The present application claims priority from Japanese Patent Application No. 2017-070461 filed on Mar. 31, 2017, the disclosure of which is incorporated herein by reference in its entirety.
The present invention relates to an actuator device including an actuator substrate having a plurality of individual conductors and a plurality of dummy conductors, and a bonding member bonded to the actuator substrate.
There is known an actuator device having an actuator substrate provided with first individual conductors, second individual conductors, and dummy conductors, on a surface thereof. The first individual conductors and the second individual conductors are aligned respectively in a predetermined alignment direction to form rows. In an end portion on one side in the alignment direction, the first individual conductors are aligned in the predetermined alignment direction without intervening the second individual conductors therebetween. In an end portion on the other side in the alignment direction, the second individual conductors are aligned in the predetermined alignment direction without intervening the first individual conductors therebetween. In an area between the end portion on the one side and the end portion on the other side in the predetermined alignment direction, the first individual conductors and the second individual conductors are alternately aligned in the predetermined alignment direction. The dummy conductors are provided respectively on the other side with respect to the first individual conductors in the predetermined alignment direction and on the one side with respect to the second individual conductors in the predetermined alignment direction. Further, a bonding member is bonded to a surface of the actuator substrate to contact respectively with the plurality of first individual conductors and the plurality of second individual conductors.
According to above actuator device, a bonding area of the bonding member to the surface of the actuator substrate includes a first bonding area in contact with the first individual conductors, and a second bonding area in contact with the second individual conductors. The first bonding area includes an area on the other side with respect to the first individual conductors in the predetermined alignment direction, and the second bonding area includes an area on the one side with respect to the second individual conductors in the predetermined alignment direction. The dummy conductors are provided within a predetermined range in an installation area of a wiring substrate, thereby being not present in each bonding area. That is, there are no conductors present in any of the end portion of the first bonding area on the other side in the predetermined alignment direction and the end portion of the second bonding area on the one side in the predetermined alignment direction. In such a case, in each bonding area, because of the part where conductors are present and the part where no conductors are present, the bonding member is uneven in height, thereby possibly giving rise to defect in bonding the bonding member to the actuator substrate.
An object of the present teaching is to provide an actuator device with such a configuration of including conductors in an area to which a bonding member is bonded, that bonding of the bonding member to the actuator substrate is improved.
According to an aspect of the present teaching, there is provided an actuator device including: an actuator substrate having actuators, individual conductors electrically connected with the actuators respectively, and dummy conductors; and a bonding member bonded to a surface of the actuator substrate provided with the individual conductors and the dummy conductors, wherein the individual conductors are aligned in an alignment direction to form a first row and a second row which are arranged in an orthogonal direction orthogonal to the alignment direction, in a first end portion of the actuator substrate on one side in the alignment direction, first individual conductors are aligned in the alignment direction without intervening second individual conductors therebetween, the first individual conductors being included in the individual conductors and forming the first row, the second individual conductors being included in the individual conductors and forming the second row, in a second end portion of the actuator substrate on the other side in the alignment direction, the second individual conductors are aligned in the alignment direction without intervening the first individual conductors therebetween, in an area of the actuator substrate between the first end portion and the second end portion in the alignment direction, the first individual conductors and the second individual conductors are aligned alternately in the alignment direction, the dummy conductors include a first dummy conductor provided on the other side of the first individual conductors in the alignment direction, and a second dummy conductor provided on the one side of the second individual conductors in the alignment direction, a bonding area, of the bonding member, bonded to the surface includes a first bonding area and a second bonding area arranged in the orthogonal direction, the first bonding area is in contact with the first individual conductors and the first dummy conductor, and in the second bonding area is in contact with the second individual conductors and the second dummy conductor.
First, referring to
The head unit 1x is of a line type (that is, a type of jetting ink to paper 9 with its position being fixed), and is elongated in a direction orthogonal to a conveyance direction of the paper 9. The head unit 1x includes a plurality of heads 1 arranged along the direction orthogonal to the conveyance direction (see
The platen 3 is arranged below the head unit 1x. The ink is jetted from the respective heads 1 onto the paper 9 supported by the platen 3.
The conveyance mechanism 4 has two pairs of rollers 4a and 4b arranged across the platen 3 in the conveyance direction. A conveyance motor 4m drives the two rollers constituting each pair of rollers 4a and 4b to rotate in mutually opposite directions with the paper 9 nipped therebetween. By virtue of this, the paper 9 is conveyed in the conveyance direction.
Based on a recording command inputted from an external device such as a PC or the like, the controller 5 controls the plurality of heads 1, the conveyance motor 4m and the like to record image on the paper 9.
Next, referring to
In each head 1, the plurality of nozzles 11n are aligned in an alignment direction (a direction forming an acute angle θ with respect to the conveyance direction), to form two nozzle rows N1 and N2 aligning in an orthogonal direction (a direction orthogonal to the alignment direction). In this manner, with the configuration of aligning the plurality of nozzles 11n in a direction (the alignment direction) forming an acute angle θ (for example, at 30 to 60 degrees) with the conveyance direction, it is possible to increase the resolution of the image in the direction orthogonal to the conveyance direction, as compared with a configuration of aligning the plurality of nozzles 11n in the direction orthogonal to the conveyance direction.
The two nozzle rows N1 and N2 each include the same number of nozzles 11n, and are arranged at a certain interval in the orthogonal direction. In a direction orthogonal to the conveyance direction, the range of distributing the plurality of nozzles 11n included in the nozzle row N1 is in conformity with the range of distributing the plurality of nozzles 11n included in the nozzle row N2.
The nozzles 11n of each of the nozzle rows N1 and N2 conform in position with each other in a direction orthogonal to the conveyance direction. That is, each nozzle 11n of the nozzle row N1 and the corresponding nozzle 11n of the nozzle row N2 are positioned on a virtual line parallel to the conveyance direction (in
Each head 1 supplies inks of four colors in total: cyan (C), magenta (M), yellow (Y), and black (K). In the nozzle row N1, the ink of magenta (M) is jetted from the eight upstream nozzles 11n in the conveyance direction while the ink of black (K) is jetted from the eight downstream nozzles 11n in the conveyance direction. In the nozzle row N2, the ink of yellow (Y) is jetted from the eight upstream nozzles 11n in the conveyance direction while the ink of cyan (C) is jetted from the eight downstream nozzles 11n in the conveyance direction. In the head unit 1x, the plurality of nozzles 11n are aligned along the conveyance direction to jet the inks in the mutually different colors. By virtue of this, it is possible to overlap the four-color inks on the paper 9.
The plurality of nozzles 11n forming the nozzle row N1 are arranged to deviate to one side in the alignment direction so as to differ in position in the alignment direction from the plurality of nozzles 11n forming the nozzle row N2. In each of the nozzle rows N1 and N2, no nozzles 11n are formed in the center in the alignment direction (the part facing an aftermentioned dummy electrode 13d3 between the eight nozzles 11n corresponding to the respective colors).
Next, referring to
As shown in
The pressure chamber plate 11b is formed of a silicon single crystal substrate. The plurality of pressure chambers 11m are formed to penetrate through the pressure chamber plate 11b to communicate respectively with the plurality of nozzles 11n shown in
The flow channel plate 11c has a plane size larger than the pressure chamber plate 11b to some degree, and is bonded to the lower surface of the pressure chamber plate 11b. The flow channel plate 11c is formed therein with a manifold 11s2 which is part of the supply flow channel 11s, a flow channel 11t connecting the manifold 11s2 and each pressure chamber 11m, and a descender 11p connecting each pressure chamber 11m and the corresponding nozzle 11n.
A flexible damper film 11v is bonded to the lower surface of the flow channel plate 11c to cover the manifold 11s2. The damper film 11v has a function of attenuating pressure variation of the ink inside the manifold 11s2. A frame-like spacer S is fixed at the periphery of the damper film 11v.
The protection plate 11d is bonded to the lower surface of the spacer S to cover the damper film 11v. The damper film 11v faces the protection plate 11d across an interspace, and is protected by the protection plate 11d.
The nozzle plate 11e is formed with the plurality of nozzles 11n penetrating through the nozzle plate 11e. The nozzle plate 11e is bonded to the lower surface of the flow channel plate 11c.
The reservoir member 11a is formed with the reservoir 11s1 which is part of the supply flow channel 11s. The reservoir 11s1 opens at the lower surface of the reservoir member 11a. The reservoir member 11a is bonded to the upper surface of the flow channel plate 11c and on the upper surface of the protection member 15 such that the reservoir 11s1 overlaps with the manifold 11s2.
The supply flow channel 11s is provided independently for each color of the ink. That is, a supply flow channel 11s is provided to supply the ink of magenta (M) and another supply flow channel 11s is provided to supply the ink of black (K) to the pressure chamber row M1, while a supply flow channel 11s is provided to supply the ink of yellow (Y) and another supply flow channel 11s is provided to supply the ink of cyan (C) to the pressure chamber row M2. Each supply flow channel 11s is in communication with a tank retaining the ink of the corresponding color via a tube or the like. The ink in each tank flows into the supply flow channel 11s by the drive of a pump (not shown), and is supplied to the plurality of corresponding pressure chambers 11m.
The actuator unit 12 is arranged, as shown in
The vibration plate 12a and the common electrode 12b are formed on almost the entire upper surface 11b1 of the pressure chamber plate 11b to cover the plurality of pressure chambers 11m. On the other hand, the plurality of piezoelectric bodies 12c and the plurality of individual electrodes 12d1 and 12d2 are arranged respectively for the pressure chambers 11m (that is, to face the plurality of pressure chambers 11m respectively).
The vibration plate 12a is a film of silicon dioxide formed by oxidizing a surface of the silicon single crystal substrate used to form the pressure chamber plate 11b. The common electrode 12b is used commonly for the plurality of pressure chambers 11m, and arranged between the vibration plate 12a and the plurality of piezoelectric bodies 12c to face the plurality of pressure chambers 11m. The plurality of piezoelectric bodies 12c are made of a piezoelectric material such as lead zirconate titanate (or PZT) or the like, and arranged on the upper surface of the common electrode 12b to face the plurality of pressure chambers 11m respectively. The plurality of individual electrodes 12d1 and 12d2 are formed on the upper surfaces of the plurality of piezoelectric bodies 12c, respectively. The individual electrodes 12d1 and 12d2 are arranged respectively to face the pressure chambers 11m forming the pressure chamber rows M1 and M2.
The parts of each piezoelectric body 12c interposed between the individual electrodes 12d1 and the common electrode 12b and between the individual electrodes 12d2 and the common electrode 12b function as an actuator 12x deformable with an application of voltage to the individual electrodes 12d1 and 12d2. That is, the actuator unit 12 has a plurality of actuators 12x covering the plurality of pressure chambers 11m respectively. By driving the actuators 12x facing the pressure chambers 11m (that is, by deforming the actuators 12x with the application of voltage to the individual electrodes 12d1 or the individual electrodes 12d2 (such as becoming convex toward the pressure chambers 11m)), those pressure chambers 11m change in volume such that the inks inside the pressure chambers 11m are assigned with a pressure, thereby being jetted from the nozzles 11n.
As shown in
The dummy electrodes 13d1 to 13d3 have the same size and the same shape as the individual electrodes 12d1 and 12d2. In the individual electrode row D1, the individual electrodes 12d1 and the dummy electrodes 13d1 and 13d3 are aligned at regular intervals. In the individual electrode row D2, the individual electrodes 12d2 and the dummy electrodes 13d2 and 13d3 are aligned at regular intervals, too.
In positions facing the dummy electrodes 13d1 to 13d3, the piezoelectric bodies 12c are arranged but the pressure chambers 11m and the nozzles 11n are not arranged.
A protection film 12i is provided (see
The respective electrodes 12d1, 12d2, and 13d1 to 13d3 are connected to individual conductors 12e1, 12e2, and dummy conductors 13e1 to 13e3 via a conductive material B filling the through holes of the protection films 12i (see
Further, as described above, the piezoelectric bodies 12c are arranged in the positions facing the dummy electrodes 13d1 to 13d3. Therefore, in the same manner as the actuators 12x, those piezoelectric bodies 12c are also deformable in the parts interposed between the dummy electrodes 13d1 to 13d3 and the common electrode 12b, with an application of voltage. However, because no drive signal is supplied to the dummy electrodes 13d1 to 13d3, the voltage is not applied to the above parts which are thus not driven. Further, because neither pressure chambers 11m nor nozzles 11n are formed in the positions facing the dummy electrodes 13d1 to 13d3, even if the above parts were driven, they would still make no contributions to jetting the inks.
The individual conductors 12e1 and 12e2 are arranged in the alignment direction to form a first row E1 and a second row E2 aligning in the orthogonal direction. The plurality of first individual conductors 12e1 forming the first row E1 are arranged to deviate to one side in the alignment direction so as to differ in position in the alignment direction from the plurality of second individual conductors 12e2 forming the second row E2. Two dummy conductors 13e1 and 13e2 (hereinbelow, the first dummy conductor 13e1 will be used to refer to the dummy conductor provided on the other side of the first individual conductors 12e1 in the alignment direction while the second dummy conductor 13e2 will be used to refer to the dummy conductor provided on the one side of the second individual conductors 12e1 in the alignment direction) are provided respectively in the blank areas formed from such deviated arrangement (in particular, one on the other side of the first individual conductors 12e1 forming the first row E1 in the alignment direction and the other on the one side of the second individual conductors 12d2 forming the second row E2 in the alignment direction, respectively). Further, a dummy conductor 13e3 is provided in the center of each of the rows E1 and E2.
Because of arranging the first individual conductors 12e1 forming the first row E1 and the second individual conductors 12e2 forming the second row E2 in the above deviated manner, in an area A1 on one end side in the alignment direction, the first individual conductors 12e1 are aligned in the alignment direction without intervening the second individual conductors 12e2 therebetween, while in an area A2 on the other end side in the alignment direction, the second individual conductors 12e2 are aligned in the alignment direction without intervening the first individual conductors 12e1 therebetween. Between the areas A1 and A2 (between the one end portion and the other end portion), an area A3 of aligning the first individual conductors 12e1 and the second individual conductors 12e2 alternately in the alignment direction and an area A4 of aligning the dummy conductors 13e3 are formed alternately in the alignment direction.
The conductors 12e1, 13e1, and 13e3 belonging to the first row E1 extend in the orthogonal direction from the first row E1 toward the second row E2. The conductors 12e2, 13e2, and 13e3 belonging to the second row E2 extend in the orthogonal direction from the second row E2 toward the first row E1. The conductors 12e1, 12e2, and 13e1 to 13e3 have the same width w (the length along the alignment direction) with each other. The width w is constant along the orthogonal direction.
An individual contact point 12f is formed at the fore-end of each of the individual conductors 12e1 and 12e2. No individual contact point 12f is formed at the fore-end of each of the dummy conductors 13e1 to 13e3. Each of the individual contact points 12f constitutes the individual conductor of the present teaching, and has a width W larger than the width w of the respective individual conductors 12e1 and 12e2.
A pair of common contact points 12g are provided to interpose the individual contact points 12f in the alignment direction. The common contact points 12g correspond to the common conductor of the present teaching, and are provided respectively on the other side with respect to the first dummy conductors 13e1 in the alignment direction and on the one side with respect to the second dummy conductors 13e2 in the alignment direction. Each common contact point 12g is connected electrically with the common electrode 12b via a conductive material (not shown) filling a through hole penetrating the protection film 12i. That is, each common contact point is connected electrically with the plurality of actuators 12x. The plurality of individual conductors 12e1 and 12e2, the plurality of dummy conductors 13e1 to 13e3, and the common contact points 12g are aligned at regular intervals (interval D) in the alignment direction.
Each common contact point 12g includes a base 12gx and six terminals 12gt. The terminals 12gt are provided to distance each other in the alignment direction, three at one side and three at the other side of the base 12gx in the orthogonal direction. Each terminal 12gt has the same width as the respective conductors 12e1, 12e2, and 13e1 to 13e3. Further, the corresponding terminals 12gt have the same interval D in the alignment direction as the conductors 12e1, 12e2, and 13e1 to 13e3. That is, the terminals 12gt and the conductors 12e1, 12e2, and 13e1 to 13e3 having the same width with each other are aligned at the regular intervals (interval D) in the alignment direction.
Notches 12gs are formed between the terminals 12gt, one at one side and the other at the other side of each common contact point 12g in the orthogonal direction. Each notch 12gs extends in the orthogonal direction between the terminals 12gt adjacent in the alignment direction. By virtue of this, the spaces between the terminals 12gt are in communication with the outside of the common contact points 12g.
As shown in
The protection member 15 has a through hole 15b at the center in the orthogonal direction. The reservoir member 11a has a through hole 11a1 at the center in the orthogonal direction. The plurality of individual contact points 12f and the bases 12gx of the pair of common contact points 12g are exposed from the through holes 15b and 11a1.
One end of the COF 18 is bonded with an adhesive C to the upper surface 11b1 of the pressure chamber plate 11b, and connected electrically with the respective contact points 12f and 12g. The COF 18 passes through the through holes 15b and 11a1 and extends upward to let the other end be connected electrically with the controller 5 (see
A driver IC 19 is mounted between the one end and the other end of the COF 18. The driver IC 19 is connected electrically with each of the contact points 12f and 12g and the controller 5 via wires (not shown) formed on the COF 18. Based on a signal from the controller 5, the driver IC 19 generates a drive signal for driving the actuators 12x, and supplies the drive signal to the respective individual electrodes 12d1 and 12d2 via the respective individual conductors 12e1 and 12e2. The common electrode 12b is maintained at the ground potential. On the other hand, the drive signal is not supplied to the dummy conductors 13e1 to 13e3 and the dummy electrodes 13d1 to 13d3.
As shown in
The first bonding area 15A1 is in contact with the first individual conductor 12e1, the first dummy conductor 13e1, the dummy conductor 13e3 in the first row E1, and the terminals 12gt of the pair of common contact points 12g at the other side in the orthogonal direction. The second bonding area 15A2 is in contact with the second individual conductor 12e2, the second dummy conductor 13e2, the dummy conductor 13e3 in the second row E2, and the terminals 12gt of the pair of common contact points 12g at the one side in the orthogonal direction. The first dummy conductor 13e1 is positioned in the end portion of the first bonding area 15A1 at the other side in the alignment direction. The second dummy conductor 13e2 is positioned in the end portion of the second bonding area 15A2 at the one side in the alignment direction.
The first individual conductor 12e1, the first dummy conductor 13e1, the dummy conductor 13e3 in the first row E1, and the terminals 12gt of the pair of common contact points 12g at the other side in the orthogonal direction extend respectively from one end 15A1a of the first bonding area 15A1 to another end 15A1b in the orthogonal direction. The second individual conductor 12e2, the second dummy conductor 13e2, the dummy conductor 13e3 in the second row E2, and the terminals 12gt of the pair of common contact points 12g at the one side in the orthogonal direction extend respectively from an end 15A2a of the second bonding area 15A2 to another end 15A2b in the orthogonal direction. That is, the respective conductors 12e1, 12e2, and 13e1 to 13e3 exist across the entire width of the respective bonding areas 15A1 and 15A2. Further, because the conductors 12e1, 12e2, and 13e1 to 13e3 have the same width w with one another, the conductors 12e1, 12e2, and 13e1 to 13e3 in the bonding areas 15A have the same area with one another.
The first individual conductors 12e1 and the second individual conductors 12e2 have the same length along the orthogonal direction with each other. The dummy conductors 13e1 to 13e3 also have the same length along the orthogonal direction with each other, and longer than the individual conductors 12e1 and 12e2 along the orthogonal direction. The respective dummy conductors 13e1 to 13e3 extend across the first bonding area 15A1 and the second bonding area 15A2.
As shown in
As described above, according to the first embodiment, the first dummy conductors 13e1 and the second dummy conductors 13e2 are provided to face the first bonding area 15A1 and second bonding area 15A2 of the protection member 15. In particular, the first dummy conductors 13e1 are provided at the other side of the first individual conductors 12e1 forming the first row E1 in the alignment direction, while the second dummy conductors 13e2 are provided at the one side of the second individual conductor 12e2 forming the second row E2 in the alignment direction. That is, the first dummy conductors 13e1 and the second dummy conductors 13e2 are provided respectively in the areas formed by arranging the first individual conductors 12e1 forming the first row E1 to deviate from the second individual conductors 12e2 forming the second row E2 (see
The first dummy conductors 13e1 are provided to face an end portion of the first bonding area 15A1 on the other side in the alignment direction, while the second dummy conductors 13e2 are provided to face an end portion of the second bonding area 15A2 on the one side in the alignment direction (see
The first dummy conductors 13e1 extend from the end 15A1a of the first bonding area 15A1 in the orthogonal direction to the other end 15A1b, while the second dummy conductors 13e2 extend from one end to the other end of the second bonding area 15A2 in the orthogonal direction (see
The first dummy conductors 13e1 and the second dummy conductors 13e2 extend respectively across the first bonding area 15A1 and the second bonding area 15A2 (see
The individual conductors 12e1 and 12e2 and the dummy conductors 13e1 to 13e3 are aligned at regular intervals (interval D) in the alignment direction (see
The respective bonding areas 15A1 and 15A2 are not only in contact with the individual conductors 12e1 and 12e2 and the dummy conductors 13e1 to 13e3 but also in contact with the common contact points 12g (see
The individual conductors 12e1 and 12e2, the dummy conductors 13e1 to 13e3 and the common contact points 12g are aligned at regular intervals (interval D) in the alignment direction (see
The respective bonding areas 15A1 and 15A2 are in contact with the terminals 12gt of the common contact points 12g (see
The interval D along the alignment direction between the corresponding individual conductors 12e1 and 12e2 is the same as the interval D along the alignment direction between the corresponding terminals 12gt (see
Further, the respective terminals 12gt have the same width as the respective conductors 12e1, 12e2, and 13e1 to 13e3. The terminals 12gt and the conductors 12e1, 12e2, and 13e1 to 13e3 having the same width are aligned at regular intervals (interval D) in the alignment direction. In this case, it is possible to more evenly bond the protection member 15 to the flow channel substrate 11 in the alignment direction. By virtue of this, an even strength of bonding is more reliably obtainable in the alignment direction, thereby bringing in a better bonding of the protection member 15 to the flow channel substrate 11.
The common contact points 12g are formed with the notches 12gs to extend respectively between the terminals 12gt in the orthogonal direction (see
The respective dummy conductors 13e1 to 13e3 have the same width w (the length along the alignment direction) as the respective individual conductors 12e1 and 12e2 (see
In the bonding area 18A of the COF 18, the width w (the length along the alignment direction) of the respective dummy conductors 13e1 to 13e3 is shorter than the width W of the respective individual conductors 12e1 and 12e2 including the individual contact points 12f (see
The convexoconcave 15x of the protection member 15 is formed on the surface facing the upper surface 11b1 of the pressure chamber plate 11b (see
Such parts of the respective dummy conductors 13e1 to 13e3 as facing the bonding areas 15A1 and 15A2 have the same area as such parts of the respective individual conductors 12e1 and 12e2 as facing the bonding areas 15A1 and 15A2 (see
Next, referring to
In the first embodiment, as shown in
According to the second embodiment, with the larger width w2 of the respective dummy conductors 213e1 to 213e3, it is possible to increase the strength of bonding of the parts of providing the dummy conductors 213e1 to 213e3.
Next, referring to
In the first embodiment, as shown in
According to the third embodiment, because the dummy conductors 313e1 to 313e3 have the same length along the orthogonal direction as the individual conductors 12e1 and 12e2, it is easy to form those conductors. Further, only the first dummy conductors 313e1 or only the second dummy conductors 313e2 are present in positions facing the respective bonding areas 315A1 and 315A2. Therefore, compared to the case of both the first dummy conductors 13e1 and the second dummy conductors 13e2 are present in the respective areas 15A1 and 15A2 (see
Next, referring to
As shown in
In the first embodiment, as shown in
In the same manner as in the first embodiment, individual contact points 412f are formed at the fore-ends of the respective individual conductors 412e1 and 412e2. The individual contact points 412f are not formed at the fore-ends of the respective dummy conductors 413e1 and 413e2.
In the first embodiment, one COF 18 is connected with the individual contact points 12f connected to the first individual conductors 12e1 forming the first row E1, and with the individual contact points 12f connected to the second individual conductors 12e2 forming the second row E2. In contrast to that, in the fourth embodiment, two COFs 418a and 418b are connected individually with contact points 412f connected to the first individual conductors 412e1 forming the first row E41, and with contact points 412f connected to the second individual conductors 412e2 forming the second row E42.
When the COFs 418a and 418b are bonded, the COFs 418a and 418b will contract to cause wires 418e of the COFs 418a and 418b to change in position. Hence, such a problem may arise that the wires 418e cannot be connected electrically with the individual conductors 412e1 and 412e2. In this regard, according to the fourth embodiment, the individual conductors 412e1 and 412e2 are arranged radially. Therefore, the wires 418e of the COFs 418a and 418b are arranged likewise radially such that even if the COFs 418a and 418b contract to cause the wires 418e change in position, it is still possible to electrically connect the wires 418e with the individual conductors 412e1 and 412e2 by adjusting the positions of the COFs 418a and 418b in the orthogonal direction. Then, in such a manner, if the dummy conductors 413e1 and 413e2 are arranged radially, imitating the individual conductors 412e1 and 412e2, and provided in the respective bonding areas 415A1 and 415A2, then it is possible to attain a good bonding of the protection member 15 to the flow channel substrate 11.
While a few preferred embodiments of the present teaching were explained hereinabove, the present teaching is not limited to the embodiments described above, but can have various design changes and/or modifications without departing from the true scope and spirit set forth in the appended claims.
[Modifications]
As far as the dummy conductors do not contribute to the drive of the actuator, they may or may not be connected electrically with the actuator. The dummy conductors may not extend to the outside of the area of bonding the bonding member but be arranged within the areas of bonding the bonding member. The dummy conductors may not extend from one end to the other end in positions facing the bonding areas in the orthogonal direction, but be arranged in at least partially in positions facing the bonding areas. The numbers of the first dummy conductors and the second dummy conductors are respectively two in the above embodiments. However, the numbers may be respectively one or more. In positions facing the bonding area of the bonding member, the dummy conductors may have a smaller width (the length along the alignment direction) than the individual conductors. In the bonding area of the wiring substrate, the dummy conductors may be as wide as or wider than the individual conductors. If in positions facing the bonding area of the bonding member, the dummy conductors have the same areas as the individual conductors, then the dummy conductors may differ in shape from the individual conductors. In positions facing the bonding area of the bonding member, the dummy conductors may differ in area from the individual conductors.
It is possible to omit the dummy conductors 13e3 provided in the center of the respective rows E1 and E2 in the alignment direction in the first embodiment (see
In the first embodiment (see
In the fourth embodiment (see
The individual conductors, the dummy conductors, and the common conductor may not be aligned at regular intervals in the alignment direction. For example, the interval along the alignment direction between the common conductor and the individual conductors or dummy conductors adjacent to the common conductor in the alignment direction may differ from the interval along the alignment direction between the individual conductors and the dummy conductors. Further, the individual conductors and the dummy conductors may not be aligned at regular intervals along the alignment direction. For example, the interval along the alignment direction between the dummy conductors and the individual conductors adjacent to the dummy conductors in the alignment direction may differ from the interval along the alignment direction between the corresponding individual conductors.
The interval along the alignment direction between the corresponding terminals of the common conductor may differ from the interval along the alignment direction between the corresponding individual conductors. The notches may not be formed in the common conductor to extend between the plurality of terminals in the orthogonal direction, and the interspaces between the terminals may be closed. The bonding area of the bonding member may be in contact with other parts than the terminals of the common conductors. The common conductor may not have a plurality of terminals. The bonding area of the bonding member may not contact with the common conductor.
The concavities and convexities of the bonding member may not be formed on the surface facing the surface of the actuator substrate. The protection member 15 is exemplified as the bonding member in the above embodiments (see
The first individual conductors and the second individual conductors overlap in the orthogonal direction in the above embodiments (see
The actuator is not limited to the piezo method using the piezoelectric elements as in the above embodiments, but may be of other methods (such as a thermal method using heater elements, an electrostatic method using electrostatic force, and the like).
In the liquid jet head, the plurality of nozzles are not limited to being aligned to form acute angles with the conveyance direction, but may be aligned in a direction orthogonal to the conveyance direction. However, as in the above embodiments (see
The liquid jet head is not limited to jetting the four color inks but may jet, for example, a single color ink (only the black), or two color inks. The liquid jet head is not limited to a line type but may be of a serial type (such as a type of causing the head to scan along a direction orthogonal to the conveyance direction while jetting a liquid on a recording medium conveyed along the conveyance direction). Further, the liquid jet apparatus is not limited to having a head unit including a plurality of liquid jet heads, but may have a single liquid jet head. The liquid jetted by the liquid jet head is not limited to ink but may be any liquid (such as a treatment liquid or the like agglutinating or precipitating the ingredients of the ink). The recording medium is not limited to paper but may be any recordable medium (such as cloth or the like). The present teaching is not limited to printers but may also be applied to facsimiles, copy machines, multifunction peripheries, and the like.
Number | Date | Country | Kind |
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2017-070461 | Mar 2017 | JP | national |
Number | Name | Date | Kind |
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7213912 | Ito | May 2007 | B2 |
9840076 | Okui | Dec 2017 | B2 |
20160031214 | Okui et al. | Feb 2016 | A1 |
Number | Date | Country |
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2016-34739 | Mar 2016 | JP |
Number | Date | Country | |
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20180281413 A1 | Oct 2018 | US |