Ink jet head and ink jet recording apparatus

Information

  • Patent Grant
  • 6783212
  • Patent Number
    6,783,212
  • Date Filed
    Thursday, May 29, 2003
    21 years ago
  • Date Issued
    Tuesday, August 31, 2004
    20 years ago
Abstract
An ink jet head includes: actuators each including a scanning electrode, a piezoelectric element and a recording electrode and arranged in a matrix pattern of n rows by m columns (where n and m are natural numbers equal to or greater than two) in terms of electrical circuit; and a driving circuit for supplying a scanning signal to the scanning electrodes for each column, while supplying a recording signal to each row of the recording electrodes in synchronization with the scanning signal. The actuators are geometrically arranged in n rows by m columns. A relay terminal, extending in a vertical direction, is provided in at least one inter-column space between vertical columns of the actuators for relaying signals from the driving circuit to the recording electrodes and the scanning electrodes. The recording electrodes and the scanning electrodes are connected to the relay terminal via lead wires extending in a horizontal direction.
Description




FIELD OF THE INVENTION




The present invention relates to an ink jet head and an ink jet recording apparatus.




BACKGROUND OF THE INVENTION




An ink jet head using piezoelectric actuators including piezoelectric elements with electrodes provided on both sides thereof is known in the art, as disclosed in Japanese Laid-Open Patent Publication No. 2001-162794. An ink jet head of this type includes a plurality of nozzles, a plurality of pressure chambers associated with the respective nozzles, and a plurality of piezoelectric actuators associated with the respective pressure chambers. Typically, a single “common electrode” is provided on one side of the plurality of piezoelectric actuators so that the common electrode is shared by the piezoelectric actuators. On the other hand, “separate electrodes” are provided independently on the other side of the plurality of piezoelectric actuators. With the ink jet head as described above, a voltage is applied between a separate electrode and the common electrode so as to expand/contract a piezoelectric element, and a pressure is applied on the ink in a pressure chamber by the expansion/contraction, thereby discharging the ink through a nozzle.




An ink jet head is provided with a driving circuit for supplying a driving signal. The driving circuit of a conventional ink jet head has the same number of channels as the number of actuators in order to supply a driving signal individually to the separate electrode of each actuator. The driving circuit is designed so that a pulse signal is applied to an actuator that is to discharge ink while a pulse signal is not applied to an actuator that is not to discharge ink, thus turning the signal ON/OFF individually for each actuator.




With such an ink jet head, however, as the number of actuators increases, the number of channels of the driving circuit increases accordingly, whereby the cost for the driving circuit increases inevitably. With the recent increase in the number of nozzles provided in an ink jet head, the increase in the cost for the driving circuit is becoming non-negligible.




In view of this, an ink jet head employing a so-called “matrix driving” method has been suggested in the art, in which scanning electrodes and counter electrodes are arranged in a matrix pattern, as disclosed in Domestic Republication of PCT Publication WO99/12739. With an ink jet head employing a matrix driving method, the number of channels of the driving circuit can be reduced significantly, and thus the cost for the driving circuit can be reduced.




In an ink jet head employing a matrix driving method as described above, relay terminals connecting the driving circuit with the scanning electrodes, and relay terminals connecting the driving circuit with the counter electrodes, are localized at corners of the head assembly.




As a result, scanning electrode lead wires connecting the relay terminals with the scanning electrodes, and counter electrode lead wires connecting the relay terminals with the counter electrodes, are relatively long. Therefore, the lead wires have relatively high electric resistances.




Moreover, the scanning electrode lead wires and the counter electrode lead wires have different lengths for different scanning electrodes or different counter electrodes. Therefore, signals supplied to different electrodes vary slightly from one another, whereby different nozzles are likely to have varied levels of ink discharging performance. As a result, the recording precision is not sufficiently high. Moreover, while it is necessary, with a matrix driving method, that signals to be applied to the scanning electrodes (hereinafter referred to as “scanning signals”) and signals to be applied to the counter electrode (hereinafter referred to as “recording signals”) need to be precisely synchronized with each other, it is difficult to achieve precise synchronization if signals supplied to different electrodes vary from one another.




Some ink jet heads use a plurality of types of ink. For example, an ink jet head for forming a color image uses a plurality of colors of ink. In such an ink jet head, a plurality of actuators are provided to form a column of actuators for each color. With a conventional ink jet head of this type, the driving circuit supplies the same driving signal to actuators of the actuator columns for all colors.




However, properties of ink such as the viscosity vary among different types of ink. Therefore, even if the same driving signal is applied, the difference in the type of ink results in a difference in the ink discharging performance.




In view of this, in the prior art, types of ink are chosen, or the physical properties of different types of ink are adjusted, so that the ink discharging characteristics are made uniform among the different types of ink. However, this imposes a certain limitation on the types of ink that can be used.




Another way is to adjust a driving signal for each type of ink. However, with such an ink jet head, as disclosed in Japanese Laid-Open Patent Publication No. 2001-162794, the configuration of the driving circuit may become complicated, leading to other problems such as an increase in the cost for the driving circuit and a decrease in the reliability in controlling the ink discharge.




Note that these problems occur not only when a plurality of types of ink are used, but also when there are variations in the actuator characteristics or the pressure chamber size among different actuator columns.




SUMMARY OF THE INVENTION




The present invention has been made in view of the above. An object of the present invention is to shorten a lead wire connecting a relay terminal with an electrode. Another object of the present invention is to suppress the variations among signals supplied to different electrodes, thereby improving the ink discharging performance. Still another object of the present invention is to precisely synchronize the scanning signal with the recording signal. Yet another object of the present invention is to provide a technique that allows easy adjustment of a driving signal for each column without complicating the configuration of the driving circuit.




An ink jet head of the present invention includes: a head assembly provided with a plurality of nozzles and a plurality of pressure chambers storing ink therein and communicated respectively to the nozzles; actuators each associated with one of the pressure chambers and each including a piezoelectric element, a scanning electrode provided on one side of the piezoelectric element, and a recording electrode provided on the other side of the piezoelectric element, wherein the actuators are arranged in a matrix pattern of n rows by m columns (where n and m are natural numbers equal to or greater than two) in terms of electrical circuit, with the recording electrodes of each row being electrically connected to one another, and the scanning electrodes of each column being electrically connected to one another; and a driving circuit for supplying a scanning signal to the scanning electrodes for each column, while supplying a recording signal to each row of the recording electrodes in synchronization with the scanning signal, wherein: the actuators are geometrically arranged in n rows by m columns on the head assembly; a relay terminal, extending in a vertical direction, is provided in at least one inter-column space between vertical columns of the actuators on the head assembly for relaying signals from the driving circuit to the recording electrodes and the scanning electrodes; and the recording electrodes and the scanning electrodes are connected to the relay terminal via lead wires extending in a horizontal direction.




In this ink jet head, the relay terminal extends in the vertical direction, and the lead wires connecting the relay terminal with the recording electrodes and the scanning electrodes extend in the horizontal direction, whereby it is not necessary to extend the lead wires in a complicated pattern, e.g., a meandering pattern, and it is thus possible to reduce the length of the lead wires. Moreover, since the relay terminal is provided in an inter-column space between actuator columns, the distance between the relay terminal and the actuators is reduced, whereby the length of the lead wires can be reduced accordingly.




It is preferred that m is an even number; and the relay terminal is provided in a central inter-column space between the actuators.




This allows for a further reduction of the length of the lead wires. Moreover, the arrangement pattern of the lead wires is left-right symmetrical with respect to the relay terminal, thereby reducing variations between signals supplied to the electrodes of the left-side actuators and those supplied to the electrodes of the right-side actuators, and thus suppressing variations in the ink discharging performance. Moreover, the scanning signal and the recording signal can be synchronized with each other more precisely.




Another ink jet head of the present invention includes: the head assembly; the actuators; and the driving circuit, wherein: a first relay terminal and a second relay terminal, both extending in a vertical direction, for relaying signals from the driving circuit to the recording electrodes and the scanning electrodes are provided on a left side and a right side, respectively, of an area on the head assembly where the actuators are arranged; and the recording electrodes and the scanning electrodes are connected to the relay terminals via lead wires extending in a horizontal direction.




Also in this ink jet head, the relay terminals extend in the vertical direction, and the lead wires connecting the relay terminals with the recording electrodes and the scanning electrodes extend in the horizontal direction, whereby it is not necessary to extend the lead wires in a complicated pattern, e.g., a meandering pattern, and it is thus possible to reduce the length of the lead wires. Moreover, the relay terminal is divided into two relay terminals, which are provided on the left side and the right side of the area where the actuators are arranged, whereby the distance between each relay terminal and the actuators associated with the relay terminal is reduced, whereby the length of the lead wires can be reduced accordingly.




It is preferred that m is an even number; the recording electrodes and the scanning electrodes of the actuators on the left side are connected to the first relay terminal; and the recording electrodes and the scanning electrodes of the actuators on the right side are connected to the second relay terminal.




This allows for a further reduction of the length of the lead wires. Moreover, the arrangement pattern of the lead wires is left-right symmetrical, thereby reducing variations between signals supplied to the electrodes of the left-side actuators and those supplied to the electrodes of the right-side actuators, and thus suppressing variations in the ink discharging performance. Moreover, the scanning signal and the recording signal can be synchronized with each other more precisely.




It is preferred that a difference in time constant between actuators belonging to different vertical columns is set to be 0.1 μs or less.




In one embodiment, an actuator that is geometrically located along a p


th


row and a q


th


column (where p is a natural number of 1 to n, and q is a natural number of 1 to m) is located along the p


th


row and the q


th


column in terms of electrical circuit.




In this ink jet head, the arrangement pattern of the actuators in terms of electrical circuit coincides with the geometric arrangement pattern thereof




In one embodiment, actuators that are geometrically adjacent to each other in the vertical direction belong to different columns in terms of electrical circuit.




The scanning signal is supplied separately for each column, and the scanning signal will not be supplied simultaneously to actuators belonging to different columns. Therefore, with this ink jet head, actuators that are geometrically adjacent to each other in the vertical direction will not be driven at the same time. Thus, it is possible to prevent crosstalk between actuators that are adjacent to each other in the vertical direction, thereby improving the ink discharging performance.




In one embodiment, actuators that are geometrically adjacent to each other in the horizontal direction belong to different columns in terms of electrical circuit.




In this way, it is possible to prevent crosstalk between actuators that are adjacent to each other in the horizontal direction, thereby improving the ink discharging performance.




In one embodiment, actuators that are geometrically adjacent to each other in the vertical direction and those that are geometrically adjacent to each other in the horizontal direction belong to different columns in terms of electrical circuit.




In this way, it is possible to prevent crosstalk between actuators that are adjacent to each other in the vertical direction and those that are adjacent to each other in the horizontal direction, thereby improving ink discharging performance.




In one embodiment, a driving signal obtained by combining the recording signal with the scanning signal varies among at least two or more actuator columns.




In this way, the voltage of the driving signal can be adjusted for each column, and it is possible to control the ink discharge for each column according to the actuator characteristics, the ink characteristics, etc., of the column.




In one embodiment, a voltage of the scanning signal is equal among different actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.




In one embodiment, a voltage of the recording signal is equal among different actuator columns; and a voltage of the scanning signal varies among at least two or more actuator columns.




In one embodiment, a voltage of the scanning signal varies among at least two or more actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.




In one embodiment, when ink is to be discharged, a driving signal obtained by combining the recording signal with the scanning signal includes an ink discharging pulse signal for driving an actuator so as to discharge ink and an auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged, and when ink is not to be discharged, the driving signal includes the auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged.




Thus, by driving an actuator to such a degree that ink is not discharged by using the auxiliary pulse signal, it is possible to, for example, suppress the residual vibration after ink is discharged, or suppress an increase in the viscosity of ink in the nozzle.




In one embodiment, a voltage of the auxiliary pulse signal varies among at least two or more actuator columns.




In this way, the voltage of the auxiliary pulse signal can be adjusted for each actuator column, and it is possible to supply the auxiliary pulse signal for each column according to the actuator characteristics, the ink characteristics, etc., of the column.




In one embodiment, the ink discharging pulse signal is included in the recording signal; and the auxiliary pulse signal is included in the scanning signal.




In this way, with respect to the production of the driving signal, the recording signal and the scanning signal can be simplified.




It is preferred that the driving circuit supplies, prior to a recording operation, a preliminary pulse signal for driving an actuator to such a degree that ink is not discharged to all actuators.




Before a recording operation, ink in a nozzle may be dry and have an increased viscosity. If the viscosity of ink in a nozzle is high, a false discharge of ink may occur through the nozzle. However, with this ink jet head, the preliminary pulse signal is supplied prior to the recording operation, thereby stirring ink in the nozzle. Therefore, a portion of ink of a high viscosity near the exit of a nozzle is mixed with a portion of ink of a low viscosity inside the nozzle, thereby suppressing the increase in the viscosity of ink. Thus, it is possible to prevent the false discharge of ink at the start of a recording operation.




In one embodiment, when a small ink droplet is to be discharged, a driving signal obtained by combining the recording signal with the scanning signal includes a first pulse signal, and when a large ink droplet is to be discharged, the driving signal includes two or more pulse signals produced after the first pulse signal.




In this way, a small ink droplet is discharged when a single pulse signal is supplied, and a large ink droplet is discharged when a plurality of pulse signals are supplied. A large ink droplet is discharged by a so-called “multi-pulse” driving method. This allows for a multi-gray-level recording operation. In a case where a small ink droplet and a large ink droplet are discharged successively, the first pulse signal for discharging a small ink droplet is supplied after the supply of a plurality of pulse signals for discharging a large ink droplet in the preceding cycle. If the plurality of pulse signals and the first pulse signal are discharged successively, the discharge of a small ink droplet is likely to be influenced by the residual vibration of the actuator from the discharge of a large ink droplet. However, with this ink jet head, the scanning signal is supplied separately for each column, whereby there is a certain time interval corresponding to the number of actuator columns between the discharge of a large ink droplet and the discharge of a small ink droplet. Therefore, the discharge of a small ink droplet after the discharge of a large ink droplet is less likely to be influenced by the residual vibration and can be done stably.




In one embodiment, the n rows by m columns of actuators are geometrically arranged on the head assembly so that at least actuators of vertical columns that are adjacent to each other, among m vertical columns each including n actuators arranged in the vertical direction, are shifted from each other with respect to the vertical direction.




In one embodiment, the actuators are geometrically arranged in a staggered pattern on the head assembly.




Still another ink jet head of the present invention includes: the head assembly; the actuators; the driving circuit, wherein a voltage of a driving signal obtained by combining the scanning signal with the recording signal varies among at least two or more actuator columns.




In this way, the driving signal is obtained by combining the scanning signal with the recording signal, whereby it is no longer necessary to produce a plurality of driving signals for different actuators. Therefore, without complicating the driving circuit, the voltage of the driving signal can be adjusted for each actuator column, and it is possible to easily supply the driving signal for each column according to the actuator characteristics, the ink characteristics, etc., of the column.




In one embodiment, a voltage of the scanning signal is equal among different actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.




In one embodiment, a voltage of the recording signal is equal among different actuator columns; and a voltage of the scanning signal varies among at least two or more actuator columns.




In one embodiment, a voltage of the scanning signal varies among at least two or more actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.




In one embodiment, when ink is to be discharged, the driving signal includes an ink discharging pulse signal for driving an actuator so as to discharge ink and an auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged, and when ink is not to be discharged, the driving signal includes the auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged; and a voltage of the ink discharging pulse signal varies among at least two or more actuator columns.




Thus, by driving an actuator to such a degree that ink is not discharged by using the auxiliary pulse signal, it is possible to, for example, suppress the residual vibration after ink is discharged, or suppress an increase in the viscosity of ink in the nozzle. By adjusting the voltage of the ink discharging pulse signal for each actuator column, it is possible to discharge ink for each column according to the actuator characteristics, the ink characteristics, etc., of the column.




In one embodiment, when ink is to be discharged, the driving signal includes an ink discharging pulse signal for driving an actuator so as to discharge ink and an auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged, and when ink is not to be discharged, the driving signal includes the auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged; and a voltage of the auxiliary pulse signal varies among at least two or more actuator columns.




Thus, the auxiliary pulse signal provides auxiliary driving of an actuator such that ink is not discharged. As a result, it is possible to, for example, suppress the residual vibration after ink is discharged, or suppress an increase in the viscosity of ink in the nozzle. By adjusting the voltage of the auxiliary pulse signal for each actuator column, it is possible to provide auxiliary driving for each column according to the actuator characteristics, the ink characteristics, etc., of the column.




In one embodiment, the ink discharging pulse signal is included in the recording signal; and the auxiliary pulse signal is included in the scanning signal.




In this way, with respect to the production of the driving signal, the recording signal and the scanning signal can be simplified.




In one embodiment, when a small ink droplet is to be discharged, the ink discharging pulse signal includes a first pulse signal, and when a large ink droplet is to be discharged, the ink discharging pulse signal includes two or more following pulse signals produced after the first pulse signal.




In one embodiment, the driving circuit supplies, prior to a recording operation, a preliminary pulse signal for driving an actuator to such a degree that ink is not discharged to all actuators.




An ink jet recording apparatus of the present invention includes: any of the ink jet heads set forth above; and movement means for relatively moving the ink jet head and a recording medium with respect to each other.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view illustrating an important part of an ink jet printer.





FIG. 2

is a plan view illustrating an ink jet head according to Embodiment 1.





FIG. 3

is a cross-sectional view taken along line III—III of FIG.


2


.





FIG. 4

is a cross-sectional view taken along line IV—IV of FIG.


2


.





FIG. 5A

to

FIG. 5E

are waveform diagrams illustrating signals used in Embodiment 1.





FIG. 6

is a plan view illustrating an ink jet head according to a comparative example.





FIG. 7

is a plan view illustrating an ink jet head according to Embodiment 2.





FIG. 8A

to

FIG. 8G

are waveform diagrams illustrating signals used in Embodiment 2.





FIG. 9A

is a bottom view illustrating an ink jet head according to a comparative example of Embodiment 3, and

FIG. 9B

is a bottom view illustrating an ink jet head according to Embodiment 3.





FIG. 10

is a plan view illustrating an ink jet head according to Embodiment 4.





FIG. 11

is a plan view illustrating an ink jet head according to Embodiment 4.





FIG. 12

is a plan view illustrating an ink jet head according to Embodiment 4.





FIG. 13A

to

FIG. 13E

are waveform diagrams illustrating signals used in Embodiment 5.





FIG. 14A

to

FIG. 14E

are waveform diagrams illustrating signals used in Embodiment 5.





FIG. 15

is a plan view illustrating an ink jet head according to Embodiment 6.





FIG. 16A

to

FIG. 16H

are waveform diagrams illustrating signals used in Embodiment 6.





FIG. 17

is a plan view illustrating an ink jet head according to Embodiment 6.





FIG. 18A

to

FIG. 18D

are waveform diagrams illustrating signals used in Embodiment 7.





FIG. 19A

to

FIG. 19D

are waveform diagrams illustrating signals used in Embodiment 7.





FIG. 20A

to

FIG. 20E

are waveform diagrams illustrating signals used in Embodiment 7.





FIG. 21A

to

FIG. 21E

are waveform diagrams illustrating signals used in Embodiment 7.





FIG. 22A

to

FIG. 22D

are waveform diagrams illustrating signals used in Embodiment 7.




FIG.


23


A and

FIG. 23B

are waveform diagrams illustrating signals used in Embodiment 7.




FIG.


24


A and

FIG. 24B

are waveform diagrams illustrating signals used in Embodiment 8.





FIG. 25

is a plan view illustrating an ink jet head according to Embodiment 9.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




Embodiments of the present invention will now be described with reference to the drawings.




Embodiment 1





FIG. 1

schematically illustrates an important part of an ink jet printer


31


including an ink jet head


30


according to the present embodiment. The ink jet head


30


is attached to a carriage


32


that is provided with a carriage motor (not shown). The carriage


32


is reciprocated by the carriage motor in the direction labeled “L


1


” in the figure while being guided by a carriage shaft


33


extending in the direction L


1


. Thus, the ink jet head


30


is reciprocated in the direction L


1


.




Recording paper


34


is sandwiched between two carrier rollers


35


, which are rotated by a carrier motor (not shown), and is carried by the carrier motor and the carrier rollers


35


in the direction labeled “L


2


” in the figure, which is perpendicular to the direction L


1


.




The carriage


32


and the carriage motor together form movement means for the direction L


1


. The carrier rollers


35


and the carrier motor together form movement means for the direction L


2


.




Note however that the recording apparatus of the present invention is not limited to the printer


31


as described above, but the present invention may alternatively be applied to other types of printers. Moreover, the recording apparatus of the present invention is not limited to a printer, but may alternatively be any other type of recording apparatus having an ink jet head therein, such as a copier or a facsimile. The recording medium is not limited to the recording paper


34


, but may alternatively be any other type of medium such as a plastic film.




As illustrated in

FIG. 2

to

FIG. 4

, the ink jet head


30


includes a nozzle plate


18


in which a plurality of nozzles


17


are provided, an ink channel substrate


11


in which the same number of pressure chambers


10


as the number of nozzles


17


are provided, a vibration plate


12


, scanning electrodes


13


extending over the pressure chambers


10


, a piezoelectric element


14


made of PZT, and recording electrodes


15


placed respectively over the pressure chambers


10


, which are layered in this order. The nozzle plate


18


and the ink channel substrate


11


together form a head assembly


19


, and the vibration plate


12


, the scanning electrode


13


, the piezoelectric element


14


and the recording electrode


15


together form an actuator


20


.




The pressure chambers


10


are provided in two columns that are next to each other in the horizontal direction (the direction L


1


), and a large number (e.g., on the order of 10 to 1000) of pressure chambers


10


are provided along each column extending in the vertical direction (the direction L


2


). Note however that in this and other subsequent embodiments, only seven pressure chambers


10


are shown to be present in the vertical direction for ease of understanding. As illustrated in

FIG. 3

, each pressure chamber


10


has an elongate shape extending in the horizontal direction. Each pressure chamber


10


is communicated to the nozzle


17


in the nozzle plate


18


near one side of the pressure chamber


10


that is closer to the center of the head assembly


19


in the horizontal direction.




The actuator


20


is a so-called “flexural vibration type” actuator. In the actuator


20


, when the scanning electrode


13


and the recording electrode


15


are both turned ON, a voltage is applied across the piezoelectric element


14


, whereby the piezoelectric element


14


expands/contracts in the longitudinal direction. The expansion/contraction of the piezoelectric element


14


is restricted by the vibration plate


12


, whereby the entire actuator


20


undergoes flexural deformation to increase/decrease the volume of the pressure chamber


10


. As the volume of the pressure chamber


10


increases/decreases, the ink pressure in the pressure chamber


10


increases/decreases, thereby discharging ink in the form of a droplet through the nozzle


17


.




As illustrated in

FIG. 2

, the actuators


20


are arranged in a pattern similar to that of the pressure chambers


10


. Specifically, m (where m=2) actuators


20


are provided in the horizontal direction, and n (where n is on the order of 10 to 1000) actuators


20


provided in the vertical direction. For actuators that are adjacent to each other in the horizontal direction, the recording electrodes


15


are connected to each other via a lead wire


16


extending in the horizontal direction. Actuators whose recording electrodes


15


are connected to each other form an “actuator row” in terms of electrical circuit. Actuators that are adjacent to each other in the vertical direction share an integrated scanning electrode


13


. Actuators that share an integrated scanning electrode


13


form an “actuator column” in terms of electrical circuit. In the present embodiment, the scanning electrodes


13


include a first scanning electrode


13


A and a second scanning electrode


13


B, which are next to each other in the horizontal direction. The first scanning electrode


13


A and the second scanning electrode


13


B each form a part of a first actuator column


20


A and a second actuator column


20


B, respectively.




Thus, in the present embodiment, actuators are arranged in a matrix pattern of n rows by m columns both in terms of electrical circuit and geometrically. An actuator that is geometrically located along the p


th


row and the q


th


column (where p is a natural number of 1 to n, and q is a natural number of 1 to m) is located along the p


th


row and the q


th


column also in terms of electrical circuit. Thus, in the present embodiment, each actuator row includes m actuators


20


arranged in the horizontal direction. Each of the actuator columns


20


A and


20


B includes n actuators


20


arranged in the vertical direction.




The first scanning electrode


13


A is formed in a rectangular shape as viewed from above and is facing all of the recording electrodes


15


of the first actuator column


20


A, and the second scanning electrode


13


B is formed in a rectangular shape as viewed from above and is facing all of the recording electrodes


15


of the second actuator column


20


B. Note however that the scanning electrodes


13


A and


13


B are not limited to a rectangular shape as viewed from above or any other particular shape as long as they are facing the recording electrodes


15


of the actuator columns


20


A and


20


B, respectively.




As illustrated in

FIG. 2

, the recording electrode


15


is formed in an elongate shape extending in the horizontal direction, as is the pressure chamber


10


, and is slightly smaller than the pressure chamber


10


.




As illustrated in

FIG. 3

, the nozzles


17


that are next to each other in the horizontal direction are spaced apart from each other by a certain interval therebetween for avoiding interference between the nozzles


17


. Accordingly, the first actuator column


20


A and the second actuator column


20


B are also spaced apart from each other by a certain interval therebetween. In the present embodiment, a relay terminal section


21


is formed in the inter-column space between the actuator columns


20


A and


20


B so as to make use of the space therebetween. Thus, the relay terminal section


21


is provided in a central portion of the head assembly


19


with respect to the horizontal direction.




The relay terminal section


21


is made of an anisotropic conductive sheet (ACF) having an elongate rectangular shape, as viewed from above, extending in the vertical direction. The relay terminal section


21


is a relay terminal connected to an FPC (flexible printed circuit board)


22


, which is connected to a driving circuit


26


. Note that the FPC


22


is not shown in

FIG. 2

for ease of understanding. As illustrated in

FIG. 4

, the relay terminal section


21


are provided over the lead wire


16


, extending from the recording electrode


15


, and lead wires


25


A and


25


B, extending from the scanning electrodes


13


A and


13


B, respectively, so as to cover the lead wires


16


,


25


A and


25


B. The FPC


22


is connected to the upper side of the relay terminal section


21


.




The driving circuit


26


supplies scanning signals to the scanning electrodes


13


A and


13


B, and recording signals to the recording electrodes


15


. A scanning signal and a recording signal are superimposed on each other to form a driving signal. Next, referring to

FIG. 5A

to

FIG. 5E

, various signals supplied from the driving circuit


26


will be described.




As illustrated in

FIG. 5A

, the scanning electrodes


13


are periodically turned ON/OFF at cycle T, so that the scanning electrode


13


A of the first column and the scanning electrode


13


B of the second column are turned ON/OFF alternately. As illustrated in

FIG. 5C

, the scanning signal is a signal of a constant potential. As a result, the scanning signal is turned ON while the scanning electrode


13


is ON, and turned OFF while the scanning electrode


13


is OFF.




As illustrated in

FIG. 5B

, the recording signal is a pulse signal that is turned ON when ink is discharged, and turned OFF when ink is not discharged. A voltage is applied across the piezoelectric element


14


of the actuator


20


only when the scanning signal and the recording signal are both ON. Thus, ink is discharged when both of the signals are ON, and is not discharged when one or both of the signals is/are OFF. As described above, in the present ink jet head


30


, the ink discharge is controlled by the combination of the scanning signal and the recording signal.




In the present ink jet head


30


, the scanning electrodes


13


and the recording electrodes


15


for driving the piezoelectric elements


14


of the actuators


20


are arranged in a matrix pattern of n rows by m columns, whereby the number of channels of the driving circuit


26


can be reduced. Specifically, the number of channels is reduced from n*m to n+m. Thus, the cost for the driving circuit


26


can be reduced.




Since the relay terminal section


21


is provided in the inter-column space between the first actuator column


20


A and the second actuator column


20


B, it is possible to reduce the distance between the relay terminal section


21


and the actuator columns


20


A and


20


B. Therefore, the lead wires


16


,


25


A and


25


B can be provided in shorter lengths, and thus the speed of signal transmission can be increased. Moreover, the electrical resistances of the lead wires


16


,


25


A and


25


B can be reduced.




In addition, since the distance between the relay terminal section


21


and the first actuator column


20


A is equal to the distance between the relay terminal section


21


and the second actuator column


20


B, the actuators of the actuator column


20


A and those of the actuator column


20


B have an equal electrical resistance R and an equal electrostatic capacity C, whereby the gradient of the signal waveform is equalized therebetween. Therefore, the ink discharging performance is unlikely to vary between the actuator columns. Moreover, it is likely that the scanning signal and the recording signal can be reliably synchronized with each other. Thus, the ink discharging performance is improved.




For example, if the relay terminal section


21


is placed on either side, as illustrated in

FIG. 6

, the difference in time constant CR between the first actuator column


20


A and the second actuator column


20


B increases. In the illustrated arrangement, the line resistance between the relay terminal section


21


and a recording electrode


15


B of the second actuator column


20


B and the line resistance between the relay terminal section


21


and a recording electrode


15


A of the first actuator column


20


A are different from each other by the resistance of the recording electrode


15


A and a wire L


11


. Then, the difference in time constant CR is 0.1 μs, assuming that the electrostatic capacity of the actuator


20


is 150 pF, the recording electrode


15


A and the wire L


11


are made of platinum whose volume resistivity is 1.05×10


−5


Ω.cm, the recording electrode


15


A has a thickness of 0.05 μm, a width of 25 μm and a length of 2000 μm, and the wire L


11


has a thickness of 0.05 μm, a width of 10 μm and a length of 2400 μm. Therefore, where a pulse signal is input as the recording signal, the gradient of the rising/falling edge of an actual pulse signal supplied to the recording electrode


15


B is smaller as compared to the recording electrode


15


A by the difference in time constant CR.




In order to examine the relationship between a difference in time constant CR and variations in the ink discharging performance, an experiment was conducted where two different pulse signals having different rising/falling edge gradients were applied to the same actuator. This experiment simulates a situation where the same pulse signal is applied to two different actuators having different time constants. The experiment revealed that for an actuator that discharges ink droplets with a drop size of 5 pl and an ink discharging velocity of 7.1 m/s, if the time constant increases by 0.1 μs, the drop size and the ink discharging velocity changed from the original values to 4.9 pl and 7 m/s, respectively. The change in drop size was 2%. It is believed that a desirable level of ink discharging performance can be normally maintained if the error in drop size is within 2%. Therefore, it is inferred that a desirable level of ink discharging performance can be obtained by appropriately arranging actuators and wires so that the difference in time constant is 0.1 μs or less.




Embodiment 2




The ink jet head


30


according to Embodiment 2 includes four actuator columns with two relay terminal sections provided on opposite sides of the array of the four actuator columns, as illustrated in FIG.


7


.




The first to fourth actuator columns


20


A to


20


D extend in the vertical direction and each include a plurality of actuators


20


, and the actuator columns


20


A to


20


D are arranged next to each other in the horizontal direction. A first relay terminal section


21


A is provided on the left side of the first actuator column


20


A, and a second relay terminal section


21


B is provided on the right side of the fourth actuator column


20


D.




Each recording electrode


15


of the first actuator column


20


A is connected to the first relay terminal section


21


A via the lead wire


16


extending in the horizontal direction. Moreover, the recording electrode


15


of the first actuator column


20


A and the recording electrode


15


of the second actuator column


20


B that belong to the same row are connected to each other via the lead wire


16


. Similarly, the recording electrode


15


of a third actuator column


20


C and the recording electrode


15


of a fourth actuator column


20


D that belong to the same row are connected to each other via the lead wire


16


. Each recording electrode


15


of the fourth actuator column


20


D is connected to the second relay terminal section


21


B via the lead wire


16


.




The scanning electrode


13


A of the first actuator column


20


A and the scanning electrode


13


B of the second actuator column


20


B are each connected to the first relay terminal section


21


A via a lead wire


25


extending in the horizontal direction. A scanning electrode


13


C of the third actuator column


20


C and a scanning electrode


13


D of the fourth actuator column


20


D are each connected to the second relay terminal section


21


B via the lead wire


25


extending in the horizontal direction.




Next, referring to

FIG. 8A

to

FIG. 8G

, the scanning signal and the recording signal supplied from the driving circuit


26


will be described.




As illustrated in

FIG. 8A

, the scanning electrodes


13


are periodically turned ON/OFF at cycle T. The scanning electrode


13


A of the first column and the scanning electrode


13


C of the third column are turned ON/OFF synchronously, and the scanning electrode


13


B of the second column and the scanning electrode


13


D of the fourth column are turned ON/OFF synchronously. As illustrated in

FIG. 8C

, the scanning signal is a signal of a constant potential. As illustrated in

FIG. 8B

, the recording signal is a pulse signal that is turned ON when ink is discharged, and turned OFF when ink is not discharged. As in Embodiment 1, in the present embodiment, ink is discharged when both of the scanning signal and the recording signal are ON.




In Embodiment 2, the two relay terminal sections


21


A and


21


B are provided, wherein the scanning electrodes


13


and the recording electrodes


15


of the actuators


20


on the left side of the head assembly


19


are connected to the first relay terminal section


21


A on the left side, while the scanning electrodes


13


and the recording electrodes


15


of the actuators


20


on the right side are connected to the second relay terminal section


21


B on the right side. Therefore, as compared to a case where relay terminal sections are locally arranged on one side of the head assembly, the lead wires


16


and


25


for connecting the relay terminal sections


21


A and


21


B with the electrodes


13


and


15


can be provided in shorter lengths. Thus, as in Embodiment 1, the speed of signal transmission can be increased. Moreover, the electrical resistances of the lead wires


16


and


25


can be reduced, thereby stabilizing the ink discharging performance. Moreover, the variations in the ink discharging performance among the actuator columns


20


A to


20


D can be better suppressed.




Embodiment 3




In Embodiment 2, the relay terminal sections


21


A and


21


B are provided on opposite sides of the array of actuator columns. Alternatively, the relay terminal sections


21


A and


21


B may be provided in inter-column spaces between actuator columns.




In Embodiment 3, the first relay terminal section


21


A is provided between the first actuator column


20


A and the second actuator column


20


B, and the second relay terminal section


21


B is provided between the third actuator column


20


C and the fourth actuator column


20


D, as illustrated in FIG.


9


B.




Each of nozzles


17


A to


17


D is provided on one side of the pressure chamber


10


that is closer to the nearest relay terminal section in the horizontal direction. Specifically, the nozzle


17


A associated with the first actuator column


20


A is provided on one side of the pressure chamber


10


that is closer to the second actuator column


20


B, and the nozzle


17


B associated with the second actuator column


20


B is provided on one side of the pressure chamber


10


that is closer to the first actuator


20


A. Moreover, the nozzle


17


C associated with the third actuator column


20


C is provided on one side of the pressure chamber


10


that is closer to the fourth actuator column


20


D, and the nozzle


17


D associated with the fourth actuator column


20


D is provided on one side of the pressure chamber


10


that is closer to the third actuator column


20


C.




According to Embodiment 3, the lead wires


16


and


25


for connecting the relay terminal sections


21


A and


21


B with the electrodes


13


and


15


can be provided in even shorter lengths. Therefore, it is possible to further stabilize the ink discharging performance. Moreover, the variations in the ink discharging performance among the actuator columns


20


A to


20


D can be further suppressed.




Moreover, according to Embodiment 3, the distance between the nozzle


17


A associated with the first actuator column


20


A and the nozzle


17


B associated with the second actuator column


20


B, and the distance between the nozzle


17


C associated with the third actuator column


20


C and the nozzle


17


D associated with the fourth actuator column


20


D, are increased by the presence of the relay terminal sections


21


A and


21


B, respectively. Thus, a nozzle interval L


22


of the present embodiment is greater than a nozzle interval L


21


where the relay terminal sections


21


A and


21


B are provided on opposite sides of the array of actuator columns (see FIG.


9


A). Therefore, it is possible to prevent mixing of ink (e.g., mixing of colors) from occurring due to short nozzle intervals.




Note that in the present embodiment, the nozzles


17


A to


17


D are each provided on one side of the pressure chamber that is closer to the relay terminal section in the longitudinal direction. However, the ink jet head of the present invention is not limited to the present embodiment, and the nozzle position is not limited to any particular position.




Embodiment 4




In the ink jet head according to Embodiment 4, the arrangement pattern of the scanning electrodes is modified so as to prevent crosstalk from occurring between adjacent actuators.




As does the ink jet head of Embodiment 1, the ink jet head illustrated in

FIG. 10

includes n rows by 2 columns of actuators in terms of electrical circuit, with the relay terminal section


21


being geometrically arranged in the inter-column space in the middle between the actuator columns. However, unlike Embodiment 1, the first scanning electrode


13


A and the second scanning electrode


13


B are each formed in a comb-shaped pattern so that they mesh with each other on each side of the head assembly


19


. Thus, in terms of electrical circuit, actuators of the first column and those of the second column are arranged in an alternating pattern in the vertical direction. Two actuators of the same row and of the same column in terms of electrical circuit are arranged next to each other via the relay terminal section


21


therebetween in the horizontal direction.




Signals similar to those of Embodiment 1 are supplied from the driving circuit


26


. The scanning signal is applied alternately to the scanning electrodes


13


A of the first actuator column


20


A and the scanning electrodes


13


B of the second actuator column


20


B. Therefore, the scanning signal will not be applied simultaneously to the scanning electrodes


13


A and


13


B, whereby the actuators of the first actuator column


20


A and those of the second actuator column


20


B will not be activated at the same time. Thus, adjacent actuators (those that are adjacent to each other in the vertical direction in the illustrated example) will not be activated at the same time, thereby suppressing the occurrence of crosstalk, i.e., the ink discharge volume of one actuator being influenced by whether an adjacent actuator is being active/inactive.




The ink jet head illustrated in

FIG. 11

includes n rows by 2 columns of actuators in terms of electrical circuit, and two relay terminal sections


21


A and


21


B geometrically arranged at opposite ends of the head assembly


19


in the horizontal direction. The first scanning electrode


13


A and the second scanning electrode


13


B are each formed in a comb-shaped pattern so that they mesh with each other. In the present ink jet head, actuators of the same row in terms of electrical circuit are arranged next to each other in the vertical direction. Moreover, actuators arranged next to each other the horizontal direction belong to the same column in terms of electrical circuit. Each lead wire


16


extending from the relay terminal sections


21


A and


21


B diverges into two branches, which are connected respectively to the recording electrode


15


of one actuator


20


of the first actuator column and the recording electrode


15


of one actuator


20


of the second actuator column.




Also in the present ink jet head, adjacent actuators will not be activated at the same time, thereby suppressing the occurrence of crosstalk.




Moreover, in the present ink jet head, the layout density of lead wires on the relay terminal sections


21


A and


21


B is about one half of the layout density of actuators in the vertical direction. Therefore, even if the density of actuators is high, the circuit can be implemented easily.




The ink jet head illustrated in

FIG. 12

also includes n rows by 2 columns of actuators in terms of electrical circuit, and two relay terminal sections


21


A and


21


B geometrically arranged at opposite ends of the head assembly


19


in the horizontal direction. The first scanning electrode


13


A includes comb-shaped scanning electrodes


41


A and


42


A arranged on the left side and on the right side, and the second scanning electrode


13


B includes comb-shaped scanning electrodes


41


B and


42


B arranged on the left side and on the right side. The scanning electrode


41


A and the scanning electrode


41


B are arranged so that they mesh with each other. The scanning electrode


42


A and the scanning electrode


42


B are also arranged so that they mesh with each other.




Also in the present ink jet head, actuators of the first column and actuators of the second column are arranged alternately in the vertical direction. In addition, in the present ink jet head, an actuator of the first column and an actuator of the second column are adjacent to each other in the horizontal direction. Thus, actuators of the same row but of different columns in terms of electrical circuit are arranged next to each other in the horizontal direction.




In the present ink jet head, actuators adjacent to each other in the horizontal direction will not be activated at the same time, in addition to that actuators adjacent to each other in the vertical direction will not be activated at the same time, thereby further suppressing the occurrence of crosstalk.




Moreover, also in the present ink jet head, the layout density of lead wires on the relay terminal sections


21


A and


21


B is about one half of the layout density of actuators in the vertical direction. Therefore, even if the density of actuators is high, the circuit can be implemented easily.




Note that while the lead wire


25


A of the first scanning electrode


13


A and the lead wire


25


B of the second scanning electrode


13


B are both connected to the second relay terminal section


21


B in the present ink jet head, one or both of the lead wires


25


A and


25


B may alternatively be connected to the first relay terminal section


21


A.




According to the present embodiment, the occurrence of crosstalk is suppressed, whereby it is possible to further improve the ink discharging performance.




Embodiment 5




The ink jet head according to Embodiment 5 is similar to the ink jet head of Embodiment 1, except that the recording signal or the scanning signal is modified according to the characteristics of each actuator column.




In some cases, the amount of deformation of an actuator or the volume of a pressure chamber may vary among different columns, depending on the configuration of the ink jet head. Moreover, in a case where different types of ink are used for different columns, the characteristics of ink (e.g., the viscosity) may vary among different columns. In such a case, by adjusting signals to be supplied to actuators for each column, it is possible to suppress the variations in the ink discharging performance among different columns. Alternatively, it is possible to control the ink discharge in a more versatile manner by actively varying the ink discharge volume, etc., among different columns.




For example, in a case where the amount of deformation of the actuators of the first column is greater than that of the actuators of the second column, the ink discharge volume of the actuators of the first column is greater than that of the actuators of the second column, if driving signals of the same voltage are supplied to the actuators of both columns, thereby resulting in variations in the ink discharging performance. However, if the voltage applied to the actuators of the first column is set to be smaller than the voltage applied to the actuators of the second column so that the actuators of both columns are deformed by an equal amount, it is possible to suppress the variations in the ink discharging performance.




Thus, in the present embodiment, driving signals of different voltages are applied to actuators of different columns.




The ink jet head of the present embodiment has a configuration similar to that of Embodiment 1 (see

FIG. 1

to FIG.


4


). In the present embodiment, however, ink of the same type is stored in a plurality of pressure chambers


10


arranged in the vertical direction, whereas different types of ink are stored in the pressure chambers


10


on the left side and in the pressure chambers


10


on the right side.




As illustrated in

FIG. 13A

to

FIG. 13E

, the voltage of the recording signal applied to the recording electrodes


15


of the first column is different from that of the recording signal applied to the recording electrodes


15


of the second column, while the voltages of the scanning signals applied to these columns are the same. Specifically, the potential of the pulse supplied to the recording electrodes


15


of the first column is V


1


, and the potential of the pulse supplied to the recording electrodes


15


of the second column is V


2


(<V


1


). As a result, the voltage of the driving signal supplied to the actuators of the first column is V


1


, and that of the driving signal supplied to the actuators of the second column is V


2


. In such a case, the actuators of the first column deform by a greater amount than the actuators of the second column. Therefore, in a case where the ink of the first column is less easily discharged than the ink of the second column, for example, the variations in the ink discharge volume can be corrected by using such signals.




Alternatively, the voltage applied to the scanning signals of the first column may be higher than that applied to the scanning signals of the second column while applying recording signals of the same voltage to these columns, as illustrated in

FIG. 14A

to FIG.


14


E. Also in such a case, the voltage of the driving signal of the first column is higher than that of the driving signal of the second column.




Note that although not shown in the figures, the voltage of the driving signal can be varied between the columns alternatively by varying both the recording signal and the scanning signal between the columns.




According to the present embodiment, a driving signal is formed by the combination of a recording signal and a scanning signal so that the voltage of the driving signal is different for each column, whereby it is possible to adjust the amount of actuator deformation and the ink discharging performance for each column without complicating the configuration of the driving circuit. Therefore, with a simple configuration, it is possible to drive the actuators according to the ink characteristics and the actuator characteristics for each column.




Embodiment 6




Two actuator columns are provided in Embodiment 5. However, the number of actuator columns is not limited to two, but may alternatively be three or more.




For example, the number of actuator columns may be four, as in the ink jet head of Embodiment 2 (see FIG.


7


). Alternatively, an ink jet head may include four actuator columns as illustrated in

FIG. 15

, for example. In such an ink jet head, recording signals of two different potentials and scanning signals of two different potentials may be combined together to produce driving signals of a total of four different voltage levels. In the present embodiment, four columns of actuators and four columns of pressure chambers are provided.




A different type of ink is stored in the pressure chambers of each of the first to fourth columns. In the present embodiment, ink of a different color is stored in pressure chambers of each column, and a total of four colors of ink are stored in the entire head. Thus, the present ink jet head is capable of color recording.




In the ink jet head illustrated in

FIG. 15

, the scanning electrodes


13


A to


13


D of the first to fourth actuator columns


20


A to


20


D are each formed in a rectangular shape, as viewed from above, extending in the vertical direction, and the scanning electrodes


13


A to


13


D are arranged next to one another in the horizontal direction. The recording electrodes


15


of the first actuator column and the recording electrodes


15


of the second actuator column are connected to each other, and are connected to the first relay terminal section


21


A at the left end of the head assembly


19


via the lead wires


16


. The recording electrodes


15


of the third actuator column and the recording electrodes


15


of the fourth actuator column are connected to each other, and are connected to the second relay terminal section


21


B at the right end of the head assembly


19


via the lead wires


16


.




The scanning electrode


13


A of the first actuator column is connected to the first relay terminal section


21


A via the lead wire


25


A. The scanning electrode


13


B of the second actuator column is connected to the second relay terminal section


21


B via the lead wire


25


B. The scanning electrode


13


C of the third actuator column is connected to the first relay terminal section


21


A via a lead wire


25


C. The scanning electrode


13


D of the fourth actuator column is connected to the second relay terminal section


21


B via a lead wire


25


D.




In the present embodiment, signals as illustrated in

FIG. 16A

to

FIG. 16H

are supplied to the actuators. Specifically, the scanning electrodes


13


A to


13


D are controlled so that a state where the first and third columns are ON while the second and fourth columns are OFF alternates with another state where the first and third columns are OFF while the second and fourth columns are ON.




The scanning signal for the first and second columns is a signal of a constant potential (=0). On the other hand, the scanning signal for the third and fourth columns is a pulse signal in which a potential V (≠0) appears repeatedly at cycle T.




The recording signal includes a first pulse of a first potential V


1


and a second pulse of a second potential V


2


(<V


1


), and the first pulse and the second pulse are repeated in an alternating manner in synchronization with the scanning electrode being turned ON/OFF.




By combining the scanning signal and the recording signal, the voltages of the driving signals of the actuators for the first, second, third and fourth columns are V


1


, V


2


, V+V


1


and V+V


2


, respectively.




In the present embodiment, driving signals of a total of four different voltage levels are produced by combining the recording signal having two different potentials with the scanning signal having two different potentials. Also in the present embodiment, it is possible to drive the actuators according to the ink characteristics and the actuator characteristics for each column without complicating the configuration of the driving circuit.




According to the present embodiment, it is possible to adjust the voltage of the driving signal for each column according to the actuator characteristics of the column. Therefore, it is possible to correct the driving signal according to the ink discharging performance for each column, thereby suppressing the variations in the ink discharging performance. Moreover, it is possible to vary the ink discharging characteristics among different columns, thereby realizing a more complicated ink discharge control.




As an alternative example, the driving signal as described above may be used with the ink jet head of Embodiment 3 (see FIG.


9


B). In the present example, a black (BK) pigment ink is stored in the pressure chambers associated with the first actuator column


20


A, a cyan (C) dye ink is stored in the pressure chambers associated with the second actuator column


20


B, a magenta (M) dye ink is stored in the pressure chambers associated with the third actuator column


20


C, and a yellow (Y) dye ink is stored in the pressure chambers associated with the fourth actuator column


20


D. Thus, a pigment ink and dye inks are used together in the same head.




A pigment ink and a dye ink differ from each other in how easily they seep into a recording medium. Therefore, in a case where paper is used as the recording medium, for example, the diameter of the ink dot formed on the recording paper is smaller with a pigment ink than with a dye ink even if the drop size of the ink droplet to be discharged is the same. Therefore, in order to realize the same dot diameter among the various colors, the drop size of the black ink needs to be larger than those of the inks of the other colors.




Nevertheless, according to the present embodiment, it is possible to easily vary the driving signal among different actuator columns by adjusting the combination of the scanning signal and the recording signal. Therefore, it is easy to make the drop size of the black ink larger than those of the inks of the other colors.




The ink jet head illustrated in

FIG. 17

includes two actuator columns of different ink discharge volumes for each color. In the ink jet head, the actuator blocks for discharging inks of different colors of black (BK), cyan (C), magenta (M) and yellow (Y) each include a first actuator column


120


and a second actuator column


220


. A relay terminal section


121


is provided for each color and is located between the first actuator column


120


and the second actuator column


220


.




The volume of each pressure chamber


115


associated with the first actuator column


120


is different from that of each pressure chamber


215


associated with the second actuator column


220


. In this example, the volume of each pressure chamber


115


is larger than that of the pressure chamber


215


. Note that also actuators of different columns have different sizes.




In a case where there are pressure chambers of different volumes as described above, the natural frequency of the vibration system of an actuator (the entire vibration system including the ink) takes a different value for each column. Therefore, it is difficult to obtain a desirable level of ink discharging performance by supplying the same driving signal for different columns. Nevertheless, according to the present embodiment, it is possible to easily vary the driving signal among different actuator columns by adjusting the combination of the scanning signal and the recording signal. Therefore, even if the volume of a pressure chamber varies among two actuator columns, it is relatively easy to adjust the driving signal so that the two actuator columns have the same level of ink discharging performance.




Note that both the size of the pressure chamber and the size of the actuator are varied between two columns in the embodiment described above. Alternatively, only one of the size of the pressure chamber and the size of the actuator may be varied between two columns. Also in such a case, it is easy to adjust the driving signal so that the two actuator columns have the same level of ink discharging performance.




Embodiment 7




Embodiment 7 is similar to Embodiment 1 except that the driving signal is modified. As illustrated in

FIG. 18A

to

FIG. 18D

, the driving signal of Embodiment 7 includes an ink discharging pulse signal P


1


that causes ink to be discharged and an auxiliary pulse signal P


2


that does not cause ink to be discharged.




The auxiliary pulse signal P


2


is a signal that deforms an actuator to such a degree that ink is not discharged, and is used for reducing the meniscus vibration in the nozzle after ink is discharged therethrough, for preventing the viscosity of ink in the nozzle from increasing, etc. The ink discharging pulse signal P


1


is applied only in particular ones of a plurality of cycles in which ink is to be discharged, whereas the auxiliary pulse signal P


2


is a signal that is applied in every cycle regardless of whether ink is to be discharged.




With the driving signal illustrated in

FIG. 18A

to

FIG. 18D

, for example, where the scanning signal is applied to the actuators of the first column in the first cycle and the third cycle, the ink discharging pulse signal P


1


and the auxiliary pulse signal P


2


are applied in the first cycle in which ink is to be discharged, whereas only the auxiliary pulse signal P


2


is applied in the third cycle in which ink is not to be discharged.




In order to produce such a driving signal, the recording signal may include the ink discharging pulse signal P


1


and the auxiliary pulse signal P


2


while the scanning signal is at a constant potential, as illustrated in

FIG. 18A

to FIG.


18


D.




Alternatively, the voltage of the ink discharging pulse signal P


1


may be varied between actuator columns, as illustrated in

FIG. 19A

to FIG.


19


D.




Alternatively, the ink discharging pulse signal P


1


may be included in the recording signal while the auxiliary pulse signal P


2


is included in the scanning signal, as illustrated in

FIG. 20A

to

FIG. 20E. A

predetermined driving signal can be obtained by superimposing such a recording signal and such a scanning signal on each other. Note that the auxiliary pulse signal P


2


may be supplied to the actuators of the first column while the auxiliary pulse signal P


2


is not supplied to the actuators of the second column.




Also in such a case, the voltage of the ink discharging pulse signal P


1


may be varied between actuator columns, as illustrated in

FIG. 21A

to FIG.


21


E.




Alternatively, the potential of the auxiliary pulse signal P


2


of the driving signal may be varied between actuator columns, as illustrated in

FIG. 22A

to FIG.


22


D. By setting the potential of the auxiliary pulse signal P


2


for each column as described above, it is possible to vary the amount of actuator deformation for each column according to the actuator characteristics or the ink characteristics of the column. For example, it is possible to freely set how much an ink is stirred according to the viscosity of the ink by, for example, setting the potential of the auxiliary pulse signal P


2


to be high for a column of a high ink viscosity while setting the potential of the auxiliary pulse signal P


2


to be low for a column of a low ink viscosity.




Typically, at the time when starting an ink discharging operation, ink in a nozzle may be dry, whereby a false discharge of ink is likely to occur through the nozzle. In view of this, a preliminary vibration pulse signal P


3


may be applied to all actuators before the ink jet head starts an ink discharging operation, as illustrated in FIG.


23


A and FIG.


23


B. In this way, preliminary stirring of ink is performed for each nozzle, thereby preventing the viscosity of ink in the nozzle from increasing. Thus, it is possible to prevent a false discharge of ink.




Embodiment 8




The ink jet head according to Embodiment 8 is an ink jet head for performing a so-called “multi-gray-level” recording operation, and is capable of selectively discharging a small ink droplet and a large ink droplet.




As illustrated in FIG.


24


A and

FIG. 24B

, the recording signal includes a first pulse signal P


11


including a single pulse and a pulse signal P


12


including a plurality of pulses. The pulse signal P


12


is applied after the first pulse signal P


11


. Although not shown in the figures, in the present embodiment, a small ink droplet is discharged when only the first pulse signal P


11


is applied, and a large ink droplet is discharged when only the pulse signal P


12


is applied.




After a large ink droplet is discharged, the magnitude of the residual vibration of ink meniscus is relatively high. Therefore, in the prior art, when a small ink droplet is discharged after discharging a large ink droplet, the ink discharging performance may become unstable due to the influence of the residual vibration.




However, in the present embodiment, the scanning signal is applied to two actuator columns in an alternating manner, whereby the driving signal is applied to the actuators of each column every other cycle. Therefore, when a large ink droplet is discharged from an actuator in one cycle (e.g., the first cycle), the actuator is not driven in the following cycle (the second cycle), whereby even if a small ink droplet is discharged in the next cycle (the third cycle), the influence of the residual vibration is suppressed sufficiently by the time when the small ink droplet is discharged in the next cycle. Therefore, it is possible to suppress the adverse influence of the residual vibration without reducing the driving frequency.




Embodiment 9




In the embodiments described above, actuators adjacent to each other in the horizontal direction are aligned with each other with respect to the vertical direction. Alternatively, actuators adjacent to each other in the horizontal direction may be shifted from each other with respect to the vertical direction.




For example, the actuators of the first actuator column


20


A and the actuators of the second actuator column


20


B may be shifted from each other by half a pitch with respect to the vertical direction, as illustrated in FIG.


25


. Then, the actuators are arranged in a staggered pattern.




The driving signal supplied to the first actuator column


20


A and the second actuator column


20


B may be a driving signal as described in Embodiment 1 or a driving signal as described in Embodiment 5.




Alternatively, actuators may be arranged in a staggered pattern in three or more actuator columns.




Alternatively, with n rows by m columns of actuators, the m vertical actuator columns (each including n actuators) may be arranged so that actuators of adjacent vertical actuator columns are shifted from each other by 1/m a pitch.




Thus, in the ink jet head of the present invention, the arrangement of n rows by m columns of actuators may be modified as necessary.




ALTERNATIVE EMBODIMENTS




The present invention is not limited to Embodiments 1 to 9 set forth above, but may be carried out in various other ways without departing from the spirit or main features thereof.




Thus, the embodiments set forth above are merely illustrative in every respect, and should not be taken as limiting. The scope of the present invention is defined by the appended claims, and in no way is limited to the description set forth herein. Moreover, any variations and/or modifications that are equivalent in scope to the claims fall within the scope of the present invention.



Claims
  • 1. An ink jet head, comprising:a head assembly provided with a plurality of nozzles and a plurality of pressure chambers storing ink therein and communicated respectively to the nozzles; actuators each associated with one of the pressure chambers and each including a piezoelectric element, a scanning electrode provided on one side of the piezoelectric element, and a recording electrode provided on the other side of the piezoelectric element, wherein the actuators are arranged in a matrix pattern of n rows by m columns (where n and m are natural numbers equal to or greater than two) in terms of electrical circuit, with the recording electrodes of each row being electrically connected to one another, and the scanning electrodes of each column being electrically connected to one another; and a driving circuit for supplying a scanning signal to the scanning electrodes for each column, while supplying a recording signal to each row of the recording electrodes in synchronization with the scanning signal, wherein: the actuators are geometrically arranged in n rows by m columns on the head assembly; a relay terminal, extending in a vertical direction, is provided in at least one inter-column space between vertical columns of the actuators on the head assembly for relaying signals from the driving circuit to the recording electrodes and the scanning electrodes; and the recording electrodes and the scanning electrodes are connected to the relay terminal via lead wires extending in a horizontal direction.
  • 2. The ink jet head of claim 1, wherein:m is an even number; and the relay terminal is provided in a central inter-column space between the actuators.
  • 3. The ink jet head of claim 1, wherein a difference in time constant between actuators belonging to different vertical columns is set to be 0.1 μs or less.
  • 4. The ink jet head of claim 1, wherein an actuator that is geometrically located along a pth row and a qth column (where p is a natural number of 1 to n, and q is a natural number of 1 to m) is located along the pth row and the qth column in terms of electrical circuit.
  • 5. The ink jet head of claim 1, wherein actuators that are geometrically adjacent to each other in the vertical direction belong to different columns in terms of electrical circuit.
  • 6. The ink jet head of claim 1, wherein actuators that are geometrically adjacent to each other in the horizontal direction belong to different columns in terms of electrical circuit.
  • 7. The ink jet head of claim 1, wherein actuators that are geometrically adjacent to each other in the vertical direction and those that are geometrically adjacent to each other in the horizontal direction belong to different columns in terms of electrical circuit.
  • 8. The ink jet head of claim 1, wherein a voltage of a driving signal obtained by combining the recording signal with the scanning signal varies among at least two or more actuator columns.
  • 9. The ink jet head of claim 8, wherein:a voltage of the scanning signal is equal among different actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.
  • 10. The inkjet head of claim 8, wherein:a voltage of the recording signal is equal among different actuator columns; and a voltage of the scanning signal varies among at least two or more actuator columns.
  • 11. The ink jet head of claim 8, wherein:a voltage of the scanning signal varies among at least two or more actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.
  • 12. The ink jet head of claim 1, wherein when ink is to be discharged, a driving signal obtained by combining the recording signal with the scanning signal includes an ink discharging pulse signal for driving an actuator so as to discharge ink and an auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged, and when ink is not to be discharged, the driving signal includes the auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged.
  • 13. The ink jet head of claim 12, wherein a voltage of the auxiliary pulse signal varies among at least two or more actuator columns.
  • 14. The ink jet head of claim 12, wherein:the ink discharging pulse signal is included in the recording signal; and the auxiliary pulse signal is included in the scanning signal.
  • 15. The ink jet head of claim 1, wherein the driving circuit supplies, prior to a recording operation, a preliminary pulse signal for driving an actuator to such a degree that ink is not discharged to all actuators.
  • 16. The ink jet head of claim 1, wherein when a small ink droplet is to be discharged, a driving signal obtained by combining the recording signal with the scanning signal includes a first pulse signal, and when a large ink droplet is to be discharged, the driving signal includes two or more pulse signals produced after the first pulse signal.
  • 17. The ink jet head of claim 1, wherein the n rows by m columns of actuators are geometrically arranged on the head assembly so that at least actuators of vertical columns that are adjacent to each other in the horizontal direction, among m vertical columns each including n actuators arranged in the vertical direction, are shifted from each other with respect to the vertical direction.
  • 18. The ink jet head of claim 1, wherein the actuators are geometrically arranged in a staggered pattern on the head assembly.
  • 19. An ink jet recording apparatus, comprising:the ink jet head of claim 1; and movement means for relatively moving the ink jet head and a recording medium with respect to each other.
  • 20. An ink jet head, comprising:a head assembly provided with a plurality of nozzles and a plurality of pressure chambers storing ink therein and communicated respectively to the nozzles; actuators each associated with one of the pressure chambers and each including a piezoelectric element, a scanning electrode provided on one side of the piezoelectric element, and a recording electrode provided on the other side of the piezoelectric element, wherein the actuators are arranged in a matrix pattern of n rows by m columns (where n and m are natural numbers equal to or greater than two) in terms of electrical circuit, with the recording electrodes of each row being electrically connected to one another, and the scanning electrodes of each column being electrically connected to one another; and a driving circuit for supplying a scanning signal to the scanning electrodes for each column, while supplying a recording signal to each row of the recording electrodes in synchronization with the scanning signal, wherein: the actuators are geometrically arranged in n rows by m columns on the head assembly; a first relay terminal and a second relay terminal, both extending in a vertical direction, for relaying signals from the driving circuit to the recording electrodes and the scanning electrodes are provided on a left side and a right side, respectively, of an area on the head assembly where the actuators are arranged; and the recording electrodes and the scanning electrodes are connected to the relay terminals via lead wires extending in a horizontal direction.
  • 21. The ink jet head of claim 19, wherein:m is an even number; the recording electrodes and the scanning electrodes of the actuators on the left side are connected to the first relay terminal; and the recording electrodes and the scanning electrodes of the actuators on the right side are connected to the second relay terminal.
  • 22. The ink jet head of claim 20, wherein a difference in time constant between actuators belonging to different vertical columns is set to be 0.1 μs or less.
  • 23. The ink jet head of claim 20, wherein an actuator that is geometrically located along a pth row and a qth column (where p is a natural number of 1 to n, and q is a natural number of 1 to m) is located along the pth row and the qth column in terms of electrical circuit.
  • 24. The ink jet head of claim 20, wherein actuators that are geometrically adjacent to each other in the vertical direction belong to different columns in terms of electrical circuit.
  • 25. The ink jet head of claim 20, wherein actuators that are geometrically adjacent to each other in the horizontal direction belong to different columns in terms of electrical circuit.
  • 26. The ink jet head of claim 20, wherein actuators that are geometrically adjacent to each other in the vertical direction and those that are geometrically adjacent to each other in the horizontal direction belong to different columns in terms of electrical circuit.
  • 27. The ink jet head of claim 20, wherein a driving signal obtained by combining the recording signal with the scanning signal varies among at least two or more actuator columns.
  • 28. The ink jet head of claim 27, wherein:a voltage of the scanning signal is equal among different actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.
  • 29. The ink jet head of claim 27, wherein:a voltage of the recording signal is equal among different actuator columns; and a voltage of the scanning signal varies among at least two or more actuator columns.
  • 30. The ink jet head of claim 27, wherein:a voltage of the scanning signal varies among at least two or more actuator columns; and a voltage of the recording signal varies among at least two or more actuator columns.
  • 31. The ink jet head of claim 20, wherein when ink is to be discharged, a driving signal obtained by combining the recording signal with the scanning signal includes an ink discharging pulse signal for driving an actuator so as to discharge ink and an auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged, and when ink is not to be discharged, the driving signal includes the auxiliary pulse signal for driving an actuator to such a degree that ink is not discharged.
  • 32. The ink jet head of claim 31, wherein a voltage of the auxiliary pulse signal varies among at least two or more actuator columns.
  • 33. The ink jet head of claim 31, wherein:the ink discharging pulse signal is included in the recording signal; and the auxiliary pulse signal is included in the scanning signal.
  • 34. The ink jet head of claim 20, wherein the driving circuit supplies, prior to a recording operation, a preliminary pulse signal for driving an actuator to such a degree that ink is not discharged to all actuators.
  • 35. The ink jet head of claim 20, wherein when a small ink droplet is to be discharged, a driving signal obtained by combining the recording signal with the scanning signal includes a first pulse signal, and when a large ink droplet is to be discharged, the driving signal includes two or more pulse signals produced after the first pulse signal.
  • 36. The ink jet head of claim 20, wherein the n rows by m columns of actuators are geometrically arranged on the head assembly so that at least actuators of vertical columns that are adjacent to each other, among m vertical columns each including n actuators arranged in the vertical direction, are shifted from each other with respect to the vertical direction.
  • 37. The ink jet head of claim 20, wherein the actuators are geometrically arranged in a staggered pattern on the head assembly.
  • 38. An ink jet recording apparatus, comprising:the ink jet head of claim 20; and movement means for relatively moving the ink jet head and a recording medium with respect to each other.
Priority Claims (2)
Number Date Country Kind
2002-164159 Jun 2002 JP
2002-164178 Jun 2002 JP
US Referenced Citations (1)
Number Name Date Kind
20030151637 Nakamura et al. Aug 2003 A1
Foreign Referenced Citations (2)
Number Date Country
2001162794 Jun 2001 JP
WO9912739 Mar 1999 WO