JP3616295B2 - Image forming apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image forming apparatus that forms a toner image by electrophotographic image formation, and sets an operation state of an image forming unit based on a detection result of a pattern image by a detection sensor.In placeRelated.
[0002]
[Prior art]
As an image forming apparatus such as a copying machine or a laser printer for performing electrophotographic image formation in which an electrostatic latent image formed on the surface of a photoconductor is visualized as a toner image and then transferred onto a recording medium. , Y (yellow), M (magenta), C (cyan), K (black), and the like, a toner image is formed with each of the toners, and these toner images are formed directly on the recording medium or on the toner image carrier. There is a color image forming apparatus in which a color image is formed by superimposing them through the two. In such a color image forming apparatus, if an error occurs in the transfer position of each color toner image on the recording medium, the quality of the color image is deteriorated.
[0003]
Therefore, in a conventional color image forming apparatus, as in Japanese Patent No. 2642351, a pattern image for adjustment is formed using each of a plurality of colors of toner, and the positional relationship between the formed pattern images of each color is confirmed. Then, there is a technique in which registration adjustment is performed so that the image forming positions of the respective colors coincide with each other by adjusting the image forming timing of the respective colors.
[0004]
[Problems to be solved by the invention]
However, in a conventional color image forming apparatus that performs resist adjustment, if the resist adjustment operation is repeated in order to improve the image quality, a large amount of toner is consumed to form a pattern image, resulting in an increase in running cost. There is. Also, in the case where a sensor for detecting the formation position of the pattern image is provided, the size of the sensor is larger than the size that the sensor can detect so that the pattern image can be reliably detected even if an error occurs in the sensor mounting position. In general, a pattern image having a large size is formed, and waste of toner due to resist adjustment becomes serious. Furthermore, in the case of providing a different sensor for each color toner, all color toners used for forming a color image are used for resist adjustment, and there is a problem that a larger amount of toner is wasted in resist adjustment. . Such a problem also occurs in an image forming apparatus that performs toner density adjustment and an image forming apparatus that controls an operation state when forming a monochrome image based on the detection result of a pattern image by a sensor.
[0005]
The object of the present invention is to confirm the sensor mounting position based on the detection result of the pattern image by the sensor, and form a pattern image with a minimum size at an appropriate position according to the confirmed sensor mounting position. An object of the present invention is to provide an image forming apparatus capable of reducing the running cost by reducing the amount of toner consumed by adjusting the registration or toner density for controlling the operation state of the forming unit.
[0006]
[Means for Solving the Problems]
The present invention has the following configuration as means for solving the above problems.
[0007]
(1) In an image forming apparatus that includes a detection sensor that optically detects a pattern image formed on an image carrier by an image forming unit, and that controls an operation state of the image forming unit based on a detection result of the detection sensor.
The image carrier is composed of a first pattern image parallel to the main scanning direction and a second pattern image including a plurality of line segments parallel to the main scanning direction with the position in the sub-scanning direction displaced stepwise. In each range of the plurality of line segments, the first pattern image and the second pattern image both form an initial pattern image larger than the detection sensor in the main scanning direction and the sub-scanning direction,
The positional relationship between the image carrier and the detection sensor is detected based on the detection result of the detection sensor for the initial pattern image formed on the image carrier.
[0008]
In this configuration, the positional relationship between the detection sensor for optically detecting the pattern image formed on the image carrier and the image carrier is confirmed based on the detection result of the initial pattern image by the detection sensor. Therefore, by forming a pattern image used for controlling the operation state of the image forming unit at a position on the image carrier according to the positional relationship with the confirmed detection sensor, the pattern image is accurately detected by the detection sensor. The operation state of the image forming unit is accurately controlled. Further, it is not necessary to form a pattern image used for controlling the operation state of the image forming unit in a wide range on the image carrier, and the toner consumption is reduced.
[0009]
(2) The initial pattern image has a shape facing the detection sensor at different timings at a plurality of positions in a direction orthogonal to the moving direction of the image carrier.
[0010]
In this configuration, the detection timing of the initial pattern image by the detection sensor is different from each other at a plurality of positions in a direction orthogonal to the moving direction of the image carrier. Therefore, from the timing when the detection sensor detects the initial pattern image, the position on the image carrier facing the detection sensor in the direction orthogonal to the moving direction of the image carrier is easily confirmed.
[0011]
(3) The initial pattern image has a shape facing the detection sensor at different positions at a plurality of positions in a direction orthogonal to the moving direction of the image carrier.
[0012]
In this configuration, the detection times of the initial pattern images by the detection sensors are different from each other at a plurality of positions in a direction orthogonal to the moving direction of the image carrier. Therefore, the position on the image carrier facing the detection sensor in the direction orthogonal to the moving direction of the image carrier can be easily confirmed from the time when the detection sensor has continuously detected the initial pattern image.
[0013]
(4) A single pattern image is detected multiple times by the detection sensor, and a plurality of detection results are detected.Exclude the maximum detection result and the minimum detection resultAn average value of detection results is determined as a detection result of the detection sensor.
[0016]
In this configuration, the pattern image formed on the image carrier is detected a plurality of times, and the average of the detection results excluding the maximum detection result and the minimum detection result among the plurality of detection results is the pattern image by the detection sensor. As a result of detection. Therefore, a stable value excluding detection results greatly different from other detection results can be obtained as the detection result of the pattern image by the detection sensor.
[0017]
(FiveThe pattern image is a pattern image for resist correction that adjusts the image formation timing on the image carrier by the image forming unit based on the detection signal of the detection sensor.
[0018]
In this configuration, registration correction is performed to adjust the image formation timing on the image carrier based on the detection result of the pattern image by the detection sensor. Therefore, the image formation timing on the image carrier is appropriately determined based on the detection result of the detection sensor.
[0019]
(6)The detection sensor is a black toner detection sensor that optically detects a black pattern image formed on an image carrier by an image forming unit, and a color toner detection sensor that optically detects a color pattern image. ,
The black toner detection sensor and the color toner detection sensor are integrally arranged at a predetermined interval in the main scanning direction,
While detecting either the black toner detection sensor or the color toner detection sensor based on the detection result of the initial pattern image of the black toner or color toner formed on the image carrier, the positional relationship with the image carrier is detected. The remaining other sensor detects the positional relationship with the image carrier from the detection result of the one sensor and the predetermined interval.It is characterized by that.
[0020]
In this configuration,A sensor in which a black toner detection sensor and a color toner detection sensor are integrally arranged at a predetermined interval in the main scanning direction as a unit, and an initial pattern image is used for either the black toner detection sensor or the color toner detection sensor An error in the mounting position is detected by the position detection process, and the error in the mounting position is calculated from the detection result of one sensor and the interval between the two sensors in the unit for the other remaining sensor. Therefore, an error in the mounting positions of a plurality of detection sensors can be obtained only by executing one sensor position detection process. In addition, the pattern image can be reliably detected by the detection sensor without increasing the size of the pattern image by displacing the formation position of the pattern image for toner density adjustment at each image forming station in accordance with the error in the mounting position of the detection sensor. Is done.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic front sectional view showing the configuration of a digital color copying machine which is a color image forming apparatus according to an embodiment of the present invention. The copying machine main body 1 includes a document table 11 and an operation panel (not shown) on the upper surface, and an image reading unit 110, an image forming unit 210, and a paper feeding unit 211. A double-sided automatic document feeder (RADF: Reversing Automatic Document Feeder) 112 is mounted on the upper surface of the document table 111. The RADF 112 feeds the originals placed on the tray one by one to the upper surface of the original table 111 in conjunction with the operation of the copying machine main body 1, and after the image reading process by the image reading unit 110 is completed. The document on the document table 111 is discharged to a discharge tray. Also, in the double-sided document mode for reading both-side images of the document, the document whose one-sided image has been read is reversed and fed to the document table 111 again, and the image reading unit 110 reads both-side images. After completion of, the document is discharged to the discharge tray. The RADF 112 is supported so that the upper surface of the document table 111 can be freely opened and closed, and the document can be handled manually with respect to the upper surface of the document table 111.
[0024]
The image reading unit 110 reads an image of a document placed on the document table 111, a first mirror base 113 equipped with an exposure lamp and a mirror, a second mirror base 114 equipped with a mirror, a lens 115, and a photoelectric conversion. A CCD line sensor (hereinafter referred to as CCD) 116 as an element is provided. The first mirror base 113 reciprocates at a constant speed in parallel with the lower surface of the transparent glass original platen 111, and scans the image surface of the original placed on the upper surface of the original platen 111 with light emitted from the exposure lamp. To do. The second mirror base 114 is reciprocated at a speed that is half the moving speed of the first mirror base 113 in parallel with the lower surface of the document table 111, and the optical path length from the image surface of the document to the CCD 116 is maintained constant. Thus, the reflected light of the exposure lamp light on the image surface of the original is distributed to the lens 115. The lens 115 forms an image of the reflected light on the image surface of the document on the light receiving surface of the CCD 116. The CCD 116 outputs an electrical signal obtained by sequentially photoelectrically converting a light image formed on the light receiving surface. The CCD 116 is a three-line line sensor that separates a color image into three primary colors R (red), G (green), and B (blue) and outputs an electrical signal corresponding to the amount of light for each color. The electrical signal output from the CCD 116 is input to an image processing unit (not shown), and after A / D conversion processing and image processing are performed, is supplied to the image forming unit 210 as image data.
[0025]
The image forming unit 210 is configured by arranging four image forming stations Pa to Pd above a transfer conveyance belt mechanism 213 including a transfer conveyance belt 216 stretched between a driving roller 214 and a driven roller 215. The paper feeding unit 211 located below the image forming unit 210 feeds the stored paper P one by one prior to the operation of the image forming unit 210 at the image forming stations Pa to Pd. The sheet P fed from the sheet feeding unit 211 is guided into the image forming unit 210 at a timing synchronized with the operation of the image forming stations Pa to Pd by the rotation of the registration roller 212. The transfer / conveyance belt mechanism 213 conveys the paper P fed by the registration rollers 212 by electrostatically adsorbing it onto the peripheral surface of the transfer / conveyance belt 216 rotating in the arrow Z direction. The image forming stations Pa to Pd are opposed to the upper surface of the transfer conveyance belt 216, and the sheet P is conveyed from the image formation stations Pa to Pd while being electrostatically attracted to the peripheral surface of the transfer conveyance belt 216. The toner image is transferred.
[0026]
The sheet P conveyed on the upper surface of the transfer conveyance belt 216 in the direction of the arrow Z is peeled off from the peripheral surface of the transfer conveyance belt 216 by the peeling device 229 and then heated and pressed by the fixing device 217 to melt the toner image. And firmly fixed on the surface of the paper P. The paper P that has passed through the fixing device 217 is discharged onto the paper discharge tray 220 via the gate 218 by the paper discharge roller 219 via the gate 218. The gate 218 guides the paper P on which the image is formed on the front surface to the switchback conveyance path 221 in the double-sided copying mode in which images are formed on both sides of the paper P. The sheet P guided to the switchback conveyance path 221 is reversed and conveyed to the registration roller 212 again, and the toner image is transferred to the back surface by the image forming stations Pa to Pd, and then the fixing device 217 and the gate 218. Is discharged to the paper discharge tray 220.
[0027]
The image forming stations Pa to Pd have substantially the same configuration. As an example, the image forming station Pa includes a photosensitive drum 222a, a charger 223a, a scanner unit 227a, a developing device 224a, a transfer device 225a, and a cleaner 226a. The photosensitive drum 222a is supported so as to be rotatable in the direction of arrow F with a part of the circumferential surface thereof facing the upper surface of the transfer conveyance belt 216. The charger 223a uniformly applies a single polarity charge to the peripheral surface of the photosensitive drum 222a by, for example, corona discharge. The scanner unit 227a includes, for example, a light source (not shown) such as a semiconductor laser element, a polygon mirror 240a, an fθ lens 241a, and mirrors 242a and 243a, and image light modulated by image data supplied from the image processing unit. Is applied to the peripheral surface of the photosensitive drum 222a. In place of the scanner units 227a to 227d, an LED head including a light emitting diode array and an imaging lens array may be used. Compared to the laser beam scanner unit, the LED head is not only excellent in quietness because it has no moving parts, but also can be configured in a small size, so that a color image forming apparatus having a plurality of image forming stations Suitable for
[0028]
An electrostatic latent image is formed on the peripheral surface of the photosensitive drum 222a that has been irradiated with the image light from the scanner unit 227a by photoconductive action. Thereafter, the developing device 224a supplies toner to the peripheral surface of the photosensitive drum 222a, and visualizes the electrostatic latent image formed on the peripheral surface of the photosensitive drum 222a into a toner image. The transfer device 225a is disposed at a position facing the circumferential surface of the photosensitive drum 222a with the transfer conveyance belt 216 interposed therebetween, and transfers a toner image carried on the circumferential surface of the photosensitive drum 222a by corona discharge or the like. By 216, the image is transferred to the surface of the sheet P being conveyed by electrostatic force.
[0029]
Each of the image forming stations Pa to Pd configured as described above forms toner images of each color of black, cyan, magenta, and yellow. Therefore, each of the scanner units 227a to 227d is supplied with image data of black, cyan, magenta, and yellow from the image processing unit. In addition, each of the developing devices 224a to 224d stores toner of each color of black, cyan, magenta, and yellow. As a result, when copying an image of a color document, toner images of black, cyan, magenta, and yellow are formed on the peripheral surfaces of the photosensitive drums 222 a to 222 d, and static images are formed on the upper surface of the transfer conveyance belt 216. The toner image is transferred while being superposed on the surface of the paper P which is electroadsorbed and conveyed in the arrow Z direction.
[0030]
FIG. 2 is a diagram showing the configuration of the pattern image detection apparatus in the digital color copying machine. In the digital color copying machine according to the embodiment of the present invention, a predetermined resist pattern image is generated at each of the image forming stations Pa to Pd at the time of turning on the power of the copying machine main body 1 and at the end of the copying operation for a predetermined number of sheets. Is directly formed on the surface of the transfer conveyance belt 216, and registration adjustment is performed to adjust the image formation timing in each of the image forming stations Pa to Pd based on the detection result of the resist pattern image, thereby preventing occurrence of color misregistration in the color image. I am doing so. For this reason, the transfer conveyance belt mechanism 213 in the copying machine main body 1 is provided with a pattern image detection device 230 that detects a resist pattern image formed on the surface of the transfer conveyance belt 216.
[0031]
The pattern image detection device 230 contacts the detection sensors 232R and 232F facing the circumferential surface of the transfer conveyance belt 216 below the rollers 214 and 215 in the transfer conveyance belt mechanism 213, and the back surface of the transfer conveyance belt 216. The rollers 231a and 231b are configured to be supported by a base 235. The base 235 has elongated holes 234a and 234b into which pins 213b and 213c protruding from the frame 213a of the transfer / conveyance belt mechanism 213 are fitted, and upper ends of springs 233a and 233b whose lower ends are locked to the frame 213a. It is locked.
[0032]
With this configuration, the base 235 is urged downward together with the detection sensors 232R and 232F and the rollers 231a and 231b by the elastic force of the springs 233a and 233b, and faces the pattern image detection device 230 at the transfer conveyance belt 216. The portion is pressed downward by the rollers 231a and 231b, and a predetermined tension is applied between the rollers 231a and 131b. As a result, the detection sensors 232R and 232F face the flat transfer / conveying belt 216 that is not slack between the rollers 231a and 131b. The detection sensors 232R and 232F are optical sensors including a light emitting element and a light receiving element, and the light reflected from the surface of the transfer conveyance belt 216 of the light emitted from the light emitting element is received by the light receiving element.
[0033]
FIG. 3 is a plan view showing the relationship between the pattern image formed in the digital copying machine and the detection sensor. In the digital copying machine according to this embodiment, when power is supplied to the copying machine main body and after a predetermined number of copies, the resist patterns P1 and P2 shown in FIG. Based on the result of detecting the formed resist patterns P1 and P2 by the detection sensors 232R and 232F formed on the transfer conveyance belt 216, the resist adjustment for adjusting the image forming position is performed for each of the image forming stations Pa to Pd. And color misregistration on the paper is prevented.
[0034]
The resist patterns P1 and P2 are sequentially formed on a surface of the transfer / conveying belt 216 in a predetermined region near both ends in a direction orthogonal to the moving direction of the transfer / conveying belt 216, and the horizontal line pattern P1 and the oblique line pattern P2 for each color. It consists of various patterns. This is read by a pair of detection sensors 232R and 232F. A slit plate is disposed in front of the light receiving area of each light receiving element in the detection sensors 232R and 232F so that the detection sensors 232R and 232F do not detect light other than the reflected light from the resist pattern that is the detection target. It is possible. However, as shown in FIG. 3, when detecting two types of resist patterns, that is, the horizontal line pattern P1 and the oblique line pattern P2 by one detection sensor 232R (232F), depending on the shape of the slit, Detection by the detection sensor 232R (232F) with respect to the oblique line pattern P2LesThere is a possibility that the bell changes and the passage of each resist pattern cannot be accurately detected.
[0035]
For example, as shown in FIG. 4, the slit plate 400 disposed between the transfer conveyance belt 216 and the detection sensor 232R (232F) includes a slit 400a included in the light receiving area 400b of the detection sensor 232R (232F). The slit 400a has a rectangular shape in which the longitudinal direction coincides with the longitudinal direction of the horizontal line pattern P1. In this case, with the movement of the transfer conveyance belt 216, as shown in FIGS. 4A to 4C, the horizontal line pattern P1 and the oblique line pattern P2 sequentially pass through the lower surface of the detection sensor 232R (232F).
[0036]
At this time, as shown in FIG. 5B, while the horizontal line pattern P1 passes through the lower surface of the detection sensor 232R (232F), the light receiving area 400b of the detection sensor 232R (232F) is a horizontal line on the entire surface of the slit 400a. Opposite the pattern P1. On the other hand, as shown in FIG. 5C, while the oblique line pattern P2 passes through the lower surface of the detection sensor 232R (232F), the light receiving area 400b of the detection sensor 232R (232F) is a part of the slit 400a. In FIG. 2, the surface of the transfer / conveyance belt 216 is opposed to the oblique line pattern P2.
[0037]
Therefore, the detection signal of the detection sensor 232R (232F) has a lower output level of the detection signal of the oblique line pattern P2 than the output level of the detection signal of the horizontal line pattern P1, as shown in FIG. There is a possibility that the passage of the oblique line pattern P2 cannot be accurately detected. In such a case, it is conceivable to switch the amplification factor of the detection signal of the detection sensor 232R (232F) between the horizontal line pattern P1 and the oblique line pattern P2, but there is a problem that the circuit configuration becomes complicated.
[0038]
Therefore, in the digital copying machine according to this embodiment, as shown in FIG. 5, the slit 500a in the slit plate 500 has a rhombus shape having a substantially intermediate angle between the inclination of the horizontal line pattern P1 and the inclination of the oblique line pattern P2. . That is, the angle θ1 formed between the longitudinal direction of the slit 500a (broken line L1) and the sub-scanning direction, which is the transport direction of the transfer transport belt 216, is 90 ° between the longitudinal direction of the horizontal line pattern P1 and the sub-scanning direction. Therefore, the angle formed by the longitudinal direction (broken line L2) of the oblique line pattern P2 and the sub-scanning direction is θ2,
θ1 = θ2 + (90−θ2) / 2
Determined by. By setting the shape of the slit 500a in this way, as shown in FIGS. 6A to 6D, a detection signal 232R (a detection signal having substantially the same output level as the horizontal line pattern P1 and the oblique line pattern P2 is generated. 232F).
[0039]
The shape of the slit 500a is not limited to the shape shown in FIGS. 5 and 6, and the output level of the detection signal of the detection sensor 232R (232F) for the horizontal line pattern P1 and the detection sensor 232R (for the diagonal line pattern P2) Any other shape can be used as long as the output level of the detection signal of 232F) substantially matches.
[0040]
Here, the laser scanning optical systems of the scanner units 227a to 227d in the image forming stations Pa to Pd have optical distortion. This distortion is caused by optical distortion in the Fθ lens group for exposing and scanning the surface of the photosensitive member at a constant speed (pitch) in the main scanning direction, bending of the optical system that exposes the surface of the photosensitive member in the main scanning direction, This is a curve distortion or the like of a line image caused by an inclination or the like. In particular, when a plastic lens is used to reduce the cost, optical distortion appears remarkably, and as a result, distortion occurs in the optical characteristics when the photosensitive member is exposed and scanned.
[0041]
Therefore, in the digital copying machine according to the embodiment of the present invention, when each pattern image is formed at both ends in the direction (main scanning direction) orthogonal to the conveying direction of the transfer conveying belt 216, the left and right optical elements in the scanning optical system are used. A pattern image is formed in an area having substantially the same distortion characteristics. Further, in a digital copying machine in which a plurality of image forming stations are arranged in parallel, a pattern image is formed in an area where the optical distortion characteristics in the scanner unit of each image forming station are substantially equal. As a result of the experiment, the result of the resist correction was most stable when the pattern image was formed in an area of 115 mm to the left and right from the center on the transfer conveyance belt 216 as an image carrier.
[0042]
As a result, a pair of pattern images are formed with a fixed positional relationship at both ends of the transfer conveyance belt 216, and the inclination of the image recorded on the transfer conveyance belt 216 (the main scanning of the transfer conveyance belt in the scanner unit). The inclination of the laser beam with respect to the direction) can be reliably corrected. In addition, registration correction when images formed at a plurality of image forming stations are sequentially superimposed on the transfer conveyance belt 216 (correction of the inclination of the laser scanning light with respect to the main scanning direction of the photoconductor in the single laser scanning unit) (Overlapping position correction between images recorded and reproduced on the photoconductor in the recording unit) is performed reliably, and each image is accurately superimposed in a predetermined positional relationship, and is faithfully reproduced as a color image.
[0043]
A detection signal processing method in the pattern image detection apparatus of the digital copying machine will be described below. After forming a resist pattern image of each color on the surface of the transfer / conveyance belt 216 at the image forming stations Pa to Pd, the transfer / conveyance belt 216 is rotated and the resist pattern image is detected by the detection sensor 232R (232F) of the pattern image detection device 230. And the passage time of each resist pattern image is detected. This process is repeated a plurality of times, and the detection value is the average value of the detection results of the maximum value and the detection result of the minimum value excluding the detection result of the minimum value. The resist correction of the image forming process in the image forming stations Pa to Pd is performed. Thus, since the average value excluding the maximum value and the minimum value in the plurality of detection results is set as the detection result, the accuracy of the detection result can be improved.
[0044]
FIG. 7 is a circuit diagram of the pattern image detection apparatus. In the pattern image detection device 230, the light reception signal in the light receiving element 232b of the reflected light emitted from the light emitting element 232a of the detection sensor 232 is input to the inverting input terminal of the comparator 232d via the amplifier 232c. The amount of reflected light on the surface of the transfer conveyance belt 216 is larger than the amount of reflected light on the resist pattern image. Therefore, the light receiving element 232b that has received the light reflected on the surface of the transfer / conveying belt 216 outputs a light receiving signal of "H" level. When the output voltage at this time is 3V, the non-inverting input terminal of the comparator 232d By setting the threshold voltage input to 2V to 2V, the output signal of the comparator 232d becomes the “L” level. On the other hand, the light receiving element 232b that has received the light reflected in the resist pattern image outputs a light receiving signal of “L” level, and when the output voltage at this time is 1V, the non-inverting input terminal of the comparator 232d is output. Since the threshold voltage of 2V is input, the output signal of the comparator 232d becomes “H” level.
[0045]
In this manner, by inputting the light reception signal of the light receiving element 232b to the inverting input terminal of the comparator 232d, a detection signal of “H” level is output from the pattern image forming apparatus 230 in a state where the resist pattern image is detected, An “L” level detection signal is output from the pattern image forming apparatus 230 in a state where no resist pattern image is detected.
[0046]
FIG. 8 is a waveform diagram of a detection signal in the pattern image detection apparatus. In the digital color copying machine according to the embodiment of the present invention, based on the detection signal of the pattern image detection device 230, the black toner pattern image PPa is used as a reference, the cyan toner pattern image PPb, the magenta toner pattern image PPc, and the yellow toner. A distance between each of the toner pattern images PPd is measured, and registration correction is performed to adjust the image formation timing in each of the image forming stations Pa to Pd based on the measurement result.
[0047]
FIG. 8A is a waveform diagram of detection signals of the pattern image detection device 230 when the image formation timings at the image forming stations Pa to Pd are appropriate. In this case, the center position Ck of the pattern image PPa is determined from the rising timing KT1 and the falling timing KT2 of the detection signal.
Ck = (KT1 + KT2) / 2
It is obtained by. Similarly, the center positions Cc, Cm, and Cy of the pattern images PPb to PPd are
Cc = (CT1 + CT2) / 2
Cm = (MT1 + MT2) / 2
Cy = (YT1 + YT2) / 2
It is obtained by. Using the center positions of the pattern images PPa to PPd thus obtained, the reference distances ΔT1 to ΔT3 between the pattern image PPa and each of the pattern images PPb to PPd are:
ΔT1 = {(KT1 + KT2) / 2} − {(CT1 + CT2) / 2}
ΔT2 = {(KT1 + KT2) / 2} − {(MT1 + MT2) / 2}
ΔT3 = {(KT1 + KT2) / 2} − {(YT1 + YT2) / 2}
It is obtained by.
[0048]
FIG. 8B is a waveform diagram of the output signal of the pattern image detection device 230 when there is an error in the image formation timing in the image forming stations Pb to Pd as compared with the image formation timing in the image forming station Pa. . In this case, the distances ΔT1 ′ to ΔT3 ′ between the black toner pattern image PPa and the other pattern images PPb to PPd are the same as described above.
ΔT1 ′ = {(KT1 ′ + KT2 ′) / 2} − {(CT1 ′ + CT2 ′) / 2}
ΔT2 ′ = {(KT1 ′ + KT2 ′) / 2} − {(MT1 ′ + MT2 ′) / 2}
ΔT3 ′ = {(KT1 ′ + KT2 ′) / 2} − {(YT1 ′ + YT2 ′) / 2}
It is obtained by.
[0049]
Therefore, the registration correction amounts A1 to A3 in the image forming stations Pb to Pd are as follows.
A1 = ΔT1−ΔT1 ′
A2 = ΔT2−ΔT2 ′
A3 = ΔT3−ΔT3 ′
It becomes. When the registration correction amounts A1 to A3 are positive values, the image forming timings at the image forming stations Pb to Pd are earlier than the image forming timings at the image forming station Pa. This means that the image forming timings at the image forming stations Pb to Pd are later than the image forming timing at the forming station Pa. As described above, the process for calculating the registration correction amount is executed a plurality of times, and the average of a plurality of calculation results in a predetermined level range is determined as the registration correction amount by excluding the maximum value and the minimum value.
[0050]
As described above, the pattern images PPa to PPd formed on the transfer conveyance belt 216 are detected a plurality of times, and the average of the detection results excluding the maximum detection result and the minimum detection result among the plurality of detection results is detected by the detection sensor. By determining the detection results of the pattern images PPa to PPd, it is possible to obtain a stable detection result that is always included in a predetermined level range, excluding detection results that differ greatly from other detection results.
[0051]
Such an effect is not limited to the detection value of the detection sensor of the pattern image for registration adjustment in the image forming process, and can be generally applied to a signal processing apparatus that detects a detection target using the detection sensor. .
[0052]
As described above, when adjusting the image forming timing in each image forming station based on the detection result of the pattern image formed on the transfer conveyance belt 216, the detection sensor detects the pattern image formed in each image forming station. Therefore, it is necessary to form a pattern image at a position where the detection sensor faces on the transfer conveyance belt. However, the position at which the detection sensor faces on the transfer / conveying belt varies depending on errors during assembly and mounting of the detection sensor. If the dimension of the pattern image is determined in consideration of this variation range, the area of the pattern image becomes large, and a large amount of toner is used for the pattern image for resist adjustment that is not an image formed in the normal image forming process. It will be wasted and the running cost will rise.
[0053]
Therefore, in the present invention, a sensor position detection process for detecting the positional relationship between the image carrier and the detection sensor is executed using the initial pattern image, and the portion where the detection sensor faces the image carrier based on the detected positional relationship. In addition, by forming a pattern image for resist adjustment, it is not necessary to increase the area of the pattern image, and waste of toner is prevented.
[0054]
FIG. 9 is a flowchart showing a processing procedure during sensor position detection processing for detecting the positional relationship between the image carrier and the detection sensor in the digital copying machine. FIG. 10 is a diagram showing an initial pattern image formed on the image carrier during the sensor position detection process, and FIG. 11 is a diagram showing a method for calculating the detection timing of the initial pattern image during the sensor position detection process. It is.
[0055]
In the sensor position detection process shown in FIG. 9, first, an initial pattern image IPP shown in FIG. 10 is formed on the surface of the transfer conveyance belt 216 as an image carrier (1001). The initial pattern image IPP includes a linear first pattern image IPP1 parallel to the main scanning direction, which is a direction orthogonal to the moving direction of the transfer conveyance belt 216, and a position in the sub scanning direction, which is the movement direction of the transfer conveyance belt 216. The first pattern image IPP1 is located on the upstream side of the second pattern image IPP2 in the moving direction of the transfer conveyance belt 216. Accordingly, the detection sensor 232 fixed at a position facing the upper surface of the transfer conveyance belt 216 faces the second pattern image IPP2 after facing the first pattern image IPP1.
[0056]
Next, the initial pattern image IPP is read by the detection sensor 232 (1002). As described above, the detection sensor 232 faces the first pattern image IPP1 and the second pattern image IPP2 in this order, and reads the second pattern image IPP2 after reading the first pattern image IPP1. Since the first pattern image IPP1 is linearly formed in a direction orthogonal to the moving direction of the transfer conveyance belt 216, even if an error occurs in the mounting position of the detection sensor 232 in the main scanning direction, the detection sensor 232 The timing facing the pattern image IPP1 is constant. On the other hand, the second pattern image IPP2 is formed by shifting the position in the moving direction of the transfer conveyance belt 216 stepwise, and therefore the detection sensor 232 according to the mounting position of the detection sensor 232 in the main scanning direction. However, the timing of facing the second pattern image IPP2 changes. Therefore, the position of the detection sensor 232 in the main scanning direction can be detected from the time from when the detection sensor 232 reads the first pattern image IPP1 to the timing when the second pattern image IPP2 is read.
[0057]
Therefore, the waveform of the detection signal of the detection sensor 232 in a state where the transfer conveyance belt 216 on which the initial pattern image IPP is formed is moved is compared with a predetermined threshold value, and the detection sensor 232 detects the first pattern image as shown in FIG. Timing T1 that faces IPP1, timing T2 that no longer opposes the first pattern image IPP1, timing T3 that opposes the second pattern image IPP2, and timing T4 that no longer opposes the second pattern image IPP2 are measured and measured. Using T1-T4,
Ts = (T3 + T4) / 2− (T1 + T2) / 2 Formula 1
To calculate the detection time Ts (ms) (1003).
[0058]
The detection time Ts (ms) calculated in this way is
Ls = (Ts × PS−La) / Ld Equation 2
Is converted into an error distance Ls (mm) of the mounting position of the detection sensor 232 (1004). Here, PS is a process speed (mm / ms) that is a moving speed of the peripheral surface of the transfer conveyance belt 216, and La is a center position of the first pattern image IPP1 and a second pattern at an appropriate mounting position of the detection sensor 232. The distance from the center position of the image IPP2 (mm), and Ld is the displacement (mm) in the sub-scanning direction of the second pattern image IPP2.
[0059]
The measurement accuracy of the error distance Ls can be improved by repeatedly executing the processes 1001 to 1004 a predetermined number of times (1005 → 1001) and calculating the average value of the obtained error distances Ls (1006). . However, the processing of 1005 and 1006 can be omitted. The measurement accuracy of the error distance Ls can also be improved by repeatedly executing the processes 1001 to 1003 a predetermined number of times and substituting the obtained average value of the plurality of detection times Ts into the above equation 2.
[0060]
Based on the error distance Ls obtained by the above processing, the pattern image for registration adjustment is reliably detected by the detection sensor 232 by correcting the formation position of the pattern image in the main scanning direction at the time of subsequent registration adjustment. be able to. That is, the resist adjustment pattern is formed on the transfer conveyance belt 216 at a position facing the detection sensor 232 by displacing the pattern image formation position in the image forming stations P1 to P4 by the error distance Ls during the registration adjustment. An image can be formed.
[0061]
FIG. 12 is a diagram showing the shape of another initial pattern image formed during the sensor position detection process, and FIG. 13 is a diagram showing a detection timing calculation method based on this other initial pattern image. The initial pattern image IPP ′ shown in FIG. 12 includes a straight line that is parallel to the main scanning direction that forms an upstream end in the sub-scanning direction, a side surface that is parallel to the sub-scanning direction of the transfer conveyance belt 216, and It has a substantially triangular shape surrounded by a broken line whose position in the sub-scanning direction is displaced stepwise according to the position. That is, the initial pattern image IPP ′ has a shape in which the length in the sub-scanning direction changes according to the position in the main scanning direction.
[0062]
When detecting an error in the mounting position of the detection sensor 232 using the initial pattern image IPP ′, as shown in FIG. 13, the timing T11 when the detection sensor 232 faces the initial pattern image IPP, and the initial pattern image Using timing T12 that is no longer opposite IPP ′,
Ts = T12−T11
Is used to calculate the detection time Ts (ms), and the calculated detection time Ts is substituted into the above equation 2 to convert it to the error distance Ls. The detection pattern of the detection sensor 232 is formed by repeating the formation of the initial pattern image IPP ′, the reading of the initial pattern image IPP ′ by the detection sensor 232, the calculation of the detection time Ts, and the conversion to the error distance Ls a predetermined number of times. The position detection accuracy can be improved. The detection time Ts can also be measured by directly measuring the time from the timing T11 to the timing T12. As described above, by using the initial pattern image IPP ′ having the shape shown in FIG. 12, the calculation process during the sensor position detection process can be simplified.
[0063]
As described above, the content of the sensor position detection process for the detection sensor for detecting the pattern image for resist adjustment has been described. By the same process, an error in the attachment position in the main scanning direction is also detected for the detection sensor for toner density adjustment. By displacing the formation position of the subsequent pattern image for adjusting the toner density based on the detection result, it is possible to prevent the waste of the toner without increasing the size of the pattern image.
[0064]
A black toner detection sensor and a color toner in an image forming apparatus including a black toner detection sensor for detecting a density of black toner and a color toner detection sensor for detecting the density of yellow, magenta, and cyan color toners. If an initial pattern image for sensor position detection processing is formed for each of the detection sensors, a large amount of toner is wasted during sensor position detection processing, and calculation processing becomes complicated.
[0065]
Therefore, as shown in FIG. 14, the black toner detection sensor 232k and the color toner detection sensor 232c are integrally arranged at a predetermined interval Sd in the main scanning direction to form a unit, thereby forming the black toner detection sensor 232k or the color toner. An error in the mounting position is detected by sensor position detection processing using the initial pattern image IPP for one of the toner detection sensors 232c, and the detection result of one sensor and the distance Sd between both sensors in the unit for the remaining other sensor. The error of the mounting position may be calculated from the above. As a result, it is possible to obtain an error in the mounting positions of a plurality of detection sensors only by executing one sensor position detection process. In addition, the detection positions of the pattern sensors PPa to PPd are not increased in size by displacing the formation positions of the toner density adjustment pattern images PPa to PPd in each image forming station according to the error of the detection sensor mounting position. , 232c can reliably detect the pattern images PPa to PPd, and the toner density can be accurately adjusted.
[0066]
The above configuration can be generally applied not only to a color image forming apparatus but also to an image forming apparatus that controls an operation state based on a detection result of a pattern image by a sensor.
[0067]
【The invention's effect】
According to the present invention, the following effects can be obtained.
[0068]
(1) Confirmed detection by confirming the positional relationship between the detection sensor for optically detecting the pattern image formed on the image carrier and the image carrier based on the detection result of the initial pattern image by the detection sensor. By forming a pattern image used to control the operation state of the image forming unit at a position on the image carrier according to the positional relationship with the sensor, the pattern image can be accurately detected by the detection sensor. The operating state of the forming unit can be accurately controlled. In addition, it is not necessary to form a pattern image used for controlling the operation state of the image forming unit over a wide range on the image carrier, so that waste of toner can be prevented and running cost can be reduced.
[0069]
(2) By making the detection timing of the initial pattern image by the detection sensor different from each other at a plurality of positions in a direction orthogonal to the moving direction of the image carrier, the image is detected based on the timing at which the detection sensor detects the initial pattern image. It is possible to easily confirm the position on the image carrier facing the detection sensor in the direction orthogonal to the moving direction of the carrier.
[0070]
(3) The detection time of the initial pattern image by the detection sensor is made different from each other at a plurality of positions in the direction orthogonal to the moving direction of the image carrier, so that the image is detected based on the time when the detection sensor detects the initial pattern image. The position on the image carrier facing the detection sensor in the direction orthogonal to the moving direction of the carrier can be easily confirmed.
[0072]
(Four) The pattern image formed on the image carrier is detected multiple times, and the average of the detection results excluding the maximum detection result and the minimum detection result among the multiple detection results is used as the detection result of the pattern image by the detection sensor. By confirming, a stable value excluding a detection result greatly different from other detection results can be obtained as a detection result of the pattern image by the detection sensor.
[0073]
(Five) By performing registration correction that adjusts the image formation timing on the image carrier based on the detection result of the pattern image by the detection sensor, the image formation timing on the image carrier is appropriate based on the detection result of the detection sensor. Can be determined.
[0074]
(6)The black toner detection sensor and the color toner detection sensor are integrally arranged at a predetermined interval in the main scanning direction to form a unit, whereby the initial pattern image is used for either the black toner detection sensor or the color toner detection sensor. The error of the mounting position can be detected by the sensor position detection process, and the error of the mounting position can be calculated from the detection result of one sensor and the distance Sd between the two sensors in the unit for the other sensor. As a result, it is possible to obtain an error in the mounting positions of a plurality of detection sensors only by executing one sensor position detection process. In addition, the pattern image can be reliably detected by the detection sensor without increasing the size of the pattern image by displacing the pattern image formation position for adjusting the toner density in each image forming station according to the error in the detection sensor mounting position. The toner density can be adjusted accurately.
[Brief description of the drawings]
FIG. 1 is a schematic front sectional view showing a configuration of a digital color copying machine which is a color image forming apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram showing a configuration of a pattern image detection apparatus in the digital color copying machine.
FIG. 3 is a plan view showing a relationship between a pattern image formed in the digital copying machine and a detection sensor.
FIG. 4 is a diagram for explaining a detection state of a pattern image by a detection sensor in a conventional digital copying machine.
FIG. 5 is a diagram showing a shape of a slit hole of a detection sensor of a digital copying machine according to an embodiment of the present invention.
FIG. 6 is a diagram for explaining a detection state of a pattern image by a detection sensor in the digital copying machine.
FIG. 7 is a circuit diagram of a pattern image detection apparatus applied to the digital copying machine.
FIG. 8 is a waveform diagram of a detection signal in the pattern image detection apparatus.
FIG. 9 is a flowchart showing a processing procedure at the time of sensor position detection processing for detecting a positional relationship between an image carrier and a detection sensor in the digital copying machine.
FIG. 10 is a diagram showing an initial pattern image formed on the image carrier during the sensor position detection process.
FIG. 11 is a diagram illustrating a method for calculating the detection timing of the initial pattern image during the sensor position detection process.
FIG. 12 is a diagram showing another shape of the initial pattern image.
FIG. 13 is a diagram illustrating a method for calculating the detection timing of the initial pattern image having another shape.
FIG. 14 is a diagram showing a relationship between a detection sensor and a pattern image according to another embodiment of the present invention.
[Explanation of symbols]
1-Digital copier (color image forming device)
216-Transfer conveyor belt (image carrier)
230-pattern image detection apparatus
232, 232F, 232R, 232k, 232c-detection sensors
PPa-PPd-pattern image
IPP, IPP'-initial pattern image

Claims (6)

In an image forming apparatus that includes a detection sensor that optically detects a pattern image formed on an image carrier by an image forming unit, and that controls an operation state of the image forming unit based on a detection result of the detection sensor.
The image carrier is composed of a first pattern image parallel to the main scanning direction and a second pattern image including a plurality of line segments parallel to the main scanning direction with the position in the sub-scanning direction displaced stepwise. In each range of the plurality of line segments, the first pattern image and the second pattern image both form an initial pattern image larger than the detection sensor in the main scanning direction and the sub-scanning direction,
An image forming apparatus that detects a positional relationship between an image carrier and a detection sensor based on a detection result of a detection sensor for an initial pattern image formed on the image carrier. The image forming apparatus according to claim 1, wherein the initial pattern image has a shape facing the detection sensor at a plurality of different timings at a plurality of positions in a direction orthogonal to the moving direction of the image carrier. The image forming apparatus according to claim 1 , wherein the initial pattern image has a shape facing the detection sensor at a plurality of positions in a direction orthogonal to the moving direction of the image carrier for different times. A single pattern image is detected a plurality of times by the detection sensor, and an average value of detection results excluding a maximum detection result and a minimum detection result among a plurality of detection results is determined as a detection result of the detection sensor. The image forming apparatus according to claim 1. The image formation according to claim 4, wherein the pattern image is a resist correction pattern image for adjusting an image formation timing on an image carrier by an image forming unit based on a detection signal of a detection sensor. apparatus. The detection sensor is a black toner detection sensor that optically detects a black pattern image formed on an image carrier by an image forming unit, and a color toner detection sensor that optically detects a color pattern image. ,
The black toner detection sensor and the color toner detection sensor are integrally arranged at a predetermined interval in the main scanning direction,
While detecting either the black toner detection sensor or the color toner detection sensor based on the detection result of the initial pattern image of the black toner or color toner formed on the image carrier, the positional relationship with the image carrier is detected. The image forming apparatus according to claim 1, wherein the remaining other sensor detects a positional relationship with the image carrier from a detection result of the one sensor and the predetermined interval .

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