JPH0445951A - Manufacture of on-demand type ink jet print head - Google Patents

Abstract

PURPOSE:To obtain the above on-demand type ink jet head which can be miniaturized with a high density and made at a low cost by arranging a plurality of piezoelectric device blocks on a large size substrate constituted of an insulating substrate having an electric lead formed thereon, processing a large number of necessary piezoelectric device shapes at a time by means of mechanical cutting or chipping or etching, and cutting off the large size substrate at every head unit. CONSTITUTION:A plurality of piezoelectric device blocks 34 constituted of piezoelectric materials and conductive materials layered alternately and baked are arranged on a large size substrate constituted of an insulating substrate 1 having electric leads formed thereon. A large number of necessary piezoelectric device shapes are processed at a time by means of mechanical cutting or chipping or etching, a plurality of ink jet units are formed on the same substrate 1, and the large size substrate is cut at every head. Further, cutting of the piezoelectric device block and forming of electrode pattern on the substrate are performed for a plurality of the piezoelectric device blocks and electrode patterns simultaneously by a wire saw.

Description

Detailed Description of the Invention [Industry - Second Field of Application] The present invention causes liquid ink to fly as droplets or mist when print data is input, and the ink droplets or mist to print on recording paper. The present invention relates to an on-demand inkjet printhead that forms dots on an inkjet printhead. Widely used as computer output terminals and color printers.

[Conventional technology]

On-demand inkjet print heads can be broadly divided into three types.The first type has a lid at the tip of the nozzle that instantly vaporizes the ink, and the expansion pressure during vaporization creates ink droplets. The second type is a so-called Bubble Shera L-514, which is made to fly, and the second one is a piezoelectric element that is deformed by a signal in a container that forms an ink reservoir, and the pressure generated during deformation causes ink to fly as droplets. In the third type, a piezoelectric element is disposed in the ink reservoir so as to face the nozzle, and the expansion and contraction of the piezoelectric element generates dynamic pressure in the nozzle area to cause ink droplets to fly.

The on-demand inkjet print head of the third type in Section 2 has a plurality of nozzle openings formed on the wall of a container constituting an ink tank, as shown in E1 Patent Publication No. 8953/1983. At the same time, piezoelectric elements are arranged so that the nozzle openings face each other and their expansion and contraction directions match.

This print head applies a print signal to a piezoelectric element to cause the piezoelectric element to expand, and the dynamic pressure of the ink generated at this time causes ink droplets to fly out from a nozzle to form dots on printing paper.

In this type of print head, it is desirable that the droplet formation efficiency and flying force be high. However, since the expansion/contraction rate per unit length and unit voltage of piezoelectric elements is extremely small, it is necessary to apply a high voltage to obtain the flying force required for printing, which complicates the drive circuit and electrical insulation measures. There is a problem of becoming

In order to solve this problem, the electrode and pressure 'F! Piezoelectric elements for inkjet printheads have been proposed in which materials are sandwiched together. According to this piezoelectric element, since the distance between the electrodes can be made as small as possible, it is possible to increase the voltage of the drive signal.

[Problem to be solved by the invention]

However, since ink sheet heads using such piezoelectric elements are manufactured for each head unit, there are problems in that costs are high and miniaturization is not easy. The present invention aims to solve the two problems and provides a method for manufacturing an on-demand inkjet head that is small in size, capable of increasing density, and is inexpensive.

[Means to solve the problem]

The method for manufacturing an on-demand inkjet print head of the present invention includes piezoelectric element blocks in which IE1vi abrasive sheet materials and conductive materials are alternately laminated and fired.
A plurality of piezoelectric elements are placed on a doll substrate consisting of an electrical lead portion formed on an insulating substrate, and a plurality of piezoelectric elements are processed simultaneously by mechanical cutting, cutting, or etching. Step 1 is to form the following inkjet units 1 to 1 on the same substrate Jz and cut the doll substrate for each head. Further, 1) the cutting of the piezoelectric element block No. 11 and the formation of the electrode pattern on the substrate-1- are simultaneously performed for a plurality of piezoelectric element blocks or more using a wire saw.

〔Example〕

FIG. 1 shows an example of an on-demand inkjet print head according to the present invention, and FIG.
) is a sectional view, and FIG. 1(b) is a view seen from above with the nozzle plate 7 removed. The piezoelectric element 4 is attached to the substrate 1 and the housing 2 by strong adhesive or brazing 15.
Fixed. The internal electrodes of the piezoelectric element are alternately formed in the opposing force direction to the cavity 11 so as to vibrate W in the d33 direction. The external electrodes of the piezoelectric element are
Lead electrode 1 formed on the substrate via an adhesive or solder (= J or conductive material)
It is electrically connected to 4. Furthermore, the gaps between the rows of piezoelectric elements are filled with an adhesive or filler whose Young's modulus is 115 or less than the Young's modulus of the piezoelectric elements. Further, the cavity portion is partitioned with a material similar to the material used to fill the gaps between the piezoelectric element rows, and each element has an independent cavity. The side surface of the cavity facing the piezoelectric element is formed of a partition block 3 made of ceramic, plastic, metal, or the like, and is fixed to the substrate 1. The on-demand type inkjet print head having the above-mentioned 11LI configuration will be described in detail while following the manufacturing process.

FIG. 2 shows the substrate 1. FIG. Each broken line a in the figure indicates one unit of the head so that a large number of pieces can be taken out at the same time. The number of sheets to be produced is determined by the number of nozzles in each head and the capacity of the manufacturing equipment. This substrate is made of insulating rice grains,
A ceramic such as alumina, a tunoras substrate, or the like is used. In the figure, reference numeral 21 denotes a through hole for ink introduction, which is penetrated through the back surface by laser or molding. 22 is a conductive paste for a conductive electrode created by firing, and is generally A, g/Pd type, A u / P d type, Pt/Pd type.
system is used. Of course, other conductive pastes can also be used, and the thickness is preferably from 3 μm to 20 μm.

The partition block 3 and the piezoelectric element block are glued to this. As the adhesive, a resin adhesive such as epoxy or silicone adhesive, Ag wax, or the like is used. FIG. 3 is a diagram in which the block 3 and the piezoelectric element block 34 are bonded onto a unit substrate. At this point, the electronic elements 34 are not divided into each array and are in a block state. This piezoelectric element block has external electrodes covering the entire surface of the upper and lower surfaces, respectively. Further, numeral 31 in the figure is a void that will form a cavity in the future. This void is filled with a film that can be later covered, such as a resist film.Alternatively, a resist for photolithography may be poured and solidified to fill the void.The piezoelectric element block is When fixing it to the substrate, the free ends on the cavity side and the opposite side need to be fixed with a high-strength member that has the same Young's modulus as the piezoelectric element.This allows the amount of expansion and contraction of the piezoelectric element to be the same as the free end on the cavity side. Therefore, in this embodiment, the housing (FIG. 1, 2), which will be described later, is made of a material with a high Young's modulus such as ceramic, and is placed in close contact with the fixed end of the piezoelectric element. An adhesive having a high Young's modulus was used at a portion 8 in FIG. 1 between the piezoelectric element and the housing 2 and the piezoelectric element. For example, it is a glass frit material, a ceramic paste material, etc., and is fixed by firing. Here, the piezoelectric element will be explained in detail.

Fig. 3 (IN indicates a piezoelectric element block; i'140. 40. 40. . . . in the figure is
Each is a conductive layer constituting one electrode, and 42
, 42. 42. . . . is a conductive layer constituting the other electrode, and each conductive layer is alternately arranged parallel to each other and piezoelectric feeds 44, 44 . . . . in a sandwich manner, and one electrode 30. 30. 30
. . . The conductive layer 42. 42. 42.・・・
. . . The N4 conductive layer is configured to be exposed on the other side. A conductive layer is formed on the exposed surface of these electrodes, and the conductive layers are electrically conductively connected in parallel, and each piezoelectric element is connected to the sleeve 1-46.46.46.
Separate by

In this type of layered construction, a suitable piezoelectric element material, such as I-T I4, a composite perovskite ceramic based on titanate and lead zirconate, is made into a green sheet, and the monthly rate of internal electrodes is printed on the surface of this green sheet using a printing method. Laminate the required number of sheets alternately.

In this way, a predetermined number of sheets are formed, and pre-drying and sintering are performed to obtain a sintered body. This state is shown in FIG. 4(a). Conductive materials 47 and 48 are respectively applied to the exposed surfaces of the rectangular parallelepiped and where the internal electrodes 42 and 40 are exposed, and then dried or fired to form the structure shown in FIG. 4(b). This is a piezoelectric element block, which is ultimately divided into arrays by making slits 46 for use.

Independent lead members are connected to the conductors 71iN47 connecting one electrode of each element configured in this way, and the other electrodes are connected to each other. A common lead member is connected to the conductive layer 48 connecting the It electrodes. As a result, when an electric signal is applied between the independent lead member and the common lead member, the piezoelectric element to which the signal phase is selectively applied by the independent lead member will be connected to the same electrode between the electrodes via the conductive layer. Since voltages are applied simultaneously, the piezoelectric feed between the electrodes expands simultaneously, the displacements of each layer are added up, and the free end side is displaced in the axial direction. Of course, since each conductive layer is formed extremely thin, an extremely small voltage is required to achieve maximum elongation.

This piezoelectric element block is electrically connected to the electrode on the substrate 1 through a conductive agent. There are various conduction methods, but generally Ag
Use brazing material or conductive paste. Also, a metal bowl may be pressed between the substrate and the piezoelectric element. The conductive space does not need to be the entire electrode surface, it is sufficient that a certain portion is properly conductive. However, as mentioned above, since the piezoelectric element block is used by cutting, it is necessary to take care to ensure continuity for each array.

Next, the thing in this state is -dotted chain line A- in Fig. 5(a).
Cut a slit in the direction of A' using a dicing saw or wire saw. At this time, cutting is performed to a depth of 10 to 50 μm from the substrate surface so that the substrate surface electrode 22 is also divided. Of course, the pitch may be any desired value.

For example, if you are making a 300DP■ head, it is 15cm per side.
At 0DPI, the pitch is 169.3 μm. At this time, the actual cutting was very popular! i (because it is done in board units, the number 1
0 head units can be cut at -degrees.

Moreover, it is only necessary that the cutting pitch be accurate, and this is the major point that makes this method Ansen I.

FIG. 5(b) is a top view of the cutting process, and AA' is the cutting line.

D in the figure is the outermost dummy that is not used as a piezoelectric element. Due to this D, the adhesion accuracy of the piezoelectric element block and the partition block to the substrate is not so important. Therefore, it is desirable that the piezoelectric element array outside the circle of each unit be a dummy. In some cases, this dummy can be treated as part of the housing. The housing shown in FIG. 1 and 2 is installed so as to surround the piezoelectric element thus cut. The housing 2 is strongly fixed to the substrate 1 and the opposite end surface of the piezoelectric element stand array on the cavity side. It is desirable that the adhesive used here has as large a Young's modulus as possible.

Next, the slit space created by cutting with a wire saw or the like is filled with a resin-based resin and hardened.

Epoxy-based, silicone-based, etc. are suitable resin-based feeds, but there is no need to be particular about these as long as the cured film has appropriate hardness, adhesion, and strength.

Next, the electrodes formed on the two sides of each piezoelectric element array are made conductive and the common electrode is taken out. The electrodes on the substrate side and the lower surface of each piezoelectric element array are already configured as individual lead electrodes, and the - side is electrically connected to the common electrode terminal on the substrate side by using, for example, the outer wall of the housing. FIG. 6(a) shows one example, in which a conductive path is formed on the surface of the housing using conductive paste. In the figure, 61 is the housing surface conductive path, and the upper surface electrode of the piezoelectric element array and the conductive paste 62
It is conducting. Further, the conductive path 61 is connected to the common electrode 1 on the substrate.
3 are electrically connected through conductive paste 63. There are various methods of electrical connection, such as using a flexible cable or wire bonding.

FIG. 6(b) shows another example of the conduction method. In the figure, housings 2a and 2b have a structure in which the electrodes 61 are formed and then the housings 2b are laminated. The nozzle plate may be bonded using the upper surface of 2b as a reference, and a method such as wire bonding 68 that does not protrude in both directions may be used to conduct the piezoelectric element 4 and the electrode 61. In addition, 69 is a conductive shrine for individual lead electrodes. Finally, the soluble resin in the space filled to form the cavity (the space shown in FIG. 2, 31) is removed. If it is a positive photoresist, it is suitable to remove it with acetone or aqueous ammonia, and if it is a negative photoresist film, it can be removed by spraying a heated strong acid aqueous solution. The surface of the head unit thus formed may be covered with the resin material 5 up to the top surface of the piezoelectric element. but,
In this state, the surface is uneven and the nozzle plate cannot be firmly fixed to the two surfaces. Therefore, the upper surface of the resin including the housing is ground to make it smooth.

Grinding is performed using a surface grinder, lapping machine, or dicing saw. Thereafter, the nozzle plate is fixed to the entire resin material surface and the surface of the spacer portion 6 using adhesive or melt bonding. Of course, there is a one-to-one correspondence between the upper hole of the cavity forming part and the nozzle of the nozzle plate. In this embodiment, a method has been described in which the cavities are arranged in rows with the partition blocks 3 in between, but it goes without saying that the number of nozzle openings may be in one row, or it is easy to arrange them in four rows.

In the print head configured in this way (Fig. 1), when an electric signal is applied to the piezoelectric element 4 via the cable 12, the piezoelectric cables 7-4, 4, 4, . . . Since it extends in the stacking direction of the electrodes, the free end of the piezoelectric element pushes out the ink on the front side towards the spacer 6.

As a result, the ink enters the nozzle opening 9 under dynamic pressure, becomes an ink droplet, flies in the external space, and forms a dot on the printing paper.

When the electric signal is no longer applied, the piezoelectric element contracts to its original state, and ink flows into the gap between the spacer 6 and the piezoelectric element 4 in preparation for the generation of the next ink droplet.

Incidentally, ink for inkjet printers may be insulative or conductive.

Especially when using conductive ink, the 7! !
The poles must be completely sealed from ink. In order to solve this problem, it is desirable to form layers of piezoelectric material on both free ends that do not participate in the piezoelectric action, such as layer a in FIG. 8. Furthermore, it is also a good method to dip the entire piezoelectric array in an insulating resin solution, for example, a polyimide=15- solution, before pouring the resin powder 5 between the slits, and to coat the surface of the piezoelectric element with a thin insulating film.

〔Effect of the invention〕

As described above, the inkjet print head with the structure and manufacturing method of the present invention can be manufactured in large numbers at the same time, is very inexpensive, and is an excellent head with high density. . Miniaturization, high density, and low cost can be achieved at the same time.

[Brief explanation of the drawing]

FIGS. 1A and 1B are cross-sectional views showing the configuration of an on-demand inkjet print head according to a first embodiment of the present invention, respectively. FIG. 2 is a diagram showing an embodiment of a substrate used in the apparatus of FIG. 1. FIG. 3 is a perspective view showing the manufacturing process of the device shown in FIG. 1. FIGS. 4(a) and 4(b) are explanatory diagrams showing a method for manufacturing and using a piezoelectric element used in the apparatus shown in FIG. 1. FIGS. 5(a) and 5(b) are explanatory diagrams showing a method of cutting piezoelectric element arrays. FIG. 6(aL) (b) is a diagram showing two examples of electrical connection methods between the piezoelectric element and the common electrode. 1... Substrate 4... Piezoelectric element 34... Piezoelectric element block Applicant Seiko Epson Co., Ltd. Agent B↑Science Kizobe Suzumoto and 1 other person (b)

Claims (2)

[Claims] (1) A plurality of piezoelectric element blocks made by laminating and firing piezoelectric material sheets and conductive materials in layers, respectively, are arranged on a large substrate formed by forming electrical lead portions on an insulating substrate, It is characterized by simultaneously processing a large number of required piezoelectric element shapes by mechanical cutting, cutting, or etching, forming a plurality or more inkjet units on the same substrate, and cutting the large substrate into head units. A method for manufacturing an on-demand inkjet print head. (2) The method of manufacturing an on-demand inkjet print head according to claim 1, wherein the cutting of the piezoelectric element blocks and the formation of electrode patterns on the substrate are simultaneously performed for a plurality of piezoelectric element blocks or more using a wire saw.