JP4507573B2 - Inkjet printhead manufacturing method - Google Patents

Description

  The present invention comprises a nozzle for ejecting ink, a pressure chamber for applying pressure to the ink, and a pressure generating means such as a piezoelectric element for changing the pressure in the pressure chamber, and a signal applied to the pressure generating means The present invention relates to an inkjet head that ejects ink by changing its volume.

  In a conventional inkjet printhead, at least a part of a connection region between a laminated piezoelectric element fixing plate made of a conductive metal and an end of the laminated piezoelectric element connected to the insulating plate is insulated, and the laminated piezoelectric element made of the conductive metal is fixed. One electrode of the flexible cable provided on the plate and the individual electrode of the laminated piezoelectric element are electrically connected by a conductive adhesive, the laminated piezoelectric element fixing plate made of the common electrode of the laminated piezoelectric element and the conductive metal, and Conductive conduction to the other electrode of the flexible cable with a conductive adhesive, and the conductive portion of the individual electrode of the flexible cable is exposed, and the portion is bonded to the individual electrode side of the laminated piezoelectric element with a conductive adhesive or the like. (For example, see Patent Document 1).

  In the following, a connection processing procedure of a joint portion between a plurality of multilayer piezoelectric elements 15 of the prior art and a conductive multilayer piezoelectric element fixing plate 16 that fixes the multilayer piezoelectric elements 15 will be described.

  First, a laminated piezoelectric element rod is installed on a conductive laminated piezoelectric element fixing plate 16 and fixed with an insulating adhesive or the like. Thereafter, a conductive adhesive is applied to the laminated piezoelectric element 15 at the tip of the portion 17-b1 in which the individual electrode 17-b of the flexible cable 17 is exposed only at the junction with the external electrode 15-a of the laminated piezoelectric element 15. Join with etc. The flexible cable 17 has a structure in which a plurality of individual electrodes 17-b and a common electrode 17-c are covered with a heat-resistant and insulating polyimide film or the like.

  Thereafter, using a dicing saw, a wire saw or the like, the laminated piezoelectric element rod is cut and divided so as to correspond to each of the individual electrodes 17-b of the flexible cable 17. At this time, the relationship between the width of the individual electrode 17-b of the flexible cable 17 and the width of the laminated piezoelectric element 15 after the division processing is “laminated piezoelectric element width> individual electrode width” so that the pitch error of the division processing can be absorbed. It has become. Each of the divided laminated piezoelectric elements 15 corresponds to one of the pressure chambers 3. Further, the other end of the flexible cable 17 is connected to an external drive circuit.

  In this way, the laminated piezoelectric element 15 is electrically connected to the laminated piezoelectric element 15 via the flexible cable 17 on the conductive laminated piezoelectric element fixing plate 16.

  On the individual electrode side, the individual electrode 17-b of the flexible cable 17 is electrically connected to the external electrode 15-a of the laminated piezoelectric element 15 by the conductive adhesive 22 and the like, and the common electrode 17-c side is electrically connected to the laminated piezoelectric element 15 and the above-mentioned conductor. The laminated piezoelectric element fixing plate 16 made of a conductive metal is directly connected by a conductive adhesive 22 or the like, and further, the flexible piezoelectric element 17 and the laminated piezoelectric element fixing plate 16 made of a conductive metal are electrically connected. The structure is such that it is conducted by the adhesive 22 or the like.

  By adopting such a configuration, it is not necessary to pattern electrodes on both the individual electrode side and the common electrode side on the laminated piezoelectric element fixing plate 16, and further, by using a general-purpose conductive metal plate or the like, The material cost is also low, and the machinability of the end face and the positioning hole for fixing the laminated piezoelectric element is improved, so that it is possible to provide inexpensive parts. When the laminated piezoelectric element fixing plate is made of stainless steel, the same performance as that of an ink jet print head using a ceramic plate laminated piezoelectric element fixing plate according to the prior art can be obtained.

JP 2003-72066 A

  However, in the case of the above-described configuration, when the exposed portion is installed on the individual electrode in order to join the flexible cable to the individual electrode of the laminated piezoelectric element, the exposed portion of the thin thickness of several tens of microns is not electrically conductive. Careful work is required so as not to hinder the mounting with the agent, handling is complicated, workability is poor, and man-hours are high.

  The present invention solves the above-described conventional problems, and an object of the present invention is to provide an inkjet printhead that is easier to manufacture and less expensive.

In order to solve the above problems, in the present invention, a plurality of pressure chambers for storing ink, nozzles communicating with the pressure chambers, a diaphragm that forms part of the wall surface of the pressure chamber, and an adhesive fixing to the diaphragm A laminated piezoelectric element facing the pressure chamber, having a common electrode on one side and an individual electrode on the other side, and generating pressure fluctuations in the pressure chamber by application of an electrical signal; and ink in the pressure chamber a restrictor for supplying a common ink supply path for supplying ink to a plurality of the pressure chamber communicates with the restrictor, and the conductive holding a plurality of the laminated piezoelectric element laminated piezoelectric element fixing plate, said in the manufacturing method of the ink jet printhead that consists of a flexible cable having an individual electrode and a common electrode which conducts each corresponding to the individual electrode and the common electrode of the laminated piezoelectric element,
Forming a front end set that serves as a flow path for ink flowing into the pressure chamber through the restrictor from the common ink supply path ;
Forming a laminated piezoelectric element set having the flexible cable and a plurality of the laminated piezoelectric elements on the laminated piezoelectric element fixing plate ;
Forming an ink jet print head by combining the front end group and the laminated piezoelectric element group; and
Furthermore, the step of forming the laminated piezoelectric element set includes:
(A) a step of bonding and fixing one or a plurality of laminated piezoelectric element rods to the laminated piezoelectric element fixing plate;
(B) The flexible cable in which the electrodes at the tips of the individual electrodes are connected by an insulating material is installed on the laminated piezoelectric element fixing plate, and the individual electrodes of the flexible cable and the external electrode surface of the laminated piezoelectric element rod continuity and, forming respective conduction between the common electrode of the flexible cable and the laminated piezoelectric element fixing plate,
(C) dividing the laminated piezoelectric element rod and the insulating material together to form the laminated piezoelectric element;
Tona and said Rukoto.

In the manufacturing method of the ink jet print head of the present invention, the insulating material and wherein the polyimide film der Rukoto.

  According to the present invention, the conductive layer is connected to the laminated piezoelectric element via the flexible cable on the conductive laminated piezoelectric element fixing plate, thereby patterning both surfaces of the laminated piezoelectric element fixing plate as electrodes on the individual electrode side and the common electrode side. It is not necessary to secure the workability that the flexible cable can be easily attached, and when installing the flexible cable necessary for conduction to the individual electrodes of the laminated piezoelectric element, the individual conductive parts of the flexible cable are insulative. Because of the state of being connected with the material, it is difficult to mount and complicated, and the workability is improved, and the handling becomes easier than before.

  Therefore, the number of work steps is reduced, and an inexpensive ink jet print head can be provided.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a perspective view showing a component structure of an ink jet head showing an embodiment of the present invention.

  FIG. 2 is a cross-sectional view showing the assembly configuration of the inkjet head according to the embodiment of the present invention.

  As shown in the figure, an orifice plate 2 having a plurality of nozzles 1 is formed. The processing accuracy of the opening shape of the nozzle 1 greatly affects the ink ejection characteristics of the ink jet print head. In order to keep the nozzle accuracy variation low among the plurality of nozzles 1, the manufacturing method of the orifice plate 2 is required to have high processing accuracy, and is formed by nickel electroforming, precision press processing of a stainless steel plate, laser processing, or the like.

  A chamber plate 4 in which the pressure chamber 3 is formed, and a restrictor plate 6 in which a restrictor 5 that controls the amount of ink flowing into the pressure chamber 3 by communicating the common ink supply path 12 and the pressure chamber 3 are provided. The chamber plate 4 and the restrictor plate 6 are manufactured by a stainless steel etching method.

  The diaphragm plate 9 is formed with a vibration transmitting portion 7 for efficiently transmitting the pressure of the laminated piezoelectric element 15 to the pressure chamber and a filter portion 8 for removing foreign matters in the ink flowing into the restrictor 5 from the common ink passage 12. Is provided. The filter portion 8 has innumerable fine holes smaller than the hole diameter of the nozzle 1. The diaphragm plate 9 is a thin plate made of stainless steel, nickel, or polymer material, and is made by an etching process, an electroforming process, a laser process or the like.

  In addition, when the vibration transmitting unit 7 and the laminated piezoelectric element 15 are fixed with the adhesive 24, the support plate 11 on which the frame 10 that defines that the adhesive protruding from the adhesion portion spreads on the vibration transmitting unit 7 is formed. Prepare. The support plate 11 is made by a stainless steel etching method or the like.

  The housing 13 has a common ink passage 12 and a housing 13 provided with an opening 13-a larger than the laminated piezoelectric element set 21 fixed to the laminated piezoelectric element fixing plate 16 for fixing the laminated piezoelectric element 15. The housing 13 is made of metal. Or it is an inexpensive part made by resin molding.

  The orifice plate 2, the chamber plate 4, the restrictor plate 6, the diaphragm plate 9, and the support plate 11 are aligned with the reference holes 18 of the respective plates with reference to the reference holes 20 of the housing 13. Appropriate amounts are applied, overlapped and pressure-bonded to form a flow path forming member after heat-curing of the adhesive.

The above components are referred to as a front end set 20. Further, 15 is a laminated piezoelectric element, 16 is a laminated piezoelectric element fixing plate using a conductive material such as metal, and 17 is a flexible cable. A partial kumi of these components is referred to as a laminated piezoelectric element set 21.

  FIG. 3 is a perspective view showing attachment of the flexible cable 17 to the laminated piezoelectric element rod according to the present invention. One or more laminated piezoelectric element rods 25 are arranged on the laminated piezoelectric element fixing plate 16 and fixed with an insulating adhesive (in the figure, one is shown). In addition, as shown in FIG. 5, the notch part 15-b is provided in the corner part of the adhesion surface with the laminated piezoelectric element fixing plate 16 that forms the individual electrode side of the laminated piezoelectric element rod 25. Further, notches 16-a are also provided at the corners of the laminated piezoelectric element fixing plate 16 serving as the opposing surface.

  First, a pin is inserted into the flexible cable positioning hole 17-d and the flexible cable 17 is installed on the laminated piezoelectric element fixing plate 16. The electrode of the portion that attaches to the laminated piezoelectric element rod 25 of the flexible cable 17 is exposed, and a conductive adhesive is applied so as to form electrical continuity with the external electrode of the laminated piezoelectric element rod 25, and is cured by heating and bonding. To do.

  Since the width of each individual electrode is very narrow, in the configuration that is divided as individual electrodes in advance, a twist or the like occurs at the time of bonding, but in the present invention, between the individual electrodes at the tip of the flexible cable as shown in the figure. Since it is in the state connected by the insulating material of the flexible cable, the adhesion part of each individual electrode does not twist, and it becomes possible to adhere appropriately and easily.

  Note that even if the individual electrodes 17-b of the flexible cable are connected by a conductive material, there is a problem in the case where the individual electrodes 17-b are separated and insulated so as to become individual electrodes when cut later. It is usable without.

  FIG. 4 is a perspective view showing the processing of the flexible cable 17 and the laminated piezoelectric element rod assembly according to the present invention.

  The processing is performed using a dicing saw, a wire saw, or the like. Here, the processing is shown in the case of a dicing saw. In the drawing, the laminated piezoelectric element rod 25 and the flexible cable 17 are cut to a desired width by the die-sink 26 to form a plurality of laminated piezoelectric elements 15.

  FIG. 5 is a cross-sectional view showing a schematic configuration of a multilayered piezoelectric element set according to the present invention.

  As described above, in order to ensure insulation between the laminated piezoelectric element 15 and the laminated piezoelectric element fixing plate 16, the external electrode 15-a of the laminated piezoelectric element 15 is not electrically connected to the laminated piezoelectric element fixing plate 16. A cutout portion 15-b is provided, and the laminated piezoelectric element fixing plate 16 is also provided with a cutout portion 16-a in order to further improve insulation.

  The electrode 17-b1 at the tip end where the individual electrode 17-b of the flexible cable 17 is exposed and the external electrode 15-a of the laminated piezoelectric element 15 are joined by a conductive adhesive. As shown in FIG. 2, the individual electrode 17-b and the common electrode 17-c of the flexible cable 17 are covered with a heat-resistant and insulating polyimide film or the like.

  Further, as shown in FIG. 5, in the flexible cable 17, in order to ensure insulation between the laminated piezoelectric element 15 and the laminated piezoelectric element fixing plate 16, the insulating portion 17-a 1 is an individual electrode 15-a of the laminated piezoelectric element 15. It covers a part of the side and covers the boundary with the laminated piezoelectric element.

  The laminated piezoelectric element rod 25 to which the flexible cable 17 is attached is a dicing saw 26. The laminated piezoelectric element and the flexible cable are combined together so as to correspond to each individual electrode 17-b of the flexible cable 17. Cut and split.

  At this time, the relationship between the width of the individual electrode 17-b of the flexible cable 17 and the width of the laminated piezoelectric element 15 after the division processing is “laminated piezoelectric element width> individual electrode width”, and pitch error during division processing. The individual electrode 17-b is prevented from being damaged due to breakage of the individual electrode 17-b. Each of the divided laminated piezoelectric elements 15 corresponds to each pressure chamber 3, and the end of the flexible cable 19 is connected to an external drive circuit in units of nozzles.

  As described above, the individual electrode side of the divided laminated piezoelectric element 15 is electrically connected to the drive power supply via the flexible cable 17 on the laminated piezoelectric element fixing plate 16 made of conductive metal. On the other hand, on the common electrode 17-c side, the laminated piezoelectric element 15 and the laminated piezoelectric element fixing plate 16 made of a conductive metal are directly connected by a conductive adhesive 22 or the like. The laminated piezoelectric element fixing plate 16 made of conductive metal and the conductive adhesive 22 are electrically connected.

  With such a configuration, there is no need to pattern electrodes on both the individual electrode side and the common electrode side on the laminated piezoelectric element fixing plate 16, and further, by using a general-purpose metal material, the material cost is reduced. The machinability of the end face for fixing the laminated piezoelectric element and the positioning hole is improved. It has been confirmed that the ink jet print head according to the present invention exhibits the same performance as the ink jet print head according to the prior art.

  FIG. 6 is a front sectional view showing the positioning and bonding operation of the front end group and the laminated piezoelectric element group according to an example of the present invention.

  In the figure, a base A (not shown) having a positioning pin for positioning a front end set 20 and a positioning dummy support plate (not shown), a base B (not shown) for fixing the laminated piezoelectric element set 21 and a laminated piezoelectric element set 21 are slightly moved. A plurality of micrometer heads (not shown) for fixing the laminated piezoelectric element set 21 and a fixing screw (not shown) for fixing the micro-movable piezoelectric element set 21 after a minute movement, and the like. In order to bond the base B, the positioning dummy support plate is provided with a positioning hole 18 in the base B by a positioning jig (not shown) provided with a linear motion guide or the like for enabling movement in the arrow direction in the figure. Set to use.

  Also, the laminated piezoelectric element set 21 is fixed to the base B, and is observed in the X and Y directions by the micrometer head with reference to the opening of the dummy support plate while observing from the surface opposite to the laminated piezoelectric element 15. Positioning is performed, and the laminated piezoelectric element set 21 is fixed by the fixing screw or the like.

  Next, the dummy support plate is removed from the base A, and the front end set 20 is inserted into the positioning pins of the base A using the positioning holes 18 and set.

  Next, an adhesive 24 is applied to the diaphragm 7 or the laminated piezoelectric element 15, and the laminated piezoelectric element set 21 is moved in the direction of the arrow on the front end set 20 side by the linear motion guide, so that the laminated piezoelectric element set is moved. 21 laminated piezoelectric elements 15 are bonded to the diaphragm 7 with the adhesive 24. At this time, since the laminated piezoelectric element 15 has already been positioned with respect to the positioning dummy support plate, it is possible to adhere the laminated piezoelectric element 15 in accordance with a specified position accurately.

  At this time, as described above, the opening 13-a of the housing 13 and the laminated piezoelectric element set 21 are positioned and bonded together with a gap. Further, a sealing agent 23 for ink sealing for preventing ink from entering the gap between the opening 13-a of the housing 13 and the multilayered piezoelectric element set 21 and causing damage to the multilayered piezoelectric element 15 due to a ground fault is provided. Fill and finish the assembly process.

  By assembling with the above-described configuration, even if the positioning accuracy between the laminated piezoelectric element and the diaphragm has a certain degree of processing variation, it is possible to minimize the variation in the bonding position, and the ink is inexpensive. It is possible to reduce variations in the injection characteristics. Further, after positioning the front end group 20 and the laminated piezoelectric element group 21, the gap between the opening 14 of the housing 13 and the laminated piezoelectric element fixing plate 16 is filled with a sealing agent 23 or the like for the purpose of ink sealing. It is possible to prevent the multilayer piezoelectric element 15 from being damaged due to the ground fault.

  Also, the gap between the laminated piezoelectric element fixing plate 16 and the housing 13 may be filled with an adhesive having an adhesive hardness of 90 degrees (Shore-A) or less, such as the sealing agent 23 for ink sealing. It is possible to absorb the strain due to the expansion and contraction due to the temperature difference with the adhesive having the hardness while maintaining the bonding position between the laminated piezoelectric element 15 and the diaphragm 7.

  By adopting the configuration described above, an inexpensive ink jet print head can be provided.

1 is a perspective view showing a schematic configuration of an ink jet print head according to the present invention. 1 is a transverse sectional view showing a schematic configuration of an ink jet print head according to the present invention. It is a perspective view which shows the attachment to the flexible cable and laminated piezoelectric element rod assembly by this invention. It is a perspective view which shows the process of the flexible cable and laminated piezoelectric element stick | rod group by this invention. It is a cross-sectional view showing a schematic configuration of a laminated piezoelectric element set according to the present invention. It is a figure which shows the positioning adhesion | attachment of the front end group and laminated piezoelectric element group which show an example by this invention. It is a perspective view which shows schematic structure of the inkjet head which consists of a prior art.

Explanation of symbols

1 is a nozzle, 2 is an orifice plate, 3 is a pressure chamber, 4 is a chamber plate, 5 is a restrictor, 6 is a restrictor plate, 7 is a diaphragm, 8 is a filter section, 9 is a diaphragm plate, 10 is a frame, 11 Is a support plate, 12 is a common ink passage, 13 is a housing, 14 is an opening, 15 is a laminated piezoelectric element, 15-a is a laminated piezoelectric element external electrode, 15-b is a laminated piezoelectric element notch, and 16 is a laminated piezoelectric element. Element fixing plate, 16-a is a laminated piezoelectric element fixing plate notch, 16-b is an individual electrode, 16-c is a common electrode, 16-d is a through hole, 16-e is a positioning hole, 17 is a flexible cable, 17-a is a flexible cable film part, 17-b is a flexible cable individual electrode, 17-b1 is a flexible cable individual electrode exposed part, and 17-c is Rexable cable common electrode, 17-d is a flexible cable positioning hole, 18 is a positioning hole, 19 is a housing positioning hole, 20 is a front end group, 21 is a laminated piezoelectric element group, 22 is a conductive adhesive, 23 is a sealing agent, Reference numeral 24 denotes an adhesive, 25 denotes a laminated piezoelectric element rod, and 26 denotes a dicing saw.

Claims (2)

A plurality of pressure chambers for storing ink, a nozzle communicating with the pressure chamber, a diaphragm forming a part of a wall surface of the pressure chamber, an adhesive fixed to the diaphragm and facing the pressure chamber, A laminated piezoelectric element that includes a common electrode on the side surface and an individual electrode on the other side surface and generates pressure fluctuation in the pressure chamber by application of an electrical signal, a restrictor that supplies ink to the pressure chamber, and a restrictor Corresponding to a common ink supply path for supplying ink to the plurality of pressure chambers in communication, a conductive laminated piezoelectric element fixing plate for holding the plurality of laminated piezoelectric elements, and individual electrodes and common electrodes of the laminated piezoelectric elements In the method of manufacturing an ink jet print head composed of a flexible cable having an individual electrode and a common electrode that are electrically connected to each other,
Forming a front end set that serves as a flow path for ink flowing into the pressure chamber through the restrictor from the common ink supply path;
Forming a laminated piezoelectric element set having the flexible cable and a plurality of the laminated piezoelectric elements on the laminated piezoelectric element fixing plate;
The step of forming an inkjet print head by combining the front end set and the laminated piezoelectric element set, and further comprising the step of forming the laminated piezoelectric element set,
(A) a step of bonding and fixing one or a plurality of laminated piezoelectric element rods to the laminated piezoelectric element fixing plate;
(B) The flexible cable in which the electrodes at the tips of the individual electrodes are connected by an insulating material is installed on the laminated piezoelectric element fixing plate, and the individual electrodes of the flexible cable and the external electrode surface of the laminated piezoelectric element rod Forming conduction and conduction between the common electrode of the flexible cable and the laminated piezoelectric element fixing plate,
(C) dividing the laminated piezoelectric element rod and the insulating material together to form the laminated piezoelectric element;
A method for producing an ink jet print head comprising :   2. The method of manufacturing an ink jet print head according to claim 1, wherein the insulating material is a polyimide film.

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