JP2012024973A - Ink jet printing apparatus and ink jet printing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ink jet printing apparatus that performs printing excellent in marker resistance etc. when a plurality of inks different in permeability are used for printing the same color.SOLUTION: Both high-permeable inks (201, 203) and a low-permeable ink (202) are used for printing an edge. Consequently, both high optical density and scratch resistance, marker resistance and fixability can be made compatible.

Description

  The present invention relates to an ink jet recording apparatus and an ink jet recording method, and more particularly to a technique for performing recording using a plurality of inks having different penetrability for the same color.

  As this type of technology, Patent Document 1 discloses that an area of an image to be recorded is divided into an outer peripheral area and an inner area, and recording is performed in the inner area with highly penetrating ink having high permeability to a recording medium. It is described that recording is performed with a low-penetration ink having low permeability to a medium. Thereby, the gap between dots formed by ink can be made inconspicuous in the inner region, and the contour of the image can be prevented from blurring in the outer peripheral region.

  Furthermore, Patent Document 2 describes that the outer peripheral area is recorded with the low-penetration ink as described above, and the inner area is recorded by mixing the low-penetration ink and the high-penetration ink. This makes it possible to achieve both high density recording using low penetrating ink and fast fixing (fixing property) using high penetrating ink, particularly in the inner region. In addition, Patent Document 2 also describes that, for the inner region, the high-penetration ink and the low-penetration ink are ejected to alternate pixels to increase the scanning speed of the recording head and achieve high-speed recording.

JP 2003-011337 A JP 2002-113850 A

  However, in Patent Documents 1 and 2, since the outer peripheral area is recorded with only the low penetrating ink, there is a problem in marker resistance, scratch resistance, or fixability. That is, after the low penetrating ink has landed on the recording medium, it has low penetrability, so that a relatively large amount of coloring material such as pigment remains on the surface of the recording medium. For this reason, when the recorded image is rubbed with the marker, the color material may melt and move to another part, or the recorded image may be rubbed with some object and a part of the image may be lost. In addition, the use of low penetrability ink in the outer peripheral region causes a problem that the fixing (penetration) time of the entire image including the outer peripheral region is delayed, which hinders improvement in recording speed.

  The present invention has been made to solve such a problem, and provides an ink jet recording apparatus and a recording method capable of executing recording with high marker resistance, scratch resistance, and fixability in an outer peripheral region. The purpose is to do.

  In order to solve this problem, the present invention provides a second nozzle array for ejecting the first ink and a second ink having the same color as the first ink and less penetrating the recording medium than the first ink. An inkjet recording apparatus that performs recording by scanning a recording head including a nozzle row that ejects ink with respect to a recording medium, and is a non-recording area in which recording is not performed among recording areas that are recorded by the recording head An outer peripheral area in contact with the outer peripheral area is recorded with the first ink and the second ink, and an inner area in contact with the outer peripheral area in the recording area is recorded with the first ink without using the second ink. As described above, the recording head includes recording control means for controlling ejection of the first and second inks from the recording head.

  According to the above configuration, when the recording area is recorded by dividing the outer peripheral area and the inner area, the inner area is recorded with the first ink with high penetration, and the outer peripheral area is recorded with the first ink with high penetration. Recording is performed using a second ink having low penetration. This makes it possible to execute recording with high marker resistance, scratch resistance, and fixability in the outer peripheral area.

1 is a perspective view illustrating a schematic configuration of a color inkjet recording apparatus according to an embodiment of the present invention. (A)-(e) is a figure explaining the application | coating (discharge) order and application | coating area | region of an ink based on embodiment of this invention. FIG. 2 is a block diagram illustrating a schematic configuration of a recording control system circuit of the ink jet recording apparatus illustrated in FIG. 1. It is a functional block diagram which shows schematic structure for the image data processing in the image processing system comprised with the inkjet recording device and host PC of the said embodiment. It is a block diagram which shows the procedure of the recording data distribution process of 1st Embodiment of this invention. (A)-(l) is a figure which shows the distribution process of 1st Embodiment in the form of data. It is a block diagram which shows the procedure of the recording data distribution process of 2nd Embodiment of this invention. It is a figure explaining the mask processing concerning a 2nd embodiment. (A)-(l) is a figure which shows the distribution process of 2nd Embodiment in the form of data. (A)-(l) is a figure which shows the distribution process of 3rd Embodiment of this invention with the form of data. It is a block diagram which shows the procedure of the recording data distribution process of 3rd Embodiment. (A)-(l) is a figure which shows the distribution process of 4th Embodiment of this invention with the form of data. (A)-(c) is a figure explaining the application | coating (discharge) order and application | coating area | region of an ink based on the 5th Embodiment of this invention. It is a figure explaining the multi-pass printing of 2 passes concerning a 5th embodiment. It is a block diagram which shows the procedure of the recording data distribution process of 5th Embodiment. (A)-(o) is a figure which shows the distribution process of 5th Embodiment in the form of data. (A) and (b) show the ink application sequence based on the data distribution described above with reference to FIGS. 15 and 16, and the arrangement of the recording head shown in FIG. 13 (a) and the recording medium shown in FIG. FIG. 6 is a diagram illustrating a recording head scanning order. (A)-(l) is a figure which shows the distribution process which concerns on 6th Embodiment of this invention with the form of data.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<Apparatus configuration and ink application order>
FIG. 1 is a perspective view showing a schematic configuration of a color inkjet recording apparatus according to an embodiment of the present invention. Each of the ink tanks 207 to 212 accommodates six types of inks: high penetration black (Bk) ink, low penetration Bk ink, high penetration Bk ink, cyan (C) ink, magenta (M) ink, and yellow (Y) ink. is doing. These Bk inks are inks of similar colors having substantially the same hue, and are visually recognized as the same hue on the recording medium. High penetration Bk ink is ink with relatively low surface tension, and low penetration Bk ink is ink with relatively high surface tension. These six types of ink can be supplied from the corresponding ink tanks to the recording heads 201 to 206. The recording heads 201 to 206 are provided corresponding to the above six types of ink, and can eject ink supplied from the ink tanks 207 to 212.

  The conveyance roller 103 rotates together with the auxiliary roller 104 while sandwiching the recording medium 107 such as recording paper to convey the recording medium 107 and hold the recording medium 107. The carriage 106 can be mounted with ink tanks 207 to 212 and recording heads 201 to 206, and is configured to be able to reciprocate in the X direction in the figure by mounting these recording heads and ink tanks. During the reciprocation of the carriage 106, ink is ejected from the recording head, whereby an image is recorded on the recording medium. During a non-recording operation such as a recovery operation of the recording heads 201 to 204, the carriage 106 is controlled to stand by at a home position position h indicated by a broken line in the drawing.

  The recording heads 201 to 206 waiting in the home position h shown in FIG. 1 discharge ink onto the recording medium 107 while moving in the X direction in the drawing together with the carriage 106 when a recording start command is input. Record an image. By this movement (scanning) of the recording head, recording is performed on an area having a width corresponding to the arrangement range of the ejection ports of the recording heads 201 to 206.

  When the printing accompanying one scan in the main scanning direction (X positive direction) of the carriage 106 is completed, the carriage 106 scans in the reverse direction of the main scanning direction (negative X direction) toward the home position h. However, recording is performed by the recording heads 201 to 206. Before the next recording scan starts after the previous recording scan ends, the transport roller 103 rotates and the recording medium is transported in the sub-scanning direction (Y direction) intersecting the main scanning direction. In this way, the recording of the image on the recording medium 107 is completed by repeating the recording scanning of the recording head and the conveyance of the recording medium. The recording operation for ejecting ink from the recording heads 201 to 206 is performed based on control by a control unit described later.

  In the above example, the configuration in which the ink tanks 207 to 212 and the recording heads 201 to 206 are detachably mounted on the carriage 106 is shown. However, a configuration in which a cartridge in which the ink tanks 207 to 212 and the recording heads 201 to 206 are integrated is mounted on the carriage may be employed. Furthermore, a configuration in which a multi-color integrated head capable of discharging a plurality of colors of ink from a single recording head is mounted on a carriage may be employed.

  2A to 2E are views for explaining the ink application (ejection) order and application region according to the embodiment of the present invention.

  FIG. 2A shows the recording heads 201 and 203 that discharge the high penetration Bk ink and the recording head 202 that discharges the low penetration Bk ink among the recording heads 201 to 206 shown in FIG. That is, in the embodiment of the present invention, for the same color ink, two recording heads that discharge high penetration ink and one recording head that discharges low penetration ink are arranged in the main scanning direction. The form of the recording head is such that, for the same color ink, these nozzle rows are integrally provided so that two nozzle rows that discharge high penetrating ink and one nozzle row that discharges low penetrating ink are arranged in the main scanning direction. Of course there may be.

  FIGS. 2B and 2C show the order of ink application to each area when an image to be recorded is divided into an outer peripheral area (edge part) and an inner area (non-edge part). FIG. 2B shows the application order when scanning in the X direction, which is one direction of the main scanning direction, and FIG. 2C shows application when scanning in the −X direction, which is the other direction of the main scanning direction. Shows the order. As shown in these drawings, in the outer peripheral regions corresponding to the ink droplets at both outermost ends in these drawings, the high penetration Bk ink is applied after the low penetration Bk ink is applied. Further, in the internal region other than the both ends, two high penetration Bk inks are applied before and after. In these drawings, the two ink droplets arranged in the vertical direction in the drawing are not necessarily applied to the same pixel in a superimposed manner, and the description of the application (landing) order may be applied to an adjacent pixel. Contains. Depending on the embodiment described below, there are cases where they overlap and may be adjacent.

  A more specific description of the above-described order of grant is as follows. When the recording head is scanned in the X direction shown in FIG. 2B, after applying the high penetration Bk ink from the recording head 203 to the inner area (non-edge portion), the low penetration Bk ink is applied from the recording head 202 to the outer peripheral area. (Edge portion) is applied only, and then the highly penetrating Bk ink is applied from the recording head 201 to the outer peripheral region (edge portion) and the inner region (non-edge portion). On the other hand, in the case where the recording head is scanned in the −X direction shown in FIG. 2C, after applying the high penetration Bk ink from the recording head 201 to the inner region (non-edge portion), the low penetration Bk from the recording head 202. Ink is applied only to the outer peripheral region (edge portion), and then highly penetrating Bk ink is applied from the recording head 203 to the outer peripheral region (edge portion) and the inner region (non-edge portion).

  FIGS. 2D and 2E show an example in which the ink application order in the outer peripheral region is the order in which the low penetration Bk ink is applied after the high penetration Bk ink is applied. In this case, compared to the conventional method in which only the low penetrating Bk is applied to the outer peripheral region, the marker resistance and the fixing property are improved. In addition, the order of recording the high penetrating Bk ink following the low penetrating Bk ink is compared. Thus, the sharpness of the edge of the image is improved. However, there are cases where the marker resistance and the fixing property are deteriorated as compared with FIG. 2 (b) and FIG. 2 (c). Therefore, the order of recording with the low penetration Bk ink followed by the high penetration Bk ink shown in FIGS. 2B and 2C is more preferable from the viewpoint of the marker resistance and the fixing property.

  As described above, the high penetration ink is applied to the inner region, and the low penetration ink and the high penetration ink are applied to the outer peripheral region. When ink having high penetrability is applied to the inner region, the penetrating speed is high, and thus the scratch resistance and marker resistance are improved. However, since dots or images with highly penetrating ink have a low optical density, it is necessary to increase the recording density in order to obtain a high optical density. For this reason, in one embodiment described below, the recording density is increased by superimposing the high penetration ink on one pixel.

  On the other hand, in the case where the high penetration ink is applied to the outer peripheral area as in the case of the internal area, it is necessary to apply the high penetration ink at a high recording density in order to obtain a high optical density. However, when the recording density is increased, the sharpness of the edge is lowered. In addition, a method of recording the outer peripheral region using only the low penetrating ink is conceivable. However, in the case of the low penetrating ink, the coloring material stays in a portion close to the surface of the recording medium, so that the scratch resistance and the marker resistance are lowered. To do. Therefore, in the present embodiment, by applying the low penetrating ink and the high penetrating ink, both high optical density, scratch resistance, marker resistance, and fixing property are achieved.

  Further, in this case, the inventors of the present application have obtained knowledge that when the low penetrating ink and the high penetrating ink are applied in this order, the optical density may be higher than in the reverse order. The reason can be inferred as follows. Most of the coloring material stays on the surface of the recording medium while the low penetrating ink applied first penetrates so as to fill the voids of the recording medium. In this state, when the high-penetration ink is applied to the recording medium next, the low-penetration ink and the high-penetration ink penetrate while mixing on the surface of the recording medium, and the permeation speeds of both are averaged. As a result, the permeation speed is faster than when recording with only the low penetrating ink. As a result, in addition to high optical density, marker resistance, scratch resistance, and fixability can be improved as compared to recording with only low penetrating ink.

  The embodiment of the present invention further enables high-speed recording with a smaller number of nozzle rows for the same color or type of ink. That is, as one configuration for increasing the recording speed, for example, two nozzle arrays are prepared for the same color or type of ink, and data to be recorded in the scanning direction is distributed to these two nozzle arrays. Thereby, the scanning speed can be doubled without changing the driving frequency of each nozzle row. In the present embodiment, this configuration is used and, as shown in FIG. 2A, two nozzle rows (201, 203) for discharging highly penetrating ink are used, but nozzle rows (202 for discharging low penetrating ink) are used. ), The scanning speed is doubled as described above. That is, as described above with reference to FIGS. 2B to 2E, in the outer peripheral region, the recording data can be distributed to the two nozzle rows of the low penetrating ink and the high penetrating ink, while in the inner region, The recording data can be distributed to two nozzle arrays of high penetration ink. As described above, in order to increase the recording speed, for example, for each of the high penetrating ink and the low penetrating ink, for example, a total of four nozzle rows are prepared for each of the two inks. Double scanning speed can be realized. As described above with reference to FIGS. 2B to 2E, this can be achieved by recording the outer peripheral area using both the high-penetration ink and the low-penetration ink. As a result, it is possible to improve the scanning speed without significantly increasing the number of nozzle rows.

<High permeability ink composition and low permeability ink composition>
The coloring material contained in the ink used in the embodiment of the present invention may be either a dye or a pigment, but it is preferable to use a pigment from the viewpoint of fastness such as water resistance and weather resistance. In addition, the concentration of the color material used in the embodiment of the present invention is 1 to 10% on a weight basis with respect to the total amount of the ink, more preferably 1 to 2% for the low penetration Bk ink and 1% to the high penetration Bk ink. A range of 3-7% is preferred. Marker resistance and fixability can be further improved by using a low penetrating Bk ink with a lower colorant concentration than a high penetrating Bk ink.

<Control of penetration rate>
Control of the permeation speed of the ink used in the embodiment of the present invention with respect to the recording medium can be controlled using the surface tension as an index. That is, the high-penetration Bk ink has a higher permeation speed with respect to the recording medium than the low-penetration Bk ink. The surface tension as an index for controlling the penetration rate can be controlled by adding a penetrating agent such as a surfactant or a penetrating solvent. In particular, the surface tension of the low permeability ink is preferably 40 to 60 mN / m, and the surface tension of the high permeability ink is preferably 20 to 40 mN / m. More preferably, the surface tension of the high permeability ink is preferably 40 to 45 mN / m, and the surface tension of the low permeability ink is 30 to 35 mN / m. If the surface tension of the low penetrability ink is less than 20 mN / m, wetting may occur near the nozzles of the recording head, which may cause problems such as non-ejection of ink and deflection of the ejection direction.

  Hereinafter, the distribution of print data for the print heads of the high-penetration ink and the low-penetration ink according to some embodiments of the basic form described above will be specifically described.

(Embodiment 1)
3 is a block diagram showing a schematic configuration of a recording control system circuit of the ink jet recording apparatus shown in FIG. The ink jet recording apparatus 600 is connected to a data supply apparatus such as a host computer (hereinafter referred to as a host PC) 1200 via an interface 400. Various data transmitted from the data supply apparatus, control signals related to recording, and the like are input to the recording control unit 500 of the inkjet recording apparatus 600. The recording control unit 500 controls the motor drivers 403 to 404 and the head driver 405 according to a control signal input via the interface 400. The recording control unit 500 performs processing of input image data and processing of a signal input from the head type signal generation circuit 405. Reference numeral 401 denotes a transport motor for rotating the transport roller 103 for transporting the recording medium 107. Reference numeral 402 denotes a carriage motor for reciprocating the carriage 106 on which the recording heads 201 to 206 are mounted. Reference numerals 403 and 404 denote motor drivers for driving the conveyance motor 401 and the carriage motor 402, respectively. Reference numeral 405 denotes a head driver for driving the recording heads 201 to 206, and a plurality of head drivers are provided corresponding to the number of recording heads. Reference numeral 406 denotes a head type signal generation circuit that supplies a signal indicating the type and number of the recording heads 201 to 206 mounted on the carriage 106 to the recording control unit 500.

  FIG. 4 is a functional block diagram showing a schematic configuration for image data processing in an image processing system including the above-described ink jet recording apparatus and a host PC. The recording control unit 500 of the inkjet recording apparatus performs data processing transferred from the host PC 1200 in which the printer driver is installed via the interface 400.

  The host PC 1200 receives the input image data 1000 from the application, and performs the rendering process 1001 on the received input image data 1000 with a resolution of 1200 dpi. Thereby, multi-value RGB data for recording 1002 is generated. In the present embodiment, the recording multi-value RGB data 1002 is 256-value data. The generated multi-value RGB data for recording 1002 is transferred to the recording control unit 500.

  The recording control unit 500 performs color conversion processing 1007 for converting multi-value R, G, B data 1002 into multi-value (256 values) K, C, M, Y data 1008. Next, the multi-value K, C, M, Y data 1008 is quantized (binarized) by quantization processing 1009 (for example, error diffusion). As a result, binary K, C, M, and Y data 1010 having a resolution of 1200 dpi is generated. Edge processing 1011 is performed on the binary K data. Here, the K data corresponds to the recording data of the high penetration Bk ink and the low penetration Bk ink. As described below, the recording data of the high penetration Bk ink and the low penetration Bk ink is generated based on the K data. Is done. The C, M, and Y data correspond to the recording data of C, M, and Y ink, respectively.

  FIG. 5 is a block diagram showing the procedure of the recording data distribution process. As shown in the figure, first, edge portion detection processing 2001 is performed on binary K data. Of the binary K data, edge portion (outer peripheral region) data, that is, edge portion data 2003 is generated. Of the binary K data, data that does not correspond to the edge portion data is referred to as non-edge portion (internal region) data 2103. In the present embodiment, one pixel constituting the outermost contour of the image is a pixel at the edge portion.

  The edge portion data 2003 is distributed to the recording head 202 that discharges the low penetrating ink and the recording head 203 or the recording head 201 that discharges the high penetrating ink, and the non-edge portion data 2103 is recorded to the recording head 201 that discharges the high penetrating ink. And the recording head 203.

  FIGS. 6A to 6L are diagrams showing this distribution processing in the form of data. In these drawings, a broken line shown in the horizontal direction of the central portion indicates a position where the scanning direction of the recording head changes. The data above the broken line is data recorded in the X direction (see FIG. 2A: right direction in FIG. 6), and the area below the broken line is the −X direction (left direction in FIG. 6). ) Is recorded.

  The binary K data shown in FIG. 6A is first converted into non-edge portion data 2103 shown in FIG. 6F and edge portion data 2003 shown in FIG. It is divided into.

  Next, the non-edge portion data 2103 in FIG. 6F is distributed to the recording head 201 data shown in FIG. 6G and the recording head 203 data shown in FIG. That is, as is apparent from FIGS. 6G and 6I, in this embodiment, two drops of highly penetrating ink are applied per pixel for recording of the non-edge portion. Thereby, the dot density by highly penetrating ink can be increased and the optical density can be increased.

  On the other hand, for the edge portion data 2003 shown in FIG. 6B, the upper recording data whose scanning direction is the X direction is the recording head 201 data shown in FIG. 6C and the recording data shown in FIG. The data is distributed to the data for the head 202. Further, the lower recording data whose scanning direction is the −X direction is divided into the recording head 203 data shown in FIG. 6E and the recording head 202 data shown in FIG. That is, the edge portion is recorded using both the high penetration ink and the low penetration ink. As a result, both high optical density and scratch resistance, marker resistance and fixability can be achieved.

  The recording data for each recording head is as follows by the recording data distribution of the edge portion and the non-edge portion.

  Data to be recorded by the recording head 201 that ejects highly penetrating ink is logical sum data (FIG. 6 (j)) of edge portion data (FIG. 6C) and non-edge portion data (FIG. 6G). . Data recorded by the recording head 202 that discharges low penetrating ink is logical sum data (FIG. 6 (k)) of edge portion data (FIG. 6D) and non-edge portion data (FIG. 6H). . Further, the data recorded by the recording head 203 that discharges highly penetrating ink is the logical sum (FIG. 6 (l)) of the edge data FIG. 6 (e) and the non-edge data FIG. 6 (i).

  Note that the above-described recording can be performed even when only one recording head ejects highly penetrating ink. In this case, the non-edge portion data 2103 can be recorded using the recording head 201 when the scanning direction is the X direction, and can be recorded using the recording head 203 when the scanning direction is the −X direction.

  The composition of the ink used in this embodiment is as follows. In the following description, “%” is based on weight and is weight% unless otherwise specified.

(High penetration Bk ink)
Pigment dispersion 26.6% (pigment concentration 4%) (CAB-O-JET300: 15% pigment concentration aqueous solution / manufactured by Cabot Corporation)
Glycerin 10%
Polyethylene glycol 1000 1%
2-pyrrolidone 5%
Acetylenol E100 0.3% (manufactured by Kawaken Fine Chemicals)
The remaining low-permeability Bk ink can be obtained by sufficiently mixing and stirring the above components and passing through a 5 μm filter.

  The surface tension of the ink having the above composition is 34.8 mN / m.

(Low penetration Bk ink)
Pigment dispersion 13.3% (pigment concentration 2%) (CAB-O-JET300: 15% pigment concentration aqueous solution / manufactured by Cabot Corporation)
Glycerin 10%
Polyethylene glycol 1000 1%
2-pyrrolidone 5%
Acetylenol E100 0.1% (manufactured by Kawaken Fine Chemicals)
Remaining ion exchange water The above-mentioned components are sufficiently mixed, stirred, and passed through a 5 μm filter to obtain the desired highly penetrating Bk ink.

  The surface tension of the ink having the above composition is 41.0 mN / m.

(Embodiment 2)
The second embodiment of the present invention relates to the distribution of print data to each print head that enables the scanning speed of the print head to be increased in the basic form described above.

  Time required to apply electrical energy used to eject ink with the print head, refill time to replenish ink to individual nozzles after ejection, time to electrically transmit data, etc. As a result, the drive frequency of the recording head is limited. In this embodiment, the scanning speed of the recording head is increased by lowering the recording resolution in the scanning direction (hereinafter referred to as scanning resolution) for one recording head without changing the driving frequency of the recording head.

  FIG. 7 is a block diagram showing the procedure of the recording data distribution process of this embodiment. In the present embodiment, two pixels from the outermost contour of the image are edge pixels.

  As shown in FIG. 7, the edge portion data 2003 is distributed to one of the three recording heads 201, 202, and 203 according to the mask process. When scanning in the X direction, the edge portion is first recorded by the recording head 202 and then recorded by the recording head 201. When scanning in the −X direction, recording is performed by the recording head 202 and then recording by the recording head 203. By assigning the recording heads according to the scanning direction, the high penetration Bk ink can be applied after the low penetration Bk ink is applied without fail even if the scanning direction changes. On the other hand, the non-edge portion data 2103 is distributed to one of the two recording heads 201 and 203 according to the mask process. When scanning in the X direction, the non-edge portion is recorded by the recording head 201 after being recorded by the recording head 203. On the other hand, when scanning in the −X direction, recording is performed with the recording head 201 and then recording with the recording head 203.

  FIG. 8 is a diagram for explaining the mask processing according to the present embodiment. In the mask process, a mask (a) and a mask (b) having the same size as the nozzle (discharge port) rows of the recording heads 201 to 203 are used. That is, by using the masks (a) and (b), the print data can be distributed to two print heads, thereby reducing the scanning resolution of one print head. Note that these masks turn OFF (do not output) the recording data corresponding to the black areas. The masks (a) and (b) of this embodiment have a pattern that has a complementary relationship of zigzag and reverse zigzag, but the above pattern can be used as long as it can realize the scanning resolution described below. It is not limited.

  FIGS. 9A to 9L are diagrams showing the distribution process of the present embodiment in the form of data. Note that the broken line shown in the horizontal direction in the center of these drawings indicates the position where the scanning direction of the recording head changes as in the case of FIG.

  By performing edge detection processing 2001 on the image data shown in FIG. 9A, non-edge data 2103 shown in FIG. 9F and edge data 2003 shown in FIG. 9B are generated. .

  The non-edge portion data 2103 in FIG. 9F includes the print head 203 data shown in FIG. 9I and the mask (b) thinned out by the mask (a) in the upper portion where the scanning direction is the X direction. ) Are distributed to the recording head 201 data shown in FIG. On the other hand, in the upper part where the scanning direction is the −X direction, the data for the recording head 203 shown in FIG. 9I thinned out by the mask (b) and the data thinned out by the mask (a) in FIG. It is distributed to the data for the recording head 201 shown in g).

  The edge portion data 2003 shown in FIG. 9B includes the print head 202 data shown in FIG. 9D and the mask (b) thinned out by the mask (a) in the upper portion where the scanning direction is the X direction. ) Is distributed to the recording head 201 data shown in FIG. In the lower part where the scanning direction is the -X direction, the data for the print head 202 shown in FIG. 9D thinned out by the mask (a) and the data thinned out by the mask (b) are shown in FIG. 9E. To the recording head 203 data shown in FIG.

  The recording data for each recording head is as follows by the recording data distribution of the edge portion and the non-edge portion.

  Data to be recorded by the recording head 201 that ejects highly penetrating ink is logical sum data (FIG. 9 (j)) of edge portion data (FIG. 9 (c)) and non-edge portion data (FIG. 9 (g)). It is. Data to be recorded by the recording head 202 is logical sum data (FIG. 9 (k)) of edge portion data (FIG. 9 (d)) and non-edge portion data (FIG. 9 (h)). Further, data to be recorded by the recording head 203 is logical sum data (FIG. 9 (l)) of edge portion data (FIG. 9 (e)) and non-edge portion data (FIG. 9 (i)).

  As can be seen from FIG. 9, according to the present embodiment, the data recorded by each of the recording heads 201 to 203 is thinned out in the main scanning direction (the X direction in FIG. 1 and the horizontal direction in FIG. 9). In each scan, half of the recording data resolution may be recorded. Thereby, the scanning speed of the recording head can be doubled without increasing (changing) the driving frequency of the recording head. For example, when the scanning resolution is 1200 dpi, in a system where the scanning speed is 25 ips, the scanning resolution can be lowered to 600 dpi, so that the scanning speed can be increased to 50 ips. As a result, the time required for the entire recording is shortened and the throughput is improved.

  In the present embodiment, ejection is not performed from the preceding recording head (the recording head 201 in the −X direction and the recording 203 in the X direction) to the outer peripheral area (edge portion), but it may be performed. However, although the optical density is improved, feathering may occur slightly. Whether ink is applied from the preceding recording head may be adjusted for each product or recording medium. In any case, by using the high-penetration Bk ink and the low-penetration Bk ink in combination, the scratch resistance and marker resistance of the edge portion can be improved.

(Embodiment 3)
The third embodiment of the present invention relates to another method of thinning processing. That is, according to the present embodiment, the odd-numbered column data and the even-numbered column data are distributed to the two recording heads in accordance with the column position of the recording data. When this method is used, when the number of pixels in the edge portion is one pixel, it is difficult to mix and record the high penetration Bk ink and the low penetration Bk ink. .

  FIGS. 10A to 10L are diagrams illustrating the distribution process of the present embodiment in the form of data, and FIG. 11 is a block diagram illustrating the procedure of the recording data distribution process of the present embodiment.

  Edge processing is performed on the binary K data 1010K. First, edge portion detection processing 2001 is performed. Of the binary K data, edge portion data, that is, edge portion data 2003 is generated. Of the binary K data, data that does not correspond to the edge portion data is referred to as non-edge portion data 2103. In the present embodiment, two pixels are selected as edge pixels.

  The non-edge portion data 2103 is distributed to the two recording heads according to the column position of the data. The odd column data is allocated to the recording head 203 and the even column data is allocated to the recording head 201. The edge portion data 2003 is distributed to the three recording heads according to the scanning direction of the recording heads 201 to 206 as well as the column position of the data. When the scanning direction is the X direction, odd-numbered column data is data to be recorded by the head 202, and even-numbered column data is data to be recorded by the recording head 201. When the scanning direction is the −X direction, odd-numbered column data is recorded by the recording head 203, and even-numbered column data is recorded by the recording head 202.

  By performing non-edge portion detection processing 2001 on the recording data shown in FIG. 10A, non-edge portion data 2103 shown in FIG. 10F and edge portion data 2003 shown in FIG. Generate.

  The non-edge portion data 2103 in FIG. 10 (f) includes data for the recording head 203 that records the odd-numbered column data shown in FIG. 10 (i) and the even-numbered column shown in FIG. 10 (g) according to the column position. Are allocated to the data for the recording head 201 for recording the data. On the other hand, the edge portion data 2103 in FIG. 10B is, in the upper part in the scanning direction X, recording head 202 data for recording odd column data and recording for even column data shown in FIG. The data is distributed to the data for the head 201. In the lower part of the scanning direction -X, the print head 203 data corresponding to odd column data and the print head 202 data corresponding to even column data are sorted.

  The recording data for each recording head is as follows by the recording data distribution of the edge portion and the non-edge portion.

  Data to be recorded by the recording head 201 is logical sum data (FIG. 10 (j)) of edge portion data (FIG. 10 (c)) and non-edge portion data (FIG. 10 (g)). Data to be recorded by the recording head 202 is logical sum data (FIG. 10 (k)) of edge portion data (FIG. 10 (d)) and non-edge portion data (FIG. 10 (h)). Further, the data to be recorded by the recording head 203 is logical sum data (FIG. 10 (l)) of edge portion data (FIG. 10 (e)) and non-edge portion data (FIG. 10 (i)).

  As can be seen from FIG. 10, the data recorded by each of the recording heads 201 to 203 is thinned out in the main scanning direction (the X direction in FIG. 1, the horizontal direction in FIG. 10). Similarly, the scanning speed can be doubled. Thereby, the time required for the entire recording is shortened, and the throughput can be improved.

(Embodiment 4)
In the fourth embodiment of the present invention, four pixels are selected as edge pixels in the configuration of the second embodiment described above.

  FIGS. 12A to 12L are diagrams showing recording data distribution processing according to the fourth embodiment in the form of data. As can be seen from the comparison with FIGS. 9A to 9L according to the second embodiment, the present embodiment relates to the distribution of recording data having a higher resolution. If the recorded data has a high resolution, it is desirable to increase the number of edge pixels accordingly. This is because it depends on the ejection amount of the recording head which is set approximately depending on the resolution. For example, in a configuration in which an image of 600 dpi × 600 dpi is recorded, the ink discharge amount of the recording head is generally set to about 15 to 30 pl. In this case, the dot diameter of plain paper is about 60 μm. In contrast, when an image is recorded at a higher resolution of 1200 dpi × 1200 dpi, the ink discharge amount is set to about 4 to 15 pl. In this case, the dot diameter of plain paper is about 30 μm. In this situation, it is not desirable for the ink in the inner region to protrude beyond the outer peripheral region, so it is desirable to keep the width of the outer peripheral region at the same level even if the resolution is different. From this point, in the example of 600 dpi × 600 dpi and 1200 dpi × 1200 dpi in the above example, the number of edge pixels in the image having a resolution of 1200 dpi × 1200 dpi is set to double that in the case of the resolution of 600 dpi × 600 dpi. Thereby, the width | variety of an outer peripheral area | region can be maintained about the same. Further, the number of edge pixels (the width of the outer peripheral region) can be set according to the difference in ink permeability, and is not limited to the number of pixels described above.

(Embodiment 5)
The fifth embodiment of the present invention relates to a form in which Bk ink uses two recording heads that eject high penetration ink and low penetration ink, and completes printing of the same printing area by two scans. Compared with the second embodiment and the like, this embodiment can reduce the cost of the recording apparatus because the throughput is reduced but the number of recording heads is small.

  FIGS. 13A to 13C are diagrams illustrating the ink application (discharge) order and application region according to the fifth embodiment.

  FIG. 13A shows two recording heads 301 and 302 for Bk ink among the recording heads 301 to 305 for C, M, Y ink, and Bk ink. The nozzle arrays of the recording heads 301 and 302 are divided into upper and lower parts, and the upper half of the recording head 301 is 301b, the lower half is 301a, the upper half of the recording head 302 is 302b, and the lower half is 302a. FIG. 13B shows the ink application sequence in the X-direction scan. On the other hand, FIG. 13C shows an ink application sequence in the scanning in the −X direction. Further, the ink ejected from the recording head 301 is a high penetration Bk ink, and the ink ejected from the recording head 302 is a low penetration Bk ink.

  FIG. 14 is a diagram for explaining 2-pass multi-pass printing according to the present embodiment. In the case of two-pass bidirectional recording, every time scanning of the recording head is completed, the recording medium is conveyed in the direction of the arrow in the figure by a distance that is half the width that the recording head can record. After recording the area (1) by scanning the recording head in the X direction, the relative positional relationship between the recording medium and the recording head is changed by the conveyance of the recording medium in the direction of the arrow. The areas (1) and (2) can be recorded by scanning. Similarly, by interposing the conveyance of the recording medium, the recording head can be scanned in the X direction to record the areas (2) and (3). This is repeated and the entire image data is recorded on the recording medium. Here, focusing on the area (1), recording by the recording head scanned in the −X direction is performed following recording by the recording head scanned in the X direction. On the other hand, when focusing on the area (2), recording by the recording head scanned in the X direction is performed following recording by the recording head scanned in the -X direction. In this way, the scanning direction of the recording head when recording a certain portion first differs depending on the region. When the scanning direction of the recording head at the time of first recording is the X direction as in the areas (1) and (3), it is expressed in this specification as “the scanning start direction is the X direction”. Also, as in the areas (2) and (4), when the scanning direction of the recording head at the first recording is the X direction, in this specification, “the scanning start direction is the −X direction”. Express.

  FIG. 15 is a block diagram showing the procedure of the recording data distribution process of this embodiment. First, edge portion detection processing 3001 is performed. Of the binary K data, edge portion data, that is, edge portion data 3003 is generated. Of the binary K data, data that does not correspond to the edge portion data is referred to as non-edge portion data 3103. In the present embodiment, two pixels are selected as edge pixels.

  The difference from the second embodiment described above is that the recording head that distributes the recording data is changed according to the scanning start direction of the recording head.

  In the non-edge portion data 3103, when the recording head scanning start direction is the X direction, the data thinned out by the mask (a) is recorded by the recording head 301b, and the data thinned out by the mask (b) is recorded by the recording head. Record at 301a. When the recording head scanning start direction is the -X direction, the data thinned out by the mask (a) is recorded by the recording head 301a, and the data thinned out by the mask (b) is recorded by the recording head 301b. On the other hand, in the edge portion data 3003, when the recording head scanning start direction is the X direction, the data thinned by the mask (a) is recorded by the recording head 302a, and the data thinned by the mask (b) is recorded. Recording is performed with the head 301a. When the recording head scanning start direction is the -X direction, the data thinned out by the mask (a) is recorded by the recording head 302b, and the data thinned out by the mask (b) is recorded by 301b.

  FIGS. 16A to 16O are diagrams showing the distribution process of the present embodiment in the form of data. In these drawings, a broken line shown in the horizontal direction of the center indicates a position where the scanning start direction of the recording head changes. The area above the broken line is the recording head scanning start direction X (rightward in FIG. 16) as in the areas (1) and (3) shown in FIG. 14, and the area below the broken line is the area shown in FIG. The recording head scanning start direction as in 2) and (4) is -X (left direction in FIG. 16).

  By performing the edge detection process 2001 on the recording data shown in FIG. 16A, non-edge data 3103 shown in FIG. 16G and edge data 3003 shown in FIG. 16B are generated. To do.

  In the edge portion data 3003 in FIG. 16B, the data thinned out by the mask (a) is the data to be recorded by the recording head 302a (FIG. 16) in the region where the recording head scanning start direction is the X direction (above the broken line). (C)). Further, the data thinned out by the mask (b) is used as data to be recorded by the recording head 301a (FIG. 16 (d)). On the other hand, in the region where the recording head scanning start direction is in the −X direction (below the broken line), the data thinned out by the mask (a) is used as data to be recorded by the recording head 302b (FIG. 16 (e)). The data thinned out in b) is data to be recorded by the recording head 301b as shown in FIG. 16 (f).

  In the non-edge portion data 3103 in FIG. 16G, the data thinned out by the mask (a) is the data to be recorded by the recording head 301b in the region where the recording head scanning start direction is the X direction (above the broken line) (FIG. 16). 16 (k)), and the data thinned out by the mask (b) is data to be recorded by the recording head 301a (FIG. 16 (i)). On the other hand, in the region where the recording head scanning start direction is in the −X direction (below the broken line), the data thinned out by the mask (a) is used as data to be recorded by the recording head 301a (FIG. 16 (i)). The data thinned out in b) is the data to be recorded by the recording head 301b (FIG. 16 (k)).

  The recording data for each recording head is as follows by the recording data distribution of the edge portion and the non-edge portion.

  Data to be recorded by the recording head 301a is logical sum data (FIG. 16 (m)) of the data shown in FIG. 16 (d) and the data shown in FIG. 16 (i). Data to be recorded by the recording head 302a is logical sum data (FIG. 16 (l)) of the data shown in FIG. 16 (c) and the data shown in FIG. 16 (h). Data to be recorded by the recording head 301b is logical sum data (FIG. 16 (o)) of the data shown in FIG. 16 (f) and the data shown in FIG. 16 (k). Further, the data to be recorded by the recording head 302b is OR data (FIG. 16 (n)) of the data shown in FIG. 16 (e) and the data shown in FIG. 16 (j).

  As can be seen from FIG. 16, the data recorded by each of the recording heads 301 to 302 is thinned out in the main scanning direction (the X direction in FIG. 1 and the horizontal direction in FIG. 16). Just record it. Thereby, the scanning speed of the recording head can be doubled, the time required for the entire recording is shortened, and the throughput is slightly improved.

  17A and 17B show the ink application sequence based on the data distribution described above with reference to FIGS. 15 and 16, and the arrangement of the recording head shown in FIG. 13A and the recording shown in FIG. It is a figure explaining using the scanning order of the recording head with respect to a medium. In FIGS. 17A and 17B, the edge and non-edge data are not masked so that the ink application sequence can be easily understood. In FIGS. 17A and 17B, the scanning start direction is the X direction in the regions (1) and (3), and the −X direction in the region (2).

  Regardless of whether the scanning direction is the X direction or the -X direction, recording is performed on all non-edge portions using the recording heads 301b and 301a. By recording with the recording head 301b and the recording head 301a, the data can be complemented although the scanning resolution is lower than that in the second embodiment.

  When the scanning start direction is the X direction, the edge portion first performs recording with the recording head 302a when scanning in the X direction, and subsequently performs recording with the recording head 301a. When the scanning start direction is the -X direction, recording is performed with the recording head 302b and then recording is performed with the recording head 301b when scanning in the X direction. When the scanning start direction is the -X direction, recording is not performed by the recording head 302a when the recording head is scanned in the -X direction. This is because the recording head 301a passes before recording with the recording 302a. Since the high-penetration Bk ink cannot be recorded after the low-penetration Bk ink, the sharpness may be lowered. It is.

(Embodiment 6)
In the above first to fifth embodiments, the case where the Bk ink corresponds to the high penetration ink and the low penetration ink has been described, but it is needless to say that the application of the present invention is not limited to this form. For example, when color images are adjacent to each other, recording as a non-edge portion is performed without performing edge portion detection processing.

  FIGS. 18A to 18L are diagrams showing the sorting process in this case in the form of data. In the recording data shown in FIG. 18A, the hatched portion is color image recording data, and the blacked portion is binary K data as in FIG. 9A. 18F shows the non-edge portion data 2103, and FIG. 18B shows the edge portion data 2003. Compared with the form shown in FIG. 9, since the colors are adjacent to each other, the right end that is considered to be an edge with Bk alone is generated as non-edge data.

  As is apparent from each of the embodiments described above, the present invention provides a recording head that discharges a highly penetrating first ink, the same hue as the first ink, and the penetrability to the recording medium from the first ink. Recording is performed using a recording head that discharges a low-penetration second ink with a low density. At that time, in the recording area, the outer peripheral area in contact with the non-recording area where recording is not performed is recorded with the first ink and the second ink, and the inner area is recorded with the first ink. The discharge of the first and second inks from the recording head is controlled. In one embodiment, the outer peripheral region is a first nozzle row that discharges the first ink, or a third nozzle row that discharges the first ink, which is different from the nozzle row, and the second Recording is performed using the second nozzle row that discharges the ink. Further, by arranging the first recording head, the second recording head, and the third recording head in this order in the scanning direction of the recording head, when recording is performed by reciprocating scanning of the recording head, the edge in the scanning in any direction The recording can be performed in the order of low penetrating ink and high penetrating ink. In addition, by arranging the recording head of the low penetrating ink and the recording head of the high penetrating ink in the nozzle arrangement direction (sub scanning direction), the recording is performed in the order of the low penetrating ink and the high penetrating ink on the edge portion. You can also Furthermore, in one embodiment, the first ink has a lower surface tension than the second ink, and the first ink has a higher proportion of the color material amount than the second ink.

201 to 206 Recording head 301 Recording control unit 407 Binary KCMY data 408 Edge processing unit

Claims (9)

Recording comprising a nozzle row for ejecting a first ink and a nozzle row for ejecting a second ink having the same color as the first ink and having a lower permeability to the recording medium than the first ink. An inkjet recording apparatus that performs recording by scanning a head with respect to a recording medium,
Of the recording area recorded by the recording head, an outer peripheral area in contact with a non-recording area where recording is not performed is recorded with the first ink and the second ink, and in the recording area, the outer peripheral area is in contact Inkjet comprising recording control means for controlling ejection of the first and second inks from the recording head so as to record the inner region with the first ink without using the second ink Recording device.   2. The inkjet recording according to claim 1, wherein the first ink has a lower surface tension than the second ink, and the first ink has a higher color material amount ratio than the second ink. apparatus.   The recording control means includes a first nozzle row for discharging the first ink or a third nozzle row for discharging the first ink, and a second nozzle for discharging the second ink. The ink jet recording apparatus according to claim 1, wherein the recording is performed using a nozzle row of the ink jet recording apparatus.   The inkjet recording apparatus according to claim 3, wherein the recording control unit records the internal region using the first nozzle row and the third nozzle row.   The inkjet recording apparatus according to claim 1, wherein the first ink and the second ink are black ink.   6. The ink jet recording apparatus according to claim 1, wherein the color material of the first ink and the second ink is a pigment.   The ink jet according to any one of claims 1 to 6, wherein the surface tension of the first ink is 20 to 40 mN / m, and the surface tension of the second ink is 40 to 60 mN / m. Recording device. The ratio (% by weight) of the color material amount of the first ink and the second ink is:
Color material amount of the first ink ≧ 3
Color material amount of the second ink ≦ 2
The ink jet recording apparatus according to claim 1, wherein the ink jet recording apparatus is an ink jet recording apparatus. A recording medium comprising: a nozzle array that ejects a first ink; and a nozzle array that ejects a second ink that has the same color as the first ink and has a lower permeability to the recording medium than the first ink. An ink jet recording method for performing recording by scanning with respect to
Out of the recording area recorded by the recording head, an outer peripheral area in contact with a non-recording area where recording is not performed is recorded with the first ink and the second ink, and out of the recording area, in contact with the outer peripheral area. And a recording control step for controlling ejection of the first and second inks from the recording head so that the inner region is recorded with the first ink without using the second ink. Inkjet recording method.

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