KR100330017B1 - printer for protecting drying of nozzle and method for controling it - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a printer and a control method thereof for preventing nozzle drying of a micro injecting device which is not used during printing in an inkjet printer having a plurality of micro injecting devices.

An object of the present invention is to prevent nozzle drying without ejecting a small amount of ink by moving a micro injecting device which is not used during a printing operation to a maintenance position.

The present invention includes a plurality of micro injecting devices having a plurality of nozzles and receiving nozzle driving data to drive the nozzles to eject ink; A plurality of micro-injecting device drivers for controlling the ejection of the nozzles and providing the nozzle drive data to cause the ink inside the nozzles to flow up and down; A carriage unit for mounting the plurality of micro injecting devices and reciprocating the printing paper on the left and right; And a control unit which drives the unused micro injecting device among the plurality of micro injecting devices to flow ink up and down.

According to the present invention, there is an effect of preventing the nozzle drying without ejecting a small amount of ink by moving the micro injecting device not used during the printing operation to the maintenance position.

Description

Printer for protecting drying of nozzle and method for controling it

The present invention relates to an inkjet printer, and more particularly, to a printer and a control method for preventing nozzle drying of a microinjecting device not used during printing in an inkjet printer having a plurality of microinjecting devices.

In general, when a micro injecting device is intended to supply a small amount of an object such as ink, injection liquid, gasoline, etc. to a specific object, for example, printing paper, human body, automobile, etc., a micro-injecting device is applied with a certain amount of electrical and thermal energy to the object, thereby providing By inducing change, it refers to a device designed to properly supply a small amount of a desired object to a desired object.

Recently, thanks to the development of electric and electronic technology, such micro injecting devices are also rapidly developing, and are expanding a wide range over the whole living area. As an example where a micro injecting device is applied in real life, for example, an inkjet printer can be exemplified.

Unlike conventional dot printers, inkjet printers using micro-injection devices have many advantages such as various colors, low noise, and beautiful print quality depending on the use of micro-injection devices. This is in an expanding trend.

In general, inkjet printers are sized according to the printing paper standard used and require sophisticated mechanical mechanisms and electronic control of semiconductor chip circuits for inserting, reversing, and feeding paper. However, the printing portion is simply made up of only a micro injecting device having ink bottles and nozzles, and a sheet of paper approximately 0.4 to 0.7 mm apart from the nozzles.

The water-soluble ink contained in the ink flows into a small chamber inside the nozzle, and when an electric signal is given to the piezo element or the thermal element, the ink is pressurized / heated to expand and printed in a straight line. The bundle of microinjecting devices is moved to the next position. The nozzles are usually 40-60 μm in diameter and 32-64 nozzles are arranged in parallel. At this time, the micro-injecting device includes nozzles for passing ink and jetting means for spraying ink to the outside through the nozzle.

Inkjet printers that produce images by spraying water-soluble ink through nozzles are roughly classified into thermal printers and piezo-aqueous printers according to the method of spraying ink from the nozzles (ie, injection means). .

The thermal transfer method is a method of printing by spraying ink by instantaneous heating at a high temperature of 200 to 300 ° C. When an electrical signal is applied to the resistance of the micro-injecting device, bubbles are rapidly generated. With the force of this bubble, ink is pushed out of the nozzle constituting the micro injecting device and printed on paper.

On the other hand, the piezoelectric element vibrates when an electric shock is applied to the piezoelectric element in the micro injecting device, and in the aftermath, ink is printed on paper as it comes out of the nozzle of the micro injecting device. The micro injecting device initially sucks the ink injected into the ink cartridge, and thereafter, ink is supplied by the surface tension, capillary action, and inertial motion of the embedded ink.

On the other hand, the color inkjet printer uses two micro injecting devices, namely, a black micro injecting device 4a for black printing and a color micro injecting device 4b for color printing, as shown in FIG. Mounted on the carriage 3, the carriage 3 is coupled to the timing belt 2 connected to the motor 1, and left and right reciprocated along the guide shaft 6, as described above in the nozzle of the color or black micro-injecting device. As described above, ink is sprayed onto the printing paper a to perform color printing.

In general, inkjet printers that print using two micro injecting devices do not print the other micro injecting device while printing through one micro injecting device.

For example, the color micro injecting device 4b is not used and is exposed to the air while printing and printing black ink onto the printing paper a using the black micro injecting device 4a.

As such, a problem occurs that the nozzle of the micro injecting device dries when the unused micro injecting device is exposed to air for a long time.

To prevent this, if one micro injecting device is printing while the other micro injecting device is exposed to the air without printing for a certain period of time, the printing pauses and the unused micro injecting device is not used. The method of moving to the maintenance position 7 and spraying a predetermined amount of ink was used.

However, this method increases the consumption of ink because the unnecessary ink is jetted, and the printing speed for the entire print data is slowed down because the operation is performed irrespective of the factor while printing the print data.

In addition, the maintenance position has a problem that a lot of noise is generated because the mechanical collision structure is generally installed.

Accordingly, an object of the present invention is to avoid nozzle drying without ejecting a small amount of ink by moving a micro injecting device which is not used during a print job to a maintenance position, which is devised to overcome the above-mentioned conventional problem. .

1 shows an inkjet printer with two micro injecting devices,

Figure 2 shows the main components of a printer preventing nozzle drying with two micro injecting devices according to the invention,

3 is a conceptual diagram showing a driving principle of a micro injecting device,

4 shows a part of a micro injecting device,

5 (a) (b) show the flow shape of the ink according to the present invention,

6 shows a carriage speed change and a printing section,

7 shows a control method of a printer for preventing nozzle drying according to the present invention.

<Description of Symbols of Major Parts of Drawings>

100: printer controller 110: print data input unit

120: memory 130: control unit

140: color micro injecting device driver

150: monochrome micro injecting device drive unit

200: color micro injecting device

300: monochrome micro injecting device

410: carriage motor drive unit

420; Carriage motor

According to an aspect of the present invention for achieving the above object, a plurality of micro-injecting device having a plurality of nozzles and receiving the nozzle drive data to drive the nozzles to eject ink; A plurality of micro-injecting device drivers for controlling the ejection of the nozzles and providing the nozzle drive data to cause the ink inside the nozzles to flow up and down; A carriage unit for mounting the plurality of micro injecting devices and reciprocating left and right on a printing paper; Disclosed is a printer which prevents nozzle drying including a control unit which drives an unused micro injecting device among the plurality of micro injecting devices to flow ink up and down.

Preferably, the control unit drives the unused micro injecting device in the acceleration and deceleration sections of the carriage to flow ink up and down.

Preferably, the plurality of micro injecting devices are color micro injecting devices for color printing and black and white micro injecting devices for black and white printing.

According to another aspect of the present invention, in a printer having a plurality of micro-injecting device mounted on the carriage unit to reciprocate the surface of the printing paper, driving the corresponding micro-injecting device when a print command occurs, A method of preventing nozzle drying including a nozzle drying step of driving an unused micro injecting device among micro injecting devices to flow ink up and down is disclosed.

Preferably, the nozzle drying step is to drive the unused micro-injecting device in the acceleration and deceleration section of the carriage portion to flow the ink up and down.

Preferably, the plurality of micro injecting devices are color micro injecting devices for color printing and black and white micro injecting devices for black and white printing.

Hereinafter, the objects, features, and advantages of the present invention described above will be described in more detail with reference to the preferred embodiments of the present invention shown in the accompanying drawings.

The terms to be described below are terms defined in consideration of functions in the present invention, and may vary according to the intention or custom of a person skilled in the art, and the definitions should be made based on the contents throughout the specification.

Referring to FIG. 2, a printer for preventing nozzle drying having two micro-injecting devices according to a preferred embodiment of the present invention is as follows.

When a print command is provided by a computer user, the computer (not shown) transmits a bitmap corresponding to each page to the printer controller 100 through a print interface connected to a serial port or a parallel port attached to the rear side.

The control unit 130 of the printer controller 100 receives bitmap information of each page through the print data input unit 110 through an interface of a serial port or a parallel port from a host computer, and stores the bitmap information in the memory 120.

In addition, the controller 130 selects a micro injecting device to perform a current print job from among the micro injecting devices 200 and 300, and prints the bitmap data stored in the memory 120 (eg, on a printing sheet). Location information to be printed) is transmitted to the micro-injecting device driver corresponding to the selected micro-injecting device.

For example, when the current color printing job is performed, the controller 130 selects the color micro injecting device driver 140 to provide print information, and the color micro injecting device 200 drives the corresponding nozzles to eject ink. do.

Meanwhile, the color micro injecting device 200 includes a plurality of nozzles, receives the nozzle driving data, drives the nozzles to spray color ink, and performs color printing. The black and white micro injecting device 300 includes a plurality of nozzles. The nozzle driving data is input to drive the nozzles to eject the black and white ink to print the black and white prints.

The carriage motor driver 410 drives the carriage motor 420 under the control of the controller 130 to mount a carriage unit (not shown) on which the color micro injecting device 200 and the black and white micro injecting device 300 are mounted. As shown in FIG. 6, the motor is separated into a stop section, an acceleration section, a constant speed section, and a deceleration section to reciprocate left and right over the printing paper.

Meanwhile, the color / black and white micro injecting device drivers 140 and 150 control ink ejection of the nozzles configured in the color / black and white micro injecting devices 200 and 300 corresponding to the position information to be printed transmitted from the controller 130. And drive nozzle drive data to the color / monochrome micro injecting devices 200, 300 to allow the ink inside the nozzles to flow up and down as shown in FIG.

Meanwhile, the controller 130 drives the unused micro injecting device of the color micro injecting device 200 and the black and white micro injecting device 300 through the corresponding micro injecting device driver to move the ink inside the nozzle up and down. To flow.

As shown in FIG. 3, the driving principle of the nozzles of the micro-injecting device is that a corresponding nozzle is driven according to the nozzle driving data input through the data line and the address line.

As shown, when there are 16 data lines and 13 address lines, the total number of nozzles of the micro injecting device may have 13 × 16 = 208 nozzles, and the nozzles are positioned at the intersections of the data lines and the address lines. The nozzle is driven when the data line and the address line are simultaneously activated.

At this time, since the injection amount of ink through the nozzle is proportional to the activation time of the data line and the address line, as shown in FIGS. And time for activation of the address line, which is about 300 microseconds, depending on the surrounding conditions such as microinjecting devices and driving circuits for each ink manufacturer.

Referring to FIG. 4, a part of the micro injecting device has a nozzle 52 having a small diameter, and the heating resistor 53 is heated for a predetermined time by a voltage applied from the outside to the heated heating resistor 53. The ink supplied from the ink reservoir 54 is heated to form air bubbles in the nozzle 52, and the size of the air bubbles is increased so that the ink is pushed out of the nozzle 52 and discharged to the printing paper.

Here, the heating resistor 53 requires a constant voltage value and a constant heating time so that a constant resistance value and a drop of ink are ejected to an appropriate size, and the micro injecting device drivers 140 and 150 adjust this value. Like this, it controls to flow up and down without spraying ink.

The control method of the printer for preventing nozzle drying according to the present invention is applied to a printer having a color / monochrome micro-injecting device, referring to the accompanying drawings.

First, it is determined whether the current print job is a color print job or a black and white print job (step S701).

As a result of the determination, in the case of monochrome printing, the carriage driving is started (step S702).

Subsequently, when the driven carriage reaches the constant speed section, black and white printing is performed, and when the driven carriage does not reach the constant speed section, the color micro injecting device 200 is driven for a predetermined time so that the color ink does not eject to the outside of the nozzle and flows up and down inside the nozzle. To prevent drying of the color nozzle (step S703).

On the other hand, when the printing for one line is finished while the monochrome printing is performed in the constant speed section and the carriage reaches the deceleration section, the color nozzle drying is prevented as described above (step S704).

Subsequently, if the carriage stops, it is determined whether there is content to be printed continuously, and if there is content to be printed, the process returns to step S701, and if there is no content to be printed, the process ends (step S705).

On the other hand, as a result of the determination in step S701, the carriage driving starts if the current print type is color printing (step: S706).

Subsequently, when the driven carriage reaches the constant speed section, color printing is performed. If the driven carriage does not reach the constant speed section, the monochrome micro injecting device 300 is driven for a predetermined time so that the black and white ink flows up and down inside the nozzle without being ejected to the outside of the nozzle. To prevent drying of the black and white nozzle (step S707).

On the other hand, when the printing for one line is finished while the color printing is performed in the constant speed section and the carriage reaches the deceleration section, drying of the black and white nozzle is prevented as described above (step S708).

Subsequently, if the carriage stops, it is determined whether there is content to be printed continuously, and if there is content to be printed, the process returns to step S701, and if there is no content to be printed, the process ends (step S709).

As described above, according to the present invention, there is an effect of preventing the nozzle drying without ejecting a small amount of ink by moving the unused micro injecting device to the maintenance position.

Although the preferred embodiments of the present invention have been described in detail above, those skilled in the art will appreciate that the present invention may be modified without departing from the spirit and scope of the invention as defined in the appended claims. It will be appreciated that modifications or variations may be made. Therefore, changes in the future embodiments of the present invention will not be able to escape the technology of the present invention.

Claims (4)

A plurality of micro injecting devices comprising a plurality of nozzles, a color micro injecting device for color printing by driving the nozzles to receive nozzle driving data and spraying ink, and a black and white micro injecting device for black and white printing. ; A plurality of micro-injecting device drivers for controlling the ejection of the nozzles and providing the nozzle drive data to cause the ink inside the nozzles to flow up and down; A carriage unit for mounting the plurality of micro injecting devices and reciprocating the printing paper on the left and right; And a control unit for driving an unused micro injecting device among the plurality of micro injecting devices to flow ink up and down. The method of claim 1, wherein the control unit, The printer for preventing nozzle drying, characterized in that for driving the unused micro-injecting device in the acceleration and deceleration section of the carriage portion to flow the ink up and down. In a printer equipped with a plurality of micro-injecting device, which is mounted on the carriage part and reciprocates the surface of the printing paper, and comprises a color micro injecting device for color printing and a black and white micro injecting device for black and white printing, Driving a corresponding micro injecting device when a print command occurs; And a nozzle drying step of flowing ink up and down by driving an unused micro injecting device among the plurality of micro injecting devices. The method of claim 4, wherein the nozzle drying step, And driving the unused micro injecting device in an acceleration and deceleration section of the carriage to flow ink up and down.