1. Field of the Invention
The present invention generally relates to a development device, a process cartridge, and an image forming apparatus and more particularly to a development device using what is called the ETH (Electrostatic Transport & Hopping) phenomenon in which two-component magnetic brush development is used so as to charge toner and form an electric field, the toner is transferred to a conveying electric field formed on a conveying base in accordance with force of the electric field, and the toner is transferred to a development area, a development device using what is called a flare phenomenon in which the toner is conveyed in accordance with movement of a surface of a conveying member in addition to the electric field, a process cartridge provided with the development device, and an image forming apparatus.
2. Description of the Related Art
Conventionally, there have been known development devices for performing development supplying developer to a latent image carrier without directly bringing the developer on a developer carrier into contact with the latent image carrier. Patent Document 1, for example, discloses a development device for supplying toner to the latent image carrier by using a conveying member. This conveying member is disposed so as to face the latent image carrier and plural electrodes are arranged on a surface thereof at a predetermined pitch. An alternating voltage of n phases is applied to the electrodes so as to generate a progressive-wave electric field for conveying toner. In accordance with the progressive-wave electric field, the toner is conveyed to a development area facing the latent image carrier while the toner is hopping in the vertical direction. While the toner conveyed to the development area is further hopping in the vertical direction, the toner receive force so as to be directed to the latent image carrier in an image area and to the conveying member in a non-image area, so that the image area is developed.
Patent Document 1: Japanese Laid-Open Patent Application No. 2004-198675
However, in these conventional development devices, unevenness of a toner cloud layer is generated in a supply area, a conveying area, and the development area. Toner moves from the supply area to the development area in accordance with the electric field, so that it is impossible to form a high electric field and supply the toner or to bring a member carrying the toner into contact with the conveying member via the toner. When the member carrying the toner is brought into contact with the conveying member, the toner may be attached to the conveying base in accordance with electrostatic force of the toner, especially, image force and non-electrostatic force (Van der Waals force, in particular). This is referred to as “adhesion”. When the toner is supplied in a non-contact manner so as to reduce the adhesion, a status of toner supply becomes uneven because of a supply gap and an uneven status of a magnetic brush. Further, the conveying member is formed using glass or resin with relatively high resistance and has at least a base layer, an electrode layer, and a surface layer. Thus, unevenness upon manufacturing such as resistance distribution, surface roughness distribution, and surface wettability may have an influence on an electric field to be formed. Moreover, in the development area, charge amount distribution becomes broad in addition to the supply and conveying, so that electric potential of the toner cloud layer becomes uneven depending on position. This has an influence on developing bias and an effective developing bias is fluctuated and becomes unstable.
It is a general object of the present invention to provide an improved and useful development device, process cartridge, and image forming apparatus in which the above-mentioned problems are eliminated.
A more specific object of the present invention is to provide a development device, process cartridge, and image forming apparatus that can form a uniform toner cloud layer and a uniform image and downsize an entire apparatus.
According to one aspect of the present invention, there is provided a development device including: a latent image carrier; a conveying member disposed so as to face the latent image carrier, the conveying member having plural electrodes insulated from one another and arranged at predetermined intervals so as to generate an electric field for moving toner on the conveying member; a voltage application unit applying a voltage of n phases (n is a positive integer not less than one) to the electrodes so as to form a cloud of the toner and the toner is adhered to the latent image carrier so as to form a visualized toner image; a toner supply unit supplying the toner to the conveying member; and a height adjusting member adjusting a uniform height for a toner layer of the toner immediately before a development area on the conveying member in which development is performed. Thus, it is possible to form a uniform toner cloud layer and a uniform image.
According to another aspect of the present invention, in the development device, the voltage application unit forms a progressive-wave electric field for moving the toner on the conveying member and the toner is conveyed to an area facing the latent image carrier. Thus, low voltage driving is possible, so that it is possible to perform high-quality development with high development efficiency.
According to another aspect of the present invention, in the development device, the toner is conveyed to the area facing the latent image carrier in accordance with movement of a surface of the conveying member in addition to the progressive-wave electric field formed by the voltage application unit.
According to another aspect of the present invention, in the development device, a potential difference is generated between an odd number electrode group as a collection of odd number electrodes and an even number electrode group as a collection of even number electrodes determined based on a predetermined electrode of the plural electrodes, and pulse voltages whose phases are shifted to each other are applied to the odd number electrodes and the even number electrodes, thereby moving the toner between the electrodes on the surface of the conveying member. Thus, when electric potential of one electrode is shifted to a plus side relative to a center of amplitude (Vpp) of the pulse voltage, it is possible to have electric potential of the other electrode shifted to a minus side relative to the center of amplitude. In accordance with this, it is possible to generate a potential difference between both electrodes, the potential difference being greater than a half of the amplitude of the pulse voltage. In such a structure, a desired potential difference is generated between both electrodes using a pulse voltage with smaller amplitude (Vpp) in comparison with a case where a pulse voltage is applied to one of the electrodes. Thus, it is possible to reduce generation of scumming.
According to another aspect of the present invention, the development device includes a voltage application unit applying a voltage to the height adjusting member. Thus, it is possible to have sharp charge amount distribution and form a toner cloud layer in a more uniform manner.
According to another aspect of the present invention, in the development device, the voltage application unit applies an alternating voltage to the height adjusting member.
According to another aspect of the present invention, in the development device, the height adjusting member is made of a material having flexibility. Thus, it is possible to absorb impact of collision of hopping toner and reduce speed, so that it is possible to have uniform height distribution of the toner cloud layer.
According to another aspect of the present invention, in the development device, the height adjusting member is oscillated. Thus, the oscillation affects the hopping toner and repulsion is absorbed, so that it is possible to adjust a uniform height for the toner cloud layer.
According to another aspect of the present invention, in the development device, plural perpendicular direction conveying electrodes are disposed on the conveying member at predetermined intervals, the plural perpendicular direction conveying electrodes forming an electric field in a perpendicular direction relative to an area formed with a conveying direction and a hopping direction of the toner, and the toner is oscillated in a perpendicular direction relative to the toner conveying direction through the electric field formed by the perpendicular direction conveying electrodes so as to adjust a uniform width for the toner and the uniform height is adjusted for the toner layer of the toner.
According to another aspect of the present invention, in the development device, coverage of additive for the toner is not less than 40%.
According to another aspect of the present invention, there is provided a process cartridge comprising: the above-mentioned development device; and at least one of a latent image carrier, a charging unit, and a cleaning unit in an electrophotographic process, wherein the process cartridge is detachable from a body of an image forming apparatus. Thus, it is possible to provide a process cartridge capable of forming a uniform toner cloud layer and a uniform image.
According to another aspect of the present invention, there is provided an image forming apparatus comprising: the above-mentioned development device or the above-mentioned process cartridge. Thus, it is possible to provide an image forming apparatus capable of forming a uniform toner cloud layer and a uniform image.
According to another aspect of the present invention, there is provided an image forming apparatus for forming a color image comprising plural process cartridges mentioned above. Thus, it is possible to provide an image forming apparatus for forming a color image capable of forming a uniform toner cloud layer and a uniform image.
In the development device according to the present invention, by disposing the height adjusting member adjusting a uniform height for the toner layer of the toner immediately before the development area for performing development on the conveying member, it is possible to form a uniform toner cloud layer and a uniform image.
Other objects, features and advantage of the present invention will become more apparent from the following detailed description when read in conjunction with the accompanying drawings.
DR=E/(IRQ−IRII)
As shown in
Then, the developer 34 made of toner and magnetic particles is carried on the sleeve 33 in a brush-like manner from magnetic force of the magnetic brush roller 31. The toner in the magnetic brush on the magnetic brush roller 31 obtains a specified amount of electrostatic charge by being mixed with the magnetic particles. Preferably, the amount of electrostatic charge of the toner on the magnetic brush roller 31 is within a range from −10 to −40 [μC/g].
A conveying member 36 is disposed so as to be brought into contact with the magnetic brush on the magnetic brush roller 31 in a toner supply area A1 adjacent to the magnetic pole N2 in the magnetic brush roller 31 and to face a photoconductor 37 in a development area A2. Moreover, a regulation member 43 having a relatively long length in a longitudinal direction is disposed along a conveying direction of the conveying member 36 so as not to increase a cloud height due to disturbance of a toner layer when the toner on the conveying member 36 is conveyed to the development area A2 between the conveying member 36 and the photoconductor 37. Further, a space in a closest portion between the regulation blade 35 and the magnetic brush roller 31 is set to be 500 μm and the magnetic pole N1 of the magnet member 32 facing the regulation blade 35 is positioned in an upstream of the rotation direction of the magnetic brush roller 31 relative to a position facing the regulation blade 35 as much as several degrees. In accordance with this, it is possible to readily form a circulating flow of the developer 34 in a casing 38.
The regulation blade 35 is brought into contact with the magnetic brush such that an amount of the developer 34 formed on the magnetic brush roller 31 is regulated at a portion facing the magnetic brush roller 31. Thus, a predetermined amount of the developer is conveyed to the toner supply area and frictional electrification of the toner and the magnetic particles in the developer 34 is accelerated.
The magnetic brush roller 31 is rotated by a rotation driving device not shown in the drawings in a direction indicated by arrow B in
The following describes supply, conveying, and development operations of the development device in
At the toner supply area A1, the toner in the magnetic brush is separated and transferred to the conveying member. An AC bias voltage is applied to the magnetic brush roller 31. In the present embodiment, supply capacity of a supply unit is 0.6 [mg/cm2] at a potential difference of 1000 [V]. In this case, rotation linear velocity of the sleeve 33 is 40 [cm/s] and conveying capacity of per width of 1 cm is expressed as: 0.6 [mg/cm2]×40 [cm/s]=24 [mg/cm·s].
In the development device 100, the toner T is conveyed to the vicinity of the photoconductor drum 200 in the conveying area of the conveying base 102. In the development area, an electric field is generated so as to direct the toner T to the photoconductor drum 200 relative to an image area of a latent image on the photoconductor drum 200 and to direct the toner T to an opposite side (conveying base 102) of the photoconductor drum 200 relative a non-image area, thereby attaching the toner T to the latent image and performing development. In the collection area, an electric field is formed so as to direct the toner T to the opposite side (conveying base 102) of the photoconductor drum 200 relative to both image area and non-image area of the latent image.
In accordance with this, in the development area, the toner is attached to the latent image on the photoconductor drum 200 and the image is visualized. Toner which does not contribute to the development is collected in the collection area of the conveying base 102 in a downstream of the rotation direction (movement direction) of the photoconductor drum 200. Thus, generation of scattered toner is prevented. It is possible to securely collect floating toner by disposing the collection area in the downstream of the movement direction of the latent image carrier relative to the development area.
In the following, a structure of the conveying base in the development device according to the first embodiment is described in detail with reference to FIGS. 5 to 9.
As shown in
On both sides of the conveying electrodes 101a, 101b, and 101c, common electrodes 106a, 106b, and 106c (these electrodes are referred to as common electrodes 106) connected to each of the conveying electrodes 101a, 101b, and 101c at both ends of the common electrodes 106 are disposed along the toner conveying direction, namely, in a direction substantially orthogonal to each of the conveying electrodes 101a, 101b, and 101c. In this case, a width of the common electrodes 106 (width in the direction orthogonal to the toner conveying direction) is wider than a width of the conveying electrodes 101 (width in the direction along the toner conveying direction). In addition, in
In the present embodiment, as shown in FIGS. 7 to 9, after patterns of the common electrodes 106a, 106b, and 106c are formed on the support base 104, an interlayer insulation film 107 is formed, and then a contact hole 108 is formed on the interlayer insulation film 107. Thereafter, the conveying electrodes 101a, 101b, and 101c are formed, so that the conveying electrodes 101a, 101b, and 101c and the common electrodes 106a, 106b, and 106c are interconnected respectively. In addition, the interlayer insulation film 107 may be made of the same materials or different materials from the surface protection layer 105. Further, the interlayer insulation film 107 may be formed on a pattern integrally formed with the conveying electrode 101a and the common electrode 106a, a pattern integrally formed with the conveying electrode 101b and the common electrode 106b may be formed on the interlayer insulation film 107, and the interlayer insulation film 107 may be further formed thereon, so that it is possible to form a pattern where the conveying electrode 101c and the common electrode 106c are integrally formed on the interlayer insulation film 107. In other words, it is possible to have the electrodes in a three-layer structure or both integrated forming with interconnection using the contact hole 108.
Moreover, in the common electrodes 106a, 106b, and 106c, an input terminal (not shown in the drawings) for applying driving signals is disposed so as to input driving signals (driving waveforms) Va, Vb, and Vc from the driving circuit 103 of
As the support base 104, it is possible to use a glass base, a base made of insulating materials such as a resin base, a ceramics base, or the like, a base made of conductive materials such as SUS on which an insulating film such as SiO2 and the like is formed, and a base made of materials capable of flexible deformation such as a polyimide film.
The conveying electrodes 101 are made by forming a film of conductive materials such as Al, Ni—Cr, or the like with a thickness of 0.1 to 10 μm, preferably, 0.5 to 2.0 μm on the support base 104 and forming a pattern of a required electrode shape using a photolithographic technique and the like. The width L of the plural conveying electrodes 101 in the movement direction of powder is within a range from not less than one time to not more than 20 times an average particle diameter of powder to be moved and a space of the conveying electrodes 101 in the movement direction of powder is also within a range from not less than one time to not more than 20 times the average particle diameter of powder to be moved.
Moreover, as the surface protection layer 105, for example, a film of SiO2, TiO2, TiO4, SiON, BN, TiN, Ta2O5, ZrO2, BaTiO3, and the like is formed with a thickness of 0.5 to 10 μm, preferably, 0.5 to 3 μm. Further, inorganic nitrides such as SiN, BN, and the like may be used. In particular, when surface hydroxyl is increased, the amount of charge of the charged toner is likely to be reduced while being conveyed, so that inorganic nitrides having a small amount of surface hydroxyl (SiOH, silanol group) is preferably used.
The following describes a principle of electrostatic conveying of toner in the conveying base constructed in this manner. When n-phase (n is positive integer not less than 2) driving waveforms are applied to the plural conveying electrodes 101 of the conveying base 102, a phase electric field (progressive-wave electric field) is generated by the plural conveying electrodes 101 and the toner charged on the conveying base 102 receives repulsive force and/or attractive force, so that the toner moves in the movement direction while hopping and being conveyed.
For example, as shown in
In this manner, as shown in
At the next timing, “+”, “G”, “G”, “+”, and “G” are applied to the plural conveying electrodes 101 as shown in (2) of
In accordance with this, by applying plural-phase driving waveforms with changing voltage to the plural conveying electrodes 101, a progressive-wave electric field is generated on the conveying base 102, so that the negatively charged toner T moves in a movement direction of the progressive-wave electric field while hopping and being conveyed. In addition, when the toner T is positively charged, the positively charged toner moves in the same direction in the same manner by reversing the above-mentioned pattern for changing the driving waveforms.
Specifically, how the toner T is conveyed is described with reference to
The following describes an entire structure of a driving circuit of
Moreover, the waveform amplifiers 103-2a, 103-2b, and 103-2c apply three-phase driving waveforms (driving pulses) Va1, Vb1, and Vc1 to each of the conveying electrodes 101 in the conveying area and each of the conveying electrodes 101 in the collection area of
As mentioned above, in the ETH, the toner is caused to be hopping, so that it is possible to perform reversal development of an electrostatic latent image on the latent image carrier using monocomponent development. In other words, in the development area, development is performed by a unit disposed for forming an electric field such that, in the development area, the toner is directed to the latent image carrier relative to the image area of the latent image and the toner is directed to the opposite side of the latent image carrier relative to the non-image area.
For example, in a case of pulse-like voltage waveforms changing from 0 to −100 V as the above-mentioned driving waveforms of hopping voltage patterns as shown in
In a case where the driving waveforms of hopping voltage patterns are pulse-like voltage waveforms changing from 20 V to −80 V, when the electric potential of the image area is about 0 V and the electric potential of the non-image area is −110 V, the electric potential of a low level of the pulse-like driving waveforms is between the electric potential of the image area and the electric potential of the non-image area of the latent image, so that the toner is directed to the latent image carrier relative to the image area and the toner is directed to the opposite side of the latent image carrier relative to the non-image area in the same manner.
In other words, by setting the electric potential of the low level of the pulse-like driving waveforms between the electric potential of the image area and the electric potential of the non-image area of the latent image, it is possible to prevent the toner from being attached to the non-image area and perform high-quality development.
In this manner, in the ETH, the toner is attracted and attached to the image area of the latent image because of the hopping of the toner and the toner is repelled and unattached in the non-image area, so that it is possible to develop the latent image using the toner. In this case, it is possible to readily convey the hopping toner to the latent image carrier since no attractive force is generated with the conveying base, so that it is possible to perform high-quality development in a low voltage.
In other words, in a conventional what is called toner projection development, applied voltage exceeding adhesion of the toner to the development roller is necessary so as to separate the charged toner from the development roller and convey the toner to the photoconductor, so that a bias voltage of DC 600 to 900 V is required. By contrast, according to the present invention, although the adhesion of the toner usually ranges from 50 to 200 nN, the adhesion to the conveying base 102 becomes substantially 0 because the toner is hopping on the conveying base 102. Thus, the necessity of force to separate the toner from the conveying base 102 is eliminated and it is possible to sufficiently convey the toner to the latent image carrier in a low voltage.
Further, even when a voltage to be applied to each of the conveying electrodes 101 is a low voltage not mote than |150 to 100 |V, an electric field to be generated has a large value, so that it is possible to readily separate the toner attached to the surface of the conveying electrodes 101 and cause the toner to be projected or hopping. In addition, it is possible to substantially reduce or eliminate an amount of ozone or NOx generated when the photoconductor such as OPC is charged, so that the present invention is very advantageous in terms of environment issues and durability of the photoconductor.
In accordance with this, it is not necessary to have a high voltage bias of 500 V to several KV applied between the development roller and the photoconductor so as to separate the toner attached to the surface of the development roller or the surface of the carrier according to the conventional method, and it is possible to form and develop the latent image while the electric potential of the photoconductor is very low.
For example, when the OPC photoconductor is used and a thickness of CTL (Charge Transport Layer) on the surface is 15 μm, relative permittivity ∈ is 3, and charge density of the charged toner is (−3E-4C/m2, surface potential of OPC is about −170 V. In this case, when pulse-like driving voltages of 0 to −100 V having duty of 50% are applied as an applied voltage to the electrodes of the conveying base, an average is −50 V, so that an electric field between the electrodes of the conveying base and the OPC photoconductor has the relationship as mentioned above when the toner is negatively charged.
In this case, when a gap (space) between the conveying base and the OPC photoconductor is from 0.2 to 0.3 mm, development is sufficiently possible. Although the development depends on Q/M of the toner, a voltage applied to the electrodes of the conveying base, and a printing speed, namely, a rotation speed of the photoconductor, the development is sufficiently possible in the case of the negatively charged toner when an electric potential for charging the photoconductor is at least not more than −300 V or −100 V when development efficiency has priority. In a case of positive charge, the electric potential of the charged toner has positive potential.
The above-mentioned ETH performs development by causing the toner to be hopping on the conveying base so as to make the adhesion to the conveying base substantially 0. However, by merely causing the toner to be hopping on the conveying base, even when the hopping toner has progressive properties towards the latent image carrier, certainty of attaching to the latent image of the latent image carrier is not assured and toner is scattered.
In view of this, the present invention provides conditions in the ETH by which the hopping toner is securely adhered to the image area of the latent image of the latent image carrier in a selective manner without being adhered to the non-image area, namely, without causing scumming.
In other words, a relationship between the electric potential (surface potential) of the latent image of the latent image carrier and the electric potential (electric field to be generated) to be applied to the conveying base is set as a predetermined relationship so as to generate the electric field for directing the toner to the latent image carrier relative to the image area of the latent image of the latent image carrier and directing the toner to the conveying base relative to the non-image area as mentioned above. In accordance with this, the toner is securely attached to the image area of the latent image and the toner directed to the non-image area is repelled to the conveying base. Thus, the toner hopping on the conveying base is efficiently used for development and it is possible to prevent the scattering of toner and perform high-quality development through low-voltage driving.
In this case, by setting an average value of electric potential (average potential) applied to the conveying electrodes of the conveying base to be an electric potential between the electric potential of the image area and the electric potential of the non-image area of the latent image of the latent image carrier, it is possible to generate the electric field for directing the toner to the latent image carrier relative to the image area and directing the toner to the conveying base relative to the non-image area of the latent image of the latent image carrier as mentioned above.
The following describes a case where AC is applied to the uniform hopping height adjusting member. As shown in
On the other hand, these facts result from a difference of hopping height due to the toner being conveyed having a charge amount distribution. Toner of high distribution has a relatively high charge amount and the intensity of an electric field affecting the toner is considered to be increased relative to the voltage applied to the conveying electrodes. Although toner of low distribution has a relatively low charge amount, the voltage applied to the uniform hopping height adjusting member affects the toner having high distribution and the relatively high charge amount, so that the height is controlled to be reduced. And, the height of the toner having the relatively low charge amount is controlled to be increased, so that unevenness of height is reduced and it is possible to have a uniform electric potential especially for the toner cloud.
Further, although the toner to be used is coated with additive so as to have fluidity, an experience of isolated toner reveals that unevenness of conveying is generated when coverage of the additive is not more than a certain value and it is impossible to convey the toner when the coverage is further reduced.
Tn=100C·√3/{2π(100−C)(1+r/R)2(r/R)(ρr/ρc)}
where R: radius of the toner, r: radius of the additive, and C: wt % of the additive relative to the toner.
As shown in
The following describes a case where the uniform hopping height adjusting member is constituted using a material having flexibility and oscillated, so that a conveying status is stabilized and the toner cloud layer becomes uniform.
As shown in
In this case, the uniform hopping height adjusting member is formed using a material having flexibility. Examples of such a material include rubber materials such as silicon, butadiene, NBR, hydrin, EPDM, and the like. It is possible to use these rubber materials when conductive agent such as carbon black is dispersed and resistance is adjusted. Depending on hardness, when a thickness of the uniform hopping height adjusting member is within a range from several tens of μm to 2 mm, impact of collision of the toner hopping from the conveying electrodes is absorbed and speed is reduced, so that it is possible to have uniform distribution of the height of the toner cloud layer. Preferably, the hardness of the materials ranges from about 10 degrees to 35 degrees in Asker C. When the hardness is less than 10 degrees, plasticizer is likely to bleed and a possibility of reacting to the toner and fixing is increased. When the hardness exceeds 35 degrees, the materials are unable to absorb the impact of the collision and the toner is repulsed with high elasticity, so that a possibility of colliding with other toner is increased. In accordance with this, disturbance in the toner cloud layer is accelerated.
Moreover, as shown in
The following describes a second embodiment of the present invention. As shown in
The charged toner layer 125 is formed by developing a solid image into a thin layer on the base 124 using a two-component development unit not shown in the drawings. The toner used in this case is polyester having a particle diameter of about 6 [μm] and a toner charge amount of about −22 [μC/g] when formed on the base 124 into the thin layer. As shown in
A result as shown in
In this case, the activity of flare is obtained from sensory evaluation of five grades by observing the toner adhered and stationary on a surface of the base 124. From
Moreover, volume resistivity of the surface layer 123 of the base 124 is specified (changed) to several points and the flare activity is confirmed in the same manner. A material used for the surface layer 123 is silicone resin and the protection layer 123 (thickness is about 5 [μm]) with a volume resistivity of 107 to 1014 [Ω·cm] is formed by changing an amount of carbon particles dispersed therein. When the protection layer 123 having a pitch p of 50 [μm] for the electrodes 122-1, 122-2, 122-3 . . . is used and the same experiment as mentioned above is conducted, a result shown in
From this result, it is confirmed that the volume resistivity of the surface layer 123 is preferably within a range from 109 to 1012 [Ω·cm]. This is because when the surface layer 123 with a very high volume resistivity is used, the surface of the base 124 remains charged due to friction between toner repeatedly projected and the surface layer 123. In accordance with this charge, surface potential of the base 124 is fluctuated, so that bias contributing to development is made unstable. By contract, when conductivity of the surface layer 123 is very high, a leak of electric charge (short circuit) is generated between the electrodes 122-1, 122-2, 122-3 . . . , so that efficient bias effects are not obtained. The protection layer 123 is required to have suitable resistivity (109 to 1012 [Ω·cm] in volume resistivity) so as to successfully flow electric charge stored on the surface of the base 124 to a group of electrodes 122-1, 122-2, 122-3 . . . This optimum range of volume resistivity is obtained from an experiment in which experimental equipment provided with a device shown in
As shown in
Although the above-mentioned example is described based on a case where pulse voltages in opposite phase to each other are applied to the odd number electrode and the even number electrode, it is not necessary to have a completely opposite phase. Even if an amount of shift of the phase is not more than a half of the cycle, when the potential of one electrode is shifted to a plus side relative to the center of amplitude (Vpp) of a pulse voltage, it is possible to have the potential of the other electrode shifted to a minus side relative to the center. However, completely opposite phases are most efficient since a period of time when the potential difference between the electrodes is the same as the amplitude is longest.
In the toner carrier 131, as shown in
In the toner carrying roller 131, in the same manner as in the above-mentioned base 124, a thin toner layer is formed on the surface protection layer 155. When the alternating voltage shown in
Toner which does not contribute to the development is returned from the image area to the magnet sleeve 157 again. Since the flare is formed, the adhesion of the toner to the toner carrying roller 131 is very low, so that the toner on the toner carrying roller 131 returned from the image area is readily scraped off or smoothed by the spike of the two-component development following in accordance with the rotation of the magnet sleeve 157. By repeating this, a substantially constant amount of toner flare is always formed on the toner carrying roller 131. While the two-component development unit 156 stirs two-component developer 163 in a container 160, the two-component development unit 156 conveys and circulates the two-component developer 163. The magnet sleeve 157 conveys a portion of the two-component developer to the toner carrying roller 131 and returns unnecessary toner which does not contribute the development from the development area.
An organic photoconductor with a thickness of 13 [μm] is used for the latent image carrier 158. The following describes a case where a latent image is formed using a laser writing system with a resolution of 1200 dpi. The photoconductor 158 is rotated by a driving unit not shown in the drawings and uniformly charged by a charging unit. The photoconductor 158 is exposed by the laser writing system as an exposure unit and an electrostatic latent image is formed. In this case, potential of charge of the photoconductor 158 ranges from −300 to −500 [V] and the electrostatic latent image is formed such that potential of writing in a solid area ranges from 0 to −50 [V].
The electrostatic latent image is developed using the toner forming the flare on the toner carrying roller 131 and a toner image is formed. In this case, when toner with a charge amount of about −22 [μC/g] and a particle diameter of 6 [μm] is used and conditions are examined so as to realize one dot of 1200 dpi with good filling in the solid area without scumming, a gap between the toner carrying roller 131 and the photoconductor 158 is about 500 [μm] and an alternating-current bias having −400 [V] and 0 [V] at peaks and an average potential of −200 [V] at each moment is applied at a frequency of 5 [kHz] from the alternating-current power supply 159 to the odd number electrode group and the even number electrode group of the toner carrying roller 131 (phases of the alternating-current bias are opposite to each other in the odd number electrode group and the even number electrode group).
The toner image on the toner carrying roller 131 is transferred by a transfer unit to a recording medium such as recording paper or the like fed from a paper feed unit. The toner image is fixed on the recording medium by a fixing unit and the recording medium is externally ejected. When excessive toner is on the toner carrying roller 131, an electric field curtain is shielded from electric charge of the toner and it is impossible to form a flare. In view of this, a direct-current bias of about 200 [V] is applied between the magnet sleeve 157 and the toner carrying roller 131 from the power supply such that an amount of toner per unit area on the toner carrying roller 131 is 0.2 [mg/cm2]. In addition, because of a toner diffusion effect from the flare, slight unevenness is allowed upon transferring the toner from the magnet sleeve 157 to the toner carrying roller 131. No element or unit is required in particular between the magnet sleeve 157 and the toner carrying roller 131 so as to superpose the alternating-current bias on the direct-current bias. Moreover, no element or unit is required in particular so as to have a strictly uniform spike of the two-component developer.
On the other hand, an amount of toner required for a solid image on the photoconductor 158 is 0.4 [mg/cm2], so that a movement speed of the toner carrying roller 131 is required to be not less than twice the movement speed of the photoconductor 158 so as not to generate a shortage of toner in the development area. In this case, the movement speed of the toner carrying roller 131 is 2.5 times higher than that of the photoconductor 158. A movement direction of the toner carrying roller 131 and a movement direction of the photoconductor 158 may be the same as shown in
In the image forming apparatus according to the present embodiment, matrix resin of the toner (main component of toner) is made of polyester or styrene acrylic resin and regular charge polarity is minus polarity (negative polarity). And what is called a reversal development is performed in which a uniformly charge area (ground area) and the latent image area of the photoconductor 158 are made to have the same polarity as the regular charge polarity of the toner (minus polarity in this example) and the toner is selectively attached to the latent image area where the potential is reduced in comparison with the ground area.
The cylindrical toner carrying roller 131 in
In the image forming apparatus provided with the protection layer 123, the protection layer 123 (surface protection layer) of the toner carrying roller 131 as a toner carrier accelerates frictional electrification of the toner to the regular charge polarity in accordance with sliding friction with the hopping toner. And frictional electrification of the toner to the opposite polarity of the regular charge polarity in accordance with the sliding friction with the protection layer 123 is prevented. In accordance with this, reduction of the amount of charge (regular charge polarity) of the toner accompanied with hopping is prevented, so that it is possible to prevent generation of failure of development resulting from failure of toner hopping.
The regular charge polarity of the toner may be plus polarity (positive polarity). In this case, the protection layer 123 may be made of materials for accelerating frictional electrification of the toner to the plus polarity in accordance with the sliding friction with the toner.
Further, electrification series of toner indicate electrification series of an entire toner in which external additives such as silica, titanium oxide, and the like are added to the matrix resin of the toner (particles). It is possible to examine order in the electrification series as described in the following. After the toner is subjected to sliding friction with the surface protection layer for a predetermined time on the surface protection layer, the toner is collected through suction. The amount of charge of the collected toner is measured using an electrometer. When this measurement result shows an increase of the amount of charge of the toner in the negative polarity, the toner is in the minus side on the electrification series relative to the surface protection layer. When the measurement result shows an increase of the amount of charge of the toner in the positive polarity, the toner is in the plus side on the electrification series relative to the surface protection layer.
Thus, according to the present embodiment, it is possible to realize higher image quality and configure a smaller development device in comparison with conventional techniques.
The embodiment shown in
Thus, according to the present embodiment, it is possible to realize higher image quality and a smaller development device in comparison with conventional techniques.
On a left side of the photoconductor 169, there are arranged image creating devices 170K, 170Y, 170C, and 170M as plural image forming units forming images of plural colors, namely, black, yellow, cyan, and magenta, for example. The photoconductor 169 is uniformly charged by a charging unit 171K at the image creating device 170K and the photoconductor 169 is exposed by a writing device as an exposure unit not shown in the drawings using a light beam 172K modulated in accordance with black image data, so that an electrostatic latent image is formed. The electrostatic latent image is developed by a development device 173K having the same structure as the development device in the above-mentioned embodiment including the two-component development unit 156 and the toner carrying roller 131 as shown in
Next, the photoconductor 169 is uniformly charged by a charging unit 171Y at the image creating device 170Y and the photoconductor 169 is exposed by the writing device as an exposure unit not shown in the drawings using a light beam 172Y modulated in accordance with yellow image data, so that an electrostatic latent image is formed. The electrostatic latent image is developed by a development device 173Y having the same structure as the development device in the above-mentioned embodiment including the two-component development unit 156 and the toner carrying roller 131 as shown in
Next, the photoconductor 169 is uniformly charged by a charging unit 171C at the image creating device 170C and the photoconductor 169 is exposed by the writing device as an exposure unit not shown in the drawings using a light beam 172C modulated in accordance with cyan image data, so that an electrostatic latent image is formed. The electrostatic latent image is developed by a development device 173C having the same structure as the development device in the above-mentioned embodiment including the two-component development unit 156 and the toner carrying roller 131 as shown in
Next, the photoconductor 169 is uniformly charged by a charging unit 171M at the image creating device 170M and the photoconductor 169 is exposed by the writing device as an exposure unit not shown in the drawings using a light beam 172M modulated in accordance with magenta image data, so that an electrostatic latent image is formed. The electrostatic latent image is developed by a development device 173M having the same structure as the development device in the above-mentioned embodiment including the two-component development unit 156 and the toner carrying roller 131 as shown in
On the other hand, a recording medium such as recording paper or the like is fed from a paper feed device not shown in the drawings. The full-color image on the photoconductor 169 is transferred to the recording medium by a transfer roller 175 as a transfer unit to which a transfer bias is applied from the power supply. In the recording medium to which the full-color image is transferred, the full-color image is fixed by a fixing device 176 and the recording medium is ejected outside. In the photoconductor 169, residual toner and the like is removed by a cleaner 177 as a cleaning unit after the full-color image is transferred.
The development devices 173K, 173Y, 173C, and 173M may employ the development device of
In this embodiment, four color toner images are written on the same photoconductor 169, so that the color images are superposed on the photoconductor with little generation of positional displacement in principle and it is possible to obtain a high-quality full-color image without positional displacement in comparison with a conventional 4 drum tandem method.
In the image forming apparatus shown in
The following describes an image forming apparatus according to a first embodiment of other aspect of the present invention with reference to
A schematic structure of an entire portion of the image forming apparatus and operations are described in the following. A photoconductor drum 301 as a latent image carrier includes a base 302 and a photoconductor layer 303 on the base 302. The photoconductor drum 301 is rotated in a direction indicated by an arrow C. The photoconductor drum 301 is uniformly charged by a charging unit 304 and an electrostatic latent image is formed on a surface of the photoconductor drum 301 through writing using a laser beam modulated in accordance with a read image from an exposure unit 305.
Then, the electrostatic latent image on the surface of the photoconductor drum 301 is visualized when toner is attached by a development device 306 according to the present invention. The visualized image is transferred to transfer paper (recording medium) 308 fed from a paper feed cassette 307 by a transfer runner 310 to which a voltage from a transfer power supply 309 is applied. The transfer paper 308 to which the visualized image is transferred is separated form the surface of the photoconductor drum 301 and fed through a space between rollers of a fixing unit 311, so that the visualized image is fixed and the transfer paper 308 is ejected to a paper ejection tray disposed outside the image forming apparatus.
On the other hand, toner residual on the surface of the photoconductor drum 301 after the transfer is finished is removed by a cleaning unit 312 and charge residual on the surface of the photoconductor drum 301 is eliminated by a charge eliminating lamp 313.
The operations of the development device according to the present invention are described. In a development device 306, charging brushes 314a and 314b are disposed so as to be brought into contact with each other and rotated, for example, as a member for charging toner powder. Toner T fed from a toner tank 315 is charged by receiving friction from the charging brushes 314a and 314b. The charged toner T is fed to a conveying base 316 and the toner T is conveyed on the conveying base 316 and caused to be hopping. The toner T is conveyed to a development area facing the photoconductor drum 301 as a latent image carrier and a required development is performed. Thereafter, residual toner T not subjected to the development is dropped from an end of the conveying base 316 and fed back to the member for charging toner (charging brush 314b) by a conveying base 317 for backward feed.
Structures of the conveying base 316 and the conveying base 317 for backward feed are the same as in the above-mentioned conveying base 102. A structure of a driving circuit for applying driving waveforms to each of electrodes on the conveying base 316 and the conveying base 317 for backward feed is the same as in the development device in each embodiment and emitted in the drawings.
By constructing the development device in this manner, it is possible to perform high-quality development and form a high-quality image. Further, by employing the uniform hopping height adjusting member in the present invention, it is possible to adjust a uniform hopping height for a toner cloud layer.
The following describes an image forming apparatus according to a second embodiment of other aspect of the present invention with reference to FIGS. 39 and 40 on which a process cartridge according to the present invention is installed.
An image forming apparatus 400 shown in
The process cartridge 402 configured using four process cartridges includes, as shown in
Inside the development device 414, there are disposed a toner supply roller 416, a charging roller 417, a conveying base 418, a toner feed base 419 for feeding toner to the conveying base 418, and a toner return roller 420 for returning collected toner. In addition, toner of each color is stored in the development device 414. On a side of the process cartridge 402, a slit 421 is formed and used as a window onto which a laser beam from the optical writing device 401 is projected.
Each of the optical writing devices 401-M, 401-C, 401-Y, and 401-Bk includes a semiconductor laser, a collimate lens, an optical deflector such as a polygon mirror, an optical system for scanning and image forming, and the like. The optical writing device projects a laser beam modulated in accordance with image data for each color input from a host (image processing device) such as an external personal computer or the like. The projected laser beam performs scanning on the photoconductor 412 of each of the process cartridges 402-M, 402-C, 402-Y, and 402-Bk so as to write an electrostatic charge image (electrostatic latent image).
When image forming is started, the photoconductor 412 of each of the process cartridges 402-M, 402-C, 402-Y, and 402-Bk is uniformly charged by the charging roller 413 and the laser beam modulated in accordance with the image data is irradiated onto each photoconductor from each of the optical writing devices 401-M, 401-C, 401-Y, and 401-Bk, so that electrostatic latent images of each color are formed on the photoconductor.
The electrostatic latent image formed on the photoconductor 412 is developed and visualized through the ETH by the conveying base 418 of the development device 414 using toner of each color. Further, toner which is not subjected to the development is conveyed on the conveying base 418 and returned to an inlet of the toner feed base 419 by the toner return roller 420. In this manner, by performing development using the development device according to the present invention, it is possible to form a high-quality image as mentioned above.
On the other hand, the recording paper in the paper feed cassette 403 is fed by the paper feed roller 404 in synchronization with image forming of each color in each of the process cartridges 402-Bk, 402-Y, 402-C, and 402-M and conveyed to transfer belt 406 by the register rollers 405 at a predetermined time. The recording paper is carried on the transfer belt 406 and successively conveyed to the photoconductors 412 of the four process cartridges 402-Bk, 402-Y, 402-C, and 402-M. Toner images of each color of Bk, Y, C, and M are successively superposed and transferred. The recording paper to which the toner images of four colors are transferred is conveyed to the fixing device 409, where a color image made using the toner images of four colors is fixed and the recording paper is ejected to the paper ejection tray 411.
The following describes an image forming apparatus according to a third embodiment of other aspect of the present invention with reference to FIGS. 41 and 42 on which a process cartridge according to the present invention is installed.
An image forming apparatus 500 shown in
The process cartridge 502 shown in
Usually, a color image forming apparatus is likely to have a large apparatus since plural image forming units are included. Further, when each of units such as the development device, the cleaning device, the charging unit, or the like separately has trouble or when the unit is to be replaced because of an end of life, it takes time and effort to replace the unit because of complexity of the apparatus.
In view of this, by constructing at least constituent elements of the image carrier and the development device in an integrally connected manner, it is possible to provide a small and highly durable color image forming apparatus capable of replacement by users.
In this case, toner on the image carrier 505 developed in the process cartridges 502-Y, 502-M, 502-C, and 502-Bk of each color is successively transferred to the transfer belt 501 extending in the lateral direction, to which a transfer voltage is applied.
In this manner, images of yellow, magenta, cyan, and black are formed on the transfer belt 501 in a multiple manner. The images are collectively transferred to a transfer material 504 by a transfer unit 503. The multiple toner images on the transfer material 504 are fixed by a fixing device not shown in the drawings.
The image forming apparatuses according to each of the above-mentioned embodiments are provided with the development device according to the present invention, so that it is possible to achieve a smaller apparatus and a lower cost and to improve image quality without toner scattering.
In the above-mentioned embodiments, toner is used as powder, for example. However, it is possible to apply the present invention to a device for conveying powder other than toner in the same manner, for example. Further, driving signals applied to the conveying electrodes are described based on the three phases, for example. However, the driving signals may have n phases (n is positive integer not less than 2), such as four phases, six phases, or the like.
The present invention is not limited to the specifically disclosed embodiment, and variations and modifications may be made without departing from the scope of the present invention.
The present application is based on Japanese priority application No. 2006-112835 filed Apr. 17, 2006, Japanese priority application No. 2007-018767 filed Jan. 30, 2007, the entire contents of which are hereby incorporated herein by reference.
Number | Date | Country | Kind |
---|---|---|---|
2006-112835 | Apr 2006 | JP | national |
2007-018767 | Jan 2007 | JP | national |