JP3978753B2 - Ink jet printer, and recording head drive apparatus and method for ink jet printer - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an inkjet printer that performs recording on a recording sheet by ejecting ink droplets from a nozzle portion, and a recording head driving apparatus and method for an inkjet printer.
[0002]
[Prior art]
In recent years, ink jet printers that perform recording on recording paper by ejecting ink droplets from nozzle portions that communicate with an ink chamber have become widespread. Conventionally, in this type of ink jet printer, one piezoelectric element is provided corresponding to one nozzle. For example, the piezoelectric element is fixed to a vibration plate that forms an outer wall of an ink chamber to which ink is supplied via an ink flow path, and is bent in accordance with a voltage waveform of an applied drive signal, whereby the ink chamber The volume of the ink was changed to generate a discharge pressure, and the ink pressure could be discharged from the nozzle by this discharge pressure.
[0003]
In this type of ink jet printer, the volume of the ink chamber is changed to generate the discharge pressure as described above, so that the ink discharged from the nozzles has a columnar shape (with a tail). The flying ink causes a time difference and a speed difference between the head portion and the tail portion of the flying ink. For this reason, minute satellite-like unnecessary ink droplets (hereinafter referred to as satellite droplets) are generated in association with the preceding main ink droplets, and an undesired printing result is generated by landing on the recording paper. . In this case, the generation of satellite droplets in a dark image that is recorded with relatively large ink droplets does not have a significant effect on the image quality, but small ink droplets are used as in the case of expressing an image with a low density or an intermediate gradation image. When recording is performed, it is expected that the image quality will be significantly lowered due to the generation of satellite droplets. Therefore, the generation of satellite droplets becomes a big problem especially when ejecting small-sized ink droplets.
[0004]
In order to deal with this problem, several measures have been proposed in the past. For example, Japanese Patent Laid-Open No. 7-76087 proposes a method in which one piezoelectric element is provided for each nozzle, and ink droplet ejection is performed by switching the change rate of the ejection voltage applied to the piezoelectric element in two stages. ing. In this method, as shown in FIG. 9, the discharge voltage is initially increased at the first voltage change rate v1, and the discharge voltage is increased from the middle at the second voltage change rate v2, which is larger than v1. It is. In FIG. 9, the vertical axis represents voltage, and the horizontal axis represents time. According to this method, since the ink is continuously ejected while following the head portion of the ink ejected first, the speed difference between the head portion and the tail portion of the ink column is reduced, and the satellite is reduced. Drops are less likely to occur.
[0005]
For example, Japanese Patent Laid-Open No. 59-133067 proposes a method in which one piezoelectric element is provided for one nozzle, and two voltage pulses independent of each other are applied to the piezoelectric element to eject ink droplets. ing. In this method, as shown in FIG. 10, first, the first pulse P1 is applied to the piezoelectric element to cause a first pressure fluctuation to start ejecting ink droplets from the nozzle, and then the first pulse After the pulse P1, the second pulse P2 is applied to the piezoelectric element before the ink droplet is ejected from the nozzle to cause the second pressure fluctuation. In FIG. 10, the vertical axis represents voltage and the horizontal axis represents time. According to this method, the ink column ejected from the nozzle is broken early, and satellite droplets are less likely to be generated.
[0006]
For example, in Japanese Patent Application Laid-Open No. 51-45931, two pressure generating means are provided for one nozzle, and ink is vibrated by superimposing vibrations from these two pressure generating means. There has been proposed an ink droplet discharge device that discharges ink.
[0007]
[Problems to be solved by the invention]
However, in the method described in the above-mentioned Japanese Patent Application Laid-Open No. 7-76087, the first voltage change rate v1 must be made smaller than the second voltage change rate v2. For this reason, compared with the case where the voltage is changed at a high voltage change rate v2 over the entire discharge stroke, the flying speed of the ejected ink droplets has to be reduced. The drop in the ink droplet speed leads to instability of ejection such as a deterioration in the linearity of the flight route and variations in the flight speed. Therefore, there is a possibility that a recording dot shift occurs and the print quality is lowered.
[0008]
Further, in the method described in the above Japanese Patent Application Laid-Open No. 59-133067, after the first pulse P1 is finished, the second pulse P2 is applied at a certain time interval Ti. Therefore, if this time interval Ti is large, the tail of the ink column becomes long and it becomes difficult to prevent the generation of satellite droplets. On the other hand, if the time interval Ti is small, the piezoelectric element cannot follow the voltage change and the desired operation cannot be obtained. This is because, in general, a piezoelectric element has inherent vibration characteristics and cannot operate at a frequency higher than its natural frequency. This point can be solved by manufacturing a piezoelectric element having a high natural frequency. However, even if the natural frequency of the piezoelectric element is increased, there is a limit to this, and there is a difficulty in manufacturing technology. This is not realistic because it leads to high costs. In the description of the above publication, the voltage value V2 of the second pulse P2 is smaller than the voltage value V1 of the first pulse P1, but the trailing part is caught up with the head part of the ink column and integrated. In order to achieve this, it is necessary to make the voltage value V2 of the second pulse P2 larger than the voltage value V1 of the first pulse P1. However, increasing the voltage applied to the piezoelectric element is expected to shorten the life of the piezoelectric element and the diaphragm excited by the piezoelectric element, and increase the residual vibration to deteriorate the frequency characteristics. The
[0009]
In addition, the ink droplet ejection apparatus described in the above Japanese Patent Application Laid-Open No. 51-45931 is intended to efficiently eject ink droplets with a small power input. High-frequency drive signals are respectively applied to the two pressure generating means, and the phase difference and amplitude of these high-frequency drive signals are changed, so that the vibrations from the two pressure generating means are superposed to vibrate the ink. Drops are ejected. That is, this ink droplet ejection device is not intended to prevent the generation of satellite droplets, and does not have a configuration for that purpose. There is no such suggestion.
[0010]
Thus, conventionally, satellites are not subject to reductions in the flying speed of ejected ink droplets, shortening of device life, deterioration of frequency characteristics, etc., and without being restricted by the natural vibration characteristics of piezoelectric elements. It was difficult to sufficiently suppress the generation of droplets.
[0011]
In order to solve these problems, the present applicant provides a piezoelectric element for preventing satellite droplets separately from the piezoelectric element for ejecting ink droplets for each nozzle, and appropriately controls the drive timing of these piezoelectric elements. An ink jet printer is proposed. According to this ink jet printer, it is possible to suppress the generation of satellite droplets during ink droplet ejection while overcoming the above-described problems.
[0012]
By the way, it is known that in this type of ink jet printer, it is necessary to increase the flying speed of ink droplets in order to maintain the stability of ink droplet ejection. This is because, when the ink droplet speed is low, as described above, the linearity of the flight route is lost, and there are problems such as variations in landing points on the recording paper. In addition, when attempting to express a light image or an intermediate gradation image, it is necessary to reduce the size of the ink droplet. Therefore, in order to realize high-quality image expression, it is not enough to prevent the generation of satellite droplets as described above, and further, there are conditions for increasing the flying speed of ink droplets and reducing the size of ink droplets. It is essential to meet.
[0013]
The present invention has been made in view of such problems, and the object thereof is to overcome the above-described problems and to suppress the generation of satellite droplets during ink droplet ejection and to increase the flying speed of ink droplets. It is another object of the present invention to provide an ink jet printer capable of reducing the size of ink droplets, and an apparatus and method for driving a recording head for an ink jet printer.
[0014]
[Means for Solving the Problems]
An ink jet printer according to the present invention is disposed at a position further away from a nozzle portion of a nozzle portion for ejecting ink droplets, an ink chamber for supplying ink to the nozzle portion, and a wall of the ink chamber, and is displaced. The first pressure generating means for generating the pressure by changing the volume of the ink chamber and the wall of the ink chamber are provided at a position closer to the nozzle portion, and the volume of the ink chamber is changed by being displaced. Second pressure generating means for generating pressure, and discharge control means for controlling the ink droplet discharge operation by applying a voltage to the first and second pressure generating means. The discharge control means simultaneously applies a voltage having the same waveform to the first pressure generation means and the second pressure generation means to move the meniscus position to a predetermined position, and then causes the first pressure generation means to 1 is applied to displace the first pressure generating means in the ink chamber contraction direction. Extruded ink with its tail pulled from the nozzle After that, when the voltage applied to the first pressure generating means is lowered to a second voltage lower than the first voltage to displace the first pressure generating means in the ink chamber expansion direction, the second pressure A third voltage lower than the first voltage is applied to the generating means to displace the second pressure generating means in the ink chamber contraction direction.
[0015]
A recording head driving device for an ink jet printer according to the present invention includes a nozzle unit for ejecting ink droplets, an ink chamber for supplying ink to the nozzle unit, and a wall of the ink chamber at a position further away from the nozzle unit. A first pressure generating means for generating pressure by changing the volume of the ink chamber by being disposed and a wall closer to the nozzle portion on the wall of the ink chamber; An ink jet printer comprising: a second pressure generating means for generating pressure by changing the volume of the chamber; and an ejection control means for controlling the ink droplet ejection operation by applying a voltage to the first and second pressure generating means Provided with a device for driving the recording head. The discharge control means simultaneously applies a voltage having the same waveform to the first pressure generation means and the second pressure generation means to move the meniscus position to a predetermined position, and then causes the first pressure generation means to 1 is applied to displace the first pressure generating means in the ink chamber contraction direction. Extruded ink with its tail pulled from the nozzle After that, when the voltage applied to the first pressure generating means is lowered to a second voltage lower than the first voltage to displace the first pressure generating means in the ink chamber expansion direction, the second pressure A third voltage lower than the first voltage is applied to the generating means to displace the second pressure generating means in the ink chamber contraction direction.
[0016]
A recording head driving method for an ink jet printer according to the present invention includes a nozzle unit for ejecting ink droplets, an ink chamber for supplying ink to the nozzle unit, and a wall of the ink chamber at a position further away from the nozzle unit. A first pressure generating means for generating pressure by changing the volume of the ink chamber by being disposed and a wall closer to the nozzle portion on the wall of the ink chamber; And a second pressure generating means for generating pressure by changing the volume of the chamber, wherein the recording head for an ink jet printer is driven by the same method as the first pressure generating means and the second pressure generating means. The waveform voltage is simultaneously applied to move the meniscus position to a predetermined position, and then the first voltage is applied to the first pressure generating means to cause the first pressure generating means to contract the ink chamber. It is displaced to Extruded ink with its tail pulled from the nozzle After that, when the voltage applied to the first pressure generating means is lowered to a second voltage lower than the first voltage to displace the first pressure generating means in the ink chamber expansion direction, the second pressure The method includes a step of applying a third voltage lower than the first voltage to the generating unit to displace the second pressure generating unit in the ink chamber contraction direction.
[0017]
In the ink jet printer and the recording head drive device for an ink jet printer according to the present invention, the first pressure generating means is located at a position further away from the nozzle portion, and the second pressure generating means is located at a position closer to the nozzle portion. Since each is provided, a voltage having the same waveform is simultaneously applied to the first pressure generating means and the second pressure generating means to move the meniscus position to a predetermined position, and subsequently to the first pressure generating means. When the first voltage is applied, the first pressure generating means is displaced in the contraction direction of the ink chamber and from the nozzle portion. With the tail pulled Ink Extrusion Is done. Thereafter, when the voltage applied to the first pressure generating means is lowered to the second voltage lower than the first voltage, and the first pressure generating means is displaced in the ink chamber expansion direction, the second voltage is applied. When a third voltage lower than the first voltage is applied to the pressure generating means, the second pressure generating means is displaced in the ink chamber contraction direction, contrary to the first pressure generating means.
[0018]
In the ink jet printer recording head driving method according to the present invention, the first pressure generating means provided at a position further away from the nozzle portion and the second pressure generation provided at a position closer to the nozzle portion. A recording head for an ink jet printer comprising: a first pressure generating means and a second pressure generating means simultaneously applying a voltage having the same waveform to move the meniscus position to a predetermined position; Applying a first voltage to the pressure generating means Extruded ink with its tail pulled from the nozzle After that, when the first pressure generating means is lowered to the second voltage lower than the first voltage to displace the first pressure generating means in the ink chamber expansion direction, a third voltage lower than the first voltage is applied to the second pressure generating means. When applied, the second pressure generating means is displaced in the ink chamber contraction direction, contrary to the first pressure generating means.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0020]
FIG. 1 shows a schematic configuration of a main part of an ink jet printer according to an embodiment of the present invention. In this embodiment, an inkjet printer including a multi-nozzle head having a plurality of nozzles will be described. However, the present invention can also be applied to an inkjet printer having a single nozzle head having a single nozzle. The recording head driving apparatus and method for an ink jet printer according to the embodiment of the present invention is embodied by the ink jet printer according to the present embodiment, and will be described below.
[0021]
The inkjet printer 1 includes a recording head 11 that performs recording by ejecting ink droplets onto the recording paper 2, an ink cartridge 12 that supplies ink to the recording head 11, the position of the recording head 11, and the recording paper 2. A head position / paper feed controller 13 for controlling the paper feed, a head controller 14 for controlling the ink droplet ejection operation of the recording head 11 by the drive signal 21, and predetermined image processing on the input image data, and print data The image processing unit 15 is supplied to the head controller 14 as 22, and the system controller 16 controls the head position / paper feed controller 13, the head controller 14, and the image processing unit 15 by control signals 23, 24, and 25, respectively. . Here, the head controller 14 corresponds to the “ejection control means” in the present invention.
[0022]
2 shows a perspective sectional structure of the recording head 11 in FIG. 1, and FIG. 3 shows a sectional structure of the recording head 11 in FIG. As shown in these drawings, the recording head 11 includes a thin nozzle plate plate 111, a flow path plate 112 stacked on the nozzle plate 111, and a vibration plate 113 stacked on the flow path plate 112. Configured. Each of these plates is bonded to each other with an adhesive (not shown), for example.
[0023]
Concave portions are selectively formed on the upper surface side of the flow path plate 112, and a plurality of elongated ink chambers 114 and a common flow path 115 communicating with the ink chambers 114 are formed by the concave portions and the vibration plate 113. It is composed. A communication portion between the common flow path 115 and each ink chamber 114 forms a narrow passage, and the flow path width increases from this point toward the ink chamber 114. On the vibration plate 113 directly above each ink chamber 114, a pair of piezoelectric elements 116a and 116b made of, for example, piezo elements are fixed at a certain distance from each other. These piezoelectric elements are arranged in the order of the piezoelectric elements 116 a and 116 b from the side closer to the common flow path 115. Electrodes (not shown) are stacked on the upper and lower surfaces of the piezoelectric elements 116a and 116b, respectively, and a drive signal from the head controller 14 (FIG. 1) is applied to these electrodes, and the piezoelectric elements 116a and 116b, and consequently By bending the vibration plate 113, the volume of the ink chamber 114 can be increased (expanded) or decreased (contracted). Here, the ink chamber 114 corresponds to an “ink chamber” in the present invention.
[0024]
In the present embodiment, the piezoelectric elements 116a and 116b are configured to have the same amount of displacement (hereinafter referred to as displacement capability) with respect to the same applied voltage. Therefore, in this embodiment, the material, thickness and area of the piezoelectric elements 116a and 116b are formed to be equal. Thereby, the same volume change can be given to the ink chamber 114 with respect to the same applied voltage. However, the two piezoelectric elements 116a and 116b may be configured such that the displacement capacity of the two piezoelectric elements 116a and 116b is changed by changing the area and thickness thereof. Here, the piezoelectric element 116a corresponds to “discharge pressure generating means” and “first pressure generating means” in the present invention, and the piezoelectric element 116b corresponds to “auxiliary pressure generating means” and “second pressure generating means” in the present invention. ".
[0025]
The portion of each ink chamber 114 opposite to the side communicating with the common flow path 115 has a structure in which the flow path width is gradually narrowed, and the flow path plate 112 at the end thereof is perforated in the thickness direction. A channel hole 117 is provided. The channel hole 117 communicates with a minute nozzle 118 formed in the lowermost nozzle plate 111 so that ink droplets are ejected from the nozzle 118. In the present embodiment, a plurality of nozzles 118 are formed in the recording head 11 at regular intervals along a paper feed direction (arrow X in FIG. 2) of the recording paper 2 (FIG. 1). However, other arrangements (for example, a staggered two-row arrangement) may be used. Here, the nozzle 118 corresponds to a “nozzle portion” in the present invention.
[0026]
The common channel 115 communicates with the ink cartridge 12 (not shown in FIGS. 2 and 3) shown in FIG. Then, the ink is always supplied from the ink cartridge 12 to each ink chamber 114 through the common flow path 115 at a constant speed. The ink supply can be performed by using, for example, a capillary phenomenon, but in addition, the ink cartridge 12 may be provided with a predetermined pressurizing mechanism and pressurized.
[0027]
As described above, the piezoelectric element 116 b is disposed at a position closer to the nozzle 118, and the piezoelectric element 116 a is disposed at a position further away from the nozzle 118. As will be described later, this is one feature of the present invention.
[0028]
The recording head 11 having such a configuration ejects ink droplets while reciprocating in a direction Y (FIG. 2) perpendicular to the paper feeding direction X of the recording paper 2 by a carriage drive motor (not shown) and a carriage mechanism accompanying the carriage driving motor. Thus, an image is recorded on the recording paper 2.
[0029]
The head controller 14 shown in FIG. 1 is, for example, a microprocessor, a ROM (Read Only Memory) in which a program executed by the microprocessor is stored, a predetermined calculation or a temporary operation by the microprocessor, although not shown. RAM (Random Access Memory) as a work memory used for various data storage, etc., a drive waveform storage unit comprising a non-volatile memory, and a digital analog for converting digital data read from the drive waveform storage unit into analog A (D / A) converter and an amplifier that amplifies the output of the D / A converter are provided. Here, the drive waveform storage unit is a set of waveform data indicating the voltage waveforms of the drive signals 21a and 21b (FIG. 4) for driving the piezoelectric elements 116a and 116b (FIG. 2) of the nozzles of the recording head 11, respectively. I remember a lot. These waveform data are created by setting various parameters (time parameter and voltage parameter) shown in FIG. 4 to various values, for example. However, a fixed relationship as described later is maintained between the driving signal 21a and the driving signal 21b of each set in order to suppress the generation of satellite droplets. These waveform data are read out by a microprocessor, converted into analog signals by a D / A converter, amplified by an amplifier, and output as a set of drive signals 21a and 21b having the same number as the number of nozzles n. The head controller 14 is not limited to the above configuration, and may be configured differently.
[0030]
Of these sets of drive signals, each drive signal 21a is applied to the piezoelectric element 116a of the corresponding nozzle, and each drive signal 21b is applied to the piezoelectric element 116b of the corresponding nozzle. In FIG. 1, n sets of drive signals 21 a and 21 b are drawn together as drive signals 21. Here, the drive signal 21a corresponds to the “main drive signal” in the present invention, and the drive signal 21b corresponds to the “auxiliary drive signal” in the present invention.
[0031]
FIG. 4 shows an example of the waveform of one period (T) of the drive signals 21a and 21b. (A) of this figure represents the drive signal 21a, and (b) represents the drive signal 21b. Here, the vertical axis represents voltage, the horizontal axis represents time, and time advances from the left to the right in the figure. Among these, the drive signal 21a is an ejection drive signal for generating a pressure for ejecting ink droplets, and can take the drawing voltage Vp and the ejection voltage Va in addition to the reference voltage 0V. The drive signal 21b is an auxiliary drive signal for generating a pressure that suppresses the generation of satellite droplets when ink droplets are ejected, and can take the drawing voltage Vp and the auxiliary voltage Vb in addition to the reference voltage 0V. The set of drive signals 21a and 21b is appropriately switched for each ejection cycle by the head controller 14 and supplied to the corresponding nozzle.
[0032]
Here, the significance of the waveform of the drive signal 21a will be described with reference to FIG. FIG. 5 shows the relationship between the waveform of the drive signal, the behavior of the piezoelectric element 116a to which the drive signal is applied, and the change in the position of the front end of the ink in the nozzle 118 (hereinafter referred to as the meniscus position). Is. (A) in this figure represents approximately one period of the waveform obtained by generalizing the drive signal 21a, and (b) in the figure shows the case where the drive signal having the waveform as shown in (a) is applied to the piezoelectric element 116a. A change in the state of the ink chamber 114 is shown, and FIG. 10C shows a change in the meniscus position in the nozzle 118 at that time.
[0033]
In FIG. 5A, first, a process of changing the drive voltage from the reference voltage 0 V to the pull-in voltage Vp (from A to B) is a first previous process, and a process of holding the pull-in voltage Vp for a certain time (from B to C To the second previous process. Further, a process (from C to D) in which the drive voltage is changed from the pull-in voltage Vp1 to the reference voltage 0V is a first process, and a time required for this process is t1. Further, the stroke (from D to E) in which the reference voltage is held at 0V and is on standby is defined as the second stroke, and the time required for this is defined as t2. Further, a process (from E to F) for changing from the reference voltage 0 V to the discharge voltage Va is a third process, and a time required for this process is t3.
[0034]
In the present embodiment, the time point E, which is the start time point of the third stroke, is a timing at which the discharge is started. Prior to this timing, the first previous stroke, the second previous stroke, the first stroke, and the first stroke Two strokes are going to be done.
[0035]
First, at time A and before, the voltage applied to the piezoelectric element 116a is 0 V, so that the state P in FIG. _A As described above, there is no deflection in the vibration plate 113, and the volume of the ink chamber 114 is maximum. At time A, the meniscus position in the nozzle 118 is the state M in FIG. _A As shown in FIG. 4, it is assumed that the nozzle is located at a position retracted by a predetermined distance from the nozzle opening end.
[0036]
Next, when the first forward stroke is performed in which the drive voltage is slowly increased from the voltage 0 V at time A to the pull-in voltage Vp at time B, the vibration plate 113 bends inward and the ink chamber 114 contracts (FIG. 5). State P of (b) _B ). Since the shrinkage speed of the ink chamber 114 at this time is slow, the decrease in the volume of the ink chamber 114 advances the meniscus position in the nozzle 118 and at the same time the ink to the common channel 115 shown in FIG. Also causes backflow. The ratio of the ink advance amount and the reverse flow rate at this time is mainly determined by the ratio between the flow path resistance in the nozzle 118 and the flow path resistance in the narrow path connecting the ink chamber 114 and the common flow path 115. By optimizing this, the state M in FIG. _B As shown, the meniscus position at time B can be set to be substantially the same position as the nozzle opening end without protruding from the nozzle opening end.
[0037]
Next, during the period from time point B to time point C, a second previous stroke is performed in which the volume of the ink chamber 114 is kept constant by holding the drive voltage at the pull-in voltage Vp. However, since the ink supply from the ink cartridge 12 is continuously performed during this time, the meniscus position in the nozzle 118 is displaced toward the nozzle opening end, and at the point C, for example, the state M in FIG. _C As shown by, it advances to a position slightly protruding from the nozzle opening end.
[0038]
Next, when the first step of reducing the drive voltage from the pull-in voltage Vp at the time point C to the reference voltage 0 V at the time point B is performed, the applied voltage to the piezoelectric element 116 becomes 0, so the deflection of the vibration plate 113 is eliminated. The ink chamber 114 expands (state P in FIG. 5B). _D ). Therefore, the meniscus in the nozzle 118 is drawn in the direction of the ink chamber 114, and at the time point D, for example, the state M in FIG. _D As shown in (1) (ie, away from the nozzle opening end). Note that the amount of meniscus pull-in in the first stroke is changed by changing the magnitude of the pull-in voltage Vp, which is the potential difference between the time point C and the time point D, and thus the ink droplet size can be controlled. . This is because the size of the ink droplet depends on the meniscus position at the start of ejection, and the deeper the meniscus position, the smaller the ink droplet size.
[0039]
Next, during a time t2 from time point D to time point E, a second step of keeping the volume of the ink chamber 114 constant by fixing the drive voltage to the reference voltage 0 V and maintaining the vibration plate 113c in a state without deflection. (State P in FIG. 5C) _D ~ P _E ). However, since the ink supply from the ink cartridge 12 is continuously performed during this time, the meniscus position in the nozzle 118 is displaced toward the nozzle opening end, and at the time point E, for example, the state M in FIG. _E Advance to the position shown in. Note that the amount of advancement of the meniscus position is changed by changing the required time t2 of the second stroke, and the meniscus position at the start of the third stroke can be adjusted. Can be controlled.
[0040]
Next, a third step is performed in which the drive voltage is rapidly increased from the voltage 0 V at time E to the ejection voltage Va at time F. Here, the time point E is the discharge start timing as described above. At this time, at the time point F, the vibration plate 113 is in the state P in FIG. _F As shown in FIG. 5B, the ink chamber 114 is greatly deflected inward, and the ink chamber 114 is rapidly contracted. _F As shown in FIG. 5, the meniscus in the nozzle 118 is pushed at a stroke toward the nozzle opening end, and is ejected as ink droplets from here. The ejected ink droplets fly in the air and land on the recording paper 2 (FIG. 2).
[0041]
Thereafter, the voltage is decreased again to the reference voltage of 0 V at a time G when a predetermined time elapses while keeping the drive voltage at the discharge voltage Va. As a result, at time point H, the state P in FIG. _H As shown in FIG. 5, the vibration plate 113 returns to a state without deflection. This state is maintained until the start time I of the first previous stroke in the next discharge operation. At a time point H immediately after the drive voltage is decreased again to 0 V, the state M in FIG. _H As shown in FIG. 5, the meniscus position is retracted by an amount corresponding to the volume obtained by adding the volume of the ejected ink droplet and the volume of the ink chamber 114, but the ink filling ( By the refilling, the meniscus position at the start time I of the first previous stroke in the next discharge operation is the state M in FIG. _I As shown in Fig. 2, the state M at the initial time A _A Will be the same.
[0042]
In this way, one discharge operation is completed. Thereafter, by repeating such a cycle operation in parallel for each nozzle 118, image recording on the recording paper 2 (FIG. 2) is continuously performed.
[0043]
In the present embodiment, the time t2 required for the second stroke is not longer than the time required for the meniscus drawn in the first stroke to reach the nozzle opening end, and the ejection voltage Va for the third stroke is the ink droplet. It is assumed that it is in a range sufficient to discharge the water. In FIG. 4A, the time required for the strokes other than the first stroke CD, the second stroke DE, and the third stroke EF is expressed as follows. AB = τ1, BC = τ2, FG = t4, GH = t5.
[0044]
Next, returning to FIG. 4 again, the waveform of the drive signal 21b will be described. In the present embodiment, portions A to D in the drive signal 21b have the same waveform as that of the drive signal 21a. On the other hand, the required time t6 of the 0V holding stroke DE ′ is set to be equal to the section DG (= t2 + t3 + t4) of the drive signal 21a, and the drive signal 21a starts to fall from the discharge voltage Va to the reference voltage 0V (= time E). ′), The drive signal 21b starts to rise from the reference voltage 0V to the auxiliary voltage Vb. In FIG. 4B, the time required for the process E′F ′ in which the drive signal 21b changes from the reference voltage 0V to the auxiliary voltage Vb is t7, and this auxiliary time from the point F ′ when the drive signal 21b reaches the auxiliary voltage Vb. The required time until the voltage Vb holding end time G ′ is expressed as t8, and the required time of the process G′H ′ in which the drive signal 21b changes from the auxiliary voltage Vb to the reference voltage 0V is expressed as t9. In this manner, the drive signal 21b is raised and the piezoelectric element 116a is raised in parallel with the displacement of the piezoelectric element 116a in the direction in which the ink chamber 114 expands (hereinafter referred to as the ink chamber expansion direction). 116b is displaced in the direction in which the ink chamber 114 contracts (hereinafter referred to as the ink chamber contracting direction).
[0045]
Next, the overall operation of the ink jet printer 1 of FIG. 1 will be briefly described.
[0046]
In FIG. 1, when print data is input to the inkjet printer 1 from an information processing apparatus such as a personal computer (not shown), the image processing unit 15 performs predetermined image processing (for example, decompression of compressed data) on the input data. And the like are sent to the head controller 14 as the print data 22.
[0047]
When the head controller 14 acquires print data 22 for n dots corresponding to the number of nozzles of the recording head 11, based on these print data 22, ink droplets for forming dots for each of the n nozzles. The size is determined, and a set of drive signals 21a and 21b to be supplied to each nozzle is selected from the determination result. For example, when expressing a high density, a set of drive waveforms (waveforms where t2, Va is large and Vp is small) that can increase the ink droplet size is selected to express a low density or high resolution expression. When performing, a set of drive waveforms (waveforms with small t2, Va and large Vp) that can reduce the ink droplet size is selected. For example, when expressing a subtle halftone, the ink droplet size is slightly changed between adjacent dots.For example, when the ink ejection characteristics vary between nozzles, this is used. A set of drive waveforms that can be corrected is selected.
[0048]
The head controller 14 selects a set of driving signals for n dots (that is, a driving signal supplied to the n nozzles 118), and then selects the piezoelectric of each nozzle 118 in the recording head 11 at the discharge cycle switching timing. At the same time as supplying the selected drive signal 21a to the element 116a, the selected drive signal 21b is supplied to the piezoelectric element 116b of each nozzle 118. The piezoelectric element 116a in each nozzle performs each process as described in FIG. 5 according to the voltage waveform of the supplied drive signal 21a, and ejects ink droplets. At this time, the piezoelectric element 116b of each nozzle is displaced as described later according to the voltage waveform of the supplied drive signal 21b, and performs an operation for assisting the ejection operation by the piezoelectric element 116a.
[0049]
Next, the discharge operation of the ink jet printer according to the present embodiment will be described in more detail with reference to FIGS.
[0050]
In the present embodiment, in order to prevent the generation of satellite droplets, the drive signal 21a is raised from the reference voltage 0V to the discharge voltage Va at time E (discharge start timing te) as shown in FIG. After the displacement of 116a in the ink chamber contraction direction, at time G, the drive signal 21a is again lowered to 0 V to displace (return) the piezoelectric element 116a in the ink chamber expansion direction, and the ink chamber expansion direction of the piezoelectric element 116a. In substantially parallel to the displacement operation, the drive signal 21b is raised from 0V to the auxiliary voltage Vb to displace the piezoelectric element 116b in the ink chamber contraction direction. This point will be further described with reference to FIG.
[0051]
FIG. 6 shows the relationship between the change in the voltage waveform of the drive signals 21a and 21b and the displacement of the piezoelectric elements 116a and 116b. Specifically, (a) in this figure represents the main waveform of the drive signal 21a, (b) represents the displacement of the piezoelectric element 116a, (c) represents the main waveform of the drive signal 21b, (d ) Represents the displacement of the piezoelectric element 116b. Here, the horizontal axis indicates time, the vertical axis in (a) and (c) indicates voltage, and the vertical axis in (b) and (d) indicates displacement.
[0052]
As shown in FIGS. 6A and 6B, the piezoelectric element 116a is displaced in the ink chamber contraction direction with the increase of the voltage of the drive signal 21a starting from the time point E, and the voltage is changed to the ejection voltage Va by the inertial force. The maximum displacement state is reached at the time point P when the time point F is reached, and the ink chamber 114 is in the most contracted state. Then, at this time point P (time point G in FIG. 5A), the drive signal 21a starts to fall and is changed to the reference voltage 0 V at time point H. Accordingly, the piezoelectric element 116a is displaced in the ink chamber expansion direction, and returns to the original state at the time point H. On the other hand, as shown in FIGS. 6C and 6D, the drive signal 21b rises from the reference voltage 0V to the auxiliary voltage Vb at the same time E ′ as the fall start time G of the drive signal 21a. Thus, the piezoelectric element 116b is displaced in a direction in which the ink chamber 114 is contracted. Then, the piezoelectric element 116b is in a maximum displacement state at a time P ′ when the voltage F reaches the auxiliary voltage Vb and overruns the time F ′ due to the inertial force similar to the above.
[0053]
Thus, in the present embodiment, the piezoelectric element 116b is displaced from the displacement 0 in the ink contraction direction in parallel with the displacement of the piezoelectric element 116a in the ink chamber expansion direction. That is, the piezoelectric elements 116a and 116b perform a displacement operation in directions opposite to each other in parallel.
[0054]
The piezoelectric element 116a, which has started to apply the ejection voltage Va of the drive signal 21a at the time point E, generates pressure in the ink chamber 114 by being displaced in the ink chamber contraction direction, and pushes ink out of the nozzle 118 by this pressure. At this time, the ink pushed out from the nozzle 118 has a tail and forms an ink column. Next, when the piezoelectric element 116a starts to be displaced in the ink chamber expansion direction at the time point P (time point G), the tail portion of the ink column is pulled back and becomes thinner. At this time P (time E '), the piezoelectric element 116b starts to be displaced in the ink chamber contraction direction and generates a new pressure in the ink chamber 114. This new pressure causes the ink to be in this time. The column is pushed out, and discontinuity occurs in the ink flow. As a result, the ink column is cut off earlier and the tail of the ink column is prevented from extending for a long time, so that the generation of satellite droplets is suppressed.
[0055]
The piezoelectric element 116a returns to zero at the time point H, and further undergoes natural vibration that gradually attenuates. Similarly, the piezoelectric element 116b returns to zero at the time H ′, and further undergoes natural vibration that gradually attenuates.
[0056]
Here, a specific example is shown. For example, piezoelectric elements 116a and 116b having a thickness of 25 μm are used, and the thickness of the vibration plate 113 is 25 μm. Further, the time parameters and voltage parameters of the drive signals 21a and 21b shown in FIG. 4 are set as follows. The unit of time parameter is μsec, and the unit of voltage parameter is volt.
[0057]
τ1 = 30, τ2 = 10,
t1 = 9, t2 = 2, t3 = 2, t4 = 3, t5 = 11, t6 = 7, t7 = 2, t8 = 8, t9 = 8,
Vp = 35, Va = 33, Vb = 30
[0058]
Next, with reference to FIG. 7 and FIG. 8, the characteristic operation in the ink jet printer of the present invention will be described.
[0059]
FIG. 7 shows the relationship between the ink droplet diameter and the applied voltage obtained when ink droplets are ejected by one or both of the piezoelectric elements 116a and 116b. In this figure, the horizontal axis represents the applied voltage, and the vertical axis represents the ink droplet diameter. Here, a curve 200b with a circle (●) indicates an ink droplet diameter obtained when ejection is performed only by the piezoelectric element 116b disposed at a position farther from the nozzle 118 (that is, the ink supply side). A curve 200a with a triangle mark (▲) indicates an ink droplet diameter obtained when ejection is performed only by the piezoelectric element 116a disposed at a position closer to the nozzle 118 (that is, the nozzle side). A curve 200ab with a square mark (■) indicates an ink droplet diameter obtained when ejection is performed by both the piezoelectric elements 116a and 116b.
[0060]
As is clear from this figure, the smallest ink droplet diameter can be obtained regardless of the applied voltage when ejection is performed by the piezoelectric element 116b on the ink supply side, followed by the piezoelectric element on the nozzle side. When the ejection is performed by 116a, the ink droplets become larger in the order of the ejection by both of the piezoelectric elements 116a and 116b. That is, it can be seen that the ink droplet size can be further reduced when ejection is performed by the ink supply side piezoelectric element 116b rather than the nozzle side piezoelectric element 116a.
[0061]
FIG. 8 shows the relationship between the flying speed of the ink droplets and the applied voltage obtained when the ink droplets are ejected by either one or both of the piezoelectric elements 116a and 116b. In this figure, the horizontal axis represents the applied voltage, and the vertical axis represents the flying speed of the ink droplet. Here, a curve 201b with a circle (●) indicates an ink droplet flying speed when ejection is performed only by the piezoelectric element 116b on the ink supply side, and a curve 201a with a triangle (▲) indicates a nozzle The ink droplet flying speed when ejected by only the piezoelectric element 116a on the side is shown, and a curve 201ab with square marks (■) indicates the ink droplet flying speed when ejected by both the piezoelectric elements 116a and 116b. Indicates.
[0062]
As is clear from this figure, the fastest ink droplet flying speed can be obtained regardless of the applied voltage when ejection is performed by both of the piezoelectric elements 116a and 116b. The ink flying speed decreases in the order of discharging with the piezoelectric element 116b and further discharging with the piezoelectric element 116a on the nozzle side. That is, it can be seen that the ink flying speed can be further increased when ejection is performed by the ink supply side piezoelectric element 116b rather than the nozzle side piezoelectric element 116a.
[0063]
Based on such examination results, in the present embodiment, as described above, the nozzle 118 is used. Far from The piezoelectric element 116a is used for discharging ink droplets, and the nozzle 118 is used. Close to The other piezoelectric element 116b is used for preventing satellite droplets. Therefore, the drive signal 21a is applied to the piezoelectric element 116a, and the drive signal 21b is applied to the piezoelectric element 116b. As a result, the generation of satellite droplets is suppressed, the ink droplets are reduced, and the flight speed is increased.
[0064]
As described above, according to the present embodiment, two piezoelectric elements 116a and 116b are provided for each ink chamber 114 corresponding to each nozzle, and one of the piezoelectric elements 116a is displaced in the ink chamber contraction direction so as to drop ink droplets. Since the ejection operation is started and then the piezoelectric element 116a is displaced so as to return to the ink chamber expansion direction, the other piezoelectric element 116b is displaced from the displacement 0 to the ink chamber contraction direction. The tail of the ink droplet can be cut off early, and as a result, the generation of satellite droplets can be suppressed. In particular, when the return start time of the piezoelectric element 116a (start of displacement in the ink chamber expansion direction) is set at or near the time when the displacement amount of the piezoelectric element 116a in the ink chamber contraction direction is maximized, Can be more effectively suppressed.
[0065]
Further, according to the present embodiment, the pressure for ink droplet ejection is generated by the piezoelectric element 116a closer to the nozzle 118, and the pressure for suppressing satellite droplets is generated by the piezoelectric element 116b far from the nozzle 118. As a result, the generation of satellite droplets can be suppressed, and both the size reduction of the ink droplets used for original recording and the increase in the flying speed can be realized.
[0066]
While the present invention has been described with reference to the embodiment, the present invention is not limited to this embodiment and can be variously changed. For example, in the above-described embodiment, the piezoelectric element 116b serving as the auxiliary pressure generating unit has been described as being used for the purpose of suppressing the generation of satellite droplets. However, the present invention is not limited to this, and the auxiliary pressure generating unit is not limited to this. The present invention can also be applied when used for the above purpose.
[0067]
For example, as a result of observing a change in the meniscus position of the ink after ejection by the ejection piezoelectric element, the present applicant has found that the meniscus position is large even after the short-period vibration of the ejection piezoelectric element has almost disappeared. It has been confirmed that fluctuations (long-period residual vibration) are exhibited, and it is proposed to drive the auxiliary piezoelectric element at an appropriate timing in order to suppress such residual meniscus vibration. Even in such a case, the auxiliary piezoelectric element is arranged closer to the nozzle, and the ejection piezoelectric element is arranged at a position farther from the nozzle, which not only suppresses residual vibration but also speeds up ink droplets. And miniaturization can be achieved together.
[0068]
In addition, when the ink droplet is ejected for the first time after the apparatus is started up, or when the ink droplet is ejected from a nozzle that has not been ejected for a long period of time, the applicant preliminarily applies a preliminary meniscus to the meniscus before ejection. An ink jet printer has been proposed in which discharge from the nozzles can be smoothly performed by applying a small vibration. Even in such a case, the auxiliary piezoelectric element is arranged closer to the nozzle, and the ejection piezoelectric element is arranged at a position farther from the nozzle. And miniaturization can be achieved together.
[0069]
In the example shown in FIG. 6, the displacement start time G of the piezoelectric element 116a in the ink chamber expansion direction and the displacement start time E ′ of the piezoelectric element 116b in the ink chamber contraction direction are made to coincide with each other. The timing may be set so that the piezoelectric element 116b is displaced in the ink chamber contraction direction substantially in parallel with the displacement of the piezoelectric element 116a in the ink chamber expansion direction. The condition for that is that the time parameter in FIG. 4 satisfies both the following conditions (1) and (2).
[0070]
t2 + t3 + t4 <t6 + t7 (1)
t2 + t3 + t4 + t5> t6 (2)
[0071]
Further, in the example shown in FIG. 6, for example, the piezoelectric element 116a starts to return to the original displacement state (in the ink chamber expansion direction) when the piezoelectric element 116a itself is displaced the most after the start of ejection. The return of displacement of the piezoelectric element 116a may be started at other timing. However, when the displacement return start time of the piezoelectric element 116a is set at or near the maximum displacement time, the tail of the ink droplet can be narrowed earlier, so that the ink droplet size can be further reduced. .
[0072]
Further, the setting values of the time parameter and the voltage parameter in FIG. 4 are not limited to the values exemplified above, and can be changed as appropriate. For example, in the present embodiment, the pull-in voltages in both the drive signals 21a and 21b are set to the same Vp, but they may be different from each other.
[0073]
Further, in the above-described embodiment, the case where two piezoelectric elements are provided for one nozzle has been described. However, three or more piezoelectric elements are provided for one nozzle, and these piezoelectric elements are used for ejection and satellite droplet suppression. The piezoelectric element closest to the ink supply side (farthest from the nozzle) may be used for ejection, and the other two or more piezoelectric elements may be used for satellite droplet suppression. By doing so, it is also possible to perform more precise control of satellite droplet suppression. Alternatively, among the three or more piezoelectric elements, only the piezoelectric element closest to the nozzle may be used for preventing satellite droplets, and the other two or more piezoelectric elements may be used for discharging. By doing so, it is also possible to increase the range of ink droplet sizes obtained. In these cases, the displacement capability of each piezoelectric element may be equal to or different from each other.
[0074]
【The invention's effect】
As described above, according to the ink jet printer according to claim 1 and the recording head drive device for ink jet printer according to claim 2, the first pressure generating means is located farther from the nozzle portion than the nozzle portion. The second pressure generating means are provided at positions closer to each other, the same waveform voltage is simultaneously applied to the first pressure generating means and the second pressure generating means to move the meniscus position to a predetermined position, Applying a first voltage to the first pressure generating means Extruded ink with its tail pulled from the nozzle After that, when the first pressure generating means is lowered to the second voltage lower than the first voltage to displace the first pressure generating means in the ink chamber expansion direction, a third voltage lower than the first voltage is applied to the second pressure generating means. As a result, the second pressure generating means is displaced in the ink chamber contraction direction as opposed to the first pressure generating means, so that the auxiliary pressure generating means can assist the ink droplet ejection operation, and It is possible to realize both the miniaturization of ink droplets ejected by the ejection pressure generating means and used for original recording and the increase in the flying speed.
Note that “assisting the ink droplet ejection operation” means that the ink droplet is ejected in a planned state, specifically, the size of the ejected ink droplet is A predetermined correction is made to the discharge pressure generated by the discharge pressure generating means so as to be able to have a flying speed or the like, or to prevent unintended (unnecessary) ink droplets from being discharged. . The same is true for the following description. For example, the second pressure generating means can be configured to generate a pressure for suppressing the generation of incidental ink droplets when ink droplets are ejected.
[0076]
According to the driving method of the recording head for an ink jet printer according to claim 3, the first pressure generating means provided at a position further away from the nozzle portion and a position closer to the nozzle portion are provided. In a recording head for an inkjet printer comprising a second pressure generating means, a voltage having the same waveform is simultaneously applied to the first pressure generating means and the second pressure generating means to move the meniscus position to a predetermined position, Subsequently, the first voltage is applied to the first pressure generating means. Extruded ink with its tail pulled from the nozzle After that, when the first pressure generating means is lowered to the second voltage lower than the first voltage to displace the first pressure generating means in the ink chamber expansion direction, a third voltage lower than the first voltage is applied to the second pressure generating means. Since the second pressure generating means is applied and displaced in the ink chamber contraction direction, contrary to the first pressure generating means, the ink droplet ejection operation can be assisted by the second pressure generating means. At the same time, it is possible to reduce both the size of the ink droplets ejected by the first pressure generating means and used for original recording and the increase in the flying speed.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a schematic configuration of an inkjet printer according to an embodiment of the present invention.
FIG. 2 is a perspective cross-sectional view illustrating a structure example of a recording head.
FIG. 3 is a cross-sectional view illustrating a structural example of a recording head.
4 is a diagram illustrating an example of a waveform of a drive signal output from the head controller in FIG. 1. FIG.
FIG. 5 is a diagram for explaining the relationship between the ejection drive signal waveform shown in FIG. 4 and the change in the ink chamber state and the meniscus position in the nozzle.
6 is a diagram illustrating an example of a relationship between a drive signal waveform illustrated in FIG. 4 and a displacement amount of a piezoelectric element.
FIG. 7 is a diagram illustrating an example of a relationship between a diameter of an ejected ink droplet and a voltage applied to a piezoelectric element.
FIG. 8 is a diagram illustrating an example of a relationship between a flying speed of ejected ink droplets and a voltage applied to a piezoelectric element.
FIG. 9 is an explanatory diagram for explaining a driving method of a conventional inkjet printer.
FIG. 10 is an explanatory diagram for explaining another conventional method of driving an inkjet printer.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Inkjet printer, 11 ... Recording head, 14 ... Head controller, 21a, 21b ... Drive signal, 22 ... Print data, 113 ... Vibration plate, 114 ... Ink chamber, 115 ... Common flow path, 116a, 116b ... Piezoelectric element, 118 ... Nozzle, Vp ... Pull-in voltage, Va ... Discharge voltage, Vb ... Auxiliary voltage, te ... Discharge start timing

Claims (3)

A nozzle portion for ejecting ink droplets;
An ink chamber for supplying ink to the nozzle portion;
A first pressure generating means which is provided at a position further away from the nozzle portion of the wall of the ink chamber and generates a pressure by changing the volume of the ink chamber by being displaced;
A second pressure generating means which is provided at a position closer to the nozzle portion of the wall of the ink chamber and generates a pressure by changing the volume of the ink chamber by being displaced;
Discharge control means for controlling the ink droplet discharge operation by applying a voltage to the first and second pressure generating means,
The discharge control means simultaneously applies a voltage having the same waveform to the first pressure generating means and the second pressure generating means to move the meniscus position to a predetermined position, and subsequently, the first pressure generating means A first voltage is applied to the first pressure generating means to displace the first pressure generating means in the ink chamber contraction direction, and the ink is pushed out from the nozzle portion while being pulled out, and then applied to the first pressure generating means. When the first pressure generating means is displaced in the ink chamber expansion direction by lowering the voltage being lowered to the second voltage lower than the first voltage, the second pressure generating means causes the first pressure generating means to A third voltage lower than the voltage is applied to displace the second pressure generating means in the ink chamber contraction direction. A nozzle unit for ejecting ink droplets, an ink chamber for supplying ink to the nozzle unit, and a wall of the ink chamber, which is provided at a position farther from the nozzle unit, and is displaced to displace the ink chamber. A first pressure generating means for generating pressure by changing the volume; and a position closer to the nozzle portion on the wall of the ink chamber, and changing the volume of the ink chamber by displacing. Driving a recording head for an ink jet printer, comprising: a second pressure generating means for generating pressure; and an ejection control means for controlling the ink droplet ejection operation by applying a voltage to the first and second pressure generating means. A device,
The discharge control means simultaneously applies a voltage having the same waveform to the first pressure generating means and the second pressure generating means to move the meniscus position to a predetermined position, and subsequently, the first pressure generating means A first voltage is applied to the first pressure generating means to displace the first pressure generating means in the ink chamber contraction direction, and the ink is pushed out from the nozzle portion while being pulled out, and then applied to the first pressure generating means. When the first pressure generating means is displaced in the ink chamber expansion direction by lowering the voltage being lowered to the second voltage lower than the first voltage, the second pressure generating means causes the first pressure generating means to A drive device for a recording head for an ink jet printer, wherein a third voltage lower than the voltage is applied to displace the second pressure generating means in the ink chamber contraction direction. A nozzle portion for ejecting ink droplets, an ink chamber for supplying ink to the nozzle portion, and a wall of the ink chamber, which is provided at a position further away from the nozzle portion, and is displaced so as to A first pressure generating means for generating pressure by changing the volume; and a position closer to the nozzle portion on the wall of the ink chamber, and changing the volume of the ink chamber by displacing. A method of driving a recording head for an ink jet printer comprising a second pressure generating means for generating pressure,
A voltage having the same waveform is simultaneously applied to the first pressure generating means and the second pressure generating means to move the meniscus position to a predetermined position, and then the first voltage is applied to the first pressure generating means. After applying and displacing the first pressure generating means in the ink chamber contraction direction to push out ink with the tail pulled from the nozzle portion , the voltage applied to the first pressure generating means is When the first pressure generating means is displaced in the ink chamber expansion direction by falling to a second voltage lower than the first voltage, a third voltage lower than the first voltage is applied to the second pressure generating means. A method of driving a recording head for an ink jet printer, wherein a voltage is applied to displace the second pressure generating means in the ink chamber contraction direction.

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