1. Field of the Invention
The present invention generally relates to a development device, a process cartridge, and an image forming apparatus such as a copier, a printer, a facsimile machine, or a multifunction machine capable of at least two of these functions that includes the development device.
2. Discussion of the Background Art
In general, electrophotographic image forming apparatuses, such as copiers, printers, facsimile machines, or multifunction devices including at least two of those functions, etc., include a latent image carrier on which an electrostatic latent image is formed and a development device to develop the latent image with developer.
There are two types of developer used in electrophotographic images forming apparatuses, namely, one-component developer consisting of magnetic or non-magnetic toner and two-component developer including toner and carrier particles. Recently, two-component developer has come to be widely used because its durability and image quality are better than those of one-component developer. Development devices using two-component developer (hereinafter “two-component development devices”) typically include a rotary cylindrical developer carrier (e.g., development sleeve) inside which a stationary magnetic field generator having multiple magnetic poles is provided to carry the developer on the development sleeve.
In certain known development devices, the magnetic field generator has five magnetic poles that can generate magnetic fields of sufficient strength for the development sleeve to carry the developer. The five magnetic poles include an attraction pole, a pre-development transport pole, a development pole, a release pole, and a post-development transport pole. The developer is attracted to a circumferential surface of the development sleeve at a position corresponding to the attraction pole (hereinafter “attraction portion”), and the pre-development pole generates a magnetic field for the development sleeve to transport the developer carried on the development sleeve to a development area or range facing the latent image carrier. The development pole contributes to latent image development in the development range, and the release pole contributes to separating the developer that has passed through the development range from the development sleeve. In this known configuration, the post-development transport pole is disposed between the development pole and the release pole and generates a magnetic field for the development sleeve to reliably transport the developer that has passed through the development range to the release position. In addition, in this known configuration, a developer regulator (e.g., doctor blade) is disposed facing the development sleeve between the attraction pole and the pre-development pole to adjust the amount of the developer carried to the development range.
With this configuration, processes of attracting the developer to the circumferential surface of the development sleeve, transporting the developer to the development range, developing the latent image with the developer, and releasing the developer from the development sleeve can be performed reliably. Alternatively, in certain known development devices, the magnetic field generator further includes a developer regulation pole disposed between the attraction pole and the pre-development pole, facing the developer regulator, and does not include the post-development transport pole.
At present, it is preferred that the development devices be more compact due to an increasing demand for more compact image forming apparatuses. The development devices can be more compact by using a development sleeve of reduced diameter.
However, in the known development devices, there in a practical limit to how much the diameter of the development sleeve can be reduced because it becomes difficult to reliably attract the developer to the development sleeve, transport the developer to the development range, develop the latent image with the developer, and release the developer from the development sleeve. Although magnets capable of generating a magnetic field of sufficient intensity are required to perform these processes reliably, the size of magnets increases as the intensity increases and therefore, it is difficult to reduce the diameter of the development sleeve inside which such large magnets are provided.
In view of the foregoing, there is a need to reduce the diameter of the developer carrier to make the development devices more compact while performing the above-described processes reliably, which the known image forming apparatuses fail to do.
In view of the foregoing, one illustrative embodiment of the present invention provides a development device.
The development device includes a developer containing part containing two-component developer including toner and magnetic carrier particles, a cylindrical developer carrier to carry by rotation the developer supplied from the developer containing part to a development range where the developer carrier faces an image carrier, a first developer transport member disposed in the developer containing part, to supply the developer to the developer carrier while transporting the developer in an axial direction of the developer carrier, and a magnetic field generator disposed inside the developer carrier, having three developer-carrying magnetic poles each capable of generating a magnetic field to keep the developer on a circumferential surface of the developer carrier.
The three developer-carrying magnetic poles consist of a development pole to generate a first magnetic field in the development range, a pre-development pole to generate a second magnetic field to transport the developer supplied from the developer containing part to the development range, and a post-development pole to generate a third magnetic field disposed between the first magnetic field and the second magnetic field, to transport the developer that has passed the development range to a release position where the developer is separated from the circumferential surface of the developer carrier. The second magnetic field causes the developer supplied from the developer containing part to be attracted to the circumferential surface of the developer carrier at a developer attraction position. The first magnetic field and the second magnetic field together keep the developer on the circumferential surface of the developer carrier from the developer attraction position to the development range. The first magnetic field and the third magnetic field together keep the developer on the circumferential surface of the developer carrier from the development range to the release position.
Another illustrative embodiment of the present invention provides a process cartridge that is removably installable to an image forming apparatus. The process cartridge includes the development device described above and at least one of an image carrier on which a latent image is formed, a charging member disposed adjacent to the image carrier, to charge a surface of the image carrier, and a cleaning member to remove any toner remaining on the surface of the image carrier after the toner image is transferred from the image carrier.
Yet another illustrative embodiment of the present invention provides a image forming apparatus including an image carrier on which a latent image is formed, a charging member disposed adjacent to the image carrier, to charge a surface of the image carrier, the development device described above, a transfer member to transfer the toner image onto a sheet of recording media, and a cleaning member to remove any toner remaining on the surface of the image carrier after the toner image is transferred from the image carrier.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
In describing preferred embodiments illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the disclosure of this patent specification is not intended to be limited to the specific terminology so selected, and it is to be understood that each specific element includes all technical equivalents that operate in a similar manner and achieve a similar result. Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views thereof, and particularly to
An endless transfer-transport belt 15 wound around support rollers 18 and 19 is provided beneath the image forming units 17. The support rollers 18 and 19 are respectively disposed on a downstream side and an upstream side in the belt transport direction. An upper side of the transfer-transport belt 15 rotates in a direction indicated by an arrow shown in
The printer 100 further includes a fixing device 24 disposed downstream from the downstream support roller 18 in the belt transport direction and a discharge tray 25 provided on an upper portion of a main body of the printer 100. The fixing device 24 fixes a toner image on the sheet P after the sheet P is separated from the transfer-transport belt 15, after which the sheet P is discharged onto the discharge tray 25.
The printer 100 further includes sheets cassettes 20, 21, and 22 each containing multiple sheets P, a feed unit 26 to feed the sheets P from the sheets cassettes 20, 21, and 22 to the image forming units 17, and a pair of registration rollers 23. The registration rollers 23 forward the sheet P sent from the sheet cassettes 20 through 22 to a transfer positions where the transfer-transport belt 15 faces the respective image forming units 17.
It is to be noted that in the configuration shown in
Each image forming unit 17 includes a drum-shaped photoconductor 1 serving as a latent image carrier. A charger 2 serving as a charging member to charge a surface of the photoreceptor 1, a developing device 3 to develop an electrostatic latent image formed on the photoconductor 1, and a cleaner 6 to clean the surface of the photoconductor 1 are provided around the photoreceptor 1. An exposure unit 16 directs writing light (e.g., writing beam) L onto the surface of each photoconductor 1 between the charger 2 and the development device 3. Thus, each image forming unit 17 has a known configuration. The photoconductor 1 may be a belt instead of a drum.
In the present embodiment, at least the developing device 3 and the photoconductor 1 are integrated into a single process cartridge that is removably installed in the body of the image forming apparatus 100.
In the above-described printer 100, when users instructs the printer to start image formation, each image forming unit 17 stars to form a single color toner image. More specifically, in each image forming unit 17, the photoconductor 1 is rotated by a main motor, not shown, and is charged uniformly at a portion facing the charger 2 as the charging process. Then, the exposure unit 16 directs writing beams L onto the respective photoconductors 1 according to yellow, cyan, magenta, and black image data decomposed from multicolor image data, thus forming electrostatic latent images thereon. Each latent image is then developed by the development device 3, and thus single-color toner images are formed on the respective photoconductors 1. While the processes described above are performed, the sheets P are fed one by one from one of the sheet cassettes 20 through 22 by the feed unit 26 to the registration rollers 23, which forward the sheet P to the transfer-transport belt 15, timed to coincide with the arrival of the toner images formed on the respective photoconductors 1. Then, the transfer-transport belt 15 transports the sheet P to the respective transfer positions.
When the surface of each photoconductor drum 1 carrying the toner image reaches a portion facing the transfer bias roller 5 via the transfer-transport belt 15, the toner image is transferred by the bias applied by the transfer bias roller 5 from the photoconductor 5 onto the transfer-transport belt 15. Thus, the K, M, Y, and C toner images are sequentially transferred from the respective photoconductors 1 and superimposed one on another on the sheet P, forming a multicolor toner image on the sheet P. The sheet P on which the multicolor toner image is formed is then separated from the transfer-transport belt 15, and then the fixing device 54 fixes the image on the sheet P thereon, after which the sheet P is discharged onto the discharge tray 25.
After the toner image is transferred from each photoconductor 1, the cleaner 6 removes any toner remaining thereon, and a discharge lamp, not shown, removes electrical potentials remaining on the photoconductor 1 as required. Then, the charger 2 again charges the surface of the photoconductor 1.
Descriptions are given below of the development devices 3K, 3M, 3Y, and 3C according to a first embodiment, which have a similar configuration except that the color of the toner used therein is different.
It is to be noted that reference characters 34p represents a center of rotation of the development sleeve 34a, 46 represents a release portion where the developer 32 leaves the circumferential surface of the development sleeve 34a, and 47 represents a attraction portion (developer attraction position) where the developer 32 is carried onto the development sleeve 34a from a supply path 37.
The development device 3 further includes two developer transport members, namely, a supply screw 39 and a circulation screw 40, both disposed in substantially parallel to a roller shaft 34c shown in
Additionally, an end portion of the partition 36 on the side of the development sleeve 34a stands vertically in
It is to be noted that, in the present embodiment, because the amount of the developer 32 in the supply path 37 decreases as the developer 32 flows downstream in the developer transport direction in the supply path 37, the height of the barrier 43 decreases toward downstream in the developer transport direction.
As shown in
The developer 32 contained in the supply path 37 is supplied onto a circumferential surface of the development sleeve 34a while transported by the supply screw 39. More specifically, the developer 32 overstrides the barrier 43 as the supply screw 39 rotates or is attracted by the magnetic force exerted by the magnetic roller 34b provided inside the development sleeve 34a. The developer 32 sent from the supply path 37 is carried on the development roller 34a in the attraction portion 47, attracted by the magnetic force exerted by the magnetic roller 34b and is transported in a direction indicate by arrow B as the development sleeve 34a rotates. While the developer 32 carried on the development sleeve 34a passes a portion facing the developer regulator 35 (hereinafter “developer regulation portion”), the developer regulator 35 scrapes off excessive developer 32 from the development sleeve 34a as indicated by arrow B1. Thus, only a predetermined or given amount of the developer 32 passes the portion facing the developer regulator 35 in the direction indicated by arrow B.
Then, the predetermined amount of the developer 32 passes through the development range A as indicated by arrow B2, after which the developer 32 leaves the development sleeve 34a and flows to a bottom portion 33b of the casing 33 and thus enters the circulation path 38. Thus, the developer 32 that is not supplied to the photoconductor 1 but remains on the development sleeve 34a after passing through the development range A is collected in the circulation path 38 instead of being transported to the supply path 37 immediately as the development sleeve 34a rotates. In the circulation path 38, the collected developer 32 is mixed with fresh toner supplied thereto and then again sent to the supply path 37. Therefore, only sufficiently agitated developer 32 can be present in the supply path 37. The developer that reaches a downstream end portion in the developer transport direction in the supply path 37 as well as the developer that has left the development sleeve 34a after passing the development range A are transported through the circulation path 38 and then sent to an upstream end portion of the supply path 37. The developer 32 in the circulation path 38 includes the developer 32 whose toner concentration is decreased while it passes through the development range A. Therefore, fresh toner is supplied to the circulation path 38 according to toner consumption calculated based on data of latent images or a detected toner concentration in the circulation path 38. Thus, the developer 32 having a proper toner concentration can be supplied to the supply path 37.
As shown in
Not all of the developer 32 sent from the circulation path 38 to the supply path 37 reaches the downstream end of the supply path 37 in the developer transport direction of the supply screw 39. As indicated by arrow B shown in
In the present embodiment, as described above, the developer leaves the development sleeve 34a after passes through the development range A and is collected in the circulation path 38. The developer whose toner concentration is decreased is not immediately supplied to the supply path 37, but the toner concentration thereof is adjusted in the circulation path 38, and thus the toner concentration can be kept constant across the supply path 37.
The development roller 34 is described in further detail below.
As shown in
In the present embodiment, the maximum magnetic flux density of the north poles N1 and N2, and the south pole S1 in the normal direction to the development sleeve 34a is not less than 10 mT. When this maximum magnetic flux density is not less than 10 mT, the strength of the magnetic fields generated by these developer-carrying magnetic poles is sufficient for keeping the developer 32 on the circumferential surface of the development sleeve 34a.
As shown in
Therefore, the present embodiment uses the development roller 34b that is a “three-pole development roller” inside which three magnets are provided (hereinafter “three-pole configuration”). Thus, by reducing the number of the magnets provided in the magnet roller 34b, the space inside the development sleeve 34a necessary for the magnet roller 34b can be reduced, that is, the diameter of the development sleeve 34a can be reduced. When the diameter of the development sleeve 34a is the same, the space for each magnet forming a single developer-carrying magnetic pole can be increased in the three-pole configuration from that in the five-pole configuration. Therefore, even when the diameter of the development sleeve 34a is so small that the each magnet in the five-pole configuration cannot generate a magnetic field of sufficient strength, each magnet in the three-pole configuration can generate a magnetic field of sufficient strength.
It is to be noted that the magnetic field generator is not limited to the magnet roller 34b in which magnets are embedded. Alternatively, magnetic poles similar to those generated by the magnet roller 34b can be generated by forming a cylindrical member with a mixture of resin and magnetic powder, and disposing a magnetizing yoke around the cylindrical member to magnetize it. Although the space for the magnetic yoke inside the development sleeve is limited when the diameter of the development sleeve is smaller, the space can be larger in the three-pole configuration.
Thus, in the present embodiment, by reducing the diameter of the development sleeve 34a, the size of the development device 3 can be reduced, and accordingly the process cartridge (image forming unit 17) including development device 3 can be more compact. Further, the image forming apparatus 100 that includes multiple process cartridges can be more compact.
Next, release of the developer 32 from the development sleeve 34a (hereinafter simply “release of developer”) in the first embodiment is described below.
As shown in
The pole N2 is disposed upstream from the development pole S1 in the rotational direction of the development sleeve 34a and functions as both the attraction pole and the pre-development transport pole (hereinafter also “pre-development pole N2”). The pre-development pole N2 generates a second magnetic field to cause the developer supplied from the developer containing part (supply path 37) to be attracted to the circumferential surface of the development sleeve 34a. The pre-development pole N2 also serves as a developer regulation pole that generates a magnetic field in a developer regulation area where the development sleeve 34a faces the developer regulator 35.
The developer is kept on the circumferential surface of the development sleeve 34a (hereinafter simply “surface of the development sleeve 34a”) by the second magnetic field generated by the pre-development pole N2 and the first magnetic field development pole S1 from the attraction portion 47 to the development range A.
The pole N1 is disposed downstream from the development pole S1 in the rotational direction of the development sleeve 34a and functions as both the post-development transport pole and the release pole (hereinafter also “post-development pole N1”) to generate a third magnetic field disposed between the first magnetic field and the second magnetic field, to transport the developer that has passed the development range A to the release portion 46 (release position) where the developer leaves the circumferential surface of the development sleeve 34a. From the development range A to the developer release position 46, the developer is kept on the surface of the development sleeve 34a by the first magnetic field generated by the development pole S1 and the third magnetic field generated by the post-development pole N1 from the development range A to the release portion 46 where the developer is separated from the development sleeve 34a.
By contrast, in the five-pole configuration shown in
In the three-pole configuration, because both the pre-development pole N2 functioning as the attraction pole and the post-development pole N1 functioning as the release pole are adjacent to the development pole S1, a longer interval can be maintained between the pre-development pole (attraction pole) N2 and the post-development pole (release pole) N1 disposed downstream from the pre-development pole N2 in the rotational direction thereof.
Referring to
If the developer 32 does not leave the development sleeve 34a or the developer that has left the development sleeve 34a is again attracted to the development sleeve 34a from the circulation path 38, the developer whose toner concentration is lower is supplied to the development range A, decreasing the image density, which is not desirable. Therefore, the developer should leave the development sleeve 34a around the release portion 46.
Mechanism of release of the developer is as follows: The developer 32 on the development sleeve 34a is transported by the development sleeve 34a due to frictional force generated between the surface of the development sleeve 34a and the developer 32. Because this frictional force is proportional to a vertical drag applied to the developer 32 on the development sleeve 34a, this frictional force increases as the magnetic force in a normal direction acting on the developer 32 is larger in a direction to attract the developer, and accordingly the ability of the development sleeve 34a to transport the developer 32 increases.
Hereinafter, the magnetic force generated by the magnet roller 34b, acting in the normal direction to the surface of the development sleeve 34a and that acting in a direction tangential to the surface of the development sleeve 34a are referred to as the “magnetic force in normal direction” and the “magnetic force in tangent direction”, respectively. Additionally, the magnetic force in normal direction is also referred to as “magnetic attraction in normal direction” when acting in the direction toward the center of rotation 34p of the development sleeve 34a and “magnetic repulsion in normal direction” when acting in the direction away from the center of rotation 34p of the development sleeve 34a.
In other words, when the magnetic attraction in normal direction is larger, the developer 32 can receive a transport force from the development sleeve 34a and be transported as the development sleeve 34a rotates. By contrast, when the magnetic attraction in normal direction is smaller, the frictional force between the development sleeve 34a and the developer 32 is weaker, and the developer 32 is likely to slip on the development sleeve 34a and is less likely to be transported by the development sleeve 34a.
When the magnetic attraction in normal direction is smaller than the weight of the developer 32 itself, or when the magnetic repulsion in normal direction acts on the developer 32, the developer 32 leaves the development sleeve 34a. When the magnetic attraction in normal direction is greater and accordingly the frictional force between the development sleeve 34a and the developer 32 is greater, the developer 32 can be transported at a velocity substantially identical to the rotational velocity of the development sleeve 34a. In other words, inertial force acts on the developer 32 because the developer 32 rotates at a high velocity similarly to the development sleeve 34a.
Therefore, when the magnetic attraction in normal direction is smaller in the release portion 46, the developer 32 can leave the development sleeve 34a due to the inertial force in addition to the weight of the developer 32. In other words, to separate the developer 32 from the development sleeve 34a, the magnetic attraction in normal direction should be smaller and the inertial force or the weight of the developer 32 should be used. Alternatively, the repulsion in normal direction should be generated to separate the developer 32 from the development sleeve 34a magnetically.
In
In
When relative positions of the post-development pole N1 and the pre-development pole N2 are set so that the angle θ3 formed by the post-development center line L3 and the pre-development center line L1 is 180° or greater, the magnetic flux forming the release pole (N1) is more likely to flow to the development pole S1, and thus the magnetic field generated between the release pole (N1) and the attraction pole (N2) can be smaller. Thus, the developer 32 can be separated from the development sleeve 34a reliably.
Therefore, in the present embodiment, because the post-development pole N1 and the pre-development pole N2 can be set so that the angle θ3 formed by the post-development center line L3 and the pre-development center line L1 is 180° or greater, the developer can be separated from the development sleeve 34a reliably even when the diameter of the development sleeve is relatively small.
As in the development device 3 shown in
In particular, by setting the angle θ3, formed by connecting the magnetic flux peak density M3 (shown in
In the first embodiment, by setting the magnetic flux density at the center M1, where the magnetic flux density is maximum in the pre-development pole N2, in normal direction to the surface of the development sleeve 34a to 10 mT or greater, the force to keep the developer on the surface of the development sleeve 34a can be greater than the force of the developer to fall under its own weight. Thus, the developer can be prevented from falling to the circulation path 38.
The magnetic fields and the release of developer when the angle θ3 is 180° are described below with reference to
When the angle θ3 is 180°, as shown in
The magnetic fields and the release of developer in a comparative example 1 in which the angle θ3 is 150° are described below with reference to
In the comparative example 1, as shown in
Next, comparison of the three-pole configuration and the five-pole configuration in the development sleeve 34a whose diameter is smaller is described below.
Typically, when the number of the developer-carrying magnetic pole is not less than five, the magnetic repulsion in normal direction to the surface of the development sleeve can be sufficiently strong to separate the developer from the development sleeve. When the development sleeve has a relatively large diameter, even when multiple magnets forming the magnet roller are provided inside the development sleeve, a certain amount of space can be maintained between the magnets, and thus flexibility in the arrangement of the magnets is increased. By contrast, when the number of the magnets is smaller, and the space between the magnetic fields generated by the respective magnets is excessively large, vectors of the density of the magnetic flux generated between the magnetic poles are more uneven, and thus it is difficult to transport the developer reliably.
In other words, when the number of the magnets is greater, the magnets are arranged at smaller intervals, and accordingly each magnet can be affected by the magnetic force generated by other magnets, failing to generate a necessary distribution of the magnetic flux density. By contrast, when the number of the magnets is smaller, the space between the magnets is excessively large, and it is difficult to transport the developer reliably. Therefore, the number of the magnets should be determined according to the diameter of the development sleeve 34a.
When a development sleeve 34aZ has a diameter within a range from about 6 mm to 12 mm and is relatively small, because the magnets are arranged at smaller intervals, each magnet is more susceptible to the magnetic force lines generated by other magnets. In other words, to attain desired distribution of magnetic flux density, the magnets should be arranged precisely, and it is difficult to attain desired distribution of magnetic flux density in this configuration.
By contrast, as described above, in the three-pole configuration shown in
When the diameter of the development sleeve 34a is smaller, because the interval between the centers (M1 and M2, and M2 and M3), which is the peak of magnetic flux density, of two adjacent magnetic poles is sufficiently small. Therefore, the single pre-development pole N2 can serve as both the attraction pole and the pre-development transport pole. Similarly, the development pole S1 and the post-development pole N1 together perform processes of three magnetic poles, namely, the development pole, the post-development transport pole, and the release pole. Thus, the magnetic fields generated by the magnets S1, N1, and N2 can be sufficiently strong for performing the processes of attracting the developer, transporting the developer, developing the latent image with the developer, and releasing the developer from the development sleeve, and thus these processes can be performed reliably.
Thus, the three-pole development roller 34 shown in
In the present embodiment, because the three magnetic poles have functions of attracting the developer to the development sleeve, development, and releasing the developer from the development sleeve, all of the processes of attraction of the developer to the development sleeve, adjustment of the amount of the developer carried on the development sleeve, development, and release of the developer from the development sleeve can be reliably performed similarly to typical configurations in which the number of magnetic poles is five.
The magnetic force F (N) can be expressed using the formula below.
wherein the B(T) represents the magnetic flux density, μ0 (H/m) represents the magnetic permeability at vacuum, μ represents a relative magnetic permeability of carrier particles, and a represents a particle diameter of carrier particles.
The graph described below illustrates the magnetic force when carrier particles have a diameter of 35 am and a relative magnetic permeability of 8 as an example.
In
Referring to
The magnetic force in normal direction functions as the magnetic attraction when being in the minus direction. In the graph shown in
By contrast, the magnetic force in normal direction functions as the magnetic repulsion when being in the plus direction.
In the development device 3 shown in
In this measurement, the magnetization, particle size, and density of the carrier particle was within a range from 30 emu/g to 120 emu/g, a range from 20 μm to 80 μm, and a range from 3 g/cm3 to 8 g/cm3, respectively.
Typically, in the five-pole development device 3Z2, the developer can be separated from the development sleeve 34aZ by generating the magnetic repulsion in normal direction in the release portion 46Z. However, when the development sleeve 34aZ has reduced diameter within a range from about 6 mm to 12 mm, because each magnet is more susceptible to the magnetic force lines generated by other magnets, it is difficult to generate desired magnetic repulsion in normal direction.
In the three-pole development device 3 shown in
The magnetic force lines from the post-development pole N1 partly flow into the development pole S1, and the rest of the magnetic force lines pass around the release portion 46 and then return to the post-development pole N1. Similarly, the magnetic force lines from the pre-development pole N2 partly flow into the development pole S1, and the rest of the magnetic force lines pass around the release portion 46 and then return to the pre-development pole N2.
The vector of magnetic force around the release portion 46 is determined by the balance between the magnetic force lines flowing from the post-development pole N1 and returning thereto and that flowing from the pre-development pole N2 and returning thereto. When the magnetic flux density in the pre-development pole N2 is reduced, the magnetic force lines flowing from the pre-development pole N2 to the development pole S1 increase relatively, and the magnetic force lines that pass around the release portion 46 are decreased. As a result, the magnetic attraction in normal direction in the release portion 46 can be reduced.
This relation can be expressed as Br1>Br3, wherein the peak of magnetic flux density in normal direction of the development pole S1 is Br1 (hereinafter simply “magnetic flux density peak in S1”), and the peak of magnetic flux density in normal direction of the pre-development pole N2 is referred to Br3 (hereinafter simply “magnetic flux density peak in N2”).
The release portion 46 was set to the angle range from −40° to 0° in the direction indicated by arrow D shown in
The magnetic attraction in normal direction can be reduced when the relation Br1>Br2 is satisfied, wherein Br1 represents the magnetic flux density peak in S1, and Br2 represents the peak of magnetic flux density in normal direction of the post-development pole N1 (hereinafter simply “magnetic flux density peak in N1”).
As described above, the magnetic force lines from the post-development pole N1 partly flow into the development pole S1, and the rest passes around the release portion 46 and return to the post-development pole N1. As shown in
From the descriptions above, it can be known that the magnetic attraction in normal direction in the release portion 46 can be reduced when both Br1>Br2 and Br1>Br3 are satisfied.
Next, the relation between Br2 (magnetic flux density peak in N1) and Br3 (magnetic flux density peak in N2) is described below.
As described above, the post-development pole N1 needs to transport the developer that has been used in development. Additionally, the post-development pole N1 needs to cause the carrier particles that have adhered to the photoconductor 1 in the development range A to be again attracted to the development sleeve 34a. Therefore, Br2 (magnetic flux density peak in N1) should be sufficiently high to transport the developer as well as to attract the carrier particles. Also in the relation between Br2 (magnetic flux density peak in N1) and Br3 (magnetic flux density peak in N2), when either of them is to be increased, the other should be reduced to balance the magnetic force on the development sleeve 34a because the developer is inhibited from leaving the development sleeve 34a if both of them are increased, that is, magnetic force in total increases.
Therefore, in the present embodiment, to secure the above-described functions of the post-development pole N1, Br2, magnetic flux density peak in N1, should be higher than Br3, magnetic flux density peak in N2 (Br2>Br3). That is, the relation Br1>Br2>Br3 is satisfied.
Next, a comparative example in which the number of the developer-carrying magnetic pole is only one (hereinafter “single-pole configuration”) is described below.
In
In the single-pole configuration, when it is assumed that the polarity of the peak position of the magnetic flux density in normal direction is N pole (negative direction in
At this time, the integrated density of magnetic flux in normal direction in the N pole range is identical or similar to the integrated density of magnetic flux in normal direction in the S pole range on the surface of the development sleeve.
A product of a peak value Br of the magnetic flux density and a half band width θh in that magnetic pole can be used as an approximation of the integrated density of magnetic flux in normal direction in the range whose polarity is identical to that of the peak position. Hereinafter, the product of the peak value Br and the half band width θh is referred to as a magnetic flux density product X. The half hand width θh means, in a magnetic field generated by a single magnetic pole, an angle in an angle range including the peak position of the magnetic flux density in normal direction, formed by the center of rotation of the development sleeve and two positions on the circumference of the development sleeve where the magnetic flux density in normal direction is half the peak value Br.
Because the integrated density of magnetic flux in normal direction in the range whose polarity is identical to that of the peak position is identical or similar to that in the range whose polarity is the opposite, the mean value of the magnetic flux density in normal direction in the range whose polarity is the opposite can be identical or similar to a value obtained by dividing the magnetic flux density product X by the center angle (360−dDEG) of the range whose polarity is the opposite.
Additionally, under any of the conditions 1 through 3 shown in table 1, the value of X/(360−dDEG) is similar to ΔZ (60), and accordingly it can be known that the integrated density of magnetic flux in normal direction in the range whose polarity is opposite that of the peak position appropriates to the product of the peak value Br and the half hand width θh.
As shown in table 1, the magnetic pole under condition 1 has a peak value of −23 mT and a half band width of 30.5°. Then, the product X of these values is 640.5, and the mean value of the magnetic flux density in normal direction of the opposite polarity is 2.1 mT. Similarly, under the condition 2, the product X of these values is 1313.5, and the mean value of the magnetic flux density in normal direction of the opposite polarity is 4.1 mT. Thus, the product X and the mean value of the magnetic flux density in normal direction of the opposite polarity under condition 2 are respectively 2.05 times and 1.95 times the values obtained under condition 1. That is, under the conditions 1 and 2 in which the values of dDEG are identical, the mean value of the magnetic flux density in normal direction of the opposite polarity is substantially proportional to the product X. Additionally, under the condition 3 in which the value of dDEG is different, a similar relation can be observed.
Although the description above concerns the single-pole configuration, in multiple magnetic-poles configurations, basically, the above-described theory works by integrating the distributions of magnetic flux density in normal direction. To be more exact, the description in the multiple-poles configuration is not so simple because it is possible that a magnetic circuit may be formed inside the development sleeve and the magnetic field does not leak to the surface. However, when the number of the magnetic poles is relatively small as in the present embodiment, an approximate graph of the distribution of magnetic flux density in normal direction can be drawn by integrating the distribution of magnetic flux density in the single-pole configuration.
That is, on the circumferential surface of the development roller, the integrated density of magnetic flux in normal direction whose polarity is S pole can be substantially identical to the integrated density of magnetic flux in normal direction whose polarity is N pole. Additionally, when the density peak of magnetic flux is relatively large as in the conditions 2 and 3 for
In the present embodiment, because the density peak of magnetic flux in the post-development pole N1 is larger, a magnetic pole S2 whose polarity is opposite the polarity of the post-development pole N1 is formed downstream from the post-development pole N1 in the rotational direction of the development sleeve 34a as shown in
As shown in
In the present embodiment, to inhibit the effect of the magnetic pole S2, it is preferred that the product X of the magnetic flux density peak Br and the half hand width θh in the development pole S1 be greater than the sum of the product (X=Br·θh) in the post-development pole N1 and the product (X=Br·θh) in the pre-development pole N2.
Setting the product X in the development pole S1 is described below. Hereinafter, reference characters Br1 θh1, and X1 represent the magnetic flux density peak in normal direction, the half hand width, and the magnetic flux density product, respectively, in the development pole S1 in the present embodiment.
Similarly, reference characters Br2 θh2, and X2 represent the magnetic flux density peak in normal direction, the half hand width, and the magnetic flux density product, respectively, in the post-development pole N1 whose peak of magnetic flux density is higher than that of the pre-development pole N2 although the polarity of them are identical. Similarly, reference characters Br3 θh3, and X3 represent the magnetic flux density peak in normal direction, the half hand width, and the magnetic flux density product, respectively, in the pre-development pole N2 whose peak of magnetic flux density is lower than that of the pre-development pole N1.
At this time, when the development roller 34 is configured so that the relations Br1>Br2>Br3 and Br1·θh1>Br2·θ2+Br3·θ are satisfied, the value of X1−(X2+X3) determines whether the mean value of magnetic flux density in normal direction in an area ε shown in
The polarity of the magnetic pole in normal direction to the surface of the development roller 34 is reversed to N in a downstream end portion in the area ε shown in
By contrast, if the value of X1−(X2+X3) is positive, the polarity of the area ε shown in
By setting the polarity of the area from the release pole (N1) to the attraction pole (N2) to the polarity identical to that of the release pole (N1), the developer can be better separated from the development sleeve 34a after passing through the development range A.
As described above, although the pole S2 is formed due to a relatively high peak value in the post-development pole N1, the magnetic flux density caused by the pole S2 can be reduced when X1>X2+X3 is satisfied. Even when the pole S2 generates an S magnetic field, because its polarity can be reversed to N immediately downstream from that magnetic field, the effects by the pole S2 can be inhibited. Therefore, fluctuations in the magnetic flux density in normal direction between the post-development pole N1 to the pre-development pole N2 can be reduced, which can facilitate release of the developer form the development sleeve 34a.
Additionally, the position where the polarity of the magnetic field generated by the pole S2 is reversed to N can be adjusted with the half band width of the attraction pole N2.
When images were output in the experiment, the developer was reliably separated from the development sleeve 34a in the case of the magnetic force distribution type A represented by ∘ shown in
As shown in
Although, in both types A and B, the magnetic attraction in normal direction was substantially zero around the release portion 46 that in the present embodiment is within the range from 0° to 50°, the developer was reliably separated from the development sleeve 34a in the type A while the developer release failure occurred in the type B.
Image failure caused by the developer release failure is described below.
Because the circulation path 38 mainly contains the used developer whose toner concentration is lower, image density is decreased when such used developer is again transported by the development sleeve 34a and used in development. By contrast, the toner concentration is higher immediately after fresh toner is supplied to the circulation path 38, and accordingly image density is higher in this case. Although it is difficult to determine whether or not the image failure was caused by developer release failure if the difference is only the image density, in the case of developer release failure, the state of the developer 32 in the circulation path 38 is reflected in resulting images, which is distinctive feature of the developer release failure. For example, when unevenness in the image density of the resulting images corresponds to the pitch of the circulation screw 40, developer release failure can be regarded as the cause.
The magnetic field generated by each magnet of the magnet roller 34b has a specific size and a specific direction, and accordingly the magnetic force generated by the magnetic field has a specific size and a specific direction. As shown in
From the graph, it can be known that, even when the magnetic force in normal direction is extremely small, the amount of carried-over developer significantly increases when the release angle is within the range from about 50° to ° 60 because, if the developer remains on the development sleeve 34a until that portion of the development sleeve 34a reaches the upper portion of the development roller 34, vertical repulsion from the development sleeve 34a increases due to the weight of the developer itself even when the magnetic force is not present at all. Accordingly, the frictional force between the development sleeve 34a and the developer carried thereon increases. As a result, the force of the development sleeve 34a to transport the developer increases, which increases the amount of carried-over developer. From the results shown in
Although, in the unidirectional development device 3 shown
The development device 3Z3 is different from the development device 3 shown in
In the development device 3Z3, similarly to the development device 3 shown in
In non-unidirectional development devices such as the development device 3Z3 shown in
Additionally, as in the comparative example 3 shown in
Therefore, it is necessary to reduce the effects of either of the release portion 46 and the attraction portion 47 given to the other by disposing them away from each other to achieve the functions of both of them.
Next, relative positions of the development sleeve 34a and the circulation screw 40 are described below. In the unidirectional developer device 3 shown in
Relations between the toner concentration and positions in the axial direction in the supply path 37 and the circulation path 38 and on the development sleeve 34a are described below according to
Similarly to the development device 3 according to the first embodiment, the development device according to the comparative example 4 includes a supply path provided with a supply screw and a circulation path provided with a circulation screw to transport the developer in a direction opposite the developer transport direction of the supply screw. However, the comparative example 4 is different from the first embodiment in that the developer that has passed through the development range is collected in the supply path, and only the developer that reaches a downstream end portion in the supply path in the developer transport direction is sent to an upstream end portion of the circulation path.
It is to be noted that the graph of the toner concentration on the developer sleeve shown in
In the first embodiment, as shown in
It is to be noted that, because the capacity of the developer container (e.g., supply path and circulation path) is smaller in a compact development device, the proportion of the toner in the developer decreases more significantly in it even when the identical amount of toner is consumed in the compact development devices and a typical development device. Therefore, in the comparative example in which the used developer is collected in the supply path, when the development device is relatively compact, the toner concentration on the development sleeve decreases more significantly as the position shifts downstream in the developer transport direction of the supply screw, which is not desirable.
By contrast, in the first embodiment in which the used developer is collected in the circulation path 38 separately provided from the supply path 37, even when it is relatively compact and accordingly the capacity of the development container is smaller, a substantially constant toner concentration can be maintained on the development sleeve 34a. Thus, image density can be kept substantially constant even when the development device is relatively compact. By increasing the interval between the pre-development pole (attraction pole) N2 and the post-development pole (release pole) N1, the developer that has passed through the development range can be collected in the circulation path 38 separately provided from the supply path 37.
Additionally, in the configuration in which the rotary shaft of the supply screw 39 is disposed above the center of rotation 34p and the developer is supplied onto the development sleeve 34a from above, the developer that has strode the barrier 43 can fall on the development sleeve 34a due to gravity. Thus, the developer can be reliably supplied to the development sleeve 34a even when the magnetic flux density in the attraction portion 47 is reduced.
This configuration is efficient when the relation Br1>Br2>Br3 is satisfied. That is, when this relation is satisfied in the three-pole magnet roller 34b, the peak Br2 in the post-development pole N1, functioning as the release pole, can be used to catch carrier particles and to facilitate the release of the developer from the development sleeve 34a simultaneously. Although the peak Br3, that is, ability to attract the developer, of the pre-development pole N2 (attraction pole) is reduced accordingly, this ability can be supplemented by supplying the developer to the development sleeve 34a from above.
Additionally, reducing the magnetic flux density in the attraction portion 47, that is, reducing the magnetic flux density peak of the pre-development pole N2, can significantly reduce the stress given to the developer upstream from the developer regulator 35 in the rotation direction of the development sleeve 34a, thus expanding the life of the developer. Reducing the stress to the developer upstream from the developer regulator 35 also can reduce load to the development sleeve 34a, and thus deformation of the development sleeve 34a can be prevented or reduced even when its diameter is smaller and accordingly its strength is reduced. As described above, in the first embodiment, the relative positions of the barrier 43 forming the supply path 37 and the development sleeve 34a are set so that gravity can be used to supply the developer to the development sleeve 34a. By arranging the surface of the development sleeve 34a below the barrier 43 as shown in
It is to be noted that, by using gravity to supply the developer, even in the present embodiment in which an identical magnetic pole serves as both the attraction pole and the developer regulation pole, that is, the number of the magnetic poles is reduced from that in the configuration that includes the attraction pole and the developer regulation pole separately, the developer can be supplied to the development range reliably.
In the first embodiment, among the magnetic poles (S1, N1, and N2) for carrying the developer onto the development sleeve 34a, the magnetic flux density peak of the magnetic field generated by the pre-development pole N2 in normal direction to the surface of the development sleeve 34a is 40 mT or less. Thus, this magnetic flux density peak of the magnetic field generated by the pre-development pole N2 is reduced from a conventional configuration in which the magnetic flux density peak of the magnetic field generated by the attraction pole is about 50 mT to 70 mT.
In particular, the load to the development sleeve 34a as well as the stress to the developer thereon can be reduced by setting the magnetic flux density in normal direction at the center M1 (magnetic flux density peak) of the pre-development pole N2 to a value not greater than 30 mT. The relation between the attraction portion 47 and the size of the magnetic flux density in the pre-development pole N2 should be set in view of the following condition: The barrier 43 to be strode by the developer should be configured so that the developer can be carried on the development sleeve 34a due to the magnetic force in the pre-development pole N2 and the frictional force between the developer and the development sleeve 34a. Additionally, the position where the developer where the developer is caused to fall is the above-described position where the developer can be carried by the development sleeve 34a and the position between the post-development pole N1 and the pre-development pole N.
When gravity is used to supply the developer onto the surface of the development sleeve 34a, the developer can be transported reliably even when the maximum magnetic flux density of the magnetic field generated by the pre-development pole N2 serving as the attraction pole in the normal direction to the development sleeve 34a is reduced to about one fourth of that in typical development devices. In this case, the load to the development sleeve 34a can be reduced to 20 percent to 30 percent of that in typical development devices.
Thus, in the present embodiment, because the load to the development sleeve 34a in the developer regulation portion is reduced, unevenness in the development gap, which can occur when the diameter of the development sleeve 34a is smaller, can be reduced, and thus image development can be performed reliably.
The strength of the development sleeve 34a decreases as the diameter thereof decreases, which is described in further detail below.
It is to be noted that the deformation amount, that is, the amount by which the sleeve is deformed, herein means a maximum deformation amount δmax (e.g., deformation amount of a center portion) when uniformly-distributed load is given to either end of the support beam. The maximum deformation amount δmax can be calculated using formula 1 shown below.
wherein w represents a load per unit length, l represents the length of the development sleeve, and E represents Young's modulus, and I represents second moment of area of the development sleeve.
In formula 1, the Young's moduli of aluminum, ordinary steel, and stainless steel (SUS) are set to 69090 MPa, 205800 MPa, and 199920 MPa, respectively. The second moment of area of the development sleeve I is calculated using formula 2 shown below.
wherein d represents the outer diameter of the development sleeve, and di represents the inner diameter of the development sleeve.
In the case of the aluminum sleeve having a diameter of 10 mm and a thickness of 0.7 mm, the deformation rate is 7 as shown in
It is to be noted that the development sleeve 34a is deformed by the load caused by the developer accumulated upstream from the position facing the developer regulator 35. More specifically, the action of the accumulated developer to expand the space between the development sleeve 34a and the casing 33 as well as the weight of the developer push the development sleeve 34a to the direction opposite the developer regulator 35. When the developer sleeve 34a is deformed by this load, a regulation gap, which is the space between the developer regulator 35 and the surface of the development sleeve 34a, is larger in the center portion in the axial direction than in the end portions. Accordingly, the amount of developer passing through the regulation gap is larger in the center portion in the axial direction than in the end portions, and thus the amount of developer transported to the development range A is not uniform in the axial direction. Also in the development range A, a development gap, which is the gap between the photoconductor 1 and the development sleeve 34a, is expanded by the developer in the center portion, and thus the development gap is uneven in the axial direction, resulting in unevenness in the image density.
As described above with reference to
In
Although the magnet S1 is disposed so that the heights of the development pole S1 and the center of rotation 34p of the development sleeve 34a are substantially similar, a development roller 341 shown in
Except that a separation plate 49 is provided, the development device 3B according to the third embodiment has a similar configuration to that of the development device 3A according to the second embodiment, and thus the descriptions thereof are omitted.
In the development device 3B shown in
It is to be noted that the configuration and position of the separation plate 49 is not limited to those shown in
Except that a supply position adjuster 81 is provided, the development device 3C according to the fourth embodiment has a similar configuration to that of the development device 3A according to the second embodiment, and thus the descriptions thereof are omitted.
It is to be noted the distribution of the magnetic flux density in normal direction in the development device 3C according to the fourth embodiment is similar to that shown in
Generally, the developer inside the development device 3C receives a large pressure upstream from the developer regulation portion and then deteriorates. More specifically, the amount of the developer transported to the development range A through the regulation gap is significantly small compared with the amount of the developer supplied to the development sleeve 34a. Therefore, the developer accumulates upstream from the regulation gap in the rotational direction of the development sleeve 34a and accordingly receives a large pressure.
Additionally, the developer 32 supplied by the supply screw 39 is carried on the surface of the development sleeve 34a due to the magnetic attraction of the pre-development pole N2 generated by the magnet disposed close to the position facing the supply screw 39. At this time, if the supply screw 39 is lower than the development sleeve 34a, the developer 32 in the supply path 37 should be carried upward to the developer sleeve 34a against the weight of the developer itself. Therefore, the pre-development pole N2 serving as the attraction pole needs a relatively high magnetic flux density to supply the developer to the development sleeve 34a reliably.
The longer the distance between the development sleeve 34a and the supply screw 39 is, or the lower the height of the supply screw 39 relative to the development sleeve 34a is, the higher the magnetic flux density in the pre-development pole (attraction pole) N2 should be to supply the developer to the development sleeve 34a reliably. However, although the developer can be reliably supplied to the development sleeve 34a by increasing the magnetic flux density in the attraction pole N2, the developer is more likely to deteriorate because the frictional force between the development sleeve 34a and the developer carried thereon increases, which is not desirable.
Therefore, if the developer can be reliably supplied to the development sleeve 34a even when the magnetic force of the attraction pole N2 is weaker, deterioration of the developer can be reduced while reliably supplying the developer to the development sleeve 34a.
As in the first, second, and third embodiments, when the supply screw 39 is disposed above the development sleeve 34a, even when the magnetic force of the attraction pole N2 is weaker, the developer overflowing from the supply path 37 by rotation of the supply screw 39 can fall onto the development sleeve 34a due to gravity. Thus, a constant amount of developer can be reliably supplied to the development sleeve 34a.
Additionally, in the fourth embodiment, the supply position adjuster 81 is disposed so that the attraction portion 47 is adjusted to a position downstream from the highest position 34t on the surface of the development sleeve 34a. When the magnetic flux density around the attraction portion 47 is smaller, although the developer can be supplied to the development sleeve 34a due to gravity, the force to keep the developer on the surface of the development sleeve 34a against gravity is weaker, and it is possible that a certain amount of the developer might pass between the development sleeve 34a and the partition 36 forming the bottom surface of the supply path 37, falling into the circulation path 38. However, the supply position adjuster 81 disposed as described above can prevent or reduce such inconvenience.
In the fourth embodiment, the supply position adjuster 81 guides the developer that has strode the barrier 43A to the position downstream from the highest point 34t on the surface of the development sleeve 34a in the rotational direction thereof. In other words, as shown in
Thus, when the casing 33 serving as the developer containing part and the development sleeve 34a are disposed so that gravity can be used to supply the developer from the supply path 37 onto the development sleeve 34a and the attraction portion 47 where the developer supplied from the supply path 37 contacts the surface of the development sleeve 34a is positioned downstream from the highest position 34t on the surface of the development sleeve 34a, the developer supplied from the supply path 37 does not fall into the circulation path 38 but can be sent to the developer regulation portion.
It is to be noted that it is not preferable that a relatively large gap is present between the developer regulator 35 and the attraction portion 47, which herein means the position where a downstream edge portion of the supply position adjuster 81 faces the development sleeve 34a, because a larger amount of developer is present in a space between the developer regulator 35 and the barrier 43A (hereinafter “buffer area”). In other words, if the amount of developer present in the buffer area is excessive, the amount of developer accumulating upstream from the regulation gap in the rotational direction of the development sleeve 34a increases, which can accelerate deterioration of the developer.
Additionally, because the developer accumulated in the buffer area presses the development sleeve 34a with its own weight, the development sleeve 34a is deformed particularly in the center portion in the axial direction.
From an experiment in which the position of the attraction portion 47 was varied by changing the shape of the supply position adjuster 81, it is known that a center angle formed by the attraction portion 47 and position on the surface of the development sleeve 34a facing the developer regulator 35 is preferably not greater than 30°.
In this embodiment, gravity is used to supply the developer from the supply path 37 onto the development sleeve 34a, and the attraction portion 47 is positioned upstream from the highest point 34t on the development sleeve 34a in the rotational direction of the development sleeve 34a, by disposing the magnet forming the pre-development pole N2 so that the peak of the magnetic flux density in normal direction of the pre-development pole N2 is close to the attraction portion 47. In this configuration, also the developer can be reliably supplied to the development sleeve 34a. In an experiment, the peak of the magnetic flux density in normal direction of the pre-development pole N2 was varied and the amount of developer fallen into the circulation path 38 was measured. In the experiment, in an angle range on the development sleeve 34a not greater than 80° to the horizontal axis 34h, when the peak of the magnetic flux density in normal direction is not greater than 10 mT, the force of the developer to fall under gravity is greater than the force generated by the attraction pole to keep the developer in the development sleeve 34a. As a result, the amount of the developer falling into the circulation path 38 increased. Therefore, it is preferred that the magnetic flux density in normal direction in the attraction portion 47 be greater than 10 mT.
It is to be noted that, the position of the peak of the magnetic flux density of the pre-development pole N2 is not necessarily identical to that of the attraction portion 47.
The development device 3E according to the sixth embodiment is different from the development device 3D shown in
As shown in
It is to be noted that, regarding shortage of the developer, the development devices 3 through 3D according to the first through fifth embodiments are more advantageous than the development device 3E according to the sixth embodiment because the developer cannot overstride the barrier 43 and cannot be supplied to the development sleeve 34a unless a certain amount of developer is accumulated in the supply path 37 in the development device 3E shown in
Even when the attraction portion 47 is disposed upstream from the highest point 34t on the development sleeve 34a in the rotational direction of the development sleeve 34a, as shown in
When the attraction portion 47 is disposed within an angle range from 70° to 80° on the surface of the development sleeve 34a, by disposing the buried member 82 across a gap of about 0.5 mm to 1 mm from the surface of the development sleeve 34a, the developer can be prevented from falling into the circulation path 38. The buried member 82 is preferably formed of a soft material such as urethane because the development sleeve 34a might wear from the contact with the buried member 82.
Additionally, when the attraction portion 47 is disposed within an angle range from 80° to 90° on the surface of the development sleeve 34a, the developer can be prevented from falling into the circulation path 38 by setting the size of the gap between the buried member 82 and the development sleeve 34a to about 1 mm to 3 mm. This configuration is preferable because reliable developer supply can be achieved while preventing the wear of the development sleeve 34a.
It is to be noted that, although the buried member 82 is provided on the partition 36 to prevent the developer from falling into the circulation path 38 in the seventh embodiment, alternatively, this objective can be achieved by reducing the size of the gap between the partition 36 and the surface of the development sleeve 34a when it can be set precisely.
When the attraction portion 47 is disposed within an angle range from 70° to 80° on the surface of the development sleeve 34a, the developer can be prevented from falling into the circulation path 38 by setting the size of the gap between the partition 36 and the development sleeve 34a to about 0.5 mm to 1 mm. Additionally, when the attraction portion 47 is disposed within the angle range from 80° to 90° on the surface of the development sleeve 34a, by setting the size of the gap between the partition 36 and the development sleeve 34a to about 1 mm to 3 mm, the developer can be prevented from falling into the circulation path 38 while preventing the wear of the development sleeve 34a.
Generally, image failure in which leading edges of images are absent tends to occur in the reverse development type due to the following reason.
Herein, a development nip and the development range A respectively mean an area where the developer on the development sleeve 34a contacts the photoconductor 1 and a portion within the development nip where development is performed due to the magnetic field. While the photoconductor 1 and the development sleeve 34a rotate in the opposite directions, the toner adhering to the photoconductor 1 in the development range A exits the development nip. The carrier particles in the developer carried on the development sleeve 34a form a magnetic brush, and, upstream from the development range A in the rotational direction of the development sleeve 34a, toner particles adhering to an edge portion of the magnetic brush move toward the development sleeve 34a due to the electrical field applied to a non-image area. Because a positive electrical field (hereinafter “counter charge”) remains on the edge portion of the magnetic brush, the toner adhering to the photoconductor 1 can be electrically removed therefrom by the counter charge, and thus leading edges of resultant images tends to be absent. Additionally, the development sleeve 34a rotating in the direction opposite the rotational direction of the photoconductor 1 can remove the toner adhering to the photoconductor 1 mechanically.
Even in the reverse development type development device 3C1, similarly to the above-described various embodiments, the image failure in which leading edges of images are absent can be inhibited by reducing the diameter of the development sleeve 34a because, when the diameter is smaller, curvature of the development sleeve 34a increases, attaining the following advantage.
In the development sleeve 34a whose diameter is smaller, the width of the development nip is significantly small. For example, the width of the development nip may be within a range from about 1.5 mm to 2.5 mm when the diameters of the development sleeve 34a and the photoconductor 1 are 10 mm and 30 mm, respectively, a smallest gap between the development sleeve 34a and the photoconductor 1 is 0.35 mm, and the amount of developer carried on the development sleeve 34a that has passed through the regulation gap is 50 mg/cm2. When the diameter of the development sleeve 34a is 18 mm and other conditions are similar, the width of the development nip may be within a range from about 4 mm to 5 mm. Thus, when the diameter of the development sleeve 34a is smaller, the width of the development nip is significantly small. Accordingly, the magnetic brush can be separated from the photoconductor 1 immediately after development, which can reduce the amount of developer mechanically removed from the photoconductor 1. Additionally, the size of the electrical field outside the development range A can be smaller when the curvature of the development sleeve 34a is larger, which can reduce the amount of toner electrically removed from the photoconductor 1.
Additionally, in the reverse development type, because the sliding between the photoconductor 1 and the development sleeve 34a can be enhanced, the photoconductor receives less effected by after images, which can obviate the need of a cleaning unit to clean the surface of the photoconductor 1.
Thus, by using the development sleeve 34a whose diameter is smaller in the reverse development type development device 3C1, the above-described image failure can be inhibited while the cleaning unit for the photoconductor 1 is omitted, which can reduce the size and the cost of the apparatus.
Herein, when the developer is supplied to the development sleeve 34a from above as in the first through seventh embodiments and the first variation, the amount of developer that passes through the regulation gap can be substantially constant regardless of whether the developer regulator 35 is formed of a magnetic material or non-magnetic material.
As shown in
Next, transportation of the developer in the development devices 3 through 3F (hereinafter correctively “development device 3”) in the first through seventh embodiments is described in further detail below.
In the state shown in
Additionally, as shown in
It is to be noted that both leakage of toner and carrying over of developer tend to occur when the amount of developer is relatively large around the downstream end in the circulation path 38 in the developer transport direction. That is, leakage of toner and carrying over of developer do not occur when the amount of developer is relatively small and the height thereof is lower around the downstream end in the circulation path 38 in the developer transport direction.
Next, prevention of the leakage of toner and the carrying over of developer in the development device 3 is described below. The amount of developer can be kept relatively small around the downstream end in the circulation path 38 in the developer transport direction with the following features: (a) increasing the force to transport the developer around the downstream end in the circulation path 38 in the developer transport direction or (b) setting the area and the position of the bring-up port 41 properly.
An eighth embodiment including the feature (a) is described below. The feature (a) can be added to the development device 3 according to any one of the above-described first through seventh embodiments.
To achieve the feature (a), a lead angle of the circulation screw 40 transporting the developer in the circulation path 38 should be set properly.
A lead angle β of a screw 80 usable as the supply screw 39 and the circulation screw 40 is described below with reference to
wherein A represents the diameter of the screw 80, and B represents the screw pitch thereof.
As shown in
Additionally, it is preferred that the circulation screw 40 should have such a configuration to apply an upward force to the developer at the position where the bring-up port 41 is disposed in the circulation path 38. More specifically, it is preferred that the lead angle of a portion of the circulation screw 40 corresponding to the bring-up port 41 in the circulation path 38 be close to an angle of 60°, for example, within a range from 45° to 70°, which is described in further detail below with reference to
In
As shown in
Therefore, the circulation screw 40 needs different functions in the bring-up portion 41a and the upstream portion 41b.
The portion of the circulation screw 40 corresponding to the upstream portion 41b needs to transport the developer in a horizontal direction efficiently, and thus the lead angle of that portion is set to an angle around 45°
By contrast, because the portion of the circulation screw 40 corresponding to the bring-up portion 41a needs to apply upward force to the developer, it is preferable that an inclined paddle is provided in that portion. Alternatively, the lead angle of that portion is set to an angle greater than 45°.
The bladed screw spiral 80b of the screw 80 applies a vertical repulsion indicated by arrow f shown in
That is, the vertical repulsion f is determined by the lead angle β (shown in
Therefore, upward force applied to the developer can be increased by increasing the lead angle of the circulation screw 40 in the portion corresponding to the bring-up portion 41a. However, when the lead angle is excessively large, the component f1 in the direction perpendicular to the axial direction is dominant in the vertical repulsion f, which is not desirable because the amount of developer entering the bring-up portion 41a decreases in this state. If the circulation screw 40 does not have a force to transport the developer in the axial direction at all in the bring-up portion 41a, the developer accumulates around a boundary between the bring-up portion 41a and the upstream portion 41b even if the circulation screw 40 tries to transport the developer in the axial direction in the upstream portion 41b. As a result, the amount of developer entering the bring-up portion 41a decreases, which reduces the efficiency in transporting the developer upward in the bring-up portion 41a.
In the example shown in
From the graph shown in
In the eighth embodiment, the lead angle of the circulation screw 40 is set to about 45° in the portion around the downstream end in the circulation path 38, which means, for example, one third of the circulation path 38 divided in the developer transport direction, disposed on the downstream side in the developer transport direction, and set to an angle greater than 45° in the portion upstream from the portion around the downstream end in the circulation path 38. Additionally, the lead angle of the circulation screw 40 is set to an angle about 60° in the portion corresponding to the bring-up portion 41a inside the portion around the downstream end in the circulation path 38.
With this configuration, because the force to transport the developer can be increased around the downstream end in the circulation path 38 in the developer transport direction, and simultaneously the developer can be transported efficiently from the circulation path 38 through the bring-up portion 41a to the supply path 37, the amount of developer accumulating in the portion around the downstream end in the circulation path 38 can be reduced, preventing or inhibiting the leakage of the developer and the carrying over of the developer.
A development device 3G according to a ninth embodiment including the feature (b) is described below.
The feature (b) can be added to the development device 3 according to any one of the above-described first through eighth embodiments.
Important factors regarding the feature (b) are the shape of the bring-up port 41 and the position thereof relative to the development sleeve 34a on a virtual plane perpendicular to the axial direction of the development sleeve 34a in the bring-up port 41.
In the development device 3G shown in
Additionally, in the development device 3G, the circulation screw 40 rotates counterclockwise (in a direction indicated by arrow J) in
In the development device 3G and 3Z7 respectively shown in
By contrast, in the ninth embodiment, because the bring-up port 41 is disposed away from the development sleeve 34a, the developer can be brought up from the circulation path 38 to the supply path 37 even when the amount of the developer is smaller than that in the comparative example 7. Accordingly, the amount of developer present in the upstream portion 41b upstream from the bring-up portion 41a can be smaller, thus inhibiting the carrying over and leakage of developer. Therefore, it is preferred that the bring-up port 41 is disposed away from the development sleeve 34a on the vertical plane perpendicular to the axial direction of the development sleeve 34a.
Next, the shape of the bring-up port is described below with reference to
In
The shape of the bring-up port 41 is not limited to the shape shown in
Additionally, it is preferred that the area of the bring-up port 41 be larger than that of the cross section of the circulation screw 40, which is described later with reference to
Next, dispersion of fresh toner supplied to the development device 3 is described below.
To compensate for the amount of consumed toner, 0.05 g of toner is supplied to the development device 3 in each supply operation. For example, when 0.3 g of toner is to be supplied, the supply operation is repeated six times intermittently. The toner supplied in each supply operation (0.05 g) should be dispersed in the developer in the longitudinal direction (axial direction) of the development sleeve 34a while transported.
Dispersion of supplied toner while the circulation screw 40 transports the developer is to be described later.
Dispersing the supplied toner in the bring-up portion 41a is described below.
To disperse the supplied toner in the longitudinal direction, the path through which the supplied toner is transported in the bring-up portion 41a may be divided. For example, as shown in
It is to be noted that, when the bring-up port 41 is divided, the opening area of the second port 412 positioned upstream from the first port 411 is preferably smaller than that of the first port 411 as shown in
It is to be noted that the dispersibility of the supplied toner can be enhanced also when the bring-up port 41 has such a shape that its width in the direction perpendicular to the axial direction of the development sleeve 34a is reduced toward upstream in the developer transport direction as in
In formula 4, C represents the toner concentration, and the left part represents changes in the toner concentration per unit time. In the right part, a first term is a transport term concerned with movement of the developer in the axial direction and a second term is a dispersion term concerned with dispersion of toner in the developer. When the dispersion coefficient D in the above-described formula 4 is larger, dispersion of toner in the developer is enhanced, that is, the toner can be better mixed with the existing developer, in the longitudinal direction.
The toner concentration is measured immediately after fresh toner is supplied and after the developer is brought up from the circulation path 38 to the supply path 37, and the coefficients D and u in formula 4 are calculated based on the distance by which the developer is transported (hereinafter “transport distance”) and the time during which the developer is transported (hereinafter transport time).
Thus, dispersibility of the supplied toner is better when the bring-up port 41 has such a shape as shown in
A tenth embodiment regarding transportation of the developer is described below. The feature of the tenth embodiment is applicable to the development device 3 according to any one of the above-described first through ninth embodiments.
The flow of the developer in the development device 3 is described below.
As shown in
In the given area Z shown in
In the development device 3, when the amount of the developer present in the area Z (hereinafter “circulation path cell”) is in equilibrium, the relation among the three flows of the developer can be expressed by the following formula A1.
Mk=Mu+Ms (A1)
In other words, the amount of developer entering the circulation path cell Z equals to that of developer going out the circulation path cell Z.
Additionally, the amount of developer in the flow Mu is determined by multiplying a cross-section area Su of the developer in an upstream end portion in the circulation path cell Z in the developer transport direction with a transport velocity Vu in the upstream end portion in the circulation path cell Z, which can be expressed by formula A2 shown below.
Mu=Su×Vu (A2)
Similarly, the amount of developer in the flow Mk is determined by multiplying a cross-section area Sk of the developer in a downstream end portion in the circulation path cell Z in the developer transport direction with a transport velocity Vk in the downstream end portion in the circulation path cell Z, which can be expressed by formula A3 shown below.
Mk=Sk×Vk (A3)
When the values of the transport velocities Vu and Vk are identical, the cross-section area Sk of the developer in the downstream end portion is larger than the cross-section area Su of the developer in the upstream end portion by an area corresponding to the amount of developer falling from the development sleeve 34a. When the relation Vk=Vu=V is established, formula A4 shown below can be obtained.
Sk×V=Su×V+Ms (A4)
The above-described formula A4 can be converted into formula A5 shown below.
Sk=Su+Ms/V (A5)
That is, the cross-section area Sk of the developer in the downstream end portion is larger than the cross-section area Su of the developer in the upstream end portion by an area corresponding “Ms/V”.
Based on the above-described theory, the surface 32f of the developer is oblique in the development device 3 in the longitudinal direction.
Formula A6 shown below can be obtained from the formulas A1 through A3.
Sk×Vk=Su×Vu+Ms (A6)
It is to be noted that the cross-section area Sk of the developer in the downstream end portion can be identical to the cross-section area Su of the developer in the upstream end portion (Sk=Su=S), that is, the height of the developer is not oblique but is constant, by configuring the development device 3 so that formula A7 shown below is established.
Vk=Vu+Ms/S (A7)
The formula A7 means that the transport velocity Vk in the downstream end portion is increased from the transport velocity Vu in the upstream end portion by a value corresponding to “Ms/S”. In other words, the surface 32f of the developer in the circulation path 38 can be uniform by increasing the transport velocity toward downstream in the developer transport direction in the circulation path 38.
Although the description above concerns the transport velocity of the developer in the circulation path 38, the transport velocity in the supply path is determined based on the similar theory.
Next, shortage of the developer, which can occur around the downstream end portion 37b in the supply path 37 in the developer transport direction, are described below.
When the developer is transported at a similar velocity across the entire supply path 37, the amount of the developer decreases toward downstream in the supply path 37 as shown in
Conditions to prevent the shortage of the developer are described below with reference to
As the condition to prevent the shortage of the developer around the downstream end portion 37b, at least the relation expressed by formula A8 shown below should be established between the amount (Mku) of developer transported from the circulation path 38 to the supply path 37 per unit time and the amount (Mzs) of developer falling from the development sleeve 34a to the circulation path 3 per unit time shown in
Mku>Mzs (A8)
That is, when the transportation of the developer in the development device 3 is in equilibrium, the amount (Mku) of developer transported from the circulation path 38 to the supply path 37 per unit time should be greater than the amount (Mzs) of developer falling from the development sleeve 34a to the circulation path 3 per unit time. If the relation expressed by the formula A8 is not established, the developer runs short how fast the transport velocity of the developer in the supply path 37 except the upstream end portion 37a.
To prevent the shortage of developer, the amount of developer transported from the circulation path 38 through the bring-up port 41 to the supply path 37 per unit time should be greater than the amount of developer passing through the development range A per unit time, carried on the development sleeve 34a.
The relation between the lead angle β of the screw and the transport force of the screw is described above with reference to
From the graph shown in
Regarding the above-described feature (b) to keep the amount of developer relatively small around the downstream end in the circulation path 38, it is preferred that the bring-up port 41 is disposed away from the development sleeve 34a on the vertical plane perpendicular to the axial direction of the development sleeve 34a as described above with reference to
In addition, it is preferred that the distance indicated by arrow W in
As described above with reference to
Therefore, to bring up the developer through the bring-up port 41, a certain amount of developer should be accumulated in the bring-up portion 41a in the circulation path 38. Because accumulating the developer around the bring-up portion 41a can cause carrying over and leakage of developer, such inconveniences can be inhibited when the distance W (shown in
However, the bring-up port 41 is preferably disposed close to the development sleeve 34a in the axial direction to keep the development device 3 relatively compact. Therefore, keeping the development device 3 relatively compact while inhibiting carrying over and leakage of developer cannot be attained by only setting the distance W between the bring-up port 41 and the development sleeve 34a properly.
To achieve both of these objectives, the opening area of the bring-up port 41 should be larger than the cross section of the circulation screw 40 because the amount of developer transported by the screw is determined by multiplying the cross section in which the developer is movable with the transport velocity as expressed by the above-described formulas A2 and A3. When the opening area of the bring-up port 41 is smaller than the cross section of the circulation screw 40, the developer moving through the bring-up port 41 needs to move at a velocity higher than the velocity at which the developer moves in an area where the circulation screw 40 gives a transport force to the developer. When the velocity of the developer moving through the bring-up port 41 is higher, a greater pressure is applied around the developer, and this pressure is transmitted to the bring-up portion 41a in the circulation path 38. As a result, the developer is likely to accumulate also around downstream end portion 38b (shown in
In other words, when the bring-up port 41 serving as a first port has an opening area sufficiently large so that the developer packed while the circulation screw 40 makes one rotation can pass the bring-up port 41, clogging of the bring-up port 41 can be prevented, and stress to the developer can be reduced.
In
As shown in
Dispersion of toner around the upstream end portion 38a in the circulation path 38 is described below.
The amount of developer contained in the casing 33 is smaller in the present embodiment than in typical development devices because the development device 3 according to the present embodiment is relatively compact. An enhanced ability to disperse toner is required when the amount of developer is thus smaller.
Table 3 shows specifications of development devices A and B whose capacity of containing developer in the development containing part is different. The development devices A and B consume an identical amount of toner when the number of output sheets per unit time is identical.
It is to be noted that in the table 3, the toner concentration is the amount of toner divided by the amount of developer, and the toner consumptions is the amount of toner consumed when A4-size solid images are recorded on sheets.
Referring to the table 3, the total amounts of developer contained in the development containing parts of the development devices A and B are 90 g and 270 g, respectively. Although the development devices A and B consume an identical amount of toner to form an identical image when the number of output sheets per unit time is identical, the ratio of toner consumption to the total amount of toner in the development containing part is different between the development devices A and B. For example, to form A4 full-size solid images, the ratio of toner consumption to the total amount of toner in the development containing part is 6% in the development device A and 2% in the development device B.
After images are output, the identical amount of toner to the toner consumption should be supplied to the developer containing part for subsequent image formation. Therefore, the amounts of toner supplied to the development devices A and B are respectively equivalent to 6% and 2% of the total amount of toner in the development containing part. Because the ratio of the amount of supplied toner to the total amount of toner is greater in the development device A than in the development device B, the development device A should have a higher ability to disperse the supplied toner in the developer.
Increasing the ability to disperse supplied toner in developer in the relatively compact development devise 3 is described below.
In the present embodiment, the toner supply position T is disposed in the upstream end portion 38a in the circulation path 38 as shown in
To enhance the ability to disperse the supplied toner into the developer, the following processes (c), (d), and (e) should be performed.
(c) Dispersing the supplied toner in the longitudinal direction of the development sleeve 34a.
(d) Merging the dispersed toner into the developer.
(e) Bring the toner into contact with carrier particles to charge the toner electrically.
The process (c) should be performed around the upstream end portion 38a shown in
To perform the process (c) while the circulation screw 40 transports the developer, the toner should overstride the bladed screw spiral 40b as indicated by arrows G in
Not only the supplied toner, but also a certain amount of developer is delayed, dropping astern the pitch of the screw spiral 40b. Consequently, the transport velocity of the developer is slowed around the upstream end portion 38a in the circulation path 38.
A circulation screw 40-1 shown in
It is to be noted that, when the paddles 401 extending in the direction of the screw shaft 40a are provided between the pitches of the screw spiral 40b as shown in
Alternatively, to enhance the dispersibility of the supplied toner, a screw, such as the screw 80 shown in
As described above with reference to
Therefore, in the present embodiment, the lead angle of the circulation screw 40 is set to an angle about 65° in the portion corresponding to the upstream end portion 38a, decreases toward downstream in the developer transport direction, and is set to an angle of about 45° in the vicinity of the downstream end in the circulation path 38 in the developer transport direction described in the eighth embodiment.
It is to be noted that, alternatively, to enhance the dispersibility of the supplied toner, a circulation screw 40-2 shown in
It is to be noted that, when the cutout 40d is formed in a portion of the screw spiral 40b downstream from the upstream end portion 38a of the circulation path 38 in the developer transport direction in addition to the upstream end portion 38a, the area of the cutout 40d in the upstream end portion 38a may be larger than that in the portion downstream from the upstream end portion 38a because the decrease in the developer transport ability as well as the increase in the dispersibility are more significant as the size of the paddle increases. Alternatively, the cutout 40d may be formed only in a portion of the screw spiral 40b in the upstream end portion 38a in the transport direction of the circulation screw 40.
Thus, the development device 3 according to the present embodiment should have such a configuration that the transport velocity can be slowed around the upstream end portion 38a while the supplied toner can be dispersed in the longitudinal direction.
All three types of the circulation screws used to obtain the graph shown in
As described above, in the present embodiment, because the fresh toner is supplied to the upstream end portion 38a in the circulation path 38 in the developer transport direction as shown in
Next, above-described (d), merging the dispersed toner into the developer, is described below.
As indicated by arrow Q shown in
The above-described process (e), bring the toner into contact with carrier particles, can be performed in the bring-up portion 41a. With the configuration described regarding the processes (c) and (d), the toner supplied to the casing 33 is dispersed in the developer contained in the circulation path 38. In the bring-up portion 41a, the pressure of the developer is increased to bring the developer upward, and this increased pressure of developer can increase the number of contact between the toner and carrier particles. Therefore, in the configuration of the development device 3 according to the present embodiment, the supplied toner can be dispersed in the developer sufficiently even when the development device 3 is relatively contact, which means that the capacity of the casing 33 to contain the developer is smaller.
Next, increasing the amount of developer on the upstream side in the circulation path 38 as well as on the downstream side in the supply path 37 is described below.
When the amount of developer moving in and the amount of developer moving out of a given area in the developer transport path per unit time are set, the amount of developer present in that area can be increased, that is, the surface of the developer layer in that area can be raised, by slowing the transport velocity of the developer in that area.
Therefore, the amount of developer on the upstream side in the circulation path 38 as well as that on the downstream side in the supply path 37 can be increased by slowing the transport velocity of the developer in those areas. Following effects (f) and (g) are available by increasing the amount of developer on the upstream side in the circulation path 38 as well as that on the downstream side in the supply path 37. Thus, by slowing the transport velocity of the developer in the circulation path 38 toward upstream in the circulation path 38 in the developer transport direction, and similarly, by increasing the transport velocity of the developer in the supply path 37 toward upstream in the supply path 37 in the developer transport direction, the surface of the developer can be uniform in the circulation path 38 and supply path 37, respectively.
(f) Expanding the life of the developer in the development device.
(g) Reducing fluctuations in the toner concentration in the developer in the development device caused by consumption and supply of toner.
Regarding the above-described effect (f), the life of the developer can be expanded by reducing the stress given to the developer around the developer regulator 35 even when the development device 3 is relatively compact as described in the first embodiment. Further, since the life of the developer is proportional to the amount of the developer in the development device 3, increasing the developer capacity of the casing 33 (e.g., developer containing part) can expand the life of the developer accordingly.
In
The graph shown in
It is to be noted that, because the developer is transported in the opposite directions in the supply path 37 and the circulation path 38, the right side in the graph of
More specifically, the lead angle of the circulation screw 40 is set to an angle of about 45° in the portion corresponding to the downstream end portion 38b, gradually increases toward upstream in the developer transport direction, and is set to an angle about 65° in the portion corresponding to the upstream end portion 38a. Similarly, the lead angle of the circulation screw 39 is set to an angle of about 45° in the portion corresponding to the upstream end portion 37a, gradually increases toward downstream in the developer transport direction, and is set to an angle about 65° in the portion corresponding to the downstream end portion 37b.
When the graphs shown in
By changing the configuration of the development device 3 from that described with reference to
It is to be noted that the configuration of the developer transport paths in the development device 3 according to the eight through tenth embodiments is suitable for relatively compact development devices using a three-pole magnet roller and a development sleeve having a relatively small diameter as in the first through seventh embodiments. However, the configuration of the developer transport paths according to the eight through tenth embodiments is also applicable to development devices in which the number of magnetic poles each generating a magnetic field sufficient to carry the developer on the development sleeve is more than four as in the comparative example 2 shown in
It is to be noted that, in the above-described various embodiments, it is preferable that the amount of developer is set so that, when the circulation screw 40 is stopped, the surface 32f (shown in
Next, a feature of agitating the developer upstream from the developer regulator 35 in the rotation direction of the development sleeve 34a, which is applicable to the development device 3 according to the first through tenth embodiments, is described below as an eleventh embodiment.
As shown in
The development device 3H has a similar configuration to that of the first through eleventh embodiments except that a paddle 51 shown in
Also in the present embodiment, the developer is poured from the supply path 37 down to the surface of development sleeve 34a under gravity as indicated by arrow I shown in
The developer supplied from the supply path 37 by the supply screw 39 to the buffer area 50 may be wavy due to the pitch of the supply screw 39, making the amount of the supplied developer uneven. If the magnetic force of the developer regulation pole is as strong as that in typical development devices, a certain degree of pressure is applied to the developer in the buffer area, and the pressure equalizes the amount of the supplied developer.
Additionally, the developer may include loosely coagulated toner particles and/or carrier particles. If such coagulations clog the regulation gap, image failure in which toner is partly absent creating while lines or the like occur. If the pressure given to the developer in the buffer area is relatively strong, the pressure can dissolve such loose coagulations, thus preventing clogging of the regulation gap.
However, in the present embodiment, because the magnetic force of the magnetic field affecting the developer in the buffer area 50 is weaker, the pressure applied to the developer in the buffer area 50 is weaker, and accordingly the agitation effect of the magnetic force is lower. Therefore, if the amount of developer supplied by the supply screw 39 is wavy due to the pitch of the supply screw 39, the magnetic force is insufficient to eliminate unevenness in the amount of developer carried on the development sleeve 34a, resulting in unevenness in image density.
Further, if a certain amount of toner particles and/or carrier particles coagulates in the developer, such coagulation might clog the regulation gap, producing substandard images including white lines.
To prevent this inconvenience, the development device 3H according to the present embodiment includes the paddle 51 serving as an agitation member as shown in
Referring to
It is to be noted that the shape of the paddle 51 is not limited to that shown in
It is to be noted that the material of the roller 52b is not limited to a specific material. For example, a metal roller or a sponge roller may be used as the roller 52b.
Similarly, by rotating or swinging the wire member 53 around a rotation shaft 53a, the developer in the buffer area 50 can be agitated. Additionally, even when the developer includes coagulations, the wire member 53 can dissolve such coagulations.
Thus, in the eleventh embodiment and variations thereof, even when the supply screw 39 supplies the developer unevenly (including the case in which in developer supply is uneven in the longitudinal direction), the above-described agitation member can equalize the developer and loose coagulations of the developer in the buffer area 50. Therefore, the developer can be uniform upstream from the regulation gap, and a constant amount of developer can be supplied onto the development sleeve 34a. Therefore, unevenness in image density and image failure can be prevented or reduced.
It is to be noted that, although the developer regulator 35 is disposed above the development sleeve 34a in the above-described various embodiments, the developer regulator 35 can be disposed beneath the development sleeve 34a when the agitation member is provided as in the eleventh embodiment.
A twelfth embodiment regarding a configuration of the development sleeve is described below. The feature of the twelfth embodiment is applicable to the development device 3 according to any one of the above-described first through eleventh embodiments.
If developer is brought up onto the development sleeve from beneath, the surface of the development sleeve should be rough to a such a degree that the developer can be kept thereon also mechanically. In such cases, surface treatment such as blast finishing of the development sleeve is necessary.
By contrast, the configuration in which the developer flows down onto the development sleeve 34a, as indicated by arrow I shown in
Therefore, the development sleeve 34a of the present embodiment has a surface roughness Rz within a range from 1 μm to 8 μm, for example, because this range of surface roughness is sufficient for carrying the developer on the surface of the development sleeve 34a. The surface roughness Rz within a range from 1 μm to 8 μm can be attained by standard turning and may be attained by processing, such as aluminum extrusion, that does not include removal processing. The surface of the development sleeve 34a of the present embodiment may be attained through standard cutting without removal processing. It is to be noted that removal processing herein means processing to produce concavities on the surface, and the development sleeve 34a in the present embodiment does not require such surface processing. Standard cutting herein means cutting processing that is performed to make the diameter of the sleeve to a predetermined diameter when blast processing is not performed.
Therefore, manufacture of the development sleeve 34a can be simpler and easier, and accordingly the cost is lower.
In particular, when the diameter of the development sleeve is smaller (e.g., 10 mm) and the surface of the development sleeve should be treated to be able to bring up the developer from beneath, the cost of surface treatment is higher. By contrast, in the present embodiment, although the development sleeve 34a has a relatively small diameter, the surface of the development sleeve can be relatively smooth because the development sleeve does not require the force to bring up the developer. Thus, the processing cost of the development sleeve 34a can be reduced.
It is to be noted that, typical turning can attain a surface roughness of about 0.8 μm, and aluminum extrusion can attain a surface roughness of about 3.2 μm.
Additionally, wear of the development sleeve 34a can be slower when the surface is relatively smooth, thus expanding the operational life. Additionally, compared with typical development sleeves on which grooves are formed, developer particles can stand on end thereon more uniformly on the surface of the development sleeve 34a, and accordingly development efficiency can be higher.
A thirteenth embodiment regarding a driving gear to drive the development sleeve is described below. The feature of the thirteenth embodiment is applicable to the development device 3 according to any one of the above-described first through twelfth embodiments.
When the module of the development gear 34gZ is larger or the number of its tooth is greater as in the comparative example shown in
By contrast, in the present embodiment, the external diameter of the development gear 34g is smaller than that of the development sleeve 34a and can be disposed within an area facing the photoconductor 1 in the longitudinal direction without interfering with the photoconductor 1, thus decreasing the size of the development device 3 in the longitudinal direction.
An example of a spur gear applicable to the development device 3 of the present embodiment is described below.
A diameter dk of the addendum circle of the spur gear can be obtained by the formula A9.
dk=do+2·m (A9)
wherein do represents a pitch diameter (z·m), m represents a module, and z represents the number of tooth.
When the external diameter of the development sleeve is 10 mm and the number of tooth as undercut limit is 17, from the formula A9, the diameter dk of the addendum circle can be 10 mm or less when the following condition is satisfied.
10=17·m+2·m
m=0.53
Therefore, the module should be 0.5 mm.
Although reducing the size of the module can increase the number of tooth, the strength of the gear decreases as the module becomes smaller. Accordingly, the gear might fail to transmit the driving force to the development sleeve 34a if the gear is extremely small. However, in the present embodiment, the load to the development sleeve 34a is reduced in the developer regulation portion, which faces the developer regulator 35, and accordingly the rotational torque of the development sleeve 34a is smaller. Consequently, the size of the module can be as small as 0.5 mm, for example.
Thus, the development gear 34g can have an external diameter smaller than that of the development sleeve 34a, thus compactness of the development device 3 can be attained.
A fourteenth embodiment regarding a preset seal is described below. The feature of the fourteenth embodiment is applicable to the development device 3 according to any one of the above-described first through thirteenth embodiments.
When development devices are shipped from factory, it is preferable that the developer is preliminarily set in the developer containing part thereof. Therefore, the development device 3 according to the present embodiment is provided with a preset seal to prevent leakage of developer from the casing 33 (developer containing part) during transportation.
It is to be noted that reference characters I1 through I7 represent the flow of the developer.
In a short side direction of the development device 3 perpendicular to its longitudinal direction, as shown in
By contrast, in the longitudinal direction (axial direction of the development sleeve 34a), the developer is circulated from the circulation path 38 through the bring-up port 41, the supply path 37, and the falling port 42 again to the circulation path 38 in that order.
By providing the above described seal member, the developer can be preset in both the supply path 37 and the circulation path 38, and the development device 3 can be transported reliably without leakage of the developer.
It is to be noted that, in the configuration shown in
In the configurations shown in
It is to be noted that, in the configuration shown in
In the configurations shown in
The seal member 60-11 is pulled through the seal cleaning member 61 from the development device 3I to remove the developer adhering to the surface of the seal member 60-11 similarly to the configurations shown in
It is to be noted that, although the configurations shown in
In addition, although the seal cleaning member 61 is used only when the seal member is pulled out upward from the development device 3 in the description above, it is preferable that the seal cleaning member 61 is provided in the configuration in which the seal member is pulled out horizontally.
Thus, by sealing the space in which the development sleeve 34a is provided and the third communication area between the supply path 37 and the circulation path 38, leakage of the developer can be prevented during transportation even when the developer is preset therein. When the development device is used as a replacement part, because package thereof can be kept clean, users do not have a feeling of discomfort.
Additionally, scattering of the developer inside the image forming apparatus can be prevented, and accordingly image failure and malfunction of the apparatus thereby can be prevented.
In the above described embodiment and variations thereof, the seal member 60 is thermally welded to the casing forming an edge portion of the communicating area to be sealed in the longitudinal direction, thus sealing the communicating area. The seal member 60 is folded on a first side in the longitudinal direction, opposite a second side from which the seal member 60 is pulled out from the development device 3. The seal member 60 is removed out from the development device 3 by pulling a second end portion of the seal member 60 that is not welded to the casing and is disposed on the opposite side of the welded side across the folded portion. By pulling the folded seal member 60, not the seal member 60 is removed entirely at once, but the seal member 60 can be removed gradually from the second end portion from the development device 3. Therefore, the force necessary to remove the seal member 60 can be reduced. Accordingly, the force applied to the seal member 60 while being pulled is reduced, which can reduce the risk of damaging the sealing member 60 to such an extent that the seam member 60 cannot be removed while pulling the seal member 60.
It is to be noted that the seal member 60 is not necessarily folded when welded. Sealing of the communicating area is not limited to thermal welding but can be any configuration as long as the seal member can reliably seal the communicating area and can be pulled out from the development device 3.
It is to be noted that the configuration according to the fourteenth embodiment is applicable to relatively compact development devices using a three-pole magnet roller and a development sleeve of reduced diameter as in the first through seventh embodiments. However, the configuration of the fourteenth embodiments is also applicable to development devices in which the number of developer-carrying magnetic poles to generate a magnetic field to keep the developer on the development sleeve is more than four, for example, five as in the comparative example 2 shown in
Numerous additional modifications and variations are possible in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the disclosure of this patent specification may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
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2009-025834 | Feb 2009 | JP | national |
2009-298609 | Dec 2009 | JP | national |
The present application is a continuation application of and claims the benefit of priority from U.S. application Ser. No. 14/030,590, filed Sep. 18, 2013, which is a continuation application of U.S. application Ser. No. 12/700,834, filed Feb. 5, 2010, now U.S. Pat. No. 8,571,449, which is based upon and claims the benefit of priority from Japanese Patent Application Nos. 2009-025834, filed on Feb. 6, 2009, and 2009-298609, filed on Dec. 28, 2009, in the Japan Patent Office, the contents of each of which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | |
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Parent | 14030590 | Sep 2013 | US |
Child | 14262338 | US | |
Parent | 12700834 | Feb 2010 | US |
Child | 14030590 | US |