JP2009288530A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus for suppressing adverse influence on image quality caused by irregular rotation speed of a rotating body. <P>SOLUTION: The image forming apparatus includes: a correction means for correcting an image forming position for the rotating body based on a correction parameter designated by a designation means; a shifting means for designating a correction parameter corresponding to a phase near a reference phase based on output timing of a detection signal from a sensor; and an adjusting means for adjusting an object to be adjusted, that is, at least either the density or the image width of an image to be formed at the image forming position just after shifting in accordance with a difference between the correction parameter designated by shifting and a correction parameter which is to be designated without shifting. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image forming apparatus.

  The image forming apparatus includes, for example, a rotating member such as a photosensitive member or a paper transport roller, and forms an image on the rotating member or a recording medium that moves as the rotating member rotates. For example, in the case of an electrophotographic printer, an electrostatic latent image is formed by optically scanning a rotating photoreceptor, and an image obtained by developing the electrostatic latent image is transferred to a recording medium.

  Here, if the rotation speed of the photosensitive member is always constant, a normal image (electrostatic latent image, image) having a uniform scanning line interval is formed by sequentially performing optical scanning at a writing timing at a constant time interval. can do. However, since the rotational speed of the photosensitive member is actually uneven, the image quality may be adversely affected, for example, an abnormal image with varying scanning line intervals may be formed.

  In view of this, there has conventionally been an image forming apparatus equipped with a technique for suppressing variations in scanning line spacing due to uneven rotation speed of a photoconductor (see Patent Document 1). In this conventional image forming apparatus, the correspondence between each actual phase in the rotational motion of the photosensitive member and the correction amount at each phase is measured in advance, and the measurement result is stored in a memory. The correction amount is a correction amount of the writing timing required to correct the scanning line interval in each phase to a predetermined reference line interval. Further, this conventional image forming apparatus has an origin sensor for detecting that the photoreceptor has reached a predetermined origin phase.

When the image forming command is issued, the image forming apparatus starts time counting based on the internal clock based on the detection timing of the origin phase by the origin sensor, and estimates the phase of the rotational motion of the photoconductor from the counted time. To do. Then, the correction amount corresponding to the estimated phase is sequentially read from the memory, and the scanning line writing timing is corrected based on the read correction amount, thereby suppressing the error of the scanning line interval with respect to the reference line interval. Yes.
JP 2000-284561 A

  However, in the conventional image forming apparatus, as described above, phases other than the origin phase are not actually detected, but are merely estimated using the internal clock. For this reason, this estimated phase may deviate from the actual phase of the photoreceptor, and the deviation may be accumulated as the rotational movement of the photoreceptor proceeds. As a result, the scanning line interval greatly deviates from the reference line interval is corrected by a correction amount corresponding to a phase that is significantly different from the actual phase. That is, the conventional image forming apparatus has a problem that the adverse effect on the image quality caused by the uneven rotation speed of the photosensitive member cannot be sufficiently suppressed. Such a problem can occur not only in an electrophotographic printer but also in an inkjet printer.

  The present invention has been completed based on the above circumstances, and an object of the present invention is to provide an image forming apparatus capable of suppressing an adverse effect on image quality due to uneven rotation speed of a rotating body. By the way.

  As means for achieving the above object, an image forming apparatus according to a first invention has an image on a recording medium having a rotating body and moving with the rotation of the rotating body. Forming means for forming, a memory in which change characteristic information of a correction parameter according to the phase of the rotating body is stored, a sensor that outputs a detection signal when the phase of the rotating body reaches a reference phase, Designating means for sequentially designating each correction parameter based on the change characteristic information stored in the memory, and an image forming position on the rotating body or the recording medium based on the correction parameter designated by the designating means. Based on the correction means for correction and the output timing of the detection signal of the sensor, the designation destination in the designation means is transferred to a correction parameter corresponding to a phase near the reference phase. Shift means, and at least one adjustment target of the density and image width of an image to be formed at the image forming position immediately after the shift by the shift means, the correction parameter designated by the shift, and the shift is not executed. Adjustment means for adjusting according to the difference from the correction parameter that should have been specified in this case.

According to the present invention, each correction parameter corresponding to the phase of the rotator is sequentially specified based on the change characteristic information, and the image forming position on the rotator or the recording medium is corrected based on the specified correction parameter. Based on the detection timing at which the phase of the rotator actually reaches the reference phase, the designation destination is shifted to the correction parameter corresponding to the phase in the vicinity of the reference phase. As a result, accumulation of deviation between the phase of the rotating body (estimated phase) grasped by the image forming apparatus and the actual phase is reduced, and adverse effects on image quality due to uneven rotation speed of the rotating body can be suppressed.
Here, there is a case where the interval between the image forming positions in the rotation direction of the rotator greatly changes due to the shift of the designation destination, and the adverse effect on the image quality may not be sufficiently suppressed. Therefore, in the present invention, at least one of the density and the image width of the image to be formed at the image forming position immediately after the transfer should be specified when the correction parameter specified by the transfer and the transfer is not executed. The adjustment is made according to the difference from the correction parameter. Thereby, it is possible to suppress an adverse effect caused by a large change in the interval between the image forming positions due to the shift.

A second invention is the image forming apparatus according to the first invention, further comprising a determining unit that determines whether or not to perform image formation at the image forming position immediately before the transition, wherein the adjusting unit is When it is determined that image formation is to be performed, the adjustment target is adjusted. When it is determined that image formation is not to be performed, the adjustment target adjustment is not performed.
If image formation is not performed at the image forming position immediately before the transfer, there is almost no adverse effect due to the large change in the interval between the image forming positions due to the transfer. Rather, it is better not to perform the adjustment of the adjustment target. There is also. Therefore, in the present invention, the adjustment target is adjusted only when image formation is performed at the image formation position immediately before the transition.

A third invention is the image forming apparatus according to the first or second invention, wherein the adjustment unit ends the adjustment of the adjustment target after adjusting the adjustment target for a plurality of image forming positions.
For example, the configuration may be such that the adjustment target is adjusted only for one image forming position after the transition, but in that case, there is a possibility that a sense of incongruity may occur between the images at other image forming positions thereafter depending on the adjustment amount. Therefore, as in the present invention, it is preferable to adjust the adjustment target for a plurality of image forming positions.

A fourth invention is the image forming apparatus according to the third invention, wherein the adjusting means gradually reduces the adjustment amount of the adjustment object between the plurality of image forming positions.
As in the present invention, by gradually reducing the adjustment amount between a plurality of image forming positions, it is possible to more effectively suppress a sense of discomfort with images at other image forming positions thereafter.

A fifth aspect of the invention is the image forming apparatus according to any one of the first to fourth aspects of the invention, wherein the rotating body is a photosensitive body, and includes an exposure device that exposes the photosensitive body. The adjustment target is adjusted by changing the exposure intensity of the exposure apparatus.
ADVANTAGE OF THE INVENTION According to this invention, adjustment of adjustment object is realizable with the method of adjusting the exposure intensity | strength of exposure apparatus.

A sixth invention is the image forming apparatus according to any one of the first to fifth inventions, wherein the forming means has a plurality of photosensitive members as the rotating member, and the recording target is provided for each photosensitive member. An image is formed on a medium, and the memory stores change characteristic information corresponding to each of at least two of the plurality of photosensitive members, and the designation unit, the correction unit, the transition unit, and the like The adjusting unit performs processing independently for each image forming position of each of the two photoconductors.
In the case of having a plurality of photoconductors, each has different rotation unevenness. For this reason, it is preferable to execute the processing of the present invention for each photoconductor.

A seventh invention is the image forming apparatus of the sixth invention, wherein at least the adjustment by the adjusting means is executed when image formation is performed on the recording medium by the plurality of photoconductors, and one photoconductor. Only when the image is formed on the recording medium by the above method.
When images are formed by a plurality of photoconductors, the images from the photoconductors are overlapped with each other. Therefore, it is necessary to adjust the adjustment target to form an accurate image. When an image is formed by a body, since it is not necessary to superimpose the images, it may not be necessary to form an image with a very high accuracy. In this case, the configuration as in the present invention is preferable.

An eighth invention is the image forming apparatus of the sixth or seventh invention, wherein the plurality of photoconductors are for forming different color images, and the adjustment amount for each photoconductor by the adjusting means is The amount is in accordance with the color characteristics corresponding to each photoconductor.
Even if the adjustment amount is the same, the influence on the image quality varies depending on the color characteristics of the colorant. Therefore, as in the present invention, the adjustment amount for each photoconductor is preferably set to an amount corresponding to the color characteristics of the colorant.

A ninth invention is the image forming apparatus according to any one of the sixth to eighth inventions, wherein the adjustment by the adjusting means corresponds to at least one color having low visibility compared to other colors. Do not execute for the photoconductor.
For colors with low visibility, the effect on image quality due to migration is relatively inconspicuous. Therefore, as in the present invention, it is preferable to reduce the processing burden by not adjusting the adjustment target for a color image photosensitive member with low visibility.

  An image forming apparatus according to a tenth aspect of the present invention has a rotating body, and a forming unit that forms an image on the rotating body or a recording medium that moves as the rotating body rotates, and the rotating body A memory that stores change characteristic information of a correction parameter according to a phase, a sensor that outputs a detection signal when the phase of the rotating body reaches a reference phase, and the change characteristic information stored in the memory A correction unit that sequentially specifies the correction parameters based on the correction parameter, a correction unit that corrects an image forming position on the rotating body or the recording medium based on the correction parameter specified by the specification unit, and the detection of the sensor. Based on a signal output timing, a transition unit that shifts a designation destination in the designation unit to a correction parameter corresponding to a phase in the vicinity of the reference phase, and a transition unit At least one of adjusted concentration and image width to be formed on the image forming position immediately after transition image, and a adjusting means for adjusting in accordance with the distance of the image forming position together immediately after the transition.

  According to the present invention, it is possible to suppress an adverse effect on image quality due to uneven rotation speed of a rotating body.

An embodiment of the present invention will be described with reference to FIGS.
(Entire printer configuration)
FIG. 1 is a side sectional view showing a schematic configuration of a printer 1 (an example of an image forming apparatus) according to the present embodiment. In the following description, the right direction in FIG. 1 is the front direction of the printer 1 and is indicated as the F direction in each figure. The printer 1 is a color printer that forms a color image with toners of four colors (black K, cyan C, magenta M, yellow Y), and has a plurality of components corresponding to each color. Hereinafter, when distinguishing each component by color, K (black), C (cyan), M (magenta), and Y (yellow) meaning each color are attached to the end of the code of the component. .

  As shown in FIG. 1, the printer 1 is a direct transfer tandem color LED printer and includes a casing 3. A supply tray 5 is provided at the bottom of the casing 3, and a recording medium 7 (for example, a sheet material such as paper) is stacked on the supply tray 5.

  The recording medium 7 is pressed toward the pickup roller 13 by the pressing plate 9 and is sent to the registration roller 17 by the rotation of the pickup roller 13. The registration roller 17 corrects the skew of the recording medium 7 and then sends the recording medium 7 onto the belt unit 21 at a predetermined timing.

  The image forming unit 19 includes a belt unit 21 as an example of a transport mechanism, an exposure unit 23 as an example of an exposure unit, a process unit 25, a fixing device 28, and the like. In the present embodiment, at least the exposure unit 23 and the process unit 25 are examples of “forming means”.

  The belt unit 21 includes an endless belt 31 provided between a pair of support rollers 27 and 29. The belt 31 circulates and moves counterclockwise in FIG. 1, for example, when the rear support roller 29 is driven to rotate, and conveys the recording medium 7 placed on the belt 31 backward.

  The exposure unit 23 includes four exposure units 23 (23K, 23C, 23M, and 23Y) corresponding to black, cyan, magenta, and yellow colors. Each exposure unit 23 employs an LED exposure method and includes a plurality of light emitting diodes (not shown) arranged in a line along the axial direction of the photosensitive member 33 (an example of a rotating member or a carrier). The plurality of light emitting diodes are controlled on and off based on the corresponding color image data, and the surface of the photoconductor 33 is exposed line by line to form an electrostatic latent image.

  Four process units 25 are provided corresponding to the respective colors of black, cyan, magenta, and yellow. Each process unit 25 has the same configuration except for the color of toner (an example of a colorant).

  Each process unit 25 includes a photoconductor 33, a charger 35, a developing cartridge 37, and the like. The developing cartridge 37 is provided with a toner containing chamber 39, a developing roller 41, and the like, and the toner in the toner containing chamber 39 is supplied onto the developing roller 41.

  The surface of the photoreceptor 33 is uniformly positively charged by the charger 35. Thereafter, the image is exposed to light J from the exposure unit 23 to form electrostatic latent images (an example of an image) corresponding to each color image to be formed on the recording medium 7.

  Next, the toner carried on the developing roller 41 is supplied to the electrostatic latent image formed on the surface of the photoreceptor 33. As a result, the electrostatic latent image on the photoconductor 33 is visualized as a toner image for each color.

  Thereafter, a transfer bias is applied to the transfer roller 43, and the recording medium 7 conveyed by the belt 31 passes through each transfer position between the photoconductor 33 and the transfer roller 43, and is applied to the surface of each photoconductor 33. The carried toner images are sequentially transferred to the recording medium 7. The recording medium 7 onto which the toner image has been transferred in this manner is thermally fixed by the fixing device 28 and then discharged onto the discharge tray 51 by the discharge roller 49.

(Photoconductor drive mechanism)
FIG. 2 is a perspective view showing a simplified internal structure of the drive unit 61 that rotationally drives the photosensitive member 33. The drive unit 61 is disposed on one end side of the photoconductor 33. The drive unit 61 is provided with four drive gears 63 (63K, 63C, 63M, 63Y) corresponding to the respective photoreceptors 33. Each drive gear 63 is rotatably provided coaxially with the corresponding photosensitive member 33 and is connected to each other by a coupling mechanism. Specifically, each drive gear 63 is coaxially formed with a fitting portion 65 that protrudes coaxially. The fitting portion 65 fits into a recess 67 formed at the end of the photosensitive member 33. The photosensitive member 33 rotates in unison with the rotational drive of the drive gear 63. Each fitting portion 65 is movable between the fitting position shown in FIG. 2 and a separated position separated from the photoconductor 33. For example, when the process unit 25 is replaced, the fitting portion 65 The process unit 25 can be detached from the casing 3 by moving the 65 to the separation position.

  Adjacent drive gears 63 are gear-coupled via an intermediate gear 69. In the present embodiment, a driving force from the driving motor 71 is applied to the intermediate gear 69 (an intermediate gear that connects the driving gear 63C and the driving gear 63M) located in the center, whereby the four driving gears 63 and four The photoconductor 33 rotates together.

  One drive gear 63 (drive gear 63C in the present embodiment) is provided with an origin sensor 73 (an example of a sensor). The origin sensor 73 has a phase of the drive gear 63C (more precisely, a phase of the rotational motion of the drive gear 63C (rotational phase). Note that the “phase” is a periodic motion such as vibration or wave and travels within one cycle. This is a sensor for detecting whether or not the phase has reached a predetermined origin phase (an example of a reference phase).

  Specifically, the drive gear 63C is provided with a circular rib portion 75 centering on the rotation axis, and a slit 75A is formed at one location. The origin sensor 73 is a transmissive optical sensor provided with a light projecting element and a light receiving element that are opposed to each other through the rib portion 75. When a portion other than the slit 75A is located in the detection area of the origin sensor 73, the light from the light projecting element is shielded by the rib portion 75, and the light receiving level at the light receiving element is relatively low. On the other hand, when the slit 75A is located in the detection area (when the phase of the drive gear 63C has reached the origin phase), the light from the light projecting element is not shielded, so the light receiving amount level at the light receiving element is high. Become. The origin sensor 73 outputs a detection signal SA corresponding to the change in the received light level, thereby detecting the timing at which the phase of the drive gear 63C has reached the origin phase (hereinafter referred to as detection timing), which will be described later. Tell CPU77.

  Since scanning line interval correction processing described later is performed for each color individually, it is necessary to detect whether or not all four drive gears 63 have reached their respective origin phases. For this purpose, one origin sensor may be provided for each drive gear 63 to individually detect that each drive gear 63 has reached the origin phase. However, the number of origin sensors increases and costs increase. In the present embodiment, the four drive gears 63 are configured to rotate by the drive force from the common drive motor 71. If the four drive gears 63 are designed so as to simultaneously reach the respective origin phases, one drive gear 63 is provided. By detecting that the drive gear 63 has reached the origin phase, it is possible to indirectly detect that the remaining drive gears 63 have reached the respective origin phases at the same time. Therefore, in the present embodiment, the origin sensor 73 is provided in only one drive gear 63.

  Since each drive gear 63 and the corresponding photosensitive member 33 rotate integrally on the same axis, the phase change of the drive gear 63 and the phase change of the photosensitive member 33 (more precisely, the rotational movement of the photosensitive member 33). It can be considered that the phase is substantially the same. Therefore, the origin sensor 73 indirectly detects whether or not the photoconductor 33 has reached the origin phase by detecting whether or not the drive gear 63 has reached the origin phase. Hereinafter, the fact that the drive gear 63 has reached the origin phase and the fact that the photoconductor 33 has reached the origin phase may be used interchangeably.

(Electrical configuration of printer)
FIG. 3 is a block diagram showing the electrical configuration of the printer 1.
The printer 1 includes a CPU 77, a ROM 79, a RAM 81, an NVRAM 83 (an example of a memory), an operation unit 85, a display unit 87, the above-described image forming unit 19, a network interface 89, an origin sensor 73, and the like.

  Various programs for controlling the operation of the printer 1 are recorded in the ROM 79. The CPU 77 controls the operation of the printer 1 while storing the processing results in the RAM 81 and the NVRAM 83 according to the program read from the ROM 79. .

  The operation unit 85 includes a plurality of buttons, and various input operations such as an instruction to start printing can be performed by the user. The display unit 87 includes a liquid crystal display and a lamp, and can display various setting screens and operation states. The network interface 89 is connected to an external computer (not shown) or the like via the communication line 70, and mutual data communication is possible.

(About change characteristics information)
The meanings of some terms that appear in the following explanation are as follows. FIG. 4 is a diagram for explaining the relationship between terms. Actually, the surface moving speed of the photosensitive member 33 and the conveying speed of the recording medium 7 may be different at the transfer position between the photosensitive member 33 and the transfer roller 43. This difference will be described later in consideration of this difference. Although it is necessary to correct the exposure timing, in the present embodiment, it is assumed that the surface moving speed of the photosensitive member 33 and the transport speed of the recording medium 7 are the same at the transfer position in order to simplify the description.
(A) “Line number (N)”: The number of scanning lines that are sequentially formed until the drive gear 63 rotates one cycle from the origin phase. The line number of the first scan line formed from the detection timing of the origin phase is “1”, and the line number of the last scan line in one cycle is “M”.
(B) “Write time interval T1”: The time difference between the write timings of each scanning line formed on the photosensitive member 33 by the exposure unit 23. The write time interval T1 (N) is the line number (N−1). It means a time difference in writing timing between the scanning line and the scanning line with the line number (N).
(C) “Initial time interval DS”: A time difference from the start of correction processing described later to the formation of the first scan line. Note that the initial time interval DS is the case where the rotational speed of the drive gear 63 is equal to the specified speed and does not coincide with the writing time interval (hereinafter referred to as the specified time interval) required for optical scanning at the specified line interval. However, in the present embodiment, they are assumed to be consistent for the sake of simplicity.
(D) “Scanning line interval”: the distance in the sub-scanning direction between the scanning lines on the recording medium 7 after transfer (in this embodiment, each scanning line formed on the photoconductor 33 by optical scanning under the above assumptions. The distance in the circumferential direction (sub-scanning direction) of the photosensitive member 33). Note that the writing position of each scanning line in the sub-scanning direction is an example of the image forming position.
(E) “Specified line interval”: A regular scanning line interval determined by printing conditions such as resolution. In other words, if the scanning line interval can be made equal to the prescribed line interval, an image satisfying the printing condition can be formed.
(F) “Prescribed speed”: Designated speed, which may be changed depending on printing conditions such as printing speed, resolution, and material of the recording medium 7.
(G) “Correction amount D (N)”: A correction amount (an example of a correction parameter) of the writing time interval required to correct the scanning line interval in each phase to the specified line interval.
(H) “Correction difference amount ΔD (N)”: the correction amount D of the current writing time interval T1 (N) with respect to the correction amount D (N−1) of the previous writing time interval T1 (N−1). (N) is the relative difference.

Therefore, the correction amount D (N) for calculating the arbitrary writing time interval T1 (N) can be expressed by the following equation 1.
[Formula 1]
D (N) = (ΔD (1) + ΔD (2) +... + ΔD (N))
An arbitrary writing time interval T1 (N) is obtained by the following equation 2.
[Formula 2]
T1 (N) = DS + D (N) = T1 (N-1) + ΔD (N)

  As will be described later, the change characteristic information is used to correct a scanning line interval, which varies due to uneven rotation speed of the photosensitive member 33, to a specified line interval. The NVRAM 83 stores change characteristic information (see FIG. 6) corresponding to each of the four drive gears 63.

  First, FIG. 5 is a graph showing the rotational speed fluctuation in one cycle of each drive gear 63. The solid line graph G1 (G1K, G1C, G1M, G1Y) is created from the measured value of the rotational speed of each drive gear 63 (63K, 63C, 63M, 63Y). More specifically, these solid line graphs G1 are created by plotting the difference values of the actually measured values with respect to the specified speed.

  For example, in the phase where the solid line graph G1 is above the zero line, it means that the actual rotational speed of the drive gear 63 is faster than the specified speed. At this time, if optical scanning is performed at the specified time interval, the scan line interval becomes wider than the specified line interval. On the other hand, in the phase where the solid line graph G1 is below the zero line, it means that the actual rotational speed of the drive gear 63 is slower than the specified speed. At this time, if optical scanning is performed at the specified time interval, the scan line interval becomes narrower than the specified line interval.

  Further, in FIG. 5, each dotted line graph G2 (G2K, G2C, G2M, G2Y) shows a change in the correction amount D (N), more specifically, each phase of the drive gear 63 and each position thereof. The correspondence relationship with the correction amount D (N) in the phase is shown. Here, “each phase” means a phase corresponding to the writing timing of each scanning line when the scanning lines are sequentially formed at a prescribed line interval, and the order of each phase from the origin phase is the above line number. Matches (N).

  Each dotted line graph G2 shows an increasing / decreasing tendency as if the corresponding solid line graph G1 was reversed in the positive / negative direction. Specifically, in the phase of the line number in which the dotted line graph G2 is below the zero line, the scanning line interval is set to the prescribed line interval by shortening the initial time interval DS by the absolute amount of the correction amount D (N). To match. On the contrary, in the phase of the line number where the dotted line graph G2 is above the zero line, the scanning time interval coincides with the specified line interval by increasing the initial time interval DS by the absolute amount of the correction amount D (N). Let

  Then, from each of the dotted line graphs G2, each line number N and the correction amount D (N) (= D (1) to D (M)) or the correction difference amount ΔD (N) (= ΔD (1) to A correspondence relationship with ΔD (M)) can be derived. In the present embodiment, the change characteristic information of each drive gear 63 is stored in the NVRAM 83 as a correspondence table between the line numbers N (1 to M) and the correction difference amount ΔD (N), as shown in FIG. Has been. This change characteristic information is information related to the correspondence between the line number N (1 to M) and the correction amount D (N) (= D (1) to D (M)) indirectly.

(Scanning line interval correction processing)
In the present embodiment, the scanning line interval correction processing shown in FIGS. 7 and 8 is not performed during monochrome printing by a single process unit 25 (for example, black process unit 25K), but is performed during color printing by a plurality of process units 25. Is called. This is because the influence of the shift in the line interval due to the uneven rotation speed of the photosensitive member 33 appears particularly as a color shift in a color image formed by combining a plurality of color images. Further, the scanning line interval correction processing is performed individually based on the change characteristic information prepared for each color. Hereinafter, for example, correction processing of a scanning line interval for a cyan image will be described as an example.

(1) Processing Before Execution of Transition Process (Correction of Estimated Phase) The CPU 77 performs a plurality of correction difference amounts ΔD corresponding to each line number N based on the change characteristic information until before execution of the transition process described later. (N) is designated in chronological order. At this time, the CPU 77 functions as a designation unit.
For example, when print data from an external computer is received by the network interface 89 or a print instruction operation is performed by the operation unit 85, the CPU 77 instructs rotation driving of the photosensitive member 33, the belt 31, and the like, and FIG. , 8 is executed. The CPU 77 counts the time such as the writing time interval T1 by the internal clock. Initially, the designated line number E for designating each line number N is “1”.

  First, in S101 of FIG. 7, it is determined whether or not the detection flag F is set (F = 1). This detection flag F is a flag indicating whether or not the detection timing has arrived (the phase of the photoconductor 33 has reached the origin phase), and is initially cleared (F = 0). When the phase of the photoconductor 33 reaches the origin phase, this is transmitted to the CPU 77 by the detection signal SA from the origin sensor 73. Then, the CPU 77 sets the detection flag F (S101: YES), and proceeds to S103, where the detection flag F is cleared.

  Next, in S105, the initial time interval DS is substituted for the writing time interval T1, and in S107, when this initial time interval DS is counted by the internal clock, the exposure unit 23 is instructed to write one scanning line in S109. Add 1 to the specified line number E.

  Subsequently, it is determined whether or not the detection flag F is set again in S111 of FIG. If the detection flag F remains cleared in S103 (S111: NO), the process proceeds to S113, and the correction difference amount ΔD (N) corresponding to the same line number N as the current designated line number E is designated and read. In S115, the correction difference amount ΔD (N) is added to the value of the previous writing time interval T1 (N−1), and this is substituted into the writing time interval T1. As a result, the writing time interval T1 (N) becomes “(T1 (N−1) + correction difference amount ΔD (N))”. Specifically, for example, if the designated line number E is “5”, the CPU 77 reads the correction difference amount ΔD (5) corresponding to the line number (5) from the change characteristic information, and sets the writing time interval T1 to “ It is corrected to “T1 (4) + ΔD (5)”. At this time, the CPU 77 functions as correction means.

  In S117, when the corrected writing time interval T1 is counted by the internal clock, in S119, the exposure unit 23 is instructed to write one scanning line, and “1” is added to the designated line number E. When the current designated line number E reaches “M”, it is returned to “1” next. If the exposure of all the print data of one job is completed (S121: YES), the correction process is terminated. If not completed (S121: NO), the process returns to S111.

(2) Problem of Phase Estimation Based on Internal Clock Here, in the present embodiment, the origin sensor 73 indicates that the phase of the photosensitive member 33 (more precisely, the rotational movement of the photosensitive member 33) is the origin phase. However, other phases other than the origin phase cannot be detected directly. The arrival time of the other phase is estimated by the CPU 77 by counting each writing time interval T1 with an internal clock based on the detection timing.

  If the accurate time can be counted by the internal clock, the estimated phase based on the internal clock and the actual phase of the photoconductor 33 coincide with each other. Therefore, in each actual phase of the photoconductor 33 as shown in FIG. The correction difference amount ΔD (N) can be designated from the change characteristic information, and the scanning line interval can be made to coincide with the prescribed line interval over the entire circumference of the photosensitive member 33.

  However, for example, a change in the internal temperature of the printer 1 may cause the pulse interval of the oscillation circuit for generating the internal clock to fluctuate, so that the accurate time may not be counted by the internal clock. As a result, the estimated phase based on the internal clock and the actual phase of the photoconductor 33 shift, and the shift amount is accumulated as the rotation of the photoconductor 33 progresses. That is, in each actual phase of the photoconductor 33, an inappropriate correction difference amount ΔD (N) that does not correspond to it is designated, and the scanning line interval cannot be made to coincide with the specified line interval.

(3) Transition processing (correction of estimated phase)
Therefore, the CPU 77 performs transition processing (processing after S123 in FIG. 8) for correcting the estimated phase. Since the detection timing of the origin phase is the timing at which the actual phase of the photoconductor 33 can be detected only, if this detection timing is used, the correction amount D (N) (writing time interval T1) is set to the actual phase. The estimated phase can be corrected to a corresponding and appropriate value.

  In the present embodiment, the designation destination of the correction difference amount ΔD (N) (correction amount D (N)) is shifted to the correction difference amount ΔD (1) corresponding to the head line number (1) based on the detection timing. Specifically, when the drive gear 63 makes one rotation, the detection signal SA is output from the origin sensor 73, and the CPU 77 knows that the detection timing has come again, and sets the detection flag F. And when it returns to S111 from S121, it progresses to a transfer process (S111: YES).

  First, the detection flag F is cleared in S123, and the designated line number E is initialized to “1” in S125. As a result, the designation destination of the correction difference amount is shifted to the correction difference amount ΔD (1) corresponding to the line number (1), the correction difference amount ΔD (1) is read from the change characteristic information, and the writing time immediately before the shift. By adding to the interval T1, the writing time interval T1 ′ immediately after the transition is obtained. At this time, the CPU 77 functions as a transition unit.

  Next, in S129, when the writing time interval T1 ′ immediately after the transition is counted by the internal clock, the exposure unit 23 is instructed to write one scanning line in S135. As described above, since it is possible to know that the phase of the photoconductor 33 has actually reached the origin phase by the arrival of the detection timing, the designated line number E is changed to “1” based on the arrival of the detection timing. Then, the correction difference amount designation destination is forcibly shifted to the correction difference amount ΔD (1) corresponding to the line number (1). Thereby, accumulation of the shift amount between the actual phase of the photoconductor 33 and the estimated phase can be eliminated.

(4) Problems in Transition Processing FIG. 9 is a graph for explaining a change in correction amount before and after the transition, and FIG. 10 is a diagram for explaining a difference in the writing time interval T1 depending on the presence or absence of the transition. When the migration process is executed, the following problems may occur. That is, when the change in the correction amount D (N) in the vicinity of the origin phase is steep, the correction amount D (N) changes greatly before and after the transition, so that the scanning line interval changes rapidly, which adversely affects the image quality. May affect.

  Specifically, as shown in FIG. 9, for example, when the estimated phase is delayed compared to the actual phase, the correction amount D (N) sequentially specified based on the estimated phase is one point in FIG. A change as shown by the chain line X is shown. Then, the detection timing arrives (the actual phase reaches the origin phase) before the estimated phase reaches the origin phase (for example, when the designated line number E is near (M-4)). Then, the writing time interval T1 is changed to the writing time interval T1 ′ immediately after the transition at the time point based on the detection timing.

  More specifically, as shown in FIG. 10, the period from the writing timing of the scanning line with the line number (M-5) until the writing timing of the scanning line with the line number (M-4) arrives (writing time interval). It is assumed that the origin phase detection timing arrives during counting of T1 (M-4). Then, the CPU 77 sets the detection flag F at this time, and then instructs the exposure unit 23 to write the scanning line with the line number (M-4) at the end of the writing time interval T1 (M-4). (S119 in FIG. 8).

Then, the process returns to S111, it is determined that the detection flag F is set, and the process proceeds to S123 to perform a transition process. The writing time interval T1 ′ immediately after the transition can be expressed by the following equation 3.
[Formula 3]
T1 ′ = T1 (M−4) + ΔD (1)
On the other hand, if the migration process is not performed, the writing time interval T0 can be expressed by the following equation 4.
[Formula 4]
T0 = T1 (M−4) + ΔD (M−3)

  As can be seen from the above formulas 3 and 4, since the amount of correction difference added to the writing time interval T1 (M-4) immediately before the transition differs between when the transition process is performed and when it is not performed, the writing time interval Is different. In the example of FIGS. 9 and 10, the writing time interval T1 ′ immediately after the transition is shorter than the writing time interval T0 at the time of non-transition. As a result, as shown in FIG. 11 (the horizontal direction in the drawing is the sub-scanning direction), the scanning line interval H2 immediately after the transition is extremely narrower than the scanning line interval H1 before the line number (M-4). . In addition, as shown in FIG. 9, the correction amount D (N) change particularly near the origin phase is steep. For this reason, the difference between the correction amount D (M−4) before the transition and the correction amount D (0) after the transition becomes large, and the continuity of the correction amount D (N) is lost. In other words, the scanning line interval may change abruptly, and the electrostatic latent image formed on the photoconductor 33 may be disturbed, which may adversely affect image quality.

(5) Adjustment Processing In this embodiment, therefore, adjustment processing is performed in S133 in FIG. 8 in order to suppress an adverse effect on image quality due to the rapid change in the scanning line interval. At this time, the CPU 77 functions as an adjustment unit. This adjustment process is a process for adjusting the image density of the scanning line L (1) immediately after the transition according to the scanning line interval H2 immediately after the transition. That is, the exposure intensity of the exposure unit 23 is weakened as the scanning line interval H2 is narrowed, and the scanning line L (1) immediately after the transition is formed at a relatively low density. The wider the scanning line interval H2, the exposure of the exposure unit 23 is. The scanning line L (1) immediately after transition is formed with a relatively high density by increasing the intensity.

  As shown in FIG. 11, even when the scanning line interval H2 immediately after the transition becomes extremely narrow, the scanning line L (1) immediately after the transition is more than the scanning line L (M-3) when the transition is not performed. By reducing the density, it is possible to make the scan line interval extremely inconspicuous visually. Further, as shown in FIG. 12, even when the scanning line interval H2 immediately after the transition becomes extremely wide, the scanning line interval has become extremely wide by increasing the density of the scanning line L (1) immediately after the transition. Can be visually inconspicuous.

  The scanning line interval immediately after the transition differs depending on which line number N the transition process is executed on. Therefore, for example, by executing the transition process for each line number N and performing the imaging process for each image printed at that time, the image density of the scanning line L (1) immediately after the transition is set as described above. A value that makes the width of the scanning line interval less noticeable is obtained. Then, a correspondence relationship between the line number N at the time of transition and a parameter for adjusting the image density (density adjustment coefficient in the present embodiment) may be obtained.

  In order to adjust more strictly, the correction amount D (1) (correction difference amount ΔD (1)) specified by the shift and the correction amount (correction difference amount) that should have been specified when the shift is not performed. In the example of 10, it is preferable to adjust the image density of the scanning line L (1) immediately after the transition according to the difference value between D (M-3) and ΔD (M-3)). In the present embodiment, for example, assuming that the transfer process has been executed for each line number N, a difference value of a correction amount (correction difference amount) based on the presence or absence of transfer is calculated, and a density adjustment coefficient is calculated according to the difference value. decide. The density adjustment coefficient is a value smaller than 1 when the correction amount D (1) at the time of transition (correction difference amount ΔD (1)) is smaller than the correction amount at the time of non-transition (correction difference amount). When the shift correction amount D (1) (correction difference amount ΔD (1)) is larger than the non-shift correction amount (correction difference amount), the value is larger than 1. Then, as shown in FIG. 13, a correspondence table between the line number N at the time of transition and the density adjustment coefficient is created and stored in the NVRAM 83. Further, since the density adjustment coefficient varies depending on the characteristics of each toner color, an individual correspondence table is stored in the NVRAM 83 for each toner color.

  In the present embodiment, the amount of toner attached to the electrostatic latent image on the photoconductor 33 is changed by changing the exposure intensity by the exposure unit 23 to adjust the image density of the scanning line L (1) immediately after the transition. The method to be adopted is adopted. Specifically, the normal target value of the light emission amount of the light emitting diode when the adjustment process is not executed is multiplied by the density adjustment coefficient. As a result, the exposure unit 23 can change the exposure intensity by applying a drive current corresponding to the density adjustment coefficient to the light emitting diode to change the light emission amount of the light emitting diode. Note that the density of the image based on the image data is adjusted by another method such as a dither method without changing the exposure intensity. Such a configuration is preferable because the adjustment process and the image density process based on the image data can be clearly divided and executed.

  Further, for example, the adjustment process may be performed only on the scanning line L (1) immediately after the transition, but in this case, depending on the adjustment amount, the density may be increased between the subsequent scanning lines L (2) and L (3). A gap may occur. Therefore, in the present embodiment, adjustment processing is also performed for the scanning lines (L (2) and L (3) as shown in FIGS. 11 and 12) after the scanning line L (1) immediately after the transition. Moreover, the adjustment amount of the exposure intensity (image density) is gradually reduced by moving the image adjustment coefficient closer to 1 along the scanning line L (1) to the scanning line L (3). For example, the image adjustment coefficient is changed from 1.2 → 1.1 → 1 or 0.8 → 0.9 → 1. In this way, the gap in density between the scanning line L (1) immediately after the transition and the subsequent scanning lines L (2) and L (3) can be more effectively suppressed.

  However, in this embodiment, the adjustment process is not always performed during the migration process. As shown in FIG. 8, when the scanning line immediately before the transition (the scanning line with the line number (M-4) in the example of FIG. 10) is actually exposed (S131: YES), the adjustment process is performed. On the other hand, since the image data is blank data and the scanning line immediately before the transition is not exposed (S131: NO), the adjustment process is not performed. At this time, the CPU 77 functions as a determination unit. If the scanning line immediately before the transition is not exposed, the problem that the scanning line interval changes suddenly due to the transition and the image quality deteriorates is hardly affected, and it may be better not to execute the adjustment process. Because there is.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and the drawings, and for example, the following various aspects are also included in the technical scope of the present invention. In particular, among the constituent elements of each embodiment, constituent elements other than the constituent elements of the top-level invention can be omitted as appropriate because they are additional elements.
(1) As the “image forming apparatus”, an LED printer is shown in the above embodiment, but the present invention can also be applied to other electrophotographic printers (for example, laser printers). Further, even if it is not a direct transfer system, it can be applied to, for example, an intermediate transfer system printer, etc., and further can be applied to an ink jet system or a thermal system printer. Further, a printer having two, three, five or more colorants may be used.

  (2) “Rotating body” includes, for example, a conveyance belt (belt 31), a conveyance roller, and a transfer belt in addition to the photosensitive member 33. Even in the case of a conveyance belt, a conveyance roller, a transfer belt, etc., it is necessary to prepare change characteristic information thereof, and the image forming position is corrected while sequentially specifying correction parameters based on the change characteristic information.

  (3) “Image” includes a developer (toner) image and an ink image in addition to the electrostatic latent image. For example, in the case of an electrophotographic printer, and the rotating body is a transport belt, a transport roller, or a transfer belt, it is a developer image, and in the case of an inkjet printer or thermal printer, the rotating body is a transport roller, etc. The image is an ink image or the like.

  (4) In the above embodiment, the change characteristic information of each drive gear 63 is a correspondence table between the line number N and the correction difference amount ΔD (N), but is not limited to this, and the line number N (1 To M) and the correction amount D (N) (= D (1) to D (M)). Further, instead of the correspondence table, function information of the correspondence may be used. Also, it may be correspondence information between the line number N and the rotation speed of the drive gear 63 (solid line graph G1 in FIGS. 5 and 9). In this case, the correction difference amount and the correction amount are derived from each rotation speed. become.

  (5) The change characteristic information may be common to a plurality of colors. For example, in the above embodiment, the rotational speed fluctuations of the drive gears 63 that are symmetrical in the front-rear direction with respect to the drive motor 71 (in FIG. 2, the drive gear 63M and the drive gear 63C, and the drive gear 63Y and the drive gear 63K) are The shape is almost reversed. Therefore, the configuration may be such that only one of the change characteristic information is provided and the other correction amount is derived from the one change characteristic information.

  (6) As a method of “correcting the image forming position”, the image forming position is corrected by changing the exposure timing in the above embodiment. However, the image forming position may be corrected by changing the rotation speed of the rotating body (photosensitive body) without changing the exposure timing.

  (7) In the above-described embodiment, the correction amount corresponding to the line number (1) is shifted at the time of transition processing. However, the present invention is not limited to this and corresponds to a phase (line number) near the origin phase. Any configuration that shifts to the correction amount to be performed may be used.

  (8) In the above embodiment, the image density of the scanning line L (1) immediately after the transition is adjusted by changing the exposure intensity in the adjustment process. However, the present invention is not limited to this, and the density of the image based on the image data is not limited. Similar to the processing, the image density of the scanning line L (1) immediately after the transition may be adjusted by a dither method (a method of changing the number of dots per unit area) or the like.

  (9) Further, the adjustment process may be configured to adjust the sub-scanning direction width (an example of the image width) of the scanning line L immediately after the transition. Specifically, the shorter the scanning line interval H2 immediately after the transition is, the thinner it is, and the longer it is, the thicker it is. Even with such a method, it is possible to suppress an adverse effect on image quality due to a rapid change in the scanning line interval. The adjustment of the width in the sub-scanning direction can be performed by changing the light emission time of each light emitting diode. In the case of an ink jet printer, adjustment processing can be performed by changing the number of dots or the dot size (ink protrusion strength).

  (10) In the above embodiment, the correspondence table between the line number N and the density adjustment coefficient at the time of transition is used at the time of adjustment processing. However, the present invention is not limited to this. ) Difference value and density adjustment coefficient. Instead of a table, it may be function information for calculating the correspondence.

  (11) In the above embodiment, the adjustment amount of the exposure intensity (image density) is gradually reduced over the plurality of scanning lines after the scanning line L (1). When the image density of the scanning line L (1) is increased, the image density of the next scanning line L (2) is decreased, and the image density of the scanning line L (1) immediately after the transition is decreased. Alternatively, the image density of the next scanning line L (2) may be increased. For example, the image adjustment coefficient may be changed so that it finally converges to 1 while the amplitude is based on 1 as 1.2 → 0.8 → 1.1 → 0.9 → 1.

  (12) In the above embodiment, the scanning line interval correction process itself is not performed in the case of single color printing. However, the present invention is not limited to this, and the correction process itself is executed even during single color printing. However, the configuration may be such that only the adjustment process is not executed (the same process as in the case of YES in S131 of FIG. 8). Furthermore, in the above-described embodiment, the adjustment processing is performed on all the color image photoreceptors 33. However, the present invention is not limited to this, and the configuration in which adjustment processing is not performed on some of the photoreceptors 33 is also provided. It may be. For example, it is not necessary to perform adjustment processing on the photosensitive member 33 for yellow or transparent toner image used for coating or the like. This is because the visibility on the image quality is relatively inconspicuous because the visibility is low compared to other colors.

1 is a side sectional view showing a schematic configuration of a printer according to an embodiment of the present invention. The perspective view which simplified and showed the internal structure of the drive unit which rotationally drives a photoreceptor Block diagram showing the electrical configuration of the printer Diagram for explaining the relationship between terms Graph showing rotation speed fluctuation of each drive gear Schematic diagram showing the data structure in NVRAM (Part 1) Flow chart of correction processing (part 1) Flow chart of correction process (2) Graph to explain change in correction amount before and after transition The figure for demonstrating the difference in the writing time interval T1 by the presence or absence of transfer Schematic diagram showing the relationship between scan line spacing and image density Schematic diagram showing the relationship between scan line spacing and image density Schematic diagram showing the data structure in NVRAM (Part 2)

Explanation of symbols

1. Printer (image forming device)
7 ... Recording medium 33 ... Photoconductor (rotating body)
73 ... Origin sensor (sensor)
77 ... CPU (designating means, correcting means, shifting means, adjusting means)
83 ... NVRAM (memory)
SA ... Detection signal

Claims (10)

A forming unit that has a rotating body and forms an image on the rotating body or on a recording medium that moves with the rotation of the rotating body;
A memory for storing change characteristic information of a correction parameter according to the phase of the rotating body;
A sensor that outputs a detection signal when the phase of the rotating body reaches a reference phase;
Designation means for sequentially designating each of the correction parameters based on the change characteristic information stored in the memory;
Correction means for correcting an image forming position with respect to the rotating body or the recording medium based on a correction parameter designated by the designation means;
Based on the output timing of the detection signal of the sensor, a transition unit that shifts the designation destination in the designation unit to a correction parameter corresponding to a phase near the reference phase;
The adjustment target of at least one of the density and the image width of the image to be formed at the image forming position immediately after the shift by the shift unit is specified when the correction parameter specified by the shift and the shift is not executed. An image forming apparatus comprising: an adjusting unit that adjusts according to a difference from a correction parameter that should have been corrected. The image forming apparatus according to claim 1,
Determining means for determining whether or not to perform image formation at the image forming position immediately before the transition;
The adjustment unit performs adjustment of the adjustment target when the determination unit determines to perform image formation, and does not perform adjustment of the adjustment target when it is determined not to perform image formation. It is. The image forming apparatus according to claim 1, wherein:
The adjusting unit ends the adjustment of the adjustment target after adjusting the adjustment target for a plurality of image forming positions. The image forming apparatus according to claim 3, wherein
The adjustment unit gradually reduces the adjustment amount of the adjustment target between the plurality of image forming positions. An image forming apparatus according to any one of claims 1 to 4, wherein
The rotating body is a photoreceptor;
An exposure device for exposing the photoreceptor;
The adjustment unit adjusts the adjustment target by changing an exposure intensity of the exposure apparatus. An image forming apparatus according to any one of claims 1 to 5,
The forming means has a plurality of photosensitive members as the rotating member, and forms an image on the recording medium for each photosensitive member,
The memory stores change characteristic information corresponding to each of at least two photoconductors of the plurality of photoconductors,
The designation unit, the correction unit, the transition unit, and the adjustment unit execute processing independently for each image forming position of the two photoconductors. The image forming apparatus according to claim 6,
The adjustment by at least the adjusting unit is performed when an image is formed on the recording medium with the plurality of photosensitive members, and is not performed when an image is formed on the recording medium with only one photosensitive member. The image forming apparatus according to claim 6 or 7, wherein
The plurality of photoconductors are for forming different color images, and the adjustment amount for each photoconductor by the adjusting means is an amount corresponding to the color characteristics corresponding to each photoconductor. The image forming apparatus according to any one of claims 6 to 8,
The adjustment by the adjusting unit is not performed on the photoconductor corresponding to at least one color having a lower visibility than other colors. A forming unit that has a rotating body and forms an image on the rotating body or on a recording medium that moves with the rotation of the rotating body;
A memory for storing change characteristic information of a correction parameter according to the phase of the rotating body;
A sensor that outputs a detection signal when the phase of the rotating body reaches a reference phase;
Designation means for sequentially designating each of the correction parameters based on the change characteristic information stored in the memory;
Correction means for correcting an image forming position with respect to the rotating body or the recording medium based on a correction parameter designated by the designation means;
Based on the output timing of the detection signal of the sensor, a transition unit that shifts the designation destination in the designation unit to a correction parameter corresponding to a phase near the reference phase;
Adjusting means for adjusting at least one of the density and image width adjustment targets of the image to be formed at the image forming position immediately after the shifting by the shifting means according to the distance between the image forming positions immediately after the shifting. Image forming apparatus.

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