The present disclosure relates to a liquid discharge head that discharges liquid.
Liquid discharge heads such as inkjet recording heads include an element substrate and a flow passage forming member. The element substrate includes a liquid discharge element, such as a heating element, that discharges a liquid. The flow passage forming member forms a discharge port and a flow passage. With the aim of preventing separation between the element substrate and the flow passage forming member made from a resin material, Japanese Patent Application Laid-Open No. 2007-160624 discusses a configuration in which an adhesion layer (an intermediate layer) made from a resin material highly adhesive between the element substrate and the flow passage forming member is disposed between them.
In recent years, there have been growing demands on the liquid discharge heads for improvement in image quality, achievement in multifunctionality, enhancement in durability, and the like. The liquid discharge heads have been equipped with discharge ports, circuits, and the like at a high density to meet the improvement in image quality. The liquid discharge heads also have been equipped with a circuit having various functions to meet the achievement of multifunctionality. According to such demands for increase in the density and the achievement of multifunctionality, the liquid discharge heads may include a conductive member for disposing a circuit on a surface of the element substrate on a side where the flow passage forming member is disposed.
In the above described configuration, the conductive member may be covered with an intermediate layer made from a resin material to prevent the conductive member mounted on the surface of the element substrate from corroding resulting from adhesion of a liquid. However, the conductive member made from a metallic material is less adhesive to the intermediate layer made from the resin material, and therefore the intermediate layer may be detached or separated from the conductive member. Starting from a detached and separated portion, further separation between the element substrate and the flow passage forming member can be occurred. Especially when the conductive member is made from a material containing gold, a possibility of occurrence of separation is increased since the conductive member is less adhesive to the intermediate layer.
Therefore, the present disclosure is directed to preventing separation between the element substrate and the flow passage forming member while protecting the conductive member mounted on the surface of the element substrate from a liquid.
According to an aspect of the present disclosure, a liquid discharge head includes a flow passage forming member that is made from a resin material and forms a flow passage in communication with a discharge port, an element substrate including a liquid discharge element configured to discharge a liquid from the discharge port, and a surface, on a side where the flow passage forming member is disposed, on which a conductive member made from a metallic material is disposed, and an intermediate layer made from a resin material and configured to join the flow passage forming member and the surface of the element substrate to each other, wherein the intermediate layer is disposed in a state, separated from the conductive member, where the conductive member is exposed from the intermediate layer, and wherein the conductive member is covered with the flow passage forming member.
Further features of the present disclosure will become apparent from the following description of example embodiments with reference to the attached drawings.
In the following description, a first example embodiment of a liquid discharge head 5 according to the present disclosure will be described. The present disclosure shall not be limited to the example that will be described below. It is also possible to employ a configuration configured like a combination of each of the present example embodiment and example embodiments that will be described below.
(Example Recording Apparatus)
First,
(Example Liquid Discharge Head Unit)
(Example Liquid Discharge Head)
The liquid discharge head 5 includes the flow passage forming member 10 and the element substrate 11. The flow passage forming member 10 includes a flow passage through which the liquid flows, such as the discharge port 6 and a pressure chamber 16 in communication with the discharge port 6. The element substrate 11 includes a liquid discharge element 14, which applies energy to the liquid to cause the liquid to be discharged. The liquid discharge head 5 further includes an adhesion layer 12 as an intermediate layer disposed between the flow passage forming member 10 and the element substrate 11.
The liquid discharged from the plurality of discharge ports 6 on one liquid discharge head 5 is ink of the same color in the present example embodiment, but ink of a different color may be used for, for example, each discharge port row. Further, the discharged liquid may be liquid different from the ink. A common flow passage (not illustrated) through which the liquid flows extends in the element substrate 11, and this common flow passage is in communication with the pressure chamber 16 via each of a plurality of individual flow passages 15. While two individual flow passages 15 are disposed for one pressure chamber 16 in the present example embodiment, one individual flow passage 15 may be disposed for one pressure chamber 16. In the present example embodiment, a circulatory flow may be formed in such a manner that the liquid flows from the individual flow passage 15 on one side into the pressure chamber 16 and then the liquid flows out of the individual flow passage 15 on the other side.
The flow passage forming member 10 according to the present example embodiment includes a discharge port forming member 10a, on which the discharge port 6 is formed, and a partition wall member 10b, which includes a partition wall for forming the pressure chamber 16. However, the flow passage forming member 10 is not limited to such a configuration. The discharge port forming member 10a and the partition wall member 10b may be formed as an integrated member, and, the flow passage forming member 10 may include another member.
The partition wall member 10b is desirably made from a resin material, and further desirably made from a photosensitive resin material to form the flow passage such as the discharge port 6 and the pressure chamber 16 by light irradiation. Desirably, resin such as epoxy resin, acrylic resin, and urethane resin soluble in an organic solvent is used as the photosensitive resin. Examples of the epoxy resin include bisphenol A-type resin, cresol novolac-type resin, and circulatory epoxy resin. Examples of the acrylic resin include polymethyl methacrylate. Examples of the urethane resin include polyurethane.
An example of a method for forming the partition wall member 10b is a lamination method using a dry film. This lamination method is to form the partition wall member 10b on one side of the element substrate 11 where a surface 11d is located, by transferring a laminate of a dry film for forming the partition wall member 10b and a support body supporting it onto the one side of the element substrate 11 where the surface 11d is located, and peeling off the support body after that. In the present example embodiment, the adhesion layer 12 is formed on the surface 11d of the element substrate 11. When the partition wall member 10b is disposed by the lamination method on the surface 11d side of the element substrate 11 having a step formed by, for example, the adhesion layer 12, a void may be unintentionally formed due to failure to completely fill the step with the partition wall member 10b. It is desirable to carry out the transfer using the roller method that presses the laminate with a roller or carry out the transfer under vacuum to prevent the formation of such a void. Examples of the support body that supports the dry film include a film, a glass, and a silicon wafer, but use of the film is desirable in consideration of the later peel-off. Examples of the film as the support body include a polyethylene terephthalate (PET) film, a polyimide film, and a polyamide (aramid) film. Further, a release promotion treatment may be applied to the film to facilitate the peel-off.
The method for forming the partition wall member 10b is not limited to the above-described method, and resist spin coating, spraying application, slit coating, or the like can also be employed therefor.
The discharge port forming member 10a can also be made from a similar material to the partition wall member 10b, and can also be formed by using a similar formation method.
At a position corresponding to the discharge port 6 on the element substrate 11 according to the present example embodiment, a heating element that applies heat energy to the liquid to cause the liquid to foam and be discharged, as an example of the liquid discharge element 14, is disposed. The pressure chamber 16 including one liquid discharge element 14 therein is defined by the partition wall member 10b. The heating element as the liquid discharge element 14 generates heat to boil the liquid based on a pulse signal input via an internal wiring 23 (
Desirably, the element substrate 11 is made of a material such as a semiconductor substrate on which an electronic device, such as the liquid discharge element 14, an electric circuit, an electric wiring, and a temperature sensor, can be formed by semiconductor processing, and a flow passage can be formed by micro electro mechanical system (MEME) processing. In the present example embodiment, layers 11a to 11c are laminated in this order from an opposite side from the flow passage forming member 10 on the element substrate 11. These layers 11a to 11c are, for example, disposed as layers containing silicon. For example, the layer 11a, the layer 11b, and the layer 11c can be disposed as a silicon substrate, an insulation layer made from silicon monoxide (SiO) or the like, and an insulation protection layer made from silicon nitride (SiN), silicon carbon nitride (SiCN), or the like covering the liquid discharge element 14, respectively. The configuration such as the laminate material and the number of layers of the element substrate 11 is not especially limited.
The adhesion layer 12 according to the present example embodiment is a layer for ensuring bondability between the flow passage forming member 10 (the partition wall member 10b) and the element substrate 11, and preventing separation between them. For example, a resin material such as polyether amide resin and epoxy resin can be used as the adhesion layer 12. However, the material of the adhesion layer 12 is not especially limited as long as the adhesion layer 12 is made from a material highly adhesive to both the layer 11c (the insulation protection layer in the present example embodiment) forming the surface 11d of the element substrate 11 and the flow passage forming member 10 and capable of improving the adhesion between them, and also stable toward the liquid. Examples of a method for forming the adhesion layer 12 include providing the adhesion layer 12 by applying a photosensitive resin material on the surface 11d of the element substrate 11 or by pressing a sheet made from a photosensitive resin material against the element substrate 11 using a roller.
A member made from a material different from the layer 11c may be disposed in a region where the adhesion layer 12 and the layer 11c forming the surface 11d of the element substrate 11 are in contact with each other due to restrictions regarding the arrangement of circuits and the like mounted on the element substrate 11. In the present example embodiment, the conductive member 20 made of a metallic material is disposed on the surface 11d, which is the surface of the element substrate 11 on the one side where the flow passage forming member 10 is disposed. This conductive member 20 contains, for example, at least any one of gold, tantalum, iridium, and the like, which are metallic materials used for the liquid discharge head 5. A bonding force between this conductive member 20 and the adhesion layer 12 made from the resin material such as the above-described examples is weak compared to a bonding force between the layer 11c of the element substrate 11 and the adhesion layer 12.
Next, a phenomenon that occurs near the conductive member 20 will be described with reference to
As illustrated in
Due to the detachment of the adhesion layer 12 from the conductive member 20, the adhesion layer 12 may also be undesirably separated from the layer 11c near there (
As illustrated in
With this configuration, the adhesion layer 12 can be prevented from being detached due to separation of the adhesion layer 12 from the conductive member 20 even when the flow passage forming member 10 and the adhesion layer 12 are swollen as shown in
Desirably, the adhesion layer 12 is disposed in such a manner that a wall 17a defining the opening portion 17 of the adhesion layer 12 and the conductive member 20 are separated from each other to reduce the number of locations that might develop as a starting point of detachment. Further, it is also desirable for the following reason that the adhesion layer 12 is kept in the state also out of contact with the side surface of the conductive member 20. That is, the present configuration can prevent the void 24 from being formed near the corner of the base of the conductive member 20 protruding from the surface 11d of the element substrate 11 due to failure of filling the void 24 with the adhesion layer 12 when the adhesion layer 12 is disposed on the surface 11d of the element substrate 11, whereby the influence of the detachment can be eliminated. Desirably, a width Lc of a gap between the wall 17a forming the opening portion 17 of the adhesion layer 12 and the conductive member 20 is approximately 10 μm to 20 μm. With this configuration, the void 24 can be prevented from being formed while a joined region is secured between the flow passage forming member 10 and the element substrate 11.
The conductive member 20 is also out of contact with the partition wall member 10b covering the conductive member 20, and there is a clearance around the conductive member 20 protruding from the surface 11d of the element substrate 11. Desirably, the surface of the liquid discharge head 5, i.e., the surface of the discharge port forming member 10a where the discharge port 6 is formed is shaped as a flat surface. To ensure flatness of the surface on which the discharge port 6 is formed, the liquid discharge head 5 may be configured in such a manner that the conductive member 20 and the partition wall member 10b are separated from each other like the present example embodiment.
The surface of the conductive member 20 (the surface on the side of the partition wall member 10b) is disposed on the surface 11d side of the element substrate 11 with respect to the surface of the adhesion layer 12 (the surface on the side of the partition wall member 10b side). In other words, a height of the protrusion of the conductive member 20 from the surface 11d of the element substrate 11, i.e., a length La of the conductive member 20 from the surface 11d in a direction perpendicular to the surface 11d is shorter than a thickness Lb of the adhesion layer 12 (a length in the perpendicular direction). For example, the height La of the protrusion of the conductive member 20 from the surface 11d of the element substrate 11 is approximately 0.4 μm, and the thickness Lb of the adhesion layer 12 is approximately 0.8 μm.
In the present example embodiment, the liquid discharge head 5 is configured in such a manner that the partition wall member 10b is fitted with the opening portion 17 of the adhesion layer 12 surrounding the conductive member 20. In other words, a distance between a portion of the partition wall member 10b that overlaps the opening portion 17 as viewed from the direction perpendicular to the surface 11d of the element substrate 11 and the conductive member 20 in the perpendicular direction is shorter than a distance between a portion of the partition wall member 10b that is joined to the adhesion layer 12 and the conductive member 20 in the perpendicular direction. Such a configuration is desirable for the following reason.
Depending on the materials of the discharge port forming member 10a and the partition wall member 10b, a heating treatment such as baking may be applied to cure these materials when the liquid discharge head 5 is manufactured. At the time of this heating treatment, air in the clearance around the conductive member 20 (the space surrounded by the adhesion layer 12, the element substrate 11, and the partition wall member 10b) is expanded. If a force derived from this expansion is stronger than the strength of the material, the expansion may cause, for example, a plastic deformation of the material. Therefore, in the present example embodiment, the partition wall member 10b is disposed in a manner such that the partition wall member 10b fits with the clearance, whereby the volume of the clearance around the conductive member 20 is reduced and thus the influence due to the expansion of the air is eased. The partition wall member 10b can fit with the clearance by, for example, adjusting a pressure on the partition wall member 10b against the element substrate 11 using the roller at mounting.
In the present example embodiment, the liquid discharge head 5 is configured in such a manner that the discharge port forming member 10a (a second member) above the conductive member 20 is removed and the conductive member 20 is covered only with the partition wall member 10b (a first member). More specifically, as illustrated in
In the present example embodiment, the discharge port forming member 10a and the partition wall member 10b have a groove 19 in a region outside the portion overlapping the conductive member 20 as viewed from the direction perpendicular to the surface 11d of the element substrate 11, and the flow passage forming member 10 is divided by this groove 19 into an inner side and an outer side. The use of the liquid discharge head 5 raises a possibility of a contact with liquid anywhere on the surface where the discharge port 6 is formed, which means that there is a possibility that the discharge port forming member 10a and the partition wall member 10b are entirely swollen. When the members are expanded due to the swell, the force derived from this expansion is applied even to the region around the conductive member 20 where the adhesion layer 12 would be easily detached, which undesirably leads to detachment of the adhesion layer 12. The influence of expansion over the entire members can be reduced in the region around the conductive member 20 by providing the groove 19 and dividing the discharge port forming member 10a and the partition wall member 10b like the present example embodiment. As a result, detachment of the adhesion layer 12 can be prevented and separation between the flow passage forming member 10 and the element substrate 11 can be further prevented.
(Example of Application of Conductive Member)
A specific example of application of the conductive member 20 will be described. The configuration that will be described here is an example, and the conductive member 20 employable for the present disclosure is not limited to the following description.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
When an accidental failure has occurred and conductivity is established between the liquid discharge element 14 and the protection layer 21 covering the liquid discharge element 14, a current flows from the liquid discharge element 14 to the fuse portion 35 by passing through the protection layer 21, by which the fuse portion 35 is blown. As a result, the protection layer 21 conductively connected to the liquid discharge element 14 can be electrically isolated from the common wiring 34, and thus an influence of alteration of the property of the protection layer 21 to be exerted on the protection layer 21 covering another liquid discharge element 14 can be prevented.
The width of the fuse portion 35 is narrower than the width of the individual wiring 33. The fuse portion 35 is therefore to be melted when a current flows from the liquid discharge element 14 to the terminal 22. The width of the fuse portion 35 should satisfy a processing dimension of several μm or narrower, and is desirably set to 3 μm or narrower to ensure the ability to blow.
In the present example embodiment, one fuse portion 35 is disposed for the protection layer 21 covering the two liquid discharge elements 14. How the liquid discharge element 14 and the fuse portion 35 are combined may be determined based on a configuration in which, when an accidental failure has occurred in the liquid discharge element 14, another liquid discharge element 14 can complement it.
However, some of the common wirings 34 are disposed between the adjacent rows of the liquid discharge elements 14 as described above. For this reason, reducing an interval between the adjacent rows of the liquid discharge elements 14 to reduce the size of the element substrate 11 leads to the necessity of also reducing the width of the common wiring 34 disposed between these rows. Consequently, wiring resistance of the common wiring 34 is increased. Further, in a case where the liquid discharge head 5 includes a large number of discharge ports 6 (the liquid discharge elements 14) and includes a long discharge port row (a heating resistance element row), the wiring resistance of the common wiring 34 increases at the fuse portion 35 having a long distance from the terminal 22 to the fuse portion 35 via the common wiring 34 among the plurality of fuse portions 35. The increase in the wiring resistance of the common wiring 34 in this manner may cause a low current to flow to the fuse portion 35, which may result in a failure to allow the fuse portion 35 to blow.
Therefore, in the present example embodiment, a wiring 37 is disposed in a layer different from a layer of the common wiring 34 in the lamination direction (the direction perpendicular to the surface 11d of the substrate 11) (
As illustrated in
Further, desirably, a terminal forming layer 22a and the wiring 37 are provided as a common layer made from the same material such as aluminum (Al), or the like to reduce the manufacturing load.
While the present disclosure has been described with reference to example embodiments, it is to be understood that the disclosure 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. 2019-072251, filed Apr. 4, 2019, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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JP2019-072251 | Apr 2019 | JP | national |
Number | Name | Date | Kind |
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20080024563 | Matsui | Jan 2008 | A1 |
20110074252 | Kura | Mar 2011 | A1 |
Number | Date | Country |
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2007-160624 | Jun 2007 | JP |
Number | Date | Country | |
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20200316941 A1 | Oct 2020 | US |