JPWO2009139273A1 - Inkjet head - Google Patents

Abstract

A connection electrode that is electrically connected to the drive electrode in the channel is provided in parallel at the end of the rear surface of the head chip having a plurality of channel rows to facilitate electrical connection with a wiring for applying a drive signal. The purpose is to secure a wide connection area with the wiring on the back of the head chip. On the rear surface of the head chip, a row A connection electrode that conducts with the drive electrode of the A row channel is arranged from the channel to the end of the head chip, and a row B connection electrode that conducts with the drive electrode of the B row channel It is arranged so as to be in parallel with the connection electrode for the A column from the channel to the end of the head chip across the A column. The A column connection electrode and the B column connection electrode are formed by using a stacked body in which a metal film layer is formed on one surface of the insulating layer and the front and back surfaces of the insulating layer can be electrically connected. The metal film layer is arranged so as to be exposed on the surface between the end portion of the head chip, and the exposed portion of the metal film layer is used as a connection region for wiring for applying a drive signal.

Description

  The present invention relates to an ink jet head, and more particularly, to an ink jet head which can easily perform electrical connection between a drive electrode in a channel and a drive circuit.

  Conventionally, as an inkjet head in which a drive wall is shear-deformed by applying a voltage to an electrode formed on a drive wall that defines a channel, and ink in the channel is ejected from a nozzle using the pressure generated at that time. There are known ones having so-called harmonica type head chips in which channel openings are arranged on the front and rear surfaces, respectively.

  In such a harmonica-type head chip, the problem is how to electrically connect each drive electrode to the drive circuit.

  For example, conventionally, by providing a through electrode on the cover substrate of the head chip that closes the upper part of the channel, the drive electrode in each channel is drawn out to the surface of the cover substrate of the head chip, and each surface of the cover substrate is subjected to FPC etc. An ink jet head has been proposed in which a drive electrode and a drive circuit are electrically connected (Patent Document 1).

  However, providing a through electrode on the cover substrate requires difficult operations such as opening a through hole and embedding a conductive material in the through hole. For this reason, a connection electrode that is electrically connected to each drive electrode is formed on the rear surface of the head chip, which is the surface opposite to the surface on which ink is ejected, and the wiring substrate is joined to the rear surface of the head chip, and is attached to the end of the wiring substrate An ink jet head has also been proposed in which each drive electrode is electrically connected to a drive circuit by bonding an FPC (Patent Document 2).

  In this way, the connection electrode that is electrically connected to the drive electrode on the rear surface of the head chip can be drawn out from each channel by using a general metal thin film patterning method. Compared to the above, it is possible to form the connection electrode easily and with high accuracy.

JP 2004-90374 A JP 2006-82396 A

  However, in the case of a head chip in which the density is increased by arranging two or more channel rows composed of a plurality of channels, the connection rows are connected to the end of the head chip because the channel rows are adjacent to each other. There is a problem that it is difficult to pull out to the department. For example, in the case of a head chip having two channel rows of A rows and B rows, it is difficult to pull out the connection electrodes from the B row channels to the end of the head chip beyond the A row. This is because the channel row of the A row must be exceeded.

  In this case, it is conceivable to pattern the connection electrodes of the channels in the B row so as to pass between the channels in the A row. However, the drive electrodes in the channels in the A row pass through the extremely fine channels. There is a problem that it is difficult to pattern so as not to short-circuit. In particular, in the case where the channels are arranged at a high density with a fine pitch, the gap between two adjacent channels is extremely narrow, and the connection electrodes of the B column channels can be connected between the A column channels without any short circuit or disconnection. It is extremely difficult to pull it out to the end of the head chip.

  Therefore, even in a harmonica type head chip in which a plurality of channel rows are provided, a drive signal from the drive circuit can be obtained by arranging connection electrodes that are electrically connected to the drive electrodes in the channel together at the end of the rear surface of the head chip. It is desired to facilitate the electrical connection with the wiring for applying the voltage.

  Therefore, the present invention applies a drive signal from the drive circuit by arranging a connection electrode that is electrically connected to the drive electrode in the channel at the end of the rear surface of the harmonica type head chip having a plurality of channel rows. It is an object of the present invention to provide an ink jet head that can facilitate the electrical connection with the wiring for the purpose, and can secure a wide connection area with the wiring on the rear surface of the head chip.

  Other problems of the present invention will become apparent from the following description.

  The above problems are solved by the following inventions.

  The invention according to claim 1 has a head chip having a plurality of channel rows in which drive walls made up of channels and piezoelectric elements are alternately arranged in parallel, and the openings of the channels are respectively arranged on the front surface and the rear surface. An inkjet head that deforms the drive wall by applying a voltage to the drive electrode formed in the channel and discharges ink in the channel from a nozzle, wherein the head of the plurality of channel rows When any one of the channel rows located on the end side of the chip is A row and the channel row adjacent to the A row is B row, the rear surface of the head chip is electrically connected to the driving electrode of the channel of the A row. A row connection electrode is arranged from the channel to the end of the head chip, and the row B connection electrode is electrically connected to the drive electrode of the channel B row. The A column connection electrode is arranged in parallel with the A column connection electrode across the channel column of the A column and the end of the head chip, and the A column connection electrode and the B column connection electrode are insulated. Using a laminate in which a metal film layer is formed on one side of the front and back sides of the layer and the front and back sides of the insulating layer can be conducted, the channel row of the A row and the end of the head chip The ink jet head is characterized in that the metal film layer is arranged so as to be exposed on a surface, and an exposed portion of the metal film layer is a connection region of a wiring for applying a drive signal from a drive circuit.

  The invention according to claim 2 is the ink jet head according to claim 1, wherein a wiring board on which wiring for applying a driving signal from a driving circuit is formed is bonded to the connection region. .

  According to a third aspect of the present invention, the number of the channel columns is four, the two channel columns positioned on the end side of the head chip are respectively the A columns, and the two channel columns positioned inside are the B columns. The inkjet head according to claim 1 or 2, wherein

  According to a fourth aspect of the present invention, in each of the channel rows A and B, an ejection channel that ejects ink and an air channel that does not eject ink are alternately arranged, and the channel row of the A row and the channel row The discharge channel and the air channel are arranged with a pitch difference from the B-row channel row, and the A-row connection electrode and the B-row connection electrode are electrically connected to the drive electrodes in the discharge channel, respectively. The inkjet head according to any one of claims 1 to 3, wherein the connection electrode for the B row closes an opening on the rear surface side of the air channel of the channel row of the A row. It is.

  According to a fifth aspect of the present invention, all the channels are ejection channels that eject ink, and each channel of the A row and each channel of the B row are arranged with a half-pitch shift, and for the A row The connection electrode and the B column connection electrode are electrically connected to the drive electrodes in all the channels, and the B column connection electrode passes between the A column channels and the A column connection electrode. The inkjet head according to claim 1, wherein the inkjet head is arranged in parallel.

  The invention according to claim 6 is the ink jet head according to any one of claims 1 to 5, wherein the laminated body has a configuration in which conduction between the front and back sides is achieved by a through electrode penetrating the insulating layer. .

  A seventh aspect of the invention is the ink jet head according to any one of the first to sixth aspects, wherein the insulating layer of the laminate is made of an organic film that can be dry-etched.

  The invention according to claim 8 is the ink jet head according to any one of claims 1 to 7, wherein the laminate is coated with a film made of polyparaxylylene or a derivative thereof.

  According to the present invention, the drive signal from the drive circuit is applied by arranging the connection electrode that is electrically connected to the drive electrode in the channel at the end of the rear surface of the harmonica type head chip provided with a plurality of channel rows. Therefore, it is possible to provide an ink jet head that can facilitate the electrical connection with the wiring for the purpose, and can secure a wide connection area with the wiring on the rear surface of the head chip.

  In particular, according to the present invention, even in an inkjet head having four channel rows, it is possible to facilitate electrical connection with a wiring for applying a drive signal from a drive circuit. An ink jet head capable of high-speed recording can be provided.

The perspective view which looked at the ink jet head concerning a 1st embodiment from the back side. (A) is a sectional view taken along line (i)-(i) in FIG. 1, and (b) is a sectional view taken along line (ii)-(ii) in FIG. The figure explaining the manufacture example of a head chip The figure explaining the manufacture example of a head chip The figure explaining the manufacture example of a head chip The figure explaining the manufacture example of a head chip Rear view of ink jet head according to second embodiment (A) is a sectional view taken along line (iii)-(iii) in FIG. 7, and (b) is a sectional view taken along line (iv)-(iv) in FIG. Rear view of ink jet head according to third embodiment Rear view of inkjet head according to fourth embodiment (V)-(v) cross-sectional view of FIG. Sectional drawing which shows the other form of a laminated body

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
1 is an exploded perspective view of an inkjet head according to the present invention as viewed from the rear side, FIG. 2A is a cross-sectional view taken along line (i)-(i) in FIG. 1, and FIG. It is a sectional view taken along line (ii)-(ii). In the sectional view, the adhesive layer is not shown.

  In the figure, 1 is a head chip, 2 is a nozzle plate joined to the front surface of the head chip 1, and 21 is a nozzle formed on the nozzle plate 2.

  In this specification, the surface on the side where ink is ejected from the head chip 1 is referred to as “front surface”, and the opposite surface is referred to as “rear surface”. Further, the outer surfaces located above and below in the figure across the channels arranged in parallel in the head chip 1 are referred to as “upper surface” and “lower surface”, respectively.

  In the head chip 1, channel rows in which drive walls 11 made of piezoelectric elements and channels 12 and 13 are alternately arranged in parallel are arranged in two rows in the vertical direction in the figure. The number of channels constituting each channel row is not limited at all.

  Here, the channel row located on the lower side in the figure is A row, and the channel row located on the upper side is B row.

  The head chip 1 is an independent channel type head chip in which each channel row is formed by arranging an ejection channel 12 that ejects ink every other channel and an air channel 13 that does not eject ink. . The shapes of the channels 12 and 13 are such that both side walls extend substantially perpendicular to the upper and lower surfaces of the head chip 1 and are parallel to each other. On the front surface and the rear surface of the head chip 1, the opening portions 121 and 131 on the front surface side of the respective channels 12 and 13 and the opening portions 122 and 132 on the rear surface surface face each other. Each of the channels 12 and 13 is a straight type in which the size and shape are not substantially changed in the length direction from the openings 122 and 132 on the rear surface side to the openings 121 and 131 on the front surface side.

  In addition, the discharge channel 12 and the air channel 13 are shifted by one pitch in the channel row A and the channel row B. That is, as shown in FIG. 1 and FIG. 2, when the head chip 1 is viewed in the vertical direction in the figure, the A-row discharge channels 12 and the B-row air channels 13 are arranged on the same line, The channel 13 and the B-row ejection channels 12 are arranged on the same line.

  A drive electrode 14 made of a metal film of Ni, Au, Cu, Al or the like is formed in close contact with the entire inner surface of each channel 12, 13.

  Further, on the rear surface of the head chip 1, one common electrode 15A that is electrically connected to the drive electrodes 14 in all of the air channels 13 in the A row is arranged in the upper direction in the direction perpendicular to the channel row (the vertical direction in the drawing). A lead-out is formed toward the B row side, extends along the channel row direction (left-right direction in the figure) between the A row and the B row, and the drive electrodes 14 in all the air channels 13 in the B row One conducting common electrode 15B is formed so as to be drawn upward in the figure, which is the same direction as the drawing direction of the common electrode 15A in the A row, and is along the channel row direction (left and right direction in the drawing) between the upper end portions. It extends.

  The common electrodes 15A and 15B in the A column and the B column are not individually formed for each channel column as shown in FIG. 1, and are not shown, but are common electrodes common to the A column and the B column. You can also. In this case, the common electrode of the A column is drawn out toward the B column side, the common electrode of the B column is drawn out toward the A column side, and the respective drawing destinations are combined into one, and the A row and the B row are combined. One common electrode may be formed between the columns along the channel column direction (the horizontal direction in the figure). Further, the common electrodes 15A and 15B may be electrically connected to the grounding wiring at the end portions of the left and right head chips 1 shown in the drawing.

Further, the surface of the head chip 1, the first connection electrodes 16A ₁ for row A that conduct the drive electrodes 14 of the discharge channel 12 of row A, and B column side a pull-out direction of the common electrode 15A Are individually drawn out toward the lower end of the head chip 1 in the opposite direction, which is in the opposite direction, and are parallel to the discharge channels 12 in the A row at the same pitch on the lower end side.

The first surface of the connection electrode 16A ₁ for each row A, and is formed separately further second connection electrodes 16A ₂ for row A, respectively. Second connection electrodes 16A ₂ for the A column, a metal film layer laminated on one surface of the insulating layer 31, stacked in the second connection electrodes 16A ₂ and the insulating layer 31 for the A column The body 3A is constituted.

Each laminate 3A, in order to achieve conduction between the second connection electrodes 16A ₂ for A row positioned to the first connection electrode 16A ₁ and the upper surface of the A row positioned on the lower surface of the insulating layer 31 The through electrode 32 is formed. Thus, each laminate 3A are adapted to be able to take the continuity of front and back by the through electrodes 32, and a second connection electrode 16A ₂ for the first connection electrodes 16A ₁ and column A for row A Conduction is performed with an insulating layer 31 interposed therebetween. The second surface of the connection electrode 16A ₂ for the A column, the connecting portion of the wiring for applying a driving signal from the drive circuit (not shown).

On the other hand, the respective discharge channels 12 of row B, the first connection electrodes 16B ₁ for row B to the interior of the electrically connected with the driving electrodes 14, shown below is a direction opposite to the drawing direction of the common electrode 15B It is individually drawn out toward the A row side, extends to the front of the common electrode 15A of the A row, and is parallel to the discharge channels 12 in the B row at an equal pitch.

Further, at the lower portion of the head chip 1 than the air channels 13 of row A, so as to be positioned between the first connection electrodes 16A ₁ for each row A, is individually height adjusting metal film 17 It is formed are parallel with the first connection electrodes 16A ₁ for the a column. This height adjusting metal film 17, the first connection electrode 16A ₁ and the same thickness for row A (the same height), the lower end portion from the vicinity of the lower end portion of the head chip 1 of each of the air channels 13 of row A It is formed over.

In order to perform electrical connection with wiring for applying a drive signal from a drive circuit (not shown) to the two channel rows of the A row and the B row on the lower end side of the rear surface of the head chip 1, Pull the first connection electrodes 16B ₁ for row B to the lower end side of the head chip 1, it is necessary to parallel with the second connection electrodes 16A ₂ for row a. For this reason, the second connection electrode 16B ₂ for the B row extends from the first connection electrode 16B ₁ for the B row to the common electrode 15A of the A row and the channel row of the A row and to the lower end portion of the head chip 1. Is formed.

Second connection electrodes 16B ₂ for row B is made of a metal film layer laminated on one surface of the insulating layer 31, laminate and the second connection electrodes 16B ₂ and the insulating layer 31 for the B column 3B is configured. The insulating layer 31 and the metal film layer are formed to have the same thickness as the insulating layer 31 and the metal film layer constituting the laminate 3A. Laminate 3B is across the air channel 13 of the common electrode 15A and the A column of the A column from the first connection electrodes 16B ₁ for row B have a length across the lower portion of the head chip 1, The insulating layer 31 side is positioned on the rear surface side of the head chip 1, and the gap between the surface of the first connection electrode 16 B ₁ for the B row and the surface of the metal film 17 for height adjustment is individually set. It is glued.

  At this time, each stacked body 3B is bonded so as to completely close the opening 132 on the rear surface side of each air channel 13 in the A row, thereby preventing the inflow of ink into each air channel 13 in the A row. The flow path is regulated as follows. Therefore, the laminate 3B can also serve as a flow path regulating member that regulates the inflow of ink into the air channels 13 in the A row.

Each stack 3B, in the region overlapping with the first connection electrodes 16B ₁ for row B, penetrating electrodes 32 that penetrate the respective insulating layers 31 are formed. Thus, each laminate 3B are adapted to be able to take the continuity of front and back by the through electrodes 32, a second first connection electrode 16B ₁ and the laminate for 3B which is formed in column B which for row B of which is conductive across the insulating layer 31 between the connection electrodes 16B _2. In the surface of the laminate 3B, the second surface of the connection electrode 16B ₂ for row B of the lower end of the head chip 1 than the channel rows of row A, for applying a drive signal from a drive circuit (not shown) It becomes the connection part of the wiring.

As a result, on the rear surface of the head chip 1, a wiring connection portion for applying a drive signal from a drive circuit (not shown) across the width L between the channel row of the A row and the lower end portion of the head chip 1. However, the second connection electrodes 16A ₂ for the A row and the second connection electrodes 16B ₂ for the B row respectively formed on the surfaces of the stacked bodies 3A and 3B are alternately exposed in parallel and formed on the surface. Is done.

Connecting part exposed over this width L, each laminate 3A, the same thickness of 3B of the insulating layer 31 and the metal film layer, and the first connecting electrodes 16A ₁ and height adjustment for the A column When the thickness of the metal film 17 is the same, it is arranged at the same height from the rear surface of the head chip 1. Therefore, for example, as shown in FIG. 2, when connecting the wiring board 4 for applying a drive signal from the drive circuit, the entire connection portion over the width L can be set as the connection region. It can be ensured widely, and the reliability of the electrical connection between the electrodes and the strong connection of the wiring board 4 are possible.

On the surface of the wiring substrate 4, a wiring electrode 41 is formed in the second connection electrodes 16B ₂ and the same pitch for the second connection electrodes 16A ₂ and row B for A column. The lower end of the wiring board 4 forms a projecting portion 42 that extends further downward and extends over the lower end portion of the head chip 1, and a driving signal from the drive circuit is applied to the wiring electrode 41 exposed to the projecting portion 42. Are electrically connected to each wiring 51 of the FPC 5.

  In the present embodiment, the laminated body 3C is individually bonded to each of the openings 132 on the rear surface side of the air channels 13 in the B row to completely close the openings 132. As with the air channel 13, the inflow of ink is blocked. Similarly to the other stacked bodies 3A and 3B, the stacked body 3C is composed of the insulating layer 31 and the metal film layer 33 on the surface thereof, and functions as a flow path regulating member.

  Next, although an example of the manufacture example of such a head chip 1 is demonstrated below based on FIGS. 3-6, it is not limited to this at all.

  First, a piezoelectric element substrate 101 made of PZT or the like that has been subjected to polarization processing (the direction of polarization is indicated by an arrow in the figure) is bonded onto one substrate 100 using an epoxy-based adhesive, and then the piezoelectric element substrate. A dry film 102 is attached to the surface of 101 (FIG. 3A).

  Next, a plurality of parallel grooves 103 are ground from the dry film 102 side using a dicing blade or the like. Each groove 103 extends from one end of the piezoelectric element substrate 101 to the other end and is ground at a constant depth almost reaching the substrate 100 so that the size and shape of the groove 103 are almost the same in the length direction. (FIG. 3B).

  Next, an electrode forming metal such as Ni, Au, Cu, or Al is applied by sputtering, vapor deposition, or the like from the side on which the groove 103 is ground, and the remaining upper surface of the dry film 102 and the inner surface of each groove 103 are applied. A metal film 104 is formed (FIG. 3C).

  Thereafter, the dry film 102 is removed together with the metal film 104 formed on the surface thereof, whereby the substrate 105 having the metal film 104 formed only on the inner surface of each groove 103 is obtained. Then, two similarly formed substrates 105 are prepared, aligned so that the grooves 103 of each substrate 105 match each other, and bonded using an epoxy adhesive or the like (FIG. 3D). .

  Next, two head substrates 106 obtained in this way are prepared, overlapped and bonded, and cut along a direction perpendicular to the length direction of the groove 103, thereby providing a plurality of channel arrays having two channel arrays. One harmonica type head chip 1 is formed at a time. Each groove 103 becomes a channel 12 or 13, the metal film 104 in each groove 103 becomes a drive electrode 14, and a drive wall 11 becomes between adjacent grooves 103. The width between the cut lines C, C... Determines the drive length (L length) of the ejection channels 12 of the head chips 1, 1... Produced thereby, and is appropriately determined according to this drive length. (FIG. 3 (e)).

Then, forming thereby a dry film 200 is adhered to the surface of the head chip 1 obtained, the common electrode 15A, the opening 201A for forming 15B, and 201B, the first connection electrodes 16A ₁ for row A An opening 202B for forming the _first connection electrode 16B1 for the B row, and an opening 203B for forming the height adjusting metal film 17 are formed by exposure and development ( FIG. 4).

Then, from the dry film 200 side, for example, Al is applied as an electrode forming metal by vacuum deposition, and an Al film is selectively formed in each of the openings 201A, 201B, 202A, 202B, and 203B. With this Al film, the common electrodes 15A and 15B, the first connection electrode 16A ₁ for the A row, the first connection electrode 16B ₁ for the B row, and the height adjusting metal film 17 are formed on the rear surface of the head chip 1, respectively. Are formed with the same thickness.

  In order to ensure the connection between the drive electrode 14 in each discharge channel 12 and the drive electrode 14 in each air channel 13, it is desirable to perform the vapor deposition twice by changing the direction. Specifically, it is desirable to carry out from a direction perpendicular to the drawing surface and from 30 degrees up and down. Further, as shown in FIG. 3D, in order to ensure the connection between the metal films 104 that are divided vertically, it is desirable to perform evaporation from the direction of 30 degrees to the right or left.

Further, the method for forming the metal film is not limited to vapor deposition, and a general thin film forming method can be employed. Moreover, the method of apply | coating an electrically conductive paste with an inkjet can also be used. In particular, the sputtering method is preferable because the direction of the flying metal particles is random, and the metal film can be formed even inside the channel without changing the direction. After the formation of the metal film, the dry film 200 is dissolved and peeled off with a solvent to remove the metal film formed on the dry film 200, and the common electrode 15A, 15B, A row is formed on the rear surface of the head chip 1. Only the first connection electrode 16A ₁ , the first connection electrode 16B ₁ for the B row, and the height adjusting metal film 17 remain (FIG. 5).

  In consideration of the workability of the dry film 200 in the development process and the water washing process, it is desirable that the dry film 200 be opened on the entire surfaces of the channels 12 and 13. Opening on the entire surface facilitates removal of the developer and washing water in the channels 12 and 13.

Next, a large film insulating layer 31 that can cover the entire rear surface is bonded to the rear surface of the head chip 1. The insulating layer 31 includes a metal film layer 33 having a size that completely blocks the air channel 13 at a position corresponding to each air channel 13 in the B row, and each first connection electrode 16B ₁ in the B row. In a corresponding position, a second connection electrode 16B ₂ for the B row having a length extending from the _first connection electrode 16B ₁ to the lower end portion of the head chip 1, and the second connection electrode 16B ₂ and the B row the first connection electrode 16B ₁ and the penetrating electrode 32 which conduct the connecting electrodes 16B ₂ of the second to the overlapping region of use, at a position corresponding to the connection electrodes 16A ₁ of the first column a, column a and second connection electrodes 16A ₂ for row a from the discharge channel 12 has a length across the lower portion of the head chip 1, and the through electrode 32 to conduct a connection electrode 16A ₂ of the second is preformed Yes. (FIG. 6).

Here, it is preferable to use an organic film as the film to be the insulating layer 31. The organic film is preferably an organic film that can be patterned by general dry etching, and examples thereof include films made of various resins such as polyimide, liquid crystal polymer, aramid, and polyethylene terephthalate. Among these, a polyimide film having good etching properties is preferable. In order to facilitate dry etching, it is desirable to use a film that is as thin as possible, but it is also preferable to use an aramid film that has high strength and can maintain strength even when thin. Further, silicon (SiO ₂ ) can be used as an insulating layer that can be dry-etched. However, it is necessary to use a special gas such as CF ₄ or SF ₆ for dry etching of silicon, and the apparatus is also special, which generally increases the cost. The thickness of the insulating layer 31 is preferably 3 to 100 μm from the viewpoint of securing strength and easy dry etching.

  Each metal film layer formed on one surface of the insulating layer 31 also functions as a mask material in a dry etching process which is a subsequent process. Examples of metals that can be used in these metal film layers include Al, Cu, Ni, W, Ti, Au, etc. Among them, Cu is preferable because it is inexpensive and easy to pattern, and Cu is sputtered. It can be formed by patterning by a normal thin film patterning technique. The thickness of these metal film layers is preferably 0.1 to 50 μm from the viewpoint of dry etching resistance and ease of patterning.

  Here, as the insulating layer 31, 5 μm of Cu was formed on a 25 μm-thick polyimide film in which the through electrode 32 was previously formed by a sputtering apparatus.

  The through electrode 32 can be formed by forming a through hole in the insulating layer 31 by laser drilling in advance and performing through hole plating.

When the insulating layer 31 is bonded, conduction between the through electrode 32 and the first connection electrode 16A ₁ for the A row and the first connection electrode 16B ₁ for the B row is performed by pressure bonding the metal films with an adhesive. This is done by the NCP method (Non Conductive Paste) which establishes electrical connection. In this case, the epoxy adhesive functions as an adhesive for the insulating layer 31 and also functions as an NCP. In the case of the NCP method, connection may be difficult if the surface of the metal film is oxidized. Therefore, the surfaces of the first connection electrode 16A ₁ for the A column and the first connection electrode 16B ₁ for the B column are A metal such as Au or Pt is desirable, and can be realized by making the metal film into multiple layers.

Further, an ACP method (Anisotropic Conductive Paste) using an adhesive in which metal particles are dispersed in an adhesive can also be used. In this case, since the metal particles break through the oxide film on the surface of the metal film and make a connection, the surfaces of the first connection electrode 16A ₁ for the A row and the first connection electrode 16B ₁ for the B row are easily oxidized. Even metal, it is easy to make a reliable electrical connection.

In particular, in the present invention, the through electrode 32 is formed in the insulating layer 31, and an adhesive containing metal particles (conductive particles) is used as the adhesive, whereby the through electrode 32 and the first connection for the A row are used. ensuring the electrical continuity between the first connection electrodes 16B ₁ of the electrode 16A 1, _B column is most preferred in achieving the reliability of both the electrical connection.

  In addition to the method of bonding the insulating layer 31 after patterning each metal film layer in advance to the rear surface of the head chip 1 in this way, a polyimide film before patterning in which a metal film such as Cu is formed on one surface, etc. The insulating layer 31 may be adhered to the rear surface of the head chip 1 and then each metal film layer may be formed by patterning the metal film by etching. Even in this case, the through electrode 32 is formed in advance.

  In this case, the pattern is transferred using a photomask, but the alignment of the photomask with respect to the head chip 1 is performed using an exposure apparatus and can be performed with a positional accuracy of several μm. Unprecedented high accuracy is obtained. Moreover, according to this method, even if the insulation layer 31 is stretched due to heating and pressurization when the insulating layer 31 is bonded due to the presence of the metal film formed on one surface, each metal film layer is subsequently formed. Since the patterning is performed at a predetermined position, there is an advantage that there is no possibility of positional deviation.

  Next, dry etching is performed on the rear surface of the head chip 1 to remove the unnecessary insulating layer 31. Specific dry etching means can be appropriately selected according to the resin used for the insulating layer 31. For example, when a polyimide film is used as in this embodiment, it is possible to perform dry etching using oxygen plasma. Here, a parallel plate RF plasma apparatus was used as the oxygen plasma apparatus. After evacuation, 50 sccm of oxygen gas was introduced and the pressure was adjusted to 10 Pa by adjusting the valve. A high frequency with a frequency of 13.56 MHz and a power of 500 W was applied, and the polyimide was decomposed and removed by the generated oxygen plasma. The polyimide can be removed in about 10 minutes. At this time, since each metal film layer on the surface is not decomposed by oxygen plasma, these metal film layers serve as a mask, and the lower insulating layer 31 remains without being etched.

  For the etching, wet etching can be used, but generally, wet etching is acidic or alkaline, and there is a possibility of damaging the drive electrode 14, so dry etching is preferable. In addition, even if the adhesive oozes out when the insulating layer 31 is adhered, unnecessary adhesive can be decomposed and removed at the same time when dry etching is performed. The problem of covering the surface is also eliminated.

  Further, since the insulating layer 31 other than the portion masked by the metal film layer is completely removed by dry etching, the outer shape of the insulating layer 31 is larger than that of the rear surface of the head chip 1 at the stage of bonding to the rear surface of the head chip 1. There is an advantage that workability is remarkably excellent.

  Furthermore, the dry etching method is not limited to the above method, and can be appropriately selected.

By such dry etching, as shown in FIG. 1, the stacked bodies 3A, 3B, and 3C are individually formed on the rear surface of the head chip 1 by the remaining insulating layer 31 and the metal film layers, respectively. over the width L in the first lower portion, the second connection electrodes 16B ₂ for the second connection electrodes 16A ₂ and B columns for row a parallel alternately, to electrically connect the wiring board 4 A connection region is formed.

  Thereafter, ink is supplied into each ejection channel 12 by joining an ink manifold or the like (not shown) to the rear surface of the head chip 1.

As described above, according to the present invention, the second connection electrodes 16A ₂ for the A row and the B row formed from the drive electrodes 14 in the discharge channels 12 of the two channel rows of the A row and the B row are provided. the second connection electrodes 16B _2, since the one end portion of the surface of the head chip 1 can be arranged in a row, electrically the wiring 41 of the wiring board 4 for applying a driving signal from the driving circuit Connection can be easily made only at one end of the head chip 1.

  In addition, since the connection region with the wiring 41 can be secured over the entire width L between the channel row of the A row and the end of the head chip 1 on the rear surface of the head chip 1, The reliability of the connection can be maintained high, and the wiring board 4 can be firmly bonded over the entire surface of the wide connection region.

By the way, in the head chip 1, the drive electrode 14 in the ejection channel 12 is in direct contact with the ink. Therefore, when water-based ink is used, a protective film is required on the surface of the drive electrode 14. In addition, since the common electrodes 15A and 15B, the second connection electrode 16A ₂ for the A row of the stacked bodies 3A and 3B, and the second connection electrode 16B ₂ for the B row are also in direct contact with the ink, solvent-based ink When these are used, a protective film is required to protect them from the solvent. Therefore, after the stacked bodies 3A to 3C are bonded to the rear surface of the head chip 1, the entire surface of the head chip 1, that is, the surface of each drive electrode 14, the common electrodes 15A and 15B, and the A columns of the stacked bodies 3A, 3B, and 3C are used. It is preferable to form a protective film on the surfaces of the second connection electrode 16A ₂ , the second connection electrode 16B ₂ for the B row, and the metal film layer 33.

  As the protective film, it is preferable to coat using a film made of polyparaxylylene or a derivative thereof (hereinafter referred to as a parylene film). The parylene film is a resin film composed of a polyparaxylylene resin and / or a derivative resin thereof, and is formed by a vapor phase synthesis method (chemical vapor deposition: CVD method) using a solid diparaxylylene dimer or a derivative thereof as an evaporation source. Form. That is, paraxylylene radicals generated by vaporization and thermal decomposition of diparaxylylene dimer are adsorbed on the surface of the head chip 1 and undergo a polymerization reaction to form a film.

  There are various types of parylene films. Depending on the required performance, etc., various types of parylene films and multi-layered parylene films in which a plurality of these types of parylene films are laminated are applied as desired parylene films. You can also.

  The thickness of such a parylene film is preferably 1 μm to 10 μm.

Since the parylene film can penetrate into a fine region and form a coating, by forming the coating on the head chip 1 before the nozzle plate 2 is bonded, not only the drive electrode 14 but also the common electrode The second connection electrodes 16A ₂ for the A row and the second connection electrodes 16B ₂ for the B row of the laminates 3A and 3B and the second connection electrodes 16B ₂ for the B row are also protected from the ink by being covered with the parylene film.

  As described above, it is preferable that the nozzle plate 2 be joined after the parylene film forming step because a film is easily formed on the drive electrode 14 in the channel.

  By forming this parylene film, each of the laminates 3A to 3C is protected from both surfaces, and the durability can be greatly improved.

  When the parylene film is formed in this way, the nozzle plate 2 is bonded thereafter.

Further, as shown in FIG. 2, when the wiring substrate 4 is bonded to the rear surface of the head chip 1, before the nozzle plate 2 is bonded to the head chip 1, after the wiring substrate 4 is bonded to the head chip 1, It is preferable to form the above-described parylene film. Thereby, while being able to ensure electrical connection of each electrode, the adhesive layer of the wiring board 4 and the head chip 1 can be protected.
(Second Embodiment)
7 is a rear view of the ink jet head according to the second embodiment, FIG. 8A is a cross-sectional view taken along line (iii)-(iii) of FIG. 7, and FIG. 8B is (iv) of FIG. FIG. In the cross-sectional view, the adhesive layer is not shown. Since the same reference numerals as those in FIGS. 1 and 2 indicate the same configuration, detailed description thereof is omitted.

  In this head chip 1 ′, the channels 12 in each of the channel rows of the A row and the B row are all ejection channels that discharge ink, and the channels 12 in the A row and the channels 12 in the B row have a half pitch. They are misaligned. That is, when the head chip 1 ′ is viewed in the vertical direction in the figure, the A column channel 12 and the B column channel 12 are not on the same line, but between the A column channels 12 and the B channel channels 12 or A. Each channel in the column and each channel 12 in the B column are arranged on the same line.

The first connection electrode 16A ₁ and second configurations of the connection electrodes 16A ₂ for row A that conduct the drive electrode 14 in each channel 12 of row A is the same as the first embodiment, all of the since channel 12 is the ejection channels, the second connection electrodes 16B ₂ for the first row B that conduct to the connection electrodes 16B ₁ for row B drawn from the drive electrodes 14 of each channel 12 of row B , from the first connection electrodes 16B ₁ for the B column through between the respective channels 12 of row a are formed over the end of the row a side of the head chip 1 ', the second for row a are arranged to parallel alternately with the connection electrodes 16A _2, the width L between the lower end portion of the connecting area connection electrodes 16A _2, 16B ₂ are exposed on the surface, the channel columns and head chip 1 of column a ' Is ensured over the period.

Therefore, in the second embodiment, the electrical connection with the wiring 41 of the wiring board 4 for applying the driving signal from the driving circuit to the driving electrodes 14 in all the channels 12 of the A column and the B column is as follows. This can be performed only in the lower end portion of the head chip 1 ′ and in a connection region having a wide width L from the channel row A row to the lower end portion of the head chip 1 ′.
(Third embodiment)
FIG. 9 is a rear view of the ink jet head according to the third embodiment. Since the same reference numerals as those in FIG. 1 indicate the same configuration, detailed description thereof is omitted.

  The head chip 1 is the same as that of the first embodiment, but the laminated body 3 on the rear surface of the head chip 1 has not undergone a separate process by etching, and the insulating layer 31 is a single large sheet. It is adhered as it is.

  For this reason, all the discharge channels 12 opened on the rear surface of the head chip 1 are also blocked by the insulating layer 31 of the large laminate 3 like each air channel 13. An ink inflow hole 34 for allowing ink to flow is individually opened for each ejection channel 12 in the A row and the B row by laser processing, etching processing, or the like. The size and shape of the ink inflow hole 34 are not particularly limited. By making the opening area of the ink inflow hole 34 smaller than the opening area of the ejection channel 12, the inflow of ink into the ejection channel 12 can be regulated. In this case, the ink inflow hole 34 can also function as a flow path regulating hole for regulating the flow path of the ink into the ejection channel 12.

  According to the third embodiment, in addition to the same effects as those of the first embodiment, the flow path regulating hole that regulates the inflow of ink into each ejection channel 12 using the insulating layer 31 of the multilayer body 3. There is an advantage that can be formed easily.

In this way, the insulating layer 31 of the laminate 3 is adhered to the rear surface of the head chip 1 in a large shape, and the ink inflow hole 34 is opened only at a position corresponding to the channel 12 that needs ink supply. Can be similarly applied to the head chip 1 'according to the second embodiment shown in FIGS. In this case, since all the channels 12 in the A row and the B row are ejection channels, the ink inflow holes 34 may be opened at positions corresponding to all the channels 12.
(Fourth embodiment)
FIG. 10 is a rear view of the inkjet head according to the fourth embodiment, and FIG. 11 is a cross-sectional view taken along line (v)-(v) in FIG. Since the same reference numerals as those in FIGS. 1 and 2 indicate the same configuration, detailed description thereof is omitted. In the cross-sectional view, the adhesive layer is not shown.

The head chip 1 ″ of the ink jet head according to the fourth embodiment is an aspect in which the channel rows of the head chip 1 of the ink jet head according to the first embodiment are configured in four rows. In the case of four channel rows, the two channel rows located outside are each A row, and the two channel rows located inside sandwiched between the two A row channel rows are each B row, and the head chip 1 The second connection electrode 16A ₂ for the A row and the second connection electrode 16B ₂ for the B row that are exposed on the surfaces of the stacked bodies 3A and 3B are arranged so as to be alternately arranged in parallel at the upper and lower end portions of ''. Is done.

  Therefore, the electrical connection of the wiring 41 of the wiring substrate 4 for applying the driving voltage from the driving circuit to the driving electrode in each ejection channel 12 can be performed on both the upper and lower ends of the head chip 1 ″. . In this case, the wiring 41 is formed on each of the projecting portions 42 and 42 projecting from the top and bottom of the head chip 1 on one wiring substrate 4, so that the connection with the FPC 5 is made at both the top and bottom ends of the wiring substrate 4. It can be carried out.

  The wiring substrate 4 is formed with a recess 43 having a width that can surround all the channels of the head chip 1 ″, and the recess 43 functions as a common ink chamber. The recess 43 is provided with an opening 44 through which ink is supplied from the ink manifold 6 joined to the back side of the wiring board 4.

Note that four channel rows can be configured in the same manner for the inkjet head according to the second embodiment.
(Other forms of laminate)
FIG. 12 is a cross-sectional view showing another embodiment of the laminated body, and here, a laminated body 3B is shown.

The laminate. 3B, the second connection electrodes 16B ₂ on the surface for row B of the insulating layer 31 are laminated, the laminated electrode 35 are laminated on the back surface. Through electrode 32 is made conductive and the second connection electrodes 16B ₂ and the laminated electrode 35 for these B columns. The laminated electrode 35 is formed at a position corresponding to the _first connection electrode 16B1 for the B row on the rear surface of the head chip 1.

Therefore, laminates 3B, the first connection since it is joined to the electrodes 16B ₁ to surface-contact with the first connection electrode 16B for row B by only the through-electrode 32 for the stacked electrode 35 and row B Compared with the case where conduction with ₁ is aimed at, the certainty of conduction can be improved.

Such laminates. 3B, be obtained by the both sides of the insulating layer 31 by using a 2-layer flexible metal film layer is formed, patterning the second connection electrodes 16B ₂ and the laminated electrodes 35 for row B Can do.

  The laminated body having the laminated electrode 35 can be similarly applied to the other laminated bodies 3 and 3A.

  In each of the above embodiments, the shear mode type inkjet head that discharges ink in the channel by shearing the drive wall 11 has been described. However, the present invention is not limited to the shear wall deformation of the drive wall 11.

1, 1 ′, 1 ″ head chip 11 drive wall 12 channel (discharge channel)
121 Front side opening 122 Rear side opening 13 Channel (air channel)
131 Front side opening 132 Rear side opening 14 Drive electrode 15A, 15B Common electrode 16A ₁ A first connection electrode for A row 16A ₂ A _second connection electrode for A row 16B _{1 First for} B row Connection electrode 16B _{2 second} connection electrode for row B 17 height adjustment metal film 2 nozzle plate 21 nozzle 3, 3A, 3B, 3C laminate 31 insulating layer 32 through electrode 33 metal film layer 34 ink inflow hole 35 Multilayer electrode 4 Wiring board 41 Wiring 42 Overhang 43 Depression 44 Opening 5 FPC
51 FPC wiring 6 Ink manifold

Claims (8)

It has a plurality of channel rows in which drive walls composed of channels and piezoelectric elements are alternately arranged in parallel, and has a head chip in which openings of the channels are arranged on the front surface and the rear surface, respectively, and is formed in the channel An inkjet head that deforms the drive wall by applying a voltage to the drive electrode and ejects ink in the channel from a nozzle,
When any one of the plurality of channel rows is located on the end side of the head chip and the channel row adjacent to the A row is a B row,
On the rear surface of the head chip, an A-row connection electrode that conducts with the drive electrode of the channel of the A row is arranged from the channel to the end of the head chip, and is electrically conducted with the drive electrode of the channel of the B row B column connection electrodes are arranged so as to be parallel to the A column connection electrodes from the channel to the end of the head chip across the A column channel column,
The A column connection electrode and the B column connection electrode are formed by using a laminate in which a metal film layer is formed on one side of the front and back sides of the insulating layer, and conduction between the front and back sides of the insulating layer is achieved. The metal film layer is arranged between the channel row of the row and the end of the head chip so as to be exposed on the surface, and the exposed portion of the metal film layer has wiring for applying a drive signal from the drive circuit An inkjet head characterized by being a connection region.   2. The ink jet head according to claim 1, wherein a wiring board on which wiring for applying a driving signal from a driving circuit is bonded to the connection region.   2. The channel rows are four rows, and two channel rows located on the end side of the head chip are respectively designated as A rows, and two channel rows located on the inner side are designated as B rows, respectively. Or the inkjet head of 2. In each of the channel rows A and B, an ejection channel that ejects ink and an air channel that does not eject ink are alternately arranged, and the channel row of the A row and the channel row of the B row The discharge channel and the air channel are arranged with a pitch deviation of 1;
The A column connection electrode and the B column connection electrode are electrically connected to the drive electrode in the ejection channel, respectively.
The inkjet head according to any one of claims 1 to 3, wherein the B row connection electrode closes an opening on a rear surface side of the air channel in the channel row of the A row. The channels are all ejection channels that eject ink, and each channel in the A row and each channel in the B row are arranged with a half-pitch shift,
The A column connection electrode and the B column connection electrode are electrically connected to the drive electrodes in all the channels,
4. The inkjet according to claim 1, wherein the B row connection electrodes are arranged in parallel with the A row connection electrodes through the channels of the A row. 5. head.   The inkjet head according to claim 1, wherein the laminated body has a configuration in which conduction between the front and back sides is achieved by a through electrode penetrating the insulating layer.   The inkjet head according to claim 1, wherein the insulating layer of the laminate is made of an organic film that can be dry-etched.   The inkjet head according to claim 1, wherein a surface of the laminate is coated with a film made of polyparaxylylene or a derivative thereof.