The present application claims priority from Japanese Patent Application No. 2018-161765 filed on Aug. 30, 2018, the disclosure of which is incorporated herein by reference in its entirety.
The present disclosure relates to a liquid discharge head configured to discharge a liquid, such as ink, on a medium.
There is known, as a liquid discharge apparatus, an ink-jet head of an ink-jet printer that forms an image by discharging ink on a recording medium while moving relative to the recording medium. For example, there is publicly known, as an ink-jet head included in a publicly known ink-jet printer, an ink-jet head that has a piezoelectric body in which piezoelectric material layers (ceramic sheet) are stacked.
The ink-jet head includes an actuator unit including the piezoelectric body in which the piezoelectric material layers are stacked and a channel unit including pressure chambers. A piezoelectric material layer included in the piezoelectric material layers has, on its surface, individual electrodes and another piezoelectric material layer included in the piezoelectric material layers has, on its surface, a common electrode. The individual electrodes are provided corresponding to the pressure chambers. The ink-jet head is controlled so that predefined voltage is simultaneously applied to two individual electrodes corresponding to two adjacent pressure chambers. Controlling the ink-jet head to discharge ink from the two adjacent pressure chambers to a nozzle enables a sufficient amount of ink discharge.
In a manufacturing process of the ink-jet head, the actuator unit may be joined to the channel unit with foreign matter, such as dust, interposed therebetween. This may cause a small crack in the piezoelectric body of the actuator unit. For example, in an area above a wall partitioning the two pressure chambers, pressure applied to the piezoelectric body when the actuator unit is joined to the channel unit can not escape, which easily cracks the piezoelectric body. Here, in order to discharge ink from two adjacent pressure chambers to one nozzle simultaneously, two individual electrodes corresponding to the two adjacent pressure chambers may be coupled to each other so that they function as one individual electrode. In that case, the coupling portion coupling the two individual electrodes to each other is positioned above the wall partitioning the two pressure chambers, which easily cracks the piezoelectric body as described above. When voltage is applied to the individual electrode with the piezoelectric body having the crack, a short circuit may occur between the coupling portion and the common electrode.
An object of the present disclosure is to provide a liquid discharge head in which, when one individual electrode is provided corresponding to two or more of pressure chambers, electrical reliability between a common electrode and a portion of the individual electrode positioned between the pressure chambers is achieved.
According to an aspect of the present disclosure, there is provided a liquid discharge head, including: a piezoelectric body including a plurality of piezoelectric layers stacked stacked in a stacking direction, the piezoelectric body having a first end and a second end which are away from each other in a first direction orthogonal to the stacking direction of the piezoelectric layers, a plurality of individual electrodes located on a first surface that is orthogonal to the stacking direction, and a first common electrode located on a second surface that is orthogonal to the stacking direction, the first common electrode being different in a position in the stacking direction from the first surface. Each of the individual electrodes includes a first portion and a second portion arranged in the first direction at an interval, and a third portion connecting the first portion and the second portion, the first portion being positioned between the first end and the third portion in the first direction, the third portion being positioned between the first portion and the second portion in the first direction, the second portion being positioned between the third portion and the second end in the first direction. The first portions, the second portions, and the third portions of the individual electrodes are arranged between the first end and the second end to form rows along a second direction orthogonal to the stacking direction and intersecting with the first direction, thus forming a first portion row, a second portion row, and a third portion row. The first common electrode includes: a first extending portion extending in the second direction to pass through a position between the first portion row and the second portion row in the first direction; a plurality of first protrusions protruding from the first extending portion toward the first end; and a plurality of second protrusions protruding from the first extending portion toward the second end. Each of the first protrusions partially overlaps in the stacking direction with one of the first portions of the individual electrodes forming the first portion row. Each of the second protrusions partially overlaps in the stacking direction with one of the second portions of the individual electrodes forming the second portion row. Portions of the first extending portion overlapping in the stacking direction with the third portions are formed having through holes passing through the first common electrode in the stacking direction.
In the above configuration, the portions of the first common electrode overlapping in the stacking direction with the third portions of the individual electrodes are formed having the through holes. The third portions of the individual electrodes thus do not overlap in the stacking direction with the first common electrode. In that configuration, when predefined voltage is applied to the individual electrodes, an electrical field in the stacking direction is not likely to occur between the third portions of the individual electrodes and the first common electrode. A short circuit between the third portions of the individual electrodes and the first common electrode in the piezoelectric body can thus be inhibited.
<Schematic Configuration of Printer>
An embodiment of the present disclosure is explained. As depicted in
A recording sheet 100, which is a recording medium, is placed on an upper surface of the platen 2. The carriage 3 driven by the carriage driving mechanism 4 reciprocates in the left-right direction (hereinafter referred to as the scanning direction) in an area facing the platen 2 along two guide rails 10 and 11. The carriage driving mechanism 4 includes a belt 12, two rollers 13 disposed at both sides in the scanning direction of the platen 2 with the platen 2 interposed therebetween, and a carriage driving motor 14. The carriage 3 is coupled to the belt 12. The belt 12 is wound around the two rollers 13 disposed away from each other in the scanning direction to form an elliptical ring that is long in the scanning direction when seen from above. As depicted in
The ink-jet head 5, which is carried on the carriage 3, reciprocates in the scanning direction together with the carriage 3. An ink supply unit 8 includes four ink cartridges 17, a cartridge holder 18 in which the four ink cartridges 17 are installed, and tubes (not depicted). The four ink cartridges 17 contain inks of four colors (black, yellow, cyan, and magenta), respectively. The ink-jet head 5 is connected to the four ink cartridges 17 via the tubes (not depicted). This allows the inks of four colors to be supplied from the ink supply unit 8 to the ink-jet head 5.
A lower surface of the ink-jet head 5 (the far side of the sheet surface of
The conveyance mechanism 6 has two conveyance rollers 19a and 19b that are disposed to interpose the platen 2 therebetween in the front-rear direction. The conveyance mechanism 6 conveys the recording sheet 100 placed on the platen 2 frontward (hereinafter also referred to as the conveyance direction) by use of the two conveyance rollers 19a and 19b.
The controller 7 includes a Read Only Memory (ROM), a Random Access Memory (RAM), and an Application Specific Integrated Circuit (ASIC) including a control circuit, and the like. The controller 7 controls the ASIC to execute a variety of processing, such as printing on the recording sheet 100, in accordance with programs stored in the ROM. For example, in print processing, the controller 7 controls the ink-jet head 5, the carriage driving motor 14, and the like to execute printing of an image on the recording sheet 100 based on a printing command input from an external apparatus, such as a PC. Specifically, the controller 7 alternately executes an ink discharge operation and a conveyance operation. In the ink discharge operation, ink is discharged during movement in the scanning direction of the ink-jet head 5 and the carriage 3. In the conveyance direction, the recording sheet 100 is conveyed in the conveyance direction by a predefined amount by use of the conveyance rollers 18 and 19.
The ink-jet head 5 mainly includes a channel unit 20, a vibration plate 30, a piezoelectric body 40, and a trace member 50 (see
The vibration plate 30 is a substantially rectangular metal plate that is long in the conveyance direction. Similarly, the metal plates 21A to 21E and the nozzle plate 22 are substantially rectangular plates when seen from above. As depicted in
The plate 21A is a metal plate in which openings functioning as pressure chambers 26 are formed regularly. The plate 21A has openings at positions overlapping with the four openings 31a to 31d of the vibration plate 30. The pressure chambers 26 form a pressure chamber row 25 in which the pressure chambers 26 are arranged in the conveyance direction at an arrangement pitch (arrangement interval) P. Although only some of pressure chamber rows 25 are depicted in
Six of the eight pressure chamber rows 25 are pressure chamber rows 25 for color inks, and the remaining two pressure chamber rows 25 are pressure chamber rows 25 for black ink. As depicted in
The position in the conveyance direction of each pressure chamber 26 in one of the two pressure chamber rows 25 for black ink is the same as that in the other. The same is true of the two pressure chamber rows 25 for cyan ink, the two pressure chamber rows 25 for magenta ink, and the two pressure chamber rows 25 for yellow ink. Two pressure chambers 26 that are included in the pressure chambers 26 forming the two pressure chamber rows 25 for each of the inks and are arranged at the same position in the conveyance direction may be referred to as a pressure chamber 26 pair.
As depicted in
The nozzle plate 22 is a plate made using a synthetic resin (e.g., polyimide resin). Each nozzle 23 is formed corresponding to the pressure chambers 26 in the plate 21A. As described above, one nozzle 23 is formed corresponding to two pressure chambers 26 forming the pressure chamber 26 pair.
As depicted in
The vibration plate 30 and the plates 21A to 21E are metal plates, and thus they can be joined with each other by metal diffusion joining. The nozzle plate 22 is a plate made using resin, and thus the nozzle plate 22 is joined to the plate 21E by adhesive instead of metal diffusion joining. The nozzle plate 22 may be a metal plate. In that case, the nozzle plate 22 can be joined to the plate 21E by metal diffusion joining similarly to the joining of the vibration plate 30 to the plates 21A to 21E. Or, all of the plates may be joined with each other by adhesive or the like.
<Piezoelectric Body 40>
For example, as depicted in
The configuration of the piezoelectric body 40 is explained below. As depicted in
In the following, ends in the scanning direction of the upper piezoelectric layer 140 are referred to as ends 140L and 140R, and ends in the conveyance direction of the upper piezoelectric layer 140 are referred to as ends 140U and 140D (see
As depicted in
As depicted in
The terminals 180L and 180R are respectively provided with bumps 182L and 182R that are connected to terminals (not depicted) of a Chip On Film (COF) 51 described below. When the bumps 182L and 182R are connected to the COF 51, predefined potential (e.g., 0V) can be supplied from the driver IC 58 to the intermediate common electrode 241 and the lower common electrode 341 via the COF 51.
<Individual Electrode 141>
As depicted in
The first individual electrode row 150 from the left among the four individual electrode rows 150 corresponds to the two pressure chamber rows 25 for black ink. The second individual electrode row 150 from the left corresponds to the two pressure chamber rows 25 for cyan ink. The third individual electrode row 150 from the left corresponds to the two pressure chamber rows 25 for magenta ink. The fourth individual electrode row 150 from the left corresponds to the two pressure chamber rows 25 for yellow ink.
As depicted in
<Intermediate Common Electrode 241>
As depicted in
The extending portion 242 and the extending portion 243 are positioned so that they do not overlap in the stacking direction with the pressure chambers 26 and the individual electrodes 141. As depicted in
The protrusion 245L has the wide portion 246L and the narrow portion 247L. The protrusion 245R has the wide portion 246R and the narrow portion 247R. The protrusions 245L and 245R are symmetric, the wide portions 246L and 246R are symmetric, and the narrow portions 247L and 247R are symmetric. In the following, when there is no need to distinguish between the left and the right, the protrusions 245L and 245R may be collectively referred to as a protrusion 245, the wide portions 246L and 246R may be collectively referred to as a wide portion 246, and the narrow portions 247L and 247R may be collectively referred to as a narrow portion 247.
<Lower Common Electrode 341>
As depicted in
The four extending portions 344 extend in the conveyance direction through an area between the individual electrodes 141 forming two individual electrode rows 150 that are arranged adjacently to each other in the scanning direction so that the four extending portions 344 do not overlap in the stacking direction with the wide portions 142 of the individual electrodes 141 forming the individual electrode rows 150 (see
Referring to
The pressure chamber 26 is longer in the scanning direction than the wide portion 142 (wide portions 142L and 142R) of the individual electrode 141. The total length in the scanning direction of the wide portion 142 and the narrow portion 144 is longer than the length in the scanning direction of the pressure chamber 26. The length in the scanning direction of the protrusion 245 of the intermediate common electrode 241 is substantially the same as the length in the scanning direction of the wide portion 142 of the individual electrode 141.
As depicted in
As depicted in
The nozzle 23 is positioned at substantially a center portion of the individual electrode 141 (substantially a center portion of the coupling portion 143 of the individual electrode 141). In other words, the nozzle 23 is positioned at an area between two pressure chambers 26 corresponding to one individual electrode 141 in the scanning direction. The nozzle 23 is positioned at substantially a center portion of the individual electrode 141 (substantially a center portion of the coupling portion 143 of the individual electrode 141) in the conveyance direction.
A center position in the conveyance direction of the protrusion 245 of the intermediate common electrode 241, a center position in the conveyance direction of the pressure chamber 26, and a center position in the conveyance direction of the wide portion 142 of the individual electrode 141 are substantially identical to each other in the conveyance direction. The pressure chamber 26 is longer in the conveyance direction than the narrow portion 247 of the intermediate common electrode 241. The ratio of the length in the conveyance direction of the pressure chamber 26 to the length in the conveyance direction of the narrow portion 247 of the intermediate common electrode 241 is approximately 2:1. In that configuration, both ends (approximately one-fourth of the length in the conveyance direction of the pressure chamber) in the conveyance direction of the pressure chamber 26 do not overlap in the stacking direction with the protrusions 245 of the intermediate common electrode 241. The wide portion 142 of the individual electrode 141 is longer in the conveyance direction than the pressure chamber 26.
Referring to
The length in the scanning direction of the protrusion 345 of the lower common electrode 341 is substantially the same as the length in the scanning direction of the wide portion 142 of the individual electrode 141. The positions in the scanning direction of inner ends of two pressure chambers 26 corresponding to one individual electrode 141 are substantially the same as the positions in the scanning direction of protruding ends in the scanning direction of the protrusions 345 of the lower common electrode 341. The positions in the scanning direction of outer ends of two pressure chambers 26 corresponding to one individual electrode 141 are substantially the same as the positions in the scanning direction of ends in the scanning direction of the extending portion 344 of the lower common electrode 341.
The positions in the scanning direction of outer ends in the scanning direction of the wide portions 142 are substantially the same as the positions in the scanning direction of protruding ends in the scanning direction of the protrusions 245 of the intermediate common electrode 241 (see
A center position in the conveyance direction of the protrusion 345 of the lower common electrode 341 is substantially the same as a center position in the conveyance direction of an area between two pressure chambers 26 arranged adjacently to each other in the conveyance direction. The length in the conveyance direction of the area between the two pressure chambers 26 arranged adjacently to each other in the conveyance direction is shorter than the length in the conveyance direction of the protrusion 345 of the lower common electrode 341. In that configuration, both ends in the conveyance direction of the pressure chamber 26 overlap in the stacking direction with the protrusion 345 of the lower common electrode 341. The length in the conveyance direction of the overlap portion in the stacking direction of the pressure chamber 26 with the protrusion 345 of the lower common electrode 341 is shorter than one-fourth of the length in the conveyance direction of the pressure chamber 26. As described above, in both ends in the conveyance direction of the pressure chamber 26, approximately one-fourth of the length in the conveyance direction of the pressure chamber 26 does not overlap in the stacking direction with the protrusion 245 of the intermediate common electrode 241. Thus, each protrusion 345 of the lower common electrode 341 does not overlap in the stacking direction with each protrusion 245 of the intermediate common electrode 241.
As described above, the center position in the conveyance direction of the pressure chamber 26 is substantially the same, in the conveyance direction, as the center position in the conveyance direction of the wide portion 142 of the individual electrode 141. The wide portion 142 of the individual electrode 141 is longer in the conveyance direction than the pressure chamber 26. In that configuration, both ends in the conveyance direction of the wide portion 142 overlap in the stacking direction with the protrusion 345 of the lower common electrode 341. The length in the conveyance direction of the overlap portion in the stacking direction of the wide portion 142 with the protrusion 345 of the lower common electrode 341 is longer than the length in the conveyance direction of the overlap portion in the stacking direction of the pressure chamber 26 with the protrusion 345 of the lower common electrode 341.
<Trace Member 50>
As depicted in
<Driving of Piezoelectric Element 401>
The piezoelectric body 40 is a substantially rectangular plate-like member in a planar view (see, for example,
When ink is discharged from two pressure chambers 26 corresponding to one individual electrode 141, the first potential is applied to the individual electrode 141 and then the potential to be applied returns to the second potential. Namely, a pulse-like voltage signal, in which the potential increases from the second potential to the first potential and the potential returns to the second potential after predefined time is elapsed, is applied to the individual electrode 141. When the first potential is applied to the individual electrode 141, the difference in potential between the individual electrode 141 and the intermediate common electrode 241 is eliminated. This makes the first active portion 41 that is deformed to be convex downward (pressure chamber 26 side) return to its original state. In that situation, the first active portion 41 is deformed upward, increasing the volume of the pressure chambers 26. When the first active portion 41 is deformed upward, the difference in potential between the individual electrode 141 and the lower common electrode 341 (here, 24V) is caused to deform the second active portion 42. The deformation of the second active portion 42 moves center portions of the pressure chambers 26 upward, thus making the increase in volume of the pressure chambers 26 large. When the potential of the individual electrode 141 has returned to the second potential, the difference in potential between the individual electrode 141 and the lower common electrode 341 is eliminated and the second active portion 42 returns to its original state. On the other hand, the potential difference between the first potential and the second potential (here, 24V) is generated between the individual electrode 141 and the intermediate common electrode 241. The first active portion 41 is thus deformed to be convex downward (pressure chamber 26 side). The deformation of the first active portion 41 applies pressure to two pressure chambers 26, discharging ink in the two pressure chambers 26 from the nozzle 23 communicating with the two pressure chambers 26.
<Technical Effects of the Embodiment>
In the above embodiment, one individual electrode 141 is provided corresponding to two pressure chambers 26. The wide portions 142L and 142R of the individual electrode 141 are arranged to overlap in the stacking direction with the two pressure chambers 26, respectively. The coupling portion 143 couples the wide portion 142L with the wide portion 142R, and thus applying predefined voltage to one individual electrode 141 allows ink to be simultaneously discharged from the two pressure chambers 26 to the corresponding nozzle 23. This results in a sufficient ink amount for ink discharge.
As depicted in
In this embodiment, the through holes 248 are formed in the areas of the intermediate common electrode 241 overlapping in the stacking direction with the coupling portions 143, and thus the coupling portions 143 do not overlap in the stacking direction with the intermediate common electrode 241. In that configuration, when predefined voltage is applied to the individual electrode 141, the electric field between the coupling portion 143 and the intermediate common electrode 241 that is high in the stacking direction is not likely to occur. Even when the piezoelectric material layer positioned below the coupling portion 143 is cracked as described above, it is possible to reduce the possibility of breakdown via the crack and to increase the reliability of electrical connection between the piezoelectric body 40 and the COF 51.
In general, when the piezoelectric body 40 is formed having a metal film, such as the individual electrode 141, residual stress remaining on the metal film is larger than residual stress remaining on the piezoelectric material layer after baking. This causes a warp or warpage of the piezoelectric body 40. Especially, when the dimension of the metal film on the piezoelectric body 40 is large, like the individual electrode 141, the piezoelectric body 40 is greatly warped. The length L1 in the conveyance direction of the coupling portion 143 is thus preferably short. In order to stably supply electrical charge in the intermediate common electrode 241, the sum (La+Lb) of the distance La between the end close to the end 240U of the through hole 248 and the end close to the end 240U of the wide portion 246 and the distance Lb between the end close to the end 240D of the through hole 248 and the end close to the end 240D of the wide portion 246 is preferably large. Thus, in this embodiment, the sum of the distance La and the distance Lb is made to be larger than the length L1 in the conveyance direction of the coupling portion 143 (L1<La+Lb, L1<2La). This stably supplies electrical charge in the intermediate common electrode 241 while reducing the warp of the piezoelectric body 40. When the individual electrode 141 is formed through printing by use of a mask, the length L1 in the conveyance direction of the coupling portion 143 is preferably equal to or more than 60 μm due to manufacturing reasons.
In the above embodiment, the individual electrode 141 includes the two narrow portions 144L and 144R. As depicted in
In contrast, when the bump 191 is provided in one of the narrow portions 144L and 144R as depicted in
In the above embodiment, one of the narrow portions 144 (e.g., the narrow portion 144R) is not provided with the bump 191. The narrow portion 144 included in the two narrow portions 144 and provided with no bump 191 may thus be removed from the individual electrode 141. In this embodiment, however, the individual electrode 141 includes the narrow portions 144 provided with no bumps 191, which makes the individual electrode 141 symmetric. Deformation of the piezoelectric element 401 can thus affect the two piezoelectric chambers 26 corresponding to one individual electrode 141 uniformly, making it possible to improve discharge characteristics of the ink-jet head.
In the above embodiment, the bump 191 is provided in one of the narrow portions 144, and no bump 191 is provided at a barycentric position of the individual electrode 141. When the bump 191 is provided at the barycentric position of the individual electrode 141, electrical charge is easily and uniformly supplied to two wide portions 142 of the individual electrode 141 separated from each other in the scanning direction. In this embodiment, however, the coupling portion 143 is on the barycentric position of the individual electrode 141. When the bump 191 is provided at the coupling portion 143, the bump 191 preferably does not overlap in the stacking direction with the intermediate common electrode 241 for the same reason as the case in which the coupling portion 143 is provided not to overlap in the stacking direction with the intermediate common electrode 241. Namely, the length D in the conveyance direction of the bump 191 is preferably shorter than the length L2 in the conveyance direction of the opening 143. However, manufacturing variability in the bump 191 may make the length D in the conveyance direction of the bump 191 longer than the length L2 in the conveyance direction of the opening 143. In that case, the bump 191 may overlap in the stacking direction with the intermediate common electrode 241. In view of the above, the bump 191 is provided at one of the narrow portions 144 instead of at the barycentric position of the individual electrode 141 in the above embodiment. Since the bump 191 is provided in one of the narrow portions 144, the length D in the conveyance direction of the bump 191 can be longer than the length L2 in the conveyance direction of the opening 143. This improves the reliability of electrical connection between the piezoelectric body 40 and the COF 51.
In the above embodiment, the distance La between the end close to the end 240U of the through hole 248 and the end close to the end 240U of the wide portion 246 is the same as the distance Lb between the end close to the end 240D of the through hole 248 and the end close to the end 240D of the wide portion 246 (La=Lb). The present disclosure, however, is not limited thereto, and the distance La may be different from the distance Lb. When electrical charge is supplied from the side close to the end 240U to the intermediate common electrode 241 in the modified embodiment, the distance La between the end close to the end 240U of the through hole 248 and the end close to the end 240U of the wide portion 246 can be longer than the distance Lb between the end close to the end 240D of the through hole 248 and the end close to the end 240D of the wide portion 246 (La>Lb). In this case, electrical charge flowing through the extending portion 244 from the end 240U toward the end 240D can be efficiently supplied to each protrusion 245.
In the above embodiment, the thickness in the stacking direction of the intermediate common electrode 241 is uniform. The present disclosure, however, is not limited thereto. For example, as depicted in
In the above embodiment, the length W1 in the conveyance direction of the wide portion 246 is substantially the same as the length in the conveyance direction of the pressure chamber 26. The present disclosure, however, is not limited thereto. For example, as depicted in
In the above embodiment, the piezoelectric body 40 has three piezoelectric layers and the upper surface of each of the piezoelectric layers is formed having the electrode(s). The present disclosure, however, is not limited thereto. The piezoelectric body may have two or more or three or more piezoelectric layers and a lower surface of each of the piezoelectric layers may be formed having the electrode(s). In the above embodiment, the piezoelectric body has two common electrodes (the intermediate common electrode and the lower common electrode). The present disclosure, however, is not limited thereto. The piezoelectric body may have only one common electrode. The shape of the common electrode (the shape of the extending portions and the shape of the protrusions) may be determined as needed. In the above embodiment, the individual electrode 141 has the wide portions 142 and the narrow portions 144. The shape of the individual electrode is not necessarily limited thereto. For example, the width in the conveyance direction of the individual electrode may be uniform in the scanning direction. The number of individual electrode rows, the number of individual electrodes per one individual electrode row, the pitch in the scanning direction of individual electrodes, the amount of shift in the scanning direction of adjacent individual electrode rows, and the like may be determined as appropriate without being limited to the examples in the above embodiment. In other words, the number of pressure chamber rows, the number of pressure chambers per one pressure chamber row, the pitch in the scanning direction of pressure chambers, the amount of shift in the scanning direction of adjacent pressure chamber rows, and the like may be determined as appropriate without being limited to the examples in the above embodiment.
Although one individual electrode is provided corresponding to two pressure chambers in the above embodiment, one individual electrode may be provided corresponding to three or more pressure chambers. Although one nozzle is provided corresponding to two pressure chambers in the above embodiment, one nozzle may be provided corresponding to one pressure chamber. Further, in the above embodiment, ink is supplied from the same manifold to two pressure chambers corresponding to one individual electrode. However, ink may be supplied from different manifolds to two pressure chambers corresponding to one individual electrode. In that configuration, ink may be supplied from one ink cartridge to multiple manifolds through which ink is supplied to two pressure chambers. Or, ink may be supplied from different ink cartridges to multiple manifolds through which ink is supplied to two pressure chambers. Alternatively, ink supplied to multiple manifolds may be circulated.
The embodiment and modified embodiments can be combined as appropriate. The embodiment and modified embodiments are examples in which the present disclosure is applied to the ink-jet head 5 configured to perform printing of an image or the like by discharging ink on a recording sheet. In the above embodiment, the ink-jet head 5 is a serial-type ink-jet head. The present disclosure, however, is not limited thereto. The present disclosure is applicable to a line-type ink-jet head. The present disclosure is not limited to the ink-jet head configured to discharge ink. The present disclosure is applicable to liquid discharge apparatuses for various uses except for the printing of an image or the like. For example, the present disclosure is applicable to a liquid discharge apparatus configured to form a conductive pattern on a surface of a substrate by discharging a conductive liquid on the substrate.
Number | Date | Country | Kind |
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2018-161765 | Aug 2018 | JP | national |