially coincide with the mirror; and each main scanning direction based on the output signal of each light beam detection means. At the same time, and based on the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, write the image in the sub-scanning direction with the light beam deflected and scanned by each of the remaining rotating polygon mirrors. Light beam generation control means for controlling the light beam generation means to startIn a light beam scanning device,With respect to the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, the rotation signal is output such that the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors is output simultaneously or always with a delay. Controlling the reference signal generating means,The phase control based on the time difference is not performed during the image writing operation, and the image writing operation is prohibited while the phase control based on the time difference is performed. To do.
[0026]
Claims 1 through7According to the invention, the light beams generated by the light beam generating means are deflected and scanned by the respective rotating polygon mirrors driven by the respective driving means onto the corresponding image carriers.
In addition, each rotation position detection means detects the rotation position of each of the rotary polygon mirrors, and the rotation drive control means based on the rotation reference signal generated by the rotation reference signal generation means and the output signal of each rotation position detection means. The driving means is controlled such that the frequency and the phase of the output signal coincide with the frequency and the phase of the rotation reference signal, and the respective rotating polygon mirrors rotate at a constant speed.
Further, each light beam detecting means detects a light beam scanned and deflected by each of the rotating polygonal mirrors at a predetermined position on each scanning path, and the light beam generation control means controls the light beam generating means, and The light beam scanning in each main scanning direction is started based on the output signal of the beam detecting means, and is deflected by each of the remaining rotating polygon mirrors based on the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror. By starting image writing in the sub-scanning direction by the scanned light beam, the writing start position of the image in the main scanning direction is adjusted to a predetermined position, and the writing start position of the image in the sub-scanning direction is adjusted with an accuracy of one scanning pitch. Adjust to the predetermined position.
Still further, the rotation control signal generation means is controlled by the phase control means, and the output signal of the light beam detection means corresponding to the reference rotation polygon mirror among the plurality of rotation polygon mirrors, and the output signal corresponding to each of the remaining rotation polygon mirrors A sub-scan is performed by calculating a time difference between the output signal of the light beam detecting means and the rotation phase of each of the remaining rotary polygon mirrors with respect to the reference rotary polygon mirror based on the time difference. The writing start position of the image in the direction is adjusted to a predetermined position with an accuracy of one scanning pitch or less.
[0027]
Then, by controlling the rotation reference signal generation means, the output signal of the light beam detection means corresponding to each of the remaining rotation polygon mirrors is changed with respect to the output signal of the light beam detection means corresponding to the reference rotation polygon mirror. By simultaneously or always delaying the output, during the period until the next phase control, the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output, and then the remaining The time difference until the output signal of the light beam detecting means corresponding to each rotary polygon mirror is output, that is, the time difference corresponding to the image shift amount is made as short as possible, and the time difference corresponding to the image shift amount is one of the output signals. Make sure that it does not suddenly become longer by the time close to the cycle.
[0028]
In particular,Claim1In the invention of,PreviousA plurality of time differences from when the output signal of the light beam detection means corresponding to the reference rotary polygon mirror is output to when the output signal of the light beam detection means corresponding to each of the remaining rotary polygon mirrors immediately after the output signal is output are plural. Times, and based on the minimum time difference that is the minimum value of the plurality of time differences, controlling the rotation reference signal generating means in a direction to reduce the minimum value to zero, so that the time difference corresponding to the image shift amount can be reduced as much as possible. In addition to shortening, the time difference corresponding to the image shift amount is prevented from being suddenly increased by a time close to one cycle of the output signal.
[0029]
In particular,Claim2In the invention of the claim,1In the light beam scanning device, when an output signal of the light beam detecting means corresponding to the reference rotating polygon is output during standby for image writing, light beam detection corresponding to each of the remaining rotating polygons immediately after the output signal is performed. By calculating the time difference until the output signal of the means is output in a certain cycle, and when the time difference becomes larger than a predetermined time difference, by performing phase control based on the minimum value of the time difference at that time, Even when the time difference is going to change over time as well as the normal fluctuation, the time difference corresponding to the image shift amount is shortened as much as possible, and the time difference corresponding to the image shift amount is close to one cycle of the output signal. Don't suddenly lengthen by minutes.
[0030]
In particular,Claim3In the invention of,PreviousA plurality of time differences from when the output signal of the light beam detection means corresponding to the reference rotary polygon mirror is output to when the output signal of the light beam detection means corresponding to each of the remaining rotary polygon mirrors immediately after the output signal is output are plural. The rotation reference signal is generated in a direction to make the subtraction value zero based on a subtraction value obtained by subtracting the variation width from any one of the plurality of time differences. By controlling the means, the time difference corresponding to the image shift amount is shortened as much as possible, and the time difference corresponding to the image shift amount is prevented from suddenly increasing by a time close to one cycle of the output signal.
[0031]
In particular,Claim4In the invention of,PreviousThe time difference from when the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors immediately after that is output is calculated. Then, based on a subtraction value obtained by subtracting a variation width of the time difference measured and stored in advance from the time difference, the rotation reference signal generating unit is controlled in a direction to make the subtraction value zero, thereby obtaining the image. The time difference corresponding to the shift amount is made as short as possible, and the time difference corresponding to the image shift amount is prevented from suddenly increasing by a time close to one cycle of the output signal.
[0032]
In particular,Claim5In the invention of the claim,3Or4Light beam scanning device, After performing the phase control based on the subtraction value when the power is turned on,There is a time difference from when the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors immediately after the output signal is output. Calculated multiple times in a cycle, and one of the multiple time differencesWhen the time difference becomes larger than a predetermined time difference or when the fluctuation width obtained from the plurality of time differences becomes larger than the fluctuation width used in the previous phase control, if the image writing is not being performed, the following phase is used. Perform control. That is, if the image writing is not being performed at that time, the output signal of the light beam detecting means corresponding to the reference rotary polygon is based on the subtraction value obtained by subtracting the fluctuation range from the time difference at that time, and The rotation reference signal generating means is controlled so that the output signals of the light beam detecting means corresponding to each of the rotary polygon mirrors are output simultaneously or always with a delay. This controlTherefore, even when the time difference is not only a normal change but also changes with time, the time difference corresponding to the image shift amount is shortened as much as possible, and the time difference corresponding to the image shift amount is one cycle of the output signal. Avoid suddenly increasing the time close to.
[0033]
In particular,Claim6In the invention of,Request3In the light beam scanning device, based on a subtraction value obtained by subtracting the fluctuation range from a maximum value of the plurality of time differences, the rotation reference signal generating unit is controlled in a direction to make the subtraction value zero, thereby obtaining the image. The time difference corresponding to the shift amount is made shorter.
[0034]
In particular,Claim7In the invention of,PreviousThe phase control based on the time difference is prevented from being performed during the image writing operation, and the image writing operation is prohibited while the phase control based on the time difference is being performed. The time difference corresponding to the image shift amount does not suddenly change during the writing operation.
[0035]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment in which the present invention is applied to a light beam scanning device used in a four-drum type color laser beam printer (hereinafter, referred to as a “color printer”) as an image forming apparatus will be described.
[Embodiment 1]
FIG. 1 is a perspective view illustrating a schematic configuration of the color printer according to the present embodiment. This color printer includes four sets of image forming units and the like for forming a color image in which images of four colors (yellow, magenta, cyan, and black) are superimposed. Each image forming unit includes a photosensitive drum 1 as an image carrier, a charging charger 2, a light beam scanning unit 3, a developing unit 4, and a transfer charger 5, and performs charging, exposure, development, and normal electrophotographic processes. By performing a transfer process, the first color image is transferred onto the recording paper 7 conveyed by the transfer belt 6 in the direction of arrow A, and then the second color image, the third color image, and the fourth color image are transferred in this order. Can be formed on the recording paper 7.
[0036]
FIG. 2 is an explanatory diagram of an optical system of the laser beam scanning unit 3, and FIG. 3 is a block diagram of a control system of a light beam scanning device including four sets of the laser beam scanning unit 3. Here, the numerical values in parentheses of the reference numerals in FIG. 3 indicate the number of sets of laser scanning units to which the constituent elements belong.
Each laser scanning unit 3 of the light beam scanning device of the present color printer includes a laser light source (LD) 8 as a light beam generating means and a rotary polygon mirror for deflecting and scanning the laser beam from the laser light source 8 onto the photosensitive drum 1. A polygon mirror 9, a polygon motor 10 as driving means for driving the polygon mirror 9 to rotate in the direction of arrow B, a Hall element 11 as rotation position detecting means for detecting the rotation position of the polygon mirror 9, and a rotation reference A motor driver (PLL control unit) 12 as rotation drive control means for controlling the polygon motor 10 so that the polygon mirror 9 rotates at a constant speed based on the rotation reference signal generated by the signal generation means and the output signal of the Hall element 11; A light beam detecting means for detecting a laser beam scanned and deflected by the polygon mirror 9 at a scanning start position. A laser beam sensor 13, a controller 14 such as a light beam generation control unit for controlling the laser light source 8 based on the output signal of the laser beam sensor 13.
[0037]
The laser beam from each of the laser light sources 8 is turned on / off by a laser driver (not shown) operating based on the color-separated image information, and is deflected and scanned by a polygon mirror 9 rotationally driven by a polygon motor 10. Then, the light is irradiated on the surface of the photosensitive drum 1 through the lens. Further, a beam detecting mirror 13a is provided at an end (scanning start position) of a scanning range (LD scanning range in FIG. 2) of the laser beam from the laser light source 8, and the laser beam reflected by the mirror 13a is used for the mirror 13a. The laser beam is detected by the laser beam detector 13 and output to the controller 14 as a beam detect pulse signal. Further, a repetitive pulse signal that is turned on / off at a frequency corresponding to the rotation of the polygon mirror 9 is output from the Hall element 11 to the motor driver (PLL control unit) 12.
[0038]
Further, the light beam scanning device includes a rotation reference signal generating means for generating a plurality of rotation reference signals corresponding to each of the polygon mirrors 9 (1) to 9 (4), and a control means therefor. As shown in FIG. 3, the rotation reference signal generating means includes a reference signal generator 15, four sets of rotation reference signal generators 16 (1) to 16 (4), and three sets of selectors 17 (2) to 17 ( 3), and the controller 14 is used as the phase control means. In addition to controlling the laser light source 8 and the selector 17, the controller 14 is also used for checking the rotation of the polygon motor 10 at a constant speed, measuring the time difference between detector pulse signals described later, and the like.
[0039]
By the way, when forming a color image with a color printer equipped with the light beam scanning device having the above configuration, it is necessary to superimpose independently created images for each color of yellow, magenta, cyan, and black at an accurate position on recording paper. is there. In order to superimpose the image of each color on the accurate position on the recording paper, the writing start position in the main scanning direction and the sub-scanning direction by the laser beam corresponding to each color on the photosensitive drum 1 must be accurately adjusted. . The main scanning direction is adjusted by always detecting the scanning start position of the laser beam with the laser beam detector 13 and adjusting the writing timing of the recording image data for each color, thereby making the light beam scanning device in the printer compatible with the light beam scanning device. Even if the relative positional relationship with the body drum 1 does not completely match for each color, color misregistration does not occur when images of each color are superimposed. On the other hand, for the adjustment in the sub-scanning direction, the photoconductor pitch (L in FIG. 1) is maintained at an integral multiple of the scanning pitch, and the laser scanning start position is always detected by the laser beam detector 13 to write the recording image data. By controlling the timing by the controller 14, each polygon mirror is driven based on the rotation reference signal of the same scanning frequency to form an image of each color, and no color shift occurs when the images of each color are superimposed. Like that.
[0040]
However, if the rotation reference signals having the same phase are used for the rotation drive of each polygon mirror 9 in controlling the laser beam scanning, one rotation pitch or less in the sub-scanning direction (84.67 μm or less in the case of 300 dpi image resolution) In the light beam scanning device according to the present embodiment, the rotational phase of the polygon motor 10 for driving the polygon mirrors 9 is controlled so that the surface phases of the polygon mirrors 9 match. Thus, the color shift is corrected.
[0041]
FIG. 4 is a flowchart of the rotation phase control of the polygon motor, and FIGS. 5A and 5B are time charts of each rotation reference signal and the output signal of each laser beam detector 13 before the phase control, respectively. FIGS. 6A and 6B are time charts of the respective rotation reference signals and the output signals of the respective laser beam detectors 13 after the phase control.
When the power switch of the color printer is turned on, power is supplied to the polygon motor 10, and the rotation reference signal / PCLK1 (see FIG. 5A) of a predetermined frequency output from the rotation reference signal generator 16 (1) is output to the motor driver. (PLL control unit) The selectors 17 (2) to 17 (4) are supplied to the controller 14 so as to select the rotation reference signal / PCLK1 from the rotation reference signal generation unit 16 (1). The remaining motors are controlled and this rotation reference signal / PCLK1 is used as rotation reference signals / PCLK2 to / PCLK4 (see FIG. 5A. / PCLK3 and / PCLK4 are not shown but are the same as / PCLK2). The signals are supplied to drivers (PLL control units) 12 (2) to 12 (4) (step 1). When an ON signal is sent from the controller 14 to each of the motor drivers (PLL control units) 12 (1) to 12 (4), the polygon motors 10 (1) to 10 (4) rotate, and the polygon motors 10 (1) to 10 (4) rotate. Is rotated at a constant speed, a motor lock signal is sent from the motor drivers (PLL control units) 12 (1) to 12 (4) to the controller 14 (steps 2 to 4).
[0042]
Next, when each polygon motor 10 rotates at a constant speed, each laser light source 8 is turned on (step 5). In this case, each laser light source 8 may be turned on only when the laser beam passes through the beam detecting mirror 13a in FIG. When the laser light source 8 is turned on, beam detection pulse signals DP1 to DP4 are transmitted from the laser beam detectors 13 (1) to 13 (4) to the controller 14 (step 6). For example, as shown in FIG. 5B, a signal DP1 is output from the laser beam detector 13 (1), and a signal DP2 is output from the laser beam detector 13 (2). Hereinafter, the remaining beam detect pulse signals DP3 and DP4 will not be described because they can be considered in the same manner as DP2. It is also assumed that the time difference between DP2 and the beam detect pulse signal DP1 fluctuates within the width of T5.
[0043]
In the present embodiment, since the phase control is performed with reference to the polygon mirror 9 (1) and the polygon motor 10 (1), the controller 14 detects the rise of the pulse of each of the beam detect pulse signals DP1 and DP2, and The time difference T1 from the pulse rise of the signal DP1 to the pulse rise of the remaining signal DP2 is calculated, and the calculated time difference is stored (steps 7, 8). Such detection of the beam detect pulse signal, calculation and storage of the time difference are repeated a predetermined number of times (n times) (steps 6 to 9). Then, the minimum value of the plurality of stored time differences is selected (step 10). In the example of FIG. 5B, the time difference T2 is selected. Then, the selected time difference T2 is converted into data for input to the rotation reference signal generator 16 (2) (step 11), and the data converted from the time difference T2 is input to the rotation reference signal generator 16 (2). (Step 12).
[0044]
In the rotation reference signal generator 16 (2), based on the data sent from the controller 14 and the reference signal sent from the reference signal generator 15, as shown in FIG. A new rotation reference signal / PCLK2 whose phase is shifted by only this is output (step 13). The rotation reference signal / PCLK2 is sent to the selector 17 (2), and the switching signal from the controller 14 causes the selector 17 (2) to switch the rotation reference signal from the signal / PCLK1 to the signal / PCLK2, and the motor driver (PLL control unit) ) 12 (2) (steps 14 and 15).
[0045]
Then, the motor driver (PLL control unit) 12 (1) receives the rotation position detection signal output from the rotation position detection hall element 11 and the rotation reference signal / PCLK2 output from the rotation reference signal generation unit 16 (2). And the phase control of the polygon motors is performed, so that each polygon motor 10 (2) rotates at a constant speed again. When the polygon motor 10 (2) rotates at a constant speed, a motor lock signal is detected (step 16).
[0046]
FIG. 6B shows detect pulse signals DP1 and DP2 after the phase control. Before the phase control shown in FIG. 5 (b), it can be seen that the phase is shifted by the maximum (T2 + T5), but is shifted by the maximum T5. In the above-described phase control, the case has been described where the rotation phase of the polygon mirror 9 (2) is controlled based on the time difference between DP2 and the detect pulse signal DP1, but the remaining polygon mirrors 9 (3) and 9 (4) are controlled. The rotation phase can be similarly controlled based on the time difference between DP3 and DP4 with respect to detect pulse signal DP1. It is preferable that the number of times of detection of the detect pulse signal and the calculation of the time difference be as large as possible.
[0047]
FIG. 7 is a flowchart of image writing control using the light beam scanning device. This image writing control is performed after the phase control of FIG. 4 is completed. In this embodiment, the beam detection pulse signal DP1 corresponding to the reference polygon mirror 9 (1) is used as an image writing start signal by each laser scanning unit 3.
In FIG. 7, when an image writing start command signal is sent from the operation unit or the external control unit (host) of the color printer, the controller 14 starts counting the reference beam detect pulse signal DP1 (step 1). . Then, when the input of the signal DP1 is started, the writing of the image of the first color is started, and the signal DP1 is written on the photosensitive drum 1 line by line as a line synchronization signal (steps 2, 3). When the signal DP1 has been counted for the specified number of lines (the number of writing lines), the writing of the image of the first color is completed on that line (steps 4 and 5).
[0048]
Here, the photoconductor pitch L between the first color laser scanning unit and the second color laser scanning unit is m times the scanning pitch (m is an integer), and the first color laser scanning unit and the third color laser scanning unit are different. Is 2 m times the scanning pitch, and the photoconductor pitch L between the first color laser scanning unit and the fourth color laser scanning unit is 3 m times the scanning pitch.
[0049]
When the count number of the reference beam detect pulse signal DP1 becomes (m + 1), the counting of the beam detect pulse signal DP2 of the second color is started (steps 6, 7). Then, when the input of the signal DP2 is started, the writing of the image of the second color is started, and the signal DP2 is written on the photosensitive drum 1 line by line as a line synchronization signal (steps 8 and 9). When the specified number of lines (number of writing lines) of the signal DP2 has been counted, the counting of the signal DP2 is terminated, and the writing of the image of the second color is terminated on that line (steps 10 to 12).
[0050]
When the count number of the reference beam detect pulse signal DP1 becomes (2m + 1), the counting of the beam detect pulse signal DP3 for the third color is started (steps 13 and 14). Then, when the input of the signal DP3 is started, the writing of the image of the third color is started, and the signal DP3 is written on the photosensitive drum 1 line by line as a line synchronization signal (steps 15 and 16). When the signal DP3 has been counted the specified number of lines (the number of writing lines), the counting of the signal DP3 is terminated, and the writing of the image of the third color is terminated on that line (steps 17 to 19).
[0051]
When the count number of the reference beam detect pulse signal DP1 becomes (3m + 1), the counting of the fourth color beam detect pulse signal DP4 is started (steps 20 and 21). Then, when the input of the signal DP4 is started, the writing of the image of the fourth color is started, and the signal DP4 is written on the photosensitive drum 1 line by line as a line synchronization signal (steps 22 and 23). When the signal DP4 has been counted the specified number of lines (the number of writing lines), the counting of the signal DP4 is terminated, and the writing of the image of the fourth color is terminated on that line (steps 24 to 26).
[0052]
As described above, in the present embodiment, the beam detect pulse signals DP2, DP3, DP4 detected immediately after the beam detect pulse signals DP1 corresponding to the reference first color image are detected a predetermined number of times (m + 1, 2m + 1, 3m + 1), respectively. By starting image writing for the second to fourth colors, the images are superimposed in units of one scanning pitch in the sub-scanning direction, so that color shift of each image does not occur.
[0053]
In addition, since the start of the image writing is controlled, the remaining signals DP2, DP3, and DP4 are always detected immediately after the beam detect pulse signal DP1, so that the entire image is scanned in units of one scanning pitch. In the present embodiment, the time difference between the remaining signals DP2, DP3, and DP4 with respect to the signal DP1 fluctuates due to uneven rotation of each polygon mirror 9 due to the above-described phase control. However, since the signals DP2, DP3, and DP4 are always output simultaneously or with a delay with respect to the DP1, it is possible to prevent sudden occurrence of a color shift close to one scanning pitch during the image writing operation.
[0054]
Further, due to the above-described phase control, the color shift of one scanning pitch or less is generated only by an amount corresponding to the variation width T5 of the time shift of the signals DP2, DP3, and DP4 with respect to the beam detect pulse signal DP1..
[0055]
[Embodiment 2]
Next, another embodiment of the present invention will be described. The optical system and the control system of the light beam scanning device according to the present embodiment are the same as those in the configurations shown in FIGS.
FIG. 8 is a flowchart of the rotation phase control of the polygon motor according to the present embodiment. The difference from the phase control in the first embodiment is that, even after the first phase control after the power is turned on and the motor lock signal is detected, the time difference is calculated from the detect pulse signal and the value is defined in advance as the value. The point is that phase control is performed based on the result of comparison with the time difference.
[0056]
Hereinafter, a control flow after detecting the motor lock signal after the first phase control will be described. When the motor lock signal is detected in the first phase control (step 16), the image writing is enabled (READY). However, the detection of the detect pulse signals DP1 to DP4 and the time difference (T1, T1 in FIG. The calculation of T2, T3, etc.) is continued n times, and the minimum value T2 of the plurality of time differences is selected (steps 17 to 21). When the time difference data (minimum value) becomes larger than the predetermined time difference data, unless the image writing is being performed, the operation after the data conversion described in the first embodiment is performed, and the same phase is obtained. Control is performed (steps 22 to 29). Then, the above operation is repeated. Here, when the newly calculated time difference data (minimum value) is equal to or less than the predetermined time difference data or during the image writing operation, the detection of the detect pulse signals DP1 to DP4 and the calculation of the time difference are repeatedly performed. Will be.
[0057]
In the flowchart of FIG. 8, the phase control of the polygon mirrors 9 (2) to 9 (4) is performed at the same time based on the time difference between DP2, DP3, and DP4 with respect to the detect pulse signal DP1. It is processed in parallel. Therefore, when only one of the minimum values of the time difference between the detect pulse signal DP1 and the remaining signals DP2, DP3, DP4 becomes larger than the predetermined time difference data, the other time difference calculation is continued. Phase control is performed only at the position where the size becomes large. The specified value of the time difference data is determined from an allowable color shift amount, may be stored in advance, and may be externally changeable.
[0058]
According to the phase control according to the present embodiment, the time difference is calculated not only when the power is turned on, but also continuously thereafter, and the phase control is executed as necessary. it can.
[0059]
[Embodiment 3]
Next, still another embodiment of the present invention will be described. The optical system and the control system of the light beam scanning device according to the present embodiment are the same as those in the configurations shown in FIGS.
FIG. 9 is a flowchart of the rotation phase control of the polygon mirror according to the present embodiment. The difference from the phase control in the first embodiment is not the minimum time difference, but the variation width calculated for n times, and the phase control is performed based on the difference obtained by subtracting the variation width from an arbitrary time difference. (Steps 10 and 11 in the figure).
[0060]
FIGS. 10 to 12 show the rotation reference signals of the polygon mirrors 9 (1) and 9 (2) after the phase control and the detect pulse signals DP1 and DP2 after the phase control, respectively, in the third embodiment. The relationship between DP1 and DP2 before the phase control is as shown in FIG. 5B, and the variation width of the time difference between DP1 and DP2 is T5. Assuming that the time difference is T2, the rotation reference signal / PCLK2 has a phase advanced by T2-T5 from the reference / PCLK1 as shown in FIG. 10A, and as a result, as shown in FIG. As shown in b), there is a time difference between the minimum T5 and the maximum T5 × 2, and a color shift occurs correspondingly (part 1). Assuming that the time difference is T1, the rotation reference signal / PCLK2 has a phase advanced by T1-T5 from the reference / PCLK1 as shown in FIG. 11A, and as a result, FIG. ), The time difference between the minimum T4 and the maximum T4 + T5, and a color shift occurs by that amount (part 2). Assuming that the time difference is T3, the rotation reference signal / PCLK2 has a phase advanced by T3-T5 from the reference / PCLK1 as shown in FIG. 12A, and as a result, FIG. ), There is a time difference between the minimum 0 and the maximum T5, and a color shift occurs correspondingly (part 3).
Although three examples have been described above, it can be seen that although there is a difference in the amount of color misregistration, color misregistration close to one line does not occur in any case.
[0061]
[Embodiment 4]
FIG. 13 is a flowchart of the phase control according to still another embodiment. This phase control is basically the same as the control flow shown in FIG. 9 of the third embodiment, except that the variation width of the time difference between the signals DP2, DP3, and DP4 with respect to the detect pulse signal DP1 is measured and stored in advance. The difference is that the stored value is used for control. In this case, as shown in steps 7 and 8 of the control flow of FIG. 13, only the time difference is calculated, the data of the fluctuation width stored in advance is subtracted from the time difference, and phase control is performed using the subtraction value. Will be.
According to the phase control according to the present embodiment, the function for calculating the fluctuation width is not required, and thus the configuration of the controller 14 can be simplified.
[0062]
[Embodiment 5]
Next, still another embodiment of the present invention will be described. The optical system and the control system of the light beam scanning device according to the present embodiment are the same as those in the configurations shown in FIGS.
FIG. 14 is a flowchart of the rotation phase control of the polygon mirror according to the present embodiment. The phase control according to the present embodiment is basically the same as the control according to the third embodiment, except that the variation width of the time difference calculated from the detect pulse signal is stored (step 11 in the figure). Even after the first phase control after power-on is completed and the motor lock signal is detected, the fluctuation width of the time difference calculated from the plurality of detect pulse signals is compared with the previous value, and further the plurality of detect pulse signals are detected. The third embodiment differs from the third embodiment in that a selected arbitrary time difference value is compared with a predetermined time difference, and phase control is performed based on the comparison result.
[0063]
In FIG. 14, after the power is turned on, the first phase control is performed, and when the motor lock signal is detected, the image writing is enabled (READY) (steps 1 to 17). Even after the READY state, the detection of the detect pulse signals DP1 to DP4 is performed, the fluctuation width obtained by n times is calculated, and an arbitrary time difference is selected from a plurality of time differences (steps 18 to 22). . Then, when the fluctuation width or the selected time difference becomes larger than the fluctuation width stored and used in the previous phase control and the predetermined time difference, if the image is not being written, the new fluctuation width is stored. Then, phase control is performed based on a subtraction value obtained by subtracting the fluctuation range from the time difference (steps 23 to 31). When the fluctuation width is equal to or less than the stored value, the time difference is equal to or less than the specified value, or when the image writing operation is being performed, processing from detection of the detect pulse signals DP1 to DP4 to comparison of data is performed. When the phase control is completed, the processes from the detection of the detect pulse signals DP1 to DP4 to the comparison of data are performed again.
[0064]
In the flowchart of FIG. 14, the phase control of the polygon mirrors 9 (2) to 9 (4) is performed simultaneously based on the time difference between DP2, DP3, and DP4 with respect to the detect pulse signal DP1, but all are described. It is processed in parallel. Therefore, when only one of the time difference or the fluctuation width between the detect pulse signal DP1 and the remaining signals DP2, DP3, and DP4 is different from the predetermined time difference or the stored fluctuation width, the other time difference or the fluctuation width is calculated. And phase control is performed only at different points. The specified value of the time difference data is determined from an allowable color shift amount, may be stored in advance, and may be externally changeable.
[0065]
According to the phase control according to the present embodiment, the time difference is calculated not only when the power is turned on, but also continuously thereafter, and the phase control is executed as necessary. it can.
[0066]
[Embodiment 6]
FIG. 15 is a flowchart of the phase control according to still another embodiment. This phase control is basically the same as the control flow shown in FIG. 14 of the fifth embodiment, except that the maximum time difference is selected from a plurality of detected time differences and used for control. In the example of the detect pulse signal shown in FIG. 5B, T3 is the maximum time difference.
According to the phase control according to the present embodiment, the amount of color misregistration can be further reduced as compared with the case of the fifth embodiment.
[0067]
[Embodiment 7]
FIG. 16 is a flowchart of the phase control according to still another embodiment. This phase control is basically the same as the control flow of FIG. 8 of the second embodiment, except that the phase control is not performed during the image writing operation, and the image writing is prohibited during the phase control. The difference is that the image writing standby state is set.
In FIG. 16, after the power is turned on, the first phase control is performed, and when the motor lock signal is detected, the image writing is enabled (READY) (steps 1 to 16). After entering the READY state, the image writing control unit is notified that the image writing is possible (step 17). Further, when the minimum value T2 is selected and the phase control is performed, the image writing disabled state is similarly notified to the image writing control unit, and the image writing standby state is set. Steps 18-25). Then, when the motor lock signal is detected after the phase control, the image writing is started (steps 26 to 32).
According to the phase control according to the present embodiment, it is possible to prevent the image from being disturbed by performing the image writing during the phase control.
[0068]
In each of the above embodiments, an example in which the light beam scanning device according to the present invention is applied to a four-drum type color printer including a laser scanning unit and four sets of photosensitive drums has been described. The present invention is not limited to the drum system, but can be applied to a two-drum, three-drum, or five-drum system. Further, the present invention can be applied to a photosensitive drum 1 provided with a plurality of laser scanning units.
[0069]
In each of the above embodiments, an example in which the light beam scanning device according to the present invention is applied to a color printer has been described. However, the present invention relates to a light beam scanning device used in another image forming apparatus such as a copying machine and a facsimile. It can also be applied to
[0070]
【The invention's effect】
Claims 1 through7According to the invention, during the period until the next phase control, the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output, and then the output signal corresponding to each of the remaining rotary polygon mirrors immediately thereafter is output. The time difference corresponding to the image shift amount until the output signal of the light beam detecting means is output is made as short as possible, and the time difference corresponding to the image shift amount is not suddenly increased by a time close to one cycle of the output signal. I have to. Therefore, the amount of image shift due to the rotational phase difference between the rotary polygon mirrors can be reduced as much as possible, and the image shift in the sub-scanning direction due to uneven rotation of the rotary polygon mirror can be prevented from occurring suddenly. .
[0071]
In particular, the claims2Or5According to the invention, even when the time difference corresponding to the image shift amount is not only a normal change but also changes over time, the time difference corresponding to the image shift amount is shortened as much as possible, and the image shift amount is reduced. Since the corresponding time difference is prevented from suddenly increasing by a time close to one cycle of the output signal, there is an effect that an image shift due to a temporal change can be prevented.
[0072]
In particular, the claims4According to the invention, the time difference between the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror and the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors is measured and stored in advance. Since the rotation reference signal generating means is controlled based on a subtraction value obtained by subtracting the fluctuation width of the time difference, the time difference is calculated a plurality of times, and the fluctuation width is further calculated from the plurality of time differences. Thus, there is an effect that the configuration of the phase control means can be simplified by the function of calculating the fluctuation width.
[0073]
In particular, the claims6According to the invention of,PreviousBased on a subtraction value obtained by subtracting the fluctuation range from the maximum value of the plurality of time differences, the time difference corresponding to the image shift amount is controlled by controlling the rotation reference signal generation unit in a direction to make the subtraction value zero. Since the length is shorter, there is an effect that the image shift amount can be further reduced.
[0074]
In particular, the claims7According to the invention, the phase control based on the time difference is not performed during the image writing operation, and the image writing operation is prohibited while the phase control based on the time difference is performed. By doing so, the time difference corresponding to the image shift amount does not suddenly change during the image writing operation, so that it is possible to prevent the image from being disturbed by performing the image writing during the phase control. There is.
[Brief description of the drawings]
FIG. 1 is a perspective view illustrating a schematic configuration of a color printer according to an embodiment of the invention.
FIG. 2 is an explanatory diagram of an optical system of a laser beam scanning unit of the color printer.
FIG. 3 is a block diagram of a control system of the light beam scanning device of the color printer.
FIG. 4 is a flowchart of rotation phase control in the light beam scanning device.
5A and 5B are time charts of a rotation reference signal before phase control and an output signal of each laser beam detector, respectively.
6A and 6B are time charts of a rotation reference signal after phase control and an output signal of each laser beam detector, respectively.
FIG. 7 is a flowchart of image writing control by the light beam scanning device.
FIG. 8 is a flowchart of rotation phase control according to another embodiment.
FIG. 9 is a flowchart of rotational phase control according to still another embodiment.
10A and 10B are time charts showing an example of a rotation reference signal and an output signal of a laser beam detector after phase control in the same rotation phase control.
11A and 11B are time charts showing another example of the rotation reference signal and the output signal of the laser beam detector after the phase control in the rotation phase control.
12A and 12B are time charts showing still another example of the rotation reference signal and the output signal of the laser beam detector after the phase control in the same rotation phase control, respectively.
FIG. 13 is a flowchart of rotational phase control according to still another embodiment.
FIG. 14 is a flowchart of rotational phase control according to still another embodiment.
FIG. 15 is a flowchart of rotational phase control according to still another embodiment.
FIG. 16 is a flowchart of rotational phase control according to still another embodiment.
FIGS. 17A and 17B are time charts of output signals of a laser beam detector before and after rotation phase control according to a conventional example, respectively.
[Explanation of symbols]
1 Photoconductor drum
3 Light beam scanning unit
8 Laser light source
9 Polygon mirror
10 Polygon motor
11 Hall element
12 Motor driver
13 Laser beam detector
14 Controller
15 Reference signal generator
16 rotation reference signal generator
17 Selector

Claims (7)

A light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position,
A rotation reference signal generating unit that generates the rotation reference signal in correspondence with each of the rotating polygon mirrors; an output signal of a light beam detection unit corresponding to the reference rotation polygon mirror among the plurality of rotation polygon mirrors; A time difference between the output signal of the light beam detecting means corresponding to the rotating polygon mirror is calculated, and the rotation phase of each of the remaining rotating polygon mirrors substantially matches the reference rotating polygon mirror based on the time difference. Phase control means for controlling the rotation reference signal generating means, light beam scanning in each main scanning direction is started based on an output signal of each light beam detection means, and light corresponding to the reference rotation polygon mirror is provided. The light beam generating means is controlled based on the output signal of the beam detecting means so as to start image writing in the sub-scanning direction by the light beam deflected and scanned by the remaining rotary polygon mirrors. In the light beam scanning apparatus and an optical beam generation control unit that,
A plurality of time differences from when the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors immediately after the output signal are output are plural. Times, and based on the minimum time difference that is the minimum value of the plurality of time differences, the output signal of the light beam detection means corresponding to the reference rotary polygon mirror is used as the light signal corresponding to each of the remaining rotary polygon mirrors. A light beam scanning device , wherein the rotation reference signal generating means is controlled so that output signals of the beam detecting means are output simultaneously or always with a delay . 2. The light beam scanning device according to claim 1 , wherein an output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output during standby for image writing, and the output signal corresponds to each of the remaining rotary polygon mirrors immediately thereafter. A time difference until an output signal of the light beam detecting means is output is calculated at a certain cycle, and when the time difference becomes larger than a predetermined time difference, phase control based on the time difference at that time is performed. Light beam scanning device. A light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position,
A rotation reference signal generating unit that generates the rotation reference signal in correspondence with each of the rotating polygon mirrors; an output signal of a light beam detection unit corresponding to the reference rotation polygon mirror among the plurality of rotation polygon mirrors; A time difference between the output signal of the light beam detecting means corresponding to the rotating polygon mirror is calculated, and the rotation phase of each of the remaining rotating polygon mirrors substantially matches the reference rotating polygon mirror based on the time difference. Phase control means for controlling the rotation reference signal generating means, light beam scanning in each main scanning direction is started based on an output signal of each light beam detection means, and light corresponding to the reference rotation polygon mirror is provided. The light beam generating means is controlled based on the output signal of the beam detecting means so as to start image writing in the sub-scanning direction by the light beam deflected and scanned by the remaining rotary polygon mirrors. In the light beam scanning apparatus and an optical beam generation control unit that,
A plurality of time differences from when the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors immediately after the output signal are output are plural. Times, the variation width is obtained from the plurality of time differences, and the output of the light beam detection means corresponding to the reference rotating polygon is based on a subtraction value obtained by subtracting the variation width from any one of the plurality of time differences. Controlling the rotation reference signal generating means so that an output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors is output simultaneously or always with respect to the signal. Scanning device. A light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position,
A rotation reference signal generating unit that generates the rotation reference signal in correspondence with each of the rotating polygon mirrors; an output signal of a light beam detection unit corresponding to the reference rotation polygon mirror among the plurality of rotation polygon mirrors; A time difference between the output signal of the light beam detecting means corresponding to the rotating polygon mirror is calculated, and the rotation phase of each of the remaining rotating polygon mirrors substantially matches the reference rotating polygon mirror based on the time difference. Phase control means for controlling the rotation reference signal generating means, light beam scanning in each main scanning direction is started based on an output signal of each light beam detection means, and light corresponding to the reference rotation polygon mirror is provided. The light beam generating means is controlled based on the output signal of the beam detecting means so as to start image writing in the sub-scanning direction by the light beam deflected and scanned by the remaining rotary polygon mirrors. In the light beam scanning apparatus and an optical beam generation control unit that,
Calculate the time difference from when the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output to when the output signal of the light beam detecting means corresponding to each of the remaining rotary polygon mirrors immediately after is output. Then, based on a subtraction value obtained by subtracting the fluctuation width of the time difference measured and stored in advance from the time difference, an output signal of the light beam detection means corresponding to the reference rotary polygon mirror is used to output the remaining signals. A light beam scanning device , wherein the rotation reference signal generating means is controlled such that output signals of the light beam detecting means corresponding to the rotary polygon mirror are output simultaneously or always with a delay . The light beam scanning device according to claim 3 or 4 ,
After controlling the rotation reference signal generating means based on the subtraction value at power ON,
From the output of the output signal of the light beam detecting means corresponding to the previous SL reference rotary polygon mirror, the difference in time output signal of the light beam detecting means corresponding to said each remaining rotary polygonal mirror immediately is output Calculated multiple times in a certain cycle, and when any one of the plurality of time differences is larger than the predetermined time difference or the fluctuation width obtained from the plurality of time differences is larger than the fluctuation width used for the previous phase control When the image writing is not being performed, based on the subtraction value obtained by subtracting the fluctuation range from the time difference at that time, the output signal of the light beam detecting means corresponding to the reference rotary polygon mirror is output to the remaining signal. so that the output signal of the light beam detecting means corresponding to each of the rotary polygon mirror is output simultaneously or constantly delayed, the light beam scanning apparatus characterized by performing phase control for controlling the rotation reference signal generating means The light beam scanning device according to claim 3 ,
A light beam scanning device, wherein a maximum value of the plurality of time differences is used as the time difference used for the phase control. A light beam generating means, a rotating polygon mirror for deflecting and scanning the light beam generated by the light beam generating means on the image carrier, a driving means for rotating the rotating polygon mirror, and detecting a rotational position of the rotating polygon mirror Rotation position detection means, rotation drive control means for controlling the drive means based on a rotation reference signal and an output signal of the rotation position detection means, and a light beam deflected and scanned by the rotary polygon mirror on a scanning path. A plurality of sets of light beam detecting means for detecting at a predetermined position,
A rotation reference signal generating unit that generates the rotation reference signal in correspondence with each of the rotating polygon mirrors; an output signal of a light beam detection unit corresponding to the reference rotation polygon mirror among the plurality of rotation polygon mirrors; calculating a time difference between the output signal of the light beam detecting means corresponding to the rotary polygon mirror, on the basis of the time difference between its said remaining rotational phases of the rotary polygon mirror with respect to the reference rotary polygon mirror substantially coincide Phase control means for controlling the rotation reference signal generating means, and light beam scanning in each main scanning direction based on an output signal of each light beam detection means, and corresponding to the reference rotating polygon mirror. The light beam generating means is controlled based on an output signal of the light beam detecting means so as to start image writing in a sub-scanning direction by a light beam deflected and scanned by each of the remaining rotary polygon mirrors. In the light beam scanning apparatus and an optical beam generation control unit that,
With respect to the output signal of the light beam detecting means corresponding to the reference rotating polygon mirror, the rotation signal is output such that the output signal of the light beam detecting means corresponding to each of the remaining rotating polygon mirrors is output simultaneously or always with a delay. Controlling the reference signal generating means,
The phase control based on the time difference is not performed during the image writing operation, and the image writing operation is prohibited while the phase control based on the time difference is performed. Light beam scanning device.

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