1. Field of the Invention
The present invention relates to an ink jet print head that ejects ink droplets to print a print medium, and in particular, to an ink jet print head having a plurality of types of nozzles arranged on the same substrate and through which ink droplets of different sizes are ejected.
2. Description of the Related Art
With the increased operating speed of ink jet printing apparatuses and improved image quality provided by the ink jet printing apparatuses, attempts have been made to reduce the size of droplets ejected by print heads while increasing ejection frequency.
A reduction in the size of ejected droplets requires a reduction in the opening area of each ejection port in the print head. However, the reduced opening area of the ejection port may increase the flow resistance to a liquid in a portion (ejection port portion) that communicates with the ejection port, preventing desired ejection performance and efficiency from being achieved. Thus, ink jet print heads disclosed in Japanese Patent Laid-Open Nos. 2004-042651 and 2004-042652 serve to reduce the flow resistance of the ejection port portion while maintaining the strength of an ejection port forming portion.
Each of the print heads disclosed in Japanese Patent Laid-Open Nos. 2004-042651 and 2004-042652 has a plurality of nozzles through which ink flows. Each of the nozzles has a bubbling chamber 38 that boils ink to generate bubbles and an ejection port portion 36 including an ejection port 37 that is a tip opening of the nozzle through which ink droplets are ejected, as shown in
In the ink jet print head 30 configured as described above, the thickness of the first ejection port portion 36a ensures the strength of a peripheral portion of the ejection port 37. Furthermore, the enlarged space of the second ejection port 36b enables a reduction in the flow resistance of the whole ejection port portion. Thus, even if the nozzle is provided with an ejection port having a small diameter and through which small droplets are ejected, a possible pressure loss in the ejection port portion 36 can be reduced. Furthermore, bubbles can be grown in an ejection direction. As a result, ink droplets can be efficiently ejected.
Such a reduction in the size of ejected droplets enables a reduction in the size of dots constituting an image and in the sense of granularity conveyed by the image. Thus, the droplet size reduction significantly contributes to improving image quality. However, the droplet size reduction has also been found to be disadvantageous in terms of costs, print speed, thermal efficiency, and the like. That is, when the entire area of the image is formed of small dots in order to reduce the sense of granularity, the number of data in the image increases sharply. This tends to increase the scales of drivers and circuits and thus costs. Furthermore, an increase in nozzle length or chip count for high-speed printing also increases the costs. Moreover, to use small dots to achieve a print speed equivalent to that at which an image is formed using large dots, a nozzle driving frequency needs to be increased compared to that required for printing using the large dots. That is, the number of dots formed per unit time needs to be increased. Thus, the thermal efficiency of a printing operation tends to decrease.
Thus, to solve these problems, a technique has been proposed which provides a plurality of types of nozzles through which ink droplets of different sizes are ejected, on the same head substrate so that one of the plural types of nozzles is selected for use depending on the density of the image. For example, a printing method has been proposed which forms small dots using small ink droplets for a low density portion and an intermediate density portion of the image, while forming large dots using large ink droplets for the intermediate density portion and a high density portion of the image. In this case, if two types of droplet sizes, that is, large and small droplet sizes, are available and the ratio of the large dot to the small dot is about 2 to 4:1, a clear image can be printed by connecting the large and small dots together from the low density portion to the high density portion according to the resolution of the image. Thus, one of the dot sizes is selected for formation depending on the density of the image to be printed. This enables the image to be quickly and efficiently formed, allowing the thermal efficiency of the printing operation to be improved.
However, for the conventional print head, which has the plural types of nozzles of different sizes, each having the ejection port portion composed of the first ejection port portion and the second ejection port portion as described above, ejection characteristics may disadvantageously be unbalanced among the nozzles.
This is because in the conventional print head, the ratio of the opening area of the ejection port to the opening area of the opening of the second ejection port portion is fixed regardless of the size of the ejection port. That is, the nozzle through which smaller ink droplets are ejected suffers a more significant variation in the rate of a pressure loss during ejection in connection with a manufacturing error (misalignment at the boundary portion between the first ejection port portion 36a and the second ejection port portion 36b) in the ejection port portion. This is likely to affect ejection performance such as the amount of ink droplets and landing accuracy. Thus, a possible manufacturing error as described above unbalances the ejection performance between the nozzle with the large ejection port and the nozzle with the small ejection port. This may in turn degrade the quality of images formed using a combination of the large and small dots.
Furthermore, the current ink jet printing apparatus has a suction recovery mechanism that forcibly sucks and discharges thickened ink in the nozzle and bubbles mixed into the ink, through the ejection port to recover the ejection performance of the nozzle. However, a possible manufacturing variation as described above sharply increases the flow resistance to the ink in the small ejection port portion, through which small ink droplets are ejected. Consequently, the suction recovery capability may be degraded, that is, old ink in the nozzle cannot be sufficiently discharged. Namely, for the conventional print head, the nozzle through which smaller ink droplets are ejected is more likely to suffer degradation of the suction recovery capability. This may also unbalance the ejection performance among the various nozzles, degrading the image quality.
An object of the present invention is to provide an ink jet print head having a plurality of types of nozzles arranged on the same substrate and through which ink droplets of different sizes are ejected, the ink jet print head exhibiting acceptable ejection performance regardless of the type of nozzle to enable high-quality images to be efficiently and quickly printed.
The present invention provides an ink jet print head having a plurality of types of nozzles arranged on the same substrate and through which ink droplets of different sizes are ejected. Each of the nozzles comprises a bubbling chamber having an ejection energy generating element allowing an ink droplet to be ejected to a position located opposite an ejection port and an ejection port portion allowing the ejection port and the bubbling chamber to communicate with each other, and the ratio of an opening area of the ejection port portion at a position where the ejection port portion and the bubbling chamber communicate with each other, to the opening area of the ejection port is higher for the nozzle with a smaller ejection amount.
According to the present invention, among the plurality of types of nozzles through which ink droplets of different sizes are ejected, even the nozzle through which small sized ink droplets are ejected can avoid being seriously affected by a manufacturing error in the ejection port portion. Therefore, the balance of the landing performance among the plural types of nozzles can be improved.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
Embodiments of the present invention will be described below in detail with reference to the drawings.
First, a first embodiment of the present invention will be described with reference to
As shown in
A plurality of ejection port portions 6, a plurality of bubbling chambers 9, and a plurality of ink supply channels 10 are formed in the channel constituting substrate 3; the plurality of ejection port portions 6 are provided opposite the respective electrothermal conversion elements 4 in each of the print element arrays H1, H2, and H3, the plurality of bubbling chambers 9 communicate with the respective ejection port portions 6, and the plurality of ink supply channels 10 communicate with the bubbling chambers 9. Each of the ejection port portions 6 has ejection ports 71, 72, and 73 each having an end that is open in one surface of the channel constituting substrate 3. The ejection ports 71, 72, and 73 are formed opposite the electrothermal conversion elements 4. Thus, the three ejection port arrays E1, E2, and E3 are formed on the element substrate 3. Of the three ejection port arrays E1, E2, and E3, the ejection port array E1 is hereinafter referred to as a first ejection port array, the ejection port array E2 is hereinafter referred to as a second ejection port array, and the ejection port array E3 is hereinafter referred to as a third ejection port array. A portion composed of the ejection port portion 6, the bubbling chamber 9, and the ink supply channel 10 is hereinafter referred to as a nozzle. The term “ink” as used herein is not limited to a predetermined coloring agent attached to a print medium to form an image but includes, for example, a transparent process liquid ejected from the print head before or after image formation in order to improve the coloring capability, weatherability, and the like of the image formed on the print medium.
In the print head with the plurality of nozzles formed therein as described above, an ink tank (not shown) is connected to the ink supply port 5 so that the ink in the ink tank is filled into the bubbling chamber 8 and the ejection port portion 6 via the ink supply channel 10 through the ink supply port 5. Here, when energized, the electrothermal conversion element 4 generates heat to instantly boil the ink in the bubbling chamber 8. This rapid change of the ink from a liquid phase to a vapor phase rapidly increases the pressure in the bubbling chamber 8 to allow ink droplets to be ejected through the ejection ports 71, 72, and 73 at a high speed. Thus, the ink jet print head 1 according to the present embodiment is of what is called a side shooter type in which the ink is ejected through the ejection ports 71, 72, and 73, formed parallel to the element substrate.
In the present embodiment, the large ejection ports 71, constituting the first ejection port array E1, are arranged at intervals of 600 dpi. Similarly, the medium ejection ports 72 in the second ejection port array E2 and the small ejection port array 73 are arranged at intervals of 1,200 dpi. However, each of the ejection ports (medium ejection ports) 72 in the second ejection port array E2 is displaced from the corresponding one of the ejection ports (small ejection ports) in the third ejection port array E3 by a distance corresponding to 1,200 dpi. That is, the distance between the medium ejection port 72 and the small ejection port 73 adjacent to each other in an ejection port arrangement direction are arranged corresponds to 1,200 dpi. The ratio of the liquid volumes of ink droplets ejected through the large, medium, and small ejection ports 71, 72, and 73 is determined by the pitch of the ejection ports and an area factor during image formation. Desirably, the ratio of the liquid volume of large ink droplets to the liquid volume of medium ink droplets and the ratio of the liquid volume of medium ink droplets to the liquid volume of small ink droplets are each about 2 to 4.
In
In
Each of the first ejection port portion 61a and the second ejection port portion 61b forms a cylindrical space centered on the center axis. The opening area S1a of the large ejection port 71, formed at the first end of the first ejection port portion 61a, is larger than that S1b of an opening 81 formed at the second end of the second ejection port portion 61b. Thus, a step portion 31 is formed on an inner surface of the ejection port portion 61 at the boundary portion between the first ejection port portion 61a and the second ejection port portion 61b. That is, in the present embodiment, the inner surface of the ejection port 61 is formed like a step.
The first ejection port portion 61 has been described. Similarly, in the second ejection port portion 62, a first ejection port portion 62a and a second port portion 62b forming a cylindrical space are formed, and in the third ejection port portion 63, a first ejection port portion 63a and a second port portion 63b forming a cylindrical space are formed. In each case, the step portion 31 is formed at the coupling portion between the first ejection port portion and the second ejection port portion.
In the present embodiment, the liquid volume (first liquid volume) Va of large ink droplets is 2.8 ng, the liquid volume (second liquid volume) Vb of medium ink droplets is 1.4 ng, and the liquid volume (third liquid volume) Vc of small ink droplets is 0.7 ng. The opening areas S1a, S2a, and S1a of the first, second, and third ejection ports 71, 72, and 73 are about 120 um2, about 60 um2, and about 30 um2, respectively. Moreover, the ratio of the opening area S1b of the opening 81 of the second ejection port portion to the opening area of the ejection port 71 is S1b/S1a=2.5. The ratio of the opening area S2b of the opening 82 of the second ejection port portion to the opening area of the ejection port 72 is S2b/S2a=3.6. The ratio of the opening area S1b of the opening 83 of the second ejection port portion to the opening area of the ejection port 73 is S3b/S3a=6.3. That is, the magnitude correlation between the ratios of the opening areas of the second ejection port portions to the opening areas of the ejection ports are as follows:
S1b/S1a<S2b/S2a<S3b/S3a (Formula 1)
The widths of the bubbling chambers 91, 92, and 93, communicating with the ejection port portions 71, 72, and 73, are denoted by S1c, S2c, and S3c. The relationship between S1c and S2c and S3c is S1c>S2c>S3c. However, the bubbling chambers 91, 92, and 93 have the same height.
Thus, in the present embodiment, the ratio of the opening area of the second ejection port portion to the opening area of the ejection port is higher for the ejection port portion having the ejection port with the smaller opening area. This is because if the ratio of the opening area of the second ejection port portion to the opening area of the ejection port is the same for the ejection port portion through which the large ink droplets are ejected and for the ejection port portion through which the small ink droplets are ejected, only the landing accuracy of the small ink droplets may decrease. That is, the small ink droplets ejected through the ejection port with the smaller opening area are more likely to be affected by air resistance or the flow resistance to the ink resulting from an alignment error during manufacture. Thus, for the ejection port portion having the ejection port with the smaller opening area, the ratio of the opening area of the second ejection port portion to the opening area of the ejection port is increased to sharply reduce the possible flow resistance in the ejection port portion. This enables a further reduction in the loss of the pressure on the ink during ejection and also allows old ink in the nozzles to be positively ejected through the large, medium, and small ejection ports during the suction recovery operation. This in turn enables prevention of inappropriate ejection from the nozzles and degradation of the ejection performance. Thus, for the nozzles through which the medium and small ink droplets are ejected, appropriate ink droplet ejection characteristics can be maintained with the adverse effects of alignment errors inhibited. This enables a drastic reduction of variation in ink droplet landing accuracy among the various nozzles. Therefore, the present embodiment allows high-quality images to be quickly and efficiently printed by combining the large, medium, and small droplets together. The present embodiment also forms the first and second ejection port portions to enable the thickness of the whole ejection port portion to be kept at a value required to maintain the appropriate physical strength of the ejection port portion.
Now, a second embodiment of the present invention will be described.
In the second embodiment, the ejection port arrays are arranged at intervals of 600 dpi. For the large ejection ports 71 constituting the first ejection port array E1 and the medium ejection ports 72 constituting the second ejection port array E2, the distance between the large ejection port 71 and medium ejection port 72 adjacent to each other in the ejection port arrangement direction is 1,200 dpi. Moreover, for the large ejection ports 71 constituting the third ejection port array E3 and small ejection ports 73 constituting the fourth ejection port array E4, the distance between the large ejection port 71 and small ejection port 73 adjacent to each other in the ejection port arrangement direction is also 1,200 dpi.
In the second embodiment, the liquid volumes of the large, medium, and small ink droplets are similar to those in the first embodiment. The opening areas of the first, second and third ejection ports 71, 72, and 73 are also similar to those in the first embodiment. Consequently, the ratios of the opening area of the second ejection port portion to the opening area of the ejection port, that is, S1b/S1a, S2b/S2a, and S3b/S3a, are 2.5, 3.6, and 6.3, respectively. That is, the magnitude correlation between the ratios of the opening area of the second ejection port portion to the opening area of the first ejection port portion is as follows:
S1b/S1a<S2b/S2a<S3b/S3a (Formula 1)
That is, the ratio of the opening area of the second ejection port portion to the opening area of the ejection port increases with decreasing opening area of the ejection port. Thus, the nozzle through which the small ink droplets are ejected is unlikely to be affected by alignment errors and air resistance. Acceptable ink droplet ejection characteristics can thus be maintained. This enables a drastic reduction in variation in ink droplet landing accuracy among the various nozzles. Therefore, high-quality images can be quickly and efficiently printed by combining the large, medium, and small droplets together.
A third embodiment of the present invention will be described.
In the second embodiment, all the ejection port portions are cylindrical. However, the ejection port portions need not necessarily be cylindrical but may have another shape. In the third embodiment, each of the ejection port portions is formed to have an elliptic cross-section.
Also in the third embodiment, the liquid volumes Va, Vb, and Vc of large, medium, and small ink droplets are 2.8 ng, 1.4 ng, and 0.7 ng, respectively. The sectional areas S1a, S2a, and S1a of the ejection ports are about 120 nm2, 60 um2, and 30 um2. The ratios of the opening area of the second ejection port portion to the opening area of the ejection port, that is, S1b/S1a, S2b/S2a, and S3b/S3a, are 3.1, 3.6, and 6.3, respectively.
Consequently, the magnitude correlation between the ratios of the opening area of the second ejection port portion to the opening area of the first ejection port portion is as follows:
S1b/S1a<S2b/S2a<S3b/S3a (Formula 1)
Thus, the third embodiment also enables a drastic reduction in variation in ink droplet landing accuracy among the various nozzles. Therefore, high-quality images can be quickly and efficiently printed by combining the large, medium, and small droplets together.
In the first to third embodiments, the values of the liquid volumes of ink droplets for the large, medium, and small dots, the opening areas of the ejection ports, and the like can be appropriately varied as long as the relationship in (Formula 1) is met.
For example, the liquid volumes Va, Vb, and Vc of large, medium, and small droplets can be set to 5 ng, 2 ng, and 0.7 ng, respectively, and the opening areas S1a, S2a, and S1a of the large, medium, and small ejection ports 71, 72, and 73 can be set to 200 um2, 80 um2, and 30 um2, respectively. In this case, the ratios of the opening area of the second ejection port portion to the opening area of the first ejection port portion in each of the ejection port portions in each ejection port array, that is, S1b/S1a, S2b/S2a, and S3b/S3a, are set to 1.7, 2.9, and 6.25, respectively. This also meets the relationship in (Formula 1). The present embodiment is thus expected to exert effects similar to those of the first to third embodiments.
The liquid volumes Va, Vb, and Vc of large, medium, and small ink droplets may be set to 2 ng, 1 ng, and 0.5 ng, respectively, and the ratios of the opening area of the second ejection port portion to the opening area of the first ejection port portion in each of the ejection port portions, that is, S1b/S1a, S2b/S2a, and S3b/S3a, may be set to 2.9 to 3.7, 4.5, and 9.1, respectively. This also meets the relationship in (Formula 1). The present embodiment is thus expected to exert effects similar to those of the first to third embodiments.
In contrast, if with the nozzles through which the ink droplets of the different sizes, that is, the large, medium, and small ink droplets, are ejected, the liquid volumes for the ejection port portions do not meet the relationship in (Formula 1), effects similar to those of the above-described embodiments are not expected to be exerted. For example, it is assumed that for example, for three types of nozzles with liquid volumes Va, Vb, and Vc of 2.8 ng, 1.4 ng, and 0.7 ng, respectively, the ratios of the opening areas of the ejection port portions, S1b/S1a, S2b/S2a, and S3b/S3a are all 2.5. In this case, with an alignment error in the ejection port portions occurring during a manufacturing process, the nozzle with a smaller ejection amount suffers a larger amount of deviation of an landing position. For example, when the second ejection port portion and the first ejection port portion are misaligned by about 1 um, the amount of deviation of the landing position of ink droplets ejected through nozzles through which ink droplets with a liquid volume Vc of 0.7 ng increases to about double that of ink droplets ejected through nozzles through which ink droplets with a liquid volume Va of 2.8 ng are ejected. In connection with the improvement of print image quality, a higher landing accuracy is required for smaller ink droplets. Thus, designing the print head such that errors such as manufacturing tolerances can be absorbed is very important.
Thus, to account for manufacturing errors to reduce the amount of deviation of the landing position, the above-described embodiment sets the ratios of the opening area of the second ejection port portion S1b to the opening area of the first ejection port portion S1a such that the ratios meet the relationship in (Formula 1) as the ejection amount for the nozzles decreases.
S1b/S1a<S2b/S2a<S3b/S3a (Formula 1)
It is assumed that the two types of nozzles with ejection amounts, one of which is about double the other, are formed in the same head substrate. In this case, when the openings of the first and second ejection port portions of one of the nozzles are defined as S1a and S1b and the openings of the first and second ejection port portions of the other nozzle are defined as S2a and S2b, then as a rule of thumb, the following relationship is preferably established.
S1b/S1a=α×S2b/S2a (α>1,2)
In the above-described embodiments, the nozzles through which the three types of ink droplets, that is, the large, medium, and small ink droplets are ejected are arranged in the print head. However, the sizes of droplets are not limited to the three types, but may be two types, large and small, or four types, large, medium, small, and very small. Furthermore, the manner of arrangement of the ejection ports is not limited to the above-described embodiments. In short, the required relationship is such that the ratio of the opening area of the second ejection port portion to the opening area of the ejection port increases with decreasing opening area of the ejection port.
In the above-described embodiments, the inner surface of the ejection port portion change in two stages, that is, changes from the first ejection port portion to the second ejection port portion. However, the ejection port portion can be formed in more stages. That is, the ejection port portion can be formed in three or more stages. However, the ejection port portions positioned in the respective stages need to be formed such that the opening area increases from the ejection port to the position where the ejection port portion and the bubbling chamber communicate with each other.
Now, a fourth embodiment of the present invention will be described with reference to
In the first to third embodiments, the first and second ejection port portions are formed, with the step portion 31 formed in the boundary portion between the first and second ejection port portions. In contrast, inner surfaces of ejection port portions 161, 162, and 163 in the fourth embodiment are each formed of a continuous surface as shown in
As shown in
More specifically, the height Ho of the ejection port portion common to the large, medium, and small ink droplets is about 20 μm to 30 μm. The height Hc of the ink supply channel is about 10 μm to 20 μm. The diameter of the ejection port portion is at least about 11 μm for the large nozzle, about 8 μm to 11 μm for the medium nozzle, and about 5 μm to 8 μm for the small nozzle.
Thus, the fourth embodiment tapers the surfaces forming the ejection port portions 162 and 163 of the nozzles through which the medium and small ink droplets are ejected. The taper angle is α. Thus, also in the present embodiment, the magnitude correlation between the ratios of the opening areas of the ejection port portion to the opening area of the ejection port is as follows.
S1b/S1a<S2b/S2a<S3b/S3a (Formula 1)
That is, the ratio of the opening areas of the ejection port portion to the opening area of the ejection port is higher for the ejection port portion having the ejection port with the smaller opening area. Thus, the flow resistance in the ejection port portion can be reduced more sharply for the ejection port portion having the ejection port with the smaller opening area. That is, even for the ejection port portion having the ejection port with the smaller opening area, the rate of the loss of the pressure on the ink during ejection can be reduced. In the fourth embodiment, the inner surfaces of the ejection port portions 71, 72, and 73 are each continuous. The present embodiment can reduce the flow resistance to the ink compared to the first to third embodiments, having the step portion on the inner surface of the ejection port portion.
Thus, the present embodiment can keep acceptable the ink droplet ejecting capability, affected by alignment errors, and the ink sucking and discharging capability based on the suction recovery operation. Consequently, the fourth embodiment enables a drastic reduction in variation in ink droplet landing accuracy among the various nozzles. Moreover, the ejection port portion through which the large ink droplets are ejected is cylindrically shaped (this shape is hereinafter also referred to as a straight shape). This enables a reduction in the sum of the volumes of the ejection port portion and the bubbling chamber with respect to the liquid volume of the ejected ink droplets. This in turn enables a reduction in variation in the amount of ejected large droplets, which may result in notable density unevenness.
As shown in
Thus, the tapered ejection port portion enables a sharp reduction in ink flow resistance without the need to change the height (thickness) of the channel constituting substrate 3 or the height of the bubbling chamber even if the small ink droplets are ejected through the ejection port portion. Consequently, the ink droplets of all the sizes can be properly ejected by tapering the ejection port portions of the nozzles through which the medium and small ink droplets are ejected, as described above. This enables high-quality images to be formed by combining the ink droplets of all the sizes together.
A fifth embodiment of the present invention will be described.
As shown in
As shown in
As described above, also in the fifth embodiment, the surfaces forming the ejection port portions 162 and 163 of the nozzles are tapered. Thus, also in the present embodiment, the magnitude correlation between the opening area S1a, S2a, S1a of the ejection port 71, 72, 73 and the opening area Sib, S2b, and S1b of the opening 81, 82, and 83 at the boundary portion between the ejection port portion 161, 162, 163 and the bubbling chamber 91, 92, 93 is as follows.
S1b/S1a<S2b/S2a=S3b/S3a
Therefore, the fifth embodiment can also properly maintain the ink droplet ejecting capability, affected by alignment errors, and the ink sucking and discharging capability based on the suction recovery operation. Consequently, the fifth embodiment enables a drastic reduction in variation in ink droplet landing accuracy among the various nozzles. Moreover, the ejection port portions 71, 72, and 73 have continuous inner surfaces without a step, enabling a reduction in the flow resistance to the ink. Furthermore, the ejection port portion through which the large ink droplets are ejected is cylindrically shaped, enabling a reduction in the ratio of the liquid volume of ejected ink droplets to the sum of the volumes of the ejection port portion and the bubbling chamber. This in turn enables a reduction in variation in the amount of ejected large droplets.
A sixth embodiment of the present invention will be described.
As shown in
Thus, the first ejection port portions 62a and 63a of the ejection port portions 62 and 63, through which the medium and small ink droplets, respectively, are ejected, are tapered. The present embodiment can reduce the flow resistance to the ink compared to the first embodiment. The sixth embodiment can thus reduce the adverse effect of a possible manufacturing variation among the ejection port portions and improve the ink discharging capability associated with the suction recovery operation. As a result, high image quality can be achieved.
The present embodiment also forms the first and second ejection port portions to ensure the required thickness of the whole ejection port portion. The sixth embodiment can thus provide the ejection port portion with a physical strength higher than that in the fourth and fifth embodiments.
A seventh embodiment of the present invention will be described with reference to
As shown in
Therefore, the seventh embodiment is provided by merging the sixth and fifth embodiments. Thus, like the sixth embodiment, the seventh embodiment can reduce the adverse effect of a manufacturing variation among the ejection port portions and improve the ink discharging capability associated with the suction recovery operation and the physical strength of the ejection port portion. In addition to exerting these effects, the seventh embodiment, like the fifth embodiment, can form high-resolution images using the small ink droplets.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2007-225812, filed Aug. 31, 2007, and No. 2008-192227, filed Jul. 25, 2008, which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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2007-225812 | Aug 2007 | JP | national |
2008-192227 | Jul 2008 | JP | national |
This is a division of U.S. patent application Ser. No. 12/195,892 filed Aug. 21, 2008.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 12195892 | Aug 2008 | US |
Child | 12752773 | US |