1. Field of the Invention
The present invention relates to a serial scan type ink jet printing apparatus and method.
2. Description of the Related Art
In a serial scan type ink jet printing apparatus of recent years, there are growing demands for faster printing speed. As a method for increasing the printing speed, it is effective to reduce the number of passes in a multipass printing method that is used to enhance a quality of printed images. The number of print passes refers to the number of scans that a print head is required to perform to have one line of image printed. Normally, the ink jet print head is mounted on a carriage which is reciprocally moved in a main scan direction that crosses a sub-scan direction in which a print medium is fed. The ink jet print head has a column of ink ejection openings arrayed in the sub-scan direction. These openings form a plurality of nozzles. An image is progressively formed on a print medium by repetitively alternating a printing scan, by which the print head ejects ink as it travels in the main scan direction, and a feeding operation, by which the print medium is fed a predetermined distance in the sub-scan direction (also referred to as a “paper feed”).
In the multipass printing method, since the print head has a predetermined number of ink ejection openings or nozzles the more the number of passes, the smaller the print medium feed distance (paper feed distance) for each pass will be. Conversely, as the number of passes is reduced, the paper feed distance for each pass increases. Therefore, the printing speed can be increased by reducing the number of passes. For example, when a 4-pass printing is changed to 2-pass printing, the printing speed theoretically increases two times. A 1-pass printing, if applicable, can further enhance the printing speed. That is, as the number of passes decreases, the number of scans that the carriage must perform to complete the printing over a predetermined print area (e.g., print surface of one sheet of print medium) decreases and the paper feed distance per pass increases. This in turn shortens the time required to print one sheet of print medium.
The print head having a plurality of ink ejection nozzles performs a printing scan in a main scan direction almost perpendicular to a direction in which the nozzles are arrayed. Thus, when for example a 2-pass printing is performed, a linear high density area is formed at a boundary between a strip area printed by a first printing scan and a strip area printed by a second printing scan.
In the 2-pass printing, since each band of area is printed by two scans, a duty of ink (relative number of ink dots) applied to the print medium in one scan is about two times greater than that of a 4-pass printing which prints one band of area in four scans. Thus, in a print medium such as plain paper, in which ink dots easily spread, a boundary portion between adjoining band areas which is applied a greater number of ink dots than in other areas has an increased risk of ink spread, although its likelihood varies depending on an ink property. As a result, a dark line (high density line) shows up, degrading the quality of a printed image.
A variety of methods have been proposed to eliminate the above-described dark lines at boundary portions and thereby enhance the quality of printed images (e.g., Japanese Patent Application Laid-open Nos. 2002-36524, 8-25693 (1996) and 7-52465 (1995)).
Japanese Patent Application Laid-open No. 2002-36524 describes a method for the serial scan system which prevents dark lines from being produced at boundary portions between bands of print area when the print head repetitively performs a printing scan, one band at a time, in the main scan direction. That is, in a printing scan that prints on the boundary portion, print data corresponding to an area close to the boundary portion is thinned according to a count value of ink dots formed in that area close to the boundary portion. By thinning the ink dots formed in the area close to the boundary portion, the formation of dark lines can be prevented.
Japanese Patent Application Laid-open No. 8-25693 (1996) describes a method for the serial scan system which makes less noticeable dark lines that are formed at the boundary portions between bands of print area when the print head repetitively performs a printing scan, one band at a time, in the main scan direction. That is, in a 1-pass printing, an image printed in a preceding scan and an image to be printed in the next scan are partly overlapped and a random mask pattern is used for the overlapping image area so that the two scans complement each other in forming ink dots in the overlapping area.
Japanese Patent Application Laid-open No. 7-52465 (1995) describes a method for a serial scan type multipass printing system which makes dark lines formed at the boundary portions less noticeable by randomly setting a paper feed distance using a random number to randomize a dark line occurrence frequency.
Although they can be applied where dark lines are always formed in the boundary portions in image areas, the conventional methods, however, cannot eliminate white lines that are caused by a paper feed accuracy problem and by a phenomenon called an “end nozzle dot deflection.” The “end nozzle dot deflection” is a phenomenon in which ink droplets ejected from end nozzles of a nozzle column in the print head land at positions deviated toward the center of the nozzle column (see Japanese Patent Application Laid-open No. 2003-145775). That is, as ink droplets are ejected from the nozzles, the surrounding air is carried away by the droplets, reducing the pressure of a space near the nozzle face of the print head relative to the surrounding. Thus, the air near the print head flows toward the reduced pressure space. This air flow draws ink droplets, particularly those ejected from the end nozzles of the nozzle column, toward the center of the nozzle column, with the result that the ink droplets land at positions deviated toward the center of the print head This process occurs in the so-called end nozzle dot deflection.
However, if an end nozzle dot deflection should occur in which the landing positions of the ink droplets ejected from the end nozzles N1, N2, N6-N8 deviate toward the center of the print head H, the boundary portion P appears as a white line and is easily noticed. Depending on the print head used, the landing positions of ink droplets ejected from end nozzles may deviate toward the outside of the print head. In that case, the boundary portion appears as a dark line. These white or dark lines vary depending on the kind of print medium. In the case of a print medium in which ink easily spreads, such as plain paper, the boundary portions are likely to appear as dark lines.
In the 2-pass printing, since the duty of ink applied to the print medium in one pass is larger than in the 4-pass printing as described above, the amount of the end nozzle dot deflection is larger than that of the 4-pass printing. Thus, when the 2-pass printing is performed on a print medium in which ink dots hardly spread, such as photograph paper, there is an increased risk that the greater end nozzle dot deflection than that of the 4-pass printing can result in more noticeable white lines at the boundary portions, significantly degrading the quality of printed images. If the white or dark lines at the boundary portions are to be made less noticeable by correcting print data corresponding to the end nozzles, as in the conventional techniques described above, the white or dark boundary lines may not be made less noticeable to an expected level and remain to show up. This phenomenon becomes conspicuous as the ink droplets become small (to less than 2.8 pl), a significant hindrance to printing high quality images such as photographs and graphics.
The present invention can overcome the problems described above and can provide an ink jet printing apparatus and an ink jet printing method for a multipass printing system which can print high-quality images even if the printing speed is increased by reducing the number of passes.
In a first aspect of the present invention, there is provided an ink jet printing apparatus for printing an image on a print medium by using a print head capable of ejecting ink from a plurality of nozzles arrayed in a line, the ink jet printing apparatus comprising:
In a second aspect of the present invention, there is provided an ink jet printing apparatus for printing an image on a print medium by using a print head capable of ejecting ink from a plurality of nozzles arrayed in a line, the ink jet printing apparatus comprising:
In a third aspect of the present invention, there is provided an ink jet printing apparatus for printing an image on a print medium by using a print head capable of ejecting ink from a plurality of nozzles arrayed in a line, the ink jet printing apparatus comprising:
In a fourth aspect of the present invention, there is provided an ink jet printing method for printing an image on a print medium by using a print head capable of ejecting ink from a plurality of nozzles arrayed in a line, the ink jet printing method comprising the steps of:
In a fifth aspect of the present invention, there is provided an ink jet printing method for printing an image on a print medium by using a print head capable of ejecting ink from a plurality of nozzles arrayed in a line, the ink jet printing method comprising the steps of:
In a sixth aspect of the present invention, there is provided an ink jet printing method for printing an image on a print medium by using a print head capable of ejecting ink from a plurality of nozzles arrayed in a column, the ink jet printing method comprising the steps of:
With this invention, even when the printing speed is increased by reducing the number of passes, it is possible to print high-quality images with no noticeable boundary lines showing up, by setting a print medium feed distance according to a state of image being printed.
The above and other objects, effects, features and advantages of the present invention will become more apparent from the following description of embodiments thereof taken in conjunction with the accompanying drawings.
Now, embodiments of this invention will be described by referring to the accompanying drawings.
In
A plurality of print heads 1 eject different color inks and the ink tanks for supplying inks accommodate different inks, such as cyan, magenta and yellow inks. Each print head 1 is replaceably mounted on the carriage 502 and positioned there. The carriage 502 is provided with a connector holder (electric connecting portion) to be connected with the connectors on the print head 1 side. Through these connectors drive signals are transmitted to respective print head 1. The carriage 502 is guided along a guide shaft 503 installed in the printing apparatus so that the carriage can be moved in the main scan direction of arrow X. The carriage 502 is fixed to a timing belt 507 stretched between a motor pulley 505 and a follower pulley 506 and is controlled by a main scan motor 504 driving the motor pulley 505. A print medium 508, such as paper and plastic thin plate, is fed in the sub-scan direction of arrow Y by the rotation of two pairs of transport rollers 509, 510 and 511, 512 through a position (printing portion) where it faces a nozzle surface (a surface formed with ejection openings) of the print head 1. In the printing portion, the print medium 508 is supported at its back on a platen (not shown) so that the print medium in the printing portion forms a flat print surface. With the print head 1 mounted on the carriage 502, the nozzle surface of the print head protrudes down from the carriage 502 and faces the print surface of the print medium 508 situated between the two pairs of transport rollers 509, 510 and 511, 512.
The print head 1 is provided with a means to generate energy for ejecting ink from the nozzles. In this example, the print head has electrothermal transducers that generate a thermal energy to eject ink. That is, the thermal energy produced by the electrothermal transducers causes a film boiling, forming bubbles in ink. The bubbles as they expand and contract produce pressure changes in ink to cause ink droplets from being ejected from the nozzles.
In
Reference numeral 514 denotes an ejection performance recovery unit which has caps 51 one for each print head 1, a suction pump 516 connected to the inside of the caps 51 through pipes 527, and a wiper 517 having a blade 518. The caps 51 cap the nozzle surfaces 621 of the print heads 1 when the corresponding print heads 1 move to positions directly above the caps. With the caps closed, activating the suction pump 516 to apply a suction force to the interior of the caps 51 causes ink not contributing to printing to be sucked out of the nozzles 622 of the print heads 1, thus maintaining the ink ejection performance of the print heads 1 in good condition. Also by causing ink not contributing to printing to be ejected from the nozzles 622 toward the inside of the caps 51 (preliminary ejection), it is possible to keep the ink ejection performance of the print heads 1 in good condition. The blade 518 of the wiper 517 wipes the nozzle surfaces 621 of the print heads 1 to clear the nozzle surfaces of adhering matters.
In
An operation unit 705 has a group of switches operated by an operator, which includes a power switch 706, a start switch 707 for initiating a printing operation, and a recovery switch 708 for starting the suction recovery operation.
A head driver 709 energizes the ejection heaters (electrothermal transducers) 625 of the print head 1 according to print data. The head driver 709 includes a shift register to match the print data to the positions of the ejection heaters 625 and arrange these information in order, a latch circuit to latch print data at an appropriate timing, a logic circuit element to energize the ejection heaters 625 in synchronism with the drive timing signal, and a timing setting unit to appropriately set a drive timing (ejection timing) to align ink dots with intended landing positions. The print head 1 of this example also has sub-heaters 712 to adjust temperature and thereby stabilize the ink ejection performance. The sub-heaters 712 may be formed on a substrate of the print head at the same time that the ejection heaters 625 are formed, or may be mounted on the print head or head cartridge.
A motor driver 711 drives the main scan motor 504. A sub-scan motor 714 is a drive source to transport the print medium 508 in the sub-scan direction. A motor driver 713 is a driver for the sub-scan motor 714.
Next, an example printing operation will be explained in detail. In this example, a 1-pass printing is performed under the control of the controller 700 as the main control unit by changing the print medium feed distance (paper feed distance) in multiple stages according to the grayscale of an image being printed.
The applicant of this invention confirmed a phenomenon in which the difference ΔL varies according to the print duty (see Japanese Patent Application Laid-open No. 2003-145775). As described above, the end nozzle dot deflection is a phenomenon in which ink droplets ejected from end nozzles situated at the ends of the nozzle column are drawn toward the center of the nozzle column and land on the print medium at positions deviated toward the center of the print head. Thus, the higher the print duty, the stronger the tendency that a pressure in the surrounding of the print head nozzle surface will decrease and the greater the landing position deviations corresponding to the difference ΔL will become.
In this example, as shown in
In
From the printed result of these patches, a selection is made of a paper feed distance for each print duty, for which a boundary line in the boundary portion P between the first scan and the second scan is least noticeable. The selected paper feed distance is set as an optimal paper feed distance for each print duty. Considering print head manufacturing variations and paper feed accuracy variations, printing the paper feed distance setting patterns as shown in
First, paper feed distance setting patterns, such as shown in
By adjusting the paper feed distance according to the average is print duty as described above, it is possible to make a boundary line less noticeable even in the 1-pass printing and thereby form an image of satisfactory quality. Further, no image degradation due to a reduced paper feed distance has been observed even if the paper feed distance is set 20 μm shorter than the length of the print head 1 of L.
If the value of average print duty does not match any one stage of print duty used in the patterns of
The average print duty may cover a whole 1-scan print area as in this example or only that area in the whole 1-scan print area which is printed by end nozzles. With this arrangement, it is possible to better adjust the paper feed distance by effectively using the average print duty in the boundary portion P.
With the printing operation controlled by setting the paper feed distance as described above, in the example of
In the first embodiment the paper feed distance is adjusted based on the average print duty for each scan. In this example, the paper feed distance is adjusted by calculating an average value of the average print duties of two adjoining scans and basing its adjustment on the calculated average value.
In this embodiment, since the average print duty of each of two successive scans is considered in adjusting the paper feed distance, boundary lines can be made even less noticeable, producing a further improvement in the image quality.
Further, the average print duty may cover the entire print area of one scan as in this example or only that area in the entire 1-scan print area which is printed by end nozzles. With this arrangement, it is possible to better adjust the paper feed distance by effectively using the average print duty in the boundary portion P.
In this example, a multipass printing is performed by setting a paper feed distance for each page.
In this example also, by setting a paper feed distance to control the printing operation, the positions of dots in the boundary portion (P) between the preceding scan (first scan) and the subsequent scan performed after the print medium has been fed a set distance (third scan) are changed in the paper feed direction.
In
After the paper feed distance has been determined as described above, boundary line elimination processing is performed as shown in
First, print data for an nth scan and an (n+2)nd scan making up the boundary portion P in the 2-pass printing is received (step S21). Then, based on the print data received, the number of dots to be formed in a predetermined dot count area is counted (step S22). The dot count value is equivalent to a print duty in the predetermined dot count area.
Next, based on the dot count value for each dot count area A, a correction rank for the respective dot count areas A is determined (step S23). A relation between the dot count value and the correction rank is set beforehand for each paper feed distance that is determined in step S15 of
The relation between the dot count value and the correction rank can be set by printing patches as shown in
In this example, as shown in
From the printed result of these patches, a correction rank is set for each print duty which makes a boundary line in the boundary portion P between the first scan and the third scan least noticeable. This correction rank for each print duty is set for each paper feed distance determined by step S15 of
Based on the preset relation between the dot count value and the correction rank, the print data is corrected for each dot count area A according to the correction rank determined by step S23 of
After the print data has been corrected by the boundary line elimination processing of
When a plurality of different inks (e.g., cyan, magenta, yellow and black inks) are used, the correction rank is determined for each ink color to correct the print data.
As described above, the print data correction process involves determining an equally applicable paper feed distance between successive scans in one page according to the print duty in that page, determining an optimal correction rank based on a combination of the paper feed distance and the print duty for the areas adjoining the boundary portion P, and correcting the print data according to the correction rank. The correction of print data not only thins print data but also adds dots to it. This process therefore can make a boundary line less noticeable by correcting the print data according to the print density in the boundary portion P and subtracting or adding dots to and from the print data in the boundary portion P. This ensures that a quality image with no apparent boundary lines can be formed also in the 2-pass printing.
It is also possible to correct the print data to change the volume of each ink droplet. What is important is that the area covered by ink in the boundary portion can be increased or decreased. The paper feed distance may be determined by taking an average print duty of each of two adjacent scans into account, as in the first and second embodiment. Further, the average print duty may be one for that area in the entire print area of each scan which is printed by end nozzles.
Further, when a plurality of different inks (e.g., cyan, magenta, yellow and black inks) are used, a print pattern consisting of a plurality of patches such as shown in
This invention is not limited to 1-pass or 2-pass printing, which is effective in increasing the printing speed, but can also be applied to other multi-pass printing methods such as 3- or 4-pass printing.
Further, in 2- or higher-pass printing, the paper feed distance may be determined by considering an average print duty of each of two adjacent scans, as in the first and second embodiment. The average print duty may also be one for that area in the entire print area of each scan which is printed by end nozzles. What is needed is that it must be possible to set the print medium feed distance (paper feed distance) according to the print density of an image. In that case, the lower the print duty, the smaller the print medium feed distance can be set.
It is also possible to set the print medium feed distance (paper feed distance) according to the kind of print medium. In that case, the feed distance is increased as the tendency for the ink used to spread on the print medium becomes more prominent.
When the print medium feed distance is set according to the amount of deviation of landing positions of ink droplets ejected from end nozzles of the print head, the feed distance is made to increase with an increasing ink dot landing position deviation toward the center of the nozzle column.
(Others)
The present invention produces excellent effects in the ink jet printing system, particularly in print heads and printing apparatus utilizing thermal energy for ink ejection.
As for the representative construction and working principle, it is preferable to use the basic principle disclosed in U.S. Pat. Nos. 4,723,129 and 4,740,796. This system can be applied to either the so-called on-demand type or continuous type. In the case of the on-demand type, in particular, electrothermal transducers installed in a sheet or ink paths holding ink are applied at least one drive signal, that matches the print data, to cause a rapid temperature rise in excess of a nucleate boiling. The electrothermal transducers generate a thermal energy enough to produce a film boiling on a heat application surface in the print head, thereby forming bubbles in ink that match the drive signals with a one-to-one correspondence. As they expand and contract, the bubbles eject ink from the nozzles, forming at least one ink droplet. It is preferred that the drive signal be formed in a pulse shape because the pulse signal can cause the bubbles to instantly and properly expand and contract, realizing a responsive ejection of ink. Preferred pulse-shaped drive signals include those disclosed in U.S. Pat. Nos. 4,463,359 and 4,345,262. An even more excellent printing can be realized if conditions, disclosed in U.S. Pat. No. 4,313,124 concerning a temperature increase rate on the heat application surface, are adopted.
As for the construction of the print head, in addition to the construction described in the above patent specifications in which nozzles, ink paths and electrothermal transducers are combined (to form linear or right-angle flow paths), this invention also includes a construction in which the heat application portion is arranged in a bent area (U.S. Pat. Nos. 4,558,333 and 4,459,600). Further, this invention can also be effectively applied to a construction in which a slit is formed as an ejection portion common to a plurality of electrothermal transducers (Japanese Patent Application Laid-open No. 59-123670 (1984)) and a construction in which an opening for absorbing a pressure wave of thermal energy is formed according to the ejection portion (Japanese Patent Application Laid-open No. 59-138461 (1984)).
Furthermore, the ink jet printing apparatus of this invention may be used not only as an image output terminal for information processing devices such as computers, but also as a copying machine in combination with a reader or as a facsimile machine with transmission and reception functions.
The present invention has been described in detail with respect to preferred embodiments, and it will now be apparent from the foregoing to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and it is the intention, therefore, that the appended claims cover all such changes and modifications.
This application claims priority from Japanese Patent Application No. 2004-107752 filed Mar. 31, 2004, which is hereby incorporated by reference herein.
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