KR100200800B1 - Ink ejecting method and apparatus of inkjet printer - Google Patents

Abstract

An ink jet method of an ink jet printer for ejecting ink droplets in accordance with a print signal and an ink jet apparatus according thereto are disclosed. The method and apparatus include two drive sources, which drive the first drive source to protrude and separate ink in the nozzle out of the outlet of the nozzle, and protrude in the process of driving and separating the second drive source. At the same time the process of re-sucking a portion of the ink. A heater that electrically heats the first drive source to generate bubbles, or a piezoelectric body that is mechanically empty in response to an electrical signal is used, and the second drive source uses a piezoelectric body of opposite polarity to the piezoelectric material. The ink droplets ejected by this method and apparatus are very fine and free of incidental drops. This provides high resolution and clear prints.

Description

Ink jetting method of ink jet printer and device therefor

1 (a) to (e) are cross-sectional views for explaining the conventional heating type printer head and its operation.

2 (a) to 2 (d) are sectional views for explaining the conventional piezoelectric printer head and its operation.

(A)-(e) are sectional drawing for demonstrating the heating type printer head and its operation | movement by this invention.

(A)-(d) are sectional drawing for demonstrating the piezoelectric printer head and its operation | movement by this invention.

* Explanation of symbols for main parts of the drawings

11, 21, 31, 42: nozzle 12, 32: heater

22,35,42,45: Piezoelectric 13,23,33,43: Ink in nozzle

13 ', 23', 33 ', 43': protruding ink column

13,23,33,43: Separated ink drops

14,34 bubble 14 ', 34': bubble expanded

14,34: contracted bubble

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ink jetting method and apparatus therefor, and more particularly to an ink jetting method for ejecting small ink droplets for high resolution printing, and an ink jetting device accordingly.

In a drop-on-demand ink jet printer, in general, the ejection of the ink is controlled by one driving source in order to eject the ink in accordance with a print signal. The smaller the size of the ejected ink droplets, the better the printing of the high resolution. The size of the ejected ink droplets will depend on the aperture of the first nozzle. However, there is a limit to the fine processing of the nozzle, which is also a limitation of high resolution printing. Secondly, it will depend on the selection of the drive source and the control function of the drive source. As the driving source, a heater that is heated by an electric signal to generate bubbles in the nozzle and a piezoelectric element that is mechanically empty by receiving an electric signal are used. However, since these driving sources themselves are limited by a limited nozzle size, it is practically difficult to reduce or adjust the size of the ink droplets. Referring to the drawings, FIG. 1 shows a heated (or bubble) printhead in which the nozzle 11 is provided with a heater 12 constituting a part of the nozzle body.

When a predetermined electric signal is applied to the heater 12 in accordance with the print signal, bubbles 14 are generated due to vaporization of moisture in the ink 13 contained in the nozzle 11. When the heater 12 continues to be heated, the bubble 14 is expanded so that the ink column 13 'as much as the expanded bubble 14' protrudes out of the injection hole (not shown) of the nozzle 11. When the electrical signal applied to the heater 12 is interrupted, the heater 12 is rapidly cooled and the bubble 14 'is contracted accordingly. By the contracted bubble 14, the tail 13a 'of the ink column 13' is tapered and finally separated from the nozzle 11 as the ink droplet 13. In the nozzle 11, new ink as much as the separated ink droplets 13 is supplied and supplemented by the shrinking force in the bubble shrinking process. Here, it can be seen that the size of the ink droplet 13 is determined according to the degree of expansion of the bubble. If the expanded bubble 14 'is small, it is difficult to separate the ink droplet 13 thereafter. As a result, there is a limit in reducing the size of the ink droplets 13, which is difficult to achieve high resolution alone.

FIG. 2 shows a piezoelectric printhead in which the nozzle 21 is provided with a piezoelectric body 22 constituting a part of the nozzle body. The piezoelectric material 22 has a property of mechanically emptying upon receiving an electric signal, and also has a degree of emptying depending on an applied voltage. Referring to the operation principle, in the preparation step, a low voltage is applied to the piezoelectric body 22 to apply a constant pressure to the ink 23 in the nozzle 21, and then the low voltage is released once in accordance with a print signal to release the nozzle 21. ), The new ink is supplied by supplying a larger volume, and again a high voltage is applied to protrude the ink column 23 ', and then the ink droplet 23 is separated by the reaction. At this time, if the pressure due to the empty type of the piezoelectric member 22 is too high, the acceleration of the ink droplets 23 may be reduced during the separation of the ink droplets 23 and may even be sucked back into the nozzle 21. Pressure must be maintained. Therefore, it is also difficult to control the size of the ink droplets 23 sprayed only by the piezoelectric body 22, and there is a limit in realizing high resolution.

As a related prior art, Patent Publication No. 83-2768 proposes a new control method for the above-described driving source (piezoelectric) in order to prevent the resolution deterioration caused by small ink droplets which are ejected in succession by ink droplets separated from the nozzle. This prevents small droplets from crushing by applying two continuous filaments to the piezoelectric body before the ink droplets are separated from the nozzle, causing the piezoelectric body to become hollow in two steps, pushing the ink tail in the process of separating the ink droplets. According to this technique, the printed matter can be processed cleanly and the spraying speed can be increased. However, the ink droplets separated by this method will be slightly larger, so the problem of lowering the resolution occurs.

DISCLOSURE OF THE INVENTION An object of the present invention is to provide an ink spraying method for ejecting ink droplets that are small and do not break other drops so as to realize high-resolution printing in view of the conventional problems, and thus an ink spraying value.

In order to achieve the above object, the ink jetting method of the present invention provides an ink projection process for partially reducing the volume of the ink ejection nozzle so that a predetermined amount of ink protrudes out of the outlet of the nozzle, and restoring the volume of the nozzle. An ink jetting method of an ink jet printer for repeatedly printing an ink separation process for separating the protruding ink according to a print signal, and printing the separated ink, the ink jetting method inflating a part of the nozzle in the ink separation process to expand the expansion force. By simultaneously performing a process of allowing a portion of the protruding ink to be sucked into the nozzle, it is characterized in that the minute ink droplets are separated.

The ink ejection device of the present invention according to the ink ejection method of the present invention comprises an ink ejection nozzle and an electric signal which forms part of the nozzle and is driven by an electric signal to partially reduce and recover the volume of the nozzle. An ink jetting apparatus of an ink jet printer comprising a first driving source for protruding and separating ink from the inside, wherein the ink forming the other part of the nozzle and being protruded out of the nozzle by the driving source are separated. And further comprising a second drive source which is partially enlarged in volume and driven so that a part of the protruding ink is absorbed into the nozzle.

As a result, the ink spraying method and apparatus of the present invention have two driving sources, and as described above with the first driving source, for example, a heater or a piezoelectric body, the process of pushing the ink in the nozzle and projecting the ink column out of the outlet of the nozzle as described above. And a process of separating the ink pillars in sequence, and returning a portion of the ink pillars in the process of separating the ink pillars with another piezoelectric body driven in a polarity opposite to the piezoelectric body of the second driving source, for example, the first driving source. Inhalation process is performed. This will reduce the size of the ink droplets that are finally separated and also prevent the presence of incidental drops mentioned in the referenced prior art. Therefore, according to the present invention, fine ink droplets are ejected in accordance with the print signal to enable high resolution printing, and the effect of contributing to the improvement of the quality as a clean print will be provided.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

3 is an example of an improvement of the existing heating type printer head (FIG. 1).

The nozzle 31 is provided with the heater 32 which is a 1st drive source, and the piezoelectric body 35 which is a 2nd drive source. The heater 32 is heated by an electric signal according to a print signal as usual to generate bubbles 34 and to reduce and recover the volume in the nozzle 31 in accordance with the expansion and contraction of the bubbles 34. . The piezoelectric body 35 is similarly mechanically deformed by receiving another electric signal according to a print signal. The piezoelectric member 35 is installed to enlarge and recover the volume of the nozzle 31 by the deformation thereof, and the driving point is that the heater 32 is heated. It becomes the cooling point after being driven so far.

Referring to the operation of the improved heating type print head having these two driving sources, when the electrical signal is applied to the heater 32 in the preparation step as shown in FIG. By vaporizing, bubbles 34 are generated as shown in FIG. 3 (b). Continued heating of the heater 32 creates an expanded bubble 34 'as shown in FIG. 3 (c), and the volume of the nozzle 31 is reduced by that amount and at the same time the ink column 33 is out of the outlet of the nozzle 31. ') Is protruding. When the electrical signal applied to the heater 32 is interrupted, the heater 32 is rapidly cooled and at the same time the piezoelectric element 35 is driven to become convex as shown in FIG. Therefore, the expanded bubble 34 'contracts and the tail portion 33a' of the ink pillar becomes thinner due to the contracting force of the contracted bubble 34, and at least a portion of the ink pillar 33 'is formed on the piezoelectric body ( Due to the expansion force of 35, the ink is sucked into the nozzle 31 and finally, fine ink droplets 33 are separated as shown in FIG. The separated ink is replenished from the inlet of the nozzle 31 by the contracting force of the contracted bubble 34.

Next, FIG. 4 is an example in which the piezoelectric printer head (second) of the related art is improved, and two driving sources are formed of piezoelectric members 42 and 45, respectively. The two piezoelectric members 42 and 45 are connected in opposite polarities and operate in opposite directions to each other. The operation will be described. In the preparing step, as shown in FIG. 4 (a), a low voltage is applied to the first piezoelectric body 42 to compress the ink 43 of the nozzle 41, and when the print signal is received, the low voltage is applied. The voltage is released to supply new ink with the restoring force of the first piezoelectric body 42 (Fig. 4 (b)). Subsequently, a high voltage is applied to the first piezoelectric body 42 and a larger pressure is applied to separate the ink column 43 'as shown in FIG. 4C, and at the same time, apply a predetermined voltage to the second piezoelectric body 45. As a result, the ink droplet 43 is separated while the ink pillar 43 'is sucked back by the expansion force.

The ink droplets 33 and 43 separated by the above two embodiments are partially sucked into the nozzles 31 and 41 by the piezoelectric members 34 and 45 before being separated. It is smaller in size than the ink droplets 13 and 23 and is separated cleanly without fear that other droplets will break behind it.

As such, the ink ejection method and the apparatus of the present invention enable the ejection of smaller and cleaner ink droplets by using two driving sources, and spray fine ink droplets from nozzles of limited diameter to provide high resolution as well as clean prints. It is an extremely effective invention.

Claims (6)

The ink ejection process of partially reducing the volume of the ink ejection nozzle so that a predetermined amount of ink protrudes out of the exit of the nozzle, and the ink separation process of restoring the volume of the nozzle to separate the protruding ink are included in the print signal. In the ink jetting method of an ink jet printer for repeating the printing, the ink jetting method for printing with the separated ink, the part of the nozzle is expanded during the ink separation process so that a part of the protruding ink is sucked into the nozzle by the expansion force. The ink jet method of the ink jet printer to perform the process at the same time, so that minute ink droplets are separated. The ink ejection and separation process is performed by expanding and contracting bubbles in the nozzle, and the ink intake process is performed by an expansion or contraction force of a piezoelectric body that is mechanically deformed by applying an electrical signal. Ink jet method of the ink jet printer, characterized in that. The ink jet method according to claim 1, wherein the ink projection and separation process and the ink suction process are performed by deforming two piezoelectric bodies connected in opposite polarities to each other. Ink in a jet printer comprising a nozzle for ejecting ink and a first driving source which forms a part of the nozzle and is driven by an electrical signal to partially reduce and recover the volume of the nozzle and protrudes and separates the ink in the nozzle. In the injector, when the ink forming the other part of the nozzle and the ink protruding out of the nozzle by the driving source is separated, the volume of the nozzle is partially enlarged so that a portion of the protruding ink is absorbed into the nozzle. The ink jetting apparatus of the ink jet printer, characterized in that it further comprises a second drive source driven to. The ink according to claim 4, wherein the first driving source is electrically heated and generates a bubble by heating the second driving source, and the second driving source is formed of a piezoelectric body that is mechanically deformed by receiving an electrical signal. Ink jetting device for jet printers. The ink jetting apparatus of an ink jet printer according to claim 4, wherein the first and second driving sources are composed of two piezoelectric bodies connected in opposite polarities to each other.