Patent Grant
8438729
1. Field of the Invention
The present invention relates to a liquid discharge head for discharging a liquid and a producing method therefor, and more particularly to an electrode pad of a substrate for the liquid discharge head.
2. Description of the Related Art
There is already known a method for producing an ink jet recording head, utilizing a semiconductor manufacturing process and enabling electrical connection of an element substrate without dust deposition, for example in a clean room (Japanese Patent Application Laid-open No. 2005-199701). In this producing method, an electrode pad of the element substrate is formed by an electrolytic plating.
In such producing method, an element substrate is prepared at first, then a gold bump for an electrode pad is formed by an electrolytic plating, and a flow path wall forming member is provided thereafter. In the step of forming the element substrate, a heater, an electrode pad for external connection, and an electrode pad for testing are formed on the substrate. As the gold bump forming step involves a chemical treatment, the flow path wall forming member is to be provided after the gold bump is formed.
The gold bump formation for the electrode pad by electrolytic plating is executed by the following steps in succession, which are an undercoat layer forming step with a high-melting point metal material such as TiW, an Au (undercoat seed gold) film forming step, a resist coating/exposure/developing step, a gold deposition step by an electrolytic plating, a resist stripping step, an etching step for the undercoat seed gold, and an etching step for the undercoat layer of high-melting point metal material.
In the manufacture of an ink jet recording head, in addition to an external connection electrode pad for exchanging electrical signals with the exterior, a test electrode pad to be used as an electrode for testing a circuit formed on the head substrate may also be formed on the substrate. In the above-described manufacturing process, however, in the case that the test electrode pad is not gold plated, the exposed test electrode pad (made of aluminum or an aluminum alloy) may be corroded at the etching of the undercoat seed gold, or of the undercoat layer of high-melting point metal material.
The test electrode pad is therefore plated with gold in order to avoid such erosion.
In the following, a process of gold plating on the test electrode pad will be described with reference to
On an aluminum wiring 10b of the test electrode pad 8, a gold bump 18b is formed, and an adhesive layer 2 utilizing a resinous material is laminated thereon. Then, a flow path wall forming member 3, having an ink flow path therein, is provided so as to cover the upper part thereof with photosensitive resin. The test electrode pad 8, though no longer necessary after the formation of the flow path wall forming member 3, has a structure connectable to the circuit and is in an electrically conductive state during the use of the ink jet recording head. Therefore, the test electrode pad 8 is insulated by the adhesive layer 2. Also on the aluminum wiring 10a of the external connection electrode pad 7, a gold bump 18a is formed, which is connected to an external electrode member 15 and is then sealed by a sealant 16.
In such structure, however, the flow path wall forming member 3 may be partly peeled by a thermal contraction at the manufacture or the insulation by the adhesive layer 2 on the test electrode pad 8 may become insufficient, so that the aluminum wiring 10b may come into contact with the ink and may be corroded. Such corrosion of the aluminum wiring 10b further induces a corrosion spreading to a wiring portion which is satisfactorily insulated.
An object of the present invention is to provide a liquid discharge head which is improved in an insulating property of a test electrode pad to liquid and is thus capable of suppressing a corrosion in an aluminum wiring connected to the test electrode pad and improving the reliability, and a producing method therefor.
Another object of the present invention is to provide a method for producing a liquid discharge head including a liquid discharge energy generating element for generating a liquid discharge energy, a liquid discharge port, a liquid flow path, an electric circuit for driving the liquid discharge energy generating element, a first electrode pad for exchanging electrical signals with the exterior and a second electrode pad for testing the electric circuit, the method including: preparing a substrate provided with a first wiring layer for forming the first electrode pad and a second wiring layer for forming the second electrode pad, forming an insulating film on the substrate so as to expose the first wiring layer and to cover the second wiring layer, forming a metal film by an electroless plating method on the surface of the first wiring layer, and stripping the insulating film.
Still another object of the present invention is to provide a liquid discharge head, which has a liquid discharge energy generating element for generating a liquid discharge energy, a liquid discharge port for discharging a liquid, a liquid flow path communicating with the liquid discharge port, and an electric circuit for driving the liquid discharge energy generating element, and in which the liquid is discharged from the liquid discharge port by the liquid discharge energy, the liquid discharge head including a first electrode pad which is formed by providing an electroless nickel-phosphorus layer, an electroless substituted gold layer and an electroless reduced gold layer in this order on the first wiring layer and which serves for exchanging electrical signals with the exterior, a second electrode pad formed by the second wiring layer and serving for testing the electric circuit, and a flow path wall forming member formed on the second wiring layer across an adhesive layer and serving to form the liquid flow path.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
In the following, an exemplary embodiment of the present invention will be described, taking an ink jet recording head as an example of the liquid discharge head, with reference to the accompanying drawings.
The ink jet recording head (liquid discharge head) includes, on a silicon substrate 1 as a substrate, heat generating elements 4 as ink discharge energy generating elements (liquid discharge energy generating elements) in which such elements are arranged with a predetermined pitch in a linear array and such linear array is formed in two rows. On the silicon substrate, a flow path wall forming member 3 formed with a photosensitive resin and an adhesive layer 2 of a polyetheramide resin for adhering a lower surface thereof are formed with a same shape. On the substrate, a passivation film 11 is formed in advance.
Lateral walls of the flow path and an upper wall of the flow path have a same photosensitive resin. In an upper part of the flow path, an ink discharge port (liquid discharge port) 5 is provided above each heat generating element 4. An ink supply aperture (liquid supply aperture) 6 is formed by an anisotropic etching, utilizing a SiO2 film as a mask, from a rear side of the silicon substrate (a side thereof on which the ink discharge energy generating elements are provided being defined as a top side). The ink supply aperture (liquid supply aperture) 6 is opened between two arrays of the heat generating elements 4.
In such ink jet recording head, a pressure generated by the heat generating element 4 is applied to the ink (liquid), filled into the ink flow path through the ink supply aperture 6. Thus the ink discharge port 5 discharges an ink droplet to deposit the ink onto a recording medium, thereby forming a record. The ink discharge port is provided in plural units, and the heat generating element is provided corresponding to each ink discharge port. Also an ink discharge port may be provided corresponding to plural heat generating elements.
In the following, a producing method for the ink jet recording head, as an exemplary embodiment of the liquid discharge head, utilizing an electroless plating will be described with reference to
A silicon substrate 1, having aluminum wirings 10a, 10b for constituting electric circuits for driving plural heat generating elements 4 for generating ink discharge energy, is prepared. The aluminum wiring 10a is a first wiring layer formed in the position of the external connection electrode pad 7, and the aluminum wiring 10b is a second wiring layer formed in the position of the test electrode pad 8. Either aluminum wiring may be formed with aluminum or an aluminum alloy.
On a surface of the silicon substrate 1 bearing the aluminum wirings, a P—SiN film is formed as a passivation film 11. Through-holes 20a, 20b for exposing the aluminum wirings are formed in positions of the passivation film 11, respectively corresponding to the external connection electrode pad 7 and the test electrode pad 8.
Then, as shown in
The screen printing enables an easy patterning of the resist film 12 as a protective layer having hole through-hole 17. The screen printing can be executed utilizing an ordinary technology, such as formation of a wiring on a printed circuit board or printing of a sealant on a glass substrate for liquid crystal display. Also, in place for the screen printing, a photolithographic patterning utilizing a photosensitive resist, containing a photosensitive cyclized rubber as a principal component, may be utilized.
Then, on the exposed portion of the aluminum wiring 10a of the external connection electrode pad 7, a metal film is formed by an electroless plating method.
The metal film is formed in the following manner. At first, as shown in
Then, as shown in
In this operation, the aluminum or aluminum alloy 10b of the test electrode pad 8, being covered by the resist film 12 containing the cyclized rubber as the principal component and serving as a protective layer, is prevented from corrosion by sulfurous acid. Stated differently, the conductive portions which may cause an electroless plating reaction are covered, excluding the portion where the metal film is to be formed by the electroless plating, by the resist film 12 whereby such portions are protected from being corroded at the plating operation.
Then, as shown in
In this operation, as in the formation of the electroless substituted gold layer 13, the aluminum or aluminum alloy 10b of the test electrode pad 8, being covered by the resist film 12 containing the cyclized rubber as the principal component and serving as a protective layer, is prevented from corrosion by the reducing gold sulfite bath.
In this manner, the electroless reduced gold layer 14, the electroless substituted gold layer 13 and the electroless nickel-phosphorus layer 9 are formed from above to below only on the external connection electrode pad 7. Thus a metal film is formed on the aluminum wiring 10a, thus completing the gold bump 18a.
Then, as shown in
Thus, the silicon substrate 1 will have a cross-sectional structure, in which so-called electroless nickel-phosphorus/gold-plated bumps are formed on the external connection electrode pads 7 while the array of the test electrode pads 8 for testing the electric circuits do not have the bumps but maintains planarity. (
Then, as shown in
Thus, in the present exemplary embodiment, the second wiring layer (aluminum wiring 10b) is covered and protected by the resin in executing the electroless plating method.
Therefore, when the adhesive layer 2 for adhering the flow path wall forming member 3, including the ink flow path therein, is formed on the silicon substrate 1, the aluminum wiring 10b can be covered by the resin for forming the adhesive layer 2, without requiring another covering treatment. However, such process is not restrictive, and the effect of the present exemplary embodiment of improving the insulating property for the test electrode pad can be expected even in case of covering the aluminum wiring 10b with another resin.
The surface irregularity in the part of the test electrode pad 8 can be maintained at about the thickness of the passivation film 11 at maximum. Therefore, the surface irregularity can be easily made smaller. Therefore, polyetheramide resin follows such surface irregularity, and can maintain a satisfactory insulating property for the test electrode pad 8. In such state, the polyetheramide resin as the adhesive layer 2 can be patterned with a uniform film thickness.
Then, as shown in
In this stage, the sealed area for the external connection electrode pad 7 for connection with an external electrode is clearly separated from the test electrode pad area which is covered by the polyetheramide resin as the adhesive layer 2 and by the covering photosensitive resin constituting the flow path wall forming member 3.
Then, as shown in
The processes described above provides a construction in which the external connection electrode pads 7 are protected by the sealant while the flow path wall forming member 3, serving as a nozzle material (material to be used for forming the ink flow path), maintains planarity and serves as an insulating film for the array of the test electrode pads 8. In this manner, an ink jet recording head is completed.
In the prior process, in the case that the polyetheramide resin as the adhesive layer 2 is coated after the formation of the bump 18b as shown in
Furthermore, the present exemplary embodiment, utilizing electroless plating instead of electrolytic plating, enables to reduce the investment in the facility, thereby allowing to produce an ink jet recording head of a lower cost.
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 priority from Japanese Patent Application No. 2006-064167 filed on Mar. 9, 2006, which is incorporated hereinto by reference.
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