JP6929678B2 - Inkjet heads and printers - Google Patents

Description

Embodiments of the present invention relate to inkjet heads and printers.

Conventionally, as a printer, a technique of circulating ink in an inkjet head and ejecting ink from a nozzle of the inkjet head has been known. Further, there are known printers that circulate ink during non-printing such as ink filling and maintenance, and printers that circulate ink during printing.

A printer that circulates ink during non-printing does not circulate ink during printing. However, a printer that circulates ink during non-printing cannot sufficiently obtain the merits of ink circulation.

A printer that circulates during printing requires that the pressure in the nozzle and the vicinity of the nozzle be uniform in the print head. However, in a printing device that circulates during printing, the ink flow rate in the vicinity of the nozzles is different, so that the temperature and the state of pigment settling vary.

Japanese Unexamined Patent Publication No. 2011-062902

An object to be solved by the present invention is to provide an inkjet head and a printer in which the flow rate in the vicinity of the nozzle is uniform in the non-printing state and the pressure in the vicinity of the nozzle is uniform in the printing state.

The inkjet head of the embodiment includes a head member, a nozzle plate, one inlet, and a plurality of outlets. The head member includes a piezoelectric actuator having a plurality of pressure chambers arranged along one direction, and a plurality of liquid chambers extending in the one direction adjacent to the piezoelectric actuator in a direction orthogonal to the one direction. include. The nozzle plate has a plurality of nozzles arranged at positions facing the plurality of pressure chambers, and covers the head member to form a common liquid chamber together with the plurality of pressure chambers and the liquid chamber. The inflow port is provided in the liquid chamber on the primary side of the common liquid chamber. The outlet is provided in the liquid chamber on the secondary side of the common liquid chamber. Some of the outlets out of the plurality of outlets are arranged at the same position as the inlet in one direction. Of the plurality of outlets, the outlets of other parts other than the partial outlets are arranged at positions where the distance from the inlet to the plurality of pressure chambers through which ink flows is constant. NS. Wherein the plurality of outlets, the outlet of said portion of said plurality of outlet opens at the time of printing, before Symbol other part the outlet is closed, and the flow of said portion at the time of non-printing outlet closed, the outlet of the other portion opens the ink flowing from the front Symbol inlet to said outlet is circulated.

Explanatory drawing which shows typically the structure of the printer which concerns on 1st Embodiment. An exploded perspective view showing the configuration of an inkjet head used in the printer. The perspective view which shows the main part structure of the inkjet head in an enlarged manner. The side view which shows the main part composition of the inkjet head in an enlarged manner. The plan view which shows the structure of the inkjet head by omitting a part. Side view showing the configuration of the inkjet head Explanatory drawing which shows an example of use of the inkjet head. Explanatory drawing which shows an example of use of the inkjet head. Explanatory drawing which shows an example of use of the inkjet head which concerns on 2nd Embodiment. Explanatory drawing which shows an example of use of the inkjet head which concerns on 3rd Embodiment.

Hereinafter, the printer 100 according to the embodiment will be described with reference to FIGS. 1 to 8. In the figure, arrows X, Y, and Z indicate three directions orthogonal to each other. In addition, for the sake of explanation in each figure, the configuration is shown enlarged, reduced, or omitted as appropriate.

FIG. 1 is a perspective view showing a printer 100 according to the present embodiment. FIG. 2 is an exploded perspective view showing the structure of the inkjet head 200 used in the printer 100 with a part omitted.

In each figure, the nozzles 11a are arranged upward for convenience of explanation, but the inkjet head 200 is provided on the printer 100 with the nozzles 11a facing downward.

As shown in FIG. 1, the printer 100 includes an inkjet head 200, a circulation circuit 300, a flow path switching member 400, and a control device 500. Further, the printer 100 supplies a sheet-shaped recording medium such as paper sheets to the inkjet head 200, and discharges the recording medium printed by the ink ejected from the inkjet head 200, and each component. Includes the outer body, etc. that houses the The printer 100 of the present embodiment is a so-called circulation type in which ink is constantly circulated and supplied to the inkjet head 200.

As shown in FIGS. 1, 2 and 6, the inkjet head 200 includes a head member 10 and a nozzle plate 11 on which a plurality of nozzles 11a are formed. The inkjet head 200 constitutes a common liquid chamber 70 in an internal space composed of a head member 10 and a nozzle plate 11.

The head member 10 includes a pair of actuator units 12 and 13 arranged to face each other on the lower surface side of the nozzle plate 11, and a pair of covers 14 and 15 covering both sides of the pair of actuator units 12 and 13. I have.

The nozzle plate 11 is formed in a rectangular plate shape. The nozzle plate 11 has a plurality of nozzles 11a arranged along one direction. The nozzle plate 11 covers the pair of actuator units 12 and 13 and the pair of covers 14 and 15 from above in FIG.

The actuator units 12 and 13 have a base portion 20. The base portion 20 is formed in a rectangular parallelepiped shape having upper and lower surfaces orthogonal to the Z axis, front and back surfaces orthogonal to the X axis, and both side surfaces orthogonal to the Y axis. The base portion 20 is made of a material selected from, for example, metal, ceramic or resin. In the present embodiment, the base portion 20 will be described below in a posture along the X-axis in the thickness direction, the Y-axis in the longitudinal direction, and the Z-axis in the width direction.

The piezoelectric actuator 21 is fixed to the upper surface (first surface) of the base portion 20 which is an end surface close to the nozzle 11a via the adhesive layer 27.

As shown enlarged in FIGS. 3 and 4, the piezoelectric actuator 21 (actuator) has a plurality of driving elements 22 arranged in the Y direction. The piezoelectric actuator 21 has a plurality of pressure chambers 23 arranged in one direction in which a plurality of driving elements 22 are arranged, that is, in the Y direction. The pressure chamber 23 includes a space sandwiched on both sides by a plurality of driving elements 22. The plurality of pressure chambers 23 are arranged corresponding to the nozzles 11a of the nozzle plate 11. That is, the drive elements 22 for ejecting ink from each nozzle 11a are arranged on both sides of each pressure chamber 23. Ink is stored inside each pressure chamber 23. The flow path cross-sectional areas of the plurality of pressure chambers 23 are configured to be the same. That is, the plurality of pressure chambers 23 have the same flow path cross-sectional area when the drive element 22 is driven, and have the same flow path cross-sectional area when the drive element 22 is not driven.

The drive element 22 has two piezoelectric elements 24a and 24b made of, for example, a PZT-based piezoelectric ceramic material. The drive element 22 has a first piezoelectric element 24a located near the nozzle 11a and a second piezoelectric element 24b located far from the nozzle 11a. The first piezoelectric element 24a and the second piezoelectric element 24b are polarized so that their polarization directions are opposite to each other, and are bonded to each other via the adhesive layer 25. An electrode 26 is provided on the surface of the drive element 22 arranged in the pressure chamber 23, that is, on the inner surface of the pressure chamber 23.

As shown in FIG. 2, an ink guide 30 is formed on the surface (second surface) of the base portion 20. The ink guide 30 includes a T-shaped guide rib 31 that rises in the X direction from the second surface, and a cylindrical guide tube 32 that extends downward from the central portion of the guide rib 31 in the Y direction. The guide rib 31 and the guide tube 32 are integrally formed.

The guide rib 31 is integrally formed with the base portion 20 by molding or the like when forming the base portion 20, for example. The guide rib 31 has an outer rib 33 extending to the upper and lower ends along the longitudinal edge of the base portion 20, and an inner rib 34 extending in the Y direction at the central portion of the base portion 20 in the Z direction. A plurality of positioning protrusions 33a are formed on the tip surface of the outer rib 33.

Three guide pipes 32 provided in the first actuator unit 12 are provided in the guide ribs 31. The guide pipes 32 of the first actuator unit 12 are arranged at three positions, the center position and the both end positions of the inner rib 34, respectively. The guide tube 32 provided in the first actuator unit 12 constitutes an ink flow path that communicates the liquid chamber 71 formed on the upper side of the guide rib 31 and the circulation circuit 300.

The guide tube 32 provided in the second actuator unit 13 is provided at one position at the center of the inner rib 34. The guide tube 32 provided in the second actuator unit 13 constitutes an ink flow path that communicates the liquid chamber 72 formed on the upper side of the guide rib 31 and the circulation circuit 300.

That is, the first actuator unit 12 and the second actuator unit 13 have different configurations in terms of the number of guide tubes 32, but other configurations have the same configuration.

The base portion 20 has a plurality of drive ICs 41 for driving the operation of the piezoelectric actuator 21 and a plurality of wirings 42 (electrodes) for connecting the drive IC 41 and the electrodes 26 on the back surface (third surface) of the base portion 20. , Have. That is, the back surface of the base portion 20 functions as a printed circuit board. The wiring 42 has a configuration in which there is a one-to-one correspondence with the drive element 22. Further, the base portion 20 has an electrical connection portion 43 formed continuously with the wiring 42 on the back surface.

The base portion 20 has a plurality of positioning recesses 20a on one end side in the Y direction of the back surface. The base portion 20 is formed with an outer rib 36 that stands up in the X direction at the edge of the back surface on the other end side in the Y direction. The outer rib 36 reaches the upper and lower ends of the base portion 20. The outer rib 36 has a plurality of positioning protrusions 36a on its protruding tip surface.

The first cover 14 is provided on the surface side of the first actuator unit 12. The first cover 14 has a plate-shaped portion 51 and an outer rib 52. The plate-shaped portion 51 covers the surface of the first actuator unit 12 with a liquid chamber 71 formed between the first cover 14 and the first actuator unit 12 and an ink flow path interposed therebetween. The outer rib 52 is erected from the edge of the plate-shaped portion 51 on the other end side in the Y direction.

The first cover 14 is formed in an L shape in a plan view. The plate-shaped portion 51 has a positioning recess 51a at the edge on one end side in the Y direction. The outer rib 52 bends in the X direction toward the first actuator unit 12 and stands upright to form the liquid chamber 71 in the assembled state. The outer rib 52 has a plurality of positioning protrusions 52a.

The second cover 15 is provided on the back surface side of the second actuator unit 13. The second cover 15 has a plate-shaped portion 61 and an ink guide 62. The plate-shaped portion 61 covers the back surface of the second actuator unit 13 with a liquid chamber 71 formed between the second cover 15 and the second actuator unit 13 and an ink flow path interposed therebetween. The ink guide 62 is formed on the inner surface of the plate-shaped portion 61. The plate-shaped portion 61 has a positioning recess 61a at the end edge on the other end side in the Y direction.

The ink guide 62 includes an L-shaped guide rib 63 that rises in the X direction from the inner surface, and a cylindrical guide tube 64 that extends downward from the center portion and both end portions of the guide rib 63 in the Y direction. The guide rib 63 and the guide tube 64 are integrally formed. The guide rib 63 constitutes the liquid chamber 73. The guide tube 64 constitutes an ink flow path. The guide rib 63 has an outer rib 65 extending from the center to the upper end along the edge of the second cover 15 on one end side in the Y direction, and an inner rib 66 extending in the Y direction at the central portion of the second cover 15 in the Z direction. .. The outer rib 65 and the inner rib 66 are integrally formed, for example, when the second cover 15 is formed. The outer rib 65 has a plurality of positioning protrusions 65a.

The first and second actuator units 12 and 13 and the first and second covers 14 and 15 are combined to form the head member 10. At this time, as shown in FIGS. 2 and 5, the plurality of positioning protrusions 33a, 52a, 36a, 65a are positioned so as to be inserted into the plurality of positioning recesses 51a, 20a, 20b, 61a. Then, the nozzle plate 11 is fixed to the head member 10.

As shown in FIGS. 1, 5 and 6, in the assembled head member 10, the tip surfaces of the outer ribs 33, 36, 52, 65 and the inner ribs 34, 66 abut against the surfaces of the opposing members. Three liquid chambers 71 to 73 partitioned by a pair of base portions 20 are formed in the upper half portion of the head member 10. That is, the plate-shaped outer ribs 33, 36, 52, and 65 formed at both ends in the Y direction form the side portions of the liquid chambers 71 to 73, and the plate-shaped inner ribs 34 extending in the Y direction at the central portion in the Z direction. 66 forms the bottom of the liquid chambers 71-73.

Further, the guide tubes 32, 32, 64 extending from the center of the three inner ribs 34, 34, 66 form an ink flow path communicating with the liquid chambers 71 to 73. The three guide tubes 32 formed in the first actuator unit 12 serve as the first outlet 74 of the ink. One guide tube 32 formed in the second actuator unit 13 serves as an ink inflow port 75. The three guide tubes 64 formed on the second cover 15 serve as the second outlet 76 for the ink.

Further, the liquid chambers 71 to 73 and the plurality of pressure chambers 23 constitute a common liquid chamber 70 through which ink flows. Such an inkjet head 200 includes a common liquid chamber 70, three first outlets 74 for discharging ink from the liquid chamber 71 through a plurality of pressure chambers 23 of one piezoelectric actuator 21, and a liquid chamber for ink. It includes one inflow port 75 for supplying to 71, and three second outflow ports 76 for discharging ink from the liquid chamber 71 through a plurality of pressure chambers 23 of the other piezoelectric actuator 21.

The liquid chambers 71 to 73 are long in one direction. Further, the liquid chambers 71 to 73 are configured to have the same length. A part of the plurality of first outlets 74 and a part of the plurality of second outlets 76, specifically, one first outlet 74 and one first outlet 74 are the lengths of the liquid chamber 72. It is arranged at a position in the longitudinal direction of the liquid chambers 71 and 73 corresponding to the position where the inflow port 75 is provided in the direction. That is, in the present embodiment in which the inflow port 75 is provided at the central position of the liquid chamber 72, one of the three first outlets 74 and one of the three second outlets 76 is the liquid chamber 71. It is arranged at the center position of 73.

Further, other than the plurality of first outlets 74 and the plurality of second outlets 76, the positions where the moving distances of the ink from the inlet 75 through the liquid chambers 71 to 73 and the plurality of pressure chambers 23 are the same. Is placed in. That is, in the present embodiment in which the inflow port 75 is provided at the central position of the liquid chamber 72, two of the three first outlets 74 and two of the three second outlets 76 are the liquid chamber 71. It is arranged on both ends of the 73 and adjacent to the pressure chambers 23 located at both ends of the piezoelectric actuator 21.

The circulation circuit 300 is, for example, a downstream ink tank 301 provided on the secondary side of the inkjet head 200, a pump 302 that supplies ink from the downstream ink tank 301 to the secondary side, and a secondary side of the pump 302. It also has an upstream ink tank 303 provided on the primary side of the inkjet head 200. Further, for example, the circulation circuit 300 has a filter and the like. The circulation circuit 300 fluidly connects the downstream ink tank 301, the pump 302, and the upstream ink tank 303 to the inkjet head 200 via a pipe. The circulation circuit 300 provides a fluid circuit that circulates ink so that the ink that has passed through the inkjet head 200 from the upstream ink tank 303 returns to the downstream ink tank 301 and is supplied to the inkjet head 200 via the upstream ink tank 303 again. Constitute.

As a specific example, the circulation circuit 300 connects the ink of the downstream ink tank 301 to the inflow port 75 of the inkjet head 200, and supplies the ink to the liquid chamber 71 in the inkjet head 200 via the inflow port 75. Further, the circulation circuit 300 is connected to three first outlets 74 and three second outlets 76 of the inkjet head 200. The circulation circuit 300 passes through the pressure chamber 23 of the inkjet head 200, collects the ink not ejected from the nozzles 11a from the outlets 74 and 76, and returns the ink to the downstream ink tank 301.

The flow path switching member 400 is, for example, six on-off valves provided on the secondary side of the three first outlets 74 and the three second outlets 76 and between the primary sides of the circulation circuit 300, respectively. It is composed of 401. The on-off valve 401 is connected to the control device 500 and is driven based on the command of the control device 500 to open and close the flow path between the outlets 74 and 76 and the circulation circuit 300. Such a flow path switching member 400 is integrally installed in the inkjet head 200, or is installed in an outer shell constituting the printer 100. For example, the flow path switching member 400 is included in the configuration of the inkjet head 200.

The control device 500 drives the pump 302 to circulate the ink in the downstream ink tank 301 in a circulation circuit composed of the inkjet head 200 and the circulation circuit 300. Further, the control device 500 keeps the pressure of the ink in each pressure chamber 23 constant at the time of printing when the ink is ejected from the nozzle 11a of the inkjet head 200 to the paper sheets, and each pressure at the time of non-printing when the ink is not ejected from the nozzle 11a. The flow rate of ink in the chamber 23 is constant.

Specifically, as shown in FIG. 7, the control device 500 opens the central first outlet 74 and the second outlet 76, which are some outlets 74 and 76, at the time of printing. Further, the control device 500 closes the on-off valve 401 connected to the two first outlets 74 and the two second outlets 76 on both ends, which are the outlets 74 and 76 of the other part, at the time of printing. In FIGS. 7 and 8, each of the outlets 74 and 76 in which the on-off valve 401 is closed is shown by describing hatching.

By opening and closing the first outlet 74 and the second outlet 76 in this way, as shown by the arrows in FIG. 7, the ink supplied from the inlet 75 into the liquid chamber 71 is the primary of the pressure chamber 23. The differential pressures on the side and the secondary side are the same in each pressure chamber 23, and the pressure in each pressure chamber 23 in the vicinity of the nozzle 11a, as a specific example, in a non-driven state becomes constant.

Further, the ink is pressed in the pressure chamber 23 by driving the drive element 22, and the ink is ejected as ink droplets from the nozzle 11a. The ink that has not been used as ink droplets is discharged to the outside of the liquid chambers 71 and 73 from the open outlets 74 and 76.

In order to eject the ink droplets from the nozzle 11a, a drive voltage is applied to the drive element 22 via the wiring 42 by the drive circuit. When a current flows through the first piezoelectric element 24a and the second piezoelectric element 24b of the drive element 22, the drive element 22 is deformed in the share mode. As a specific example, the first piezoelectric element 24a and the second piezoelectric element 24b shown in FIG. 4 are bent in opposite directions to each other. Due to the bending of both piezoelectric elements 24a and 24b, the driving element 22 is bent and deformed in an "L" shape, and the volume of the adjacent pressure chamber 23 is reduced. When the pressure chamber 23 becomes smaller and the ink in the pressure chamber 23 becomes high pressure, ink droplets are vigorously ejected from the nozzle 11a.

Further, as shown in FIG. 8, the control device 500 opens the on-off valve 401 connected to the first outlet 74 and the second outlet 76 on both ends and the first outlet 74 in the center without printing. And close the second outlet 76. As a result, as shown in FIG. 8, the distance at which the ink supplied from the inflow port 75 into the liquid chamber 71 flows through the pressure chamber 23 to each of the first outlet 74 and the second outlet 76 becomes constant, and the nozzle The flow rate of the ink flowing in the vicinity of 11a, that is, the flow rate of the ink when passing through each pressure chamber 23 becomes constant.

Here, the non-printing time does not include the standby time for printing, such as before or after printing. That is, the non-printing time is, for example, when there is an external command such as maintenance for cleaning the nozzle 11a, or when there is a command for periodic maintenance or the like programmed in the control device 500 or the like. Therefore, when the power is supplied, the printer 100 is constantly controlled to keep the pressure constant, and when a maintenance command is given, the printer 100 is temporarily controlled to keep the flow rate constant only during the maintenance.

According to the printer 100 using the inkjet head 200 configured in this way, the pressure of the ink in the vicinity of the nozzle 11a can be kept constant at the time of printing even if the ink is circulated. As a result, when the piezoelectric actuator 21 is driven so as to reduce the volume of the pressure chamber 23, the amount of ink discharged from the nozzle 11a is made uniform. Further, by keeping the pressure constant in the inkjet head 200, it is possible to prevent variations in the temperature at each nozzle 11a and the state of sedimentation of the pigment in the ink.

Further, since the flow rate in the vicinity of the nozzle 11a can be kept constant during non-printing, the effect of maintenance can be improved.

As described above, in the printer 100 of the embodiment, the inkjet head 200 is provided with a plurality of outlets 74 and 76, and the pressure of ink passing through these outlets 74 and 76 in each pressure chamber 23 during printing or non-printing or It opens and closes selectively so that the flow rate is constant. As a result, the printer 100 makes the flow rate in the vicinity of the nozzle 11a uniform during non-printing and makes the pressure in the vicinity of the nozzle 11a uniform during printing.

The present embodiment is not limited to the above-mentioned example. In the above-described example, the inkjet head 200 is configured to have three first outlets 74 and three second outlets 76, but is not limited thereto. For example, as in the second embodiment shown in FIG. 9, the inkjet head 200 may have two each of the first outlet 74 and the second outlet 76. In FIG. 9, the pressure chamber 23 and the like are omitted, and the ink flow is indicated by arrows.

In this case, each of the outlets 74 and 76 is provided with two guide pipes 32 on both ends in the longitudinal direction of the inner rib 34 of the first actuator unit 12, and the outlets 74 and 76 are provided with two guide pipes 32 in the longitudinal direction of the inner rib 66 of the second cover 15. It is configured by providing two second outlets 76, that is, guide pipes 64 on both ends. Further, the inflow port 75 is configured by providing one guide pipe 32 on one end side in the longitudinal direction of the inner rib 34 of the second actuator unit 13.

As shown in FIG. 9, the inkjet head 200 of the second embodiment opens the first outlet 74 and the second outlet 76 adjacent to the inlet 75 at the time of printing, and the other first stream. The outlet 74 and the second outlet 76 are closed. As a result, the pressure of the ink in the vicinity of each nozzle 11a becomes constant. Further, as shown in FIG. 9, the inkjet head 200 opens the first outlet 74 and the second outlet 76 on the side far from the inflow port 75 at the time of non-printing. As a result, the flow rate of ink in the vicinity of each nozzle 11a becomes constant.

Similarly, as in the third embodiment shown in FIG. 10, the inkjet head 200 has one piezoelectric actuator 21, and the liquid chamber 71, respectively, in the direction orthogonal to the longitudinal direction of the piezoelectric actuator 21. The configuration may be such that 72 is provided. The inkjet head 200 of the third embodiment has an outflow port 74 provided at both ends in the longitudinal direction of the liquid chamber 71 and one inflow port 75 provided at one end in the longitudinal direction of the liquid chamber 72. Have. Then, at the time of printing, the control device 500 has an outlet 74 on one end side in the longitudinal direction of the liquid chamber 71, in other words, an outlet 74 at the same position as the inlet 75 in one direction in which the inlet 75 and the liquid chamber 71 extend. And close the outlet 74 on the other end side. Further, the control device 500 closes the outlet 74 on one end side of the liquid chamber 71 and opens the outlet 74 on the other end side of the liquid chamber 71 at the time of non-printing. Similar to the inkjet head 200 of the first embodiment and the second embodiment, the inkjet head 200 of the third embodiment has a constant pressure in the vicinity of the nozzle 11a during printing, and a flow rate in the vicinity of the nozzle 11a during non-printing. Become constant.

Further, in the above-described example, the configuration in which the inkjet head 200 has a pair of actuator units 12 and 13 and a pair of covers 14 and 15 covering both sides of the pair of actuator units 12 and 13 has been described. Not limited. For example, the inkjet head 200 may have a configuration in which a pair of piezoelectric actuators 21 are fixed to the main surface of a rectangular plate-shaped base substrate, and the base substrate is provided with outlets 74 and 76 and inlets 75, which are holes. good.

Further, in the above-described example, the flow path switching member 400 is configured such that the on-off valve 401 is provided in each of the guide pipes 32 and 64 constituting the outlets 74 and 76, but the present invention is not limited to this. For example, the flow path switching member 400 joins the ink flow paths on the secondary side of the inkjet head 200 for each group of outlets 74 and 76 that open and close in conjunction with printing and non-printing, and each flow path. The on-off valve 401 may be provided in the air. The flow path switching member 400 having such a configuration is provided only by providing two on-off valves, an on-off valve 401 for the outflow ports 74 and 76 that opens during printing, and an on-off valve 401 for the outflow ports 74 and 76 that open during non-printing. good.

According to the inkjet head and printer of at least one embodiment described above, by selectively opening and closing a plurality of outlets during printing and non-printing, the flow rate in the vicinity of the nozzle is uniform during non-printing, and , The pressure near the nozzle becomes uniform during printing.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.
The following is a description equivalent to the invention described in the claims of the original application of the present application.
[1] A piezoelectric actuator having a plurality of pressure chambers arranged along one direction, and a plurality of liquid chambers extending in the one direction adjacent to the piezoelectric actuator in a direction orthogonal to the one direction are included. With the head member
A nozzle plate having a plurality of nozzles arranged at positions facing the plurality of pressure chambers and covering the head member to form a common liquid chamber together with the plurality of pressure chambers and the liquid chambers.
An inflow port provided in the liquid chamber on the primary side of the common liquid chamber, and
A plurality of outlets provided in the liquid chamber on the secondary side of the common liquid chamber, and
With
In the plurality of outlets, a part of the outlets of the plurality of outlets is opened at the time of printing, the outlets of the other portion of the plurality of outlets are closed, and the one is described at the time of non-printing. The outlet of the part closes, the outlet of the other part opens,
An inkjet head in which ink flowing from the inlet to the outlet circulates.
[2] The partial outlet is one, and is arranged at the same position in the same direction as the outlet.
The inkjet head according to [1], wherein the outlet of the other portion is configured such that the distance from the inlet to the plurality of pressure chambers through which ink flows is constant.
[3] Two piezoelectric actuators are provided.
The plurality of liquid chambers are provided in three directions orthogonal to the one direction of the two piezoelectric actuators.
The inflow port is provided in the liquid chamber arranged in the center in a direction orthogonal to the one direction.
The inkjet head according to [2], wherein the plurality of outlets are provided in two liquid chambers arranged at both ends in a direction orthogonal to the one direction.
[4] One piezoelectric actuator is provided.
Two of the plurality of liquid chambers are provided in a direction orthogonal to the one direction of the piezoelectric actuator.
The inflow port is provided on one end side of the liquid chamber in the one direction.
The partial outlet is provided on one end side of the other liquid chamber in the one direction.
The inkjet head according to [2], wherein the outlet of the other portion is one, and is provided on the other end side in the one direction of the other liquid chamber.
[5] The inkjet head according to [1] and
An on-off valve connected to the plurality of outlets,
An upstream ink tank connected to the primary side of the inkjet head,
A downstream ink tank connected to the secondary side of the inkjet head,
A pump connected to the upstream ink tank and the downstream ink tank and supplying the ink to the upstream ink tank.
A printer equipped with.

10 ... head member, 11 ... nozzle plate, 11a ... nozzle, 12 ... first actuator unit (actor unit), 13 ... second actuator unit (actor unit), 14 ... first cover (cover), 15 ... Second cover, 15 ... cover, 20 ... base part, 20a ... positioning recess, 20b ... positioning recess, 21 ... piezoelectric actuator, 22 ... drive element, 23 ... pressure chamber, 24a ... first piezoelectric element ( Piezoelectric element), 24b ... Second piezoelectric element (piezoelectric element), 25 ... Adhesive layer, 26 ... Electrode, 27 ... Adhesive layer, 30 ... Ink guide, 31 ... Guide rib, 32 ... Guide tube, 33 ... Outer rib, 33a ... Positioning protrusions, 34 ... Inner ribs, 36 ... Outer ribs, 36a ... Positioning protrusions, 42 ... Wiring, 43 ... Electrical connections, 51 ... Plate-shaped parts, 51a ... Positioning recesses, 52 ... Outer ribs, 52a ... Positioning protrusions, 61 ... Plate-shaped parts, 61a ... Positioning recesses, 62 ... Ink guides, 63 ... Guide ribs, 64 ... Guide tubes, 65 ... Outer ribs, 65a ... Positioning protrusions, 66 ... Inner ribs, 70 ... Common liquid Chamber, 71-73 ... Liquid chamber, 74 ... First outlet (outlet), 75 ... Inlet, 76 ... Second outlet (outlet), 100 ... Printer, 200 ... Inkjet head, 300 ... Circulation circuit, 301 ... downstream ink tank, 302 ... pump, 303 ... upstream ink tank, 400 ... flow path switching member, 401 ... on-off valve, 500 ... control device.

Claims (4)

A piezoelectric actuator having a plurality of pressure chambers arranged along one direction, and a head member including a plurality of liquid chambers extending in one direction adjacent to the piezoelectric actuator in a direction orthogonal to the one direction. ,
A nozzle plate having a plurality of nozzles arranged at positions facing the plurality of pressure chambers and covering the head member to form a common liquid chamber together with the plurality of pressure chambers and the liquid chambers.
One inflow port provided in the liquid chamber on the primary side of the common liquid chamber, and
A plurality of outlets provided in the liquid chamber on the secondary side of the common liquid chamber, and
With
Some of the outlets among the plurality of outlets are arranged at the same position as the inlet in the same direction.
Of the plurality of outlets, the outlets of other parts other than the partial outlets are arranged at positions where the distance from the inlet to the plurality of pressure chambers through which ink flows is constant. ,
Wherein the plurality of outlets, the outlet of said portion of said plurality of outlet opens at the time of printing, before Symbol other part the outlet is closed, and the flow of said portion at the time of non-printing outlet closed, the outlet of the other portion is opened,
An inkjet head in which ink flowing from the inlet to the outlet circulates. Two piezoelectric actuators are provided.
The plurality of liquid chambers are provided in three directions orthogonal to the one direction of the two piezoelectric actuators.
The inflow port is provided in the liquid chamber arranged in the center in a direction orthogonal to the one direction.
The inkjet head according to claim 1 , wherein the plurality of outlets are provided in two liquid chambers arranged at both ends in a direction orthogonal to the one direction. One piezoelectric actuator is provided.
Two of the plurality of liquid chambers are provided in a direction orthogonal to the one direction of the piezoelectric actuator.
The inflow port is provided on one end side of the liquid chamber in the one direction.
Said outlet of said portion is provided on one end side of the one direction of the other of the liquid chamber,
The inkjet head according to claim 1 , wherein the outlet of the other portion is one, and is provided on the other end side in the one direction of the other liquid chamber. The inkjet head according to any one of claims 1 to 3.
An on-off valve connected to the plurality of outlets,
An upstream ink tank connected to the primary side of the inkjet head,
A downstream ink tank connected to the secondary side of the inkjet head,
A pump connected to the upstream ink tank and the downstream ink tank and supplying the ink to the upstream ink tank.
A printer equipped with.

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