JP7433858B2 - Image forming device - Google Patents

Description

The present invention relates to a technique for determining the lifespan of a developing device installed in an image forming apparatus such as a copying machine, a printer, or a facsimile machine using an electrophotographic method, an electrostatic recording method, or the like.

In an image forming apparatus such as a printer using an electrophotographic image forming method (electrophotographic process), an electrophotographic photoreceptor (hereinafter referred to as "photoreceptor") as an image carrier is uniformly charged, and the charged photoreceptor is An electrostatic image is formed on the photoreceptor by selectively exposing the body to light. The electrostatic image formed on the photoreceptor is visualized as a toner image using toner as a developer. The toner image formed on the photoreceptor is then transferred to a recording material such as recording paper or a plastic sheet, and the toner image is transferred to the recording material by applying heat and pressure to the toner image transferred onto the recording material. An image is recorded by fixing it.
Such image forming apparatuses generally require replenishment of developer and maintenance of various process means. In order to facilitate the replenishment of this developer and the maintenance of various process means, the photoreceptor, charging means, developing means, cleaning means, etc. are assembled into a cartridge in a frame, and the cartridge can be detachably attached to the main body of the image forming apparatus. It has been put into practical use as a cartridge. According to the process cartridge method, it is possible to provide an image forming apparatus with excellent usability.
In such a process cartridge, as the number of image formation increases, toner is generated which is collected many times without being developed on a photosensitive drum, which is an example of a photosensitive member. In such toners, as toner image formation is repeated many times, the added external additives may be released from or embedded in the resin particles that form the toner's base, causing deterioration. There is. In such a case, the toner may not be able to obtain a desired amount of charge, and so-called fogging, in which the toner adheres to the white background portion of the image, may occur. Therefore, Patent Document 1 proposes a system that calculates the degree of deterioration of toner within an image forming apparatus and integrates the deterioration degree to determine that the developing device has reached the end of its lifespan. Furthermore, Patent Document 2 proposes a system that determines the optimal lifespan of the developing device by taking into consideration the degree of deterioration of the developing roller due to the degree of so-called filming, in which toner and external additives accumulate on the developing roller. has been done.

Patent No. 4743273 JP2016-161645A

In recent years, one of the various market demands has been to increase image density and expand color tones in order to obtain richer images. The following techniques are known to achieve this purpose. In addition to the mode for obtaining general image density, there is also a mode that changes the circumferential speed ratio of the photosensitive drum and developing roller as a means to achieve high density and increase in color tone, and toner supply to the photosensitive drum. There is a technique to achieve this by increasing the amount of toner on the recording medium.
The inventor's studies have revealed that when printing is performed using this technique by increasing the circumferential speed ratio between the photosensitive drum and the developing roller, this affects the deterioration of the developing roller. When the developing roller deteriorates early, the volume resistance value becomes high, and the electric charge of the toner on the developing roller becomes difficult to escape to the developing roller, and the toner accumulates electric charge. As a result, for example, the toner on the developing roller has an excessive charge, and the regulation by the regulation member becomes insufficient. for that,
So-called poor regulation may occur at an early timing, or due to poor regulation, the amount of toner on the developing roller increases and banding due to slip between the developing roller and the photosensitive drum may occur at an early timing. In other words, it is desired to notify the user of the lifespan of the developing device at an appropriate timing.
An object of the present invention is to solve such problems. That is, it is an object of the present invention to provide a technique that can more appropriately determine the lifespan of a developing device in an image forming apparatus in which an image forming mode that changes the rotational peripheral speed ratio of a photosensitive drum and a developing roller can be selected.

In order to achieve the above object, the image forming apparatus of the present invention includes:
a rotatable image carrier;
a developing device having a developer carrier that supplies developer to the image carrier and develops the electrostatic latent image on the image carrier;
a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier; and a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier. an image forming apparatus having a second mode in which the image forming apparatus rotates at a peripheral speed ratio of 2;
storage means for storing a first life threshold of the developing device corresponding to the first mode and a second life threshold of the developing device corresponding to the second mode;
The developing method is based on first drive amount information when the developer carrier operates in the first mode and second drive amount information when the developer carrier operates in the second mode. a control means for updating the lifespan judgment value by accumulating or cumulatively decrementing the driving amount information of the developer carrier from the initial value with respect to the lifespan judgment value of the device;
and a notification means;
The control means includes:
(i) A third lifespan threshold and the lifespan calculated based on the first lifespan threshold and the lifespan judgment value, or (ii) using the second lifespan threshold and information regarding the first lifespan threshold. making a first judgment regarding the lifespan of the first mode based on the judgment value;
(i) A fourth lifespan threshold and the lifespan calculated based on the second lifespan threshold and the lifespan judgment value, or (ii) using the first lifespan threshold and information regarding the second lifespan threshold. Judgment value and
make a second judgment regarding the lifespan of the second mode based on;
The notification means is
The present invention is characterized in that notification is performed based on the determination result by the control means.
Further, in order to achieve the above object, the image forming apparatus according to the present invention includes:
a rotatable image carrier;
a developing device having a developer carrier that supplies developer to the image carrier and develops the electrostatic latent image on the image carrier;
a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier; and a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier. an image forming apparatus having a second mode in which the image forming apparatus rotates at a peripheral speed ratio of 2;
storage means for storing any one of a first life threshold of the developing device corresponding to the first mode and a second life threshold of the developing device corresponding to the second mode;
Lifespan determination based on first drive amount information when the developer carrier operates in the first mode and second drive amount information when the developer carrier operates in the second mode. a control means for calculating the value;
and a notification means;
The control means includes:
(i) A third lifespan threshold and the lifespan calculated based on the first lifespan threshold and the lifespan judgment value, or (ii) using the second lifespan threshold and information regarding the first lifespan threshold. Judgment value and
making a first judgment regarding the lifespan of the first mode based on;
(i) A fourth lifespan threshold and the lifespan calculated based on the second lifespan threshold and the lifespan judgment value, or (ii) using the first lifespan threshold and information regarding the second lifespan threshold. Judgment value and
make a second judgment regarding the lifespan of the second mode based on;
The notification means is
The present invention is characterized in that notification is performed based on the determination result by the control means.
Further, in order to achieve the above object, the image forming apparatus according to the present invention includes:
a rotatable image carrier;
a developing device having a developer carrier that supplies developer to the image carrier and develops the electrostatic latent image on the image carrier;
a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier; and a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier. an image forming apparatus having a second mode in which the image forming apparatus rotates at a peripheral speed ratio of 2;
storage means for storing a lifespan threshold of the developing device;
The first drive amount information when the developer carrier operates in the first mode and the second drive amount information when the developer carrier operates in the second mode. control for calculating a first life judgment value corresponding to one mode, and calculating a second life judgment value corresponding to the second mode based on the first drive amount information and the second drive amount information; means and
and a notification means;
The control means includes:
causing the notification means to issue a notification regarding the lifespan of the developing device in the first mode based on a comparison between the lifespan threshold value and the first lifespan judgment value;
The present invention is characterized in that the notifying means is caused to issue a notification regarding the lifespan of the developing device in the second mode based on a comparison between the lifespan threshold value and the second lifespan judgment value.

According to the present invention, even in an image forming apparatus having a plurality of image forming modes in which the rotation peripheral speed ratio between the photosensitive drum and the developing roller is different, it is possible to appropriately determine the lifespan of the developing device.

Schematic diagram of image forming device Schematic diagram of drum cartridge Schematic diagram of developer cartridge Hardware block diagram of image forming device Explanatory diagram of the relationship between developing roller traveling distance, poor regulation, and banding Development cartridge life judgment sequence chart Sequence chart for determining the lifespan of another developer cartridge Sequence chart for determining the lifespan of another developer cartridge Sequence chart for determining the lifespan of another developer cartridge Relationship diagram between the remaining amount of toner and the remaining life of the developing roller Explanatory diagram of developing roller life line Diagram showing the notification timing of developer cartridge lifespan Diagram showing the occurrence of banding in high density mode

EMBODIMENT OF THE INVENTION Below, with reference to drawings, the form for implementing this invention is illustratively described in detail based on an Example. However, the dimensions, materials, shapes, and relative arrangement of the components described in this embodiment should be changed as appropriate depending on the configuration of the device to which the invention is applied and various conditions. That is, the scope of the present invention is not intended to be limited to the following embodiments.

[Example 1]
The overall configuration of an embodiment of an electrophotographic image forming apparatus (image forming apparatus) will be described. FIG. 1 is a sectional view of an image forming apparatus 100 of this embodiment. The image forming apparatus 100 of this embodiment is a full-color laser beam printer that employs an in-line method and an intermediate transfer method. The image forming apparatus 100 can form a full-color image on a recording material (eg, recording paper, plastic sheet, cloth, etc.) according to image information. Image information is input to the image forming apparatus main body from an image reading device connected to the image forming apparatus main body or a host device such as a personal computer communicably connected to the image forming apparatus main body. The image forming apparatus 100 includes a plurality of image forming sections SY, SM, SC, and SK for forming images of yellow (Y), magenta (M), cyan (C), and black (K), respectively. have In this embodiment, the image forming units SY, SM, SC, and SK are arranged in a line in a direction intersecting the vertical direction.

In order to simplify maintenance, the image forming apparatus 100 in this embodiment includes a photosensitive drum 1, a charging roller 2, a cleaning blade 6, and a drum cartridge frame 11 shown in FIG. 2, which will be described in detail later. The drum cartridge 210 is configured as a drum cartridge 210. Furthermore, the developing roller 4, toner supply roller 5, toner amount regulating member 8, developing chamber 20a, and developer container 22 constituting the developer storage chamber 20b shown in FIG. A developing cartridge 200 is used.
The above-mentioned image forming section includes a drum cartridge 210 (210Y, 210M, 210C, 210K) and a developing cartridge 200 (200Y, 200M, 200C, 200K). These drum cartridge 210 and developer cartridge 200 can be attached to and removed from the image forming apparatus 100 via attachment means such as an attachment guide and a positioning member provided in the image forming apparatus main body. In this embodiment, the drum cartridge 210 and developer cartridge 200 for each color all have the same shape, and the developer cartridge 200 for each color contains yellow (Y), magenta (M), and cyan (C), respectively. , black (K) are stored therein. In this embodiment, a configuration will be described in which the drum cartridge 210 and the developer cartridge 200 are independently attachable and detachable, but a configuration in which the drum cartridge 210 and the developer cartridge 200 are integrally detachable from the image forming apparatus main body may also be used.

The photosensitive drum 1 is rotationally driven by a drive means (drive source) not shown. A scanner unit (exposure device) 30 is arranged around the photosensitive drum 1 . The scanner unit 30 is an exposure unit that forms an electrostatic image (electrostatic latent image) on the photosensitive drum 1 by irradiating a laser beam based on image information. In the main scanning direction (direction perpendicular to the conveying direction of the recording material 12), laser exposure is started for each scanning line based on a position signal in a polygon scanner called BD. On the other hand, in the sub-scanning direction (direction in which the recording material 12 is conveyed), the scanning is performed with a predetermined time delay from the TOP signal, which is started from a switch (not shown) in the recording material 12 conveyance path. Thereby, the four process stations Y, M, C, and K can always perform laser exposure on the same position on the photosensitive drum 1.

An intermediate transfer belt 31 serving as an intermediate transfer member for transferring the toner image on the photosensitive drum 1 onto the recording material 12 is arranged opposite to the four photosensitive drums 1 . The intermediate transfer belt 31, which is an endless belt and serves as an intermediate transfer member, contacts all the photosensitive drums 1 and circulates (rotates) in the direction of arrow B (counterclockwise) in the figure. On the inner peripheral surface side of the intermediate transfer belt 31, four primary transfer rollers 32, which serve as primary transfer means, are arranged in parallel so as to face each photosensitive drum 1. Then, a bias having a polarity opposite to the normal charging polarity of the toner is applied to the primary transfer roller 32 from a primary transfer bias power source (high voltage power source) as a primary transfer bias applying means (not shown). As a result, the toner image on the photosensitive drum 1 is transferred onto the intermediate transfer belt 31 (primary transfer).

Further, a secondary transfer roller 3 serving as a secondary transfer means is provided on the outer peripheral surface side of the intermediate transfer belt 31.
3 is placed. Then, a bias having a polarity opposite to the normal charging polarity of the toner is applied to the secondary transfer roller 33 from a secondary transfer bias power source (high voltage power source) serving as a secondary transfer bias applying means (not shown). As a result, the toner image on the intermediate transfer belt 31 is transferred onto the recording material 12 (secondary transfer). For example, when forming a full-color image, the above-described process is sequentially performed in the image forming sections SY, SM, SC, and SK, and toner images of each color are sequentially superimposed and primarily transferred onto the intermediate transfer belt 31. Thereafter, the recording material 12 is conveyed to the secondary transfer section in synchronization with the movement of the intermediate transfer belt 31. Then, by the action of the secondary transfer roller 33 that is in contact with the intermediate transfer belt 31 via the recording material 12, the four-color toner image on the intermediate transfer belt 31 is secondarily transferred onto the recording material 12 at once. Ru.

The recording material 12 onto which the toner image has been transferred is conveyed to a fixing device 34 as a fixing means. The toner image is fixed on the recording material 12 by applying heat and pressure to the recording material 12 in the fixing device 34 .

[Drum cartridge]
The configuration of the drum cartridge 210 installed in the image forming apparatus 100 of this embodiment will be described. FIG. 2 is a cross-sectional (main cross-sectional) view of the drum cartridge 210 of this embodiment as viewed along the longitudinal direction (rotation axis direction) of the photosensitive drum 1. As shown in FIG.
The photosensitive drum 1 is rotatably attached to the drum cartridge 210 via a bearing (not shown). The photosensitive drum 1 is rotationally driven in the direction of arrow A in the figure in accordance with the image forming operation by receiving the driving force of a drive motor serving as a photosensitive drum driving means (drive source M210).

The photosensitive drum 1 is an organic photosensitive member in which the outer peripheral surface of an aluminum cylinder with a diameter of 30 mm is coated with a subbing layer, a high resistance layer, a carrier layer, and a carrier transport layer, which are functional films, in this order. Since the carrier transport layer is scraped and worn out by the image forming operation, it is necessary to form a film thickness that corresponds to the lifespan of the drum cartridge 210. In response to recent market demands, the thickness was set to 25 μm in this example in order to achieve a longer service life.

Further, in the drum cartridge 210, a charging roller 2 and a cleaning blade 6 made of an elastic body are arranged so as to be in contact with the circumferential surface of the photosensitive drum 1. Further, a drum cartridge frame 11 having a storage space for storing the toner on the photosensitive drum 1 removed by the cleaning blade 6 is provided. A bias sufficient to place an arbitrary charge on the photosensitive drum 1 is applied to the charging roller 2 from a charging bias power source (high voltage power source) serving as a charging bias applying means (not shown). In this example, the applied bias was set so that the potential (charging potential: Vd) on the photosensitive drum 1 was -500V. A laser 35 is irradiated from the scanner unit 30 based on image information to form an electrostatic image (electrostatic latent image) on the photosensitive drum 1. As a result of being irradiated with the laser 35, the charge on the surface of the photosensitive drum 1 disappears in the irradiated portion due to carriers from the carrier generation layer, and the potential thereof decreases. As a result, an electrostatic latent image is formed in which the irradiated portion of the laser 35 has a predetermined bright potential (Vl) and the non-irradiated portion has a predetermined dark potential (Vd).

The drum cartridge 210 is also provided with a nonvolatile memory (hereinafter referred to as O memory m1) which is a storage means. The O-memory m1 stores information such as the rotational speed and serial number of the photosensitive drum 1, and the usage amount of the drum cartridge can be determined based on the information held by the O-memory m1. Note that the O memory m1 is configured to be able to communicate (write and read information) with the control unit 300 of the image forming apparatus 100 shown in FIG.

[Developer cartridge]
Next, the configuration of the developer cartridge 200 installed in the image forming apparatus 100 of this embodiment will be explained. FIG. 3 is a cross-sectional (main cross-sectional) view of the developer cartridge 200 of the present invention as viewed along the longitudinal direction (rotation axis direction) of the developer roller 4. As shown in FIG.

The developing cartridge 200 includes a developing chamber 20a, a developer containing chamber 20b, a developing roller 4, a toner supply roller 5, and a developer container 22 that constitutes the developing chamber 20a and the developer containing chamber 20b. The developer storage chamber 20b is arranged below the development chamber 20a. Toner 9 as a developer is stored inside this developer storage chamber 20b. In this embodiment, the normal charge polarity of the toner 9 is negative, and the case where a negatively chargeable toner is used will be described below. However, the present invention is not limited to negatively chargeable toner.

Further, the developer storage chamber 20b is provided with a developer conveying member 21 for conveying the toner 9 to the developing chamber 20a. is being transported to. The developer conveying member 21 is composed of an elastic sheet-like member that extends in the longitudinal direction of the cartridge.

In the developing chamber 20a, a developing roller 4 serving as a developer carrying member is in contact with the corresponding photosensitive drum 1 and rotates in the direction of arrow D in the figure by receiving the driving force of a driving motor serving as a developing driving means (driving source M200). is provided. In this embodiment, the developing roller 4 and the photosensitive drum 1 rotate so that their surfaces move in the same direction at the opposing portions (contact portions). Further, the developing roller 4 is provided with a conductive elastic rubber layer having a predetermined volume resistance around a metal core. Then, a bias sufficient to develop and visualize the electrostatic latent image on the photosensitive drum 1 as a toner image is applied from a developing bias power source (high voltage power source) serving as a developing bias applying means (not shown).

Further, inside the developing chamber 20a, a toner supply roller (hereinafter simply referred to as "supply roller") 5 and a toner supply roller 5 supplying toner conveyed from the developer storage chamber 20b to the developing roller 4. A toner amount regulating member (hereinafter simply referred to as "regulating member") 8 is arranged to regulate the amount of toner coated on the developing roller 4 and apply electric charge.

Further, the developer cartridge 200 is provided with a nonvolatile memory (hereinafter referred to as DT memory m2) which is a storage means. The DT memory m2 stores the total drive amount of the developing roller 4, the remaining amount of toner, etc., and the usage amount of the developing cartridge can be grasped based on the information held in the DT memory m2. The remaining amount of toner is the amount of toner remaining among the toner contained in the developer cartridge 200. Note that the DT memory m2 is configured to be able to communicate (write and read information) with the control unit 300 of the image forming apparatus 100 in a non-contact manner or in contact via an electrical contact (not shown).

[Image formation mode]
The image forming apparatus 100 of this embodiment has two image forming modes. The first mode is an image forming mode (hereinafter referred to as normal mode) in which normal image density is obtained. The second mode lowers the dark potential on the image carrier while increasing the rotational speed ratio of the photosensitive drum 1 as the image carrier and the developing roller 4 as the developer carrier, allowing selection of high density and color. This is an image forming mode (hereinafter referred to as high density mode) for obtaining an increased range. In this way, the rotational circumferential speed ratio in the second mode (second circumferential speed ratio) is larger than the rotational circumferential speed ratio in the first mode (first circumferential speed ratio).
Table 1 below shows specific differences in control between the normal mode and the high concentration mode in this embodiment.

表１中の暗部電位Ｖｄは、帯電ローラ２で感光ドラム１表面を帯電した後の感光ドラム１表面の電位である。また、明部電位Ｖｌは、レーザ３５が照射された後の感光ドラム１表面の電位である。現像電位Ｖｄｃは現像ローラ４に現像バイアス電源によって印加される電位である。

The dark potential Vd in Table 1 is the potential of the surface of the photosensitive drum 1 after the surface of the photosensitive drum 1 is charged by the charging roller 2. Further, the bright area potential Vl is the potential of the surface of the photosensitive drum 1 after being irradiated with the laser 35. The development potential Vdc is a potential applied to the development roller 4 by the development bias power supply.

The rotational circumferential speed ratio in this embodiment is the rotational circumferential speed ratio of the developing roller 4 when the rotational circumferential speed of the photosensitive drum 1 is set to 1. Specifically, in the normal mode, the rotational peripheral speed of the photosensitive drum 1 is set to 200 mm/sec, and the rotational peripheral speed of the developing roller 4 is set to 280 mm/sec. On the other hand, in the high density mode, the peripheral rotation speed of the photosensitive drum 1 is set to 100 mm/sec, and the peripheral rotation speed of the developing roller 4 is set to 250 mm/sec. Here, the reason why the peripheral speed of rotation of the photosensitive drum 1 is slowed in the high density mode is to increase the amount of toner on the recording material 12 and thereby ensure good fixing performance. Although it is possible to increase the heat applied to the recording material 12 in the fixing device 34, the power consumption increases, so in this embodiment, the peripheral speed of rotation of the photosensitive drum 1 is slowed down.

As shown in Table 1, the difference between the development potential Vdc and the bright area potential Vl (hereinafter referred to as development contrast) is set larger in the high density mode than in the normal mode. As a result, the amount of toner developed onto the photosensitive drum 1 out of the toner coated on the developing roller 4 is greater in the high density mode than in the normal mode. Further, by setting a large rotational peripheral speed ratio between the photosensitive drum 1 and the developing roller 4, the amount of toner supplied from the developing roller 4 per unit area of the photosensitive drum 1 increases. These two effects make it possible to increase the amount of toner on the recording material 12, making it possible to print images with high density and a wide color gamut.

[Toner remaining amount detection method]
Here, a method for detecting the remaining amount of toner using the video counting method used in this embodiment will be explained. FIG. 4 shows a hardware block diagram of the image forming apparatus in this embodiment. The control unit 300 of the image forming apparatus 100 includes a correction information acquisition unit that performs various calculation processes and acquires correction amount information such as a correction distance of the developing roller 4, which will be described later, and a remaining amount acquisition unit that acquires information about the remaining amount of toner. A CPU 501 is provided which also serves as a section. Additionally, a memory 502 on the image forming apparatus main body side in which information necessary for controlling the motor drive unit 511 and the high voltage power supply 512 is stored is also provided. Further, the information stored in the O memory m1 of the drum cartridge 210 and the DT memory m2 of the developer cartridge 200 is input/output to the CPU 501 from the input/output I/F 503 via the memory communication unit 500, and is used for communication with the control unit 300. Is going. Further, a video count measuring section 305 is connected to the control section 300, which measures a video signal output by an image forming operation.
The principle of detecting the remaining amount of toner using video counting will be explained. Another control device (not shown) is arranged upstream of the control unit 300, and the laser drive signal (video signal) from the control device is branched, and during the period of forming an electrostatic latent image on the photosensitive drum, the video signal is Sample the signal. The sampled video signal is input to a hardware counter in the control unit 300, the number of ON/OFF states of the video signal is counted, and the value is read by the CPU 501. This read value indicates the amount of toner consumed, and the value obtained by cumulatively subtracting this count value from the predetermined initial value becomes information indicating the remaining amount of toner. Then, if we divide the number of ONs of the video signal by the number of ONs that would be counted if all black images were printed in the area where the image is printed on the recording material, we can calculate how many times it would take to form an electrostatic latent image. The ratio of how many lasers are lit can be determined. The electrostatic latent image is formed on the portion irradiated with the laser, and toner adheres thereto, so the remaining amount of toner can be calculated based on the lighting ratio of the laser. Note that the count by the video count measurement unit 305 specifically corresponds to the count of ON video signals that irradiate the laser beam, but the sampling period does not need to be synchronized with the video clock of the video signal. If sampling is performed at a cycle shorter than the video clock, the video count measurement unit 305 may count the pixel information asynchronously with the video clock. Then, the CPU 501 included in the control unit 300 calculates the remaining amount of toner 9 in the developer cartridge 200 from the measured video count value.

The video count measurement unit 305 measures pixel information (video count value VCn) of the output image. In this embodiment, one video count value VCn corresponds to one sheet of recording material 12 to be output. The CPU 501 calculates the remaining amount of toner using the following procedure. First, the video count value VCn measured by the video count measurement unit 305 is added to the cumulative video count value VCr stored in the DT memory m2 of the developer cartridge 200 since the start of use of the developer cartridge 200, resulting in a total video count value VCt. Calculate.
VCt=VCr+VCn

Next, the CPU 501 calculates the remaining amount of toner TP in the developer cartridge 200 from the video count threshold VCth stored in the DT memory m2 and the total video count value VCt.
TP [%] = (1-VCt/VCth) x 100
Then, the CPU 501 writes the total video count value VCt into the DT memory m2 as the cumulative video count value VCr.
Here, when the remaining amount of toner TP=100%, the toner 9 in the developer cartridge 200 is in a full state, indicating that the developer cartridge 200 is new. Further, when the remaining amount of toner TP=0%, the remaining amount of toner 9 in the developer cartridge 200 is almost exhausted, indicating that it is time to replace the developer cartridge 200.
In this embodiment, the video count threshold VCth when the remaining amount of toner TP=0% is determined by the amount of toner supplied from the supply roller 5 to the developing roller 4 even when printing a high print image such as a solid image. The setting is based on the remaining amount of toner 9 that does not cause this. Therefore, the actual remaining amount of toner may be set to TP=5%, for example.

[Developing roller life calculation method]
Next, a method for calculating the lifespan of the developing roller 4 will be explained. The life of the developing roller 4 is determined according to the traveling distance Wu of the developing roller 4. Hereinafter, the explanation will be given using the traveling distance Wu as an example of driving amount information indicating how far the developing roller 4 has been driven. , various parameters can be used. For example, the total driving time of the developing cartridge 200 or the total number of rotations of the developing roller 4 may be used. Alternatively, the number of sheets printed using the developer cartridge 200 may be used.
The image forming apparatus 100 is equipped with a developing roller traveling distance measurement unit 302 that measures the traveling distance Wu of the developing roller 4. The travel distance Wu is being corrected.

The developing roller traveling distance measurement unit 302 measures the traveling distance Wu from the driving time Td of the developing cartridge 200, the process speed Ps of the image forming apparatus 100, and the circumferential speed ratio Sr of the developing roller 4 to the photosensitive drum 1.
Wu=Td×Ps×Sr
Here, the traveling distance Wu represents how far a certain point on the surface of the developing roller 4 has traveled due to the rotation of the developing roller 4. Further, the process speed Ps of the image forming apparatus 100 is the rotation speed of the photosensitive drum 1.

The CPU 501 reads the developing roller travel distance correction coefficient k, which is the first correction coefficient, stored in the DT memory m2. The CPU 501 may read a developing roller travel distance correction coefficient k (second correction coefficient) according to information regarding the usage amount of the developing cartridge 200. The information regarding the amount of use of the developer cartridge 200 may include information such as the cumulative number of rotations of the developing roller 4, the cumulative rotation time of the developing roller 4, the amount of toner used, and the remaining amount of toner TP. The amount of toner used is the amount of used toner 9 out of the toner 9 contained in the developer cartridge 200. The remaining toner amount TP is the amount of toner 9 remaining among the toner 9 contained in the developer cartridge 200. The amount of toner used may be determined by subtracting the remaining toner amount TP from the amount of toner in the developer cartridge 200 before the start of use. The remaining toner amount TP may be determined by subtracting the amount of toner used from the amount of toner in the developer cartridge 200 before the start of use. The information regarding the usage amount of the developer cartridge 200 may be a value obtained by dividing the cumulative number of rotations or the cumulative rotation time of the developing roller 4 by a first predetermined value regarding the developing roller 4 . The first predetermined value regarding the developing roller 4 is the number of rotations or the rotation time of the developing roller 4, and is a value set based on the lifespan of the developing roller 4. The information regarding the usage amount of the developer cartridge 200 may be a value obtained by dividing the toner usage amount by the amount of toner in the developer cartridge 200 before the start of use. The information regarding the usage amount of the developer cartridge 200 may be a value obtained by dividing the remaining toner amount TP by the amount of toner in the developer cartridge 200 before the start of use. The CPU 501 can obtain information regarding the usage amount of the developer cartridge 200 based on the information held in the DT memory m2.
The CPU 501 may read a developing roller traveling distance correction coefficient k (third correction coefficient) according to the image forming mode. Specifically, the CPU 501 reads the developing roller traveling distance correction coefficient k according to the rotational circumferential speed ratio of the photosensitive drum 1 and the developing roller 4. For example, the developing roller travel distance correction coefficient k read by the CPU 501 can be set to k=1 in the normal mode and k=1.5 in the high density mode. Further, the CPU 501 may read the developing roller traveling distance correction coefficient k calculated by multiplying the correction coefficient k1 corresponding to the information regarding the usage amount of the developing cartridge 200 by the correction coefficient k2 corresponding to the image forming mode. Correction coefficients k1 and k2 are stored in DT memory m2.
Then, the CPU 501, as a correction distance acquisition unit, calculates the corrected developing roller travel distance Hu by multiplying the predetermined travel distance Wu by the developing roller travel distance correction coefficient k.
Hu=Wu×k

Next, the CPU 501 adds the corrected developing roller traveling distance Hu to the cumulative developing roller traveling distance HT _n-1 from the start of use of the developing cartridge 200 stored in the DT memory m2. By doing so, the CPU 501 calculates the total corrected developing roller traveling distance HT _n (n=1, 2...n, HT ₀ =0), which is the total correction distance, that is, the latest cumulative developing roller traveling distance HT Calculate _n .
HT _n = HT _n-1 + Hu

Then, the CPU 501 calculates the remaining life of the developing roller in the normal mode DP1 using the following calculation formula from the developing roller traveling distance threshold Wth ₁ in the normal mode stored in the DT memory m2 and the latest cumulative developing roller traveling distance HT _n . Calculate.
DP1 [%] = (1-HT _n /Wth ₁ ) x 100
Further, the CPU 501 calculates the remaining life of the developing roller in the normal mode using the following calculation formula from the developing roller traveling distance threshold Wth ₂ in the high density mode stored in the DT memory m2 and the latest cumulative developing roller traveling distance HT _n . Calculate DP2.
DP2 [%] = (1-HT _n /Wth ₂ ) x 100
The developing roller travel distance threshold Wth ₁ (hereinafter referred to as travel distance threshold Wth ₁ ) in the normal mode is an example of a first life threshold related to the life of the developing roller 4. The developing roller traveling distance threshold value Wth ₂ (hereinafter referred to as traveling distance threshold value Wth ₂ ) in the high density mode is an example of a second lifespan threshold value regarding the lifespan of the developing roller 4.

Then, the latest post-cumulative developing roller travel distance HT _n (lifetime determination value) is written and updated in the DT memory m2 as the post-cumulative developing roller travel distance HT _n-1 at the next lifespan determination.
Here, if the remaining life of the developing roller DP1 or DP2 is 100%, this indicates that the developing cartridge 200 is new. Further, if the developing roller remaining life DP1 or DP2≦0%, it indicates that it is time to replace the developing cartridge 200.

In this embodiment, the traveling distance threshold value Wth ₁ in the normal mode is the developing roller at which the amount of toner coated on the developing roller 4 is no longer sufficiently regulated by the regulating member 8, and toner fogging on the white background portion occurs due to poor regulation in the normal mode. Set based on mileage. The traveling distance threshold value Wth ₂ in the high density mode is the developing roller that causes density unevenness due to banding due to slipping of the photosensitive drum 1 and the developing roller 4 when the circumferential speed ratio of the photosensitive drum 1 and the developing roller 4 is set high in a predetermined state. Set based on mileage. The predetermined state is a state in which a slight regulation defect occurs in the latter half of the life of the developing roller 4, even if the regulation defect is not so bad as to cause toner fogging on the white background portion.

Here, the relationship between the developing roller travel distance, poor regulation, and banding will be explained. The supply roller 5 , the regulating member 8 , and the surface of the photosensitive drum 1 are in contact with the developing roller 4 , and a predetermined potential difference is created between the developing roller 4 and the surface of the supply roller 5 , regulating member 8 , and photosensitive drum 1 . is occurring. At this time, a current flows through the developing roller 4, and the resistance value of the developing roller 4 increases (current deterioration). When the resistance value of the developing roller 4 increases, the charge held by the toner 9 on the developing roller 4 becomes difficult to escape, and the amount of charge of the toner 9 increases. When the adhesion force of the toner 9 to the developing roller 4 increases and the adhesion force of the toner 9 exceeds the regulating force of the regulating member 8, the regulating member 8 cannot sufficiently regulate the toner 9, resulting in poor regulation.
The current deterioration varies depending on the magnitude of the current flowing through the developing roller 4. FIG. 5A is a graph showing the relationship between the rotational circumferential speed ratio of the developing roller 4 and the photosensitive drum 1 and the value of the current flowing from the photosensitive drum 1 to the developing roller 4. FIG. When the rotational circumferential speed ratio between the photosensitive drum 1 and the developing roller 4 changes, as shown in FIG. 5A, the larger the rotational circumferential speed ratio, the larger the value of the current flowing through the developing roller 4. That is, the larger the rotation peripheral speed ratio, the more the deterioration due to energization progresses. If there are modes with different rotation peripheral speed ratios, it is necessary to correct them.

With reference to FIG. 5(B), banding that occurs when the amount of toner on the developing roller 4 increases due to poor regulation in the latter half of the life of the developing roller 4 will be described when the high density mode is set. Due to poor regulation, the amount of toner on the developing roller 4 increases at the location shown by arrow G1 in FIG. The roller 4 will no longer be able to follow the rotation of the photosensitive drum 1. As a result, the developing roller 4 slips and speed unevenness occurs in the developing roller 4, resulting in unevenness in the amount of toner developed on the photosensitive drum 1 at a location shown by arrow G2 in FIG. 5(B). As a result, density unevenness (banding) occurs over the entire image printed on the recording material 12, as shown in FIG. 5(C). When there is a mode in which the peripheral speed ratio of the photosensitive drum 1 and the developing roller 4 is different, such as the normal mode and the high density mode, the timing at which the regulation failure occurs is different. Regarding banding that occurs in the high density mode, the timing at which banding occurs is earlier as the circumferential speed ratio is larger, so it is necessary to set the developing roller travel distance threshold for each image forming mode. Furthermore, the degree of progression of deterioration caused by energization changes depending on the characteristics of the developing roller 4. Since the specifications of the developing roller 4 may change, it is preferable to store the developing roller traveling distance threshold value in each image forming mode in the DT memory M2 mounted in the developing cartridge 200. However, the information is not limited to this, and may be stored in the memory of the main body of the image forming apparatus.

[Developer cartridge life judgment sequence]
FIG. 6 is a sequence chart for determining the lifespan of the developer cartridge 200 in the first embodiment. Based on the information in the DT memory m2 installed in the developer cartridge 200, the CPU 501 built in the control unit 300, as a control means or determination means, performs the processing shown in the flowchart of FIG. 6 to determine the lifespan of the developer cartridge 200. , and notify the user of the determination result.

The flowchart shown in FIG. 6 will be explained. First, the image forming apparatus 100 receives print data based on a document created on an external computer through the external I/F 504 (S501).
For example, if the setting information included in the print data is set to "0", the CPU 501 selects the normal mode, and if the setting information is set to "1", selects the high density mode, and executes the subsequent processing. (S502).

Next, the CPU 501 starts the image forming operation of the image forming apparatus 100 including the developer cartridge 200 (S503). The image forming operation here includes the charging potential of the charging roller 2, the development potential setting of the developing roller 4, the rotational driving of the photosensitive drum 1 and the developing roller 4 with a predetermined rotational circumferential speed ratio, etc., as explained in Table 1. , including all operations necessary for image formation. Note that when the driving of the developing roller 4 is started, the CPU 501 measures the traveling distance Wu, and such measurement processing is also included in the image forming operation here. The traveling distance Wu measured when the normal mode is selected in S501 corresponds to the first drive amount information of the first mode, and the traveling distance Wu measured when the high concentration mode is selected corresponds to the second driving amount information. This corresponds to the second drive amount information of the mode.

Next, the CPU 501 reads the developing roller traveling distance correction coefficient k from the DT memory m2 (S504). As described above, the CPU 501 reads the developing roller traveling distance correction coefficient k corresponding to the information regarding the usage amount of the developing cartridge 200 and/or the developing roller traveling distance correction coefficient k corresponding to the image forming mode. When the CPU 501 reads the developing roller traveling distance correction coefficient k according to the image forming mode, for example, if the image forming mode is high density mode, k = 1.5, or if the image forming mode is normal mode, k = 1. , the CPU 501 reads. Note that if the correction coefficient of the selected image forming mode is 1, there is no need to perform correction, so the CPU 501 may skip the process of S102.

Next, the CPU 501 calculates the corrected developing roller traveling distance Hu using the read developing roller traveling distance correction coefficient k (S505). Note that the timing at which the CPU 501 calculates the corrected developing roller traveling distance Hu may be after the end of printing or at predetermined intervals. In either case, the calculation target is the uncalculated travel distance Wu.

Then, the CPU 501 determines the latest cumulative developing roller travel distance as a life judgment value from the corrected developing roller traveling distance Hu and the previous cumulative developing roller traveling distance HT _n-1 stored in the DT memory m2. A distance HT _n is calculated (S506).
Next, the CPU 501 determines whether the image forming mode is normal mode or high density mode (S507). When the image forming mode is the normal mode, the CPU 501 reads the normal mode mileage threshold Wth ₁ from the DT memory M2 (S508). Thereafter, the CPU 501 compares the latest post-cumulative developing roller travel distance HT _n with the normal mode travel distance threshold Wth ₁ , and determines whether the latest post-cumulative developing roller travel distance HT _n is the normal mode travel distance threshold Wt.
It is determined whether _h1 has been exceeded (S509). Then, if the latest post-cumulative developing roller travel distance HT _n exceeds the normal mode travel distance threshold value Wth ₁ , the CPU 501 writes the latest post-cumulative developing roller travel distance HT _n in the DT memory m2 (S511). Thereafter, the notification means is used to notify the user through the external I/F 504 that the developing cartridge 200 has reached the end of its life (S512). Note that the notification means may be a display device such as a monitor, an audio speaker, etc., but is not limited to these. For example, it may be possible to send a message to an external device such as a PC connected to the image forming apparatus. good.

In S509, the life span of the developing roller 4 has been determined using the normal mode travel distance threshold value Wth ₁ stored in the DT memory m2, but the present invention is not limited thereto. The travel distance threshold _Wth2 in the high density mode and the developing roller life threshold correction coefficient C1 in the normal mode may be stored in the DT memory m2. In S508, the CPU 501 reads the travel distance threshold Wth ₂ for the high density mode and the developing roller life threshold correction coefficient C1 for the normal mode, and calculates the travel distance threshold Wth _1-1 for the normal mode using the following formula. Good too.
Wth _1-1 = Wth ₂ ×C1
Then, in S509, the CPU 501 compares the latest post-cumulative developing roller travel distance HT _n with the normal mode travel distance threshold Wth _1-1 , and determines that the latest post-cumulative developing roller travel distance HT _n is the normal mode travel distance. It may be determined whether the threshold value Wth _1-1 has been exceeded. The running distance threshold Wth _1-1 in the normal mode is an example of a third lifespan threshold related to the lifespan of the developing roller 4. Note that the method of calculating the running distance threshold Wth _1-1 in the normal mode using the developing roller life threshold correction coefficient C1 in the normal mode is the same in FIGS. 7 to 9 described later.
Table 2 below shows the travel distance threshold _Wth2 in the high density mode and the developing roller life threshold correction coefficient C1 in the normal mode. However, the numerical values shown in Table 2 are just an example, and the present invention is not limited to these numerical values.

In the above, the CPU 501 determines the lifespan of the developing roller 4 based on whether the latest cumulative developing roller travel distance HT _n exceeds the normal mode travel distance threshold value Wth ₁ , but the present invention is not limited to this. That is, in S509, the CPU 501 calculates the remaining life DP1 of the developing roller in the normal mode using the following formula, and determines whether the remaining life DP1 of the developing roller 4 in the normal mode is 0 or less than a predetermined value. You can also judge the lifespan of
DP1 [%] = (1-HT _n /Wth ₁ ) x 100
Further, the developing roller remaining life DP1 may be calculated using the travel distance threshold value Wth _1-1 in the normal mode. Note that the method using the developing roller remaining life DP1 in the normal mode is the same in FIG. 8, which will be described later.

In S509, if the latest cumulative developing roller travel distance HT _n does not exceed the normal mode travel distance threshold Wth ₁ , the CPU 501 writes the latest cumulative developing roller travel distance HT _n in the DT memory m2 and updates it. (S510). The image forming apparatus 100 then prepares for the next image formation. Note that when Wth _1-1 is used in S509 and S510, the CPU 501 performs the same processing as when Wth ₁ is used.

When the image forming mode is the high density mode, the CPU 501 reads the travel distance threshold Wth ₂ for the high density mode from the DT memory M2 (S513). Thereafter, the CPU 501 compares the latest post-cumulative developing roller travel distance HT _n with the high-density mode travel distance threshold Wth ₂ , and determines that the latest post-cumulative developing roller travel distance HT _n is equal to the high-density mode travel distance threshold Wth ₂ . It is determined whether the limit has been exceeded (S514). Then, if the latest post-cumulative developing roller travel distance HT _n exceeds the high-density mode travel distance threshold Wth ₂ , the CPU 501 writes the latest post-cumulative developing roller travel distance HT _n in the DT memory m2 (S516). . Thereafter, the notification means is used to notify the user through the external I/F 504 that the developer cartridge 200 has reached the end of its life (S512). After performing the notification process in S512, the CPU 501 may permit or prohibit the image forming operation of the image forming apparatus 100 in the normal mode, depending on an instruction from the user. Further, after performing the notification process in S512, the CPU 501 may allow or prohibit the image forming operation of the image forming apparatus 100 in the normal mode, regardless of instructions from the user.

In the above description, the lifespan of the developing roller 4 has been determined using the travel distance threshold value Wth ₂ in the high density mode stored in the DT memory m2, but the present invention is not limited thereto. The travel distance threshold value _Wth1 in the normal mode and the developing roller life threshold correction coefficient C2 in the high density mode may be stored in the DT memory m2. In S513, the CPU 501 reads the normal mode travel distance threshold Wth ₁ and the high density mode developing roller life threshold correction coefficient C2, and calculates the high density mode travel distance threshold Wth _2-1 using the following formula. You can.
Wth _2-1 = Wth ₁ ×C2
Then, in S514, the CPU 501 compares the latest post-cumulative developing roller travel distance HT _n with the high-density mode travel distance threshold Wth _2-1 , and determines whether the latest post-cumulative developing roller travel distance HT _n in the high-density mode is It may also be determined whether the mileage threshold Wth _2-1 has been exceeded. The travel distance threshold value Wth _2-1 in the high density mode is an example of a fourth lifespan threshold related to the lifespan of the developing roller 4. Note that the method of calculating the travel distance threshold Wth _2-1 in the high density mode using the developing roller life threshold correction coefficient C2 in the high density mode is the same in FIGS. 7 to 9 described later.
Table 3 below shows the travel distance threshold _Wth1 in the normal mode and the developing roller life threshold correction coefficient C2 in the high density mode. However, the numerical values shown in Table 3 are just an example, and the present invention is not limited to these numerical values.

In the above, the CPU 501 determines the lifespan of the developing roller 4 based on whether the latest post-accumulation developing roller travel distance HT _n exceeds the high density mode travel distance threshold value Wth ₂ , but the present invention is not limited to this. That is, in S514, the CPU 501 calculates the developing roller remaining life DP2 using the following formula, and determines the life of the developing roller 4 based on whether the developing roller remaining life DP2 is 0 or less than a predetermined value. Good too.
DP2 [%] = (1-HT _n /Wth ₂ ) x 100
Further, the developing roller remaining life DP2 may be calculated using the traveling distance threshold value Wth _2-1 in the high density mode. Note that the method using the developing roller remaining life DP2 in the high density mode is the same in FIG. 8, which will be described later.

Further, the reference travel distance threshold Wth _R , the normal mode developing roller life threshold correction coefficient C1, and the high density mode developing roller life threshold correction coefficient C2 may be stored in the DT memory m2. The reference travel distance threshold value Wth _R is an example of a reference lifespan threshold value regarding the lifespan of the developing roller 4.
In S508, the CPU 501 may read the reference travel distance threshold Wth _R and the normal mode developing roller life threshold correction coefficient C1, and calculate the normal mode travel distance threshold Wth _1-2 using the following formula.
Wth _1-2 = Wth _R ×C1
Then, in S509, the CPU 501 compares the latest post-cumulative developing roller travel distance HT _n with the normal mode travel distance threshold value Wth _1-2 , and determines the latest post-cumulative developing roller travel distance HT _n.
It may be determined whether or not exceeds the travel distance threshold value Wth _1-2 in the normal mode. The travel distance threshold Wth _1-2 in the normal mode is an example of a third lifespan threshold related to the lifespan of the developing roller 4. Note that the method of using the travel distance threshold value Wth _1-2 in the normal mode is the same in FIGS. 7 to 9, which will be described later.
In S513, the CPU 501 reads the reference travel distance threshold Wth _R and the developing roller life threshold correction coefficient C2 for the high density mode, and calculates the travel distance threshold Wth _2-2 for the high density mode using the following formula. good.
Wth _2-2 = Wth _R ×C2
Then, in S514, the CPU 501 compares the latest post-cumulative developing roller travel distance HT _n with the high-density mode travel distance threshold Wth _2-2 , and determines whether the latest post-cumulative developing roller travel distance HT _n is the high-density mode travel distance. It may also be determined whether the mileage threshold Wth _2-2 has been exceeded. The travel distance threshold value Wth _2-2 in the high density mode is an example of a fourth lifespan threshold value regarding the lifespan of the developing roller 4. Note that the method of using the travel distance threshold value Wth _2-2 in the high concentration mode is the same in FIGS. 7 to 9, which will be described later.

In S514, if the latest cumulative developing roller traveling distance _HTn , which is the total post-correction developing roller traveling distance, does not exceed the traveling distance threshold value _Wth2 , the CPU 501 sets the latest cumulative developing roller traveling distance _HTn to DT. The data is written to the memory m2 and updated (S515). The image forming apparatus 100 then prepares for the next image formation.

On the other hand, after receiving the image information based on the print data (S517), the CPU 501 measures the video count value VC using the video count measurement unit 305, and calculates the total video count value VCt (S518). After that, the CPU 501 calculates the remaining amount of toner TP (S519), and determines whether the remaining amount of toner is low, that is, whether the remaining amount of toner TP is 0% or less (or less than a predetermined threshold remaining amount). (S520). If the remaining toner amount TP has reached 0% or less, the CPU 501 writes the cumulative video count value VCr to the DT memory m2 (S522), and notifies the user that the developer cartridge 200 has reached the end of its life (S512). . On the other hand, if the remaining toner amount TP has not reached 0% or less, the CPU 501 writes the cumulative video count value VCr into the DT memory m2 (S521). The image forming apparatus 100 then prepares for the next image formation.

Note that although calculation of the remaining toner amount TP has been described as a method for determining whether or not the remaining amount of toner is low, the present invention is not limited to this. For example, since the total video count value VCt indicates the amount of toner consumption itself, the CPU 501 determines whether the total video count value Vct exceeds a predetermined threshold value and determines whether the remaining amount of toner is low or not. may be judged. Further, although the method for detecting the amount of remaining toner using a video counting method has been described as an example, the method is not limited to this. For example, a capacitance-based remaining amount detection method or a light transmission-based remaining amount detection method may be used, or they may be used in combination. Specifically, when the remaining amount of toner obtained by the video counting method becomes less than or equal to a predetermined remaining amount, either the capacitance method or the light transmission method may be used. That is, a configuration may be adopted in which a more suitable method for obtaining the remaining amount of toner is selected depending on the level of the remaining amount of toner. Note that the capacitive method uses an electrode whose detected capacitance changes according to changes in the state of the toner 9 inside the developer storage chamber (for example, a conductive member is attached to the wall of the storage chamber). This method obtains the amount of toner 9 based on the detected change in capacitance. Since this is a conventionally known method, detailed explanation will be omitted. The light transmission method uses a light source that irradiates light into the developer storage chamber and a light receiving section that receives the light that has passed through the developer storage chamber. This is a way to get the amount of . This method is also a conventionally known method, and detailed explanation will be omitted. The same applies to the flowcharts described later.

In the first embodiment in which this series of flowcharts is executed, the traveling distance threshold Wt of the developing roller 4 is
Set according to the image forming mode. By doing so, the lifespan of the developer cartridge 200 can be appropriately determined and notified to the user. In addition, the detection result of the remaining amount of toner is also used to detect that the amount of toner in the developer cartridge 200 is almost completely exhausted. As a result, it is possible to notify not only the lifespan of the developing roller 4 due to deterioration due to energization, but also the lifespan of the developer cartridge 200 based on the remaining amount of toner 9, and it is possible to more appropriately notify the user of the lifespan of the developer cartridge 200.

[First different developer cartridge life judgment sequence]
In the explanation of FIG. 6, the corrected developing roller running distance Hu is cumulatively added to HT _n-1 , which corresponds to the previous total corrected developing roller running distance, and the latest cumulative developing roller running distance (total running distance) HT _n We have explained the method of determining the lifespan of the developing roller 4 by finding it as needed. However, it is not limited to this. For example, the corrected developing roller travel distance Hu is cumulatively decremented from the developing roller travel distance TD (Total Distance), which is stored in the DT memory m2 and is an initial value at the time of starting use of the developer cartridge 200. In this way, the travelable distance _HT'n may be calculated as a lifespan determination value for determining the lifespan of the developing roller 4. Note that HT ₀ coincides with the developing roller travelable distance TD as an initial value.
HT' _n =HT' _n-1 - Hu

Hereinafter, using the flowchart of FIG. 7, the developing cartridge life determination sequence based on the cumulative reduction process performed by the CPU 501 will be described in detail. First, the processing from S601 to S605 in FIG. 7 is similar to the processing from S501 to S505 described with reference to FIG. 6, so a detailed explanation will be omitted. Next, the corrected developing roller traveling distance Hu is cumulatively decreased from the initial value (developing roller traveling distance TD) stored in the DT memory m2 or the previous traveling distance HT'n _-1 to obtain the latest traveling distance. HT' _n is calculated (S606). Note that this latest travelable distance _HT'n corresponds to the life judgment value.
The processes in S607 and S608 in FIG. 7 are the same as the processes in S507 and S508 described in FIG. 6, so a detailed explanation will be omitted. Then, the CPU 501 compares the latest travelable distance HT' _n with the travel distance threshold Wth ₁ in the normal mode, and determines whether the latest travel distance HT' _n is less than the travel distance threshold Wth ₁ in the normal mode. A judgment is made (S609). If the CPU 501 determines in S609 that the travelable distance HT' _n is less than the normal mode travel distance threshold Wth ₁ , the CPU 501 writes the cumulatively reduced travelable distance HT' _n in the DT memory m2 (S611 ). Thereafter, the notification means is used to notify the user through the external I/F 504 that the developer cartridge 200 has reached the end of its life (S612).

In S609, the CPU 501 determines the lifespan of the developing roller 4 based on whether the travelable distance _HT'n is less than the travel distance threshold value _Wth1 in the normal mode, but the present invention is not limited to this. That is, in S609, the CPU 501 calculates the remaining life DP1' of the developing roller in the normal mode using the following formula, and determines whether the remaining life DP1' of the developing roller in the normal mode is 0 or less than a predetermined value. The lifespan of the roller 4 may also be determined.
DP1' [%] = (HT' _n /Wth ₁ ) x 100
Note that the method using the developing roller remaining life DP1' in the normal mode is the same in FIG. 9, which will be described later.

In S609, if the latest drivable distance HT' _n is not less than the normal mode drivable distance threshold Wth ₁ , the CPU 501 writes the latest drivable distance HT' _n to the DT memory m2 and updates it ( S610). The image forming apparatus 100 then prepares for the next image formation.

The process of S613 in FIG. 7 is the same as the process of S513 explained in FIG. 6, so a detailed explanation will be omitted. Then, the CPU 501 compares the latest drivable distance HT' _n with the drivable distance threshold Wth ₂ in the high concentration mode, and determines whether the latest drivable distance HT' _n is less than the drivable distance threshold Wth ₂ in the high concentration mode. (S614). If the CPU 501 determines in S614 that the travelable distance HT' _n is less than the high concentration mode travel distance threshold Wth ₂ , the CPU 501 writes the cumulatively reduced travelable distance HT' _n in the DT memory m2 ( S616). Thereafter, the notification means is used to notify the user through the external I/F 504 that the developer cartridge 200 has reached the end of its life (S612). After performing the notification process in S612, the CPU 501 may allow or prohibit the image forming operation of the image forming apparatus 100 in the normal mode according to an instruction from the user. Further, after performing the notification process in S612, the CPU 501 may allow or prohibit the image forming operation of the image forming apparatus 100 in the normal mode, regardless of an instruction from the user.

In S614, if the latest drivable distance HT' _n is not less than the high concentration mode drivable distance threshold Wth ₂ , the CPU 501 writes the latest drivable distance HT' _n to the DT memory m2 and updates it. (S615). The image forming apparatus 100 then prepares for the next image formation. Other processing is similar to the flowchart shown in FIG. 6, so detailed explanation will be omitted.
Note that, in S614, the CPU 501 determines the lifespan of the developing roller 4 based on whether the travelable distance _HT'n is less than the travel distance threshold value _Wth2 in the high density mode, but the present invention is not limited to this. That is, in S614, the CPU 501 calculates the developing roller remaining life DP2' in the high density mode using the following formula, and determines whether the developing roller remaining life DP2' in the high density mode is 0 or less than a predetermined value. , the lifespan of the developing roller 4 may be determined.
DP2' [%] = (HT' _n /Wth ₂ ) x 100
Note that the method using the developing roller remaining life DP2' in the high density mode is the same in FIG. 9, which will be described later.

Note that the frequency with which the processes of S604 to S616 are executed is not limited to a specific frequency. For example, the processes of S604 to S616 may be performed on the traveling distance Wu measured by the CPU 501 at any time every second. Alternatively, each time a print job is completed, the processing in S604 to S616 may be performed on the travel distance Wu measured from the start of the print job. Furthermore, the processes in S604 to S616 may be performed every time a predetermined number of print jobs are completed. The same applies to the processing from S504 to S516 in FIG. 6 described above.

[Second different developer cartridge life judgment sequence]
In the explanation of FIGS. 6 and 7 above, the CPU 501 updates the cumulative developing roller traveling distance HT _n and the possible traveling distance HT' _n at a predetermined frequency, and determines whether the developing cartridge 200 has reached the end of its life. I explained to them to decide whether or not to do so. However, a similar effect can be obtained with another lifespan determination sequence.
For example, the total traveling distance Wt ₀ of the developing roller in the normal mode and the total traveling distance Wt ₁ of the developing roller in the high density mode are respectively stored, and the CPU 501 selects the developing roller 200 based on the stored Wt ₀ and Wt ₁ . You can also judge the lifespan of Note that in the subscript of Wt, "0" means normal mode, and "1" means high concentration mode. The configuration will be described in detail below using the flowchart in FIG.

First, the processing from S701 to S703 in FIG. 8 is similar to the processing from S101 to S103 described in FIG. 6, so a detailed explanation will be omitted. Next, the CPU 501 updates Wt ₀ or Wt ₁ based on the image forming mode selected in S702 and the traveling distance Wu measured in S703 (S704). For example, if the image forming mode selected in S702 is the high density mode, the traveling distance Wu measured in S703 is added to the developing roller total traveling distance Wt ₁ , and the CPU 301 adds the latest Wt ₀ and Wt Get ₁ . Here, Wt ₀ is the first total value obtained by adding up the first driving amount information, which is the traveling distance Wu measured in the normal mode, and Wt ₁ is the second driving amount information, which is the traveling distance Wu measured in the high concentration mode. This corresponds to a second total value obtained by summing up , respectively, and will be explained using this term below.

Next, the CPU 501 reads the developing roller traveling distance correction coefficient k according to the image forming mode from the DT memory m2 (S705). Then, the CPU 501 calculates the corrected developing roller traveling distance Hu ₀ in the normal mode and the corrected developing roller traveling distance Hu ₁ in the high density mode based on the developing roller traveling distance correction coefficient k read in S705 (S706). . For example, when the developing roller traveling distance correction coefficient k for the normal mode is 1 and the developing roller traveling distance correction coefficient k for the high density mode is 1.5, the CPU 501 calculates Hu ₀ =Wt ₀ ×1, Hu ₁ =Wt ₁ Hu ₀ and Hu ₁ are calculated as ×1.5.
Then, the CPU 501 uses the calculated Hu ₀ and Hu ₁ to calculate the total traveling distance Ht using the formula Ht=Hu ₀ + Hu ₁ (S707). The processing in S708 and S709 in FIG. 8 is similar to the processing in S507 and S508 described in FIG. 6, so a detailed explanation will be omitted. After that, the CPU 501 determines whether the calculated total travel distance Ht exceeds the travel distance threshold value Wth ₁ in the normal mode (S710). In S711 and S712, the CPU 501 writes the first total value Wt ₀ and second total value Wt ₁ updated in S704 to the DT memory m2.
The processes in S713 and S714 in FIG. 8 are similar to the processes in S512 and S513 described in FIG. 6, so a detailed explanation will be omitted. Next, the CPU 501 determines whether the calculated total traveling distance Ht exceeds the traveling distance threshold value Wth ₂ for the high concentration mode (S715). In S716 and S717, the CPU 501 writes the first total value Wt ₀ and second total value Wt ₁ updated in S704 to the DT memory m2. Note that the processing in each of the other steps is as described with reference to FIG. 6, so a detailed description thereof will be omitted here.

[Third different developer cartridge life judgment sequence]
Furthermore, the flowchart explained in FIG. 8 is changed, and the first total value Wt ₀ and the second total value Wt ₁ in the high density mode are subtracted from the developing roller travelable distance TD as the initial value, and the life of the developing cartridge 200 is calculated. You can judge. The configuration will be described in detail below using the flowchart in FIG.
The processing from S801 to S806 in FIG. 9 is similar to the processing from S701 to S706 described with reference to FIG. 8, so a detailed explanation will be omitted. Next, the CPU 501 subtracts the first total value Wt ₀ and the second total value Wt ₁ from the developing roller travelable distance TD as an initial value to calculate the travelable distance Ht' (S807).
Ht'=TD-(Hu ₀ + Hu ₁ )
The processes in S808 and S809 in FIG. 9 are similar to the processes in S507 and S508 described in FIG. 6, so a detailed explanation will be omitted.
Next, the CPU 501 determines whether the calculated travelable distance Ht' is less than the normal mode travel distance threshold Wth ₁ (S810). In S811 and S812, the CPU 501 writes the first total value Wt ₀ and second total value Wt ₁ updated in S804 to the DT memory m2.
The processes in S813 and S814 in FIG. 9 are similar to the processes in S512 and S513 described in FIG. 6, so a detailed explanation will be omitted. Next, the CPU 501 determines whether the calculated travelable distance Ht' is less than the travel distance threshold value Wth ₂ for the high concentration mode (S815). In S816 and S817, the CPU 501 writes the first total value Wt ₀ and second total value Wt ₁ updated in S804 to the DT memory m2. Note that the processing in each of the other steps is as described with reference to FIG. 6, so a detailed description thereof will be omitted here.

また、表４では、トナー残量ＴＰに応じて現像ローラ走行距離補正係数ｋを変える場合について説明したが、これに限るものではない。現像ローラ４の累積回転数、現像ローラ４の累積回転時間又はトナー使用量に応じて替えてもよいし、これらを組み合わせて用いてもよい。用いる現像ローラ４の劣化に寄与するパラメータの変化に応じて適正に現像ローラ走行距離補正係数ｋが決められるようにすればよい。 For example, in FIG. 6 described above, the CPU 501 sets each of the normal mode running distance threshold Wth1 (first life threshold) and the high density mode running distance threshold Wth2 (second life threshold) to the corrected total developing roller running distance. Compared with HTn. Then, the CPU 501 determines the lifespan of the developer cartridge 200 in each mode based on the comparison results. For example, in the flowchart of FIG. 8, the CPU 501 compares each of the mileage threshold Wth1 (first life threshold) in the normal mode and the mileage threshold Wth2 (second life threshold) in the high concentration mode with the total mileage Ht. . Then, the CPU 501 determines the lifespan of the developer cartridge 200 in each mode based on the comparison results. In both flowcharts, the mileage threshold (lifespan threshold) of each mode is used. However, it is not limited to this form.
For example, the life threshold Wth may be set to one value, the CPU 501 reads the life threshold from the DT memory m2, and the CPU 501 calculates and prepares the total traveling distance for each of the normal mode and the high concentration mode. . Hereinafter, a case will be described in which the CPU 501 reads out a set of mileage threshold values Wth from the DT memory m2.
First, the CPU 501 obtains the total developing roller travel distance HTn (first life judgment value), which is the calculation result in step S506. Then, the total developing roller traveling distance HTn' (second life determining value) obtained by multiplying the total developing roller traveling distance HTn (first life determining value) by the correction coefficient D1 is set as the high-density total developing roller traveling distance. For example, if Wth = 3,000,000 [mm], HTn = 2,500,000 [mm], and D1 = 1.25, the total high-density developing roller travel distance HTn' = HTn x D1 = 2,500,000 [mm] x 1.25 = 3,125,000 [ mm]. That is, when Wth<3125000 [mm], the CPU 501 determines that the developer cartridge 200 has reached the end of its life in the high density mode. In the case of the flowchart in FIG. 8, the same effect can be obtained by multiplying Ht calculated by the CPU 501 in step S707 by D1.
That is, the DT memory m2 stores a lifespan threshold Wth (mileage threshold Wth). Then, the CPU 501 calculates a first lifespan judgment value for the normal mode (first mode) and a first lifespan judgment value for the high density mode (second mode) from the developing roller traveling distance HTn as the lifespan judgment value obtained by the cumulative process of S506 in FIG. ) to find the second life judgment value. Note that the developing roller traveling distance HTn itself may be used as the first life judgment value. Then, the CPU 501 compares the first lifespan judgment value with the lifespan threshold value Wth stored in the DT memory m2, and determines whether the latest first lifespan judgment value exceeds the lifespan threshold value Wth. Further, the CPU 501 compares the second lifespan determination value with the lifespan threshold value Wth stored in the DT memory m2, and determines whether the latest second lifespan determination value exceeds the lifespan threshold value Wth. Note that various processes performed after the CPU 501 determines that each lifespan judgment value exceeds the lifespan threshold value Wth are the same as those described above, and detailed description thereof will be omitted here.
In the case of the flowchart of FIG. 7, the CPU 501 calculates the high-concentration drivable distance (HT'n)' based on the drivable distance HT'n calculated in step S606 for the normal mode. More specifically, the correction coefficient may be set to E1, and the value obtained by subtracting E1 from the drivable distance HT'n may be set as the high-concentration drivable distance (HT'n)'. In this case, one mileage threshold Wth (lifetime threshold Wth) is used to compare the possible mileage.
For example, it is assumed that E1=600000 [mm], mileage threshold value Wth (lifetime threshold)=0 [mm], and possible mileage HT'n (first possible distance) calculated in step S606 is 500000 [mm]. In that case, the travelable distance (HT'n) (second travelable distance)' in high concentration mode is (HT'n)' = 500000 [mm] - 600000 [mm] = -100000 < 0 (life threshold Wth), and the CPU 501 determines that the developer cartridge 200 has reached the end of its life in the high density mode. On the other hand, the travelable distance HT'n (500000 [mm])>0 (lifetime threshold Wth), and the CPU 501 does not determine that the developer cartridge 200 has reached the end of its lifespan in the normal mode. Note that various processes performed after the CPU 501 determines that each lifespan determination value exceeds the lifespan threshold are the same as those described above, and detailed description thereof will be omitted here.
Furthermore, in the case of the flowchart in FIG. 9, the same effect can be obtained by subtracting E1 from the travelable distance Ht' calculated by the CPU 501 in step S807.
That is, the DT memory m2 stores a lifespan threshold Wth (mileage threshold Wth). Then, the CPU 501 determines the first possible travel distance (first life judgment value ) and a second travelable distance (second life judgment value) corresponding to the high concentration mode. The CPU 501 calculates the second possible travel distance (second life judgment value) by subtracting, for example, E1 from the first possible travel distance (first life judgment value). Further, the first drivable distance (first life judgment value) may be the drivable distance Ht'n or the drivable distance Ht' determined in S606 of FIG. 7 or S807 of FIG. 9.
Then, the CPU 501 compares each drivable distance with a set of drivable distance thresholds Wth (lifetime threshold Wth) stored in the DT memory m2, and determines that each drivable distance (each lifespan judgment value) is equal to the drivable distance threshold. It is determined whether or not the value has fallen below Wth. The mileage threshold Wth can be set to Wth=0, for example. Note that various processes performed after the CPU 501 determines that each lifespan determination value (each possible travel distance) is less than the lifespan threshold value Wth are the same as those described above, and detailed description thereof will be omitted here.
<Specific example>
In this embodiment, the developing roller traveling distance correction coefficient k is changed depending on the remaining amount of toner TP. That is, as shown in Table 4, the developing roller traveling distance correction coefficient k is divided into a plurality of correction coefficients (k1 to k3) according to the range of the remaining toner amount TP. It is also possible for the CPU 501 to use correction coefficients classified according to the remaining amount of toner TP as the developing roller traveling distance correction coefficient k. These multiple correction coefficients are stored in, for example, the DT memory m2, and read by the CPU 501 as appropriate. The correction coefficients classified according to the remaining toner amount TP in Table 4 may be applied only to the normal mode or the high density mode, or may be applied to both modes. Note that there are three ways to classify the remaining toner amount TP in Table 4, but the method is not limited to this. For example, it may be divided into five categories in more detail. Further, the correction coefficient may be calculated and used in a sequential manner depending on the value of the remaining amount of toner TP. Furthermore, similar classification can be achieved by replacing the remaining amount of toner TP with the cumulative amount of toner used.

Further, in Table 4, a case has been described in which the developing roller traveling distance correction coefficient k is changed depending on the remaining amount of toner TP, but the present invention is not limited to this. It may be changed according to the cumulative number of rotations of the developing roller 4, the cumulative rotation time of the developing roller 4, or the amount of toner used, or a combination of these may be used. The developing roller travel distance correction coefficient k may be appropriately determined in accordance with changes in parameters that contribute to the deterioration of the developing roller 4 used.

10(A), (B), and (C) show how the image forming apparatus 100 is operated by changing the print area (printing rate: consumption amount of toner 9 per sheet) printed on one sheet of recording material 12. 4 is a diagram showing the relationship between the remaining toner amount TP and the remaining life of the developing roller 4 when printing is performed using the developing roller 4. FIG. In each figure, the vertical axis represents the remaining toner amount TP [%], and the horizontal axis represents the remaining life of the developing roller DP [%]. In each figure, Zone 1 is an area to which developing roller travel distance correction coefficient k1 is applied, Zone 2 is an area to which developing roller travel distance correction coefficient k2 is applied, and Zone 3 is an area to which developing roller travel distance correction coefficient k3 is applied. It shows the area. When calculating the corrected developing roller traveling distance Hu, it is determined which developing roller traveling distance correction coefficient k to use depending on which Zone the remaining toner amount TP is in. Furthermore, in each figure, the solid line shows the change in the remaining life DP of the developing roller when the traveling distance of the developing roller 4 is corrected, and the broken line shows the change in the remaining life DP of the developing roller when the traveling distance of the developing roller 4 is not corrected. It shows.

FIG. 10A shows a case where printing is performed at a constant printing rate of about 1%. In the case of FIG. 10A, since the solid line and the broken line always exist within Zone 1, the developing roller traveling distance correction coefficient k1=1.0 is applied. Therefore, the remaining life DP of the developing roller shown by the solid line and the remaining life DP of the developing roller without correction shown by the broken line overlap. Then, when the developing roller remaining life DP reaches 0% (point A1), the life of the developing cartridge 200 is notified.

FIG. 10(B) shows a case where printing is performed at a constant printing rate of about 1 to 2%. In the case of FIG. 10B, since the solid line and the broken line exist in Zone 1 until the remaining toner amount TP reaches 40%, the developing roller traveling distance correction coefficient k1=1.0 is applied. When the remaining toner amount TP is in the range of 40% to 21%, the solid line and the broken line exist in Zone 2, so the developing roller traveling distance correction coefficient k2=1.3 is applied. The slope of the solid line changes from point B1 (toner remaining amount TP=40%). That is, when the traveling distance W of the developing roller 4 is corrected, the increase in the traveling distance of the developing roller 4 becomes large in the range of the remaining toner amount TP from 40% to 21%. Then, when the traveling distance of the developing roller 4 is corrected, when the remaining toner amount TP reaches 20% (point A2), the remaining life DP of the developing roller reaches 0%, and the life of the developing cartridge 200 ends. Announcements will be made. On the other hand, the slope of the dashed line remains unchanged. In other words, if the traveling distance of the developing roller 4 is not corrected, the increase in the traveling distance of the developing roller 4 is constant regardless of the remaining amount of toner TP.

FIG. 10C shows a case where printing is performed at a constant printing rate of approximately 7 to 8%. In the case of FIG. 10C, since the solid line and the broken line exist in Zone 1 until the remaining toner amount TP reaches 41%, the developing roller traveling distance correction coefficient k1=1.0 is applied. When the remaining amount of toner TP becomes lower than 41%, the solid line and the broken line exist in Zone 2, so the developing roller traveling distance correction coefficient k2=1.3 is applied. When the remaining toner amount TP becomes lower than 21%, the solid line and the broken line exist in Zone 3, so the developing roller traveling distance correction coefficient k3=5.0 is applied. The slope of the solid line changes from point B6 (toner remaining amount TP=40%) and point B7 (toner remaining amount TP=20%). In other words, when the traveling distance of the developing roller 4 is corrected, the traveling distance of the developing roller 4 increases greatly when the remaining toner amount TP is in the range of 40% to 21%, and the remaining toner amount TP is 20% to 0. %, the increase in the travel distance of the developing roller 4 becomes even greater. When the traveling distance of the developing roller 4 is corrected, the end of the life of the developing cartridge 200 is notified when the remaining toner amount TP reaches 0% (point B8).

Here, specific examples of each case in FIGS. 10(A), (B), and (C) will be summarized. FIG. 11 shows a developing roller life line α connecting point A1 in FIG. 10(A), point B2 in FIG. 10(B), and point B5 in FIG. 10(C) with a straight line. The developing roller life line α is a line indicating the life of the developing cartridge 200 when the traveling distance of the developing roller 4 is not corrected. As shown in FIG. 11, when the remaining life of the developing roller 4 is short (the traveling distance of the developing roller 4 is long) and the remaining toner amount TP is small, that is, before the remaining life of the developing roller 4 reaches 0%, , a developing roller life line α is drawn. This is because when the traveling distance of the developing roller 4 is long and the remaining amount of toner 9 becomes small, the adhesion force of the toner 9 to the developing roller 4 becomes high, and a regulation failure occurs in the region β of FIG. 11. Therefore, by correcting the traveling distance of the developing roller 4, the life of the developing cartridge 200 can be reached before reaching this region β.

通常モードの走行距離閾値Ｗｔｈ_１よりも高濃度モードの走行距離閾値Ｗｔｈ_２を低く設定する理由は、先述したように高濃度モードにおいて、バンディングによる濃度ムラが発生しやすいためである。 For example, the normal mode mileage threshold Wth ₁ and the high concentration mode mileage threshold Wth ₂ may be set to the values shown in Table 5.

The reason why the travel distance threshold value Wth ₂ in the high density mode is set lower than the travel distance threshold value Wth ₁ in the normal mode is that density unevenness due to banding is likely to occur in the high density mode as described above.

FIG. 12 shows the timing at which the life of the developing cartridge 200 is notified in the normal mode and the high density mode. The developing roller life line α shown by the solid line in FIG. 12 is the life line in the normal mode, and poor regulation occurs in the region β. The developing roller life line Z (wavy line) shown by the broken line in FIG. 12 is the life line in the high density mode, and density unevenness occurs due to banding in the region γ and the region β. That is, the developing cartridge 200 can be used up to the developing roller life line α (solid line) in the normal mode, and can be used up to the developing roller life line Z (broken line) in the high density mode. Then, the lifespan notification of the developing cartridge 200 is performed at an optimal timing according to the image forming mode.
As described above, by setting the mileage threshold for each image forming mode, it is possible to perform life notification that matches the timing of image defects that occur in each mode, without causing image defects in each mode. , the lifespan of the developer cartridge 200 can be notified.
Although the cartridge configuration has been described separately into the developer cartridge 200 and the drum cartridge 210, the present invention is not limited to this embodiment, such as an AIO cartridge in which the developer cartridge 200 and the drum cartridge 210 are integrated.
Although the description has been given in which the nonvolatile memory of the cartridge is provided with a function for storing information regarding the lifespan, the present invention is not limited to storing the information in the image forming apparatus 100, for example. Although two image forming modes, a normal mode and a high density mode, have been described, the present invention is not limited to this embodiment, as the image forming apparatus 100 may further have a plurality of modes.

また、各モードの現像ローラ走行距離補正係数と、現像ローラ走行可能距離ＴＤとの関係についても同様である。

このように、各モードに対する現像ローラ走行距離補正係数及び走行距離閾値Ｗｔｈの組み合わせは様々な形態が想定されるが、何れでも同様の効果を得られる。即ち、現像ローラ４の同じ駆動量に対して、通常モードにおいて累加又は累減する駆動量情報の大きさを、高濃度モードにおける累加又は累減する駆動量情報の大きさよりも大きくし、寿命判断値を更新できる。 [Modified example of how to use the developing roller travel distance correction coefficient k]
In the explanation of FIGS. 6 to 9, the developing roller running distance correction coefficient k in the normal mode is 1, and the developing roller running distance correction coefficient k in the high density mode is 1.5, but the present invention is not limited to this. If the ratio relationship between the developing roller traveling distance correction coefficient value of each mode and the traveling distance threshold Wth1 of the normal mode and the traveling distance threshold _Wth2 of the high density mode is maintained, a different correction coefficient is applied to each mode. May be assigned. Examples are shown in Tables 6 and 7 below.

Further, the same holds true for the relationship between the developing roller travel distance correction coefficient for each mode and the developing roller travelable distance TD.

As described above, various combinations of the developing roller traveling distance correction coefficient and the traveling distance threshold value Wth for each mode are assumed, but the same effect can be obtained in any of them. That is, for the same amount of drive of the developing roller 4, the magnitude of the drive amount information that accumulates or decreases in the normal mode is made larger than the magnitude of the drive amount information that accumulates or decreases in the high density mode, and the lifespan is determined. Values can be updated.

Furthermore, as described above, when the developing roller travel distance correction coefficient k is 1, reading of the correction coefficient by the CPU 501 may be skipped; however, when a correction coefficient other than 1 is assigned, The CPU 501 needs to read the correction coefficient. That is, depending on what kind of correction coefficient is assigned to each mode, the CPU 501 may use the correction coefficient only for the mileage Wu measured in the normal mode or high concentration mode, or use the correction coefficient only for the mileage Wu measured in each mode. A correction coefficient may be used for both. In addition, in the case of FIGS. 8 and 9, the correction coefficient is used only for the first total value Wt ₀ or the second total value Wt ₁ , or the first total value Wt ₀ and the second total value accumulated in each mode A correction coefficient may be used for both values _Wt1 . In this manner, in this embodiment, the lifespan of the developer cartridge 200 can be appropriately determined by using various correction coefficients.

In this embodiment, the developing roller traveling distance correction coefficient k may be changed depending on the remaining life DP of the developing roller. That is, first, as shown in Table 8, the developing roller travel distance correction coefficient k is divided into a plurality of correction coefficients (k1 to k3) according to the range of the developing roller remaining life DP. It is also possible for the CPU 501 to use correction coefficients categorized according to the remaining lifespan DP of the developing roller, as the aforementioned developing roller travel distance correction coefficient k. These plurality of correction coefficients are stored, for example, in the DT memory m2, and read by the CPU 501 as appropriate. Note that there are three ways to classify the developing roller remaining life DP in Table 8, but the method is not limited to this. For example, it may be divided into five categories in more detail. Further, a correction coefficient may be calculated and used in a sequential manner depending on the value of the developing roller remaining life DP. Furthermore, the same classification can be made by replacing the developing roller remaining life DP with the cumulative driving amount of the developing roller.

The correction coefficients classified according to the developing roller remaining life DP in Table 8 may be applied only to the normal mode or the high density mode, or may be applied to both modes. Furthermore, in Table 8, a case has been described in which the developing roller travel distance correction coefficient k is changed depending on the developing roller remaining life DP, but the present invention is not limited to this. The remaining life DP of the developing roller and information regarding the usage amount of the developing cartridge 200 may be used together. It is only necessary to appropriately determine the developing roller travel distance correction coefficient k in accordance with changes in parameters that contribute to the deterioration of the developing roller 4 used.

[Example 2]
In this embodiment, the correction coefficient is also stored in the O memory m1 mounted on the drum cartridge 210, and is determined together with the correction coefficient stored in the DT memory m2 mounted on the developer cartridge 200. It is something. As shown in FIG. 13, the occurrence of density unevenness due to banding in the high density mode differs depending on the combination of the remaining life of the drum cartridge 210 and the remaining life of the developing cartridge 200. This is because when the remaining life of the drum cartridge 210 decreases, the surface roughness of the photosensitive drum 1 increases, and the coefficient of friction generated between the developing roller 4 and the photosensitive drum 1 decreases. That is, the slip of the developing roller 4 is suppressed, and the occurrence of speed unevenness with respect to the photosensitive drum 1 is suppressed. In other words, the lifespan of the developer cartridge 200 in the high density mode changes depending on the lifespan of the drum cartridge 210. Therefore, in the O memory m1 mounted on the drum cartridge 210, a plurality of correction coefficients (fourth correction coefficient) are stored according to the remaining life of the drum cartridge, as shown in Table 9. By determining the final developing roller traveling distance correction coefficient k together with the above-mentioned developing roller traveling distance correction coefficient, more accurate lifespan notification can be given to the user. Note that there are three ways to classify the remaining life of the drum cartridge in Table 9, but the method is not limited to these. For example, it may be divided into five categories in more detail. Further, the correction coefficient may be calculated and used in a sequential manner depending on the value of the remaining life of the drum cartridge. Furthermore, the same classification can be made by replacing the remaining life of the drum cartridge with the cumulative driving amount of the drum cartridge.
Further, in this embodiment, the correction coefficient is stored in the O memory m1 mounted on the drum cartridge 210, but any method that can correctly determine the relationship between the remaining life of the drum cartridge 210 and the correction coefficient may be used. Not limited. For example, information indicating the relationship between the usage status of the drum cartridge 210 and the correction coefficient may be stored on the image forming apparatus main body side, so that the CPU 501 can recognize the usage status of the drum cartridge 210 from the O memory m1.

[Developing roller life calculation sequence in this example]
A sequence for calculating the traveling distance of the developing roller in this embodiment will be explained. Note that the description of parts that overlap with Example 1 will be omitted. The remaining life of the drum cartridge is determined from the number of rotations of the photosensitive drum 1, the thickness of the carrier transport layer of the photosensitive drum 1 in the initial state stored in the O memory m1, the wear rate of the carrier transport layer, etc. It is determined using the degree of wear and tear. Using the tables in Tables 4 and 9, the corrected developing roller traveling distance Hu is determined by adding the developing roller traveling distance correction coefficient kn stored in the DT memory m2 and the O memory m1 to the predetermined traveling distance Wu. It is obtained by multiplying the developing roller traveling distance correction coefficient on. The same applies to the corrected developing roller traveling distances Hu ₀ and Hu ₁ explained in FIGS. 8 and 9.
Hu=Wu×kn×on (n=1,2,3)
For example, when the remaining toner amount TP is 30% and the remaining life of the drum cartridge is 20%, the developing roller traveling distance correction coefficient k is k=k1×o3=1.3×0.85=1.105. . In this way, when calculating the corrected developing roller running distance Hu, the developing roller running distance correction coefficient kn (corrected developing roller running distance correction coefficient k) corrected with the developing roller running distance correction coefficient on may be used.
According to this embodiment, by setting the developing roller travel distance correction coefficients in accordance with the remaining life of the drum cartridge, it is possible to perform life notification that matches the timing of image defect occurrence. Therefore, it is possible to notify the lifespan of the developer cartridge 200 without causing image defects in each image forming mode.

[Example 3]
In this embodiment, the developing roller travel distance threshold is stored in the O memory m1 mounted on the drum cartridge 210. The developing roller traveling distance threshold value as shown in Table 10 is stored in the O memory m1 mounted on the drum cartridge 210, and the CPU 501 calculates the remaining lifespan DP of the developing roller accordingly. Thereby, more accurate lifespan notification can be given to the user. For example, in the O memory m1 installed in the drum cartridge 210, the travel distance threshold values Wth ₂ , Wth ₃ , Wth ₄ for the high density mode, which are divided into a plurality of groups according to the remaining life of the drum cartridge, as shown in Table 10, are stored. Store it. Note that there are three ways to classify the remaining life of the drum cartridge in Table 10, but the method is not limited to this. For example, it may be divided into five categories in more detail. Further, the threshold value may be calculated and used in a sequential manner according to the value of the remaining life of the drum cartridge. Furthermore, the same classification can be made by replacing the remaining life of the drum cartridge with the cumulative driving amount of the drum cartridge.
Furthermore, in this embodiment, the developing roller traveling distance threshold is stored in the O memory m1 mounted on the drum cartridge 210, but there is a method that can correctly determine the relationship between the remaining life of the drum cartridge 210 and the developing roller traveling distance threshold. If so, it is not limited to this. For example, even if information indicating the relationship between the usage status of the drum cartridge 210 and the developing roller travel distance threshold is stored on the image forming apparatus main body side, and the CPU 501 is configured to recognize the usage status of the drum cartridge 210 from the O memory m1. good.

[Developing roller traveling distance calculation sequence in this embodiment]
A sequence for calculating the travel distance of the developing roller in this embodiment will be described. Note that descriptions of parts that overlap with Example 1 and Example 2 will be omitted.
For example, the CPU 501 determines the travel distance threshold value Wth _L (L=2, 3, 4) for the high density mode using the remaining life of the drum cartridge determined in Example 2 and the table in Table 10. The CPU 501 calculates the remaining life of the developing roller DP1 in the normal mode from the total post-correction developing roller travel distance _HTn and the normal mode traveling distance threshold value _Wth1 . Further, the CPU 501 calculates the remaining life of the developing roller DP2 in the high density mode from the total post-correction developing roller travel distance HT _n and the travel distance threshold value Wth _L in the high density mode.
DP1 [%] = (1-HT _n /Wth ₁ ) x 100
DP2 [%] = (1-HT _n /Wth _L ) x 100 (L = 2, 3, 4)
For example, when the remaining life of the drum cartridge is 20%, the travel distance threshold Wth ₁ =3,000,000 in the normal mode, and the travel distance threshold Wth _L =Wth ₄ =2,700,000 in the high density mode. The developing roller remaining life DP1 in the normal mode and the developing roller remaining life DP1 in the high density mode are as follows.
DP1 [%] = (1-HT _n /3000000) x 100
DP2 [%] = (1-HT _n /2700000) x 100
The same applies to the remaining lifespan of the developing roller DP1' in the normal mode and the remaining lifespan DP2' of the developing roller in the high density mode described with reference to FIG. That is, the CPU 501 calculates the remaining life of the developing roller DP1' in the normal mode from the travelable distance _HT'n and the running distance threshold value _Wth1 in the normal mode. Further, the CPU 501 calculates the remaining life of the developing roller DP2' in the high density mode from the travelable distance _HT'n and the travel distance threshold value _WthL in the high density mode.
DP1' [%] = (HT' _n /Wth ₁ ) x 100
DP2' [%] = (HT' _n /Wth _L ) x 100 (L = 2, 3, 4)
As described above, by setting the developing roller travel distance thresholds in accordance with the lifespan of the drum cartridge, it is possible to perform lifespan notification in accordance with the timing at which an image defect occurs. As a result, it is possible to notify the lifespan of the developer cartridge 200 without causing image defects in each image forming mode.

表１１に示すように、ドラムカートリッジの残寿命が少なくなるほど、高濃度モードの現像ローラ寿命閾値補正係数ｐｋに割り当てられた数値が大きくなる。本実施例ではドラムカートリッジ２１０に搭載のＯメモリｍ１内に、ドラムカートリッジの残寿命に応じた高濃度モードの現像ローラ寿命閾値補正係数ｐｋを格納している。しかし、ドラムカートリッジ２１０の残寿命と高濃度モードの現像ローラ寿命閾値補正係数ｐｋとの関係を正しく判断できる方法であれば、これに限定されない。例えば、画像形成装置本体側にドラムカートリッジ２１０の使用状況と高濃度モードの現像ローラ寿命閾値補正係数ｐｋとの関係を示す情報を格納し、ＣＰＵ５０１が、ドラムカートリッジ２１０の使用状況をＯメモリｍ１から認識できるようにしてもよい。 [Example 4]
In this embodiment, the developing roller life threshold correction coefficient pk (k=2, 3, 4) for the high density mode is stored in the O memory m1 mounted on the drum cartridge 210.
The CPU 501 stores a developing roller life threshold correction coefficient pk (fifth correction coefficient) for the high density mode according to the remaining life of the drum cartridge as shown in Table 11 in the O memory m1 mounted on the drum cartridge 210. The remaining life DP of the developing roller is calculated accordingly. Note that there are three ways to classify the remaining life of the drum cartridge in Table 11, but the method is not limited to these. For example, it may be divided into five categories in more detail. Further, the threshold value may be calculated and used in a sequential manner according to the value of the remaining life of the drum cartridge. Furthermore, the same classification can be made by replacing the remaining life of the drum cartridge with the cumulative driving amount of the drum cartridge.

As shown in Table 11, as the remaining life of the drum cartridge decreases, the numerical value assigned to the developing roller life threshold correction coefficient pk in the high density mode increases. In this embodiment, the O memory m1 mounted on the drum cartridge 210 stores a developing roller life threshold correction coefficient pk for the high density mode according to the remaining life of the drum cartridge. However, the method is not limited to this, as long as it is a method that can correctly determine the relationship between the remaining life of the drum cartridge 210 and the developing roller life threshold correction coefficient pk in the high density mode. For example, information indicating the relationship between the usage status of the drum cartridge 210 and the developing roller life threshold correction coefficient pk in the high density mode is stored in the main body of the image forming apparatus, and the CPU 501 stores the usage status of the drum cartridge 210 from the O memory m1. It may be made recognizable.

[Developing roller travel distance judgment sequence in this embodiment]
A sequence for determining the travel distance of the developing roller in this embodiment will be described. Note that explanations of parts that overlap with Examples 1 to 3 will be omitted.
Using the remaining life of the drum cartridge and the table of Table 11, the CPU 501 determines the developing roller life threshold correction coefficient pk for the high density mode. Then, the CPU 501 determines the travel distance threshold value Wth _k in the high concentration mode using the following formula.
Wth _k = Wth ₁ × pk (k=2, 3, 4)
The CPU 501 calculates the remaining life of the developing roller DP1 in the normal mode from the total post-correction developing roller travel distance _HTn and the normal mode traveling distance threshold value _Wth1 . Further, the CPU 501 calculates the remaining life of the developing roller DP2 in the high density mode from the total post-correction developing roller travel distance HT _n and the travel distance threshold value Wthk in the high density mode.
DP1 [%] = (1-HT _n /Wth ₁ ) x 100
DP2 [%] = (1-HT _n /Wth _k ) x 100 (k = 2, 3, 4)
For example, when the remaining life of the drum cartridge is 20%, the travel distance threshold Wth _k in the high density mode is 2700000 (Wth ₃ = 3000000 x 0.9), the remaining life of the developing roller DP1 in the normal mode and the high density mode, DP2 is as follows.
DP1 [%] = (1-HT _n /3000000) x 100
DP2 [%] = (1-HT _n /2700000) x 100
Further, the same applies to the developing roller remaining life DP1' in the normal mode and the developing roller remaining life DP2' in the high density mode explained with reference to FIG. 8, and the calculation method is the same as in the third embodiment.
As described above, by setting the developing roller life threshold correction coefficient in the high density mode according to the drum cartridge life, it is possible to perform life notification that matches the timing of occurrence of image defects. Therefore, it is possible to notify the lifespan of the developer cartridge 200 without causing image defects in each image forming mode.

1... Photosensitive drum, 4... Developing roller, 100... Image forming device, 300... Control unit, 501... CPU, m1... O memory, m2... DT memory

Claims (17)

a rotatable image carrier;
a developing device having a developer carrier that supplies developer to the image carrier and develops the electrostatic latent image on the image carrier;
a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier; and a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier. an image forming apparatus having a second mode in which the image forming apparatus rotates at a peripheral speed ratio of 2;
storage means for storing a first life threshold of the developing device corresponding to the first mode and a second life threshold of the developing device corresponding to the second mode;
The developing method is based on first drive amount information when the developer carrier operates in the first mode and second drive amount information when the developer carrier operates in the second mode. a control means for updating the lifespan judgment value by accumulating or cumulatively decrementing the driving amount information of the developer carrier from the initial value with respect to the lifespan judgment value of the device;
and a notification means;
The control means includes:
(i) A third lifespan threshold and the lifespan calculated based on the first lifespan threshold and the lifespan judgment value, or (ii) using the second lifespan threshold and information regarding the first lifespan threshold. making a first judgment regarding the lifespan of the first mode based on the judgment value;
(i) A fourth lifespan threshold and the lifespan calculated based on the second lifespan threshold and the lifespan judgment value, or (ii) using the first lifespan threshold and information regarding the second lifespan threshold. making a second judgment regarding the lifespan of the second mode based on the judgment value;
The notification means is
An image forming apparatus characterized in that a notification is made based on a determination result by the control means. The control means includes:
Comparing the lifespan judgment value with the first lifespan threshold, and determining whether the lifespan judgment value exceeds or falls below the first lifespan threshold;
The image forming apparatus according to claim 1, wherein the lifespan judgment value is compared with the second lifespan threshold to determine whether the lifespan judgment value exceeds or falls below the second lifespan threshold. further comprising a remaining amount acquisition unit that acquires the amount of developer contained in the developer container to be supplied to the developer carrier,
The control means determines that the developing device has reached the end of its life when the remaining amount of the developer is small even if the life judgment value does not exceed the first life threshold or the second life threshold. 3. The image forming apparatus according to claim 2, wherein the image forming apparatus determines that: a rotatable image carrier;
a developing device having a developer carrier that supplies developer to the image carrier and develops the electrostatic latent image on the image carrier;
a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier; and a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier. an image forming apparatus having a second mode in which the image forming apparatus rotates at a peripheral speed ratio of 2;
storage means for storing any one of a first life threshold of the developing device corresponding to the first mode and a second life threshold of the developing device corresponding to the second mode;
Lifespan determination based on first drive amount information when the developer carrier operates in the first mode and second drive amount information when the developer carrier operates in the second mode. a control means for calculating the value;
and a notification means;
The control means includes:
(i) A third lifespan threshold and the lifespan calculated based on the first lifespan threshold and the lifespan judgment value, or (ii) using the second lifespan threshold and information regarding the first lifespan threshold. Judgment value and
making a first judgment regarding the lifespan of the first mode based on;
(i) A fourth lifespan threshold and the lifespan calculated based on the second lifespan threshold and the lifespan judgment value, or (ii) using the first lifespan threshold and information regarding the second lifespan threshold. Judgment value and
make a second judgment regarding the lifespan of the second mode based on;
The notification means is
An image forming apparatus characterized in that a notification is made based on a determination result by the control means. The control means includes:
Comparing the lifespan judgment value with the first lifespan threshold or the third lifespan threshold, and determining whether the lifespan judgment value exceeds or falls below the first lifespan threshold or the third lifespan threshold;
The lifespan judgment value is compared with the second lifespan threshold or the fourth lifespan threshold, and it is determined whether the lifespan judgment value exceeds or falls below the second lifespan threshold or the fourth lifespan threshold. The image forming apparatus according to claim 4. further comprising a remaining amount acquisition unit that acquires the amount of developer contained in the developer container to be supplied to the developer carrier,
The control means is configured to control the remaining amount of the developer even if the life judgment value does not exceed the first life threshold, the second life threshold, the third life threshold, or the fourth life threshold. 6. The image forming apparatus according to claim 5, wherein the image forming apparatus determines that the developing device has reached the end of its lifespan if the amount of the developing device is low. The image forming apparatus according to any one of claims 1 to 6, wherein the control means continues to allow execution of the first mode after making a notification based on the determination result of the second determination. The storage means stores a first correction coefficient,
The control means reads out the first correction coefficient stored in the storage means and uses it for the first drive amount information and/or the second drive amount information, thereby controlling the same drive of the developer carrier. With respect to the amount, the magnitude of the cumulative or cumulative driving amount information based on the second driving amount information is made larger than the size of the cumulative or cumulative driving amount information based on the first driving amount information. The image forming apparatus according to any one of claims 1 to 7, wherein the judgment value is updated. The first correction coefficient includes at least one of a second correction coefficient according to information regarding the usage amount of the developing device and a third correction coefficient according to the rotational peripheral speed ratio of the image carrier and the developer carrier. 9. The image forming apparatus according to claim 8, further comprising: an image forming apparatus; The storage means stores a fourth correction coefficient according to the remaining life of the image carrier,
According to claim 8 or 9, the control means uses the first correction coefficient corrected by the fourth correction coefficient for the first drive amount information and/or the second drive amount information. The image forming apparatus described above. The second lifespan threshold is divided into a plurality of ranges depending on the remaining lifespan of the developer carrier,
The control means is characterized in that the control means makes a second judgment regarding the lifespan of the second mode based on the second lifespan threshold divided into the plurality of ranges and the lifespan judgment value. The image forming apparatus according to any one of Items 1 to 10. The storage means stores a fifth correction coefficient according to the remaining life of the image carrier,
12. The control means makes the second determination based on the second life threshold corrected by the fifth correction coefficient and the life judgment value. The image forming apparatus according to item 1. a rotatable image carrier;
a developing device having a developer carrier that supplies developer to the image carrier and develops the electrostatic latent image on the image carrier;
a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier; and a first mode in which the developer carrier rotates at a first peripheral speed ratio with respect to the image carrier. an image forming apparatus having a second mode in which the image forming apparatus rotates at a peripheral speed ratio of 2;
storage means for storing a lifespan threshold of the developing device;
The first drive amount information when the developer carrier operates in the first mode and the second drive amount information when the developer carrier operates in the second mode. control for calculating a first life judgment value corresponding to one mode, and calculating a second life judgment value corresponding to the second mode based on the first drive amount information and the second drive amount information; means and
and a notification means;
The control means includes:
causing the notification means to issue a notification regarding the lifespan of the developing device in the first mode based on a comparison between the lifespan threshold value and the first lifespan judgment value;
The image forming apparatus is characterized in that the notifying means is made to issue a notification regarding the lifespan of the developing device in the second mode based on a comparison between the lifespan threshold value and the second lifespan judgment value. The information regarding the first lifespan threshold is the developer carrier lifespan correction threshold coefficient of the first mode, and the second lifespan threshold is multiplied by the developer carrier lifespan correction threshold coefficient of the first mode. The image forming apparatus according to any one of claims 1 to 12, wherein the third life threshold is calculated by: . A claim characterized in that the developer carrier life correction threshold coefficient in the first mode is greater than 1.
15. The image forming apparatus according to item 14. The information regarding the second lifespan threshold is the developer carrier lifespan correction threshold coefficient of the second mode, and is obtained by multiplying the first lifespan threshold by the developer carrier lifespan correction threshold coefficient of the second mode. The image forming apparatus according to any one of claims 1 to 12, wherein the fourth life threshold is calculated by: . 17. The image forming apparatus according to claim 16, wherein the developer carrier life correction threshold coefficient in the second mode is smaller than 1.

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