The present application is based on, and claims priority from JP Application Serial Number 2018-239218, filed Dec. 21, 2018, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present disclosure relates to a droplet discharge head.
An example of a droplet discharge head that discharges minute droplets is JP-A-9-327909 and the like. JP-A-9-327909 discloses a droplet discharge head that abruptly draws a meniscus m that draws a meniscus m stationary at a nozzle opening, displaces a central region mc of the meniscus relatively large toward a pressure generation chamber, contracts a pressure generation chamber to generate an inertia flow when the movement of the central region of the meniscus to the pressure generation chamber is reversed, concentrates the inertial flow on the central region of the meniscus near the pressure generation chamber side, and extrudes only the central region at a high speed to stably discharge ink droplets thinner than the diameter of the nozzle opening at a speed suitable for printing.
However, when the droplet discharge head described in the above document is applied to a high-viscosity liquid of 50 mPa or more, the following problems occur. When a high-viscosity liquid of 50 mPa or more is discharged, the energy required for separating the droplets from the meniscus is larger than that of a discharged liquid of the related art. Therefore, in the droplet discharge head described in JP-A-9-327909, it is necessary to increase “the amount of expansion and contraction of an actuator” or “the area where a vibration plate forms a pressure generation chamber” in order to increase the excluded volume generated by the expansion and contraction of the actuator. In order to increase “the expansion/contraction amount of the actuator”, the actuator becomes longer in the expansion/contraction direction. Accordingly, in order to maintain the rigidity of the actuator, the area of the surface of the actuator that comes into contact with the vibration plate increases, and it is difficult to dispose the nozzles at high density. In addition, when the “area in which the vibration plate forms the pressure generation chamber” is increased, the volume of the pressure generation chamber increases, and it is difficult to dispose the nozzles at high density.
According to an aspect of the present disclosure, there is provided a droplet discharge head each including a first liquid chamber formed on a flow path forming substrate, a nozzle communicating with the first liquid chamber, and a first inflow path for supplying a liquid to the first liquid chamber, and a first actuator that individually changes a pressure in the first liquid chamber, a second actuator that changes pressures in a plurality of the first liquid chambers in common, in which an expansion/contraction amount of the second actuator is larger than that of the first actuator.
The droplet discharge head includes a first vibration plate forming a part of the wall surface of the first liquid chamber, in which the first actuator may be fixed to the first vibration plate, and the second actuator may displace the first vibration plate by displacing the first actuator.
In the droplet discharge head, the first actuator may be interposed between the second actuator and the first vibration plate.
The droplet discharge head includes a first vibration plate forming a part of the wall surface of the first liquid chamber, and a second vibration plate forming a part of the wall surface of the first inflow path, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate.
In the droplet discharge head, a plurality of the first actuators may be disposed with the second actuator interposed therebetween, the first actuator may be fixed to a bridging member, and the second actuator may be fixed to the bridging member
In the droplet discharge head, a plurality of the second actuators may be provided, the plurality of second actuators may be disposed with the first actuator interposed therebetween, the plurality of second actuators may be fixed to a bridging member, and the bridging member may be fixed to a plurality of the first actuators.
The droplet discharge head includes a first vibration plate forming a part of a wall surface of the first liquid chamber, and a second vibration plate forming a part of the wall surface of the first liquid chamber, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate.
The droplet discharge head includes a nozzle plate forming part of a wall surface of the first liquid chamber, and a second vibration plate forming a part of the wall surface of the first liquid chamber, in which the nozzle may be formed on a nozzle plate, the first actuator may be fixed to the nozzle plate, and the second actuator may be fixed to the second vibration plate.
In the droplet discharge head, the first inflow path may include a second liquid chamber having a larger width than the first inflow path, and the second actuator may be fixed to the second vibration plate forming a part of a wall surface of the second liquid chamber.
The droplet discharge head includes a first vibration plate forming a part of a wall surface of the first liquid chamber, a second vibration plate forming a part of a wall surface of the first inflow path, and a displacement amplifying mechanism for amplifying an expansion/contraction amount of the second actuator to displace the second vibration plate, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate via the displacement amplifying mechanism.
The droplet discharge head includes an outflow path through which the liquid flows out from the first liquid chamber, a first vibration plate forming a part of a wall surface of the first liquid chamber, a second vibration plate forming a part of a wall surface of the outflow path, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate.
The droplet discharge head each includes a first liquid chamber formed on a flow path forming substrate, a nozzle communicating with the first liquid chamber, a first inflow path for supplying a liquid to the first liquid chamber, and a second inflow path communicating with the nozzle, and a first actuator that individually changes a pressure in the first liquid chamber, and a second actuator that changes pressures in the plurality of nozzles in common, in which an expansion/contraction amount of the second actuator may be larger than that of the first actuator.
The droplet discharge head described above is a droplet discharge head is mounted on a droplet discharge apparatus including a control unit for controlling droplet discharge, in which based on a drive signal from the control unit, the second actuator may be driven to draw a meniscus in the nozzle by depressurizing the first liquid chamber, and after the meniscuses in a plurality of the nozzles are drawn, the first actuator may be driven to discharge droplets from the nozzle by pressurizing the first liquid chamber.
In the droplet discharge head, the plurality of nozzles may include a first nozzle that discharges droplets and a second nozzle that does not discharge droplets, and based on a drive signal from the control unit, after the meniscuses in the plurality of nozzles are drawn, the first actuator corresponding to the first nozzle may be driven to pressurize the first liquid chamber communicating with the first nozzle, and after the meniscuses in the plurality of nozzles are drawn, the first actuator corresponding to the second nozzle may not be driven.
In the droplet discharge head, the plurality of nozzles may include a first nozzle that discharges droplets and a second nozzle that does not discharge droplets, and based on a drive signal from the control unit, when the second actuator is driven and the first liquid chamber is depressurized to draw the meniscus in the first nozzle and the second nozzle, the first actuator of the second nozzle may be driven to pressurize the first liquid chamber communicating with the first nozzle, and when the second actuator is driven and the first liquid chamber is pressurized to push the meniscus in the first nozzle and the second nozzle, the first actuator of the second nozzle may be driven to depressurize the first liquid chamber communicating with the first nozzle.
In the droplet discharge head, the plurality of nozzles may include a first nozzle that discharges droplets and a second nozzle that does not discharge droplets, in which a diameter of a droplet discharged from the first nozzle may be less than two-thirds of an opening of the first nozzle.
In the droplet discharge head, the speed at which the liquid column formed in the nozzle moves in the direction toward the nozzle opening may be higher than the speed at which the meniscus in the nozzle moves in the direction toward the nozzle opening.
According to another aspect of the present disclosure, there is provided a droplet discharge head each including a first liquid chamber formed on a flow path forming substrate, a nozzle communicating with the first liquid chamber, and a first inflow path for supplying a liquid to the first liquid chamber, and a first actuator that individually changes a pressure in the first liquid chamber, a second actuator that changes pressures in a plurality of the first liquid chambers in common, in which an excluded volume generated by the second actuator may be larger than an excluded volume generated by the first actuator.
Hereinafter, embodiments of the present disclosure will be described with reference to drawings. In the following drawings, the scale of each layer and each member is made different from an actual scale so that each layer and each member can be recognized.
Schematic Configuration of Droplet Discharge Apparatus
The printer 92 includes a head unit 1, a transport mechanism 94, a control unit 95, a first tank 961, and a second tank 962. The control unit 95 will be described later.
The head unit 1 includes a head control unit 6 and a droplet discharge head 11 (see
The transport mechanism 94 includes a carriage moving mechanism 941 and a recording medium transport mechanism 942. The carriage moving mechanism 941 drives a motor 943 to move the carriage 97 including the head unit 1 in a carriage moving direction (see
The first tank 961 stores the liquid supplied to the droplet discharge head 11 through a first inflow path 131. The first tank 961 also has a first pump 964. The first pump 964 pressurizes the liquid flowing through the first inflow path 131 by pressurizing the inside of the first tank 961. The liquid supplied to the droplet discharge head 11 is discharged onto the recording medium 93 by driving a first actuator 311 and a second actuator 411 in the droplet discharge head 11 (see
The second tank 962 stores a liquid that is not discharged from the droplet discharge head 11 to the recording medium 93 through an outflow path 161. The second tank 962 also has a second pump 965. The second pump 965 sucks the liquid from the droplet discharge head 11 through the outflow path 161 by depressurizing the inside of the second tank 962. Either one of the first pump 964 and the second pump 965 may be omitted (see
The outflow path 161 of Embodiment 1 has a cap 963 that contacts the droplet discharge head 11. The second pump 965 depressurizes the inside of the cap 963 through the second tank 962 and sucks the thickened liquid from the droplet discharge head 11. Thereby, the droplet discharge head 11 can suppress accumulation of sediment components in the liquid.
Block Diagram of Droplet Discharge Apparatus
The output IF 911 exchanges data with the printer 92. The CPU 912 is an arithmetic processing apparatus for performing overall control of the computer 91. The memory 913 includes a RAM, an EEPROM, a ROM, a magnetic disk apparatus, and the like and stores a computer program used by the CPU 912. Computer programs stored in the memory 913 include application programs and printer drivers. The CPU 912 performs various controls according to the computer program.
The printer driver is a program that converts image data into print data. This print data is output to the printer 92. The print data is data in a format that can be interpreted by the printer and includes various command data and pixel data (SI). The command data is data for instructing the printer to execute a specific operation. The command data includes, for example, command data for instructing paper feed, command data for indicating a transport amount, and command data for instructing paper discharge. Pixel data (SI) is data relating to pixels of an image to be printed.
Here, a pixel is a unit element constituting an image, and an image is formed by arranging these pixels in a two-dimensional manner. Pixel data (SI) in the print data is data (for example, gradation values) relating to dots formed on the recording medium 93.
Next, the configuration of the control unit 95 inside the printer 92 will be briefly described. The control unit 95 includes an input interface 951 (input IF), a CPU 952, a memory 953, a drive signal generation circuit 957, a transport mechanism drive circuit 954, a print timing generation circuit 955, a first pump drive circuit 956, a second pump drive circuit 958. The input IF 951 exchanges data with the computer 91 which is an external apparatus. The CPU 952 is an arithmetic processing device for performing overall control of the printer 92. The memory 953 includes a RAM, an EEPROM, a ROM, a magnetic disk apparatus, and the like and stores a computer program used by the CPU 952. The CPU 952 controls each circuit in accordance with a computer program stored in the memory 953.
The computer program includes a drive signal generation program, a transport mechanism drive program, a print timing generation program, a first pump drive program, a second pump drive program, and the like.
The drive signal generation circuit 957 generates a drive signal when a clock signal (CK) is input. The drive signal generation circuit 957 periodically generates two or more types of drive signals and outputs the signals to the head control unit 6.
The transport mechanism drive circuit 954 controls the transport amount of the transport mechanism 94 via the motors 943 and 944 and the like. For example, the motor 943 of the carriage moving mechanism 941 is rotated to transport the carriage 97 in the carriage movement direction. At this time, a linear encoder 945 attached to the motor 943 calculates the transport amount of the carriage 97 from a rotation amount of the motor 943 and outputs the amount to the print timing generation circuit 955. The print timing generation circuit 955 generates a clock signal (CK) based on the transport amount and outputs the signal to the head control unit 6 and the transport mechanism drive circuit 954.
The first pump drive circuit 956 drives the first pump 964 to control the pressure in the first tank 961. Similarly, the second pump drive circuit 958 drives the second pump 965 to control the pressure in the second tank 962. The second pump 965 depressurizes the inside of the second tank 962 when the droplet discharge head 11 is cleaned and sucks the thickened liquid (ink) from the droplet discharge head 11.
Schematic Configuration of Droplet Discharge Head
The first liquid chamber 121 is a space formed by forming a recess in the flow path forming substrate 51 and sealing the opening of the recess with the first vibration plate 21. The first liquid chamber 121 communicates with the first inflow path 131 for supplying the liquid to the first liquid chamber 121 and the nozzle 111 for discharging the liquid to the outside.
The first vibration plate 21 is fixed to the flow path forming substrate 51 and constitutes a part of the wall surface of the first liquid chamber 121. The first vibration plate 21 is a plate-like member (diaphragm) that is configured to be bent and deformed in a first direction and a second direction opposite to the first direction. Here, the first direction refers to a direction in which the first vibration plate 21 is displaced so as to reduce the volume of the first liquid chamber 121, and the second direction refers to a direction in which the first vibration plate 21 is displaced so as to increase the volume of the first liquid chamber 121.
The first actuator 311 and the second actuator 411 are disposed on the first vibration plate 21. More specifically, the first actuator 311 is sandwiched between the first vibration plate 21 and the second actuator 411 and is mechanically coupled to each. The second actuator 411 is fixed to the lid member 52. Since the rigidity of the lid member 52 is higher than that of the first vibration plate 21, the first vibration plate 21 is displaced in the first direction or the second direction as the first actuator 311 and the second actuator 411 expand and contract. Here, the second actuator 411 displaces the first vibration plate 21 by displacing the first actuator 311. In this way, the first actuator 311 and the second actuator 411 can apply the pressure of the first liquid chamber via the same vibration plate, and the responsiveness of the liquid in the nozzle to the pressure change generated by the second actuator 411 is improved.
In Embodiment 1, the first actuator 311 and the second actuator 411 are configured by piezoelectric elements that expand and contract in accordance with an applied voltage. The first vibration plate 21, the first actuator 311, the second actuator 411, and the lid member 52 may be fixed via islands or electrodes.
The second actuator 411 is fixed to a plurality of the first actuators 311, 312, and 313. The expansion/contraction amount of the second actuator 411 is larger than that of the first actuators 311, 312, and 313. Thus, even when the area of the surface of the second actuator 411 that displaces the first vibration plate 21 is large, since the plurality of first actuators 311, 312, and 313 can be arranged on the surface of the second actuator 411 that displaces the first vibration plate 21, the nozzles 111, 112, and 113 can be arranged with high density.
Description of Head Control Unit 6
The head control unit 6 receives a clock signal (CK), a latch signal (LAT), a change signal (CH), a first drive signal (COM-A), a second drive signal (COM-B), and a setting signal including pixel data (SI) and setting data (SP) from the control unit 95. The first drive signal (COM-A) is applied to the first actuators 311, 312, and 313, and the second drive signal (COM-B) is applied to the second actuator 411.
When the setting signal is input to the head control unit 6 in synchronization with the clock signal (CK), pixel data (SI) is set in the first shift register 611, 612, and 613 (SR1), and setting data (SP) is set in the second shift register 62 (SR2). In accordance with the pulse of the latch signal (LAT), the pixel data (SI) is latched in the LAT circuits 631, 632, and 633, and the setting data (SP) is latched in the selection signal generation circuit 64, respectively.
The selection signal generation circuit 64 generates a plurality of selection signals based on the setting data (SP) and the change signal (CH). The decoder 65 selects one of the plurality of selection signals input from the selection signal generation circuit 64 in accordance with the pixel data (SI) latched in the LAT circuits 631, 632, and 633. The selected selection signal is output from the decoders 651, 652, and 653 as a switch signal.
The first drive signal (COM-A) and the switch signal are input to the switch circuits 661, 662, and 663. For example, when the switch signal is at an H level, the switch circuit 661 is turned on, and the first drive signal (COM-A) is applied to the first actuator 311. When the switch signal is at an L level, the switch circuit 661 is turned off, and the first drive signal (COM-A) is not applied to the first actuator 311.
On the other hand, since the second actuator 411 is driven periodically regardless of discharged or non-discharge, the second drive signal (COM-B) is periodically applied to the second actuator 411.
Next, discharge control and non-discharge control methods will be described. In Embodiment 1, since the second actuator 411 is fixed to the plurality of first actuators 311, 312, and 313 as shown in
Droplet Discharge Control
As shown in
In the initial state standby process in the period t0, the liquid in the nozzle 111 before the discharge control is started is maintained at a meniscus pressure resistance or lower. At this time, as shown in
In the drawing process in the period t1, the first actuator 311 and the second actuator 411 contract and the first vibration plate 21 is displaced in the second direction (
As shown in
In the standby step in the period t2, since the head control unit 6 holds the applied voltage of the first actuator 311 and the second actuator 411 constant, the position of the first vibration plate 21 is kept. During this time, the pressure wave generated by driving the first actuator 311 and the second actuator 411 during the period t1 reciprocates at a natural frequency Tc of the first liquid chamber 121.
In the liquid column forming step in the period t3, the first actuator 311 and the second actuator 411 are extended, whereby the first vibration plate 21 is displaced in the first direction (
In the pushing process in the period t4, the first vibration plate 21 is displaced in the first direction by the second actuator 41 extending until the second actuator 41 reaches an intermediate potential (
In at least one of the period t3 and the period t4, the liquid in the nozzle 111 is pressurized by the displacement of the first vibration plate 21 in the first direction. The pressurized liquid in the nozzle 111 concentrates on the liquid column and selectively pressurizes only the liquid column. This is because a pseudo-nozzle is formed at the center of the nozzle 111, and the channel resistance at the center of the nozzle 111 is smaller than the channel resistance of the nozzle wall surface 171. Thereby, the speed at which the liquid column moves in the direction toward the opening 172 of the nozzle 111 is higher than the speed at which the extreme value MT of the meniscus moves in the direction toward the opening 172 of the nozzle 111. When the total energy applied to the liquid column exceeds the energy that separates the liquid column from the meniscus, the liquid column is discharged as a droplet from the opening 172 of the nozzle 111 (
In the refilling process in the period t5, the position of the first vibration plate 21 is maintained. At this time, the meniscus in the nozzle 111 returns to the stable state by supplying the liquid from the first inflow path 131.
Non-Discharge Control
As shown in
In the drawing process in the period t7, the second actuator 411 contracts to displace the first vibration plate 21 in the second direction (
In the standby step in the period t8, since the head control unit 6 holds the applied voltage of the first actuator 312 and the second actuator 411 constant, the position of the first vibration plate 21 is kept.
In the pushing process in the period t9, the first vibration plate 21 is displaced in the first direction by the second actuator 411 extending until the second actuator 411 reaches the intermediate potential (
As described above, in the droplet discharge head 11 according to Embodiment 1, the second actuator 411 applies a pressure to a plurality of the first liquid chambers 121, 122, and 123, and the first actuator 311, 312, and 313 applies a pressure to each of the first liquid chambers 121, 122, and 123. The structure of the second actuator 411 tends to be relatively large in order to increase the amount of expansion and contraction, but since the first actuators 311, 312, and 313 are not required to expand and contract as compared with the second actuator 411, it is possible to reduce the size of the first actuator. Thereby, even if it is a high viscosity-droplet discharge head having a plurality of nozzles, a nozzle density can be raised.
Schematic Configuration of Droplet Discharge Head
The second actuator 411 is mechanically coupled to the second vibration plate 22 via a plurality of island portions 231, 232, and 233 and is fixed to the lid member 52. The expansion/contraction amount of the second actuator 411 is larger than that of the first actuators 311, 312, and 313. Thereby, even when the area of the surface of the second actuator 411 that displaces the second vibration plate 22 is large, since the plurality of island portions 231, 232, and 233 can be arranged on the surface of the second actuator 411 that displaces the second vibration plate 22, the nozzles 111, 112, and 113 can be arranged with high density. The island portion 231 may be integrally formed with the second vibration plate 22.
Next, discharge control and non-discharge control methods will be described. In Embodiment 2, since the second actuator 411 is coupled to the plurality of first inflow paths 131, 132, and 133 as shown in
Droplet Discharge Control
In the initial state standby process in the period t0, the liquid in the nozzle 111 before the discharge control is started is maintained at a meniscus pressure resistance or lower. At this time, as shown in
In the drawing process in the period t1, when the first actuator 311 contracts, the first vibration plate 21 is displaced in the second direction, and when the second actuator 411 contracts, the second vibration plate 22 is displaced in the second direction (
In the standby process in the period t2, the head control unit 6 holds the position of the first vibration plate 21 by keeping the applied voltage of the first actuator 311 constant and holds the position of the second vibration plate 22 by keeping the applied voltage of the second actuator 411 constant. During this time, the pressure wave generated by driving the first actuator 311 and the second actuator 411 during the period t1 reciprocates at a natural frequency Tc of the first liquid chamber 121.
In the liquid column forming process in the period t3, when the first actuator 311 extends, the first vibration plate 21 is displaced in the first direction, and when the second actuator 411 extends, the second vibration plate 22 is displaced in the first direction (
In the liquid column forming process in the period t3 and the pushing process in the period t4, the second vibration plate 22 is displaced in the first direction until the second actuator 411 reaches the intermediate potential (
In the refilling process in the period t5, the positions of the first vibration plate 21 and the second vibration plate 22 are maintained. At this time, the meniscus in the nozzle 111 returns to the stable state by supplying the liquid from the first inflow path 131.
Non-Discharge Control
In the drawing process in the period t7, the second actuator 411 contracts to displace the second vibration plate 22 in the second direction (
In the standby process in the period t8, the position of the first vibration plate 21 is maintained by the head control unit 6 holding the applied voltage of the first actuator 312 constant, and the position of the second vibration plate 22 is maintained by holding the applied voltage of the second actuator 411 constant.
In the pushing process in the period t9, the second actuator 411 extends until reaching the intermediate potential, whereby the second vibration plate 22 is displaced in the first direction (
As described above, in the droplet discharge head 12 according to Embodiment 2, the second actuator 411 applies a pressure to a plurality of the first inflow paths 131, 132, and 133, and the first actuator 311, 312, and 313 applies a pressure to each of the first liquid chambers 121, 122, and 123. The structure of the second actuator 411 tends to be relatively large in order to increase the amount of expansion and contraction, but since the first actuators 311, 312, and 313 are not required to expand and contract as compared with the second actuator 411, it is possible to reduce the size of the first actuator. Thereby, even if it is a high viscosity-droplet discharge head having a plurality of nozzles, a nozzle density can be raised.
In the droplet discharge control of Embodiment 2, the start timing of the drawing process of the first actuator 311 and the start timing of the drawing process of the second actuator 411 are the same timing, but the head control unit 6 may drive the first actuator 311 with a delay of predetermined time Δt compared to the second actuator 411. This is because the second actuator 411 is positioned upstream of the first actuator 311 in the liquid flow path. The pressure wave generated by the first actuator 311 propagates to the liquid in the nozzle 111 via the first liquid chamber 121, whereas the pressure wave generated by the second actuator 411 propagates to the liquid in the nozzle 111 via the first inflow path 131 and the first liquid chamber 121. Thereby, the pressure change of the liquid in the nozzle 111 can be appropriately controlled. The first vibration plate 21 and the second vibration plate 22 may be integrally formed.
The present disclosure is not limited to the above-described embodiment, and various modifications and improvements can be added to the above-described embodiment. Modification examples will be described below.
In Embodiment 1 described above, the second actuator 411 is disposed on the first actuator 311 as shown in
In Modification Example 1 described above, it is described that the second actuator 411 is disposed between the first actuators 311 and 314 as shown in
In Embodiment 2, as shown in
In Modification Example 3, as shown in
In Embodiment 2, as shown in
In Embodiment 2, it is described that the second actuator 411 is disposed on the second vibration plate 22 forming a part of the wall surface of the first inflow path 131 as shown in
In Embodiment 2, as shown in
It is described that the droplet discharge head 12 of Embodiment 2 includes the first inflow path 131 and the nozzle 111, but may further communicate with the outflow path 161. One opening of the outflow path 161 communicates with the first liquid chamber 121. The other opening of the outflow path 161 communicates with the first tank 961 or the second tank 962. Thereby, it is possible to suppress discharge failure due to thickening of the liquid in the first liquid chamber 121 or the nozzle 111 and discharge failure due to bubbles mixed from the opening 172 of the nozzle 111.
In Modification Example 8 above, as in the droplet discharge head 80 shown in
In the above modification 8, it is described that one opening of the outflow path 161 communicates with the first liquid chamber 121, but as shown in the droplet discharge head 81 of
In the above embodiment, in the timing chart of droplet discharge control (
In the above modification example, in the droplet discharge control timing chart (
In the above embodiment, in the droplet discharge control timing chart (
In the above embodiment, in the non-discharge control timing chart (
The second actuator 411 of the above embodiment may be configured by various elements that generate displacement, such as an air cylinder, a solenoid, and a magnetostrictive element. In this way, the same effect as described above can be obtained.
In the above embodiment, liquids of different colors may be supplied to the plurality of first liquid chambers 121, 122, and 123, respectively. In this way, the same effect as described above can be obtained.
In the above embodiment, when the droplet discharge head discharges droplets continuously (that is, the timing charts of
In the above embodiment, the transport mechanism 94 is described as the recording medium transport mechanism 942 and the carriage moving mechanism 941, but the transport mechanism may be a 3D drive stage, and when the droplet discharge head is a line head, the carriage moving mechanism 941 may be omitted.
In the above embodiment, the nozzle 111 according to the above-described embodiment is described as a tapered shape, the nozzle 111 may have a cylindrical shape. In the cylindrical nozzle, the shape of the meniscus drawn into the nozzle in the drawing process can be stabilized. Thereby, repeatability can be improved.
The contents derived from the embodiment will be described below.
A droplet discharge head of the present application each includes a first liquid chamber formed on a flow path forming substrate, a nozzle communicating with the first liquid chamber, and a first inflow path for supplying a liquid to the first liquid chamber, and a first actuator that individually changes a pressure in the first liquid chamber, a second actuator that changes pressures in a plurality of first liquid chambers in common, in which an expansion/contraction amount of the second actuator is larger than that of the first actuator.
According to this configuration, the second actuator applies a pressure to the plurality of first liquid chambers, and the first actuator applies a pressure to each first liquid chamber. The structure of the second actuator tends to be relatively large in order to increase the amount of expansion and contraction, but since the first actuators are not required to expand and contract as compared with the second actuator, it is possible to reduce the size of the first actuator. Thereby, even if it is a high viscosity-droplet discharge head having a plurality of nozzles, a nozzle density can be raised.
The droplet discharge head includes a first vibration plate forming a part of the wall surface of the first liquid chamber, in which the first actuator may be fixed to the first vibration plate, and the second actuator may displace the first vibration plate by displacing the first actuator.
According to this configuration, the second actuator having a large expansion/contraction amount reduces the pressure in the nozzle, and therefore the meniscus can be largely drawn into the nozzle and a pseudo nozzle can be formed. After the pseudo nozzle is formed, the first actuator pressurizes the liquid in the nozzle to invert the meniscus in the nozzle and form a liquid column. Furthermore, the first actuators are individually disposed on the first vibration plate of the first liquid chamber, and the second actuator are disposed over the plurality of first actuators, whereby the nozzle density can be increased while maintaining the amount of the meniscus. Thereby, even if it is a high viscosity-droplet discharge head having a plurality of nozzles, a nozzle density can be raised.
In the droplet discharge head, the first actuator may be interposed between the second actuator and the first vibration plate.
According to this configuration, since the first liquid chamber can be efficiently disposed on the flow path forming substrate, the nozzle density can be increased.
The droplet discharge head includes a first vibration plate forming a part of the wall surface of the first liquid chamber, and a second vibration plate forming a part of the wall surface of the first inflow path, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate.
According to this configuration, the second actuator having a large expansion/contraction amount reduces the pressure in the nozzle, and therefore the meniscus can be largely drawn into the nozzle and a pseudo nozzle can be formed. After the pseudo nozzle is formed, the first actuator pressurizes the liquid in the nozzle to invert the meniscus in the nozzle and form a liquid column. Furthermore, the first actuators are individually disposed on the first vibration plate of the first liquid chamber, and the second actuator are disposed over the plurality of first inflow paths, whereby the nozzle density can be increased while maintaining the amount of the meniscus. Thereby, even if it is a high viscosity-droplet discharge head having a plurality of nozzles, a nozzle density can be raised.
In the droplet discharge head, a plurality of the first actuators may be disposed with the second actuator interposed therebetween, the first actuator may be fixed to a bridging member, and the second actuator may be fixed to the bridging member.
According to this configuration, the dimension in the height direction of the droplet discharge head can be shortened.
In the droplet discharge head, a plurality of the second actuators may be provided, the plurality of second actuators may be disposed with the first actuator interposed therebetween, the plurality of second actuators may be fixed to a bridging member, and the bridging member may be fixed to a plurality of the first actuators.
According to this configuration, heat generated by driving the second actuator can be easily radiated.
The droplet discharge head includes a first vibration plate forming a part of the wall surface of the first liquid chamber, and a second vibration plate forming a part of the wall surface of the first liquid chamber, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate.
According to this configuration, the propagation path of the pressure wave generated by the second actuator can be shortened, and the meniscus response to the displacement of the second vibration plate is improved.
The droplet discharge head includes a nozzle plate forming a part of a wall surface of the first liquid chamber, and a second vibration plate forming a part of the wall surface of the first liquid chamber, in which the nozzle may be formed on a nozzle plate, the first actuator may be fixed to the nozzle plate, and the second actuator may be fixed to the second vibration plate.
According to this configuration, the propagation path of the pressure wave generated by the first actuator to the nozzle can be shortened, thereby improving the responsiveness of the meniscus to the driving of the first actuator.
In the droplet discharge head, the first inflow path may include a second liquid chamber having a larger width than the first inflow path, and the second actuator may be fixed to the second vibration plate forming a part of a wall surface of the second liquid chamber.
According to this configuration, the displacement amount of the second vibration plate can be increased.
The droplet discharge head includes a first vibration plate forming a part of a wall surface of the first liquid chamber, a second vibration plate forming a part of a wall surface of the first inflow path, and a displacement amplifying mechanism for amplifying an expansion/contraction amount of the second actuator to displace the second vibration plate, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate via the displacement amplifying mechanism.
According to this configuration, the same effect as described above can be obtained.
The droplet discharge head includes an outflow path through which the liquid flows out from the first liquid chamber, a first vibration plate forming a part of a wall surface of the first liquid chamber, a second vibration plate forming a part of a wall surface of the outflow path, in which the first actuator may be fixed to the first vibration plate, and the second actuator may be fixed to the second vibration plate.
According to this configuration, the same effect as described above can be obtained.
The droplet discharge head of the present application each includes a first liquid chamber formed on a flow path forming substrate, a nozzle communicating with the first liquid chamber, a first inflow path for supplying a liquid to the first liquid chamber, and a second inflow path communicating with the nozzle, and a first actuator that individually changes a pressure in the first liquid chamber, and a second actuator that changes pressures in a plurality of nozzles in common, in which an expansion/contraction amount of the second actuator may be larger than that of the first actuator.
According to this configuration, the pressure fluctuation due to the second actuator is transmitted to the nozzle without passing through the first liquid chamber, and therefore compliance can be reduced.
The droplet discharge head described above is a droplet discharge head is mounted on a droplet discharge apparatus including a control unit for controlling droplet discharge, in which based on a drive signal from the control unit, the second actuator may be driven to draw a meniscus in the nozzle by depressurizing the first liquid chamber, and after the meniscuses in a plurality of the nozzles are drawn, the first actuator may be driven to discharge droplets from the nozzle by pressurizing the first liquid chamber.
According to this configuration, the second actuator having a large expansion/contraction amount reduces the pressure in the plurality of first liquid chambers, and therefore the meniscuses of the plurality of nozzles can be largely drawn and a pseudo nozzle can be formed. After the pseudo nozzle is formed, the first actuator pressurizes the liquid in the plurality of the first liquid chambers to invert the meniscus in the plurality of nozzles and form a liquid column. Furthermore, the first actuator changes the pressure of each first liquid chamber individually, and the second actuator changes the pressures of the plurality of first liquid chambers in common, whereby the nozzle density can be increased while maintaining the amount of the meniscus.
In the droplet discharge head, the plurality of nozzles may include a first nozzle that discharges droplets and a second nozzle that does not discharge droplets, and based on a drive signal from the control unit, after the meniscuses in the plurality of nozzles are drawn, the first actuator corresponding to the first nozzle may be driven to pressurize the first liquid chamber communicating with the first nozzle, and after the meniscuses in the plurality of nozzles are drawn, the first actuator corresponding to the second nozzle may not be driven.
According to this configuration, even when the second actuator changes the pressures of the plurality of first liquid chambers, discharge and non-discharge control can be executed for each nozzle.
In the droplet discharge head, the plurality of nozzles may include a first nozzle that discharges droplets and a second nozzle that does not discharge droplets, and based on a drive signal from the control unit, when the second actuator is driven and the inside of the first liquid chamber is depressurized to draw the meniscus in the first nozzle and the second nozzle, the first actuator of the second nozzle may be driven to pressurize the inside of the first liquid chamber communicating with the first nozzle, and when the second actuator is driven and the inside of the first liquid chamber is pressurized to push the meniscus in the first nozzle and the second nozzle, the first actuator of the second nozzle may be driven to depressurize the first liquid chamber communicating with the first nozzle.
According to this configuration, the behavior of the meniscus in the non-discharge nozzle can be reduced, and drying of the liquid in the nozzle is suppressed.
In the droplet discharge head, the plurality of nozzles may include a first nozzle that discharges droplets and a second nozzle that does not discharge droplets, in which a diameter of a droplet discharged from the first nozzle may be less than two-thirds of an opening of the first nozzle.
According to this configuration, since the inside of the pseudo nozzle diameter liquid film formed in the nozzle has a diameter that is two-thirds of the nozzle inner diameter, a liquid having a diameter less than two-thirds of the nozzle inner diameter can be discharged.
In the droplet discharge head, the speed at which the liquid column formed in the nozzle moves in the direction toward the nozzle opening may be higher than the speed at which the meniscus in the nozzle moves in the direction toward the nozzle opening.
According to this configuration, it is possible to promote separation of the liquid column from the liquid in the nozzle.
The droplet discharge head of the present application each includes a first liquid chamber formed on a flow path forming substrate, a nozzle communicating with the first liquid chamber, a first inflow path for supplying a liquid to the first liquid chamber, and a first actuator that individually changes a pressure in the first liquid chamber, a second actuator for changing the pressure in the plurality of first liquid chambers in common, in which an excluded volume generated by the second actuator may be larger than an excluded volume generated by the first actuator.
According to this configuration, the second actuator applies a pressure to the plurality of first liquid chambers, and the first actuator applies a pressure to each first liquid chamber. The structure of the second actuator tends to be relatively large in order to increase the excluded volume, but since the first actuators are not required to have an excluded volume as compared with the second actuator, it is possible to reduce the size of the first actuator. Thereby, even if it is a high viscosity-droplet discharge head having a plurality of nozzles, a nozzle density can be raised.
Number | Date | Country | Kind |
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JP2018-239218 | Dec 2018 | JP | national |
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20200198337 A1 | Jun 2020 | US |