JP5095171B2 - Developing device and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a developing apparatus capable of extending the life of a developer, using a two-component developer, and an image forming apparatus comprising the developing apparatus. <P>SOLUTION: A range in which an angle of a restricting member upstream side central angle &alpha;, which is a central angle of the surface of a developing roller 131 on the upstream side of a restricting member Sb opposing position opposing a doctor blade 135 serving as a developer amount restricting member with respect to a surface of the developing roller 131 being a developer carrier, is not less than 0[&deg;] and not more than 60[&deg;] is set as a low magnetic flux density area &gamma; in which the maximum value of a normal direction magnetic flux density on the surface of the developing roller 131 is not more than 30 [mT]. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a developing device used for a copying machine, a facsimile, a printer, and the like. More specifically, the developing device uses a two-component developer composed of a toner and a carrier, and a copying machine, a facsimile, a printer, and the like using the developing device. The present invention relates to an image forming apparatus.

In a conventional developing device, a developer is conveyed by a developer carrying member, a voltage is applied between the image carrying member carrying the electrostatic latent image and the developer carrying member, and the toner is moved to the electrostatic latent image. In some cases, a developing method that visualizes the image is used.
As this developing method, for example, there is a magnetic brush developing method using a two-component developer. In this developing method, a magnetic brush is formed by a magnetic carrier on the surface of a developing sleeve as a developer carrying member having a magnet disposed therein, using a two-component developer composed of a non-magnetic toner and a magnetic carrier. Then, the magnetic brush is rubbed or brought close to a photosensitive member which is a latent image carrier that is opposed to the developing sleeve while maintaining a minute developing gap. Here, by applying a developing voltage between the developing sleeve and the photosensitive member, the toner particles carried on the magnetic carrier forming the magnetic brush on the developing sleeve are attached to the latent image of the photosensitive member for development. .

Further, in the developing device using the magnetic brush developing method, the developer carrying amount on the developing sleeve is developed by the gap (doctor gap) between the developer amount regulating member and the developing sleeve arranged to face the developing sleeve surface. Regulate to the appropriate amount. A magnetic brush made of a developer controlled to an amount suitable for development on the developing sleeve is rubbed or brought close to the photoconductor in a state suitable for development, and an image is formed by a development voltage.
As such a developing device, there is a developing device described in Patent Document 1, for example.

JP 11-194617 A

In the conventional developing device, the magnetic flux density in the normal direction on the surface of the developer carrier in the region near the doctor gap upstream of the developer carrier surface movement direction with respect to the doctor gap facing the developer amount regulating member is High value. In the developing device of Patent Document 1, the maximum magnetic flux density in the normal direction with respect to the surface on the surface of the developer carrier in the region close to the doctor gap on the upstream side in the direction of movement of the developer carrier relative to the doctor gap. The value is as high as 60 [mT]. This caused the following problems.
That is, when the magnetic flux density in the normal direction is high with respect to the surface of the developer carrying member, a magnetic brush having a strong connection between carriers is formed on the surface of the developer carrying member. Further, in the region upstream of the developer carrier surface movement direction in the vicinity of the developer doctor, when the developer passes through the doctor gap, which is the gap between the developer amount regulating member and the developer carrier, it is more than the doctor gap. The high magnetic brush collides with the developer amount regulating member. When a magnetic brush having a strong connection between carriers collides with the developer amount regulating member, the carriers are not easily separated, and the developer particles and the developer amount regulating member are separated from each other and between the particles in the developer. Will be rubbed by strong stress. When the developer is rubbed with a strong stress, the developer deteriorates and the life of the developer is reduced.
Therefore, when the lifetime of the developer is taken into consideration, it is necessary to reduce the stress received by the developer at the facing portion between the developer amount regulating member and the developer carrier.

  The present invention has been made in view of the above problems, and an object thereof is a developing device using a two-component developer, and a developing device capable of extending the life of the developer, and An image forming apparatus is provided.

In order to achieve the above object, the invention of claim 1 is characterized in that a two-component developer composed of a magnetic carrier and a toner is carried on the surface, the surface moves, and the developing region is opposed to the latent image carrier. A developer carrying member for supplying the toner to the latent image on the surface of the latent image carrying member for development; a developer supplying unit for feeding the developer to the surface of the developer carrying member; and the developer carrying member surface And a developer amount regulating member that regulates the layer thickness of the developer that is supplied onto the surface of the developer carrying member and conveyed in the development area by the developer supply unit. A wall member that forms a developer supply / conveyance path as the developer supply section that supplies the developer to the surface of the developer carrier while conveying the developer, and is provided on the side of the wall member facing the developer carrier. The position of the surface of the developer carrying member facing the end of the wall, which is the tip, The developer amount regulating member is above the rotation center of the developer carrier, and the developer amount regulating member is opposed to the surface of the developer carrier above the rotation center of the developer carrier in the vertical direction. With respect to the position on the surface of the developer carrying member facing the downstream side of the surface of the developer carrying member in the surface movement direction, and with respect to the regulating member facing position facing the developer amount regulating member on the surface of the developer carrying member A low magnetic flux density region in which the magnetic flux density in the normal direction on the surface of the developer carrying member is in the range of 0 [mT] or more and 30 [mT] or less in the range upstream of the surface of the developer carrying member. and then, above the low flux density region is characterized in that the peak of the normal magnetic flux density of the magnetic pole provided on the developer carrying body position is not arranged.
The invention of claim 2 is characterized in that, in the developing device of claim 1, the magnetic flux density in the normal direction of the low magnetic flux density region is in the range of 0 [mT] to 5 [mT]. To do.
According to a third aspect of the present invention, the surface of the latent image carrier is supported in a development region opposite to the latent image carrier by carrying a two-component developer comprising a magnetic carrier and toner on the surface and moving the surface. A developer carrier for developing the latent image by supplying the toner, a developer supply unit for supplying the developer to the surface of the developer carrier, and the developer carrier surface facing the developer carrier. In a developing device having a developing unit including a developer amount regulating member that regulates a layer thickness of the developer that is supplied onto the surface of the developer carrying member and conveyed in the development region by a developer feeding unit. A wall end portion that is a tip of the wall member on the side facing the developer carrier, and includes a wall member that forms a developer supply conveyance path as the developer supply portion that supplies the developer carrier surface The position of the surface of the developer carrying member facing to the rotation of the developer carrying member in the vertical direction The developer amount regulating member is above the center, and the developer amount regulating member is opposed to the surface of the developer carrier above the rotation center of the developer carrier in the vertical direction and is opposed to the wall end. The developer carrying member is positioned on the downstream side of the developer carrying member in the surface movement direction with respect to the body surface position, and on the developer carrying member surface with respect to the regulating member facing position facing the developer amount regulating member. the range of surface movement direction upstream side, the magnetic flux density in the normal direction at the surface of the developer carrying member, it is an 0 [mT] and becomes the low flux density region and to said Rukoto.
The invention of claim 4 is carried in the developing device according to claim 1, 2 or 3, the developer carrying member, a plurality of magnetic field generating means fixed inside, the developer on the surface thereof And a rotatable non-magnetic developing sleeve.
According to a fifth aspect of the present invention, the surface of the latent image carrier is supported in a development region opposite to the latent image carrier by carrying a two-component developer comprising a magnetic carrier and toner on the surface and moving the surface. A developer carrier for developing the latent image by supplying the toner, a developer supply unit for supplying the developer to the surface of the developer carrier, and the developer carrier surface facing the developer carrier. In a developing device having a developing unit including a developer amount regulating member that regulates a layer thickness of the developer that is supplied onto the surface of the developer carrying member and conveyed in the development region by a developer feeding unit. A wall end portion that is a tip of the wall member on the side facing the developer carrier, and includes a wall member that forms a developer supply conveyance path as the developer supply portion that supplies the developer carrier surface The position of the surface of the developer carrying member facing to the rotation of the developer carrying member in the vertical direction The developer amount regulating member is above the center, and the developer amount regulating member is opposed to the surface of the developer carrier above the rotation center of the developer carrier in the vertical direction and is opposed to the wall end. The developer carrying member is positioned on the downstream side of the developer carrying member in the surface movement direction with respect to the body surface position, and on the developer carrying member surface with respect to the regulating member facing position facing the developer amount regulating member. The range on the upstream side in the surface movement direction is a low magnetic flux density region in which the normal direction magnetic flux density on the surface of the developer carrying member is in the range of 0 [mT] to 30 [mT], and the developer carrying The body comprises a plurality of magnetic field generating means fixed inside, and a nonmagnetic developing sleeve which can carry and rotate the developer on the surface thereof, and is disposed inside the nonmagnetic developing sleeve in the low magnetic flux density region. Characterized by not providing magnetic field generation means A.
The invention of claim 6, claim 1, 2, 3, in the developing apparatus 4 or 5, the developing unit may recover the developer that has passed the developing region is supplied to the developer carrying member And a developer recovery section.
The invention of claim 7, claim 1, 2, 3, 4, in the developing device 6 was 5 or, characterized in that it comprises a toner replenishing means for replenishing the toner to the developer is there.
The invention of claim 8, claim 1, 2, 3, in the developing apparatus 4 or 5, can transfer the developer between the developing unit, stirring means for stirring the developer It has a stirring part provided with.
Further, the invention of claim 9 is the developing device according to claim 8 , wherein the developing unit and the stirring unit are configured separately, and the developing unit and the stirring unit are connected by a developer transfer path forming member. It is characterized by that.
According to a tenth aspect of the present invention, in the developing device of the ninth aspect , the agitating section conveys the developer from below to above and agitates the developer.
The invention of claim 11 is the developing device according to claim 12 , wherein the agitating portion rotates with a cylindrical member containing the developer therein, and rotates the developer in the cylindrical member downward. And a screw member that is conveyed upward.
According to a twelfth aspect of the present invention, in the developing device according to the tenth or eleventh aspect , the toner replenishing unit replenishing the developer with the toner is provided, and the toner replenishing unit for replenishing the toner from the toner replenishing unit is stirred. It is provided below the part.
The invention of claim 13 is characterized in that, in the developing device of claim 8 , the developing section and the stirring section are integrally formed.
The invention of claim 14, claim 8, in the developing device of 9,10,11,1 2 or 13, as more than half of the developer in the developing device is present in the stirring section It is characterized by comprising.
The invention of claim 15, in the developing device according to claim 8, 9,10,11,12,1 3 or 14, includes a toner replenishing means for replenishing the toner to the developer, the toner replenishing The developer replenished with the toner by means is transferred to the developing unit after being stirred by the stirring unit.
The invention of claim 16, claim 8, in the developing device of 9,10,11,12,13,1 4 or 15, the developing unit is the developing region is supplied to the developer carrying member A developer collecting unit that collects the developer that has passed through is provided, and the collected developer collected by the developer collecting unit is transferred to the stirring unit, and stirred by the stirring unit and then transferred to the developing unit. It is characterized by that.
The invention of claim 17, in the developing apparatus according to claim 1,2,3,4,5,6,7,8,9,10,11,12,13,14,1 5 or 16, The developer amount regulating member has a blade shape whose tip is opposed to the surface of the upper developer carrying member.
The invention of claim 18, the developing device according to claim 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,1 6 or 17 In the above, the developer amount regulating member has a roller shape that can be rotated with respect to the surface movement of the developer carrying member.
According to a nineteenth aspect of the present invention, there is provided at least a latent image carrier, charging means for charging the surface of the latent image carrier, and formation of a latent image for forming an electrostatic latent image on the latent image carrier. And a developing unit for developing the electrostatic latent image into a toner image, wherein the developing unit is defined as claim 1, 2, 3, 4, 5, 6, 7, 8 , it was 9,11,12,13,14,15,16,1 7 or is characterized in the use of the developing apparatus according to 18.

In the developing device having the configuration according to any one of claims 1 , 3, and 5 , the position of the surface of the developer carrying member facing the wall end is on the downstream side in the surface movement direction of the developer carrying member, and the position facing the regulating member On the other hand, the range on the upstream side of the surface of the developer carrying member is a low magnetic flux density region in which the normal direction magnetic flux density is in the range of 0 [mT] to 30 [mT]. In addition, it is possible to weaken the connection between the magnetic carrier of the developer carried in the regulating member facing position and the region upstream of the developer carrying body surface moving direction in the vicinity of the regulating member facing position.

Therefore, in the developing device according to the first to 19th aspects, when the developer passes through the doctor gap at the position facing the restricting member, the connection between the carriers of the developer is weak, and the position is higher than the doctor gap. Even when the developer contacts the developer amount regulating member, the developer easily moves in accordance with the shape of the developer amount regulating member. Thereby, it is possible to suppress the developer from being rubbed by strong stress in the doctor gap.

According to the first to twentieth aspects of the present invention, since the developer can be prevented from being rubbed by strong stress in the doctor gap, the deterioration of the developer can be suppressed and the life of the developer can be extended. Has an excellent effect.

[Embodiment 1]
A first embodiment in which the present invention is applied to an electrophotographic copying machine (hereinafter simply referred to as copying machine 100) as an image forming apparatus will be described below.
First, a basic configuration of the copying machine 100 according to the first embodiment will be described. FIG. 1 is a schematic configuration diagram showing a main part of the copying machine 100. The copying machine 100 includes a document reading unit 1, an automatic document feeding unit 2, a printer unit 3, and a paper feeding unit 4.

The automatic document feeder 2 automatically supplies a document (not shown) placed on the upper surface thereof onto a contact glass 5 described later.
The document reading unit 1 is for reading an image of a document (not shown). When a start switch (not shown) is operated while a document is placed on the contact glass 5 fixed on the upper portion of the document reading unit 1 by a user's manual operation, the document reading unit 1 starts reading the document immediately. Is done. Further, when the start switch is operated with the document placed on the automatic document feeder 2, the document is automatically fed onto the contact glass 5, and then the document reading by the document reading unit 1 is started. . When reading is started, the document placed on the contact glass 5 is illuminated with a light source 6 that moves in the right direction in the figure. The reflected light image from the document is sequentially reflected by the first mirror 7 and the second mirror 8. Then, after passing through the imaging lens 9, it is detected by the image sensor 10 comprising a CCD or the like for reading the reflected light image, and the image information is read.

  The printer unit 3 is for forming a toner image as an image on a transfer paper P as a recording member, and includes an optical writing unit 11 and a photosensitive member 12 as a drum-like latent image carrier. Further, around the photosensitive member 12, a charging device 13, a developing device 130 as a developing unit, a transfer conveyance unit 14, a photosensitive member cleaning device 15, a static eliminator 16, and the like are provided. Further, a fixing device 17, a reverse paper discharge unit 18, a registration roller pair 19 and the like are also provided. When the start switch is operated, rotation of the photosensitive member 12 by a driving unit (not shown) is started.

  The optical writing unit 11 optically modulates the laser beam L based on the image signal read by the document reading unit 1 and exposes the photoconductor 12. Specifically, the laser light L is emitted from the exposure light source 20 made of a laser diode or the like. The laser beam L is deflected in the main scanning direction (axial direction of the photosensitive member 12) on the rotary polygon mirror 22 that is rotationally driven by the polygon motor 21, and the scanning imaging lens system 23 including an fθ lens or the like. Pass through. Then, it passes through the mirror 24 and the lens 25 and reaches the rotationally driven photoconductor 12 to scan the surface of the electrostatic latent image.

  The transfer conveyance unit 14 abuts against the circumferential surface of the photoconductor 12 to form a transfer nip while the transfer conveyance belt is endlessly moved while being tensioned by a plurality of tension rollers. Further, a transfer bias roller (not shown) is brought into contact with the back surface (the inner peripheral surface of the hoop) of the transfer conveyance belt in the transfer nip. A transfer bias is applied to the transfer bias roller by a power source (not shown), and a transfer electric field is formed in the transfer nip by this application.

  The electrostatic latent image formed on the photoconductor 12 by exposure by the optical writing unit 11 is developed by the developing device 130 to become a toner image, and then enters the transfer nip. On the other hand, the registration roller pair 19 sandwiches the transfer paper P sent from the paper supply unit 4 described later between the rollers based on the operation of the start switch. Then, the transfer paper P is sent out at a timing at which the transfer paper P can be superimposed on the toner image on the photoconductor 12 at the transfer nip. By this feeding, the toner image on the photoreceptor 12 is brought into close contact with the transfer paper P at the transfer nip. Then, the image is transferred from the surface of the photoconductor 12 to the surface of the transfer paper under the influence of the transfer electric field and the nip pressure. The transfer paper P that has passed through the transfer nip is fed into the fixing device 17 by the transfer conveyance belt of the transfer conveyance unit 14. The fixing device 17 sandwiches the transferred transfer paper P between the heating roller 17a and the pressure roller 17b. Then, the toner image is discharged toward the reverse discharge unit 18 while being fixed on the transfer paper P by the influence of heat and pressure.

  The reverse paper discharge unit 18 passes the transferred transfer paper P through a discharge path 18a and discharges it to a paper discharge tray (not shown) outside the apparatus. However, when the double-sided copy mode is selected by the user, the transfer paper P is passed through the reversing unit 18 b and turned upside down, and then conveyed toward the registration roller pair 19. As a result, the transfer paper P is sent again from the registration roller pair 19 toward the transfer nip, and a new toner image is transferred to the surface opposite to the surface on which the toner image has been previously transferred.

  The photoconductor cleaning device 15 cleans the transfer residual toner adhering to the surface of the photoconductor 12 after passing through the transfer nip, and stores it in a recovery tank 90 that is a toner recovery unit. The surface of the photoreceptor 12 after cleaning is discharged by the charge eliminator 16 and then uniformly charged by the charging device 13 to prepare for the next image formation.

  The paper feed unit 4 includes three paper feed cassettes 26, 27, and 28 arranged in multiple stages, each of which accommodates a plurality of transfer papers P. A paper feed path 33 having a plurality of pairs of transport rollers 32 is also provided. The paper feed cassettes 26, 27, 28 press the paper feed rollers 26 a, 27 a, 28 a against the uppermost paper of the transfer paper P accommodated therein, and the uppermost paper is directed toward the paper feed path 33 by its rotational drive. And send it out. When the start switch is operated, the transfer paper is sent out from any one paper feed cassette to the paper feed path 33. The paper feed path 33 feeds the received transfer paper P toward the registration roller pair 19 of the printer unit 3 by a plurality of pairs of conveyance rollers 32.

Next, the developing device 40 as a developing unit will be described.
A developing device 130 disposed on the side of the photoreceptor 12 and a stirrer 140 as a stirring unit capable of delivering a two-component developer composed of a magnetic carrier and toner to the developing device 130 are developed. The developer transfer path forming members are connected by two developer transfer pipes. The developing device 40 as developing means is mainly composed of the developing device 130 and the stirrer 140.
Of the two developer transfer pipes, the first developer transfer pipe 120 is the one that transfers the developer from the stirrer 140 to the developer 130, and the first one that transfers the developer from the developer 130 to the stirrer 140. Two developer transfer pipes 150.

FIG. 2 is an explanatory perspective view of the developing device 40. FIG. 3 is a schematic cross-sectional view of the developing device 130 as viewed from the direction of arrow A in FIG. FIG. 4 is a schematic cross-sectional view of the vicinity of the front end portion of the developing device 130 in FIG.
The developing device 130 is a so-called two-component developing device, and a two-component developer (hereinafter simply referred to as a developer) in which toner and a magnetic carrier are mixed is accommodated in the developing operation. This developer is a two-component developer comprising a toner having a particle size of 4 to 10 [μm] (volume average particle size) and a carrier having a particle size of 15 to 60 [μm] (average particle size, microtrack). It is. The toner concentration varies depending on the selection of each size, but can be used up to about 3.5 to 10%. The developing device 40 has a toner particle diameter of 7 [μm], a carrier particle diameter of 35 [μm], and a toner concentration of 7 [%].

Further, the developing device 130 includes a developing roller 131 that is a developer carrying member, and a supply and conveyance screw that is a developer supply and conveyance member that supplies the developer to the developing roller 131 while conveying the developer in the direction of arrow C in FIG. 132 is provided. The developing roller 131 includes a magnet roller 131b having a plurality of magnets, which are magnetic field generating means described later in detail, and a nonmagnetic sleeve 131a that is rotatably provided on the outside of the magnet roller 131a. Further, a recovery transport screw that is a developer recovery transport member that is supplied to the development roller 131 and collects the developer on the surface of the development roller 131 after passing through the development area and transports the developer in the direction of arrow D in FIG. 133 is provided. The supply conveyance screw 132 and the recovery conveyance screw 133 are development unit conveyance members that convey the developer in the developing device 130 that is a development unit. These developing unit conveying members are formed by spirally winding a blade on a spindle, and the blade has a diameter of φ = 18 [mm] and a helical pitch of 27 [mm].
In addition, a toner container 110 that stores unused toner is connected to the stirrer 140 by a toner supply path 141 that is a toner supply unit.

A space for accommodating the developer in the developing device 130 includes a supply conveyance path 136 that is a developer supply conveyance path as a supply unit provided with a supply conveyance screw 132 by a partition wall 134 that is a partition member, and a recovery conveyance screw 133. It is partitioned into a recovery transport path 137 as a developer recovery transport path. The partition wall 134 includes an opening (not shown) on the downstream side in the transport direction of the supply transport screw 132, and communicates the supply transport path 136 and the recovery transport path 137.
The developing roller 131 moves the surface in the direction of arrow E in FIG. 3 and removes the developer in the supply conveyance path 136 by the magnetic force of the magnet roller 131b provided inside thereof and the frictional force between the surface of the sleeve 131a and the developer. Supported on the surface. The amount of the developer carried on the surface of the developing roller 131 is regulated by a doctor blade 135 as a developer carrying amount regulating means, and is conveyed to a developing area that is a portion where the developing roller 131 and the photosensitive member 12 are opposed to each other. . The latent image on the surface of the photoconductor 12 is developed in the developing area, and the developer that has consumed the toner is separated from the developing roller 131 at the opposed portion between the developing roller 131 and the collecting and conveying screw 133 and collected and conveyed as the collected developer. Collected in the path 137. Further, the excess developer that has reached the downstream end in the conveyance direction of the supply conveyance screw 132 without being supplied from the supply conveyance path 136 to the developing roller 131 passes through the opening of the partition wall 134 to the recovery conveyance path 137. It is transported and transported by the recovery transport screw 133 together with the recovered developer.
The developing device 130 includes a toner concentration sensor 139 that detects the toner concentration of the collected developer near the downstream end in the conveyance direction of the collection conveyance screw 133 in the collection conveyance path 137.

The first developer transfer pipe 120 and the second developer transfer pipe 150 are pipe-shaped developer transfer path forming members made of metal, resin, rubber, and the like that connect the developing device 130 and the stirrer 140. The first developer transfer pipe 120 includes a first auger 121 as a stirred developer transfer member that transfers the developer from the stirrer 140 to the developer 130. On the other hand, the second developer transfer pipe 150 includes a second auger 151 as a developed developer transfer member that transfers the developer from the developer 130 to the stirrer 140. The first auger 121 and the second auger 151 are coiled without an axis.
The first developer transfer pipe 120 is connected to the developing device 130 above the supply conveyance path 136, and the first developer transfer pipe 120 is connected to the first developer transfer pipe 120 by the developing device upper opening 123 provided on the upper surface of the developing device 130. The internal space communicates with the supply conveyance path 136. On the other hand, the second developer transfer pipe 150 is connected to the developing device 130 below the collection conveyance path 137, and the second developer transfer pipe 150 is formed by a developing device lower opening 153 provided on the lower surface of the developing device 130. The space inside 150 communicates with the collection conveyance path 137.
A first auger drive shaft 122 is connected to the end of the first auger 121 on the developing device 130 side, and a second auger drive shaft 152 is connected to the end of the second auger 151 on the developing device 130 side. The supply conveyance screw 132 and the collection conveyance screw 133 or the driving source of the developing roller 131 and the first auger driving shaft 122 and the second auger driving shaft 152 are connected by a gear or the like, and rotate together with each member of the developing device 130. .

FIG. 5 is a schematic cross-sectional view of the stirrer 140 viewed from the direction of arrow A in FIG.
The stirrer 140 includes a developer inlet 42 through which the developer transferred from the developer 130 flows, and a developer outlet 43 through which the developer transferred toward the developer 130 flows. Further, a toner supply port 44 through which toner supplied from the toner container 110 flows is provided.
Further, the agitator 140 is provided with an agitator 41 as a stirring means for stirring the developer, and is rotated by a stirring motor 45 provided outside. In the agitator 41, a plurality of stirring blades 41b are attached to the stirring shaft 41a as shown in the figure, and the developer is stirred by the rotation of the stirring blades 41b.
At the developer outlet 43 below the stirrer 140, a valve 47 serving as a transfer path opening / closing member as a developer transfer amount control means is installed. The valve 47 is made of resin, metal, etc., and the cross section thereof is the same circle as the cross section of the developer outlet 43, and the valve rotation shaft 47 a that is the rotation axis flows out of the developer passing through the developer outlet 43. It is installed so as to be perpendicular to the direction. A valve motor 46 is connected to the valve rotation shaft 47 a, and the valve 47 is rotated by driving the valve motor 46.
By controlling the rotation of the valve motor 46 by a control means (not shown), the rotation of the valve 47 can be controlled, the developer outlet 43 can be opened or shut off, and the amount of developer flowing out can be adjusted. it can.

  The toner container 110 is made of metal, resin, or the like. The toner container 110 and the stirrer 140 are connected by a toner supply path 141. A toner conveyance auger 142 made of a coil screw or the like is provided inside the toner replenishment path 141, and the toner conveyance auger 142 is rotated by rotation of a toner replenishment motor 148 provided outside, so that toner is supplied to the agitator 140. To be replenished.

Next, the circulation of the developer in the developing device 40 will be described.
In the developing device 130, the developer in the supply conveyance path 136 is supplied to the surface of the developing roller 131 from the partition wall end portion 134 a that is the tip of the partition wall 134 that faces the developing roller 131. The developer that has been supplied from the supply conveyance path 136 to the surface of the developing roller 131 and has passed through the development region is collected as a collected developer in a collection conveyance path 137 including a collection conveyance screw 133, and sequentially in the direction of arrow D in FIG. Be transported. Further, the developer that has reached the downstream end in the transport direction of the supply transport screw 132 without being supplied to the developing roller 131 passes from the supply transport path 136 to the recovery transport path through an opening provided in the partition wall 134 as an excess developer. 137 falls under its own weight. Excess developer that has fallen into the collection conveyance path 137 is conveyed in the direction of arrow D in FIG. The developer transported in the direction of arrow D by the recovery transport screw 133 and reaching the downstream end in the transport direction of the recovery transport screw 133 falls by its own weight at the developing device lower opening 153 and enters the second developer transfer pipe 150. .

  The developer that has entered the second developer transfer pipe 150 is transferred to the stirrer 140 by the second auger 151. As shown in FIG. 5, developer is stored in the stirrer 140 in advance, and the developer flows from the developer inlet 42 and is stirred by the agitator 41. Below the stirrer 140, the developer is discharged from the developer outlet 43 by its own weight, but the rotation of the valve 47 is controlled by controlling the rotation of the valve motor 46 by a control means (not shown). The amount of developer discharged can be controlled. The discharged developer falls into the first developer transfer pipe 120 and is transferred above the supply conveyance path 136 of the developing device 130 by the first auger 121. The developer that has reached the upper side of the supply conveyance path 136 falls by its own weight at the upper opening 123 of the developing device and is transferred to the supply conveyance path 136. The developer transferred to the supply conveyance path 136 is supplied to the developing roller 131 while being conveyed in the direction of arrow C in FIG. 4 by the supply conveyance screw 132.

  The developer in the developer is consumed when the developer carried on the surface of the developing roller 131 passes through the developing area, which is the opposed portion of the developing roller 131 and the photosensitive member 12, by the developer circulation described above. When the toner is consumed, the toner density of the developer decreases, and the toner density sensor 139 detects that the toner density has decreased. In order to replenish the reduced toner, the toner is replenished from the toner container 110 through the toner replenishment path 141 to the agitator 140, and the developer in the agitator 140 and the replenished toner are mixed. Note that the amount of toner to be replenished can also be calculated by detecting the formed image area ratio. Further, the installation position of the toner density sensor is not limited to the developing device 130 but may be provided in the stirrer 140.

  When the developing device 40 is operating normally, the valve 47 rotates at a constant speed, and the amount of developer discharged from the stirrer 140 is constant. When the developing device does not perform image formation, the valve 47 is first closed and the developing device is driven as it is. Then, the developer sequentially accumulates in the stirrer 140, and almost all of the developer is eventually stored in the stirrer 140. At this time, the developing device 130 continues to be driven, but since the developer is not contained, the developer is not subjected to stress. However, the developing device 130 can be stopped. When the image formation is performed again, if the valve 47 is rotated at a constant speed, the developer is transferred from the stirrer 140 to the developer 130, and the circulation of the developer starts.

Next, the characteristic part of the developing device 130 which is the developing part of Embodiment 1 will be described with reference to FIG.
As shown in FIG. 3, the developing device 130 includes a developing roller 131 as a developer carrying member that is closely opposed to the photosensitive member 12 that is a latent image carrying member, and has a gap from the surface of the developing roller 131. Is provided with a doctor blade 135 as a developer amount regulating member. The developing roller 131 which is a developer carrying member includes a magnet roller 131b having a plurality of magnets as magnetic field generating means fixed therein, and a non-magnetic sleeve 131a which can rotate around the magnet roller 131b. Configure. The sleeve 131a is driven by a driving means (not shown) and is driven to rotate in the direction of arrow E in the figure. When the developer in the supply conveyance path 136 is supplied to the surface of the sleeve 131 b of the developing roller 131, the developer is conveyed in the direction of arrow E together with the sleeve 131 b and is a developing region that is a portion facing the photoreceptor 12. Then, development is performed by supplying toner to the latent image on the photoreceptor 12.

In the developing device 130 according to the first embodiment, the low magnetic flux density region γ is formed on the upstream side of the surface of the developing roller 131 in the moving direction of the surface of the developing roller 131 due to the magnetic pole arrangement of the magnet roller 131b. Forming. This low magnetic flux density region γ is a region where the magnetic flux density in the normal direction on the surface of the developing roller 131 is low. As a result, it is possible to weaken the connection between the magnetic carrier of the developer carried on the position facing the doctor blade 135 on the surface of the developing roller 131 and the upstream side of the developing roller 131 surface movement direction from this position. .
As a result, when the developer passes through the doctor gap, which is the gap between the doctor blade 135 and the surface of the developing roller 131, the connection between the carriers of the developer becomes weak, and the developer at a position higher than the doctor gap Even if it contacts the blade 135, it easily moves in accordance with the shape of the doctor blade 135. Thereby, it is possible to suppress the developer from being rubbed by strong stress in the doctor gap. Therefore, deterioration of the developer can be suppressed and the life of the developer can be extended.
As shown in FIG. 3, the doctor blade 135 faces the surface of the developing roller 131 above the developing roller center point 131P that is the rotation center of the sleeve 131a in the vertical direction. In such a position, the frictional force between the developer and the surface of the developing roller 131 due to the developer's own weight contributes to the loading of the developer on the surface of the developing roller 131, and thus is required for carrying and transporting the developer. Magnetic force can be reduced. In particular, as shown in FIG. 3, when the doctor blade 135 opposes around the uppermost part of the surface of the developing roller 131, the frictional force due to the developer's own weight increases, and the magnetic force required to carry and transport the developer. Can be further reduced.
The width of the doctor gap, which is the gap between the doctor blade 135 and the developing roller surface, is 0.3 [mm] to 1.0 [mm]. In the developing device 40 of the first embodiment, the width of the doctor gap is 0.5 [mm].

In FIG. 3, the magnetic flux density in the normal direction on the surface of the developer carrier in the conventional developing device is shown in the low magnetic flux density region γ in the region upstream of the developer carrier surface movement direction with respect to the developer amount regulating member Was set high. This is due to the following reason.
In the two-component development using the magnetic brush development method, the developer on the developer carrier is developed for development by appropriately setting the gap (doctor gap) between the developer carrier and the developer amount regulating member. The transport amount is appropriate. The toner in the developer on the developer carrying member regulated to an amount suitable for development is attached to the electrostatic latent image on the photoreceptor by applying a development voltage to form an image.
Here, when a poorly charged toner, which is a toner with insufficient charge, is used for development, the poorly charged toner contained in the developer carried on the developer carrier is scattered, and toner scattering occurs. This is because a poorly charged toner that does not have sufficient charge has a weak adsorption force to the magnetic carrier and is easily detached from the magnetic carrier, so that the toner is easily scattered. When the toner scatters, problems such as contamination inside the apparatus and background contamination on the image occur. Therefore, in order to attach an appropriate amount of toner to the electrostatic latent image, it is necessary to adjust the charge amount of the toner.

In order to charge the toner, when a two-component developer is used, a method using frictional charging between the toner and the carrier is generally used. Specifically, in the developing device, a predetermined amount of toner and carrier are mixed in advance in a transport path for transporting the developer, and transported while stirring.
At this time, the stirring until the developer is supplied to the developer carrying member of the conventional developing device depends on the conditions such as the output chart image area ratio (* the most disadvantageous is the continuous image passing through the high image area) and the usage environment. In some cases, the charge amount could not be increased sufficiently.
This is because an auger or screw as a developer conveying member that conveys a developer while stirring the developer has a shape suitable for conveying the developer, and the function for stirring is not sufficient. This is because, under disadvantageous conditions, the effect of stirring and charging the toner may be insufficient. Some developing devices supply toner to the developer that has passed through the developing region and have been consumed, and return to the developer supply unit without passing through the agitation process. In some cases, the charge amount of the toner cannot be sufficiently increased until the developer is supplied to the agent carrier.

Further, by increasing the stress received when the excess developer is scraped off by the developer amount regulating member after being pumped up on the developing roller, strong friction is applied between the toner and the carrier, and the friction charging at this time As a result, the charge amount of the toner is increased to a charge suitable for development. In order to increase the stress applied to the developer by the developer amount regulating member, the normal direction on the surface of the developer carrying body in the region upstream of the developer carrying surface with respect to the developer amount regulating member The magnetic flux density was set high, and the developer was rubbed with strong stress.
Thus, by increasing the stress received from the developer amount regulating member, the charge amount of the toner particles can be increased to a state suitable for development. If the charge amount of the toner is always adjusted to a charge amount suitable for development, high-quality image formation can be performed. That is, in the conventional developing device, in order to increase the charge amount of the toner to a charge suitable for development, the magnetic flux density in the upstream region in the direction of surface movement of the developer carrier is set higher than the developer amount regulating member. Was.

  On the other hand, in the developing device 40 of the first embodiment, the low magnetic flux density region γ is formed on the upstream side in the surface movement direction of the developing roller 131 from the position facing the doctor blade 135. In the developing device 40, after the developer is sufficiently stirred by the stirrer 140 that is the stirring unit, the developer is transferred to the developing unit 130 that is the developing unit. Therefore, the developer toner supplied to the surface of the developing roller 131 is used. Is in a state suitable for development. Therefore, it is not necessary to increase the charge amount of the toner by frictional charging at the opposite portion between the doctor blade 135 and the developing roller 131, and even if the low magnetic flux density region γ is formed on the developing roller 131, It is possible to suppress the occurrence of toner scattering.

  The developer in the stirrer 140 of the developing device 40 is transported by its own weight, and includes an agitator 41 provided for stirring the developer. Therefore, compared to a conventional stirring member that is also a transport unit. The developer can be stirred more efficiently. Further, more than half of the developer in the developing device 40, specifically, 50 [%] to 80 [%] of the developer as a whole is accommodated in the stirrer 140. It is desirable to ensure the stirring time so that the toner can be charged more reliably to the desired charge level. However, in high-speed machines, the developer circulation speed in the developing device is fast, so the toner is sufficiently charged. It is difficult to ensure the stirring time to be allowed. With respect to such a problem, the developing device 40 increases the capacity of the stirrer 140 and accommodates more than half of the developer in the developing device in the stirrer 140 to ensure the developer stirring time. Thus, the charge amount of the toner can be increased more reliably.

In the developing device 40, the stirrer 140 includes a toner replenishing path 141 as a toner replenishing unit that replenishes the developer in the developing device 40 with the toner in the toner container 110. As a result, the developer having been replenished with toner is transferred to the developing device 130 through a stirring process in the stirrer 140, so that even if uncharged unused toner is replenished, it is charged to a charge amount suitable for development. In this state, it can be transferred to the developing device 130. Further, in the developing device 40, a developing device 130 is supplied to the developing roller 131 includes a collecting path 137 is a developer collecting section for collecting the developer having passed through the developing region, it recovered collected developer in the collection conveyance path 137 Is transferred to the stirrer 140 by the second developer transfer pipe 150. Then, when agitating with the agitator 140, the toner density that has been reduced is adjusted by being agitated with unused toner and transferred to the developing device 130 as a developer having a toner density suitable for development. As a result, it is possible to suppress the occurrence of image defects due to fluctuations in the toner density of the developer.

  Further, some conventional developing devices replenish toner from above a conveyance path that conveys the developer in a substantially horizontal direction using an auger or a screw. When the toner is replenished in this way, the replenished toner slides on the upper boundary surface of the developer, and the replenished uncharged toner is not stirred with the carrier. On the other hand, since the developer moves in the vertical direction due to its own weight like the stirrer 140, the developer moves more than in the horizontal direction, thereby preventing the replenished toner from slipping and resulting from the top slip. A charging failure can be prevented.

  When charging is performed at the doctor gap, which is the gap between the doctor blade 135 and the surface of the developing roller 131, the developer is charged rapidly, so that it is necessary to apply high stress to the developer, leading to deterioration of the developer. On the other hand, since charging by the stirrer 140 is charged over a long period of time, the charge amount can be increased with low stress, and deterioration of the developer can be suppressed.

As in the case of the stirrer 140, when the capacity of the stirring unit in the developing device is increased in order to sufficiently stir the toner, the charging time can be secured. However, the conventional developing unit and the stirring unit are integrated into a single developing device. Then, the developing device becomes large and the machine main body becomes large.
On the other hand, in the developing device 40, the developing device 130 as the developing unit and the stirrer 140 as the stirring unit are separately formed, and the developer 130 and the stirrer are formed by a developer transfer pipe as a developer transfer path forming member. Such a problem can be solved by connecting 140.
By providing a stirring unit in addition to the developing unit and stirring the developer, the developer can be supplied to the developing roller more reliably with the toner charged. Further, since the developer circulation path is longer than that of the developing device in which the developing unit and the agitation unit are integrated, the contact opportunity between the toner and the carrier is increased, and toner charging failure is less likely to occur. Furthermore, by providing the developing unit and the agitation unit separately, the agitation unit can be provided at a position away from the development unit, and the development unit and the agitation unit are integrated into a space for providing the development unit. It can be made smaller than the developing device. As a result, the degree of freedom in the layout of the entire image forming apparatus is increased, and the copying machine 100 main body can be reduced in size. Further, even if the stirrer 140 is increased in size, the main body of the copying machine 100 can be downsized by providing the stirrer 140 in a dead space in the copying machine 100.

The developer can be transferred to the developing device 130 after sufficient charging performance is imparted in advance by stirring with the stirrer 140 as described above. As a result, a low magnetic flux density region γ in which the magnetic flux density in the normal direction on the surface of the developer carrier is lowered is provided in a region upstream of the developer carrying member in the surface movement direction with respect to the developer amount regulating member. Even if the stress at the time of passing through the doctor gap is reduced, the toner chargeability can be ensured and a high image can be maintained over a long period of time.
The shape of the developer stirring means and the stirrer 140 provided in the stirrer 140 is not limited to the above-described configuration, and any shape can be used as long as the developer can be sufficiently stirred and the toner can be charged to a state suitable for development. Any configuration may be used.

  Furthermore, by providing the developing device 130 and the stirrer 140 separately, the arrangement of the stirrer 140 becomes free. Thereby, even if the position where the developing device 130 is installed is a position that is easily affected by temperature and outside air, the stirrer 140 can be disposed at a position that is not easily affected by temperature and outside air. As a result, the deterioration and deterioration of the developer due to the outside air and temperature can be suppressed.

  Further, in some conventional developing devices, a developer supply unit is provided below the developer carrier, and the developer is pumped up by the magnetic force of the magnet inside the developer carrier. If the developer is pumped up by magnetic force and the magnetic flux density in the normal direction of the surface of the developer carrier is lowered in the region upstream of the developer carrier surface movement direction relative to the developer amount regulating member, poor pumping will occur. May occur. When poor developer pumping occurs, poor image quality (for example, an uneven image) occurs.

  On the other hand, in the developing device 40 of the first embodiment, the developer supply position Sa facing the partition wall end portion 134a where the supply conveyance path 136 serving as a developer supply unit supplies the developer to the surface of the developing roller 131 is vertical. Above the developing roller center point in the direction. As a result, the frictional force between the developer and the surface of the developing roller 131 due to the developer's own weight contributes to the loading of the developer on the surface of the developing roller 131, so that the developer supplied from the supply conveyance path 136 is carried. Magnetic force required for conveyance can be reduced. As a result, even if the magnetic flux density in the normal direction on the surface of the developer carrying member is lowered in the region upstream of the developer carrying member in the surface moving direction with respect to the developer amount regulating member, it is possible to prevent the pumping failure from occurring. be able to. In the developing device 130 shown in FIG. 3, by reducing the central angle α on the upstream side of the regulating member at the developer supply position Sa, the frictional force due to the developer's own weight increases, and the developer is carried and conveyed. The magnetic force required to do this can be further reduced.

  Next, a specific example of the magnetic pole arrangement of the magnet roller 131b that forms the low magnetic flux density region will be described. In each embodiment, as shown in FIG. 3, the position facing the doctor blade 135 on the surface of the developing roller 131 is defined as the regulating member facing position Sb, and the position facing the partition wall end 134a is defined as the developer supply position Sa. Further, the position at the upstream side in the surface movement direction of the developing roller 131 with respect to the regulating member facing position Sb and the central angle at the developing roller center point 131P that is the rotation center of the sleeve 131a with respect to the regulating member facing position Sb It is represented by a side center angle α. Furthermore, the central angle at the developing roller center point 131P between the position on the downstream side in the surface movement direction of the developing roller 131 relative to the regulating member facing position Sb and the developing roller center point 131P between the regulating member facing position Sb is represented by the regulating member downstream side central angle β.

[ Example]
FIG. 6 is a schematic explanatory diagram of a first example of the magnetic pole arrangement of the magnet roller 131b of the developing roller 131 applicable to the developing device 40 of the first embodiment.
As shown in FIG. 6, the magnet roller 131b of the embodiment has an S1, N1, S2, N2, and N3 poles and is fixed, and the sleeve is rotatably provided. The maximum value of the magnetic flux density in the normal direction on the surface of the developing roller 131 of each magnetic pole is 60 [mT] for the S1 pole, 120 [mT] for the N1 pole, 120 [mT] for the S2 pole, and 80 [mT] for the N2 pole. The N3 pole is 80 [mT]. 6, the distance from each curve to the surface of the sleeve 131a indicates the magnitude of the magnetic flux density in the normal direction on the surface of the sleeve 131a.
The developer amount regulating member 4 is, for example, a doctor blade disposed with a gap from the surface of the developing sleeve. As shown in FIG. 3 , it is arranged between the S1 pole and the N3 pole. Further, the N3 pole is arranged so that the magnetic force does not affect the area on the surface of the developing roller 131 on the downstream side in the surface movement direction with respect to the developer supply position Sa.
The developer is supplied from the partition wall end portion 134a to the developer supply position Sa on the surface of the developing roller 131 by its own weight, and is carried on the developing roller 131 by the frictional force with the surface of the developing roller 131 by its own weight. Here, the developer supply position Sa in the present embodiment is on the straight line connecting the center of the developing roller 131 and the partition wall end portion 134 a on the surface of the developing roller 131. Then, the sleeve 131a is rotated and conveyed on the developing roller 131 to a regulating member facing position Sb that is a portion facing the doctor blade 135. The developer on the surface of the developing roller 131 is thinned by passing through a doctor gap that is a gap with the doctor blade 135 at the regulating member facing position Sb. Then, after passing through the doctor gap, the S1 pole conveys the developer to the development nip region, and development on the photoconductor 12 is performed at the N1 pole. After the development is completed, the pole that is transported by the magnetic force of the S2 pole and peels the developer from the developing roller 131 becomes the repulsive magnetic force of the N2 pole and the N3 pole.

In an embodiment, the angle of the regulating member upstream central angle α is, 0 [°] or more, the range of the 60 [°] or less, and a low magnetic flux density region γ not disposed magnetic poles on the inside of the sleeve 131a. In the embodiment, the developing roller 131 and the partition wall 134 are arranged such that the partition wall end portion 134a is disposed at a position where the angle of the upstream central angle α of the regulating member at the developer supply position Sa is 60 [°]. Is arranged. That is, a magnetic field is generated inside the sleeve 131a in a range downstream of the developer supply position Sa in the surface movement direction of the developing roller 131 and upstream of the regulating member facing position Sb in the surface movement direction of the developing roller 131. The magnetic poles as means are not arranged.
In the embodiment , in the low magnetic flux density region γ, the magnetic flux density in the normal direction of the surface is set to 0 [mT] or more and 30 [mT] or less. Specifically, downstream of the regulating member so that the maximum value G of the normal direction magnetic flux density in the low magnetic flux density region γ by the magnetic field of the S1 pole at the regulating member facing position Sb is 30 [mT] or less. The S1 pole regulating member downstream center angle β closest to the regulating member on the side and the S1 pole magnetic force are adjusted.

  The developer supplied to the developing roller 131 is less affected by the magnetic force in the normal direction from the magnet roller 131b in the low magnetic flux density region γ, and the connection between the carriers is weak. The agent passes through the doctor gap and is thinned. Therefore, developer deterioration is suppressed and high image quality can be maintained in the long term.

The smaller the value of the magnetic flux density in the normal direction in the low magnetic flux density region γ, the better. When the magnetic force of the S1 pole is not changed, the value of the central angle β on the downstream side of the regulating member of the S1 pole is increased so that the low magnetic flux density region γ is not affected by the magnetic force of the S1 pole as shown in FIG. S1 is arranged. At this time, the developer at the time of passing through the doctor gap is arranged such that the maximum value G of the magnetic flux density in the normal direction by the magnetic field of the S1 pole at the regulating member facing position Sb is 5 [mT] or less. Can be further reduced.
As will be described later with reference to FIG. 9, the N3 pole is disposed inside the sleeve 131a in a range where the upstream central angle α of the regulating member is 0 [°] or more and 60 [°] or less, and the N3 pole There is a configuration in which a low magnetic flux density region γ is formed by using a magnet having a weak magnetic force. However, it is difficult to arrange the N3 pole so that the maximum value G of the magnetic flux density in the normal direction in the low magnetic flux density region γ is 5 [mT] or less. Therefore, in order to set the maximum value G of the magnetic flux density in the normal direction to 5 [mT] or less, it is preferable to form the low magnetic flux density region γ by disposing no magnetic pole inside the sleeve 131a.
More preferably, the maximum value of the magnetic flux density in the normal direction in the low magnetic flux density region γ is so small that it is nearly zero, and the developer is not so held as to be held by the magnetic force on the surface of the developing roller 131. . At this time, the supplied developer passes through the doctor gap with the rotational conveyance force of the sleeve 131a and the weak magnetic force attracted from the S1 pole, and is then conveyed by the magnetic force generated at the S1 pole, to the development area. It is this to arrive.
In consideration of the developer transportability after passing through the doctor gap, the central angle β on the downstream side of the regulating member of the S1 pole is preferably within 15 [°], and within this range, the regulating member facing position Sb Adjustment is made so that the magnetic flux density in the normal direction is 5 [mT] or less.
This is due to the following reason.
That is, in order to transport the developer with a weak magnetic force exceeding the central angle β on the downstream side of the regulating member S1 of 15 [°], the half width of the S1 pole must be widened. In this case, the movement of the magnetic brush in the developing area (the movement of the magnetic brush lying or standing due to the change in the magnetic flux density in the normal direction depending on the position on the surface of the developing roller 131) becomes large. Flying is difficult to control, and it is disadvantageous for the toner to adhere uniformly to the image carrier. If it is within 15 [°], it is not necessary, and it is advantageous for uniformly adhering the toner to the image bearing member, and it is possible to realize high image quality faithful to the latent image.

In the embodiment, the developing roller 131 and the partition wall 134 are disposed so that the partition wall end portion 134a is disposed at a position where the central angle α of the upstream side of the regulating member at the developer supply position Sa is 60 [°]. is doing. Here, by setting the upstream central angle α of the regulating member at the developer supply position Sa to a smaller angle, for example, the angle of the upstream central angle α of the regulating member at the developer supply position Sa is set to 45 ° or less. This makes it possible to stabilize the developer transport. This is because the smaller the central angle α on the upstream side of the regulating member at the developer supply position Sa, the smaller the inclination of the tangent line on the surface of the developing roller 131 at the developer supply position Sa, and the developer immediately after being supplied to the surface of the developing roller 131. This is because the frictional force with the developing roller 131 due to its own weight increases.

  Note that the low magnetic flux density region γ, which is a range in which the magnetic flux density in the normal direction is 30 [mT], or a range in which no magnetic pole as a magnetic field generating unit is arranged inside the sleeve 131a, is a central angle α on the upstream side of the regulating member. Is more preferably in the range of 0 [°] or more and 20 [°] or less. If the magnetic flux density in the normal direction upstream of the doctor gap with respect to the doctor gap is sufficiently small, even if the angle of the low magnetic flux density region γ is small, the developer does not stay or even if it stays, a large stress is applied. It can be conveyed without. Further, by setting the low magnetic flux density region γ as narrow as 0 [°] or more and 20 [°] or less, the developer is smoothly conveyed by receiving the weak magnetic attractive force derived from the S1 pole, and the weight of the developer is reduced. Therefore, the developer dropped from the supply transport path 136 is easily transported by the transport force in the rotation direction of the sleeve 131a.

[Comparative Example 1]
FIG. 8 is a schematic explanatory diagram of a first comparative example of the magnetic pole arrangement of the magnet roller 131b. Comparative Example 1 was made with the same magnetic pole arrangement as in the example, with the central angle β on the downstream side of the regulating member of S1 pole being 0 [°].
As shown in FIG. 8, except the arrangement of S1, which is the same as the embodiment shown in FIG. Since the downstream central angle β of the regulating member for the S1 pole is set to 0 [°], the maximum value G of the magnetic flux density in the normal direction due to the magnetic field of the S1 pole at the regulating member facing position Sb is equal to the normal direction of the S1 pole. It is substantially the same value as 60 [mT] which is the maximum value of the magnetic flux density. When the maximum value G of the magnetic flux density in the normal direction increases as described above, the connection between the carriers becomes stronger, so that excessive stress is applied when the developer passes through the doctor gap, and the deterioration of the developer is promoted. To do.

[ Reference Example 1 ]
FIG. 9 is a schematic explanatory diagram of a second example of the magnetic pole arrangement of the magnet roller 131b of the developing roller 131 applicable to the developing device 40 of the first embodiment.
Similar to the embodiment, the magnet roller 131b of Reference Example 1, S1 pole, N1 pole, S2 pole, N2 pole, is fixed with a pole N3, and the sleeve 131a rotatably provided. The developer amount regulating member 4 is, for example, a doctor blade disposed with a gap from the surface of the developing sleeve. As shown in FIG. 9 , it is arranged between the S1 pole and the N3 pole.
The developer is attracted onto the developing roller 131 by its own weight and the magnetic force of the N3 pole, and is conveyed on the surface of the developing roller 131 to the regulating member facing position Sb, which is the position facing the doctor blade 135, by the rotation of the sleeve 131a. The developer on the surface of the developing roller 131 is thinned by passing through a doctor gap that is a gap with the doctor blade 135 at the regulating member facing position Sb. Then, after passing through the doctor gap, the S1 pole conveys the developer to the development nip region, and development on the photoconductor 12 is performed at the N1 pole. After the development, the pole that is conveyed by the magnetic force of the S2 pole and peels the developer from the developing sleeve becomes the repulsive magnetic force of the N2 pole and the N3 pole.

In Reference Example 1 , a low magnetic flux density in which the value of the magnetic flux density in the normal direction on the surface of the developing roller 131 is small in a range where the angle of the upstream central angle α of the regulating member is 0 [°] or more and 60 [°] or less. Region γ. Specifically, the normal direction of the N3 pole, which is a magnetic field generating means provided in the sleeve 131a in a range where the central angle α on the upstream side of the regulating member is 0 [°] or more and 60 [°] or less. The maximum value G of the magnetic flux density is 30 [mT] or less. Also, Reference Example 1, as the partition wall end portion 134a is disposed at a position where the angle of the regulating member upstream central angle α equally developer supply position Sa and examples be 60 [°], the developing roller 131 And a partition wall 134 are arranged. That is, the maximum magnetic flux density in the normal direction in the range downstream of the developer supply position Sa in the surface movement direction of the developing roller 131 and upstream of the regulating member facing position Sb in the surface movement direction of the developing roller 131. The value G is 30 [mT] or less.

The developer supplied to the surface of the developing roller 131 is not strongly held and conveyed by the developing sleeve only by the magnetic force generated at the N3 pole. That is, the developer is carried on the developing roller 131 by the lower magnetic force generated at the N3 pole and the frictional force with respect to the sleeve 131a due to its own weight, and the developer passes through the doctor gap by the conveying force generated as the sleeve 131a rotates. It is passed to the magnetic field of the later S1 pole.
In Reference Example 1 , when the developer passes through the doctor blade, the influence of the magnetic force of the N3 pole is small, and stress due to compression when passing through the doctor gap is reduced, so that deterioration of the developer can be suppressed in the long term.

[Comparative Example 2]
FIG. 10 is a schematic explanatory diagram of a second comparative example of the magnetic pole arrangement of the magnet roller 131b. Comparative Example 2 was made with the same magnetic pole arrangement as in Reference Example 1, with the maximum value G of the magnetic flux density in the normal direction of the N3 pole set to 60 [mT].
In FIG. 10, the maximum value G of the magnetic flux density in the normal direction is 60 [mT] in the range where the angle of the upstream central angle α of the restricting member is 0 [°] or more and 60 [°] or less. Furthermore, the maximum value of the magnetic flux density in the normal direction does not fall below 30 [mT] even if the angle of the upstream central angle α of the regulating member is 0 [°] or more and 20 [°] or less.
Therefore, the developer retained by the magnetic force of the N3 pole stays in the upstream side before passing through the doctor gap, and when it passes through the doctor gap, it is subjected to great stress by being compressed. Deteriorates due to stress. Therefore, although a high image can be maintained in the initial stage, charging failure occurs with time and image quality is degraded.

FIG. 11 is a graph showing a relationship between the maximum value G [mT] of the magnetic flux density in the normal direction of the N3 pole and the torque applied to the developer in the same magnetic pole arrangement as in Reference Example 1 and Comparative Example 2.
The maximum value G [mT] of the magnetic flux density in the normal direction at the N3 pole is a force applied to the developer held on the sleeve 131a at the position of the N3 pole. Further, the torque [N · m] applied to the developer is a value obtained by subtracting the torque of the empty unit when there is no developer from the torque of the entire developing unit containing the developer. From FIG. 11, it can be seen that when the maximum value G [mT] of the magnetic flux density in the normal direction of the N3 pole is increased, the torque applied to the developer is increased and high stress is applied to the developer. Therefore, the developer deterioration progresses as the maximum value G [mT] of the magnetic flux density in the normal direction increases.

[Example 3]
FIG. 12 is a schematic explanatory diagram of a third example of the magnetic pole arrangement of the magnet roller 131b of the developing roller 131 applicable to the developing device 40 of the first embodiment.
In Reference Example 2, Reference Example 1 position of the doctor blade 135 than is provided below, the regulating member facing position Sb and the developer supply position Sa is also a configuration diagram of a developing device 130 provided below the Reference Example 1 It is.
In the developing device 40 of Reference Example 2 , since it is necessary to pump up the developer upward, the maximum value of the magnetic flux density in the normal direction of the N3 pole is set to 40 [mT], which is set larger than that of Reference Example 1 . . Then, the developer is held on the surface of the developing roller 131 by the magnetic force of the N3 pole, and the sleeve 131a is conveyed while rotating. In the N3 pole, the maximum value of the normal direction magnetic flux density is 30 [mT] in the range where the angle of the upstream central angle α of the regulating member is 0 [°] or more and 20 [°] or less. The arrangement and the magnetic force to be generated are set.

In the case of the configuration of Reference Example 2, the amount of pumping is increased by increasing the magnetic force, and the stress applied to the developer is increased as compared to the configuration of Reference Example 1. Compared with a developing device to which a strong magnetic holding force is applied, stress applied to the developer can be reduced.

[Comparative Example 3]
The magnet roller 131b in which the N2 pole of the magnetic pole arrangement described in the comparative example 2 is changed to the S3 pole is applied to a developing device having a biaxial screw and a developer supply unit arranged below the developing roller. It was set to 3.
FIG. 13 is a schematic explanatory diagram of the developing device 40 of Comparative Example 3. The developing device 40 of Comparative Example 3 includes a supply / recovery conveying screw 232 and a stirring screw 233 as a biaxial screw. A supply / recovery conveyance path 236 provided with the supply / recovery conveyance screw 232 and a stirring / conveyance path 237 provided with the agitation / conveyance screw 233 are partitioned by a partition wall 134.
In the developing device 40 shown in FIG. 13, the developer that has passed through the development region is recovered in the supply / recovery conveyance path 236 while supplying the developer in the supply / recovery conveyance path 236 to the surface of the developing roller 131. The developer that has reached the downstream side in the conveyance direction of the supply / recovery conveyance path 236 is transferred to the agitation conveyance path 237, receives toner replenishment indicated by an arrow F in the figure, and is conveyed while being agitated in the agitation conveyance path 237. The developer that has reached the downstream side in the conveyance direction of the agitation conveyance path 237 is transferred again to the supply / recovery conveyance path 236 as indicated by an arrow H in the figure.

Regarding the developing roller 131, the magnet roller 131b provided therein has the S3 pole as a pumping magnetic pole, and after development is completed, the poles that are transported by the magnetic force of the S2 pole and peel the developer from the developing roller 131 are the S2 pole and the S3 pole. It becomes the repulsive magnetic force of the pole.
The developing device 40 shown in FIG. 13 is a conventionally known general biaxial screw pumping system, and the magnetic force of the S3 pole and the N3 pole is set large in order to pump up the developer. Further, the developer that forms a magnetic brush having a strong connection between the carriers due to the large magnetic force of the N3 pole is deteriorated by a high stress when the developer passes through the doctor gap, and image deterioration is likely to occur during long-term repeated printing. Further, if the magnetic force of the N3 pole is reduced by this method and the stress applied to the developer is weakened, the density unevenness in the longitudinal direction of the developing roller 131 due to poor pumping of the developer and an appropriate charge amount may not be maintained. I know.

Next, with respect to the configuration shown in FIG. 7 of the example and the configuration of Comparative Example 3, the charge amount of the toner on the sleeve 131a that is the developing sleeve and the charge amount of the toner in the stirring unit were compared.
FIG. 14 is a graph showing the transition of the toner charge amount in each part of the developing device, FIG. 14A shows the transition of the toner charge amount in the developing device of the example , and FIG. 6 shows the transition of the charge amount of toner in the developing device of Comparative Example 3.
In FIG. 14, Q / M on the vertical axis represents the charge amount when the developer 1 [g] is measured and measured by the blow-off method. Further, the measured value of the agitation unit is a measurement value of the charge amount of the developer coming out of the agitation unit at the most downstream side in the developer moving direction in each agitation unit. The measured value on the developing sleeve is a measured value of the charge amount of the developer that has passed through the doctor gap and reached the developing area.
The amount of charge shown in FIG. 14 is an evaluation with an initial developer, and is a measured value at a temperature of 23 [° C.] and a humidity of 50 [° C.].
In the developing device of the embodiment shown in FIG. 14A, the Q / M value of the stirring section is 30 [-μC / g], and the Q / M value on the developing sleeve is 35 [-μC / g]. Met. On the other hand, in the developing device of Comparative Example 3 shown in FIG. 14B, the Q / M value of the stirring section is 18 [-μC / g], and the Q / M value on the developing sleeve is 35 [-μC. / G].
In the measurement by the blow-off method, developer 1 [g] is weighed on a blow-off gauge with a mesh of 22 [μm] and air is blown to separate only the toner from the carrier in the developer (carrier) Is left on the mesh) and the charge of the separated toner is measured.

In the embodiment , when the developer is supplied from the stirrer 140 serving as the stirring unit to the developing roller 131 through the supply conveyance path 136, the developer is charged by sufficient stirring in the stirrer 140. The charge amount Q / M is relatively high. The charge amount Q / M between the developer, the developer in the supply conveyance path 136, and the developer on the surface of the developing roller 131 is substantially the same level. Specifically, the amount of change in the charge amount of the toner after being supplied from the stirrer 140 to the supply conveyance path 136 is at a level within 5 [−μC / g].
In addition, some stress is applied to the stirrer when the charge amount is raised by stirring by agitators such as agitators and screws, but compared with the strong stress when passing through the doctor gap of the developing unit, it is highly efficient with significantly lower stress. It can be charged.

On the other hand, in Comparative Example 3, the supply / recovery conveying screw 232 and the agitating / conveying screw 233 function both for agitation and conveyance, and for these reasons, a sufficient agitating / conveying distance cannot be made for the sake of downsizing the apparatus. Cannot impart sufficient charge to the developer. Therefore, charging is usually performed by applying a strong stress when passing through the doctor gap. Therefore, although the charge amount Q / M of the developer in the supply / recovery conveyance path 236 which is also the stirring unit is low, the development amount on the developing sleeve is rapidly increased. Specifically, the amount of increase in the developer charge amount after passing through the doctor gap is 5 [μC / g] or more.
In the configuration of Comparative Example 3, the developer is deteriorated due to stress applied when the charge amount Q / M is suddenly started up, and the charging capability is lowered with time. Therefore, the configuration of the example is preferable.

[Experiment 1]
Next, the change in the charge amount of the developer over time and the quality of image formation when a running test was performed using the developing devices having the configurations of Example , Reference Example 1, Reference Example 2, and Comparative Example 3. Was evaluated. Specifically, the developer charge amount Q / M before and after the running test was confirmed, and at the same time, the background stain and toner scattering on the image after the running test were evaluated.
Experimental conditions were set as follows.
Experimental apparatus: RICOH printer IPSIO8000
・ Photosensitive drum diameter: φ30 [mm]
Photoconductor linear speed: 160 [mm / sec]
・ Developing sleeve: φ18 [mm]
・ Developing sleeve linear velocity: 240 [mm / sec]
Development gap (gap between the development sleeve and the photosensitive drum): 0.3 [mm]
・ Image formation speed: 45 sheets of A4 size paper per minute
Developer: Toner (6.8 [μm]) and carrier (35 [μm]) are mixed.
・ Before running (initial): 10 [sheets] after launching ・ After running (timed): 50000 [sheets] • Running mode: Image area 20 [%], continuous 100 [sheets / 1 Job]
The toner charge amount Q / M [-μC / g] is measured by picking up the developing unit after a predetermined number of paper passes, sampling the developer from the surface of the developing sleeve after passing through the doctor blade, and developing a V blow-off device (Ricoh Creative Development). ).

FIG. 15 shows the transition of the toner charge amount Q / M in Experiment 1. In FIG. 15, the configuration shown in FIG. 7 of the embodiment is the configuration (A), the reference example 1 is the configuration (B), the reference example 2 is the configuration (C), and the comparative example 3 is the configuration (D).
Due to image quality issues such as background stains on the image and toner scattering, a threshold value for charging deterioration is set. Although it is maintained, it can be seen that in the configuration (d), the charging deteriorates as the quality deteriorates.
As a criterion for setting the image quality to OK, an image that becomes ◯ or Δ described later using Table 1 was set as an allowable range. Therefore, a value close to the lower limit of the charge amount of the developer that achieves a background stain and toner scattering level that is greater than or equal to the visual evaluation Δ was set as a threshold value.
The charging deterioration / threshold value in FIG. 15 was Q / M = 25 [−μC / g].

The experimental results of this experiment are shown in Table 1.

Regarding Table 1, the background stain on the image is visually observed (loupe) on the background of the transfer paper on the transfer paper after the continuous 50000 [sheet] output durability test in an environment of temperature 10 [° C.] and humidity 15 [%]. ). From the good ones, the evaluation was ○, Δ, ×. The mark ○ indicates that the toner stain is not observed at all and is in a good state, and the symbol Δ indicates that a slight stain is observed but does not cause a problem. X indicates that dirt is conspicuous and is outside the allowable range.
Toner scattering was visually evaluated for toner contamination in the copying machine after the continuous 50000 [sheet] output durability test in an environment of a temperature of 40 [° C.] and a humidity of 90 [%]. ○ indicates that the toner is not observed at all and is in a good state, and Δ indicates that only a slight amount of contamination is observed. X is outside the allowable range and very dirty and out of the allowable range.
As in the results shown in Table 1, in the configurations of Example , Reference Example 1 and Reference Example 2 , there is little decrease in the charge amount after 50000 [sheets] from the initial stage, and both toner scattering and background stains on the image are acceptable. It was in. On the other hand, in the configuration of Comparative Example 3, the amount of charge decreased greatly after 50000 [sheets] from the beginning, and both toner scattering and background stains on the image were outside the allowable range.

[Modification 1]
In the developing device 40 of the first embodiment, a second developer transport pipe 150 that transfers the developer from the developing device 130 to the stirrer 140 is connected above the stirrer 140, and the developer is supplied from the stirrer 140 to the developing device 130. The first developer transport pipe 120 to be transferred is connected to the lower side of the stirrer 140. Hereinafter, the second developer transport pipe 150 is connected below the stirrer 140, the first developer transport pipe 120 is connected above the stirrer 140, and the developer in the stirrer 140 is transported from below to above. Modification 1 in which stirring is performed will be described.
FIG. 16 is a perspective explanatory view of the developing device 40 of the first modification. The developing device 130 of the developing device 40 according to the first modification can be the same as the developing device 130 of the developing device 40 according to the first embodiment described with reference to FIGS. 3 and 4. Description is omitted. In the developing device 40 of Modification 1, a first developer transfer pipe 120 that transfers the developer from the stirrer 140 to the developing device 130 is connected above the stirrer 140 as shown in FIG. On the other hand, a second developer transfer pipe 150 for transferring the developer from the developing device 130 to the stirrer 140 is connected to the lower side of the stirrer 140.

FIG. 17 is a schematic cross-sectional view of the stirrer 140 of Modification 1 as viewed from the direction of arrow A in FIG.
The stirrer 140 includes a stirring casing 49 that is a cylindrical member that accommodates the developer therein, and a stirring screw 48 as a screw member. The stirring screw 48 includes a stirring fin 48b and a stirring rotating shaft 48b, and is rotated by a stirring motor 45 provided outside. By this rotation, the developer in the stirring casing 49 is conveyed from below to above and stirred. .
Further, as shown in FIG. 16, the stirrer 140 includes a developer inlet 42 into which the developer transferred from the developing unit 130 flows, below the stirring casing 49, and the developer transferred toward the developing unit 130. Is provided above the stirring casing 49. Further, a toner supply port 44 into which toner supplied from the toner container 110 flows is provided below the stirring casing 49.

The developer transported from the developing device 130 to the developer inlet 42 below the stirrer 140 by the second developer transfer pipe 150 and flows into the stirring casing 49 is moved upward (in the direction of arrow J in the figure) by the stirring screw 48. ). The developer that reaches the upper side of the stirring casing 49 is pushed out from the developer outlet 43 toward the first developer transfer pipe 120, and is conveyed again to the developing device 130 by the first developer transfer pipe 120. .
Since the stirring screw 48 is driven to rotate by the stirring motor 45, the stirring speed is arbitrarily controlled by controlling the rotational speed of the motor according to the developer state (toner concentration, deterioration state) and external conditions (environment, use mode). The rotational speed of the screw 48 can be adjusted.
On the other hand, the toner replenished to the developer in the stirring casing 49 is supplied from the toner storage container 110 through the toner supply path 141 into the stirring casing 49 through the toner supply port 44 below the stirrer 140. By supplying the toner downward, the replenished toner and the developer are mixed while being transported in the upward direction, so that sufficient agitation is performed and the toner in the developer including the replenished toner is mixed. The charge amount can be sufficiently increased and conveyed to the developing device 130. A toner density sensor 139 shown in FIG. 3 is provided in the vicinity of the developing device lower opening 153 that is a developer discharge port of the developing device 130. The toner density sensor 139 detects the toner density of the developer in which the collected developer and the excess developer that have passed through the development area are mixed, and supplies the toner from the toner container 110 according to the detection result feedback information. It is a control method.

  Next, the circulation of the developer in the developing device 40 of Modification 1 will be described. Since the developer flow in the developing device 130 is the same as that in the first embodiment, only the differences will be described. The developer that has reached the second developer transport pipe 150 from the developing device 130 is transported through the second developer transport pipe 150 and flows into the stirrer 140 from below the stirrer 140. The developer that has flowed into the stirrer 140 is replenished and adjusted with toner. As will be described in detail later, the developer is stirred when it is lifted upward from below by a stirring screw 48 inside the stirrer 140. The developer whose toner has been replenished and adjusted and whose toner charge amount has been increased by stirring is supplied to the developing device 130 through the first developer transfer pipe 120.

Next, the flow of the developer in the stirrer 140 of Modification 1 will be described in detail.
The developer in the stirrer 140 is lifted upward by applying a conveying force that is conveyed upward from below by the rotation of the stirring screw 48, and the developer in the upper part of the stirring casing 49 is lifted up. The first developer transfer pipe 120 is discharged from the developer outlet 43 and transported to the developing device 130. At this time, the developer flow in the stirring casing 49 includes a flow in which the developer is transferred upward by the stirring screw 48 as indicated by an arrow J in the figure, and an agitation as indicated by an arrow K in the figure. There is a flow that falls due to its own weight in the gap δ between the screw 48 and the inner wall of the cylindrical stirring casing 49. The developer flowing into the stirring casing 49 is mixed with the flow indicated by the arrow J and the flow indicated by the arrow K, so that the opportunity to be stirred by the upward movement or the downward movement increases. Certain mixing is possible. Further, due to the movement of the developer in the stirring casing 49, the developer is charged by being rubbed against the inner wall of the cylindrical stirring casing 49 and the stirring fin 48 b of the stirring screw 48 and supplied to the developing device 130. It is considered that this contributes to stabilization of the charge amount of the developer.

With respect to the flow of the developer indicated by the arrow K in FIG. 17, the amount of the developer that is directed downward is affected by the size of the gap δ. If the gap δ is small, the amount of the developer going downward becomes smaller than the amount of the developer going upward due to the rotation of the stirring screw 48, and the developer flowing into the stirrer 140 is discharged in a short time and insufficient stirring. Otherwise, there is a possibility that the developer is clogged in a small area between the stirring fin and the stirring casing and cannot be transferred from below to above. On the other hand, if the gap δ is too large, the developer may spill out of the gap and may not be transported upward. For this reason, it is important to set the gap δ to an appropriate value.
Therefore, the present inventors used a stirring casing 49 shown in FIG. 17 with a stirring casing 49 having a cylindrical inner diameter of 14 [mm] and a height of 100 [mm] from the inner bottom surface to the developer outlet 43. An experiment was conducted to adjust the value of the gap δ by changing the conditions of the stirring screw 48. At this time, when the stirring screw 48 having an outer diameter of the stirring rotating shaft 48a of 12 [mm] and a pitch width of the stirring fin 48b of 15 [mm] was rotated at a rotational speed of 1400 [rpm], the outer side of the stirring fin 48b was rotated. When the diameter was in the range of 11 to 13 [mm], both the amount of outflow from the developer outlet 43 and the charge amount of the toner supplied to the developing device 130 could be in an appropriate state. That is, it was found that the range of 0.5 to 1.5 [mm] is appropriate as the interval δ of the stirrer 140.
In the developing device 40 equipped with the stirrer 140 used in the experiment, as in the first embodiment, the developer having a toner particle diameter of 7 [μm], a carrier particle diameter of 35 [μm], and a toner concentration of 7 [%]. And the height from the upper surface of the developer in the stirring casing 49 to the developer outlet 43 is about 10 in a state where the developer circulates stably between the stirrer 140 and the developer 130. [Mm].

  In addition, the angle indicated by ε in FIG. 17 indicates the angle with respect to the horizontal plane of the stirring rotation shaft 48a of the stirring screw 48, and in the stirrer 140 shown in FIG. 17, the angle of ε has a maximum value of 90 [°]. Yes. With respect to this angle ε, it is preferable to set an angle of 60 ° or more in order to maintain the stirring property. The stirring efficiency varies with the angle ε, and the stirring efficiency with the stirring screw 48 decreases as the value decreases. In the stirrer 140 used in the above experiment, when the angle ε is 60 [°] or less, the contact between the upward flow J and the downward flow K of the developer is reduced, and the charging performance is reduced. It was confirmed that the charging performance could not be obtained as the desired charge amount became insufficient in the mixing effect due to the rubbing up and down, and the angle became lower (that is, the direction approached horizontal).

In the developing device 40 according to the first embodiment, since the developer can be prevented from being rubbed by strong stress in the doctor gap, the deterioration of the developer can be suppressed and the life of the developer can be extended. . And even if it is a developing device using a stirrer that stirs while transporting the developer from below to above like the developing device 40 of Modification 1, the deterioration of the developer is similarly suppressed, The lifetime of the developer can be extended.
The first auger 121 and the second auger 151 are provided as developer transfer members provided inside the first developer transfer pipe 120 and the second developer transfer pipe 150 that connect the developing device 130 and the stirring unit 140. It has been. The developer transfer member is not limited to an auger, and a suction method using a screw or air can be used. Here, when an auger or a screw is used as the developer transfer member, if the stirring screw 48 in the stirrer 140 is also included, there is a lot of mechanical contact in the entire conveying process of the developing device 40, so that the developer is stressed. It is conceivable that the developer deteriorates. However, in reality, the developer stressed by the first auger 121, the second auger 151, the stirring screw 48, etc. reduces deterioration compared to the developer stressed by the friction in the conventional doctor gap. It turned out that it can be kept in the state.

18 applies the configuration of the first embodiment shown in FIG. 7 as the developing device 130 of the developing device 40 of the first modification, runs under the same experimental conditions as in the first experiment, and sets the developer deterioration characteristic Q / M. It is a graph which shows the measurement result. The configuration of the developing device 40 of Modification 1 to which the configuration of the embodiment is applied as the developing device 130 is configured (e). The configuration (d) shows Comparative Example 3.
The difference between Experiment 1 and the experiment whose result is shown in FIG. 18 is that the experiment 1 uses the developer after running as it is, while the experiment whose result is shown in FIG. And the developer charge amount of a newly made developer of the toner and NEW toner. This is because the measurement of the charge amount in Experiment 1 includes the deterioration of the charge between the toner and the carrier, and the measurement of the charge amount in the experiment of FIG. 18 is a measurement paying attention to the charging ability of the carrier. In the experiment of FIG. 18, the toner and the carrier in the developer were separated and the measurement was performed using a mag roll mill (small stirring device).
As shown in FIG. 18, the configuration of the modification 1 maintains a state in which the developer deterioration characteristics are good as compared with the configuration of the comparative example 3 over a long period of time. This is because the flow of developer in the stirrer 140 is larger in the configuration of the first modification, and thus is dispersed and subjected to stress (stress is reduced). Further, since the agitator 140 can sufficiently stir, the configuration of the embodiment shown in FIG. 7 can be applied as the developing device 130, and the magnetic flux density in the normal direction on the surface of the developing sleeve in the developing device 130 can be applied. Is set in the low magnetic flux density region, resulting in extremely reduced stress applied to the developer. On the other hand, in the configuration of Comparative Example 3 in which the magnetic force of the doctor pole is high and the rubbing at the doctor gap is performed, local high stress is concentrated on the developer due to rubbing when passing through the doctor gap, and the developer is deteriorated.

Note that the developer deterioration characteristics in FIG. 18 are carrier charging ability (CA) in the developer. The measuring method is that a new toner is added to the carrier from which the toner has been blown off from the developer over time, and the developer is rotated at 280 [rpm] for 300 [sec] by a Magroll mill (manufactured by Ricoh Creative Development Co., Ltd.). The Q / M value is measured by the blow-off method described above. This Q / M value is called carrier charging ability (CA). It is obvious that the carrier charging ability (CA) decreases as the stress increases.
As described above, the agitator that mixes and conveys the developer from the lower side to the upper side as in Modification 1 as compared with the configuration in which high stress is given by the conventional doctor gap as in Comparative Examples 1 to 3. The configuration in which 140 is provided and the developer is circulated between the developing device 130 configured as in the embodiment , the reference example 1 and the reference example 2 can reduce the stress of the developing device 40 as a whole.

As in the developing device 40 of the first modification, the stirrer 140 is transported upward from below, so that the motion of transporting upward and the motion of the developer falling due to gravity are mixed. Since the mixing and stirring of the agent and the replenished toner are satisfactorily performed, a highly efficient charging effect can be obtained and a stable image quality can be obtained.
In addition, since the charging efficiency in the stirrer 140 is increased, the role of charging in passing through the doctor gap of the conventional developing device is greatly reduced, which is a problem in rubbing during charging. Developer deterioration due to high stress can be suppressed. Therefore, in the developing device 40 including the stirrer 140 that performs stirring by conveying the developer from below to above using the screw, the developing device 40 as a whole can be less stressed than the conventional configuration. Thus, it is possible to realize a long life of the developer.

[Modification 2]
In the developing device 40 of the first embodiment, the developer is transferred between the developing device 130 and the stirrer 140 by using two augers (first auger 121 and second auger 151) as developer transferring members. Yes. Hereinafter, Modification 2 in which the developer transfer member is provided only in one of the developer delivery between the developing device 130 and the stirrer 140 will be described.
FIG. 19 is a schematic configuration diagram of the developing device 40 according to the second modification. The developing device 40 of Modification 2 includes a stirrer 140 above the developing device 130. The recovered developer recovered in the recovery conveyance path 137 passes through the second developer transfer pipe 150 and is lifted up to the agitator 140 by a developer transfer member made of an auger or the like provided therein. The developer whose toner concentration is adjusted and agitated by the agitator 140 passes through the first developer transfer pipe 120 due to its own weight and is transferred to the supply conveyance path 136 of the developer 130. Thus, by providing the stirrer 140 upward and transferring the developer from the stirrer 140 to the developing unit 130 by its own weight, the developer transfer member can be reduced. Further, since the toner is simply dropped by its own weight, the stress applied to the developer can be reduced compared to the developer transport using an auger or a screw, and the life of the developer can be extended. As shown in FIG. 19, the arrangement of the stirrer 140 is not limited to that arranged in the vicinity of the developing unit 130, and any position in the position where the developer can be transferred by its own weight. It can be placed anywhere.
When the developer transfer member provided in the second developer transfer pipe 150 uses an auger or a screw as the collected developer, the developer is transported to the stirrer 140 above the developer 130. In addition, the developer may be stressed and deteriorated. However, the stress caused by transporting the developer upward can be suppressed lower than the stress caused when the developer is pumped and carried on the developing roller 131 by a strong magnetic force and is rubbed by the doctor gap. Therefore, as compared with the conventional configuration in which a high stress is applied to the doctor gap, the developer is lifted up to the stirrer 140 installed at a position higher than the developing unit 130 as in Modification 2, and transferred to the supply conveyance path 136 by its own weight, The configuration of supplying to the surface of the developing roller 131 can reduce the developer stress in the entire developing device 40.

[Embodiment 2]
In the first embodiment, the developing device 40 in which the developing unit and the agitating unit are separately provided has been described. However, as a developing device for preventing toner scattering due to poorly charged toner, the developing unit and the agitating unit are provided. An integral developing device may be used. Hereinafter, as a second embodiment, a developing device in which a developing unit and a stirring unit are integrally formed will be described.
FIG. 20 is a schematic configuration diagram of the developing device 40 according to the second embodiment. In the developing device 40 of the first embodiment, the stirrer 140 is provided separately from the developing device 130. However, the developing device 40 of the second embodiment is provided with the stirrer 140 integrally with the developing device 130. Different from the developing device 40 of the first embodiment. Since other configurations are the same as those of the first embodiment, only differences will be described.

As illustrated in FIG. 20, the stirrer 140 of the developing device 40 according to the second embodiment is formed by an agitating and conveying path 237 that is integrated with the developing device 130 and includes an agitating and conveying screw 233 that is a developer agitating unit. The downstream end of the stirring and conveying path 237 in the conveying direction of the stirring and conveying screw 233 communicates with the upstream end of the supply and conveying path 136 in the conveying direction by the first transfer opening 220. On the other hand, the upstream end in the transport direction of the stirring transport screw 233 in the stirring transport path 237 communicates with the downstream end in the transport direction of the recovery transport path 137 through the second transfer opening 250.
Unlike the supply conveyance path 136 and the collection conveyance path 137 that convey the developer in a substantially horizontal direction, the stirring conveyance path 237 is obliquely upward from the collection conveyance path 137 provided below to the supply conveyance path 136 provided above. To the developer.

In addition, since charging is not performed in the doctor gap, which is the gap between the doctor blade 135 and the developing roller 131, the stirring is sufficiently performed by the stirrer 140, and the charge amount of the toner is increased to a state suitable for development. There is a need.
In the developing device shown in FIG. 20, in order to increase the toner charge amount to a state suitable for development, it is necessary to ensure a long stirring time.
Since the developer is conveyed obliquely upward in the agitation conveyance path 237, even if the agitation conveyance screw 233 has the same shape as the supply conveyance screw 132 and rotates at the same rotation speed, the conveyance speed becomes slow. The developer is stored in the stirrer 140 longer than the developer 130. By shortening the time for accommodating the developer in the stirrer 140, a longer stirring time can be secured.
Furthermore, in order to ensure the stirring time, it is desirable to use a stirring and conveying screw 233 having a shape having a low conveying ability.

FIG. 21 is a perspective view comparing the shape of the first example of the agitating and conveying screw 233 having a low conveying ability with the shape of the supply and conveying screw 132. As shown in FIG. 21, the stirring and conveying screw 233 has a blade pitch width of the wing portion wound around the shaft portion smaller than a screw pitch width of the wing portion of the supply and conveying screw 132. If the screw pitch width of the transport screw is made fine, the distance for transporting the developer is shortened while the transport screw rotates once. Therefore, when the agitating and conveying screw 233 and the supply and conveying screw 132 have the same rotational speed, the conveying speed of the agitating and conveying screw 233 is slower than the conveying speed of the supplying and conveying screw 132.
As a result, a longer agitation time can be ensured, so that the developer having a stable toner charge amount can be transferred to the supply conveyance path 136, and toner scattering and background contamination can be suppressed. it can.

FIG. 22 is a perspective view comparing the shape of the second example of the stirring and conveying screw 233 having a low conveying ability with the shape of the supply and conveying screw 132. As shown in FIG. 14, the agitating and conveying screw 233 has a configuration in which ribs 233a, which are plate-like members parallel to the axial direction, are provided on the shaft portion. By providing the rib 233a on the agitating / conveying screw 233, a force that moves in the rotational direction is applied to the developer that is pushed by the blade by the rotation of the agitating / conveying screw 233 and moves in the axial direction by the rib. The transport efficiency is reduced. Therefore, when the agitating and conveying screw 233 and the supply and conveying screw 132 have the same rotational speed, the conveying speed of the agitating and conveying screw 233 is slower than the conveying speed of the supplying and conveying screw 132. Furthermore, since the force which moves to a rotation direction is added with a rib, stirring property rises.
Accordingly, the stirring time can be ensured longer and the stirring property can be improved, so that the developer having a stable charge amount of the toner can be transferred to the supply conveyance path 136, and the toner scattering, Occurrence of soiling can be suppressed.

  It should be noted that the agitation transport path 237 is formed so as to have a larger capacity than the supply transport path 136 and the recovery transport path 137 because it is not possible to cope with an increase in speed simply by reducing the transport speed in the simple transport path 237. Thereby, most of the developer in the developing device 40 can be accommodated in the agitation transport path 237, and the developer agitation time can be ensured for a long time.

In addition, a toner replenishing unit (not shown) replenishes unused toner at the downstream end in the transport direction of the collection transport path 137 near the second transfer opening 250 or the upstream end in the transport direction of the stirring transport path 237. Thereby, the uncharged unused toner can be surely agitated, and the toner scattering and the background stain caused by the unused toner becoming the poorly charged toner can be suppressed.
Also, as shown in FIG. 20, if the integrated type is used, the developing device 40 can be easily detached from the copying machine 100 main body, which is an image forming apparatus, so that maintenance is facilitated.

[Modification 3]
In the first and second embodiments, a blade-like doctor blade is used as the developer amount regulating member. In the developing device 40 of these embodiments, since the agitator 140 is sufficiently agitated and it is not necessary to apply high stress in the doctor gap, the developer amount regulating member is not limited to the blade.
FIG. 23 is a schematic configuration diagram of a developing device 130 that is a developing unit according to Modification 3. As shown in FIG. 23, in the developing device 130 of the third modification, as a developer amount regulating member, a roller shape that rotates with the surface movement of the developing roller 131 in the direction of arrow E in the drawing and is rotatable in the direction of arrow I in the drawing. The doctor roller 135R is provided.
As described above, by using the roller-shaped doctor roller 135R as the developer amount regulating member, it is possible to further reduce the stress in the doctor gap and to prolong the life of the developer.

As described above, according to the first embodiment, the upstream center of the developing roller 131 in the surface movement direction of the regulating member facing position Sb facing the doctor blade 135 as the developer amount regulating member on the surface of the developing roller 131 as the developer carrying member. The maximum angle G of the normal direction magnetic flux density is 30 [mT] or less within a range in which the angle of the restriction member upstream side central angle α, which is an angle, is 0 [°] or more and 60 [°] or less. The low magnetic flux density region γ is as follows. As a result, the influence of the magnetic force in the normal direction from the magnet roller 131b is small and the connection between the carriers is weak, so that the developer passes through the doctor gap and is thinned without receiving excessive stress. Therefore, the deterioration of the developer is suppressed, and the life of the developer can be extended. Further, by suppressing the deterioration of the developer, it is possible to suppress a decrease in image quality due to the deterioration of the developer, and it is possible to maintain a high image quality in the long term.
Further, in the low magnetic flux density region γ where the maximum value G of the magnetic flux density in the normal direction is 30 [mT] or less, the angle of the upstream central angle α of the regulating member is 0 [°] or more and 20 [ °] By narrowing to the following range, the conveyance becomes smooth by receiving the weak magnetic attractive force derived from the S1 pole. Further, since the acceleration of its own weight is applied, the developer dropped from the supply conveyance path 136 which is the developer supply unit is easily conveyed by the conveyance force in the rotation direction of the sleeve 131a.
In addition, the supply conveyance path 136 serving as a developer supply unit is located downstream of the developer roller 131 in the surface movement direction with respect to the developer supply position Sa for supplying the developer to the surface of the developing roller 131 and at the regulating member facing position Sb. On the other hand, the range on the upstream side of the surface movement direction of the developing roller 131 is a low magnetic flux density region where the maximum value G of the magnetic flux density in the normal direction is 30 [mT] or less. As a result, the influence of the magnetic force in the normal direction from the magnet roller 131b is small and the connection between the carriers is weak, so that the developer passes through the doctor gap and is thinned without receiving excessive stress. Therefore, the deterioration of the developer is suppressed, and the life of the developer can be extended. Further, by suppressing the deterioration of the developer, it is possible to suppress a decrease in image quality due to the deterioration of the developer, and it is possible to maintain a high image quality in the long term.
In addition, by setting the maximum value G of the magnetic flux density in the normal direction of the low magnetic flux density region γ to 5 [mT] or less, the stress when passing through the doctor gap can be further reduced, and the life of the developer can be extended. I can plan.
Further, the magnetic flux density in the normal direction of the low magnetic flux density region γ is set to 0 [mT], and the developer is transported only by the frictional force with the surface of the developing roller 131 due to the developer's own weight, so that the stress at the time of passing through the doctor gap. Can be further reduced, and the life of the developer can be extended.
In addition, the magnetic pole as the magnetic field generating means is arranged inside the sleeve 131a as the non-magnetic developing sleeve so that the angle of the central angle α on the upstream side of the regulating member is at least 0 [°] or more and 60 [°] or less. The low magnetic flux density region γ is not set. As a result, the influence of the magnetic force in the normal direction from the magnet roller 131b is small and the connection between the carriers is weak, so that the developer passes through the doctor gap and is thinned without receiving excessive stress. Therefore, the deterioration of the developer is suppressed, and the life of the developer can be extended. Further, by suppressing the deterioration of the developer, it is possible to suppress a decrease in image quality due to the deterioration of the developer, and it is possible to maintain a high image quality in the long term.
In addition, a magnetic pole is provided on the downstream side in the surface movement direction of the developing roller 131 with respect to the developer supply position Sa and on the upstream side in the surface movement direction of the developing roller 131 with respect to the regulating member facing position Sb. A low magnetic flux density region γ that is not arranged is used. As a result, the influence of the magnetic force in the normal direction from the magnet roller 131b is small and the connection between the carriers is weak, so that the developer passes through the doctor gap and is thinned without receiving excessive stress. Therefore, the deterioration of the developer is suppressed, and the life of the developer can be extended. Further, by suppressing the deterioration of the developer, it is possible to suppress a decrease in image quality due to the deterioration of the developer, and it is possible to maintain a high image quality in the long term.
Further, the doctor blade 135 faces the surface of the developing roller 131 above the developing roller center point 131P that is the rotation center of the sleeve 131a in the vertical direction. In such a position, the frictional force between the developer and the surface of the developing roller 131 due to the developer's own weight contributes to the loading of the developer on the surface of the developing roller 131, and thus is required for carrying and transporting the developer. Magnetic force can be reduced.
Further, the developer supply position Sa that faces the partition wall end 134a where the supply conveyance path 136 serving as a developer supply section supplies the developer to the surface of the developing roller 131 is more than the developing roller center point in the vertical direction. Above. As a result, the frictional force between the developer and the surface of the developing roller 131 due to the developer's own weight contributes to the loading of the developer on the surface of the developing roller 131, so that the developer supplied from the supply conveyance path 136 is carried. Magnetic force required for conveyance can be reduced. Therefore, it is possible to suppress the occurrence of image quality defects (for example, uneven images) due to poor developer pumping.
Further, by setting the developer supply position Sa within the low magnetic flux density region γ, the developer supplied to the surface of the developing roller 131 is hardly affected by the magnetic force, and the frictional force with the surface of the developing roller 131 due to its own weight. To reach the doctor gap. Thereby, the stress in the doctor gap can be reduced.
Further, by providing a recovery conveyance path 137 as a developer recovery unit that recovers the developer that has passed through the development area on the surface of the developing roller 131, it is possible to prevent the developer having a lowered toner concentration from being used again for development. And stable image quality can be maintained.
In addition, since the developer can be transferred to and from the developing device 130 and has a stirrer 140 including an agitator 41 as a stirring unit that can be charged more reliably than a conventional developing device, Even in a configuration in which charging in the gap is not performed, the occurrence of toner scattering and scumming can be suppressed.
Further, the developing device 130 that is the developing unit and the stirrer 140 that is the stirring unit are configured separately, and the first developer transfer pipe 120 that is the two developer transfer pipes that are the developer transfer path forming member and the first developer transfer pipe 120. By connecting the developing device 130 and the stirrer 140 with the two developer transfer pipes 150, a stirring portion can be provided at a position away from the developing portion, and a space for providing the developing portion is provided between the developing portion and the stirring portion. Can be made smaller than that of a developing device in which the unit is integral. Thereby, the degree of freedom of the layout of the entire image forming apparatus is widened, and the apparatus main body can be downsized. Furthermore, by disposing the stirrer 140 at a position that is not easily affected by temperature or outside air, the developer in the stirrer 140 can be prevented from being deteriorated or altered by the outside air or temperature.
Further, more than half of the developer in the developing device 40, specifically, the developer of 50 [%] to 80 [%] of the entire developer is accommodated in the stirrer 140. Therefore, the developer agitation time can be ensured and the toner charge amount can be increased more reliably, so that the occurrence of toner scattering can be more reliably suppressed.
Further, the stirrer 140 is provided with a toner replenishing path 141 as a toner replenishing means for replenishing the developer in the developing device 40 with the toner in the toner container 110. As a result, the developer having been replenished with toner is transferred to the developing device 130 through a stirring process in the stirrer 140, so that even if uncharged unused toner is replenished, it is charged to a charge amount suitable for development. In this state, it can be transferred to the developing device 130. As a result, it is possible to prevent the uncharged unused toner from becoming uncharged toner and supplied to the developing roller 131 and causing toner scattering.
In addition, the developing device 40 includes a recovery conveyance path 137 that is a developer recovery unit that recovers the developer that has been supplied to the developing roller 131 and passed through the development area to the developing device 130, and collects the collected development collected in the recovery conveyance path 137. The developer is transferred to the stirrer 140 by the second developer transfer pipe 150. Then, when agitating with the agitator 140, the toner density that has been reduced is adjusted by being agitated with unused toner and transferred to the developing device 130 as a developer having a toner density suitable for development. As a result, it is possible to suppress the occurrence of image defects due to fluctuations in the toner density of the developer.
Further, by using the blade-shaped doctor blade 135 as the developer amount regulating member, the developer on the surface of the developing roller 131 can be regulated to an amount suitable for development with a simple configuration.
Further, by using the roller-shaped doctor roller 135R as the developer amount regulating member, it is possible to reduce the developer stress in the doctor gap while regulating the developer on the surface of the developing roller 131 to an amount suitable for development. it can.
Further, the copying machine 100 that is an image forming apparatus has the developing device 40 as the developing means, thereby making it possible to extend the life of the developer. Furthermore, by suppressing the deterioration of the developer, it is possible to suppress a decrease in image quality due to the deterioration of the developer, and it is possible to maintain a high image quality in the long term.
Further, according to the developing device 40 of the second embodiment, since the developing device 130 and the stirrer 140 are integrally configured, the developing device 40 can be easily detached from the main body of the copying machine 100 that is an image forming apparatus. And maintenance becomes easy.

1 is a schematic configuration diagram of a copier according to a first embodiment. FIG. 3 is an explanatory perspective view of the developing device according to the first embodiment. FIG. 3 is a schematic cross-sectional view of the developing device viewed from the direction of arrow A in FIG. 2. FIG. 3 is a schematic cross-sectional view of the vicinity of the front end portion of the developing device in FIG. 1 is a schematic cross-sectional view of a stirrer according to Embodiment 1. FIG. The schematic explanatory drawing of the magnetic pole arrangement | positioning of the magnet roller which concerns on an Example . The schematic explanatory drawing of the more preferable magnetic pole arrangement | positioning of the magnet roller which concerns on an Example . FIG. 5 is a schematic explanatory diagram of a magnetic pole arrangement of a magnet roller according to Comparative Example 1. FIG. 3 is a schematic explanatory diagram of magnetic pole arrangement of a magnet roller according to Reference Example 1 . FIG. 6 is a schematic explanatory diagram of magnetic pole arrangement of a magnet roller according to Comparative Example 2. The graph which shows the relationship between the maximum value of the magnetic flux density of the normal direction of N3 pole, and the torque concerning a developing agent. FIG. 5 is a schematic explanatory diagram of magnetic pole arrangement of a magnet roller according to Reference Example 2 . FIG. 9 is a schematic explanatory diagram of a developing device according to Comparative Example 3. 6 is a graph showing the transition of the charge amount of toner in each part of the developing device. (A) shows the change in the toner charge amount in the developing device of the example , and (b) shows the change in the toner charge amount in the developing device of Comparative Example 3. 6 is a graph showing a change in toner charge amount Q / M in Experiment 1; FIG. 9 is a perspective explanatory view of a developing device according to Modification 1. FIG. 17 is a schematic cross-sectional view of the developing device viewed from the direction of arrow A in FIG. 16. 10 is a graph showing a transition of developer deterioration characteristics Q / M in an experiment using the developing device of Modification 1; FIG. 10 is a schematic cross-sectional view of a developing device according to Modification 2. FIG. 3 is a schematic configuration diagram of a developing device according to a second embodiment. The perspective explanatory drawing of the 1st example of the stirring conveyance screw of a shape with low conveyance capability. The perspective explanatory drawing of the 1st example of the stirring conveyance screw of a shape with low conveyance capability. FIG. 10 is a schematic configuration diagram of a developing device according to Modification 3.

Explanation of symbols

DESCRIPTION OF SYMBOLS 40 Developing device 41 Agitator 41a Stirring shaft 41b Stirring blade 42 Developer inflow port 43 Developer outflow port 44 Toner supply port 45 Stirring motor 46 Valve motor 47 Valve 47a Valve rotation shaft 100 Copying machine 110 Toner container 120 First developer transfer Pipe 121 First auger 122 First auger drive shaft 123 Developing unit upper opening 130 Developing unit 131 Developing roller 132 Supply conveyance screw 133 Collection conveyance screw 134 Partition wall 135 Doctor blade 136 Supply conveyance path 137 Collection conveyance path 139 Toner density sensor 140 Stirrer 141 Toner supply path 142 Toner transport auger 148 Toner supply motor 150 Second developer transfer pipe 151 Second auger 152 Second auger drive shaft 153 Developer lower opening 236 Supply recovery transport path 232 Supply / recovery transport screw

Claims (19)

A two-component developer composed of a magnetic carrier and toner is carried on the surface, the surface moves, and the toner is supplied to the latent image on the surface of the latent image carrier in a development area facing the latent image carrier. A developer carrier to be developed
A developer supply section for supplying the developer to the surface of the developer carrier;
Development comprising a developer amount regulating member facing the surface of the developer carrying body and regulating the layer thickness of the developer supplied on the surface of the developer carrying body by the developer supply unit and conveyed in the development area In a developing device having a section,
A wall member that forms a developer supply transport path as the developer supply section that supplies the developer carrying surface while transporting the developer;
The position of the surface of the developer carrying member facing the wall end which is the tip of the wall member facing the developer carrying member is above the rotation center of the developer carrying member in the vertical direction;
The developer amount regulating member faces the developer carrier surface above the rotation center of the developer carrier in the vertical direction,
A regulating member facing downstream of the developer carrying member in the surface movement direction relative to the position of the developer carrying member surface facing the wall end and facing the developer amount regulating member on the developer carrying member surface A range on the upstream side in the surface movement direction of the developer carrying member with respect to the facing position,
The magnetic flux density in the normal direction at the surface of the developer carrying member, 0 [mT] or more, and a low magnetic flux density region to be 30 [mT] following ranges,
The developing device according to claim 1, wherein the low magnetic flux density region is not provided with a peak position of a magnetic flux density in a normal direction of a magnetic pole provided in the developer carrier. The developing device according to claim 1 .
A developing device, wherein a magnetic flux density in a normal direction of the low magnetic flux density region is in a range of 0 [mT] to 5 [mT]. A two-component developer composed of a magnetic carrier and toner is carried on the surface, the surface moves, and the toner is supplied to the latent image on the surface of the latent image carrier in a development area facing the latent image carrier. A developer carrier to be developed
A developer supply section for supplying the developer to the surface of the developer carrier;
Development comprising a developer amount regulating member facing the surface of the developer carrying body and regulating the layer thickness of the developer supplied on the surface of the developer carrying body by the developer supply unit and conveyed in the development area In a developing device having a section,
A wall member that forms a developer supply transport path as the developer supply section that supplies the developer carrying surface while transporting the developer;
The position of the surface of the developer carrying member facing the wall end which is the tip of the wall member facing the developer carrying member is above the rotation center of the developer carrying member in the vertical direction;
The developer amount regulating member faces the developer carrier surface above the rotation center of the developer carrier in the vertical direction,
A regulating member facing downstream of the developer carrying member in the surface movement direction relative to the position of the developer carrying member surface facing the wall end and facing the developer amount regulating member on the developer carrying member surface A range on the upstream side in the surface movement direction of the developer carrying member with respect to the facing position,
The magnetic flux density in the normal direction at the surface of the developer carrying member, 0 [mT] to become a developing device according to claim to Rukoto and low flux density regions. The developing device according to claim 1, 2 or 3,
The developer carrying member comprises a plurality of magnetic field generating means fixed inside, and a non-magnetic developing sleeve which carries the developer on its surface and is rotatable. A two-component developer composed of a magnetic carrier and toner is carried on the surface, the surface moves, and the toner is supplied to the latent image on the surface of the latent image carrier in a development area facing the latent image carrier. A developer carrier to be developed
A developer supply section for supplying the developer to the surface of the developer carrier;
Development comprising a developer amount regulating member facing the surface of the developer carrying body and regulating the layer thickness of the developer supplied on the surface of the developer carrying body by the developer supply unit and conveyed in the development area In a developing device having a section,
A wall member that forms a developer supply transport path as the developer supply section that supplies the developer carrying surface while transporting the developer;
The position of the surface of the developer carrying member facing the wall end which is the tip of the wall member facing the developer carrying member is above the rotation center of the developer carrying member in the vertical direction;
The developer amount regulating member faces the developer carrier surface above the rotation center of the developer carrier in the vertical direction,
A regulating member facing downstream of the developer carrying member in the surface movement direction relative to the position of the developer carrying member surface facing the wall end and facing the developer amount regulating member on the developer carrying member surface A range on the upstream side in the surface movement direction of the developer carrying member with respect to the facing position,
A magnetic flux density in the normal direction on the surface of the developer carrying member is a low magnetic flux density region in a range of 0 [mT] to 30 [mT],
The developer carrier comprises a plurality of magnetic field generating means fixed inside, and a non-magnetic developing sleeve which carries the developer on its surface and is rotatable.
2. A developing apparatus according to claim 1, wherein said magnetic field generating means is not disposed inside said non-magnetic developing sleeve in said low magnetic flux density region. The developing device according to claim 1, 2, 3, 4 or 5,
The developing device includes a developer collecting unit that collects the developer supplied to the developer carrying member and passed through the developing region. Claim 1, 2, 3, 4, 5 or in the developing device 6,
A developing device comprising toner replenishing means for replenishing the developer with the toner. The developing device according to claim 1, 2, 3, 4 or 5,
A developing device, comprising: an agitation unit capable of delivering the developer to and from the developing unit and provided with an agitation unit for agitating the developer. The developing device according to claim 8 .
The developing unit is a single housing provided with a developer collecting unit that collects the developer supplied to the developer carrying member and passed through the developing region, and the developer supplying unit.
The stirring unit is a case separate from the developing unit and includes the stirring unit therein.
The housing of the developing unit and the housing of the stirring unit are connected by two developer transfer path forming members,
The developer in the developer recovery section is transferred to the stirring section via one developer transfer path forming member,
The developing device, wherein the developer in the stirring section is transferred to the developer supply section through the other developer transfer path forming member. The developing device according to claim 9 .
The developing device, wherein the agitating unit conveys and stirs the developer from below to above. The developing device according to claim 10 .
The agitation section includes a cylindrical member that houses the developer therein, and a screw member that rotates to convey the developer in the cylindrical member upward from below. Development device. The developing device according to claim 10 or 11 ,
A toner replenishing means for replenishing the developer with the toner;
A developing device comprising a toner replenishing portion for replenishing toner from the toner replenishing means below the stirring portion. The developing device according to claim 8 .
The developing device, wherein the developing unit and the stirring unit are integrally formed. The developing device according to claim 8, 9,10,11,1 2 or 13,
A developing device characterized in that more than half of the developer in the developing device is present in the stirring section. The developing device according to claim 8, 9,10,11,12,1 3 or 14,
A toner replenishing means for replenishing the developer with the toner;
A developing device configured to transfer the developer, which has been replenished with the toner by the toner replenishing unit, to the developing unit after being stirred by the stirring unit. The developing device according to claim 8, 9,10,11,12,13,1 4 or 15,
The developing unit includes a developer collecting unit that collects the developer supplied to the developer carrying member and passed through the developing region,
A developing apparatus configured to transfer the collected developer collected by the developer collecting unit to the stirring unit, and then to the developing unit after stirring by the stirring unit. The developing device according to claim 1,2,3,4,5,6,7,8,9,10,11,12,13,14,1 5 or 16,
2. A developing device according to claim 1, wherein the developer amount regulating member has a blade shape whose tip is opposed to the surface of the upper developer carrying member. The developing device according to claim 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,1 6 or 17,
The developing device according to claim 1, wherein the developer amount regulating member has a roller shape that can be rotated with respect to the surface movement of the developer carrying member. At least a latent image carrier;
Charging means for charging the surface of the latent image carrier;
Latent image forming means for forming an electrostatic latent image on the latent image carrier;
In an image forming apparatus having developing means for developing the electrostatic latent image into a toner image,
As developing means, claim 1,2,3,4,5,6,7,8,9,11,12,13,14,15,16,1 7 or uses a developing apparatus according to 18 An image forming apparatus.

Images