JPH0631923A - Electrostatic inkjet recording apparatus - Google Patents

Abstract

PURPOSE:To obtain an image of high resolution by so arranging nozzles as to satisfy each specific formula of the distance P1 of ink nozzles, the minimum positional shift P2 in the inclining direction of arrays of nozzles, the distance W of nozzle arrays and the inclination theta of nozzle arrays. CONSTITUTION:A printing head 10 is inclined by an angle theta to the moving direction, and arrays of nozzles are inclined to the moving direction of the printing head subsequent to the inclination of the head 10. Supposing that the center lines of nozzle arrays are (a), (b), ink nozzles 20 are denoted sequentially from the upper one as N1-N16, the inverse number of the dot density is P, and the inclination of the center lines (a), (b) to the moving direction of the printing head is theta, tantheta=1/2 is held, and the pitch P1 of nozzles of even numbers and that of nozzles of odd numbers becomes 2X5<1/2>XP. At the same time, the positional shifting amount P2 of nozzles of even numbers and nozzles of odd numbers is set to be 5<1/2>/5XP and the distance W between the center lines (a) and (b) is 12/5<1/2>XP. Accordingly, the distance between the nozzles 20 is secured wide, making it possible to obtain images with high resolution.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrostatic ink jet recording apparatus having a print head for ejecting ink droplets from an ink nozzle by using an electrostatic field to print on recording paper.

[0002]

2. Description of the Related Art FIG. 4 shows a conventional structure of an electrostatic ink jet recording apparatus of this type. According to this structure, the back electrode 2 is provided so as to face the front surface of the print head 1, and the recording paper 3 is fed between the back electrode 2 and the front surface of the print head 1. On the front surface of the print head 1, a slit-shaped ink ejection port 4 is formed over the full line corresponding to the width of the recording paper 3, and a back electrode 2 is arranged so as to face the ink ejection port 4. ing.
The ink ejection port 4 is provided in the front part of an ink chamber 7 formed between the lower plate 5 and the upper plate 6. Lower plate 5 and upper plate 6
Is made of an insulating material, and a plurality of recording electrodes 8 are arranged in parallel on the inner surface of the lower plate 5 at a predetermined interval corresponding to the dot density. A high voltage power source 9 is connected to each recording electrode 8 so that a high voltage pulse corresponding to a recording signal is applied during printing. Then, when the ink chamber 7 is filled with ink, a continuous ink meniscus is formed at the ink ejection port 4, and when a high voltage pulse corresponding to a recording signal is applied to the recording electrode 8 during printing, An electrostatic field is generated between the back electrode 2 and this electrostatic field, and the ink ejection port 4
Ink drops are supposed to be ejected from.

[0003]

However, in such a structure, since the recording electrodes 8 are juxtaposed at extremely small intervals corresponding to the dot density, the dot density is set high and the image If the resolution is increased, there is a problem that high precision cannot be coped with, and dielectric breakdown occurs between the recording electrodes 8 and a high-resolution image cannot be obtained.

An object of the present invention is to provide an electrostatic ink jet recording apparatus capable of obtaining a high resolution image.

[0005]

SUMMARY OF THE INVENTION The present invention is an electrostatic ink jet recording apparatus having a print head for ejecting ink droplets from an ink nozzle to print on a recording paper by utilizing an electrostatic field. A plurality of ink nozzles are provided so as to be movable in a direction perpendicular to the feed direction, and a plurality of ink nozzles are arranged in parallel in a direction inclined with respect to the moving direction of the print head at equal intervals. P is the reciprocal of the dot density, P1 is the interval between the ink nozzles in each nozzle row, and P2 is the minimum displacement of the ink nozzles in the nozzle row tilt direction between the nozzle rows.
Tan θ, where W is the interval between the nozzle rows and θ is the inclination of each nozzle row with respect to the moving direction of the print head.
= ^1/2 , P1 = 2 × 5 ^1/2 × P, P2 = (5 ^1/2 /
5) × P, W = ( 12/5 1/2) the ink nozzles to satisfy × P is characterized by being arranged.

[0006]

According to the present invention, the distance between the ink nozzles is set to be larger than the reciprocal of the dot density, so that the distance between the ink nozzles is wide. Therefore, even if the dot density is set high and the resolution of the image is increased, it is possible to deal with high accuracy, and it is possible to secure a wide space between the electrodes in each ink nozzle so as not to cause dielectric breakdown. Images can be obtained.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An electrostatic ink jet recording apparatus to which the present invention is applied will be described below with reference to the drawings. In this electrostatic ink jet recording apparatus, a back electrode 11 is provided so as to face the front surface of the print head 10 as shown in FIG. 1, and the recording paper 1 is provided between the back electrode 11 and the front surface of the print head 10.
3 is sent.

The back electrode 11 is formed in a cylindrical shape and extends in a direction (direction of arrow A) orthogonal to the paper feeding direction, and also acts as a platen. A power supply 14 is connected to the back electrode 11, and the voltage of the power supply 14 is applied.

The print head 10 is guided by guide means (not shown) so as to be moved in parallel with the back electrode 11, that is, in the direction orthogonal to the paper feed direction. As shown in FIG. 2, the print head 10 includes a frame-shaped base 15 and a plate-shaped upper plate 16 and a lower plate 17 on both upper and lower end surfaces thereof.
The ink chamber 18 surrounded by the base 15, the upper plate 16, and the lower plate 17 is formed inside. The base 15, the upper plate 16 and the lower plate 17 are made of an insulating material.

An ink supply port 19 opening rearward is formed at the rear of the ink chamber 18, and ink is supplied into the ink chamber 18 from an ink tank (not shown) through the ink supply port 19. This ink chamber 18
In the front of the ink head, an ink nozzle 2 that opens to the front of the print head
0 is formed, and ink droplets are ejected from the ink nozzle 20.

A plurality of ink nozzles 20 are arranged side by side at equal intervals, two nozzle rows are provided in parallel, and a recording electrode 21 is provided inside each ink nozzle 20. That is, a plurality of notches 15a are formed at equal intervals on the upper and lower surfaces of the front part of the base body 15. Each of these notches 15a is formed.
Thus, a plurality of ink nozzles 20 are formed at equal intervals between the base 15 and the upper plate 16 and between the base 15 and the lower plate 17, and two nozzle rows are provided in parallel.
A plurality of recording electrodes 21 are attached and formed on the lower plate 6 and the lower plate 17 so as to correspond to the respective cutouts 15a, and the recording electrodes 21 are provided inside the respective ink nozzles 20. Each recording electrode 2
A high-voltage power source (not shown) is connected to 1 so that a high-voltage pulse corresponding to a recording signal is applied during printing. The recording electrode 21 can be easily formed by forming a conductive film on the surfaces of the upper plate 16 and the lower plate 17 with metallic chromium, gold or the like by low temperature sputtering, and etching the conductive film in a pattern. For this purpose, it is desirable to form the upper plate 16 and the lower plate 17 with a material such as machinable ceramics or photosensitive glass that facilitates the patterning of the electrodes.
Glass bonding using a low melting point glass for encapsulation can be used for the bonding.

The respective ink nozzles 20 are arranged in a staggered manner as shown in FIG. 3 with the center line of each nozzle row being inclined with respect to the print head moving direction (direction of arrow A) (in FIG. 3). The position of the ink nozzle 20 is indicated by a circle for convenience). That is, as shown in FIG. 1, the print head 10 is tilted by an angle θ with respect to the moving direction, and the tilt of the print head 10 causes the nozzle row to move in the print head moving direction (direction of arrow A) as shown in FIG. Is inclined to. The center lines of the nozzle rows are a and b, the positions of the ink nozzles 20 are sequentially numbered N1 to N16 from the upper side (paper feed direction side), the reciprocal of the dot density is P, and the center lines a, When the inclination of b in the print head moving direction (direction of arrow A) (the inclination of each nozzle row with respect to the print head moving direction) is θ, tan θ = 1/2, and the nozzle pitch P1 and odd number of even-numbered nozzles are odd. The nozzle-to-nozzle pitch P1 (distance between the ink nozzles 20 in each nozzle row) is 2 × 5 ^1/2 × P. Further, the positional deviation amount between the even-numbered nozzles and the odd-numbered nozzles (the positional deviation amount of the ink nozzles 20 in the nozzle row inclination direction between the nozzle rows) P2 is set to (5 ^1/2 / 5) × P. In addition, the distance W between the center lines a and b (the distance between the nozzle rows) is set to (12/5 ^1/2 ) × P.
The reciprocal P of the dot density is, for example, 30
When it is 0 DPI (dot / inch), it is 25.4.
/ 300mm, which is about 0.0846mm. Also, when the dot density is 400 DPI, 25.4 / 4
It becomes 00 mm and becomes 0.0635 mm.

Next, the operation will be described. At the time of printing, a high voltage pulse corresponding to a recording signal is applied to the recording electrode 21 from a high voltage power source (not shown), and the application of this voltage causes a potential difference between the recording electrode 21 and the back electrode 11 to cause an electrostatic field between both electrodes. This electrostatic field causes ink droplets to flow from the nozzle opening 20a of the ink nozzle 20 along the lines of electric force to the back electrode 1.
The ink jets toward the recording sheet 1 and ink is attached to the recording sheet 2 to form recording dots on the recording sheet 2.

In this embodiment which operates in this way, the distance between the ink nozzles 20 in each nozzle row is set to 2 × 5 ^1/2 times the reciprocal of the dot density, and the distance between each nozzle row is Since it is set to 12/5 ^1/2 times the reciprocal of the dot density, a wide space is secured between the ink nozzles 20. Therefore, even if the dot density is set high and the resolution of the image is increased, it is possible to deal with high accuracy, and it is possible to secure a wide space between the recording electrodes 21 in each ink nozzle 20 so as not to cause dielectric breakdown, A high resolution image can be obtained.

In the above embodiment, an example of application to an electrostatic ink jet recording apparatus having a so-called edge shooter type print head has been described, but the present invention is not limited to this and other structures such as a so-called side shooter type print head. Of course, it is also applicable to the electrostatic ink jet recording apparatus having the print head of.

[0016]

As described above, according to the electrostatic ink jet recording apparatus of the present invention, the distance between the ink nozzles can be set to be 2 × 5 ^1/2 times wider than the reciprocal of the dot density. Therefore, even if the dot density is set high and the resolution of the image is increased, it is possible to deal with the high precision and it is possible to dispose a wide interval between the electrodes. The margin between the applied voltage and the dielectric breakdown voltage can be improved.

[Brief description of drawings]

FIG. 1 is a schematic perspective view of an electrostatic ink jet recording apparatus to which the present invention is applied.

FIG. 2 is an exploded perspective view of a main part of the print head of FIG.

FIG. 3 is an array diagram of the ink nozzles of FIG.

FIG. 4 is a perspective view showing a conventional structure.

[Explanation of symbols]

 10 print head 20 ink nozzle

Claims (1)

[Claims] 1. An electrostatic ink jet recording apparatus having a print head for ejecting ink droplets from an ink nozzle to print on a recording paper by utilizing an electrostatic field, wherein the print head is in a direction orthogonal to a paper feeding direction. A plurality of the ink nozzles are movably provided and are arranged in parallel at equal intervals in a direction inclined with respect to the moving direction of the print head, and a plurality of nozzle rows are provided in parallel. Let P be the reciprocal number, P1 be the interval between the ink nozzles in each nozzle row, be P2 be the minimum displacement of the ink nozzles in the nozzle row tilt direction between each nozzle row, and When the interval is W and the inclination of each nozzle row with respect to the moving direction of the print head is θ, tan θ = ^1/2 , P1 = 2 × 5 ^1/2 × P, P2 = (5 ^1/2 / 5 ) × P, W (12/5 ^1/2) electrostatic inkjet recording apparatus characterized by the respective ink nozzles are arranged so as to satisfy × P.