This invention relates generally to inkjet printing and more particularly to controlling back pressure in inkjet printing systems.
Inkjet printing technology is used in many commercial products such as computer printers, graphics plotters, copiers, and facsimile machines. One type of inkjet printing known as “drop on demand” employs a pen that ejects drops of ink onto a print medium such as a sheet of paper. The pen is typically mounted to a reciprocating carriage that traverses back-and-forth across the print medium. As the pen is moved repeatedly across the print medium, it is activated under command of a controller to eject drops of ink at appropriate times. With proper selection and timing of the drops, the desired pattern is obtained on the print medium.
The pen includes a drop-generating device known as a printhead, which has a plurality of nozzles or orifices through which the drops of ink are ejected. Adjacent to each nozzle is a firing chamber that contains the ink to be ejected through the nozzle. Ejection of an ink drop through a nozzle may be accomplished using any suitable ejection mechanism, such as thermal bubble or piezoelectric pressure wave to name a few. Ink is delivered to the firing chambers from an ink feed hole that is in fluid communication with an ink supply. The ink supply can be wholly contained within the pen body to form a print cartridge. Such an ink supply is considered to be “on-board.” In other cases, the ink supply can comprise an internal chamber that is fluidly coupled to a remote ink reservoir via one or more ink transfer conduits. These particular systems are conventionally known as “off-axis” printing units.
With drop on demand printing systems, a slight back pressure (i.e., a less-than-atmospheric or negative gauge pressure) is established within the printhead so that ink will be retained until deliberately ejected. The back pressure is set to be sufficient to prevent ink from leaking or “drooling” out of the nozzles between periods of active ink ejection but not so great so as to draw air into the printhead through the nozzles or to impede the rapid refilling of ink into the firing chambers. Printheads often include a pressure regulator that functions to maintain a preset back pressure.
It is often desirable to enable a printing system to operate in a variety of “print modes.” A print mode is the set of operating parameters, including the maximum drop firing frequency and printhead scanning method, that define a particular printing process. For instance, high frequency, single-pass, bi-directional printing is the fastest print mode but can be sensitive to missing or misdirected nozzles, ink bleed, and the like. Thus, for some print jobs, it may be desirable to select a slower print mode (e.g., a low frequency, multi-pass mode) to improve print quality. Print modes are generally chosen on a job-by-job basis depending on factors such as print media selection, content to be printed and desired print quality, but print modes can also be changed on a page-by-page, or even line-by-line, basis based on local content changes within the printed page.
The maximum drop firing frequency of,a printhead design depends on how rapidly the firing chamber can be refilled after a drop is ejected. The faster the chamber can be refilled, the sooner another drop can be ejected through the nozzle. As the firing chamber is filled with liquid ink, the ink forms a meniscus in the corresponding nozzle. The meniscus behaves like a naturally damped membrane that seeks equilibrium undergoing simple harmonic oscillations. At equilibrium, a constant volume of ink is present. However, before equilibrium is reached (i.e., while the meniscus is still oscillating), the ink volume will also be oscillating. Thus, if the firing frequency is such that drops are being ejected while the meniscus is oscillating, the drops can vary in weight and velocity. Additionally, the shape of an ejected drop and how quickly it breaks up into smaller drops will change as the meniscus position changes. For example, if a drop is ejected when the meniscus is on a maximum excursion (bulging out), the resulting drop will have a higher drop weight and a lower drop velocity. Such drop variation results in print quality issues. Damping, or reducing the fluidic natural frequency of the design, can reduce meniscus oscillations and drop variation problems but will result in a lower maximum firing frequency. Pen architecture designs optimized for high frequency performance are under-damped to allow for refill at high flow rates. However, such designs will experience significant meniscus overshoot, oscillation and drop size and shape variation when operating at mid-level frequencies. One solution has been to simply avoid print modes that use firing frequencies residing in the maximum overshoot frequency range. However, this severely restricts the ability to select from a wide range of print modes.
In one embodiment, the present invention provides a method of inkjet printing in a number of distinct print modes. The method includes providing a printhead and supplying ink to the printhead. The method further includes establishing a back pressure corresponding to a desired print mode in the printhead and changing the back pressure in response to a change in print mode.
In another embodiment, the present invention provides a printing system comprising an ink supply and a printhead having a plurality of ink ejection nozzles fluidly connected to the ink supply. The printing system includes means for controlling meniscus condition (i.e., meniscus overshoot and/or meniscus location) in the nozzles by selectively changing back pressure in the printhead.
In yet another embodiment, the present invention provides a printing system capable of operating in a number of distinct print modes. The printing system includes an ink supply and an inkjet pen including a printhead in fluid communication with the ink supply. Also provided is a means for setting back pressure in the printhead. The back pressure is set to a first value when the printing system is operating in a first print mode to a second value when the printing system is operating in a second print mode.
In still another embodiment, the present invention provides an inkjet pen having a body defining an ink reservoir and a printhead mounted to an outer surface of the body in fluid communication with the ink reservoir. A back pressure control unit having multiple back pressure settings is located in the body.
The present invention and its advantages over the prior art will be more readily understood upon reading the following detailed description and the appended claims with reference to the accompanying drawings.
The subject matter that is regarded as the invention is particularly pointed out and distinctly claimed in the concluding part of the specification. The invention, however, may be best understood by reference to the following description taken in conjunction with the accompanying drawing figures in which:
Referring to the drawings wherein identical reference numerals denote the same elements throughout the various views,
The internal reservoir 22 of the pen 12 receives ink from the ink supply 14 via the back pressure control unit 16. The ink supply 14 is preferably, although not necessarily, pressurized. The back pressure control unit 16 operates to change and selectively set the back pressure in the reservoir 22, and thus in the printhead 24. That is, the back pressure control unit 16 supplies ink to the reservoir 22 at a selected pressure so as to establish the desired back pressure in the reservoir 22 and the printhead 24. To this end, the back pressure control unit 16 includes two pressure chambers 26 and 28. The first pressure chamber 26 is provided with a first pressure regulator 30 calibrated to a first back pressure set point, and the second pressure chamber 28 is provided with a second pressure regulator 32 calibrated to a second back pressure set point. For instance, the first pressure chamber 26 could be set at a gauge pressure of negative 4.5 inches of water, and the second pressure chamber 28 could be set at a gauge pressure of negative 12 inches of water gauge pressure. The first and second pressure regulators 30 and 32 are fluidly connected to the ink supply 14 via an ink supply conduit 34 and operate to admit ink into the corresponding pressure chamber when the pressure in that chamber falls below its set point.
The back pressure control unit 16 further includes a diverter valve 36 connected to the first pressure chamber 26 by a first conduit 38 and connected to the second pressure chamber 28 by a second conduit 40. The diverter valve 36 is also connected to the reservoir 22 by an ink feed conduit 42. The valve 36 is operated under control of the controller 18 to selectively place the reservoir 22 in fluid communication with either one of the two pressure chambers 26 and 28, thereby establishing a back pressure in the reservoir 22 and the printhead 24 that corresponds to the pressure of the selected pressure chamber. Thus, the back pressure control unit 16 provides two different back pressure settings. While the illustrated embodiment shows two pressure chambers for providing two different back pressure settings, it should be noted that the back pressure control unit 16 could include more than two pressure chambers for providing more than two different back pressure settings.
In operation, the performance of the printing system 10 can be adjusted real-time depending on the printing application at hand. For example, the back pressure control unit 16 can set the back pressure in the printhead 24 to a first value when the printing system 10 is operating in a first print mode and to a second value when the printing system 10 is operating in a second print mode. In other words, the back pressure in the printhead 24 can be increased or decreased to adjust printing system performance to different printing modes. Print modes can be changed on a job-by-job basis (i.e., between print jobs) or on a page-by-page, or even line-by-line, basis (i.e., during print jobs).
Changing back pressure in the printhead 24 at a given frequency can affect printing system performance because the change in back pressure will have an effect on the degree of meniscus overshoot. Namely, using a greater back pressure produces a more damped system with less meniscus overshoot. (Note that as used herein, “greater back pressure” means a more negative gauge pressure, and thus a lower pressure value, while “lesser back pressure” means a less negative gauge pressure, and thus a higher pressure value.) Changing back pressure can also affect the meniscus location (i.e., the position of the meniscus in the nozzle). Accordingly, as used herein “controlling meniscus condition” refers to controlling meniscus overshoot and/or meniscus location.
An example of how different back pressures can affect performance for two print modes having different firing frequencies is illustrated graphically in
This active control of back pressure allows system performance to be optimized for a number of print modes with a single pen design. Lower back pressure levels provide under-damped performance that maximizes printing speed for fast or draft modes. Although sacrificing speed, higher back pressure minimizes meniscus overshoot, thereby minimizing puddling and directionality errors and is therefore ideal for best mode printing. If more than two back pressure settings are available, intermediate levels of back pressure can be used to optimize printing at all modes in between these extremes. Active control of back pressure can also be used to modulate the drop weight the pen delivers at a given frequency (in some instances it is desirable to provide different drop weights) and allow for system tuning when different rheology (viscosity, surface tension, etc.) inks are to be used with the same printhead architecture.
The internal reservoir 56 receives ink from the ink supply 48 via the back pressure control unit 50. The ink supply 48 is preferably, although not necessarily, pressurized. The back pressure control unit 50 operates to change and selectively set the back pressure in the reservoir 56, and thus in the printhead 58. That is, the back pressure control unit 50 supplies ink to the reservoir 56 at a selected pressure so as to establish the desired back pressure in the reservoir 56 and the printhead 58. In this embodiment, the back pressure control unit 50 includes a single pressure chamber 62 maintained at a variable back pressure, a pump 64, and an ink return staging tank 66. The pump 64, which can be a viscous effect pump, is arranged to pump ink from the pressure chamber 62 through a first conduit 68, thereby lowering pressure (i.e., increasing back pressure) in the pressure chamber 62. Ink removed from the pressure chamber 62 by the pump 64 is fed to the ink return staging tank 66 by a second conduit 70. Ink in the ink return staging tank 66 is delivered to the ink supply 48 via a third conduit 72. When needed, ink is fed from the ink supply 48 to the pressure chamber 62 via an ink supply conduit 74. The pressure chamber 62 is connected to the reservoir 56 by an ink feed conduit 76. A pressure sensor 78 is provided for detecting the pressure in the pressure chamber 62 and providing a signal thereof to the controller 52.
The back pressure control unit 50 further includes first, second and third control valves 80, 82, 84 that are used in conjunction (under command of the controller 52) to control ink flow and regulate back pressure in the pressure chamber 62. The first control valve 80 is positioned in the ink feed conduit 76 between the pressure chamber 62 and the reservoir 56, the second control valve 82 is positioned in the first conduit 68 between the pressure chamber 62 and the pump 64, and the third control valve 84 is positioned in the ink supply conduit 74 between the pressure chamber 62 and the ink supply 48.
With this arrangement, the back pressure control unit 50 will function to maintain the back pressure in the printhead 58 at the desired setting. As the printhead 58 consumes ink, more ink will be fed to the printhead 58 from the pressure chamber 62 because the first control valve 80will be open while the system is actively printing. In response, the controller 52 will open the third control valve 84 so to deliver an appropriate replacement volume of ink to the pressure chamber 62 from the ink supply 48, and thereby maintain the back pressure in the pressure chamber 62 at the desired level as sensed by the pressure sensor 78. When it is desired to change the back pressure in the printhead 58, the controller 52 will operate the control valves and the pump 64 as needed to effect the desired change. To increase back pressure, the second control valve 82 will be opened and the pump 64 will be activated to remove ink from the pressure chamber 62 and thereby increase back pressure. When the new desired back pressure is reached, this will be detected by the pressure sensor 78, and the controller 52 will inactivate the pump 64. To decrease back pressure, the third control valve 84 will be opened to allow ink from the ink supply 48 to flow into pressure chamber 62, thereby decreasing the back pressure. The pressure sensor 78 will detect when the desired back pressure is attained, and the controller 52 will then cause the third control valve 84 to be shut. Thus, the back pressure control unit 50 provides a wide range of possible back pressure settings.
In the printing system embodiments described above, the back pressure control unit is located remote from the pen. Having the pressure control mechanism located off-axis reduces pen module cost, thereby reducing customer supply costs. However, it is also possible to provide an inkjet printing system in which means for controlling back pressure are included with the pen.
The back pressure control unit 88 includes first and second air bags or “bagophragms” 108 and 110 situated within a U-shaped frame 112 mounted inside the pen body 90. The air bags 108 and 110 are preferably made of a thin, high-barrier material that is flexible and non-elastic. The first air bag 108 is vented to the atmosphere outside of the pen body 90 through first tubing 114 and a first air vent 116 formed in the pen body 90. The second air bag 110 is vented to the atmosphere outside of the pen body 90 through second tubing 118 and a second air vent 120 formed in the pen body 90. First and second sliding air seals 122 and 124 are provided on the outer surface of the pen body 90 for selectively closing the air vents 116 and 120, respectively. The air seals 122 and 124 operate so that only one of the two air bags 108, 110 at a time is vented to atmosphere. In other words, when the first air bag 108 is vented, the second air bag 110 is closed (as shown in
The back pressure control unit 88 further includes a T-shaped valve lever 126 pivotally mounted inside the pen body 90. The valve lever 126 includes a moment arm 128, a first sealing arm 130 supporting a first ink seal 132, and a second sealing arm 134 supporting a second ink seal 136. The first and second ink seals 132, 136 are preferably made of an elastomer material. The valve lever 126 is mounted to pivot about a pivot axis 138 located at the intersection of the three arms 128, 130, 134. The moment arm 128 is positioned between the first and second air bags 108 and 110, and the first and second sealing arms 130, 134 extend outwardly in opposite directions from the upper end of the moment arms 128 so as to position the first and second ink seals 132, 136 against the first and second ink inlets 100 and 102, respectively, when the valve lever 126 is in its central, equilibrium position as illustrated in
During operation, the ink level in the reservoir 92 will drop as ink is ejected from the nozzles 96, resulting in a drop in ink pressure (i.e., an increase in back pressure). With the first air vent 116 open, as shown in
The back pressure control unit 88 is configured so that each air bag has a different set point or preset pressure level at which ink will be admitted into the reservoir 92. Specifically, the geometry of the back pressure control unit 88 (e.g., the size of the air bags 108, 110 and the relative positions of the air bags 108, 110, the frame 112 and the valve lever 126) is such that there will be two different set points so that the pen 86 will have two different back pressure settings. Which back pressure setting is selected is determined by which one of the two air vents 116 and 120 is open.
Referring to
The back pressure control unit 142 includes first and second air bags or “bagophragms” 162 and 164 and a frame 166 mounted inside the pen body 144. The frame 166 has a first column 168 abutting the first air bag 162 and a second column 170 abutting the second air bag 164. The first air bag 162 is vented to the atmosphere outside of the pen body 144 through first tubing 172 and a first air vent 174 formed in the pen body 144. The second air bag 164 is vented to the atmosphere outside of the pen body 144 through second tubing 176 and a second air vent 178 formed in the pen body 144. First and second sliding air seals 180 and 182 are provided on the outer surface of the pen body 144 for selectively closing the air vents 174 and 178, respectively. The air seals 180 and 182 operate so that only one of the two air bags 162 and 164 at a time is vented to atmosphere. In other words, when the first air bag 162 is vented, the second air bag 164 is closed (as shown in
The back pressure control unit 142 further includes first and second L-shaped valve levers 184 and 186 pivotally mounted inside the pen body 144. The first valve lever 184 includes a first moment arm 188 and a first sealing arm 190 that supports a first ink seal 192. The first valve lever 184 is mounted to pivot about a first pivot axis 194 located at the intersection of the first moment arm 188 and the first sealing arm 190. The first air bag 162 is positioned between the first moment arm 188 and the first column 168, and a first spring 196 is connected between the first moment arm 188 and the first column 168. The first sealing arm 190 extends from the upper end of the first moment arm 188 so as to position the first ink seal 192 against the first ink inlet 154 when the first valve lever 184 is in its central, equilibrium position as illustrated in
During operation, the ink level in the reservoir 146 will drop as ink is ejected from the nozzles 150, resulting in a drop in ink pressure (i.e., an increase in back pressure). With the first air vent 174 open, as shown in
The back pressure control unit 142 is configured so that each air bag has a different set point or preset pressure level at which ink will be admitted into the reservoir 146. Specifically, the geometry of the back pressure control unit 142 (e.g., the size of the air bags 162, 164 and the relative positions of the air bags 162, 164, the columns 168, 170 and the valve levers 184, 186) is such that there will be two different set points so that the pen 140 will have two different back pressure settings. Which back pressure setting is selected is determined by which one of the two air vents 174 and 178 is open.
In this embodiment, the back pressure control unit 210 includes a bubble generator cylinder 230 rotatively mounted in a bottom wall 228 of the pen body 212. As seen in
In operation, as the printhead 224 ejects ink drops, the depletion of ink from the reservoir 214 decreases the pressure therein (i.e., increases back pressure). When the back pressure in the reservoir 214 reaches a threshold value, it is sufficient to draw an air bubble through the active bubble generator orifice. This pressure is termed the “bubble pressure” and is principally dependent on the diameter of the active orifice and the viscosity of the ink. (Back pressures smaller than the bubble pressure are insufficient to overcome the surface tension at the ink/air interface and thus are unable to draw bubbles through the active bubble generator orifice.) The introduction of an air bubble through the active bubble generator orifice into the reservoir 214 lowers the back pressure in the reservoir 214 (and thus in the printhead 220) below the threshold value momentarily, until continued ejection of ink again brings it to the bubble pressure and another bubble is introduced. Continued printing results in the periodic introduction of bubbles, causing the volume of air in the reservoir 214 to increase. During this “steady state” printing condition, the back pressure in the reservoir 214 oscillates in a closely bounded range about the bubble pressure. By providing orifices of different diameters, the back pressure control unit 210 is thus able to selectively set the back pressure in the reservoir 214 and the printhead 220 to one of three possible back pressure settings. While the illustrated example provides three back pressure settings, it should be noted that additional back pressure settings could be made available by providing additional orifices of different diameters.
While specific embodiments of the present invention have been described, it will be apparent to those skilled in the art that various modifications thereto can be made without departing from the spirit and scope of the invention as defined in the appended claims. Other embodiments for providing back pressure modulation are possible. For instance, back pressure modulation could also be accomplished with an inkjet pen with two or more different foam chambers having different pressures or two or more different banks of supplies having different pressures.
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