1. Field of the Invention
The present invention relates to a process for producing a liquid ejection head provided with a piezoelectric body.
2. Description of the Related Art
A piezoelectric type ink jet head provided with a piezoelectric body containing a piezoelectric material such as PZT (Pb(Zr, Ti)O3; lead zirconate titanate) is known. In the piezoelectric type ink jet head, a pressure chamber for applying an ejection pressure to an ink is formed, and an electrode electrically connected to a head substrate is provided on an inner wall surface and an outer wall surface of the pressure chamber. A voltage is applied to the electrode from the head substrate, whereby a side wall, a bottom wall and a top wall of the pressure chamber are deformed to change a capacity of the pressure chamber. An ejection pressure is thereby applied to an ink within the pressure chamber, and an ink droplet is ejected from an ejection orifice communicated with the pressure chamber.
In the production of the piezoelectric type ink jet head, a wiring electrode composed of a metal thin film may be formed on a lateral surface of the piezoelectric body, on which surface the ejection orifice of the pressure chamber is located, in some cases. In this case, it is difficult to form a pattern by an ordinary liquid resist on the lateral surface of the piezoelectric body because the ejection orifice is present, and so a dry film resist is suitably used. In order to prevent pattern defect (abnormality) such as release of the resist, it is important to ensure adhesion between the dry film resist and the piezoelectric body. It is thus conducted to remove air in a vacuum chamber and then bond the dry film resist to the surface of the piezoelectric body under pressure while being heated (vacuum lamination).
In the technology described in Japanese Patent Application Laid-Open No. 2010-181813, a further device is provided for the dry film resist. Specifically, in the dry film resist, a surface roughness Ra of a surface, coming into contact with a resist layer, of a protecting layer laminated on the resist layer (photosensitive resin layer) is controlled to more than 0.5 μm. Irregularities are applied to the protecting layer in this manner, whereby a bubble liable to remain at a contact surface between the protecting layer and the resist layer can be efficiently removed.
However, the dry film resist is relatively good in adhesion to a metal such as Cu or Al, but not very good in adhesion to a piezoelectric body such as PZT. The conventional vacuum lamination technology and the technology described in Japanese Patent Application Laid-Open No. 2010-181813 pay attention to the removal of the bubble and cannot sufficiently ensure adhesion between the dry film resist and the piezoelectric body. In particular, when a pattern is formed on the lateral surface of the piezoelectric body, on which surface the ejection orifice is located, with the dry film resist, pattern release may occur due to insufficient adhesion though the bubble can be sufficiently removed. In fact, when the dry film resist is vacuum-laminated on the ejection orifice of the piezoelectric body, the dry film resist may be pushed into the interior of the pressure chamber through the ejection orifice of the piezoelectric body in some cases. In order to remove the resist pushed into the interior of the pressure chamber by development, a longer development time is required compared with a resist present on a flat portion. However, if the development time is long, a resist portion (resist pattern) intended to remain is also released from the surface of the piezoelectric body to cause pattern defects. It is thus desired to more improve the adhesion between the dry film resist and the piezoelectric body.
It is an object of the present invention to provide a process capable of forming a metal thin film on a surface of a piezoelectric body, on which surface an ejection orifice is located, without causing pattern defects.
The process for producing a liquid ejection head according to the present invention is a process for producing a liquid ejection head having a piezoelectric body provided with an ejection orifice for ejecting a liquid and a pressure chamber communicating with the ejection orifice for retaining the liquid to be ejected from the ejection orifice, wherein an electrode is formed on an inner wall surface of the pressure chamber so that the pressure chamber is deformed by a piezoelectric action caused by applying a voltage to the electrode, thereby ejecting the liquid, the process comprising the steps of: providing the piezoelectric body in which a surface thereof on which the ejection orifice is located has a surface roughness within a range of 0.1 μm or more and 1 μm or less in terms of arithmetic mean roughness Ra, forming a pattern of a dry film resist on the surface of the piezoelectric body so as to expose the ejection orifice and a linear region connected to the ejection orifice, and forming a pattern of a metal thin film that is connected to the electrode on the inner wall surface and continuously extends from the inner wall surface to the linear region by using the pattern of the dry film resist as a mask.
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.
A process for producing a liquid ejection head (ink jet head) according to a first embodiment will be described with reference to
In this embodiment, a piezoelectric body in which a pressure chamber and an air chamber are two-dimensionally arranged is first provided by subjecting a piezoelectric substrate to treatments such as electrode formation, grooving and poling, and laminating plural sheets of the piezoelectric substrate subjected to the treatments as illustrated in
A first piezoelectric substrate 1 is first provided as illustrated in
A first mark M1 as an alignment mark is then formed on a first principal surface 1a of the first piezoelectric substrate 1. The first mark M1 can be formed by preparing a pattern on the first principal surface 1a of the first piezoelectric substrate 1 by mechanical machining or laser beam machining. A pattern of a metal film formed by a lift-off technique of a metal film including a photolithography process or an etching technique may also be provided as the first mark M1.
A first electrode 2 is then formed on the first principal surface 1a. The position of the first electrode 2 is determined on the basis of the first mark M1. Methods for forming the first electrode 2 include a lift-off technique of a metal film including steps of photolithography, metal film deposition and resist stripping. As a method for forming the metal film, a sputtering method or a chemical vapor deposition (CVD) method may be favorably utilized. After a thin seed film is formed on the piezoelectric substrate 1 by lift-off of a metal film, a relatively thick metal film may be formed by plating to provide the first electrode 2. In that case, examples of the seed layer include a two-layer film formed in the order of Cr and Pd, and examples of the relatively thick metal film include a two-layer film formed in the order of Ni and Au.
When the first mark M1 is formed from a pattern of a metal, the first electrode 2 is favorably formed by the same method as the method for forming the first mark M1 at the same time as the formation of the first mark M1. The first mark M1 and the first electrode 2 are formed at the same time, whereby the positions of the first electrode 2 to the first mark M1 can be determined with higher precision.
As illustrated in
First, a seed layer (not illustrated) for forming the electrode pad 2a, the electrode wiring 2b and the second mark M2 is formed on the first piezoelectric substrate 1 by a lift-off technique of a metal film including a photolithography process. More specifically, a Cr layer having a thickness of 20 nm and a Pd layer having a thickness of 150 nm are formed in this order on the second principal surface 1b and lateral surface 1c of the first piezoelectric substrate 1 by a sputtering method to provide the seed layer. Upon the sputtering, the piezoelectric substrate 1 is arranged in such a manner that the second principal surface 1b faces a target for sputtering. In this case, by utilizing the coatability of sputtering, the seed layer for the electrode wirings 2b can be formed on the lateral surface 1c (see
The seed layer is then utilized to successively form thin Ni and Au films respectively having thicknesses of about 1 μm and about 0.1 μm by an electroless plating method, thereby providing the electrode pad 2a, the electrode wiring 2b and the second mark M2. The first electrode 2 formed on the first principal surface 1a of the first piezoelectric substrate 1 is thereby drawn out on the second principal surface 1b of the first piezoelectric substrate 1 through the electrode wiring 2b and the electrode pad 2a. In addition, the second mark M2 is formed on the basis of the first mark M1.
As illustrated in
Sizes of the first and second grooves 3 and 4 in a thickness-wise direction Y (hereinafter referred to as groove depths), sizes in a direction Z along which each groove extends, and sizes in a width-wise direction X (hereinafter referred to as groove widths) intersecting the direction Z along which each groove extends and the thickness-wise direction Y may respectively vary. Grinding by a super-abrasive wheel is favorable as a method for forming the first and second grooves 3 and 4. As an example, the first groove 3 and the second groove 4 may be arranged in parallel with one another at regular intervals with the sizes and arrangement periods (arrangement intervals) thereof made the same. For example, the first and second grooves 3 and 4 are grooves periodically arranged and each having a groove length (size in the direction Z) of 50 mm, a groove width of 0.1 mm and a groove depth of 0.15 mm with the grooves being formed at intervals of 0.212 mm between adjoining grooves.
As illustrated in
At the same time as the formation of the second electrode 5, a plurality of electrode wirings (not illustrated) are formed on the second principal surface 1b. Several electrodes 5 formed on the inner wall surface of the groove 3, of all second electrodes 5, are electrically connected to the electrode pad 5a with some of the plurality of the electrode wirings. Several electrodes 6 formed on the inner wall surface of the groove 4 adjoining the groove 3, of all third electrodes 6, are electrically connected to the electrode pad 2a with electrode wirings not connected to the electrodes 5 of the plurality of the electrode wirings. However, the electrode pad 2a and the electrode pad 5a are electrically separated from each other.
Methods for forming the second electrode 5, the electrode pad 5a, the third electrode 6 and the electrode wirings on the second principal surface 1b may be the same as the method for forming the first electrode 2 on the first principal surface 1a as described in
An electric field is then applied between the electrode pad 2a and the electrode pad 5a to conduct a poling treatment to the lateral and bottom walls of the first groove 3. The main direction of poling is a direction indicated by the arrow 7 in
The poling treatment is conducted in such a state that the first piezoelectric substrate 1 has been heated as needed. For example, the electric field is applied in such a state that the first piezoelectric substrate 1 has been kept at 100° C. In order to prevent dielectric breakdown (creeping discharge) between electrodes due to the electric field when the first piezoelectric substrate 1 is subjected to the poling treatment, the poling treatment may also be conducted in such a state that the piezoelectric substrate 1 has been immersed in an insulating liquid (for example, silicone oil).
After the poling of the first piezoelectric substrate 1, an aging treatment is conducted as needed. Specifically, the first piezoelectric substrate 1 subjected to the poling treatment is held for a certain period of time in a state of being heated, thereby stabilizing the piezoelectric characteristics thereof. The aging treatment is conducted by, for example, leaving the first piezoelectric substrate 1 subjected to the poling treatment to stand for 10 hours in an oven of 100° C.
As illustrated in
The working of the second piezoelectric substrate 8 is conducted according to the same methods as in the working of the first piezoelectric substrate 1 as described in
As illustrated in
Upon the joining, the positions of the respective substrates are determined on the basis of a fifth mark M5 provided on the first support substrate 13 to join them. For example, when the second piezoelectric substrate 8 is joined, the mark M4 on the second piezoelectric substrate 8 is aligned with the mark M5. When the first piezoelectric substrate 1 is joined, the mark M2 on the first piezoelectric substrate 1 is aligned with the mark M5.
The first support substrate 13 favorably has a flexural rigidity higher than the second piezoelectric substrate 8 and first piezoelectric substrate 1 subjected to the grooving. The value of the flexural rigidity of the piezoelectric substrate after the grooving may be the flexural rigidity value of a bottom wall with the lowest flexural rigidity. The flexural rigidity of the bottom wall may be simply calculated from a material constant of the piezoelectric substrate and the shape of the groove.
The first support substrate 13 may be a flat plate. Since the flexural rigidity of the flat plate is determined by a material constant and a thickness of the plate, the flexural rigidity of the first support substrate 13 that is a flat plate can be simply calculated.
The piezoelectric substrates bonded to the first support substrate 13 may be worked and heated together with the first support substrate 13 in some cases in a post step for producing the liquid ejection head. Taking easiness of working in such a step and thermal expansion upon the heating into consideration, the first support substrate 13 is favorably composed of the same material as the piezoelectric substrate.
Thereafter, the second support substrate 15 is bonded so as to sandwich the piezoelectric substrates with the first support substrate 13. The material of the second support substrate 15 conforms to the first support substrate 13. The second support substrate 15 may be made unnecessary in some cases.
The joining of the piezoelectric substrate 1 to the support substrate or the joining between the piezoelectric substrates is conducted through, for example, a bonding layer 14. The bonding layer 14 includes a layer composed of, for example, a thermosetting resin. The thickness of the bonding layer 14 is, for example, 1 to 3 μm. Joint strength at a joining interface is 3 MPa or more. This strength can be simply realized by a commercially available adhesive. For example, the bonding layer 14 is applied on to the second principal surface 1b (or 8b) of the piezoelectric substrate 1 by a transfer method, and alignment is then made to conduct the joining under pressurizing and heating conditions.
A laminate 16 of the piezoelectric substrates obtained by the joining as described above is divided (not illustrated) as needed. By such dividing, a plurality of piezoelectric bodies 18 each having a desired pressure chamber length and a desired number of pressure chambers can be obtained.
In the piezoelectric body 18 illustrated in
The lateral wall, bottom wall and top wall of the pressure chamber 30 are mainly poled in thickness-wise directions (direction X and direction Y) thereof as indicated by arrows 7, 12. The second electrode 5 and fourth electrode 9 present on the inner wall surface of the pressure chamber 30 may be joined to each other to provide an individual electrode. Likewise, the first electrode 2, third electrode 6 and fifth electrode 11 present on the inner wall surfaces of the air chambers 40, 100 may be joined to one another to provide a common electrode. A drive signal (drive voltage) is applied between the individual electrode and the common electrode, whereby a piezoelectric action is caused, the lateral wall, bottom wall and top wall of the pressure chamber 30 are deformed by the piezoelectric action so as to be elongated or contracted, and an ink retained in the pressure chamber 30 can be ejected. This is what is called a Gould type piezoelectric body.
As illustrated in
Attention will now be paid to a portion surrounded by the dotted line D in
In order to form the wiring electrodes 19, 20, the arithmetic mean roughness Ra of the lateral surface 18a of the piezoelectric body 18 is first adjusted as illustrated in
The adjustment of the arithmetic mean roughness Ra can be conducted by using a method of corroding the lateral surface 18a with a liquid or a method by mechanical polishing. However, when the liquid is used, it is necessary to protect a substrate surface not intended to be roughened, so that a process becomes complicated. In addition, in the case of a ceramic substrate such as a piezoelectric substrate, the piezoelectric substrate may cause progress of microcracking and falling of crystal grain in some cases. Accordingly, the adjustment of the arithmetic mean roughness Ra is favorably conducted by mechanical polishing.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
The process illustrated in
The metal this film 22 connected to the electrodes 5, 9 on the inner wall surface of the pressure chamber 30 is the first wiring electrode 19 illustrated in
In this embodiment, as illustrated in
In this embodiment, as illustrated in
As described above, the surface roughness Ra of the lateral surface is adjusted to the range of 0.1 μm and more and 1.0 μm or less upon the formation of the wiring electrodes on the lateral surface of the piezoelectric body having the ejection orifice and the opening by the lift-off method, whereby the process failure such as stripping of the resist pattern or the defect of the wiring electrode can be reduced.
A process for producing a liquid ejection head according to a second embodiment will be described with reference to
In this embodiment, a seed layer is deposited on a lateral surface and on the inner wall surfaces of a pressure chamber and an air chamber using a pattern of a dry film resist 21 as a mask by the lift-off method described in first embodiment. Thereafter, the pattern of the dry film resist 21 is removed, and a metal plating film (wiring electrode) is further formed on the seed layer by a plating method. Details will hereinafter be described.
A piezoelectric body 18 is first provided according to the procedure illustrated in
As illustrated in
In this embodiment, the wiring electrodes are formed by the two stages of the formation of the seed layers and the formation of the plating films as described above. The merits thereof are as follows. First, since the seed layers may be relatively thin, they are more easily lifted off than a thick metal film. In particular, the size and degree of burrs which may be produced in the lift-off step become small as the metal film is thin. As a result, a pattern of the seed layer can be formed with high precision. Second, a relatively thick wiring electrode can be formed by plating. When there is need to lower the resistance of the wiring electrode in particular, a large film thickness can be simply realized by thickening the plating film. If it is attempted to obtain a thick metal film only by the lift-off, there is a possibility that pattern precision may be deteriorated in association with burrs or the like. On the other hand, when a plating film is added on to the thin seed layer, the pattern precision of the wiring electrode is hard to be deteriorated even when the thickness of the plating film is made relatively thick. Third, the plating film is grown in a thickness-wise direction, and at the same time grown even in a lateral direction, so that break or discontinuity of the wiring electrode which may be caused at an interface between piezoelectric substrates can be easily prevented.
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. 2012-140698, filed Jun. 22, 2012, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2012-140698 | Jun 2012 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5289209 | Suzuki et al. | Feb 1994 | A |
5622611 | Marks et al. | Apr 1997 | A |
5685491 | Marks et al. | Nov 1997 | A |
6174051 | Sakaida | Jan 2001 | B1 |
7156505 | Suzuki | Jan 2007 | B2 |
7591544 | Shimada | Sep 2009 | B2 |
7695103 | Nagashima | Apr 2010 | B2 |
8784591 | Wang | Jul 2014 | B2 |
20020191055 | Shingai et al. | Dec 2002 | A1 |
Number | Date | Country |
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2010-181813 | Aug 2010 | JP |
Number | Date | Country | |
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20130340219 A1 | Dec 2013 | US |