JP2008221578A - Liquid ejection head drive system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid ejection head drive system which can facilitate control of a voltage being applied to a piezoelectric element. <P>SOLUTION: When a head control section 30 designates an SW section 36 to turn a switching element SW on, a drive voltage application section 32 applies a predetermined drive voltage (drive waveform) to the individual electrode 44 of a piezoelectric element 40. A power supply control section 34 applies a voltage including a variation voltage dependent on the environmental information of ink temperature, or the like, to a common electrode 42. When the piezoelectric element 40 is polarized, the power supply control section 34 is controlled to apply a voltage having a negative polarity to the common electrode 42. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a droplet discharge head driving device for an inkjet printer.

  In general, an ink jet printer using a piezoelectric element such as a piezoelectric element is known as an actuator. In this ink-jet printer, the volume (volume) is changed by expanding and contracting the pressure chamber filled with ink by deforming the piezoelectric element, and the pressure chamber is communicated with the internal pressure due to the change. A head for discharging ink droplets from the tip of the nozzle is provided.

Expansion and contraction of the pressure chamber are performed by applying a voltage to both electrodes of the piezoelectric element by a droplet discharge head driving device. There is known a technique in which a drive voltage having a predetermined drive waveform is applied to one electrode of a piezoelectric element and the other electrode is grounded by a liquid ejection head drive device. (For example, refer to Patent Document 1 and Patent Document 2). In addition, a technique of applying a voltage to both electrodes of the piezoelectric element to apply a potential higher than the ground in order to prevent spontaneous discharge of the piezoelectric element during printing (for example, see Patent Document 3), or abnormality of the piezoelectric element. Technology (see, for example, Patent Document 4), technology for changing the potential according to the drive voltage to reduce power (see, for example, Patent Document 5), and bias output when driving is stopped to reduce power There are known techniques for blocking the above (for example, see Patent Document 6).
JP-A-55-123476 Japanese Patent Laid-Open No. 06-198874 JP 2003-072069 A Japanese Patent Laid-Open No. 2003-21665 Japanese Patent Application Laid-Open No. 2004-174872 JP 2005-313612 A

  In the above conventional technique, for example, in order to adjust the voltage applied to the electrode of the piezoelectric element according to the environmental information such as the temperature of the ink and the characteristics of the head unit, the drive voltage of the drive waveform is not changed. Do not. When there are a plurality of heads, it is necessary to generate a complicated drive voltage for each head. Further, if the piezoelectric element is to be polarized after the droplet discharge head is formed, a voltage sufficient to polarize may not be applied to the electrode.

  An object of the present invention is to provide a droplet discharge head driving device that can easily control a voltage applied to a piezoelectric element in accordance with environmental information.

  In order to achieve the above object, the droplet discharge head driving device of the present invention applies a voltage to a piezoelectric element that deforms according to an applied voltage and generates a volume change in a pressure chamber in which a liquid is accommodated. Drive voltage applying means for applying a drive voltage having a predetermined drive waveform to one electrode of the pair of electrodes, power supply control means for applying a predetermined voltage to the other electrode of the pair of electrodes, and the input And a head control means for controlling the drive voltage application means and the power supply control means so that a voltage corresponding to the environmental information of the liquid is applied to the pair of electrodes.

  According to the first aspect of the present invention, the voltage applied to the piezoelectric element can be easily controlled in accordance with the environmental information as compared with the case where the present configuration is not provided. Is obtained.

  According to the second aspect of the present invention, it is possible to easily change the applied voltage.

  According to the third aspect of the present invention, it is possible to obtain an effect that the ground potential can be connected to the electrode of the piezoelectric element when printing is suspended.

  According to the fourth aspect of the present invention, there is an effect that the potential difference between the pair of electrodes is controlled by turning on and off the switch portion.

  According to the present invention described in claim 5, an effect that the potential difference between the pair of electrodes can be increased is obtained. That is, it becomes possible to apply a voltage higher than the breakdown voltage of the driver IC to the piezoelectric element.

  According to the sixth aspect of the present invention, there is an effect that the voltage applied to the piezoelectric element can be easily controlled in accordance with the information related to the viscosity of the liquid.

[First Embodiment]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that the droplet discharge head driving apparatus 10 according to the present embodiment will be described in the case of analog waveform driving in which the piezoelectric element is driven in an arbitrary waveform shape.

  FIG. 1 shows a schematic configuration of a droplet discharge head driving apparatus 10 according to the present embodiment. The droplet discharge head driving apparatus 10 of the present embodiment includes a head control unit 30, a drive voltage application unit 32, a SW (switch) unit 36, and a power supply control unit 34, and the droplet discharge head. 20 is driven.

  Here, a specific example of the droplet discharge head 20 is shown in FIG. The droplet discharge head 20 of the present embodiment includes m head units 24, and each head unit 24 includes a droplet ejector 50 (see FIG. 5) including n nozzles for discharging droplets. 3). The configuration of the droplet discharge head 20 is not limited to this, and the head unit 24 and the nozzles 48 may be of any number, and the arrangement of the head units 24 and the nozzles 48 is other arrangement such as a staggered pattern. Also good.

  In the liquid droplet ejection head driving apparatus 10 of the present embodiment, the voltage applied to both electrodes (the common electrode 42 and the individual electrode 44) of the piezoelectric element 40 is controlled for each head unit 24, as shown in FIG. Shows only one of the m head units 24.

  FIG. 3 shows a specific example of the droplet ejector 50 according to the present embodiment. The droplet ejector 50 uses a piezoelectric element (piezo element) 40 as a pressure generating element serving as an actuator. The droplet ejector 50 includes a pressure chamber 46, a common electrode (vibrating plate) 42, and a nozzle portion 48.

  The piezoelectric element 40 is deformed by a voltage applied from the common electrode 42 and the individual electrode 44 to vibrate the common electrode (vibrating plate) 42 forming a part of the wall surface of the pressure chamber 46 of the droplet ejector 50. . At this time, the piezoelectric element 40 deforms the common electrode (vibrating plate) 42 so that the pressure chamber 46 expands when the voltage of the individual electrode with respect to the common electrode decreases, and the pressure increases when the voltage increases. The common electrode (vibrating plate) 42 is deformed so as to contract the chamber 46. The droplet ejector 50 causes the ink in the pressure chamber 46 to be ejected from the nozzle portion 48 as an ink droplet 52 by the expansion and contraction of the common electrode (vibrating plate) 42. The piezoelectric element as the actuator is not limited to this example, and one side of the laminate may be a common electrode and the other may be an individual electrode. Further, the expansion and contraction of the pressure chamber due to the decrease and increase of the potential may be different from those of the present embodiment depending on the polarization direction of the piezoelectric element, but can be applied without any problem.

  The head control unit 30 is connected to an overall control unit (not shown) that controls the driving of the entire ink jet printer provided with the droplet discharge head driving device 10 of the present embodiment. Instruction, image data, sensor information such as ink temperature, and the like are input. The head control unit 30 includes a CPU, a memory, a ROM, and the like (not shown). In the CPU, a control routine, which will be described in detail later, is executed in order to control the driving of the liquid ejection head 20. The control routine program is stored in a ROM as a storage medium. The memory stores in advance a relationship between environmental information (details will be described later) such as ink temperature, a printing mode, and the like, and a bias voltage and a driving voltage (driving waveform) applied to the piezoelectric element 40.

  The drive voltage application unit 32 applies a drive voltage (drive waveform) to the individual electrode 44 of the piezoelectric element 40 via the SW unit 36 in accordance with an instruction from the head control unit 30. The SW unit 36 includes n switching elements SW (SW1 to SWn). Each of the switching elements SW is connected to the individual electrode 44 and is turned on / off by an instruction from the head controller 30. When turned on, a drive voltage (drive waveform) is applied from the drive voltage application unit 32 to the individual electrode 44, and when turned off, the drive voltage (drive waveform) is cut off. When the switching element SW is turned on, when the voltage V1 is applied to the individual electrode 44 and the voltage V2 is applied to the common electrode 42, the potential difference between the individual electrode 44 and the common electrode 42 is V1-V2. become. On the other hand, in the state where the switching element SW is turned off, the potential difference between the individual electrode 44 and the common electrode 42 maintains the potential difference immediately before being turned off (when it is in the on state). In the present embodiment, the switching element SW is provided for each of the piezoelectric elements 40. However, this embodiment includes a configuration in which a plurality of drive waveform application units are provided and a plurality of SWs are connected to the individual electrodes. Not limited to. The power supply control unit 34 includes a variable power supply 56 (see FIG. 5), and applies a bias voltage or a ground voltage to the common electrode 42 in accordance with an instruction from the head control unit 30.

  Next, the droplet discharge head drive control process executed by the head controller 30 of the liquid discharge head drive device 10 of the present embodiment will be described in detail with reference to FIGS.

  FIG. 4 is a flowchart showing a control routine of a droplet discharge head drive control process executed by the head controller 30 of the liquid discharge head drive device 10. The droplet discharge head drive control process shown in FIG. 4 is executed when, for example, a print command, a power-on process command, a polarization process command after a certain period of time has been input from the overall control unit to the head control unit 30, or the like. Is done.

  In step 98, a command from the upper overall control unit is waited for. If there is a command, the next step 99 reads environmental information and the like.

  In this embodiment, the environmental information is information related to the viscosity of the ink, and includes, for example, the temperature and humidity of the ink, the characteristics of the head unit 24 to be controlled, the duration of the resting state, and the like. Specifically, the ink temperature refers to a sensor provided in the head unit 24 or the liquid ejection head 20, a sensor provided in the vicinity of the head unit 24 or the liquid ejection head 20, and a liquid ejection head driving device. 10 is a temperature detected by a sensor or the like provided in another place in the printer 10 and may be the ink temperature itself as long as the relationship with the ink temperature is obtained in advance. The humidity specifically refers to a sensor provided in the head unit 24 or the liquid ejection head 20, a sensor provided in the vicinity of the head unit 24 or the liquid ejection head 20, and a liquid ejection head drive device. 10 is a humidity detected by a sensor or the like provided in another place in the room. If the humidity is high, the ink is difficult to thicken.

  The characteristics of the head unit 24 and the like are characteristics caused by variations in manufacturing of the piezoelectric element 40 and the nozzle portion 48 that constitute the head unit 24. In addition, the pause state duration time is a time period in which the printer is in a pause state before starting the printing. Specifically, for example, the previous printing or the purge process (recording for discharging the thickened ink) is performed. This means the time from the ejection to the ink absorber, not the medium) to the start of the printing. The ink thickens in proportion to the pause time.

  It should be noted that not only the environmental information but also printing information such as a printing mode (the size of ejected droplets) is set so that it is also read.

  In the next step 100, it is determined whether or not the command is printing (image formation). If a print instruction is input from the overall control unit, the determination is affirmative and the process proceeds to step 112. On the other hand, if negative, the process proceeds to step 102. In step 102, it is determined whether or not the command is for performing polarization of the piezoelectric element 40. The command of polarization from the overall control unit is, for example, whether or not a fixed time has elapsed since the last execution of polarization by reading a timer or the like not shown, and comparing the value of a polarization state detector not shown and a preset value It is executed depending on the result. If the determination is affirmative, the process proceeds to step 104, and after performing the polarization process 104, the process proceeds to step 126. The details of polarization and polarization processing 104 will be described later.

  On the other hand, if the result in Step 102 is negative, it is determined that the command is a pause command, and the process proceeds to Step 106. In step 106, the SW unit 36 is instructed to turn off the switching elements SW1 to SWn, and in the next step 108, the power supply control unit 34 is instructed to put the droplet discharge head 20 in a dormant state, and the process proceeds to step 126. move on. In the present embodiment, the resting state means a state in which neither printing (image formation) nor polarization is performed, and is a state in which the driving of the droplet discharge head 20 is resting. Note that the flowchart of FIG. 4 is an example, and there are other types of commands from the overall control unit, and the operation of the drive control unit may be in accordance therewith.

  If an electric field (voltage) is applied to the piezoelectric element 40 in the resting state, that is, if the voltage is applied to the piezoelectric element for a long time, problems such as deterioration of the polarization state of the piezoelectric element occur. Therefore, control is performed so that no voltage is applied to the piezoelectric element 40. In the present embodiment, when a pause instruction is input, the power supply control unit 34 applies a ground voltage to the common electrode 42. A specific example is shown in FIG. In the case shown in FIG. 5A, the power supply control unit 34 includes a variable power supply 56. When a pause instruction is input from the head control unit 30 to the variable power supply 56, the variable power supply 56 generates a GND potential. Then, the GND potential is output to the common electrode 42. 5B, the power supply control unit 34 includes a variable power supply 56 and a switch 58. When a pause instruction is input from the head control unit 30 to the variable power supply 56, the switch 58 The connection destination of the common electrode 42 is switched from the output part of the variable power source 56 to GND.

  On the other hand, in step 112 when an affirmative determination is made in step 100, the drive voltage and the bias voltage are determined based on the environmental information read in step 99 and the like. The bias voltage refers to the voltage at the start point = the end point of the drive voltage (also referred to as drive waveform) applied to the piezoelectric element during ejection, to be exact, the potential difference applied to the piezoelectric element.

  Here, the relationship between the environmental information and the bias voltage will be described with reference to FIGS. An example of the relationship between ink temperature and print density (Optical Density, OD value) is shown in FIG. The ink temperature in this case is specifically a temperature detected by a sensor provided in the head unit 24. As can be seen from FIG. 6, as the ink temperature increases, the print density also increases. Since the print density is substantially proportional to the amount of ejected droplets, the amount of ejected droplets increases as the ink temperature increases. FIG. 7 shows an example of the relationship between the bias voltage applied to the piezoelectric element 40 and the volume of the ejected droplet (the amount of droplet). FIG. 7 illustrates three cases where the droplet size is large, medium, and small. As can be seen from FIG. 7, regardless of the size of the droplet, as the bias voltage increases, the volume of the droplet (the amount of the droplet) decreases.

  Therefore, in order to make the volume of the ejected droplets constant, there is a predetermined relationship between the bias voltage and the ink temperature. When the ink temperature increases, the bias voltage increases, while when the ink temperature decreases. Decrease the bias voltage.

  In the memory (not shown) of the head control unit 30, a predetermined bias voltage, a driving voltage (driving waveform), and a fluctuation voltage corresponding to environmental information are stored in advance, and in step 112, this is read from the memory and driven. The voltage applied to the individual electrode 44 from the voltage application unit 32 and the voltage applied to the common electrode 42 from the power supply control unit 34 are determined.

  In the next step 114, the SW unit 36 is instructed to turn on the switching elements SW1 to SWn (H level signal transmission), and in the next step 116, the drive voltage application unit 32 starts to apply a voltage to the individual electrode 44. And instruct the power supply control unit 34 to start applying a voltage to the common electrode 42. In the next step 118, the voltage applied by the drive voltage applying unit 32, the voltage applied by the power supply control unit 34, and the on / off control of the switching elements SW1 to SWn according to the image data are performed. A droplet is discharged to

  In the next step 120, it is determined whether or not to end printing. For example, if printing of print data (image data) input from the overall control unit still remains, the process returns to step 118 to control the drive voltage application unit 32 and the power supply control unit 34, and the switching element. The control of SW1 to SWn is repeated. On the other hand, if all printing has been completed, the determination is affirmative and the routine proceeds to step 121.

  In step 121, all the switching elements SW1 to SWn are turned on, and in step 122, the drive voltage application unit 32 and the power supply control unit 34 are instructed to stop application of all voltages. In step 124, the SW unit 36 is instructed. Is instructed to turn off the switching elements SW1 to SWn (L level signal transmission), and the process proceeds to step 126.

  Here, an example of the control in steps 112 to 124 will be described with reference to FIGS. In FIG. 8, a driving voltage (driving waveform) in consideration of a bias voltage is applied from the driving voltage application unit 32 to the individual electrode 44 of the piezoelectric element 40, and a variation voltage corresponding to environmental information is applied from the power supply control unit 34 to the common electrode 42. The case where it is applied is shown. In the present embodiment, the time until the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 reaches a bias voltage value from 0 is referred to as charging, and the time during which droplets are being discharged is referred to as discharging. That is, after all the instructed printing is completed (droplet ejection is completed), the time until the potential difference becomes 0 from the bias voltage is called discharging.

  As shown in FIG. 8, the drive voltage application unit 32 applies a bias voltage to the individual electrode 44 with a waveform having a predetermined slope during charging. A drive voltage (drive waveform) is applied during ejection, and the applied voltage is reduced by a waveform having a predetermined slope during discharge. Further, the power supply control unit 34 normally applies 0 to the common electrode at the time of charging, discharging, and discharging, and applies only the variable voltage corresponding to the environmental information to the common electrode. FIG. 8 shows a case where the fluctuation voltage is not taken into consideration. An example of the width of the fluctuation voltage generated by the power supply control unit 34 according to the environmental information is shown in FIG. The reference is zero voltage (voltage value = 0).

  Therefore, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 is as shown in FIG.

  Another example of the control will be described with reference to FIGS. In FIG. 10, the drive voltage (drive waveform) is applied from the drive voltage application unit 32 to the individual electrode 44 of the piezoelectric element 40, and the fluctuation voltage and the bias voltage corresponding to the environmental information are applied from the power supply control unit 34 to the common electrode 42. Shows the case. In the present embodiment, a bias voltage having a negative polarity is applied from the power supply control unit 34.

  As shown in FIG. 10, the drive voltage application unit 32 outputs 0 V during charging, applies a drive voltage (drive waveform) during discharge, and outputs 0 V during discharge in the same manner as during charging. . Further, the power supply control unit 34 applies a bias voltage to the common electrode 42 with a waveform having a predetermined slope during charging. When discharging, a constant voltage (bias voltage) is applied, and when discharging, the application of the bias voltage is stopped by a waveform having a predetermined slope opposite to that during charging. Further, the power supply control unit 34 further applies a variable voltage corresponding to the environmental information to the common electrode 42 during charging, discharging, and discharging. FIG. 10 shows a case where the fluctuation voltage is not taken into consideration. An example of the width of the fluctuation voltage generated by the power supply control unit 34 according to the environmental information is shown in FIG. Based on the bias voltage value.

  Therefore, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 is as shown in FIG.

  In step 126, it is determined whether or not to end this process. If not, the process returns to step 98 and waits for a command from the main body control unit. On the other hand, if the determination is affirmative, this process is terminated.

  In the present embodiment, the voltage output from the power supply control unit 34 (the voltage applied to the common electrode 42) is changed according to the environmental information. However, for example, the environmental information such as a large variation in the ink temperature. In the case where there is a large fluctuation, the drive voltage (drive waveform) applied from the drive voltage application unit 32 may be further changed.

  In order to prevent thickening of ink, for example, the page printer switches to the next page after charging the bias voltage and before the print trigger (droplet ejection timing) or during ejection. The voltage is applied from the power supply control unit 34 to about 1/8 to 1/4 of the normal time so that the liquid droplets are not discharged. A fine vibration waveform (fine vibration voltage) may be applied to the common electrode 42 by performing fine control.

(Polarization treatment)
Next, the polarization process executed in step 104 will be described in detail with reference to FIGS. FIG. 12 is a flowchart of the polarization process in step 104 described above.

  First, in step 200, the SW unit 36 is instructed to turn on the switching element SW. In accordance with the environmental information read in step 100, in the next step 202, the drive voltage application unit 32 is instructed to apply the voltage V1 (positive polarity) to the individual electrode 44, and in the next step 204, the power supply control unit 34. Is instructed to apply a voltage V2 (negative polarity) to the common electrode 42.

  In the next step 206, voltage application by the drive voltage application unit 32 and voltage application by the power supply control unit 34 are controlled. In the next step 208, it is determined whether or not to end the polarization process. Whether or not to end the polarization process is determined by, for example, holding time (for example, holding the polarization voltage according to the read environmental information or according to the polarization state (not shown) in order to sufficiently polarize the piezoelectric element). 1 minute) is determined in advance, and when the holding time has elapsed after reading a timer (not shown), it may be determined that the polarization process is to be terminated. If the holding time has not passed yet, the result is negative, and the process returns to step 206 to control the voltage application by the drive voltage application unit 32 and the voltage application by the power supply control unit 34. On the other hand, if the holding time has elapsed, the determination is affirmative and the process proceeds to step 210.

  In step 210, the drive voltage application unit 32 and the power supply control unit 34 are instructed to stop application of all voltages (voltage V1 and voltage V2), and in the next step 212, the switching element SW is turned off to the SW unit 36. This process is terminated.

  Here, an example of the polarization process will be described in detail with reference to FIG. FIG. 13 is a timing chart for explaining an example of polarization processing. When the switching element SW is turned on, application of the voltage V <b> 1 to the individual electrode 44 is started by the drive voltage application unit 32. Further, the power supply control unit 34 starts applying the voltage V2 to the common electrode 42. As a result, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 is first changed to the voltage V1 when the voltage V1 is applied from the drive voltage application unit 32, and further, the voltage V2 from the power supply control unit 34. Is applied, the voltage becomes V1-V2. Therefore, the polarization voltage is V1-V2. However, since the voltage V2 is negative, the polarization voltage is higher than the voltage V1.

  When the holding time has elapsed, first, the application of the voltage V1 by the drive voltage application unit 32 is stopped, and further, the application of the voltage V2 by the power supply control unit 34 is stopped. As a result, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 first becomes the voltage −V2 when the application of the voltage V1 by the drive voltage application unit 32 is stopped, and further, the power supply control unit 34. When the application of the voltage V2 due to is stopped, the voltage becomes zero. Accordingly, the polarization voltage becomes 0, the switching element SW is turned off, and the polarization process ends.

  Another example of polarization processing will be described in detail with reference to FIG. FIG. 14 is a timing chart for explaining another example of polarization processing. When the switching element SW is turned on, a voltage is gradually applied to the individual electrode 44 by the drive voltage application unit 32, and the voltage V1 is applied. Further, the power supply controller 34 gradually applies a voltage to the common electrode 42 so that the voltage V2 is applied. Thereby, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 gradually increases, and the polarization voltage becomes V1−V2.

  When the holding time has elapsed, the application of the voltage V1 by the drive voltage application unit 32 and the application of the voltage V2 by the power supply control unit 34 are stopped. As a result, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 gradually decreases. Accordingly, the polarization voltage becomes 0, the switching element SW is turned off, and the polarization process ends.

  In addition, if the applied voltage V 1 -the applied voltage V 2 are voltages necessary for polarization, that is, a potential difference necessary for polarization may be generated between the common electrode 42 and the individual electrode 44.

  Further, the polarization process may be performed for each piezoelectric element 40, may be performed for each head unit 24, or may be simultaneously performed for all the piezoelectric elements 40 included in the head 20.

  As described above, in the present embodiment, since the power supply control unit 34 includes the variable power supply 56 and a voltage having a negative polarity can be applied from the power supply control unit 34 to the common electrode 42, the piezoelectric element The potential difference generated at 40 is the voltage applied from the drive voltage application unit 32 and the voltage applied from the power supply control unit 34. Thereby, even after the head 20 is formed, a voltage sufficient for polarization can be applied. For example, in order to perform polarization, it may be necessary to apply a voltage several times the drive voltage for driving the element. Particularly, when a thin film piezoelectric element is used as the piezoelectric element 40, the thin film piezoelectric element is used. A large voltage is required to polarize the hard material. When polarization is performed before the head 20 is formed, it is necessary to limit the Curie temperature of the piezoelectric element in the manufacturing process. Further, if an attempt is made to apply such a large voltage from the drive voltage application unit 32 after the head 20 is formed, the voltage may not be applied because, for example, the breakdown voltage of the IC for driving is exceeded. Even in this case, since a voltage having a negative polarity can be applied to the common electrode 42 from the power supply control unit 34, the potential difference between both electrodes of the piezoelectric element 40 can be increased, and a sufficiently large polarization can be obtained. Polarization can be performed by voltage.

  As described above, in the present embodiment, the power supply control unit 34 includes the variable power supply 56 and can apply a voltage according to environmental information or the like to the common electrode 42. Voltage can be easily controlled. Thereby, the voltage according to environmental information etc. can be easily applied to the piezoelectric element 40, without changing a drive waveform (drive voltage). In addition, voltage control according to the characteristics of each piezoelectric element 40 and voltage control for each head unit 24 can be easily performed. Furthermore, there is no temperature restriction in the manufacturing process, and polarization processing with a voltage exceeding the breakdown voltage of the IC for driving can be performed.

[Second Embodiment]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, the droplet discharge head driving device 10 ′ of the present embodiment will be described with respect to a case where the piezoelectric element is driven in a rectangular wave using a constant voltage pulsed driving waveform. Since the present embodiment has substantially the same configuration as that of the first embodiment, the same portions and the same processes are denoted by the same reference numerals, and detailed description thereof is omitted.

  FIG. 15 is a diagram showing a schematic configuration of a droplet discharge head driving device 10 ′ according to the present embodiment. The droplet discharge head drive device 10 ′ of this embodiment includes a head control unit 30, a drive voltage application unit 32, a SW (switch) unit 36, and a power supply control unit 34, and droplet discharge. The head 20 is driven. The SW unit 36 includes charge switches SWC1 to SWn and discharge switches SWD1 to SWDn. The charge switch SWC is connected between the drive voltage application unit 32 and the individual electrode 44 and is turned on / off according to an instruction from the head control unit 30. The discharge switch SWD is connected between the common electrode 42 and the individual electrode 44 and is turned on / off according to an instruction from the head control unit 30. In FIG. 15, only one of the n SWDs, only one of the n SWCs, n piezoelectric elements 40 of the head 20 (head unit 24), and the common electrode 42, respectively. Only one of each of the individual electrodes 44 is shown.

  Next, the droplet discharge head drive control process executed by the head controller 30 of the liquid discharge head drive device 10 ′ of the present embodiment will be described in detail with reference to FIGS. 16 to 20.

  FIG. 16 is a flowchart showing a control routine of a droplet discharge head drive control process executed by the head controller 30 of the liquid discharge head drive device 10 '. The droplet discharge head drive control process shown in FIG. 16 includes the first embodiment, SWC1 to SWn and SWD1 to SWD1 in step 114 ′, control instructions (corresponding to step 114 in the first embodiment), step Control of voltage application by the drive voltage application unit 32 of 118 'and voltage application by the power supply control unit 34 (corresponding to step 118 of the first embodiment), SWC1-n and SWD1-n control instructions of step 121' (Corresponding to step 121 in the first embodiment) and SWC1 to n and SWD1 to SWD1 in step 124 ′ and only the control instruction end (corresponding to step 124 in the first embodiment) are different. Only different processing will be described in detail with reference to FIGS.

  First, as an example, FIG. 17 illustrates a case where the drive voltage is applied from the drive voltage application unit 32 to the individual electrode 44 of the piezoelectric element 40, and the fluctuation voltage corresponding to the environmental information is applied from the power supply control unit 34 to the common electrode 42. Will be described with reference to FIG.

  As shown in FIG. 17, the drive voltage application unit 32 applies a constant drive voltage to the individual electrode 44 during charging, discharging, and discharging. Further, the power supply control unit 34 normally applies 0 to the common electrode 42 at the time of charging, discharging, and discharging, and applies only the variable voltage corresponding to the environmental information to the common electrode 42. FIG. 17 shows a case where the fluctuation voltage is not considered. An example of the width of the fluctuation voltage generated by the power supply control unit 34 in accordance with the environmental information is shown in FIG. The reference is zero voltage (voltage value = 0).

  The charging switch SWC is finely turned on and off by a short pulse signal (rectangular wave) during charging. At the time of ejection, it is turned on and off by a pulse signal having a predetermined width for ejecting droplets in accordance with printing. Turned off when discharging. The discharge switch SWD is turned off during charging. At the time of discharge, it is turned on by a pulse signal having a predetermined width so as to be turned on while the charging switch SWC is turned off. At the time of discharging, it is turned on and off finely by a short pulse signal. Note that the drive voltage is applied from the drive voltage application unit 32 to the common electrode 42 only while the charge switch SWC is on, and the potential difference between the common electrode 42 and the individual electrode 44 increases. On the other hand, while the discharge switch SWD is turned on, the potential difference generated between the common electrode 42 and the individual electrode 44 decreases.

  Accordingly, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 is as shown in FIG. During charging, the battery is gradually charged in multiple stages according to the number of pulse signals for turning on / off the charge switch SWC. At the time of discharge, the charge switch SWC is turned on / off and the discharge switch SWD is turned on / off. Thus, the droplets 52 are ejected from the nozzles 48. In discharging, the battery is gradually discharged in multiple stages according to the number of pulse signals for turning on / off the discharge switch SWD.

  As another example, a predetermined driving voltage applied from the driving voltage application unit 32 to the individual electrode 44 of the piezoelectric element 40 increases (during charging) and decreases (during discharging) with a waveform having a predetermined slope. A case where a fluctuating voltage corresponding to the environmental information is applied from the power supply control unit 34 to the common electrode 42 will be described with reference to FIG.

  As shown in FIG. 19, the drive voltage application unit 32 applies a voltage to the individual electrode 44 with a waveform having a predetermined slope during charging. A constant voltage is applied during discharge, and the applied voltage is reduced by a waveform having a predetermined slope during discharge. Further, the power supply control unit 34 normally applies 0 to the common electrode 42 at the time of charging, discharging, and discharging, and applies only the variable voltage corresponding to the environmental information to the common electrode 42. FIG. 17 shows a case where the fluctuation voltage is not considered.

  The charging switch SWC is turned on by a pulse signal (rectangular wave) at the time of charging, and turned on and off by a pulse signal having a predetermined width for discharging droplets in accordance with printing. Turned off when discharging. The discharge switch SWD is turned off at the time of charging, turned on and off by a pulse signal having a predetermined width so as to be turned on while the charging switch SWC is turned off at the time of discharging, and turned on at the time of discharging. The

  Accordingly, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 is as shown in FIG. At the time of charging, charging is performed with a waveform having a predetermined slope as the voltage is applied from the drive voltage application unit 32. At the time of discharging, the charging switch SWC is turned on and off, and the discharging switch SWD is turned on and off. Thus, the droplets 52 are ejected from the nozzles 48. At the time of discharging, discharging is performed with a waveform having a predetermined slope as the voltage is applied from the driving voltage applying unit 32.

  Furthermore, as another example, a constant drive voltage (for example, 1/2 of the required drive voltage) is applied from the drive voltage application unit 32 to the individual electrode 44 of the piezoelectric element 40, and the common electrode 42 is supplied from the power supply control unit 34. A case where a voltage obtained by adding a variable voltage according to environmental information to a constant voltage (for example, ½ of a required drive voltage) is applied will be described with reference to FIG.

  As shown in FIG. 20, the drive voltage application unit 32 starts applying a voltage that is ½ of a predetermined drive voltage to the individual electrode 44 during charging, and continues to 1 of the predetermined drive voltage during discharge. A voltage of / 2 is applied, and the voltage application is stopped during discharging. In addition, the power supply control unit 34 starts application of a voltage that is ½ of a predetermined drive voltage (however, negative polarity) after the drive voltage application unit 32 starts applying voltage during charging, and during discharge. Applies a voltage half the predetermined drive voltage as it is, and at the time of discharging, after the drive voltage application unit 32 stops applying the voltage, the voltage application is stopped. Note that FIG. 20 illustrates a case in which the fluctuating voltage corresponding to the environmental information is not considered.

  The charging switch SWC is turned on by a pulse signal (rectangular wave) at the time of charging, and turned on and off by a pulse signal having a predetermined width for discharging droplets in accordance with printing. Turns on when discharging. The discharge switch SWD is turned off at the time of charging, turned on and off by a pulse signal having a predetermined width so as to be turned on while the charging switch SWC is turned off at the time of discharge, and turned off at the time of discharging. The

  Accordingly, the potential difference between the common electrode 42 and the individual electrode 44 of the piezoelectric element 40 is as shown in FIG. At the time of charging, charging is performed in two stages according to the voltage application start from the drive voltage application unit 32 and the voltage application start from the power supply control unit 34, and at the time of discharge, the charge switch SWC is turned on and off, and the discharge switch SWD is turned on The liquid droplets 52 are ejected from the nozzles 48 by being driven to be turned off. At the time of discharging, discharging is performed in two stages according to the voltage application stop of the drive voltage application unit 32 and the voltage application stop of the power supply control unit 34. Note that the voltage applied to the individual electrode 44 from the drive voltage application unit 32 and the voltage applied to the common electrode 42 from the power supply control unit 34 are not half of the drive voltage, respectively. It is sufficient that the potential difference with the individual electrode 44 is a predetermined potential (voltage). In addition, either the drive voltage application unit 32 or the power supply control unit 34 may perform the voltage application start and application stop first.

  In this embodiment, the on / off of the charge switch SWC and the discharge switch SWD is controlled. As a combination of the time and interval at which each switch is turned on / off, for example, for charging, discharging The time etc. may be stored in a memory inside the SW unit 36 (not shown), and the combination may be read from the memory to control the charge switch SWC and the discharge switch SWD.

  In the drawing of the embodiment, the symbol of analog SW is used for the charge switch SWC and the discharge switch SWD, but a simple Tr configuration may be used. In this example, one charge switch and one discharge switch are shown. However, a configuration having a plurality of switches may be used for adjusting the inclination of the drive waveform and adjusting the voltage amplitude. As described above, in the present embodiment, on / off of the charge switch SWC and the discharge switch SWD can be controlled, so that the voltage applied to the piezoelectric element 40 can be controlled. Therefore, the piezoelectric element 40 can be driven in a rectangular wave using a constant voltage pulsed drive waveform.

1 is a configuration diagram showing a schematic configuration of a droplet discharge head driving device according to a first embodiment of the present invention. It is explanatory drawing which shows a specific example of the head which the droplet discharge head drive device concerning the 1st Embodiment of this invention drives. It is explanatory drawing which shows a specific example of the droplet discharge ejector which concerns on the 1st Embodiment of this invention. It is an example of the flowchart which shows the control routine of the droplet discharge head drive control processing which concerns on the 1st Embodiment of this invention. It is explanatory drawing for demonstrating the dormant state of the power supply control part which concerns on the 1st Embodiment of this invention. It is explanatory drawing explaining the relationship between ink temperature and printing density. It is explanatory drawing explaining the relationship between a bias voltage and droplet volume. It is an example of the timing chart for demonstrating control of a drive voltage application part and a power supply control part. It is explanatory drawing explaining an example of the width | variety of the voltage which a power supply control part generate | occur | produces according to environmental information. It is another example of the timing chart for demonstrating control of a drive voltage application part and a power supply control part. It is explanatory drawing explaining another example of the width | variety of the voltage which a power supply control part produces | generates according to environmental information. It is a flowchart which shows the polarization process which concerns on the 1st Embodiment of this invention. It is a timing chart for demonstrating an example of a polarization process. It is a timing chart for explaining other examples of polarization processing. It is a block diagram which shows schematic structure of the droplet discharge head drive device which concerns on the 2nd Embodiment of this invention. It is an example of the flowchart which shows the control routine of the droplet discharge head drive control processing which concerns on the 2nd Embodiment of this invention. It is an example of the timing chart for demonstrating control of charge switch SWC, discharge switch SWD, a drive voltage application part, and a power supply control part. It is explanatory drawing explaining an example of the width | variety of the voltage which a power supply control part generate | occur | produces according to environmental information. It is another example of the timing chart for demonstrating control of charge switch SWC, discharge switch SWD, a drive voltage application part, and a power supply control part. It is another example of the timing chart for demonstrating control of charge switch SWC, discharge switch SWD, a drive voltage application part, and a power supply control part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Liquid discharge head drive device 20 Droplet discharge head 30 Head control part 32 Drive voltage application part 34 Power supply control part 36 SW (switch) part 40 Piezoelectric element (piezo element)
42 Common electrode (diaphragm)
44 Individual electrode 56 Variable power supply

Claims (6)

A drive voltage having a predetermined drive waveform is applied to one electrode of a pair of electrodes for applying a voltage to a piezoelectric element that deforms according to the applied voltage and generates a volume change in a pressure chamber containing a liquid. Driving voltage applying means for
Power control means for applying a predetermined voltage to the other electrode of the pair of electrodes;
Head control means for controlling the drive voltage application means and the power supply control means so that a voltage corresponding to the input environmental information of the liquid is applied to the pair of electrodes;
A droplet discharge head driving device comprising:   The droplet discharge head driving apparatus according to claim 1, wherein the power supply control unit includes a variable power supply.   3. The liquid according to claim 1, wherein the head control unit controls the power source control unit so that a potential of a voltage applied to the other electrode becomes a ground potential when printing is suspended. Drop ejection head drive device. A switch unit for controlling a voltage applied to the piezoelectric element;
4. The liquid according to claim 1, wherein the head control unit controls a potential difference between the pair of electrodes by controlling on and off of the switch unit. 5. Drop ejection head drive device.   5. The head control unit controls the power source control unit so that a voltage having a negative polarity is applied to the other electrode. 6. Droplet discharge head drive device.   6. The droplet discharge head driving apparatus according to claim 1, wherein the environmental information is information related to the viscosity of the liquid.

Images