KR100643227B1 - Ink jet printer and ink discharging apparatus - Google Patents

Abstract

The present invention relates to an inkjet printer having an ink chamber having a nozzle through which ink is ejected, the inkjet printer comprising: a main heater disposed in the ink chamber to heat ink in the ink chamber; A sub heater disposed in the ink chamber to heat the ink in the ink chamber, wherein the sub heater is electrically connected in series with the main heater; And a switching unit disposed on a path bypassing the sub heater and opened and closed based on a predetermined condition. This makes it possible to compensate for the inability or deterioration of the ink discharge by adjusting the ink discharge amount with a simple configuration.

Inkjet Printer, Page Width Printer Head, Main Heater, Sub Heater, Nozzle Sewing Machine

Description

Inkjet Printer and Ink Dispenser {INK JET PRINTER AND INK DISCHARGING APPARATUS}

1 is a schematic view showing a conventional inkjet printer,

2 is a schematic view showing an inkjet printer according to an embodiment of the present invention,

FIG. 3 is a circuit diagram of the inkjet printer of FIG. 2.

* Explanation of symbols for the main parts of the drawings

100: ink discharge unit 110: ink chamber

120: nozzle 130: ink flow path

140: main heater 150: sub heater

160: switching unit 170: bypass wiring

180: power supply wiring 200: power supply

300: power switching unit 400: control unit

The present invention relates to an inkjet printer, and more particularly, to an inkjet printer having an improved print head.

In general, inkjet printers are widely used because they are inexpensive, enable high resolution printing, and are advantageous for color image formation. The inkjet printer ejects the ink stored in the ink cartridge to the printing paper through a plurality of fine nozzles to form an image.

1 is a schematic view showing a conventional inkjet printer. As shown, the inkjet printer 1 has a print head portion 10 in which a plurality of ink ejecting portions 20 are arranged.

The ink ejecting portion 20 includes an ink chamber 22 and a nozzle 24. The ink chamber 22 receives ink supplied from an ink reservoir (not shown) through an ink passage (not shown). The ink chamber 22 is provided with a heater (not shown) for heating ink. The heater (not shown) heats ink when current is applied to form ink bubbles in the ink chamber 22. As the ink bubble expands, the ink contained in the ink chamber 22 is pressurized and discharged through the nozzle 24. The discharged ink I is adsorbed and dried on the printing paper P to form an image.

However, deterioration or incapability of ink ejection performance of some of the ink ejecting portions 20a may occur. Deterioration or incapacity of ink ejection performance may occur due to various reasons such that the nozzle 24 is closed by a solidified ink mass. When the ink discharging performance decreases or becomes impossible in some of the ink discharging portions 20a, some of the ink discharging portions 20a may not discharge the ink sufficiently or may not discharge at all. Since no image is formed in the portion corresponding to 20a), the image quality of the entire image may be degraded.

In particular, in the case of an inkjet printer having a printhead 20 in which a plurality of ink ejecting portions 20 are arranged so as to correspond to the width of the printing paper P, some ink ejecting portions 20a are ink. When the discharge performance decreases or becomes impossible, a problem may arise in which the entire print head 10 needs to be replaced.

It is therefore an object of the present invention to provide an inkjet printer and an ink ejection apparatus which can compensate for the inability or deterioration of ink ejection by adjusting the ink ejection amount with a simple configuration.

An object of the present invention is an inkjet printer having an ink chamber having a nozzle from which ink is ejected, the inkjet printer comprising: a main heater disposed in the ink chamber and heating ink in the ink chamber; A sub heater disposed in the ink chamber to heat ink in the ink chamber and electrically connected in series with the main heater; And a switching unit disposed on a path bypassing the subheater and opened and closed based on a predetermined condition.

The switching unit may be a MOS FET.

The above object is an ink discharging device according to the present invention, comprising: an ink chamber containing ink, the ink chamber having a nozzle from which the ink is discharged; A main heater disposed in the ink chamber to heat the ink; A sub heater disposed in the ink chamber to heat the ink and electrically connected to the main heater in series; And a switching unit disposed on a path bypassing the subheater and opened and closed based on a predetermined condition.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

2 is a schematic view showing an inkjet printer according to an embodiment of the present invention, Figure 3 is a circuit diagram of the inkjet printer of FIG. As shown in the drawing, the ink discharge unit 100 includes an ink chamber 110, a main heater 140, a sub heater 150, and a switching unit 160 including the nozzle 120. The inkjet printer according to the embodiment of the present invention includes a printer head portion (not shown) in which a plurality of such ink ejecting portions 100 are arranged. The ink discharge unit 100 may be arranged in the print head unit (not shown) to correspond to the width length of the printing paper.

The ink discharging unit 100 discharges ink onto printing paper to form an image. The ink discharge unit 100 includes an ink chamber 110 filled with ink. The ink chamber 110 receives ink from the ink storage unit (not shown) that stores the ink through the fine ink channel 130. The ink chamber 110 has a nozzle 120 positioned to face the printing paper. Ink filled in the ink chamber 110 is discharged to the printing paper through the nozzle 120.

The main heater 140 and the sub heater 150 are disposed in the ink chamber 110. The main heater 140 and the sub heater 150 generate heat when the power is supplied to heat the ink contained in the ink chamber 110 to form an ink bubble so that ink is discharged through the nozzle 120.

The main heater 140 and the sub heater 150 are arranged side by side at a predetermined interval on the same plane. However, the main heater 140 and the sub heater 150 may be disposed on different planes, or may be arranged at an angle to each other. The main heater 140 and the sub heater 150 are disposed at a predetermined position with respect to the nozzle 120. A part of the main heater 140 may be disposed to correspond to the nozzle 120, the entire main heater 140 may be disposed to correspond to the nozzle 120, and the main heater 140 and the sub heater ( A portion between the portions 150 may correspond to the nozzle 120.

The main heater 140 and the sub heater 150 may be formed in various shapes. The main heater 140 and the sub heater 150 may be formed in a rectangular plate shape. At this time, the plate area of the main heater 140 is preferably larger than the plate area of the sub heater 150. In addition, at least one of the main heater 140 and the sub heater 150 may be one or a plurality of heating elements.

The main heater 140 and the sub heater 150 are electrically connected in series. One end of the main heater 140 and one end of the sub heater 150 are connected to the power supply wiring 180. The power supply wiring 180 may be connected to the power supply unit 200 to supply power to the main heater 140 and the sub heater 150. The power supply unit 200 may be a current power supply or a voltage power supply. The power supply switching unit 300 is connected to the power supply wiring 180. The power supply switching unit 300 may be a TR, a J-FET, or other conventional switching device, and is preferably a metal oxide silicon field effect transistor (MOS FET).

The control unit 400 generates a power supply signal S2 for driving the ink discharge unit 100 according to the received original image information, and supplies the generated power supply signal S2 to the power switching unit 300. The controller 400 drives the power switch 300 on so that power is supplied to the main heater 140 and the sub heater 150 when the ink discharge part 100 needs to discharge ink. In this case, the power switching unit 300 is driven off.

The switching unit 160 is disposed on the bypass wiring 170 which bypasses the sub heater 150. The switching unit 160 shorts or opens the bypass wiring 170 by opening and closing based on a predetermined condition. The switching unit 160 may be a TR, a J-FET, or other conventional switching device. The switching unit 160 may be a metal oxide silicon field effect transistor (MOS FET). In particular, when the power supply switching unit 300 is a MOS FET, the switching unit is also preferably a MOS FET. At this time, if one of the power source switching unit 300 and the switching unit 160 is an N-MOS FET, the other may be a P-MOS FET.

The predetermined condition at which the switching unit 160 is opened and closed may be determined by the ink discharge amount discharged by the ink discharge unit 100. When the ink discharge unit 100 needs to discharge a normal ink discharge amount, the switching unit 160 may be shorted. Accordingly, the sub heater 150 is bypassed to block the power supply to the sub heater 150, and only the main heater 140 is supplied with power. Therefore, since only the main heater 140 heats the ink, a normal amount of ink is discharged through the nozzle 120. On the contrary, when the ink discharging unit 100 has to discharge a large amount of ink discharging amount, the switching unit 160 may be opened. Accordingly, power is supplied not only to the main heater 140 but also to the sub heater 150. Therefore, since the main heater 140 and the sub heater 150 simultaneously heat the ink in the ink chamber 110, the ink having an increased amount than the normal ink discharge amount may be discharged through the nozzle 120.

The controller 400 generates a driving signal S1 for opening and closing the switching unit 160. The control unit 400 may receive information on the state of the ink discharge unit 100 from a detector (not shown) that detects degradation or inability information of the ink discharge performance of the ink discharge unit 100. The control unit 400 may control the power supply to the sub heater 150 by opening or shorting the switching unit 160 based on the received information. The detection unit (not shown) may be a conventional means for detecting an ink discharge state of the plurality of ink discharge units 100 arranged in the print head unit (not shown) such as an ink discharge test pattern sensor.

Hereinafter, the operation of the ink jet printer according to the embodiment of the present invention will be described with reference to FIG. 3. A plurality of ink ejecting portions are arranged in the print head portion (not shown) of the inkjet printer according to the embodiment of the present invention. The control unit 400 controls the power switching unit 300 based on the input document image information so that each ink discharge unit 100 discharges ink to form an image on printing paper.

In the normal case, the controller 400 short-circuits the switching unit 160. Accordingly, the sub heater 150 is bypassed to supply power only to the main heater 140. Only the main heater 140 heats the ink in the ink chamber 110 so that a normal amount of ink is discharged through the nozzle 120 to be adsorbed onto the printing paper.

When a drop or incapacity of ink ejection performance of a particular ink ejecting unit 100 is generated among the plurality of ink ejecting units 100 of the print head unit (not shown), the control unit 400 controls the ink through a sensing unit (not shown). Information on the ink ejection state of the discharge unit 100 can be received. At this time, the control unit 400 opens the switching unit 160 of at least one ink discharge unit 100 adjacent to the ink discharge unit 100. Accordingly, power is simultaneously supplied to the sub heater 150 and the main heater 140. Both the sub heater 150 and the main heater 140 heat the ink in the ink chamber 110 so that an amount of ink that is increased from the normal amount is discharged through the nozzle 120. As a result, the ink discharging unit 100 may be compensated for inferior or incapable ink discharging performance, and the deterioration of print quality may be prevented.

Hereinafter, an ink ejection apparatus according to an embodiment of the present invention will be described with reference to FIG. 2. As illustrated, the ink ejection apparatus 100 includes an ink chamber 110, a main heater 140, a sub heater 150, and a switching unit 160.

The ink chamber 110 accommodates ink and has a nozzle 120 through which ink is discharged. The main heater 140 and the sub heater 150 are disposed in the ink chamber 110 to heat the ink contained in the ink chamber 110. The main heater 140 and the sub heater 150 are electrically connected in series. The switching unit 160 is disposed on the bypass wiring 170 bypassing the sub heater 150 and is opened and closed based on a predetermined condition.

Predetermined conditions under which the switching unit opens and closes in the inkjet printer and the ink ejection apparatus according to the embodiment of the present invention are not limited to compensating for the performance deterioration or incapacity of the ink ejection apparatus, when adjustment of the ink ejection amount is required. For example, the switching unit may be opened or closed to adjust the overall density of the printed image. When a dark print image is selected through a predetermined user interface, a dark print image can be obtained by opening the switching unit to increase the ink discharge amount.

Alternatively, the switching unit may be opened or closed for ink saving printing. It is possible to adjust the heating capacity of the main heater and the sub heater, open the switching to operate both the main heater and the sub heater in the case of normal printing, and short-circuit the switching so that only the main heater is operated in the case of ink saving printing.

As can be seen from the above, the inkjet printer and the ink ejection apparatus according to the present invention can adjust the ink ejection amount with a simple configuration. As a result, when a decrease or incapacity of ink ejection performance of some ink ejection nozzles occurs, the amount of ink ejection may be increased to compensate for a decrease or incapacity of ink ejection performance to prevent print quality from being lowered.

Claims (3)

An inkjet printer having an ink chamber having a nozzle through which ink is discharged, the inkjet printer comprising: A main heater disposed in the ink chamber to heat ink in the ink chamber; A sub heater disposed in the ink chamber to heat ink in the ink chamber and electrically connected in series with the main heater; And And a switching unit disposed on a path bypassing the sub-heater and opened and closed based on a predetermined condition. The method of claim 1, The switching unit is an inkjet printer, characterized in that the MOS FET. In the ink discharging device, An ink chamber accommodating ink and having a nozzle through which the ink is ejected; A main heater disposed in the ink chamber to heat the ink; A sub heater disposed in the ink chamber to heat the ink and electrically connected to the main heater in series; And And a switching unit disposed on a path bypassing the sub-heater and opened and closed based on a predetermined condition.

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