The present disclosure relates to a printing element substrate and a liquid ejection head.
In a liquid ejection apparatus that ejects liquid to perform printing or the like, the liquid ejected from ejection ports separates into a main droplet and a satellite droplet associated therewith or mist. The satellite droplet lands at a position deviated from a desired position, and the minuscule mist cannot reach a printing medium and can adhere to the liquid ejection head or the liquid ejection apparatus, possibly causing a decrease in print quality or breakdown of the apparatus. For that reason, generation of satellite droplets and mist may be reduced.
A liquid ejection head disclosed in Japanese Patent Laid-Open No. 2013-914 includes protrusions on the inner surface of each of ejection ports that eject liquid to increase the meniscus between the protrusions to thereby decrease tailing of the ejected droplets, thereby reducing generation of mist.
However, in the liquid ejection head disclosed in Japanese Patent Laid-Open No. 2013-914, a wiping operation of wiping liquid droplets or foreign substances adhering to the surface of an ejection-port formed member can deform or break the protrusions as the wiping member comes into contact with the protrusions.
Japanese Patent Laid-Open No. 2013-914 also discloses forming each ejection port in a recessed portion that is recessed from the surface of the ejection-port formed member. In this case, the wiping member hardly comes into contact with the protrusions, and therefore the protrusions are hard to break. However, forming an ejection port in a recessed portion makes it difficult for the wiping member to come into contact with not only the protrusions but also the outer periphery of the ejection port, therefore making it difficult to remove liquid droplets or foreign substances adhering to the vicinity of the ejection port.
The present disclosure provides a printing element substrate having protrusions for preventing generation of mist in which the protrusions are hard to break and in which liquid droplets and foreign substances adhering to the outer peripheries of ejection ports can be removed as well as a liquid ejection head including the same.
A printing element substrate according to a first aspect of the present disclosure includes a substrate, an energy generating element, and an ejection-port formed member. The energy generating element is disposed on one surface of the substrate and configured to generate energy for use in ejecting liquid. The ejection-port formed member includes ejection ports that eject the liquid. A protrusion protruding toward inside of each of the ejection ports is provided on an inner surface of the ejection port. In a surface of the ejection-port formed member remote from the substrate, a tip portion of the protrusion is positioned closer to the substrate than an outer periphery of the ejection port.
A liquid ejection head according a second aspect of the present disclosure includes the above-described printing element substrate.
Further features and aspects of the present disclosure will become apparent from the following description of various example embodiments with reference to the attached drawings.
Various example embodiments of the disclosure will be described with reference to the accompanying drawings. In the specification and the drawings, components having the same function may be denoted by the same reference signs, and redundant descriptions may be omitted.
Example Configuration of Liquid Ejection Head
The liquid ejection head 20 includes the printing element substrate 100, a head main body 21, and a connecting member 22. The printing element substrate 100 includes a substrate 1 and an ejection-port formed member 8. The ejection-port formed member 8 has a plurality of ejection ports 9. The printing element substrate 100 is mounted on the head main body 21 via the connecting member 22. The liquid ejection head 20 is mounted on a liquid ejection apparatus (not shown) and ejects liquid, such as ink, from the ejection ports 9 to perform various processes, such as printing, on a printing medium (not shown).
Example Configuration of Printing Element Substrate
A channel forming member 5 and the ejection-port formed member 8 are disposed in layers on the substrate 1. Energy generating elements 2 are disposed at positions corresponding to the plurality of ejection ports 9 disposed in the ejection-port formed member 8 on the substrate 1. The energy generating elements 2 generate energy for ejecting liquid. The channel forming member 5 includes a channel-wall member 5a that forms a channel wall and partition members 5b that each form a partition wall for separating adjacent energy generating elements 2 from each other. Between the adjacent partition members 5b, a pressure chamber 7 including the energy generating element 2 therein and channels 6 that supply liquid to the pressure chamber 7 are provided. Between the channel-wall member 5a and the partition member 5b, a common liquid chamber 3 communicating with the channels 6 is provided. A direction in which the energy generating elements 2 are arranged in line, that is, a direction in which the ejection ports 9 are arrayed, is referred to as y-direction, and an in-plane direction that is parallel to a surface of the substrate 1 and is perpendicular to the y-direction is referred to as x-direction. In this case, one channel 6 extends in the x-direction on each side of the pressure chamber 7, and the common liquid chamber 3 communicating with the channels 6 is disposed outside the channels 6 in the x-direction. The substrate 1 has supply passages 4 passing therethrough in the thickness direction. The supply passages 4 communicate with the common liquid chamber 3. In the present embodiment, the common liquid chamber 3 communicates with the two channels 6. Although not illustrated in
The ejection ports 9 are disposed at an interval of 600 dpi in the y-direction. The openings of the supply passages 4 in one surface of the substrate 1 are disposed at an interval of 300 dpi in the y-direction, that is, parallel to the ejection ports 9. The openings of the supply passages 4 are each 40 μm in length in the x-direction and the y-direction. The dimensions of the ejection ports 9 are 20.5 μm in the y-direction, and 20 μm in the x-direction. The thinner the ejection-port formed member 8, the lower the viscosity resistance that the liquid receives, so that, even if the moisture in the liquid evaporates from the ejection ports 9 to increase the viscosity of the liquid, increasing the viscosity resistance, the liquid droplets can easily be ejected. The thickness of the ejection-port formed member 8 is preferably in the range of 10 μm or less and 3 μm or more. The thickness within the range allows both of ease of ejection and the strength of the ejection-port formed member 8 to be achieved. The height of the pressure chamber 7 is preferably about 16 μm or less to enhance the coherence of the liquid droplets. In the present embodiment, the thickness of the ejection-port formed member 8 is 4.5 μm, and the height of the pressure chamber 7 from the substrate 1 to a surface of the ejection-port formed member 8 adjacent to the substrate 1 is 5.0 μm. Therefore, the distance from the surface of the substrate 1 in which the energy generating elements 2 are disposed to the surface of the ejection-port formed member 8 remote from the substrate 1 is 9.5 μm. If the pressure chamber 7 is low in height, the liquid supply speed to the pressure chamber 7 could decrease. However, the present embodiment prevents a decrease in the supply speed by supplying the liquid from both sides of the pressure chamber 7, as described above.
Example Configuration of Ejection Ports
The ejection port 9 is a through-hole passing through the ejection-port formed member 8. The ejection port 9 has protrusions 11 that protrude toward the inside of the ejection port 9. An outer periphery 12 of the ejection port 9 is a portion enclosing the opening of the ejection port 9. A surface 8a of the ejection-port formed member 8 remote from the substrate 1 is flat. Therefore, the outer periphery 12 is flush with the surface 8a of the ejection-port formed member 8. The tip portions of the protrusions 11 are positioned closer to the substrate 1 than the ejection-port formed member 8. Therefore, the tip portions of the protrusions 11 are closer to the substrate 1 than the outer periphery 12 of the ejection port 9. The base portions of the protrusions 11 in contact with the inner surface of the ejection port 9 is flush with the outer periphery 12, and the protrusions 11 are inclined to the substrate 1 from the surface 8a of the ejection-port formed member 8 with increasing distance from the base portions to the tip portions.
The protrusions 11 extend in the x-direction illustrated in
Example Method for Manufacturing Printing Element Substrate
Referring first to
Referring next to
After the cured portion 31a of the first negative photosensitive resist 31 has been formed, film of a second negative photosensitive resist 32 is formed on the first negative photosensitive resist 31, as illustrated in
To form a latent image of a channel pattern formed using the cured portion 31a of the first negative photosensitive resist 31, the exposure sensitivity of the second negative photosensitive resist 32 may be higher than the exposure sensitivity of the first negative photosensitive resist 31. For that purpose, the second negative photosensitive resist 32 may contain much more photoacid generator than the first negative photosensitive resist 31. Examples of a method for forming the film of the second negative photosensitive resist 32 include a method of solvent coating and a method of forming a dry film and transferring it onto a substrate. Between them, the film of the second negative photosensitive resist 32 may be formed using the method of forming a dry film and transferring it onto the substrate 1. This is because, if the solvent coating method is used, a solvent contained in the second negative photosensitive resist 32 can dissolve the first negative photosensitive resist 31. The film thickness of the second negative photosensitive resist 32 is not particularly limited. For example, the thickness may be 3 μm or more and 60 μm or less.
After the film of the second negative photosensitive resist 32 has been formed, film of a third negative photosensitive resist 33 is formed as a water repellent layer on the film of the second negative photosensitive resist 32, as illustrated in
Referring next to
Furthermore, as illustrated in
After the development, the channel of the liquid and the ejection ports 9 are exposed, as illustrated in
Referring next to
That is one example of a method for manufacturing the printing element substrate 100. This method allows the tip portions of the protrusions 11 to be located closer to the substrate 1 than the ejection-port formed member 8 by forming the ejection-port formed member 8 made of the layers of two or more kinds of material having different cure shrinkage characteristics and deforming the protrusions 11 using an exposure process and heat treatment.
In the above example, the ejection-port formed member 8 is formed with the second negative photosensitive resist 32 and the third negative photosensitive resist 33, but the present disclosure is not limited to this example. For example, a water-repellant solvent may be applied to the second negative photosensitive resist 32 instead of the third negative photosensitive resist 33, and the collective development in
In the printing element substrate 100, the tip portions of the protrusions 11 are positioned closer to the substrate 1 with respect to the surface 8a of the ejection-port formed member 8. This reduces the possibility that a wiping member, such as a blade, comes into contact with the protrusions 11 even if a wiping operation of wiping the surface 8a of the ejection-port formed member 8 with the wiping member is performed, reducing the possibility of breakage, such as breakage of the protrusions 11. In particular, the thickness of the ejection-port formed member 8 is as thin as 4.5 μm, and the strength of the printing element substrate 100 against an external force decreases as the thickness of the ejection-port formed member 8 decreases. For that reason, it is particularly effective to reduce the possibility that the protrusions 11 come into contact with the wiping member, thereby making the protrusions 11 hard to break. Furthermore, only the tip portions of the protrusions 11 are positioned closer to the substrate 1 than the surface 8a of the ejection-port formed member 8, and the outer peripheries 12 of the ejection ports 9 are flush with the surface 8a of the ejection-port formed member 8. This allows deposit, such as liquid droplets, adhering to the outer peripheries 12 to be removed at the wiping operation. In the field of liquid ejection apparatuses, ink that contains a lot of solid content has recently been used to form higher quality images with better coloring and stability. For example, when an ink having a solid content concentration (coloring material concentration) of 8.0% by weight or more is used, deposit tends to be generated.
In Example (1) and Example (2) of
The printing element substrate 200 differs from the printing element substrate 100 in the shape of the ejection port 9. In the present embodiment, the ejection port 9 is larger in the width D2 of each of the base portions of the protrusions 11 in contact with the inner surface of the ejection port 9 than the width D1 of each of the tip portions of the protrusions 11. The base portions of the protrusions 11 are curved. A stress against an external force tends to focus on the base portions of the protrusion 11. For that reason, the strength of the protrusions 11 can be increased by increasing the width D2 of each base portion. The coherence of the ejected liquid droplets can be improved by making the width D1 of each tip portion of the protrusions 11 smaller than the width D2.
As in the first embodiment, a direction in which the ejection ports 9 are arrayed is referred to as y-direction, and an in-plane direction that is parallel to a surface of the substrate 1 and is perpendicular to the y-direction is referred to as x-direction. The protrusions 11 of the printing element substrate 200 also protrude in the x-direction. The width D1 of the tip portions of the protrusions 11 is 2 μm, and the width D2 of each of the base portions of the protrusions 11 is 4 μm. The curvature radius R of each of the base portions of the protrusions 11 is 4 μm. The distance between a pair of protrusions 11 provided at the same ejection port 9 is 3 μm. The major axis of the ejection port 9 (the length in the y-direction) is 20.5 μm, and the minor axis (the length in the x-direction) is 20 μm. The length of each protrusion 11 is 8.5 μm. Increasing the thickness of base portions of the protrusions 11 increases the strength against an external force. However, the ratio of the length L of the protrusion 11 to the width D2 of the base portion, L/D2, is 2 or higher, resulting in a high aspect ratio. As a result, if an external force from the wiping member or the like is exerted on the protrusions 11, the protrusions 11 can be broken only by devising the shape of the protrusions 11. For that reason, the tip portions of the protrusions 11 of in the present embodiment are also positioned closer to the substrate 1 than the ejection-port formed member 8, as in the first embodiment. This more reliably reduces or eliminates breakage of the protrusions 11 by preventing stress concentration by increasing the thickness of the base portions of the protrusions 11 while preventing the wiping member from coming into contact with the protrusions 11. Thus, high-definition, high-quality images can be provided with stability.
where E is the Young's modulus of the wiping member 14, I is the second moment of inertia of the wiping member 14, w (N/m) is a load on the wiping member 14, and L is the major axis of the ejection port 9.
To prevent the protrusions 11 from coming into contact with the wiping member 14, a distance k from the surface 8a of the ejection-port formed member 8 to the tip portions of the protrusions 11 is preferably set larger than the distance δ. At that time, the distance k satisfies Exp. (2).
Since the value of the distance δ depends on the material and the shape of the wiping member 14, the shape of the protrusions 11 may be determined depending on the material and shape of the wiping member 14 using Exp. (2). Alternatively, after the shape of the protrusions 11 has been determined, the material and the shape of the wiping member 14 may be determined so as to satisfy Exp. (2).
Suppose that the Young's modulus E of the wiping member 14 is 40 MPa, the length of each of the sides of the wiping member 14 in contact with the ejection-port formed member 8 is 50 μm, the load w that the wiping member 14 applies to the ejection-port formed member 8 is 2 MPa, the entire length of the wiping member 14 is 20 mm, and the diameter L of the ejection port is 24 μm. At that time, the maximum entry distance δ of the wiping member 14 is 0.21 μm. Therefore, when the protrusions 11 is positioned 0.21 μm or more closer to the substrate 1 than the surface 8a of the ejection-port formed member 8, breakage of the protrusions 11 hardly occurs.
Having described the present disclosure with reference to the embodiments, the present disclosure is not limited to the above example embodiments. It is to be understood that various modifications will occur to those skilled in the art in the configuration and the details of the disclosure within the scope of the technical spirit of the disclosure.
For example, although the liquid ejection head 20 of the above embodiments includes the printing element substrate 100, the liquid ejection head 20 may include any one of the printing element substrates 200, 300, and 400, instead of the printing element substrate 100.
In the above embodiments, the printing element substrate has a configuration in which liquid is supplied to the pressure chamber 7 from both sides of each ejection port 9, but the disclosure is not limited to this example. The configuration other than the ejection ports 9 is given for mere illustration, and the present disclosure can be applied to printing element substrates with various configurations other than the example. For example, one of the supply passages 4 formed on both sides of each ejection port 9 may be used to supply liquid to the pressure chamber 7, and the other may be used to recover the liquid from the pressure chamber 7. In this case, the recovered liquid may be circulated. In other words, the liquid in the pressure chamber may be used in a liquid ejection head with a configuration in which liquid is circulated between the pressure chamber and the outside. In such a liquid ejection head in which liquid is circulated, the distance between the plurality of protrusions 11 can be made relatively small, which is particularly effective in reducing satellite droplets and mist.
For example, in the above embodiments, a pair of protrusions 11 are formed on the inner surface of each ejection port 9. However, the present disclosure is not limited to the above example. For example, at least one protrusion 11 may be formed for each ejection port 9.
According to the various example embodiments of the disclosure, in a printing element substrate including a protrusion for preventing generation of mist, breakage of the protrusion can be prevented, and liquid droplets and foreign substances adhering to the outer periphery of the ejection port can be removed.
While the disclosure has been described with reference to example embodiments, it is to be understood that the invention is not limited to the disclosed example 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. 2016-106222 filed May 27, 2016, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2016-106222 | May 2016 | JP | national |
Number | Name | Date | Kind |
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20070076053 | Hart | Apr 2007 | A1 |
20140125735 | Takei | May 2014 | A1 |
20180086076 | McMullen | Mar 2018 | A1 |
Number | Date | Country |
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2013000914 | Jan 2013 | JP |
Number | Date | Country | |
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20170341388 A1 | Nov 2017 | US |