JP2004198661A - Development device and image forming apparatus using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the response of the autonomous control of the electrostatic charge and toner concentration of developer and to obtain uniform development characteristics free from uneven concentration. <P>SOLUTION: The development device includes: a developer storage part 3 which is adjacent to a developer carrier 1 and stores the developer G upstream a regulating member 2; a toner storage part 4 which is provided communicating with the developer carrier 1 via the developer storage part 3 and stores toner T so that the toner can be supplied; and a rotary member 5 which is disposed in the developer storage part 3, rotates in contact with or close to the developer carrier 1, and takes the toner T from the toner storage part 4 into the developer storage part 3 with the rotating force applied to the developer G in the developer storage part 3. Among the magnetic poles 11 of an electric field generation means 10, the magnetic force pattern of the electrode 11 (e.g., 11c) that is closest to the rotary member 5 is disposed downstream the developer transport direction on the developer carrier 1 with respect to the facing part Q of the developer carrier 1 and rotary member 5. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a developing device for visualizing an electrostatic latent image formed on an image carrier, in particular, using a two-component developer containing a toner and a carrier, and using a toner concentration detecting unit. The present invention relates to a developing device capable of autonomously controlling the toner concentration without using the developing device and an improvement in an image forming apparatus using the developing device.
[0002]
[Prior art]
In general, as a developing device used in an image forming apparatus such as an electrophotographic system, there is known a developing device which visualizes an electrostatic latent image formed on an image carrier such as a photosensitive drum with a developer. I have.
This type of developing device has a mode in which a two-component developer containing a toner and a carrier is used as a developer, or a mode in which a one-component developer containing only a toner is used. In this case, the toner density decreases as the toner consumption increases, so that the toner is periodically supplied to maintain the toner density.
Such toner replenishment is performed, for example, when the toner density is detected by a toner density detection sensor and it is determined that the toner density has decreased based on this detection information.
[0003]
However, in this type of method, the toner density must be detected by a toner density detection sensor. Therefore, a toner density detection sensor is indispensable. There is a problem that the detection system is troublesome.
Therefore, as a prior art for solving such a problem, a developing device has been already provided in which toner is taken in by the movement of a developer without using a toner concentration detection sensor, and the toner concentration is controlled autonomously. .
[0004]
A typical example of this type of prior art is disclosed in Patent Document 1, for example.
This is because a magnetic particle layer is formed on a developing sleeve, toner is contained in a toner supply section in a container so as to come into contact with the magnetic particle layer, and the magnetic particles in the magnetic particle layer move as the developing sleeve rotates. This is a developing device that takes in toner from the outer toner layer into the magnetic particle layer in the toner supply section, regulates the layer thickness of the developer in which the toner and the magnetic particles are mixed by the regulating member, and conveys the developer to the developing section.
Here, the magnet fixed in the developing sleeve does not have a magnetic pole facing the toner supply unit, and has a magnetic pole on the downstream side of the toner supply unit in the rotation direction of the developing sleeve, and on the upstream side of the regulating member, A shielding member is provided opposite to the developing sleeve at a position within the range of the magnetic field of the magnetic pole, and forms a region filled with the magnetic particle layer between the developing sleeve and the developing sleeve.
[0005]
Further, in Patent Document 2, a developer carrier having a magnetic field generating means therein for carrying and transporting a two-component developer including a toner and a carrier, and a second device for regulating the amount of developer on the developer carrier are disclosed. A first regulating member, a second regulating member provided upstream of the first regulating member and passing an increase in the developer layer thickness due to an increase in toner concentration, a first regulating member, and a second regulating member. A developer accommodating section provided between the developer accommodating member and a toner accommodating section which is adjacent to the developer accommodating section and supplies toner to the developer accommodating section. A technique is disclosed in which the state of contact between the developer and the toner is changed, the state of the toner taken in by the developer on the developer carrier is changed, and the toner supply is constantly controlled to be constant.
[0006]
Further, in Patent Document 3, a developer carrier having a magnetic field generating means therein for carrying and transporting a two-component developer containing a toner and a carrier, and regulating the amount of the developer on the developer carrier A regulating member, a developer accommodating portion accommodating the developer scraped off by the regulating member, and being adjacent to the developer accommodating portion and being taken in contact with the developer on the developer carrying member. A toner accommodating portion for accommodating the toner, and further comprising a rotating member that rotates in the same rotation direction as the developer carrier in contact with or in proximity to the developer carrier, in the developer accommodating portion. A technique is disclosed in which the rotating member is disposed at the most upstream position in the surface moving direction of the developer carrier in the developer accommodating portion, and the supply of toner from the upstream toner accommodating portion is stabilized. .
[0007]
Further, in Patent Document 4, a developer carrier, a first regulating member for regulating the amount of developer on the developer carrier, and a developer carrying member provided upstream of the first regulating member are provided. A second regulating member for regulating the amount of developer on the body, a developer accommodating portion provided between the first and second regulating members and accommodating the developer scraped off by the first regulating member; A toner storage portion that is adjacent to the developer storage portion and stores toner to be supplied to the developer carrying member; and communicates the toner storage portion with the developer storage portion to take in the toner in the toner storage portion. A toner supply path for forming a developer circulating section for adjusting the toner concentration to a suitable value, and a stirring member provided in the toner supply path for stirring the developer circulating section, and utilizing a change in the bulk of the developer due to the toner concentration. In addition, a technique for adjusting the toner concentration to an appropriate level is disclosed. .
Further, in Patent Document 5, a developer carrier, a regulating member for regulating the amount of developer on the developer carrier, a developer stagnating portion in which the developer blocked by the regulating member stagnates, A toner supply port, which is a space communicating with the developer storage section, and a toner storage section adjacent to the developer storage section via the toner supply port, and a toner stirring member is provided in the toner supply port, and A technique for stably supplying toner has been disclosed.
[0008]
[Patent Document 1]
Japanese Patent Publication No. 5-67233 (Summary of the invention, FIG. 1)
[Patent Document 2]
JP 9-197833 A (Means for solving the problem, FIG. 1)
[Patent Document 3]
JP 2001-117370 A (Means for solving the problem, FIG. 2)
[Patent Document 4]
JP-A-2000-66497 (Means for solving the problem, FIG. 1)
[Patent Document 5]
JP 2000-275939 A (Means for solving the problem, FIG. 1)
[0009]
[Problems to be solved by the invention]
However, in Patent Documents 1 to 3, the method of taking in the toner is to supply the toner by bringing the toner into contact with the developer layer on the developer carrier (or the developing sleeve). There are technical issues.
For example, in Patent Document 1, it may be possible to easily adjust the toner density.
However, if the developer layer on the developing sleeve is thick, it takes time for the supplied toner to uniformly diffuse and disperse in the developer, and stable toner supply and agitation against a rapid change in toner consumption. There is a possibility that the background cannot be stained or the density cannot be maintained.
[0010]
Further, even in Patent Document 2, the toner is diffused by the circulation of the developer in order to make the toner concentration uniform, but a certain amount of time is required until the whole becomes uniform, In some cases, the responsiveness of switching between the toner take-in and the stop operation is slow with respect to a change in toner consumption (change in image density). If the responsiveness is slow, the toner density decreases when the toner consumption increases abruptly on the toner consuming side, so that a high image area density cannot be secured, and the image density may be reduced. In addition, when the toner consumption decreases sharply, the toner density increases, and there is a possibility that the background becomes dirty and the density becomes excessive.
[0011]
Further, in Japanese Patent Application Laid-Open No. H11-163, although the responsiveness of taking in the toner is certainly improved to some extent, the uniform dispersion of the toner may be insufficient.
That is, the layer-regulated developer is conveyed to the developing section by the developer carrier, transported again into the developing device, contacts the toner in the toner supply section, takes in the toner, and returns to the developer accommodating section. Since the developer layer is strongly attracted to the developer carrier by the magnetic force, the replacement of the developer in the developer accommodating portion becomes insufficient. For this reason, frictional charging due to agitation between the taken-in toner and the carrier is not sufficient, and when forming an image such as a halftone, a mottled density unevenness is likely to occur.
In any case, when the toner concentration is reduced and the toner is taken in, the toner is supplied directly to the developer layer on the developer carrier, and the supplied toner is transported again to the developing unit without being sufficiently stirred. Therefore, there is a possibility that the density unevenness is likely to occur more easily.
[0012]
Further, in Patent Document 4, a toner supply path formed as a developer circulating section for optimizing toner concentration is provided between a developer carrier and a toner storage section, and a stirring member is provided in the toner supply path. It operates as follows.
That is, for example, if the toner concentration in the developer is within an appropriate range, a developer stagnant portion is formed in the toner replenishment path, and taking-in of the toner is prevented where the developer and the toner are in contact.
On the other hand, when the toner is consumed and the toner concentration in the developer is out of the appropriate range, the bulk of the developer is reduced, the developer stagnation portion is reduced, and the toner is taken into the developer circulation portion accordingly. Then, the bulk of the developer is gradually increased, and the developer stagnant portion is formed again to interrupt the intake of the toner.
At this time, the stirring member keeps the developer circulating section uniformly and actively circulating, prevents a bridge from being formed in the developer stagnation section, and furthermore, the developer is locally consumed. prevent.
[0013]
In Patent Literature 4, there is a device for uniformly taking in the toner into the developer carrying member. However, the developer is stored between the first regulating member and the second regulating member when the toner is consumed. When the toner concentration in the developer is out of the proper range, the bulk of the developer is reduced, the developer stagnation portion at the entrance of the toner supply path is reduced, and a space is provided before the second regulating member. The developer is taken into the developer circulation section. Then, when the bulk of the developer gradually increases, the developer stagnant portion is formed again, and the taking in of the toner is interrupted.
As described above, the developer in the developer accommodating portion and the developer in the developer circulating portion are substantially separated from each other by the second regulating member, and when the toner is rapidly consumed, the responsiveness of taking in the toner may be deteriorated. There is.
[0014]
Further, in Patent Document 5, since the toner is stirred at the toner supply port connecting the developer storing section and the toner storage section, the toner facing the developer storing section is easily supplied. There is a technical problem that the toner is not rapidly taken in with respect to the change in the toner concentration in the stagnant portion, and the responsiveness of taking in the toner tends to be insufficient when the toner is rapidly consumed.
[0015]
In order to improve such a problem, the applicant of the present application firstly attaches a developer accommodating portion for accommodating a developer adjacent to the developer carrying member and upstream of the regulating member, and a developer accommodating portion. A toner accommodating portion provided in communication with the developer carrying member through which the toner can be supplied; and a toner accommodating portion provided in the developer accommodating portion and rotatable in contact with or close to the developer carrying member. A rotation member that takes in toner from the toner storage unit into the developer storage unit while applying a rotation force to the developer in the unit, and transfers the toner along the transport direction of the rotation member by the developer transportation force of the rotation member. An incorporation was proposed (for example, refer to Japanese Patent Application No. 2002-079234).
[0016]
However, in this proposal, when the developer conveying force in the vicinity of the rotating member was further examined, it was found that the developer conveying force in the vicinity of the rotating member greatly depends on the magnetic pole arrangement inside the developer carrier substantially opposed to the rotating member. did.
Specifically, depending on the arrangement of the magnetic poles inside the developer carrying member substantially opposed to the rotating member, there is a concern that the developer carrying force may be insufficient. For example, if the developer carrying force is insufficient, the toner consumption may be reduced. It takes a long time for the supplied toner to uniformly diffuse and disperse in the developer in response to a sudden change, and it is not possible to stably supply and agitate the toner, and there is a possibility that background contamination and density maintenance cannot be performed.
[0017]
The present invention has been made in order to solve the above technical problems, and has improved the responsiveness of the toner concentration in the developer and the autonomous control of the charging, and has a uniform developing property without density unevenness. And an image forming apparatus using the same.
[0018]
[Means for Solving the Problems]
That is, according to the present invention, as shown in FIG. 1, a two-component developer G including a magnetic field generating means 10 therein and containing a toner T and a magnetic carrier C (see FIGS. 2 and 3) is carried and carried. A developer carrier 1, a regulating member 2 for regulating the amount of developer conveyed on the developer carrier 1, and a developer G adjacent to the developer carrier 1 and upstream of the regulating member 2. And a toner storage unit 4 provided in communication with the developer carrier 1 via the developer storage unit 3 and configured to supply the toner T so as to be supplied thereto, and the developer storage unit 3. The toner T from the toner container 4 is developed while being provided in the unit 3 and rotating in contact with or close to the developer carrier 1 and applying a rotational force to the developer G in the developer container 3. A rotating member 5 to be taken into the agent container 3, and a magnetic pole 11 of the magnetic field generating means 10. For example, among 11 a to 11 d), the magnetic force pattern by the magnetic pole 11 (for example, 11 c) closest to the rotating member 5 causes the development on the developer carrying member 1 with respect to the opposing position Q between the developer carrying member 1 and the rotating member 5. It is characterized by being displaced downstream in the agent transport direction.
[0019]
In such technical means, the developer carrier 1 may be appropriately selected as long as it has a magnetic field generating means 10 therein and carries and transports the two-component developer G. A magnet roll having a rotatable non-magnetic sleeve and a magnet member fixedly disposed in the sleeve is often used.
As long as the regulating member 2 regulates the amount of the developer on the developer carrier 1, a blade, a roll, or the like may be appropriately selected, and the layout thereof may be arbitrarily selected.
Further, the toner container 4 normally contains only the toner T. However, if the requirement that the toner T can be supplied is satisfied, for example, the toner concentration is higher than the toner concentration contained in the developer container 3. Of the developer G is also included.
[0020]
Further, as long as the developer accommodating section 3 and the toner accommodating section 4 are in communication with each other, they may have any positional relationship.
However, the toner container 4 is required to be “suppliable with toner”, and is not limited to a mode in which a toner supply member is provided inside. For example, the toner container 4 is disposed above the developer container 3, A mode in which the toner T is moved downward by its own weight is also included.
In this case, the specific gravity of the toner T differs from that of the carrier, so that the toner T floats upward with respect to gravity. For this reason, especially in the case of non-magnetism, an appropriate pressing pressure is required from the toner container 4 to bring the toner T into contact with the developer G and take it in.
If the pressing pressure is insufficient, the toner T accumulates on the inner wall of the developing device by its own weight due to gravity, and the contact with the developer G is unstable. On the other hand, if the pressing pressure is too strong, agglomeration of the toner T, which is called blocking, occurs, and an image quality abnormality occurs due to inhibition of toner supply and poor dispersion in the developer G.
[0021]
Furthermore, the toner container 4 needs to be “provided in communication with the developer carrier 1 via the developer container 3”. It is not adjacent, and means that the developer accommodating portion 3 is interposed between the two.
As a result, the toner T in the toner container 4 does not directly contact the developer G in the immediate vicinity on the developer carrier 1, but only through the developer G in the developer container 3. Supplied to the side.
In this case, since the rotating member 5 is provided in the developer accommodating section 3, the toner T in the toner accommodating section 4 comes into contact with the developer G near the rotating member 5, and the developer is transported by the rotating member 5. The toner T is taken in by force along the transport direction of the rotating member 5.
[0022]
Further, as the rotating member 5, a roll, a brush, a paddle, or the like may be appropriately selected as long as it conveys the nearby developer G in the rotating direction.
However, from the viewpoint of preventing banding, which is an image defect, the rotating member 5 is preferably in a roll shape.
The function of the rotating member 5 is to transport the developer G in the vicinity of the rotating member 5 in the rotating direction. The flow behavior of the developer G changes according to the toner concentration. Utilizing the toner T, which comes into contact with the developer G, is utilized.
[0023]
Further, as a preferable embodiment of the rotating member 5, there is an embodiment in which the rotating member 5 has magnetism. Typically, a magnetic roll (preferably using a soft magnetic member) is used. Also includes magnetic paddles.
When such a magnetic rotating member 5 is used, the magnetic rotating member 5 is magnetized by the magnetic field generating means 10 in the developer carrier 1, and the rotation of the developer G by the carrier chain with the rotation of the magnetic rotating member 5 is further improved. Can be promoted.
As a result, the rotational conveyance behavior of the developer G can be made more active.
[0024]
Another preferred embodiment of the rotating member 5 is a magnet roll including a rotatable non-magnetic sleeve and a magnet member fixedly disposed in the sleeve.
In this embodiment, due to the magnetization of the rotating member 5, the interaction between the magnetic field from the magnetic field generating means 10 of the developer carrier 1 and the magnetic field from the rotating member 5 causes the developer to rotate with the rotation of the rotating member 5. The rotation of the G by the carrier chain can be further promoted.
[0025]
The structure of the toner container 4 may be appropriately selected. However, in a mode in which the toner container 4 is juxtaposed at substantially the same horizontal position as the developer container 3, a preferable embodiment of the toner container 4 is as follows. In order to supply the toner T from the toner storage unit 4 to the developer storage unit 3, an element for sending out the stored toner T is usually required. It is preferable to provide a pressing and conveying member against which the toner T is pressed.
[0026]
Further, the rotation direction of the rotating member 5 may be appropriately selected. However, from the viewpoint of securing the accumulation state of the developer G in the developer accommodating section 3, the surface moving direction of the rotating member 5 It is preferable that the direction is the same as the surface movement direction of the developer carrier 1 at the opposing portion of the developer carrier 1.
Further, as a preferable mode of the developer accommodating section 3, it is preferable that the developer accommodating section 3 includes an auxiliary regulating member 6 that regulates the amount of the developer G conveyed by the rotating member 5.
The auxiliary regulating member 6 facilitates formation of a developer pool in the developer accommodating section 3, prevents developer jamming between the developer carrier 1 and the rotating member 5, and allows the uncharged toner T It has various functions of avoiding the situation of being transported to the carrier 1.
Further, as a preferable layout of the auxiliary regulating member 6, a gap between the rotating member 5 and the auxiliary regulating member 6 is set to be smaller than a gap between the developer carrier 1 and the rotating member 5. preferable.
As described above, the magnitude relation of the gap is preferable in that the developer pool in the developer accommodating section 3 is more reliably formed.
[0027]
In a preferred embodiment when the rotating member 5 is a roll-shaped member, it is preferable that the surface of the roll-shaped member is roughened.
The term "roughening" used herein may employ various methods such as sand blasting. By roughening the surface, it is possible to suppress the sliding of the developer G on the surface and secure the transportability of the developer G. can do.
Further, from the viewpoint of improving the supply of the toner T to the developer carrier 1 and from the viewpoint of fixing the toner on the rotating member 5, the direction in which the toner T is transferred to the developer carrier 1 on the rotating member 5. Is preferably applied.
[0028]
Furthermore, the behavior of the developer G in the developer storage section 3 includes the behavior accompanying the scraping of the developer G by the regulating member 2 in addition to the rotation and transport of the developer G by the rotating member 5. A dam member is provided at a position adjacent to the regulating member 2 of the developer container 3 so that the developer G of the developer container 3 does not mix with the toner T of the toner container 4 in accordance with the behavior of the developer G. Is preferred.
In particular, for example, under conditions where the behavior of the developer G scraped off by the regulating member 2 is so severe that the toner G is excessively taken up by the developer G, a portion of the developer accommodating portion 3 adjacent to the regulating member 2 It is preferable to provide a dam member facing the rotating member 5 so as to suppress excessive intake of the toner T based on the behavior of the developer G scraped off by the regulating member 2.
[0029]
Further, the magnetic force pattern by the magnetic pole 11 (for example, 11c) closest to the rotating member 5 among the magnetic poles 11 of the magnetic field generating means 10 includes both the normal component and the tangential component of the magnetic flux density.
When such a magnetic force pattern of the target magnetic pole 11 (11c) is displaced on the downstream side in the developer conveying direction with respect to the opposing position Q between the developer carrier 1 and the rotating member 5, the magnetic force pattern becomes It is presumed to assist the responsiveness of the toner supply by No. 5.
Here, as a typical mode of the magnetic force pattern by the target magnetic pole 11 (11c), the position where the normal component of the magnetic flux density of the magnetic force pattern by the target magnetic pole 11 (11c) is a peak is the developer carrier 1 and the rotating member. 5 or the position where the tangential direction component of the magnetic flux density of the magnetic force pattern by the target magnetic pole 11 (11c) is 0, the developer carrier 1 and the rotating member 5 Is located downstream of the opposing position Q.
[0030]
Further, the present invention is not limited to the developing device described above, but also covers an image forming device.
In this case, the present invention relates to an image forming apparatus including an image carrier 7 and a developing device 8 for visualizing the electrostatic latent image Z on the image carrier 7, What is necessary is just to use the developed developing device 8.
[0031]
Next, the operating principle of the developing device according to the present invention will be described with reference to FIGS.
Now, as shown in FIG. 2A, when the toner concentration TC in the developer pool near the rotating member 5 (for example, a magnetic roll or a magnet roll) is high, the magnetic permeability decreases and the carrier chain CC becomes short.
At this time, the developer G in the vicinity of the rotating member 5 is transported / stirred by the rotational force of the rotating member 5, but the layer thickness of the transported / stirred developer G becomes small.
That is, in the carrier chain CC, as shown in FIG. 3, the toner T between the carriers C acts as a roller, and the shearing force is difficult to be transmitted, so that the developer layer near the rotating member 5 (m in FIG. The developer layer located on the inner side shown in FIG. 1 flows, but the developer layer further outside the fluidized layer G1 is hardly affected by the magnetic force and is not conveyed. As a result, the developer G in the vicinity of the toner accommodating portion 4 stagnates and becomes the immobile layer G2, so that even if the developer G and the toner T are in contact with each other, the toner T is not taken in.
Further, when the toner concentration TC is high, the volume of the developer G increases due to the increase in the bulk density of the developer G, and the developer G fills the space near the developer reservoir, which also helps to prevent the toner T from being supplied. I have.
[0032]
On the other hand, when the toner concentration TC in the developer pool near the rotating member 5 is low, as shown in FIG. 2B, the magnetic permeability of the developer G increases and the carrier chain CC becomes longer.
At this time, the developer G in the vicinity of the rotating member 5 is transported / stirred by the rotating force of the rotating member 5, but the layer thickness of the transported / stirred developer G becomes larger than in the above case.
That is, in the carrier chain CC, as shown in FIG. 4, since there is little toner T between the carriers C, the role as a roller is weak, and a shear force is easily transmitted between the carriers C. For this reason, the developer layer flows not only in the vicinity of the rotating member 5 but also to a portion separated from the rotating member 5 to some extent as shown by m in FIG.
Here, according to the toner concentration TC of the developer G, the fluidized layer G1 reaches the interface between the developer G and the toner T, and the developer G in the vicinity of the toner container 4 flows in the rotation direction of the rotating member 5, and the developer G Is taken into the developer G. The developer layer outside the fluidized bed G1 is the immobile layer G2.
Further, the volume of the developer G is reduced due to the decrease in the bulk density of the developer G, the space near the developer pool is vacant, and the toner T is supplied and buried in the vacant space, so that the toner T is easily taken in. .
With the above mechanism, the toner concentration TC of the developer G is controlled autonomously.
[0033]
Next, among the magnetic poles 11 (for example, 11a to 11d) of the magnetic field generating means 10, the magnetic force pattern by the magnetic pole 11 (for example, 11c) which is closest to the rotating member 5 indicates the position Q between the developer carrier 1 and the rotating member 5. A description will be given of the principle that the toner take-up responsiveness is improved by a mode in which the toner take-up response is shifted downstream on the developer carrying member 1 in the developer conveying direction.
As a comparative example, among the magnetic poles 11 (11a, 11b, 11c ', 11d) of the magnetic field generating means 10, the magnetic force pattern by the target magnetic pole 11 (for example, 11c') is in the developer transport direction with respect to the facing position Q. Assuming a case in which the developer G is displaced upstream, as shown in FIG. 5B, the developer G in the vicinity of the rotating member 5 is conveyed by the rotation of the rotating member 5, and the developer carrier 1 and the rotating member 5 are rotated. When passing through the opposing position Q, the magnetic flux (the thick solid line: the normal component of the magnetic flux density, the thick dotted line: the tangential component of the magnetic flux density) of the target magnetic pole 11 (11c ′) causes the passing developer G 11 (11c ').
Therefore, a force acting to cancel the conveying force of the rotating member 5 acts, and as a result, the amount of the developer conveyed is significantly reduced. This effect is more remarkable when the toner concentration TC is low because the magnetic permeability of the developer G increases.
Thereby, particularly when the toner concentration TC is low, it is inhibited that the toner T is taken in along the transport direction of the rotating member 5 by the developer transport force.
[0034]
On the other hand, in the embodiment of the present invention, among the magnetic poles 11 (11a to 11d) of the magnetic field generating means 10, the magnetic force pattern by the target magnetic pole 11 (for example, 11c) is on the downstream side in the developer transport direction with respect to the opposing position Q. 5A, the developer G in the vicinity of the rotating member 5 is conveyed by the rotation of the rotating member 5, and the opposing position between the developer carrier 1 and the rotating member 5, for example, as shown in FIG. When passing through Q, the passing developer G is attracted to the target magnetic pole 11 (11c) by the magnetic field of the target magnetic pole 11 (11c) and receives a force in the transport direction of the developer G.
Therefore, the passage of the developer G at the opposing position Q is promoted by the resultant force with the transport force of the rotating member 5, and as a result, the developer transport amount is improved. This effect is more remarkable when the toner concentration TC is low because the magnetic permeability of the developer G increases.
Thereby, especially when the toner concentration TC is low, the responsiveness of taking in the toner T along the transport direction of the rotating member 5 by the developer transport force is improved.
[0035]
In FIG. 5B, for example, in a mode in which the magnetic force distribution by the target magnetic pole 11 (11c ′) is substantially equally distributed around the opposing position Q, the magnetic field by the target magnetic pole 11 (11c ′) is used. As a result, the passing developer G passing through the opposing position Q is attracted to the target magnetic pole 11 (11c ′), but does not contribute to the direction of promoting the passing of the developer G.
[0036]
The reason why it is preferable to focus on the normal component or the tangential component of the magnetic flux density when defining the magnetic force pattern by the target magnetic pole 11 (for example, 11c) will be described below.
That is, in the vicinity of the opposing portion between the developer carrier 1 and the rotating member 5, as shown in FIGS. 1 and 5A, the magnetic pole 11 (for example, 11c) of the magnetic field generating means 10 in the developer carrier 1 is set. They are arranged substantially facing each other.
Here, as a typical embodiment of the developer carrier 1, an example is provided in which a plurality of magnetic poles 11 are arranged around the magnet roll, which is fixedly installed, and a non-magnetic sleeve that rotates around the magnet roll. The force received by the developer G magnetically adsorbed on the developer carrier 1 includes a magnetic attraction force (magnetic force) and the conveyance of the developer carrier 1 (specifically, a sleeve). There is a friction force (in the case of the developer G just above the surface of the developer carrier 1) and gravity.
Further, in the case of the developer G magnetically adsorbed from directly above the developer carrier 1 via developer particles, the developer G is not a conveyance force due to a frictional force from the developer carrier 1 (specifically, a sleeve), but a developing force. It receives a conveying force due to a frictional force with the developer particles directly above the developer carrier 1.
The magnetic attraction force can be represented by a magnetic attraction force F = (m · ∇) B (where m and B are vectors), where m represents the magnetic moment of the developer particles and B represents the magnetic flux density.
[0037]
FIG. 7A shows a magnetic flux density distribution on the developer carrier 1 (specifically, a sleeve), and shows a normal component Bn and a tangential component Bt. The horizontal axis x is the circumferential distance of the surface of the developer carrier 1 (specifically, sleeve).
At this time, the magnetic attraction (magnetic force) is expressed by the equations (1) and (2) as shown in FIG.
Here, n and t represent the magnetic flux density components in the x direction and the y direction, ie, the tangential direction and the normal direction of the sleeve surface.
Also, the magnetic moment of the particles may be assumed to be proportional to the magnetic flux density since the developer particles can be regarded as a soft magnetic material. Equations (1) and (2) shown in FIG. ), Are represented by the equations (3) and (4).
[0038]
Therefore, the magnetic attraction force Ft in the tangential direction is determined by two terms, for example, as shown in equations (3) and (3) of FIG.
The first term is, as shown in FIG. 7B, proportional to the slope of the tangential component curve of the magnetic flux density, and the force acts in a direction away from the point where the tangential component of the magnetic flux density becomes zero.
The second term is proportional to the rate of change in the tangential direction component of the magnetic flux density in the normal direction as shown in FIG. 7C, and the force acts toward the point where the tangential component of the magnetic flux density becomes zero. .
In the normal use range, the contribution of the second term is large, and the developer tends to gather toward a point where the tangential component of the magnetic flux density becomes zero.
[0039]
On the other hand, the magnetic attraction force Fn in the normal direction is similarly determined by two terms (see equations (4) and (4) in FIG. 6B).
The first term is proportional to the gradient of the component curve of the magnetic flux density in the normal direction. The farther from the point where the component of the magnetic flux density in the normal direction becomes the peak value, the larger the force acts on the sleeve.
The second term is proportional to the rate of change in the normal direction component of the magnetic flux density, and the maximum force acts on the sleeve at the point where the normal component of the magnetic flux density reaches a peak value.
In the normal use range, the contribution of the second term is large, and the maximum force acts on the developer G in the direction in which the developer G is attracted to the sleeve at the point where the normal component of the magnetic flux density has a peak value.
[0040]
Due to the effect of the frictional force between the developer particles and the sleeve surface, the magnetic attraction force Fn in the normal direction is correlated with the transport force of the developer G accompanying the rotation of the sleeve.
From the above, the distribution of the tangential component of the magnetic flux density is dominant in discussing the direction of the magnetic attraction force Ft in the tangential direction, and the tangential component of the magnetic flux density is controlled in controlling the magnetic attraction force Ft in the tangential direction. It turns out that defining is important.
On the other hand, from the viewpoint of the conveying force, it is understood that it is important to define the normal component of the magnetic flux density.
[0041]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.
◎ Embodiment 1
FIG. 8 is an explanatory diagram showing Embodiment 1 of the image forming apparatus to which the present invention is applied.
In FIG. 1, the image forming apparatus employs, for example, an electrophotographic method, and includes a photosensitive drum 20 and a developing device 30 for visualizing an electrostatic latent image formed on the photosensitive drum 20. And
[0042]
In this embodiment, as shown in FIGS. 8 and 9, the developing device 30 has a developing housing 31 that opens toward the photosensitive drum 20, and a developing roll 32 that faces the opening of the developing housing 31. A regulating member 33 for regulating the layer thickness of the two-component developer G on the developing roll 32 is provided at the upper edge of the opening of the developing housing 31, and the regulating member 33 of the developing housing 31 adjacent to the developing roll 32 is provided. A developer accommodating portion 34 accommodating the developer G and a toner accommodating portion 35 communicating with the developing roll 32 via the developer accommodating portion 34 and accommodating the toner T are formed at the portions. is there.
In the present embodiment, for example, a magnetic toner is used as the toner T of the developer G, but a non-magnetic toner may be used.
[0043]
In the present embodiment, as shown in FIG. 10, the developing roll 32 includes a rotatable non-magnetic sleeve 321 and a magnetic pole roll 322 fixedly disposed inside the sleeve 321.
The magnetic pole roll 322 has a plurality of magnetic poles (four poles in this example: S1 (development pole), S2 (transport pole), N1 (trimming pole), N2 (transport pole)) at predetermined angular intervals around the roll body. The two-component developer G containing the toner T and the carrier (magnetic powder) is magnetically attached to the outer periphery of the developing roll 32. The configuration of the magnetic pole is arbitrary, and a repulsive magnetic pole may be provided at a portion facing the developer accommodating section 34 so that the developer layer on the developing roll 32 is once peeled off.
Further, a bias power source 323 for applying a predetermined developing bias VB is connected to the sleeve 321.
[0044]
Further, the regulating member 33 is made of, for example, a SUS304 plate, and is disposed between the regulating member 33 and the developing roll 32 by a gap g0 (for example, 300 to 600 μm) for regulating the layer thickness of the developer G.
The layout of the regulating member 33 may be appropriately selected, but in the present embodiment, the regulating member 33 is disposed slightly upstream of the trimming pole (N1 in this example).
[0045]
Further, the developer accommodating portion 34 has a space for accommodating the developer G, and a magnetic roll 40 is rotatably disposed in a portion of the developer accommodating portion 34 that is close to (or in contact with) the developing roll 32. ing.
In the present embodiment, the bottom shape of the developer accommodating portion 34 has a curved shape along the developing roll 32 and the magnetic roll 40, and the developing roller 32 and the magnetic roll 40 have a predetermined distance between the developing roll 32 and the magnetic roll 40. The agent transport path is secured.
In particular, in the present embodiment, the magnetic roll 40 is made of a roll using a soft magnetic material (for example, SUM, SUS430, etc.), and its surface roughness is roughened to, for example, about Rz 10 to 30 μm (Rz 20 μm in this example). Has become something.
The magnetic roll 40 is disposed at a position substantially opposite to the transport pole S2 of the developing roll 32 substantially opposite to the developing pole S1 with a predetermined gap g1 (for example, 0.8 to 1.2 mm). The rotational movement direction of the magnetic roll 40 is set to the same direction as the rotational movement direction of the developing roll 32 at a portion facing the developing roll 32 (more precisely, the sleeve 321).
[0046]
In particular, in the present embodiment, the magnetic force pattern by the transport pole S2, which is the magnetic pole closest to the magnetic roll 40, is located on the downstream side in the developer transport direction on the developing roll 32 with respect to the opposing position Q between the developing roll 32 and the magnetic roll 40. Are offset.
Specifically, the magnetic force pattern by the transport pole S2 is such that the peak value of the normal component of the magnetic flux density is located downstream of the facing position Q, or the tangential component of the magnetic flux density is zero. The position may satisfy at least one of the aspects located downstream of the opposing position.
[0047]
Further, in the present embodiment, an auxiliary regulating member 50 made of, for example, a SUS304 plate is attached to the bottom of the developer accommodating portion 34 in the vicinity of the magnetic roll 40 and on the side opposite to the developing roll 32. A gap g2 (for example, 0.4 to 0.8 mm) between the magnetic roll 40 and the auxiliary regulating member 50 is set smaller than the gap g1.
Furthermore, a bias power supply 41 for applying a predetermined bias as needed is connected to the magnetic roll 40. Here, the bias power source 41 means a bias that generates an electric field that transfers the toner T to the developing roll 32 side.
[0048]
Further, the toner accommodating section 35 has an agitator 351 (see FIG. 8) through which the accommodated toner T is stirred and conveyed. The agitator 351 includes, for example, an elastic film attached to a rotating body. The toner T is swept out along the bottom wall.
The bottom of the toner container 35 has a curved shape along the locus of movement of the agitator 351, and a communication port 36 is provided at a connection between the developer container 34 and the toner container 35. The lower end edge of the communication port 36 is set slightly lower than the center position of the agitator 351.
On the other hand, a blocking block 37 is provided near the upper end edge of the communication port 36 to effectively prevent the situation in which the developer G of the developer storage section 34 enters the toner storage section 35 side.
[0049]
Further, the drive system for the developing roll 32, the magnetic roll 40, and the agitator 351 may be appropriately selected. For example, as shown in FIG. 9, the developing roll 32 and the agitator 351 are driven by the first drive motor 61 and the drive transmission. The magnetic roll 40 is driven by a second drive motor 63 and a drive transmission system (transmission belt, pulley, gear, etc.) 64. ing.
[0050]
Next, the operation of the image forming apparatus according to the present embodiment will be described focusing on the developing device.
Now, in FIG. 10, assuming that the toner concentration TC of the developer layer on the developing roll 32 is sufficiently high, when the developer G returns to the developing housing 31 with the rotation of the developing roll 32, Since the toner concentration TC of the developer G in the accommodating portion 34 is high, the magnetic permeability is low, and the developer behavior (poor fluidity) shown in FIGS. 2A and 3 is exhibited.
At this time, the magnetic roll 40 is magnetized by the magnetic field of the magnetic pole roll 322 in the developing roll 32, the developer G is magnetically attracted to the surface thereof, and the developer G is transported in the rotation direction of the magnetic roll 40.
For this reason, the developer G located near the magnetic roll 40 flows as the fluidized layer G1, but many of the developer layers outside thereof do not move as the immobile layer G2, and a developer pool is formed.
Therefore, the toner T from the toner container 35 is not taken in the developer G but stays in the developer pool.
[0051]
On the other hand, assuming that the toner T is rapidly consumed, the toner concentration TC of the developer layer on the developing roll 32 becomes low, so that the developer G returns to the developing housing 31 with the rotation of the developing roll 32. In this case, since the developer G in the developer accommodating portion 34 has a low toner concentration TC, the magnetic permeability increases, and the developer behavior (good fluidity) shown in FIGS. 2B and 4 is exhibited.
At this time, the magnetic roll 40 is magnetized by the magnetic field of the magnetic pole roll 322 in the developing roll 32, the developer G is magnetically attracted to the surface thereof, and the developer G is transported in the rotation direction of the magnetic roll 40.
For this reason, many developer layers up to the portion distant from the magnetic roll 40 flow as the fluidized layer G1, so that the immobile layer G2 is not formed outside the layer.
[0052]
When the developer G in the vicinity of the magnetic roll 40 is conveyed and passed to the opposite portion between the developing roll 32 and the magnetic roll 40 with the rotation of the magnetic roll 40, the magnetic force pattern by the conveying pole S2 is changed by the developing roll 32. And the magnetic roll 40 is displaced downstream from the opposing position Q, so that the magnetization distribution of the magnetic roll 40 also becomes strong downstream in the developer transport direction, and thereby the developing roll 32 and the magnetic roll 40 A magnetic attractive force acts on the downstream side of the opposing portion of.
Therefore, since a large rotational conveyance force acts on the developer G around the magnetic roll 40, the toner T from the toner storage unit 35 is sequentially taken into the developer G having the rotational conveyance behavior. The toner concentration in the developer G conveyed by the rotation of 40 immediately increases.
[0053]
The developer G in which the toner T has been taken in this way is forcibly moved with the rotation of the magnetic roll 40, but the toner T is sequentially diffused into the developer G having such a rotational conveyance behavior. Is sufficiently charged with the movement of the carrier chain, and is conveyed to the developing roll 32 side.
Therefore, the toner T supplied from the toner container 35 is not immediately conveyed to the developing roll 32, but moves to the developing roll 32 while being sufficiently charged.
Therefore, the toner concentration of the developer layer on the developing roll 32 is immediately and autonomously controlled.
[0054]
Particularly, in the present embodiment, the auxiliary regulating member 50 is disposed on the magnetic roll 40, and the layer of the developer G transported on the magnetic roll 40 is regulated by the auxiliary regulating member 50.
Therefore, the developer G scraped off by the regulating member (first regulating member) 33 and the developer G scraped off by the auxiliary regulating member 50 (second regulating member) form a pool, It comes into contact with the toner T supplied from the communication port 36 of the toner container 35.
As described above, the auxiliary regulating member 50 effectively forms the developer pool, acts to suppress the jamming of the developer G between the developing roll 32 and the magnetic roll 40 and the deterioration of the developer, and provides a function near the magnetic roll 40. The developer G is transported by the rotation of the magnetic roll 40, but the excess toner T is scraped off by regulating the spikes of the developer G on the magnetic roll 40, so that the toner T is immediately transported to the developing roll 32. This serves to prevent unevenness in image quality due to uncharged toner T.
[0055]
◎ deformation form
In the above-described embodiment, the magnetic roll 40 is used. However, the present invention is not limited to this. For example, as shown in FIG. A magnetic roll 80 having a magnetic pole roll (magnet member) 82 may be used.
In the present embodiment, the number of magnetic poles and the arrangement of the magnetic poles of the magnetic pole roll 82 may be appropriately selected. However, for example, two poles (S, N in this example) may be arranged.
Further, the auxiliary regulating member 50 is provided in the vicinity of the magnet roll 80, the surface of the sleeve 81 is roughened, and a bias power supply 83 for applying a predetermined bias to the sleeve 81 is provided as necessary. It may be selected as appropriate.
[0056]
According to this aspect, substantially the same operation as that of the first embodiment is obtained, but the magnet roll 80 is originally magnetized and the influence of the magnetic field from the developing roll 32 is superimposed as compared with the first embodiment. The holding and transporting force of the developer G by the magnet roll 80 is further strengthened than in the first embodiment, and the rotation and transport behavior of the developer G accompanying the rotation of the magnet roll 80 appears more strongly.
For this reason, the autonomous control of the toner concentration and charging in the developer G is performed more reliably.
[0057]
◎ Embodiment 2
FIG. 12 is an explanatory diagram showing Embodiment 2 of the image forming apparatus to which the present invention is applied.
In the figure, the image forming apparatus includes a developing device 30 substantially the same as the first embodiment (however, the shape of the regulating member 33 and the shape of the developer accommodating portion are slightly different from the first embodiment). However, this developing device includes a blocking block 38 different from that of the first embodiment.
The blocking block 38 is formed in a V-shaped cross section projecting downward.
Further, the bottom of the developer accommodating portion 34 has an inclined surface 341 directed in an oblique direction, and an oblique surface is provided between one inclined surface 381 of the blocking block 38 and the inclined surface 341 of the developer accommodating portion 34. A toner intake path 39 inclined in the direction is formed.
The toner take-in path 39 has a shape such that the toner T from the toner containing section 35 receives a force toward the developer containing section 34 by its own weight, and accordingly, the responsiveness of the toner taking-up can be improved. it can.
[0058]
【Example】
◎ Example
In the present embodiment, the developing device according to the second embodiment is embodied, and the toner intake characteristics are measured.
The test conditions of the present embodiment are as follows.
-Two-component developer G:
The average particle diameter of the carrier was 35 μm, the amount used was 40 g, and the toner T used was a magnetic toner containing 15 wt% of magnetic powder, and the average particle diameter of the toner T was 10 μm. Conveyance developer amount MOS is 45 to 55 mg / cm ^Two It is.
・ Developing roll 32:
It has a 4-pole configuration and has a magnetic pattern as shown in FIG. FIG. 13 shows a magnetic force pattern when the developing roll 32 of FIG. 12 is viewed from the back side.
MSA (Magnet Set Angle) is + 3 °.
The peripheral speed is 416 rpm.
・ S2 pole (transport pole):
The peak value of the component of the magnetic flux density in the normal direction is located at a position 7.5 ° from the center of the developing roll 32 on the downstream side in the rotation direction of the magnetic roll 40 from the position facing the magnetic roll 40. The magnetic force is 64 mT.
-Restriction member 33:
T / G (trimming gap) is 0.4mm
-Magnetic roll 40:
A surface roughening treatment of SUS 7 with an outer diameter of φ7 mm and Rz of 10 to 15 μm is performed by sandblasting # 60. The peripheral speed is 916 rpm.
[0059]
When the normal direction component and the tangential direction component of the magnetic flux density on the sleeve 321 in such a developing roll 32 were measured, the results shown in FIG. 14 were obtained.
Here, a Gauss meter is used as a magnetic flux density measuring device. For example, GAUSS METER MODEL HGM-8300LWGP (body) and FX-95A (sensor) manufactured by ADS Co., Ltd. were used.
As a measuring method, a sensor was brought into contact with the surface of the sleeve 321 and the internal magnet roll was rotated 360 ° to measure the magnetic flux density in the normal direction and the tangential direction of the sleeve.
The sensor and the developing roll 32 are fixed by a special jig so that the two axes of the Hall elements in the sensor are perpendicular and parallel to the axis of the developing roll 32, respectively.
[0060]
The magnetic flux density distribution was obtained by estimating the magnetization distribution of the magnetic field generating means (magnetic pole) from the magnetic flux densities on the surface of the developing roll 32 in the normal direction and the tangential direction, and calculating the magnetic flux density distribution from the magnetization distribution by the finite element method.
Further, the magnetic attraction force (magnetic force) was calculated from a mathematical formula for determining the magnetic attraction force F = (m · ∇) B (where m and B are vectors) by making the carrier particles spherical with a relative magnetic permeability of 12 and a particle diameter of 35 μm. . Here, m is the magnetic dipole moment of the carrier particles [Am ^Two ], B is the magnetic flux density [Wbm ^-2 And the specific gravity of the particles is 5 mg / cm ^Two I put it.
[0061]
In FIG. 14, the solid line indicates the normal component of the magnetic flux density in the magnetic force pattern, and the dotted line indicates the tangential component of the magnetic flux density in the magnetic force pattern.
Here, the opposing position Q between the developing roll 32 and the magnetic roll 40 (indicated by a dashed line in the figure) is a position of 232 ° in this example, and the tangential component of the magnetic flux density at the opposing position Q is a negative value. It is understood that
This indicates that the tangential component of the magnetic flux density is oriented in the rotation direction of the developing roll 32, and that the transfer of the developer G is promoted at the facing portion between the developing roll 32 and the magnetic roll 40. Guessed.
[0062]
Actually, when the developing device according to the example was operated under the above-described test conditions and the change over time in the toner concentration TC was examined, the toner intake characteristics were obtained as shown in FIG.
In the figure, at t = 0, the developing roll, the magnetic roll, and the agitator are driven at a predetermined number of revolutions in a state where only the carrier is stored in the developer storing section and 40 g of the toner is stored in the toner storing section. The developer is sampled on the developing roll at time intervals, and the toner concentration TC of the developer is measured by a blow-off method.
According to the figure, it is understood that the rising characteristic at the time of taking in the toner is sharp, and reaches the predetermined toner concentration TC immediately after the operation of the developing device is started.
This indicates that even if the toner is rapidly consumed and the toner concentration TC decreases, the toner is immediately supplied and the toner concentration TC returns to the predetermined level.
[0063]
◎ Comparative Example 1
This is configured in the same manner as in the embodiment except for the location of the S2 pole.
Here, the S2 pole positions the peak value of the component of the magnetic flux density in the normal direction at a position of 2.5 ° as viewed from the center of the developing roll 32, on the upstream side in the rotation direction of the magnetic roll 40 from the position facing the magnetic roll 40. And its peak magnetic force is 64 mT.
[0064]
Also in Comparative Example 1, as in the example, when the normal direction component and the tangential direction component of the magnetic flux density on the sleeve 321 were measured on the developing roll 32, the results shown in FIG. 15 were obtained.
In this figure, the opposing position Q (indicated by a dashed line in the figure) between the developing roll 32 and the magnetic roll 40 is a position of 232 ° in this example, and the tangential component of the magnetic flux density at the opposing position Q is positive. It is understood that it is a value.
This indicates that the tangential component of the magnetic flux density is oriented in the anti-rotation direction of the developing roll 32, and the direction in which the transport of the developer G is inhibited at the opposing portion between the developing roll 32 and the magnetic roll 40. It works for you.
[0065]
Actually, when the developing device according to Comparative Example 1 was operated under the same test conditions as in the example, and the change over time in the toner concentration TC was examined, the toner taking-in characteristic was obtained as shown in FIG.
According to this, it is understood that the comparative example 1 has a lower toner take-up characteristic than the example.
[0066]
◎ Comparative Example 2
This is configured in the same manner as in the embodiment except for the location of the S2 pole.
Here, the S2 pole has the peak value of the normal component of the magnetic flux density positioned at 10 ° as viewed from the center of the developing roll 32 on the upstream side in the rotation direction of the magnetic roll 40 from the position facing the magnetic roll 40. And its peak magnetic force is 64 mT.
[0067]
As for the comparative example 2, similarly to the example, when the normal direction component and the tangential direction component of the magnetic flux density on the sleeve 321 were measured on the developing roll 32, the result shown in FIG. 16 was obtained.
In this figure, the opposing position Q (indicated by a dashed line in the figure) between the developing roll 32 and the magnetic roll 40 is a position of 232 ° in this example, and the tangential component of the magnetic flux density at the opposing position Q is positive. It is understood that the value is larger than Comparative Example 1.
This indicates that the tangential component of the magnetic flux density is oriented in the anti-rotation direction of the developing roll 32, and the direction in which the transport of the developer G is inhibited at the opposing portion between the developing roll 32 and the magnetic roll 40. It works for you.
[0068]
Actually, when the developing device according to Comparative Example 2 was operated under the same test conditions as in the example, and the temporal change of the toner concentration TC was examined, the toner take-in characteristic was obtained as shown in FIG.
According to this, it is understood that Comparative Example 2 has even worse toner take-up characteristics than Comparative Example 1 as well as Examples.
[0069]
As described above, when the embodiment is compared with the comparative examples 1 and 2, the take-in speed of the toner of the embodiment is about five times as large as that of the comparative examples 1 and 2 at the rising edge at which the toner concentration reaches the predetermined toner concentration TC. It is understood that has been reached.
This indicates that even if the toner is rapidly consumed and the toner concentration TC decreases, the toner is immediately replenished and the toner concentration TC returns to the predetermined level, which confirms the performance of the second embodiment. Things.
[0070]
【The invention's effect】
As described above, according to the present invention, the developer accommodating portion is provided adjacent to the developer carrier and upstream of the regulating member, and the toner communicates with the developer carrier via the developer accommodating portion. A rotating member provided with an accommodating portion, and in which the toner from the toner accommodating portion is rotated in contact with or in proximity to the developer carrying member and in which a rotational force is applied to the developer in the developer accommodating portion; Further, by devising a magnetic force pattern by a magnetic pole closest to the rotating member among magnetic poles of the magnetic field generating means, a developer transporting direction with respect to the developer passing through a position where the developer carrying member and the rotating member are opposed to each other. The following basic effects can be obtained by giving the movement promotion power toward the vehicle.
First, autonomous control of the toner concentration and charging in the developer can be stabilized.
Specifically, even if there is a rapid consumption of toner, the responsiveness of toner supply by the rotating member is good, so that the toner concentration of the developer layer on the developer carrier can be quickly and accurately controlled.
Further, the toner is supplied to the developer near the rotating member, and the toner is positively dispersed in the developer by the rotational force of the rotating member. The toner is sufficiently triboelectrically charged by the transport of the developer by the member, and accordingly, a charged state suitable for image formation is obtained.
[0071]
Second, uniform developability without density unevenness can be obtained.
In other words, since the supplied toner is once supplied into the developer being conveyed by the rotating member, the uncharged raw toner does not directly get on the developer layer on the developer carrying member. In addition, since the toner near the developer accommodating portion is taken in while being broken by the rotating member, the diffusion of the toner into the developer is improved.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an outline of a developing device according to the present invention and an image forming apparatus using the same.
FIG. 2A is an explanatory diagram showing the behavior of a developer around a rotating member of the developing device in a state where the toner concentration is high and the magnetic permeability is low, and FIG. 2B is a diagram illustrating the developing device in a state where the toner concentration is low and the magnetic permeability is high. FIG. 5 is an explanatory diagram showing behavior of a developer around a rotating member of FIG.
FIG. 3 is an enlarged explanatory view showing the behavior of a developer around a rotating member in a state where the toner concentration is high and the fluidity is poor.
FIG. 4 is an enlarged explanatory view showing behavior of a developer around a rotating member in a state where toner concentration is low and fluidity is good.
FIG. 5A is an explanatory view showing the periphery of a portion where a developer carrying member and a rotating member of a developing device according to the present invention are opposed to each other, and FIG. 5B is a diagram showing a developer carrying member and a rotating member of a developing device according to a comparative embodiment; It is explanatory drawing which shows the periphery of the facing part with a member.
6A is an explanatory diagram showing a relational expression regarding a magnetic attraction force Ft in a tangential direction and a magnetic attraction force Fn in a normal direction, and FIG. 6B is a case where a magnetic moment of developer particles is proportional to a magnetic flux density. It is explanatory drawing which shows the relational expression.
7A is a graph showing a magnetic attraction force Ft in a tangential direction and a magnetic attraction force Fn in a normal direction, and FIG. 7B is a first term change in the equation (3) of FIG. 6B. FIG. 6C is a graph showing the change of the second term in the equation (3) of FIG. 6B.
FIG. 8 is an explanatory diagram illustrating an overall configuration of the image forming apparatus according to the first embodiment;
FIG. 9 is an enlarged view of a main part thereof.
FIG. 10 is an explanatory diagram showing a drive system of the developing device in the present embodiment.
FIG. 11 is an explanatory diagram showing a modification of the developing device according to the embodiment.
FIG. 12 is an explanatory diagram illustrating an overall configuration of an image forming apparatus according to a second embodiment.
FIG. 13 is an explanatory diagram showing an example of a magnetic pole pattern of a developing roll used in the embodiment.
FIG. 14 is an explanatory diagram showing a change in a magnetic flux density of a developing roll used in an example in a normal direction and a tangential direction.
FIG. 15 is an explanatory diagram showing changes in the normal direction and the tangential direction of the magnetic flux density of the developing roll used in Comparative Example 1.
FIG. 16 is an explanatory diagram showing changes in the normal direction and the tangential direction of the magnetic flux density of the developing roll used in Comparative Example 2.
FIG. 17 is an explanatory diagram illustrating a toner intake characteristic of the developing device according to the example.
FIG. 18 is an explanatory diagram illustrating a toner intake characteristic of the developing device according to Comparative Example 1.
FIG. 19 is an explanatory diagram illustrating a toner intake characteristic of the developing device according to Comparative Example 2.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Developer carrier, 2 ... Regulatory member, 3 ... Developer accommodation part, 4 ... Toner accommodation part, 5 ... Rotating member, 6 ... Auxiliary regulation member, 7 ... Image carrier, 8 ... Developing device, 10 ... Magnetic field Generating means, 11 (11a to 11d): magnetic poles, G: two-component developer, Q: opposing position between developer carrier and rotating member, Z: electrostatic latent image

Claims (6)

A developer carrying member having a magnetic field generating means therein and carrying and carrying a two-component developer containing a toner and a magnetic carrier,
A regulating member for regulating an amount of developer conveyed on the developer carrying member;
A developer accommodating portion that accommodates the developer adjacent to the developer carrier and upstream of the regulating member;
A toner accommodating portion provided in communication with the developer carrying member via the developer accommodating portion and accommodating toner therein;
The toner from the toner storage unit is provided in the developer storage unit, rotates in contact with or close to the developer carrier, and applies a rotational force to the developer in the developer storage unit. With a rotating member to take in,
Of the magnetic poles of the magnetic field generating means, the magnetic force pattern of the magnetic pole closest to the rotating member is displaced on the downstream side of the developer carrying direction on the developer carrying member with respect to the position where the developer carrying member and the rotating member face each other. A developing device. The developing device according to claim 1,
Of the magnetic poles of the magnetic field generating means, the magnetic force pattern by the magnetic pole closest to the rotating member is such that the position where the component of the magnetic flux density in the normal direction is a peak is located downstream of the position where the developer carrier and the rotating member face each other. A developing device, wherein the developing device is located. The developing device according to claim 1,
Among the magnetic poles of the magnetic field generating means, the magnetic force pattern by the magnetic pole closest to the rotating member is such that the position where the tangential component of the magnetic flux density is 0 is located downstream from the position where the developer carrier and the rotating member face each other. A developing device. The developing device according to claim 1,
A developing device, wherein the rotating member has magnetism. The developing device according to claim 1,
A developing device, wherein the rotating member is a roll-shaped member whose surface is roughened. In an image forming apparatus including an image carrier and a developing device that visualizes an electrostatic latent image on the image carrier,
An image forming apparatus, wherein the developing device according to claim 1 is used as the developing device.

Images