The present invention relates to an image-forming apparatus which forms an image by ejecting an ink through plural ink ejection orifices, and to an image-forming method employing the image-forming apparatus.
Image-forming apparatuses such as ink-jet printers are widely used. The ink-jet printer ejects an ink (ink droplets) through plural ink ejection orifices (nozzle outlets) provided on a printing head. By a known technique for ejecting an ink through ink nozzles, a thermal energy is applied to an ink in a nozzle in accordance with a driving pulse to cause film boiling of the ink, and the ink is ejected from the nozzle by a bubble formed by the boiling. Many ink droplets are ejected through the nozzle onto a recording medium corresponding to the image to be formed.
For increasing the image recording speed (image-forming speed), some of the ink-jet printers employing the above technique have line heads having multiple ink ejection nozzles respectively and placed perpendicularly to the delivery direction of the recording medium, and the ink is ejected simultaneously the ink ejection orifices (line printer: ref. e.g., Japanese Patent Application Laid-Open No. 2005-238556).
The image-forming apparatuses for forming an image on a recording medium are required to be capable of forming the image in high quality with a high resolution. The aforementioned line printers and the like ink-jet printers can satisfy the requirements. The ink-jet printers do not bring the printing heads into contact with the recording medium in printing to enable stable image recording, advantageously.
Mostly, the above line printer employs a printing head which has ink ejection orifices arranged parallel perpendicularly to the direction of the recording medium delivery. Image formation with plural printing heads, six heads as an example, arranged along the direction of the recording medium delivery is described with reference to
After one cycle of printing with printing heads K1-K6 in this order, the next printing cycle is repeated successively. During the time between the printing by K6 and the next printing by K1, the recording medium is delivered by the distance corresponding to the positional interval between the printing heads K1 and K6. Since the timing of the printing by K1-K6 (ink ejection timing) can be adjusted by confirming the printed image on the recording medium, various methods are disclosed for correcting the error caused by the printing head.
In the printing as described above, further increase of the image-forming speed can cause positional deviation between the print zone with the printing head K1 and the print zone with the printing head K6 to lower the image quality owing to decline of accuracy in the delivery of the recording medium. That is, further increase of the speed of delivery of the recording medium to increase further the image formation speed will make significant the positional deviation of the picture elements in the delivery direction. The ink droplets ejected from printing head K1 can partly overlap with the ink droplets ejected from the printing head K6 to give rise to a black stripe as shown in
Further, the recording medium P can be delivered obliquely (in the direction shown by two-dot chain line arrow in
The present invention intends to provide an image-forming apparatus which does not cause a decline of the image quality (printing precision) from an error in delivery of the recording medium, or a like error. The present invention intends also to provide an image-forming method employing the apparatus.
A first embodiment of the image-forming apparatus of the present invention has plural rows of ink ejection orifices arranged parallel perpendicularly to the delivery direction of the recording medium, and forms an image on a recording medium by ejecting an ink successively through a row of ink ejection orifices selected from the plural rows of ink ejection orifices onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A second embodiment of the image-forming apparatus of the present invention has plural rows of ink ejection orifices arranged parallel perpendicularly to the delivery direction of the recording medium, and forms an image on a recording medium by ejecting an ink successively through a row of ink ejection orifices selected from the plural rows of ink ejection orifices onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A third embodiment of the image-forming apparatus of the present invention has plural rows of ink ejection orifices arranged parallel perpendicularly to the delivery direction of the recording medium, and forms an image on a recording medium by ejecting an ink successively through a row of ink ejection orifices selected from the plural rows of ink ejection orifices onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A fourth embodiment of the image-forming apparatus of the present invention has six ink ejection orifice rows arranged parallel perpendicularly to the delivery direction of the recording medium, and forms an image on a recording medium by ejecting successively an ink, through a row of ink ejection orifices selected from the six ejection orifice rows arranged parallel perpendicularly to the delivery direction of the recording medium, onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A fifth embodiment of the image-forming apparatus of the present invention has four ink ejection orifice rows arranged parallel perpendicularly to the delivery direction of the recording medium, and forms an image on a recording medium by ejecting successively an ink, through a row of ink ejection orifices selected from the four ejection orifice rows arranged parallel perpendicularly to the delivery direction of the recording medium, onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A first embodiment of the image-forming method of the present invention serves to form an image on a recording medium by ejecting an ink successively through a row of ink ejection orifices selected from plural rows of ink ejection orifices arranged parallel perpendicularly to the delivery direction of the recording medium onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium parallel perpendicularly to the delivery direction of the recording medium, wherein
A second method embodiment of the image-forming method of the present invention serves to form an image on a recording medium by ejecting an ink successively through a row of ink ejection orifices selected from plural rows of ink ejection orifices arranged parallel perpendicularly to the delivery direction of the recording medium onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A third embodiment of the image-forming method of the present invention serves to form an image on a recording medium by ejecting an ink successively through a row of ink ejection orifices selected from plural rows of ink ejection orifices arranged parallel perpendicularly to the delivery direction of the recording medium onto one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A fourth embodiment of the image-forming method of the present invention serves to form an image on a recording medium by ejecting successively an ink through a row of ink ejection orifices selected from six ink ejection orifice rows arranged parallel perpendicularly to the delivery direction of the recording medium, onto one of raster line zones constituted of plural picture element domains arranged parallel perpendicularly to the delivery direction of the recording medium. This method conducts simultaneously steps of:
A fifth embodiment of the image-forming method of the present invention serves to form an image on a recording medium by ejecting successively an ink through a row of ink ejection orifices selected from four ink ejection orifice rows arranged parallel perpendicularly to the delivery direction of the recording medium, onto one of raster line zones constituted of plural picture element domains arranged parallel perpendicularly to the delivery direction of the recording medium. This method conducts simultaneously steps of:
A still another embodiment of the image-forming apparatus has plural rows of image-forming elements arranged parallel perpendicularly to the delivery direction of the recording medium, and forms an image on a recording medium successively a portion of an image, with a row of the image-forming elements selected from the plural rows of image-forming elements arranged parallel perpendicularly to the delivery direction of the recording medium, on one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
A still another embodiment of the image-forming method of the present invention serves to form an image on a recording medium by forming successively a portion of an image, with a row of image-forming elements selected from plural rows of image-forming elements arranged parallel perpendicularly to a delivery direction of the recording medium, on one of raster line zones constituted of plural picture element domains arranged, on the recording medium, parallel perpendicularly to the delivery direction of the recording medium, wherein
The term “image-forming element” herein includes an ink ejection orifice on a printing head in an ink-jet type of image-forming apparatus, and a heater element on a printing head of a thermal transfer type image-forming apparatus.
In the present invention, onto two raster line zones adjacent to the front and rear sides of the raster line zone in the delivery direction onto which the ink is ejected from orifices of the first row of the ink ejection orifices in the delivery direction of the recording medium, the ink is ejected from rows of orifices other than the rearmost row of ink ejection orifices in the delivery direction of the recording medium. In the case where no error is caused in production or the image-forming apparatus or in delivery of the recording medium, the ink ejected from the plural ink ejection orifice rows can impact the designed positions without lowering the printing precision (image quality) even if the speed of delivery of the recording medium is high. Actually, however, some errors can arise in operations such as delivery of the recording medium, which may cause an error in impact position of the ink droplets ejected from plural rows of ink ejection orifices. Since among the ink ejection orifice rows, the front row and the rearmost row of the ink ejection orifices are farthest in distance, the possibility is high that the deviation between the impact positions of the ink droplets ejected from the front and rearmost rows may cause a larger error. However, as described above, onto two raster line zones adjacent to the front and rear sides of the raster line zone in the delivery direction onto which the ink is ejected from orifices of the front row of the ink ejection orifices in the delivery direction of the recording medium, the ink is not ejected from the rearmost row of ink ejection orifices in the delivery direction of the recording medium, whereby the above error (deviation) can be prevented. Therefore, the decline of the image quality (printing precision) owing to the error in delivery of the recording medium can be prevented.
The present invention has been realized in a line printer which ejects the same color of ink through plural printing heads.
A skeleton of a line printer incorporating a printing module (printing unit), an example of the image-forming apparatus of the present invention, is described briefly with reference to
The line printer 10 has a printing head unit 20 and a delivery unit 40: the printing unit 20 has printing heads K1, K2, K3, K4, K5, and K6, for ejecting an ink on a recording medium like a recording paper sheet for forming an image; and the delivery unit 40 delivers a recording medium in an arrow-A direction (recording medium delivery direction). From all of the printing heads K1, K2, K3, K4, K5, and K6, a black ink is ejected. The printing head unit 20 has a head-driving motor 118 (
The engine base 30 which holds the printing unit 20 thereon is rectangular, and four corners thereof are fixed to nuts 32. The nuts 32 are fit to screwed axes 34. The nuts 32 are moved vertically by rotating the four screwed axes 34. At the lower portion of the respective screwed axes 34, a sprocket 36 is fixed. The four sprockets 36 are connected by a chain 38. The motor 41 is driven to circulate the chain 38 to rotate the screw axes 34 synchronously, whereby the printing head unit 20 is vertically moved together with the engine base 30.
The delivery unit 40 has four delivery belts 42 for delivering a recording medium through under the printing head unit 20. The delivery belts 42 are stretched around the driven rollers 44,45,46, the encoder roller 47, and the driving roller 48 with application of a tension by a tensioner 49. These delivery belts 42 are circulated in the direction of the recording medium delivery (arrow-A direction) by a driving roller 48 driven by a timing belt 43 driven by a driving motor 41.
The line printer 10 has an ink-feeding unit 50 to feed an ink to the printing head 20. The ink-feeding unit 50 has therein subsidiary tanks 52a-52f (hereinafter referred to as “sub-tanks”) for storing the ink to be fed to the printing heads K1-K6, and ink tanks 53a, etc. (
The connection of the printing head unit 20 with the ink-feeding unit 50 is described below with reference to
The combination of the printing head unit 20 with the ink-feeding unit 50 connected by the tubes is called “a print module”. This print module 20 incorporates a control system described later with reference to
The ink flow paths in and between the printing head 20 and the ink-feeding unit 50 are described with reference to
The ink tank 53a storing a black ink is connected by an ink-sucking tube 56 to the sub-tank 52a. A suction pump 58 is placed in the flow path of the ink-sucking tube 56 for sucking the ink from the ink tank 53a and feeds the ink to the sub-tank 52a. As illustrated in
The sub-tank 52a is connected to an air communication hole 88a, and the inside pressure can be equalized to an atmospheric pressure by opening the valve 88. The sub-tank 52a is provided with an ink level sensor (liquid level detection sensor) 51 having an electrodes 51a,51b,51c for sensing the presence of the ink and the liquid level of the ink. By sensing the presence of the ink, the ink surface level can be controlled to be constant. The sub-tank 52a and the printing head K1 are placed at positions so as to apply a suitable negative pressure by water head difference to the ink ejection orifice of the printing head K1.
The sub-tank 52a is connected to the printing head K1 through the ink-feeding tube 60a and the ink-returning tube 62a to circulate the ink. An ink-feeding pump 59 is placed between the sub-tank 52a and the ink-feeding tube 60a. The ink is fed from the sub-tank to the printing head K1 by driving the ink-feeding pump 59. Below the printing head K1, a recovery unit 22 is placed to receive the ink discharged from the printing head K1. The recovery unit 22 and the sub-tank 52a are connected with each other through an ink-recovering tube 57 and an ink-sucking tube 56. The ink collected in the recovery unit 22 is recovered to the sub-tank by driving the suction pump 58 with the valve 82 closed and the valve 81 opened.
Next, the initial process for filling an ink from the respective ink tanks 53a-53f to printing heads K1-K6 is described in the case where a line printer 10 is newly mounted.
The initial ink filling operation is started when the printer 10 has been started up initially. In the initial start-up of the line printer 10, no ink is contained in the sub-tank 52a, the ink-sucking tube 56, the ink-feeding tube 60a, the ink-recovering tube 62a, and the printing head K1. In this initial filling operation, the ink is filled into the sub-tank 52a, the ink-feeding tube 60a, and the ink-returning tube 62a, or only into the sub-tank 52a.
To fill the ink into the sub-tank 52a, the ink-feeding tube 60a, and ink-returning tube 62a, the ink-feeding tube 60a is disconnected from the printing head K1 before feeding the ink from the sub-tank 52a to the printing head K1, and the ink is filled into the sub-tank 52a and the ink-feeding tube 60a from the main tank 53a. Then the ink-feeding tube 60a is connected with the printing head K1, and the ink is fed through the ink-feeding tube 60a to the printing head K1. After completion of the initial filling operation, the ink adhering to the head face K1s is wiped off by a cleaning blade 22b as described later.
For filling the ink-feeding tube 60a with the ink, the ink-feeding tube 60a is disconnected from the printing head K1, the disconnected end 60 at of the ink-feeding tube 60a and the end 62 at of the ink-returning tube 62a are connected together directly or indirectly, and the ink-feeding pumps 58,59 are driven to circulate the ink through main tank 53a, sub-tank 52a, the ink-feeding tube 60a, and the ink-returning tube 62a. Thereby, the ink expels the air from the ink-feeding tube 60a to fill the ink-feeding tube 60a. Then the ink-feeding tube 60a is disconnected from the ink-returning tube 62a, and is connected to the printing head K1. The ink is fed from the ink-feeding tube 60a to the printing head K1. In such a manner, intrusion of air from the ink-feeding tube 60a into the printing head K1 is prevented. This prevents evolution of an air bubble in the printing head K1. Thereby, when the ink is pushed out from the printing head K1 to the cap 22a, the ink is not expelled by a large amount of the air bubble not to cause overflow of the ink from the cap 22a. As mentioned above, in the initial ink filling operation, the ink may be filled from the ink tank 53a into the sub-tank 52a only. For this ink feeding, the suction pump 58 is driven with the valves 81 and 87 closed and the valve 82 opened.
The control system 100 of the printer 10 is described with reference to
The data or commands for recording are transmitted from a host PC 11 through an interface controller 102 to a CPU 100. The CPU 101 is a processing unit for controlling entirely the operation of the printer 10 such as reception of recording data, and recording of the data. The CPU 101, after analyzing received commands, develops the image data for the respective color as a bit map in the image memory 106 and draw an image. As the operation prior to the recording, a capping motor 122 and a head-driving motor 118 are driven through an output-input port 114 and a motor-driving assembly 116 to move the printing heads K1-K6 respectively to be apart from the cap 22a (
Then, the position of the front edge of the recording medium is detected by a front edge-detecting sensor (not shown in the drawing) for determining the timing (recording timing) of ejection of the ink onto the delivered recording medium. Thereafter, the CPU 101 reads out recorded color data from the image memory 106 in synchronization with the delivery of the recording medium according to the output signal successively from the encoder roller 47 (
The CPU 101 is operated in accordance with the processing program memorized in a program ROM 104. The program ROM 104 memorizes a processing program and tables corresponding to the control flow. A work RAM 108 is used as the operation memory. In the operation of cleaning and recovery of the respective printing heads K1-K6, the CPU 101 controls ink pressurization and ink sucking by driving a pump motor 124 through an input-output port 114 and a motor-driving assembly 116. An image is formed on a recording medium in accordance with a horizontal synchronization signal for the record in synchronization with the delivery of the recording medium. As described later, the raster is divided by the CPU 101, and the raster divisions are input to the image memory 106 as the image data for image formation with the six recording heads K1-K6. On receiving the horizontal synchronization signal, the CPU 101 transmits one raster division of the image data stored in the image memory 106 to the printing head-controlling circuit 112. In accordance with the transmitted image data, the ink is ejected from the corresponding printing head, as mentioned later.
A process for image formation under control by the above-mentioned control system 100 is described with reference to
A recording medium P (e.g., rolled paper sheet, or cut paper sheet) is delivered in the arrow-A direction by a delivery unit 40 (
The one raster line zone has plural picture element domains aligned in the aforementioned crossing direction (arrow-B direction). The term “picture element” herein denotes an image formed by one ink droplet ejected from one ink ejection orifice. The term “picture element domain” denotes an area (a portion or a range) where one ink droplet ejected from one ink ejection orifice deposits. Onto the one raster line zone, one of the printing heads K1-K6 ejects the ink selectively and simultaneously from a row of plural ink ejection orifices thereof. The printing heads K1-K6 are made preliminarily to correspond respectively to one of the raster line zones L1-L6. Here, the printing head K1 ejects the ink onto the raster line zone L1 to form plural picture elements: the printing head K2 ejects the ink onto the raster line zone L2 to form plural picture elements. Similarly, the printing head K3 corresponds to the raster line zone L3, the printing head K4 corresponds to the raster line zone L4, the printing head K5 corresponds to the raster line zone L5, and the printing head K6 corresponds to the raster line zone L6. When the raster line zone L1 has reached the position directly below the printing head K1, the ink is ejected from the ink ejection orifice row of the printing head K1 toward the raster line zone L1. Similarly when the raster line zone L2 has reached the position directly below the printing head K2, the ink is ejected from the ink ejection orifice row of the printing head K2 toward the raster line zone L1. The ink is ejected similarly onto the raster line zones L3-L6.
The six printing heads K1-K6 of the printer 10 respectively extend in the above-mentioned crossing direction (arrow-B direction) as shown in
As described above, image data (print data) for printing (formation) of an image on a recording medium are divided by CPU 101 into raster divisions. The term “raster” herein signifies a pattern of a number of picture elements arranged generally in lateral lines to form an image; in this embodiment the picture elements are arranged in lines in a direction perpendicular to the recording medium delivery direction (the length direction of the printing head). The term “raster division” herein signifies division of the data of a raster constituting the image to correspond to the printing heads K1-K6 for formation of plural picture elements of the raster line by ejection of the ink from the one row of ink ejection orifices. In this embodiment, the raster division is effected by the CPU 101 to input the divided data for printing by the six printing heads K1-K6 to the image memory 106. Otherwise, the image data of the raster may be divided into raster divisions by a driver (not shown in the drawing) of the host PC 11 or the like, and transmitted to the printer 10.
With the delivery of the recording medium P in the arrow-A direction, respective raster line zones reach successively the positions directly below the printing heads K1-K6. CPU 101 controls the printing head K1 to eject the ink from the selected ink ejection orifices of the ink ejection orifice row of the printing head K1 at the timing when the raster line zone L1 reaches the position directly below the printing head K1 in accordance with the image data. (The same is true with other printing heads.) As described above, in this embodiment, an image is formed by six rows of ink ejection orifices. In this case, the third row numbered from the upstream front side of the six ink-ejection orifice rows (ink ejection orifice row of the printing head K3) in the delivery direction ejects the ink onto the raster line zone L3 which is adjacent to a raster line zone L1 onto which the ink has been ejected from the ejection orifice row at the upstream front side (first row: ink ejection orifice row of the printing head K1). The fifth ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K5) ejects the ink onto the raster line zone L5 which is adjacent to the downstream side of the raster line zone L3 onto which the ink has been ejected from the third ink ejection orifice row (the ejection orifice row of the printing head K3). The sixth ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K6) ejects the ink onto the raster line zone L6 which is adjacent to the downstream side of the raster line zone L5 onto which the ink has been ejected from the fifth ink ejection orifice row (the ejection orifice row of the printing head K5). The fourth ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K4) ejects the ink onto the raster line zone L4 which is adjacent to the downstream side of the raster line zone L5 onto which the ink has been ejected from the sixth ink ejection orifice row. The second ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K2) ejects the ink onto the raster line zone L2 which is adjacent to the downstream side of the raster line zone L4 onto which the ink has been ejected from the fourth ink ejection orifice row (the ejection orifice row of the printing head K5). The first ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K1) ejects the ink onto the raster line zone L1 which is adjacent to the downstream side of the raster line zone L2 onto which the ink has been ejected from the second ink ejection orifice row.
As described above, the ink is ejected from predetermined printing heads for printing an image in raster line zones. In this embodiment, onto the raster line zone (L1), the ink is ejected from the ink ejection orifices of the first row from the upstream side (ink ejection orifice row of the printing head K1). Onto the raster line zones (L2 and L3) adjacent to the both sides of the raster line zone (L1), the ink is ejected from the ink ejection orifice rows of the printing head other than the rearmost printing head K6 on the downstream end side in the delivery direction. The positions of the impact of the ink droplets ejected from the two ink-ejection orifice rows at the upstream front side and the downstream end side can deviate relatively from the intended positions owing to errors in production working of the printer 10 or errors in recording medium delivery. However, such errors do not affect the printing since, onto the raster line zones adjacent to the raster line zone onto which ink has been ejected from the ink ejection orifice row on the upstream front side, the ink is not ejected from the ink ejection orifice rows on the downstream end side. Thereby, decline of the image quality (printing precision) caused by delivery error or a like error can be avoided.
Another process of image formation is described in which four rows of ink ejection orifices are employed as illustrated in
The image “FT” is the same as that in
In the state illustrated in
With the delivery of the recording medium P in the arrow-A direction, respective raster line zones reach successively the positions directly below the printing heads K1-K4. CPU 101 controls the printing head K1 to eject the ink from the selected ink ejection orifices of the ink ejection orifice row of the printing head K1 at the timing when the raster line zone L1 reaches the position directly below the printing head K1 in accordance with the image data. (The same is true with other printing heads.) As described above, in this embodiment, an image is formed by four rows of ink ejection orifices. In this case, the second row numbered from the upstream side of the four ink-ejection orifice rows (ink ejection orifice row of the printing head K2) in the delivery direction ejects the ink onto the raster line zone L2 which is adjacent to the downstream side of the raster line zone L1 onto which the ink has been ejected from the ejection orifice row (first row) at the upstream front side (ink ejection orifice row of the printing head K1). The fourth ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K4) ejects the ink onto the raster line zone L4 which is adjacent to the downstream side of the raster line zone L2 onto which the ink has been ejected from the second ink ejection orifice row. The third ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K3) ejects the ink onto the raster line zone L3 which is adjacent to the downstream side of the raster line zone L4 onto which the ink has been ejected from the fourth ink ejection orifice row (the ejection orifice row of the printing head K4). The first ink ejection orifice row numbered from the upstream side of the delivery (ink ejection orifice row of the printing head K1) ejects the ink onto the raster line zone L1 which is adjacent to the downstream side of the raster line zone L3 onto which the ink has been ejected from the third ink ejection orifice row.
The timing of ejection of the ink from the four printing heads of the above example is described with reference to
The raster lines (image data) L1-1, L2-1, . . . L2-Fin, L4-Fin corresponding to the printing head K1-K4 are formed into an actual image by ejecting the ink droplets from K1-K4 at timing described later as shown in
On the upstream side of the recording medium delivery direction, a front edge sensor (not shown in the drawing) is placed at a distance of 2 inches (1 inch: 2.54 cm) between the sensing position and the printing head K1 (more precisely the ink ejection orifice row). The adjacent printing heads (e.g., printing head K1 and printing head K2) are placed at intervals of 1 inch (precisely, distance between the ink ejection orifice rows of the printing heads K1 and K2). Each of the printing heads K1-K4 has ink ejection orifices (nozzles) at a pitch (resolution) of 600 [dots/inch], and has the maximum recording breadth (printing breadth) of 4 inches. Thus, each of the printing heads K1-K4 has 2400 ink-ejection orifices for the recording: one ink ejection orifice row has 2400 ink ejection orifices.
In this embodiment, the recording medium delivery speed (recording rate) is controlled to be 24 inches per second (about 610 mm/sec). The printing resolution in the recording medium delivery direction is adjusted to be 600 dots/inch. Accordingly, the image is formed with 600 raster lines per inch in the recording medium delivery direction: one raster line zone has a breadth (length in delivery direction) of 1/600 inch.
The encoder roller 47 (
This positional pulse is utilized as a trigger signal (print-starting signal) for each of the raster lines printed by the printing head K1 placed on the upstream front side of the printing heads in the delivery direction, and for the other three printing heads, K2, K3, and K4, the print-starting signals are transmitted with delay of 70 μsec, 139 μsec, and 208 μpsec, respectively from the above-mentioned positional pulse. The delay time is adjusted depending on the delivery speed.
The recording medium is delivered at a constant speed in the delivery direction (arrow-A direction in
Subsequently, an image corresponding to L1-3 in
At the time when the recording medium has been delivered by one more inch (by 3 inches after detection of the front edge of the recording medium by the edge sensor), the printing with the printing head K2 is started to print the raster line L2-1 (the second raster line from the first raster line (L1-1)). Then the raster lines L2-2 and L2-3 are printed in this order with intervals in the same manner as the printing with the printing head K1. The intervals are the same as in printing with the printing head K1 (conducted below in the same manner). As illustrated in
Further at the time when the recording medium has been delivered by one more inch (by 4 inches after detection of the front edge of the recording medium by the edge sensor), the printing with the printing head K3 is started to print the raster line L3-1 (the fourth raster line from the first raster line (L1-1) ). Then the raster lines L3-2 and L3-3 are printed with intervals. As illustrated in
Further at the time when the recording medium has been delivered by one more inch (by 5 inches after detection of the front edge of the recording medium by the edge sensor), the printing with the printing head K4 is started to print the raster line L4-1 (the third raster line from the first raster line (L1-1) ). Then the raster lines L4-2 and L4-3 are printed with intervals. As illustrated in
As described above, respective raster lines are formed successively on the recording medium being delivered. When the printing comes near to the end portion, the printing head K1 prints the raster line L1-(Fin-2) (eleventh raster line from the final raster line L4-Fin), the raster line L1-(Fin-1), and the raster line L1-Fin in this order to finish the printing by the printing head K1.
The printing is continued further. When the recording medium has been delivered by one inch after printing of the raster line L1-Fin, the printing head K2 prints the raster line L2-(Fin-2) (tenth raster line from the final raster line L4-Fin), the raster line L2-(Fin-1), and the raster line L2-Fin to finish the printing by the printing head K2.
When the recording medium has been delivered by one inch more, the printing head K3 prints the raster line L3-(Fin-2) (ninth raster line from the final raster line L4-Fin), the raster line L3-(Fin-1), and the raster line L3-Fin in this order to finish the printing by the printing head K3.
When the recording medium has been delivered by one inch more, the printing head K4 prints the raster line L4-(Fin-2) (eighth raster line from the final raster line L4-Fin), the raster line L4-(Fin-1), and the raster line L4-Fin to finish the printing by the printing head K4.
As described above, monochromatic image data spread in a continuous region are divided, for example, into raster lines for four black-color printing head, whereby the recording speed is increased to four times that with the single printing head of 6 inch/sec, namely 24 inches/sec. As a secondary effect, inherent characteristics in printing of the orifices of the printing heads K1-K4 are not continuous, and the recording is conducted separately for every four raster lines, so that the image quality can be improved remarkably. That is, the image quality can be made reliable regardless of incidental ejection failure.
In the above embodiment, an image raster is divided into raster divisions and the raster divisions are printed respectively with predetermined printing heads: onto the raster line zone (L1 in this example) onto which the ink is ejected from the ink ejection orifices of a front row in the delivery direction (K1 in this example), and the ink is not ejected onto the adjacent raster line zones on both sides thereof from the ink ejection orifices of the rearmost row in the delivery direction (orifice row of the printing head K4).
The points of the impact of the ink droplets ejected from the orifices of the two ink-ejection orifice rows at the upstream front side and the downstream end side of the printing heads can deviate from the predetermined positions owing to errors in production working of the printer 10 or errors in recording medium delivery. However, such errors do not affect the printing in the above embodiment since, onto the raster line zones adjacent to the raster line zone onto which ink has been ejected from the front ejection orifice row in the delivery direction, the ink is not ejected from the rear most ejection orifice rows in the delivery direction. Thereby, deterioration of the image quality (printing precision) caused by delivery error or a like error can be avoided.
An example is described for prevention of decline of the image quality (printing precision), caused by an error in delivery of the recording medium, with reference to
In
In
In the example shown in
In other words, onto the plural raster line zones arranged orderly in the direction of recording medium delivery (arrow-A direction), ink is ejected from the corresponding ink ejection orifice rows (indicated by circled numbers 1-6). The ink is ejected onto one raster line zones from the odd-numbered rows (indicated by circled numbers 1, 3, and 5 in the delivery direction of the ink ejection orifice) in the number-ascending order. Onto the following raster line zones after the above raster line zones, the ink is ejected from the even-numbered rows (indicated by circled numbers 2, 4, and 6 in the delivery direction of the ink ejection orifice) in the number-descending order. Thereby the same effect as above can be achieved. Otherwise, the ink may be ejected from the odd-numbered ink ejection orifice rows (rows of circled numbers 1, 3, and 5) in a number-descending order, and from the even-numbered ink ejection orifice rows (rows of circled numbers 2, 4, and 6) in a number-ascending order. Accordingly, the present invention can minimize deviation between the adjacent raster line zones, even when the recording medium is delivered obliquely as shown in
The image-forming apparatus of thermal transfer type employing the image-forming method of the present invention is described below with reference to
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2006-176695 | Jun 2006 | JP | national |
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2005-238556 | Sep 2005 | JP |
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20070296747 A1 | Dec 2007 | US |