JP2004184820A - Image forming apparatus and process cartridge - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus and a process cartridge that prevent waste toner from overflowing when toner particles on a transfer medium transport body or an intermediate transfer body are recovered into the waste-toner storage parts provided in a plurality of image forming means. <P>SOLUTION: Electrode antennas 14c and 14d are provided to measure an amount of waste toner present in each waste-toner storage part 14b. Also, electrode antennas 13e and 13f are provided to measure an amount of unused toner present in each development device 13 serving as an unused toner storage part. Based upon the measured amount of waste toner or the measured amount of waste toner and the measured amount of unused toner, a waste-toner amount control part 7 in the controller of the main body of the image forming apparatus determines and controls a ratio at which waste toner is recovered to each of the plurality of waste toner storage parts 14b. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electrophotographic image forming apparatus such as a copying machine, a printer, and a facsimile, and a process cartridge. More specifically, the present invention relates to a color image forming apparatus having a plurality of image forming means. And the control when storing the collected toner particles in the waste toner storage unit.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, dry-type electrophotographic image forming apparatuses such as copiers, printers, and facsimile machines have been known. However, due to recent colorization of office documents, those image forming apparatuses that form color images have increased. I have. In this specification, a “color image” means an image formed by overlapping two or more colors, for example, an image that forms an image with two colors of black and red, cyan, magenta, yellow, It refers to one that forms a full-color image using four colors of black.
2. Description of the Related Art In an electrophotographic color image forming apparatus, a toner image of each color is formed on an image carrier such as a photoreceptor and then transferred onto a recording paper or a transfer material such as an OHP by a direct transfer method or an intermediate transfer method. In many cases, a method of forming a color image is used. The “direct transfer method” is a transfer method in which a toner image on an image carrier is directly transferred to a transfer material carried on a transfer material carrier, and toner images of each color are superimposed on the transfer material. . On the other hand, the "intermediate transfer method" is a transfer method in which a toner image on an image carrier is once transferred to an intermediate transfer member, and the toner image on the intermediate transfer member is further transferred to a transfer material. It is superimposed on the transfer body.
[0003]
In either the direct transfer method or the intermediate transfer method, it is necessary to clean the transfer material transporting member or the intermediate transfer member in order to form a good image for a long time. The reason is as follows.
In the direct transfer method, since the toner image is directly transferred to the transfer material, there is no process for forming the toner image on the transfer material transport body during the formation of the output image. Seems unnecessary. However, immediately before or immediately after the image forming operation, toner particles may adhere to the transfer material transporting body from the image carrier while the transfer material is not being transported to the transfer material transporting body. Further, in an image forming apparatus in which a toner patch is formed on a transfer material conveyance body to perform color matching and density correction, a toner image is positively formed on the transfer material conveyance body even in a direct transfer method. If the toner particles on the transfer material transport member are not cleaned, the toner particles remaining on the transfer material transport member adhere to the back surface of the transfer material and stain the paper surface. In particular, in an image forming apparatus having a function of forming an image on both surfaces of one transfer material, toner particles remaining on the transfer material conveyance body during image formation on the second surface of the transfer material are transferred to the first surface of the transfer material. The image formed on the first surface is stained by the adhesion to the surface.
In the intermediate transfer method, after a toner image is formed on an intermediate transfer member, it is secondarily transferred to a transfer material. Here, if the secondary transfer rate is 100%, all the toner particles existing on the intermediate transfer body are transferred to the transfer material, so that cleaning of the intermediate transfer body becomes unnecessary. In practice, however, it is not easy to achieve a transfer rate of 100%, and some toner particles remain on the intermediate transfer member. Therefore, if this is left without cleaning, as in the case of the direct transfer method, the back surface of the transfer material and the first surface during double-sided image formation will be contaminated.
[0004]
Therefore, in both the direct transfer method and the intermediate transfer method, a process of cleaning toner particles on the transfer material transport body or the intermediate transfer body is required. When the particles are collected, a problem is how to treat the collected waste toner. If the collected waste toner continues to accumulate in the waste toner box, the toner may overflow from the waste toner box.
To prevent such problems, it is conceivable to reuse the toner or design a large waste toner box. However, since the toner collected from the transfer material conveyance body or the intermediate transfer body is mixed in color, the toner is recycled. However, increasing the size of the waste toner box leads to an increase in the size of the apparatus, which is not preferable from the viewpoint of space saving.
On the other hand, it is conceivable to detect that the waste toner box is full and replace it, but increasing the number of replacement parts in the first place undesirably complicates maintenance.
[0005]
As an image forming apparatus premised on maintenance by replacement, a “process cartridge type” in which at least one of a developing unit, a charging unit, a cleaning unit, and the like is integrated with an image bearing member and is to be replaced is well known. Has been. As a representative of the process cartridge, an image carrier, a developing unit, a charging unit, a cleaning unit (the charging unit and the developing unit may also have a cleaning function), and an “all” in which a predetermined amount of toner particles are all integrally formed. An "in-one cartridge" is known, but in addition to the above, a method in which two units, a drum unit including an image carrier and a unit including a developing unit and toner particles, are individually replaced may be considered. Which of the image forming elements is used as the exchange unit may be appropriately determined according to the life of each image forming element or the like.
Further, as an image forming apparatus on the premise of maintenance by replacement, in addition to the process cartridge system, a system in which a toner cartridge containing only toner particles is to be replaced alone can be considered. Hereinafter, a maintenance method for performing maintenance by replacing a cartridge such as a process cartridge or a toner cartridge is referred to as a “cartridge method”.
[0006]
In the cartridge system, it is burdensome for a user or a service person to maintain a device having many replacement targets. Therefore, it is not preferable to store the toner particles collected from the transfer material transporting body and the intermediate transfer body in a dedicated waste toner box and individually replace them.
Therefore, it is conceivable to collect the toner particles on the transfer material conveyance body or the intermediate transfer body once on the image carrier and store the toner particles in a cleaning unit for collecting the toner on the image carrier. By using this method, it is not necessary to use a waste toner box dedicated to the transfer material transporting body or the intermediate transfer body, so that it is possible to suppress an increase in replacement parts, and to suppress an increase in burden on a user or the like even in a cartridge type image forming apparatus. It becomes possible.
[0007]
However, when the toner particles on the transfer material conveyance body or the intermediate transfer body are collected by the cleaning means for the image carrier, unlike the case where such a cleaning means is used for collecting only the toner particles on the image carrier, There is a problem that it is difficult to predict the amount of waste toner to be collected. That is, when the cleaning means for the image carrier is used to collect only the toner particles on the image carrier, the standard transfer rate at which the toner particles migrate from the image carrier to the transfer material or the intermediate transfer member is used. It is possible to estimate the amount of waste toner based on the value of the toner. In addition, when toner particles on the transfer material conveyance body or the intermediate transfer body are collected by the cleaning means for the image carrier, the transfer It is difficult to predict at what ratio the toner particles on the material conveyance body and the intermediate transfer body are collected by each cleaning unit. Further, as described above, when a toner pattern is formed on a transfer material transporting body or an intermediate transfer body and collected in a waste toner box for an image carrier, the number of times the toner pattern is formed depends on how the toner is used. Because of the difference, it is more difficult to predict the amount of waste toner. For example, in an image forming apparatus in which a toner pattern is formed on a transfer material conveyance body or an intermediate transfer body every time the power is turned on and color matching is performed, the amount of waste toner varies depending on the number of times the power is turned on. In an image forming apparatus that performs color matching or the like by forming a color on a transfer material transporting body or an intermediate transfer body, the amount of waste toner varies depending on the frequency of occurrence of jam. As described above, the amount of waste toner generated can vary greatly depending on the control method of the device and the usage of the user.
[0008]
If the amount of the waste toner is too large, a problem may occur that the waste toner storage unit for storing the toner particles collected from the image bearing member becomes full and the waste toner particles overflow.
In order to prevent this, it is conceivable to make each waste toner storage unit large enough.However, the waste toner storage unit, which is a replacement part, becomes large and inconvenient for the user to handle, and from the viewpoint of environmental protection, Is also not preferred.
In Patent Document 1, in order to prevent the amount of waste toner from overflowing, a capacitor is formed by a developing sleeve in a developing unit and an antenna electrode in a process cartridge, and a capacitor is generated on the antenna electrode by an AC bias applied to the developing sleeve. A method has been proposed in which the capacitance of the capacitor is recognized using the current value to be measured, and the remaining amount of toner is grasped from the capacitance.
In Patent Document 2, a planar antenna having two conductor patterns that are not in contact with each other is provided on a side surface of a process cartridge, and the capacitance between the conductor patterns obtained by applying an AC bias between the two conductor patterns is provided. A method of replacing the value with the remaining amount of toner has been proposed.
[0009]
On the other hand, from the viewpoint of reducing replacement objects, an unused toner storage unit that stores unused toner particles for use in image formation and a waste toner storage unit are integrally configured and attached to and detached from the image forming apparatus main body. It is desirable to use a method in which the replacement of the unused toner storage unit and the waste toner storage unit can be performed only once by making it possible. However, in such a system, if a mismatch occurs between the unused toner particles in the unused toner storage unit and the amount of waste toner in the waste toner storage unit, the waste toner particles may remain even though the unused toner particles remain. In some cases, the toner particles are full and must be replaced, or conversely, the waste toner storage unit still has ample room, but the unused toner particles are consumed, so that replacement is required. In the former case, the cartridge must be replaced before the unused toner particles are consumed, which causes a loss to the user and increases the environmental load. In the latter case, an increase in the amount of waste toner stored in the other waste toner storage unit accelerates the replacement time of the other waste toner storage unit, and as a result, the cartridge in the cartridge including the other waste toner storage unit Unused toner particles are not consumed, causing loss to the user and increasing the environmental burden.
[0010]
[Patent Document 1]
Example 1 of JP-A-2001-222161
[Patent Document 2]
JP-A-2002-132029 [0041] to [0043] and FIG.
[0011]
[Problems to be solved by the invention]
In view of the above problems, a first object of the present invention is to perform control while detecting the amount of waste toner to collect toner particles on a transfer material transporting body or an intermediate transfer body in a waste toner storage unit. Another object of the present invention is to provide an image forming apparatus and a process cartridge in which waste toner is prevented from overflowing.
Further, a second object of the present invention is to provide an image forming apparatus and a process cartridge capable of performing appropriate and user- and environment-friendly maintenance by balancing the amount of waste toner and the amount of unused toner. It is.
[0012]
[Means for Solving the Problems]
According to an aspect of the present invention, there is provided an image forming apparatus including a transfer member and a plurality of image forming units disposed along a moving direction of the transfer member. The image unit includes at least an image carrier, a developing unit that develops a latent image on the image carrier as a toner image, an unused toner storage unit that stores toner particles to be used for development, and toner particles on the image carrier. A cleaning unit that collects the toner particles, and a waste toner storage unit that stores the toner particles collected by the cleaning unit. The cleaning unit collects the toner particles transferred from the transfer body to the image carrier. In the image forming apparatus performing cleaning of toner particles, the waste toner storage unit is a waste toner storage unit including a waste toner amount measuring unit that measures an amount of waste toner existing therein, Image forming apparatus is an image forming apparatus characterized by having a collecting ratio determining means for determining the ratio of the toner particles stored in each waste toner storage unit based on the measurement result of the waste toner amount measuring means.
In the image forming apparatus according to the first aspect, the amount of waste toner to be stored in each waste toner storage unit is determined while measuring the amount of waste toner, and the toner particles on the transfer material conveyance body or the intermediate transfer body are removed from the waste toner storage unit. Even when the waste toner is collected, the toner is prevented from overflowing from the waste toner storage unit.
Note that "measuring the amount of waste toner" includes not only measuring the absolute amount of waste toner, but also determining only whether the amount of waste toner is equal to or more than a predetermined value.
In addition, "determining a ratio" means not only determining a ratio when storing waste toner in each of a plurality of waste toner storage units, but also determining not storing waste toner in a specific waste toner storage unit at all. Or to determine to store waste toner only in a specific waste toner storage unit.
[0013]
Incidentally, the inventors of the present invention have studied diligently and found that when an electric force is applied to the charged toner particles to transfer the toner particles from the transfer body to the image bearing member, the `` measure waste toner amount The method of `` doing '' is not an indirect method of predicting waste toner based on the time when bias is applied to transfer toner from the transfer member to the image carrier, but the amount of stored waste toner is actually measured. I found that it was necessary to measure. The reason is as follows.
When the toner particles are transferred from the transfer body to the image carrier as in the present invention, the charge amount of the toner particles left on the transfer body for a certain period of time easily changes, and the transfer amount from the transfer body to the image carrier is changed. Even if a bias is applied, it is difficult to predict how much toner particles actually transfer to the image carrier. Further, the amount of the transferred toner particles also changes depending on the thickness of the toner layer on the transfer member and the temperature and humidity conditions. In order to solve such difficulties, a charging mechanism for forcibly charging the toner on the transfer member has been provided, but the amount of toner particles charged until the image carrier can be collected by a single forcible charging is provided. However, the improvement effect was not sufficient due to fluctuations in the toner layer thickness and the like, and it was also difficult to collect all the toner particles on the transfer member to the image carrier.
Therefore, when the toner particles are collected from the transfer body to the image carrier by an electric force, unlike the case where the physically collected toner particles are conveyed by a conveying mechanism by a rubbing force or the like, a bias is applied. A method of predicting the amount of waste toner based on indirect data such as time cannot accurately measure the amount of waste toner, and a method of measuring a capacitance by applying a voltage between electrodes in contact with waste toner, a method of storing waste toner, and the like. It has been found that it is necessary to actually measure the capacity of the waste toner, such as a method of measuring the amount of transmitted light of light incident on the device.
[0014]
According to a second aspect of the present invention, in the image forming apparatus according to the first aspect, the waste toner storage unit is configured integrally with an unused toner storage unit, and the unused toner storage unit is An unused toner amount measuring unit for measuring an amount of unused toner therein; and the collection ratio determining unit stores the waste toner based on a measurement result of the waste toner amount measuring unit and a measurement result of the unused toner amount measuring unit. The image forming apparatus is a collection determining unit that determines a ratio of toner particles stored in a unit.
In the image forming apparatus according to claim 2, the amount of waste toner to be stored in each waste toner storage unit is determined while measuring not only the amount of waste toner but also the amount of unused toner, and the amount of waste toner and the amount of unused toner are determined. Balance.
Here, "measuring the amount of unused toner" includes not only measuring the absolute amount of unused toner but also determining only whether or not the amount of unused toner is equal to or more than a predetermined value.
[0015]
According to a third aspect of the present invention, in the image forming apparatus according to the first or second aspect, the collection ratio determining unit includes a transfer unit that stores the waste toner in a waste toner storage unit in which the amount of waste toner is a predetermined value or more. An image forming apparatus is a collection ratio determining unit that determines a collection ratio so as not to collect toner particles.
In the image forming apparatus according to the third aspect, waste toner particles on the transfer member are prevented from being collected in a waste toner storage portion having no capacity for collecting toner particles on the transfer member, thereby preventing toner overflow. I do. Further, it is possible to avoid a situation in which the waste toner becomes full while the unused toner remains, and the replacement is forced.
According to a fourth aspect of the present invention, in the image forming apparatus according to the first or second aspect, the recovery ratio determination unit is configured integrally with an unused toner storage unit in which the amount of unused toner is equal to or less than a predetermined value. An image forming apparatus comprising: a collection ratio determination unit that determines a collection ratio so that toner particles on a transfer body are preferentially collected in the waste toner storage unit.
In the image forming apparatus according to the fourth aspect, the waste toner is preferentially stored in the waste toner storage unit integrally formed with the unused toner storage unit in which the remaining amount of the unused toner is smaller than a predetermined threshold value. Then, the waste toner is preferentially stored in the waste toner storage unit near replacement.
According to a fifth aspect of the present invention, in the image forming apparatus according to the first or second aspect, the collection ratio determination unit is configured to separate the waste toner storage unit and the waste toner storage unit that are integrally formed into waste toner storage units. The usage rate of the unused toner with respect to the accumulation rate of the waste toner is calculated, and the waste toner storage unit where the usage rate of the unused toner with respect to the accumulation rate of the waste toner is relatively large is to preferentially collect the toner particles on the transfer body. And a collection ratio determining unit for determining a collection ratio.
In the image forming apparatus according to the fifth aspect, the waste toner is preferentially stored in a waste toner storage unit in which the usage rate of the unused toner with respect to the accumulation rate of the waste toner is relatively large. Balance reduction with increased waste toner. In other words, according to the present invention, the unused toner storage unit and the waste toner storage unit, which are integrally formed, reach the replacement time when the unused toner is properly consumed and the waste toner is properly accumulated. It becomes. As a result, it is possible to prevent the waste toner from spilling over one waste toner storage unit in a concentrated manner, and to reduce the capacity of each waste toner storage unit, thereby contributing to a space-saving design.
[0016]
According to a sixth aspect of the present invention, in the image forming apparatus according to any one of the first to fifth aspects, the image forming apparatus is capable of forming a predetermined toner pattern on a transfer body, An image forming apparatus, comprising: means for detecting a toner pattern formed on the image forming apparatus.
In the image forming apparatus according to the sixth aspect, since a large amount of toner used for forming the toner pattern on the transfer body is stored in the waste toner storage unit, the invention according to the first to fifth aspects can be applied. Very effective.
[0017]
According to another aspect of the present invention, there is provided a process cartridge detachably mountable to an image forming apparatus main body including a transfer body, wherein the process cartridge includes an image forming unit, and a plurality of the process cartridges are arranged along a moving direction of the transfer body. A process cartridge provided, wherein the image forming means includes at least an image carrier, a developing means for developing a latent image on the image carrier as a toner image, and an unused toner for storing toner particles to be used for development. A storage unit, a cleaning unit that collects toner particles on the image carrier, and a waste toner storage unit that stores the toner particles collected by the cleaning unit, wherein the toner particles are transferred from the transfer body to the image carrier. A process cartridge for cleaning the toner particles on the transfer body by collecting the toner by a cleaning means. Waste toner amount measuring means for measuring the amount of waste toner present in the waste toner storage unit, and a collection ratio provided in the image forming apparatus main body for determining a ratio of toner particles stored in each waste toner storage unit A transmission unit for transmitting the measurement result of the waste toner amount measurement unit to the determination unit.
According to an eighth aspect of the present invention, in the process cartridge according to the seventh aspect, the waste toner storage unit is formed integrally with an unused toner storage unit, and the unused toner storage unit is provided inside the process cartridge. Unused toner amount measuring means for measuring the amount of unused toner, and the recovery ratio determining means, based on the measurement result of the waste toner amount measuring means and the measurement result of the unused toner amount measuring means, includes a waste toner storage unit. A process determining means for determining a ratio of toner particles to be stored in the process cartridge.
[0018]
According to a ninth aspect of the present invention, in the process cartridge according to the seventh or eighth aspect, the collection ratio determining means includes a toner storage unit where the amount of waste toner is equal to or more than a predetermined value. A process cartridge is a collection ratio determining means for determining a collection ratio so as not to collect particles.
According to a tenth aspect of the present invention, in the process cartridge according to the seventh or eighth aspect, the recovery ratio determination unit is configured integrally with an unused toner storage unit in which the amount of unused toner is equal to or less than a predetermined value. The process cartridge is a collection ratio determining unit that determines a collection ratio so that the toner particles on the transfer body are preferentially collected in the waste toner storage unit.
According to an eleventh aspect of the present invention, in the process cartridge according to the seventh or eighth aspect, the recovery ratio determination unit is configured to collect the waste toner for each of the integrally formed unused toner storage unit and the waste toner storage unit. The usage rate of the unused toner with respect to the accumulation rate is calculated, and the toner particles on the transfer body are preferentially collected in the waste toner storage unit where the usage rate of the unused toner with respect to the accumulation rate of the waste toner is relatively large. A process cartridge characterized by a collection ratio determining means for determining a collection ratio.
According to a twelfth aspect of the present invention, in the process cartridge according to any one of the seventh to eleventh aspects, the unused toner storage unit and the waste toner storage unit are configured to be detachable from an image forming unit. A process cartridge characterized by the above-mentioned.
The process cartridge according to any one of claims 7 to 12 employs a cartridge system to improve maintainability.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. In each drawing, the same parts are represented by the same symbols.
FIG. 1 is a schematic configuration diagram of an image forming apparatus to which the present invention can be applied. In the present embodiment, as an example, a transfer carrier is described as a transfer body, but the “transfer body” of the present invention includes both a transfer material carrier and an intermediate transfer body. Here, the “transfer material transport body” is a transfer body that transports a transfer material such as recording paper or OHP to an image carrier while carrying the same, and directly transfers the toner image on the image carrier to the transfer material. The “intermediate transfer member” is a transfer member that carries a toner image primarily transferred from an image carrier, moves the toner image to a contact portion with a transfer material, and secondary-transfers the toner image onto the transfer material. The shape of the transfer body is not limited as long as it functions as a transfer material transporting body or an intermediate transfer body, and may be a drum shape or a belt shape.
In a normal image forming operation, a transfer material such as a recording sheet supplied from the sheet feeding device 5 is attracted to the transfer material transport belt 2 as a transfer body by applying a predetermined voltage to the attraction roller 2a. Can be The transfer material moves together with the transfer material transport belt while being supported by the transfer material transport belt 2, and during the transfer, the toner images are transferred from the process cartridges 1K, 1M, 1C, and 1Y serving as image forming means. When the transfer material passes through the conveyor belt 2 and reaches the fixing device 3, the toner image on the transfer material is heated while being sandwiched between the heating roller 3a and the pressure roller 3b, thereby being fixed on the transfer material, and transferred. A visible image is formed on the material.
[0020]
In the mode for adjusting the color misregistration and the toner density of each color toner image, a toner image of a predetermined pattern is formed directly on the transfer material conveying belt 2 from the process cartridges 1K, 1M, 1C and 1Y, and the toner is applied by the P sensor 2b. The pattern is detected, the writing timing and the developing bias are changed based on the detection result, and the state is adjusted so that an optimal color image can be obtained. After that, the toner pattern on the transfer material transport belt 2 is collected by the process cartridges 1K, 1M, 1C, and 1Y, so that the transfer material transport belt 2 is cleaned. This cleaning operation will be described later.
Here, 1K, 1M, 1C, and 1Y are process cartridges for forming black, magenta, cyan, and yellow toner images, respectively. As shown in FIG. 2, such a process cartridge is detachable from a space opened when the transfer material transport belt 2 is retracted, and can be replaced by a user. At the time of image formation, the writing devices 4K, 4M, 4C, and 4Y irradiate the process cartridges 1K, 1M, 1C, and 1Y with writing light corresponding to black, magenta, cyan, and yellow image information, respectively. The process cartridge forms a toner image corresponding to the writing light and transfers the toner image to a transfer material.
[0021]
The transfer roller 2b opposed to the image carrier 11 via the transfer material conveying belt 2 has at least a cored bar and a conductive elastic layer covering the cored bar. The conductive elastic layer is formed by mixing and dispersing a conductivity-imparting agent such as carbon black, zinc oxide, tin oxide, or the like into an elastic material such as polyurethane rubber or ethylene-propylene-diene polyethylene (EPDM) to obtain an electric resistance value (volume resistivity). ) Is adjusted to a medium resistance of 106 to 1010 Ω · cm.
The writing devices 4K, 4M, 4C, and 4Y are devices for writing a latent image on the charged image carrier 11 in accordance with image information. Various devices such as an optical scanning device using a polygon and an LED array can be used.
[0022]
Next, the process cartridge of this embodiment will be described with reference to FIG. Since the process cartridges 1K, 1M, 1C and 1Y have the same structure, only one will be described.
The image carrier 11 is a negatively charged organic photoconductor, and is provided so as to be rotated in a direction indicated by an arrow, that is, in a counterclockwise direction by a rotation driving mechanism (not shown).
The cleaning device 14 has a cleaning blade 14a contacted by a counter in the rotation direction of the image carrier 11, and a waste toner storage unit 14b for storing the cleaned toner particles as waste toner.
Two electrode antennas 14c and 14d etched or printed on a printed circuit board are provided on one side surface of the waste toner storage unit 14b, and waste toner storage is performed by using a capacitance value between the electrode antennas 14c and 14d. It is configured to measure the amount of waste toner in the unit 14b. The principle of measuring the amount of waste toner by the electrode antennas 14c and 14d will be described later.
[0023]
The charging member 12 is a flexible charging roller in which a medium resistance layer 12b made of a urethane resin, carbon black as conductive particles, a sulfide agent, a foaming agent, etc., and a medium resistance layer 12b is formed on a cored bar 12a in a roller shape. It is. The material of the medium resistance layer 12b is not limited to the above, and may be formed of urethane, ethylene-propylene-diene polyethylene (EPDM), butadiene acrylonitrile rubber (NBR), silicone rubber, isoprene rubber, or the like for resistance adjustment. A rubber material in which a conductive substance such as black or metal oxide is dispersed, or a foamed material thereof can be used. In this embodiment, the contact charging method is employed, but a proximity charging method or another charging method may be used.
[0024]
The developing device 13 includes a developing roller 13a that is rotated clockwise and comes into contact with the image carrier 11, a supply roller 13b that coats the developing roller 13a with toner particles, and a toner roller that is coated on the developing roller 13a. It has an elastic blade 13c for negatively charging toner particles by friction while regulating the thickness, and a stirring member 13d for moving the toner particles in the process cartridge toward the supply roller while stirring. Further, in a state where the process cartridge 1 is mounted on the image forming apparatus main body, a DC bias can be applied to the developing roller 13a from a power source described later. Specifically, when the electrical contacts provided on the side surface of the process cartridge 1 and the electrical contacts on the image forming apparatus main body contact, a DC bias is applied to the developing roller 13a from the power supply on the apparatus main body side.
Further, toner particles (not shown) are stored in the developing device 13 which also serves as an unused toner storage unit. At the start of use of the process cartridge 1, toner particles enough to fill the supply roller 13b are stored, but the toner particles decrease as they are used. On one side surface of the developing device 13, two electrode antennas 13 e and 13 f etched or printed on a printed board are provided, and the value of the capacitance between the electrode antennas 13 e and 13 f is used to form the inside of the developing device 13. It is configured to measure the amount of unused toner. The principle of measuring the amount of unused toner by the electrode antennas 13e and 13f will be described later.
[0025]
Next, the operation of the process cartridge will be described.
The image forming apparatus of this example is an image forming apparatus that can function as a copier and a printer. When functioning as a copier, image information read from a scanner is subjected to various image processing such as A / D conversion, MTF correction, and gradation processing, and is converted into write data. When functioning as a printer, image information in a format such as a page description language or bitmap transferred from a computer or the like is subjected to image processing and converted into write data.
Prior to image formation, the image carrier 11 starts rotating in the direction of the arrow in FIG. 3, that is, in the counterclockwise direction so that the moving speed of the surface becomes a predetermined measure. Further, the charging roller 12 is rotated around the image carrier 11. At this time, a DC voltage of -1000 V is applied to the core of the charging roller 12 from a charging bias application power source, whereby the surface of the image carrier 11 is charged to about -400 V.
The writing device 4 (4C, 4M, 4Y, 4K) performs exposure on the charged image carrier 11 in accordance with the write data. That is, the potential of the image portion is changed by the light irradiation to generate a difference from the potential of the non-image portion not irradiated with the light, and an electrostatic latent image is formed by this potential contrast.
[0026]
The electrostatic latent image formed on the image carrier 11 by the writing device 4 is one-component developed by the developing device 13, and is visualized on the image carrier 11 as a toner image by attaching toner particles to an image portion. You. The developing device 13 of this embodiment forms a toner image on the image carrier 11 by a contact-type non-magnetic one-component developing method. Specifically, the developing roller 13a is rotated clockwise, and the supply roller 13b made of an elastic body that rotates clockwise is brought into contact with the developing roller 13a, so that the toner particles on the supply roller are coated on the developing roller 13a. . The toner particles coated on the developing roller 13a are negatively charged by friction with the elastic blade 13c while the thickness thereof is regulated by the elastic blade 13c, and are then conveyed to a portion facing the image carrier 11 as the developing roller 13a rotates. Let me do.
In the opposing portion between the developing roller 13a and the image carrier 11, a DC electric field is formed between the developing roller 13a and the image carrier 11 by applying a -300V DC bias from the power supply to the developing roller 13a. Then, the negatively charged toner particles are selectively adhered only to the image portion on the image carrier 11 by the DC electric field to form a toner image.
[0027]
The transfer material is conveyed from the paper feeder 5 at the same time that the toner image formed on the image carrier 11 reaches the transfer portion, which is the portion where the transfer roller 2 and the image carrier 11 face each other. The toner image on the carrier 11 is transferred to a transfer material by a voltage applied to the transfer roller 2. The transferred toner image is fixed on the transfer material by the fixing device 3, and an image is output.
On the other hand, the toner remaining on the image carrier 11 without being transferred (transfer residual toner) is cleaned by the cleaning device 14, and the surface of the image carrier 11 after cleaning is used for the next image formation.
[0028]
(Waste toner amount measurement)
Next, the developer amount measuring device 6 for sequentially measuring the amount of waste toner stored in the waste toner storage unit 14b will be described with reference to FIG. Hereinafter, the amount of developer measured by the developer measuring device 6 indicates the amount of waste toner.
As described above, the cleaning device 14 has the cleaning blade 14a that is brought into contact with the counter in the rotation direction of the image carrier 11, and the waste toner storage unit 14b that stores the cleaned toner particles as waste toner. Two electrode antennas 14c and 14d etched or printed on a printed circuit board are provided on one side surface of the waste toner storage unit 14b. The electrode antenna 14c in the present embodiment is electrically connected to the developing roller 13a, and is configured to have the same potential as the developing roller 13a.
[0029]
As shown in FIG. 4, the electrode antenna 14c can be considered to form a capacitor with the electrode antenna 14d. In the following, the capacitance of the capacitor composed of the electrode antenna 14c and the electrode antenna 14d is represented by C1. Write.
When a voltage V1 is applied to the developing roller 13a from the power supply 7 in the image forming apparatus main body, the electrode antenna 14c also has the same potential as the developing roller 13a. A charge is induced. The induced charge amount Q is proportional to the capacitance C1 if the potential difference V between the electrode antenna 14c and the electrode antenna 14d is constant (the relationship of Q = C1 × V). Here, the value of C1 varies depending on the dielectric constant of a substance between the electrode antenna 14c and the electrode antenna 14d, but exists in the waste toner storage unit 14b because the dielectric constant is different between the toner particles and air. The dielectric constant changes as the amount of waste toner increases. That is, the value of C1 has a correlation with the amount of waste toner.
Therefore, by detecting the charge amount Q induced in the electrode antenna 14d, the waste toner amount can be detected via the capacitance C1.
[0030]
Therefore, a mechanism for detecting the charge amount Q induced in the electrode antenna 14d will be described in detail.
As described above, in the image forming apparatus main body of the present example, the power supply 7 as the voltage applying unit for applying the voltage V1 to the developing roller 13a and the electrode antenna 14c exists. When V1 is applied, a predetermined voltage is generated across the capacitor C1, and a current I1 is generated. The current I1 is connected to the detection circuit 61 via a rectifier circuit, and the current Isearch, which is obtained by extracting only a portion having a positive value from I1, reaches the detection circuit 61.
On the other hand, V1 applied to the developing roller 13a is also simultaneously applied to the reference capacitor Cref. When V1 is applied, a predetermined voltage is generated at both ends of the reference capacitor Cref, and a current I2 is generated. The reference capacitor Cref is connected to the detection circuit 61 via a rectifier circuit. Iref, which is a current obtained by extracting only a portion having a negative value from I2, reaches the detection circuit 61. Here, the reference capacitor is provided to prevent the detection accuracy from deteriorating due to the development bias fluctuation.
The detection circuit 61 obtains the capacitance C1 from Isearch and Iref and converts this into a table to recognize the amount of waste toner. The conversion table is specific to each process cartridge 1 and the image forming apparatus, and is stored in the image forming apparatus main body at the time of shipment from the factory.
[0031]
Details of obtaining the capacitance C1 from Isearch and Iref will be described below. A method for applying an AC bias described in the related art (Patent Documents 1 and 2) will be described with reference to FIG. 5A, and a method for applying a DC direct current bias will be described with reference to FIG. I do. In this example, since the development is performed by applying a DC bias, a method described with reference to FIG. 5B is used in order to prevent cost increase by providing a dedicated power supply. Is an AC bias, it is preferable to use the method described with reference to FIG.
[0032]
In FIG. 5A, since an AC bias is applied as the voltage V1, V1 naturally becomes an AC wave. Since electric charge is induced in the capacitor when V1 changes, the current I1 takes a positive value when V1 rises and takes a negative value when V1 falls. Since only a portion of I1 having a positive value passes through the rectifier circuit, Isearch becomes as shown.
Here, assuming that the frequency of V1 as the AC bias is f [Hz] and the amplitude is Vp [V], the integral value Isearch (sum) of Isearch that reaches the detection circuit 61 per unit time is
Isearch (sum) = f × Vp × C1
It becomes. On the other hand, similarly, the integral value Iref (AV) of Iref reaching the detection circuit 61 per unit time is
Iref (sum) = − f × Vp × Cref
It becomes. Since Isearch + Iref arrives at the detection circuit 61, the integrated value per unit time is eventually obtained as follows.
Isearch (sum) + Iref (sum) = f × Vp × (C1−Cref) Equation (1)
Therefore, if the integrated value Isearch (sum) + Iref (sum) of the current reaching the detection circuit 61 per unit time is obtained, the value of C1 can be obtained from Expression (1). The value of Isearch (sum) + Iref (sum) or C1 is sent to the main body side control unit (a controller for controlling the operation of the entire image forming apparatus), and the amount of waste toner is obtained by table conversion. The obtained waste toner amount is displayed on the operation panel or sent to the host PC and displayed as a gauge on a bar graph.
[0033]
FIG. 5B illustrates a developer detection device 6 that determines C1 without applying an AC bias.
The control unit of the image forming apparatus according to the present embodiment includes a waste toner amount measurement mode for intermittently turning on / off the power supply 7 as a mode different from the normal developing bias application mode. This mode is executed at the time, when there is a user's instruction, when a predetermined time has elapsed since the last measurement, when a predetermined number of image forming operations have been performed, or when the power is turned on. When the waste toner amount measurement mode is executed, the power supply 7 is turned on / off in a short cycle, and as a result, a voltage V1 as shown in FIG. 5B is generated. Since electric charge is induced in the capacitor when V1 changes, the current I1 takes a positive value when V1 rises and takes a negative value when V1 falls. Since only a portion of I1 having a positive value passes through the rectifier circuit, Isearch becomes as shown.
Here, the frequency at which the power supply 7 is turned ON / OFF is fonoff [Hz], the voltage value at the time of ON is Vdc [V], and if the voltage can be reduced to a sufficiently low value when the power supply is turned off, the detection circuit 61 per unit time The integrated value of Isearch, Isearch (sum), is
Isearch (sum) = fonoff × Vdc × C1
It becomes. On the other hand, similarly, the integral value Iref (AV) of Iref reaching the detection circuit 61 per unit time is
Iref (sum) = − fooff × Vdc × Cref
It becomes. Since Isearch + Iref arrives at the detection circuit 61, the integrated value per unit time is eventually obtained as follows.
Isearch (sum) + Iref (sum) = fonoff × Vdc × (C1-Cref) Equation (2)
Therefore, as in the case of applying the AC bias, if the integrated value Isearch (sum) + Iref (sum) of the current reaching the detection circuit 61 per unit time is obtained, the value of C1 can be obtained from Expression (2). . The value of Isearch (sum) + Iref (sum) or C1 is sent to the main body side control unit, and the amount of waste toner is obtained by table conversion. The obtained waste toner amount is displayed on the operation panel or sent to the host PC and displayed as a gauge on a bar graph.
[0034]
Here, when the amount of waste toner is detected by intermittently turning ON / OFF the DC power, the amount of waste toner is detected during the image forming operation, unlike the case where the amount of waste toner is detected using AC power. There is a specific problem that an attempt to detect the amount causes a problem in image formation.
That is, when the amount of waste toner is detected using an AC power supply, Isearch (sum) + Iref (sum) can be easily obtained during image formation because the development bias itself changes the voltage value. Can be. However, when the amount of waste toner is detected using the DC power supply, there is a possibility that streaks on the image, toner adhesion, and the like may occur. The reason is described below.
[0035]
When a DC power supply is used, the rising performance of the voltage value varies depending on the product, but is generally several hundred [V / μsec] at present. For this reason, several [μsec] is required only for the rise and fall times of the voltage. On the other hand, in the measurement method described above, it is preferable to detect the current value as an integrated value from the viewpoint of the reliability and accuracy of current detection. However, since the current Isearch and Iref flow only at the time of rising and falling of the power supply, In order to obtain a large current value, it is necessary to turn on / off the power supply 7 as many times as possible per unit time. If a time of, for example, 2 [μsec] is required only for the rise and fall times, ON / OFF can be performed only 50,000 times per second at the maximum. The speed of current image forming apparatuses is increasing, and some image forming apparatuses move the surface of the image carrier 11 at a speed of 100 [mm / sec]. When the image forming apparatus is turned on / off 50,000 times per second, the developing bias is turned on / off at an interval of 2 [μm] in the image. Since this interval is about half of the number average particle diameter of the toner, the influence on each toner is large, and the development becomes unstable, and there is a possibility that stripe unevenness or the like may occur.
[0036]
Further, for example, when the image carrier 11 is a negatively charged photoreceptor, the image portion potential is not necessarily discharged to 0 [V], and a residual potential of -50 to -100 [V] may exist. When the DC power supply is turned off during the development, toner adheres to the non-image portion of the image carrier 11. Even when an AC bias is applied, there is a time during which a bias is generated to apply toner to the non-image area. However, in the case of the AC bias, the toner attached to the non-image area is developed due to a large voltage amplitude. It is easy to transfer to the developing roller 13a again on the downstream side of the nip. On the other hand, when the DC bias is intermittently applied, the electric field for returning the toner adhering to the non-image portion to the developing roller 13a is weaker than in the case of the AC bias, and the toner adhesion becomes serious.
For this reason, the waste toner amount measurement mode in which a DC bias is applied to the developing roller 13a in order to prevent the occurrence of streak unevenness on an image and to prevent toner from adhering to a non-image portion is different from the image forming operation. It is necessary to provide a mode or to devise a bias to be applied when measurement is performed during image formation.
[0037]
Therefore, in this embodiment, the waste toner amount measurement mode in which a DC bias is applied to the developing roller 13a is set to a mode different from the image forming operation, and the waste toner amount measurement is performed during non-image formation. For example, the amount of waste toner is measured when image formation is stopped, or the amount of waste toner for cyan, magenta, and yellow is measured during monochrome image formation. In this case, since the developing bias is applied during non-image formation, the toner is developed if the image carrier 11 is not charged, or the image is developed if the image carrier 11 is not rotating. Oscillation voltage may be continuously applied to one location on the carrier 11 to cause a hazard.
[0038]
Therefore, when measuring the amount of waste toner during non-image formation, one of the following items or an operation combining two or more of these items is performed.
(1) At the time of measuring the amount of waste toner, an electric field that does not transfer toner particles onto the image carrier 11 is formed by charging the image carrier 11 with the charging device 12 while rotating the image carrier 11.
(2) When measuring the amount of waste toner, the developing roller 13a is separated from the image carrier 11 so as to be in a non-contact state.
(3) At the time of measuring the amount of waste toner, the developing roller 13a and the image carrier 11 are brought into conduction, so that they have the same potential.
In the case of (1), when an intermittent DC bias is applied by the power supply 7, the controller for controlling the entire image forming apparatus rotates the image carrier 11 and activates the charging device 12 to operate the image forming apparatus. What is necessary is just to charge the surface of the support 11.
[0039]
FIG. 6 shows a case where (2) and (3) are performed simultaneously as an example of a case where (2) and (3) are performed.
6A, the cam member B rotates from the position shown by the dotted line to the position shown by the solid line when the remaining amount of the developer is measured. As a result, the process cartridge 1 rotates around the rotation center A. As a result, the developing roller 13a is separated from the image carrier 11. As shown in FIG. 6B, a contact C electrically connected to the base of the image carrier 11 and a conductor member D electrically connected to the developing roller 13a are provided on the side surface of the process cartridge 1. ing. The conductor member D is configured to be in contact with the electrical contact on the image forming apparatus main body side regardless of whether the developing roller 13a is in contact with or separated from the image carrier 11, and through the conductor member D A voltage is applied from the power supply 7 to the developing roller 13a.
[0040]
In such a configuration, when the developing roller 13a is not separated from the image carrier 11, the conductor member D and the contact C are not in contact with each other as shown in FIG. 6B. For this reason, a voltage is applied from the power supply 7 only to the developing roller 13a. On the other hand, when the developing roller 13a is separated from the image carrier 11, the conductor member D and the contact C come into contact as shown in FIG. 6C, and the image carrier 11 and the developing roller 13a have the same potential.
With such a configuration, the developing roller 13a and the image carrier 11 are separated from each other when the remaining amount of the developer is measured, so that the application of a bias to the developing roller 13a prevents the hazard and toner from adhering to the surface of the image carrier 11. it can. Furthermore, since the developing roller 13a and the image carrier 11 have the same potential when measuring the amount of waste toner, the toner does not fly from the developing roller 13a to the image carrier 11, and the toner is not unexpectedly transferred to the image carrier 11. The toner adhesion can be prevented.
In FIG. 6, the hazards to the image forming elements are effectively reduced by simultaneously performing the operations (2) and (3). There is a hazard reduction effect on the image element.
[0041]
The configuration for measuring the amount of waste toner in the case where the AC bias is used and the case where only the DC bias is used has been described above. However, the method for measuring the amount of waste toner used in the present invention is not limited to the method using the electrode antenna. Absent. For example, a bias is applied to an image forming element such as the developing roller 13a, the charging member 12, and the cleaning device 14 (in the case of electrostatic cleaning), and a charge induced on a metal plate opposed to the image forming element across waste toner. May be used to detect the capacitance. In addition, as the electrode antenna, the developing roller 13a or the like is used as one electrode antenna, and a metal piece extending in the longitudinal direction of the image carrier 11 is provided inside the developing device 13 or the like, and this is used as the other electrode antenna. A method (a method as in Patent Document 1) may be used.
Further, the present invention is not limited to the case where the measurement is performed by the capacitance. For example, the waste toner storage unit 14b is irradiated with light from the side, and the light is detected by the sensor on the opposite side. If the amount of light is small, it may be detected that the amount of waste toner is large.
Further, one waste toner amount measuring means in the present invention is provided for each image forming means, but when an electrode antenna or the like is used, all or a part thereof is integrally formed with the image forming means. Alternatively, in the case of the pixel count method or the light transmission method, the image forming means may be configured separately from the image forming means.
[0042]
(Unused toner amount measurement)
Next, a mechanism for measuring the amount of unused toner inside the developing device 13 will be described below.
As described above, two electrode antennas 13e and 13f etched or printed on a printed board are provided on one side surface of the developing device 13. The electrode antenna 13e in this example is electrically connected to the developing roller 13a, and is configured to have the same potential as the developing roller 13a.
In this embodiment, the principle of measuring the amount of unused toner inside the developing device 13 is exactly the same as the principle of measuring the amount of waste toner inside the cleaning device 14. FIG. 7 shows the relationship between the detection circuit 62 for measuring the amount of unused toner inside the developing device 13 and the electrode antennas 13e and 13f provided in the developing device 13. The electrode antenna 14c is connected to the electrode antenna 13e. If the antenna 14d is replaced with the electrode antenna 13f, the amount of unused toner can be measured in exactly the same manner as the mechanism for measuring the amount of waste toner in the cleaning device 14 described with reference to FIG.
At this time, since the potentials of the electrode antenna 14c and the electrode antenna 13e are the same, the detection circuits 61 and 62 may share the value of Iref. In that case, Iref flowing into each of the detection circuits 61 and 62 becomes unstable. Therefore, the detection circuits 61 and 62 do not directly detect Isearch (sum) + Iref (sum) as a current value, but output Isearch (sum) and Isearch (sum). It is preferable to first detect each value of Iref (sum) and to calculate Iserch (sum) + Iref (sum) by using this value.
[0043]
Further, in this example, the detection circuits 61 and 62 are provided for each color. However, from the viewpoint of reducing the number of circuits, only one detection circuit 61 and 62 is provided and 61C, 61M, 61Y, 61K and 62C are provided. , 62M, 62Y, and 62K, and the measurement of the amount of waste toner or the amount of unused toner for each color may be performed with a staggered measurement time. In this case, the measured value of the waste toner amount or the like is a measurement value with a time lag, but if the measurement target is properly switched, the waste toner amount control described below is hindered. There is no error.
[0044]
(Waste toner amount control)
Next, control of the amount of waste toner, which is a main part of the present invention, will be described.
The waste toner amount control is performed by a recovery ratio determining unit that determines the ratio of the toner particles stored in each waste toner storage unit 14b. The collection ratio determination unit is a waste toner amount control unit 7 that is provided in a controller provided in the image forming apparatus main body. In the cleaning mode of the transfer material transport belt 2, the waste toner amount control unit 7 has a function of determining which of the process cartridges collects the waste toner and controlling the transfer bias. Here, the execution of the cleaning mode of the transfer material conveying belt 2 is started by a command from the controller.
Periodic cleaning performed after a predetermined number of image forming operations since the end of the previous cleaning mode
A toner pattern removal cleaning that is always performed after a toner pattern is formed on the transfer material transport belt 2 and color misregistration and toner density adjustment are performed.
The cleaning is performed at the two timings.
[0045]
The specific configuration of the waste toner amount control unit 7 will be described below with reference to FIG.
The waste toner amount control unit 7 includes a C color waste toner amount acquisition unit 71c, an M color waste toner amount acquisition unit 71m, a Y color waste toner amount acquisition unit 71y, and a K color waste toner amount which respectively acquire the waste toner amounts of CMYK colors. An acquisition unit 71k, a C color unused toner amount acquisition unit 72c, an M color unused toner amount acquisition unit 72m, a Y color unused toner amount acquisition unit 72y that acquires the unused toner amounts of the respective CMYK colors, and a K color unused It comprises a toner amount acquisition unit 72k and an analysis unit 73. Here, the amount of waste toner of each color of CMYK is a value calculated by the main body side control unit based on the output from the detection circuits 61C, 61M, 61Y and 61K. The unused toner amount of each color of CMYK is a value calculated by the control unit on the main body side based on the output from the detection circuits 62C, 62M, 62Y, and 62K.
[0046]
The analysis unit 73 calculates the amount of waste toner to be stored in the process cartridge 1 of each color from the amount of waste toner and the amount of unused toner of each color of CMYK, and according to the calculation result, the toner particles on the transfer material transport belt 2 The transfer bias is controlled so as to be stored in. FIG. 9 shows a flowchart for executing the cleaning mode including this calculation algorithm.
In FIG. 9, when the cleaning mode of the transfer material conveying belt 2 starts (S701), the controller carries the developing roller 13a on each of the process cartridges 1C, 1M, 1Y, and 1K (hereinafter, abbreviated as "PC"). It is separated from the body 11 (S702). This separation has been described with reference to FIG. 6, but this prevents the toner from adhering to the image carrier 11 when the DC bias is intermittently applied, and the waste toner collected from the transfer material transport belt 2 removes the cleaning blade 14a. Even if it slips through, it is possible to prevent such toner from entering the developing device 13.
Next, the amount of waste toner in each of the process cartridges 1C, 1M, 1Y, and 1K is determined by obtaining a C color waste toner amount acquisition unit 71c, an M color waste toner amount acquisition unit 71m, a Y color waste toner amount acquisition unit 71y, and a K color waste toner amount. The unused toner amount of each color of CMYK is acquired by the unit 71k, the unused amount of C color toner acquisition unit 72c, the unused amount of M color toner acquisition unit 72m, the unused amount of Y color toner acquisition unit 72y, the unused toner of K color It is acquired by the quantity acquisition unit 72k and sent to the analysis unit 73 (S703).
[0047]
The analysis unit 73 obtains the number m of the process cartridges 1 in which the amount of waste toner is equal to or less than the predetermined value by comparing the amount of waste toner of each of the process cartridges 1C, 1M, 1Y, and 1K with a predetermined threshold value ( S704). This processing takes into consideration that waste toner overflows when the waste toner is stored in the process cartridge 1 in which the waste toner amount is equal to or more than a predetermined amount. Is a process based on the idea of not storing. Therefore, in the next step, it is determined whether or not the number m of the process cartridges 1 in which the waste toner amount is equal to or less than the predetermined value is zero (S705). If m = 0, the waste toner on the transfer material transport belt 2 is stored. Since the process cartridge 1 does not exist, an error message such as "Replace the process cartridge" is displayed (7S07), and the process ends (S708).
[0048]
On the other hand, if m is not 0 (S706), the number k of process cartridges 1 in which the amount of waste toner is equal to or less than a predetermined value and the amount of unused toner is equal to or less than a predetermined value is acquired. Specifically, the following processing is performed for each of the process cartridges 1C, 1M, 1Y, and 1K.
(1) The amount of waste toner is compared with a predetermined threshold value. If the amount of waste toner is equal to or smaller than the threshold value, the first flag is set to 1. If the amount of waste toner is greater than the threshold value, the first flag is set. One flag is set to 0.
(2) The unused toner amount is compared with a predetermined threshold value. If the unused toner amount is equal to or less than the threshold value, the second flag is set to 1; The flag is set to 0.
(3) The logical product of the first flag and the second flag is calculated, and if the result is 1, the waste toner amount of the process cartridge is equal to or smaller than the predetermined value and the unused toner amount is equal to or smaller than the predetermined value. Judge that there is.
The reason for performing the processing of S706 is as follows. That is, among the process cartridges 1 (= process cartridges having a waste toner amount of a predetermined value or less) capable of storing waste toner on the transfer material conveying belt 2, the process cartridges 1 having an unused toner amount of a predetermined value or less can be replaced. It is expected to be close. It is preferable to actively store the waste toner in the process cartridge 1 from the viewpoint of reducing the load on the other process cartridges 1.
[0049]
Accordingly, in S709, it is determined whether or not there is a process cartridge 1 in which the waste toner amount is equal to or less than the predetermined value and the unused toner amount is equal to or less than the predetermined value, and k = 0, that is, such a process cartridge 1 exists. If not, all the process cartridges 1 whose waste toner amount is equal to or less than the predetermined value are set as “waste toner storage target PCs” (S710). If k is not 0, the waste toner amount is equal to or less than the predetermined value. Only the process cartridge 1 whose unused toner amount is equal to or less than the predetermined value is set as a “waste toner storage target PC” (S711). Here, the “PC for storing waste toner” refers to the process cartridge 1 that collects the toner particles on the transfer material transport belt 2. In any case, the analysis unit 73 obtains the number n of all the “waste toner storage target PCs” and j that is an ID for specifying each “waste toner storage target PC”. In this example, a number is assigned to the process cartridge 1 as j. This number is a number that counts up from the upstream side to the downstream side in the moving direction of the transfer material transport belt 2 when the position where the suction roller 2a and the transfer material transport belt 2 are in contact with each other is the most upstream. For example, if the “PC for storing waste toner” is 1M and 1K, n = 2, and the ID of 1M is 1, and the ID of 1K is 2.
[0050]
Next, the toner particles on the transfer material transport belt 2 are evenly collected for each “waste toner storage target PC”. That is, in S712, the distance Xj (j = j) between the contact position between the suction roller 2a and the transfer material transport belt 2 and the contact position between the image carrier 11 and the transfer material transport belt 2 for each "PC for storing waste toner". 1 to n). In step S713, the image carrier 11 and the transfer material transport belt 2 are driven.
In S714, a bias is applied to the suction roller 2a prior to collecting the toner particles on the transfer material conveying belt 2. Although this bias is set to +700 V in this example, since the driven roller of the transfer material transport belt 2 facing the suction roller 2a is grounded, discharge may occur between the suction roller 2a and the transfer material transport belt 2. become. This discharge charges the toner particles on the transfer material transport belt 2. That is, from the viewpoint of toner charging, the bias applied to the attraction roller 2a only needs to be equal to or higher than the discharge starting voltage.
[0051]
In S715, j = 0 is set, and in S716, j is incremented.
Next, the analysis unit 73 issues a command to the controller to apply a voltage to the transfer rollers 2bc, 2bm, 2by, and 2bk facing the process cartridges 1C, 1M, 1Y, and 1K according to the algorithm shown in S717. In S715, Lbelt is the peripheral length of the transfer material transport belt 2, Vbelt is the peripheral speed of the transfer material transport belt 2, and T = Lbelt / Vbelt.
The time t = Xj / Vbelt is the time at which the contact between the suction roller 2a and the transfer material transport belt 2 at t = 0 reaches the contact between the j-th process cartridge and the transfer material transport belt 2. The time interval T / n is a time required for the j-th process cartridge to contact all of one partial area of the transfer material transport belt 2. Here, the partial area is one area when the transfer material conveying belt 2 is divided into n areas. Therefore, from time Xj / Vbelt to time T / n + Xj / Vbelt, all of one partial area starting from the contact point where the suction roller 2a and the transfer material conveying belt 2 are in contact with each other at t = 0 is j-th. Of the process cartridge.
[0052]
Therefore, at this time, a transfer bias for collecting toner particles from the transfer material conveying belt 2 is applied to the j-th process cartridge, and the process cartridges 1 other than the j-th process cartridge 1 have a polarity opposite to that of the j-th process cartridge 1. When the transfer bias is applied, the toner particles are exclusively collected from the transfer material conveying belt 2 to the j-th process cartridge 1 and are not collected to the other process cartridges 1. In this example, since the toner particles are positively charged by the suction roller 2a, "applying the transfer bias for collecting the toner particles from the transfer material conveying belt" means, specifically, the j-th process cartridge. This means that a positive voltage (+1000 V in this example) is applied to the transfer roller 2 opposite to the transfer roller 1. “To apply a transfer bias having a polarity opposite to that of the j-th process cartridge 1 to the process cartridges 1 other than the j-th process” means to apply a negative voltage (−300 V in this example) to the process cartridges 1 other than the j-th process cartridge 1. Means to do.
In S718, it is checked whether or not the processing shown in S717 has been performed on all the "PCs for storing waste toner". If Yes, the cleaning mode is ended. If No, the processing returns to S716 and repeats the processing. By performing the processing as described above, if the processing shown in S717 is performed on all the “waste toner storage target PCs”, the toner particles existing in the entire area on the transfer material conveying belt 2 will be collected.
[0053]
As described above, in this embodiment, the toner particles on the transfer material transport belt 2 are collected in the appropriate process cartridge 1 while detecting the amount of waste toner stored in each of the process cartridges 1C, 1M, 1Y, and 1K. It is possible to prevent waste toner from concentrating on a specific process cartridge 1 and overflowing the toner. Further, since the process cartridge 1 in which the amount of waste toner is equal to or more than the predetermined value is controlled so as not to collect the toner particles on the transfer material conveying belt 2, the waste toner is full even though the unused toner still exists. , The unused toner can be continued to be used without worrying that the waste toner overflows. Furthermore, the amount of unused toner in each of the process cartridges 1C, 1M, 1Y, and 1K is measured, and the process cartridge 1 having a small amount of unused toner is controlled so that waste toner is intensively stored. The waste toner can be intensively collected in the process cartridge 1, and the other process cartridges 1 can be protected from the problem that the replacement time is shortened due to the full waste toner.
Further, in this embodiment, the developing roller 13a is separated from the image carrier 11 when the transfer material conveying belt is in the cleaning mode, so that the toner particles on the image carrier 11 are transferred to the developing device 13 even if a cleaning failure occurs. Color mixing can be effectively prevented. Further, since the toner particles on the transfer material conveying belt 2 are charged by the suction roller prior to the execution of the cleaning mode, the cleaning efficiency can be improved.
[0054]
When m = 0 in S705, an error message may be displayed, or the cleaning mode may not be simply executed. That is, the “predetermined value” in S704 is a threshold value used to determine whether or not there is room in the waste toner storage unit for collecting the toner pattern on the transfer material conveying belt. Considering that the increased amount of waste toner is larger than the amount of transfer residual toner generated in normal image formation, this "predetermined value" is set to a limit value for determining whether the waste toner storage unit is full. May be distinguished. Therefore, even if the waste toner amount exceeds the “predetermined value” in S704 in all the process cartridges 1, the waste toner amount is set to the “limit value for determining whether or not the waste toner storage unit is full”. Until it exceeds, control can be performed so that normal image formation is continued and the cleaning mode is not executed.
By doing so, the execution of the color misregistration correction processing and the like is restricted, but there is an advantage that the process cartridge 1 can be used until the waste toner is full.
Needless to say, the present invention is also applicable to a color image forming apparatus using an intermediate transfer belt, a transfer drum, an intermediate transfer drum, and the like.
[0055]
[Embodiment 2]
The first embodiment measures the amount of unused toner and the amount of waste toner from the viewpoint of whether the amount of unused toner or waste toner is equal to or more than a predetermined threshold. This measures only the alternative relationship of whether the use of the process cartridge 1 is approaching the final stage.
However, in the measurement with the electrode antenna, what percentage was consumed when the initial stage of the unused toner amount was 100%, or what percentage was the current waste toner amount when the full state of the waste toner amount was 100%. It is possible to sequentially measure whether there is. Therefore, in the present embodiment, the usage rate of unused toner and the accumulation rate of waste toner are checked, and control is performed so that the usage rate of unused toner and the accumulation rate of waste toner are balanced. The details of the processing are shown below.
[0056]
The second embodiment is the same as the first embodiment except that the execution flowchart of the cleaning mode is different. Therefore, only the flowchart will be described with reference to FIG.
In FIG. 10, when the cleaning mode of the transfer material conveying belt 2 is started (S730), the controller separates the developing roller 13a from the image carrier 11 in each of the process cartridges 1C, 1M, 1Y, and 1K (S731).
Next, the amount of waste toner in each of the process cartridges 1C, 1M, 1Y, and 1K is determined by the C color waste toner amount acquisition unit 71c, the M color waste toner amount acquisition unit 71m, the Y color waste toner amount acquisition unit 71y, and the K color waste toner amount. The unused toner amount of each color of CMYK is acquired by the acquiring unit 71k, and the unused toner amount of each color of CMYK is acquired by the unused toner amount acquiring unit 72c of C color, the acquired amount of unused toner amount of M color 72m, the acquired amount of unused toner amount of Y color 72y, and the unused color of K color It is acquired by the toner amount acquiring unit 72k and sent to the analyzing unit 73 (S732).
[0057]
The analysis unit 73 obtains the number k of the process cartridges 1 whose unused toner amount is equal to or less than a predetermined value by comparing the waste toner amount of each of the process cartridges 1C, 1M, 1Y, and 1K with a predetermined threshold value. (S733). Specifically, the unused toner amount is compared with a predetermined threshold value for each process cartridge, and if the unused toner amount is equal to or less than the threshold value, the unused toner amount is determined to be equal to or less than the predetermined value. to decide.
The reason for performing the process of S733 is as follows. That is, among the process cartridges 1C, 1M, 1Y, and 1K, it is expected that the process cartridge 1 whose unused toner amount is equal to or less than the predetermined value is almost replaced. It is preferable to actively store the waste toner in the process cartridge 1 from the viewpoint of reducing the load on the other process cartridges 1.
[0058]
Therefore, in S734, it is determined whether there is any process cartridge 1 in which the unused toner amount is equal to or less than the predetermined value. If k = 0, that is, if no such process cartridge 1 exists, all the process cartridges 1 are set to “ If k is not 0, only the process cartridge 1 whose unused toner amount is equal to or less than a predetermined value is set as a "waste toner storage target PC" (S736). In any case, the analysis unit 73 obtains the number n of all the “waste toner storage target PCs” and j that is an ID for specifying each “waste toner storage target PC”.
In step S737, the distance Xj (j = 1 to n) between the contact position between the suction roller 2a and the transfer material transport belt 2 and the contact position between the photosensitive member and the transfer material transport belt 2 is determined for each “PC for storing waste toner”. ) To get.
[0059]
S738 is a characteristic part of this embodiment, which is a pair with S743, and acquires a value Uj for each “PC for storing waste toner”. Here, Uj means the following value U in the j-th process cartridge.
U = (use rate of unused toner−accumulation rate of waste toner + 100) / 2
The usage rate of the unused toner is a value indicating how much of the unused toner has been used up to now, when the unused toner in the initial state is 100%. For example, when 30% of the toner is consumed by image formation, the usage rate of unused toner is 30%.
If the initial unused toner amount is such that the electrode antennas 13e and 13f are completely filled, the decrease in the unused toner amount cannot be measured until a predetermined amount of toner particles are consumed. The usage rate of the used toner is kept at 0%.
The waste toner accumulation rate is a value indicating how many percent of the waste toner has been accumulated up to now, when the waste toner amount in a state where the waste toner is full (this value is predetermined) is 100%. It is. For example, in a process cartridge in which the state in which 100 g of waste toner is accumulated is defined as full, the state in which 40 g of waste toner is accumulated is a waste toner accumulation rate = 40%.
[0060]
Here, it is desirable that the usage rate of unused toner and the accumulation rate of waste toner be balanced. (Ideally, it is desirable that the usage rate of unused toner is 100% and the accumulation rate of waste toner is also 100% without waste of space. However, the amount of waste toner generated is determined by the number of times a toner pattern is formed. Therefore, it is generally considered that it is unlikely that the usage rate of unused toner becomes 100% and the accumulation rate of waste toner becomes 100% at the same time. Uj is used to control the balance between the usage rate of unused toner and the accumulation rate of waste toner.
After calculating Uj, the image carrier 11 and the transfer material transport belt 2 are driven in S739. In S740, a bias similar to that of the first embodiment is applied to the suction roller 2a before the toner particles on the transfer material conveying belt 2 are collected.
[0061]
In S741, j = 0 is set, and in S742, j is incremented.
Next, the analysis unit 73 issues a command to the controller to apply a voltage to the transfer rollers 2bc, 2bm, 2by, and 2bk facing the process cartridges 1C, 1M, 1Y, and 1K according to the algorithm shown in S743. That is, in t = Xj / Vbelt to T × Uj / SUM (Uj) + Xj / Vbelt, a transfer bias for collecting toner particles from the transfer material conveying belt 2 is applied to the jth process cartridge, and processes other than the jth process cartridge are applied. A transfer bias having a polarity opposite to that of the j-th process cartridge 1 is applied to the cartridge 1.
The time t = Xj / Vbelt is the time when the contact point where the suction roller 2a and the transfer material transport belt 2 are in contact at t = 0 reaches the contact point between the j-th process cartridge 1 and the transfer material transport belt 2. . The time interval T × Uj / SUM (Uj) is the time during which the j-th process cartridge 1 collects the toner particles on the transfer material conveying belt 2. Here, SUM (Uj) is the sum of Uj for n process cartridges 1. For example, when toner particles are collected in all four process cartridges 1C, 1M, 1Y, and 1K, SUM (Uj) = U1 + U2 + U3 + U4. Therefore, Uj / SUM (Uj) is the ratio of the j-th process cartridge 1 weighted by U.
[0062]
As described above, U = (use rate of unused toner−accumulation rate of waste toner + 100) / 2, and this value increases as the usage rate of unused toner increases and the accumulation rate of waste toner decreases. It is. In other words, the process cartridge 1 in which U has a larger value tends to consume unused toner but not accumulate waste toner. That is, the process cartridge 1 is a process cartridge 1 having a relatively high possibility that unused toner is consumed and replacement is performed, although there is enough room for storing waste toner. Therefore, it is desirable to store a larger amount of waste toner than other process cartridges 1. From this point of view, in S743, control is performed using the weighting of Uj / SUM (Uj) so that the time for collecting the toner particles in the process cartridge having a large value of Uj is relatively long.
In the present embodiment, by performing such processing, the usage rate of unused toner and the storage rate of waste toner can be balanced, and the amount of waste toner can be controlled more precisely.
The value of the transfer bias is the same as in the first embodiment.
[0063]
In S744, it is checked whether or not the processing shown in S743 has been executed on all the "PCs for storing waste toner". If Yes, the cleaning mode is ended. If No, the processing returns to S742 again to repeat the processing. By performing the processing in this way, if the processing shown in S743 is performed on all the “waste toner storage target PCs”, the toner particles existing in the entire area on the transfer material transport belt 2 will be collected.
Therefore, according to the present embodiment, the control is performed such that the balance between the amount of the unused toner and the amount of the waste toner is maintained, so that the control of the amount of the waste toner can be performed more precisely than in the first embodiment. Can be done.
[0064]
[Embodiment 3]
In the third embodiment, as compared with the second embodiment, toner particles are collected only in the process cartridge 1 having the maximum value of Uj from the process cartridges 1 weighted by Uj during the execution of the cleaning mode. That is, the third embodiment is the same as the second embodiment except that the execution flowchart of the cleaning mode is different. Therefore, only the flowchart will be described with reference to FIG.
11, when the cleaning mode of the transfer material conveying belt 2 starts (S760), the controller separates the developing roller 13a from the image carrier 11 in each of the process cartridges 1C, 1M, 1Y, and 1K (S761).
Next, the amount of waste toner in each of the process cartridges 1C, 1M, 1Y, and 1K is determined by the C color waste toner amount acquisition unit 71c, the M color waste toner amount acquisition unit 71m, the Y color waste toner amount acquisition unit 71y, and the K color waste toner amount. The unused toner amount of each color of CMYK is acquired by the acquiring unit 71k, and the unused toner amount of each color of CMYK is acquired by the unused toner amount acquiring unit 72c of C color, the acquired amount of unused toner amount of M color 72m, the acquired amount of unused toner amount of Y color 72y, and the unused color of K color. It is acquired by the toner amount acquiring unit 72k and sent to the analyzing unit 73 (S762).
[0065]
In S763, similarly to the second embodiment, Uj defined below is acquired.
U = (use rate of unused toner−accumulation rate of waste toner + 100) / 2
The definitions of the usage rate of unused toner and the accumulation rate of waste toner are the same as in the second embodiment.
In step S764, the process cartridge having the maximum value of Uj is set as the “waste toner storage target PC”, and the ID j is acquired. If there is more than one with the maximum value of Uj, one of them is selected. That is, in this example, only one process cartridge 1 collects the waste toner in the cleaning mode. Here, as a method of selecting any one when there are a plurality of values having the largest value of Uj, various methods such as setting priorities in color order in advance can be adopted.
[0066]
In S765, the contact position between the image carrier included in the "PC for waste toner storage" and the transfer material transport belt 2, the suction roller 2a, and the transfer material transport belt for only one selected "PC for waste toner storage" is selected. The distance Xj between the two points and the contact position with the two belts is obtained.
Thereafter, in step S766, the image carrier 11 and the transfer material transport belt 2 are driven. In S767, the same bias as in the first and second embodiments is applied to the attraction roller 2a before the toner particles on the transfer material transport belt 2 are collected.
[0067]
The analysis unit 73 issues a command to the controller to apply a voltage to the transfer rollers 2bc, 2bm, 2by, and 2bk facing the process cartridges 1C, 1M, 1Y, and 1K according to the algorithm shown in S768. That is, a transfer bias for collecting toner particles from the transfer material transport belt 2 is applied to the j-th process cartridge 1 which is a “waste toner storage target PC”, and the j-th process cartridge 1 is applied to process cartridges other than the j-th process cartridge 1. A transfer bias having a polarity opposite to that of 1 is applied. This bias is desirably applied for a period of time equal to or longer than one rotation of the transfer material conveying belt 2. The application time may be appropriately determined. For example, the application may be continued while the transfer material conveying belt 2 makes two rotations. The value of the transfer bias is the same as in the first embodiment.
[0068]
When the transfer bias is applied for a predetermined time in S768, the cleaning mode ends (S769).
In the present embodiment, by performing such processing, toner particles are collected only in the process cartridge 1 having the worst balance between the usage rate of unused toner and the storage rate of waste toner. As a result, the waste toner on the transfer material conveying belt 2 is stored only in the specific process cartridge 1, but the value Uj decreases in the specific process cartridge 1 as the toner particles are stored. Therefore, there is a high possibility that the process cartridge 1 having the largest Uj is switched at a certain point in time, and by repeating the switching, the waste toner is uniformly stored in each of the process cartridges 1C, 1M, 1Y, and 1K. .
Therefore, according to this embodiment, the amount of waste toner can be more precisely controlled by a simple algorithm.
[0069]
[Embodiment 4]
In the fourth embodiment, compared to the first to third embodiments, unused toner particles can be supplied from outside the developing device 13 and waste toner particles can be discharged to the outside of the cleaning device 14. What is possible is different.
Specifically, in the image forming apparatus of the present embodiment, as shown in FIG. 12, toner waste toner cartridges 102C, 102M, 102Y, and 102K respectively corresponding to the process cartridges 1C, 1M, 1Y, and 1K are provided in the image forming apparatus main body. It is provided to be removable. Here, the toner waste toner cartridge 102 is configured integrally with an unused toner storage unit for supplying unused toner to the developing device 13 and a waste toner storage unit for discharging waste toner from the cleaning device 14. Things.
As shown in FIG. 13, the structure of the process cartridges 1C, 1M, 1Y, and 1K is substantially the same as that of the first embodiment, except that a carry-in pipe 13x for carrying unused toner is provided on the side surface of the developing device 13. Another difference is that a discharge pipe 14x for discharging waste toner exists on the side surface of the cleaning device 14.
In the toner waste toner cartridge 102, an unused toner storage unit 1022 for storing unused toner particles and a waste toner storage unit 1021 for storing waste toner particles are integrally formed.
[0070]
Next, the connection between the process cartridge 1 and the waste toner cartridge 102 will be described.
First, when the process cartridge 1 or the toner waste toner cartridge 102 is mounted, as shown in FIG. 13A, both are inserted into positions slightly separated from each other, and then the toner waste toner cartridge 102 is directed toward the process cartridge 1 by the cam member 103. 13 (b). At this time, the carry-in pipe 13x enters while opening a valve made of rubber or the like provided in the unused toner storage unit 1022, and discharges a pipe while opening a valve made of rubber or the like provided in the waste toner storage unit 1021. When 14x enters, unused toner and waste toner can be moved.
When the process cartridge 1 or the toner waste toner cartridge 102 is removed, the cam member 103 rotates to shift from the state shown in FIG. 13B to the state shown in FIG. 13A, and the process cartridge 1 or the toner waste toner cartridge 102 can be removed. It becomes.
[0071]
With such a configuration, the toner waste toner cartridge 102 and the process cartridge 1 can be separately replaced, and the replacement of the toner waste toner cartridge 102 supplies unused toner particles and causes the waste toner particles to go out of the image forming apparatus. Can be discharged. Therefore, even when the life of the image forming element does not correspond to the storage limit of unused toner particles or the storage limit of waste toner particles, only one of them needs to be replaced, and the environmental load can be reduced. Further, by replacing the toner waste toner cartridge 102, supply of new toner and supply of waste toner can be performed only once, thereby improving the user appliance by reducing replacement parts. Further, in the present embodiment, since the toner particles on the transfer material transport belt 2 are also collected in the toner waste toner cartridge 102, the recovery of the waste toner on the transfer material transport belt 2 is achieved only by replacing the toner waste toner cartridge 102. Yes, good user appliance.
[0072]
Further, the toner waste toner cartridge 102 is provided with an electrode antenna 1022b for measuring the amount of unused toner and an electrode antenna 1021b for measuring the amount of waste toner. These electrode antennas 1022b and 1021b are connected to a dedicated power supply through contacts on the image forming apparatus main body side, and have the same capacitance as the electrode antennas 13e, 13f, 14c and 14d described in the first embodiment. The value is measured and converted to a toner amount.
As a method of controlling the amount of waste toner, the amount of waste toner is controlled in each of the toner waste toner cartridges 102C, 102M, 102Y, and 102K according to the flowchart described in any one of the first to third embodiments.
Therefore, in the present embodiment, while detecting the amount of waste toner stored in each of the toner waste toner cartridges 102C, 102M, 102Y, and 102K, the toner particles on the transfer material transport belt 2 are collected into an appropriate toner waste toner cartridge 102. Accordingly, it is possible to prevent the waste toner from being concentrated on the specific toner waste toner cartridge 102 and overflowing the toner. In addition, the same effects as those described in each embodiment can be obtained for the toner waste toner cartridge 102.
[0073]
[Modification 1]
As a first modification, in each embodiment, the measurement of the amount of unused toner may be performed by a pixel count method instead of using the electrode antenna.
In the pixel counting method, the number of pixels of an image formed is added and stored in a storage unit, and by referring to the added value, the amount of toner consumed up to the present time, and thus the usage rate of unused toner, is predicted. It is a method. Considering that there is an unexpected replacement of the toner cartridge, it is desirable to store the value of the pixel count in a memory integrated with each toner cartridge.
[0074]
[Modification 2]
As a second modification, in each embodiment, the measurement of the amount of unused toner or the amount of waste toner may be performed by a light transmission method instead of using the electrode antenna.
The light transmission method is a method in which light enters a light transmission path provided in a waste toner storage unit or an unused toner storage unit, and the amount of the developer is measured by detecting the transmitted light.
When it is detected only that the amount of unused toner or the amount of waste toner is equal to or more than a predetermined threshold value, it is only necessary to determine whether or not transmitted light is detected. On the other hand, when measuring the usage rate of unused toner and the accumulation rate of waste toner, light with a relatively large spot is incident to receive transmitted light, and the light receiving area is used to determine the usage rate of unused toner and the accumulation of waste toner. What is necessary is just to convert into a rate.
[0075]
【The invention's effect】
As described above, according to the present invention, since the toner particles on the transfer body are collected in an appropriate waste toner storage while detecting the amount of waste toner, the waste toner concentrates in a specific waste toner storage. An image forming apparatus and a cartridge in which toner is prevented from overflowing can be provided.
Further, by detecting the amount of unused toner and determining the collection ratio based on the amount of unused toner and the amount of waste toner, it is possible to provide an image forming apparatus and a cartridge that are friendly to the user and the environment.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram illustrating an example of an image forming apparatus to which the present invention can be applied.
FIG. 2 is a diagram illustrating a state in which a transfer material conveying belt is retracted and a process cartridge is attached and detached in FIG.
FIG. 3 is a schematic configuration diagram for explaining a process cartridge.
FIG. 4 is a block diagram for explaining a method for measuring the amount of waste toner.
FIGS. 5A and 5B are timing charts for explaining a method of detecting capacitance, showing (a) when an AC bias is applied, and (b) when a DC bias is applied.
FIGS. 6A and 6B are views showing the process cartridge when measuring the amount of waste toner, in which FIG. 6A is a side sectional view, FIG. 6B is an external view when the image carrier is in contact with the developing roller, and FIG. FIG. 4 is an external view when a body and a developing roller are separated from each other.
FIG. 7 is a block diagram for explaining a method of measuring an unused toner amount.
FIG. 8 is a diagram illustrating a configuration of a waste toner control unit.
FIG. 9 is a flowchart of a cleaning mode in the first embodiment.
FIG. 10 is a flowchart of a cleaning mode according to the second embodiment.
FIG. 11 is a flowchart of a cleaning mode in the third embodiment.
FIG. 12 is a schematic configuration diagram illustrating an image forming apparatus according to a fourth embodiment.
FIG. 13 is a schematic configuration diagram illustrating a process cartridge and a toner waste toner cartridge according to a fourth embodiment, where (a) is before mounting both cartridges and (b) is after mounting.
[Explanation of symbols]
1 Process cartridge
102 Toner waste toner cartridge
1021 Waste toner storage unit
1021b Electrode antenna
1022 unused toner storage unit
1022b Electrode antenna
103 cam member
2 Transfer material transfer belt
2a Suction roller
2b P sensor
3 Fixing device
3a Heat roller
3b Pressure roller
4 Writing device
5 Paper feeder
6 Developer amount measuring device
61, 62 detection circuit
63 power supply
7 Waste toner amount control unit
71 Waste Toner Acquisition Department
72 Unused toner acquisition unit
73 Analysis unit
11 Image carrier
12 Charging member
12a metal core
12b Medium resistance layer
13 Developing device
13a Development roller
13b supply roller
13c elastic blade
13d stirring member
13e, 13f Electrode antenna
13x Loading pipe
14 Cleaning device
14a Cleaning blade
14b Waste toner storage unit
14c, 14d electrode antenna
14x discharge pipe
A center of rotation
B Cam member
C contact
D Conductor member

Claims (12)

An image forming apparatus including a transfer body and a plurality of image forming units disposed along a moving direction of the transfer body,
Each of the plurality of image forming units includes at least an image carrier, a developing unit that develops a latent image on the image carrier as a toner image, an unused toner storage unit that stores toner particles to be used for development, A cleaning unit that collects the toner particles, and a waste toner storage unit that stores the toner particles collected by the cleaning unit,
In an image forming apparatus for cleaning toner particles on a transfer body by collecting toner particles transferred from a transfer body to an image carrier by a cleaning unit,
The waste toner storage unit is a waste toner storage unit including a waste toner amount measurement unit that measures the amount of waste toner present therein,
The image forming apparatus has a collection ratio determining unit that determines a ratio of toner particles stored in each waste toner storage unit based on a measurement result of the waste toner amount measuring unit. The image forming apparatus according to claim 1,
The waste toner storage unit is configured integrally with the unused toner storage unit, and the unused toner storage unit has an unused toner amount measurement unit that measures an internal unused toner amount,
The collection ratio determination unit is a collection determination unit that determines a ratio of toner particles stored in the waste toner storage unit based on a measurement result of the waste toner amount measurement unit and a measurement result of the unused toner amount measurement unit. Image forming apparatus. The image forming apparatus according to claim 1, wherein
The collection ratio determination unit is a collection ratio determination unit that determines a collection ratio so that toner particles on a transfer body are not collected in a waste toner storage unit in which the amount of waste toner is equal to or greater than a predetermined value. Image forming device. The image forming apparatus according to claim 1, wherein
The collection ratio determining unit may preferentially collect the toner particles on the transfer body in a waste toner storage unit configured integrally with the unused toner storage unit in which the amount of the unused toner is equal to or less than a predetermined value. An image forming apparatus, which is a collection ratio determining unit that determines a collection ratio. The image forming apparatus according to claim 1, wherein
The collection ratio determining means calculates, for each of the integrally formed unused toner storage unit and the waste toner storage unit, the usage ratio of the unused toner with respect to the accumulation ratio of the waste toner, and calculates the unused toner with respect to the accumulation ratio of the waste toner. An image forming apparatus comprising: a collection ratio determining unit that determines a collection ratio so that toner particles on a transfer body are preferentially collected in a waste toner storage unit having a relatively high usage rate. The image forming apparatus according to claim 1, wherein
The image forming apparatus is characterized in that the image forming apparatus is capable of forming a predetermined toner pattern on a transfer body, and has means for detecting a toner pattern formed on the transfer body. A process cartridge detachable from an image forming apparatus main body including a transfer body,
The process cartridge includes an image forming unit, and a plurality of the process cartridges are arranged along a moving direction of the transfer body.
The image forming unit includes at least an image carrier, a developing unit that develops a latent image on the image carrier as a toner image, an unused toner storage unit that stores toner particles to be used for development, and a toner on the image carrier. A cleaning unit that collects the particles, and a waste toner storage unit that stores the toner particles collected by the cleaning unit,
In a process cartridge for cleaning the toner particles on the transfer body by collecting the toner particles transferred from the transfer body to the image carrier by a cleaning unit,
The process cartridge includes a waste toner amount measuring unit that measures a waste toner amount existing inside the waste toner storage unit,
Transmitting means for transmitting the measurement result of the waste toner amount measuring means to collection ratio determining means provided in the image forming apparatus main body for determining the ratio of toner particles stored in each waste toner storing section. Characteristic process cartridge. The process cartridge according to claim 7, wherein
The waste toner storage unit is configured integrally with the unused toner storage unit, and the unused toner storage unit has an unused toner amount measurement unit that measures an internal unused toner amount,
The collection ratio determination unit is a collection determination unit that determines the ratio of toner particles stored in the waste toner storage unit based on the measurement result of the waste toner amount measurement unit and the measurement result of the unused toner amount measurement unit. And process cartridge. 9. The process cartridge according to claim 7, wherein the recovery ratio determination unit determines the recovery ratio so that the toner particles on the transfer body are not recovered in a waste toner storage unit having a waste toner amount equal to or more than a predetermined value. A process ratio determining means for determining a process cartridge. The process cartridge according to claim 7, wherein
The collection ratio determining unit may preferentially collect the toner particles on the transfer body to a waste toner storage unit configured integrally with the unused toner storage unit in which the amount of the unused toner is equal to or less than a predetermined value. A process cartridge characterized by a collection ratio determining means for determining a collection ratio. The process cartridge according to claim 7, wherein
The collection ratio determining means calculates, for each of the integrally formed unused toner storage unit and the waste toner storage unit, the usage ratio of the unused toner with respect to the accumulation ratio of the waste toner, and calculates the unused toner with respect to the accumulation ratio of the waste toner. A collection ratio determining means for determining a collection ratio so that toner particles on a transfer body are preferentially collected in a waste toner storage unit having a relatively high usage rate. The process cartridge according to any one of claims 7 to 11,
The process cartridge according to claim 1, wherein the unused toner storage unit and the waste toner storage unit are configured to be detachable from an image forming unit.

Images