This application is based upon and claims the benefit of priority from the corresponding Japanese Patent Applications No. 2018-188493 filed on Oct. 3, 2018 and No. 2018-230746 filed on Dec. 10, 2018, the entire contents of which are incorporated herein by reference.
The present disclosure relates to a developing device used in an image forming apparatus such as a copier, printer, facsimile machine, or the like. More particularly, the present disclosure relates to a method for suppressing clogging of a gap between a developing roller and a regulating blade with developer.
A conventionally common developing system adopted in image forming apparatuses using an electrophotographic process typically uses powdery developer and involves a process of visualizing an electrostatic latent image formed on an image carrier such as a photosensitive drum with the developer, then transferring the visualized image (toner image) to a recording medium, and then fixing the image.
Developer is broadly classified into two-component developer comprising toner and magnetic carrier and one-component developer comprising non-magnetic or magnetic toner alone. As a development system using magnetic one-component developer, what is called a jumping one-component development system is known in which a fixed magnet with a plurality of magnetic poles is arranged inside the developing roller to carry toner in a developer container onto the developing roller using a magnetic carrying force and then thin toner layer is formed by regulating the layer thickness using the regulating blade to let toner fly to a photosensitive drum at a developing position.
In the magnetic one-component development system, the sufficient magnetic force is required at the tip end of the regulating blade for ensuring stability of the toner layer on the developing roller and for improving performance of electrostatic charging of toner. Thus, there is a known technique in which the magnetic force at the tip end of the regulating blade is enhanced by attaching a blade magnet on the side face of the regulating blade. However, attaching the blade magnet makes the toner likely to agglomerate inside the developing device around the blade magnet and at the tip end of the blade. As a result, the toner layer on the developing roller is disturbed and this makes an image failure such as white streaks likely to occur.
To avoid this, there is a known method for suppressing toner agglomeration in which a developer carrier is rotated reversely within a predetermined range when a temperature sensing member for sensing the temperature of the regulating member senses a temperature higher than a predetermined value. There is also a known method for improving the degradation of image quality due to a decline in image density and fogging with a white portion by, according to the environment and status of use of the image forming apparatus, changing the arrangement angle of a magnetic field generation means with a plurality of magnetic poles arranged inside the developer carrier.
According to one aspect of the present disclosure, a developing device includes a housing, a developer carrier, a regulating blade, a magnetic member, and a blade magnet and develops an electrostatic latent image formed on an image carrier. The housing stores magnetic developer. The developer carrier is rotatably supported on the housing to carry developer on its outer circumferential face. The regulating blade is formed of a magnetic material and is arranged at a predetermined interval from the developer carrier. The regulating blade forms a regulating portion for regulating the layer thickness of the developer carried on the developer carrier. The magnetic member includes a shaft arranged inside the developer carrier and a plurality of magnetic poles including an S pole and an N pole fixed to an outer circumferential face of the shaft. The blade magnet is fixed to the regulating blade to induce a magnetic pole at the tip end of the regulating blade. The magnetic member is movable between a first position where a magnetic pole having the same polarity as that of a facing magnetic pole of the blade magnet facing the developer carrier is arranged at the regulating portion and a second position where a magnetic pole having a different polarity from the facing magnetic pole is arranged at the regulating portion. The developing device can perform a first developer eliminating mode in which the developer stagnating at the regulating portion is eliminated by, during non-image forming period, moving the magnetic member from the first position to the second position and rotating the developer carrier in a forward direction which is a rotation direction during image formation.
This and other objects of the present disclosure, and the specific benefits obtained according to the present disclosure, will become apparent from the description of embodiments which follows.
Hereinafter, with reference to the accompanying drawings, embodiments of the present disclosure will be described.
In the image forming portion 9, there are provided, along the rotation direction of the photosensitive drum 1 (in the clockwise direction), a charging device 2, an exposure unit 3, the developing device 4, a transfer roller 6, a cleaning device 7, and a static eliminator (unillustrated). The photosensitive drum 1 is, for example, an aluminum drum coated with a photosensitive layer, and its surface can be electrostatically charged uniformly by the charging device 2. As the surface is irradiated with a laser beam from the exposure unit 3, which will be described later, the electric charge is so attenuated as to form an electrostatic latent image. Although there is no particular restriction on the photosensitive layer mentioned above, an amorphous silicon (a-Si) photosensitive layer which excels in durability or the like are preferable.
The charging device 2 electrostatically charges the surface of the photosensitive drum 1 uniformly. Used as the charging portion 2 is, for example, a corona discharge device which causes electric discharge by application of a high voltage to a thin piece of wire acting as an electrode. Usable Instead of a corona discharge device is a contact-type charging device which applies a voltage while keeping the surface of the photosensitive drum 1 in contact with a charging member as exemplified by a charging roller. The exposure unit 3 irradiates the photosensitive drum 1 with a light beam (for example, a laser beam) based on image data, and thereby forms an electrostatic latent image on the surface of the photosensitive drum 1.
The developing device 4 forms a toner image by attaching toner to the electrostatic latent image on the photosensitive drum 1. In this embodiment, magnetic one-component developer (hereinafter referred to as toner) comprising magnetic toner is stored in the developing device 4. The developing device 4 will be described in detail later. The cleaning device 7 is provided with a cleaning roller, cleaning blade, or the like that makes line contact with the photosensitive drum 1 in its longitudinal direction (the direction perpendicular to the plane of
Toward the photosensitive drum 1, where the toner image has now been formed as described above, a sheet is conveyed to the image forming portion 9 with predetermined timing from a sheet storage portion 10 through a sheet conveying passage 11 via a registration roller pair 13. The transfer roller 6 conveys (transfers), without disturbing, the toner image formed on the surface of the photosensitive drum 1 to the sheet conveyed through the sheet conveying passage 11. Then, in preparation for the subsequent formation of a new electrostatic latent image, the cleaning device 7 removes the unused toner on the surface of the photosensitive drum 1, and the static eliminator removes the remaining electric charge.
The sheet having the toner image transferred to it is separated from the photosensitive drum 1, and is conveyed to a fixing device 8, where, under application of heat and pressure, the toner image is fixed to the sheet. The sheet having passed through the fixing device 8 passes between a discharge roller pair 14, and is discharged onto a sheet discharge portion 15.
The first stirring screw 23 and the second stirring screw 24 are each configured to have a helical blade around a supporting shaft (rotary shaft), and they are rotatably pivoted on the housing 20 parallel to each other. As shown in
By rotating according to the rotation of the photosensitive drum 1 (see
A regulating blade 29 is formed such that its width in the longitudinal direction (the left-right direction in
At the bottom face of the second storage chamber 22 which faces the second stirring screw 24, there is provided a toner amount detection sensor (unillustrated) that detects the amount of toner stored inside the housing 20. Based on the detection result from this toner amount detection sensor, toner stored in the toner container 5 (see
DS rollers 31a and 31b are rotatably fitted around the rotary shaft of the developing roller 25. The DS rollers 31a and 31b, by touching the opposite ends of the outer circumferential face of the photosensitive drum 1 in the axial direction, strictly regulate the distance between the developing roller 25 and the photosensitive drum 1. A bearing is incorporated in each of the DS rollers 31a and 31b, and by rotating by following the photosensitive drum 1, it can prevent the drum surface from wearing. At the opposite ends of the developing roller 25 in the axial direction, magnetic seal members 33a and 33b are arranged for preventing toner from leaking through the gap between the housing 20 and the developing roller 25.
As shown in
To one end of the shaft 27e, a drive input gear 37 is fixed. To the drive input gear 37, a magnet drive motor 43 (see
As shown back in
By this magnetic field, a magnetic brush comprising chains of toner particles is formed between the regulating blade 29 and the developing roller 25. While the magnetic brush passes the regulating portion 30, its layer thickness is restricted to a desired height. On the other hand, toner unused in the magnetic brush formation stagnates along the upstream-side (right-side) side face of the regulating blade 29. Then, when the developing roller 25 rotates in the counter-clockwise direction and the magnetic brush moves to a region (a developing region) facing the photosensitive drum 1, a magnetic field is applied by the N1 pole (main pole) 27b, and the magnetic brush touches the surface of the photosensitive drum 1 to develop an electrostatic latent image.
When the developing roller 25 rotates further in the counter-clockwise direction, a magnetic field in the direction along the outer circumferential face of the developing roller 25 is now applied by the S1 pole (conveyance pole) 27a, and the magnetic brush is, together with the toner unused in the toner image formation, collected onto the developing roller 25. Furthermore, at a hollow portion between the S1 pole 27a and the N2 pole 27d, the magnetic brush separates from the roller 25 and falls into the housing 20. Then, after being stirred and conveyed by the second stirring screw 24, the magnetic brush is again formed on the developing roller 25 by the magnetic field of the N2 pole (scooping pole) 27d.
In the housing 20 which covers the both ends of the developing roller 25, magnetic seal members 33a and 33b are arranged. In
A developing driving portion 40 includes the developing drive motor 41, a developing clutch 42, and the magnet drive motor 43. The developing drive motor 41 drives to rotate the first stirring screw 23, the second stirring screw 24, and the developing roller 25. The developing clutch 42 turns on and off the rotation driving force input from the developing drive motor 41 to the first stirring screw 23, the second stirring screw 24, and the developing roller 25. The magnet drive motor 43 rotates the shaft 27e and thereby rotates the fixed magnet 27 fixed to the shaft 27e through a predetermined angle.
The voltage control circuit 51 is connected to a charging voltage power supply 52, a developing voltage power supply 53, and a transferring voltage power supply 54, and makes those power supplies operate according to output signals from the control portion 90. According to control signals from the voltage control circuit 51, predetermined voltages are respectively applied from the charging voltage power supply 52 to the wire inside the charging device 2, from the developing voltage power supply 53 to the developing roller 25 inside the developing device 4, and from the transferring voltage power supply 54 to the transfer roller 6.
An image input portion 60 is a reception portion for receiving image data transmitted to the image forming apparatus 100 from a PC or the like. The image signal input via the image input portion 60 is converted to a digital signal and is then transmitted to a temporary storage portion 94.
An inner temperature/humidity sensor 61 is for sensing the temperature and the humidity inside the image forming apparatus 100, especially around the developing device 4, and is arranged near the image forming portion 9.
An operation portion 70 has a liquid crystal display portion 71 and LEDs 72 that show different statuses, and is configured to display the status of the image forming apparatus 100, the status of image formation, the number of copies printed, and so on. Various settings of the image forming apparatus 100 are made via a printer driver on a PC.
The control portion 90 is provided at least with a CPU (central processing unit) 91, a ROM (read-only memory) 92 that is a read-only storage portion, a RAM (random access memory) 93 that is a readable-writable storage portion, the temporary storage portion 94 that temporarily stores image data and the like, a counter 95, a timer 97, a plurality of (here, two) I/Fs (interfaces) 96 which transmits control signals to different devices in the image forming apparatus 100 and receives input signals from the operation portion 70.
The ROM 92 stores data and the like that are not changed during the use of the image forming apparatus 100, such as control programs for the image forming apparatus 100 and numerical values needed for control. The RAM 93 stores necessary data generated during the control of the image forming apparatus 100, data temporarily needed to control the image forming apparatus 100, and the like. What is stored in the RAM 93 (or the ROM 92) includes a table (see Table 1) which defines the relationship of the cumulative drive time T of the developing device 4 counted by the timer 97 described later with the level of agglomeration at the regulating portion 30 (see
The temporary storage portion 94 temporarily stores an image signal that is input, after being converted to a digital signal, from an image input portion 60 which receives image data transmitted from a PC and the like. The counter 95 counts the number of printed sheets in a cumulative manner. The timer 97 separately counts the cumulative drive time Tsum (a first drive time) after the start of use of the developing device 4 and the cumulative drive time T (a second drive time) after the latest execution of the developer eliminating mode.
The control portion 90 transmits control signals to different parts and devices in the image forming apparatus 100 from the CPU 91 through the I/F 96. From the different parts and devices, signals that indicate their statuses and input signals are transmitted through the I/F 96 to the CPU 91. The different parts and devices controlled by the control portion 90 include, for example, the fixing device 8, the image forming portion 9, a developing driving portion 40, a voltage control circuit 51, an image input portion 60, and an operation portion 70.
As described previously, when continuous printing is performed in a high-temperature environment using a low melt toner as a magnetic one-component developer, the toner stagnating at the regulating portion 30 of the developing device 4 softens to cause blocking and clogging. As a solution, in this embodiment, a first developer eliminating mode can be performed during non-image forming period to eliminate the toner (developer) which stagnates at the regulating portion 30. Hereinafter, the first developer eliminating mode will be described in detail.
When a printing instruction is input from a host device such as a PC and printing is started (step S1), the control portion 90 (see
When the number of printed sheets has reached the predetermined number (Yes in Step 3), sheet feeding from the sheet storage portion 10 is stopped according to a control signal from the control portion 90 (step S4). Application of a developing bias from the developing voltage power supply 53 (see
Then, a control signal is transmitted from the control portion 90 to the magnet drive motor 43 (see
Then, the fixed magnet 27 is rotated in the reverse direction (clockwise direction in
According to the control shown in
Especially, when a low melt toner with a glass transition point (Tg) of 55° C. or lower is used in a developing system where the developing roller 25 has a line speed (processing speed) of 500 mm/sec or higher, even when continuous printing in a high-temperature environment is repeated, no toner agglomerate G stagnates at the regulating portion 30, suppressing blocking with toner due to heat and mechanical stress. It is thus possible to effectively prevent clogging with toner at the regulating portion 30 and the resulting image failure such as white streaks and vertical gray streaks.
In the example of control in
When the N1 pole 27b approaches the regulating portion 30 from the reverse direction (the left direction in
When the fixed magnet 27 rotates further in the reverse direction from the state in
Furthermore, how frequently the first developer eliminating mode is performed may be changed according to the detection result from the inner temperature/humidity sensor 61. Specifically, by performing the first developer eliminating mode more frequently (shortening the interval) as the inner temperature becomes higher, it is possible to suppress agglomeration of toner and to prevent image failure effectively.
Instead of the inner temperature/humidity sensor 61, an outer temperature sensor for sensing the temperature outside the image forming apparatus 100 (the outer temperature) may be provided and the frequency of performing the first developer eliminating mode may be changed according to the temperature outside the device sensed by the outer temperature sensor.
In this embodiment, the N1 pole 27b or the N2 pole 27d of the fixed magnet 27 is moved to a position facing the regulating blade 29 (step S7), and the developing clutch 42 (see
According to this embodiment, by arranging the S2 pole 27c having the same polarity as the blade magnet 35 (a polarity different from that induced at the tip end of the regulating blade 29) at a position facing the regulating blade 29, as shown in
In this way, by performing the second developer eliminating mode subsequently to the first developer eliminating mode, the toner agglomerate G attached to the tip end of the regulating blade 29 and the toner agglomerate G attached to the tip end of the blade magnet 35 can both be eliminated effectively.
While the first developer eliminating mode is performed, as shown in
Here, the S2 pole 27c approaches the facing magnetic pole 35a (S pole) of the blade magnet 35 from inside the developing device 4, a repulsive magnetic field pointing outward of the developing device 4 is generated between the facing magnetic pole 35a and the S2 pole 27c. With this, the toner agglomerate G attached to the tip end of the blade magnet 35 is swung outward of the developing device 4 (toward the left direction in
As in the first embodiment, it is possible to change the frequency of performing the first and second developer eliminating modes according to the detection result from the inner temperature/humidity sensor 61.
Next, a third embodiment of the present disclosure will be described.
Thus, in this embodiment, the timing of performing the first developer eliminating mode is determined based on the developing drive time T. Specifically, based on the developing drive time T, whether the level of agglomeration has reached a first level (here, level 2) or not is checked, and when it reaches the first level, the first developer eliminating mode is performed.
Here, with consideration given to temperature dependency of the agglomeration coefficient, the developing drive time T at each different temperature is converted into the drive time Tst at a reference temperature S.
Tst=T×(a_N/a_S) (1)
where
a_S is the agglomeration coefficient at the reference temperature S, and
a_N is the agglomeration coefficient at the temperature N.
Incidentally, as toner in the developing device 4 degrades, the level of agglomeration becomes higher, and thus it is preferable to determine the frequency of performing the first developer eliminating mode with consideration given to the degree of toner degradation. Thus, in this embodiment, with consideration given to the degree of toner degradation, the calculated drive time Tcal is calculated according to the following formula (2).
Tcal=T×(a_N/a_S)×α (2)
where
α is the toner degradation coefficient.
The toner degradation coefficient α is determined according to the printing rate and the cumulative drive time Tsum (first drive time) of the developing device 4. In general, the lower the printing rate and the longer the cumulative drive time Tsum, the higher the degree of toner degradation.
Based on
Similarly, when the printing rate is 1% or lower and the cumulative drive time Tsum is 117 mins or longer, or when the printing rate is higher than 1% and lower than or equal to 3.8% and the cumulative drive time Tsum is 200 mins or longer, or when the printing rate is higher than 3.8% or lower than or equal to 5% and the cumulative drive time Tsum is 400 mins or longer (the level of toner degradation is 30 or higher), the degree of toner degradation is evaluated as 2 and, as shown in Table 1, the toner degradation coefficient α is set at 2. When the printing rate is 1% or lower and the cumulative drive time Tsum is 183 mins or longer, or when the printing rate is 3.8% or lower and the cumulative drive time Tsum is 1283 mins or longer (the level of toner degradation is 45 or higher), the degree of toner degradation is evaluated as 3 and, as shown in Table 1, the toner degradation coefficient α is set at 5.
When the printing rate is higher than 3.8% but lower than or equal to 5% (between the dotted line and the broken line in
When a printing instruction is input from a host device such as a PC and printing is started (step S1), the control portion 90 (see
When printing has ended (Yes in Step S2), the developing drive time T counted by the timer 97 is sensed (step S3). Also, by the inner temperature/humidity sensor 61 (see
Also, using formula (1), the developing drive time T is converted into the drive time Tst at the reference temperature S (35° C.) (step S6). Furthermore, based on the printing rate and the cumulative drive time Tsum of the developing device 4, the toner degradation coefficient α is determined (step S7), and the calculated drive time Tcal is calculated using formula (2) (step S8).
The control portion 90 checks whether the calculated drive time Tcal is less than a threshold value (here, 240 mins) or not (step S9). When the calculated drive time Tcal is less than 240 mins (Yes in step S9), the procedure returns to step S1 and printing is restarted. When the calculated drive time Tcal is equal to or more than 240 mins (No is step S9), the N2 pole 27d is moved to a position facing the regulating blade 29 (step S10) and the developing roller 25 is rotated in the forward direction (in the counter-clockwise direction in
According to the control shown in
As in the second embodiment, it is possible to perform the second developer eliminating mode subsequently to the first developer eliminating mode. After the level of agglomeration reaches the second level (here, level 3) which is higher than the first level (level 2), when the developing device 4 operates for a given period, at least one of an indication of the life of the developing device 4 or one requesting the replacement of the developing device 4 is displayed on the liquid crystal display portion 71. This prevents the developing device 4 from being used with toner degraded for a long time, and thus makes it possible to prevent clogging with toner at the regulating portion 30 and vertical streaks in images resulting from degraded toner.
Provided on the top face of the magnet supporting stay 36 are a shaft 36a penetrating the top face of the regulating blade 29 and a pressed face 36b fixed to the top end of the shaft 36a and having a larger diameter than the shaft 36a (see
Over the regulating blade 29, an eccentric cam 39 is arranged. When the eccentric cam 39 rotates while in contact with the pressed face 36b, the pressing force of the eccentric cam 39 and the biasing force of the coil spring 38 vertically move the blade magnet 35 along with the magnet supporting stay 36. The eccentric cam 39 is coupled to a blade magnet moving motor 44. The shaft 36a, the pressed face 36b, the coil spring 38, and the eccentric cam 39 are provided at least at each end of the regulating blade 29 in its longitudinal direction (the direction perpendicular to the plane in
The blade magnet 35 is, during image formation, arranged at a reference position (position in
When a printing instruction is input from a host device such as a PC and printing is started (step S1), the control portion 90 (see
When the number of printed sheets has reached the predetermined number (Yes in Step S3), sheet feeding from the sheet storage portion 10 is stopped according to a control signal from the control portion 90 (step S4). Application of a developing bias from the developing voltage power supply 53 (see
Then, a control signal is transmitted from the control portion 90 to the magnet drive motor 43 (see
With this, as shown in
Next, the fixed magnet 27 is rotated from the state in
By arranging the S2 pole 27c having the same polarity as the facing magnetic pole 35a of the blade magnet 35 (a polarity different from that induced at the tip end of the regulating blade 29) at a position facing the regulating blade 29, as shown in
Here, the blade magnet 35 is arranged at the projecting position where the tip-end edge of the facing magnetic pole 35a projects outward of the tip end of the regulating blade 29. Thus, the toner agglomerate G stagnating in a stepped part between the regulating blade 29 and the blade magnet 35 is pushed out to the developing roller 25 side, and this makes it easier to eliminate by the developing roller 25 in reverse rotation the pushed-out toner agglomerate G.
Then, a control signal is transmitted from the control portion 90 to the blade magnet moving motor 44, and the eccentric cam 39 is rotated so that the small-diameter portion of the eccentric cam 39 makes contact with the pressed face 36b. This makes the blade magnet 35 move to the reference position (see
According to the control shown in
In particular, when a low melt toner with a glass transition point (Tg) of 55° C. or lower is used in a developing system where the developing roller 25 has a line speed (processing speed) of 500 mm/sec or higher, even when continuous printing in a high-temperature environment is repeated, no toner agglomerate G stagnates at the regulating portion 30, thus suppressing blocking with toner due to heat and mechanical stress. It is thus possible to effectively prevent clogging with toner at the regulating portion 30 and the resulting image failure such as white streaks and vertical gray streaks.
By performing the second developer eliminating mode subsequently to the first developer eliminating mode, the toner agglomerate G attached to the tip end of the regulating blade 29 and the toner agglomerate G attached to the tip end of the blade magnet 35 can both be eliminated effectively. Furthermore, when the second developer eliminating mode is performed, by moving the blade magnet 35 from the reference position to the projecting position, the toner agglomerate G stagnating in a stepped part between the regulating blade 29 and the blade magnet 35 is pushed out by the blade magnet 35, and thus the toner agglomerate G can be eliminated effectively.
In the example of control in
When the N1 pole 27b approaches the regulating portion 30 from the reverse direction (the left direction in
When the fixed magnet 27 rotates further in the reverse direction from the state in
While the first developer eliminating mode is performed, as shown in
Here, the S2 pole 27c approaches the facing magnetic pole 35a (S pole) of the blade magnet 35 from inside the developing device 4, and thus a repulsive magnetic field pointing outward of the developing device 4 is generated between the facing magnetic pole 35a and the S2 pole 27c. With this, the toner agglomerate G attached to the tip end of the blade magnet 35 is swung outward of the developing device 4 (toward the left direction in
Furthermore, how frequently the first developer eliminating mode is performed may be changed according to the detection result from the inner temperature/humidity sensor 61. Specifically, by performing the first developer eliminating mode more frequently (shortening the interval) as the inner temperature becomes higher, it is possible to suppress agglomeration of toner and to prevent image failure effectively.
Instead of the inner temperature/humidity sensor 61, an outer temperature sensor for sensing the temperature outside the image forming apparatus 100 (the outer temperature) may be provided and the frequency of performing the first developer eliminating mode may be changed according to the temperature outside the device sensed by the outer temperature sensor.
Next, a fifth embodiment of the present disclosure will be described. In the fifth embodiment, the timing of performing the first developer eliminating mode is determined based on the developing drive time T. Specifically, in a similar manner as in the third embodiment shown in
When a printing instruction is input from a host device such as a PC and printing is started (step S1), the control portion 90 (see
When printing has ended (Yes in Step S2), the developing drive time T counted by the timer 97 is sensed (step S3). Also, by the inner temperature/humidity sensor 61 (see
Also, using formula (1), the developing drive time T is converted into the drive time Tst at the reference temperature S (35° C.) (step S6). Furthermore, based on the printing rate and the cumulative drive time Tsum of the developing device 4, the toner degradation coefficient α is determined (step S7), and the calculated drive time Tcal is calculated using formula (2) (step S8).
The control portion 90 checks whether the calculated drive time Tcal is less than a threshold value (here, 240 mins) or not (step S9). When the calculated drive time Tcal is less than 240 mins (Yes in step S9), the procedure returns to step S1 and printing is restarted. When the calculated drive time Tcal is equal to or more than 240 mins (No is step S9), the N2 pole 27d is moved to a position facing the regulating blade 29 (step S10) and the developing roller 25 is rotated in the forward direction (in the counter-clockwise direction in
Next, by moving the S2 pole 27c to a position facing the regulating blade 29 (step S12) and moving the blade magnet 35 to the projecting position (step S13), and then rotating the developing roller 25 in the reverse direction (clockwise direction in
According to the control shown in
After the level of agglomeration reaches the second level (here, level 3) which is higher than the first level (level 2), when the developing device 4 operates for a given period, at least one of an indication of the life of the developing device 4 or one requesting the replacement of the developing device 4 is displayed on the liquid crystal display portion 71. This prevents the developing device 4 from being used with toner degraded for a long time, and thus makes it possible to prevent clogging with toner at the regulating portion 30 and vertical streak lines in images resulting from degraded toner.
The embodiments described above are in no way meant to limit the present disclosure, which thus allows for many modifications and variations within the spirit of the present disclosure. For example, in the above embodiments, the fixed magnet 27 is configured to have four poles, namely two N poles and two S poles. The present disclosure is applicable similarly to a fixed magnet 27 configured to have five or three poles.
In the fourth and fifth embodiments described above, the second developer eliminating mode is performed after the execution of the first developer eliminating mode. However, the first developer eliminating mode can be performed also after the execution of the second developer eliminating mode. The fourth and fifth embodiments described above are configured such that the blade magnet 35 is moved to the reference position and the projecting position by the coil spring 38, the eccentric cam 39, and the blade magnet moving motor 44. However, the moving mechanism for the blade magnet 35 is not limited to this, and any well-known mechanism such as a solenoid or a rack-and-pinion mechanism can be used.
The present disclosure is applicable to a developing device which uses magnetic one-component developer and a developer carrier used in such a developing device. Based on the present disclosure, it is possible to provide a developing device which can prevent clogging with toner even when continuous printing is performed in a high-temperature environment, and to provide an image forming apparatus provided with such a developing device.
Number | Date | Country | Kind |
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2018-188493 | Oct 2018 | JP | national |
2018-230746 | Dec 2018 | JP | national |
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