JP2009169002A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus for suitably determining a service life of a photoreceptor with high accuracy. <P>SOLUTION: A digital copying machine 1 divides image signals for a page unit into a plurality of main scanning direction divided regions SP1 to SPn and sub scanning direction divided regions HP1 to HPm, calculates accumulated value for image signal quantity in respective divided regions which are divided into respective main scanning direction divided regions SP1 to SPn and sub scanning direction divided regions HP1 to HPm and determines the service life of the photoreceptor belt 34 based on the accumulated value. Therefore, the service life of the photoreceptor belt 34 due to a partial deterioration can be determined with high accuracy. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an image forming apparatus, and more particularly, to an image forming apparatus such as an electrophotographic copying apparatus, a laser printer apparatus, and a facsimile apparatus that appropriately determines the life of a photoreceptor.

  In an image forming apparatus such as a copying apparatus, a printer apparatus, or a composite apparatus, various setting information such as a system setting value, a printed sheet count value, and a printing setting is stored in a nonvolatile memory, and the image forming apparatus is used by using the setting information. Operation control and consumables management. For example, the number of printed sheets is counted, and the counted value is stored in a non-volatile memory to control the operation of the image forming apparatus, manage consumables such as life management of the photosensitive member, and the like.

  In such consumables management, it is the management of the life of the photoreceptor that has an important influence on the image quality. Conventionally, when image data received from an external host computer or the like is developed into an image signal, the image signal The lifetime of the photoconductor is determined by integrating the amount (see Patent Document 1), or the lifetime of the photoconductor is determined based on the rotation speed of the photoconductor and the integrated value of the image signal (see FIG. Patent Document 2).

JP 2002-251110 A Japanese Patent No. 3441912

  However, in the above prior art, since the lifetime of the photoconductor is determined based on the total integrated value of the image signals used for image formation, it is possible to cope with image quality deterioration due to partial deterioration of the photoconductor. There was a need for improvement.

  That is, for example, when the image position of the image data is biased and an electrostatic latent image is intensively formed only at a specific position of the photoreceptor, the electrostatic latent image is affected by light fatigue or the like. Deterioration may progress only in the area of the photoconductor formed by concentrating. However, in each of the prior arts described above, since the life of the photoconductor is determined based only on the image signal amount of the entire photoconductor, the life of the photoconductor due to such partial deterioration is appropriately determined. There was a need for improvement.

  SUMMARY An advantage of some aspects of the invention is that it provides an image forming apparatus that appropriately and accurately determines the life of a photoreceptor.

  In order to achieve the above object, an image forming apparatus of the present invention is an image forming apparatus that forms an image by forming an electrostatic latent image on a photoconductor on the basis of an image signal. An area dividing unit that divides the image signal in a plurality of divided areas, a calculating unit that calculates an accumulated value of the image signal for each divided area, and an accumulated value of the image signal in each divided area. Life determining means for determining the life of the photoconductor on the basis thereof.

  In the image forming apparatus according to the aspect of the invention, the image signal amount calculation unit may calculate the accumulated value of the image signal for each divided region based on the image signal for each image signal having the predetermined sub-scanning length. The calculation may be performed before the electrostatic latent image is formed or after the electrostatic latent image is formed based on the image signal.

  Furthermore, in the image forming apparatus according to the present invention, the lifetime determination unit extracts a maximum value from the accumulated value of the image signal in each of the divided areas, and when the maximum value is larger than a predetermined lifetime threshold, the photoconductor It may be characterized that it is determined that there is no lifetime.

  In the image forming apparatus according to the aspect of the invention, the lifetime determination unit may extract a minimum value from the accumulated value of the image signals of the divided areas, and the image of an adjacent divided area adjacent to the divided area of the minimum value. If the difference from the accumulated value of the signal is larger than a predetermined threshold value, it may be determined that there is no lifetime of the photoconductor.

  Furthermore, in the image forming apparatus of the present invention, the area dividing unit divides the image signal into a plurality of main scanning direction divided areas in the main scanning direction, or a plurality of main / sub scanning directions in both the main scanning direction and the sub-scanning direction. It is good also as dividing to a sub direction division field.

  According to the image forming apparatus of the present invention, an image signal at a predetermined main scanning length and a predetermined sub-scanning length is divided into a plurality of divided areas, and a cumulative value of the image signal is calculated for each of the divided areas. Since the lifetime of the photoconductor is determined based on the cumulative value of the image signals in the divided areas, the lifetime of the photoconductor due to partial deterioration can be determined with high accuracy, and the image quality can be improved.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, since the Example described below is a suitable Example of this invention, various technically preferable restrictions are attached | subjected, However, The range of this invention is unduly limited by the following description. However, not all the configurations described in the present embodiment are essential constituent elements of the present invention.

  1 to 9 are views showing an embodiment of an image forming apparatus of the present invention. FIG. 1 is a front view of an electrophotographic digital copying apparatus 1 to which an embodiment of the image forming apparatus of the present invention is applied. It is a schematic block diagram.

  In FIG. 1, the digital copying apparatus 1 includes a main body housing 2 in which a paper feeding unit 10, a plotter unit 20, and the like are housed, and a scanner unit 110 is disposed above the main body housing 2. Although not shown, the digital copying apparatus 1 includes an operation display unit that performs various operations of the digital copying apparatus 1 and displays necessary information.

  The scanner unit 110 irradiates the original with reading light, performs main scanning / sub-scanning on the original, reads an image of the original, and transfers the read image data of the original to the plotter unit 20.

  The paper feed unit 10 includes a first paper feed tray 11, a second paper feed tray 12, paper feed rollers 13 and 14, separation pads 15 and 16, a transport roller 17 and a registration roller 18. 11 and 12 each store a plurality of recording papers P of various paper sizes. The paper supply unit 10 separates the recording paper P in the paper supply trays 11 and 12 one by one by the paper supply rollers 13 and 14 and the separation pads 15 and 16, and sends them to the conveyance roller 17. 18 to transport. The registration roller 18 adjusts the timing of the recording paper P conveyed by the conveyance roller 17 and then conveys it to the plotter unit 20.

  The plotter unit 20 includes a photosensitive belt unit 30, M (magenta), C (cyan), Y (yellow), and K (black) developing units 40M, 40C, 40Y, and 40K, an intermediate transfer belt unit 50, and a secondary transfer. A unit 60, a writing unit 70, a charging unit 80, a fixing unit 90, a paper discharge unit 100, and the like are provided. The digital copying apparatus 1 is provided with a paper discharge tray 3 in the main body housing 2 above the plotter unit 20. Is formed.

  The photosensitive belt unit 30 includes rollers 31, 32, and 33, a belt-shaped photosensitive belt 34 that is formed in an annular shape and stretched between the rollers 31 to 33, a photosensitive member cleaning unit 35, a photosensitive member waste toner bottle 36, and the like. The photosensitive belt 34 rotates in the clockwise direction in FIG. 1 (the direction indicated by the arrow in FIG. 1) along at least one of the rollers 31 to 33 when the rollers 31 to 33 are rotationally driven. Driven.

  The charging unit 80 is disposed in the vicinity of the roller 32 in the vicinity of the photosensitive belt 34 and uniformly charges the photosensitive belt 34.

  The writing unit 70 sequentially irradiates the photosensitive belt 34 uniformly charged by the charging unit 80 with the laser beam modulated based on the image data of each color from the scanner unit 110 one by one. Each time the belt 34 makes one revolution, an electrostatic latent image of each color is sequentially formed on the photosensitive belt 34.

  The developing units 40M to 40K are arranged in the order of M (magenta), C (cyan), Y (yellow), and K (black) from the lower side, and the toner bottles 41M, 41C, 41Y of each color of MCYK, respectively. 41K is accommodated in the cartridges 42M, 42C, 42Y, and 42K. Each of the developing units 40M to 40K is supplied with toner of each color from the toner bottles 41M, 41C, 41Y, and 41K of each color, and each time the photoconductor belt 34 sequentially makes one turn, the writing unit is based on the image data of each color. The toner of the corresponding color is supplied to the electrostatic latent image of the corresponding color on the photosensitive belt 34 formed by 70 to develop and sequentially form toner images of the respective colors.

  In this case, the plotter unit 20 contacts and separates the developing units 40M to 40K from the photosensitive belt 34 in the order of the developing unit 40K → the developing unit 40C → the developing unit 40Y → the developing unit 40M. The toner is transferred (primary transfer) from the corresponding color developing units 40M to 40K to the corresponding electrostatic latent image, and each time the photosensitive belt 34 makes one turn, the color of each color is transferred onto the photosensitive belt 34. Toner images are sequentially formed.

  The photoreceptor belt 34 is rotated so that the toner image of each color formed on the photoreceptor belt 34 is sequentially transferred to the intermediate transfer belt 51 of the intermediate transfer belt unit 50 at the roller 33 portion every round. The images are superimposed and transferred, and a full-color toner image is transferred and formed on the intermediate transfer belt 51.

  After the transfer, the remaining toner is removed by the photoreceptor cleaning unit 35 and the removed waste toner is stored in the photoreceptor waste toner bottle 36.

  In the intermediate transfer belt unit 50, the intermediate transfer belt 51 is stretched around a plurality of rollers 52, and at least one roller 52 is driven to rotate, thereby being counterclockwise in FIG. 1 (indicated by an arrow in FIG. 1). Direction). The intermediate transfer belt unit 50 includes an intermediate transfer belt cleaning unit 53, an intermediate transfer waste toner bottle 54, an intermediate transfer roller 55, and the like. The intermediate transfer roller 55 intermediates toner images of each color on the photosensitive belt 34. A color toner image is formed by sequentially superimposing and transferring on the transfer belt 51.

  The intermediate transfer belt 51 is provided with a secondary transfer unit 60 at a position opposite to the photosensitive belt 34, and the paper feeding unit is interposed between the secondary transfer unit 60 and the intermediate transfer belt 51. The recording paper P is fed out from the ten paper feed trays 11 and 12 and the timing is adjusted by the registration rollers 18.

  The secondary transfer unit 60 transfers the color toner image on the intermediate transfer belt 51 onto the recording paper P that has been conveyed to the intermediate transfer belt 51.

  After the transfer is completed, the remaining toner is removed by the intermediate transfer belt cleaning unit 53 and the removed waste toner is stored in the intermediate transfer waste toner bottle 54.

  The plotter unit 20 conveys the recording paper P onto which the color toner image has been transferred by the secondary transfer unit 60 to the fixing unit 90, and heats and presses the recording paper P while conveying the recording paper P by the fixing unit 90. The toner image on P is fixed on recording paper P.

  The fixing unit 90 conveys the recording paper P that has been fixed to the paper discharge unit 100, and the paper discharge unit 100 discharges the recording paper P that has been fixed onto the paper discharge tray 3. In addition, the fixing unit 90 includes a fixing oil application unit 91 for applying fixing oil to the fixing unit 90 so as to maintain fixability and glossiness.

  As shown in FIG. 2, the writing unit 70 includes an LD (laser diode) unit 121, a cylinder lens 122, a polygon mirror 123, a WTL lens 124, an fθ lens 125, a first mirror 126, a second mirror 127, a third mirror. A mirror 128, a synchronization detection mirror 129, a synchronization detection sensor 130, a dustproof glass 131, and the like are provided. The polygon mirror 123 is rotated at a constant speed by a polygon mirror motor.

  The LD unit 121 emits a laser beam driven and modulated by image data to the polygon mirror 123 that is rotationally driven, and the polygon mirror 123 deflects the incident laser beam to cause the WTL lens 124 and the fθ lens 125 to move. Let it pass. The writing unit 70 sequentially reflects the laser beam that has passed through the lenses 124 and 125 by the first mirror 126, the second mirror 127, and the third mirror 128 to form an image on the photosensitive belt 34, and also reflects and deflects the laser beam. The laser beam incident on the photosensitive belt 34 is incident on a synchronization detection mirror 129 disposed outside the scanning region and at a position where the laser beam reflected and deflected by the polygon mirror 123 is incident. The laser beam reflected by the synchronization detection mirror 129 is incident on the synchronization detection sensor 130.

  The synchronization detection sensor 130 is composed of a light receiving element such as a photodiode, and performs photoelectric conversion of an incident laser beam to maintain a constant scanning start position in the main scanning direction in which an image is written on the photosensitive belt 34. Is converted into a synchronous detection signal.

  The digital copying apparatus 1 includes an engine control unit 200 as shown in FIG. 3, and the engine control unit 200 includes a CPU (Central Processing Unit) 201, a ROM (Read Only Memory) 202, and a RAM (Random Access Memory). ) 203 and an image processing LSI (Large Scale Integrated circuit) 204 and the like.

  The ROM 202 stores a control program for controlling the plotter unit 20 and the scanner unit 110, which are engines, a photoconductor life determination program for executing a photoconductor life determination process of the present invention described later, and necessary data. Based on the program in the ROM 202, the engine is controlled using the RAM 203 as a work memory, the engine operation of the digital copying apparatus 1 is performed, and the photoconductor lifetime determination process is performed.

  The image processing LSI 204 performs image processing according to printing conditions and conversion processing to an image signal on the image data. The image processing LSI 204 and the CPU 201 have a communication bus for exchanging image data, and two communication paths of clock and data serial communication for operation control. The CPU 201 controls the image processing LSI 204 using serial communication. To do.

  The image processing LSI 204 sends the image signal converted from the image data to the LD unit 105 of the writing unit 70, and the LD unit 105 controls the light emission of the LD based on the image signal as described above.

  The digital copying apparatus 1 includes a ROM, an EEPROM (Electrically Erasable and Programmable Read Only Memory), an EPROM, a flash memory, a flexible disk, a CD-ROM (Compact Disc Read Only Memory), a CD-RW (Compact Disc Rewritable), and a DVD. (Digital Video Disk), SD (Secure Digital) card, MO (magneto-optic disc), etc., a photoconductor for executing the photoconductor life determination process of the present invention recorded on a recording medium readable by the digital copying apparatus 1 It is constructed as a digital copying apparatus 1 that executes a photoconductor life determination process described later by reading a life determination program, introducing it into the ROM 202, and executing it. This photoconductor lifetime determination program is a computer-executable program written in a legacy programming language such as assembler, C, C ++, C #, Java (registered trademark), an object-oriented programming language, or the like. Can be stored and distributed.

  Next, the operation of this embodiment will be described. The digital copying apparatus 1 according to the present embodiment is the main unit of the developed image signal developed as a continuous image signal in which an electrostatic latent image is formed on the photosensitive belt 34 from the image data, for example, an image signal for one page. The image data belt 34 is conceptually divided into a plurality of divided areas in the scanning direction or in the main scanning direction and the sub-scanning direction, the image signal amount belonging to the divided areas is accumulated for each page, and the accumulated result is obtained. The photoconductor lifetime determination process for appropriately determining the lifetime of the photoconductor is performed.

  First, a method for dividing the developed image signal corresponding to the photosensitive belt 34 that is the basis of the determination will be described.

  As an image signal dividing method, for example, as shown in FIG. 4, an image area PG of a developed image signal in which an electrostatic latent image is formed on the photosensitive belt 34 is conceptually divided into a plurality of main scanning directions. It is possible to use a main scanning direction division method that divides into divided areas SP1 to SPn.

  As an image signal dividing method, for example, as shown in FIG. 5, an image area PG of a developed image signal on which an electrostatic latent image is formed on a photosensitive belt 34 is conceptually divided into a plurality of main images. A main scanning / sub-scanning direction dividing method is used in which the main scanning direction division regions SP1 to SPn are divided into a plurality of sub-scanning direction division regions HP1 to HPm in the sub-scanning direction. be able to.

  Further, as the image signal dividing method, for example, a sub-scanning direction dividing method that divides only into the sub-scanning direction divided regions HP1 to HPm in the sub-scanning direction shown in FIG. 5 may be used.

  Furthermore, the image signal dividing method is not limited to the above dividing method, and an area division that can determine the life of the photosensitive belt 34 by appropriately dividing the image area PG of the developed image signal into a plurality of divided areas. For example, the image region PG may be divided into a plurality of regions in an oblique direction with respect to the main scanning and sub-scanning directions. However, as will be described later, it is preferable to use a division method that is easy to process for calculating the cumulative value of the image signal amount of each divided area and that can appropriately determine the deterioration of the photosensitive belt 34. The scanning direction division method and the main scanning / sub-scanning direction division method are suitable for calculating the cumulative value of the image signal amount.

  In the area division, the number of divisions in at least one of the main scanning direction and the sub-scanning direction may be appropriately set by operating the operation display unit.

  In this way, the life of the photosensitive belt 34 can be determined based on the number of divisions according to the usage mode of the digital copying apparatus 1 by the user.

  Next, a divided region image signal amount cumulative value calculation process in which the image region PG of the developed image signal is divided by an arbitrary division method among the image signal division methods and the cumulative value of the image signal in each divided region is calculated. This will be described with reference to FIG.

  When an instruction to start copying is given on the operation display unit, the CPU 201 starts rotation of the polygon mirror motor to rotate the polygon mirror 123 as shown in FIG. 6 (step S101), and then the LD unit. Instruct 121 to turn on the LD (step S102). Next, the CPU 201 causes the image processing LSI 204 to convert image data sent from a controller unit (not shown) into an image signal (step S103). Here, the image signal is a signal for instructing whether or not to form a pixel of an electrostatic latent image for each color.

  The image processing LSI 204 divides the image signal into main scanning direction divided areas SP1 to SPn in the main scanning direction according to the number of divisions specified in advance from the image signal, or further subscans the main scanning direction divided areas SP1 to SPn. The image processing LSI 204 further divides the main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm in each direction. The image signal amount to be drawn is calculated from the image signal converted from the image data (step S104).

  Then, the image processing LSI 204 uses the image signal amount calculated for each of the divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm to each of the divided areas SP1 to SPn or the main scanning direction. It is added to the image signal amount accumulated values of the divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm, and each main scanning direction divided area SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HP1. The accumulated image signal amount value of HPm is updated (step S105).

  When the conversion from the image data to the image signal and the calculation of the image signal amount are completed, the CPU 201 stabilizes the light amount of the already lit LD so that the laser beam is input to the synchronization detection sensor 130 by the polygon mirror 123. Then, the waiting for synchronization detection is terminated (step S106). Then, the CPU 201 uses the laser beam irradiation to the synchronization detection sensor 130 as a trigger to output an image signal for one line from the image processing LSI 204 to the LD unit 121, and causes the LD unit 121 to perform LD based on the image signal for the one line. The laser is turned on / off to irradiate the photosensitive belt 34, and line scanning is performed to form an electrostatic latent image SG (see FIGS. 4 and 5) on the surface of the photosensitive belt 34 (step S107).

  When the line scanning is completed, the CPU 201 checks whether an image signal remains (step S108). If the image signal remains, the CPU 201 returns to step S106 and scans the next line in the same manner as described above from the wait for synchronization detection (steps S106 to S106). S108).

  The synchronization wait and line scanning are sequentially repeated, and when the image signal is finished in step S108, it is checked whether there is image data for the next page, that is, whether the print job is finished (step S109). If not, the process returns to step S103, and the same processing is repeated from the process of converting the image data of the next page into an image signal (steps S103 to S109).

  In step S109, when there is no image data on the next page and the job ends, the CPU 201 turns off the LD of the LD unit 121 (step S110), stops the rotation of the polygon mirror motor, and ends the process (step S109). S111).

  As described above, before writing the electrostatic latent image of one page having the predetermined main scanning length and the predetermined sub-scanning length, the image signal is counted and the main scanning direction divided areas SP1 to SPn or the main scanning direction are counted. When the accumulated image signal amount values of the divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm are calculated, it is possible to prevent unnecessary formation of an electrostatic latent image on the photosensitive belt 34 determined to have no life. It is possible to reduce energy consumption and improve usability.

  Further, the divided region image signal amount cumulative value calculation processing is not limited to the one shown in FIG. 6, and may be executed as shown in FIG. In the description of FIG. 7, the description of the processing steps similar to the processing steps of FIG. 6 is simplified.

  That is, when an instruction to start copying is given on the operation display unit, the CPU 201 starts to rotate the polygon mirror motor as shown in FIG. 7 (step S201), and instructs the LD unit 121 to turn on the LD. In step S202, the image processing LSI 204 converts image data sent from a controller unit (not shown) into an image signal (step S203).

  When the light quantity of the already lit LD is stabilized and the laser beam is input to the synchronization detection sensor 130 by the polygon mirror 123, the CPU 201 ends the synchronization detection waiting (step S204). Then, the CPU 201 uses the laser beam irradiation to the synchronization detection sensor 130 as a trigger to output an image signal for one line from the image processing LSI 204 to the LD unit 121, and causes the LD unit 121 to perform LD based on the image signal for the one line. The laser is turned on / off to irradiate the photosensitive belt 34, and line scanning is performed to form an electrostatic latent image SG on the surface of the photosensitive belt 34 (step S205).

  When the line scanning is completed, the CPU 201 checks whether an image signal remains (step S206). If the image signal remains, the CPU 201 returns to step S204 and scans the next line in the same manner as described above from the wait for synchronization detection (steps S204 to S204). S206).

  The synchronization wait and line scanning are sequentially repeated, and when the image signal ends in step S206, the image processing LSI 204 divides the image signal in the main scanning direction in the main scanning direction according to the number of divisions specified in advance from the image signal. Divided into regions SP1 to SPn, or the main scanning direction divided regions SP1 to SPn are further divided into sub-scanning direction divided regions HP1 to HPm in the sub-scanning direction, and the image processing LSI 204 further performs division into main scanning direction divided regions SP1 to SPn. Alternatively, for each of the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm, the image signal amount to be drawn is calculated from the image signal converted from the image data (step S207).

  Then, the image processing LSI 204 uses the image signal amount calculated for each of the divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm to each of the divided areas SP1 to SPn or the main scanning direction. It is added to the image signal amount accumulated values of the divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm, and each main scanning direction divided area SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HP1. The accumulated image signal amount value of HPm is updated (step S208).

  The CPU 201 checks whether there is image data of the next page, that is, whether the print job has been completed (step S209). If not, the process returns to step S203, and the image data of the next page is converted into an image signal. It repeats similarly to the above from the process which converts to (step S203-S209).

  In step S209, when there is no image data on the next page and the job ends, the CPU 201 turns off the LD of the LD unit 121 (step S210), stops the rotation of the polygon mirror motor, and ends the process (step S210). S211).

  In the processing shown in FIGS. 6 and 7, the image signal amount cumulative value is calculated for each of the divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm. Although it is performed by the image processing LSI 204, it may be performed by the CPU 201.

  Further, the image signal amount may be the number of pixels, or may include information indicating the number of pixels and the laser beam intensity.

  As described above, after the writing of the electrostatic latent image of one page having the predetermined main scanning length and the predetermined sub scanning length is completed, the main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning length are subtracted. When the accumulated image signal amount values of the scanning direction divided regions HP1 to HPm are calculated, the accumulated image signal amount value can be calculated for each page, and the image processing LSI 204 or the CPU 201 calculates the accumulated image signal amount value. The load can be reduced.

  Further, the calculation timing of the image signal amount accumulated value is not limited to the timing of FIG. 6 and FIG. 7, and for example, from the rotation start of the polygon mirror motor (step S201) to the end of rotation of the polygon mirror motor (step S211). In the meantime, the accumulated image signal amount for each of the main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm may be performed. In this way, the calculation of the image signal amount can be simplified.

  When the digital copying apparatus 1 calculates the cumulative value of the image signal amount, the life determination process for determining the life of the photosensitive belt 34 is executed as shown in FIG.

  That is, when the CPU 201 calculates the accumulated image signal amount for each of the main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm, The maximum value of the accumulated image signal amount for each of the divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm is extracted (step S301). It is checked whether or not it is equal to or longer than the set photosensitive belt 34 life threshold (step S302). This lifetime threshold value can be appropriately set by operating the operation display unit in consideration of the lifetime of the photosensitive belt 34.

  If the maximum value is smaller than the lifetime threshold value in step S302, the CPU 201 determines that the lifetime of the photosensitive belt 34 is still present and ends the processing.

  If the maximum value is equal to or greater than the life threshold value in step S302, the CPU 201 cancels the print operation when there is a print operation being executed (step S303), and indicates that the photosensitive member has a life on the operation display unit. By performing display or the like, the fact is notified to the user, and the process is terminated (step S304).

  As described above, the digital copying apparatus 1 according to the present embodiment divides an image signal in a page unit having a predetermined main scanning length and a predetermined sub-scanning length into a plurality of divided areas, and accumulates image signals in the divided areas. A value is calculated, and the life of the photosensitive belt 34 is determined based on the accumulated value of the image signal of each divided region.

  Therefore, the life of the photoreceptor belt 34 due to partial deterioration can be determined with high accuracy, and the image quality can be improved.

  Further, the digital copying apparatus 1 of this embodiment forms an electrostatic latent image based on the accumulated value of the image signal for each divided area for each image signal of one page having a predetermined sub-scanning length. It is calculated before it is made.

  Therefore, it is possible to prevent formation of an unnecessary electrostatic latent image on the photosensitive belt 34 that has been determined to have no life, and it is possible to reduce energy consumption and improve usability.

  Further, the digital copying apparatus 1 according to the present embodiment uses the accumulated value of the image signal for each divided region to calculate the electrostatic latent image based on the image signal for each image signal of one page having a predetermined sub-scanning length. It is calculated after being formed.

  Therefore, the life of the photosensitive belt 34 can be determined without imposing a load on the normal image formation control procedure, and the processing load can be suppressed.

  Further, the digital copying apparatus 1 of the present embodiment extracts the maximum value from the cumulative value of the image signals in each divided area, and determines that the photosensitive belt 34 has no life if the maximum value is larger than the life threshold. ing.

  Therefore, the presence / absence of the life of the photoconductor belt 34 can be reliably and easily determined based on the image signal amount of the most frequently used divided area, and the life accuracy of the photoconductor belt 34 can be further improved. Can do.

  Further, the digital copying apparatus 1 according to the present embodiment divides the image signal into a plurality of main scanning direction divided areas SP1 to SPn in the main scanning direction, and obtains the accumulated value of the image signals in the main scanning direction divided areas SP1 to SPn. Based on this, the life of the photosensitive belt 34 is determined.

  Therefore, the life of the photosensitive belt 34 can be accurately determined even when use is made such that an electrostatic latent image is preferentially formed at a specific position in the main scanning direction of the photosensitive belt 34. .

  Further, the digital copying apparatus 1 of the present embodiment divides an image signal into a plurality of main scanning direction divided areas SP1 to SPn and sub scanning direction divided areas HP1 to HPm in both the main scanning direction and the sub scanning direction. The lifetime of the photosensitive belt 34 is determined based on the cumulative value of the image signals of the divided areas divided into both the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm.

  Therefore, it is possible to determine the presence / absence of a life due to deterioration in the further divided areas of the photoconductor belt 34, and to further determine the life of the photoconductor belt 34 with high accuracy.

  Further, the image signal is divided only into a plurality of sub-scanning direction divided areas HP1 to HPm in the sub-scanning direction, and the image signals of the sub-scanning direction divided areas HP1 to HPm divided into the respective sub-scanning direction divided areas HP1 to HPm. The life of the photosensitive belt 34 may be determined based on the accumulated value of.

  In this way, the life of the photosensitive belt 34 can be accurately determined even when the use is such that an electrostatic latent image is intensively formed at a specific position in the sub-scanning direction of the photosensitive belt 34. be able to.

  In the process of determining the life of the photosensitive belt 34, the accumulated image signal amount and the life threshold value of each of the main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm. For example, as shown in FIG. 9, each main scanning direction divided region SP1 to SPn or the main scanning direction divided regions SP1 to SPn and the peripheral divided regions of the sub scanning direction divided regions HP1 to HPm, as shown in FIG. You may make it determine by comparing the image signal amount accumulation value. In FIG. 9, processing steps similar to those in FIG. 8 are denoted by the same step numbers, and the description thereof is simplified.

  In this case, as shown in FIG. 9, the CPU 201 calculates the image signal amount cumulative values of the main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm. And the maximum image signal amount cumulative value of each main scanning direction divided region SP1 to SPn or main scanning direction divided region SP1 to SPn and sub-scanning direction divided region HP1 to HPm is extracted (step S301). It is checked whether the value is equal to or greater than a preset life threshold value of the photosensitive belt 34 (step S302).

  If the maximum value is equal to or greater than the life threshold value in step S302, the CPU 201 determines that the life of the photosensitive belt 34 is not present, and stops the printing operation when there is a printing operation being performed (step S303). Then, the fact that the photoconductor is at the end of its life is displayed on the operation display unit, so that the user is notified of this, and the process is terminated (step S304).

  In step S302, when the maximum value is smaller than the lifetime threshold, the CPU 201 does not immediately determine that the lifetime of the photosensitive belt 34 is still present, but first, the main scanning direction division regions SP1 to SPn or the main regions are not detected. The minimum value of the accumulated image signal amount for each of the scanning direction divided areas SP1 to SPn and the sub-scanning direction divided areas HP1 to HPm is extracted (step S401), and the minimum value is set to a preset minimum guaranteed life threshold value. It is checked whether this is the case (step S402). This minimum guaranteed life threshold value can be appropriately set by operating the operation display unit in consideration of the life of the photosensitive belt 34.

  If the minimum value is smaller than the minimum guaranteed lifetime threshold value in step S402, the CPU 201 determines that the lifetime of the photosensitive belt 34 is still present and ends the process.

  If the minimum value is equal to or greater than the minimum guaranteed life threshold value in step S402, the CPU 201 determines whether the image signal amount cumulative value is adjacent to the divided region having the minimum value in the main scanning direction divided regions SP1 to SPn or the main scanning direction divided regions SP1 to SP1. The difference between the SPn and the image signal amount accumulated value of the sub-scanning direction divided regions HP1 to HPm is calculated (step S403), and a predetermined value by which it can be determined that the difference from the image signal amount accumulated value of the adjacent divided region is extremely large. As described above, for example, in FIG. 9, it is checked whether or not it is three times or more (step S404). This predetermined value can be set as appropriate by operating the operation display unit.

  If it is determined in step S404 that the difference between the image signal amount accumulated value of the adjacent divided areas is equal to or greater than a predetermined value, the photoconductor belt 34 has no life, and if there is a printing operation being executed, the CPU 201 Stops the printing operation (step S303), notifies the user of the fact that the photosensitive member is at the end of its life on the operation display unit, and terminates the process (step S304).

  In step S404, when the difference between the image signal amount accumulated values of the adjacent divided areas is smaller than a predetermined value, the CPU 201 determines that the life of the photoconductor belt 34 is still present, and the life of the photoconductor belt 34 is reached. The determination process ends.

  In this way, printing due to the extremely large difference between the accumulated values of the image signals of the adjacent main scanning direction divided areas SP1 to SPn or the main scanning direction divided areas SP1 to SPn and the sub scanning direction divided areas HP1 to HPm. The lifetime of the photoreceptor belt 34 can be more appropriately determined while preventing a difference in image quality from occurring on the image.

  In the above description, the partial life of the photosensitive belt 34 is determined and the life of the photosensitive belt 34 is notified. However, the main scanning direction divided regions SP1 to SPn or the main scanning direction divided regions SP1 to SPn are notified. In addition, a portion of the photosensitive belt 34 that is determined to be deteriorated is avoided from the formation position of the electrostatic latent image SG based on the accumulated image signal amount values and the image signals in the sub-scanning direction divided areas HP1 to HPm. The latent image forming position may be offset so as to be formed. For example, when forming an electrostatic latent image SG having a pattern for image quality adjustment, the electrostatic latent image SG may be formed on a very small part of the photosensitive belt 34, so that a deteriorated portion of the photosensitive belt 34 is avoided. An electrostatic latent image SG is formed.

  In this way, the electrostatic latent image SG is created by avoiding the deteriorated portion of the photosensitive belt 34, and the life of the photosensitive belt 34 can be extended.

  Further, the life of the photosensitive belt 34 may be determined by considering the rotation time and the number of rotations of the photosensitive belt 34 in addition to the cumulative value of the image signal, or by combining the number of sheets to be passed. Good.

  In this way, the life of the photosensitive belt 34 can be determined with higher accuracy.

  The invention made by the present inventor has been specifically described based on the preferred embodiments. However, the present invention is not limited to that described in the above embodiments, and various modifications can be made without departing from the scope of the invention. It goes without saying that it is possible. Moreover, it is not limited to what was demonstrated in 1st Example and 2nd Example, The technique equivalent to these is also contained in the technical scope of this invention.

  The present invention can be used in an image forming apparatus such as an electrophotographic printer apparatus, a facsimile apparatus, a copying apparatus, and a composite apparatus that appropriately determines the life of a photoreceptor.

1 is a schematic front view of a digital copying apparatus to which an embodiment of the present invention is applied. The principal part perspective view of a writing unit. The block block diagram of the engine control part of a digital copying apparatus. 4 is an explanatory diagram of an image signal dividing method for dividing an image signal into regions in a main scanning direction. FIG. FIG. 3 is an explanatory diagram of an image signal dividing method for dividing an area in a main scanning direction and a sub-scanning direction. The flowchart which shows a division area image signal amount accumulated value calculation process. 9 is a flowchart showing another example of a divided area image signal amount cumulative value calculation process. 6 is a flowchart showing photoconductor lifetime determination processing. 7 is a flowchart illustrating another example of the photoconductor lifetime determination process.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Digital copying apparatus 2 Main body housing | casing 10 Paper feed part 11 1st paper feed tray 12 2nd paper feed tray 13, 14 Paper feed roller 15, 16 Separation pad 17 Conveyance roller 18 Registration roller 20 Plotter part 30 Photosensitive belt unit 31 , 32, 33 Roller 34 Photoconductor belt 35 Photoconductor cleaning unit 36 Photoconductor waste toner bottle 40M, 40C, 40Y, 40K Developing unit 41M, 41C, 41Y, 41K Toner bottle 42M, 42C, 42Y, 42K Cartridge 50 Intermediate transfer belt Unit 51 Intermediate transfer belt 52 Roller 53 Intermediate transfer belt cleaning unit 54 Intermediate transfer waste toner bottle 55 Intermediate transfer roller 60 Secondary transfer unit 70 Writing unit 80 Charging unit 90 Fixing unit 100 Paper discharge unit 110 Scanner 121 LD unit 122 a cylindrical lens 123 a polygon mirror 124 WTL lenses 125 f [theta] lens 126 first mirror 127 a second mirror 128 third mirror 129 synchronization detection mirror 130 synchronization detection sensor 131 dust proof glass 200 engine control unit 201 CPU
202 ROM
203 RAM
204 Image processing LSI
SP1 to SPn Main scanning direction divided area HP1 to HPm Sub scanning direction divided area PG Image area

Claims (5)

  In an image forming apparatus for forming an image by forming an electrostatic latent image on a photoreceptor based on an image signal, region division for dividing the image signal at a predetermined main scanning length and a predetermined sub-scanning length into a plurality of divided regions Means, calculating means for calculating the accumulated value of the image signal for each divided area, and life determining means for determining the life of the photoconductor based on the accumulated value of the image signal in each divided area. An image forming apparatus.   The image signal amount calculation means calculates the accumulated value of the image signal for each of the divided areas, for each image signal of the predetermined sub-scanning length, before the electrostatic latent image is formed based on the image signal, The image forming apparatus according to claim 1, wherein the calculation is performed after the electrostatic latent image is formed based on the image signal.   The life determination means extracts a maximum value from the accumulated value of the image signal in each of the divided areas, and determines that the life of the photoconductor has no life when the maximum value is larger than a predetermined life threshold value. The image forming apparatus according to claim 1 or 2.   The life determination means extracts a minimum value from the accumulated value of the image signal in each divided area, and a difference between the minimum value and the accumulated value of the image signal in an adjacent divided area adjacent to the divided area is a predetermined value. 4. The image forming apparatus according to claim 1, wherein the image forming apparatus determines that the lifetime of the photoconductor is not greater than a threshold value. 5.   The region dividing means divides the image signal into a plurality of main scanning direction divided regions in the main scanning direction, or divides the image signal into a plurality of main / sub direction dividing regions in both the main scanning direction and the sub scanning direction. The image forming apparatus according to any one of claims 1 to 4.

Images