JP2006110977A - Inkjet head and inkjet recording device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inkjet head improved in supply performance of ink to discharge openings, which stably draw dots of desired sizes even when the dots are drawn at a high speed, and also to provide an inkjet recording device. <P>SOLUTION: The inkjet head discharges ink as ink liquid droplets, and has discharge opening discharging ink droplets. A shape of the opened discharge opening is made to have 1 or more of an aspect ratio of its long and short diameter. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention belongs to the field of ink jet recording in which ink is ejected as ink droplets. Specifically, an ink jet head that ejects ink droplets by applying an electrostatic force to the ink, and ink jet recording using the ink jet head It relates to the device.

  In the electrostatic ink jet recording method, electrostatic force is generated by applying a predetermined voltage (drive voltage) to the discharge electrode (drive electrode) of the ink jet head in accordance with image data using ink containing charged fine particles. In this method, ink ejection is controlled to record an image corresponding to image data on a recording medium. As an electrostatic ink jet recording apparatus, for example, an ink jet recording apparatus disclosed in Patent Document 1 is known.

  FIG. 7 is a schematic configuration diagram of an example of an ink jet head of the electrostatic ink jet recording apparatus disclosed in Patent Document 1. The inkjet head 100 shown in the figure conceptually represents only one ejection unit of the inkjet head disclosed in Patent Document 1, and includes a head substrate 102, an ink guide 104, an insulating substrate 106, and a control. An electrode 108, a counter electrode 110, a DC bias voltage source 112, and a pulse voltage source 114 are provided.

  Here, the ink guide 104 is disposed on the head substrate 102, and a through-hole (ejection port) 116 is opened in the insulating substrate 106 at a position corresponding to the arrangement of the ink guide 104. The ink guide 104 passes through the through-hole 116, and the convex tip portion 104a protrudes above the surface of the insulating substrate 106 on the recording medium P side. Further, the head substrate 102 and the insulating substrate 106 are arranged with a predetermined distance therebetween, and a flow path 118 for the ink Q is formed between them.

  The control electrode 108 is provided in a ring shape so as to surround the periphery of the through hole 116 on the surface of the insulating substrate 106 on the side of the recording medium P for each ejection unit. The control electrode 108 is connected to a pulse voltage source 114 that generates a pulse voltage in accordance with image data. The pulse voltage source 114 is grounded via a DC bias voltage source 112.

  The counter electrode 110 is disposed at a position facing the tip portion 104a of the ink guide 104 and is grounded. The recording medium P is disposed on the surface of the counter electrode 110 on the ink guide 104 side. That is, the counter electrode 110 functions as a platen that supports the recording medium P.

  During recording, ink Q including fine particles (color material particles) charged to the same polarity as the voltage applied to the control electrode 108 by an ink circulation mechanism (not shown) passes through the ink flow path 118 from the right side to the left side in the drawing. It is circulated toward. Further, a high voltage of, for example, 1.5 kV is constantly applied to the control electrode 108 by the DC bias voltage source 102. At this time, a part of the ink Q in the ink flow path 118 passes through the through hole 116 of the insulating substrate 106 due to a capillary phenomenon or the like, and is concentrated on the tip portion 104a of the ink guide 104.

  When a pulse voltage of, for example, 0 V is applied from the pulse voltage source 114 to the control electrode 108 biased to 1.5 kV by the bias voltage source 112, 1.5 kV on which both voltages are superimposed is applied to the control electrode 108. Applied. In this state, the electric field strength in the vicinity of the front end portion 104 a of the ink guide 104 is relatively low, and the ink Q containing the color material particles concentrated on the front end portion 104 a of the ink guide 104 jumps out of the front end portion 104 a of the ink guide 104. Absent.

  On the other hand, when a pulse voltage of 500 V, for example, is applied from the signal voltage source 114 to the control electrode 108 biased to 1.5 kV, 2 kV on which both voltages are superimposed is applied to the control electrode 108. As a result, the ink Q containing the coloring material particles concentrated on the tip portion 104a of the ink guide 104 is ejected as an ink droplet R from the tip portion 104a by electrostatic force, and is pulled by the grounded counter electrode 110 to be recorded. Adhering onto P, a dod of colorant particles is formed.

  In this way, recording is performed with the dod of the color material particles while relatively moving the inkjet head 100 and the recording medium P supported on the counter electrode 110, whereby an image corresponding to the image data is recorded on the recording medium P. Is done.

JP 10-138493 A

  By the way, in the electrostatic ink jet head, when a multi-channel head is configured by arranging a plurality of ejection portions in a matrix, it becomes increasingly difficult to connect signal wiring to the control electrode of each ejection portion. For this reason, when the number of channels is large, it is conceivable to form an insulating substrate in a multilayer wiring structure and connect the signal wiring to the control electrode. Therefore, as the number of channels increases in the future, the thickness of the insulating substrate tends to gradually increase.

  However, as the insulating substrate becomes thicker, the length of the through hole becomes longer than the opening diameter of the through hole. Therefore, the resistance between the ink and the inner wall of the through hole is increased, and the ink is difficult to be ejected. Also, when the insulating substrate becomes thicker than the ink flow speed, the ink stays in the through hole and the ink supply to the tip of the ink guide deteriorates, so the responsiveness to the ejection frequency deteriorates. There is a problem that the dot diameter gradually decreases as the drawing speed increases.

  The object of the present invention is to solve the problems based on the above prior art, improve the ink supply to the ejection port, and stably draw dots of a desired size even if dots are drawn continuously at high speed. An object is to provide an ink jet head and an ink jet recording apparatus capable of drawing.

  In order to achieve the above object, the present invention provides an inkjet head that ejects ink as ink droplets, and has ejection ports for ejecting ink droplets, and the aperture shape of the ejection ports is the major axis of the aperture. And an ink jet head characterized in that the aspect ratio of the minor axis is larger than 1.

Further, the discharge port substrate in which the discharge port is opened, a head substrate that is disposed at a predetermined interval from the discharge port substrate, and that forms an ink flow path between the discharge port substrate, and from the discharge port Control means for controlling the ejection of ink droplets, and the opening shape of the ejection port is a shape larger than 1 in terms of the aspect ratio between the length in the ink flow direction and the length in the direction perpendicular to the ink flow direction. Is preferred.
Here, it is preferable that the aspect ratio of the discharge port is 1.5 or more.
Moreover, it is preferable that the said control means is a discharge electrode arrange | positioned around the said discharge port of the said discharge port board | substrate.

  The ink jet head of the present invention further includes a discharge electrode that is disposed so as to surround the discharge port, and that discharges ink droplets by applying an electrostatic force to the ink. It is preferable that the effective portion contributing to the discharge has a substantially symmetric shape with respect to the discharge port.

Here, the discharge electrode is symmetric with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and a longitudinal portion formed in the major axis direction of the discharge port is centered on the ejection port. It is preferable that the shape is symmetrical with respect to a plane that is perpendicular to the long axis direction.
Alternatively, the discharge electrode is symmetrical with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and the length of the longitudinal portion formed in the major axis direction of the discharge port is the major axis of the discharge port It is preferable to have a shape longer than the length in the direction.
Alternatively, the discharge electrode is symmetric about a line passing through the center of the discharge port and parallel to the major axis direction, and the center of the longitudinal portion formed in the major axis direction of the discharge port is the center of the discharge port Preferably, the shape is on a plane that passes through and is perpendicular to the major axis direction.
Alternatively, the discharge electrode is symmetrical with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and the center of the longitudinal portion formed in the major axis direction of the discharge port is the center of the ejection port Preferably, the shape is on a plane that passes through and is perpendicular to the major axis direction.
Further, it is preferable that the ejection electrode has a shape in which a part on the upstream side in the ink flow direction is cut out.
Moreover, it is preferable that the discharge electrode has any one of a substantially C shape, a substantially U shape, an elliptical shape, and a substantially U shape.

Further, the head substrate is arranged at a position corresponding to the arrangement of the ejection ports on the ejection port substrate side, passes through the ejection ports, and a tip portion of the ejection substrate is opposite to the head substrate. It is preferable to have an ink guide that protrudes from the surface.
In addition, it is preferable that the ink guide has a wide structure corresponding to the shape of the ejection port.
In addition, it is preferable to include an ink guide weir provided on a surface of the head substrate on the ink flow path side to form an ink flow from the upstream side of the ink flow of the ink toward the ejection port.

The ink is preferably a solvent in which charged fine particles are dispersed.
The present invention also provides an ink jet recording apparatus that records an image corresponding to image data on a recording medium using any one of the ink jet heads.

According to the present invention, by setting the opening shape of the ejection port to a shape in which the aspect ratio of the major axis and the minor axis of the aperture is larger than 1, it is possible to improve the ink supply property to the ejection port. Furthermore, by providing a shape in which the aspect ratio between the length in the ink flow direction and the length in the direction orthogonal to the ink flow direction is greater than 1, the ink supply property to the ejection port can be further improved. As described above, according to the present invention, the responsiveness of the discharge frequency at the time of image recording is improved by improving the ink supply property to the discharge port, and the dot diameter can be continuously drawn even at high speed. Can be suppressed, so that dots of a desired size can be stably drawn.
Further, by making the ink guide have a wide structure corresponding to the shape of the ejection port, ejection can be made more stable.
Furthermore, by providing the guide weir on the head substrate, it is possible to further improve the ink supply property.

In addition to the above effect, the effective portion of the discharge electrode that contributes to the discharge of the ink droplets is substantially symmetrical with respect to the discharge port. It is possible to prevent the dot division caused by the deviation of the landing position on the recording medium, and to stably form a high-resolution image.
Further, the discharge electrode is symmetrical with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and a longitudinal portion formed in the major axis direction of the discharge port passes through the center of the ejection port and is in the major axis direction. By making the shape symmetric with respect to the vertical plane, the ink ejection direction is more stable, and the dot breakup caused by shifting the landing position of the ink droplet on the recording medium can be prevented, making it more stable Thus, a higher resolution image can be formed.

Hereinafter, an ink jet head and an ink jet recording apparatus of the present invention will be described in detail based on preferred embodiments shown in the accompanying drawings.
FIG. 1A schematically shows a cross-section of the schematic configuration of the ink jet head according to the present invention, and FIG. 1B shows a view taken along line IB-IB in FIG. As shown in FIG. 1A, the inkjet head 10 includes a head substrate 12, an ink guide 14, and an ejection port substrate 16 on which ejection ports 28 are formed. On the discharge port substrate 16, discharge electrodes 18 are arranged so as to surround the discharge port 28. A counter electrode 24 that supports the recording medium P and a charging unit 26 of the recording medium P are disposed at a position facing the ink discharge side surface (upper surface in the drawing) of the inkjet head 10.
In addition, the head substrate 12 and the discharge port substrate 16 are arranged at a predetermined interval while facing each other. An ink flow path 30 that supplies ink to each ejection port 28 is formed by a space formed between the head substrate 12 and the ejection port substrate 16.

  The inkjet head 10 has a multi-channel structure in which a plurality of ejection ports 28 (nozzles) are two-dimensionally arranged in order to perform higher density image recording at high speed. FIG. 2 schematically shows a state in which a plurality of discharge ports 28 are two-dimensionally arranged on the discharge port substrate 16 of the inkjet head 10. In FIGS. 1A and 1B, only one of the plurality of discharge ports is shown for easy understanding of the configuration of the inkjet head.

  In the inkjet head 10 of the present invention, the number of ejection ports 28, the physical arrangement position thereof, and the like can be freely selected. For example, not only a multi-channel structure as shown in FIG. 2 but also a single discharge port may be provided. Further, a so-called (full) line head having a row of ejection openings corresponding to the entire area of the recording medium P may be used, or a so-called serial head (shuttle type) scanned in a direction orthogonal to the direction of the nozzle row. Good. The ink jet head of the present invention can be used for both monochrome and color recording apparatuses.

FIG. 2 shows an arrangement of a part of the multi-channel structure (3 rows and 3 columns), and in a preferred embodiment, in the ink flow direction, the outlets 28 on the downstream side are arranged on the upstream side. The nozzles are arranged so as to be shifted by a predetermined pitch in the direction perpendicular to the ink flow with respect to the ejection ports. In this way, by disposing the discharge ports in the downstream row in a direction perpendicular to the ink flow direction with respect to the discharge ports in the upstream row, it is possible to satisfactorily supply ink to the discharge ports. In the inkjet head of the present invention, n rows and m columns (n and m are positive) are arranged such that the discharge ports in the downstream column are shifted in the direction perpendicular to the ink flow direction with respect to the discharge ports in the upstream column. May be configured such that each of the discharge ports is perpendicular to the ink flow with respect to the discharge ports located on the upstream side. You may arrange | position by shifting continuously in a direction (downward or upward direction in FIG. 2). The number, pitch, repetition period, and the like of the discharge ports can be appropriately set according to the resolution and the feed pitch.
In addition, in FIG. 2, as a preferred mode, in the ink flow direction, the discharge ports in the downstream row are shifted from the discharge ports in the upstream row in the direction perpendicular to the ink flow, but the present invention is not limited to this. Instead, the downstream outlet and the upstream outlet may be arranged on the same straight line in the ink flow direction. In this case, it is preferable to dispose each ejection port in each row in the ink flow direction with respect to each ejection port in a row adjacent to the row in a direction perpendicular to the ink flow.

  In such an ink jet head 10, an ink Q is used, which includes a coloring material such as a pigment and is dispersed in an insulating liquid (carrier liquid) with charged fine particles (hereinafter referred to as coloring material particles). . Then, a driving voltage is applied to the ejection electrode 18 provided on the ejection port substrate 16 to generate an electric field at the ejection port 28, and the ink in the ejection port 28 is ejected by electrostatic force. Further, by turning on / off the drive voltage applied to the ejection electrode 18 according to the image data (ejection on / off), the ink droplets are ejected from the ejection port 28 according to the image data, and the recording medium P Record the image on top.

  Hereinafter, the structure of the inkjet head 10 of the present invention shown in FIGS. 1A and 1B will be described in more detail.

  As shown in FIG. 1A, the discharge port substrate 16 of the inkjet head 10 includes an insulating substrate 32, a guard electrode 20, a discharge electrode 18, and an insulating layer 34. A guard electrode 20 and an insulating layer 34 are sequentially stacked on the upper surface of the insulating substrate 32 in the drawing (the surface opposite to the side facing the head substrate 12). In addition, the discharge electrode 18 is formed on the lower surface of the insulating substrate 32 in the figure (the surface facing the head substrate 12).

Further, the discharge port substrate 16 is formed with a discharge port 28 for discharging the ink droplet R penetrating the insulating substrate 32. As shown in FIG. 1B, the ejection port 28 is a bowl-shaped opening (slit) elongated in the ink flow direction in which both short sides of the rectangle are semicircular, and has a length L in the ink flow direction. And the length D in the direction perpendicular to the ink flow has an aspect ratio (L / D) of 1 or more.
In the present invention, in this way, the opening 28 has an aspect ratio (L / D) between the length L in the ink flow direction and the length D in the direction perpendicular to the ink flow of 1 or more (the ink flow direction is long). By making it a shape having shape anisotropy as a side and a long hole shape having a long side in the ink flow direction, ink can easily flow into the ejection port 28. That is, it is possible to improve the ink particle supply to the ejection port 28, improve the frequency response, and prevent clogging. This will be described in detail later together with the action of discharging ink droplets.

  In the present embodiment, the ejection port 28 is formed as an elongated bowl-shaped opening. However, the present invention is not limited to this, and ink can be ejected from the ejection port 28, and the length in the direction perpendicular to the ink flow is the length in the direction perpendicular to the ink flow. As long as the aspect ratio is 1 or more, any shape such as a substantially circular shape, an elliptical shape, a rectangular shape, a rhombus shape, or a parallelogram shape can be used. For example, a rectangular shape having a long side in the ink flow direction, or an ellipse or a rhombus having a long axis in the ink flow direction can be used. Alternatively, the upstream side of the ink flow may be an upper base, the downstream side may be a lower bottom, and the height in the ink flow direction may be longer than the lower base. In this case, the upstream side may be lengthened or the downstream side may be lengthened. Alternatively, a shape in which a circle having a diameter larger than the short side of the rectangle is connected to both short sides of the rectangle having the long side in the ink flow direction. Further, the discharge port 28 may have a symmetric shape or an asymmetric shape on the upstream side and the downstream side with respect to the center thereof. For example, the discharge port may be formed by making a semicircular shape at least one of the upstream and downstream ends of the rectangular discharge port.

  The ink guide 14 of the inkjet head 10 is made of a ceramic flat plate having a predetermined thickness, and is disposed on the head substrate 12 corresponding to each ejection port 28 (ejection unit). The ink guide 14 is formed wide according to the length in the long side direction of the bowl-shaped discharge port 28. As described above, the ink guide 14 passes through the ejection port 28, and the tip end portion 14 a projects upward from the surface of the ejection port substrate 16 on the recording medium P side (the surface of the insulating layer 34).

The leading end portion 14a of the ink guide 14 is formed into a substantially triangular shape (or trapezoid) that gradually becomes thinner toward the counter electrode 24 side. The ink guide 14 is disposed so that the inclined surface of the tip portion 14a intersects the ink flow direction. As a result, the ink flowing into the ejection port 28 reaches the apex of the distal end portion 14 a along the inclined surface of the distal end portion 14 a of the ink guide 14, so that an ink meniscus is stably formed at the ejection port 28.
Further, by forming the ink guide 14 wider in the long side direction of the ejection port 28, the width in the direction perpendicular to the ink flow can be shortened, and the influence on the ink flow can be reduced, and A meniscus described later can be formed stably.

The shape of the ink guide 14 is not particularly limited as long as the colorant particles in the ink Q can be concentrated in the tip portion 14a through the discharge port 28 of the discharge port substrate 16, and for example, the tip portion 14a. The shape does not have to be thinned toward the counter electrode, and can be changed as appropriate. For example, a cutout serving as an ink guide groove that collects the ink Q in the front end portion 14a may be formed in the center portion of the ink guide 14 in the vertical direction in the drawing by capillary action.
Further, it is preferable that a metal is deposited on the most advanced portion of the ink guide 14. By depositing metal on the leading edge of the ink guide 14, the dielectric constant of the tip portion 14a of the ink guide 14 is substantially increased. Thereby, it becomes easy to generate a strong electric field, and the discharge property of ink can be improved.

  As shown in FIG. 1B, the ejection electrode 18 is formed on the lower surface of the insulating substrate 32 (the surface facing the head substrate 12). The ejection electrode 18 is arranged in a U-shape in which one side on the upstream side of the ink flow is cut out along the peripheral edge of the ejection port 28 so as to surround the periphery of the rectangular ejection port 28. In FIG. 1B, the ejection electrode 18 is formed in a U-shape, but may be any shape as long as the electrode is disposed so as to face the ink guide, for example, a square electrode, Various shapes such as a ring-shaped circular electrode, an elliptical electrode, a divided circular electrode, a parallel electrode, and a substantially parallel electrode can be used depending on the shape of the discharge port 28.

As described above, since the inkjet head 10 has a multi-channel structure in which the discharge ports 28 are two-dimensionally arranged, the discharge electrode 18 corresponds to each discharge port 28 as schematically shown in FIG. They are arranged two-dimensionally.
The ejection electrode 18 is exposed to the ink flow path 30 and is in contact with the ink Q flowing through the ink flow path 30. Thereby, the discharge property of ink droplets can be greatly improved. This point will be described later together with the action of discharge. However, the ejection electrode 18 is not necessarily exposed to the ink flow path 30 and in contact with the ink. That is, the discharge electrode 18 may be formed inside the discharge port substrate 16, or the exposed surface of the discharge electrode 18 may be covered with a thin insulating layer or the like.

  As shown in the figure, the discharge electrode 18 is connected to the control unit 33. The controller 33 can control the voltage applied to the ejection electrode 18 when ink is ejected and when ink is not ejected.

The guard electrode 20 is formed on the surface of the insulating substrate 32, and the surface of the guard electrode 20 is covered with an insulating layer 34. FIG. 3 schematically shows the planar structure of the guard electrode 20. FIG. 3 is a view taken along the line III-III in FIG. 1A, and schematically shows a planar structure of the guard electrode 20 in the case of an inkjet head having a multi-channel structure. As shown in FIG. 3, the guard electrode 20 is a sheet-like electrode common to each discharge electrode such as a metal plate, and the discharge electrode 18 formed around each discharge port 28 arranged two-dimensionally. Has an opening 36 at a position corresponding to. The opening 36 is formed in a rectangular shape. The length and width of the opening 36 of the guard electrode 20 are formed larger than the length and width of the discharge port.
The guard electrode 20 can shield electric lines of force between the adjacent ejection electrodes 18 to suppress electric field interference, and a predetermined voltage is applied to the guard electrode 20 (including 0 V due to grounding). In the illustrated example, the guard electrode 20 is grounded to 0V.

As shown in FIG. 1A, the guard electrode 20 is preferably formed in a layer different from the ejection electrode 18 and further covered with an insulating layer 34 as a preferred embodiment.
By having such an insulating layer 34, electric field interference between the adjacent ejection electrodes 18 can be suitably prevented, and the color material particles of the ink Q are coated between the ejection electrodes 18 and the guard electrodes 20 to discharge. Can also be prevented.

Here, the guard electrode 20 secures the electric lines of force that act on the corresponding discharge ports 28 (hereinafter referred to as “own channels” for convenience) among the electric lines of force generated from the discharge electrodes 18. It is necessary to provide the electric lines of force of the discharge electrode 18 provided in the discharge port 28 (also referred to as “other channels”) and the electric lines of force to the other channels.
In the absence of the guard electrode 20, the electric lines of force generated from the end of the discharge electrode 18 on the discharge port side (hereinafter referred to as the inner edge of the discharge electrode) during the discharge of ink droplets are inside the discharge electrode 18, that is, the discharge It converges in a region surrounded by the inner edge of the electrode 18 and acts on its own channel to generate an electric field necessary for discharging ink droplets. On the other hand, electric lines of force generated from the end of the discharge electrode 18 opposite to the discharge port (hereinafter referred to as the outer edge of the discharge electrode) diverge further outward than the outer edge of the discharge electrode 18 and affect other channels. Cause electric field interference.

In consideration of the above points, the width and length of the rectangular opening 36 of the guard electrode 20 are such that the discharge of the self-channel is not observed when viewed from the plane of the substrate so as not to shield the lines of electric force to the self-channel. The electrode 18 is also preferably enlarged. In other words, the end of the guard electrode 20 on the discharge port 28 side is preferably separated (retreated) from the discharge port 28 rather than the inner edge of the discharge electrode 18 of the own channel.
Further, in order to efficiently shield the lines of electric force to other channels, the length and width of the rectangular opening 36 of the guard electrode 20 are set so that the discharge electrode 18 of the own channel when viewed in the substrate plane. It is preferable to make it smaller than the interval between the outer edge portions. That is, it is preferable that the inner edge portion of the guard electrode 20 is closer (advanced) to the discharge port 28 than the outer edge portion of the discharge electrode 18 of the own channel. According to the study of the present inventor, this proximity amount is preferably 5 μm or more, particularly preferably 10 μm or more.
By having the above-described configuration, the ejection stability from the ejection port 28 is sufficiently ensured, and variations in the ink landing position due to electric field interference between adjacent channels are suitably suppressed, and the stability can be increased. It is possible to perform image recording with high image quality.

  The opening 36 of the guard electrode 20 is substantially similar to the shape formed by the inner edge or the outer edge of the ejection electrode 18, and the inner edge of the guard electrode 20 is more ejected than the inner edge of the ejection electrode 18 of its own channel. The guard electrode 20 may be provided so as to be separated from (retracted from) 28 and closer to (advance) the discharge port 28 than the outer edge of the discharge electrode (that is, the opening 36 of the guard electrode 20 may be formed). Good).

In the above example, the guard electrode 20 is a sheet-like electrode. However, the present invention is not limited to this, and may be provided so as to shield the electric lines of force of other channels between the discharge ports. Any shape or structure may be used. For example, the guard electrode 20 may be provided in a mesh shape between the discharge ports. In addition, in a plurality of discharge ports arranged in a matrix, for example, when the intervals between adjacent discharge ports in the row direction and the column direction are different, between the discharge ports sufficiently separated so as not to cause electric field interference. May not be provided with a guard electrode, but may be provided only between adjacent outlets.
Even in such a case, the inner edge portion of the guard electrode 20 is further away from the discharge port 28 than the inner edge portion of the discharge electrode 18 with respect to the discharge electrode 18 of the self-channel, and the discharge port 28 is separated from the outer edge portion of the discharge electrode 18. The guard electrode 20 may be formed so as to be close to the electrode.
Here, the shape of the opening 36 of the guard electrode 20 is substantially the same as the shape of the discharge port 28, but the shape is not limited to this, and the lines of electric force between the adjacent discharge electrodes 18 are shielded. As long as the electric field interference can be prevented, it can be formed into an arbitrary shape. For example, the shape may be a circle, an ellipse, a square, a rhombus, or the like.

In addition, in the ink jet head 10 of the present embodiment, as a preferred embodiment, an ink guide weir 40 that guides ink to the ejection port 28 is provided on the head substrate 12. Hereinafter, the ink guide weir 40 will be described.
FIG. 4A is a partial cross-sectional perspective view showing the configuration in the vicinity of the ejection portion in the inkjet head 10 of FIG. In the drawing, in order to clearly show the structure of the ink guide weir 40, the discharge port substrate 16 is shown cut along the ink flow direction at a substantially central position of the ink guide 14.

  The ink guide weir 40 is located upstream and downstream in the ink flow direction of the ink guide 14 disposed at a position corresponding to the ejection port 28 on the ink channel 30 side surface of the head substrate 12, that is, the bottom surface of the ink channel 30. The surface is provided on the side and is inclined so as to gradually approach the discharge port substrate 16 from the vicinity of the position corresponding to the discharge port 28 toward the position corresponding to the center of the discharge port 28 with respect to the ink flow direction. have. That is, the ink guide weir 40 has a shape that is inclined toward the ejection port 28 along the ink flow direction.

  In addition, the ink guide weir 40 has a shape having a width substantially the same as the ejection port 28 in the direction orthogonal to the ink flow and having a wall surface extending from the bottom surface. In addition, the ink guide weir 40 does not block the discharge port 28 and secures a flow path for the ink Q from the surface on the ink flow channel 30 side of the discharge port substrate 16, that is, from the upper surface of the ink flow channel 30. It is provided at intervals. Such an ink guide weir 40 is provided in each discharge part.

  Thus, by providing the ink guide weir 40 that is inclined toward the ejection port 28 along the ink flow direction on the bottom surface of the ink flow path 30, an ink flow toward the ejection port 28 is formed, and the ink Q The discharge port 28 is guided to the opening on the ink flow path 30 side. Therefore, the ink Q can be suitably flown into the discharge port 28, and the ink particle supply property can be further improved. Furthermore, clogging can be prevented more reliably.

  The length l in the ink flow direction of the ink guide weir 40 may be set as appropriate so that the ink Q can be suitably guided to the ejection port 28 within a range that does not interfere with the adjacent ejection unit. As shown in FIG. 4, the height h of the highest part of the ink guide weir 40 is preferably 3 times or more (l / h ≧ 3), more preferably 8 times or more (l / h ≧ 8). preferable.

  The width of the ink guide weir 40 in the direction perpendicular to the ink flow is preferably equal to or slightly wider than the ejection port 28. Further, the width of the ink guide weir 40 is not limited to a uniform one as shown in the drawing, and may be one in which the width gradually decreases or one in which the width gradually increases. Further, the wall surface is not limited to a vertical surface, and may be an inclined surface or the like.

  The inclined surface (ink guiding surface) of the ink guide weir 40 may be a shape suitable for guiding the ink Q to the ejection port 28, and may be a slope having a certain tilt angle. It may be a changing surface or a curved surface. The surface is not limited to a smooth surface, and one or more wrinkles, grooves, or the like may be formed in the ink flow direction or radially toward the center of the ejection port 28.

  Further, the vicinity of the contact portion of the upper part of the ink guide weir 40 with the ink guide 14 may have a smoothly connected shape without a step as in the illustrated example.

  In the illustrated example, the ink guide weir 40 is arranged on the upstream side and the downstream side of the ink guide 14, but a trapezoidal ink guide weir 40 having slopes on the upstream side and the downstream side of the ejection port 28 is provided. The ink guide 14 may be erected on the upper portion, or the ink guide 14 and the ink guide weir 40 may be integrally formed. As described above, the ink guide weir 40 may be formed separately or integrally with the ink guide 14 and attached to the head substrate 12, or the head substrate 12 is shaved by a conventionally known excavation means. It may also be formed.

  The ink guide weir 40 may be provided on the upstream side of the ejection port 28, but the height in the ejection direction of the ink droplets R is also ejected on the downstream side of the ejection port 28 as shown in the illustrated example. It is preferable to be provided so as to become lower as the distance from the outlet 28 increases. As a result, the ink Q guided toward the discharge port 28 by the upstream ink guide weir 40 flows smoothly to the downstream side, so that the ink Q does not become turbulent and the ink flow can be kept stable. , Discharge stability can be maintained.

  In the example of FIG. 4, the ink guide weir 40 is disposed on the upper surface of the head substrate 12. However, the present invention is not limited to this. An ink guide weir may be provided.

  For example, an ink flow groove having a predetermined depth passing through a position corresponding to the ejection port 28 is provided along the ink flow direction, and is inclined toward the ejection port 28 along the ink flow direction at a position corresponding to the ejection port. An ink guide weir having a surface is provided. As described above, by providing the ink flow groove, most of the ink Q flowing through the ink flow path 30 can be selectively flowed to the ink flow groove. By providing the ink flow path weir, the ink Q is discharged from the ejection port 28. The ink can be preferably introduced into the ink guide, and the ink supply to the ink guide tip portion 14a can be improved.

As shown in FIG. 1A, the counter electrode 24 is disposed so as to face the ejection surface of the ink droplet R of the inkjet head 10.
The counter electrode 24 is disposed at a position facing the front end portion 14a of the ink guide 14, and is disposed on the grounded electrode substrate 24a and the lower surface of the electrode substrate 24a in the drawing, that is, the surface on the inkjet head 10 side. The insulating sheet 24b is used.
The recording medium P is held on the lower surface of the counter electrode 24 in the drawing, that is, the surface of the insulating sheet 24b by, for example, electrostatic adsorption, and the counter electrode 24 (insulating sheet 24b) is used as a platen of the recording medium P. Function.

At least during recording, the recording medium P held on the insulating sheet 24b of the counter electrode 24 is charged by the charging unit 26 to a predetermined negative high voltage having a polarity opposite to the drive voltage applied to the ejection electrode 18.
As a result, the recording medium P is negatively charged and biased to a negative high voltage, acts as a substantial counter electrode with respect to the ejection voltage 18, and is electrostatically adsorbed to the insulating sheet 24 b of the counter electrode 24.

  The charging unit 26 includes a scorotron charger 26a for charging the recording medium P to a negative high voltage, and a bias voltage source 26b for supplying a negative high voltage to the scorotron charger 26a. The charging means of the charging unit 26 used in the present invention is not limited to the scorotron charger 26a, and various discharging means such as a corotron charger, a solid charger, and a discharge needle can be used.

In the illustrated example, the counter electrode 24 includes an electrode substrate 24a and an insulating sheet 24b, and the recording medium P is charged to a negative high voltage by the charging unit 26, whereby a bias voltage is applied to the counter electrode. However, the present invention is not limited to this, and the counter electrode 24 is constituted only by the electrode substrate 24a, and the counter electrode 24 (electrode substrate 24a itself) is formed. May be connected to a negative high voltage bias voltage source so as to be constantly biased to a negative high voltage so that the recording medium P is electrostatically attracted to the surface of the counter electrode 24.
Further, the electrostatic adsorption of the recording medium P to the counter electrode 24 and the charging of the recording medium P to a negative high voltage or the application of a negative bias high voltage to the counter electrode 24 are separate negative high voltage sources. The holding of the recording medium P by the counter electrode 24 is not limited to the electrostatic adsorption of the recording medium P, and other holding methods and holding means may be used.

  Hereinafter, the present invention will be described in more detail by explaining the operation of ejecting ink droplets R in the inkjet head 10.

As shown in FIG. 1A, in the inkjet head 10, a color charged to the same polarity as the voltage applied to the ejection electrode 18 at the time of recording, for example, positive (+) by an ink circulation mechanism including a pump (not shown). Ink Q containing material particles circulates in the ink flow path 30 in the direction of the arrow (from the left to the right in the figure).
On the other hand, at the time of recording, the recording medium P is supplied to the counter electrode 24 and charged by the charging unit 26 to a polarity opposite to that of the color material particles, that is, negative high voltage (for example, −1500 V) and charged with a bias voltage. Thus, it is electrostatically attracted to the counter electrode 24.
In this state, while the recording medium P (counter electrode 24) and the inkjet head 10 are relatively moved, the controller 33 applies a pulse voltage (hereinafter referred to as a drive voltage) to the ejection electrode 18 in accordance with the supplied image data. ) Is applied. Basically, the ink droplet R is modulated and ejected according to the image data by ejecting on / off by applying the drive voltage on / off, and an image is recorded on the recording medium P.

Here, in a state where the drive voltage is not applied to the ejection electrode 18 (or in a state where the applied voltage is at a low voltage level), that is, in a state where only the bias voltage is applied, the ink Q has a bias voltage and Coulomb attractive force with the charge of the color material particles (charged particles) of the ink Q, Coulomb repulsive force between the color material particles, carrier liquid viscosity, surface tension, dielectric polarization force, and the like are acting. These are coupled to move the color material particles and the carrier liquid. As shown conceptually in FIG. 1A, the ink Q has a meniscus shape slightly raised from the ejection port 28 and is balanced. It is taken.
Further, the color material particles are aggregated in the discharge port 28 by the electric field generated from the discharge electrode 18. The colorant particles move toward the recording medium P charged with a bias voltage by so-called electrophoresis due to the above-described Coulomb attractive force or the like. Accordingly, the ink Q is concentrated in the meniscus formed at the ejection port 28.

  From this state, a driving voltage is applied to the ejection electrode 18. As a result, the drive voltage is superimposed on the bias voltage, and the motion coupled by the superposition of the drive voltage further occurs in the previous coupling. An electrostatic force acts on the colorant particles and the carrier liquid by an electric field generated by applying a drive voltage to the ejection electrode 18. The electrostatic force causes the colorant particles and the carrier liquid to be pulled to the bias voltage (counter electrode) side, that is, the recording medium P side, so that the meniscus formed at the ejection port grows upward and substantially above the ejection port 28. A conical ink liquid column so-called tailor cone is formed. Similarly to the above, the color material particles are moved to the meniscus by electrophoresis and the electric field from the discharge electrode, and the meniscus ink Q is concentrated and has a large number of color material particles. It is in a state.

When a finite time has passed after the start of application of the drive voltage to the discharge electrode 18, a force (Coulomb force) mainly acting on the color material particles at the tip portion of the meniscus having a high electric field strength due to movement of the color material particles or the like. Etc.) and the surface tension of the carrier liquid are lost, and the meniscus is abruptly stretched to form an elongated ink liquid column having a diameter of several μm to several tens of μm, which is called a kite string.
Further, when a finite time elapses, the silk thread grows, and the growth of the silk thread, vibration caused by Rayleigh / Weber instability, uneven distribution of colorant particles in the meniscus, uneven distribution of electrostatic field on the meniscus, etc. The silk thread is broken by the interaction. Then, the divided string is ejected as ink droplets R, flies toward the recording medium, and is pulled by the bias voltage to land on the recording medium P. It should be noted that the growth and splitting of the kite and the movement of the color material particles to the meniscus (spinner) occur continuously during the application of the drive voltage. Therefore, by adjusting the time during which the drive voltage is applied, the ink droplet ejection amount per pixel can be adjusted.
Further, when the application of the driving voltage is finished (discharge is turned off), the state returns to the state of the meniscus to which only the bias voltage is applied.

Here, as shown in FIG. 1, the ejection port of the inkjet head of the present invention has an elongated slit shape elongated in the ink flow direction. In this way, the ejection port 28 is formed into an elongated slit-like long hole shape, that is, a shape in which the aspect ratio between the length in the ink flow direction and the length in the direction perpendicular to the ink flow is 1 or more, whereby the ink is ejected from the ejection port. It becomes easy to flow inside, and the ink particle supply property to the ejection port 28 becomes high. Thereby, the ink particle supply property to the ink guide tip 14a can be improved. Therefore, the ejection frequency at the time of image recording is improved, and a dot of a desired size can be stably drawn even if dots are drawn continuously at a high speed. Furthermore, by setting the aspect ratio of the ejection port to 1 or more, the flow of ink becomes smooth and clogging at the ejection port can be prevented.
In consideration of the image output time, it is desired that the ejection frequency can be drawn at 5 kHz, preferably at 10 kHz, more preferably at 15 kHz.

Here, the ejection port preferably has an aspect ratio of 1.5 or more between the ink flow direction and the direction perpendicular thereto.
By setting the aspect ratio to 1.5 or more, ink supply to the ink guide is further improved, and even when continuous large dots are formed, dots can be formed more stably, with higher frequencies. Drawing can be performed at a drawing frequency.

  Here, as in the above-described embodiment, the above-described effect is more preferable by making the opening shape of the ejection port a shape in which the aspect ratio between the length in the ink flow direction and the length in the direction perpendicular to the ink flow is 1 or more. However, the ink jet head of the present invention is not limited to this, and by making the opening shape of the ejection port the aspect ratio of the major axis and minor axis of the aperture to 1 or more, the flow of ink is made smooth, Clogging at the exit can be prevented.

  Further, it is preferable that the ejection electrode has a shape in which a part of the upstream side in the ink flow direction is missing as in the present embodiment. Accordingly, since an electric field that prevents the inflow of the color material particles from the upstream side in the ink flow direction to the ejection port is not formed, the color material particles can be efficiently supplied to the ejection port. Further, by disposing the ejection electrode on the downstream side of the ink, an electric field is formed in a direction in which the color material particles flowing into the ejection port are retained at the ejection port. As described above, by making the ejection electrode into a shape in which the upstream side in the ink flow direction is partially missing, it is possible to further improve the ability to supply particles to the ejection port.

Here, FIGS. 5A to 5F are schematic views showing various forms of the ejection electrode. Here, in FIGS. 5A to 5F, it is assumed that ink flows from the left to the right in the drawing.
As shown in FIG. 5A, the discharge electrode is symmetrical with respect to a plane (X-ray in FIG. 5A) that passes through the center of the discharge port and is parallel to the major axis direction of the discharge port. A longitudinal portion of the discharge electrode formed in the major axis direction of the outlet, that is, a portion of the ejection electrode excluding the hatched portion S in FIG. 5A passes through the center of the ejection port and is orthogonal to the major axis direction of the ejection port. It is preferable to have a symmetric shape with respect to (Y line in FIG. 5A).
Since the discharge part has a high contribution to the electric field formation, and it is the longitudinal part of the discharge electrode that works substantially effectively. By forming the discharge electrode as described above, it passes through the center of the discharge port and the discharge port. An electric field that is substantially symmetrical with respect to the plane parallel to the major axis direction and a plane perpendicular to the longitudinal direction is formed, the ejection position is stable, and the landing position of the ink droplet can be made constant, enabling more stable image formation. Thus, a high-quality image can be formed.
Further, since the ejection electrode shown in FIG. 5A has a shape in which a part of the upstream side of the ink is cut out, the particle supply property to the ejection port is improved as described above, and the ejection of the ink droplet is performed. The position can be stabilized.

Here, in the above embodiment, the ejection electrode has a U-shape in which one side on the upstream side of the ink flow is cut out, but the present invention is not limited to this. For example, an elongated saddle-shaped shape in which both short sides of a rectangle obtained by cutting out a part of the upstream side of the ink flow as shown in FIG. 5B are semicircular may be used, as shown in FIG. An elliptical shape in which a long axis and a direction parallel to the ink flow direction are formed and a part on the upstream side of the ink flow is cut off may be used. Furthermore, a parallel electrode in which rectangular electrodes as shown in FIG. 5D are arranged in parallel to the major axis direction of the discharge port can also be suitably used.
Thus, with respect to a plane (X-ray in FIGS. 5A to 5D) passing through the center of the ejection port as shown in FIGS. 5A to 5D and parallel to the longitudinal direction of the ejection port. In addition, the discharge electrode shown in FIG. 5 (D) is a portion excluding the shaded portion S, which is symmetrical, and further, the discharge electrode shown in FIG. 5 (A), FIG. 5 (B) and FIG. The discharge electrode has a shape that is symmetric with respect to a plane that passes through the center of the discharge port and that is parallel to the direction perpendicular to the major axis direction of the discharge port (the Y line in FIGS. 5A to 5D). As a result, the landing position of the ink droplet can be stabilized, and a higher quality image can be formed.
Also, the discharge electrodes shown in FIGS. 5B to 5D have a shape in which a part of the upstream side of the ink flow is cut out, similarly to the discharge electrodes shown in FIG. The particle supply property can also be improved.

  Here, the shape of the discharge port is not limited to a long and narrow bowl shape, and may be a shape in which the aspect ratio of the major axis and the minor axis of the opening is 1 or more. For example, as shown in FIG. In this case, as described above, it is symmetric with respect to a plane passing through the center of the ejection port and parallel to the longitudinal direction of the ejection port (X-ray in FIG. 5E), and further, the longitudinal portion of the ejection electrode (FIG. 5 (E), the portion excluding the hatched portion S) is symmetric with respect to a plane that passes through the center of the discharge port and is perpendicular to the longitudinal direction (Y line in FIG. 5E). The ejection position of the ink droplet can be stabilized.

  Also, the major axis direction of the ejection port is not limited to the direction parallel to the ink flow, and the major axis direction of the ejection port may be any direction, and the shape of the ejection electrode with respect to the opening shape of the ejection port passes through the center of the ejection port. Further, it is symmetric with respect to a plane parallel to the major axis direction of the discharge port, and further, the longitudinal part of the discharge electrode has a symmetrical shape with respect to a plane that passes through the center of the discharge port and is orthogonal to the major axis direction of the discharge port. As a result, the ink droplet ejection position can be stabilized.

  Further, the shape of the discharge electrode is symmetrical with respect to a plane that passes through the center of the discharge port and is parallel to the major axis direction of the discharge port from the point that a substantially symmetric electric field can be easily formed on the discharge port. Furthermore, it is preferable that the longitudinal portion of the ejection electrode has a symmetric shape with respect to a plane that passes through the center of the ejection port and is orthogonal to the major axis direction of the ejection port. The effective part which contributes to the discharge of a droplet should just be a shape substantially symmetrical with respect to the discharge outlet. As an example, as shown in FIG. 5 (F), the ink upstream side is rectangular and the ink downstream side is semi-circular, and the longitudinal part (the part excluding the hatched part S in FIG. 5 (F)). ) Is not symmetrical with respect to a plane (Y line in FIG. 5F) that passes through the center of the discharge port and is orthogonal to the major axis direction of the discharge port. That is, an electric field that is substantially point-symmetric with respect to the center of the ejection port or an electric field that is substantially symmetrical with respect to a plane that passes through the center of the ejection port and is perpendicular to the major axis direction of the ejection port. The droplet discharge position can be stabilized.

  5A to 5F, the discharge electrode is notched, but the present invention is not limited to this. For example, a circular electrode or an ellipse without a notch is formed. The electrode, the rectangular electrode, etc. also have an effective portion that contributes to the ejection of the ink droplets of the ejection electrode in a shape that is substantially symmetrical with respect to the ejection port, preferably the center of the ejection port and the major axis direction of the ejection port. The ink droplets are symmetrical with respect to a parallel plane, and the longitudinal portion of the discharge electrode is symmetrical with respect to a plane that passes through the center of the discharge port and is orthogonal to the major axis direction of the discharge port. The discharge position can be stabilized.

  Further, the shape of the discharge electrode is not limited to the above shape, and the discharge electrode is symmetrical with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and is formed in the longitudinal direction formed in the major axis direction of the ejection port. A shape in which the length of the part is longer than the length in the major axis direction of the ejection port, or the ejection electrode is symmetric about a line passing through the center of the ejection port and parallel to the major axis direction, and the major axis direction of the ejection port A shape in which the center of the longitudinal part formed on the surface passes through the center of the discharge port and is perpendicular to the major axis direction, or the discharge electrode is symmetrical with respect to a plane that passes through the center of the discharge port and is parallel to the major axis direction In addition, it is possible to stabilize the ejection position of the ink droplets by forming the center of the longitudinal portion formed in the major axis direction of the ejection port on the plane passing through the center of the ejection port and perpendicular to the major axis direction. Can do.

In the inkjet head 10 shown in FIGS. 1A and 1B, the ejection electrode 18 is exposed to the ink flow path 30. That is, the ejection electrode 18 is in contact with the ink Q in the ink flow path 30.
As described above, when the drive voltage is applied to the discharge electrode 18 in contact with the ink Q in the ink flow path 30 (discharge is turned on), a part of the charge supplied to the discharge electrode 18 is injected into the ink Q, and the discharge port 28. The conductivity of the ink Q located between the discharge electrode 18 and the discharge electrode 18 is increased. Therefore, in the inkjet head 10 of the present embodiment, the ink Q is in a state in which the ink droplet R is easily ejected when the driving voltage is applied to the ejection electrode 18 (when ejection is on) (the ejection performance is improved). To do).
Further, by applying a voltage having the same polarity as that of the color material particles to the U-shaped ejection electrode 18 at the time of non-ejection, that is, when no driving voltage is applied, electric charge is injected into the ink even at the time of non-ejection. As a result, the conductivity of the ink can be further increased, and the charged color material particles floating in the ink flowing from the upstream side can be reliably held down by the discharge port 28 by the electrostatic force generated by the discharge electrode 18.

Here, the ink used for the inkjet head 10 of this invention is demonstrated.
Ink Q is obtained by dispersing colorant particles in a carrier liquid. The carrier liquid is preferably a dielectric liquid (nonaqueous solvent) having a high electric resistivity (10 ⁹ Ω · cm or more, preferably 10 ¹⁰ Ω · cm or more). If the electric resistance of the carrier liquid is low, the carrier liquid itself is charged by charge injection due to the drive voltage applied to the control electrode, and the colorant particles do not concentrate. In addition, a carrier liquid having a low electrical resistance is not suitable because there is a concern of causing electrical conduction between adjacent control electrodes.

The relative dielectric constant of the dielectric liquid used as the carrier liquid is preferably 5 or less, more preferably 4 or less, and still more preferably 3.5 or less. By setting the relative dielectric constant in such a range, an electric field effectively acts on the colorant particles in the carrier liquid, and migration easily occurs.
Note that the upper limit value of the specific electric resistance of such a carrier liquid is desirably about 10 ¹⁶ Ω · cm, and the lower limit value of the relative dielectric constant is desirably about 1.9. The reason why it is desirable that the electric resistance of the carrier liquid is in the above range is that if the electric resistance is low, ink ejection under a low electric field is deteriorated, and the reason why the relative dielectric constant is preferably in the above range is the reason. This is because, when the dielectric constant increases, the electric field is relaxed by the polarization of the solvent, and the color of the dots formed thereby becomes thin or causes blurring.

  The dielectric liquid used as the carrier liquid is preferably a linear or branched aliphatic hydrocarbon, alicyclic hydrocarbon, or aromatic hydrocarbon, and halogen-substituted products of these hydrocarbons. For example, hexane, heptane, octane, isooctane, decane, isodecane, decalin, nonane, dodecane, isododecane, cyclohexane, cyclooctane, cyclodecane, benzene, toluene, xylene, mesitylene, Isopar C, Isopar E, Isopar G, Isopar H, Isopar L, Isopar M (isopar: trade name of Exxon), Shellsol 70, Shellsol 71 (shellsol: trade name of Shell Oil), Amsco OMS, Amsco 460 Solvent (trade name of Amsco: Spirits), Silicone oil (for example, KF-96L manufactured by Shin-Etsu Silicone) or the like can be used alone or in combination.

  The colorant particles dispersed in such a carrier liquid may be dispersed in the carrier liquid as the colorant itself as colorant particles, but preferably contain dispersed resin particles for improving fixability. When the dispersed resin particles are included, the pigment is generally coated with the resin material of the dispersed resin particles to form resin-coated particles, and the dye is colored with the dispersed resin particles to form colored particles. Is common.

As the color material, any pigments and dyes that have been conventionally used in inkjet ink compositions, printing (oil-based) ink compositions, or electrophotographic liquid developers can be used.
As the pigment used as the color material, regardless of inorganic pigments or organic pigments, those generally used in the technical field of printing can be used. Specifically, for example, carbon black, cadmium red, molybdenum red, chrome yellow, cadmium yellow, titanium yellow, chromium oxide, viridian, cobalt green, ultramarine blue, Prussian blue, cobalt blue, azo pigment, phthalocyanine pigment Conventionally known pigments such as quinacridone pigments, isoindolinone pigments, dioxazine pigments, selenium pigments, perylene pigments, perinone pigments, thioindigo pigments, quinophthalone pigments and metal complex pigments are used without particular limitation. be able to.
As dyes used as coloring materials, azo dyes, metal complex dyes, naphthol dyes, anthraquinone dyes, indigo dyes, carbonium dyes, quinoneimine dyes, xanthene dyes, aniline dyes, quinoline dyes, nitro dyes, nitroso dyes, benzoquinone dyes, naphthoquinone dyes And oil-soluble dyes such as phthalocyanine dyes and metal phthalocyanine dyes.

Further, as dispersed resin particles, for example, rosins, rosin-modified phenol resins, alkyd resins, (meth) acrylic polymers, polyurethane, polyester, polyamide, polyethylene, polybutadiene, polystyrene, polyvinyl acetate, polyvinyl alcohol, polyvinyl alcohol, acetal-modified Products, polycarbonate and the like.
Among these, from the viewpoint of ease of particle formation, the weight average molecular weight is in the range of 2,000 to 1,000,000 and the polydispersity (weight average molecular weight / number average molecular weight) is 1.0 to 5 Polymers in the range of 0.0 are preferred. Furthermore, from the viewpoint of ease of fixing, a polymer having any one of a softening point, a glass transition point, and a melting point within a range of 40 ° C. to 120 ° C. is preferable.

  In the ink Q, the content of the color material particles (the total content of the color material particles or further dispersed resin particles) is preferably contained in the range of 0.5 to 30% by weight with respect to the whole ink, and more preferably. Is preferably contained in the range of 1.5 to 25% by weight, more preferably 3 to 20% by weight. If the content of the colorant particles is reduced, problems such as insufficient printed image density or difficulty in obtaining a strong image due to difficulty in obtaining the affinity between the ink Q and the surface of the recording medium P are likely to occur. On the other hand, when the content increases, it becomes difficult to obtain a uniform dispersion, or the ink Q is easily clogged with an inkjet head or the like, and it is difficult to obtain stable ink discharge. .

  The average particle diameter of the colorant particles dispersed in the carrier liquid is preferably 0.1 to 5 μm, more preferably 0.2 to 1.5 μm, and still more preferably 0.4 to 1.0 μm. . This particle size is determined by CAPA-500 (trade name, manufactured by Horiba, Ltd.).

After the colorant particles are dispersed in the carrier liquid (a dispersant may be used if necessary), the chargeant is added to the carrier liquid to charge the colorant particles, and the charged colorant The ink Q is obtained by dispersing particles in a carrier liquid. When dispersing the colorant particles, a dispersion medium may be added as necessary.
As an example of the charge control agent, various materials used in electrophotographic liquid developers can be used. Also, “Recent development and commercialization of electrophotographic development systems and toner materials”, pages 139 to 148, “The Basics and Applications of Electrophotographic Technology” edited by Electrophotographic Society, pages 497 to 505 (Corona Inc., published in 1988), Yuji Harasaki Various charge control agents described in “Electrophotography” 16 (No. 2), p. 44 (1977) can also be used.

The color material particles may be positively charged or negatively charged as long as they have the same polarity as the drive voltage applied to the control electrode.
The charge amount of the color material particles is preferably in the range of 5 to 200 μC / g, more preferably 10 to 150 μC / g, and still more preferably 15 to 100 μC / g.

In addition, since the electric resistance of the dielectric solvent may change due to the addition of the charge control agent, the distribution ratio P defined below is preferably 50% or more, more preferably 60% or more, and even more preferably 70% or more. And
P = 100 × (σ1−σ2) / σ1
Here, σ1 is the electrical conductivity of the ink Q, and σ2 is the electrical conductivity of the supernatant obtained by applying the ink Q to the centrifuge. The electrical conductivity was measured using an LCR meter (AG-4311 manufactured by Ando Electric Co., Ltd.) and an electrode for liquid (LP-05 type manufactured by Kawaguchi Electric Manufacturing Co., Ltd.) under the conditions of an applied voltage of 5 V and a frequency of 1 kHz. This is the measured value. Centrifugation was performed for 30 minutes using a small high-speed cooling centrifuge (Tomy Seiko Co., Ltd. SRX-201) under conditions of a rotational speed of 14500 rpm and a temperature of 23 ° C.
By using the ink Q as described above, migration of charged particles is likely to occur, and concentration is facilitated.

The electrical conductivity of the ink Q is preferably 100 to 3000 pS / cm, more preferably 150 to 2500 pS / cm, and still more preferably 200 to 2000 pS / cm. By setting the electric conductivity in the above range, the voltage applied to the control electrode does not become extremely high, and there is no fear of causing electrical continuity between adjacent recording electrodes.
The surface tension of the ink Q is preferably in the range of 15 to 50 mN / m, more preferably 15.5 to 45 mN / m, and still more preferably 16 to 40 mN / m. By setting the surface tension within this range, the voltage applied to the control electrode does not become extremely high, and the ink does not leak around the head to be contaminated.
Furthermore, the viscosity of the ink Q is preferably 0.5 to 5 mPa · sec, more preferably 0.6 to 3.0 mPa · sec, and still more preferably 0.7 to 2.0 mPa · sec.

As an example, such an ink Q can be prepared by dispersing color material particles in a carrier liquid to form particles, and adding a charge adjusting agent to the dispersion medium to cause the color material particles to be charged. Specific methods include the following methods.
(1) A method in which a color material or further dispersed resin particles are mixed (kneaded) in advance, and then dispersed in a carrier liquid using a dispersant as required, and a charge adjusting agent is added.
(2) A method in which a coloring material, or further dispersed resin particles and a dispersing agent are simultaneously added to a carrier liquid, dispersed, and a charge adjusting agent is added.
(3) A method in which a coloring material and a charge adjusting agent, or further dispersed resin particles and a dispersing agent are simultaneously added to a carrier liquid and dispersed.

FIG. 6 shows a conceptual diagram of an embodiment of the ink jet recording apparatus of the present invention using the ink jet head of the present invention.
An ink jet recording apparatus 60 (hereinafter referred to as a printer 60) shown in the figure is an apparatus that performs four-color printing on one side of a recording medium P, and includes a conveying means for the recording medium P, an image recording means, and a solvent recovery means. Yes, these are housed in a housing 61.
The conveying means includes a feed roller pair 62, a guide 64, rollers 66 (66a, 66b and 66c), a conveying belt 68, a conveying belt position detecting means 69, an electrostatic adsorption means 70, a static eliminating means 72, a peeling means 74, and a fixing. -It has the conveyance means 76 and the guide 78. The image recording forming unit includes a head unit 80, an ink circulation system 82, a head driver 84, and a recording medium position detecting unit 86. Further, the solvent recovery means includes a discharge fan 90 and a solvent recovery device 92.

  In the conveyance means for the recording medium P, the feed roller pair 62 is a conveyance roller pair provided adjacent to the carry-in port 61 a provided on the side surface of the housing 61. The feed roller 62 feeds the recording medium P supplied from a stocker (not shown) to the transport belt 68 (portion supported by the roller 66a). The guide 64 is provided between the feed roller pair 62 and a roller 66 a that supports the conveyance belt 68, and guides the recording medium P to the conveyance belt 68.

It should be noted that a foreign matter removing means for removing foreign matter such as dust and paper dust adhering to the recording medium P is preferably provided in the vicinity of the feed roller pair 62.
As the foreign matter removing means, one or more of non-contact methods such as known suction removal, blow-off removal, electrostatic removal, and contact methods using brushes, rollers, etc. may be used in combination. Alternatively, the feed roller pair 62 may be a slightly adhesive roller, and a cleaner for the feed roller pair 62 may be provided to remove foreign matters such as dust and paper powder when the recording medium P is fed by the feed roller pair 62.

The conveyor belt 68 is an endless belt stretched around the three rollers 66. At least one of the rollers 66a, 66b, and 66c is connected to a drive source (not shown), and rotates the conveyor belt 68.
The conveyance belt 68 functions as a platen for holding the recording medium P in addition to the scanning conveyance means for the recording medium P during image recording by the head unit 80, and further conveys the image to the fixing / conveyance means 76 after image recording. Therefore, the transport belt 68 is preferably formed of a material having excellent dimensional stability and durability. For example, the transport belt 68 is formed of a metal, a polyimide resin, a fluororesin, another resin, or a composite thereof.

In the illustrated example, since the recording medium P is held on the conveyance belt 68 by electrostatic attraction, the conveyance belt 68 is insulative on the side (front surface) that holds the recording medium P and is in contact with the roller 66 (back surface). ) Has conductivity. In the illustrated example, the roller 66a is a conductive roller, and the back surface of the transport belt 68 is grounded via the roller 66a.
That is, the conveyance belt 68 functions as the counter electrode 24 composed of the electrode substrate 24a and the insulating sheet 24b shown in FIG. 1A when holding the recording medium P.

As such a transport belt 68, a metal belt coated with a fluororesin on the surface side of the metal belt, a belt coated with any of the above resin materials on a metal belt, a resin sheet and a metal belt are bonded together with an adhesive or the like. A belt having a metal layer and an insulator layer manufactured by various methods such as a metal belt or a belt formed by metal vapor deposition on the back surface of a belt made of the above resin may be used.
Further, it is preferable that the surface of the conveying belt 68 that contacts the recording medium P is smooth, and thereby, good adsorbability of the recording medium P can be obtained.

  The conveyor belt 68 is preferably suppressed from meandering by a known method. As a meandering suppression method, for example, the roller 66c is a tension roller, and the shaft of the roller 66c is adjusted between the roller 66a and the roller 66b in accordance with the output of the conveying belt position detecting means 69, that is, the detecting position in the width direction of the conveying belt 68. A method of suppressing meandering by changing the tension at both ends in the width direction of the conveyor belt by tilting with respect to the axis is exemplified. Further, the meandering may be suppressed by forming the roller 66 in a tapered shape, a crown shape, or other shapes.

  Here, as described above, the conveying belt position detecting unit 69 suppresses the meandering of the conveying belt and regulates the position of the recording medium P in the scanning conveying direction at the time of image recording to a predetermined position. 68 is used to detect the position in the width direction, and known detection means such as a photosensor is used.

The electrostatic attraction means 70 applies a predetermined bias voltage to the head unit 80 (the ink jet head of the present invention) to the recording medium P and attracts it to the conveying belt 68 by electrostatic force to hold it. Is charged to a predetermined potential.
In the illustrated example, the electrostatic attraction unit 70 includes a scorotron charger 70a for charging the recording medium P, and a negative high-voltage power supply 70b connected to the scorotron charger 70a. While the recording medium P is conveyed by the feed roller pair 62 and the conveying belt 68, the recording medium P is charged with a negative bias voltage by the scorotron charger 70a connected to the negative high voltage power source 70b, and is applied to the insulating layer of the conveying belt 68. It is electrostatically attracted.

In addition, the conveyance speed of the conveyance belt 68 when charging the recording medium P may be in a range that can be stably charged, and may be the same as or different from the conveyance speed at the time of image recording. Alternatively, the recording medium P may be rotated a plurality of times so that the electrostatic adsorption means acts on the same recording medium P a plurality of times to perform uniform charging.
In the illustrated example, the electrostatic adsorption unit 70 performs electrostatic adsorption and charging of the recording medium P. However, the electrostatic adsorption unit and the charging unit may be provided separately.

  The electrostatic attraction means is not limited to the illustrated scorotron charger 70a, and various other means and methods such as a corotron charger, a solid charger, and a discharge needle can be used. Further, as will be described in detail later, at least one of the rollers 66 is a conductive roller, or a conductive platen is provided on the back surface side (opposite side of the recording medium P) of the conveying belt 68 at the recording position on the recording medium P. By arranging and connecting this conductive roller or conductive platen to a negative high voltage power source, the electrostatic attraction means 70 may be configured, or the conveying belt 68 is an insulating belt and the conductive roller is grounded. The conductive platen may be connected to a negative high voltage power source.

The recording medium P charged by the electrostatic attraction means 70 is transported to the position of the head unit 80 described later by the transport belt 68.
The head unit 80 records an image on the recording medium P by ejecting ink droplets according to image data using an inkjet head that performs the inkjet head control method of the present invention. Here, the ink jet head of the present invention discharges the ink droplet R by superimposing the drive voltage on the bias voltage by applying the drive voltage to the discharge electrode 18 with the charging potential of the recording medium P as the bias voltage, The image is recorded on the recording medium P as described above. At this time, by providing a heating means for the conveying belt 68 and increasing the temperature of the recording medium P, fixing of the ink droplets R on the recording medium P can be promoted, and bleeding is further suppressed and image quality is improved. Can be achieved.
The image recording by the head unit 80 or the like will be described in detail later.

The recording medium P on which the image is recorded is discharged by the discharging unit 72, peeled off from the transport belt 68 by the peeling unit 74, and transported to the fixing / transporting unit 76.
In the illustrated example, the static elimination unit 72 is a so-called AC corotron static eliminator having a corotron static eliminator 72a, an AC power source 72b, and a DC high-voltage power source 72c grounded at one end. In addition to the above, as the static elimination means, various means and methods such as a scorotron static eliminator, a solid charger, a discharge needle, etc. can be used, and a conductive roller, A configuration using a conductive platen is also preferably used.
As the peeling means 74, a known technique such as a peeling blade, a reverse rotation roller, an air knife or the like can be used.

The recording medium P peeled off from the conveying belt 68 is sent to the fixing / conveying means 76, and the image formed by ink jet is fixed. A roller pair including a heat roller 76a and a conveyance roller 76b is used as the fixing / conveying means 76, and the recorded image is heated and fixed while the recording medium P is nipped and conveyed.
The recording medium P on which the image is fixed is guided by a guide 78 and discharged to a discharge stocker (not shown).

Examples of the heat fixing means include general heat fixing such as irradiation with infrared rays or a halogen lamp or a xenon flash lamp, or hot air fixing using a heater, in addition to the heat roll fixing described above. In the heat fixing / conveying means 76, the heating means performs only heating, and the conveying means and the heat fixing means may be provided separately.
In the case of heat fixing, when coated paper or laminated paper is used as the recording medium P, a phenomenon called blistering occurs in which the water inside the paper rapidly evaporates due to a rapid temperature rise and the paper surface is uneven. May occur. In order to prevent this, it is preferable to arrange a plurality of fixing devices and change one or both of the power supply of each fixing device and the distance to the recording medium P so that the temperature of the recording medium P gradually increases.

The printer 60 is preferably configured so that nothing touches the image recording surface of the recording medium P from at least the image recording by the head unit 80 until the fixing by the fixing / conveying means 76 is completed.
Further, the moving speed of the recording medium P at the time of fixing in the fixing / conveying means 76 is not particularly limited, and may be the same as or different from the conveying speed by the conveying belt 68 at the time of image formation. . When the conveyance speed is different from that at the time of image formation, it is preferable to provide a speed buffer for the recording medium P immediately before the fixing / conveyance means 76.

Hereinafter, image recording in the printer 60 will be described in detail.
As described above, the image recording means of the printer 60 includes the head unit 80 that discharges the ink jet, the ink circulation system 82 that supplies and recovers the ink Q to the head unit 80, a computer (not shown), a RIP (Raster Image Processor), and the like. A head driver 84 that drives the head unit 80 by an output image signal from an external device, and a recording medium position detecting unit 86 that detects the recording medium P in order to determine the image recording position in the recording medium P are configured.

FIG. 6B is a perspective view schematically showing the head unit 80 and the conveying means for the recording medium P around it.
The head unit 80 has four inkjet heads 80a corresponding to ink ejection of four colors of cyan (C), magenta (M), yellow (Y), and black (K) for recording a full color image. Then, in accordance with a signal from the head driver 84 supplied with the image data, the ink Q supplied by the ink circulation system 82 is ejected as an ink droplet R, and the recording medium P being conveyed by the conveying belt 68 at a predetermined speed. Record an image on The inkjet heads 80 a for the respective colors are arranged in the conveyance direction of the conveyance belt 68.
In addition, the inkjet head 80a of each color of the head unit 80 is an inkjet head according to the present invention.

In the illustrated example, the inkjet heads 80a are line heads in which the ejection ports 28 are arranged in the entire width direction of the recording medium P, and are preferably arranged in a staggered manner as shown in FIG. And a multi-channel head having a plurality of nozzle rows.
Accordingly, in the illustrated example, the recording medium P is held by the transport belt 68 and the recording medium P is simply passed through the head unit 80 once by transport, that is, only one scanning transport is performed. An image is formed on the entire surface of the recording medium P. Therefore, image recording (drawing) can be performed at a higher speed than when the ejection head is serially scanned.

The ink jet head of the present invention can also be used for a so-called serial head (shuttle type). Therefore, the printer 60 may also be in this mode.
In this case, the head unit 80 is configured by aligning the row of the ejection ports 28 of each inkjet head (which may be single row or multi-channel) with the carrying direction of the carrying belt 68, and the head unit 80 is carried by the recording medium P. Scanning means for scanning in a direction orthogonal to the direction is provided. As the scanning means, known scanning means can be used.
The image recording may be performed in the same manner as a normal shuttle type ink jet printer. The recording medium P is intermittently conveyed by the conveying belt 68 according to the length of the row of the ejection ports 28, and is synchronized with the intermittent conveyance. Then, at the time of stop, the head unit 80 is scanned to record an image on the entire surface of the recording medium P.
Thus, the image formed on the entire surface of the recording medium P by the head unit 80 is fixed by the fixing / conveying means 76 by the recording medium P being nipped and conveyed by the fixing / conveying means 76 as described above. Is done.

The head driver 84 receives image data from an external device, receives image data from a system control unit (not shown) that performs various processes, and drives the head unit 80 based on the image data.
This system control unit performs color separation, division into appropriate numbers of pixels and gradations, etc. on image data received from external devices such as computers, RIPs, image scanners, magnetic disk devices, and image data transmission devices. Thus, the head driver 84 serves as image data for driving the head unit 80 (inkjet head). Further, the system control unit controls the ink ejection timing by the head unit 80 in accordance with the conveyance timing of the recording medium P by the conveyance belt 68. The discharge timing is controlled by using an output from the recording medium position detecting unit 86 and an output signal from the encoder disposed on the conveying belt 68 or the driving unit of the conveying belt 68.
The recording medium position detection means 86 is for detecting the recording medium P conveyed to the ink droplet ejection position by the head unit 80, and an already known detection means such as a photosensor is used. it can.
Here, the head driver 84 divides the drawing when there are a large number of ejection units (number of channels) to be controlled, such as when a line head is applied, and a known resistance matrix driving method or resistance diode matrix driving method. May be used. Thereby, the number of ICs used by the head driver 84 can be reduced, and the cost can be reduced and the control circuit size can be suppressed.

  The ink circulation system 82 is for flowing the ink Q through the ink flow paths 30 (see FIG. 1) of the ink jet heads 80a of the respective colors of the head unit 80, and inks of four colors (C, M, Y, K). An ink circulation device 82a having a tank, a pump, a replenishment ink tank (not shown), and the like, and ink Q of each color is supplied from the ink tank of the ink circulation device 82a to the ink flow path 30 of each color inkjet head of the head unit 80 An ink supply system 82b for recovering ink from the ink flow path 30 of the ink jet head of each color of the head unit 80 to the ink circulation device 82a.

The ink circulation system 82 supplies ink Q for each color from the ink tank to the head unit 80 via the ink supply system 80b by the ink circulation device 82a, and for each color from the head unit 80 via the ink supply system 80c. Any ink Q can be used as long as it can be collected and circulated in the ink tank.
The ink tank stores ink Q of each color, and the ink Q is pumped out by a pump and sent to the head unit 80. As the ink is discharged from the head unit 80, the density of the ink circulating in the ink circulation system 82 is decreased. In the ink circulation system 82, the ink density is detected by the ink density detector and replenished accordingly. It is desirable to appropriately replenish ink from the ink tank and maintain the ink density within a predetermined range.

Further, the ink tank is preferably provided with a stirring device for suppressing precipitation / concentration of the solid component of the ink and an ink temperature management device for suppressing temperature change of the ink. This is because if the temperature is not controlled, the ink temperature changes due to changes in the environmental temperature, etc., and the dot diameter changes due to changes in the physical properties of the ink, making it impossible to stably form high-quality images. Because there is.
As the stirring device, a rotary blade, an ultrasonic vibrator, a circulation pump, or the like can be used.
As the ink temperature control device, a known method such as a method in which a heating element such as a heater or a Peltier element or a cooling element is arranged in the head unit 80, ink tank, ink piping system, etc., and control is performed by a temperature sensor, for example, a thermostat. Can be used. When the temperature control device is arranged in the ink tank, it is preferable to arrange it together with the stirring device so as to make the temperature distribution constant. Further, the stirring device for keeping the concentration distribution in the tank constant may be shared with the stirring device for suppressing the precipitation and concentration of the solid component of the ink.

As described above, the printer 60 has the solvent recovery means including the exhaust fan 90 and the solvent recovery device 92. The solvent recovery means recovers the carrier liquid that evaporates from the ink droplets ejected from the head unit 80 onto the recording medium P, particularly the carrier liquid that evaporates from the recording medium P when fixing the image formed by the ink droplets. To do.
The discharge fan 90 is for sucking air inside the casing 61 of the printer 60 and sending it to the solvent recovery device 92.
The solvent recovery device 92 includes a solvent vapor absorber, and adsorbs the solvent component of the gas containing the solvent vapor sucked by the exhaust fan 90 to the solvent vapor absorber, and the gas after the solvent is adsorbed and recovered. The paper is discharged out of the casing 61 of the printer 60. As the solvent vapor absorbing material, various activated carbons are preferably used.

  In the above description, an electrostatic ink jet recording apparatus that records a color image using four color inks of C, M, Y, and K has been described. However, the present invention is not limited to this, and a monochrome recording apparatus Alternatively, recording may be performed using an arbitrary number of inks of other colors, for example, light colors or special colors. In that case, the number of head units 80 and ink circulation systems 82 corresponding to the number of ink colors are used.

  In each of the above examples, the ink jet discharges ink droplets R by charging the color material particles in the ink positively and setting the opposite electrode on the back of the recording medium or recording medium P to a negative high voltage. However, the present invention is not limited to this, and conversely, the color material particles in the ink may be negatively charged, and the recording medium or the counter electrode may be set to a positive high voltage to perform image recording by inkjet. . Thus, when the polarity of the colored charged particles is reversed from the above example, the polarity of the voltage applied to the electrostatic adsorption means, the counter electrode, and the drive electrode of the inkjet head may be reversed from the above example. .

  Here, the ink jet head of the present invention is preferably used in the electrostatic ink jet recording method described above, but is not limited to this, and can be used in various ink jet recording methods such as a piezo method and a thermal method.

  As described above, the ink jet head and the ink jet recording apparatus of the present invention have been described in detail. However, the present invention is not limited to the above embodiment, and various improvements and modifications can be made without departing from the gist of the present invention. Of course it is good.

(A) is the schematic diagram which showed schematic structure of the inkjet head according to this invention, (B) is the IB-IB line arrow directional view of (A). 2 is a schematic diagram illustrating a state in which a plurality of discharge ports are two-dimensionally arranged on the discharge port substrate 16 of the inkjet head. FIG. It is the schematic diagram which showed the planar structure of the guard electrode of the inkjet head of a multichannel structure. (A) is a partial cross-sectional perspective view showing the configuration in the vicinity of the ejection portion in the ink jet head of FIG. 1, and (B) is a diagram for explaining the shape dimensions of the ink guide weir. (A)-(F) is a schematic diagram which shows an example of the shape of a discharge electrode, respectively. (A) is a conceptual diagram of an embodiment of the ink jet recording apparatus of the present invention using the ink jet head of the present invention, and (B) shows a transport unit for the head unit 80 and its surrounding recording medium P. It is a perspective view showing typically. It is a schematic diagram which shows an example of the conventional inkjet head.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Inkjet head 12 Head substrate 14 Ink guide 14a Tip part 16 Discharge port substrate 18 Discharge electrode 20 Guard electrode 24 Counter electrode 24a Electrode substrate 24b Insulating sheet 26a Scorotron charger 26b Bias voltage source 28 Each discharge port 30 Ink flow path 32 Insulating substrate 33 Control Unit 36 Opening 40 Guide Weir 60 Inkjet Recording Device (Inkjet Printer)
62 Feed roller 64 Guide 66 Roller 66a Roller 68 Conveying belt 69 Conveying belt position detecting means 70 Electrostatic adsorption means 70a Scorotron charger 70b High voltage power supply 72 Discharge means 72a Corotron neutralizer 72b AC power supply 72c DC high voltage power supply 76 Fixing / conveying means 76a Heat roller 78 Guide 80 Head unit 80a Each inkjet head 80b, 80c Ink supply system 82 Ink circulation system 82a Ink circulation device 82b Ink supply system 82c Ink collection system 84 Head driver 86 Recording medium position detection means 90 Discharge fan P Recording medium Q Ink R Ink droplet

Claims (13)

An inkjet head that ejects ink as ink droplets,
Having a discharge port for discharging ink droplets;
2. An ink jet head according to claim 1, wherein an opening shape of the discharge port is a shape having an aspect ratio of a major axis and a minor axis of the aperture larger than 1. Furthermore, a discharge port substrate in which the discharge port is opened,
A head substrate that is disposed at a predetermined interval from the ejection port substrate and forms an ink flow path between the ejection port substrate;
Control means for controlling the ejection of ink droplets from the ejection port,
2. The ink jet head according to claim 1, wherein the shape of the opening of the ejection port is larger than 1 in terms of an aspect ratio between the length in the ink flow direction and the length in the direction perpendicular to the ink flow direction.   The inkjet head according to claim 2, wherein the control unit is a discharge electrode disposed around the discharge port of the discharge port substrate. Furthermore, it has a discharge electrode that is arranged so as to surround the discharge port and discharges ink droplets by applying an electrostatic force to the ink,
The inkjet head according to claim 1, wherein an effective portion of the ejection electrode that contributes to ejection of ink droplets has a substantially symmetric shape with respect to the ejection port.   The discharge electrode is symmetric with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and a longitudinal portion formed in the major axis direction of the discharge port passes through the center of the ejection port and has a major axis The inkjet head according to claim 4, wherein the inkjet head has a symmetrical shape with respect to a plane perpendicular to the direction.   The discharge electrode is symmetrical with respect to a plane passing through the center of the discharge port and parallel to the major axis direction, and the length of the longitudinal portion formed in the major axis direction of the discharge port is in the major axis direction of the discharge port. The inkjet head according to claim 4, wherein the inkjet head has a shape longer than the length.   The inkjet head according to claim 3, wherein the ejection electrode has a shape in which a part on the upstream side in the ink flow direction is cut out. Furthermore, a discharge port substrate in which the discharge port is opened,
A head substrate disposed at a predetermined interval from the discharge port substrate and forming an ink flow path between the discharge port substrate and
The opening shape of the ejection port is a shape larger than 1 in an aspect ratio of a length in a direction perpendicular to the ink flow direction and a length in the ink flow direction. Inkjet head.   Further, the head substrate is arranged at a position corresponding to the arrangement of the ejection ports on the ejection port substrate side, passes through the ejection ports, and a tip portion of the ejection substrate is opposite to the head substrate. The ink jet head according to claim 2, further comprising an ink guide protruding from the surface.   The inkjet head according to claim 9, wherein the ink guide has a wide structure corresponding to a shape of the ejection port.   11. An ink guide weir provided on a surface of the head substrate on the ink flow path side for forming an ink flow from an upstream side of an ink flow of the ink toward the ejection port. 11. An ink jet head according to claim 1.   The inkjet head according to claim 1, wherein the ink is a solvent in which charged fine particles are dispersed.   An inkjet recording apparatus that records an image according to image data on a recording medium using the inkjet head according to claim 1.

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