JPH078566B2 - Inkjet recording device - Google Patents

Description

The present invention relates to an ink jet recording apparatus using electrostatic force and air flow.

[Conventional technology]

Fig. 9 shows a conventional ink jet recording device using electrostatic force and air flow (Nikkei Electronics; 1984, 5, 21, 171).
Page, page 173).

In this device, the ink I is generated by the potential difference generated between the electrode 2 on the front surface of the nozzle 1 and the ink I in the ink ejection port 3.
Is used to eject the ink I toward the recording paper with a constantly flowing air flow. Since ink is ejected by electrostatic force attraction, a general on-demand method that uses pressure waves is used. Compared to the minimum amount of ink that can be recorded
It can be about 1/10.

[Problems to be solved by the invention]

However, in this conventional apparatus, the ink I is horizontally attracted to the nozzle portion 1 by the electrode 2, and the attracted ink is cut off and jetted by an airflow that is directed horizontally from the vertical direction. There is a problem that the flow direction of the air flow is not uniform in the nozzle portion 1 and a large variation occurs in the flight direction of the ink.

Further, since this conventional device is configured to eject ink in the recording paper direction using nozzles, in order to perform recording over the entire recording paper width, a structure for scanning the nozzles or a large number of nozzles is used. A complicated structure such as a multi-nozzle structure arranged in parallel is required, which causes a problem of manufacturing difficulty.

The present invention has been made in view of such circumstances, and it is an object of the present invention to provide an inkjet recording apparatus having a simple head configuration that enables printing over the entire recording paper width without disturbance of the ink ejection direction and flying particles. .

[Means for solving problems]

In the present invention, a vertical slit having a length corresponding to the width of the recording paper and forming a horizontal slit through which an air flow passes, and having a length corresponding to the width of the recording paper and supplying ink up to the horizontal slit height is provided. A substrate formed on the lower side of the horizontal slit, an air supply means for supplying an air flow to the horizontal slit, a conduit for guiding the air from the air supply means to the horizontal slit, and an ink for the vertical slit. A plurality of electrodes arranged in parallel along the length direction of the horizontal slit on the upper surface of the horizontal slit so as to face the vertical slit, and a plurality of electrodes corresponding to the image signal. In an ink jet recording apparatus, which comprises voltage applying means for applying a voltage for pulling up ink in the vertical slits to each electrode, Characterized in that the static pressure to determine the pressure of the flow rate and the conduit of the air supply means so as to match the substantially atmospheric pressure.

[Action]

When a predetermined voltage is applied to the plurality of electrodes by the voltage applying means in accordance with an image signal, the ink below the electrodes to which the voltage is applied among the inks filled in the vertical slits is instantly leveled by an electric field. When it is pulled up to the slit and then reaches a certain height, it is cut by the air flow passing through the horizontal slit and is ejected as ink particles toward the recording paper. In addition, the static pressure in the horizontal slits matches the atmospheric pressure so that the ink can be pulled up from the vertical slits with a smaller voltage and the ink does not overflow from the vertical slits to the horizontal slits. I am trying to do it.

〔Example〕

1 and 2 show an embodiment of the present invention. In this ink jet recording apparatus, the horizontal slit 11
The air flow passes through in the direction of arrow B at high speed. A plurality of electrodes 13 are provided on the base 12 above the horizontal slits 11 as recording paper.
They are arranged in parallel along the ten main scanning directions A. The ink I in the ink tank 19 is attached to the base 14 below the horizontal slit 11.
There is provided a vertical slit 15 for pulling up the ink I to the position of the horizontal slit 11 by the capillary phenomenon so as to pull up the ink I in the direction perpendicular to the air flow. These horizontal slits 11
The vertical slits 15 each have a length corresponding to at least the width of the recording paper 10 in the main scanning direction A. Further, the plurality of electrodes 13 are provided on the slit surface of the upper base 12 so as to face the vertical slits 15.

In such a configuration, the airflow flows from the pump 16 into the slit 11 via the conduit 17 and is directed toward the recording paper 10. In this state, the drive pulse applying means 18 selectively applies the drive pulse to a desired electrode of the plurality of electrodes 13 according to the image signal. The voltage of this drive pulse is 300V
In the range of up to 1000V, for example, 800V. Then, the ink I that has risen to the upper portion of the vertical slit 15 due to the capillary phenomenon is instantly pulled up by the electric field created in the slit 11, and then pulled up to a certain height,
After being cut into ink particles by the airflow passing through the slits 11, the ink particles fly toward the recording paper 10.

By the way, in the configuration of this embodiment, the air flow rate from the pump 16 is Q, the static pressure in the pipeline 17 is P ₁ , and the cross-sectional area of the pipeline 17 is
S ₁ , the static pressure at the slit 11 is P ₂ , the flow velocity V ₁ at the slit 11 pipeline 17 is S _{2 at} the outlet cross-section, and the air density is ρ, Flow velocity at slit exit V ₂ And then Bernoulli's theorem Is established. However, the compressibility of air is at most atmospheric pressure.
Since it is 1.1 times or more, the compression rate is ignored in the above equation.

When determining the flow rate Q of the pump and the pipe line pressure P ₁ , P ₂ ≈atmospheric pressure is satisfied in the above equation.

This is because the ink I has a vertical slit 15 when P ₂ <atmospheric pressure.
To the horizontal slit 11 and when P ₂ > atmospheric pressure, the ink I is pushed down in the vertical slit 15,
This is because it is necessary to increase the voltage applied to the electrode 13 in order to raise the ink, and P ₂ must substantially match the atmospheric pressure.

In this embodiment, the height of the horizontal slit 11 is 50 μm, and the length of the horizontal slit 11 in the main scanning direction A is 290 mm. Therefore, S ₂ = 1.45 × 10 ⁻⁵ m ² and S ₁ = 1.45 × It was set to 10 ^-2 m ² . Therefore, the pressure P ₁ and the flow rate Q of the air flow were obtained from the above equation, and P ₁ = 5.6 mm H ₂ O Q = 9.1 / min.

In this case, the electrode 13 has a density of 12 dots / mm and a wiring width duty of 50%. The width of the vertical slit 15 in the air flow direction was 50 μm. The physical properties required for the ink I may be such that the resistance value is 10 ⁶ to 10 ⁹ Ω · cm, the viscosity coefficient is 1 to 500 cp, and the surface tension is 20 to 80 dyne / cm. In this case, the resistivity is 10 ⁹ Ω · cm. cm, viscosity coefficient 300 cp, surface tension 20 dy
Ne / cm ink was used.

The diameter of the ink drop created by such an embodiment is approximately 35-
The diameter is 45 μm, and when it collides with the recording paper 10, the diameter is 70-
It was 80 μm, and a resolution of 12 dots / mm could be secured. The diameter of the generated ink droplet is determined by the height of the horizontal slit 11, the width of the electrode 13, the width of the vertical slit 15, and the like, and these values may be determined according to the required resolution.

By the way, according to the above configuration, when the pulsed voltage is applied to the electrode 13, the ink I is pulled up toward the electrode 13 by the electric field, and when the pulling height reaches a certain level or more, the ink I is cut by the air flow and the recording paper 10 is cut. Although the ink I flies in the direction, at this time, the ink I is induced and charged to a negative charge by the positive potential applied to the electrode 13. Therefore, as shown in FIG. 3, if an electrode 20 having a polarity opposite to that of the ink is provided on the back surface of the recording paper 10 and the ink droplets are sucked by the electrode 20, the ink droplets are ejected more than in the case of flying only by the air flow. Can stabilize the flight of.

Next, FIG. 4 shows another embodiment of the present invention.

In this embodiment, the horizontal slit 11 through which the air flow passes is divided by a plurality of walls 21, and the horizontal slit 11 has an independent thin tube structure for each electrode 13. When manufacturing this tube structure,
For example, as shown in FIG. 5, after forming the divided electrodes 13 on the substrate 22, a photosensitive resin 21 is applied to a predetermined thickness (corresponding to the height of the wall 21) and the resin 21 on the electrode portion is removed by etching. I did it. By this method, it was possible to form a duct having a square cross section with a width of 50 μm and a height of 50 μm across the width of the recording paper.

According to the configuration of the divided conduits, when the ink I is pulled up from the vertical slit 15 to the horizontal slit 11 by the electric field generated by the electrode 13, the ink I ascends along the wall 21 and thus the voltage applied to the electrode 13 is applied. For example, there is an advantage that it can be lowered to about 150V.

In the structure shown in FIG. 4, the horizontal slit 11
Although only the vertical slit 15 is divided into a thin tube structure, the vertical slit 15 may be divided in the same manner so that both the horizontal slit 11 and the vertical slit 15 have a tubular structure.

FIG. 6 shows still another embodiment of the present invention,
An air flow continuation drum 30 that interrupts the air flow is provided behind the slit 11. As for this drum 30,
There are those in which a plurality of slits SL are formed along the cylinder axis as shown in FIG. 7 or those in which spiral slits SL are formed as shown in FIG. Air flows into the drum 30 through a hole provided in the shaft 31 and passes through the slit SL, whereby air is intermittently supplied. When using the drum of FIG. 7, the air flow is intermittent to all 13 parts of the electrode, and
When the drum shown in the figure is used, the air flow is sent out serially through each electrode 13 part in order.

When using the drum shown in FIG. 7, the diameter of the cylinder is 10 cm,
The length is 290 cm, and the width is 2.61 cm at intervals of 60 degrees on this cylindrical surface.
Slits were formed. The print speed when this drum is rotated at 1510 rpm is 300 SPI (SPOT PER I
NCH) was 0.5 inch / sec (= 1.27 cm / sec). These cylinder diameter, slit width, and rotation speed may be determined according to the required printing speed and resolution.

When such an air flow interrupting drum is provided, it is possible to send the air flow only when necessary, instead of always flowing the air. Therefore, immediately after the ink is pulled up by the electric field, the air flow is ejected to eject the ink droplets. Can be formed, and the influence of the air flow is eliminated while the ink is being pulled up to a predetermined height by the electric field, and ink droplets having a uniform diameter can be obtained.

〔The invention's effect〕

As described above, according to the present invention, in the ink jet recording in which the ink in the vertical slit is pulled up to the horizontal slit by the electric field, and the ink is cut and ejected by the airflow flowing in the horizontal slit to perform the recording, Since the static pressure in the horizontal slits is set to about atmospheric pressure, it is possible to pull up the ink from the vertical slits with a smaller voltage, and it is possible to prevent the ink from overflowing from the vertical slits to the horizontal slits. A high quality image can be obtained.

[Brief description of drawings]

FIG. 1 is a schematic perspective view showing a first embodiment of the present invention, FIG. 2 is a schematic sectional view of the same embodiment, and FIG. 3 is a second embodiment of the present invention.
FIG. 4 is a schematic perspective view showing a third embodiment of the present invention, FIG. 5 is a perspective view for explaining a partial manufacturing process of the apparatus of the same embodiment, and FIG. FIG. 7 is a schematic perspective view showing a fourth embodiment of the present invention, FIGS. 7 and 8 are perspective views showing an example of an air flow interrupting drum used in the same embodiment, and FIG. 9 is an example of a conventional device. It is a schematic sectional drawing which shows. 1 ... Nozzle, 2 ... Electrode, 3 ... Ink ejection port, 10 ...
... Recording paper, 11 ... Horizontal slits, 12,14 ... Substrate, 13 ...
... electrode, 15 ... vertical slit, 16 ... pump, 17 ... pipe, 18 ... driving pulse applying means, 19 ... ink chamber, 20 ...
… Back electrode, 21 …… Wall, 22 …… Substrate, 30 …… Air flow interrupting drum.

Claims (2)

[Claims] 1. A vertical slit having a length corresponding to the width of the recording paper, forming a horizontal slit through which an air flow passes, and having a length corresponding to the width of the recording paper, for supplying ink to the horizontal slit height. A base formed on the lower side of the horizontal slit, an air supply means for supplying an air flow to the horizontal slit, a conduit for guiding the air from the air supply means to the horizontal slit, and the vertical slit. Ink supply means for supplying ink, a plurality of electrodes arranged in parallel along the length direction of the horizontal slit on the upper surface of the horizontal slit so as to face the vertical slit, and a plurality of these electrodes according to an image signal. An ink jet recording apparatus comprising voltage applying means for applying a voltage for pulling up ink in the vertical slits to the respective electrodes of the horizontal slits. An ink jet recording apparatus, characterized in that the flow rate of the air supply means and the pressure in the pipe line are determined so that the static pressure is substantially equal to the atmospheric pressure. 2. The air supply means includes an air flow continuation means for continuing the air flow supplied to the horizontal slit, and an air interruption means for disconnecting the air interruption means before applying a voltage to the electrode. The ink jet recording apparatus according to claim (1), further comprising a unit that brings the air continuation unit into a continuous state after a voltage is applied.