JP4113665B2 - Image forming apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention allows an image to be attached to a recording member by discharging colored particles in a colored liquid held on a substrate having a plurality of parallel electrodes arranged in parallel at a predetermined pitch from the tip of the parallel electrodes. The present invention relates to an image forming apparatus and an image forming method.
[0002]
[Prior art]
Conventionally, as this type of image forming apparatus, one disclosed in JP-A-8-90825 is known. FIGS. 13A, 13B, and 13C are a longitudinal sectional view, a plan view, and a front view, respectively, showing the main configuration of the image forming apparatus. In these drawings, the recording head 1 includes an insulating substrate 4 on which a plurality of discharge electrodes 2 as parallel electrodes are formed, and a pair in which a common electrode 14 facing each discharge electrode 2 with a predetermined gap is formed. And an insulating top plate 13 which is a face plate.
[0003]
The tip of each discharge electrode 2 is tapered, and the insulating substrate is arranged so as to protrude from the insulating top plate 13 to the left in the drawing so that only the tapered portion does not face the common electrode 14. It is installed. Each discharge electrode 2 is electrically independent of each other, and a common voltage is applied to them by a power source 8a. In addition, a recording voltage is applied to any discharge electrode 2 by adding a recording voltage to the common voltage by a recording signal power source 7 in order to cause a toner aggregate described later to fly from the tip.
[0004]
A bias voltage is applied to the common electrode facing each ejection electrode 2 by a power source 8b.
[0005]
Between the insulative substrate 4 and the insulative top plate 13, a colored liquid 6 composed of toner as colored particles charged in positive polarity and a liquid carrier is accommodated.
[0006]
In a state where no voltage is applied to each ejection electrode 2 or common electrode 14, as shown in FIG. 14A, the toner T is uniformly dispersed in the colored liquid. From such a dispersed state, when a positive voltage is applied from the power source 8a to each discharge electrode 2, and a lower positive voltage is applied from the power source 8b to the common electrode 14, The toner T is electrophoresed toward the common electrode 14 having a lower potential. In this state, when the colored liquid is pressed by a pressing means (not shown), as shown in FIG. 14B, the toner T is applied to the inclined liquid surface formed between the tip of the common electrode 14 and the tip of the discharge electrode 2. It flows unevenly along and gathers at the tip of the discharge electrode 2. Then, the toner is electrostatically attracted to the grounded counter electrode 9 and further gathers at a portion slightly protruding from the tip to form a toner aggregate. When the recording voltage is applied to any discharge electrode 2 with the toner aggregates formed in this manner, the toner aggregates fly from the tip of the discharge electrode 2, and the recording head 1. One dot is formed by adhering to a recording paper (not shown) disposed between the counter electrode 9.
[0007]
[Problems to be solved by the invention]
In the conventional image forming apparatus shown in FIG. 13, the common electrode 14 faces each discharge electrode 2 and the tip of each discharge electrode 2 tapers in order to generate the toner aggregate as described above. A complicated electrode configuration is adopted in which the electrode is formed in the shape of the common electrode 14 so as to protrude toward the counter electrode 9 side. In addition, there is a problem in that the cost of the recording head 1 is increased by such a complicated electrode configuration.
[0008]
On the other hand, the inventors made a prototype of a discharge test apparatus as shown in FIG. In the figure, the discharge test apparatus 100 includes transparent glass plates 101 and 102. On the glass plate 101, a counter electrode 9 made of transparent ITO (indium tin oxide) and having a width of 1000 [μm] (W1) is laminated. On the glass plate 102, discharge electrodes 2a, 2b, and 2c made of ITO and having a width of 100 [μm] (W2) are stacked in parallel with a gap of 100 [μm]. The glass plate 102 is disposed beside the glass plate 101 so that the tips of the discharge electrodes 2a, 2b, and 2c face the counter electrode 9 through a gap G1 of 120 [μm].
[0009]
Although the above Japanese Patent Laid-Open No. 8-90825 does not describe the toner concentration of a colored liquid, the apparatus shown in FIG. 13 has a toner concentration and viscosity equivalent to those of a general liquid developer (toner concentration: about 1 wt%, (Viscosity of about 1.5 mPa · s) is considered to be used. Therefore, a conventional general liquid developer discharge test was performed as follows using the discharge test apparatus 100.
[0010]
[Discharge test 1]
A conventional general liquid developer, which is a colored liquid, was dropped on the glass plate 102 shown in FIG. 1, and the liquid droplet was leveled with a wire bar to form a liquid film having a thickness of 20 [μm]. Then, while the counter electrode 9 is grounded, while applying a positive discharge voltage to the discharge electrodes 2a and 2c at both ends, the state of the colored liquid near the tip of each discharge electrode 2a, 2b and 2c is measured with a microscope. Observation was performed while taking a picture with a high-speed camera attached to the camera. Then, no matter how much the discharge voltage is increased, the toner does not fly from the tips of the discharge electrodes 2a and 2c. 1 is not configured to generate toner aggregates in advance, and the tip of the discharge electrode 2 is sharpened to concentrate the electric field at a position where toner aggregates are generated. Since this is not the case, it can be said that this is a natural result when a liquid developer having a low toner concentration is used.
[0011]
Next, the present inventors conducted a similar ejection test by replacing a conventional general liquid developer with a colored liquid having a higher toner concentration and higher viscosity.
[Discharge test 2]
A colored liquid having a viscosity of 500 [mPa · s] in which a positive polarity toner having a concentration of 15 [wt%] is contained in polysiloxane oil as a liquid carrier was used. Then, even when the discharge voltage was increased to +0.8 [kV], no change was observed in the colored liquid. However, when the discharge voltage was further increased, the colored liquid started to move gradually and increased to +1.0 [kV]. When raised, as shown in FIG. 2A, the colored liquid 6 was raised by about 10 [μm] from the tips of the ejection electrodes 2a and 2c. However, the raised portion maintained its shape while slightly vibrating without extending to the counter electrode 9. Since the force to return to the original shape by the surface tension and the electrostatic force due to the electric field formed by the potential difference between the discharge electrode 2 and the counter electrode 9 acted on the raised portion with almost the same strength, the raised portion Seems to have vibrated slightly while maintaining its shape.
[0012]
If the value of the discharge voltage is further increased to 1.2 [kV] in the state where the raised portion is vibrated slightly, the raised portion further extends as shown in FIG. 9 was reached, and the counter electrode 9 and the discharge electrode 2b were bridged. Then, as shown in FIG. 2 (c), the raised portions immediately cut off in the middle and remained on the discharge electrodes 2a, 2c side were pulled back toward the discharge electrodes 2a, 2c, respectively. Therefore, depending on the toner concentration of the colored liquid 6, even with a simple electrode configuration such as the ejection test apparatus 100 of FIG. 1, the colored liquid 6 can be raised from the tip of the ejection electrode 2 and attached to the recording member. I understood.
[0013]
[Discharge test 3]
Next, the inventors created a glass plate 102 in which the gap between the ejection electrodes 2 was reduced from 100 [μm] to half 50 [μm], assuming higher-resolution image formation, and A test similar to the discharge test 2 was performed. Then, an unexpected problem occurred. The colored liquid 6 rises also from the tip of the discharge electrode 2b to which no discharge voltage of +1.2 [kV] is applied, and is integrated with the colored liquid 6 raised from the tips of the discharge electrodes 2a and 2c on both sides. Thus, it adhered to the counter electrode 9. Then, it was cut off in the middle and left on the side surface of the glass plate 101. On the side surface of the glass plate 101, dots were originally formed in places that should be non-pixel portions. The reason why the colored liquid 6 is raised from the tip of the discharge electrode 2b is that the colored liquid 6 having a high viscosity (500 mPa · s) raised from the tips of the discharge electrodes 2a and 2c on both sides is located near the tip of the discharge electrode 2b. The colored liquid 6 has been dragged out by surface tension. Generally, the colored liquid 6 such as a liquid developer increases in viscosity as the toner concentration increases. Therefore, when using the colored liquid 6 having a relatively high toner concentration in order to simplify the electrode configuration of the recording head, such dragging is performed. Is very likely to cause.
[0014]
As a method for suppressing the dragging of the colored liquid 6, it is conceivable to provide a partition wall between the ejection electrodes 2. However, since the colored liquid 6 contains high-concentration (15 wt%) toner, if such a partition wall is provided, in an actual apparatus, the substrate on which the ejection electrode 2 is formed and the surface facing this are provided. The toner is easily clogged with the facing plate. In addition, although the electrode configuration is simplified, there is a possibility that the cost of the recording head cannot be reduced by providing the partition wall.
[0015]
  The present invention has been made in view of the above background.,eachAn image forming apparatus capable of suppressing the dragging of the nearby colored liquid by the colored liquid raised from the tip of the parallel electrode without providing a partition wall between the parallel electrodes.PlaceIs to provide.
[0016]
[Means for Solving the Problems]
  In order to achieve the above object, the invention of claim 1 is arranged in parallel at a predetermined pitch on a liquid holding surface of a substrate holding a colored liquid containing charged colored particles and a liquid carrier. A plurality of parallel electrodes, a facing plate facing the liquid holding surface, and a counter electrode facing the tip of each parallel electrode through a predetermined gap, and colored particles in the colored liquid on the parallel electrode An image forming apparatus that discharges the aggregate from the tip toward the counter electrode by the potential difference between the parallel electrode and the counter electrode, and attaches the ejected aggregate to a recording member to form an imageIn,A liquid repellent coating is provided only in a part of a predetermined distance range from the front end to the rear end of the substrate facing the counter electrode in the region between the parallel electrodes on the substrate, and the repellent film on the facing plate is provided. A liquid repellent film is also provided in a region facing the liquid film, and the liquid repellent film on the substrate and the liquid repellent film on the facing plate are provided., Forming cavities without colored liquidsI didIt is characterized by this.
[0017]
  “Colored liquid” in this image forming apparatus indicates a type of colored liquid designated by the manufacturer or distributor of the apparatus. This designation is made by, for example, listing the name or standard of a colored liquid that can be used in the instruction manual or sticker sticker of the apparatus, or packing the colored liquid together with the apparatus.
  In this image forming apparatus,Liquid repellent coating provided on substrate and facing plateBy forming a cavity in which no colored liquid exists in a region corresponding to between each parallel electrode between the substrate and the facing plate, the surface tension of the colored liquid raised from the tip of the parallel electrode is increased on the other parallel electrode. It is difficult to convey to the colored liquid located near the tip of the. In such a configuration, it is possible to suppress the dragging of the nearby colored liquid due to the colored liquid raised from the tip of the parallel electrode without providing a partition wall between the parallel electrodes.
Further, in this image forming apparatus, since the amount of the colored liquid existing between the parallel electrodes is reduced by a predetermined distance range from the front end to the rear end of the substrate, the area other than the distance range in which the amount is not reduced is reduced. However, the amount of the colored liquid held on the substrate is larger than that in the area within the distance range. Thus, from the region where the amount of the colored liquid is increased, the colored liquid is smoothly supplied onto the parallel electrodes that have consumed the colored liquid by image formation. Therefore, supply shortage of the colored liquid on each parallel electrode can be suppressed.
[0024]
  Claim2The invention of claim1In this image forming apparatus, a fluororesin film is provided as the liquid repellent film.
[0025]
In this image forming apparatus, the fluororesin coating, which has been confirmed in the tests of the present inventors, has good liquid repellency with respect to a colored liquid containing a toner that is a colored particle and a polysiloxane oil that is a liquid carrier. The colored liquid existing between the parallel electrodes can be favorably moved to the adjacent parallel electrodes.
[0028]
  Claim3The invention of claim1 or 2In this image forming apparatus, the distance range is set to 0.2 [mm] or more and 0.9 [mm] or less.
[0029]
In this image forming apparatus, for the reason described below, the length of the liquid repellent film from the front end of the substrate is set too long while suppressing the dragging of the colored liquid due to being set too short. Insufficient supply of the colored liquid on each parallel electrode due to the above can be suppressed. That is, the inventors made a prototype of a recording head using the ejection test apparatus 100 described above. Then, dots were continuously formed using this recording head in which the appropriate length of the liquid repellent coating from the head tip (a fluororesin coating in the prototype) was set to various values. Then, when the length of the liquid repellent coating from the head tip is less than 0.2 [mm], the surface tension of the colored liquid raised from the tip of the parallel electrode causes the colored liquid located near the tip on the other parallel electrode. Thus, the effect of making it difficult to convey was not obtained, and dragging of the latter colored liquid by the former colored liquid was observed. Also, if the length of the liquid repellent film from the head tip exceeds 0.9 mm, the color from the area where the liquid repellent film is not provided on the substrate onto the parallel electrode in the area where the liquid repellent film is provided It was confirmed that the liquid was not supplied smoothly and the colored liquid on the parallel electrode was cut off. Therefore, by setting “0.2 mm ≦ distance range ≦ 0.9 mm”, it is possible to suppress the dragging of the colored liquid and the insufficient supply of the colored liquid as described above.
[0030]
  Claim4The invention of claim 1 and 2Or 3This image forming apparatus is characterized in that recording member moving means is provided for moving the recording member in a direction orthogonal to the arrangement direction of the parallel electrodes at a position facing the tip of each parallel electrode.
[0031]
In this image forming apparatus, dots are sequentially formed on the moving recording member by the parallel electrodes on the substrate. In such a configuration, not only a one-dimensional line image in which a plurality of dots are arranged in a straight line but also a two-dimensional image such as a character image or a video image can be formed.
[0032]
By the way, as described above, the toner in the conventional liquid developer did not fly from the tip of the discharge electrode 2b in the discharge test 1. As a matter of fact, at this time, the toner on the discharge electrodes 2a and 2c It moved to the middle discharge electrode 2b and concentrated. This is because the positive toner located on the discharge electrodes 2a and 2c that are supplied with the positive discharge voltage is electrostatically electrophoresed toward the discharge electrode 2b having a lower potential. On the other hand, in the discharge tests 2 and 3, toner concentration on the discharge electrode 2b was not so noticeable. However, it may cause a slight amount of toner electrophoresis similar to that in the ejection test 1.
[0033]
If a preliminary voltage is supplied to all the discharge electrodes 2 in advance, and a predetermined voltage is added to the discharge electrode 2b to which the colored liquid (liquid developer) is to be discharged from the tip, the discharge electrodes 2 are supplied. It should be possible to reduce the potential difference between them and suppress the electrophoresis of the toner. Therefore, the present inventors performed the following discharge test.
[0034]
[Discharge test 4]
About the said discharge test apparatus 100, the same thing as the time of the said discharge test 2 (The thing which does not shorten the distance between the discharge electrodes 2) was used. After the liquid film of the colored liquid 6 (toner concentration: 15 wt%, viscosity: 500 mPa · s) used in the ejection tests 2 and 3 is formed on the glass 102, the surface of the glass plate 101 facing the glass plate 102. A plain paper (thickness: 70 μm) as a recording member was fixed to the sheet. Then, a preliminary voltage of +1.0 [kV] was applied to each of the ejection electrodes 2a, 2b, and 2c, and the colored liquid 6 was raised from the tip of each electrode. In this state, each raised portion does not reach the plain paper. Next, among the discharge electrodes 2, a voltage of +0.2 [kV] was applied for 5 [msec] only to the discharge electrode 2b, and a discharge voltage of +1.2 [kV] was supplied. As a result, among the raised portions, only those at the tips of the ejection electrodes 2a and 2c reached the plain paper and formed dots with a high image density of about 100 [μm] and a sharp shape. When the state of the toner on the ejection electrodes 2a, 2b, and 2c at this time is photographed with a high-speed camera and the photographed image is slowly reproduced, not only the electrophoresis of the toner between the ejection electrodes 2 is suppressed, The toner did not electrophore at all.
[0035]
[Discharge test 5]
A discharge test similar to the discharge test 4 was performed by replacing the colored liquid 6 with a conventional liquid developer (toner concentration: 1 wt%, viscosity: 1.5 wt%). Then, from the discharge electrodes 2a and 2c to which the discharge voltage (1.0 + 0.2 kV) of +1.2 [kV] is supplied, to the discharge electrode 2b to which only the preliminary voltage of +1.0 [kV] is supplied. It was confirmed that the toner was electrophoresed and collected in the same manner as in the discharge test 1. Furthermore, even if the additional supply of +0.2 [kV] to the discharge electrodes 2a and 2b is finished and the potential difference between the discharge electrodes 2a and 2b and between the discharge electrodes 2b and 2c disappears, the collected toner remains in the discharge electrode. It was in a state as it was without returning to 2a, 2c. When the toner collects in this way, the liquid developer on the discharge electrodes 2a and 2c has a lower toner concentration than usual, and the liquid developer on the discharge electrode 2b has a higher toner concentration than usual. The density and size of the dots formed are different for each ejection electrode, and an image with stable quality cannot be obtained. In the image forming apparatus disclosed in Japanese Patent Application Laid-Open No. 8-90825, which is supposed to use a conventional liquid developer, if a potential difference occurs between the discharge electrodes 2, the toner that has been electrophoresed from the discharge electrode 2 side to the common electrode side However, there is a risk of electrophoresis toward the discharge electrode 2 having a lower potential.
[0036]
[Discharge test 6]
Walls were formed between the discharge electrodes 2a to 2b and between the discharge electrodes 2b to 2c in order to prevent toner electrophoresis. Then, a test similar to the discharge test 5 was performed. Then, as expected, the toner that was electrophoresed from the discharge electrode 2a side to the discharge electrode 2b side collided with the wall formed between these electrodes and concentrated on the wall surface. Further, the toner that was electrophoresed from the discharge electrode 2c side to the discharge electrode 2b side also collided with the wall formed between these two electrodes and concentrated on the wall surface. However, even if the additional supply of the voltage of +0.2 [kV] to the discharge electrodes 2a and 2c is finished and the potential difference between the discharge electrodes 2 disappears (each +1.0 kV), the toner collected on each wall is discharged to the discharge electrode. The state was maintained as it was with little return on 2a, 2c. Therefore, even if a wall is provided between the ejection electrodes 2, it is not possible to avoid instability of image quality due to toner electrophoresis.
[0037]
On the other hand, the present inventors made a prototype of an electrophoresis test apparatus as shown in FIG. 3 in order to observe the state of electrophoresis of toner in the liquid. In FIG. 3, the migration test apparatus 105 includes a transparent glass plate 106, a T-shaped transparent first electrode 107 laminated on the surface of the transparent glass plate 106, and a migration gap G2 of 100 [μm]. A T-shaped transparent second electrode 108 and the like laminated on the glass plate 106 so as to be in a line-symmetric posture with respect to 107 are provided. Each of the first electrode 107 and the second electrode 108 is made of ITO. A conductive tape 109 is connected to the end of the second electrode 108 laminated with a thickness of 0.15 [μm] so as to be conductive, and the conductive tape 109 is further connected to a power source 110. Further, a grounded conductive tape 111 is connected to the end of the first electrode 107 laminated with the same thickness.
[0038]
In the migration test apparatus 105 having such a configuration, the second electrode 108 corresponds to the ejection electrode 2, and the first electrode 107 corresponds to the counter electrode 9. The present inventors performed the following migration test using this migration test apparatus 105.
[0039]
[Electrophoresis test 1]
For the colored liquid having a lower viscosity than the colored liquid used in the ejection test 4 and a higher viscosity than the conventional liquid developer, the state of electrophoresis of the toner in the migration test apparatus 105 was observed. Specifically, in FIG. 4, a colored liquid 6 having a toner concentration of 15 [wt%] and a viscosity of 100 [mPa · s] is dropped onto the migration gap G2 of 100 [μm] to about 20 [μm]. After squeezing to a thickness, an electrophoretic test apparatus 105 was disposed between a high-speed video camera 112 equipped with a 50 × objective lens and a cold light 113 as a non-heat-generating light source. Then, a positive DC voltage is output from the power supply 111, and the state of the toner that is electrophoresed from the second electrode 108 side to the first electrode 107 side is expressed by a high-speed video camera 112 (Kodak high speed filming camera Model 4540). One frame was shot every / 500 to 1/5000 seconds.
[0040]
When the photographed image was played back in slow motion, “1.0 × 10 5” was observed between the first electrode 107 and the second electrode 108.⁶Even if an electric field having an intensity of “V / m” acts, the toner in the colored liquid 6 does not undergo electrophoresis, and “2.0 × 10 6⁶When an electric field having an intensity of “V / m” was applied, it started to move gradually after a time lag of 100 [msec] or more had elapsed. Therefore, in the colored liquid 6 used in the migration test, the minimum electric field strength that can cause electrophoresis of the toner in the interior is “2.0 × 10 6.⁶V / m ”, and when the electric field having this electric field strength acts for 100 [msec] or more, the toner starts to be electrophoresed (hereinafter, this electric field strength is referred to as electrophoretic starting electric field strength). The electrophoretic velocity of the toner that has started to move is indicated by the electric field strength of “3.0 × 10⁶V / m ”,“ 5.0 × 10⁶V / m "," 7.0 × 10⁶V / m "gradually increases as it gets stronger.⁷It was found that when it reached V / m, it reached 1 to 10 [mm / sec].
[0041]
[Electrophoresis test 2]
A migration test similar to the migration test 1 was performed using a conventional liquid developer (1 wt%, 1.5 mPa · s). Then, the toner in the liquid developer is “1.0 × 10⁶It was found that the electrophoresis started immediately at a speed of 1 to 10 [mm / sec] only by the action of the electric field having the intensity of “V / m”. Accordingly, in the conventional liquid developer, the migration start electric field strength of the toner inside the liquid developer is “1.0 × 10 6.⁶It is much weaker than “V / m” and “1.0 × 10”⁶If an electric field having an intensity of “V / m” or more acts, the toner will immediately start electrophoresis without a time lag. In the discharge tests 5 and 6 using such a liquid developer, “2.0 × 10 6” is provided between the discharge electrode 2 b and the discharge electrode 2 a and between the discharge electrode 2 b and the discharge electrode 2 c.⁶An electric field with an intensity of “V / m” is formed. Since the electric field having such an intensity has acted on the toner in the liquid developer, the toner immediately starts high-speed migration, and gathers on the discharge electrode 2b from the discharge electrode 2a or the discharge electrode 2c in a short time of 1 [msec]. It has been done.
[0042]
The reason why the migration start electric field strength of the toner in the migration test 2 is significantly weaker than the migration start electric field strength of the toner in the migration test 1 is considered as follows. That is, the toner in the liquid developer having a low viscosity (1.5 mPa · s) can be electrophoresed by pushing away the liquid carrier surrounding the toner, whereas the toner in the colored liquid 6 having a high viscosity (100 mPa · s). The toner must be electrophoresed along with the surrounding liquid carrier. For this reason, it is considered that a stronger electrostatic force needs to be applied for migration. In addition, since the toner dispersed in the liquid developer having a low toner concentration (1 wt%) is kept at a certain distance from other toners, it can be electrophoresed almost without being affected by the charge of other toners. Can do. On the other hand, each toner dispersed in the colored liquid 6 having a high toner concentration (15 wt%) is in a state of being close to each other and receives electrostatic repulsion due to the charge of the surrounding toner. It is considered that a stronger electrostatic force needs to be given to the.
[0043]
Since the colored liquid (viscosity: 500 mPa · s) used in the above-described ejection test 4 has a higher viscosity than the colored liquid (viscosity: 100 mPa · s) used in the migration test 1, the toner migration start electric field It is thought that the strength has also increased. That is, “2.0 × 10⁶It is thought that it is stronger than “V / m”. In the discharge test 4, between the discharge electrode 2b and the discharge electrode 2a or between the discharge electrode 2b and the discharge electrode 2c, “2.0 × 10⁶An electric field having an intensity of “V / m” is formed, but this intensity was weaker than the migration starting electric field intensity of the colored liquid having a viscosity of 500 [mPa · s], so that the toner on the ejection electrodes 2a and 2c It is considered that electrophoresis could not be performed toward It should be noted that the toner migration start electric field strength in a colored liquid having a viscosity of 500 [mPa · s] is the same as that in a colored liquid having a viscosity of 100 [mPa · s] “2.0 × 10”.⁶Even if it is “V / m”, the toner does not undergo electrophoresis unless an electric field of such intensity acts for 100 [msec] or more. In the above discharge test 4, since the electric field between the discharge electrodes 2 acts on the toner only for 1 [msec], even if the toner migration start electric field strength and the electric field strength between the discharge electrodes 2 are the same. The toner did not electrophorese.
[0044]
On the other hand, in the discharge test 4, between the grounded counter electrode 9 and the discharge electrodes 2a and 2c to which the discharge voltage (1.0 + 0.2 kV) of +1.2 [kV] is applied (gap G1 = 120 μm). Is “1.0 × 10” respectively.⁷An electric field for discharge having an intensity of “V / m” is formed. This strength is stronger than the migration start electric field strength of the toner in the colored liquid used in the ejection test 4, and countless toners existing near the tip of the ejection electrode 2b are opposed to each other by attracting the high-viscosity liquid carrier by the influence of the electric field. In order to perform electrophoresis toward the electrode 9 with a strong force, it is considered that the colored liquid has risen from the tips of the ejection electrodes 2a and 2c.
[0049]
  In view of the above discharge test and migration test, claims5The invention of claim4In this image forming apparatus, the plurality of substrates are arranged in the moving direction of the recording member.
[0050]
In this image forming apparatus, a dot formed by a substrate disposed on the downstream side in the moving direction is formed by interposing a gap between dots formed on the recording member by the substrate disposed on the upstream side in the moving direction of the recording member. Can be filled with. Therefore, even when a relatively high resolution image such as 600 [dpi] is formed, the distance between the parallel electrodes is ensured to some extent, and the electric field strength between the parallel electrodes is more surely less than the migration start electric field strength. can do.
[0051]
  Claim6The invention of claim4In the image forming apparatus, a substrate moving means for moving the substrate in the direction in which the parallel electrodes are arranged is provided, and the recording member is moved along a moving path that repeatedly passes through a position facing the tip of each parallel electrode. The recording member moving means is configured as described above.
[0052]
In this image forming apparatus, unlike the image forming apparatus according to claim 11, which uses a plurality of substrates, the gap between the dots can be filled by going through the following process. become. That is, first, a plurality of dots arranged with a gap are formed on a recording member that passes through a position facing the tip of each parallel electrode. Next, after the substrate is moved a little in the direction in which the parallel electrodes are arranged (hereinafter referred to as the main scanning direction) by the substrate moving means, the gap portion of the recording member that is moved again to the opposing position by the recording member moving means To form dots. If these series of processes are performed a number of times according to the size of the gap, it is possible to fill the gap between the dots using a single substrate. Therefore, even when a relatively high resolution image is formed, the distance between the parallel electrodes can be secured to some extent, and the electric field strength between the parallel electrodes can be more reliably less than the migration start electric field strength. In addition, the number of parallel electrodes and expensive HVICs can be greatly reduced as compared with the image forming apparatus of claim 11 using a plurality of substrates.
[0053]
  Claim7The invention of claim4In the image forming apparatus, the recording member moving means is configured to move the recording member also in the arrangement direction of the parallel electrodes.
[0054]
In this image forming apparatus, instead of moving the substrate in the main scanning direction as in the image forming apparatus according to claim 12, the recording member is moved in the main scanning direction, so that a single substrate is used to move between the dots. It becomes possible to fill the gap. Therefore, even when a relatively high resolution image is formed, the distance between the parallel electrodes can be secured to some extent, and the electric field strength between the parallel electrodes can be more reliably less than the migration start electric field strength. In addition, the number of parallel electrodes and expensive HVICs can be greatly reduced as compared with the image forming apparatus of claim 11 using a plurality of substrates.
However, in this image forming apparatus, if an image is formed by the following process, the image forming speed is decreased by reciprocating the recording member in the main scanning direction many times. That is, first, the recording member is temporarily stopped in the sub-scanning direction (the passing direction of the recording member at the opposite position) to form each dot, and then the recording member is moved slightly in the main scanning direction. The dots are formed so as to fill the intervals between the dots. Then, after the dots are formed by moving the recording member a little in the sub-scanning direction so that the new region of the recording member faces each parallel electrode, the recording member is moved in the main scanning direction opposite to the above, Dots are formed to fill In such a series of processes, an image is formed while the recording member is repeatedly reciprocated in the main scanning direction. The number of reciprocating movements varies depending on the length of the recording member in the main scanning direction, the resolution of the formed image, etc., but is at least several tens of times for an A4 size recording member, and the recording member moves in the sub-scanning direction. The number of times of stopping is in units of one hundred to several hundred times twice this. In this process in which the movement of the recording member in the sub-scanning direction needs to be stopped many times as described above, naturally, the image forming speed is slowed down by repeatedly stopping the recording member.
[0055]
  Therefore, the claim8The invention of claim7In this image forming apparatus, the recording member moving means is configured to move the recording member along a movement path that repeatedly passes the facing position.
[0056]
In this image forming apparatus, an image can be formed by the following process. That is, first, dots that are spaced are sequentially formed while moving in the sub-scanning direction without stopping the recording member, and the recording member that has passed through the position facing the tip of each parallel electrode is slightly moved in the sub-scanning direction. It is moved and moved again to the opposite position, and dots are sequentially formed so as to fill the interval. In this process, since the image can be formed without stopping the movement of the recording member in the sub-scanning direction or repeatedly reciprocating in the main scanning direction, the recording member is repeatedly reciprocated in the main scanning direction. Therefore, it is possible to avoid a reduction in image forming speed due to the above.
[0057]
  Claim9The invention of claim 1, 2, 3, 4, 5, 6, 7Or 8In this image forming apparatus, an intermediate recording member is used as the recording member to which the colored liquid from the front ends of the parallel electrodes is attached, and transfer means for transferring an image formed on the intermediate recording member to another recording member is provided. It is characterized by comprising.
[0058]
In this image forming apparatus, after a specific type of intermediate recording member is conveyed to a recording position between the counter electrode and each parallel electrode and an image is recorded thereon, various types of paper such as plain paper, cardboard, and OHP sheet are used. Transfer to a type of recording member. Therefore, unlike when images are recorded on various types of recording members at the recording position, the liquid moving distance from the front end of the substrate to the intermediate recording member at the recording position, the liquid adhesion to the intermediate recording member, the intermediate recording The liquid repellency on the member is kept constant. Therefore, it is possible to form a stable quality image regardless of the type of recording member used without changing the image quality due to changes in the liquid movement distance, liquid adhesion, and liquid repulsion. Can do.
[0059]
  Claim 10The invention of claim 1, 2, 3, 4, 5, 6, 7Or 8In the image forming apparatus, a conveying means for conveying the recording member to a recording position between the counter electrode and each parallel electrode, and a discharging means for discharging the recording member on which an image is recorded at the recording position to the apparatus main body. And is provided.
[0060]
In this image forming apparatus, unlike the image forming apparatus according to claim 15, in which an image is once recorded on an intermediate recording member and then transferred to another recording member, final paper such as plain paper, cardboard, and OHP sheet is recorded at the recording position. Since an image is directly recorded on a new recording member, an intermediate recording member and a transfer unit are not necessary. Therefore, it is possible to eliminate the increase in size and cost of the apparatus due to the provision of these intermediate recording members and transfer means.
[0061]
The invention according to claim 17 includes charged colored particles and a liquid carrier between a substrate having a plurality of parallel electrodes arranged in parallel at a predetermined pitch and a facing plate facing the electrode surface. Holding the colored liquid, a step of causing a potential difference between the parallel electrode and the counter electrode opposed to the tip of each parallel electrode of the substrate through a predetermined gap, and the colored particles on the parallel electrode In an image forming method for forming an image by performing a step of discharging from the tip toward the counter electrode side by a potential difference and a step of attaching the discharged colored particles to a recording member, In such a state that the particles are dispersed in a liquid carrier and discharged from the tip of the parallel electrode by the potential difference and adhere to the recording member, and at least the colored liquid is discharged from the tip. When to is characterized in that moving the said parallel electrodes provided adjacent the colored liquid present between the parallel electrodes on the substrate.
[0062]
In this image forming method, the common electrode is made to face each parallel electrode, the tip of each parallel electrode is tapered, and the device used for image formation has the same action as the image forming apparatus of claim 1 An image can be formed without employing a complicated electrode configuration in which the tapered portion protrudes toward the counter electrode rather than the common electrode.
Further, without providing a partition wall between the parallel electrodes of the apparatus used for image formation, it is possible to suppress the dragging of the nearby colored liquid due to the colored liquid protruding from the tip of the parallel electrode.
[0063]
DETAILED DESCRIPTION OF THE INVENTION
First, before describing the image forming apparatus according to the embodiment, the tests performed to complete the present invention will be described in a little more detail.
[Discharge test 7]
In the discharge test 4, a common voltage of +1.0 [kV] is applied to each of the discharge electrodes 2a, 2b, and 2c, and a voltage of +0.2 [kV] is added and applied only to the discharge electrode 2b. The potential difference between the discharge electrodes 2 was reduced. The discharge voltage required to discharge the colored liquid 6 from the tip of the discharge electrode 2 is +1.2 [kV], but the common voltage is set higher than +1.0 [kV] and is increased by that amount. If the discharge voltage is lowered and the discharge voltage is adjusted to +1.2 [kV], the potential difference between the discharge electrodes 2 can be further reduced.
[0064]
Therefore, the inventors of the present invention conducted a test similar to the discharge test 4 while gradually increasing the common voltage from +1.0 [kV] and lowering the additional voltage by less than +0.2 [kV]. Went. Then, the colored liquid 6 raised from the tip of the discharge electrode 2b cannot be reliably attached to the plain paper, or the colored liquid 6 raised from the discharge electrodes 2a and 2b by applying a common voltage to the plain paper. In some cases, it should not be attached, but it was attached. This is because the adhesion between the counter electrode 9 and the plain paper is changed for each test and the distance between each discharge electrode 2 and the plain paper is changed, or the viscosity of the colored liquid 6 is changed every day.
[0065]
When the same discharge test was repeatedly performed, the colored liquid 6 to be adhered to the plain paper was surely adhered and the colored liquid 6 that should not be adhered to the plain paper even when such a distance change or viscosity change occurred. It was found that in order to prevent the adhesion, it is necessary to secure a potential difference of 0.2 [kV] or more between the common voltage and the additional voltage.
[0066]
[Piezo inkjet test]
A conventional liquid developer (toner concentration: 1 wt%, viscosity: 1.5 wt%) was accommodated in a multilayer piezo ink jet apparatus made by the present inventors and printed on plain paper. As a result, dots with a very large diameter of about 180 [μm], a thin image density of 0.89 [ID], and blurring around were formed. It is considered that such poor quality dots are formed because the liquid developer scatters when landing on plain paper, flows along the paper fiber, or enters the paper fiber. Therefore, in the ejection test apparatus 100 shown in FIG. 1, even if the conventional liquid developer can be ejected from the tip of the ejection electrode 2, only low-quality dots can be formed as in this test. On the other hand, in the above-described discharge test 4, the colored liquid 6 (15%, 100 mPa · s) does not scatter on the plain paper, does not flow along the paper fiber, and does not enter the paper fiber. Small dots (100 μm), high image density (1.41 [ID]), and sharp edges were formed.
[0067]
[Discharge test 8]
The present inventors applied the ejection test apparatus 100 shown in FIG. 1 to create the following simple recording bed. That is, the discharge electrodes 2a, 2b, and 2c of 100 [μm] width (W2) in FIG. 1 are laminated in parallel on the glass plate 102 with a gap of 50 [μm], respectively, and then the non-electrode of the glass plate 102 Using a mask material provided with openings corresponding to the portions, a primer was spray applied to the non-electrode portions. Next, this primer was dried in an environment of 80 [° C.] for 30 minutes to form a primer layer having a thickness of 0.1 [μm] on the non-electrode portion of the glass plate 102. Further, using the above mask material, the primer layer is spray-coated with a fluorine-containing resin solution (manufactured by Asahi Glass Co., Ltd .: trade name Cytop), and heat-treated in an environment of 120 [° C.] for 2 hours to obtain a thickness A fluororesin film of 0.4 [μm] was formed. A simple recording head was prepared by facing the facing glass plate to the electrode forming surface of the glass plate 102 on which the fluororesin coating was formed in this way with a gap of 30 [μm]. The formed fluororesin film was firmly fixed to the glass plate 102 through the primer layer.
[0068]
A colored liquid 6 having a toner concentration of 15 [wt%] and a viscosity of 500 [mPa · s] is introduced from the rear end of the plate into a gap of 30 [μm] between the glass plate 102 of the simple recording head and the facing glass plate. Injected towards the tip. Then, in the non-electrode portion of the glass plate 102, the colored liquid 6 was repelled by the excellent liquid repellency of the fluororesin coating to form a cavity. In the colored liquid 6 having a high viscosity and a strong surface tension, the cavity is larger than a liquid having a relatively low surface tension such as water. The injected colored liquid 6 was applied with pressure to the extent that it did not spill from the tip of the simple recording head. The counter electrode 9 was opposed to the tip of the simple recording head into which the colored liquid 6 was injected in this way through a gap of 120 [μm] and grounded. Then, after applying a voltage of +1.0 [kV] to the discharge electrodes 2a, 2b and 2c, respectively, a pulse voltage of +0.2 [kV] and 5 [msec] width is applied only to the discharge electrodes 2a and 2c at both ends. An attempt was made to form dots by applying the image on top. Then, the colored liquid 6 in the simple recording head did not rise from the tip of the discharge electrode 2b to which no pulse voltage was applied, but rose from the tip of the discharge electrodes 2a and 2b to which the pulse voltage was applied. Then, two dots were formed that adhered to the side surface of the glass plate 101 holding the counter electrode 9 and arranged with a gap.
[0069]
In the prototype simple recording head, the surface tension of the colored liquid 6 raised from the tip of each of the discharge electrodes 2a and 2c is caused by the color on the discharge electrode 2b by forming a cavity between the discharge electrodes by the fluororesin film. It is difficult to reach the liquid 6. As a result, the dragging of the colored liquid 6 on the ejection electrode 2b by the raised colored liquid 6 is suppressed, and the two dots are neatly formed without the colored liquid 6 being raised from the tip of the ejection electrode 2b.
[0070]
However, when such 2 dot formation is repeated, rarely the colored liquid 6 rises from the tip of the discharge electrode 2b and adheres to the side surface of the glass plate 101 on which the counter electrode 9 is formed, and the 3 dots are connected. Sometimes formed. The state at this time was photographed with a high-speed camera, and when the photographed image was slowly reproduced and observed, the colored liquid 6 actually protrudes from the facing glass plate portion facing this tip, not the tip of the discharge electrode 2b. I found out. When the simple recording head is closely observed from the side, as shown in the longitudinal section of FIG. 5A and the front of FIG. 5B, the cavity 11 is surely formed on the fluororesin coating 5 of the glass plate 102. However, this was not connected to the facing glass plate 114, and a layer of the colored liquid 6 was formed on the upper side of the cavity 11.
[0071]
In this discharge test 8, the strength of the electric field formed between the discharge electrodes 2 is “(0.2 × 10³) / (50 × 10^-6) = 4.0 × 10⁶V / m ”, however, even when an electric field of this strength was applied to the toner on the glass plate 102 for 5 [msec], the toner was not electrophoresed between the ejection electrodes 2.
[0072]
[Discharge test 9]
Also on the facing glass plate 114, a fluororesin film similar to the glass plate 102 is formed in a portion facing the discharge electrode 2 to recreate the simple recording head, and then the colored liquid 6 is injected. Observed well from. Then, as shown in the longitudinal section of FIG. 6A and the front of FIG. 6B, the colored liquid 6 is repelled by the fluororesin coating 3 on the facing glass plate 114 side, and the cavity 11 faces the glass plate 102. Connected between the 114 glass plates. For this reason, between the two plates, the colored liquid 6 was not completely present on the non-electrode portion.
[0073]
In this state, the formation of 2 dots was repeated in the same manner as in the ejection test 8 described above. As a result, the colored liquid 6 did not bulge from the tip of the ejection electrode 2b no matter how many times it was performed, leaving a gap. Two aligned dots were formed neatly.
[0074]
However, while 2 dots are continuously formed, the colored liquid 6 is rarely discharged from the tips of the discharge electrodes 2a and 2c, so that dots are not formed. When the situation before and after this was observed by slow reproduction of the photographed image, the following phenomenon was observed. That is, pressure is applied to the colored liquid 6 in the simple recording head from the rear end of the head as needed so that the colored liquid 6 does not spill from the front end of the head. For this reason, basically, even if the colored liquid 6 is consumed in the vicinity of the head tip due to the formation of dots, the colored liquid 6 moves from the head rear end and is supplied to the head tip. However, when continuous recording is performed, this supply may not be able to catch up, and a portion where the colored liquid 6 is interrupted in the length direction on the ejection electrodes 2a and 2c occurs. When this portion moved to the head tip with continuous recording, the colored liquid 6 was not discharged from the tip of these discharge electrodes.
[0075]
[Discharge test 10]
The inventors of the present invention have made various attempts to improve the replenishability of the colored liquid 6 to the head tip, and form the fluororesin coatings 3 and 5 only in a limited region from the head tip to the rear end. Then, it discovered that a favorable replenishment property was acquired. In such a configuration, the amount of the colored liquid 6 per unit area is larger in the region where the fluororesin coatings 3 and 5 are formed from the front end to the rear end of the head than in the region where the fluororesin coatings 3 and 5 are formed. As described above, the colored liquid 6 is smoothly supplied from the region where the amount of the colored liquid 6 is increased toward the tip of the head having a small amount. However, it is necessary to appropriately set the length from the head tip of the region where the fluororesin coatings 3 and 5 are formed. If the length from the tip of the head is less than 0.2 [mm], the surface tension of the colored liquid 6 raised from the tips of the ejection electrodes 2a and 2c is sufficiently transmitted to the colored liquid 6 on the ejection electrode 2b. Thus, dragging out of the latter colored liquid 6 by the former colored liquid 6 was observed. If the length from the head front end exceeds 0.9 mm, the supply of the colored liquid 6 from the head rear end side to the head front end side is not smoothly supplied, and the color liquid on the ejection electrodes 2a and 2c is not supplied. It was confirmed that 6 was cut off halfway. Therefore, the length from the tip of the head in the region where the fluororesin coatings 3 and 5 are formed is preferably set to 0.2 [mm] or more and 0.9 [mm] or less.
[0076]
Next, an embodiment in which the present invention is applied to a printer which is an image forming apparatus will be described.
FIG. 7 is a cross-sectional view showing the main part of the recording head of the printer according to this embodiment. In FIG. 7, a recording head 1 includes an insulating substrate 4 on which a plurality of ejection electrodes 2 as parallel electrodes are formed, and an insulating plate as a facing plate facing the electrode forming surface with a gap of 30 [μm]. And a sex top plate 13. This gap serves as a liquid chamber of the recording head 1, and a viscosity of 500 [mPa], in which the toner, which is a positively charged colored particle, is contained in polysiloxane oil as a liquid carrier at a concentration of 15 wt%. Contains s] colored liquid 6 The colored liquid 6 is appropriately supplied to the liquid chamber by a replenishing means (not shown).
[0077]
The toner in the colored liquid 6 is obtained by dispersing a pigment made of carbon black in a matrix made of epoxy resin, and has an average particle size of 2.0 [μm], a specific gravity of 1.0, and an average charge amount of +60 [μC / g. ] Has been adjusted. In the discharge test 4, the value of the discharge voltage for forming the discharge electric field having the adhesion strength was +1.2 [kV], but this value varies depending on the configuration of the apparatus. Even for colored liquids having the same toner concentration and viscosity, if the average particle diameter, specific gravity, average charge amount, etc. of the toner are different, the required discharge voltage and the toner migration start electric field strength are also different.
[0078]
Each ejection electrode 2 is formed so as to be electrically independent, and a voltage of +1.0 [kV] is commonly applied to each ejection electrode 2 from the power source 8a when the recording head 1 is driven. A voltage of +0.2 [kV] is applied for 5 [msec] to each discharge electrode 2 to form dots by controlling the voltage ON / OFF driver 10 connected to the power source 8c. The As a result of this extra application, a discharge voltage of +1.2 [kV] is applied to the discharge electrode 2 where dots are to be formed by 5 [msec].
[0079]
The insulating top plate 13 and the insulating substrate 14 are partially coated with fluororesin films 3 and 5, respectively.
[0080]
FIG. 8 is a perspective view showing the insulating substrate 4. In the drawing, 2480 discharge electrodes 2 having a width W3 of 34.7 [μm] are arranged in parallel with a gap (pitch = 84.7 μm) of 50 [μm]. With these discharge electrodes 2, an image can be formed in an area corresponding to A4 lateral width (210 mm). A dot pitch of 84.7 [μm] corresponds to a resolution of 300 [dpi]. Further, it has been confirmed by the present inventors that each ejection electrode 2 having a width W3 of 34.7 [μm] forms a dot having a diameter of about 60 [μm].
[0081]
Between the discharge electrodes 2, the above-described fluororesin coating 5 is coated only in a region having a length L <b> 1 from the front end to the rear end of the insulating substrate 4. In the printer according to the present embodiment, the length L1 is set to 0.5 [mm]. Further, the fluororesin coating 3 of the insulating top plate 13 is formed only on the portion facing the fluororesin coating 5. In the part where the fluororesin coating 5 and the fluororesin coating 5 face each other, as shown in FIG. 7, the colored liquid 6 is repelled by both coatings to form a cavity 11 in which the colored liquid 6 does not exist.
[0082]
FIG. 9 is a schematic configuration diagram of the printer according to the present embodiment. In FIG. 9, the printer includes two recording heads 1, an intermediate recording drum 20, a paper feed cassette 21, a registration roller pair 22, a transfer roller 23, a power supply 8d, a fixing device 24, a drum cleaning device 26, and the like.
[0083]
The intermediate recording drum 20 is formed by coating a peripheral surface of a grounded aluminum drum 20a as a counter electrode with a high resistance rubber layer 20b as an intermediate recording member with a thickness of 0.03 [mm]. It is rotated in the direction of the arrow in the figure at a peripheral speed of 40 [mm / sec] by the driving means that does not.
[0084]
Two recording heads 1 are stacked on the right side of the intermediate recording drum 20 in the drawing so as to face the intermediate recording drum 20 with a gap of 120 [μm]. Each of the recording heads 1 is arranged such that the lower one in the drawing is shifted by 42.3 [μm] from the upper one in the drawing. That is, the two recording heads 1 are arranged so as to be shifted in the main scanning direction by 42.3 [μm] corresponding to a dot pitch of 600 [dpi].
[0085]
The transfer roller 23 is in contact with the lower peripheral surface of the intermediate recording drum 20 in the figure to form a transfer nip. In this transfer nip, a transfer electric field is formed by the potential difference between the grounded aluminum drum 20a of the intermediate recording drum 20 and the transfer roller 23 to which a negative positive transfer bias is applied by the power source 8d.
[0086]
The paper feeding cassette 21 accommodates a transfer paper 25 as a recording member therein, and the uppermost bundle of transfer paper 25 accommodated therein is rotated by rotating the paper feeding roller 21a. Send out toward pair 22.
[0087]
In the printer according to the present embodiment, for example, when a one-line image extending in the main scanning direction is formed on the transfer paper 25, the following process is performed. That is, first, of the two recording heads 1, the one positioned on the upper side in the drawing is approximately 60 [ 2480 dots Dt having a diameter of μm] are formed at a pitch of 84.7 [μm]. Next, the dot Dt having a diameter of about 60 [μm] is similarly formed at a position where the recording head 1 located on the lower side in the figure is displaced by 42.3 [μm] from the upper recording head 1 in the main scanning direction. 2480 pieces are formed at a pitch of 84.7 [μm] (FIG. 10B). At this time, the dots Dt formed by the lower recording head 1 are located in the gaps between the dots Dt formed by the upper recording head 1 to fill the gaps, thereby forming a one-line image. .
[0088]
The image formed on the high resistance rubber layer 20b of the intermediate recording drum 20 by the two recording heads 1 enters the transfer nip as the drum rotates.
[0089]
On the other hand, prior to this entry, the paper feed cassette 21 feeds the transfer paper 25 toward the registration roller pair 22. The registration roller pair 22 sandwiches the transferred transfer 25 between both rollers, and sends it toward the transfer nip in a timing that allows the transfer 25 to overlap the image on the high resistance rubber layer 20b at the transfer nip.
[0090]
The image on the high-resistance rubber layer 20b superimposed on the transfer paper 25 at the transfer nip is transferred onto the transfer paper 25 by the action of the transfer electric field or nip pressure, and then the heating roller 24a in the fixing device 24 and It is sandwiched between the pressure roller 24b and the toner is melted while being pressed. The image is fixed on the transfer paper 25 by the pressurization and the melting of the toner. After the fixing, the transfer paper 25 is discharged from the fixing device 24 to the outside of the apparatus.
[0091]
The residual colored liquid adhering to the high resistance rubber layer 20b after passing through the transfer nip is scraped off by the cleaning blade 26a of the drum cleaning device 26.
[0092]
In the printer having the above-described configuration, even if the aggregate of the colored particles 6 is not generated at the tip of the discharge electrode 2, the colored liquid 6 is discharged from the tip and adhered to the high resistance rubber layer 20b. The assembly can be attached to the high resistance rubber layer 20b to form an image. Therefore, unlike the image forming apparatus disclosed in JP-A-8-90825, it is not necessary to generate toner aggregates at the tip of the ejection electrode 2. For this reason, a complicated electrode configuration in which the common electrode 14 faces each discharge electrode 2, the tip of each discharge electrode 2 is tapered, and the tapered portion protrudes toward the counter electrode 9 from the common electrode 14. An image can be formed without adopting it.
[0093]
Further, the fluororesin coating 5 provided in the region from the tip of the recording head 1 to 0.5 [mm] (L1) between the ejection electrodes 2 on the insulating substrate 4 and the insulating ceiling so as to face this. Both the fluororesin film 3 formed on the plate 13 repels the colored liquid 6 near the head tip between the discharge electrodes 2 toward each discharge electrode 2, whereby each discharge electrode 2 near the head tip. A cavity is formed between them. Since this cavity is formed from the surface of the insulating substrate 4 to the surface of the insulating top plate 13, the colored liquid 6 is not completely present between the ejection electrodes 2 near the head tip. For this reason, the surface tension of the colored liquid 6 raised from the tip of the ejection electrode 2 is not transmitted to the colored liquid 6 on the adjacent ejection electrode 2, and the former colored liquid can be used even if continuous recording is performed. The latter dragging of the latter colored liquid can be reliably suppressed.
[0094]
Further, by setting the length of the fluororesin coatings 3 and 5 to 0.5 [mm] (L1) from the tip of the recording head 1, while suppressing the dragging of the colored liquid 6 due to being set too short, Insufficient supply of the colored liquid 6 onto each discharge electrode 2 due to being set too long can be suppressed.
[0095]
Further, the toner concentration of the colored liquid 6 on each discharge electrode 2 is kept uniform without causing the toner to migrate between the discharge electrodes 2 while the recording head 1 is driven. For this reason, the density and the size of the dots formed on the high resistance rubber layer 20b by each discharge electrode 2 can be maintained uniformly.
[0096]
Further, by using the high-concentration and high-viscosity colored liquid 6 having a toner concentration of 15 [wt%] and a viscosity of 500 [mPa · s], the toner migration start electric field strength is raised to avoid the migration, and the toner It is possible to reliably form an electric field that is equal to or higher than the adhesion strength required for the discharge between each discharge electrode 2 and the aluminum drum 20b.
[0097]
Further, since the gap between the dots Dt formed by the recording head 1 on the upstream side in the drum rotation direction can be filled with the dots Dt formed by the recording head 1 on the downstream side, the dot diameter 60 [μm], the dot pitch Although the image of 42.3 [μm] and 600 [dpi] is formed, the distance between the discharge electrodes 2 is secured by 50 [μm], and the electric field strength between the discharge electrodes 2 is further ensured. It can be less than the electrophoretic starting electric field strength.
[0098]
In Japanese Patent No. 2920960, an image forming apparatus in which a liquid repellent film is provided on a recording head is described. However, unlike this printer, this has an ability to discharge colored liquid (ink) from the front end of the recording head. In order to increase, a liquid repellent film is provided only on the electrodes, not between the electrodes.
[0099]
Next, printers according to the respective examples in which a more characteristic configuration is added to the printer according to the present embodiment will be described.
[Example 1]
FIG. 11 is a schematic configuration diagram showing the intermediate recording drum 20 of the printer according to the first embodiment together with the peripheral devices. As shown, this printer has only one recording head 1. That is, the number of recording heads 1 is half that of the printer of the embodiment. The recording head 1 is provided with a head moving means (not shown) as a substrate moving means for moving the recording head 1 in the main scanning direction (depth direction in the figure). Further, a marker detection sensor 27 for detecting a marker image formed on the high resistance rubber layer 20b of the intermediate recording drum 20 is disposed upstream of the recording head 1 in the drum rotation direction. The drum cleaning device 26 is provided with a cleaning contact / separation means (not shown) for contacting and separating the drum cleaning device 26 from the intermediate recording drum 10. Further, the transfer roller 23 is also provided with a roller contact / separation means (not shown) that contacts and separates the transfer roller 23 from the intermediate recording drum 10.
[0100]
The voltage ON / OFF driver 10 shown in FIG. 7 is provided with 2480 expensive HVICs for individually switching ON / OFF of voltage application to 2480 ejection electrodes 2. Therefore, in the printer according to the first embodiment, not only the number of recording heads 1 is reduced to ½, but the number of expensive HVICs is also reduced to ½.
[0101]
In this printer, an image is formed by the following process. That is, first, when the image forming operation of the printer main body is started, the transfer roller 23 and the drum cleaning device 26 are moved away from the drum surface by the roller contact / separation means and the cleaning contact / separation means, respectively. Next, a control unit (not shown) converts image information sent from a personal computer or the like into output image information for 600 [dpi], which is further converted into 1 for 300 [dpi] with a pitch of 84.7 [μm]. The image is divided into the next output image information and the secondary output image information. Then, a control signal based on the image information is sent to the recording head 1.
[0102]
When the recording head 1 receives the control signal based on the primary output image information, the recording head 1 first forms the marker image in the non-image area of the high resistance rubber layer 20b in the intermediate recording drum 20 that rotates in the arrow direction in the figure. Thereafter, a primary image based on the primary output image information is formed in the image region of the high resistance rubber layer 20b. Thereby, a marker image and a primary image are formed on the high resistance rubber layer 20b. After the primary image is formed, the recording head 1 is moved by the head moving means while the intermediate recording drum 20 returns to the recording position which is the position where the drum and the recording head 1 are opposed. It can be moved by 42.3 [μm] from the near side to the far side in the figure.
[0103]
When the marker image passes through the marker detection sensor 27 as the intermediate recording drum 20 rotates, the marker detection sensor 27 detects the marker image and sends a detection signal to the control unit. Based on this detection signal, the control unit sends a control signal based on the secondary output image information to the recording head 1 at an appropriate timing.
[0104]
Upon receiving this control signal, the recording head 1 forms a secondary image based on the secondary output image information so as to be superimposed on the primary image. By this superposition, the gap between the dots of the primary image is filled, and an image of 600 [dpi] is formed on the high resistance rubber layer 20b.
[0105]
Prior to this image entering the transfer nip, the transfer roller 23 and the drum cleaning device 26 are moved to contact the intermediate recording drum 20.
[0106]
After the image formed on the surface of the high resistance rubber layer 20b is transferred onto the transfer paper 25 at the transfer nip, the remaining colored liquid remaining on the surface is scraped off by the cleaning device 26.
[0107]
In the printer configured as described above, although the image forming speed is reduced to ½ or less of that of the printer of the embodiment, the number of the recording heads 1 and expensive HVICs can be reduced to ½ to reduce the cost. .
[0108]
[Example 2]
The main configuration of the printer of the second embodiment is almost the same as that of the first embodiment shown in FIG. However, in this printer, instead of providing the head moving means in the recording head 1, drum moving means (not shown) for moving the intermediate recording drum 20 in the main scanning direction is provided. The image forming process in the printer is the same as that of the first embodiment except that the intermediate recording drum 20 is moved in the main scanning direction instead of moving the recording head 1 in the main scanning direction.
[0109]
Here, in this printer, it is also possible to form an image by the following process. That is, first, immediately after the image area of the high-resistance rubber layer 20b of the intermediate recording drum 20 enters the recording position as the drum rotates, the rotation of the drum is temporarily stopped and each dot is formed by the recording head 1. Then, after the intermediate recording drum 10 is moved by 42.3 [μm] in the main scanning direction by the drum moving means, each dot is formed by the recording head 1. Next, after rotating the intermediate recording drum 10 by 42.3 [μm] to form each dot by the recording head 1, the recording head is moved in the main scanning direction opposite to the previous one, and each dot is formed. carry out. By repeating the above series of processes until the intermediate recording drum 20 is rotated by the length of the transfer paper 25, an image of 600 [dpi] can be formed on the high resistance rubber layer 20b.
[0110]
However, in such a process, the intermediate recording drum 20 is reciprocated in the sub-scanning direction while stopping the rotation of the intermediate recording drum 20 an enormous number of times, thereby significantly reducing the image forming speed. On the other hand, in this printer, an image can be formed without slowing the image forming speed in this way.
[0111]
Also in the printer having the above configuration, the number of recording heads 1 and expensive HVICs can be reduced to ½ to reduce the cost.
[0112]
[Example 3]
FIG. 12 is a schematic configuration diagram of a printer according to the third embodiment. In the figure, the grounded counter electrode 9 is opposed to the tips of the three recording heads 1 with a gap of 120 [μm]. When the transfer paper 25 sent out from the paper feed cassette 21 enters a recording position where the three recording heads 1 and the counter electrode 9 face each other, an image is recorded on the front surface of the transfer paper 25 while the back surface is in close contact with the counter electrode 9. The
[0113]
In the printer having such a configuration, the intermediate recording drum 20 and the transfer roller 23 are not provided, so that the apparatus main body can be made compact as illustrated.
[0114]
【The invention's effect】
  Claims 1, 2, 3, 4, 5, 6, 7, 8, 9Or 10According to this invention, without providing a partition wall between each parallel electrode, there exists an outstanding effect that the drag of the colored liquid of the vicinity by the colored liquid which protruded from the front-end | tip of a parallel electrode can be suppressed.Furthermore, there is also an excellent effect that insufficient supply of the colored liquid onto each parallel electrode can be suppressed.
[0118]
SpecialAnd claims2According to the invention, the fluororesin coating has an excellent effect that the colored liquid existing between the parallel electrodes can be favorably moved to the adjacent parallel electrodes.
[0120]
  In particular, the claims3According to the invention, the length of the liquid repellent coating from the front end of the substrate is suppressed to be set too short, and the dragging of the colored liquid is suppressed, while the length is set on the parallel electrodes. There is an excellent effect that shortage of supply of colored liquid can be suppressed.
[0121]
  In particular, the claims4, 5, 6, 7 or 8According to the invention, it is possible to form not only a one-dimensional line image in which a plurality of dots are arranged in a straight line but also a two-dimensional image such as a character image or a video image.
[0124]
  In particular, the claims5, 6, 7 or 8According to the invention, even when a relatively high-resolution image is formed, the distance between the parallel electrodes can be secured to some extent, and the electric field strength between the parallel electrodes can be more surely made less than the migration start electric field strength. There is an excellent effect of being able to.
[0125]
  In particular, the claims6, 7 or 8According to the invention, a plurality of substrates are used.ConstitutionRather, the number of parallel electrodes and expensive HVIC can be greatly reduced.
[0126]
  In particular, the claims8According to the invention, there is an excellent effect that it is possible to avoid the reduction in the image forming speed due to the reciprocating movement of the recording member in the main scanning direction.
[0127]
  And especially claims9According to the invention, there is an excellent effect that an image having a stable quality can be formed regardless of the type of recording member used.
[0128]
  In particular, claim 10According to the invention, there is an excellent effect that it is possible to eliminate the increase in size and cost of the apparatus due to the provision of the intermediate recording member and the transfer means.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a main part of a discharge test apparatus experimentally manufactured by the present inventors.
FIGS. 2A to 2C are schematic views showing toner discharge states in the same discharge test apparatus. FIG.
FIG. 3 is a perspective view showing a migration test apparatus made by the present inventors as a prototype.
FIG. 4 is a schematic diagram for explaining a test using the migration test apparatus.
FIG. 5A is a longitudinal sectional view showing a state of a colored liquid repelled by a fluororesin coating between discharge electrodes in a simple recording head made by the present inventors as a prototype.
(B) is a front view which shows the same state.
FIG. 6A is a longitudinal sectional view showing a state of a colored liquid repelled by the fluororesin film and a fluororesin on a facing glass plate in the simple recording head.
(B) is a front view which shows the same state.
FIG. 7 is a cross-sectional view illustrating a main part of a recording head of the printer according to the embodiment.
FIG. 8 is a perspective view showing an insulating substrate of the recording head.
FIG. 9 is a schematic configuration diagram of the printer.
FIGS. 10A to 10C are schematic views showing dots formed by the recording head, respectively.
FIG. 11 is a schematic configuration diagram illustrating an intermediate recording drum of the printer according to the first embodiment together with peripheral devices.
FIG. 12 is a schematic configuration diagram of a printer according to a third embodiment.
FIG. 13A is a longitudinal cross-sectional view showing a main configuration of a conventional image forming apparatus.
(B) is a top view which shows the principal part structure.
(C) is a front view which shows the principal part structure.
FIGS. 14A and 14B are schematic views showing the state of toner in the recording head of the image forming apparatus, respectively.
[Explanation of symbols]
1 Recording head
2 Discharge electrode (parallel electrode)
3 Fluorine resin coating
4 Insulating substrate (substrate)
5 Fluorine resin coating
6 Colored liquid
7 Recording signal power supply
8 Power supply
9 Counter electrode
10 Voltage ON / OFF driver
13 Insulating top plate
20 Intermediate recording drum
20a Aluminum drum (counter electrode)
20b High resistance rubber layer (intermediate recording member)
21 Paper cassette
22 Registration roller pair
23 Transfer roller
24 Fixing device
25 Transfer paper (recording member)
26 Drum cleaning device
27 Marker detection sensor
100 Discharge test device
101, 102 glass plate
105 Electrophoresis test equipment
106 glass plate
107 1st electrode
108 Second electrode
109, 111 conductive tape
110 Power supply
112 High-speed camera
113 cold light
114 facing glass plate
T toner (colored fine particles)
Dt dot

Claims (10)

A substrate for holding a colored liquid containing charged colored particles and a liquid carrier, a plurality of parallel electrodes arranged in parallel at a predetermined pitch on the liquid holding surface of the substrate, and a pair facing the liquid holding surface A face plate and a counter electrode facing the tip of each parallel electrode through a predetermined gap, and an aggregate of colored particles in the colored liquid on the parallel electrode is generated by a potential difference between the parallel electrode and the counter electrode. tip is ejected toward the counter electrode side from depositing the discharged so was the aggregate to the recording member in an image forming apparatus for forming an image,
A liquid repellent coating is provided only in a part of a predetermined distance range from the front end to the rear end of the substrate facing the counter electrode in the region between the parallel electrodes on the substrate, and the repellent film on the facing plate is provided. repellent coating provided in a region facing the liquid film, between the lyophobic coating liquid repellent film and said pair faceplate of the substrate, is characterized in that so as to form a non-existent cavity of colored liquid Image forming apparatus . The image forming apparatus according to claim 1 .
An image forming apparatus comprising a fluororesin coating as the liquid repellent coating . The image forming apparatus according to claim 1 or 2 ,
An image forming apparatus, wherein the distance range is set to 0.2 [mm] or more and 0.9 [mm] or less. The image forming apparatus according to claim 1, 2 or 3 .
An image forming apparatus, comprising: a recording member moving unit that moves the recording member in a direction orthogonal to the arrangement direction of the parallel electrodes at a position facing the front end of each parallel electrode. The image forming apparatus according to claim 4 .
An image forming apparatus, wherein a plurality of the substrates are arranged in the moving direction of the recording member. The image forming apparatus according to claim 4 .
Substrate moving means for moving the substrate in the direction in which the parallel electrodes are arranged is provided, and the recording member moving means is moved so that the recording member is moved along a movement path that repeatedly passes the position facing the tip of each parallel electrode. An image forming apparatus comprising: The image forming apparatus according to claim 4 .
An image forming apparatus, wherein the recording member moving means is configured to move the recording member also in the direction in which the parallel electrodes are arranged. The image forming apparatus according to claim 7 .
An image forming apparatus characterized in that the recording member moving means is configured to move the recording member along a moving path that repeatedly passes the facing position. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7, or 8 .
An image forming apparatus comprising: an intermediate recording member as the recording member to which the colored liquid from the tip of the parallel electrode is attached; and a transfer unit that transfers an image formed on the intermediate recording member to another recording member. apparatus. The image forming apparatus according to claim 1, 2, 3, 4, 5, 6, 7 or 8 .
A conveying means for conveying the recording member to a recording position between the counter electrode and each parallel electrode; and a discharging means for discharging the recording member on which an image is recorded at the recording position to the apparatus main body. An image forming apparatus.

Images