Inkjet recording device capable of performing ink refresh operation without stopping printing operation

Information

  • Patent Grant
  • 6679586
  • Patent Number
    6,679,586
  • Date Filed
    Friday, September 13, 2002
    22 years ago
  • Date Issued
    Tuesday, January 20, 2004
    20 years ago
Abstract
A sheet-position synchronizing signal is generated once each time a recording sheet is transported by a single-line worth of distance in a sheet feed direction. A print-driving signal and a refresh-driving signal are generated within a time interval of two successive sheet-position synchronizing signal. When the print-driving signal is applied to a piezoelectric element of a nozzle, then a print ink droplet is ejected, thereby a dot is formed on a recording sheet. On the other hand, when the refresh-driving signal is applied to the piezoelectric element, then a negatively-charged refreshing ink droplet is ejected. The refresh ink droplet refreshing ink droplet is deflected by an electric field and collected by a metal mesh without reaching the recording sheet.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to an on-demand type inkjet recording device, and more specifically a line-scanning type high-speed inkjet recording device having a plurality of nozzles.




2. Related Art




There have been proposed a continuous inkjet recording device that continuously ejects ink droplets and an on-demand inkjet recording device that ejects ink droplets only when needed.




Because the on-demand inkjet recording device ejects ink droplets only when needed, non-ink-ejection periods occur during printing operations. When a water-based ink is used in such an on-demand type inkjet recording device, the water-based ink clinging around nozzles evaporates and thus gets dense during the non-ink-ejection periods. Condensed ink prevents proper ink ejection, and in a worse case blocks off the nozzles, thereby disabling ink ejection.




Although such a problem does not occur in the continuous-type inkjet recording device, this is a serious problem in the on-demand type inkjet recording device.




In order to overcome this problem, Japanese Patent-Application Publication No. SHO-57-61576 has proposed a device that performs ink vibration for generating vibration in ink inside the nozzles by applying a driving energy smaller than that for ejecting ink to a piezoelectric element. In this manner, ink solidification is prevented, and thus clogging in the nozzles due to solidified ink is prevented. However, because the ink vibration cannot prevent evaporation of ink, if ink ejection is not performed over a long time period, then the ink will be gradually condensed, resulting in improper ink ejection or even ejection failure.




Japanese Patent-Application Publication NO. HEI-9-29996 has proposed a device that overcomes the above problem by performing ink refresh operations in addition to the ink vibrations. In the ink refresh operations, a recording head ejects refresh ink droplets to remove defective ink from the nozzles. Because the condensed ink is removed from and fresh ink is supplied to the nozzles, preferable ink ejection performance is reliably maintained.




However, this ink refresh operation cannot be performed in a printing region where the recording head is in confrontation with a recording sheet. Accordingly, when the ink refresh operation is needed during the printing operation, it is necessary to stop the printing operation and to move the recording head out of the printing region. This requires a considerable amount of time, and reduces the overall printing speed, and also wastes ink. However, decreasing the frequency of the ink refresh operations in order to accelerate the printing speed and to save the ink increases the danger of nozzle clogging due to condensed ink.




Also, there has been provided a line-scanning-type recording device that includes a recording head formed with nozzle arrays. Because the recording head has a width equivalent to the entire width of a recording sheet, printing is performed on the recording sheet that is being transported in its lengthwise direction relative to the recording head without moving the recording head in the widthwise direction across the recording sheet. With this configuration, the printing operation is performed at high speed.




In this line-scanning type recording head, however, it is difficult to stop the high-speed printing operation for the ink refresh operation. Moreover, it takes long time to move the recording head out of a printing region. Although it is conceivable to perform the ink refresh operation between pages, this is impossible when a continuous sheet rather than cutout sheets is used.




Moreover, once the printing operation is started in the high-speed inkjet recording device, such as the above mentioned line-scanning type recording device, that prints at 100 ppm (page/minute) or more, the recording device is expected to continue the printing more than ten minutes (1,000 pages or more) without stop. Accordingly, in order to satisfy this ten-minute requirement, it is necessary to maintain the proper ink ejection by the ink vibrations alone without the ink refresh operations.




However, the effect of the ink vibration on ink ejection performance lasts for only several seconds to several tens of seconds. Also, because there are usually several million of nozzles formed in a single line-scanning type recording head, it is extremely difficult to keep each of the nozzles in good ejection condition for more than ten minutes by the ink vibration only.




SUMMARY OF THE INVENTION




It is an objective of the present invention to overcome the above problems and to provide an on-demand ink jet recording device capable of maintaining its proper ink ejection without stopping printing operation.




In order to achieve the above and other objects, there is provided an inkjet recording device including an ejection means for ejecting ink droplets and a driving signal generation means for generating a print-driving signal and a maintenance signal. The ejection means ejects print ink droplets as the ink droplets when the print-driving signal is generated, and the ejection means performs maintenance operations when the maintenance signal is generated. The print ink droplets reach a recording medium to form dots on the recording medium. The print-driving signal is repeatedly generated at a predetermined time interval, and the maintenance signal is repeatedly generated at the predetermined interval in a time phase different from the print-driving signal.











BRIEF DESCRIPTION OF THE DRAWINGS




In the drawings:





FIG. 1

a block diagram showing a configuration of a print device according to an embodiment of the present invention;





FIG. 2

is a plan view of a sheet-feed mechanism of the print device of

FIG. 1

;





FIG. 3

is a cross-sectional view of one of nozzle module of the print device;





FIG. 4

is an explanatory plan view showing a nozzle surface of the print device on which a coordinate system is defined;





FIG. 5

is a block diagram showing a configuration of a piezoelectric-element driver of the print head;





FIG. 6

is a general timing chart of the piezoelectric-element driver;





FIG. 7

is a perspective view of the nozzle module;





FIG. 8

is a cross-sectional explanatory view showing ink deflection;





FIG. 9

is a block diagram of a unit serving as both a analog-drive signal generating unit and common-electric-field generation unit of the print device;





FIG. 10

is a timing chart of the piezoelectric-element driver;





FIG. 11

is a first example of an ink-refresh digital-ejection signal;





FIG. 12

is a block diagram of the digital-driving-signal generating unit;





FIG. 13

is a second example of an ink-refresh digital-ejection signal;





FIG. 14

is a timing chart of the piezoelectric-element driver according to a third example of the embodiment;





FIG. 15

is a third example of an ink-refresh digital-ejection signal;





FIG. 16

is a timing chart of the piezoelectric-element driver according to a fourth example of the embodiment; and





FIG. 17

is a fourth example of an ink-refresh digital-ejection signal.











PREFERRED EMBODIMENT OF THE PRESENT INVENTION




Next, an inkjet recording device according to an embodiment of the present invention will be described while referring to the attached drawings.




First, a configuration of an inkjet recording device


1


will be described. As shown in

FIG. 1

, the inkjet recording device


1


includes a sheet-feed mechanism unit


601


and a print head


501


mounted on the sheet-feed mechanism unit


601


. As shown in

FIG. 2

, the sheet-feed mechanism unit


601


includes a guide


603


, a sheet-feed roller


604


, and a rotary encoder


605


. Although not shown in the drawings, the sheet-feed mechanism unit


601


further includes a sheet transport mechanism that transports a rolled uncut recording sheet


602


in a sheet feed direction indicated by an arrow Y, introduces the same to a position directly beneath the print head


501


, which forms images on the recording sheet


602


, and discharges the recording sheet


602


via the sheet-feed roller


604


. The rotary encoder


605


is attached to the sheet-feed roller


604


for detecting the position of the recording sheet


602


. A motor (not shown) is also attached to the sheet-feed roller


604


.




As shown in

FIG. 1

, the print head


501


includes a plurality of nozzle modules


401


and a plurality of piezoelectric-element drivers


402


in one-to-one correspondence with the nozzle modules


401


. In the present embodiment,


20


nozzle modules


401


and, thus,


20


piezoelectric-element drivers


402


are provided.




As shown in

FIG. 1

, the inkjet recording device


1


further includes a buffer memory


102


, a data processing portion


103


, such as a CPU, an ejection-data memory


105


, a sheet-control unit


106


, an analog-drive-signal generating unit


110


, and a digital-drive-signal generating unit


111


. Although not shown in the drawings, a computer system is connected to the inkjet recording device


1


.




The buffer memory is for temporarily storing a single-job worth (plural-page worth) of bitmap data


101


transmitted from the computer system. Although there are various types of bitmap data, the bitmap data


101


used in this embodiment is monochromatic single-bit data, which indicates “print” when the bitmap data


101


is “1”, and indicates “not-print” when the bitmap data


101


is “0”. It should be noted that not only the monochromatic single-bit data, but also color bitmap data or multi-bit data could be easily used in the present invention by using a conventional expansion method. Because such a method is well-known, details are not described here.




During or after the bitmap data


101


is stored in the buffer memory


102


, the data processing portion


103


consecutively converts the bitmap data


101


into ejection data


104


in a format suitable for the inkjet recording device


1


and stores the ejection data


104


into the ejection-data memory


105


. When the ejection data


104


is all stored in the ejection-data memory


105


, then the sheet-control unit


106


outputs a driving signal


107


commanding the sheet-feed mechanism unit


601


to start transporting the recording sheet


602


. The rotary encoder


605


of the sheet-feed mechanism unit


601


outputs a pulse signal


108


indicating the position of the recording sheet


602


to the sheet-control unit


106


.




When the recording sheet


602


reaches a predetermined recording position, the sheet-control unit


106


generates a sheet-position synchronizing signal


109


in accordance with a resolution of the print head


501


, and outputs the signal


109


to the analog-drive-signal generating unit


110


and the digital-drive-signal generating unit


111


, and also to the piezoelectric-element drivers


402


as shown in

FIG. 5

as a latch clock L-CLK.




The analog-drive-signal generating unit


110


generates and outputs an analog drive signal


406


to all the piezoelectric-element drivers


402


. Although the analog-drive-signal generating unit


110


provides the same analog drive signal


406


to all the piezoelectric-element drivers


402


in the present embodiment, it is possible to provide a different analog drive signal to each of the piezoelectric-element drivers


402


if, for example, characteristics vary among the nozzle modules


401


. In the present embodiment, the analog drive signal


406


includes a print-driving signal


905


and a refresh-driving signal


904


(

FIG. 10

) to be described later.




The digital-drive-signal generating unit


111


retrieves the ejection data


104


from the ejection-data memory


105


and transmits the retrieved ejection data


104


to the piezoelectric-element drivers


402


as a digital ejection signal


407


. In the present embodiment, the digital ejection signal


407


includes a print-ink ejection signal


407


P and a refresh-ink ejection signal


407


R (

FIG. 10

) to be described later. Also, the digital-drive-signal generating unit


111


generates and transmits a shift clock S-CLK (

FIG. 5

) to the piezoelectric-element drivers


402


and also to the ejection-data memory


105


.




Next, the nozzle modules


401


of the print head


501


will be described in detail. As shown in

FIG. 5

, each nozzle module


401


is formed with a plurality of nozzles


300


having an orifice


301


, which define a nozzle line L extending in a line direction C. In the present embodiment, each nozzle module


401


is provided with 128 nozzles


300


numbered starting from 0 to 127 (nozzles Nos. 0 through 127). That is, total of 2,560 nozzles


300


(128 nozzles×20 nozzle modules) are provided in the print head


501


. A nozzle pitch with respect to the line direction C is 75 nozzle/inch (npi).





FIG. 3

shows a cross-sectional view of the nozzle module


401


. As shown in

FIG. 3

, each nozzle module


401


is formed with the plurality of nozzles


300


(only one is shown in

FIG. 3

) and a common ink supply channel


308


that distributes ink to the nozzles


300


, and includes an orifice plate


312


having a nozzle surface


301


A, a restrictor plate


310


, a pressure-chamber plate


311


, a supporting plate


313


, and a piezoelectric element supporting substrate


306


. Each nozzle


300


includes an orifice


301


formed in the orifice plate


312


, a pressure chamber


302


formed in the pressure-chamber plate


311


, and a restrictor


307


formed in the restrictor plate


310


. The restrictor


307


fluidly connects the common ink supply channel


308


to the pressure chamber


302


and regulates the ink flow into the pressure chamber


302


.




Further, each nozzle


300


is provided with a diaphragm


303


, and a piezoelectric element


304


attached to the diaphragm


303


by a resilient material, such as a silicon adhesive. The piezoelectric element


304


has a pair of signal input terminals


305


. The piezoelectric element


304


deforms when a voltage is applied to the signal input terminal


305


, and maintains its initial shape when a voltage is not applied. The supporting plate


313


supports the diaphragm


303


.




The diaphragm


303


, the restrictor plate


310


, the pressure-chamber plate


311


, and the supporting plate


313


are all formed from stainless steel, for example. The orifice plate


312


is formed from nickel material. The piezoelectric element supporting substrate


306


is formed from an insulating material, such as ceramics and polyimide.




In the above configuration, ink supplied from an ink tank (not shown) is distributed to the restrictors


307


via the common ink supply channel


308


and supplied into the pressure chambers


302


and the orifices


301


. When a voltage is applied to one of the signal input terminals


305


, then the piezoelectric element


304


deforms, whereby ink inside the pressure chamber


302


is ejected as an ink droplet through the orifice


301


.




In order to facilitate the explanation, x-y coordinate system is defined, as shown in

FIG. 4

, on the nozzle surface


301


A of the print head


501


, wherein the y axis is parallel to the sheet-feed direction Y, and x axis is parallel to a widthwise direction of the recording sheet


602


. A location of the center of each orifice


301


is expressed by a coordinate value (nx, ny).




As shown in

FIG. 4

, the nozzle modules


401


are arranged side by side in the x direction while the nozzle line L defines an angle θ with respect to the x direction. With this configuration, a nozzle pitch with respect to the y direction (sheet feed direction Y) is increased more than 75 npi, which is the nozzle pitch with respect to the line direction C. Here, in the present embodiment, images with 309 dot/inch (dpi) in both the x and y directions are formed, so that the angle θ is set such that tan θ=4. In this manner, the nozzle pitch in the x direction becomes 309 npi, which is 20 times the nozzle pitch in the y direction.




The nozzle modules


401


has a length of approximately 42 mm in the y direction and a width of approximately 8.3 inches in the x direction, enabling to form images on a recording sheet having a width of a A4-sized cutout sheet. It should be noted that in a multicolor printer, four or more print heads


501


having the above configuration are provided for different colored ink, such as cyan, magenta, yellow, and black. In the present embodiment, however, it is assumed that only a single print head


501


is provided in order to simplify the explanation.




Next, configuration of the piezoelectric-element drivers


402


will be described in detail. As shown in

FIG. 5

, each piezoelectric-element driver


402


includes 128 analog switches


403


in one-to-one correspondence with the nozzles


300


, the latch


404


connected to all the analog switches


403


, and a shift register


405


connected to the latch


404


. The digital ejection signal


407


and the shift clock S-CLK both from the digital-drive-signal generating unit


111


are input to the shift register


405


. The digital ejection signal


407


is a 128-bit serial data corresponding to the 128 nozzles


128


. The digital ejection signal


407


having a value “1” indicates “ejection”, and the digital ejection signal


407


having a value “0” indicates “non-ejection”. In accordance with the digital-ejection signal


407


, the shift register


405


outputs a 128-bit parallel data to the latch


404


. In addition to the 128-bit parallel data, the latch clock L-CLK is also input to the latch


404


.




The analog switch


403


has a switch terminal


403




a


, an input terminal


403




b


, and an output terminal


403




c


. An output signal from the latch


404


is input to the switch terminal


403




a


, and the analog drive signal


406


is input to the input terminal


403




b


. When a signal of “1” is input to the switch terminal


403




a


, then the analog switches


403


output, through the output terminal


403




c


, the analog drive signal


406


received at the input terminal


403




b


, whereas when a signal of “0” is input to the switch terminal


403




a


, then the analog switches


403


open the output terminal


403




c


. Here, the output terminal


403




c


is connected to one of the signal input terminals


305


of the corresponding nozzle


300


, and the another one of the signal input terminals


305


is grounded. That is, the analog drive signal


406


is a driving signal commonly used for all the 128 nozzles


300


of the corresponding nozzle module


401


in order to drive the 128 piezoelectric elements


304


. Although the analog drive signal


406


of the present embodiment has a trapezoid waveform as shown in

FIG. 6

, there have been provided various kinds of waveforms that could be used in the present embodiment.





FIG. 6

shows a general timing chart of the piezoelectric-element drivers


402


. As shown, the digital ejection signal


407


is sequentially stored in the shift register


405


in synchronization with the shift clock S-CLK. When 128 digital ejection signals


407


is stored, all the 128 digital ejection signals


407


are stored in the latch


404


at once in synchronization with the latch clock L-CLK and output to the switch terminal


403




a


of the analog switches


403


. At the same time, the analog drive signal


406


is input to the input terminal


403




b


of the analog switches


403


. As a result, ink droplets are ejected from the nozzles


300


corresponding to the digital ejection signal


407


of “1”, whereas no ink droplet is ejected from the nozzles


300


corresponding to the digital ejection signal


407


of “0”.




Here, because the resolution of the images in the y direction is 309 dpi as mentioned above, the sheet-position synchronizing signal


109


(latch clock L-CLK) is generated once each time the recording sheet


602


is transported by a distance of {fraction (1/309)} inch in the sheet feed direction Y. In other words, the sheet-position synchronizing signal


109


(latch clock L-CLK) is generated with a time interval D


1


(

FIG. 6

) equivalent to a time duration required for forming one-line worth of image. However, this time duration will fluctuate depending on variation in sheet feed speed.




In addition to the above configuration, the inkjet recording device


1


is also provided with an ink-droplet deflecting mechanism, which will be next described in detail.




As shown in

FIGS. 7 and 8

, the ink-droplet deflecting mechanism includes an ink-collect electrode


801


and a back electrode


805


. The ink-collect electrode


801


is a plate-shaped electrode with a thickness of 0.4 mm, and is attached on the nozzle surface


301


A in parallel with the nozzle line L with a distance of 0.3 mm therebetween such that there is a uniform positional relationship between the ink-collect electrode


801


and each nozzle


300


. The ink-collect electrode


801


and the orifice plate


312


are both grounded. Provided in a surface


801


A of the ink-collect electrode


801


is a metal mesh


802


, which has a length longer than that of the ink-collect electrode


801


, so that as shown in

FIG. 7

both ends


802


A of the metal mesh


802


protrude from the ink-collect electrode


801


. A pair of tubes


803


made of vinyl are attached to the ends


802


A and connected to pumps (not shown).




The back electrode


805


, which is electrically insulated plate-shaped electrode, extends rear side of the recording sheet


602


in the nozzle direction C, which is perpendicular to the sheet surface of

FIG. 8

, such that there is a uniform positional relationship between the back electrode


805


and each nozzle


300


. In the present embodiment, a distance from the orifice


301


to the surface of the back electrode


805


is 1.5 mm.




The ink-droplet deflecting mechanism of the present invention further includes, as shown in

FIG. 1

, a common-electric-field generation unit


112


and a power source


114


. The common-electric-field generation unit


112


generates a common-electric-field signal


113


in synchronization with the sheet-position synchronizing signal


109


. The power source


114


generates a high voltage in accordance with the common-electric-field signal


113


, and applies the same to the back electrode


805


. Because the orifice plate


312


and the ink-collect electrode


801


are both grounded, when the high voltage is applied to the back electrode


805


, then an electric field is generated among the orifice plate


312


and the ink-collect electrode


801


and the back electrode


805


.




In practice, as shown in

FIG. 9

, a single unit


700


serves as both the analog-drive-signal generating unit


110


and the common-electric-field generation unit


112


. The unit


700


includes a line-address generation unit


1001


, an in-line address generation unit


1002


, a memory


1003


, a digital-to-analog (D/A) converter


1004


, and an amplifier


1005


. The line-address generation unit


1001


and the in-line address generation unit


1002


are formed of binary counters.




Here, “line” indicates a dot line extending in the widthwise direction on the recording sheet


602


onto which ink droplets ejected from the nozzles


300


form dots. In other words, “line” represents a location of each nozzle


300


or the print head


501


relative to the recording sheet


602


with respect to the sheet feed direction Y.




The line-address generation unit


1001


is reset when a print-start signal (not shown) is generated, counts up the sheet-position synchronizing signals


109


, and generates 7-bit line address data


1006


. The line-address generation unit


1001


repeatedly counts 128 sheet-position synchronizing signals


109


to repeatedly generate 128 sets of the line address data


1006


of “0” through “127” (0, 1, 2, . . . , 127, 0, 1, . . . ) indicating line addresses. The in-line address generation unit


1002


is reset each time the sheet-position synchronizing signal


109


is generated, counts up a high-frequency clock


1007


, and generates 10-bit in-line address data


1008


. In the present example, the high-frequency clock


1007


is 4 Mhz, and the sheet-position synchronizing signal


109


is generated approximately once every 200 μs. Hence, the in-line address generation unit


1002


counts approximately 800 high-frequency clock


1007


within 200 μs.




The memory


1003


is an ordinary memory that receives address data, outputs data, and prestores data that is necessary to generate the print-driving signal


905


and the refresh-driving signal


904


. In the present embodiment, the memory


1003


receives the 7-bit line address data


1006


and the 10-bit in-line address data


1008


, and outputs 10-bit data


1009


and 2-bit common-electric-field signal


113


once every 250 ns. The 10-bit data


1009


is D/A converted and amplified through the D/A converter


1004


and the amplifier


1005


to generate the analog drive signal


406


(refresh-driving signal


904


or print-driving signal


905


)





FIG. 10

shows a timing chart of the piezoelectric-element driver


402


and the ink-droplet deflecting mechanism according to the present embodiment. When the sheet-position synchronizing signal


109


is generated, 128-bit print-ink ejection signal


407


P is output during the first 80 μs and 128-bit refresh-ink ejection signal


407


R is output during the subsequent 80 μs to the shift register


405


of the piezoelectric-element driver


402


in synchronization with the shift clock S-CLK. Because the time interval of the sheet-position synchronizing signals


109


is about 200 μs, about 40 μs left after the 128-bit refresh-ink ejection signal


407


R is output. This 40 μs time duration serves as a margin that absorbs fluctuation in generation timing of the sheet-position synchronizing signal


109


, i.e., the sheet feed speed. The latch clock L-CLK includes a first latch clock


902


and the second latch clock


903


. The first latch clock


902


is output in synchronization with the sheet-position synchronizing signal


109


in order to latch the refresh-ink ejection signal


407


R that the shift register


405


have previously received, and the second latch clock


903


is output 40 μs after the first latch clock


902


in order to latch print-ink ejection signal


407


P which the shift register


405


have previously received.




The refresh-driving signal


904


is generated within 40 μs after the first latch clock


902


, and the print-driving signal


905


is generated within 40 μs after the second latch clock


903


. That is, both the refresh-driving signal


904


and the first latch clock


902


are repeatedly generated in the same time interval but in a different time phase.




The common-electric-field signal


113


has a deflection voltage of +1.5 kV with pulses P having a charging voltage of −1.5 kV. The pulse P has a width of 10 μs whose center is concurrent with an ink-droplet separation timing Ts (described later).




An ink droplet ejected in response to the print-driving signal


905


is a print ink droplet to print a dot on the recording sheet


602


, whereas an ink droplet ejected in response to the refresh-driving signal


904


is a refreshing ink droplet, which will be next described in detail while referring to FIG.


8


. First, the refreshing ink droplet will be described.




When the refresh-driving signal


904


is selectively applied to the piezoelectric elements


304


, a refreshing ink droplet


806


shown in

FIG. 8

is ejected. More specifically, ink is ejected through the orifice


301


with its rear portion still connected to a meniscus


301


M. When the ejected ink elongates to a certain length, then the rear end separates from the meniscus


301


M at the above-mentioned ink-droplet separation timing Ts, whereby the refreshing ink droplet


806


is formed. There has been known that the ink-droplet separation timing Ts maintains constant regardless of change in environmental factors or in the ink ejection speed.




In the present example, as shown in

FIG. 10

, the back electrode


805


is applied with the common-electric-field signal


113


of −1.5 kV around the ink-droplet separation timing Ts. Because the orifice plate


312


is grounded as described above, this generates an electric field E


1


shown in FIG.


8


. Although the direction of the electric field E


1


slightly inclines to the left in

FIG. 8

due to the existence of the ink-collect electrode


801


, the direction near the orifice plate


312


is substantially perpendicular to the recording sheet


602


, so that the refreshing ink droplet


806


is positively charged.




Then, almost immediately after the ink-droplet separation time Ts, the voltage of the common-electric-field signal


113


returns to the deflection voltage of +1.5 kV, so that an electric field E


2


is generated. The electric field E


2


has an upward direction and so decelerates the flying speed of the positively charged refreshing ink droplet


806


and forces the refreshing ink droplet


806


back toward the orifice plate


312


. Here, because the direction of the electric field E


2


is slightly inclined to the right in

FIG. 8

due to the ink-collect electrode


801


, thus deflected refreshing ink droplet


806


reaches the metal mesh


802


on the ink-collect electrode


801


without returning to the orifice


301


. In this manner, the refreshing ink droplet


806


is collected by the metal mesh


802


. Then, the ink reaches the tubes


803


due to the capillary action and discharged therethrough. Because the refreshing ink droplet


806


is collected to the metal mesh


802


without reaching to the recording sheet


602


, it is possible to perform the ink refresh operations with the print head


501


facing to the recording sheet


602


, that is, without moving the print head


501


out of a print region.




The position where the refreshing ink droplet


806


is reversed in its flying direction is determined in a formula:








L=m×vo




2


/(2×


q×E


)






wherein




L is a maximum distance from the orifice


301


toward the back electrode


805


, i.e., a vertical direction V in this embodiment;




m is a mass of the refreshing ink droplet


806


;




vo is an ejection velocity of the refreshing ink droplet


806


;




q is a charging amount of the refreshing ink droplet


806


; and




E is a component of the electric field E


2


in the vertical direction V.




From the above formula, it is understood that the ejection speed can be set slow so as to reliably collect the refreshing ink droplets


806


in the metal mesh


802


. Accordingly, in the present embodiment, the ejection speed of print ink droplets is set to 8 m/s, whereas the ejection speed of refreshing ink droplets


806


is set to 4 m/s.




A simple method to control the ejection speed is to change the electric current flowing through the piezoelectric element


304


. In the present embodiment, the print-driving signal


905


has a voltage of 24 V, whereas the refresh-driving signal


904


is set to smaller voltage than the print-driving signal


905


to achieve the velocity vo of 4.0 m/s.




Next, a print ink droplet will be described. When the print-driving signal


905


is applied to the piezoelectric element


304


, ink is ejected from the corresponding nozzle


300


. When the ejected ink elongates to a certain length, the ink is separated from the meniscus


301


M, whereby a print ink droplet (not shown) is formed. Although it is preferable not to apply any voltage to the back electrode


805


at the time of the separation, the common-electric-field signal


113


is maintained to the deflecting voltage of +1.5 kV at this time in order to facilitate the deflection of the refreshing ink droplet


806


.




Accordingly, the print ink droplet is negatively charged. The negatively charged print ink droplet flies through the electric field E


2


, which accelerates the flying speed of the print ink droplet, and then the print ink droplet reaches the recording sheet


602


to form a dot thereon. Although the print ink droplet is slightly deflected to the left in

FIG. 8

due to the ink-collect electrode


801


, the print ink droplet is hardly influenced by the electric field E


2


because of its high ejection speed (8 m/s) and thus the deflection amount thereof is insignificant.





FIG. 12

shows a configuration of the digital-drive-signal generating unit


111


. The digital-drive-signal generating unit


111


includes a digital ejection signal memory


1501


, a temporary memory


1502


, an inverter


1503


, an AND circuit


1504


, and a data selector


1505


. The digital ejection signal memory


1501


receives the line address data


1006


from the line-address generation unit


1001


shown in FIG.


9


and the sheet-position synchronizing signal


109


from the sheet-control unit


106


, and outputs an ink-refresh digital ejection signal


1506


to the AND circuit


1504


. The ink-refresh digital-ejection signal


1506


is prestored in the digital ejection signal memory


1501


for each orifice


301


. The ink-refresh digital ejection signal


1506


includes signals of “1” and “0” for realizing a predetermined refresh ink ejection timing, such as the timing shown of

FIG. 11

to be described later.




The inverter


1503


outputs an inverted signal


1507


of the ejection data


104


to the AND circuit


1504


. Based on the inverted signal


1507


and the ink-refresh digital ejection signal


1506


, the AND circuit


1504


outputs the refresh-ink ejection signal


407


R that is either “1” or “0”.




The ejection data


104


is input to the temporary memory


1502


also. Upon reception of a latch clock L-CLK, one-line worth of ejection data


104


is stored in the temporary memory


1502


. Upon reception of a subsequent latch clock L-CLK, the temporary memory


1502


outputs the one-line worth of ejection data


104


as the digital ejection signal


407


P to the data selector


1505


. Then, within a time interval of the successive two latch clocks L-CLK, the data selector


1505


outputs the refresh-ink ejection signal


407


R and the print-ink ejection signal


407


P in this order. In this configuration, when the print-ink ejection signal


407


P is “1”, then the refresh-ink ejection signal


407


R is automatically set to “0”, so that image forming operation will not be performed simultaneously with the ink refresh operation. Here, if these operations are performed at the same time, the ink ejection frequency increases to double, preventing stabilized ink ejection. Because there is no need to perform the ink refresh operation as long as print ink droplets are ejected, this configuration is rational. On the other hand, when the print-ink ejection signal


407


P is “0”, then the digital-ejection signal


407


will be either “1” or “0” depending on the ink-refresh digital-ejection signal


1506


.




Next, a first example of ink refresh operation performed in the print device


1


will be described. In the present example, the line-address generation unit


1001


(

FIG. 9

) is not used, so only the in-line address data


1008


is input to the memory


1003


, and no line address data


1006


is output to the memory


1003


.





FIG. 11

shows an ink-refresh digital-ejection signal


1506


(refresh-ink ejection signal


407


R) of the first example. In

FIG. 11

, the ink-refresh digital-ejection signal


1506


is represented by a resultant dot pattern on the recording sheet


602


assuming that ejected refreshing ink droplets


806


reach the recording sheet


602


in order to facilitate the explanation. In other words, hatched cells represent the ink-refresh digital-ejection signal


1506


of “1”, i.e., “ejection”, and white cells represent the ink-refresh digital-ejection signal


1506


of “0”, i.e., “non ejection”. This is also same in

FIG. 13

(describe later). Nos. 0 through 127 assigned to the 128 nozzles of a representative nozzle module


401


are shown in the horizontal direction, line Nos. are shown in the vertical direction. In the example shown in

FIG. 11

, the lines are repeatedly numbered starting from 0 in 309 dpi. In the example of

FIG. 11

, the ink-refresh digital-ejection signal


1506


of “1” is generated once every four lines, i.e., a period Pd is 4 (Pd=4).




Because the line direction C of the nozzles


300


is unparallel to the widthwise direction (x direction) as shown in

FIG. 3

, the actual ink ejection timing differs among the 128 nozzles


300


even through all the nozzles


300


eject refreshing ink droplet in the same lines. Accordingly, interferes among the nearby nozzles


300


are prevented, properly ejecting the refreshing ink droplets


806


.




In this example, the ink-refresh digital-ejection signal


1506


for realizing the specific pattern shown in

FIG. 11

is prestored in the digital-ejection signal memory


1501


. However, it is possible that the processing portion


103


generates ink-refresh digital-ejection signal


1506


to achieve an optimum pattern in accordance with various parameters by, for example, using software if sufficient time is secured for executing such an operation before printing. In this case, the ink-refresh digital-ejection signal


1506


is not stored in the digital-ejection signal memory


1501


, but is generated by the data processing portion


103


and output to the piezoelectric-element driver


402


through the digital-driving-signal generating unit


111


.




For example, when the recording sheet


602


is lifted upward, there is a danger that the refreshing ink droplets


806


may reach the recording sheet


602


without being collected onto the metal mesh


802


and may form undesirable visible dots on the recording sheet


602


. Taking this danger into consideration, the data processing portion


103


can generate an ink-refresh digital-ejection signal


1506


while referring to the ejection data


104


, i.e., type of the images to be formed. For example, fine images, such as fine characters, graphs, images that require accurate whiteness, or the like, will be easily misinterpreted if unnecessary dots are formed on the recording sheet


602


by refresh ink droplets. In this case, the data processing portion


103


can control so as not to perform the ink refresh operation or to decrease the frequency of the ink refresh operation.




Also, clogging in the orifice


301


more likely occurs in arid environment, and so the period Pd can be set small when the ambient air is dry. For example, the period Pd is set to 2,048 when the humidity is equal to or greater than 70%, 1,024 when the humidity is 60% through 69%,


512


when the humidity is 50% through 59%, and


256


through


128


when the humidity is equal to or less than 49%. These settings of the period Pd can be manually made by a user or automatically made based on a detection signal from well-known temperature/humidity sensor.




Because the ink-collect electrode


801


is usually dry at the time of when a power switch of the inkjet recording device


1


is turned ON, the period Pd at this time can be set small to wet the ink-collect electrode


801


quickly with ink so as to maintain the high humidity around the orifice


301


. In this manner, nozzle clogging can be prevented.




Next, a second example of the ink refresh operation performed in the print device


1


will be described.

FIG. 13

shows a second example of the ink-refresh digital-ejection signal


1506


. In this embodiment, the period Pd=8, and the hashed cells representing “1” do not align in the x direction, but are distributed at random. In this case, even if the refreshing ink droplets


806


accidentally reach and form dots on the recording sheet


602


without being collected by the metal mesh


802


when, for example, the recording sheet


602


flows upward for some reasons, thus formed dots will be hardly noticed and thus will hardly degrade the overall image quality. This contrasts to the above-described first example where there is a danger that the refreshing ink droplet


806


may form on the recording sheet


602


a visible straight line in the x direction, which users may misunderstand consists original images.




Next, a third example of the ink refresh operation performed in the print device


1


will be described with reference to

FIGS. 9

,


14


, and


15


.




As described above, the ejection speed of the refreshing ink droplet


806


is set to 4 m/s so as to reliably collect the refreshing ink droplet


806


in the metal mesh


802


. However, when the ejection speed is set slow, such as 4 m/s, then the ejection performance will become less stable, so that it is necessary to suppress the variation in ejection speeds of the refreshing ink droplet


806


among the nozzles


300


as much as possible.




Moreover, if the ejection speed drops as low as 2 m/s, then even slight change in ink clinging around the nozzle will undesirably angle the ink ejection direction or collect more ink around the nozzle. Such an ink accumulated near the nozzle will prevent ink ejection and worsen ink ejection performance. In worse case, ink ejection speed further decreases, whereby ink is scattered around to nearby nozzles, and ink ejection become impossible. In order to prevent these problems, it is necessary to achieve the ink ejection speed of 4 m/s precisely.




When there are a plurality of nozzles as in the present embodiment, a single print-driving signal


905


is used for driving all the nozzles


300


, so that generally different print-driving signals


905


cannot be supplied individually to the nozzles


300


because of mechanical reasons. However, in the present embodiment, the refresh-driving signal


904


individually controls the ejection speed of the refresh ink droplet


806


for each of the nozzles


300


in the following manner so as to achieve precise ink ejection speed of 4 m/s.





FIG. 14

shows a timing chart of the piezoelectric-element drivers


402


that is used in the present example. In the present example, the line-address generation unit


1001


shown in

FIG. 9

is used and repeatedly counts


128


sheet-position synchronizing signals


109


to repeatedly generate 128 sets of the line address data


1006


of “0” through “127” (0, 1, 2, . . . , 127, 0, 1, . . . ) indicating line addresses. The memory


1003


stores 128 different refresh-driving signals


904


-


1


through


904


-


128


, which are sequentially retrieved. The voltage of the refresh-driving signals


904


-


1


to


194


-


128


is set to gradually increase in this order such that the refresh-driving signal


904


-


1


has the smallest voltage, and the refresh-driving signal


904


-


128


has the largest voltage.




More specifically, a voltage with which the ejection speed of 4 m/s is achieved in average is set to 100%, then the voltage of the refresh-driving signal


904


-


1


is set to 80% of the voltage, and the voltage of the refresh-driving signal


904


-


128


is set to 120% of the voltage. The difference in voltage between successive refresh-driving signals


904


is set depending on the number of the corresponding nozzles


300


.





FIG. 15

shows the ink-refresh digital-ejection signal


1506


and the output timing of the refresh-driving signal


904


according to the third example. Here, stable ink-jet performance of the nozzles


300


can be maintained by performing the ink refresh operations in 1,000-times frequency of the printing ink ejection. Accordingly, it is possible to perform ink refresh in each nozzle


300


using appropriate one of the refresh-driving signals


904


-


1


to


904


-


128


by generating these signals


904


-


1


to


904


-


128


in different line addresses 0 through 127 to which the refresh-driving signals


904


-


1


to


904


-


128


are assigned.




More specifically, when the ejection speed of ink droplets ejected from a certain nozzle


300


in response to a refresh-driving signal


904


with 100% voltage is too fast, then a refresh-driving signal


904


with less than 100% voltage is selected for the certain nozzle


300


. When the ejection speed of ink droplets ejected from a different nozzle


300


in response to a refresh-driving signal


904


with 100% voltage is too slow, then a refresh-driving signal


904


with more than 100% voltage is selected for the different nozzle


300


. This is because the ink ejection speeds can be controlled by adjusting the voltage of the refresh-driving signal


904


as described above referring to the formula.




In the example shown in

FIG. 15

, the ejection speed of the nozzle No. 0 is fast, so that the refresh-driving signal


904


-


1


with the 80% voltage is selected for the nozzle No. 0. The refresh-driving signal


904


-


2


with the 80.8% voltage is selected for the nozzle No. 1 because the ejection speed of the nozzle No. 1 is fast but slightly slower than the nozzle No. 0. In this manner, an appropriate one of the refresh-driving signals


904


-


1


to


904


-


128


, i.e., the line addresses 0 to 127, is selected for each one of the nozzles


300


. Then, the ink refresh is performed in a nozzle


300


in a line address corresponding to a selected refresh-driving signal


904


-


1


to


904


-


128


.




The period Pd is set to 1,024 in this example, so the line addresses 0 through 127 repeats eight times (eight cycles) in the period Pd of 1,024. As shown in

FIG. 15

, the nozzle No. 0 performs ink refresh when the line address is 0, that is, in response to the refresh-driving signal


904


-


1


. The piezoelectric-element driver


402


includes no other nozzles that eject ink refresh droplets when the line address is 0.




Here, it should be noted that unlike

FIGS. 11 and 13

of the first and second examples,

FIG. 15

shows the real output timing of the ink-refresh digital-ejection signal


1506


, rather than a resultant dot pattern formed on the recording sheet


602


by ejected refreshing ink droplets


806


. The same is true in

FIG. 17

(described later).




When the line address is 1, no nozzle


300


performs ink refresh. When the line address is 2, the nozzle No. 2 performs ink refresh. When the line address is 3, no nozzles


300


performs ink refresh. In this manner, all the nozzles


300


perform the ink refresh once by the time the line address counts up to 127. When the line addresses repeats seven more times from 0 to 127 without the nozzles


300


performing ink refresh, the line number increases to 1,024, then the above operation is repeated starting from the nozzle No. 0.




In this manner, uniform ejection speeds of refresh ink droplets are achieved while suppressing the variation in ejection speeds among the nozzles


300


, so that stable ink refresh can be maintained.




Here, in order to avoid interference among nozzles


300


, it is preferable to control nozzles


300


that are located proximate to one another and assigned to the same refresh-driving signal


904


-n to perform the ink refresh at different cycles, so that the ink refresh timing differs among these nozzles


300


, that is, a large number of the proximate nozzles


300


are prevented from performing ink refresh at the same time.




Next, a fourth example of the ink refresh operation performed in the print device


1


will be described while referring to FIG.


16


. In this embodiment, the ink refresh and ink vibration are used in combination. As described above, ink vaporizes more easily when humidity is lower, so that the ink refresh frequency can be increased when the humidity is low. However, increasing the frequency wastes ink, so that it is unfavorable that the period Pd be less than 128. Although it is conceivable to provide an ink collecting system to prevent wasting ink with using smaller period Pd, this will increase the number of components and thus costs of the inkjet recording device


1


.




However, if the period Pd is set too large in a dry environment, then the ink will easily get dense and disable normal ink ejection. Accordingly, in the present example, an ink vibration is performed in addition to the ink refresh.





FIG. 16

shows a timing chart of the piezoelectric-element driver


402


. The refresh-driving signal


904


is generated once every 4 lines, that is, in lines 4×n (n=0,1,2, . . . ), a vibration signal


1301


is generated three times every four lines. That is, the lines Nos. n through n+3 constitute one group, and the same operation is performed in each group. The vibration signal


1301


is for vibrating the meniscus


301


M but not for ejecting any ink. There have been proposed vibration signals with various waveforms. For example, the vibration signal may be generated by lowering the voltage of the ejection signal, or may be generated with totally different waveform from that of the ejection signal. In the present embodiment, the trapezoidal waveform with small voltage shown in

FIG. 16

is used.




Because the refresh-driving signal


904


is generated only once every four lines (4×n), the common-electric-field signal


113


will have the charging voltage of −1.5 kV only once every 4 lines. This elongates the time duration for applying the deflection voltage to the back electrode


805


while the refreshing ink droplets


806


are in flight, thereby making easier to collect the refreshing ink droplet


806


.





FIG. 17

shows an ink-refresh digital-ejection signal


1506


(refresh-ink ejection signal


407


R) of the present example. 128 nozzles from No. 0 through No. 127 are shown in the horizontal direction. In the vertical direction, the line Nos. and the line addresses are shown. In the present example, the line addresses repeat from 0 through 511. The hatched cells represent the ink-refresh digital-ejection signal


1506


of “1” and the white cells represent the signals of “0”. As shown in

FIG. 17

, the analog drive signal


406


for all of the nozzles becomes refresh-driving signal


904


in lines No. 4n (N=0,1,2, . . . ) which are encircled with a bold line. In the remaining lines, the analog drive signal


406


for all the nozzles become the vibration signal


1301


. In the present embodiment, when the line address is 4×n (n=0,1,2 . . . ), the ink refresh droplet is ejected only from the nozzle No. n.




Specifically, when the line No. and the line address are both 0, the ink-refresh digital-ejection signal


1506


for the nozzle No. 0 is 1, so that a refresh ink droplet is ejected from only the nozzle No. 0. When the line No. and the line address are both 1, the ink-refresh digital-ejection signal


1506


for the nozzle No. 0 is 1, so that the ink vibration is performed only in the nozzle No. 0. When the line number and the line address are both 2 and when the both are 3, the ink-refresh digital-ejection signal


1506


for the nozzles Nos. 1 and 2 are 1, so that the ink vibration is performed in the nozzles Nos. 1 and 2.




When the line No. and the line address are both 4, the ink-refresh digital-ejection signal


1506


for the nozzle No. 1 is 1, so that the refresh ink droplet is ejected from only the nozzle No. 1. When the line No. and the line address are both 5, the ink-refresh digital-ejection signal


1506


for the nozzle No. 2 is 1, so that the ink vibration is performed in the nozzles Nos. 2. When the line No. and the line address are both 6 and when the both are 7, the ink-refresh digital-ejection signal


1506


for the nozzles Nos. 2 and 3 are 1, so that the ink vibration is performed in the nozzles Nos. 2 and 3.




In the same manner, the operation is performed until the line No. and the line address both increase to 511. Then, the line address returns to 0 and then the same operation is repeated.




As described above, when the line address is 4×n (n=0,1,2 . . . ), the ink refresh droplet is ejected only from the nozzle No. n. Accordingly, the refresh-driving signal


904


-n at that time can be a refresh-driving signal


904


prepared only for the nozzle No. n. Therefore, it is possible to determine an optimum one of rate of voltages R-


1


through R-


128


of the refresh-driving signal


904


for each of the nozzles


300


beforehand by performing experiments and to store waveforms specially prepared only for corresponding nozzles


300


into the memory


1003


.




In this manner, the variation in ejection speeds of refresh ink droplets among the nozzles


300


can be suppressed, so the stable ink ejection can be performed. Also, in the present embodiment in the ink refresh operations, ink vibration is performed five times before the ink refresh is performed each time. For example, the nozzle No. 2 performs ink vibration in lines addresses of 2, 3, 5, 6, 7, and then performs ink refresh in the line address of 8. The nozzle No. 2 does not perform ink vibration in line address of 4 because the refresh-driving signal


904


is generated in the line address 4.




In the present embodiment, the number of the ink vibration before the ink refresh is set to 5. This number has been determined in the following manner.




The inventers have conducted experiments for confirming the effect of the ink vibration frequency (5 kHz at maximum) and the number of ink vibration on the ink ejection performance of the nozzles


300


. Through the experiments, ink vibration frequency of 5 kHz, which equals to a dot frequency, is confirmed good for maintaining nozzle performances stable. On the other hand, the number of the ink vibration cannot be too many nor too small. Performing the ink vibration too many times will facilitate evaporation of the ink and thus clogging in the nozzles


300


. Performing the ink vibration appropriate times is confirmed providing maximum effect.




In the present embodiment, performing ink vibration about 100 times at 5 kHz during 20 msec before each ink ejection is confirmed optimum. It is conceivable and possible to vibrate ink during 20 msec immediately before the print-ink ejection is performed by using software installed into the data processing portion


103


. However this is generally difficult. In the present embodiment, ink is vibrated during 20 msec immediately before the refresh-ink ejection signal


407


R is generated. Because the refresh-ink ejection signal


407


R is periodically generated, generation of the refresh-ink ejection signal


407


R is easily predicted, and thus the control of the ink vibration is relatively easy.




According to the present example, the variation in ink ejection speeds among the nozzles


300


is suppressed by generating a different refresh-driving signal


904


for each of the nozzles


300


. Moreover, the vibrating ink immediately before the refresh ink ejection makes the ink refresh more stable.




Although the refresh-driving signal


904


is generated once ever four lines, and the vibration signal


1301


is generated three time every four lines, the frequency of the refresh-driving signal


904


could be increased or decreased in accordance with the ambient environment.




As described above, according to the present invention, it is possible to perform the ink refresh operation during the printing. Therefore, there is no need to stop printing or move the print head


501


out of a print region in order to perform the ink refresh operation.




While some exemplary embodiments of this invention have been described in detail, those skilled in the art will recognize that there are many possible modifications and variations which may be made in these exemplary embodiments while yet retaining many of the novel features and advantages of the invention.



Claims
  • 1. A drop-on-demand inkjet recording device comprising:an ejection means for ejecting ink droplets; and a driving signal generation means for generating a print-driving signal and a maintenance-driving signal, wherein the ejection means ejects print ink droplets as the ink droplets based on the print-driving signal, and the ejection means performs maintenance operations based on the maintenance-driving signal, and wherein the print ink droplets reach a recording medium to form dots on the recording medium, wherein the print-driving signal is repeatedly generated at a predetermined time interval, and the maintenance-driving signal is repeatedly generated at the predetermined interval in a time phase different from the print-driving signal.
  • 2. The drop-on-demand inkjet recording device according to claim 1, wherein the predetermined time interval is a time duration required for forming a single dot on the recording medium.
  • 3. The drop-on-demand inkjet recording device according to claim 1, further comprising an electric-field generation means for generating an electric field, and a collecting means, wherein the maintenance-driving signal is a refresh-driving signal, and the ejection means ejects refresh ink droplets based on the refresh-driving signal, and the electric field deflects the refresh ink droplets, and the collecting means collects the deflected refresh ink droplets, all of the refresh ink droplets being collected by the collecting means.
  • 4. The drop-on-demand inkjet recording device according to claim 3, wherein the maintenance-driving signal is one of the refresh-driving signal and a vibration-driving signal, and the ejection means performs ink vibration based on the vibration-driving signal.
  • 5. The drop-on-demand inkjet recording device according to claim 4, wherein the drive signal generation means selectively generates the refresh-driving signal and the vibration-driving signal in accordance with humidity of ambient air.
  • 6. The drop-on-demand inkjet recording device according to claim 1, wherein the maintenance-driving signal is a vibration-driving signal, and the ejection means performs ink vibrations based on the vibration-driving signal.
  • 7. The drop-on-demand inkjet recording device according to claim 1, wherein the ejection means includes a plurality of nozzles each including a piezoelectric element, and the print-driving signal and the maintenance-driving signal are selectively applied to the piezoelectric element of all the nozzles.
  • 8. The drop-on-demand inkjet recording device according to claim 7, further comprising an ejection signal generation means for generating a print-ink ejection signal based on which the print-driving signal is selectively applied to the piezoelectric element, and also generating a refresh-ink ejection signal based on which the maintenance-driving signal is selectively applied to the piezoelectric element.
  • 9. The drop-on-demand inkjet recording device according to claim 8, further comprising an address counter that repeatedly counts line addresses, wherein the ejection signal generation means generates the refresh-ink ejection signal based on a counter value of the address counter.
  • 10. The drop-on-demand inkjet recording device according to claim 8, wherein the ejection signal generation means generates a print-ink ejection signal based on at least one of humidity of ambient air and a print signal.
  • 11. The drop-on-demand inkjet recording device according to claim 7, wherein the drive signal generation means generates a plurality of maintenance-driving signals having different voltages one at a time, and each maintenance-driving signal is applied to a corresponding one of the nozzles.
  • 12. The drop-on-demand inkjet recording device according to claim 1, wherein the driving signal generation means generates the print-driving signal and the maintenance-driving signal in alternation.
  • 13. The drop-on-demand inkjet recording device according to claim 1, wherein the ejection means is a drop-on-demand inkjet head that selectively ejects ink droplets based on the print-driving signal.
  • 14. A drop-on-demand inkjet recording device comprising:an ejection means for ejecting ink droplets; and a driving signal generation means for generating a print-driving signal and a maintenance-driving signal, wherein the ejection means selectively ejects print ink droplets as the ink droplets based on the print-driving signal, and the ejection means performs maintenance operations based on the maintenance-driving signal, and wherein the print ink droplets reach a recording medium to form dots on the recording medium, wherein the print-driving signal is repeatedly generated at a predetermined time interval, and the maintenance-driving signal is generated at a timing between two successive print-driving signals.
  • 15. The drop-on-demand inkjet recording device according to claim 14, further comprising an electric-field generation means for generating an electric field, and a collecting means, whereinthe maintenance-driving signal is one of a refresh-driving signal and a vibration-driving signal; the ejection means selectively ejects a refresh ink droplet based on the refresh-driving signal, and performs ink vibration based on the vibration-driving signal; the electric field deflects the refresh ink droplets; and the collecting means collects the deflected refresh ink droplets.
Priority Claims (1)
Number Date Country Kind
P2001-288103 Sep 2001 JP
US Referenced Citations (4)
Number Name Date Kind
5278582 Hongo Jan 1994 A
5563634 Fujii et al. Oct 1996 A
RE37862 Hertz et al. Oct 2002 E
6494555 Ishikawa Dec 2002 B1
Foreign Referenced Citations (2)
Number Date Country
57-61576 Apr 1982 JP
9-29996 Feb 1997 JP