JP5333904B2 - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus that can suppress disturbance in a hopping state of toner on a toner carrier so as to prevent occurrence of density variation in an image formed on a recording medium. <P>SOLUTION: This image forming apparatus includes the toner carrier 1 having a plurality of electrodes 11 arranged on its surface at predetermined intervals; a voltage applying means 5 that generates, on the surface of the toner carrier, an electric field for hopping the toner while applying an n-phase alternate voltage varying with time to the plurality of electrodes; a hole forming member 45 having a plurality of holes 41 formed thereon and facing the toner carrier; a plurality of flying electrodes 42 in which each is provided at least one of a periphery and an inner wall of the hole on the surface of the hole forming member facing the toner carrier corresponding to the respective holes so as to cause the toner to fly from the toner carrier; and an opposing electrode 31 that faces the toner carrier through the hole forming member therebetween so as to form an electric field for attracting the flying toner. The application of the alternate voltage to the plurality of electrodes is intermittently carried out with the voltage applying means. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to an image forming apparatus such as a printer, a facsimile machine, and a copying machine, and more specifically, forms an image by flying and adhering toner ejected from a toner carrier onto a recording medium through a toner passage hole that is controlled to open and close. The present invention relates to an image forming apparatus.

  As a conventional image forming apparatus, an image forming apparatus employing a direct recording type image forming method called toner jet, direct toning, toner projection or the like (hereinafter referred to as a direct recording type image forming apparatus) is known. (Patent Document 1 etc.). In this type of image forming apparatus, a latent image formed on a photoconductor is developed with an image forming agent such as toner as in an electrophotographic process, and the developed image is transferred from the photoconductor to a recording paper or transfer body. The image is not directly transferred, but the flying image forming agent is attached to the recording paper or transfer body to directly form the image on the recording paper or transfer body.

  FIG. 17 is a configuration diagram illustrating an example of a main configuration of a conventional direct recording type image forming apparatus. In FIG. 17, a toner carrier 501 is disposed so that its axis extends in the left-right direction in the figure, and carries the charged toner T on its surface while being driven to rotate by a driving means (not shown). Under the toner carrier 501, a flexible printed circuit board (hereinafter referred to as FPC) 503 as a hole forming member for forming a plurality of holes 502 is disposed. The FPC 503 includes a plurality of ring-shaped flying electrodes 504 formed on the side facing the toner carrier 501 so as to surround each hole 502.

  Below the FPC 503, a counter electrode 506 that faces the toner carrier 501 through the FPC 503 and a recording paper 507 that is transported by the transport unit on the counter electrode 506 are disposed. In FIG. 17, for convenience, only one hole 502 and one flying electrode 504 are shown, but actually, a plurality of these combinations are formed in the FPC 503. Specifically, for example, in an FPC 503 for 600 dpi, 4960 combinations of these are formed.

The toner carrier 501 is provided with a plurality of electrodes 511 at predetermined intervals in the circumferential direction of the insulating support base. These electrodes 511 are formed by repeatedly arranging electrode pairs composed of two adjacent electrodes. An alternating electric field is formed between the two electrodes in each electrode pair. Then, the toner located on one electrode in the electrode pair floats and landes on the other electrode, or floats on the other electrode and landes on one electrode. By repeatedly performing such toner hopping, the toner carrier 501 carries, for example, the toner T charged in the negative polarity on the surface in a cloud state while being grounded. When a positive polarity flying voltage is applied to the flying electrode 504, the toner T floating near the surface of the toner carrier 501 at the position facing the flying electrode 504, or the toner T floating near the toner T An electric field of a predetermined strength acts on the Due to the action of this electric field, the toner T selectively flies from the toner carrier 501 and enters the hole 502. The toner T that has entered the hole 502 continues to fly by being attracted by the electric field formed by the counter electrode 506 to which a positive-polarity counter bias is applied, passes through the hole 502, and adheres to the surface of the recording paper 507. Dot image.
JP 59-181370 A

  Here, the alternating electric field is switched so that the toner located on one electrode floats and landes on the other electrode, or floats on the other electrode and landes on one electrode. When the toner hops by following, the toner hopping state is relatively uniform at any location on the toner carrier 501.

  However, if some of the toners cannot follow the switching of the alternating electric field, toners that have landed on the electrodes or toners that have not landed on the electrodes at the time of switching of the alternating electric fields are mixed, and the hopping state of the toner is disturbed. End up. Since the distribution of the toner that cannot follow the switching of the alternating electric field is different for each location on the toner carrier 501, the toner hopping state is different for each location on the toner carrier 501. As described above, if the toner hopping state varies depending on the location on the toner carrier 501, the toner density of the toner cloud formed by the toner hopping varies depending on the location on the toner carrier 501. . When the toner density in the toner cloud varies in this way, the amount of toner that flies from the toner carrier 501 and passes through each of the plurality of holes 502 formed in the FPC 503 is different for each of the plurality of holes 502. Therefore, the toner adhering amount of each dot pixel image formed corresponding to each of the plurality of holes 502 is fluctuated through the plurality of holes 502 and flying to the surface of the recording paper 507, and these dot pixel images are collected. There arises a problem that unevenness of image density occurs in the formed image.

  There is also known an image forming apparatus that does not hop toner so as to reciprocate between two electrodes but hops toner while moving the toner on the surface of the toner carrier in a certain direction. For example, in an image forming apparatus using a toner carrier in which three electrodes of A phase, B phase, and C phase are repeatedly arranged in that order, toner is transferred from the A phase electrode to the B phase on the surface of the toner carrier. The toner on the surface of the toner carrier is moved in a certain direction by sequentially hopping on the electrodes, from the B phase electrode to the C phase electrode, and from the C phase electrode to the A phase electrode. Even the image forming apparatus having such a configuration has the above-described problems.

  The present invention has been made in view of the above problems, and an object of the present invention is to suppress irregularities in the hopping state of the toner on the toner carrier and to cause image density unevenness in an image formed on the recording member. An object of the present invention is to provide an image forming apparatus that can be suppressed.

In order to achieve the above object, the invention according to claim 1 is directed to a toner carrier having a plurality of electrodes arranged at predetermined intervals along the surface of the support substrate, and carried on the surface of the toner carrier. Voltage applying means for applying an n-phase (n is 1 or more) alternating voltage to the plurality of electrodes so that an electric field for hopping the toner charged to a predetermined polarity is generated on the surface of the toner carrier; A hole forming member having a plurality of holes formed so as to face the toner carrier, and a surface of the hole forming member facing the toner carrier corresponding to each of the plurality of holes A plurality of flying electrodes provided on at least one of the periphery of the hole or the inner wall of the hole for forming an electric field for selectively flying toner from the toner carrier, and the toner carrier via the hole forming member Arranged to face each other, A counter electrode for forming an electric field that attracts toner flying from the toner carrier, and the toner selectively ejected from the toner carrier by forming the flying electric field based on image information, In the image forming apparatus that forms an image by being transferred to the counter electrode side through the hole and then depositing on the recording member, the voltage application unit intermittently applies the alternating voltage to the plurality of electrodes. It is characterized by comprising.
According to a second aspect of the present invention, in the image forming apparatus of the first aspect, the voltage applying means applies an alternating voltage having a period T1 a predetermined number of times m within a predetermined time T2, and T2> T1 × m. It is characterized by satisfying this relationship.
According to a third aspect of the present invention, in the image forming apparatus according to the first or second aspect, the n-phase alternating voltage applied between the plurality of electrodes of the toner carrier by the voltage applying means is the same timing and different. It is characterized by alternating in phases.
According to a fourth aspect of the present invention, in the image forming apparatus of the second aspect, at least one of the n-phase alternating voltages applied between the plurality of electrodes of the toner carrier by the voltage applying unit is the period. It is an alternating voltage of T1.
According to a fifth aspect of the present invention, in the image forming apparatus according to the first, second, third, or fourth aspect, the flying electrode is provided around the hole on the surface on the opposite side so as to correspond to each of the plurality of holes. A plurality of outer peripheral electrodes, and between the counter electrode and the outer peripheral electrode, the flying toner crosses the flying electrode from the outer peripheral electrode side to the counter electrode side through the hole. Thus, it is configured to form an electric field that shifts.
According to a sixth aspect of the present invention, in the image forming apparatus according to the fifth aspect, the outer peripheral electrode has a shape surrounding the outside of the flying electrode in a ring shape through an insulating region.
According to a seventh aspect of the present invention, in the image forming apparatus of the fifth aspect, the outer peripheral electrode is provided in a solid shape outside the flying electrode via an insulating region.
According to an eighth aspect of the present invention, in the image forming apparatus according to the fifth, sixth or seventh aspect, the outer peripheral electrode is provided on the same plane as the flying electrode via an insulating region. is there.
According to a ninth aspect of the present invention, in the image forming apparatus according to the first, second, third, fourth, fifth, sixth, seventh, or eighth aspect, the electrodes adjacent to the plurality of electrodes disposed on the surface of the toner carrier. A voltage having a relationship of alternately repeating the toner attracting direction and the repelling direction is applied by the voltage applying means, and the pitch between the two phases applied to the electrodes or the n-phase is applied to each n-th electrode. The phase voltage is applied.
The tenth aspect of the present invention is the image forming apparatus according to the first, second, third, fourth, fifth, sixth, seventh or eighth aspect, wherein an electrode adjacent to the plurality of electrodes disposed on the surface of the toner carrier is provided. A voltage having a relationship of alternately repeating the toner attracting direction and the repelling direction is applied by the voltage applying means, and the pitch between the two phases applied to the electrodes or the n-phase is applied to each n-th electrode. The distance between the surface of the toner carrier and the surface of the hole forming member on the toner carrier side is larger than the pitch between the n-phase electrodes when the phase voltage is applied.
The invention according to claim 11 is the image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10, wherein the recording member is recording paper, and the hole forming member is The counter electrode is provided at a position on the back side of the recording paper facing the toner carrier.
According to a twelfth aspect of the present invention, in the image forming apparatus of the first, second, third, fourth, fifth, sixth, seventh, eighth, ninth, or tenth aspect, the recording member is an intermediate transfer member, and the intermediate transfer member. The counter electrode is provided at a position on the back surface of the intermediate transfer member facing the toner carrier via itself or the hole forming member.
The invention according to claim 13 is the image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12, wherein the recording member is formed by superimposing different color toners. A color image is formed thereon.

  In the present invention, since the alternating voltage is intermittently applied to the plurality of electrodes by the voltage applying means, the toner hopping is intermittently performed, and the toner when the alternating voltage is not applied and the toner is not hopped is not supported by the toner. It is carried on the body. As a result, even if toner that cannot follow the switching of the alternating voltage appears, toner hopping is intermittently performed, so that the hopping start position can be aligned on the toner carrier when toner hopping is not performed. . Therefore, when the alternating voltage is next applied and toner hopping is started, the toner jumps from the toner carrier at any location on the toner carrier, and the alternating voltage is applied continuously. As a result, it is possible to prevent the toner hopping state from being disturbed at each location on the toner carrier. Accordingly, it is possible to prevent the toner density of the toner cloud formed by toner hopping from being scattered at each location on the toner carrier, and fly from the toner carrier and pass through each of the plurality of holes. Variations in the amount of toner can be suppressed. Therefore, the dispersion of the toner adhesion amount of each dot pixel image formed corresponding to each of the plurality of holes by flying through the plurality of holes to the surface of the recording member is suppressed, and these dot pixel images are formed together. It is possible to suppress the occurrence of uneven image density or the like in the processed image.

  As described above, according to the present invention, there is an excellent effect that it is possible to suppress the irregularity of the hopping state of the toner on the toner carrier and to suppress the occurrence of uneven image density in the image formed on the recording member.

Embodiments of the present invention will be described below with reference to the accompanying drawings. An embodiment of the present invention will be described with reference to the schematic configuration diagram of FIG.
In this embodiment, a toner carrier 1 in the form of a roller that carries toner T in a clouded state, a recording medium 3 to which the toner T is attached, and between the toner carrier 1 and the recording medium 3. And a toner control means 4 having a plurality of toner passage holes 41 arranged on the surface.

  The toner carrier 1 has a predetermined pitch formed along a direction (here, an axial direction) orthogonal to a direction in which the toner T is conveyed at a predetermined interval in the direction (here, the circumferential direction) in which the toner T is conveyed to the surface side. A pulse voltage (cloud pulse) having an average potential Vs having a different potential with time is applied from the voltage application means 5 to each electrode 11 of the toner carrier 1. This constitutes a means for converting the toner T into a cloud.

For example, a pulse voltage having a frequency of 0.5 [kHz] to 7 [kHz] is applied and the distance between the electrodes 11 and 11 is set at a fine pitch, so that a strong electric field is formed between the electrodes 11 and 11. The Therefore, the toner T flies vigorously from the surface of the electrode 11 at a potential repelling the charged polarity of the toner T, and the toner T that has flew is attracted to the electrode 11 to which the potential of the attracting polarity is applied, and a pulse is generated. By switching, the vertical flight according to the pulse frequency is repeated, and the toner T is in a cloud state. In the region where the frequency of the pulse is high, the toner T that has flew upward may change its pulse while flying, and may fly upward again before returning to the surface of the electrode 11.
In order to further stabilize the flying of the toner T, it is effective to apply a further adjusted pulse voltage. Details will be described later.

  The toner control means 4 is provided with a plurality of toner passage holes (openings) 41 through which the toner T can pass, and around the toner passage holes 41 on the toner supply side surface (surface on the toner carrier 1 side) of the toner control means 4. A control electrode 42 is provided in a ring shape, and a common electrode 43 common to the plurality of toner passage holes 41 is provided outside the control electrode 42 with respect to the toner passage hole 41 via an insulating region.

  For example, a control pulse Vc as shown in FIG. 3 is applied from the control pulse generating means 6 to the control electrode 42 of the toner control means 4. In this case, the voltage Vc-on is applied to the control electrode 42 when the toner T is allowed to pass through the toner passage hole 41 (ON state), and the control is performed when the toner T is not allowed to pass (OFF state). A voltage Vc-off is applied to the electrode 42. A voltage Vg is applied to the common electrode 43 from the power source 7. The control electrode 42 of the toner control means 4 can operate only around the toner passage hole 41, but on both the inner wall surface of the toner passage hole 41 or the inner wall surface of the toner passage hole 41 and the periphery on the toner carrier 1 side. It may be provided.

  On the recording medium 3 side, a back electrode as an electrode means serving as a bias voltage applying means to which a bias voltage for applying the toner T that has passed the toner control means 4 to the recording medium 3 is applied to the back surface of the recording medium 3. The bias voltage Vp from the bias power supply unit 8 is applied to attach the toner T that has passed through the toner control unit 4 to the recording medium 3. This recording medium 3 may be an intermediate transfer recording medium or recording paper on which an image is once formed and then transferred to paper. For the application of the bias voltage Vp to the recording medium 3, for example, a back electrode 31 is disposed on the back side (the side opposite to the toner carrier 1) of the recording medium 3 and the recording medium 3 is passed over the back electrode 31; Alternatively, in the case of an intermediate transfer recording medium, a configuration in which an electrode is embedded inside (a configuration in which an electrode on the recording medium side is used as an internal electrode) or a configuration in which a back electrode 31 is disposed on the back surface of the intermediate transfer recording medium can be employed.

  Here, as means for clouding the toner on the surface of the toner carrier 1, a plurality of electrodes 11 provided on the surface of the toner carrier 1 are provided, and a voltage Vs is applied to each electrode 11. At this time, a two-phase inter-electrode pitch p (or n is applied to each of the n electrodes 11 for applying a voltage that alternately repeats the direction of attracting and repelling the toner T between the adjacent electrodes 11. The distance d between the surface of the toner carrier 1 and the side surface of the toner carrier 1 of the toner control means 4 (meaning the surface on the toner carrier 1 side) is The toner carrier 1 and the toner control means 4 are arranged in a relationship of increasing (p <d).

  That is, in the relationship of p> d, the flying electric field formed on the surface of the electrode 11 of the toner carrier 1 causes interference with the ON / OFF electric field on the toner carrier 1 side surface of the toner controller 4, and the toner controller 4 described later. This is because the loop electric field is disturbed. Therefore, toner adhesion to the surface of the control electrode 42 is likely to occur. Under the condition of p <d, it is possible to reliably prevent the toner from adhering to the control electrode 42, and a good image can be obtained without changing the density even if continuous dots are printed.

Next, an example of a specific configuration of the toner control unit 4 will be described with reference to FIG. 4A is an explanatory view on the printing surface side of the toner control means, and FIG. 4B is an explanatory view of the toner supply side surface.
In this example, a ring-shaped control electrode 42 having a width of 10 to 100 [μm] is provided on the surface of the insulating substrate (base material) 45 on the toner supply side (toner carrier 1 side) so as to surround the toner passage hole 41. A bias common to the plurality of toner passage holes 41 on the same surface as the control electrode 42 at an interval of 20 to 50 [μm] from the control electrode 42, that is, through an insulating region formed by the insulating substrate 45. In this configuration, a common electrode 43 for applying the voltage Vg is provided.

  The toner passage hole 41 has a diameter of φ30 [μm] to φ150 [μm], which is determined by the size of the dot diameter to be formed. The control electrode 42 is connected to a lead pattern 42a for connection to a driver circuit (drive circuit) for controlling ON / OFF of the passage of the toner T, and the common electrode 43 is connected to a common lead pattern 43a. Yes. Further, the toner passing hole 41 is opened on the printing surface side (the surface on the recording medium 3 side) of the insulating substrate 45.

  As described above, the common electrode 43 of the toner control unit 4 is configured to surround the outside of the control electrode 42 in a ring shape through the insulating region, so that the bias potential on the recording medium side and the outside of the control electrode 42 are Since the electric force formed between the common electrodes 43 can be formed as an independent line of electric force for each toner passage hole, mutual interference (multiple other toner passage holes) at the time of multi-drive (driving the toner from a plurality of toner passage holes) Will not occur).

  Further, by forming the control electrode 42 and the common electrode 43 of the toner control means 4 on the same surface, they can be formed simultaneously in a single manufacturing process, and the electrodes can be made with high accuracy and at low cost.

Another example of the specific configuration of the toner control unit 4 will be described with reference to FIG. 5A is an explanatory view of the toner control unit 4 on the printing surface side, and FIG. 5B is an explanatory view of the toner supply side surface.
In this example, a ring-shaped control electrode 42 having a width of 10 to 100 [μm] is provided on the surface of the insulating substrate (base material) 45 on the toner supply side (toner carrier 1 side) so as to surround the toner passage hole 41. A common electrode 43 for applying a common bias voltage Vg to the plurality of toner passing holes 41 is provided in a solid shape so as to cover the entire space with an interval of an insulating region of 20 to 50 [μm] from the control electrode 42. The configuration is as follows.

  As described above, the common electrode 43 of the toner control unit 4 is configured to be solid on the outside of the control electrode 42 via the insulating region, that is, the common electrode 43 is formed over the entire outer region of the control electrode 42. As a result, the electric field of the bias potential on the recording medium side can be shielded, toner adhesion to the control electrode 42 can be reduced, and toner utilization efficiency can be improved.

  A specific method for manufacturing the toner control unit 4 is an insulating member serving as the insulating substrate 45, which is a resin film, for example, polyimide, PET, PEN, PES, etc. in terms of cost and manufacturing process, and has a thickness of 30. [Μm] to 100 [μm] is used, and an Al deposited film of 0.2 [μm] to 1 [μm] is first formed on the film surface. Next, in the photolithography process, after applying a photoresist with a spinner, pre-baking and mask exposure are performed, development is performed, and after the photoresist is heated and cured, Al patterning is performed with an Al etching solution. If an electrode pattern is also required on the back side of the film, it is possible in the same manner as described above, but a pattern used as a mask for hole processing may be formed on the back side. The formation of the through-hole serving as the toner passage hole 41 is caused by positional displacement according to mechanical processing by pressing after pattern formation, excimer laser processing using a pattern formed on the back surface, or dry etching processing such as sputter etching processing. High-accuracy drilling can be performed.

  In the image forming apparatus configured as described above, by applying a pulse voltage of the average potential Vs to the electrode 11 of the toner carrier 1, the toner T flies over the toner carrier 1 to be clouded, and the toner The toner T is transported by the rotation of the carrier 1 or by the traveling wave electric field. On the other hand, the printing bias voltage Vp is applied to the back electrode 31 on the recording medium 3 side.

  In this state, when the voltage Vg is applied to the common electrode 43 of the toner control means 4 so that the toner T can pass through the toner passage hole 41 with respect to the control electrode 42 (ON state), it is shown in FIG. When the voltage Vc-on at the time of ON is applied and the toner T enters a state where it cannot pass through the toner passage hole 41 (OFF state), the voltage Vc-off at the time of OFF shown in FIG. 3 is applied.

  In this case, the voltages for these electrodes 11, 31, 42, 43 are set as will be described later so that the toner T of the toner carrier 1 can pass through the toner carrier 1 toward the recording medium 3. In this case, the electric force lines 10 are formed in a loop shape around the control electrode 42 that controls the passage of toner between the recording medium 3 side and the common electrode 43 of the toner control means 4.

  As a result, the clouded toner on the toner carrier 1 rides on the electric field generated by the electric force lines 10 and passes through the toner passage hole 41 of the toner control unit 4 and lands on the recording medium 3. Therefore, a toner image can be directly formed on the recording medium 3 by performing ON / OFF control (open / close control) of each toner passage hole 41 of the toner control unit 4 according to the image. Since the electric lines of force 10 are formed in a loop shape around the control electrode 42 that controls the passage of toner between the recording medium 3 side and the common electrode 43 of the toner control means 4, Toner adhesion to the periphery of the toner passage hole 41 is reduced, and the use efficiency of the toner is improved by making the toner cloud.

  Therefore, the average potential Vs of the pulse voltage for the electrode 11 of the toner carrier 1, the bias voltage Vp on the recording medium 3 side, the control pulse voltage Vc for the control electrode 42 of the toner control means 4, and the voltage Vg for the common electrode 43 are shown in FIG. Will also be described. FIG. 6 is an explanatory diagram showing electric lines of force that pass through the toner passage holes based on the simulation results of the two-dimensional cross-sectional electric field intensity distribution of the toner carrier 1, the toner control unit 4, and the recording medium 3.

  A pulse voltage having an average potential Vs (a potential at which the potential varies with time) is applied to the electrode 11 of the toner carrier 1. In this case, the peak value of the bias voltage is set according to the electrode pitch, the toner to be used, and the like. For example, it is preferable to set within a range of ± 60 to ± 300 Vpp (pp is peak-peak), and here, a voltage of ± 150 Vpp and a DC voltage component 0 [V] is applied. Therefore, the DC bias on the toner carrier 1 side with respect to the toner control unit 4 is 0 [V], and the average potential Vs = 0 [V]. The distance d between the toner carrier 1 and the toner control means 4 is 0.3 [mm].

  Further, in this example, the diameter φ100 [μm] of the toner passage hole 41 of the toner control means 4, the width of the ring-shaped control electrode 42 in the center direction of the hole is 30 [μm], and the distance between the control electrodes 42 and the common electrode 43 is 50 [μm].

  The bias Vg to the common electrode 43 of the toner control means 4 is DC-125 [V], and the relationship with the average potential Vs of the pulse voltage to the toner carrier 1 always directs the toner T to the toner carrier 1 side. Due to the directional bias, no toner adheres to the surface of the common electrode 43.

  When the toner T is in a state (ON state) in which the toner T can pass through the toner passage hole 41, the control pulse voltage Vc-on is +50 [V] and the toner T is passed through the control electrode 42 of the toner control unit 4. The voltage Vc-off in the blocking state other than the time (to make it impossible to pass) is set to -125 [V]. Although the bias voltage Vp to the back electrode 31 of the recording medium 3 depends on the interval between the toner control means 4 and the recording medium 3, for example, a DC voltage of +200 to +1500 [V] may be applied. Here, DC + 300 [V] is applied as an interval of 0.3 [mm] between the toner control unit 4 and the recording medium 3, and a potential gradient that draws negatively charged toner to the surface of the recording medium 3 is set.

  By setting the relationship between the potentials applied to the electrodes 11, 42, 43, and 31 as described above, when the toner charged negatively is allowed to pass through the toner passage hole 41, the most positive side is set. Of the electric lines of force generated from the back electrode 31 on the side of the recording medium 3 having a high potential, most of the electric lines of force passing through the toner passage hole 41 of the toner control means 4 pass through the toner passage hole 41 and then have the highest potential. The low common electrode 43 is entered. At this time, since the control electrode 42 and the common electrode 43 of the toner control unit 4 located at close distances also have a potential of 175 V, strong lines of electric force are generated between them.

  For this reason, as shown in FIG. 6A, when the toner T is allowed to pass through the toner passage hole 41 (ON state), the electricity passing through the toner passage hole 41 from the rear electrode 31 on the recording medium 3 side. The force line 10 does not enter the control electrode 42 (bypassing the control electrode 42), and most of the force line 10 enters the common electrode 43 having the lowest potential of −125 [V]. That is, the electric lines of force 10 are formed in a loop shape around the control electrode 42 between the recording medium 3 side and the common electrode 43 of the toner control means 4.

  Therefore, the negatively charged toner T in the cloud state on the toner carrier 1 passes through the toner passage hole 41 along the electric force lines 10, and a lot of toner T can move to the surface of the recording medium 3.

  At this time, +50 [V] is applied to the control electrode 42, and the relationship between the toner carrier 1 and 0 [V] is the relationship in which the toner T is attracted to the control electrode 42. While the toner is supposed to adhere to the surface of the control electrode 42 while V] is applied, as can be seen from the simulation result of FIG. 6A, above the control electrode 42 to which +50 [V] is applied. Is covered by the lines of electric force 10 entering the common electrode 43 from the recording medium 3 side electrode through the toner passage hole 41, so that the toner T is prevented from adhering to the control electrode 42.

  On the other hand, when the toner T enters a blocking state (OFF state) in which the toner cannot pass through the toner passage hole 41, −125 [V] is applied to the control electrode 42, which is the same potential as the potential with respect to the common electrode 43. The relationship with the potential 0 [V] of the carrier 1 is a relationship in which the toner T is repelled toward the toner carrier 1, and the toner T does not adhere to the toner control means 4, and as shown in FIG. Further, since there is no electric force line through which the electric force from the recording medium 3 side electrode passes through the toner passage hole 41, the toner T does not pass through the toner passage hole 41, and a background image is not generated. Note that the voltage applied to the control electrode 42 in the blocking state (OFF state) does not have to be the same as the potential of the common electrode 43, and even if the potential is more negative, the toner T is blocked from passing (OFF state). Can).

  As described above, the toner carrying body 1 that carries the toner in a clouded manner, the recording medium to which the toner is attached, and the plurality of toner passage holes arranged between the toner carrying body 1 and the recording medium are provided. Toner control means 4, and the toner control means 4 is provided with a control electrode 42 for controlling the passage of the toner on at least one of the periphery of the toner passage hole and the inner wall of the hole on the surface of the toner carrier 1. When a common electrode 43 common to a plurality of toner passage holes is provided outside the control electrode 42 and the toner passage hole of the toner control means 4 is in a state where the toner on the toner carrier 1 can pass toward the recording medium, A control line is formed between the recording medium side and the common electrode 43 of the toner control means 4 so as to bypass the control electrode 42 and form a line of electric force in a loop. 42 can greatly reduce the adhesion of toner to the surface and its surroundings, and can stably control the on / off of the passage of toner, and between the bias potential on the recording medium side and the common electrode 43 outside the control electrode 42. The lines of electric force formed on the toner carrier 1 are larger than the diameter of the toner passage hole on the toner carrier 1 side, so that the clouded toner can be captured in a wide range and fly toward the printing surface side. The use efficiency of the printer can be improved, the printing density can be ensured, and the printing speed can be improved.

  Further, regarding the relationship of the potential applied to each electrode, the DC bias of the electrode 11 of the toner carrier 1 is −50 [V], the pulse peak value is +150 [V] to −150 [V], and ± 150 Vpp−50 When [V] DC is applied, the average potential Vs becomes −50 [V]. Even if the potential Vc-on of the control electrode 42 of the toner control means 4 when the toner passage is ON is 0 V and the potential Vc-off when the toner passage is OFF is -175 [V], it is equivalent to the above-described example. . In this case, since the voltage Vc applied to the control electrode 42 is ON or OFF with a unipolar voltage of 0 to -175 [V], the configuration of the driver circuit is simplified, which is advantageous in terms of cost.

  As described above, the relationship between the potentials applied to the respective electrodes when the toner passage is ON is set as follows, so that the control electrode 42 is provided between the recording medium side and the common electrode 43 of the toner control unit 4. The electric lines of force can be formed in a loop shape by bypassing.

  That is, when a pulse voltage having an average potential Vs that varies with time is applied to the electrode 11 of the toner carrying member 1 so that the toner can pass through the toner passage hole 41 with respect to the control electrode 42 of the toner control means 4. And the voltage Vc-off is applied when the toner cannot pass through the toner passage hole 41, the voltage Vg is applied to the common electrode 43, and the toner that has passed through the toner control means 4 is removed. When a bias voltage Vp is applied to the recording medium 3 in order to guide the recording medium 3 to adhere toner, the relationship between the potentials when the toner is allowed to pass through the toner passage hole 41 is expressed as Vp> Vc−. On> Vs> Vg, and when the toner is a negatively charged toner, the bias voltage Vp is increased to the positive potential side. When the toner is a positively charged toner, the bias voltage Vp is increased to the negative potential side. It is a constant.

  In this case, the relationship between the potentials when the toner cannot pass through the toner passage hole 41 is Vs> Vg and Vs> Vc−off, and the toner is negatively charged toner. In this case, it is preferable that the average potential Vs be increased to the positive potential side. In the case of positively charged toner, the average potential Vs is preferably increased to the negative potential side.

  By setting the potential relationship with respect to each electrode 11, 42, 43, 31 to the above-described relationship, the lines of electric force directly formed between the bias potential on the recording medium side and the potential of the toner carrier 1 are reduced, and recording is performed. An electric force can be formed between the bias potential on the medium side and the common electrode 43 outside the control electrode 42, thereby greatly reducing toner adhesion to the control electrode 42 to which a potential for attracting toner is applied. The control potential is stabilized. In addition, since the electric lines of force formed between the bias potential on the recording medium side and the common electrode 43 outside the control electrode 42 are larger than the diameter of the toner passage hole on the toner supply side, the clouded toner is captured in a wide range. As a result, it is possible to fly toward the printing surface side, the use efficiency of the toner can be improved, the printing density can be ensured, and the printing speed can be improved. Further, since the common electrode 43 of the toner control unit 4 is at a potential that always repels the toner, toner adhesion does not occur, and the potential of the common electrode 43 can be kept constant, and the reliability is high. An image forming apparatus can be realized.

  Furthermore, when the amount of toner on the surface of the toner carrier 1 is increased due to high-speed printing, or when printing is performed using a toner having a large charge amount, the toner potential due to the charge of the toner cannot be ignored. Consideration must be made in determining the potential applied to each electrode.

More specifically, the change in toner potential with respect to the supplied toner amount [m / Am] ([g / cm ² ) on the surface of the toner carrier 1 is as shown in FIG. Here, the toner is an example of a negatively charged toner, and as the amount of toner per unit area on the surface of the toner carrier 1 increases, the surface potential viewed from the control electrode 42 side increases to a negative potential. Then, a voltage is applied to the electrode on the surface of the toner carrier 1 with respect to the potential Vo where the supplied toner is simply attached to the surface of the toner carrier 1, and the toner moves up and down along the lines of electric force between the electrodes 11. The potential Vt in the cloud state where the flight repeats greatly increases. This is because when the toner is in a space above the surface of the toner carrier 1, the coupling capacitance with respect to the periphery of the individual toner is reduced, and as a result, the potential is increased.

  The measurement of the toner potential Vt in the cloud state can be easily performed by applying a pulse voltage to each electrode 11 on the surface of the toner carrier 1 and setting the surface potential meter above the supplied toner in the cloud state. Can be measured. Specifically, the toner control unit applies a pulse that causes clouding, rotates the toner carrier 1 while supplying toner from a one-component or two-component roller, which will be described later, or conveys the toner with a traveling wave pulse, and controls toner In the position where 4 is set, the surface potential meter is installed about 2 [mm] above the surface of the toner carrier 1 and measured. The result of FIG. 7 is that Vo when the toner having a charged charge amount of −15 to −25 [μC / g] is supplied, and the toner is in a cloud state in the range of flying height of 200 [μm] from the vicinity of the surface. This is an example in the case of the toner potential Vt.

The amount of toner adhering to the surfaces of the control electrode 42 and the common electrode 43 of the toner control unit 4 as a result of printing by performing ON / OFF control of the passage of toner by the toner control unit 4 for each supply toner amount shown in FIG. FIG. 8 shows the result of the evaluation. In the result of FIG. 8, in the region where the supplied toner amount is small, the toner does not adhere to the control electrode 42 and the common electrode 43, but the supplied toner amount increases and the toner potential Vt is 0.9 [mg / cm ² ]. −80 [V], and toner adhesion to the control electrode 42 begins to occur.

  This is because, as a result, the potential of the toner carrier 1 is increased to the negative side and the potential difference with the common electrode 43 of the toner control means 4 is reduced, so that the toner passing hole 41 exits from the recording medium 3 side electrode. This is because, among the passing electric force lines, the electric force lines directly entering the toner carrier 1 are increased, and the loop-shaped electric force lines entering the common electrode 43 are decreased. That is, when the number of loop electric lines of force decreases, toner having high flying energy rides on the loop electric lines of force and does not fly in the direction of the printing surface, but jumps to the control electrode 42 to which the ON voltage is applied. It is to do.

Further, when the supplied toner amount increases and exceeds 1.2 [mg / cm ² ], the toner potential Vt becomes a value of −120 [V] or more. In this region, the potential difference from the bias potential Vg (−125 [V]) of the common electrode 43 of the toner control means 4 disappears, and the toner having flying energy starts to reach the common electrode 43 and the toner adheres. . In addition, the amount of toner attached to the control electrode 42 also increases.

  These toner adhesions are not unusable by increasing the frequency of periodic electrode cleaning, but image quality deteriorates. As long as toner adhesion does not occur, a highly reliable image recording apparatus can be achieved without decreasing image density even in continuous printing.

  Therefore, when the amount of toner is large, or when an image is formed using toner with a large amount of charged charge, the potential for each electrode is set under the following conditions to avoid toner adhesion to the electrode and use of toner High efficiency enables high-speed printing without lowering image density.

  That is, when the toner potential seen from the side of the control electrode 42 in the cloud state where the charged toner flies from the surface of the toner carrier 1 is Vt (the other conditions are the same as above), the toner passage is turned on. Vp> Vc-on> (Vs + Vt)> Vg, Vp is higher on the positive potential side in the case of negatively charged toner, and Vp is higher on the negative potential side in the case of positively charged toner. Set.

  The relationship between the potentials when the toner passage is turned off is (Vs + Vt)> Vg, and (Vs + Vt)> Vc−off, and in the case of negatively charged toner, (Vs + Vt) is higher on the positive potential side. In the case of positively charged toner, the relationship is set such that (Vs + Vt) increases to the negative potential side.

  The potentials for the electrodes 11, 42, 43, and 31 are set as described above. That is, the potentials on the toner supply side are appropriately set in consideration of the potential due to the toner flying on the surface of the toner carrier 1. With this setting, even when the amount of supplied toner is fast and the charge amount of the toner is large, the toner adhesion to the control electrode 42 and the like can be reduced and the toner utilization efficiency can be improved. Thus, an image forming apparatus for high-speed printing can be realized. In this case, even when the toner is not clouded (no pulse is applied), the toner is not attached to the control electrode 42 or the like by setting the above-described potential relationship, so that the reliability is improved.

  In the above example, the condition in which the cloud pulse is applied to the plurality of electrodes on the surface of the toner carrier 1 and the toner is in the cloud state has been described. However, from the control electrode 42 side where the toner is not flying. By setting the same condition as above when the potential due to the observed toner is Vt, there is an effect of avoiding toner adhesion to the electrode. That is, even when the application of the cloud pulse is turned off and there is no toner cloud, a slight amount of toner is floating. Although the slight potential of the floating toner is negligible, there is a toner potential that is landed on the surface of the toner carrying member 1, and (Vs + Vt) in consideration of this potential Vt is also set within the same range as described above. The same effect can be obtained.

  As described above, in the present embodiment, when the toner on the surface of the toner carrier 1 is hopped into a cloud, a temporally varying voltage is applied to the plurality of electrodes 11 of the toner carrier 1. For example, the toner is supplied from the toner carrier 1 having a plurality of electrodes 11 provided at a predetermined pitch in the direction orthogonal to the direction in which the toner is conveyed on the surface of the toner carrier 1 that conveys and supplies the toner. Here, when the common electrode 43 of the toner control unit 4 is not provided or when the potential setting for each of the electrodes 11, 42, 43, and 31 is not within the above-described range, the toner adheres to the control electrode 42. A decrease in the reliability of toner flight control such as rapid occurrence is unavoidable. In addition, since the use efficiency of the clouded toner is greatly reduced, it is difficult to ensure image density and perform high-speed printing.

  Even when the toner on the surface of the toner carrier 1 is sufficiently crowded and activated, a good image is not necessarily obtained as an image formed by collecting dots printed from each toner passage hole 41. There is a case. In order to investigate the cause, the cloud state of the toner was observed with a high-speed camera. Vmax and p which are voltages applied to the electrode 11 of the toner carrier 1 were fixed under sufficiently activated conditions, and the frequency of the applied voltage (alternating voltage) was changed. When the frequency of the alternating voltage applied to the electrode 11 is low, the toner on the electrode 11 is lifted by the voltage switching and repeatedly moves on the adjacent electrode 11, and the toner hopping state is relatively uniform. When the frequency of the alternating voltage applied to the electrode 11 is set to a higher frequency, the toner moves up from the electrode 11 and adheres to the neighboring electrode 11 due to the switching of the voltage, but at the next voltage switching. It was observed that a part of the flying toner was in a state before adhering to the neighboring electrode 11, and could not follow the next voltage switching, and the toner hopping state was disturbed. In addition, since the condition that the toner hopping state is disturbed and the condition that the dots printed on the recording medium 3 are likely to be disturbed coincide with each other, the toner carrier 1 is subjected to the condition that the toner hopping state is disturbed. The presence of toner that is not sufficiently controlled in the electric field for hopping the toner between the electrodes is considered to contribute to the instability of the printed dots.

  In other words, when some toner cannot follow the switching of the alternating electric field between the electrodes, the toner that has landed on the electrode 11 or the toner that has not landed on the electrode 11 at the time of switching the alternating electric field is mixed. The hopping state is disturbed. Since the distribution of the toner that cannot follow the switching of the alternating electric field is different for each location on the toner carrier 1, the toner hopping state is different for each location on the toner carrier 1. As described above, when the hopping state of the toner is different at each location on the toner carrier 1, the toner density (cloud density) of the toner cloud formed by the hopping of the toner is different at each location on the toner carrier 1. It will vary. When the toner density of the toner cloud varies as described above, the amount of toner flying from the toner carrier 1 and passing through each of the plurality of toner passage holes 41 formed in the insulating substrate 45 is the plurality of toner passage holes 41. Will be different. For this reason, the toner adhering amount of each dot pixel image formed corresponding to each of the plurality of toner passage holes 41 varies by passing through each of the plurality of toner passage holes 41 and flying to the surface of the recording medium 3. There arises a problem that image density unevenness occurs in an image formed by collecting images.

  Therefore, in the present embodiment, an alternating voltage is intermittently applied to the electrode 11 of the toner carrier 1 by the voltage application means 5. As described above, the alternating voltage is intermittently applied to the plurality of electrodes 11 by the voltage applying means 5, so that the toner when the alternating voltage is not applied to the plurality of electrodes 11 and hopping is not performed is used as the toner carrier 1. Supported on. As a result, even when toner that cannot follow the switching of the alternating voltage appears, the toner hopping is intermittently performed, so that the toner hopping start position can be set at any location on the toner carrier 1. Can be on top. Therefore, when the alternating voltage is applied next and toner hopping is started, the toner jumps from the toner carrier 1 at any location on the toner carrier 1, and the alternating voltage is continuously applied. It is possible to prevent the toner hopping state from being disturbed at each location on the toner carrier 1 than when the toner is carried. Therefore, it is possible to prevent the toner density of the toner cloud formed by toner hopping from being scattered at each location on the toner carrier 1, and the toner cloud 1 can fly from the toner carrier 1 and have a plurality of toner passage holes 41. Variations in the amount of toner passing through each can be suppressed. That is, as shown in FIG. 6A, when toner passes on, the control electrode 42 is bypassed (stranded) between the recording medium 3 side and the common electrode 43 of the toner control means 4, and the electric force is looped. Since the line 10 is formed, the toner in the vicinity of the loop-shaped electric force line 10 receives a force toward the recording medium 3 through the toner passage hole 41. At this time, a stable toner cloud is generated in a region that receives a force from the electric force line 10 between the toner carrier 1 and the insulating substrate 45 (toner control means 4) through the toner passage hole 41 toward the recording medium 3 side. If there is, a stable amount of toner passes through the toner passage hole 41 along the electric force line 10 from the toner carrier 1 side and is printed on the recording medium 3. Therefore, the toner adhering amount of each dot pixel image formed corresponding to each of the plurality of toner passage holes 41 through the plurality of toner passage holes 41 and flying to the surface of the recording medium 3 is suppressed. It is possible to suppress image density unevenness in an image formed by collecting pixel images.

  In addition, the printed image density is easily obtained as the applied voltage is switched more frequently. If the alternating voltage applied to the electrode 11 is simply set to a low frequency, it is difficult to obtain a sufficient image density. Therefore, in order to obtain a good image, it becomes a problem to achieve both control of the hopping state of the toner and image density.

  In the present embodiment, in order to solve the above-described problem, voltages as shown in FIG. 1 are applied in two phases (A phase and B phase). This voltage is obtained by repeating the application of alternating the alternating voltage of the cycle T1 m times in the cycle T2. First, the alternating voltage of the cycle T1 is first applied m times continuously within a predetermined time indicated by the cycle T2. In the remaining time after the m times of voltage application, the voltage application of the alternating voltage of the period T1 is not performed. As described above, in this embodiment, there is a time during which the alternating voltage for hopping the toner is not applied to the electrode 11 within the predetermined time T2. Therefore, such voltage application is performed every T2, in other words, the alternating voltage of the period T1 is intermittently performed, so that the toner hopping state is settled and the toner hopping state is prevented from being uncontrolled. be able to. As a result, as can be seen from the experimental results to be described later, it is possible to appropriately control the cloud state of the toner by applying the alternating voltage of the cycle T1 for a predetermined number of times m every predetermined time T2. The desired image density can be obtained by applying the alternating voltage of the period T1 to the electrode 11 repeatedly m times.

  FIG. 9 shows an example of an alternating voltage applied to the electrode 11 of the toner carrier 1. The A phase is a voltage in which the pulses of the cycle T2 with the cycle T1 alternate m times, and the B phase is a voltage that alternates with the cycle T1 in the opposite phase to the A1 phase T1. Even when such a voltage is applied to the electrode 11 of the toner carrier 1, the toner cloud is stabilized, and a sufficient cloud density is obtained and the image density is obtained by m alternating times.

Next, an example of the image forming apparatus according to the present invention will be described with reference to FIG. FIG. 10 is a schematic configuration diagram of the image forming apparatus.
In this image forming apparatus, four units of the above-described embodiment are provided to form a cloud of toner for four colors of yellow (Y), magenta (M), cyan (C), and black (K), and toner control unit 104. 2 is an example of an image forming apparatus that forms a color image by performing ON / OFF control according to FIG.

  That is, this image forming apparatus supplies toner for four colors of yellow (Y), magenta (M), cyan (C), and black (K) in a cloud form along the intermediate transfer member 103 as a recording medium. 4 toner supply units 100y, 101m, 101c, and 101k (referred to as “toner supply unit 100” when colors are not distinguished from each other; the same shall apply hereinafter) are arranged between each toner supply unit 100 and the intermediate transfer member 103. Further, a toner control unit 104 having the same configuration as the toner control unit 4 of the above-described embodiment is disposed.

  Here, the intermediate transfer member 103 is wound around the two rollers 132 and 133 and moves in the direction indicated by the arrow. A back electrode 131 which is a recording medium side electrode is disposed on the back surface (inside) of the intermediate transfer member 103 corresponding to each toner supply unit 100. Further, a cleaning unit 135 for removing residual toner on the intermediate transfer member 103 after transfer is provided.

  The toner supply unit 100 includes a cylindrical toner carrier 101 having a configuration similar to that of the toner carrier 1 in which a plurality of electrodes 111 for applying a voltage for arranging the toner into a cloud are arranged side by side. A rotating toner supply roller 113 for supplying toner, and a blade 114 for regulating the amount of toner on the toner carrier 101.

  Here, toner is replenished from the toner replenishing roller 113 to the toner carrier 101 and frictional charging of the toner is performed by friction between the toner on the toner replenishing roller 113 and the toner carrier 101. The blade 114 on the downstream side of the toner replenishing roller 113 keeps the toner amount on the surface of the toner carrying member 101 constant by a thin layer and stabilizes the toner charge amount.

  Then, the toner supplied by the toner supply unit 100 is turned on / off according to the image by the toner control unit 104, so that it flies onto the intermediate transfer member 103, and a color toner image is formed on the intermediate transfer member 103. Is done.

  On the other hand, a paper feeding unit 105 that accommodates the recording paper 150 is disposed below, and the recording paper 150 is fed from the paper feeding unit 105 by the pickup roller (paper feeding roller) 106 and the intermediate transfer member 103 is wound around the roller. The toner image on the intermediate transfer member 103 is transferred by the transfer roller 107 disposed so as to be opposed to 132, and the toner is melt-fixed on the recording paper 150 by the fixing unit 108 and discharged.

  Although not shown here, the toner image is transferred from the intermediate transfer member 103 to the surface of the recording paper 150 by applying a + bias to the transfer roller 107 on the back side of the recording paper 150. Further, as described above, the intermediate transfer member 103 is cleaned with the remaining toner by the cleaning unit 135, and the next image formation is performed.

  As described above, this image forming apparatus is an intermediate transfer recording method in which a four-color image is formed on an intermediate transfer recording body and then transferred to a recording sheet supplied from a paper feeding unit. In the case of this intermediate transfer recording method, it is easy to ensure the accuracy of keeping a constant distance between the printing surface (the surface on which the toner lands and the image forming surface) and the toner control means 104, and the toner flying speed is low. High image quality can be achieved under certain conditions. In addition, an image forming apparatus that prints directly with ON / OFF of the passage of the clouded toner can obtain a printing surface that is smooth and does not accumulate charges by adjusting the volume resistivity, and has no potential fluctuation, and has high sensitivity to potential, Although image quality fluctuations are likely to occur with respect to fluctuations in the printing surface bias potential, this configuration makes it possible to obtain a reliable and high-quality color image.

Next, another example of the image forming apparatus according to the present invention will be described with reference to FIG. FIG. 11 is a schematic configuration diagram of the image forming apparatus.
This image forming apparatus is an example in which an image is directly formed on a recording sheet using a recording medium as a recording sheet. That is, here, the recording paper 150 supplied from the paper supply unit 105 is electrostatically attracted to the paper transport belt 161 and passed through the area of the toner supply unit 100, and ON / OFF according to the image of the toner control unit 104. A color image is directly formed on the recording paper 150 by the OFF control.

  The paper transport belt 161 is formed of polyimide or the like, is wound around two rollers 162 and 163, moves around in the direction of the arrow, and is charged by a charging unit such as a charging roller (not shown), thereby being recorded on the recording paper 150. Are electrostatically attracted and transported. A guide 164 and a registration roller 165 for guiding the recording paper 150 from the paper supply unit 105 to the paper transport belt 161 are also arranged.

  In this configuration, there is a paper transport belt 161 such as polyimide and the recording paper 150 between the toner control means 104 that controls the passage of toner and the back electrode 131 that applies a bias for guiding the toner after passing to the recording paper 150. However, it is difficult to set the distance between the toner control unit 104 and the back electrode 131 very narrow, but on the other hand, since a color image is formed directly on the recording paper 150 and there is no transfer process, the image quality deteriorates due to toner scattering due to transfer. Nothing will happen.

  Further, the belt cleaning mechanism as in the configuration described with reference to FIG. 10 is not necessary, which is advantageous for realizing a small and low-cost image forming apparatus. In this configuration where the toner is made into a cloud, it is possible to guide the toner by setting the printing surface bias low, so that the landing speed of the toner on the paper surface can also be set low, and a high quality image that does not cause toner scattering. A forming device can be obtained.

Next, an example of the toner carrier 101 used in the above-described image forming apparatus will be described with reference to FIG. 12A is a schematic plan view illustrating the toner carrier 101 in a developed state, and FIG. 12B is a schematic cross-sectional view illustrating the same.
In this example, a plurality of electrodes are provided on the surface of the toner carrying member 101, two pairs of electrodes for every other pair are provided in common, and two-phase pulses having different phases of 180 [°] (see FIG. 1) are applied. This is an example of the toner carrier 101 that forms a two-phase electric field that repeats suction and repulsion between adjacent electrodes.

  This toner carrier 101 is provided with an A-phase electrode 111A and a B-phase electrode 111B as a plurality of electrodes 111 on the surface of an insulating substrate 101A, and a surface protective layer 101B provided thereon. . Comb-like electrodes 111A and 111B are provided in parallel at a fine pitch in a direction orthogonal to the toner transport direction, and both sides are connected to an external two-phase pulse generation circuit (not shown) by common bus lines 111Aa and 111Ba, respectively. It is connected.

  The pulse voltage applied to the electrodes 111A and 111B is a pulse voltage having a frequency of 0.5 [kHz] to 7 [kHz] and including a DC voltage as a bias, and its peak value is ± 60 to ± 300 [V], etc. A pulse voltage corresponding to the electrode width and electrode interval is applied. In the case of this two-phase electric field, toner repulsion flight and suction flight are repeated according to switching of the electric field direction between adjacent ones, and the toner reciprocates between the mutual electrodes. The entire toner carrier 101 rotates in the direction in which the toner is conveyed.

  As described above, the means for flying the toner on the surface of the toner carrying member 101 to form a cloud extends on the surface of the toner carrying member 101 in a direction perpendicular to the toner transport direction and is arranged at a predetermined interval. The voltage applied to each electrode is a voltage having a relationship that alternately repeats the direction of attracting and repelling toner between adjacent electrodes, and the toner carrier 101 rotates to move the toner. And the clouding configuration, the toner transport on the surface of the toner carrier 101 can be stably transported regardless of the toner charging quality, and the image forming apparatus with high reliability can be obtained as a whole. realizable.

Next, another example of the toner carrier 101 used in the above-described image forming apparatus will be described with reference to FIG. FIG. 13A is a schematic plan view illustrating the toner carrier 101 in a developed state, and FIG. 13B is a schematic cross-sectional view illustrating the same.
This example is an example of the toner carrier 101 that forms a three-phase traveling wave electric field. The A-phase and B-phase electrodes 111A and 111B are formed on the insulating substrate 101A, the insulating layer 101C is formed thereon, and then the C-phase electrode 111C is formed. The surface protective layer 101B is provided on the C-phase electrode 111C. ing.

  Each ABC 3-phase electrode 111A, 111B, 111C is provided in parallel at a fine pitch in a direction orthogonal to the toner conveyance direction, and external buses 111Aa, 111Ba, 111Ca are provided on both sides by a common 3-phase pulse (not shown). Each is connected to a generator circuit.

  In the case of using this three-phase traveling wave electric field, as shown in FIG. 14, by sequentially applying a pulse voltage whose phase is shifted by 120 [°] in one cycle, the surface of the toner carrier 101 is changed with the switching of the pulse. In this case, a traveling wave electric field that sequentially shifts the electric field is generated, and the charged toner is transported at the same time as it repeatedly flies upward in the direction in which the electric field switches, so that the toner carrier 101 basically remains stationary without rotating. .

  As described above, the means for flying the toner on the surface of the toner carrying member 101 to form a cloud extends on the surface of the toner carrying member 101 in a direction perpendicular to the toner transport direction and is arranged at a predetermined interval. A toner carrier by applying a n-phase phase voltage to each n electrodes and forming a traveling wave electric field between the electrodes, thereby carrying the toner and forming a cloud. With respect to the toner conveyance on the surface 101, the toner conveying portion does not need to be driven to rotate, so that a flat belt shape is possible, and the entire apparatus can be reduced in size and cost due to the freedom of layout.

  Further, when fine particles such as an external additive of toner are deposited on the electrode surface during long-term use, the surface of the toner carrier 101 is cleaned by a cleaning mode sequence other than the image formation time. Transport reliability can be ensured. The cleaning is configured to come into contact with the surface of the toner carrier 101 only in the cleaning mode, and cleaning is performed with a rotating brush, a blade, a suction slit, and the like. The pulse voltage applied to the electrodes 111A, 111B, and 111C is a pulse voltage having a frequency of 0.5 [kHz] to 7 [kHz] and including a DC voltage as a bias, as described above, and its peak value is ± 60. A pulse corresponding to the electrode width and electrode interval, such as up to ± 300 [V], is applied.

In a specific configuration of the toner carrier 101, the insulating base 101A as a base substrate is, for example, a base made of an insulating material such as resin or ceramics, or a base made of a conductive material such as aluminum. A film formed of an insulating film such as SiO ₂ or a film made of a flexible and deformable material such as a polyimide film can be used. The electrode 111 is formed by forming a conductive material such as Al or Ni—Cr with a thickness of 0.1 to 1 [μm] on a base substrate, and patterning it into a required electrode shape using a photolithographic technique or the like. Alternatively, the copper foil may be formed by lamination, plating or the like and then patterned by photolithography.

As the surface protective layer 101B, for example, SiO ₂ , TiO ₂ , TiN, Ta ₂ O _{5 and the} like are formed by vapor deposition with a thickness of 0.5 to 2 [μm], or polycarbonate, polyimide, methyl methacrylate, etc. The organic material may be applied by thin film printing to a thickness of 2 to 10 [μm] and heat-cured.

  In the toner carrier 101 configured as described above, a flying electric field is formed by applying a flying pulse from the drive circuit, so that the charged toner on the toner carrier 101 receives a repulsive force or an attractive force. Flight in the vertical direction and transport in the traveling wave direction are performed.

Next, an example of a specific configuration of the toner supply unit 100 in the image forming apparatus will be described with reference to FIG.
This toner supply unit 100 is an example in which a two-component recording material comprising a magnetic carrier and a non-magnetic toner is used. The recording agent storage unit 201 is divided into two chambers 201 </ b> A and 201 </ b> B and is connected by recording agent passages (not shown) at both ends in the toner supply unit 100. The recording agent storage unit 201 stores a two-component recording agent and is transported through the recording agent storage unit 201 while being stirred by the stirring transport screws 202A and 202B in the chambers 201A and 201B.

  A toner supply port 203 is disposed in the chamber 201 </ b> A of the recording agent storage unit 201, and is supplied into the recording agent storage unit 201 from a toner storage unit (not shown) through the toner supply port 203. The recording agent storage unit 201 is provided with a toner concentration sensor (not shown) that detects the magnetic permeability of the recording agent, and detects the concentration of the recording agent. When the toner concentration in the recording agent storage unit 201 decreases, toner is supplied into the recording agent storage unit 201 from the toner supply port 203.

  A magnet brush 204 as a toner replenishing roller is disposed at a position facing the agitating and conveying screw 202B. A fixed magnet is disposed inside the mag brush roller 204, and the recording agent in the recording agent storage unit 201 is pumped up to the surface of the mag brush roller 204 by the rotation and magnetic force of the mag brush roller 204. A recording material layer regulating member 205 is provided at a position facing the mag brush roller 204 upstream of the recording material pumping position in the rotational direction of the mag brush roller 204.

  The recording agent pumped up at the pumping position is regulated to a certain amount of recording agent layer by the recording agent layer regulating member 205. The recording agent that has passed through the recording agent layer regulating member 205 is conveyed to a position facing the toner carrier 101 as the magnetic brush roller 204 rotates. A supply bias is applied to the magnet brush roller 204 by the first voltage applying means 211.

  The above-described voltage shown in FIG. 1 or FIG. 14 is applied to the electrode 111 by the second voltage applying means 212 to the toner carrier 101. At a position facing the mag brush roller 204, an electric field is generated between the toner carrier 101 and the mag brush roller 204 by the first voltage applying means 211 and the second voltage applying means 212. Under the electrostatic force from the electric field, the toner is separated from the carrier and moves to the surface of the toner carrier 101. The toner that has reached the surface of the toner carrier 101 is clouded by the electric field formed by the voltage applied to the electrode 111 from the second voltage application unit 212, and is generated by the rotation of the toner carrier 101 or the traveling wave electric field of the toner carrier 101. Be transported.

  Then, the toner conveyed to a position facing the toner control means 104 is selectively jumped to the recording medium side by the control electric field of toner control ON / OFF of the control electrode 42, and the dot printing of the toner is controlled. .

Next, an example of a specific configuration of the toner supply unit 100 in the image forming apparatus will be described with reference to FIG.
The toner supply unit 100 is an example using a one-component recording material made of non-magnetic toner. The toner is stored in the recording material storage unit 201. The toner is frictionally charged with the toner supply roller 113 by the charging roller 220, and is pumped up onto the toner supply roller 113 by electrostatic force. The toner on the toner supply roller 113 is made into a thin layer by the blade 114 and is conveyed to a position facing the toner carrier 101 as the toner supply roller 113 rotates.

  At this time, a supply bias is applied to the toner supply roller 113 by the first voltage applying unit 221. A voltage is applied to the electrode 111 by the second voltage applying means 222 in the toner carrier 101. Accordingly, at the position facing the toner carrier 101, an electric field is generated between the toner carrier 101 and the toner supply roller 113 by the first voltage application unit 221 and the second voltage application unit 222, and electrostatic force from the electric field is generated. In response, the toner is separated from the toner supply roller 113 and moved to the surface of the toner carrier 101.

  Similar to the above example, the toner that reaches the surface of the toner carrier 101 is clouded by the electric field formed by the voltage applied to the electrode 11 from the second voltage applying means 222, and the rotation of the toner carrier 101 or the toner carrier It is carried by the traveling wave electric field of the body 101.

  Then, the toner conveyed to a position facing the toner control means 104 is selectively ejected to the recording medium side by the control electric field of toner control ON / OFF of the control electrode, and the dot printing of the toner is controlled.

  In each of these toner supply units 100, the toner that has not contributed to the printing is further conveyed by the toner carrier 101 and is collected from the surface of the toner carrier 101 by a collecting means (not shown). The collected toner is returned again to the recording material container 201 and circulates in the toner supply unit 100.

  In the above description, mainly negatively charged toner is taken as an example, but positively charged toner can also be used.

[Experiment]
Next, it is formed on the recording paper 150 when the method of applying the voltage applied to the plurality of electrodes 111 of the toner carrier 101 in the toner supply unit is changed using the image forming apparatus shown in FIG. An evaluation experiment of the state of the image to be performed will be described.

  In Example 1, a two-phase alternating voltage of ± 150 Vpp is applied to the plurality of electrodes 111 of the toner carrier 101 so as to have different phases at the same timing, and every 2 [ms] period (period T2). First, an alternating voltage having a period of 0.2 [ms] (period T1) is continuously applied three times (m = 3), and is alternated for the remaining time (for 1.2 [ms]) after the continuous application. An alternating voltage having a period of 0.2 [ms] was intermittently applied to the electrode 111 without applying a voltage.

  In Example 2, two-phase alternating voltages of ± 150 Vpp are applied to the plurality of electrodes 111 of the toner carrier 101 so as to have different phases at the same timing, and every 2 [ms] period (period T2). First, an alternating voltage having a period of 0.2 [ms] (period T1) is continuously applied four times (m = 4), and alternating for the remaining time after the continuous application (for 1.2 [ms]). An alternating voltage having a period of 0.2 [ms] was intermittently applied to the electrode 111 without applying a voltage.

  In Example 3, a two-phase alternating voltage of ± 150 Vpp is applied to the plurality of electrodes 111 of the toner carrier 101 so as to have different phases at the same timing, and every 2 [ms] period (period T2). First, an alternating voltage having a period of 0.2 [ms] (period T1) is continuously applied 6 times (m = 6), and the alternating voltage is alternating for the remaining time (for 1.2 [ms]) after the continuous application. An alternating voltage having a period of 0.2 [ms] was intermittently applied to the electrode 111 without applying a voltage.

  In Embodiment 4, two-phase alternating voltages of ± 150 Vpp are applied to the plurality of electrodes 111 of the toner carrier 101 so as to have different phases at the same timing, and every 2 [ms] period (period T2). First, an alternating voltage having a period of 0.2 [ms] (period T1) is continuously applied 7 times (m = 7), and the alternating voltage is alternated for the remaining time (for 1.2 [ms]) after the continuous application. An alternating voltage having a period of 0.2 [ms] was intermittently applied to the electrode 111 without applying a voltage.

  In the fifth embodiment, one of the two-phase alternating voltages is ± 150 [Vpp], and the other alternating voltage is the center voltage of the voltage amplitude of the one alternating voltage, that is, 0 [V]. First, an alternating voltage having a period of 0.2 [ms] (period T1) is applied four times (m = 4) every 2 [ms] period (period T2). The voltage was continuously applied, and the alternating voltage was intermittently applied to the electrode 111 without applying the alternating voltage for the remaining time (1.2 [ms]) after the continuous application. .

  In Example 6, one of the two-phase alternating voltages is ± 300 [Vpp], and the other alternating voltage is the center voltage of the voltage amplitude of the one alternating voltage, that is, 0 [V]. First, an alternating voltage of 0.2 [ms] period (period T1) is applied four times (m = 4) every 2 [ms] period (period T2). The voltage was continuously applied, and the alternating voltage was intermittently applied to the electrode 111 without applying the alternating voltage for the remaining time (1.2 [ms]) after the continuous application. .

  In Comparative Example 1, a two-phase alternating voltage of ± 150 Vpp and a period of 2 [ms] was continuously applied to the plurality of electrodes 111 of the toner carrier 101 so as to have different phases at the same timing.

  In Comparative Example 2, a two-phase alternating voltage of ± 150 Vpp and a period of 0.2 [ms] was continuously applied to the plurality of electrodes 111 of the toner carrier 101 so as to have different phases at the same timing. .

  The evaluation of the state of the image formed on the recording paper 150 under each experimental condition is based on subjective evaluation of the diameter and density of the dots forming the image by visual observation. Those that were acceptable for use were marked with “◯”, and those that were unacceptable for actual use were marked with “x”.

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

  In Examples 1 to 6, all evaluations were good “「 ”or“ ◯ ”acceptable in actual use, and in Comparative Examples 1 and 2, neither evaluation was acceptable in actual use“ × ” " From this, by intermittently applying an alternating voltage to the plurality of electrodes 111 of the toner carrying member 101, it is possible to prevent the toner hopping state from being disturbed and to appropriately control the toner cloud state. It can be seen that good image formation can be performed for the reasons described above.

  Further, from the experimental results of Example 1 to Example 6, the number m of applying the alternating voltage of 0.2 [ms] period (T1) is the number m of 6 or less in terms of dot diameter variation reduction. The effect was strongly seen. Regarding the dot density, the density m was almost the same when the number m was 4 or more. Therefore, the density of the toner in the cloud state (cloud density) increases as the value of the number of times m increases. It can be seen that the density (cloud density) is sufficient.

  Further, in the fifth embodiment, the potential difference between the electrodes is ½ that when the alternating voltage as in the second embodiment is applied to both electrodes, that is, in the second embodiment, the potential difference is 150 [V]. On the other hand, in Example 5, the potential difference is 75 [V]. For this reason, the toner hopping is not activated as much as the potential difference is smaller than that in the second embodiment, so that it is considered that the density of the toner in the cloud state is smaller than that in the first embodiment.

  In Example 6, the evaluation result was obtained by doubling the amplitude of the alternating voltage with respect to the experimental condition of Example 5 and setting the potential difference between the electrodes in Example 6 to 150 [V], which is the same as in Example 2. However, the same results as in Example 2 were obtained. In other words, the potential difference between the electrodes is the same as that in the second embodiment, and the alternating voltage of 0.2 [ms] period (T1) is applied four times (m = 4) as in the first embodiment. This is considered to be because the density of the toner in the state (cloud density) is about the same as in Example 2.

As described above, according to the present embodiment, the toner carrier 1 in which the plurality of electrodes 11 are arranged at predetermined intervals along the surface of the support base, and the n phase that changes with time (n is 1 or more). Voltage applying means 5 for generating an electric field on the surface of the toner carrying member 1 by applying the alternating voltage of the above to the plurality of electrodes 11 and hopping the toner charged to a predetermined polarity carried on the surface of the toner carrying member 1. A plurality of toner passage holes 41 are formed, and an insulating substrate 45 which is a hole forming member disposed so as to face the toner carrier 1 and an insulating substrate 45 corresponding to each of the plurality of toner passage holes. Are provided on at least one of the periphery of the toner passage hole and the inner wall of the toner passage hole on the surface opposite to the toner carrier 1 to form a plurality of electric fields for selectively flying the toner from the toner carrier 1. flying A control electrode 42 that is a pole and a rear surface that is disposed so as to face the toner carrier 1 through the insulating substrate 45 and is a counter electrode for forming an electric field that attracts toner flying from the toner carrier 1 The toner is selectively ejected from the toner carrier 1 by the formation of the flying electric field based on the image information, and is transferred to the back electrode 31 side through the toner passage hole 41 and then on the recording member. In the image forming apparatus that forms an image by adhering to the electrode, the alternating voltage is applied to the plurality of electrodes 11 by the voltage applying means 5 intermittently. In this embodiment, since the alternating voltage is intermittently applied to the plurality of electrodes 11 by the voltage applying means 5, the toner when the alternating voltage is not applied to the plurality of electrodes 11 and hopping is not performed is used as the toner carrier. 1 is carried. As a result, even when toner that cannot follow the switching of the alternating voltage appears, the toner hopping is intermittently performed, so that the toner hopping start position can be set at any location on the toner carrier 1. Can be on top. Therefore, when the alternating voltage is applied next and toner hopping is started, the toner jumps from the toner carrier 1 at any location on the toner carrier 1, and the alternating voltage is continuously applied. It is possible to prevent the toner hopping state from being disturbed at each location on the toner carrier 1 than when the toner is carried. Therefore, it is possible to prevent the toner density of the toner cloud formed by toner hopping from being scattered at each location on the toner carrier 1, and the toner cloud 1 can fly from the toner carrier 1 and have a plurality of toner passage holes 41. Variations in the amount of toner passing through each can be suppressed. Therefore, the toner adhering amount of each dot pixel image formed corresponding to each of the plurality of toner passage holes 41 through the plurality of toner passage holes 41 and flying to the surface of the recording medium 3 is suppressed. It is possible to suppress image density unevenness in an image formed by collecting pixel images.
In addition, according to the present embodiment, the voltage applying means 5 applies the alternating voltage of the cycle T1 a predetermined number of times m within the predetermined time T2, and satisfies the relationship of T2> T1 × m as described above. As described above, it is possible to obtain a sufficient image density while calming the hopping state of the toner.
In addition, according to the present embodiment, the n-phase alternating voltage applied between the plurality of electrodes 11 of the toner carrier 1 by the voltage applying unit 5 is switched at the same timing and at different phases, thereby switching the voltage. The toner can be efficiently hopped by following the timing, and the toner cloud state is stabilized, and a sufficient cloud density (concentration of the toner in the cloud state) is obtained by m times of alternation. The amount of toner flying from 1 and passing through the plurality of toner passage holes 41 does not vary for each toner passage hole 41, and as a result, an image can be formed on the recording medium 3 with a desired image density.
Further, according to the present embodiment, at least one of the n-phase alternating voltages applied between the plurality of electrodes 11 of the toner carrier 1 by the voltage applying means 5 is the alternating voltage having the period T1. Even in such a configuration, the cloud state of the toner is stabilized, and a sufficient cloud density (concentration of the toner in the cloud state) is obtained by m times of alternating, so that the toner flies from the toner carrier 1 and the plurality of toner passage holes 41. The amount of toner passing through the toner does not vary for each toner passage hole 41, and as a result, an image can be formed on the recording medium 3 with a desired image density.
Further, according to the present embodiment, the common electrode 43 that is a plurality of outer peripheral electrodes provided via the control electrode 42 around the toner passage hole on the surface on the opposite side corresponding to each of the plurality of toner passage holes. The electric field between the back electrode 31 and the common electrode 43 is such that the flying toner moves from the common electrode 43 side to the control electrode 42 through the toner passage hole 41 toward the back electrode 31 side. Was configured to form. Here, the electric lines of force representing the state of the electric field formed in this way pass through the toner passage hole 41 and straddle the control electrode 42, and the toner carrier 1 and the insulating substrate 45 (toner control means 4). A space between the back electrode 31 and the common electrode 43 is formed. Therefore, the toner flying from the toner carrier 1 toward the control electrode 42 reaches the electric force line before reaching the control electrode 42, and passes through the toner passage hole 41 from the common electrode 43 side along the electric force line. It moves toward the back electrode 31 side. Therefore, the toner flying from the toner carrier 1 becomes difficult to reach the control electrode 42, and the toner adhering to the control electrode 42 can be reduced. When toner accumulates on the surface of the control electrode 42 over time, the electric field for flying the toner formed by the control electrode 42 is weakened, and the flying efficiency of the toner is reduced. For this reason, the amount of toner passing through the toner passage hole 41 changes with time, and a desired image density cannot be obtained. Therefore, by reducing the toner adhering to the control electrode 42 as in this embodiment, it is possible to suppress the toner flying efficiency from being reduced, and a desired image density can be obtained over time.
Further, according to the present embodiment, the common electrode 43 is formed so as to surround the outside of the control electrode 42 in a ring shape with an insulating region interposed therebetween, so that the common electrode 43 is interposed between the back electrode 31 and the common electrode 43 outside the control electrode 42. Since the electric force to be formed can be formed as an independent line of electric force for each toner passage hole 41, mutual interference (the state of the other toner passage holes 41) at the time of multi-drive (drive that causes toner to fly from the plurality of toner passage holes 41). Can be suppressed.
Further, according to the present embodiment, the common electrode 43 is provided in a solid shape outside the control electrode 42 via the insulating region, that is, the common electrode 43 is formed over the entire outer region of the control electrode 42, so that the back electrode The electric field on the 31st side can be shielded, toner adhesion to the control electrode 42 can be reduced, and toner utilization efficiency can be improved.
In addition, according to the present embodiment, the common electrode 43 is provided on the same plane as the control electrode 42 via the insulating region, so that it can be simultaneously formed in a single manufacturing process and controlled to the insulating substrate 45 with high accuracy and low cost. The electrode 42 and the common electrode 43 can be formed.
In addition, according to the present embodiment, a voltage having a relationship in which a toner suction direction and a repulsion direction are alternately repeated between adjacent electrodes of a plurality of electrodes 11 disposed on the surface of the toner carrier 1 is applied with a voltage. The configuration is such that an n-phase phase voltage is applied to each of the n electrodes 11 by applying a pitch between the two electrodes applied by the means 5 and applied to the electrodes 11. Phase voltage is applied, and toner hopping can be efficiently performed following the voltage switching timing. In addition, it is possible to suppress the occurrence of mutual interference (receiving the state of other toner passage holes 41) during multi-drive (drive that causes toner to fly from the plurality of toner passage holes 41).
In addition, according to the present embodiment, a voltage having a relationship in which a toner suction direction and a repulsion direction are alternately repeated between adjacent electrodes of a plurality of electrodes 11 disposed on the surface of the toner carrier 1 is applied with a voltage. The pitch of the toner carrier 1 is greater than the pitch between the two-phase electrodes applied by the means 5 and applied to the electrodes 11 or the n-phase pitch between the n-phase electrodes 11. Since the distance between the surface and the surface of the insulating substrate 45 on the toner carrier 1 side is larger, as described above, it is possible to reliably prevent toner from adhering to the control electrode 42, and even if continuous dots are printed. A good image can be obtained without changing the density.
Further, according to the present embodiment, the recording medium 3 is a recording paper, and the back electrode 31 is provided at a position on the back of the recording paper facing the toner carrier 1 with the insulating substrate 45 interposed therebetween. Various effects as described above can be obtained.
Further, according to the present embodiment, the recording medium 3 is an intermediate transfer body, and the back electrode 31 is provided at a position that is the back surface of the intermediate transfer body facing the toner carrier 1 via the intermediate transfer body itself or the insulating substrate 45. Even with the provided configuration, various effects as described above can be obtained.
Further, according to the present embodiment, a direct recording type image forming apparatus to which the present invention is applied, which is configured to form a color image on the recording medium 3 by superimposing different color toners on the recording medium 3. By forming a color image, a high-quality color image can be obtained as described above.

FIG. 6 is a waveform diagram illustrating an example of a pulse voltage applied to an electrode of a toner carrier. FIG. 3 is a schematic configuration diagram of a direct recording method. Explanatory drawing which shows an example of the control pulse applied to a control electrode. (A) Schematic diagram of the toner control means on the printing surface side. FIG. 6B is an explanatory diagram of a toner supply side surface of the toner control unit. (A) Schematic diagram of the toner control means on the printing surface side. FIG. 6B is an explanatory diagram of a toner supply side surface of the toner control unit. (A) Explanatory drawing which shows the electric force line which passes a toner passage hole based on the simulation result of the two-dimensional cross-sectional electric field strength distribution when a toner control means is a state which can pass toner. (B) Explanatory drawing which shows the electric force line which passes a toner passage hole based on the simulation result of the two-dimensional cross-sectional electric field strength distribution when a toner control means cannot pass toner. 6 is a graph showing the relationship between the supplied toner amount and the toner potential. 6 is a graph showing the relationship between the supplied toner amount and the toner adhesion amount to the toner control means. FIG. 6 is a waveform diagram when a rectangular wave pulse voltage is applied to one electrode of a toner carrier and a DC voltage is applied to the other electrode. 1 is a schematic explanatory diagram illustrating an example of an image forming apparatus according to an embodiment. FIG. 6 is a schematic explanatory view showing another example of the image forming apparatus according to the present embodiment. (A) Schematic plane explanatory drawing shown in the state which developed an example of the toner carrier. (B) A schematic cross-sectional explanatory view of the toner carrier. (A) The typical plane explanatory view shown in the state where other examples of the toner carrier were developed. (B) A schematic cross-sectional explanatory view of the toner carrier. FIG. 6 is a waveform diagram showing another example of a pulse voltage applied to an electrode of a toner carrier. FIG. 3 is a schematic explanatory diagram illustrating an example of a toner supply unit. FIG. 6 is a schematic explanatory diagram illustrating another example of a toner supply unit. FIG. 10 is a schematic diagram showing a basic configuration of a conventional direct recording apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Toner carrier 3 Recording medium 4 Toner control means 5 Voltage application means 6 Control pulse generation means 7 Power supply 8 Bias power supply means 10 Electric field line 11 Electrode 31 Back electrode 41 Toner passage hole 42 Control electrode 42a Lead pattern 43 Common electrode 43a Lead Pattern 45 Insulating substrate 100 Toner supply unit 101 Toner carrier 101A Insulating substrate 101B Surface protective layer 101C Insulating layer 103 Intermediate transfer recording medium 104 Toner control means 105 Paper feed unit 107 Transfer roller 108 Fixing unit 111 Electrode 113 Toner supply roller 114 Blade 131 Back electrode 132 Roller 135 Cleaning unit 150 Recording paper 161 Paper transport belt 162 Roller 164 Guide 165 Registration roller 201 Recording agent container 203 Toner supply port 204 Mag brush roller 205 Recording agent layer regulating member 211 First voltage applying means 212 Second voltage applying means 220 Charging roller 221 First voltage applying means 222 Second voltage applying means 501 Toner carrier 502 Hole 504 Flying electrode 506 Counter electrode 507 Recording Paper 511 electrode

Claims (13)

A toner carrier having a plurality of electrodes arranged at predetermined intervals along the surface of the support substrate;
An n-phase (n is 1 or more) alternating voltage is applied to the plurality of alternating voltages so that an electric field for hopping the toner charged to a predetermined polarity carried on the surface of the toner carrier is generated on the surface of the toner carrier. Voltage applying means for applying to the electrode;
A hole forming member in which a plurality of holes are formed and disposed to face the toner carrier;
Corresponding to each of the plurality of holes, the hole forming member is provided on at least one of the periphery of the hole or the inner wall of the hole on the surface on the side facing the toner carrier, and the toner is selectively ejected from the toner carrier. A plurality of flying electrodes to form a simple electric field;
A counter electrode disposed so as to face the toner carrier via the hole-forming member, and for forming an electric field that attracts toner flying from the toner carrier;
Based on the image information, the toner selectively ejected from the toner carrier by the formation of the flying electric field is transferred to the counter electrode side through the hole and then adhered to the recording member to form an image. In the image forming apparatus,
An image forming apparatus configured to intermittently apply the alternating voltage to the plurality of electrodes by the voltage applying unit. The image forming apparatus according to claim 1.
The image forming apparatus, wherein the voltage applying unit applies an alternating voltage having a cycle T1 a predetermined number of times m within a predetermined time T2, and satisfies a relationship of T2> T1 × m. The image forming apparatus according to claim 1 or 2,
An n-phase alternating voltage applied between a plurality of electrodes of the toner carrier by the voltage applying means alternates at the same timing and in different phases. The image forming apparatus according to claim 2.
An image forming apparatus, wherein at least one of the n-phase alternating voltages applied between the plurality of electrodes of the toner carrier by the voltage applying means is the alternating voltage having the period T1. The image forming apparatus according to claim 1, 2, 3, or 4.
Having a plurality of outer peripheral electrodes provided via the flying electrodes around the holes on the surface on the opposite side corresponding to each of the plurality of holes;
An electric field is formed between the counter electrode and the outer peripheral electrode so that the flying toner moves from the outer peripheral electrode side to the counter electrode side through the hole across the flying electrode. An image forming apparatus. The image forming apparatus according to claim 5.
The image forming apparatus, wherein the outer peripheral electrode has a shape surrounding the outside of the flying electrode in a ring shape with an insulating region interposed therebetween. The image forming apparatus according to claim 5.
The image forming apparatus, wherein the outer peripheral electrode is provided in a solid shape outside the flying electrode through an insulating region. The image forming apparatus according to claim 5, 6 or 7.
The image forming apparatus, wherein the outer peripheral electrode is provided on the same plane as the flying electrode through an insulating region. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7 or 8.
A voltage having a relationship of alternately repeating the direction of attracting and repelling the toner between adjacent electrodes of the plurality of electrodes disposed on the surface of the toner carrier is applied by the voltage applying means, An image forming apparatus characterized in that an n-phase phase voltage is applied to a pitch between two-phase electrodes to be applied or every n electrodes. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7 or 8.
A voltage having a relationship of alternately repeating the direction of attracting and repelling the toner between adjacent electrodes of the plurality of electrodes disposed on the surface of the toner carrier is applied by the voltage applying means, More than the pitch between the two-phase electrodes to be applied or the pitch between the n-phase electrodes when the n-phase voltage is applied to each n-th electrode, the surface of the toner carrier and the toner carrier side of the hole forming member An image forming apparatus having a larger distance from the surface. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10.
An image forming apparatus, wherein the recording member is a recording sheet, and the counter electrode is provided at a position on the back side of the recording sheet facing the toner carrier through the hole forming member. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9 or 10.
The recording member is an intermediate transfer member, and the counter electrode is provided at a position on the back surface of the intermediate transfer member facing the toner carrier via the intermediate transfer member itself or the hole forming member. Image forming apparatus. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12.
An image forming apparatus, wherein a color image is formed on the recording member by superimposing different color toners.

Images