JP4375047B2 - Developing device and image forming apparatus using the same - Google Patents

Description

  The present invention relates to a developing device used in an image forming apparatus such as a copying machine or a printer, and in particular, uses a two-component developer including a magnetic carrier and a toner, and does not use a toner concentration detecting means. The present invention relates to a developing device that autonomously controls the image forming apparatus and an image forming apparatus using the developing device.

Japanese Patent Publication No. 5-67233 JP-A-5-119625 Japanese Patent Laid-Open No. 9-22178 JP 2000-352877 A JP-A-9-197833

  In general, as a developing device used in an image forming apparatus such as an electrophotographic system, an electrostatic latent image formed on an image carrier such as a photosensitive drum is visualized with a developer. Yes. As a developing system used in this type of developing device, a one-component developing system that uses only toner that is colorant particles as a developer, and a carrier that is magnetic particles and toner that is colored particles are mixed and stirred as a developer. It is roughly divided into a two-component development system using the above.

  2. Description of the Related Art Conventionally, as a two-component developing type developing device, there are many excellent points such as image quality, cost, and stability. Therefore, there is a magnetic brush developing method in which a developer in which toner is mixed in a magnetic carrier is conveyed and developed by a magnetic field. Widely used. In this magnetic brush developing method, the toner is supported on the surface of the magnetic carrier by the electrostatic force generated by the friction between the toner and the magnetic carrier. When the toner approaches the electrostatic latent image on the image carrier, The electrostatic latent image is visualized by flying on the electrostatic latent image by an electric field formed between the electrostatic latent image carrier and the developer carrier. Further, the developer is repeatedly used while replenishing the toner consumed by the development.

  However, in such a magnetic brush developing method, if the toner concentration (mixing ratio of toner and magnetic carrier) is not controlled to be within a certain range, toner scattering and fogging occur when the toner concentration increases. On the other hand, when the toner density is reduced, density reduction, density spots, image omission, and the like occur. Therefore, it is necessary to keep the toner density constant in order to obtain a stable image.

  Therefore, in the conventional magnetic brush development method, in order to obtain a stable image, the toner density is detected using a toner density sensor, or a development patch is created to detect the toner development amount. Control is performed to keep the toner density constant by operating. For example, when the toner density is detected by the toner density sensor and it is determined that the toner density has decreased based on the detection information, the toner supply is performed by the toner supply member.

  However, in this type of magnetic brush developing method, a toner density sensor and a toner replenishing member that can be independently driven ON / OFF are indispensable, and an increase in the size and cost of the developing device cannot be avoided. In addition, there is a problem that the toner density detection system is troublesome, such as creating a density patch to be detected.

  As a prior art for solving such a problem, a developing device and a control method for maintaining a constant toner density without using a toner density sensor or a toner replenishing member have already been proposed (see, for example, Patent Documents 1 to 5). . Such a developing apparatus has a developer accommodating portion that accommodates a two-component developer, and a toner accommodating portion that communicates with the developer accommodating portion and accommodates toner, and the amount of the two-component developer on the developer carrier is reduced. The toner density is adjusted by regulating by the regulating member and autonomously controlling the toner intake of the two-component developer by changing the toner density of the two-component developer on the developer carrier.

  In addition, the autonomous control method generates a developer moving layer carried and transported by the developer carrier and a developer circulation layer in which the developer circulates in the developer container, and communicates with the developer container. The toner is taken in from the toner container. That is, when toner is consumed in the development process, the volume of the developer stored in the developer storage unit decreases, and the reduced amount of toner is supplied from the toner storage unit to the developer storage unit. The developer in the developer container holds the toner concentration.

  As an example of the developing device, in Patent Document 1, a magnetic particle layer is formed on a developing sleeve, and toner is accommodated in the toner supply unit in the container so as to come into contact with the magnetic particle layer. By the movement of the magnetic particles in the magnetic particle layer, the toner supply unit takes in the toner from the outer toner layer into the magnetic particle layer, and the developer in which the toner and the magnetic particles are mixed is regulated by the regulating member. By transporting the toner to the developing unit, insufficient charging due to excessive supply of toner is prevented.

  In Patent Document 2, in a developing sleeve rotating type magnetic brush developing device having an internal magnetic pole, an insulating layer is provided on the surface of the developing sleeve, a toner supply roll is provided near the developing sleeve, and the toner supply roll and the developing sleeve are provided. By applying an alternating voltage between them, the toner concentration and toner charging are stabilized.

  Further, Patent Document 3 uses a magnetic toner as a toner constituting the developer to stabilize toner charging and prevent toner scattering.

  Further, in Patent Document 4, the toner density is configured to be equal to or less than the limit toner density at which the toner is completely covered on the surface of one carrier when the developer carrying speed is the fastest. Therefore, it is intended to prevent soiling and toner scattering.

  Further, in Patent Document 5, in the developer accommodating portion, the second upstream of the developer carrying member in the developer carrying direction relative to the first regulating member that regulates the amount of developer carried and carried by the developer carrying member. Therefore, the toner density adjustment is simplified.

  However, in each of the above prior arts, the toner concentration is controlled by the change in the volume of the developer corresponding to the change in the toner concentration and the movement of the developer. It is necessary to make the movement of Under such demands, it is necessary to reduce the amount of developer charged around the developer carrying member and to make the volume change and the like remarkable, as compared with the usual two-component development method. The circulation of the developer is poor, and there are a portion where the developer moves actively and a portion where the developer moves inactive, so that the toner is not uniformly captured. Furthermore, if the magnetic carrier comes out of the main body of the developing device due to deterioration of charging performance or magnetization characteristics and the amount of magnetic carrier in the developer containing chamber decreases, the toner amount ratio to the amount of magnetic carrier in the developer containing portion becomes large when the toner concentration is stable. Become. As a result, there has been a problem in that sufficient toner charging is not performed and background contamination and toner scattering occur.

  In addition, since the amount of developer is small, the absolute amount of toner contained in the developer is small, and even if the toner concentration is reduced, the volume fluctuation of the developer is gradual and the toner intake speed is slow. When a high-density image with high intensity is output continuously, there is a problem that a desired density cannot be maintained.

  Furthermore, since the developer amount must be set small in advance, the stress applied to one magnetic carrier is increased, and the life of the magnetic carrier is shortened. That is, the running cost is increased and the response is slow, so that there is a problem that the density of the high-density image cannot be secured.

  In order to solve such a problem, the present inventor previously stated in Japanese Patent Application No. 2003-185499 that a small and low-cost developing device that does not require a toner density sensor or a toner replenishing mechanism is used, and the toner charge rising characteristics are In addition to improving, stable toner concentration can be maintained even if the amount of magnetic carrier changes, so that scumming and toner scattering can be suppressed. The present invention provides a developing device and an image forming apparatus using the same that realize a long life by reducing the running cost by setting a large amount of developer in advance.

  However, in the method of the invention described above, the amount of developer retracted to the developer retracting portion becomes very large after the continuous output of high-density images and during the toner density recovery process, and the toner replenishing portion of the developer accommodating portion is large. There is a concern that a space is generated, and a large amount of toner likes the space of the developer accommodating portion, and the developer toner concentration on the developer carrier temporarily becomes higher than a desired value.

  Therefore, the present invention has been made in view of the above problems.For example, after a high-density image is continuously output and during output, even when a large amount of developer is retracted to the developer retracting portion, an excessive amount is generated at a time. An object of the present invention is to provide a developing device capable of suppressing oversaturation of the toner density of the developer carrying member and maintaining stable image quality without supplying toner to the developer containing portion, and an image forming apparatus using the same. To do.

  In order to achieve the above object, as shown in FIG. 1, the developing device of the present invention applies a two-component developer 2 containing toner and a magnetic carrier in a predetermined (arrow) direction by the magnetic force of the magnetic field generating means 1. A developer carrying body 3 to be carried and conveyed, a first developer containing portion 4a for containing the two-component developer 2 adjacent to the developer carrying body 3, and a first developer containing adjacent to the developer carrying body 3. A developer retracting portion 7 that is provided downstream of the developer carrier 3 in the developer transport direction with respect to the portion 4a and communicates with the first developer accommodating portion 4a, and the first developer accommodating portion 4a and the developer retracting portion 7 In contrast, a part of the two-component developer 2 that is provided downstream of the developer carrying member 3 in the developer carrying direction and carried and carried by the developer carrying member 3 is damped as an excess developer, and the second developer 2 is transferred according to the toner concentration. The excess developer is separated into one developer containing portion 4a or developer retracting portion 7. The toner concentration of the two-component developer 2 that is provided in communication with the developer carrier 3 via the first developer container 4 a and is carried and conveyed by the developer carrier 3. A second developer accommodating portion 4b that accommodates the two-component developer 2 having a high toner concentration so as to be supplied to the first developer accommodating portion 4a, and the first developer accommodating portion 4a and the second developer accommodating portion 4b. And a toner container 5 that is provided in communication with the developer carrier 3 and accommodates the second developer container 4b so that toner can be supplied.

  In such technical means, the developer carrier 3 may be appropriately selected as long as the developer carrier 3 includes the magnetic field generating means 1 inside and conveys and carries the two-component developer 2, and can be rotated, for example. There is a mode in which a nonmagnetic sleeve and a magnet member fixedly disposed in the nonmagnetic sleeve and provided with the magnetic field generating means 1 are provided.

  Here, the magnetic field generating means 1 may be any one having a plurality of magnetic poles 10. For example, as a configuration example of the magnetic poles 10, a developing magnetic pole 10 a for contributing to development and a developer can be captured. Examples include a pickup magnetic pole 10c having a function, and conveyance magnetic poles 10b and 10d for conveying the developer, but are not limited thereto, and may be appropriately selected. The toner may be magnetic or nonmagnetic as long as it adheres to the magnetic carrier.

  The first developer accommodating portion 4a may be any one that accommodates the two-component developer 2 adjacent to the developer carrier 3, and the second developer accommodating portion 4b includes the first developer accommodating portion 4a and the first developer accommodating portion 4a. Any one that contains the two-component developer 2 having a higher toner concentration than the two-component developer 2 that communicates and contributes to the development carried and conveyed by the developer carrier 3 may be used. In order to realize such an aspect, the two-component developer 2 accommodated in the second developer accommodating portion 4b is more than the average toner concentration of the two-component developer 2 accommodated in the first developer accommodating portion 4a. The average toner concentration is preferably high. Further, in order to allow the first developer container 4a to uniformly take in the two-component developer having a high concentration from the second developer container 4b, a stirring member or the like is provided in the first developer container 4a. Is preferred. Thus, by providing the stirring member in the first developer accommodating portion 4a, the two-component developer supplied from the second developer accommodating portion is sufficiently stirred and mixed, and then supplied to the developer carrier 32. As a result, the chargeability of the toner in the two-component developer can be stabilized and the toner density on the developer carrier 3 can be made uniform. Further, the toner storage unit 5 may be any unit that communicates with the second developer storage unit 4b and stores the toner in the second developer storage unit 4b so that toner can be supplied.

  The developer retracting unit 7 temporarily stores the two-component developer 2 from the first developer storage unit 4a, and temporarily lacks or flows the two-component developer 2 in the first developer storage unit 4a. As long as the two-component developer having a high toner concentration from the second developer accommodating portion 4b is guided to the first developer accommodating portion 4a, it is only necessary. According to this aspect, the circulation in the first developer accommodating portion 4a is improved, and the space in the first developer accommodating portion 4a or the two-component developer flow portion generated by retracting the developer in the developer retracting portion 7 is achieved. In addition, a two-component developer having a high toner concentration can be replenished, and the concentration of the entire developer in the first developer accommodating portion 4a can be increased.

  Here, the high-concentration two-component developer is a two-component developer having a higher toner weight ratio than the two-component developer in which the toner concentration is saturated. Further, the two-component developer in which the toner concentration is saturated means that the two-component developer 2 carried and transported by the developer carrier 3 is first changed by the developer separating means 8 according to the toner concentration. This is a two-component developer having a toner concentration in a boundary state when separated and introduced into the developer accommodating portion 4a side or the developer retracting portion 7 side (hereinafter, this toner concentration is referred to as a saturated toner concentration). Sometimes called).

  Furthermore, in order to generate the circulation path 6 that passes through the developer storage portions 4a and 4b and the developer retracting portion 7 and to activate the flow of the two-component developer 2, on the upstream side of the developer separating means 8, A partition portion 12 is provided to separate the first developer accommodating portion 4a and the developer retracting portion 7, and the two-component developer 2 separated and introduced into the developer retracting portion 7 by the partition portion 12 is supplied to the first developer accommodating portion. It is preferable to be configured to flow out to both 4a and the second developer accommodating portion 4b.

  Such a circulation path 6 is formed by, for example, communicating the first developer accommodating portion 4a and the developer retracting portion 7 at least at two locations, thereby allowing the two-component developer 2 from the first developer accommodating portion 4a to be communicated. May enter the developer retracting portion 7 from the vicinity of the developer carrier 3 and return to the first developer accommodating portion 4a again. The circulation path 6 passing through the partition member 12 in the present invention communicates with the first developer accommodating portion 4a on the upstream side with respect to the developer flow direction, and the first developer accommodating portion 4a and the second development on the downstream side. It is necessary to communicate with the agent container 4b. Here, the position and size of the circulation path 6 may be appropriately selected.

  In this case, since the second developer accommodating portion 4 b needs to accommodate the two-component developer 2 flowing out from the developer retracting portion 7 on the partition member 12, the bottom surface thereof communicates with the developer retracting portion 7. It suffices if the positional relationship is lower in the direction of gravity than the portion.

  Further, the developer separating means 8 may be any one that separates the two-component developer 2 conveyed by the developer carrier 3 according to the toner concentration (the toner ratio with respect to the magnetic carrier). At this time, the developer separating means 8 is a mode in which the path of the two-component developer 2 is made different according to the toner concentration. Usually, the two-component developer 2 having a low toner concentration is developed out of the excess developer. A mode in which the two-component developer 2 having a high toner concentration is separated into the first developer accommodating portion 4a is employed in the agent retracting portion 7. Here, the surplus developer is the two-component developer 2 that is not conveyed to the image carrier 9 side among the two-component developer 2 carried and conveyed by the developer carrier 3.

  Further, in order to stop the excess developer from the two-component developer 2 carried and conveyed by the developer carrier 3 and prevent the excess developer from being conveyed to the image carrier 9 side, for example, a developer separating unit. It is preferable that 8 has a damming portion 11 which is disposed so as to face the developer carrier 3 and dams excess developer. Further, the developer separating means 8 preferably includes a magnetic pole 10 (for example, a transport magnetic pole 10b) which is a magnetic field generating means 1 provided on the developer carrier 3.

  In this case, in the two-component developer 2 having a low toner concentration, since the amount of toner in the developer is small, the magnetic carrier density per unit volume is high and the magnetic attractive force received from the external magnetic field is increased. In the two-component developer 2 having a high value, the amount of toner covering the surface of the magnetic carrier is large, so the density of the magnetic carrier per unit volume decreases, the magnetization of the developer decreases, and the magnetic attractive force received from the outside decreases. By utilizing the property, the developer flow is separated according to the toner concentration.

  That is, according to the developer separating means 8 formed by combining the damming portion 11 and the magnetic pole 10, when the two-component developer 2 transported by the developer carrier 3 has a low toner concentration, Since the magnetic attraction force attracted to the surface is large, the conveyance force to the two-component developer 2 due to the rotation of the developer carrier 3 is increased, and the retention force is retained by the damming force of the damming portion 11 and the magnetic restraining force of the conveyance magnetic pole 10b. The two-component developer (low toner concentration) 2 is pushed out, and the pushed two-component developer 2 with low toner concentration moves to the developer retracting section 7.

  On the other hand, when the two-component developer 2 conveyed by the developer carrier 3 has a high toner concentration, the two-component developer generated by the rotation of the developer carrier 3 because the magnetic attraction force attracted inside the developer carrier 3 is small. The conveyance force with respect to the developer 2 is weak, and the two-component developer 2 staying in the damming portion 11 cannot be pushed out. Therefore, it does not reach the two-component developer 2 staying in the damming portion 11 but falls halfway and returns to the first developer accommodating portion 4a. This operation utilizes the above-described property due to the difference in toner density.

  Further, from the viewpoint of forming a large number of rising states of the two-component developer 2 on the developer carrier 3 and blocking the two-component developer 2 by the blocking portion 11, the blocking portion 11 constituting the developer separating means 8 is The developer carrier 3 is preferably disposed adjacent to the downstream side of the transport magnetic pole 10b with respect to the developer transport direction. At this time, if the arrangement position and magnetic field strength of the magnetic pole 10 as the magnetic field generating means 1 in the developer carrier 3 are changed as the developer separating means 8, the first developer accommodating portion 4 a or the developer retreat The degree of toner concentration (saturated toner concentration) of the two-component developer 2 separated into the unit 7 can be variably set.

  Further, from the viewpoint of regulating the layer thickness of the two-component developer 2 without separately providing a regulating member that regulates the amount of the two-component developer 2 conveyed by the developer carrier 3, the damming portion 11 is used for developing. It is preferable to also use a regulating member that regulates the developer layer carried on the agent carrying body 3.

  From the viewpoint of easily guiding the two-component developer 2 having a low toner concentration in the developer retracting section 7 to the first developer accommodating section 4a or the second developer accommodating section 4b, The partition portion 12 that separates the one developer accommodating portion 4a allows the two-component developer 2 in the developer retracting portion 7 to be more developer than either the first developer accommodating portion 4a or the second developer accommodating portion 4b. It is preferable to be inclined so as to guide

  The partition 12 is preferably set higher on the developer carrier 3 side than the opposite end. However, the present invention is not limited to this aspect, and the center of the partition 12 is set low, and the second portion is formed in this portion. It may be selected as appropriate, for example, by providing a circulation path 6 leading to one developer accommodating portion 4a or the second developer accommodating portion 4b.

Further, from the viewpoint of securing the supply amount of the two-component developer 2 to the developer carrier 3, the gap between the developer carrier 3 and the partitioning portion 12 between the developer retracting portion 7 and the first developer accommodating portion 4 a. Is preferably set larger than the gap between the damming portion 11 and the developer carrier 3.
The present invention is not limited to the above-described developing device, and an image forming apparatus that visualizes the electrostatic latent image on the image carrier 9 by using these developing devices is also an object.

  According to the present invention, there is provided a developer separating means that blocks a part of the two-component developer conveyed by the developer carrying member as an excess developer and separates it into the developer accommodating portion or the developer retracting portion according to the toner concentration. Therefore, when the toner concentration is low, the two-component developer is temporarily guided to the developer retracting portion, thereby enhancing the bulk change and fluidity of the two-component developer in the first developer accommodating portion. As a result, the two-component developer in the developer accommodating portion can quickly take in the two-component developer having a high toner concentration in the second developer accommodating portion. For this reason, the toner take-in speed is significantly increased, and it is possible to cope with continuous output of high-density images.

  In the present invention, the saturated toner concentration on the developer carrying member depends on the magnetic attractive force acting on the two-component developer and does not depend on the bulk of the two-component developer. Even when the amount of the magnetic carrier decreases, the saturated toner concentration can be maintained at a stable value.

  Further, even when a large amount of developer is retracted to the developer retracting portion after the high-density image is being output, the developer is not supplied to the first developer accommodating portion at one time. Since the toner density of the carrier does not become supersaturated, stable image quality can be maintained.

Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.
<Embodiment>

  First, a schematic configuration of an image forming apparatus including a developing device according to the present invention will be described with reference to FIG. FIG. 2 is a schematic configuration diagram showing an embodiment of an image forming apparatus according to the present invention.

  In FIG. 2, reference numeral 21 denotes an electrostatic latent image carrier made of an organic photoreceptor that rotates in the direction of the arrow. The electrostatic latent image carrier 21 is charged by a charging device 22 such as a scorotron, An electrostatic latent image is written by the exposure device 23 having an LED array. This electrostatic latent image is formed as a potential image based on a contrast with a high potential portion not exposed to light because the surface potential of the electrostatic latent image carrier 21 exposed to light is lowered. Further, the developing device 24 accommodates a two-component developer composed of toner and carrier as colored particles in a developing housing 31, and supports the two-component developer on a developer carrier 32, and this developer carrier 32. By applying a developing bias from the bias power source 25 to the toner, the developer carrier 32 is held at an intermediate potential between the high potential portion and the low potential portion of the electrostatic latent image, and the image portion of the electrostatic latent image is charged. The toner is developed with toner. Further, the transfer device 26 is constituted by, for example, a transfer roll disposed in contact with the electrostatic latent image carrier 21, and applies a transfer bias in a direction in which the toner image on the electrostatic latent image carrier 21 is attracted by the bias power source 27. By being applied, the toner image on the electrostatic latent image carrier 21 is transferred to the recording material 28. The toner remaining on the electrostatic latent image carrier 21 is removed by, for example, a doctor blade type cleaning device 29.

  Further, in the present embodiment, the recording material 28 to which the toner image on the electrostatic latent image carrier 21 is transferred is conveyed to the fixing device 50, and the toner image is fixed to the recording material 28 by the fixing device 50. The The fixing device 50 has, for example, a heat roll method, and includes a heating roll 51 and a pressure roll 52. By passing the recording material 28 between the heating roll 51 and the pressure roll 52, the toner image is recorded. 28 is fixed.

  Next, the configuration of the developing device according to the present embodiment will be described with reference to FIG. FIG. 3A is a configuration diagram showing an outline of the developing device according to the present embodiment, and FIG. 3B is an enlarged view of a partition portion and its peripheral portion.

  In FIG. 3, the developing device 24 has a developing housing 31 that opens toward the electrostatic latent image carrier 21, and a developer carrier 32 is disposed facing the opening of the developing housing 31. 31, a portion adjacent to the developer carrier 32 has a first developer accommodating portion 33a that accommodates the two-component developer G, and a portion adjacent to the developer carrier 32 and the first developer accommodating portion 33a. On the other hand, two-component development with a high toner concentration communicated with the developer carrier 32 via the developer retracting part 34 provided downstream of the developer carrier 32 in the developer conveying direction and the first developer container 33a. A developer carrying member 32 via a second developer containing portion 33b containing the two-component developer G flowing out from the developer and developer retracting portion 34, and the first developer containing portion 33a and the second developer containing portion 33b. To the second developer container 33b. It is obtained by forming a toner accommodating portion 35 for accommodating the toner T to be fed.

  In the present embodiment, the two-component developer G is a developer composed of toner T and a magnetic carrier, and the toner T uses, for example, a non-magnetic toner. Magnetic toner may be used.

  Further, in the present embodiment, the developer carrier 32 includes a rotatable rotating sleeve 321 and a magnetic pole roll 322 fixedly disposed inside the rotating sleeve 321. The magnetic pole roll 322 has, for example, a conveying magnetic pole (S2 in this example) aligned with the right side of the horizontal plane passing through the roll body center O, and the conveying magnetic pole (S2) with respect to the rotation direction (counterclockwise) of the rotating sleeve 321. ) From the transport magnetic pole (S2) to the upstream side at 30 ° intervals, while the transport magnetic pole (N2 in this example) and the developing magnetic pole (S1 in this example) are arranged downstream from the transport magnetic pole (30). In this example, N1), a transfer magnetic pole (S3 in this example), and a transfer magnetic pole (N3 in this example) are arranged.

  In the present embodiment, the development magnetic pole (S1) faces the electrostatic latent image carrier 21, and the pickup magnetic pole (N1) captures the two-component developer G in the first developer accommodating portion 33a. However, the arrangement and number of magnetic poles may be appropriately selected.

  On the other hand, the rotating sleeve 321 rotates counterclockwise, and faces the electrostatic latent image carrier 21 in the developing portion where the developing magnetic pole (S1) of the magnetic pole roll 322 is disposed.

  In the present embodiment, the first developer accommodating portion 33a has a space for accommodating the two-component developer G, and is close to (or in contact with) the developer carrier 32 in the first developer accommodating portion 33a. ), The first developer stirring member 36a is rotatably (clockwise) disposed. Further, the bottom shape of the first developer accommodating portion 33a has a curved shape along the developer carrier 32 and the first developer agitating member 36a, and the developer carrier 32 and the first developer agitating member 36a. A developer conveyance path having a predetermined interval is secured between the two.

  In the present embodiment, the first developer agitating member 36a is made of, for example, a magnetic or non-magnetic roll, but may be a spiral auger or a plurality of them may be provided.

  The two-component developer G stirred by the first developer stirring member 36a is captured in the vicinity of the pickup magnetic pole (N1) of the developer carrier 32, and is carried and conveyed by the rotation of the rotating sleeve 321 of the developer carrier 32. It has become so.

  In the present embodiment, the second developer accommodating portion 33b has a space for accommodating a two-component developer having a higher toner concentration than the two-component developer G supported and conveyed by the developer carrier 33 and contributing to development. The toner T supplied from the toner storage unit 35, the two-component developer G flowing out from the developer retracting unit 34, and the existing two-component developer having a high toner concentration, and the first developer storage unit A second developer agitating member 36b for conveying to 33a is provided. Specifically, for example, a two-component developer having an average toner concentration that is about three times higher than the average toner concentration of the two-component developer housed in the first developer container 33a is the second developer container. It is preferable to be accommodated in 33b. The second developer agitating member 36b is formed, for example, by attaching an elastic film to a rotating body, and sweeps out a two-component developer having a high toner concentration along the bottom wall surface of the second developer accommodating portion 33b. It is. The second developer agitating member 36b also has a function of drawing the toner T from the toner accommodating portion 35 into the second developer accommodating portion 33b and agitating and mixing with the two-component developer G.

  And the bottom part shape of this 2nd developer accommodating part 33b has the curved shape along the movement rotation locus | trajectory of the 2nd developer stirring member 36b, The 1st developer accommodating part 33a and the 2nd developer accommodating part A developer replenishment path 37a is provided at a connecting portion between the developer supply path 33b and the connecting portion 33b.

  Further, in the present embodiment, the toner storage unit 35 includes a toner stirring member 351 that stirs the toner T stored therein and transports the toner T to the second developer storage unit 33b. For example, an elastic film is attached to the rotating body, and the toner T is swept out along the bottom wall surface of the toner containing portion 35.

  The bottom shape of the toner accommodating portion 35 has a curved shape along the movement rotation locus of the toner agitating member 351, and a connecting portion between the second developer accommodating portion and the toner accommodating portion 35 includes A toner supply path 37b is provided.

  In the present embodiment, the first developer accommodating portion 33a and the developer retracting portion 34 are separated by a partition portion 39. For example, as shown in FIG. 3B, the partition portion 39 has a base plate 39a formed with a width approximately the same as that of the developer carrier 32. The base plate 39a has a developer carrier 32 side facing upward. , And are arranged obliquely downward so that the opposite side is downward. The inclined portion of the base plate 39a is set so that a part of the developer flowing on the inclination flows out to the first developer accommodating portion 33a and the surplus portion flows out to the second developer accommodating portion 33b. The tip 39b of the base plate 39a located on the developer carrier 32 side is directly above the transport magnetic pole (N2) in the developer carrier 32 or upstream from the transport magnetic pole (N2) in the developer transport direction ( The surface of the developer carrier 32 is opposed to the surface of the developer carrier 32 at a position of several hundred μm to several mm.

  On the other hand, the other end 39c opposite to the tip 39b is shaped to form the upper wall surface of the developer supply path 37a described above. The inclination angle of the base plate 39a may be arbitrarily set.

  In the present embodiment, the developer retracting portion 34 and the first portion 39b between the leading end portion 39b of the partition portion 39 and the developer carrying member 32 and the developer supply path 37a are connected to the first and second developer retracting portions 34b through the second developer containing portion 33b. A circulation path 40 that communicates with the developer accommodating portion 33a is formed.

  In the circulation path 40, for example, the two-component developer G in the first developer accommodating portion 33a flows into the developer retracting portion 34 from the tip end portion 39b side, and the inflowed two-component developer G flows into the other end portion 39c. From the side, the second developer containing portion 33b and the developer supply path 37a flow out to the first developer containing portion 33a. At this time, all of the two-component developer G flowing out from the other end 39c does not flow out into the first developer accommodating portion 33a via the developer supply path 37a, but a part thereof is the second developer. It flows out to the accommodating part 33b. As described above, the chargeability of the toner in the two-component developer G can be further stabilized by allowing the toner to flow out and circulate through both the first developer container 33a and the second developer container 33b.

  Here, the ratio of the amount of developer flowing out from the developer retracting portion 34 to the first developer accommodating portion 33a or the second developer accommodating portion 33b can be appropriately selected. For example, if a large amount of developer is caused to flow out of the first developer accommodating portion 33a, the developer is caught in the flow of the developer having a large flow rate flowing out from the developer retracting portion 34 to the first developer accommodating portion 33a, and the second developer accommodating portion 33a. The high-concentration two-component developer in the developer accommodating portion 33b is taken into the first developer accommodating portion 33a, and the high-density two-component developer taken in by this large flow rate is stirred and mixed. On the other hand, if a large amount of developer is caused to flow out into the second developer accommodating portion 33b, the developer is supplied to the first developer accommodating portion 33a through stirring and mixing in the second developer accommodating portion 33b. Thus, the two-component developer G having a uniform toner concentration by sufficient stirring and mixing can be supplied.

  Further, in the present embodiment, the transport magnetic pole (N2), the development magnetic pole (S1), and the transport magnetic pole (N2) in the developer carrier 32 are positioned downstream of the transport magnetic pole (N2) in the developer transport direction (counterclockwise direction side). Between them, a damming portion 41 is disposed so as to face the developer carrier 32. The damming portion 41 has the same width as the developer carrier 32, one end is supported by the development housing 31, and the tip is close to the developer carrier 32 with a gap of several tens to several hundreds of μm. I am letting.

  In the present embodiment, since a large amount of the two-component developer G is supplied to the damming portion 41, the gap between the tip 39b of the partitioning portion 39 and the developer carrying member 32 is the damming portion 41 and the developer. It is set wider than the gap with the carrier 32.

  In the present embodiment, the damming portion 41 also serves as a layer thickness regulating function that regulates the layer thickness of the two-component developer G carried and conveyed by the developer carrier 32. What is the layer thickness regulating function? You may make another. In this case, for example, a mode in which the layer thickness regulating member 42 is provided between the damming portion 41 and the developing magnetic pole (S1) can be mentioned.

  Next, the operation of the image forming apparatus according to the present embodiment will be described focusing on the developing device.

  In FIG. 3, the two-component developer G in the first developer accommodating portion 33a is agitated by the first developer agitating member 36a and captured by the pickup magnetic pole (N1) in the developer carrier 32. Thereafter, the two-component developer G that has been captured is subjected to the developer carrier 32 (rotating sleeve 321) by the magnetic attraction force of the pickup magnetic pole (N1) and the transport magnetic pole (S2) and the frictional force between the surface of the developer carrier 32. ) In the rotation direction. When the transported two-component developer G reaches the vicinity of the damming portion 41, a spike is formed by the transport magnetic pole (N2). Further, the rising of the two-component developer G is regulated by the damming portion 41, so that the developer layer is formed on the developer carrier 32, and this developer layer is conveyed to the development area. . Further, the developer layer of the two-component developer G conveyed to the development area forms a magnetic brush by the magnetic attraction force of the developing magnetic pole (S1), and the toner T in the two-component developer G forming this magnetic brush is The electrostatic latent image on the electrostatic latent image carrier 21 is visualized by a developing electric field formed between the electrostatic latent image carrier 21 and the developer carrier 32.

  Next, the behavior of the two-component developer G in the vicinity of the damming portion 41 will be described with reference to FIGS.

  First, in FIG. 4, it is assumed that the toner density of the two-component developer G carried and conveyed by the developer carrier 32 is low. Since the two-component developer G has a small amount of toner in the developer, the magnetic carrier density per unit volume is relatively large. That is, since the magnetic attraction force received by the two-component developer G from the external magnetic field (N2 in this example) increases, the two-component developer G having a low toner concentration is reliably conveyed to the vicinity of the damming portion 41. The two-component developer G reliably transported to the damming portion 41 pushes out the staying developer staying near the damming portion 41 by the damming force of the damming portion 41 and the magnetic restraining force of the conveying magnetic pole (N2). The pushed-out staying developer becomes a falling developer and falls onto the partition portion 39, passes through the developer retracting portion 34, and then flows into the second developer accommodating portion 33b as shown in FIG.

  At this time, when the two-component developer G having a low toner concentration is led to the developer retracting portion 34 as described above, as shown in FIG. 5, there is a corresponding space in the first developer accommodating portion 33a. Will be made. As a result, the two-component developer G in the developer supply path 37a from the developer supply path 37a to the first developer accommodating portion 33a is transported by the first developer stirring member 36a and the two-component developer. Due to the weight of G, the two-component developer in the vicinity of the developer supply path 37a is quickly drawn into the space and flows. As a result, the developer supply path 37a receives the two-component developer G having a high toner concentration from the second developer accommodating portion 33b, and the two-component developer G having a high toner concentration passes through the developer supply path 37a. The toner is quickly supplied to the first developer accommodating portion 33a. Further, in the second developer accommodating portion 33b, a space for receiving the toner from the toner accommodating portion 35 is formed corresponding to the amount of developer supplied to the first developer accommodating portion 33a, which is in the toner replenishment path 37b. The toner T is quickly supplied to the second developer accommodating portion 33b by the drawing of the second developer stirring member 36b, the weight of the toner T and the sweeping of the toner stirring member.

  On the other hand, assuming that the toner concentration of the two-component developer G carried and conveyed by the developer carrier 32 is high, the two-component developer G has a large amount of toner covering the surface of the magnetic carrier, The magnetic carrier density per unit volume is small. That is, as shown in FIG. 6, since the magnetic attraction force received by the two-component developer G from the external magnetic field (N2 in this example) is small, most of the two-component developer G having a high toner concentration is in the developer carrier 32. It will fall in the position of the upstream side rather than the front-end | tip of the partition part 39 with respect to a rotation direction. As a result, the two-component developer G does not reach the staying developer staying in the vicinity of the damming portion 41 and does not fall on the partition portion 39. For this reason, as shown in FIG. 7, the two-component developer G does not fall on the partition portion 39, and is upstream of the tip end portion 39 b of the partition portion 39 with respect to the rotation direction of the developer carrier 32. It falls at the position and returns directly to the first developer accommodating portion 33a. At this time, unlike the case where the toner density is low, no space is created in the first developer accommodating portion 33a, and the two-component developer G in the vicinity of the developer supply path 37a does not flow. Thus, the two-component developer G having a high toner concentration is not supplied from the second developer accommodating portion 33b. Similarly, no space for receiving the toner T from the toner storage unit 35 is formed in the second developer storage unit 33b, and thus the toner T is not supplied.

  As described above, the toner replenishment mechanism according to the present embodiment uses the change in magnetic attraction force in addition to the change in fluidity and bulk of the two-component developer G according to the toner concentration. The toner is supplied to the low two-component developer G, and the toner is not supplied to the two-component developer G having a high toner concentration.

  That is, according to the present embodiment, when the toner density is low, the two-component developer G is temporarily guided to the developer retracting portion 34 to thereby cause the two-component developer in the first developer accommodating portion 33a. The bulk change and fluidity of G are emphasized, and accordingly, the two-component developer G in the first developer accommodating portion 33a is two-component developed with a high toner concentration in the second developer accommodating portion 33b. The agent can be quickly taken in, and the continuous output of high-density images can be supported. Further, the toner T is supplied from the toner container 35 to the second developer container 33b in a space formed by the supply of the two-component developer having a high toner concentration to the first developer container 33a. Is done. Further, due to the mechanism described above, the saturated toner concentration on the developer carrier 32 depends on the magnetic attractive force acting on the two-component developer and does not depend on the volume of the two-component developer. Even when the amount of magnetic carrier in the apparatus is reduced, the saturated toner concentration is maintained at a stable value. When the two-component developer having a high toner concentration is supplied from the second developer accommodating portion 33b, the two-component developer G passes through the developer retracting portion 34, so that the two components in the first developer accommodating portion 33a are provided. Since the circulation of the developer G becomes very active, the two-component developer having a high concentration is uniformly taken in. Further, the bulk change and fluidity of the two-component developer G are emphasized, and the magnetic carrier may flow out from the first developer accommodating portion 33a and the developer retracting portion 34 to the second developer accommodating portion 33b. Since it is a structure, it is not necessary to increase the developer density in the first developer accommodating portion 33a and the amount of the developer to be charged can be increased, so that stress on the developer is reduced and the length of the developer is reduced. Life expectancy and low running cost can be realized. Further, the amount of developer retracted to the developer retracting section 34 becomes very large after the high density image continuous output and during the toner density recovery process during the output, and the developer supply path 37a of the first developer accommodating section 33a is greatly opened. Even in this case, since the two-component developer having a high toner concentration is supplied, excess toner does not enter the first developer accommodating portion 33a at a time, so that the toner concentration on the developer carrying member is reduced. There is no supersaturation. As a result, stable image quality can be maintained.

  The range of the toner concentration of the two-component developer G that falls onto the partition 39 and is guided to the developer retracting section 34 will be described in detail in the following embodiments.

In this example, two-component development that falls on the partition 39 when the transport magnetic pole (N2 or S2) of the magnetic pole roll 322 is changed using the developing device (see FIG. 3) according to the above-described embodiment. The relationship between the flow rate of the agent G and the concentration range of the toner is measured. In this embodiment, the conditions of the image forming apparatus excluding the developing device are as follows (see FIG. 2).
Electrostatic latent image carrier 21: An organic photoreceptor having a diameter of 30 was used, the peripheral speed was set to 170 mm / s, the image portion potential was set to -150V, and the non-image portion potential was set to -650V.
Charging device 22: A scorotron was used, the scorotron wire was set to -4 kV, and the grit voltage was set to -400V.
Exposure device 23: An LED array capable of writing at a density of 600 dpi was used.
Transfer device 26: A transfer roll of φ12 (with a conductive rubber layer formed on a metal roll) was used, the peripheral speed was set to 170 mm / s, and the bias power source 27 was set to a direct current of 1.2 kV.
Cleaning device 29: An elastic rubber blade was used, and the abutting pressure was set to 1.5 g / mm.
Fixing device 50: A φ25 elastic roll (equipped with a power supply heater) was used as the heating roll 51, a φ25 metal roll was used as the pressure roll 52, the peripheral speed was set to 170 mm / s, and the fixing temperature was set to 180 ° C.

The conditions of the developing device in this embodiment are as follows (see FIG. 3).
Two-component developer G: As a magnetic carrier, a semiconductive particle diameter of 50 μm on average was used, and as toner T, particles containing 20% by weight of a magnetic material and having an average particle diameter of 9.0 μm were used. The initial two-component developer charge amount was 100 g in the first developer accommodating portion 33a.
Developer developing member 36: A cylindrical magnetic body of φ10 was used, and the peripheral speed was set to 240 mm / s (rotated clockwise).
Partition part 39: The partition part tip 39b was set to be 3 mm from the surface of the developer carrier 32 at a position upstream of the transport magnetic pole (N2) in the developer transport direction.
Damping portion 41: Set so as to be 400 μm apart from the surface of the developer carrier 32 on the downstream side in the developer transport direction from the transport magnetic pole (N2).
Developer carrier 32: Developer conveyance amount is 400 g / m ² , gap with electrostatic latent image carrier 21 is 350 μm, and DC component of −300 V is superposed with AC component of 1.3 kVpp and frequency of 3.5 kHz. The developed developing bias and the peripheral speed were set to 340 mm / s.
-Rotating sleeve 321: A metal sleeve of φ18 was used, and the 10-point average surface roughness Rz of the surface was set to 7 μm.
Magnetic pole roll 322: The developing magnetic pole (S1) is set to 120 mT, the conveying magnetic pole (S3) is set to 60 mT, the pickup magnetic pole (N1) is set to 80 mT, the conveying magnetic pole (N3) is set to 80 mT, and the conveying magnetic pole (S2) and the conveying magnetic pole ( N2).

  Under the above conditions, the transport magnetic pole (N2) was fixed at 40 mT, and the transport magnetic pole (S2) was changed (0 to 30 mT). As a result, the measurement results shown in FIG. 8 were obtained.

  As can be seen from the drawing, when the magnetic force of the transport magnetic pole (S2) is increased, even a developer having a high toner concentration falls onto the partition portion 39 and is guided to the developer retracting portion 34. That is, in order to set the toner density (saturated toner density) when the developer flow rate falling on the partition 39 becomes zero, the magnetic force of the transport magnetic pole (S2) may be set strongly. I understand.

  On the other hand, when the carrier magnetic pole (S2) was fixed to 30 mT and the carrier magnetic pole (N2) was changed (20 to 40 mT), the measurement results shown in FIG. 9 were obtained.

  As can be seen from the drawing, when the magnetic force of the transport magnetic pole (N2) is increased, even a developer having a high toner concentration falls onto the partition portion 39. That is, it can be seen that in order to set the toner density when the developer flow rate falling on the partition 39 becomes zero, the magnetic force of the transport magnetic pole (N2) should be set strongly. From the above measurement results, not only the magnetic pole (N2 in this embodiment) in the vicinity of the damming portion 41 but also the magnetic pole (S2 in this embodiment) on the upstream side of the developer carrier 32 in the developer carrying direction with respect to the carrying magnetic pole (N2). It is understood that the range of the toner density falling on the partition portion 39 can be controlled by selecting the strength of ().

  In this embodiment, a comparatively known developing device (developing device A) that does not include a toner density sensor and a toner replenishment mechanism is used as a comparative example, and the developing device 24 (developing device B) according to the embodiment is realized. A high density image output follow-up test was performed using the measured image density, and the change in image density at this time was measured. In addition, the image forming apparatus except the developing device is the same as that used in Example 1 (see FIG. 2). The picture chart was a 100% solid image.

  First, a conventionally known developing device (developing device A) that does not include a toner density sensor and a toner supply mechanism will be described with reference to FIG.

  As shown in FIG. 10, the developing device A has a developing housing 61 that opens toward the electrostatic latent image carrier 21, and a developer carrier 62 is disposed facing the opening of the developing housing 61. A regulating member 63 for regulating the layer thickness of the two-component developer G on the developer carrier 62 is provided at the upper edge of the opening of the development housing 61, and a portion of the development housing 61 adjacent to the developer carrier 62 is provided. Are formed with a developer accommodating portion 64 that accommodates the two-component developer G, and a toner accommodating portion 65 that communicates with the developer carrier 62 via the developer accommodating portion 64 and accommodates the toner T. It is a thing.

  The developer carrier 62 includes a rotatable sleeve 621 and a magnetic pole roll 622 fixedly disposed inside the sleeve 621. The magnetic pole roll 622 is provided with four magnetic poles (developing magnetic pole (S1), conveying magnetic pole (S2), conveying magnetic pole (N1), conveying magnetic pole (N2)) at predetermined angular intervals around the roll body. The two-component developer G containing the toner T and the carrier is magnetically attached to the outer periphery of the developer carrier 62. Further, the toner storage unit 65 includes a stirring member 651 that allows the stored toner T to be stirred and conveyed.

  In the developing device A, when the toner is consumed by the development, the volume occupied by the two-component developer G in the developer accommodating portion 64 decreases, so that a void is formed in the developer accommodating portion 64. The toner T in the toner container 65 is replenished to the gap by the rotation of the stirring member 651, and toner density control is performed.

Next, the conditions of the developing device A are shown below.
Two-component developer G: As a magnetic carrier, an average semiconductive particle diameter of 50 μm was used, and as toner T, particles containing 20% by weight of a magnetic material and having an average particle diameter of 9.0 μm were used. The initial two-component developer charge amount was 50 g, and the toner concentration was 10% by weight.
Developer carrier 62: Developer conveyance amount is 400 g / m ² , gap with electrostatic latent image carrier 21 is 350 μm, and DC component of −300 V is superposed with AC component of 1.3 kVpp and frequency of 3.5 kHz. The developed developing bias and peripheral speed were set to 340 mm / s.
Sleeve 621: A φ18 metal sleeve was used, and the surface ten-point average surface roughness Rz = 7 μm.
Magnetic pole roll 622: The developing magnetic pole (S1) was set to 120 mT, the conveying magnetic pole (S2) was set to 80 mT, the conveying magnetic pole (N1) was set to 80 mT, and the conveying magnetic pole (N2) was set to 90 mT.

On the other hand, since the developing device B is an embodiment of the developing device according to the above-described embodiment, the details are omitted. Each condition is almost the same as that in the first embodiment (see FIG. 3), but the initial charge amount and toner density of the two-component developer G are as follows.
First developer container: 100 g developer charge, 10% toner concentration
Second developer storage unit: developer charging amount 100 g, toner concentration 50% by weight

  The two-component developer G used in the developing devices A and B is the same as that in the first embodiment. Further, the transport magnetic pole N2 in the magnetic pole roll in the developer carrying body was set to 40 mT, and the transport magnetic pole S2 was set to 30 mT.

  The measurement results as shown in FIG. 11 were obtained by operating the developing device A according to the comparative example and the developing device B according to the example under the above conditions. Specifically, ten 100% black solid images were output by each of the developing devices A and B, and the image quality was evaluated by density measurement with a reflection densitometer X-Rite 404 and visual observation.

  According to the figure, in the case of the developing device A, the solid area density (solid image density) decreases from the initial value of 1.38 to 0.08 points between the first and tenth output sheets. The tolerance value was below 1.35. Further, white spots were visually observed after the eighth output sheet (the broken line portion in the figure).

  On the other hand, in the case of the developing device B, the permissible value of 1.35 or more was maintained up to the 10th output sheet, and no image quality defect such as white spot was observed even visually.

  Next, the initial value of the toner density was set to 5% by weight, and the toner density recovery characteristics when the developing devices A and B were rotated were measured, and the results shown in FIG. 12 were obtained. However, for the developing device B, the toner concentration in the first developer accommodating portion 33a is 5% by weight, and the toner concentration in the second developer accommodating portion 33b is 50% by weight. As can be seen from the drawing, in the case of the developing device A, it took about 60 seconds until the toner density returned to 10% by weight.

  On the other hand, in the case of the developing device B, it can be seen that it has returned to 10% by weight in about 10 seconds. From the above results, the developing device B of the embodiment has a faster toner capturing performance than the conventionally known developing device A that does not include a toner density sensor and a toner replenishment mechanism, and therefore has excellent tracking performance for high-density image output. It is understood that

  In this example, the developing devices A and B similar to those in Example 2 were used to print a 5 kPV half-tone image at 5 kPV, and the toner charge amount at this time was measured.

  As shown in FIG. 13, in the developing device A (comparative example), the toner charge amount after the initial set value of 5 kPV printing has dropped by about 5 μC / g or more, whereas in the developing device B, the toner charge amount has almost dropped. There is no sign of deterioration in the developer amount.

  Therefore, it can be understood that the developing device B according to the present embodiment performs uniform toner intake and less stress on the developer than the conventionally known developing device A that does not include the toner density sensor and the toner replenishing mechanism.

  In this example, the background level when a white paper image was printed at 10 kPV using the developing devices A and B similar to those in Example 2 was evaluated. In this evaluation, the background level of 2.0 or less is the spec allowable range.

  As shown in FIG. 14, in the developing device A (comparative example), the background level exceeded 2.0 during 6 kPV printing. On the other hand, in the developing device B, the background level was 2.0 or less up to 10 kPV. Therefore, it has been clarified from this embodiment that the developing device B has a longer life of the developing device than the conventionally known developing device A that does not include the toner density sensor and the toner replenishing mechanism.

  In this example, using the same developing devices A and B as in Example 2, the initial developer charge amount (developing device A: 50 g, developing device B: 100 g (first developer accommodating portion)) is 10 respectively. %, And a blank paper image is output at 1 kPV, and the background level at that time is evaluated. In both developing devices, the initial toner concentration was set to a saturation value of 10% when a normal amount of developer was charged. As a result of visual evaluation, in the developing device A (comparative example), the 1 kPV blank paper image showed noticeable scumming (smudge level 2.0 or higher), whereas in the developing device B all blank papers up to 1 kPV were observed. No smudge was observed in the image (stain level less than 2.0).

  Further, FIG. 15 shows changes in the toner density of the developer on the developer carrying member at this time. It can be seen that the developing device A (comparative example) is saturated at a value of 15% or more, while the saturated toner concentration at the time of normal developer amount charging is about 10%. On the other hand, it can be seen that the developing device B is stable at 10%, which is the same as the saturated toner concentration when a normal amount of developer is charged.

  Here, FIG. 16 shows the variation of the saturated toner density with respect to the developer charging amount.

  As can be seen from FIG. 3, the developing device A (comparative example) tends to diverge the saturated toner concentration when the developer charging amount decreases, while the developing device B does not change the developer charging amount. The saturated toner concentration is stably maintained around 10%.

  From the above, it has been clarified that the developing device B according to the present embodiment exhibits a stable saturated toner density characteristic even with respect to fluctuations in the developer charge amount. Therefore, even with a decrease in the amount of magnetic carrier over time, it is less likely to cause scumming and toner scattering than the conventionally known developing device A that does not include a toner concentration sensor and a toner replenishing mechanism, and has a stable saturated toner concentration characteristic. It is understood to show.

  Next, the developing device B in this embodiment (see FIG. 3) and the developing device C as a comparative example (the first developer accommodating portion and the toner accommodating portion without the second developer accommodating portion among the components of the developing device B) The following comparative verification was carried out using

First, the conditions of the developing device B are shown below.
Two-component developer G: Toner T having a particle size of 9.0 μm containing 20% magnetic powder was used. A magnetic carrier having an average particle diameter of 50 μm was used. The charging to the developing device B is 100 g of developer having a toner concentration of 10% by weight in the first developer container 33a, and 100g of developer having a toner concentration of 50% by weight in the second developer container 33b, the toner container. 35 contains 40 g of toner.
Developer carrier 32: The diameter of the rotating sleeve 321 was φ18, the surface roughness Rz = 7 μm, and the peripheral speed was 340 mm / s. The pattern of the magnetic pole roll 322 included in the rotating sleeve 321 is 80 mT for the developing magnetic pole (S1), 60 mT for the conveying magnetic pole (S3), 60 mT for the conveying magnetic pole (N3), 80 mT for the picking magnetic pole (N1), and 30 mT for the conveying magnetic pole (S2). The trimming magnetic pole (N2) was set to 40 mT.
Developer stirring member 36: A paddle (non-magnetic) of φ10 was used, the rotation direction was clockwise, and the peripheral speed was 170 mm / s.

Next, conditions of the developing device C are shown below.
Two-component developer G: Toner T having a particle size of 9.0 μm containing 20% magnetic powder was used. A magnetic carrier having an average particle diameter of 50 μm was used. In the developing device B, 110 g of a developer having a toner concentration of 10% by weight (partially in the toner container) was stored in the developer container 33, and 40 g of toner was stored in the toner container 35.
Developer carrier 32: The diameter of the rotating sleeve 321 was φ18, the surface roughness Rz = 7 μm, and the peripheral speed was 340 mm / s. The pattern of the magnetic pole roll 322 included in the rotating sleeve 321 is 80 mT for the developing magnetic pole (S1), 60 mT for the conveying magnetic pole (S3), 60 mT for the conveying magnetic pole (N3), 80 mT for the picking magnetic pole (N1), and 30 mT for the conveying magnetic pole (S2). The trimming magnetic pole (N2) was set to 40 mT.
Developer stirring member 36: A paddle (non-magnetic) of φ10 was used, the rotation direction was clockwise, and the peripheral speed was 170 mm / s.

  Under the conditions as described above, first, 10 solid images were continuously collected using both developing devices B and C, and then 10 halftone 20% images were continuously collected for visual verification and evaluation. For the developing device B, an image having a uniform density was obtained from the first sheet to the tenth sheet in the axial direction of the developer carrier. On the other hand, with regard to the developing device C, there was a portion in which the image density was extremely high in the axial direction in the first halftone image. In addition, although the image spots tended to be relaxed as the number of output sheets overlapped, it was possible to visually confirm up to the fifth sheet.

  Further, after collecting 10 solid images using the developing devices B and C, one halftone 20% image is subsequently collected, and then the toner density of the developer on the developer carrier is pivoted in each developing device. Measurements were made at five locations across the direction. The measurement results are shown in FIG.

  As is understood from FIG. 17, in the developing device B in which density unevenness does not occur in the halftone image, the developer toner concentration is stable at 10% by weight over the entire axial direction of the developer carrier. It was. On the other hand, with regard to the developing device C in which a portion where the density is extremely high is seen in the halftone image, the toner density in the axial direction of the developer carrier varies with the occurrence of density spots. (The higher the image density, the higher the toner density).

  That is, in the developing device C, a large amount of toner is consumed due to the output of the solid image, and the amount of the developer flowing on the partition plate is very large. Therefore, the space for taking in the toner in the developer accommodating portion is wide and free at a time. This toner is supplied to the developer accommodating portion, and there is a portion where the toner concentration temporarily becomes excessive (the toner concentration is higher than the saturated toner concentration). On the other hand, for the developing device B, a two-component developer in which the toner and the magnetic carrier are sufficiently stirred and mixed is supplied from the second developer accommodating portion even if a wide space is similarly formed in the first developer accommodating portion. Therefore, a uniform image can be obtained without excessive toner concentration. Incidentally, the solid image density of the developing devices B and C was maintained at 1.35 or more by the X-Rite 404 measurement up to the 10th sheet.

  As described above, according to the developing device of the present invention, a stable toner density is maintained and the developer is retracted to the developer retracting portion during and after the high-density image output as compared with the developing device having the conventional configuration. It was verified that even when the amount of the developer is large, it is possible to obtain a high-quality image in which the toner density of the developer carrier is not supersaturated.

It is explanatory drawing which shows the outline | summary of the image development apparatus concerning this invention. 1 is an explanatory diagram showing an embodiment of an image forming apparatus including a developing device to which the present invention is applied. (A) is explanatory drawing which shows the developing device which concerns on embodiment, (b) is an enlarged view of a partition part and its peripheral part. FIG. 6 is an explanatory diagram when a two-component developer having a low toner concentration is carried and conveyed in the embodiment. FIG. 4 is an explanatory diagram illustrating a flow of a two-component developer having a low toner concentration and toner in the embodiment. 6 is an explanatory diagram when a two-component developer having a high toner concentration is carried and conveyed in the embodiment. FIG. FIG. 4 is an explanatory diagram illustrating a flow of toner and a two-component developer having a high toner concentration in the embodiment. FIG. 6 is an explanatory diagram illustrating a relationship between a developer flow rate and a toner concentration range when the strength of a conveyance magnetic pole (N2) is fixed in Example 1. FIG. 6 is an explanatory diagram illustrating a relationship between a developer flow rate and a toner concentration range when the strength of a transport magnetic pole (S2) is fixed in Example 1. FIG. 10 is an explanatory view showing a conventional developing device A. FIG. 10 is an explanatory diagram showing a change in image density in Example 2. FIG. 10 is an explanatory diagram illustrating toner density recovery characteristics in Example 2. FIG. 10 is an explanatory diagram illustrating a change in toner charge amount in Example 3. FIG. 12 is an explanatory diagram illustrating a blank image background level in Example 4. FIG. 10 is an explanatory diagram showing a change in toner density in Example 5. FIG. 10 is an explanatory diagram showing a change in saturated toner density in Example 5. FIG. 10 is an explanatory view showing a comparative example developing device C in Example 6. FIG. 10 is an explanatory diagram illustrating a toner density distribution of a developer in an axial direction of a developer carrier in Example 6.

Explanation of symbols

  1: magnetic field generating means, 2: two-component developer, 3: developer carrier, 4a: first developer container, 4b: second developer container, 5: toner container, 6: circulation path, 7 : Developer retracting section, 8: developer separating means, 9: image carrier, 10: magnetic pole, 10a: development magnetic pole, 10b, 10d: transport magnetic pole, 10c: pickup magnetic pole, 21: electrostatic latent image carrier, 22 : Charging device, 23: Exposure device, 24: Development device, 25: Bias power supply, 26: Transfer device, 27: Bias power supply, 28: Recording material, 29: Cleaning device, 31: Development housing, 32: Developer carrier 33: Developer container, 33a: First developer container, 33b: Second developer container, 34: Developer retracting part, 35: Toner container, 36: Developer stirring member, 36a: First Developer stirring member 36b: second developer stirring member 37 : Toner supply path, 37a: developer supply path, 39: partition part, 39a: base plate, 39b: tip part, 39c: other end part, 40: circulation path, 41: damming part, 42: layer thickness regulating member, 50 : Fixing device, 51: heating roll, 52: pressure roll, 61: developing housing, 62: developer carrier, 63: regulating member, 64: developer containing section, 65: toner containing section, 321: rotating sleeve, 322: magnetic pole roll, 351: toner stirring member, 621: sleeve, 622: magnetic pole roll, 651: stirring member, A, B, C: developing device, G: two-component developer, T: toner

Claims (9)

A developer carrying member for carrying and conveying a two-component developer containing toner and a magnetic carrier in a predetermined direction by magnetic force;
A first developer accommodating portion for accommodating a two-component developer adjacent to the developer carrying member;
A two-component developer having a toner concentration higher than the toner concentration of the two-component developer provided in communication with the developer carrier through the first developer container and carried by the developer carrier is first A second developer accommodating portion that can be supplied to the developer accommodating portion;
Adjacent to the developer carrier and provided above the first developer container, the upper end thereof faces the developer carrier, and the lower ends thereof are a first developer container and a second developer container. A partition member disposed between,
A developer retracting portion that is separated from the first developer accommodating portion by the partition member and forms a circulation path via the first developer accommodating portion and the second developer accommodating portion;
A part of the two-component developer provided on the downstream side of the developer carrying member in the developer carrying direction with respect to the first developer accommodating portion and the developer retracting portion and carried by the developer carrying member is used as an excess developer. A developer separating means for separating the surplus developer into the first developer accommodating section or the developer retracting section, based on the magnetic attraction force received by the two-component developer according to the damming and toner density ;
A toner container that is provided in communication with the developer carrier via the first developer container and the second developer container and accommodates the second developer container so that toner can be supplied ;
The developer separating means allows the excess developer passing through the developer retracting portion to pass through the developer retracting portion as the toner concentration of the two-component developer carried and transported by the developer carrier in the previous period decreases. Without separating the excess developer so as to be more than the excess developer in the previous period accommodated in the first developer accommodating portion,
The partition member is arranged and configured to cause the two-component developer separated and introduced into the developer retracting portion to flow out to both the first developer accommodating portion and the second developer accommodating portion. Development device. The average toner concentration of the two-component developer accommodated in the second developer accommodating portion is higher than the average toner concentration of the two-component developer accommodated in the first developer accommodating portion. The developing device according to claim 1 . 3. The developing device according to claim 1, wherein the developer separating unit includes a damming portion that is disposed to face the developer carrying member and dams excess developer. 4. The developing device according to claim 3 , wherein the damming portion also serves as a regulating member that regulates the thickness of the developer layer carried on the developer carrying member. The developer separating means, a developing device according to any one of claims 1, characterized in that it comprises a magnetic pole is the magnetic field generating means provided on the developer carrying member 4. The developing device according to claim 5 , wherein the developer separating unit has a damming portion disposed adjacent to the downstream side of the transport magnetic pole with respect to the developer transport direction of the developer carrier. . The developer separating means, disposed opposite to the developer carrying member and includes a stop part which excess developer is blocked, the gap between the developer carrier and the partition member, the developer carrying said stop part 7. The developing device according to claim 1 , wherein the developing device is set to be larger than a gap with the body. The developer separating means is separated and introduced into the developer retracting portion by changing the magnetic attraction force with respect to the two-component developer by changing the magnetic pole generating position or the magnetic field strength as the magnetic field generating means in the developer carrying member. an apparatus according to any one of the two claims 1 and changing the predetermined toner concentration of component developer 7 during that. An image forming apparatus comprising: a developing device according to any one of claims 1 to 8.

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