The present invention relates to a liquid ejection head.
Structures obtained by microfabricating silicon are widely used as MEMS-field and electromechanical functional devices. An example thereof is a liquid ejection head ejecting liquid. For example, the liquid ejection head is used as a liquid ejection head of a liquid ejection recording type in which an ejected droplet is placed onto a recording medium for recording. The liquid ejection head of the liquid ejection recording type includes a substrate provided with an energy-generating element generating energy for use in ejecting liquid and a discharge port ejecting liquid supplied from a liquid supply port provided in the substrate. In a recent liquid ejection recording device, there is a demand for improvement in printing performance such as high resolution and high-speed printing and size reduction and densification of the liquid ejection head in manufacture.
Japanese Patent Application Laid-Open No. 2011-161915 proposes a method for processing a silicon substrate enabling a structure provided with a plurality of individual supply ports communicating with a common liquid chamber with high forming accuracy to be obtained at a high yield. In this method, the silicon substrate is subject to the following two-stage etching process. First, dry etching serving as first etching is performed to form a recess serving as a common liquid chamber. Subsequently, using as a mask an intermediate layer provided on a bottom portion of the recess and having a plurality of openings formed therein, second etching is performed to form a plurality of individual supply ports. In this manner, the silicon substrate having the plurality of individual supply ports communicating with the common liquid chamber constituting the recess is formed.
According to the present invention, there is provided a liquid ejection head including: a substrate including an energy-generating element; a flow path forming member including a discharge port and having a liquid flow path formed between the flow path forming member and the substrate; and plurality of through-passages passing through the substrate, each of the through-passages including a first through-passage part serving as a common liquid chamber and a plurality of second through-passage parts communicating with the first through-passage part, wherein a separation wall separating the adjacent first through-passage parts includes a plate-shaped member separating the adjacent first through-passage parts and approximately vertical to a substrate in-plane direction and, at least one protrusion protruding from the plate-shaped member in the substrate in-plane direction and contacting a bottom portion of the first through-passage part.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Preferred embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
Substrate processing using dry etching enables highly anisotropic microfabrication and is thus suitable for forming a high-aspect-ratio vertical shape in a silicon substrate. In a liquid ejection head, by forming vertical common liquid chambers by means of dry etching and narrowing a beam width of a separation wall (wall width) produced between the adjacent common liquid chambers, the substrate (chip) size can be shrunk.
Meanwhile, in the present specification, the term “beam” means a plate-shaped member (particularly, a flat-plate-shaped member) which separates common liquid chambers adjacent to each other in a substrate in-plane direction and which is approximately vertical to the substrate in-plane direction. Also, “approximately vertical” includes not only a strictly vertical shape but also a tapered shape generated at the time of processing. That is, displacement from a vertical shape caused by processing accuracy is allowed. Similarly, “approximately parallel” includes not only a strictly parallel state, and displacement from a parallel state caused by processing accuracy is allowed.
When rectangular opening patterns 9 as in
However, in a case in which the beam width of the separation wall is narrowed and shrunk as in
In this manner, in the shrinking method of simply shrinking the distance between the opening patterns, the separation wall will be in the high aspect shape and decrease its strength when the substrate is etched deeply. Thus, the separation wall may be broken during manufacture of the liquid ejection head or during use of the liquid ejection head recording device.
An object of the present invention is to provide a liquid ejection head restricting a decrease of mechanical strength of a separation wall and enabling shrinking without fear of breakage of the separation wall even in a case of narrowing a beam width of the separation wall.
According to the present invention, for example, when a separation wall having a narrowed beam width and formed in a high-aspect-ratio vertical shape is formed, at least one protrusion contacting a bottom surface of an opening pattern is provided on a side surface of a beam. The beam is a plate-shaped member which separates common liquid chambers adjacent to each other and which is approximately vertical to a substrate in-plane direction. The protrusion is a member protruding from the beam in the substrate in-plane direction. Accordingly, even in a case in which the beam width of the separation wall is narrowed, the protrusion is structured to reinforce the beam portion of the separation wall. Thus, the separation wall with higher mechanical strength than that of a separation wall with no protrusion can be formed. The protrusion is desirably formed integrally with the substrate. The present invention is particularly suitable when an aspect ratio of the depth of the separation wall to the beam width (beam depth/beam width) is as high as 10 or higher. Hence, even when the beam width of the separation wall is narrowed, the chip size can be shrunk while restricting breakage of the separation wall. According to the present invention, further size reduction of a liquid ejection head can be achieved.
Embodiments of the present invention will now be described below, and the present invention is not limited to these embodiments.
In
The flow path forming member 6 includes a discharge port 2 ejecting liquid and a liquid flow path 3 communicating with the discharge port 2. The surface of the flow path forming member 6 is provided with a liquid-repellent layer (not illustrated) to improve ejection performance. The liquid flow path is formed between the substrate and the flow path forming member.
The substrate 1 is provided with a plurality of through-passages passing through the substrate. Each of the through-passages includes a first through-passage part (common liquid chambers 4) and a plurality of second through-passage parts (individual supply ports 5) communicating with the first through-passage part. More specifically, the substrate 1 includes the individual supply ports 5 serving as the second through-passage parts for supplying liquid to the liquid flow path 3, the common liquid chambers 4 serving as the first through-passage part communicating with the individual supply ports 5, and separation walls 7 separating the adjacent common liquid chambers 4. Each of the separation walls 7 has protrusions 8. The plurality of individual supply ports 5 are formed on the bottom surface of each common liquid chamber 4. Also, the plurality of common liquid chambers 4 are formed on one surface of the substrate on the opposite side of the other surface provided with the flow path forming member 6. Each individual supply port 5 is formed to pass through the substrate 1 from the bottom surface of the common liquid chamber 4.
The substrate 1 can include an energy-generating element, particularly an ejection-energy-generating element (labeled with reference sign 19 in
An opening shape of the bottom portion of the first through-passage part (common liquid chamber 4) in the substrate in-plane direction is a shape in which at least one side (for example, one side or two opposed sides) of a quadrangle is recessed due to the protrusions 8 of the separation wall 7. Meanwhile, in a case in which the bottom portion of the common liquid chamber 4 is not planar, the opening shape of the bottom portion in the substrate in-plane direction means a shape when the opening shape of the bottom portion (contour line of the opening) is projected (in a substrate normal direction) on a plane parallel to the substrate in-plane direction.
The plurality of second through-passage parts (individual supply ports 5) are arranged in the first through-passage part (common liquid chamber 4) along a beam of the separation wall in the substrate in-plane direction.
Also, the plurality of common liquid chambers serving as the through-passages are arranged to be approximately parallel to the arranging direction of the second through-passage parts. The respective common liquid chambers are arranged so that the opening shapes of the bottom portions of the respective common liquid chambers, that is, the aforementioned quadrangles, may be parallel to each other.
Although, in the structure illustrated in
The separation wall 7 separating the adjacent common liquid chambers 4 (first through-passage part) includes at least one protrusion 8 contacting the bottom portion of the first through-passage part (common liquid chamber 4). By the protrusion 8, a recess from a side of the aforementioned quadrangle (opening shape of the bottom portion of the common liquid chamber in the substrate in-plane direction) extending in a separation wall beam direction (direction in which the beam extends) is defined. That is, the contour of the protrusion 8 forms the recess.
In the structure illustrated in
In the structure illustrated in
As in
To obtain a structure in which the protrusions 8 contact the bottom portion of the common liquid chamber 4, the substrate is patterned to form the separation wall including the protrusions and is dug down by means of reactive ion etching serving as anisotropic etching to form the common liquid chamber. Thus, the separation wall including the protrusions and the bottom portion of the common liquid chamber are formed integrally.
To shrink the head size, it is desirable to provide the individual supply port 5 to be as close to the neighborhood of the beam portion as possible without the individual supply port 5 interfering with the protrusion 8. As in
Also, as illustrated in
When the area of the protrusion 8 contacting the sidewall of the beam portion is larger, the reinforcing effect is higher. Thus, from a viewpoint of the reinforcing effect, a width n (thickness in a direction perpendicular to a direction of the length m) of the protrusion 8 is desirably longer.
The shape of the protrusion 8 is not limited as long as the protrusion 8 contacts the bottom surface of the common liquid chamber and the sidewall of the beam portion, and as long as the shape is effective in reinforcing the beam portion. For example, the protrusion 8 may be in a shape as in
In a case in which the separation wall 7 has at least one protrusion 8, this exerts the reinforcing effect for the separation wall. However, the more the number of protrusions is, the further the number of positions in which the beam of the separation wall is reinforced increases. Thus, the protrusion is desirably arranged at every available position.
As a material for the intermediate layer, a resin material, silicon oxide, silicon nitride, silicon carbide, a metal other than silicon, metal oxide thereof, metal nitride thereof, or the like can be used. That is, the material for the intermediate layer can be a resin layer, a silicon oxide film, a silicon nitride film, a silicon carbide film, a metal film other than silicon, a metal oxide film thereof, a metal nitride film thereof, or the like. An example of the resin layer that can be raised is a photosensitive resin layer. Among others, the photosensitive resin layer or the silicon oxide film is desirably used as the intermediate layer for easy formation. In a case of using a substrate other than the SOI substrate, the first substrate is provided with the common liquid chambers, the second substrate is provided with the individual supply ports, and the respective substrates are connected via an adhesive.
In an opening pattern in
For example, as in
To solve such a problem, the SOI substrate including the silicon oxide film 12, which effectively functions as a stop layer for dry etching, is desirably used. As illustrated in
In the present embodiment, as illustrated in
Thus, liquid flowing in a certain common liquid chamber can pass through an individual supply port communicating with the common liquid chamber and the liquid flow path 3, flow into an adjacent individual supply port, and reach a different common liquid chamber. That is, liquid supplied from an outside to the liquid ejection head is supplied via a common inflow path (common liquid chamber 4a on an inflow side) and an individual inflow port (individual supply port 5a on the inflow side) to the liquid flow path 3. The liquid can thereafter flow outside via an individual outflow port (individual supply port 5b on an outflow side) and a common outflow path (common liquid chamber 4b on the outflow side). In this manner, in the pair of adjacent supply ports, the common inflow path (common liquid chamber 4a on the inflow side) functions as a liquid inflow port, and the common outflow path (common liquid chamber 4b on the outflow side) functions as a liquid outflow port, to enable a forced liquid flow (circulating liquid flow) to be generated. That is, liquid in the pressure chamber including the energy-generating element is circulated between the inside and the outside of the pressure chamber. In a normal configuration with no circulating liquid flow, liquid around the discharge port 2 may be evaporated to cause a decrease in ejection speed and alteration of color material concentration of print dots. However, due to this circulating liquid flow, the liquid state around the discharge port can be kept constant, and the possibility of the printing alteration can thus be reduced.
Meanwhile, in the individual supply port 5b, not supply of liquid (to the discharge port) but discharge of liquid is performed. However, in this context, the individual supply port 5b is referred to as the “supply port” for convenience. The individual supply port on the outflow side means the second through-passage part on the outflow side.
In the present embodiment as well, by shortening the beam width of the separation wall 7 to cause the individual inflow port 5a and the individual outflow port 5b to be closer to the beam portion 20, the liquid ejection head size can be shrunk. Also, since the individual inflow port (5a) and the individual outflow port (5b) are provided to be close to the ejection-energy-generating element to improve refilling performance of liquid, high-speed printing can be performed.
Also, it is desirable for the stable circulating liquid flow to arrange the individual inflow port (5a) and the individual outflow port (5b) symmetrically across the discharge port 2. Thus, a favorable positional relationship between the individual inflow port (5a) and the individual outflow port (5b) is to arrange the individual outflow port (5b) with respect to the individual inflow port (5a) in a 90-degree direction to the arrangement of the individual inflow ports (5a) in the substrate in-plane direction. That is, it is desirable to arrange the individual supply port 5b or 5a in the other through-passage with respect to the individual supply port 5a or 5b in one through-passage in a direction perpendicular to the arranging direction of the individual supply ports 5a or 5b, the individual supply ports communicating with each other via one liquid flow path 3.
Meanwhile, in the structure illustrated in
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. 2016-243420, filed Dec. 15, 2016, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2016-243420 | Dec 2016 | JP | national |
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Number | Date | Country |
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2011-161915 | Aug 2011 | JP |
Number | Date | Country | |
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20180170047 A1 | Jun 2018 | US |